Hostname: page-component-7c8c6479df-24hb2 Total loading time: 0 Render date: 2024-03-29T08:33:10.895Z Has data issue: false hasContentIssue false

Sustainable life support on Mars – the potential roles of cyanobacteria

Published online by Cambridge University Press:  03 August 2015

Cyprien Verseux*
Affiliation:
Department of Biology, University of Rome Tor Vergata, Rome, Italy NASA EAP Associate, NASA Ames Research Center, Moffett Field, California, USA
Mickael Baqué
Affiliation:
Department of Biology, University of Rome Tor Vergata, Rome, Italy
Kirsi Lehto
Affiliation:
Department of Plant Physiology and Molecular Biology, University of Turku, Turku, Finland
Jean-Pierre P. de Vera
Affiliation:
German Aerospace Center (DLR), Institute of Planetary Research, Berlin, Germany
Lynn J. Rothschild
Affiliation:
Earth Sciences Division, NASA Ames Research Center, Moffett Field, California, USA
Daniela Billi
Affiliation:
Department of Biology, University of Rome Tor Vergata, Rome, Italy
Rights & Permissions [Opens in a new window]

Abstract

Even though technological advances could allow humans to reach Mars in the coming decades, launch costs prohibit the establishment of permanent manned outposts for which most consumables would be sent from Earth. This issue can be addressed by in situ resource utilization: producing part or all of these consumables on Mars, from local resources. Biological components are needed, among other reasons because various resources could be efficiently produced only by the use of biological systems. But most plants and microorganisms are unable to exploit Martian resources, and sending substrates from Earth to support their metabolism would strongly limit the cost-effectiveness and sustainability of their cultivation. However, resources needed to grow specific cyanobacteria are available on Mars due to their photosynthetic abilities, nitrogen-fixing activities and lithotrophic lifestyles. They could be used directly for various applications, including the production of food, fuel and oxygen, but also indirectly: products from their culture could support the growth of other organisms, opening the way to a wide range of life-support biological processes based on Martian resources. Here we give insights into how and why cyanobacteria could play a role in the development of self-sustainable manned outposts on Mars.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2015 

Introduction

Sending humans to Mars within a few decades is now a realistic goal (e.g., Baker & Zubrin Reference Baker and Zubrin1990; Horneck et al. Reference Horneck2006; Drake Reference Drake2009; Zubrin & Wagner Reference Zubrin and Wagner2011). However, even though leaving a footprint and planting a flag could be achieved with not much more than the current state-of-the-art of engineering, a definite pay-back is still in doubt. On the other hand, if a Mars mission can allow extensive human scientific activity and yield meaningful scientific data, the effort is justified. In such a case, scientists will need to spend a considerable period on site, and multiple short-term missions are not a viable option. Given the time, costs and challenges associated with the journey, long-term human bases will likely be needed.

But while the vision of long-term human presence on Mars is compelling, providing consumables to sustain crews is a challenge. Even though launch costs vary depending on mission scenarios and might be reduced in the coming decades, they have been estimated to be in the order of $300 000 kg−1 (Massa et al. Reference Massa, Emmerich, Morrow, Bourget and Mitchell2007). Sending from Earth all the needed resources does not seem financially sustainable. Should Mars colonization be consequently deemed too expensive to be realistic? Maybe not. There are alternatives.

One is recycling – using regenerative systems. Such systems should have biology-based components: various life-support functions can be provided by physicochemical processes, but some valuable products such as high-protein food cannot currently be produced by the latter (Drysdale et al. Reference Drysdale, Ewert and Hanford2003; Montague et al. Reference Montague, McArthur, Cockell, Held, Marshall, Sherman, Wang, Nicholson, Tarjan and Cumbers2012). In addition, many components of physicochemical life-support systems are heavy, highly energy-consuming and/or require high temperatures. Even in the case where these are the backbones of life-support systems, biological modules could both complement them and provide safe redundancies. Consequently, various bioregenerative life-support systems (BLSS) are or have been under development for recycling food, water and gases both in space (e.g., Godia et al. Reference Godia, Albiol, Montesinos and Pérez2002; Gitelson et al. Reference Gitelson, Lisovsky and MacElroy2003; Drysdale et al. Reference Drysdale, Rutkze, Albright and LaDue2004; Lobascio et al. Reference Lobascio, Lamantea, Cotronei, Negri, De Pascale, Maggio, Foti and Palumberi2007; Nelson et al. Reference Nelson, Pechurkin, Allen, Somova, Gitelson, Wang, Ivanov, Tay and Hung2010; Giacomelli et al. Reference Giacomelli2012) and within lunar and Martian outposts (e.g., Gitelson Reference Gitelson1992; Blüm et al. Reference Blüm, Gitelson, Horneck and Kreuzberg1994; Tikhomirov et al. Reference Tikhomirov, Ushakova, Kovaleva, Lamaze, Lobo and Lasseur2007; Nelson et al. Reference Nelson, Pechurkin, Allen, Somova, Gitelson, Wang, Ivanov, Tay and Hung2010). This may sound promising: instead of sending resources in amounts almost proportional to the mission length, only a few weeks’ worth of consumables would be sent and recycled. The issue is: 100% recycling efficiency cannot be reached and losses are unavoidable. For quantitative information regarding the theoretical recycling efficiencies of the Micro-Ecological Life Support System Alternative (MELiSSA), for example, see Poughon et al. (Reference Poughon, Farges, Dussap, Godia and Lasseur2009).

A regenerative system's running time without re-supply is consequently limited. It also cannot be expanded, as the mass of cycling components is, at a given time, at most equal to their initial mass. In addition to this, most current BLSS projects represent a large initial volume and mass, as well as a high power consumption. For instance, the mass of consumables needed to sustain a crew of 6 using the MELiSSA system has been assessed to be about 30 metric tons (mt), hygiene water not included, for a 1000-day mission (Langhoff et al. Reference Langhoff, Cumbers, Rothschild, Paavola and Worden2011). Re-supply is thus needed and the most advanced BLSS projects heavily depend on materials imported from Earth – although a theoretical physicochemical/biological resource production system relying on Martian resources has recently been patented (Cao et al. Reference Cao, Concas, Corrias, Licheri, Orru’ and Pisu2014). These projects are consequently not suitable for autonomous, long-term human bases on Mars: the mass problem is reduced, but not solved.

There is however a promising solution: producing resources from local materials. Like all human settlers of previous generations, the Martian pioneers must ‘live off the land’. A critical question this fact raises is whether it is possible to feed biological systems with local resources. On the one hand, water (H2O), solar energy, carbon (C), nitrogen (N) and many other life-supporting nutrients are found on Mars (Meyer & McKay Reference Meyer and McKay1989; Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010; Cockell Reference Cockell2014). But on the other hand, they cannot be directly exploited in the form in which they are found there by key organisms of current BLSS projects. This limitation may lead one to think that BLSS based on local resources are irrelevant for Mars exploration. What if, however, Martian resources could be exploited and processed into suitable forms by an additional biological module? What if there was a biological link between on-site resources and BLSS? This link might be created by cyanobacteria. All the inputs needed to sustain a diazotrophic (N-fixing), bioleaching cyanobacterium's metabolism could in theory be obtained from Mars's mineral resources, water, atmospheric gases and incident solar energy. Firstly, some (e.g., Anabaena spp. and various desert species) have the ability to extract and biologically fix nutrients from analogues of Martian rocks (Brown & Sarkisova Reference Brown and Sarkisova2008; Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010). Owing to these abilities and to their useful products, cyanobacteria have already been suggested as a basis for creating planetary BLSS relying on local resources (Brown Reference Brown2008a; Brown et al. Reference Brown, Garrison, Jones, Allen, Sanders, Sarkisova and McKay2008; Stanford-Brown 2011 iGEM team 2011). They are also able to fix C from carbon dioxide (CO2) and some species can fix N from dinitrogen (N2), both of which are found in the Martian atmosphere, leading to organic matter and dioxygen (O2) production without dependency on carbohydrate feedstock. Some species are highly tolerant to extreme environments (e.g., Rothschild & Mancinelli Reference Rothschild and Mancinelli2001); consequently their culture is less demanding in terms of hardware than that of more environmentally sensitive microbial species. Cyanobacteria could be used directly to produce resources such as food and O2, but products from their cultures could also be used to feed other living organisms, so opening the way to a wide range of life-support biological processes.

Cyanobacteria could thus provide the key link between BLSS and Martian resources, making the former sustainable and expandable in human bases on Mars. An artist's rendering of such a cyanobacterium-based BLSS (‘CyBLiSS’) is given in Fig. 1. The present paper is not intended as a specific mission design, but rather as an overview of how and why cyanobacteria could be grown on Mars. We first outline their potential applications there. Then we discuss the associated challenges and possible ways of facing them. Finally, we outline the research efforts needed to design functional, cyanobacterium-based BLSS for human outposts on Mars. A summary of this paper's contents is given in Fig. 2.

Fig. 1. Artist's rendering of a cyanobacterium-based biological life-support system on Mars. Figure design: Cyprien Verseux and Sean McMahon (Yale University). Layout: Sean McMahon.

Fig. 2. Visual table of contents.

Potential roles of cyanobacteria in Mars-specific BLSS

Feeding other microorganisms

Heterotrophic microorganisms have been used throughout human history and would be highly useful on Mars. Potential applications include the production of drugs, food, biomaterials and various industrially useful chemicals, metal leaching and food processing for taste improvement (Cumbers & Rothschild Reference Cumbers and Rothschild2010; Langhoff et al. Reference Langhoff, Cumbers, Rothschild, Paavola and Worden2011; Montague et al. Reference Montague, McArthur, Cockell, Held, Marshall, Sherman, Wang, Nicholson, Tarjan and Cumbers2012; Menezes et al. Reference Menezes, Cumbers, Hogan and Arkin2014; Verseux et al. Reference Verseux, Paulino-Lima, Baqué, Rothschild, Billi, Hagen, Engelhard and Toepfer2016). As most of these applications require relatively small culture volumes and no solar light, cultures could be performed under Earth-like conditions with reasonable costs. However, heterotrophic microorganisms rely on organic materials whose availability on Mars remain very poorly known and are not expected to be abundant there (Ming et al. Reference Ming2014). Could the local resources be processed into suitable substrates by cyanobacteria? Related phenomena naturally occur on Earth, where cyanobacteria are known to support different heterotrophic communities. They can for instance be the earliest colonizers of desert habitats and allow the development of local ecosystems (including heterotrophic bacteria) through the production of organic compounds, N fixation and rock leaching (e.g., Eldridge & Greene Reference Eldridge and Greene1994; Danin et al. Reference Danin, Dor, Sandler and Amit1998; Herrera et al. Reference Herrera, Cockell, Self, Blaxter, Reitner, Thorsteinsson, Arp, Dröse and Tindle2009). In aquatic ecosystems as well, cross-feeding and metabolite exchange occur between cyanobacteria and heterotrophic microorganisms (see, for instance, Stevenson & Waterbury Reference Stevenson and Waterbury2006 and Beliaev et al. Reference Beliaev2014).

The question of water is addressed in subsection ‘Water’. Heterotrophic organisms also need, first of all, organic compounds as a source of C and energy. Lysed cyanobacterial biomass could be used as such (and as a source of other critical macronutrients such as hydrogen [H], oxygen [O], phosphorus [P] and sulphur [S]; for N, see the following paragraph). Consistently, a filtrate of grinded Anabaena sp. PCC7120 (100 mg of dried biomass ml−1 before filtration) has been used as the only source of organic compounds and fixed N to grow Escherichia coli K-12 MG1655 in phosphate-buffered saline, reaching more than 109 cells ml−1 within 24 h (Verseux, unpublished data). Note that these results are preliminary and that no optimization step (e.g., choice of a strain that can metabolize sucrose, alteration of culture conditions to modify cyanobacterial biomass's composition and/or more efficient extraction method) has yet been performed. Lysed cyanobacterial biomass has also been shown to be a suitable substrate for ethanol production in yeasts (Aikawa et al. Reference Aikawa, Joseph, Yamada, Izumi, Yamagishi, Matsuda, Kawai, Chang, Hasunuma and Kondo2013; Möllers et al. Reference Möllers, Cannella, Jørgensen and Frigaard2014). In lysogeny broth (LB), the most common growth medium for heterotrophic bacteria in laboratories, the concentration of fermentable sugars and sugar equivalents (sugar phosphates, oligosaccharides, nucleotides, etc.) utilizable by E. coli is very low (<100 µM), constraining bacteria to use amino acids as C sources (McFall & Newman Reference McFall, Newman, Neidhardt, Curtiss, Ingraham, Lin, Low, Magasanik, Reznikoff, Riley, Schaechter and Umbarger1996; Sezonov et al. Reference Sezonov, Joseleau-Petit and D'ari2007). However, non-destructive ways of harvesting nutrients could lead to more efficient processes. Substrates could for instance be secreted. This solution has been investigated in Lynn Rothschild's laboratory (at NASA Ames Research Center, Moffett Field, CA) since the 2011 Stanford-Brown iGEM team engineered Anabaena sp. PCC7120 to secrete sucrose (Stanford-Brown 2011 iGEM team 2011), which was then used as a C source to grow Bacillus subtilis (Ryan Kent et al., unpublished data). Prior to this, Synechococcus elongatus PCC7942 was engineered to produce and secrete either glucose and fructose, or lactate, then used as a substrate for E. coli (Niederholtmeyer et al. Reference Niederholtmeyer, Wolfstädter, Savage, Silver and Way2010). In this kind of system, a major limitation arises from low sugar yields, which are due to relatively low synthesis rates and to the consumption of sugars by the cyanobacteria themselves. Production rates could be increased by further genetic engineering to either increase synthesis or decrease processing of these products by the producer strains. External conditions could also be modified; for instance, osmotic stress induces sucrose accumulation in many cyanobacteria, especially when synthesis of other osmoprotectants is impaired (Miao et al. Reference Miao, Wu, Wu and Zhao2003).

Then, fixed N is needed. Heterotrophic bacteria can obtain N from various organic and inorganic sources such as single amino acids (e.g., Crawford et al. Reference Crawford, Hobbie and Webb1974) and amino acid chains (e.g., Hollibaugh & Azam Reference Hollibaugh and Azam1983; Coffin Reference Coffin1989), nucleic acids (Paul et al. Reference Paul, Jeffrey, David, Deflaun and Cazares1989) and ammonium (NH4 +). Diazotrophic cyanobacteria can produce all these compounds after N fixation and, here again, a simple way of making this N available to heterotrophic bacteria is to lyse cyanobacteria. But NH4 + can be naturally released by some diazotrophic cyanobacteria, without cell lysis; for instance, extracellular NH4 + can reach several mM in cultures of Anabaena spp. (mutants or wild-type, depending on species) relying on atmospheric N2 as a sole N source (Spiller et al. Reference Spiller, Latorre, Hassan and Shanmugam1986; Subramanian & Shanmugasundaram Reference Subramanian and Shanmugasundaram1986). NH4 + is the preferred N source for most microorganisms and becomes limiting at extremely low concentrations (e.g., below a few μM for E. coli; see Kim et al. Reference Kim, Zhang, Okano, Yan, Groisman and Hwa2012), several orders of magnitudes below the above-mentioned concentrations. Released NH4 + could be used for feeding not only heterotrophic microorganism, but also some phototrophic species of interest which cannot fix N. Within the MELiSSA loop (e.g., Godia et al. Reference Godia, Albiol, Montesinos and Pérez2002), NH4 + (there resulting from human and plant waste processing by thermophilic anaerobic bacteria) is converted into nitrates by nitrifying bacteria before being transferred to Arthrospira sp. cultures. Even though nitrate is considered the preferred N source for this species (as for most non-N fixing filamentous cyanobacteria), using NH4 + instead of nitrates has been shown not to reduce growth rates (Filali et al. Reference Filali, Lasseur and Dubertret1997). A drawback is that NH4 + becomes growth-limiting from relatively low concentrations (a few mM) and should consequently, if limiting below these concentrations, be regularly (or continuously) added to the culture medium. Semi-separated cultures, where cyanobacteria's and heterotrophic microorganisms’ culture vessels communicate through membranes that allow medium but not cell exchange, can also be considered. In such a case, extensive system characterization is needed to predict outputs, and processes could be optimized by improving the culture setup and by performing evolutionary selection of the co-culture to improve metabolic interactions. In any case, the rates of NH4 + release by strains of interest under Mars-like constraints, as well as the use of this NH4 + as an N source for non-N fixers, should be further investigated.

Many heterotrophic microorganisms also need O2. E. coli, for example, roughly needs 1 g of O2 per gram of dry weight (gdw) (Shiloach & Fass Reference Shiloach and Fass2005). O2 consumption and cell mass vary according to strain and cultures conditions, but this figure corresponds to approximately 1 g of O2 l−1 to reach a culture of 2 × 109 cells ml−1. Cyanobacteria produce O2 through photosynthesis; details are given in subsection ‘Producing oxygen’.

Finally, metals must be provided. Some (macronutrients) are needed in relatively large amounts; these are mostly potassium (K), magnesium (Mg) and iron (Fe) and, for some species, sodium (Na) and calcium (Ca). Others (micronutrients) are needed in trace amounts by some microorganisms and include, for instance, chromium (Cr), manganese (Mn), nickel (Ni) and zinc (Zn) (Madigan et al. Reference Madigan, Martinko and Parker2000). As an example, E. coli needs about 108 atoms cell−1 of K and Mg; 105 atoms cell−1 of Ca, Zn and Fe; and 104 atoms cell−1 of Mn, molybdenum (Mo) and selenium (Se) (Finney & O'Halloran Reference Finney and O'Halloran2003). All the needed elements seem to be present in Martian regolith (Cockell Reference Cockell2014), but some of them may be poorly available to most organisms with no leaching abilities. However, rock-dwelling cyanobacteria can extract metal nutrients from a wide range of rocks (see Olsson-Francis et al. Reference Olsson-Francis, Simpson, Wolff-Boenisch and Cockell2012). Besides mobilizing them in their own cells, they help release them in the aqueous phase, increasing their concentration there (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010; Olsson-Francis et al. Reference Olsson-Francis, Simpson, Wolff-Boenisch and Cockell2012) and availability for non-leaching organisms. Anabaena cylindrica has for instance been shown to release elements including K, Mg, Na, Ca, Fe, Mn, Ni and Zn from a Mars basalt analogue (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010). The metals needed in highest amounts by E. coli, namely K and Mg, reached concentrations of 125 and 55 µM, respectively, in large excess compared with E. coli's needs (roughly, 0.3 µM to reach 2 × 109 cells ml−1). Even though lysing cyanobacterial biomass is the most straightforward option for transferring nutrients from cyanobateria to heterotrophic microorganisms, it may thus not be necessary. What solution minimizes the cost-to-productivity ratio is still to be determined.

Supporting plant growth

The majority of BLSS projects include plants for air and water regeneration and food production. Interestingly, all of the nutrients needed to grow plants (C, H, N, O, P, S, K, Mg, Fe, Na, Ca and micronutrients) seem to be present on Mars. Banin (Reference Banin and Stoker1989) proposed using Martian regolith to grow plants and this approach is still under investigation (e.g., Silverstone et al. Reference Silverstone, Nelson, Alling and Allen2003, Reference Silverstone, Nelson, Alling and Allen2005; Nelson et al. Reference Nelson, Dempster and Allen2008; Maggi & Pallud Reference Maggi and Pallud2010; Wamelink et al. Reference Wamelink, Frissel, Krijnen, Verwoert and Goedhart2014). However, even though Martian regolith is mostly basaltic and weathered basalt can yield extremely productive soils on Earth (Dahlgren et al. Reference Dahlgren, Shoji, Nanzyo, Shoji and Nanzyo1993), regolith will require physicochemical and/or biological treatment before it can be used as a growth substrate for plants. Besides excess salts, oxides and toxins, the main limiting factors are its low nutrient bioavailability and poor water-holding potential caused by low organic C contents (Maggi & Pallud Reference Maggi and Pallud2010; Cockell Reference Cockell2011). Enrichment of N, in particular, is critical: most plants cannot fix atmospheric N (a few, mainly legumes, benefit from symbiotic N fixation by specific bacteria harboured in their root tissues).

Some elements could be obtained by recycling human waste and inedible biomass from previous crops. However, relying solely on this would strongly limit sustainability and scalability of the system: without adding new components to the loop, the pool of supplies can only decrease over time. Again, inputs for plant cultivation should rather be provided from local resources. An interesting approach has been proposed in the context of lunar exploration. Following this approach, plant species which are tolerant to harsh growth conditions would be grown in local regolith, after inoculating seeds with a carefully chosen consortium of bioleaching bacteria to deliver nutrients to plant roots and to protect them against excessive accumulation of toxic elements. Once these ‘first-generation plants’ would have been grown, their biomass would be converted by microorganisms into a fertile protosoil used to support the growth of more demanding plants (Kozyrovska et al. Reference Kozyrovska2006; Zaets et al. Reference Zaets, Burlak, Rogutskyy, Vasilenko, Mytrokhyn, Lukashov, Foing and Kozyrovska2011). An alternative strategy could rely on cyanobacteria to process elements from rocks and fix N. Even though no plant cultures are currently produced using cyanobacteria as exclusive nutrient sources, the latter are used in agriculture to improve soil fertility, balance mineral nutrition and release biologically active substances that promote plant growth and increase plant resistance (Singh Reference Singh2014). In the context of space exploration, cyanobacterial cultures have already been proposed as a way of releasing chemical elements from rocks to hydroponic solutions (Brown & Sarkisova Reference Brown and Sarkisova2008). N fixed by cyanobacteria could also be used in hydroponic and/or soil-based systems. It could come from two main sources: from processed biomass containing for instance amino acid chains, and from released NH4 +.

Within the MELiSSA loop, NH4 + is converted into nitrates before being transferred to plants, but plants can also efficiently uptake NH4 + (see, e.g., Howitt & Udvardi Reference Howitt and Udvardi2000). In theory, plant growth rates can even be higher with NH4 + than with nitrates due, first, to the energy needed to reduce nitrates to NH4 + before its incorporation into organic compounds (Bloom et al. Reference Bloom, Sukrapanna and Warner1992) and, second, to a reduced need for photons, water and catalytic metal use per unit of C fixed when relying on NH4 + (see Raven et al. Reference Raven, Wollenweber and Handley1992). However, experimental data often do not support this hypothesis (e.g., Raven et al. Reference Raven, Wollenweber and Handley1992). NH4 + induces toxicity at lower concentrations than nitrate, with a threshold which varies widely among species (Britto & Kronzucker Reference Britto and Kronzucker2002). As a consequence, preference for NH4 + over nitrate is species-dependent (Barker & Mills Reference Barker and Mills1980; Zhou et al. Reference Zhou, Zhang, Wang, Cui, Xia, Shi and Yu2011). Even though NH4 + toxicity is not fully understood, it can presumably be explained in large part by the effect of the absorbed N's form on the uptake of other ions: NH4 + leads to higher anion uptake and lower cation uptake. It also affects pH: nitrate and NH4 + absorption induce, respectively, a release of hydroxyl ions (HO) and a release of protons (H+), and for some plants NH4 +'s negative effects can be reversed by buffering the medium (Britto & Kronzucker Reference Britto and Kronzucker2002). Harmful effects could consequently be mitigated by controlling pH and adjusting the supply of other nutrients (Muhlestein et al. Reference Muhlestein, Hooten, Koenig, Grossl and Bugbee1999), and by keeping NH4 + concentrations below toxic levels. Further studies could ascertain to what extent the growth-limiting effects of high NH4 + concentrations can be mitigated; more generally, work is needed to determine whether the benefits brought by nitrifying bacteria would justify the complexity and costs associated with their culture. Besides NH4 +, organic N from cyanobacterium biomass can be considered as an N source: plants can uptake amino acid chains (e.g., Lipson & Näsholm Reference Lipson and Näsholm2001; Näsholm et al. Reference Näsholm, Kielland and Ganeteg2009). Uptake of single amino acids and short peptides, and possibly di- and tri-peptides, occurs via membrane transporters in root cells (Rentsch et al. Reference Rentsch, Schmidt and Tegeder2007). Some plants can also uptake proteins after degradation by fungal symbionts (e.g., Bajwa et al. Reference Bajwa, Abuarghub and Read1985) and at least some can do it without prior degradation by other organisms, either directly (presumably by endocytosis) or via the secretion of proteolytic enzymes (Godlewski & Adamczyk Reference Godlewski and Adamczyk2007; Paungfoo-Lonhienne et al. Reference Paungfoo-Lonhienne, Lonhienne, Rentsch, Robinson, Christie, Webb, Gamage, Carroll, Schenk and Schmidt2008).

Symbioses between plants and diazotropic cyanobacteria naturally occur. The best-known instances involve aquatic ferns from the genus Azolla and their symbionts from the genus Anabaena (Peters & Meeks Reference Peters and Meeks1989), and angiosperms from the genus Gunnera and their symbionts from the genus Nostoc (Bergman et al. Reference Bergman, Johansson and Soderback1992), but interactions naturally occur between cyanobacteria and representatives of most plant groups. Artificial symbioses between diazotrophic cyanobacteria and plants which normally do not harbour cyanobacterial symbionts, where the former provide fixed N to the latter, have also been successfully created with various plants including cereals (Gusev et al. Reference Gusev, Baulina, Gorelova, Lobakova, Korzhenevskaya, Rai, Bergman and Rasmussen2002). In a hydroponic system, an Anabaena variabilis strain has even been shown to provide fixed N to wheat grown in an otherwise N-free medium, yielding plant growth comparable with that of the control plants grown in a nitrate-containing medium (Spiller & Gunasekaran Reference Spiller and Gunasekaran1990). Assessments of the cyanobacterium-to-plant biomass conversion efficiency, when all substrates besides CO2 and water come from cyanobacteria, require further experiments.

Even though experimental research is needed to quantify the nutrient composition of culture supernatants (with and without cell lysis), to determine the most efficient way of transferring nutrients from cyanobacterial cultures to other organisms and to get quantitative estimates of the system's requirements, cyanobacteria could thus be considered as a useful tool for processing local inorganic resources into a form which is available to other organisms (for a visual summary, see Fig. 3). But cyanobacteria could also be used directly for various applications. The most critical are outlined below.

Fig. 3. Using cyanobacteria to process Martian resources into substrates for other organisms. In this scheme, cyanobacteria are fed with various nutrients obtained from the regolith, gaseous carbon and nitrogen from the atmosphere, energy from solar radiation, and water from various possible sources including ice caps, subsurface ice, atmosphere and hydrated minerals. Additional organic material, CO2 and water could be provided from metabolic and manufacturing waste resulting from human activity. Products from cyanobacterial cultures are then used as a substrate for heterotrophic microorganisms and plants.

Producing food

If all food came from Earth and assuming the easiest option of providing shelf-stable, prepackaged food similar to International Space Station's provisions, the amount to be sent would be about 1.8 kg day−1 crewmember−1 (Allen et al. Reference Allen2003). Adding the needed vehicle and fuel weight to carry it and assuming a 10:1 vehicle-to-payload ratio (Hoffman & Kaplan Reference Hoffman and Kaplan1997), 1-year food supply for a crew of 6 would add more than 29 mt to the initial mass of the transit vehicle. Worse, the load needed for a healthy diet would be much higher: even though convenient due to reduced need for storage facilities and contamination risks, a diet composed exclusively of this type of food would be nutritionally incomplete and thus not adequate in the long term. Frozen food could be seen as an interesting complement but would be extremely demanding in terms of storage facilities, could not be kept at commercial temperatures for more than about 1 year without losing palatability and would be unreliable due to potential freezing failure. Thus, even though current space food systems are relevant for short-term space missions and missions close to Earth (in low Earth orbit and possibly on the Moon), they must be developed further to meet the requirements of a manned mission to Mars (Perchonok et al. Reference Perchonok, Cooper and Catauro2012). Establishing long-term human settlement on Mars seems unrealistic without local food production systems.

Growing plants might appear as an obvious option, even though creating an adequate environment on Mars would be particularly challenging at the first steps of colonization (details are given in the ‘Plants or cyanobacteria?’ section below). However, cyanobacteria could be an interesting alternative. Some species are edible, can be grown at a large scale and are expected (based on comparisons of metabolic pathways and human nutritional requirements) to be a nearly complete nutritional source, lacking only vitamin C and possibly essential oils (Way et al. Reference Way, Silver and Howard2011). Some species, notably from the genus Arthrospira, have consequently been studied as a potential food source in life-support systems (Hendrickx et al. Reference Hendrickx, De Wever, Hermans, Mastroleo, Morin, Wilmotte, Janssen and Mergeay2006; Lehto et al. Reference Lehto, Lehto and Kanervo2006). Arthrospira platensis is already used on Earth as a food supplement, and its nutritional value and lack of toxicity are well-characterized. Its dried biomass has been categorized ‘Generally Recognized As Safe’ (GRAS) for human consumption by the Food and Drug Administration (FDA) of the United States (FDA GRAS Notice No. GRN 000127). It has high protein contents (roughly, 50–70% of the dry weight) and a high productivity: cultures in outdoor ponds under non-optimized conditions typically yield from 1 to 3 × 107 gdw ha−1 yr−1 (Jiménez et al. Reference Jiménez, Cossío and Niella2003) and produce 20 times more proteins per hectare than soya's (Hendrickx et al. Reference Hendrickx, De Wever, Hermans, Mastroleo, Morin, Wilmotte, Janssen and Mergeay2006; Henrikson Reference Henrikson2009). Yields can be much enhanced in more controlled conditions. Cultures in photobioreactors can produce about 1 gdw l−1  day−1 and, with such yields and assuming energetic contents of 3.75 kcal gdw−1 (Tokusoglu & Unal Reference Tokusoglu and Unal2003), 2000 kcal day−1 can be produced with about 0.53 m3. That being said, this figure is a very rough approximation of the actual needs: even though it covers mean caloric needs for a 30–50-year-old adult, it does not represent the amounts needed to cover nutritional needs. On the other hand, production rates can be further increased; for instance, a productivity of 16.8 gdw m−2  h−1 (there corresponding to 1.2 gdw l−1  h−1) has been attained for a short period of time using high A. platensis cell densities, a very short light path (14 mm), a very high photon flux (8000 µmol m−2 s−1; about four times the solar flux on Earth when the Sun is directly overhead) and highly turbulent mixing (Qiang et al. Reference Qiang, Zarmi and Richmond1998). Arthrospira spp. have health-promoting properties, including antiviral and antimutagenic functions which are especially relevant in Mars's highly irradiated environment (Lehto et al. Reference Lehto, Kanervo, Stahle, Lehto, Cockell and Horneck2007). They are also much more digestible than eukaryotic microalgae from the genus Chlorella, their main competitor as a photosynthetic microorganism-based food source, which have poorly digestible cellulose-containing cell walls.

However, Arthrospira spp. biomass currently cannot be used as a staple food: in addition to a taste that very few people would qualify as appealing, its carbohydrate-to-protein ratio is low, it contains very high levels of vitamin A, and it lacks vitamin C and possibly essential oils. Due to this nutritional imbalance, it is generally not recommended to consume more than 10 g day−1. Cyanobacteria could be mixed with other microalgae and plants to optimize nutrient and fibre contents, as well as to diversify taste and texture, but limitations could also be addressed using synthetic biology (Way et al. Reference Way, Silver and Howard2011). Modifying the sugar, protein and lipid proportions, as well as introducing molecules that humans require (e.g., vitamin C) could be achieved using metabolic engineering and other genetic manipulations. Preliminary work has been done in this direction; for instance, mutant strains of A. platensis have been selected that are richer than the wild-type in compounds including essential amino acids, phycobiliproteins and carotenoids (Brown Reference Brown2008b). Novel taste, smell and colour molecules could be produced by cells to increase palatability, attractiveness and meal diversity. It should also be taken into account that, depending on its adjusted pressure, Martian atmosphere can strongly affect the composition of cyanobacterial cultures: A. cylindrica cells grown under low pressure and high CO2 concentrations showed decreased protein contents and increased sugar contents compared with cells grown under ambient conditions (Lehto et al., unpublished data), shifting the protein/carbohydrate ratio closer to humans’ needs.

Research has been extensively focused on Arthrospira spp., but other cyanobacterial species such as Nostoc commune, Nostoc flagelliforme and Anabaena spp. in symbiosis with Azolla spp. are traditionally consumed and more are edible. Arthrospira cultures require extensive nutrient supply (including fixed N), a high temperature with an optimum around 35°C and an alkaline pH. Other species which are less demanding in terms of culture conditions might thus be more suitable on Mars and, even within the genus Arthrospira, species could be screened for the highest productivity under on-site constraints.

Cyanobacteria could also be used for food complementation without being directly eaten or even inactivated, as they can be engineered to secrete nutritional compounds (Way et al. Reference Way, Silver and Howard2011). As mentioned above, the possibility of engineering them to produce and secrete sugars has already been demonstrated (Niederholtmeyer et al. Reference Niederholtmeyer, Wolfstädter, Savage, Silver and Way2010; Stanford-Brown 2011 iGEM team 2011).

Finally, high-protein food could be suggested to come from animals. Granted, it is unrealistic to envision growing large species on Mars during its earliest colonization steps, due for instance to the need for an Earth-like environment, to low protein yields-to-allocated resources (area, water, vegetal-originated proteins, working time, etc.) ratios and to the risk of pathogen transmission to humans. However, aquaculture of densely growing fish species (e.g., Tilapia spp.), crustaceans and shellfish may be considered (McKay et al. Reference McKay, Meyer, Boston, Nelson, McCallum, Lewis, Matthews and Guerrieri1993) and cyanobacteria could be used for feeding them. Cyanobacteria are already used on Earth as a main food source for larvae of many species of fish, zooplankton (itself used for feeding fish larvae), crustaceans and shellfish (Pulz & Gross Reference Pulz and Gross2004).

Producing oxygen

O2 will be one of the most critical resources in human bases on Mars, the most obvious reasons being human respiration and fuel oxidation. But it represents only 0.13% of Mars's atmosphere, against 21% of Earth's. Given the total pressures of both atmospheres, its partial pressure on Mars is more than 20 000 times lower than on Earth. O2 thus needs to be either brought to Mars or produced there and, as for other resources, the second option is likely the most viable in the long term. On-site O2 production could be performed using physicochemical methods: by processing regolith, water and/or atmospheric CO2 (e.g., by combining a CO2 scrubber, a Sabatier reactor and an electrolyser). However, cyanobacterium-based O2 production from H2O and CO2 could provide a safe redundancy (Sychev et al. Reference Sychev, Levinskikh and Shepelev2003) and complement physicochemical methods. It could also be less energy demanding, and faster to set up and expand to face unexpected needs.

How much O2 is needed? Each crewmember consumes about 1 kg of O2 per day for respiration, assuming 2 h a day of intensive physical exercise (Horneck et al. Reference Horneck2003). If produced photosynthetically, this requires the fixation of more than 1.3 kg of CO2 a day, part of which could be provided, if useful, by recycling CO2 produced by the crew's metabolic activity (about 1 kg day−1 crewmember−1) and manufacturing activity in addition to using atmospheric CO2.

Cyanobacteria are very efficient O2 producers: whereas trees release about 2.5–11 t of O2 ha−1 yr−1, industrial cultivation in open ponds of Arthrospira species in Southeastern California release about 16.8 t of O2 ha−1 yr−1. Cultures have been stated to be about 2.5 times more productive in the tropics (Henrikson Reference Henrikson2009); under these conditions, about 80 m2 of culture per crewmember would be needed to cover human respiration needs. However, O2 production rates can be dramatically increased by photobioreactor-like culture systems which optimize for instance temperature, nutrient flow rates, cell density and illumination. Photosynthetic microorganisms from a eukaryotic microalgal genus, Chlorella, have been well-studied in the context of O2 production for life-support systems. For instance, an experimental system (‘BIOS-I’) was designed and tested in the 1960s where a man living in a sealed volume had his atmosphere and water regenerated by a Chlorella vulgaris culture. This work was preceded by experiments aimed at investigating the potential use of Chlorella spp. for air regeneration, performed by Y. Y. Shepelev and G. I. Meleshko at the Institute of Aerospace Medicine, Moscow, in 1960–1961 (Salisbury et al. Reference Salisbury, Gitelson and Lisovsky1997). In BIOS-I, CO2 excreted by the man and biogenous elements from his urine (N, P, S and K) were fed into the algal culture, which in turn produced O2 and purified water. Investigators showed that producing 500 g of dry algal biomass per person and per day was enough for water and air generation, and could be achieved in 20 litres only (with a 0.5 cm thick cultivation compartment between 8 m2 plane parallel walls to maximize light absorption), using one-side illumination with photosynthetically active radiation at 250–300 W m−2 (Kirensky et al. Reference Kirensky, Terskov, Gitelson, Lisovsky, Kovrov and Okladnikov1968; Gitelson Reference Gitelson1992). The system was further developed, plants were added and various manned closure experiments were performed within ‘BIOS-2’ and ‘BIOS-3’, where Chlorella sp. was used to recycle part of the air (even though the Chlorella compartment was later replaced with additional plant compartments, mainly for food-related issues; see Salisbury et al. Reference Salisbury, Gitelson and Lisovsky1997).

Productivity will depend on conditions which will be provided on site. It should also be noted that the needed resources do not need to be dedicated to O2 production, as O2 will anyway be a side product of other processes relying on cyanobacteria and could be coupled with, for instance, food production.

Producing biofuels

If sending it from Earth, fuel would represent most of the load's mass to be sent from Earth and (for the journey back, assuming a return mission) from Mars. If it could be produced on-site, costs and technical challenges would be much reduced.

The next question concerns fuel-type. Dihydrogen (H2) can be used for reducing local CO2 to hydrocarbons, and it has been proposed to bring some to Mars to produce methane (CH4) and H2O (the latter can then be hydrolysed into O2 and H2). H2 could theoretically be directly used as a fuel: a mixture of liquid H2 and O2 have suitable propulsion performances. It is however much less attractive than CH4, among other reasons because of its very low density which induces a need for specialized combustion apparatus. In the Mars Direct plan (Baker & Zubrin Reference Baker and Zubrin1990; Zubrin et al. Reference Zubrin, Baker and Gwynne1991; Zubrin & Wagner Reference Zubrin and Wagner2011), 6 t of H2 would be used to generate enough CH4 and O2 to bring the return vehicle back to Earth and to power ground vehicles on the Martian surface. Mass could be further reduced if H2 was also obtained on Mars. Many cyanobacteria can produce it; among them, N-fixing heterocystous species such as Nostoc and Anabaena spp. are the most promising candidates. Their H2 production activity comes from their nitrogenases. These enzymes mainly catalyse the reduction of N2 to NH4 + but also, in the absence of N, reduce H+ to H2. On Earth, though, H2 photoproduction is currently too low for it to have practical applications. As an example, A. cylindrica grown in a standard medium for cyanobacteria (BG11), at ambient air composition and pressure, yields only about 0.2 µmol H2 mg Chl a−1 h−1 (Murukesan et al. Reference Murukesan, Leino, Mäenpää, Stahle, Raksajit, Lehto, Allahverdiyeva-Rinne and Lehto2015). One of its main limitations is the inhibition by atmospheric O2 and N2: nitrogenases are irreversibly inactivated by O2, while N2 strongly inhibits H+ reduction. The high CO2, low O2 and N2 composition of the Martian atmosphere could thus be an advantage here. Consistently, yields above 20 ml l−1 h−1 (about 0.8 mmol l−1 h−1) were obtained with concentrated cultures of about 50 mg Chl a l−1 of A. variabilis (so, roughly, 16 µmol H2 mg Chl a−1 h−1) under a 99% argon (Ar), 1% CO2 atmosphere (Liu et al. Reference Liu, Bukatin and Tsygankov2006). Recently, levels of about 25 µmol mg Chl a−1 h−1 were also reached with A. cylindrica cultures under high CO2/low N conditions (Murukesan et al. Reference Murukesan, Leino, Mäenpää, Stahle, Raksajit, Lehto, Allahverdiyeva-Rinne and Lehto2015). With a concentration of 50 mg Chl a ml−1, these rates could lead to 1.5 mmol l−1 h−1 (about 35 ml l−1 h−1 at room temperature, with 30 µmol mg Chl a−1 h−1) of H2. Producing 6 t of H2 would then require about 228 m3 yr. It corresponds, for example, to 22 days in a culture system the size of 3 m-deep Olympic swimming pool, or to 2 years and 4 months in 100 m3, assuming yields can be maintained at this scale. But these figures are very rough approximations: rates that would effectively be obtained on Mars depend on the mission scenario and technology choices for culture systems. Finally, current productivity is still far from its maximum, and increases are regularly obtained by culture conditions’ optimization and metabolic engineering.

Leaving H2 aside, cyanobacteria can generate various biofuel precursors and components including alkanes, ethylene, hydrogen peroxide (H2O2; which can be used as a monopropellant) and lipids, without relying on organic precursors (see, for instance, Quintana et al. Reference Quintana, Van der Kooy, Van de Rhee, Voshol and Verpoorte2011). They could also provide organic substrates for production of biofuel precursors by other organisms, particularly relevant on Mars where importing substrates from Earth would be impractical. For instance, as mentioned above, lysed cyanobacterial biomass has been used as a fermentation substrate for ethanol production in yeasts (Aikawa et al. Reference Aikawa, Joseph, Yamada, Izumi, Yamagishi, Matsuda, Kawai, Chang, Hasunuma and Kondo2013; Möllers et al. Reference Möllers, Cannella, Jørgensen and Frigaard2014). However, genetic engineering could remove the need for other organisms even for production of biofuel precursors which are not naturally produced by cyanobacteria in adequately large amounts – if at all. For instance, some cyanobacteria have been engineered to produce ethanol. Whereas yeasts rely on a sugar-based pathway and thus on the availability of agricultural substrates, engineered cyanobacteria produced it directly from CO2 and solar energy, following a much simpler process where pyruvate is first converted to acetaldehyde by a pyruvate decarboxylase and then to alcohol by an alcohol dehydrogenase (Deng & Coleman Reference Deng and Coleman1999; Dalton & Roberto Reference Dalton and Roberto2008; Dexter & Fu Reference Dexter and Fu2009). Generally speaking, a lot of work has been done to engineer new biofuel (or biofuel precursor) production pathways – or to improve existing ones – in cyanobacteria (see, e.g., Ducat et al. Reference Ducat, Way and Silver2011). There is still much room for improvement, especially under Mars-like conditions.

Thus, even though extensive development and optimization is needed, cyanobacterium-based biotechnologies could represent original contributions to the production of rocket fuel for the return flight, for powering surface vehicles and, more generally, for powering equipment that can be operated by combustion engines.

Other applications

Various other applications involving cyanobacteria have been proposed for human outposts on Mars. One, for instance, is biomining. Microorganisms are used on Earth to extract metals of industrial interest (e.g., copper and gold) from rocks, and their use on Mars to mine basalt and potential ores has been suggested (Cockell Reference Cockell2010, Reference Cockell2011; Navarrete et al. Reference Navarrete, Cappelle, Schnittker and Borrok2012). Cyanobacteria are known to leach a wide range of rock types, including terrestrial volcanic rocks with compositions similar to Mars's regolith (Brown & Sarkisova Reference Brown and Sarkisova2008; Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010; Olsson-Francis et al. Reference Olsson-Francis, Simpson, Wolff-Boenisch and Cockell2012). The use of cyanobacteria, possibly engineered to increase their ability to dissolve rocks and harvest specific elements (Cockell Reference Cockell2011), can thus be considered for simple bioleaching processes that would not rely on imported C sources (needed for heterotrophic microorganisms) or toxic elements such as cyanide (used in non-biological leaching processes). Extracted elements could be used within a wide range of chemical and manufacturing processes such as, for instance, CO2 cracking, electroplating, production of alloys and manufacturing of solar cells (Dalton & Roberto Reference Dalton and Roberto2008; Cockell Reference Cockell2011).

Cyanobacteria have also been suggested for controlling Mars's surface dust, through the production of biological crusts, in enclosed structures such as greenhouses and habitats (Liu et al. Reference Liu, Cockell, Wang, Hu, Chen and De Philippis2008). Indeed, some can grow and form biofilms within the interstices of desert minerals and produce extracellular polysaccharides that bind the particles together, preventing wind-induced dust release. Such crusts could also be used as an air filter to remove dust from the atmosphere (Cockell Reference Cockell2010). Then, the use of dehydrated Chroococcidiopsis cells as a gene repository for on-site molecular biology has been suggested (Billi et al. Reference Billi, Baqué, Smith and McKay2013), as they can preserve plasmids during long-term desiccation (Billi Reference Billi2012) and presumably repair them when damaged. Cyanobacteria could also be used to process human waste products and recycle their organic C, water, nitrates and mineral nutrients. Cultures could be used directly (Filali et al. Reference Filali, Lasseur and Dubertret1997; Godia et al. Reference Godia, Albiol, Montesinos and Pérez2002; Lehto et al. Reference Lehto, Lehto and Kanervo2006; Yang et al. Reference Yang, Liu, Li, Yu and Yu2008) but also indirectly; for instance, H2O2 generated from cyanobacterium-produced O2 and H2O could be used to oxidize human wastes following a physicochemical process developed by researchers of the Institute of Biophysics of the Siberian Branch of the Russian Academy of Sciences (Kudenko et al. Reference Kudenko, Gribovskaya and Zolotukhin2000); nutrients could then be recycled in cyanobacterial cultures (Tikhomirov et al. Reference Tikhomirov, Ushakova, Kovaleva, Lamaze, Lobo and Lasseur2007). Cyanobacteria have also been suggested for the production, beyond Earth, of various chemicals including nutritional molecules, drugs, bioplastics and cellulosic building materials (Way et al. Reference Way, Silver and Howard2011; Menezes et al. Reference Menezes, Cumbers, Hogan and Arkin2014).

Finally, the ability of cyanobacteria to produce organic material from Martian resources, coupled to our increasing abilities in metabolic engineering, make it possible to consider many other applications ranging from performing basic life-support functions to generating comfort products.

Plants or cyanobacteria?

Assuming that both plants and cyanobacteria can be grown on Mars, some functions such as food and O2 production could be performed by either or both of them. For these functions, plants are the most commonly proposed photosynthetic organisms. This choice, however, is mostly due to our historical reliance on – and experience with – them: they have been a highly available food source throughout most of human history. Matters need to be reconsidered where environmental conditions, resources and other constraints are different.

Photosynthetic microorganisms are more efficient, on a volume basis, at capturing solar energy than plants. Their culture in photobioreactors could yield much more biomass (especially proteins) and O2 for a given volume and light intensity than greenhouse-type cultures of staple edible plants (Dismukes et al. Reference Dismukes, Carrieri, Bennette, Ananyev and Posewitz2008; Way et al. Reference Way, Silver and Howard2011; Wang et al. Reference Wang, Wang, Zhang and Meldrum2012). This is critical where resources are scarce and cultivation areas are highly controlled. Moreover, a considerable part of plant biomass (e.g., roots or stems, depending on species) is inedible and hard to recycle: plant cell walls are among the least degradable polymers in BLSS (Hendrickx & Mergeay Reference Hendrickx and Mergeay2007).

Plants are also much more demanding in terms of environmental conditions. For instance, they are harmed by anoxia (roughly, a partial pressure of O2 of at least 50 hPa is needed for proper development, mainly for non-photosynthetic tissues; see Thomas et al. Reference Thomas, Sullivan, Sprice and Zimmerman2005) and high concentrations of CO2 (negative effects have been observed in some plants above 4 hPa [Wheeler Reference Wheeler and Looney2004], while the partial pressure of CO2 [pCO2] on Mars is above 6 hPa). Photosynthetic cultures on Mars, be they vegetal or bacterial, will have to be protected from biocidal environmental conditions. The needed level of protection – and the associated costs – will depend on the ability of cultured organisms to withstand these conditions, and many cyanobacteria are much more resistant than staple plants to the Martian surface's environmental stressors. They thrive in the most extreme habitable conditions on Earth, such as in dry deserts and ice lakes of Antarctica, and within ices of high Arctic seas (Wierzchos et al. Reference Wierzchos, Ascaso and McKay2006; Scalzi et al. Reference Scalzi, Selbmann, Zucconi, Rabbow, Horneck, Albertano and Onofri2012). Some have an outstanding resistance to environmental factors occurring on Mars's surfaces, including ultraviolet (UV) and ionizing radiation (see, for instance, Billi et al. Reference Billi, Baqué, Smith and McKay2013 and Thomas et al. Reference Thomas, Boling, Boston, Campbell, McSpadden, McWilliams and Todd2006) and can survive in space when protected from UV radiation (Olsson-Francis et al. Reference Olsson-Francis, de la Torre and Cockell2010).

In habitable compartments, gas consumed and produced by crewmembers must be balanced with gas consumed and produced by an atmosphere regenerating system. Since CO2 will be available in the atmosphere and since both CO2 and O2 will be generated as by-products of other processes, this system could be more flexible on Mars than in places where simple closed systems would be used: losses could be compensated and excess vented out. However, extensive control of the atmospheric balance would both increase safety and reduce resource consumption. By adjusting culture conditions, controlling cultures’ assimilation quotient (CO2 consumed/O2 produced) to match humans’ respiratory quotient (CO2 produced/O2 consumed) is much easier with cyanobacteria than with plants, making the atmospheric O2/CO2 balance much more manageable with the former (Averner et al. Reference Averner, Moore, Bartholomew and Wharton1984; Horneck et al. Reference Horneck2003).

As crewmembers should be available for research and colony settlement and maintenance, time spent on culture management will have to be kept to a minimum. Culturing plants requires significant manpower; within Biosphere 2, for instance, agricultural and food-related tasks took about 45% of crew time (Silverstone & Nelson Reference Silverstone and Nelson1996). In this framework, automation should be extensive. Cyanobacterial cultures are much more suitable for automation than plants’ due to their culture homogeneity, growth in liquid medium and lack of inedible parts that should be sorted out. They are also much more manageable; culture parameters could be more easily adjusted to cover human needs, with a safety margin but without excess. Outputs could thus be much more controllable and predictable.

The time needed to establish cultures also matters. Even though shelf-stable food can be sent to sustain crews before cultures are first set up, it is important to be able to re-establish cultures in case of accidental loss – likely enough, and something with catastrophic consequences if not rapidly fixed. Being able to quickly extend cultures to cover unexpected needs (e.g., to compensate an O2 loss) can also be critical. Even though some plants can be grown faster, staple crops can take 3–4 months to mature even under favourable conditions (Drysdale et al. Reference Drysdale, Ewert and Hanford2003). On the other hand, microbial cultures can be quickly expanded and re-deployed from very small amounts.

Finally, cyanobacteria are much easier to engineer than plants due to their rapid division times, compatibility to transformation, unicellularity and relatively simple genetic background (Koksharova & Wolk Reference Koksharova and Wolk2002; Way et al. Reference Way, Silver and Howard2011; Berla et al. Reference Berla, Saha, Immethun, Maranas, Moon and Pakrasi2013). They could therefore be much more easily modified for new functions and adaptation to Martian conditions (see section ‘Engineering cyanobacteria’ below).

It should however be noted that plants have some advantages over cyanobacteria: they could provide tasty and carbohydrate-rich comfort food, and have beneficial psychological impacts on crewmembers (Allen Reference Allen1991). Establishing small-scale cultures is not obviously unrealistic, especially if nutrients are provided from local resources as described above.

Besides plants, one may wonder why the present paper focuses on cyanobacteria rather than eukaryotic microalgae, which could also perform some of the functions described above. Reasons include cyanobacteria's overall better abilities to use Martian resources (e.g., by N fixation and regolith leaching) and to withstand Martian conditions, the higher digestibility of their edible species and their higher growth and photosynthetic rates. They are also more suitable for genetic engineering, in part due to current transformation systems which are much simpler and well developed for cyanobacteria than for eukaryotic microalgae (Wang et al. Reference Wang, Wang, Zhang and Meldrum2012; Wijffels et al. Reference Wijffels, Kruse and Hellingwerf2013).

What about non-photosynthetic (chemotrophic) microorganisms? Heterotrophs may be useful on Mars, but not as primary producers (see subsection ‘Feeding other microorganisms’). Resources needed to feed the metabolism of some chemoautotrophs, on the other hand, may be found on Mars; for example, reduced iron could be used as an energy source by iron-oxidizing bacteria (Nixon et al. Reference Nixon, Cousins and Cockell2013). Chemoautotrophs could thus be considered for some applications, such as the extraction of industrially useful minerals (Cockell Reference Cockell2010, Reference Cockell2011). However, none has the versatility of cyanobacteria to be the basis for BLSS: none combines, for instance, high N fixation rates, high growth rates, ability to rely exclusively on Martian resources, O2 production, H2 production, amenability to genetic manipulation and edible biomass.

Growing cyanobacteria on Mars

All organisms we currently know have evolved on Earth and none of them would be able to grow efficiently on the Martian surface. Cyanobacteria must be provided with shielding and an environment suitable for metabolism and growth. Elaborated hardware systems providing Earth-like conditions have been proposed but they rely on complex technology and require accurate control of all the process parameters (e.g., gases, temperatures and pressures in each compartment), are very demanding in terms of construction materials and energy consumption, need to be constructed on Earth, are very massive and expensive to carry to Mars, and can consequently be applied to small-scale cultures only. In order to be cost-effective and reliable, culture hardware for large-scale, long-term, sustainable BLSS on Mars should be much simpler.

Fortunately, reproducing Earth-like conditions is not needed: cyanobacteria can grow under conditions which are much closer to Mars's. In addition, most inputs – if not all – needed for growing cyanobacteria can be found on-site. An adequate culture system could thus provide a set of parameters (radiation shielding, atmospheric composition and pressure, gravity, nutrient supply, etc.) resulting from a compromise between (i) efficient support to growth and metabolism, and (ii) system feasibility and substrate availability on Mars's surface.

This culture system should be able to resist an inside/outside pressure difference, fine dust, large temperature gradients and strong radiation fluxes. Whatever its final design, efforts should be made to keep its weight, cost and energy consumption as low as reasonably possible given the other requirements. Ideally, the design should allow manufacturing from on-site compounds (e.g., regolith-based materials for radiation shielding, glass manufactured using silicon dioxide from Martian soil, and metallic parts derived from metal oxides mined in the regolith), assuming that equipment needed for processing is available on site. The potential of ultimately creating many of these facilities with local resources is currently being explored in Lynn Rothschild's laboratory.

Nutrient sources

Most elements needed for feeding plants and microorganisms can be found in Martian regolith.

Data on the composition of Martian soils and rocks have been obtained from analyses of the SNC (Shergottites, Nakhlites, Chassignites) group of meteorites (McSween Reference McSween1994), the Viking (Clark et al. Reference Clark, Baird, Weldon, Tsusaki, Schnabel and Candelaria1982), Pathfinder (Rieder Reference Rieder1997) and Phoenix (Hecht et al. Reference Hecht2009) landers, the Spirit rover (Morris et al. Reference Morris2004), instruments operated from orbiters – noteworthy the Thermal Emission Spectrometer on Mars Global Surveyor (see Christensen et al. Reference Christensen2001), the Gamma Ray Spectrometer on Mars Odyssey (Boynton et al. Reference Boynton2007) and the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) on the Mars Reconnaissance Orbiter (Mustard et al. Reference Mustard2008) – and, recently, using X-ray spectrometers aboard the Opportunity and Curiosity rovers. In particular, the latter two have allowed detailed mineral compositions to be deduced at multiple sites in the Endeavour crater (Arvidson et al. Reference Arvidson, Squyres and Bell2014) and Gale crater (Grotzinger et al. Reference Grotzinger2014; McLennan et al. Reference McLennan2014; Ming et al. Reference Ming2014; Vaniman et al. Reference Vaniman2014). On Earth, basalt is the dominant rock type on the surface. It harbours much of the biosphere and, as an abundant source of redox couples and macronutrients, provides an efficient support to microbial life (for a review in the context of the search for life on Mars, see McMahon et al. Reference McMahon, Parnell, Ponicka, Hole and Boyce2013). Martian regolith is also in large part composed of basaltic minerals; more generally, Mars's surface seems to be mostly basaltic (McSween et al. Reference McSween, Taylor and Wyatt2009; Taylor & McLennan Reference Taylor and McLennan2009). All basic elements needed for cyanobacteria and other organisms (C, H, O, N, P, S, K, Mg, Na, Ca, Fe), as well as other elements needed in smaller amounts (Mn, Cr, Ni, Mo, Cu, Zn, etc.), have been detected there.

The most convenient sources of C and N will probably be atmospheric CO2 and N2 (see ‘Atmospheric pressure and composition’ section below). Additional C can be found in the CO2 ice caps, in the surface and subsurface regolith due to exchange with the atmosphere, and possibly in reservoirs formed when the atmosphere was thicker (Kurahashi-Nakamura & Tajika Reference Kurahashi-Nakamura and Tajika2006). It has also been suggested that fixed N, derived from Mars's atmospheric N2, may be buried in the regolith (Mancinelli & Banin Reference Mancinelli and Banin2003; Boxe et al. Reference Boxe, Hand, Nealson, Yung and Saiz-Lopez2012). Consistent with this, N-bearing compounds have been detected there (Ming et al. Reference Ming2014). However, the exact nature and bioavailability of these compounds has not yet been determined.

Thus, all elements needed to support life seem to be present in Mars's rocks (Cockell Reference Cockell2014) and atmosphere. These nutrients can be directly made available to cyanobacteria, as multiple species thrive in a lithotrophic lifestyle, extracting all their needed mineral nutrients from rocky substrates (including basalt) and obtaining their whole N and C supply via photosynthesis and biological N fixation. Accordingly, some strains (e.g., A. cylindrica) have been grown in distilled water containing only powdered Mars basalt analogues (experiments were performed under terrestrial atmosphere; considerations on what atmospheric conditions are suitable are given in the ‘Atmospheric pressure and composition’ section below). Non-N fixing cyanobacteria could also grow when NaNO2 was added. On Mars, fixed N could come from N fixers (see above sections), while the possibility that nitrate beds are present cannot be ruled out. Supplementing the media with a sulphate source, (NH4)2SO4, had a positive impact on some of the tested species. The authors suggested that, on Mars, gypsum (NaSO4·2H2O) could be used as such a supplement (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010). Gypsum dunes have indeed been found in the northern polar region of Mars by the OMEGA instrument on ESA's Mars Express orbiter (Langevin et al. Reference Langevin, Poulet, Bibring and Gondet2005) and the CRISM and High Resolution Imaging Science Experiment instruments on NASA's Mars Reconnaissance Orbiter (Roach et al. Reference Roach2007), and later confirmed by the rover Opportunity (Squyres et al. Reference Squyres2012). Other studies showed that the growth of several siderophilic cyanobacterial species isolated from iron-depositing hot springs in Yellowstone National Park was stimulated by the presence of Martian soil analogues in culture media (Brown & Sarkisova Reference Brown and Sarkisova2008) and that Nostoc sp. HK-01 could grow on a Mars regolith stimulant for at least 140 days, without other nutrient source besides atmospheric gas (Arai et al. Reference Arai, Tomita-Yokotani, Sato, Hashimoto, Ohmori and Yamashita2008). Other cyanobacteria have been grown using other Martian soil analogues as substrates, in distilled water or spread on gelified water plates. DLR's P-MRS and S-MRS simulants (Böttger et al. Reference Böttger, de Vera, Fritz, Weber, Hübers and Schulze-Makuch2012), and NASA JSC's Mars-1A simulant (Allen et al. Reference Allen, Morris, Lindstrom, Lindstrom and Lockwood1997), for instance, efficiently supported the growth of Matteia sp. and Anabaena sp. PCC7120 (see Fig. 4), respectively (Verseux et al., unpublished data). The need for providing regolith might be an issue for automation. However, using drilling photobioreactors that extract raw materials from the surface and directly bring them to cultures has been suggested (Cumbers & Rothschild Reference Cumbers and Rothschild2010) and technologies have been designed to excavate large amounts of regolith with minimal weight and time (see, e.g., Mueller & Van Susante Reference Mueller and Van Susante2011).

Fig. 4. Anabaena sp. PCC7120 growing in distilled water containing JSC Mars-1A regolith simulant, in Lynn Rothschild's laboratory.

Thus, even though it might be relevant to adequately mix rock types to have all nutrients in appropriate proportions and suitable pH, and even though some salts, oxides and toxins might need to be removed, all nutrients and micronutrients needed to support cyanobacterial metabolism seem to be present on Mars. Additional nutrients could come from human waste. If some micronutrients (e.g., some cofactors) could not be mined or produced on site, bringing them from Earth would add a negligible mass to the initial payload as they are needed in trace amounts only. Methods for physicochemical preprocessing of Martian regolith and atmosphere (to generate, for instance, a broth of pre-leached regolith and nitric acid in which CO2 is bubbled; see Cao et al. Reference Cao, Concas, Corrias, Licheri, Orru’ and Pisu2014) could be considered, if the increased productivity outweighed the increased running cost and complexity.

Atmospheric pressure and composition

Use of the minimal suitable pressure would greatly lower construction weight and cost of cyanobaterial culture systems on Mars, and would minimize the risk of organic matter leakage (Lehto et al. Reference Lehto, Lehto and Kanervo2006). Relying on a gas composition which is as close as possible to Mars's would make the establishment of such systems even simpler and cost-effective.

What is this minimal suitable pressure? No clear answer has been given to this question, as little work has been focused on microbial growth at low pressure. The lowest pressure at which biological niches are naturally present on Earth is about 330 hPa (at the top of the Mount Everest), way above Mars's surface pressure of about 5–11 hPa (Fajardo-Cavazos et al. Reference Fajardo-Cavazos, Waters, Schuerger, George, Marois and Nicholson2012). Although viable bacteria have been sampled a few times from stratospheric air above 30 km (e.g., Wainwright et al. Reference Wainwright, Wickramasinghe, Narlikar and Rajaratnam2003), where atmospheric pressure goes down to Mars's surface pressure, no microbial growth there was indisputably evidenced. Some methanogens can keep metabolic activity (shown by detectable CH4 production) at 50 hPa of pressure under simulated Martian environmental conditions (Kral et al. Reference Kral, Altheide, Lueders and Schuerger2011; Schirmack et al. Reference Schirmack, Böhm, Brauer, Löhmannsröben, de Vera, Möhlmann and Wagner2014), and a few bacteria such as Serratia liquefaciens (Schuerger et al. Reference Schuerger, Ulrich, Berry and Nicholson2013) and isolates from Siberian permafrost samples (Nicholson et al. Reference Nicholson, Krivushin, Gilichinsky and Schuerger2013) have been grown under 7 hPa of CO2-enriched anoxic atmospheres, but a wide range of microorganisms have been shown to be unable to grow on a semisolid agar medium at pressures below 25 hPa of ambient air (Nicholson et al. Reference Nicholson, Fajardo-Cavazos, Fedenko, Ortíz-Lugo, Rivas-Castillo, Waters and Schuerger2010).

It might be possible to decrease the lowest suitable pressure. As no biological niche is naturally present on Earth at pressures close to Mars's, selective pressure is virtually non-existent for current terrestrial microorganisms and the full potential for growth at low pressures is probably far from being reached. There might thus be much room for improvement by artificially evolving cyanobacteria to grow faster under low (and to grow at lower) pressures, including low pressures of Mars-like gas compositions. Consistently, an isolate of B. subtilis showed increased fitness at 50 hPa after a 1000 generation culture at this pressure (Nicholson et al. Reference Nicholson, Fajardo-Cavazos, Fedenko, Ortíz-Lugo, Rivas-Castillo, Waters and Schuerger2010). The minimal suitable pressure can also be dependent on atmospheric composition, as described below, and on medium type (liquid or solid). It should however be noted that a physical limitation derives from the need to maintain a liquid phase at growth-permissive temperatures.

In recent experiments, a decreased atmospheric pressure (50 kPa instead of the ambient 100 kPa) negatively affected the growth of cyanobacteria from several genera (Qin et al. Reference Qin, Qingni, Weidang, Yongkang, Jin and Shuangsheng2014). But this was performed under ambient gas composition and, like atmospheric pressure, atmospheric composition matters. CO2 and N2 are present in Mars's atmosphere but their partial pressures differ from Earth's (see Table 1). Mars's higher-than-Earth pCO2 (6.67 versus 0.38 hPa) might actually be beneficial: elevated levels of CO2 can have a fertilizing effect on cyanobacterial cultures (Murukesan et al. Reference Murukesan, Leino, Mäenpää, Stahle, Raksajit, Lehto, Allahverdiyeva-Rinne and Lehto2015). Below one atmosphere of pressure, CO2 seems to become the limiting factor and cyanobacteria benefit from much higher-than-normal CO2 concentrations; Synechocystis sp. PCC 6803 was shown to grow more than three times faster under 100 hPa with 5% CO2 (as well as under 1 bar with 5% CO2) than under 1 bar of ambient air (0.04% CO2), and to grow under 33 hPa of 100% CO2 with growth rates close to those obtained under 1 bar of ambient air (Lehto et al. Reference Lehto, Kanervo, Stahle, Lehto, Cockell and Horneck2007; see the culture system in Fig. 5). Later results showed that an increase in CO2 concentration (at least up to 20%, even though growth rates started to decrease after 10% for the 1-bar samples) under either 1 bar or 100 hPa leads to higher growth rates than ambient air composition at the corresponding pressure (Murukesan et al. Reference Murukesan, Leino, Mäenpää, Stahle, Raksajit, Lehto, Allahverdiyeva-Rinne and Lehto2015; unpublished data). Thus, this strain seems to benefit from higher-than-usual pCO2, with a saturation about 4 hPa, at which level an around 3.5-fold increase in growth rates is observed for cells previously grown in ambient terrestrial atmosphere. When CO2 is not limiting, its growth rates are not negatively affected by a 10-fold reduction in atmospheric pressure. Similarly, cultures of A. platensis and A. cylindrica were shown to benefit from higher-than-ambient CO2 concentrations (Murukesan et al. Reference Murukesan, Leino, Mäenpää, Stahle, Raksajit, Lehto, Allahverdiyeva-Rinne and Lehto2015). Finally, at least some cyanobacteria are able to survive (Synechococcus PCC7942, Anabaena sp.) and even to grow (Plectonema boryanum) in liquid culture under 1 bar (1000 hPa) of pure CO2, at least in the short term, when pCO2 is gradually increased by 150 hPa day−1 (Thomas et al. Reference Thomas, Sullivan, Sprice and Zimmerman2005). If needed, bacterial resistance to high CO2 levels could probably be further increased by preventing pH decrease in the medium, which happens due to carbonic acid (H2CO3) formation when CO2 dissolves in water.

Fig. 5. Underpressurized culture vials used in Kirsi Lehto's laboratory (at the University of Turku, Finland) to grow cyanobacteria in low-pressure/high pCO2 atmospheres.

Table 1. Environmental parameters on Mars and Earth surfaces (adapted from Graham [Reference Graham2004] and Kanervo et al. [Reference Kanervo, Lehto, Ståhle, Lehto and Mäenpää2005])

The most striking shortage of substrates on Mars derives from the low partial pressure of N2 (pN2) in the atmosphere and the presumed low availability of N in the regolith. Some work performed with Azotobacter vinelandii and Azomonas agilis showed that microbial N fixation is possible at a pN2 of 5 hPa, even though below 400 hPa growth rates decreased with decreasing pN2 (Klingler et al. Reference Klingler, Mancinelli and White1989). The lower limit for N fixation might vary among species and is still to be defined, but it has been proposed to be within the range of 1–10 hPa (McKay & Marinova Reference McKay and Marinova2001). Crossing this limit using Mars's air composition would require at least 5–50 times the local ambient pressure (reaching a total pressure of approximately 40 hPa to 40 kPa). However, pN2 would still be limiting and higher values are needed for efficient processes. Rather than only increasing the total pressure to reach adequate pN2 values, N2 could be concentrated by separating CO2 from the other atmospheric gases (mainly N2 and Ar) and mixing them in different proportions to reach an appropriate pN2 value in an otherwise optimized total pressure. Gas separation techniques are well developed (see, for instance, Meyer & McKay Reference Meyer, McKay, Stoker and Emmart1996 and Zubrin & Wagner Reference Zubrin and Wagner2011) and could be based on processes routinely used by industry on Earth. Assuming similar pN2 needs for cyanobacteria as for A. vinelandii and A. agilis (see Klingler et al. Reference Klingler, Mancinelli and White1989), a pN2 of 95 hPa would only slightly limit growth (experiments are planned to define the lowest pN2 allowing efficient growth of diazotrophic cyanobacteria). For wild-type, diazotrophic cyanobacteria, a 100 hPa atmosphere with 95% N2 and non-limiting (5%) CO2 could thus lead to higher growth rates than an Earth-like atmosphere. Cultures could also be supplemented with N recycled from human and biomass waste, even though this should not be the only N source as sustainability and expandability would be compromised.

Depending on its adjusted pressure, a Martian-like atmosphere can strongly affect other aspects of the lithotrophic growth of cyanobacteria through indirect effects (e.g., a lowered pH due to H2CO3 formation can influence both cell viability and nutrient release from substrates). As for all processes suggested here, extensive and faithful simulations of culture conditions expected to be provided on-site are needed.

Atmosphere of selected gas composition and pressure could be provided within inflatable, tunnel-like containments (Lehto et al. Reference Lehto, Lehto and Kanervo2006). Tight sealing should allow the desired pressure to be maintained, and adjusted gas supply systems could allow CO2 and some N2 to be provided from Martian atmosphere – possibly after N enrichment. An onion-like structure, with a pressure gradient throughout layers, has also been proposed. This would offer the additional advantages of a better filtering of the Martian dust and a better thermal insulation (Lehto et al. Reference Lehto, Lehto and Kanervo2006).

Water

One of the most critical resources to provide to cyanobacterial cultures will be water. As water is needed within human outposts, regardless of the use of cyanobacteria, various hardware systems for its extraction and processing on Mars have been suggested elsewhere. There follow a few examples of water sources and mining techniques under consideration. This list is not exhaustive.

Water could be generated on Mars by importing H2 from Earth and combining it to O from local CO2 (Zubrin et al. Reference Zubrin, Baker and Gwynne1991) but, even though H represents only 11% by weight of pure H2O, relying on imported H2 would strongly limit the autonomy and sustainability of human outposts. However, water can be found in various forms throughout Mars (reviewed in Tokano Reference Tokano2005; Rapp Reference Rapp2007 and Cockell Reference Cockell2014). It is present in large amounts as ice at the north polar ice cap and under the south carbon ice cap, and throughout the planet as near-surface deposits of water ice. The presence of liquid water has to date not been unquestionably established, but several lines of evidence strongly suggest transient liquid brines (Zisk & Mouginis-Mark Reference Zisk and Mouginis-Mark1980; McEwen et al. Reference McEwen, Ojha, Dundas, Mattson, Byrne, Wray, Cull, Murchie, Thomas and Gulick2011; Martín-Torres et al. Reference Martín-Torres2015). It might also exist below the cryosphere, in areas where temperatures and pressures are high enough (e.g., Clifford et al. Reference Clifford, Lasue, Heggy, Boisson, McGovern and Max2010), possibly within drilling range. The abundance, location and nature of near-surface water deposits is still to be accurately determined, but mining these to generate usable water may be practical (e.g., Rapp Reference Rapp2013). If it appears that mining liquid water or large ice deposits cannot be done, water could be extracted from the soil's hydrated minerals. Energy requirements for heating soil at 500°C in an oven, before collecting steam, have been assessed to be about 5.2 kWh kg−1 of water in a 2%-water soil, plus a small amount (below 0.1 kWh kg−1 of water) for excavating and conveying the soil (Stoker et al. Reference Stoker, Gooding, Roush, Banin, Burt, Clark, Flynn, Gwynne, Lewis, Matthews and Guerrieri1993). Other processes where soil is heated for water extraction are under consideration, including the use of focused light and of microwaves, the latter being one of the most promising regarding energy requirements, mass and reliability (Wiens et al. Reference Wiens, Bommarito, Blumenstein, Ellsworth, Cisar, McKinney and Knecht2001; Ethridge & Kaulker Reference Ethridge and Kaulker2012). A team of the Colorado School of Mines designed a system, referred to as the Microwave Pizza Oven, aimed at extracting water from the soil of Mars using microwaves (generated using about 12 kWh kg−1 of water, provided by silicon solar cells) in conjunction with a conveyor belt mechanism to process soil and extract bound water. Expected yields are in the order of 1 kg of water per 2.5 h in a 2%-water soil, for a system's mass below 20 kg (Wiens et al. Reference Wiens, Bommarito, Blumenstein, Ellsworth, Cisar, McKinney and Knecht2001). The use of microwave heating could also reduce dramatically excavation needs, as microwaves could be inserted down bore holes to heat at desired depths (Ethridge & Kaulker Reference Ethridge and Kaulker2012). But energy and excavation needs for water extraction from the soil could be further reduced: according to Zubrin & Wagner (Reference Zubrin and Wagner2011), a 0.1 mm thick polyethylene dome could be used to farm-selected soil sites by increasing temperature and collecting volatilized water in a cold trap device. Using this approach, a 25 m, 100 kg dome ringed by reflectors could allow about 150 kg of water to be farmed in an 8 h day from a soil with 2% water (Zubrin & Wagner Reference Zubrin and Wagner2011).

There is also water vapour in the atmosphere. Relying on it rather than on soil water would remove the need for processing regolith and/or to move to new locations once a site has been dried up. Concentrations vary through time and location and are very low, but total atmospheric water has been assessed to amount to approximately 1.3 km3 (1.3 × 109 litres), in very large excess compared with human need for a research base, and extracted water would be renewed naturally by exchange with regolith and polar caps (McKay et al. Reference McKay, Meyer, Boston, Nelson, McCallum, Lewis, Matthews and Guerrieri1993). In spite of the large volumes of atmosphere that need to be processed, water extraction from the Martian atmosphere could be done with an energy consumption below 100 kWh kg−1 using a process of atmosphere cooling/compression and water condensation designed by Meyer & McKay (Reference Meyer, McKay and Boston1984) and improved by Clapp (Reference Clapp and McKay1985). Note that energy used in this process would not be dedicated to water extraction, as atmospheric gas could be isolated using the same setup. Energy needs for water extraction from the atmosphere could be brought further down, as shown by a system referred to as the Water Vapour Adsorption Reactor (WAVAR). In WAVAR, atmosphere is filtered and drawn through a regenerative adsorbent bed of zeolite molecular sieve, from which water is later desorbed using microwave radiation (Williams et al. Reference Williams, Coons and Bruckner1995; Coons et al. Reference Coons, Williams and Bruckner1997; Schneider & Bruckner Reference Schneider, Bruckner and El-Gen2003). Energy consumption has been assessed as ranging from approximately 3 to 30 kWh kg−1 of water, depending on time and location (Grover & Bruckner Reference Grover and Bruckner1998). Additional water could be recycled from human metabolism (about 0.4 kg of transpiration water and respiration moisture a day per crewmember) and human waste (Meyer & McKay Reference Meyer and McKay1989; Tikhomirov et al. Reference Tikhomirov, Ushakova, Kovaleva, Lamaze, Lobo and Lasseur2007). It will also be a by-product of physicochemical processes such as on-site production of biofuels and materials (e.g., Zubrin et al. Reference Zubrin, Brian and Tomoko1997). The systems described above are still in their infancy; increasing knowledge of Mars's resources, coupled to engineering effort, will likely support the development of more efficient water mining technologies and processes.

Strategies can also be developed to minimize water needs for cyanobacterial culture systems, in addition to recycling water from culture effluents. For the production of some products where cells lysis is not needed, water requirements (as well as requirements for maintenance, nutrients and energy) could be reduced by immobilizing cyanobacteria within polymeric matrices. Such entrapment can preserve cyanobacteria's metabolic activities for prolonged periods of time, up to several years (Lukavský Reference Lukavský1988; Hertzberg & Jensen Reference Hertzberg and Jensen1989; Chen Reference Chen2001). Water requirements could be further reduced by growing terrestrial cyanobacteria as biofilms, directly on the surface of Martian rocks, in a semi-closed environment where suitable temperature, pressure and moisture are provided. Such a growth system could be relatively close to the natural lifestyle of rock-dwelling cyanobacteria, noteworthy in terrestrial deserts (see, e.g., Friedmann & Ocampo Reference Friedmann and Ocampo1976; de la Torre et al. Reference de la Torre, Goebel, Friedmann and Pace2003; Warren-Rhodes et al. Reference Warren-Rhodes, Rhodes, Pointing, Ewing, Lacap, Gómez-Silva, Amundson, Friedmann and McKay2006 and Billi et al. Reference Billi, Baqué, Smith and McKay2013) but with more favourable moisture, UV protection and temperatures.

Finally, a reduced pressure at growth-permissive temperatures, as envisioned in the culture system, will foster water evaporation. However, if pN2 sets the lower limit for atmospheric pressure and the culture system provides about a tenth of Earth's atmospheric pressure at sea level (see subsection ‘Atmospheric pressure and composition’), evaporation can easily be reduced by saturating the incoming air with water vapour (Kirsi Lehto, personal communication). Besides, as the system needs to be air-tight (apart from controlled gas exchange), water loss by evaporation can be minimized.

Solar energy and harmful radiations

On Earth, the solar flux is in large excess compared with the needs of cyanobacteria and green plants, which cannot use more than about 10–20% of maximal sunlight on the surface (Way et al. Reference Way, Silver and Howard2011). Some cyanobacterium species such as Arthrospira spp. can utilize higher light densities but, at least for A. platensis, the radiation level for maximal photosynthesis activity is well below terrestrial mean day values – provided agitation intensity and cell density allow sufficient exposure (Hoshino et al. Reference Hoshino, Hamochi, Mitsuhashi and Tanishita1991). Even though Mars is on average 1.52 times farther from the Sun than Earth and consequently receives about 43% as much sunlight at comparable latitude and time of day, this is in excess compared with photosynthesis needs, even in the case of a dust storm (McKay et al. Reference McKay, Meyer, Boston, Nelson, McCallum, Lewis, Matthews and Guerrieri1993). The light flux needed for optimal photosynthesis of many cyanobacterial species is about 3 × 1019 photons m−2 s−1, which is only about 10% of Mars's average ambient light flux (Lehto et al. Reference Lehto, Kanervo, Stahle, Lehto, Cockell and Horneck2007). At lower light levels photosynthesis is still possible, albeit at lower efficiencies. It has for example been assessed that, at midday at vernal equinox, light levels on Mars are about 5000 times greater than the minimum required for photosynthesis (Cockell & Raven Reference Cockell and Raven2004).

It might be thought challenging to let photosynthetically active radiation (PAR light; 400–700 nm) reach cultures while protecting the latter from harsh radiation – namely UV radiation, solar energetic particles (SEP) and galactic cosmic rays (GCR). First, the fraction of biologically effective UV radiation reaching the surface of Mars is much greater than that reaching the surface of Earth and includes UV-C radiation (<280 nm). The models of Cockell et al. (Reference Cockell, Catling, Davis, Snook, Kepner, Lee and McKay2000) and Schuerger et al. (Reference Schuerger, Mancinelli, Kern, Rothschild and McKay2003) predict a maximum flux of around 50 W m−2 of UV200−400 nm irradiance on the equatorial Martian surface at the mean orbital distance. Recent data from the Curiosity rover suggest lower values, with a maximum UV200−380 nm irradiance of about 20 W m−2 recorded at midday at Gale's crater (Gómez-Elvira et al. Reference Gómez-Elvira2014). Despite being strongly germicidal on the surface, this radiation can be blocked by a few millimetres of Martian dust coverage (Mancinelli & Klovstad Reference Mancinelli and Klovstad2000; Dartnell & Patel Reference Dartnell and Patel2014) or, to let PAR light in, by mere transparent covers such as glass filters.

Besides UV, ionising radiations of SEP and GCR can reach the Martian surface and subsurface with high energies due to Mars's lack of intrinsic magnetic field and thin atmosphere. Pavlov et al. (Reference Pavlov, Vasilyev, Ostryakov, Pavlov and Mahaffy2012) and Dartnell et al. (Reference Dartnell, Desorgher, Ward and Coates2007) assessed absorbed dose rates at the surface to be in the range of 50–150 mGy yr−1, and data from the Curiosity rover indicate an absorbed dose rate of 76 mGy yr−1 at Gale crater (Hassler et al. Reference Hassler2013). Could cells be protected from this radiation? Even though the primary cosmic radiation component decreases with shielding, secondary particles (lighter particles including neutrons and gamma-rays) form when radiation penetrates substrates and dose rates increase with shielding until the Pfotzer maximum, before decreasing due to energy loss, absorption and decay processes. From 76 mGy yr−1 at the surface, for instance, they reach 96 mGy yr−1 under 10 cm of Martian rock with a density of 2.8 g cm−3 (Hassler et al. Reference Hassler2013). The design of culture chambers and the choice of material used for shielding should take into account their interactions with primary radiations on the Martian surface (see Le Postollec et al. Reference Le Postollec2009).

Approximately 5 m of Mars dirt would confer a protection to radiation equivalent to Earth's atmosphere (McKay et al. Reference McKay, Meyer, Boston, Nelson, McCallum, Lewis, Matthews and Guerrieri1993). However, bacterial cells are overall much more radiation-resistant than human cells and such a protection is unlikely to be needed. In addition, cyanobacteria are known to have high ploidy levels (Griese et al. Reference Griese, Lange and Soppa2011), pigments and specific morphological features which tend to increase radio-resistance. The resistance of cyanobacteria to photon irradiation (gamma-rays and X-rays) has been studied as early as in 1951 (Bonham & Palumbo Reference Bonham and Palumbo1951), and the high resistance of some species was observed in the early 1960s (Shields et al. Reference Shields, Durrell and Sparrow1961; Godward Reference Godward and Lewin1962). In the following decade, the resistance of a wide range of species from various genera was tested. Resistance appeared to be highly variable among species, ranging from sensitive ones with D10 (dose required to reduce the viable number of cells by 90%) below 1 kGy to highly resistant ones with D10 above 10 kGy (e.g., Shields et al. Reference Shields, Durrell and Sparrow1961; Godward Reference Godward and Lewin1962; Bruce Reference Bruce1964; Kumar Reference Kumar1964; Kraus Reference Kraus1969; Asato Reference Asato1971). These results were confirmed and deepened by recent studies. Synechococcus and Synechocystis spp. were shown to be relatively sensitive to gamma rays, with D10 of about 0.3 kGy (Domain et al. Reference Domain, Houot, Chauvat and Cassier-Chauvat2004; Agarwal et al. Reference Agarwal, Rane and Sainis2008) and 0.7 kGy (Domain et al. Reference Domain, Houot, Chauvat and Cassier-Chauvat2004), respectively. Two Anabaena strains were shown to tolerate a 5 kGy gamma-ray dose without loss of survival, to have a GI50 (dose where growth is inhibited by 50%) of 6–11 kGy and to survive doses of 15 kGy (Singh et al. Reference Singh, Fernandes and Apte2010; Singh et al. Reference Singh, Anurag and Apte2013). Arthrospira sp. PCC 8005 cells were shown to be able to survive exposure to doses of at least 6.4 kGy of gamma irradiation, 1 kGy of He particle radiation and 2 kGy of Fe particle radiation (Badri et al. Reference Badri, Monsieurs, Coninx, Wattiez and Leys2015). Chroococcidiopsis spp. cells were shown to withstand 2.5 kGy of X-ray irradiation in liquid culture with small to medium viability loss: 20–65%, depending on the strain, with a D10 of 2–5 kGy (Billi et al. Reference Billi, Friedmann, Hofer, Caiola and Ocampo-Friedmann2000a). Viable Chroococcidiopsis spp. cells were also recovered after exposure to 15 kGy of X-rays (Billi et al. Reference Billi, Friedmann, Hofer, Caiola and Ocampo-Friedmann2000a) and to 12 kGy of gamma-rays (Verseux et al. manuscript in preparation). Moreover, no significant DNA or membrane damage was detected after exposure to 1 kGy of He particle radiation, 2 kGy of Fe particle radiation or 1 kGy of Si particle radiation (Verseux et al. manuscript in preparation). A dose of 1 kGy roughly corresponds to a thousand years on the Martian surface, a timeframe way beyond that of division and repair of metabolically active cyanobacteria; cells are therefore not expected to be affected in BLSS cultures. The biological effect of ionizing radiation cannot be assessed based on the dose only: other parameters are to be taken into account – for instance, the composition of the radiation flux and its modification when interacting with the environment and the cells’ properties – but the studies mentioned above show the orders of magnitude involved. Even if the effect of radiation on Mars was, at equivalent dose, more damaging by several orders of magnitude than the radiation flux used in these studies, the replication time and repair dynamics of even slow-growing strains would be way below the time needed to receive a sterilizing dose. Consistently, it has been estimated that even vegetative cells of the bacterium E. coli could survive the ionizing radiation dose that would be received after more than a thousand years on the surface of Mars (Dartnell et al. Reference Dartnell, Desorgher, Ward and Coates2007). More generally, ionizing radiation on Mars is not expected to prevent microbial life (Dartnell et al. Reference Dartnell, Desorgher, Ward and Coates2007; Horneck Reference Horneck2008).

Cultures could be buried inside regolith or covered with regolith-based material: although not expected to be needed for radiation protection, regolith shielding could be relevant for temperature control (taking advantage of the regolith's thermal insulating properties) and protection from the wind and dust. Manufacturing processes could be simple and cost-effective, taking for instance advantage of: (i) the cement-like properties of unprocessed regolith mixed with water (McKay & Allen Reference McKay and Allen1996); (ii) the ubiquity of clay-like materials on Mars; (iii) the large fraction (about 40% by weight of Viking 1 and 2 soil samples) of Martian soil represented by silicon dioxide (the basic constituent of glass); and (iv) the fact that plastics may be derived from local C and H (Zubrin & Wagner Reference Zubrin and Wagner2011). In this case, artificial lighting, mirrors or fibre optics could be used to bring PAR light to the cultures. Lighting could also be electrically powered, using for instance solar, wind or geothermal energy sources. Various studies have been performed regarding electrical lighting for plants in BLSS (easily adaptable to cyanobacterial culture), light-emitting diode (LED)-based systems being the most promising (Massa et al. Reference Massa, Emmerich, Morrow, Bourget and Mitchell2007). However, even though electrical lighting would allow an accurate control on light intensity and photoperiods, energy and mass requirements could be greatly reduced – compared with electrical lighting – by using systems based on fibre-optics technology to harvest and transmit selected wavelengths from solar energy. Several of such systems have been developed in the context of space exploration, among others for the cultivation of microbial phototrophs (Mori et al. Reference Mori, Ohya, Matsumoto and Furune1987) and plants (Jack et al. Reference Jack, Nakamura, Sadler and Cuello2002; Nakamura et al. Reference Nakamura, Van Pelt, Yorio, Drysdale, Wheeler and Sager2009). Equivalent system mass calculations showed a net benefit of using solar lighting rather than electric lighting in this context, under realistic mission assumptions (Drysdale et al. Reference Drysdale, Nakamura, Yorio, Sager and Wheeler2008). The cost effectiveness of such systems may be limited by temporary decreases in light availability (due to diurnal and seasonal light cycles, variable distance from the Sun and global dust storms), which drives a need for increasing collector size relative to culture areas, and may consequently be inadequate for growing plants in Mars BLSS (Massa et al. Reference Massa, Emmerich, Morrow, Bourget and Mitchell2007). They could however represent a solution for growing cyanobacteria, which use light more efficiently and suffer less than plants from temporary reduction of light and from changes in illumination patterns. That being said, the simplest and most cost-effective way of providing PAR could be to directly expose cultures to solar light while protecting them from lethal levels of radiation. A transparent but UV-blocking and thermal insulating material, which should also be resistant to Mars surface conditions in the long term, could be used. Radiation coming from straight above could also be stopped by regolith-based materials, while allowing light to come from the sides at adequate intensities for photosynthesis to occur (de Vera et al. Reference de Vera, Schulze-Makuch, Khan, Lorek, Koncz, Möhlmann and Spohn2014).

Heating will be needed to maintain liquid water and allow metabolism. Heating systems could be either directly based on solar energy, or on electricity generated by solar energy (e.g., using solar panels) and/or based on other power sources used within Martian outposts (e.g., wind, geothermal activity or fuels produced on site). This issue is largely documented elsewhere, as it applies to other components of human colonies such as habitats, and will not be detailed here.

Gravity

Would Mars's lower-than-Earth gravity affect cyanobacteria? The earliest microbiology experiments in space, reported in the early 1960s, did not show any effect of microgravity on individual cells (Zhukov-Verezhnikov et al. Reference Zhukov-Verezhnikov1962). Consistently, theoretical studies suggested that microgravity would not directly affect cells of a diameter below 10 µm, in part due to the density uniformity and smallness of intracellular components (Pollard Reference Pollard1965, Reference Pollard, Gordon and Cohen1967). Later, experiments on-board the orbital station Salyut 6 and biosatellites Kosmos 1887 and 2044 showed that unicellular algae were not affected in their development by microgravity (Sychev et al. Reference Sychev, Shepelev, Meleshko, Gurieva, Levinskikh, Podolsky, Dadasheva and Popov2001). However, a wide range of altered behaviour and growth properties such as increased virulence, reduced lag phase, increased final cell population, increased productivity of secondary metabolites and increased conjugation rates have been reported in later microbiology experiments in spaceflight and simulated microgravity (see, e.g., Nickerson et al. Reference Nickerson, Mark Ott, Mister, Morrow, Burns-Keliher and Pierson2000; Benoit & Klaus Reference Benoit and Klaus2007 and Wilson et al. Reference Wilson2007), in various prokaryotes including cyanobacteria (Wang et al. Reference Wang, Li, Li, Liu, Song, Tong, Liu and Cheng2004, Reference Wang, Chen, Li, Chen, Li, Hu, Chen and Liu2006; Xiao et al. Reference Xiao, Liu, Wang, Hao and An2010). A well-supported hypothesis suggests that these effects are motility-dependent, with non-motile cells being the most affected. This might be explained by the reduced flow of metabolites and nutrients and by the reduced exchanges between bacteria and the environment (e.g., because mass-driven convection does not occur), which result in a modified chemical environment around cells that alters biological responses (Horneck et al. Reference Horneck, Klaus and Mancinelli2010). However, microgravity was shown not to reduce N fixation abilities, photosynthetic O2 production rates or growth in cyanobacteria (e.g., Wang et al. Reference Wang, Chen, Li, Chen, Li, Hu, Chen and Liu2006). Mars's reduced gravity (0.38 g) is consequently not expected to be an obstacle to cyanobacterium-based processes, especially if stirring generates a non-limiting flux of nutrients and metabolites. Studies aimed at confirming that reduced gravity do not alter cell processes of interest would however be useful.

Engineering cyanobacteria

In addition to adapting the Martian environment to cyanobacteria, work can be done to adapt cyanobacteria to the Martian environment. Synthetic biology may provide the tools for this. This field, or set of fields, aroused NASA's interest due to its potential for engineering microorganisms with useful features for resource production in space (Cumbers & Rothschild Reference Cumbers and Rothschild2010; Langhoff et al. Reference Langhoff, Cumbers, Rothschild, Paavola and Worden2011; Menezes et al. Reference Menezes, Cumbers, Hogan and Arkin2014; Verseux et al. Reference Verseux, Paulino-Lima, Baqué, Rothschild, Billi, Hagen, Engelhard and Toepfer2016). In the present context, the use of synthetic biology tools and methods is investigated for optimizing the abilities of selected cyanobacteria to: (i) withstand environmental stresses faced during space exploration missions, and (ii) grow and perform biological functions of interest under on-site constraints (see Fig. 6).

Fig. 6. Simplified overview of the potential roles of synthetic biology in the development of Mars-specific, cyanobacterium-based BLSS.

Increasing cyanobacteria's abilities to withstand extreme conditions would allow failure risk and culture system-related costs to be minimized (Cockell Reference Cockell2010; Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010). First, for storage during the journey: cells’ tolerance to long periods of dehydration, possibly in a differentiated state (e.g., akinetes), would allow a storage free of risk of loss by freezing failure. Secondly, for growth on site: higher tolerance to Mars's environmental factors would reduce the required level of shielding. It would also increase safety in case of system malfunction during which cultures could be exposed to harsher conditions (e.g., desiccation, low pressure, high radiation levels, altered pH and sudden temperature shift), either when stored or grown. Thirdly, increasing the abilities of cyanobacteria to rely on on-site resources would allow productivity to be increased while relaxing constraints and supplementation needs. In particular, it would be highly beneficial to increase their abilities to leach Martian mineral resources and to get most of their nutrients from these, within a wide range of pH, and to fix N at a lower pN2. Finally, new functions and nutritional properties could be engineered and optimized under conditions that would be provided within Mars bases.

To increase their resistance, cyanobacteria could be transformed with heterologous genes known to increase fitness under conditions found on the surface of Mars (Cumbers & Rothschild Reference Cumbers and Rothschild2010). This approach has been successful in other contexts: for instance, E. coli's resistance to gamma irradiation, to desiccation and to low temperatures has been increased by expressing, respectively, the PprI protein from Deinococcus radiodurans (Gao et al. Reference Gao, Tian, Liu, Sheng, Shen and Hua2003), a sucrose-6-phosphate synthase from Synechocystis sp. strain PCC 6803 (Billi et al. Reference Billi, Wright, Helm, Prickett, Potts and Crowe2000b) and the chaperonin Cpn60 and co-chaperonin Cpn10 from the psychrophilic bacterium Oleispira antarctica (Ferrer et al. Reference Ferrer, Chernikova, Yakimov, Golyshin and Timmis2003). Once specific genes have been shown to confer an advantage to a targeted stress in a target organism, they could be improved using various computational and molecular biology tools and methods. These are becoming more and more efficient thanks to, among other factors, a sharp decrease in DNA synthesis costs, the improvement of automated gene assembly methods, and the development of biological computer-aided design (BioCAD) and other computational tools.

However, despite the fact that expressing heterologous genes (or overexpressing homologous genes) may confer a significant advantage in coping with some environmental stressors, this approach might be much more challenging for resistance features which are highly multifactorial, each individual factor having a relatively weak impact. There is not a single factor that confers on D. radiodurans its extreme radiation resistance, for instance, but a very wide combination of features, including efficient DNA repair mechanisms, anti-oxidation mechanisms and specific morphological features (see, for instance, Slade & Radman Reference Slade and Radman2011). For this kind of feature, dramatic increases through rational design seem very challenging given bio-engineering's current state-of-the-art. Instead, directed evolution – iterations of mutagenesis and artificial selection – at the scale of the whole organism can allow complex modifications, affecting both known and unknown mechanisms. The dynamics of experimental evolution have been widely studied in recent decades and have been successfully used to increase organisms’ specific properties (see, e.g., Elena & Lenski Reference Elena and Lenski2003 and Conrad Reference Conrad2011), including radiation resistance in bacteria (Ewing Reference Ewing1995; Harris et al. Reference Harris2009; Wassmann et al. Reference Wassmann, Moeller, Reitz and Rettberg2010; Goldman & Travisano Reference Goldman and Travisano2011).

For increasing the abilities of cyanobacteria to use resources found on-site, and for conferring on them abilities (and/or improving these abilities) to produce resources of interest from local resources, rational genetic engineering might be more efficient than it is for increasing resistance. Some clues have even been given regarding the engineering of microorganisms with increased bioleaching abilities (Cockell Reference Cockell2011). However, despite metabolomics's great advances in the last decade and the synthetic biology benefiting from it (see, for instance, Ellis & Goodacre Reference Ellis and Goodacre2012 and Lee Reference Lee2012), the complex interactions occurring in cells are still hard to predict and whole-cell-scaled directed evolution will here again be very useful.

One of the main issues when designing an optimization process based on directed evolution is the need for either linking the optimized function (e.g., production of a compound of industrial interest) to organisms’ fitness or selecting mutants after screening. When increasing resistance to environmental stressors (e.g., low pressure or radiation) or abilities to use a given nutrient source (e.g., Martian regolith or atmosphere), the process is more straightforward: selection can be done by applying increasing levels of the targeted stress (when improving resistance) or by conducting growth/re-inoculation cycles to let fast-growing mutants become dominant (when improving use of a given nutrient source). Directed evolution can be improved by automation (Dykhuizen Reference Dykhuizen1993; de Crecy et al. Reference de Crecy, Jaronski, Lyons, Lyons and Keyhani2009; Marlière et al. Reference Marlière, Patrouix, Döring, Herdewijn, Tricot, Cruveiller, Bouzon and Mutzel2011; Grace et al. Reference Grace, Verseux, Gentry, Moffet, Thayabaran, Wong and Rothschild2013; Toprak et al. Reference Toprak, Veres, Yildiz and Pedraza2013) and by recent methods such as, for instance, genome shuffling (Patnaik et al. Reference Patnaik, Louie, Gavrilovic, Perry, Stemmer, Ryan and del Cardayré2002) and multiplex genome engineering (Wang et al. Reference Wang, Isaacs, Carr, Sun, Xu, Forest and Church2009). It might also be more efficiently performed on Mars, once a microbial production system is well established and automated (Way et al. Reference Way, Silver and Howard2011): Earth-based simulations of some of the factors encountered on Mars (and their combinations) are difficult, expensive and cannot faithfully reproduce all of their effects. The most straightforward use of directed evolution would be to improve cyanobacterial cultures’ productivity by, for example: (i) increasing the abilities of cyanobacteria to grow faster under low (and to grow at lower) pressures, including low pressures of Mars-like gas compositions; (ii) improving their efficiency to extract mineral nutrients from Martian regolith; and (iii) increasing their resistance to potentially toxic elements in the regolith (e.g., perchlorates). As selective pressure for some of these factors is low or inexistent on Earth, fitness under these conditions is likely far from its evolutionary potential and could be largely increased by directed evolution. The amounts of resources allocated to cyanobacterial cultures for producing a given amount of other resources could thereby be significantly reduced. Besides direct applications, performing directed evolution could give clues on whether and how much organisms can genetically adapt to the Martian environment, and therefore help assessing the risk of biological contamination in case of accidental release.

Rational genetic engineering and directed evolution are not mutually exclusive: they can be used in combination (Rothschild Reference Rothschild2010). Rationally engineered organisms can be submitted to directed evolution for optimization and, conversely, data obtained from genome sequencing of evolved organisms (so as to understand which mutations are responsible for improved properties) can give gene targets for rational design.

Besides increased resistance and abilities to thrive on local substrates, synthetic biology could be used to confer on cyanobacteria specific functions for Mars-specific BLSS. Numerous genetic engineering tools and methods have been developed for enhancing their metabolic capabilities. Various applications which are considered on Earth (see, e.g., Wang et al. Reference Wang, Wang, Zhang and Meldrum2012 and Berla et al. Reference Berla, Saha, Immethun, Maranas, Moon and Pakrasi2013) could be useful on Mars as well, but others might be developed specifically for this planet (Verseux et al. Reference Verseux, Paulino-Lima, Baqué, Rothschild, Billi, Hagen, Engelhard and Toepfer2016). Some resources may be much easier to obtain using synthetic biology when on Mars, while being easier to obtain by other means (e.g., by chemical methods, using the natural host or by simply harvesting rather than producing them) when on Earth. Finally, metabolic pathways might differ: the set of potential starting compounds will be much reduced on Mars and some substrates that are cheap and abundant on Earth will be extremely hard to provide there, changing the cost-effectiveness of a given pathway.

A critical issue to be faced is genetic instability: artificial gene constructs might be lost. Plasmids are useful for screening and optimization steps, but are generally too unstable to be used on a large scale and in the long term. Exogenous genes should rather be irreversibly inserted in cyanobacteria's genomes, which leads to much higher stability and more control over expression levels (e.g., Herrero et al. Reference Herrero, De Lorenzo and Timmis1990; Heap et al. Reference Heap, Ehsaan, Cooksley, Ng, Cartman, Winzer and Minton2012). Genome insertion in cyanobacteria is made harder than in most model bacteria by their polyploidy and the unviability of recA mutants (Murphy et al. Reference Murphy, Gasparich, Bryant and Porter1990; Matsuoka et al. Reference Matsuoka, Takahama and Ogawa2001), but specific methods are available to do so (e.g., Andersson et al. Reference Andersson, Tsinoremas, Shelton, Lebedeva, Yarrow, Min and Golden2000: Takahama et al. Reference Takahama, Matsuoka, Nagahama and Ogawa2004; Clerico et al. Reference Clerico, Ditty and Golden2007; Chaurasia et al. Reference Chaurasia, Parasnis and Apte2008). For standard, organism-scaled directed evolution, genome integration will not be an issue as variability will mostly affect genomes. However, even when integrated into a genome, modifications may be lost. How commonly this phenomenon is encountered among teams performing cyanobacterium genetic engineering, and how limiting the issue is, is hard to assess due to a tendency not to document failures (Jones Reference Jones2014). Many reports of successful and stable genetic constructs in cyanobacteria can be found (e.g., Guerrero et al. Reference Guerrero, Carbonell, Cossu, Correddu and Jones2012; Bentley et al. Reference Bentley, Zurbriggen and Melis2014; Dienst et al. Reference Dienst, Georg, Abts, Jakorew, Kuchmina, Börner, Wilde, Dühring, Enke and Hess2014), but a few others document instability (e.g., Takahama et al. Reference Takahama, Matsuoka, Nagahama and Ogawa2003; Angermayr et al. Reference Angermayr, Paszota and Hellingwerf2012). In spite of the lack of available data, it is expected that modifications having a negative effect on growth (e.g., insertion of a system to produce a chemical of no use to the producing cyanobacteria) is more likely to be counter-selected than modifications conferring an advantage on cyanobacteria (e.g., a better ability to use provided substrates or to withstand environmental stress factors) under a given selection pressure, as far as this pressure is maintained. Studies are needed to determine how problematic genetic instability in cyanobacteria is and to develop appropriate solutions

Future research needs

What would be the efficiency of a cyanobacterium-based BLSS? This question can currently be answered only tentatively. There follows an example of a scenario, with some back-of-the-envelope calculations. Using a strain of wild-type Anabaena sp. and assuming that regolith on Mars is as suitable as a substrate as terrestrial basaltic analogues, obtaining a saturated culture from a tenfold dilution takes, roughly, 1 month (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010; Olsson-Francis et al. Reference Olsson-Francis, Simpson, Wolff-Boenisch and Cockell2012; Verseux et al., unpublished data), without taking into account the growth-enhancing effects of a low-pressure/high-CO2 atmosphere and of potential nutrients from recycled human waste products. Starting with a 1 litre culture (or from cyanobacteria concentrated from 1 litre, to further reduce volume and mass) and if the limiting factor was cyanobacterial growth, a 103 m3 (106 litre) saturated culture could be obtained within 6 months, and a 1 km3 (1012 litre) culture within 1 year. Assuming growth rates and final biomass yields as in Olsson-Francis & Cockell (Reference Olsson-Francis and Cockell2010)'s experiments with a basaltic regolith simulant, growth rates would be roughly 0.3 day−1 and biomass at saturation 100 mg l−1. With a 103 m3 culture, 1.5 × 105 litres of culture (corresponding to 15 kg of dry biomass) could be harvested every day. How do these figures relate to needs in BLSS? Assuming energy contents similar to A. platensis's (Tokusoglu & Unal Reference Tokusoglu and Unal2003), about 500 g of dry biomass per crewmember would cover the crew's caloric needs (as mentioned above, covering caloric needs do not imply providing a healthy diet). If cells produce O2 with yields per unit of dry biomass as C. vulgaris in BIOS-I (Kirensky et al. Reference Kirensky, Terskov, Gitelson, Lisovsky, Kovrov and Okladnikov1968; Gitelson Reference Gitelson1992), the amount of culture used as food would also provide enough O2 for crewmembers’ respiration. Based on preliminary results, a 10 litre batch of lysed cyanobacteria could yield 10 ml of a culture medium for heterotrophic microorganisms in which E. coli could reach more than 109 cells ml−1 in 24 h; the amounts of cyanobacterial culture allocated to the growth of heterotrophic microorganisms would thus be negligible for most applications. Assessing the conversion efficiency of cyanobacterium-to-plant biomass would be too tentative without further experiment; however, given that more than 90% of plants’ dry weight comes from C, O and H (see, for instance, Latshaw & Miller Reference Latshaw and Miller1934), which can be obtained by plant photosynthesis from CO2 and H2O, it is reasonable to assume that the plant mass-to-cyanobacterium mass ratio can be much higher than 1, as with nutrients provided in commercial hydroponic systems.

These estimations are far from accurate; firstly, because productivity will be highly dependent on choices which are still to be made and, secondly, because too much biological data are missing. In addition, these estimations are on the pessimistic side, as they are based on preliminary experiments performed in conditions which were not optimized. In this scenario, the time to develop large cultures is not an issue (crewmembers could rely on resources imported from Earth during the first months) but outputs per resource unit can be, and should be, extensively improved. Consequently, much work is still to be done before functional cyanobacterium-based BLSS are developed. Some of the needed tasks, mostly dealing with optimization and characterization, are briefly described below. This list is not exhaustive and the mentioned requirements have room for flexibility.

Firstly, the most promising strains should be selected according to their relevance for Mars BLSS. Selection criteria can include their abilities to grow under conditions easily providable within Mars bases (mainly, to leach Martian regolith analogues, to efficiently fix N, and to be undemanding and flexible regarding nutrient inputs), their resistance to environmental conditions to be faced on Mars and during the journey, their growth rates, their suitability for genetic engineering, their abilities to perform specific tasks and/or their nutritional properties. The best option may be a combination of species rather than a single species, but versatility could reduce the number of strains and keep the system simple. Among interesting candidates are species from the genera Arthrospira, Cyanothece, Chroococcidiopsis, Anabaena/Nostoc and Synechococcus/Synechocystis. As described above, Arthrospira species are well studied in the context of life support because of the high productivity of their cultures, their edibility and their nutritional values. However, these species are demanding in terms of culture conditions, do not seem to efficiently leach regolith (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010) and do not fix N. Cyanothece sp. ATCC 51142 has been proposed as a complement to plants in BLSS due to its relatively high growth rates, N fixation abilities, versatile metabolism and probable edibility (Schneegurt et al. Reference Schneegurt, Arieli, McKeehen, Stephens, Nielsen, Saha, Trumbo and Sherman1995, Reference Schneegurt, Arieli, Nielsen, Trumbo and Sherman1996; Schneegurt & Sherman Reference Schneegurt and Sherman1996). Chroococcidiopsis species (see Fig. 7) have also been suggested as BLSS components (Billi et al. Reference Billi, Baqué, Smith and McKay2013), as they are dominant in terrestrial sites considered as Mars analogues due to radiation, rock composition, drought and extreme temperatures, and have been shown to be highly resistant to various simulated space and Martian conditions (Thomas et al. Reference Thomas, Boling, Boston, Campbell, McSpadden, McWilliams and Todd2006; Cockell et al. Reference Cockell, Rettberg, Rabbow and Olsson-Francis2011; Baqué et al. Reference Baqué, de Vera, Rettberg and Billi2013, Reference Baqué, Verseux, Rabbow, de Vera and Billi2014). Another advantage comes from their resistance to long-term desiccation (Billi Reference Billi2009), which is of strong interest for long-term storage: cells could be carried in a dry state and be rehydrated upon arrival. Among bacteria that can withstand long-term desiccation, the only species that can currently be genetically engineered belong to this genus (Billi Reference Billi and Méndez-Vilas2010, Reference Billi2012). Their main drawbacks are their slow growth rates (depending on the strain, their generation time ranges from about 4 to 16 days; see Billi Reference Billi and Méndez-Vilas2010) – a common feature among rock-interacting extremophiles (Cockell Reference Cockell2011) – and, as in the case of Arthrospira spp., their need for fixed N supplementation (a few studies suggest that some strains could fix N under specific conditions [Boison & Mergel Reference Boison and Mergel2004; Banerjee & Verma Reference Banerjee and Verma2009], but this is still to be confirmed). Then, species from the closely related Anabaena and Nostoc genera (see Fig. 7) seem very promising. In addition to their high growth rates (by cyanobacterial standards), they can fix N and some species have extensive bioleaching abilities (Arai et al. Reference Arai, Tomita-Yokotani, Sato, Hashimoto, Ohmori and Yamashita2008; Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010; Olsson-Francis et al. Reference Olsson-Francis, Simpson, Wolff-Boenisch and Cockell2012). When cyanobacterium species from different genera were tested for their abilities to grow in distilled water containing only powdered analogues of Mars basaltic rocks, A. cylindrica had the maximum biomass production and the greatest specific growth rate under these conditions (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010). This species also forms akinetes, providing high resistance to simulated Martian surface conditions (Olsson-Francis & Cockell Reference Olsson-Francis and Cockell2010), to simulated space conditions and to low Earth orbit conditions (Olsson-Francis et al. Reference Olsson-Francis, de la Torre, Towner and Cockell2009). Some species are suitable for genetic engineering and Anabaena sp. PCC7120 has already been modified to produce and secrete sucrose, which can be used to sustain the growth of heterotrophic organisms (Stanford-Brown 2011 iGEM team 2011). Several strains, notably A. cylindrica, are very efficient H2 producers (Abed et al. Reference Abed, Dobretsov and Sudesh2009). Additionally, some strains are edible: N. commune, N. flagelliforme and Anabaena spp. in symbiosis with Azolla spp., for instance, are traditionally consumed. Finally, using model cyanobacteria such as Synechocystis spp. and Synechococcus spp. might also be a fruitful approach: their natural metabolic and resistance properties may be less appealing than those of the above-mentioned strains, but their high growth rates, well-characterized metabolism and availability of engineering tools (Berla et al. Reference Berla, Saha, Immethun, Maranas, Moon and Pakrasi2013) could make them relevant chassis organisms, provided extensive engineering is performed. Whether emphasis should be put on extremophile properties or metabolic functions of interest when selecting strains in this context has been questioned. The answer might vary according to the scenario, and stages, of colonization: if protection can be provided at low cost, for instance, the need for resistance is reduced and priority can be given to metabolic functions. It may also depend on the development of our abilities to confer new metabolic pathways on extremophiles and to increase resistance of species of metabolic interest. A summary of the main advantages of the genera mentioned in this paragraph is given in Table 2. Generally speaking, a relatively low number of cyanobacterium species and strains have been tested so far against factors relevant for BLSS. Systematic tests could point out new candidate species and strains. After and/or in parallel to the selection, genetic engineering can be used to improve the relevance of the strains of interest.

Fig. 7. Two examples of cyanobacteria: Anabaena sp. PCC7120 and Chroococcidiopsis sp. CCMEE 029.

Table 2. Examples of cyanobacterial genera of relevance for Mars-specific BLSS

Next, a compromise should be identified between (i) conditions (radiation shielding, atmospheric composition and pressure, gravity, nutrient supply, etc.) optimizing growth and metabolism of the selected microorganisms, and (ii) conditions that depend as much as possible on resources available on site and that minimize costs (e.g., low atmospheric pressure mainly composed of CO2 and N2). The minimal parameters needed for efficient metabolism of photosynthetic microorganisms remain poorly defined and, even more than extreme values of individual parameters, the effects of their combinations are poorly documented (Harrison et al. Reference Harrison, Gheeraert, Tsigelnitskiy and Cockell2013). Extensive characterization work is thus needed. More specifically, conditions closest to Martian surface conditions while supporting growth, photosynthetic activity and, for some species, N fixation and H2 production, should be defined. In particular, the minimal pressure of a gas mixture similar to the Martian atmosphere (possibly enriched in N2, though) which is suitable should be identified. The use of Martian regolith as a nutrient source for all compounds except C and N should also be studied in this context, as microorganisms’ interactions with minerals are poorly characterized, even in ambient terrestrial environments. It should be noted that suitable culture conditions are expected to be organism- and application-specific and, as described above, all these features could also be increased by genetic engineering. In any case, the genetic stability of the strains of interest under expected culture conditions should be tested to ensure that the efficiency of targeted processes and nutritional properties are not affected in the long term: targeted modifications may be lost (as described in section ‘Engineering cyanobacteria’), but mutations can also appear at other genomic loci and spread, even in the absence of a strong selection pressure (e.g., Kanesaki et al. Reference Kanesaki, Shiwa, Tajima, Suzuki, Watanabe, Sato, Ikeuchi and Yoshikawa2012; Trautmann et al. Reference Trautmann, Voß, Wilde, Al-Babili and Hess2012).

Once a compromise between efficient growth and low cost has been identified, culture hardware that can provide the selected conditions directly on Mars's surface, from on-site resources, can be designed. Extensive on-ground testing should be performed to demonstrate operational capability of all the components of the system. A prototype could then be tested for its ability to support the growth of cyanobacteria in the long term in simulated Mars surface conditions

If edible cyanobacteria and plants are to be used as food during Mars missions, whether their nutraceutical properties are affected under the expected conditions should be investigated. A suitable diet could then be designed, which would cover nutritional needs while being psychologically satisfying in the long term. It might involve a combination of processed cyanobacteria and plants to balance protein, carbohydrate and lipid ratios while having a pleasant taste, although adequate processing and genetic modifications of cyanobacteria may make the use of plants unnecessary in this context.

Outputs (biomass, released metals, O2, etc.) under the expected culture conditions should be accurately characterized for a clear vision of the scale needed and to assess the relevance of the system in various mission scenarios, including varying duration of mission and crew size. In particular, it would be useful to determine in which cases this system would be advantageous compared with stored supplies and resupply from Earth. How many resources could be produced, and how many crewmembers could be supported as a function of starting compounds (e.g., regolith amounts, atmospheric gas and culture supplements), initial payload mass, needed cultivation surface, crew-time and energy consumption? Extensive mathematical modelling, including results from laboratory simulations, would be useful. Some physical tests should be conducted on Earth (where the experiment can be stopped in case of a major problem), possibly with isolated crews in Mars analogue sites. However, some of the conditions that will be faced on-site (e.g., reduced gravity and space radiation) cannot be faithfully simulated. In particular, despite giving useful insights, ground-based reduced gravity simulators each have specific artefacts (e.g., centrifugal accelerations of clinostats) and only real spaceflight can be used for unambiguously asserting the effects of reduced gravity on a biological system (Herranz et al. Reference Herranz2013). Testing the components of the system in space, for instance on-board the International Space Station or within commercial satellites, would consequently be an important step in demonstrating the system's feasibility. Some useful regolith simulants are available, but given differences between these and real Martian regolith, validating some aspects of the system (e.g., growth rates while using it as a nutrient source, toxicity, etc.) would ideally be done using real Martian soil, provided sufficient amounts could be brought back by sample return missions.

The investigated processes should obviously not be developed in total isolation, but rather be grounded into broader Mars exploration plans and foreseen technologies. In particular, it seems critical to ensure its compatibility with currently developed life-support systems: since a cyanobacterium-based system could connect on-site resources and BLSS by turning the former into a substrate for the latter, it could be conjugated with advanced BLSS projects (e.g., MELiSSA), making these suitable for a Martian base. Technologies and processes could be developed and tested to make the link between the concepts described in this paper and other BLSS projects. For instance, studies could point out the most efficient ways of processing cyanobacterial biomass and released nutrients to feed specific BLSS's plant and microbial modules.

As BLSS for human bases on Mars implies growing living organisms there, planetary protection is a critical concern. The Committee on Space Research (COSPAR)'s requirements for planetary protection need to be extended for manned Mars exploration (Horneck Reference Horneck2008), especially if human colonies rely on microbial cultures for life support and industrial processes. The planetary protection-associated risks of the concepts described above should be thoroughly investigated, and strategies to mitigate these risks developed. The main concern will be to bring contamination risks at regions of scientific interest down to close to zero.

Then, generated data can be gathered to propose an accurate and practical solution for the establishment of BLSS which are suitable for sustainable human outposts on Mars. The next steps will be to integrate this solution into mission plans, to test it on site while backup resources are available, and finally to implement it.

Conclusion

Advances in applied physics will allow us to step on Mars; advances in applied biology can allow us to settle there.

Landing humans on Mars in the 2020–2030s is targeted by several public and private institutions. NASA's Orion capsule successfully made its first in-space test last December. SpaceX's CEO Elon Musk will unveil his Mars colonization plans by the end of the year. Mars One is in the process of selecting crewmembers. Other institutions might enter this ‘Mars race’. But whoever is the first to land, the same issue will have to be faced: if we are to stay on Mars in the long term to obtain valuable scientific data, we need to learn to be independent of Earth. However, while space travel technologies have made great steps forward in the last half century, current life-support technologies are not sufficiently developed for sustaining Mars manned exploratory missions (Horneck et al. Reference Horneck2006). Extensive efforts in this area should start now, so that life support does not become the limiting factor.

Living organisms, wild-type or modified using synthetic biology, are likely to become essential components of life-support systems. But in order to be independent of Earth, they should rely almost exclusively on local resources once set up from an initial set of components. Biological systems should be connected to Martian resources and cyanobacteria could provide this link. Selected – and possibly engineered – cyanobacteria and an appropriate culture system kept to a minimum thanks to cyanobacteria's adaptability to extreme environmental conditions.

The concepts presented in this paper are not intended as a full life-support system plan. They are rather intended as a proposed link between on-site resources and BLSS, through processing of local materials to make these suitable inputs for BLSS. This basis could be combined to currently developed BLSS, making these sustainable, autonomous and expandable within Mars bases. Efforts can thus be combined rather than duplicated. Basic requirements (e.g., food and O2) could also be covered directly by cyanobacterial cultures. Some of these functions could be performed by other means (e.g., physicochemical technologies and cultures of other organisms), but cyanobacteria would provide simple (and consequently characterized by a relatively low number of potential causes of failure) and flexible processes to complement other technologies and provide a safe redundancy. With the extremely fast progress which is being made in microbial engineering, more and more processes needed within Martian outposts could be performed by cyanobacteria. This versatility is a strong advantage when mass and resource use need to be kept to a strict minimum.

Even though the last decades have raised our knowledge in this field, much work is still needed to develop the concepts presented here. How challenging it will be to turn these concepts into reliable systems is currently hard to predict. Firstly, we are still learning about the Martian environment; several parts of this paper had to be modified during the writing process to integrate new inputs from the Curiosity rover. Discovering new factors can make things appear easier – for instance, if organic substrates are discovered to be widely available – or more challenging – for instance, with the discovery of toxic elements. Secondly, the pace at which biology engineering is progressing – not unlike microcomputers in the past 40 years – suggests that unexpected and highly efficient ways of modifying cyanobacteria and other organisms will become available. As we could once have scarcely imagined how much we rely on computers now, engineered biological systems on Mars may be more versatile and important in pioneers’ everyday life than we can envisage at present. Our abilities to discover life on Mars might depend on our abilities to handle life on Earth.

Acknowledgements

The authors are grateful to Sean McMahon (Yale University) for his remarkable artistic rendering. They thank Rocco L. Mancinelli and an anonymous reviewer, whose comments led to significant improvements to the manuscript. They are also grateful to Ivan G. Paulino-Lima, Kosuke Fujishima, Ryan Kent, Griffin McCutcheon, Evie Pless, Jesica Navarrete, Diana Gentry and J. Mike Grace (Lynn Rothschild's laboratory, NASA Ames Research Center) for stimulating discussions. Finally, they thank Christiane Heinicke (Aalto University) for proofreading the penultimate version of the manuscript. This work was supported by the Italian Space Agency, noteworthy through their support to the BIOMEX_Cyano and BOSS_Cyano experiments. It was also supported by CV's appointment to the NASA Education Associates Program managed by the Universities Space Research Association.

References

Abed, R.M.M., Dobretsov, S. & Sudesh, K. (2009). Applications of cyanobacteria in biotechnology. J. Appl. Microbiol. 106, 112.Google Scholar
Agarwal, R., Rane, S.S. & Sainis, J.K. (2008). Effects of 60Co γ radiation on thylakoid membrane functions in Anacystis nidulans . J. Photochem. Photobiol. 91, 919.Google Scholar
Aikawa, S., Joseph, A., Yamada, R., Izumi, Y., Yamagishi, T., Matsuda, F., Kawai, H., Chang, J.-S., Hasunuma, T. & Kondo, A. (2013). Direct conversion of Spirulina to ethanol without pretreatment or enzymatic hydrolysis processes. Energy Environ. Sci. 6, 18441849.Google Scholar
Allen, C.C., Morris, R.V., Lindstrom, D.J., Lindstrom, M.M. & Lockwood, J.P. (1997). JSC Mars-1: Martian regolith simulant. In Lunar and Planetary Science XXVII, LPI Contribution No. 1593, Houston, TX, id. 1797.Google Scholar
Allen, C.S. et al. (2003). Guidelines and Capabilities for Designing Human Missions (NASA/TM–2003–210785) . NASA Johnson Space Center, Houston, TX.Google Scholar
Allen, J.L. (1991). Biosphere 2: the Human Experiment. Penguin Books, New York.Google Scholar
Andersson, C.R., Tsinoremas, N.F., Shelton, J., Lebedeva, N.V., Yarrow, J., Min, H. & Golden, S.S. (2000). Application of bioluminescence to the study of circadian rhythms in cyanobacteria. Methods Enzymol. 305, 527542.CrossRefGoogle Scholar
Angermayr, S.A., Paszota, M. & Hellingwerf, K.J. (2012). Engineering a cyanobacterial cell factory for production of lactic acid. Appl. Environ. Microbiol., 78, 70987106.Google Scholar
Arai, M., Tomita-Yokotani, K., Sato, S., Hashimoto, H., Ohmori, M. & Yamashita, M. (2008). Growth of terrestrial cyanobacterium, Nostoc sp., on Martian Regolith Simulant and its vacuum tolerance. Biol. Sci. Space 22, 817.Google Scholar
Arvidson, R., Squyres, S. & Bell, J. (2014). Ancient aqueous environments at Endeavour crater, Mars. Science 343, 18.Google Scholar
Asato, Y. (1971). Photorecovery of gamma irradiated cultures of blue-green alga, Anacystis nidulans . Radiat. Bot. 11, 313316.Google Scholar
Averner, M., Moore, B., Bartholomew, I. & Wharton, R. (1984). Atmosphere behavior in gas-closed mouse-algal systems: an experimental and modelling study. Adv. Space Res. 4, 231239.Google Scholar
Badri, H. Monsieurs, P., Coninx, I., Wattiez, R. & Leys, N. (2015). Molecular investigation of the radiation resistance of edible cyanobacterium Arthrospira sp. PCC 8005. MicrobiologyOpen 4, 187207.Google Scholar
Bajwa, R., Abuarghub, S. & Read, D.J. (1985). The biology of Mycorrhiza in the Ericaceae. X. The utilization of proteins and the production of proteolytic enzymes by the mycorrhizal endophyte and by mycorrhizal plants. New Phytol. 101, 469486.Google Scholar
Baker, D. & Zubrin, R. (1990). Mars direct: combining near-term technologies to achieve a two-launch manned Mars mission. J. Br. Interplanet. Soc. 43, 519526.Google Scholar
Banerjee, M. & Verma, V. (2009). Nitrogen fixation in endolithic cyanobacterial communities of the McMurdo Dry Valley, Antarctica. ScienceAsia 35, 215219.Google Scholar
Banin, A. (1989). Mars soil – a sterile regolith or a medium for plant growth? In The Case for Mars III, ed. Stoker, C.L., pp. 559571. Univelt, San Diego, CA.Google Scholar
Baqué, M., de Vera, J.-P., Rettberg, P. & Billi, D. (2013). The BOSS and BIOMEX space experiments on the EXPOSE-R2 mission: endurance of the desert cyanobacterium Chroococcidiopsis under simulated space vacuum, Martian atmosphere, UVC radiation and temperature extremes. Acta Astronaut. 91, 180186.Google Scholar
Baqué, M., Verseux, C., Rabbow, E., de Vera, J.-P.P. & Billi, D. (2014). Detection of maromolecules in desert cyanobacteria mixed with a lunar mineral analogue after space simulations. Orig. Life Evol. Biosph. 44, 209221.Google Scholar
Barker, A.V. & Mills, H.A. (1980). Ammonium and nitrate nutrition of horticultural crops. Hort. Rev. 2, 395423.Google Scholar
Beliaev, A.S. et al. (2014). Inference of interactions in cyanobacterial-heterotrophic co-cultures via transcriptome sequencing. ISME J. 8, 22432255.Google Scholar
Benoit, M.R. & Klaus, D.M. (2007). Microgravity, bacteria, and the influence of motility. Adv. Space Res. 39, 12251232.Google Scholar
Bentley, F.K., Zurbriggen, A. & Melis, A. (2014). Heterologous expression of the mevalonic acid pathway in cyanobacteria enhances endogenous carbon partitioning to isoprene. Mol. Plant 7, 7186.CrossRefGoogle ScholarPubMed
Bergman, B., Johansson, C. & Soderback, E. (1992). The Nostoc-Gunnera symbiosis. New Phytol. 122, 379400.Google Scholar
Berla, B.M., Saha, R., Immethun, C.M., Maranas, C.D., Moon, T.S. & Pakrasi, H.B. (2013). Synthetic biology of cyanobacteria: unique challenges and opportunities. Front. Microbiol. 4, 246.Google Scholar
Billi, D. (2009). Subcellular integrities in Chroococcidiopsis sp. CCMEE 029 survivors after prolonged desiccation revealed by molecular probes and genome stability assays. Extremophiles 13, 4957.Google Scholar
Billi, D. (2010). Genetic tools for desiccation- and radiation-tolerant cyanobacteria of the genus Chroococcidiopsis . In Current Research, Technology and Education Topics in Applied Microbiology and Microbial Biotechnology, ed. Méndez-Vilas, A., pp. 15171521. Formatex Research Center, Badajoz, Spain.Google Scholar
Billi, D. (2012). Plasmid stability in dried cells of the desert cyanobacterium Chroococcidiopsis and its potential for GFP imaging of survivors on Earth and in space. Orig. Life Evol. Biosph. 42, 235245.CrossRefGoogle ScholarPubMed
Billi, D., Friedmann, E.I., Hofer, K.G., Caiola, M.G. & Ocampo-Friedmann, R. (2000a). Ionizing-radiation resistance in the desiccation-tolerant cyanobacterium Chroococcidiopsis . Appl. Environ. Microbiol. 66, 14891492.Google Scholar
Billi, D., Wright, D.J., Helm, R.F., Prickett, T., Potts, M. & Crowe, J.H. (2000b). Engineering desiccation tolerance in Escherichia coli . Appl. Environ. Microbiol. 66, 16801684.Google Scholar
Billi, D., Baqué, M., Smith, H. & McKay, C. (2013). Cyanobacteria from extreme deserts to space. Adv. Microbiol. 3, 8086.Google Scholar
Bloom, A.J., Sukrapanna, S.S. & Warner, R.L. (1992). Root respiration associated with ammonium and nitrate absorption and assimilation by barley. Plant Physiol. 99, 12941301.CrossRefGoogle ScholarPubMed
Blüm, V., Gitelson, J., Horneck, G. & Kreuzberg, K. (1994). Opportunities and constraints of closed man-made ecological systems on the moon. Adv. Space Res. 14, 271280.Google Scholar
Boison, G. & Mergel, A. (2004). Bacterial life and dinitrogen fixation at a gypsum rock. Appl. Environ. Microbiol. 70, 70707077.Google Scholar
Bonham, K. & Palumbo, R.F. (1951). Effects of x-rays on snails, crustacea, and algae. Growth 15, 155168.Google Scholar
Böttger, U., de Vera, J.-P., Fritz, J., Weber, I., Hübers, H.-W. & Schulze-Makuch, D. (2012). Optimizing the detection of carotene in cyanobacteria in a Martian regolith analogue with a Raman spectrometer for the ExoMars mission. Planet. Space Sci. 60, 356362.Google Scholar
Boxe, C.S., Hand, K.P., Nealson, K.H., Yung, Y.L. & Saiz-Lopez, A. (2012). An active nitrogen cycle on Mars sufficient to support a subsurface biosphere. Int. J. Astrobiol. 11, 109115.Google Scholar
Boynton, W.V. et al. (2007). Concentration of H, Si, Cl, K, Fe, and Th in the low- and mid-latitude regions of Mars. J. Geophys. Res.: Planets 112, E12.Google Scholar
Britto, D.T. & Kronzucker, H.J. (2002). NH4 + toxicity in higher plants: a critical review. J. Plant Physiol. 159, 567584.Google Scholar
Brown, I.I. (2008a). Cyanobacteria to Link Closed Ecological Systems and In-Situ Resources Utilization Processes. In 37th COSPAR Scientific Assembly, Montréal, Canada, p. 383.Google Scholar
Brown, I.I. (2008b). Mutant strains of Spirulina (Arthrospira) platensis to increase the efficiency of micro-ecological life support systems. In 37th COSPAR Scientific Assembly, Montréal, Canada, p. 384.Google Scholar
Brown, I.I. & Sarkisova, S. (2008). Bio-weathering of lunar and Martian rocks by cyanobacteria: a resource for Moon and Mars exploration. In Lunar and Planetary Sciences XXXIX, pp. 12.Google Scholar
Brown, I.I., Garrison, D.H., Jones, J.A., Allen, C.C., Sanders, G., Sarkisova, S.A. & McKay, D.S. (2008). The Development and Perspectives of Bio-ISRU. In Joint Annual Meeting of LEAG–ICEUM–SRR, Cape Canaveral, Florida, p. 4048.Google Scholar
Bruce, A.K. (1964). Extraction of the radioresistant factor of Micrococcus radiodurans . Radiat. Res. 22, 155164.Google Scholar
Cao, G., Concas, A., Corrias, G., Licheri, R., Orru’, R. & Pisu, M. (2014). Process for the production of useful materials for sustaining manned space missions on Mars through in-situ resources utilization. US Patent Application US 2014/016546 A1.Google Scholar
Chaurasia, A.K., Parasnis, A. & Apte, S.K. (2008). An integrative expression vector for strain improvement and environmental applications of the nitrogen fixing cyanobacterium, Anabaena sp. strain PCC7120. J. Microbiol. Methods 73, 133141.Google Scholar
Chen, Y.-C. (2001). Immobilized microalga Scenedesmus quadricauda (Chlorophyta, Chlorococcales) for long-term storage and for application for water quality control in fish. Aquaculture 195, 7180.Google Scholar
Christensen, P.R. et al. (2001). Mars Global Surveyor Thermal Emission Spectrometer experiment: investigation description and surface science results. J. Geophys. Res. 106, 2382323871.Google Scholar
Clapp, M. (1985). Water supply for a manned Mars base. In The Case for Mars II, ed. McKay, C.P., pp. 557566. Univelt, San Diego, CA.Google Scholar
Clark, B.C., Baird, A.K., Weldon, R.J., Tsusaki, D.M., Schnabel, L. & Candelaria, M.P. (1982). Chemical composition of Martian fines. J. Geophys. Res. Solid Earth 87, 1005910067.Google Scholar
Clerico, E.M., Ditty, J.L. & Golden, S.S. (2007). Specialized techniques for site-directed mutagenesis in cyanobacteria. Methods Mol. Biol. 362, 155171.CrossRefGoogle ScholarPubMed
Clifford, S.M., Lasue, J., Heggy, E., Boisson, J., McGovern, P. & Max, M.D. (2010). Depth of the Martian cryosphere: revised estimates and implications for the existence and detection of subpermafrost groundwater. J. Geophys. Res. 115, E07001.Google Scholar
Cockell, C.S. (2010). Geomicrobiology beyond Earth: microbe–mineral interactions in space exploration and settlement. Trends Microbiol. 18, 308314.Google Scholar
Cockell, C.S. (2011). Synthetic geomicrobiology: engineering microbe–mineral interactions for space exploration and settlement. Int. J. Astrobiol. 10, 315324.Google Scholar
Cockell, C.S. (2014). Trajectories of Martian habitability. Astrobiology 14, 182203.Google Scholar
Cockell, C.S., Catling, D.C., Davis, W.L., Snook, K., Kepner, R.L., Lee, P. & McKay, C.P. (2000). The ultraviolet environment of Mars: biological implications past, present, and future. Icarus 146, 343359.CrossRefGoogle ScholarPubMed
Cockell, C.S. & Raven, J.A. (2004). Zones of photosynthetic potential on Mars and the early Earth. Icarus 169, 300310.Google Scholar
Cockell, C.S., Rettberg, P., Rabbow, E. & Olsson-Francis, K. (2011). Exposure of phototrophs to 548 days in low Earth orbit: microbial selection pressures in outer space and on early earth. ISME J. 5, 16711682.CrossRefGoogle ScholarPubMed
Coffin, R.B. (1989). Bacterial uptake of dissolved free and combined amino acids in estuarine waters. Limnol. Oceanogr. 34, 531542.Google Scholar
Conrad, T. (2011). Microbial laboratory evolution in the era of genome-scale science. Mol. Syst. Biol. 7, 509.CrossRefGoogle ScholarPubMed
Coons, S., Williams, J. & Bruckner, A. (1997). Feasibility study of water vapor adsorption on Mars for in situ resource utilization. In 33rd Joint Propulsion Conf. and Exhibit, Seattle, WA, AIAA 97–2765.Google Scholar
Crawford, C.C., Hobbie, J.E. & Webb, K.L. (1974). The utilization of dissolved free amino acids by estuarine microorganisms. Ecology 55, 551563.Google Scholar
Cumbers, J. & Rothschild, L.J. (2010). BISRU: synthetic microbes for Moon, Mars and beyond. In Astrobiology Science Conf. 2010, LPI Contribution No. 1538, League City, TX, id. 5672.Google Scholar
Dahlgren, R., Shoji, S. & Nanzyo, M. (1993). Mineralogical characteristics of volcanic ash soils. In Volcanic Ash Soils – Genesis, Properties and Utilization, ed. Shoji, S. & Nanzyo, M., pp. 101143. Elsevier Science Ltd, Amsterdam.Google Scholar
Dalton, B. & Roberto, F. (2008). Lunar Regolith Biomining: Workshop Report (NASA/CP-2008-214564) . NASA Ames Research Center, Moffett Field, CA.Google Scholar
Danin, A., Dor, I., Sandler, A. & Amit, R. (1998). Desert crust morphology and its relations to microbiotic succession at Mt. Sedom, Israel. J. Arid Environ. 38, 161174.CrossRefGoogle Scholar
Dartnell, L.R. & Patel, M.R. (2014). Degradation of microbial fluorescence biosignatures by solar ultraviolet radiation on Mars. Int. J. Astrobiol. 13, 112123.Google Scholar
Dartnell, L.R., Desorgher, L., Ward, J.M. & Coates, A.J. (2007). Modelling the surface and subsurface Martian radiation environment: implications for astrobiology. Geophys. Res. Lett. 34, L02207.Google Scholar
de Crecy, E., Jaronski, S., Lyons, B., Lyons, T.J. & Keyhani, N.O. (2009). Directed evolution of a filamentous fungus for thermotolerance. BMC Biotechnol. 9, 74.Google Scholar
de la Torre, J.R., Goebel, B.M., Friedmann, E.I. & Pace, N.R. (2003). Microbial diversity of cryptoendolithic communities from the McMurdo Dry Valleys, Antarctica. Appl. Environ. Microbiol. 69, 38583867.Google Scholar
Deng, M.D. & Coleman, J.R. (1999). Ethanol synthesis by genetic engineering in cyanobacteria. Appl. Environ. Microbiol. 65, 523528.CrossRefGoogle ScholarPubMed
de Vera, J.-P., Schulze-Makuch, D., Khan, A., Lorek, A., Koncz, A., Möhlmann, D. & Spohn, T. (2014). Adaptation of an Antarctic lichen to Martian niche conditions can occur within 34 days. Planet. Space Sci. 98, 182190.Google Scholar
Dexter, J. & Fu, P. (2009). Metabolic engineering of cyanobacteria for ethanol production. Energy Environ. Sci. 2, 857.Google Scholar
Dienst, D., Georg, J., Abts, T., Jakorew, L., Kuchmina, E., Börner, T., Wilde, A., Dühring, U., Enke, H. & Hess, W.R. (2014). Transcriptomic response to prolonged ethanol production in the cyanobacterium Synechocystis sp. PCC6803. Biotechnol. Biofuels 7, 21.Google Scholar
Dismukes, G.C., Carrieri, D., Bennette, N., Ananyev, G.M. & Posewitz, M.C. (2008). Aquatic phototrophs: efficient alternatives to land-based crops for biofuels. Curr. Opin. Biotechnol. 19, 235240.CrossRefGoogle ScholarPubMed
Domain, F., Houot, L., Chauvat, F. & Cassier-Chauvat, C. (2004). Function and regulation of the cyanobacterial genes lexA, recA and ruvB: LexA is critical to the survival of cells facing inorganic carbon starvation. Mol. Microbiol. 53, 6580.Google Scholar
Drake, B.G. (ed.) (2009). Human Exploration of Mars: Design Reference Architecture 5.0 (NASA-SP-2009-566). NASA Johnson Space Center, Houston, TX.Google Scholar
Drysdale, A., Ewert, M. & Hanford, A. (2003). Life support approaches for Mars missions. Adv. Space Res. 31, 5161.Google Scholar
Drysdale, A., Nakamura, T., Yorio, N., Sager, J. & Wheeler, R. (2008). Use of sunlight for plant lighting in a bioregenerative life support system – equivalent system mass calculations. Adv. Space Res. 42, 19291943.CrossRefGoogle Scholar
Drysdale, A.E., Rutkze, C.J., Albright, L.D. & LaDue, R.L. (2004). The minimal cost of life in space. Adv. Space Res. 34, 15021508.CrossRefGoogle ScholarPubMed
Ducat, D.C., Way, J.C. & Silver, P.A. (2011). Engineering cyanobacteria to generate high-value products. Trends Biotechnol. 29, 95103.Google Scholar
Dykhuizen, D.E. (1993). Chemostats used for studying natural selection and adaptive evolution. Methods Enzymol. 224, 613631.Google Scholar
Eldridge, D. & Greene, R. (1994). Microbiotic soil crusts-a review of their roles in soil and ecological processes in the rangelands of Australia. Soil Res. 32, 389415.Google Scholar
Elena, S.F. & Lenski, R.E. (2003). Evolution experiments with microorganisms: the dynamics and genetic bases of adaptation. Nat. Rev. Genet. 4, 457469.Google Scholar
Ellis, D.I. & Goodacre, R. (2012). Metabolomics-assisted synthetic biology. Curr. Opin. Biotechnol. 23, 2228.Google Scholar
Ethridge, E.C. & Kaulker, W.F. (2012). Microwave extraction of volatiles for Mars science and ISRU. In Concepts and Approaches for Mars Exploration, LPI Contribution No. 1679, Houston, TX, id. 4328.Google Scholar
Ewing, D. (1995). The directed evolution of radiation resistance in E. coli . Biochem. Biophys. Res. Commun. 2, 549553.Google Scholar
Fajardo-Cavazos, P., Waters, S.M., Schuerger, A.C., George, S., Marois, J.J. & Nicholson, W.L. (2012). Evolution of Bacillus subtilis to enhanced growth at low pressure: up-regulated transcription of des-desKR, encoding the fatty acid desaturase system. Astrobiology 12, 258270.Google Scholar
Ferrer, M., Chernikova, T.N., Yakimov, M.M., Golyshin, P.N. & Timmis, K.N. (2003). Chaperonins govern growth of Escherichia coli at low temperatures. Nat. Biotechnol. 21, 12661267.Google Scholar
Filali, R., Lasseur, C. & Dubertret, G. (1997). MELiSSA: nitrogen sources for growth of the cyanobacterium Spirulina. In Proc. Sixth European Symp. on Space Environmental Control Systems, Noordwijk, The Netherlands, pp. 909912.Google Scholar
Finney, L.A. & O'Halloran, T.V. (2003). Transition metal speciation in the cell: insights from the chemistry of metal ion receptors. Science 300, 931936.Google Scholar
Friedmann, E.I. & Ocampo, R. (1976). Endolithic blue-green algae in the Dry Valleys: primary producers in the Antarctic desert ecosystem. Science 193, 12471249.Google Scholar
Gao, G., Tian, B., Liu, L., Sheng, D., Shen, B. & Hua, Y. (2003). Expression of Deinococcus radiodurans PprI enhances the radioresistance of Escherichia coli . DNA Repair 2, 14191427.Google Scholar
Giacomelli, G. et al. (2012). Bio-regenerative life support system development for Lunar/Mars habitats. In 42nd Int. Conf. on Environmental Systems, San Diego, CA.Google Scholar
Gitelson, I., Lisovsky, G. & MacElroy, R. (2003). Manmade Closed Ecological Systems. Taylor & Francis, London and New York.Google Scholar
Gitelson, J. (1992). Biological life-support systems for Mars mission. Adv. Space Res. 12, 167192.Google Scholar
Godia, F., Albiol, J., Montesinos, J. & Pérez, J. (2002). MELISSA: a loop of interconnected bioreactors to develop life support in space. J. Biotechnol. 99, 319330.Google Scholar
Godlewski, M. & Adamczyk, B. (2007). The ability of plants to secrete proteases by roots. Plant Physiol. Biochem. 45, 657664.Google Scholar
Godward, M.B.E. (1962). Invisible radiations. In Physiology and Biochemistry of Algae, ed. Lewin, R.A., pp. 551566. Academic Press, New York.Google Scholar
Goldman, R.P. & Travisano, M. (2011). Experimental evolution of ultraviolet radiation resistance in Escherichia coli . Evolution 65, 34863498.Google Scholar
Gómez-Elvira, J. et al. (2014). Curiosity's Rover Environmental Monitoring Station: overview of the first 100 sols. J. Geophys. Res.: Planets 119, 16801688.Google Scholar
Grace, J.M., Verseux, C., Gentry, D., Moffet, A., Thayabaran, R., Wong, N. & Rothschild, L. (2013). Elucidating microbial adaptation dynamics via autonomous exposure and sampling. In AGU Fall Meeting Abstracts, San Francisco, CA, p. 597.Google Scholar
Graham, J.M. (2004). The biological terraforming of Mars: planetary ecosynthesis as ecological succession on a global scale. Astrobiology 4, 168195.Google Scholar
Griese, M., Lange, C. & Soppa, J. (2011). Ploidy in cyanobacteria. FEMS Microbiol. Lett. 323, 124131.CrossRefGoogle ScholarPubMed
Grotzinger, J.P. et al. (2014). A habitable fluvio-lacustrine environment at Yellowknife Bay, Gale crater, Mars. Science 343, 1242777.Google Scholar
Grover, M.R. & Bruckner, A.P. (1998). Water vapor extraction from the Martian atmosphere by adsorption in molecular sieves. In 34th AIAA/ASME/SAE/ASEE Joint Propulsion Conf., Cleveland, OH, AAIA 98–3302.Google Scholar
Guerrero, F., Carbonell, V., Cossu, M., Correddu, D. & Jones, P.R. (2012). Ethylene synthesis and regulated expression of recombinant protein in Synechocystis sp. PCC 6803. PLoS ONE 7, e50470.Google Scholar
Gusev, M.V., Baulina, O.I., Gorelova, O.A., Lobakova, E.S. & Korzhenevskaya, T.G. (2002). Artificial cyanobacterium-plant symbioses. In Cyanobacteria in Symbiosis, ed. Rai, A.N., Bergman, B. & Rasmussen, U., pp. 253312. Springer, The Netherlands.Google Scholar
Harris, D.R. et al. (2009). Directed evolution of ionizing radiation resistance in Escherichia coli . J. Bacteriol. 191, 52405252.Google Scholar
Harrison, J.P., Gheeraert, N., Tsigelnitskiy, D. & Cockell, C.S. (2013). The limits for life under multiple extremes. Trends Microbiol. 21, 204212.Google Scholar
Hassler, D.M. et al. (2013). Mars’ surface radiation environment measured with the Mars Science Laboratory's Curiosity rover. Science 343, 1244797.Google Scholar
Heap, J.T., Ehsaan, M., Cooksley, C.M., Ng, Y.K., Cartman, S.T., Winzer, K. & Minton, N.P. (2012). Integration of DNA into bacterial chromosomes from plasmids without a counter-selection marker. Nucleic Acids Res. 40, e59.Google Scholar
Hecht, M.H. et al. (2009). Detection of perchlorate and the soluble chemistry of Martian soil at the Phoenix lander site. Science 325, 6467.Google Scholar
Hendrickx, L. & Mergeay, M. (2007). From the deep sea to the stars: human life support through minimal communities. Curr. Opin. Microbiol. 10, 231237.Google Scholar
Hendrickx, L., De Wever, H., Hermans, V., Mastroleo, F., Morin, N., Wilmotte, A., Janssen, P. & Mergeay, M. (2006). Microbial ecology of the closed artificial ecosystem MELiSSA (Micro-Ecological Life Support System Alternative): reinventing and compartmentalizing the Earth's food and oxygen regeneration system for long-haul space exploration missions. Res. Microbiol. 157, 7786.Google Scholar
Henrikson, R. (2009). Earth Food Spirulina, Revised ed. Ronore Enterprises, Inc., Hana, Maui, HI.Google Scholar
Herranz, R. et al. (2013). Ground-based facilities for simulation of microgravity: organism-specific recommendations for their use, and recommended terminology. Astrobiology 13, 117.Google Scholar
Herrera, A., Cockell, C.S., Self, S., Blaxter, M., Reitner, J., Thorsteinsson, T., Arp, G., Dröse, W. & Tindle, A.G. (2009). A cryptoendolithic community in volcanic glass. Astrobiology 9, 369381.Google Scholar
Herrero, M., De Lorenzo, V. & Timmis, K.N. (1990). Transposon vectors containing non-antibiotic resistance selection markers for cloning and stable chromosomal insertion of foreign genes in gram-negative bacteria. J. Bacteriol. 172, 65576567.CrossRefGoogle ScholarPubMed
Hertzberg, S. & Jensen, A. (1989). Studies of alginate immobilized marine microalgae. Bot. Marina 32, 267274.Google Scholar
Hoffman, S.J. & Kaplan, D.I. (1997). Human Exploration of Mars: the Reference Mission of the NASA Mars Exploration Study Team (NASA Special Publication 6107). NASA Johnson Space Center, Houston, TX.Google Scholar
Hollibaugh, J.T. & Azam, F. (1983). Microbial degradation of dissolved proteins in seawater. Limnol. Oceanogr. 28, 11041116.Google Scholar
Horneck, G. (2008). The microbial case for Mars and its implication for human expeditions to Mars. Acta Astronaut. 63, 10151024.Google Scholar
Horneck, G. et al. (2003). HUMEX, a study on the survivability and adaptation of humans to long-duration exploratory missions, part I: lunar missions. Adv. Space Res. 31, 23892401.CrossRefGoogle Scholar
Horneck, G. et al. (2006). HUMEX, a study on the survivability and adaptation of humans to long-duration exploratory missions, part II: missions to Mars. Adv. Space Res. 38, 752759.Google Scholar
Horneck, G., Klaus, D.M. & Mancinelli, R.L. (2010). Space microbiology. Microbiol. Mol. Biol. Rev. 74, 121156.Google Scholar
Hoshino, K., Hamochi, M., Mitsuhashi, S. & Tanishita, K. (1991). Measurements of oxygen production rate in flowing. Appl. Microbiol. Biotechnol. 35, 8993.CrossRefGoogle Scholar
Howitt, S.M. & Udvardi, M.K. (2000). Structure, function and regulation of ammonium transporters in plants. Biochim. Biophys. Acta – Biomembranes 1465, 152170.Google Scholar
Jack, D.A., Nakamura, T., Sadler, P. & Cuello, J.L. (2002). Evaluation of two fiber optic-based solar collection and distribution systems for advanced space life support. Trans. ASAE 45, 15471558.Google Scholar
Jiménez, C., Cossío, B.R. & Niella, F.X. (2003). Relationship between physicochemical variables and productivity in open ponds for the production of Spirulina: a predictive model of algal yield. Aquaculture 221, 331345.CrossRefGoogle Scholar
Jones, P.R. (2014). Genetic instability in cyanobacteria – an elephant in the room? Front. Bioeng. Biotechnol. 2, Art. 12.Google Scholar
Kanervo, E., Lehto, K., Ståhle, K., Lehto, H. & Mäenpää, P. (2005). Characterization of growth and photosynthesis of Synechocystis sp. PCC 6803 cultures under reduced atmospheric pressures and enhanced CO2 levels. Int. J. Astrobiol. 4, 97.Google Scholar
Kanesaki, Y., Shiwa, Y., Tajima, N., Suzuki, M., Watanabe, S., Sato, N., Ikeuchi, M. & Yoshikawa, H. (2012). Identification of substrain-specific mutations by massively parallel whole-genome resequencing of synechocystis sp. PCC 6803. DNA Res. 19, 6779.Google Scholar
Kim, M., Zhang, Z., Okano, H., Yan, D., Groisman, A. & Hwa, T. (2012). Need-based activation of ammonium uptake in Escherichia coli . Mol. Syst. Biol. 8, 616.Google Scholar
Kirensky, L.V, Terskov, I.A., Gitelson, I.I., Lisovsky, G.M., Kovrov, B.G. & Okladnikov, Y.N. (1968). Experimental biological life support system. II. Gas exchange between man and microalgae culture in a 30-day experiment. Life Sci. Space Res. 6, 3740.Google Scholar
Klingler, J.M., Mancinelli, R.L. & White, M.R. (1989). Biological nitrogen fixation under primordial Martian partial pressures of dinitrogen. Adv. Space Res. 9, 173176.Google Scholar
Koksharova, O. & Wolk, C. (2002). Genetic tools for cyanobacteria. Appl. Microbiol. Biotechnol. 58, 123137.Google Scholar
Kozyrovska, N. et al. (2006). Growing pioneer plants for a lunar base. Adv. Space Res. 37, 9399.Google Scholar
Kral, T., Altheide, T.S., Lueders, A.E. & Schuerger, A.C. (2011). Low pressure and desiccation effects on methanogens: implications for life on Mars. Planet. Space Sci. 59, 264270.Google Scholar
Kraus, M.P. (1969). Resistance of blue-green algae to 60Co gamma radiation. Radiat. Bot. 9, 481489.Google Scholar
Kudenko, Y. A., Gribovskaya, I.V. & Zolotukhin, I.G. (2000). Physical-chemical treatment of wastes: a way to close turnover of elements in LSS. Acta Astronaut. 46, 585589.Google Scholar
Kumar, H.D. (1964). Effects of radiations on blue-green algae II: effects on growth. Annal. Bot. 28, 555564.CrossRefGoogle Scholar
Kurahashi-Nakamura, T. & Tajika, E. (2006). Atmospheric collapse and transport of carbon dioxide into the subsurface on early Mars. Geophys. Res. Lett. 33, L18205.Google Scholar
Langevin, Y., Poulet, F., Bibring, J.-P. & Gondet, B. (2005). Sulfates in the north polar region of Mars detected by OMEGA/Mars Express. Science 307, 15841586.Google Scholar
Langhoff, S., Cumbers, J., Rothschild, L.J., Paavola, C. & Worden, S.P. (2011). What are the Potential Roles for Synthetic Biology in NASA's Mission? (NASA/CP-2011-216430). NASA Ames Research Center, Moffett Field, CA.Google Scholar
Latshaw, W.L. & Miller, E.C. (1934). Elemental composition of the corn plant. J. Agric. Res. 27, 845861.Google Scholar
Lee, S.Y. (2012). Metabolic engineering and synthetic biology in strain development. ACS Synth. Biol. 1, 491492.Google Scholar
Lehto, K., Kanervo, E., Stahle, K. & Lehto, H. (2007). Photosynthetic life support systems in the Martian conditions. In ROME: Response of Organisms to the Martian Environment (ESA AP-1299) , ed. Cockell, C. & Horneck, G., pp. 151160. ESA Communications, Noordwijk, The Netherlands.Google Scholar
Lehto, K.M., Lehto, H.J. & Kanervo, E.A. (2006). Suitability of different photosynthetic organisms for an extraterrestrial biological life support system. Res. Microbiol. 157, 6976.Google Scholar
Le Postollec, A. et al. (2009). Monte Carlo simulation of the radiation environment encountered by a biochip during a space mission to Mars. Astrobiology 9, 311323.CrossRefGoogle ScholarPubMed
Lipson, D. & Näsholm, T. (2001). The unexpected versatility of plants: organic nitrogen use and availability in terrestrial ecosystems. Oecologia 128, 305316.Google Scholar
Liu, J., Bukatin, V.E. & Tsygankov, A.A. (2006). Light energy conversion into H2 by Anabaena variabilis mutant PK84 dense cultures exposed to nitrogen limitations. Int. J. Hydrog. Energy 31, 15911596.Google Scholar
Liu, Y., Cockell, C.S., Wang, G., Hu, C., Chen, L. & De Philippis, R. (2008). Control of Lunar and Martian dust – experimental insights from artificial and natural cyanobacterial and algal crusts in the desert of Inner Mongolia, China. Astrobiology 8, 7586.CrossRefGoogle ScholarPubMed
Lobascio, C., Lamantea, M., Cotronei, V., Negri, B., De Pascale, S., Maggio, A., Foti, M. & Palumberi, S. (2007). Plant bioregenerative life supports: The Italian CAB Project. J. Plant Interact. 2, 125134.Google Scholar
Lukavský, J. (1988). Long-term preservation of algal strains by immobilization. Archiv für Protistenkunde 135, 6568.Google Scholar
Madigan, M.T., Martinko, J.M. & Parker, J. (2000). Brock Biology of Microorganisms, 9th edn. Prentice Hall, Upper Saddle River, NJ.Google Scholar
Maggi, F. & Pallud, C. (2010). Space agriculture in micro- and hypo-gravity: a comparative study of soil hydraulics and biogeochemistry in a cropping unit on Earth, Mars, the Moon and the space station. Planet. Space Sci. 58, 19962007.Google Scholar
Mancinelli, R.L. & Banin, A. (2003). Where is the nitrogen on Mars? Int. J. Astrobiol. 2, 217225.Google Scholar
Mancinelli, R.L. & Klovstad, M. (2000). Martian soil and UV radiation: microbial viability assessment on spacecraft surfaces. Planet. Space Sci. 48, 10931097.Google Scholar
Marlière, P., Patrouix, J., Döring, V., Herdewijn, P., Tricot, S., Cruveiller, S., Bouzon, M. & Mutzel, R. (2011). Chemical evolution of a bacterium's genome. Angew. Chem. 50, 71097114.Google Scholar
Martín-Torres, F.J. et al. (2015). Transient liquid water and water activity at Gale Crater on Mars. Nat. Geosci. 8, 357361.Google Scholar
Massa, G.D., Emmerich, J.C., Morrow, R.C., Bourget, C.M. & Mitchell, C.A. (2007). Plant-growth lighting for space life support: a review. Gravit. Space Biol. 19, 1930.Google Scholar
Matsuoka, M., Takahama, K. & Ogawa, T. (2001). Gene replacement in cyanobacteria mediated by a dominant streptomycin-sensitive rps12 gene that allows selection of mutants free from drug resistance markers. Microbiology 147, 20772087.Google Scholar
McEwen, A.S., Ojha, L., Dundas, C.M., Mattson, S.S., Byrne, S., Wray, J.J., Cull, S.C., Murchie, S.L., Thomas, N. & Gulick, V.C. (2011). Seasonal flows on warm Martian slopes. Science 333, 740743.Google Scholar
McFall, E. & Newman, E.B. (1996). Amino acids as carbon sources. In Escherichia coli and Salmonella: Cellular and Molecular Biology, ed. Neidhardt, F.C., Curtiss, R. III, Ingraham, J.L., Lin, E.C.C., Low, K.B., Magasanik, B., Reznikoff, W.S., Riley, M., Schaechter, M. & Umbarger, H.E., pp. 358379. ASM Press, Washington, DC.Google Scholar
McKay, C.P. & Marinova, M. (2001). The physics, biology, and environmental ethics of making Mars habitable. Astrobiology 1, 89110.Google Scholar
McKay, C.P., Meyer, T.R., Boston, P.J., Nelson, M. & McCallum, T. (1993). Utilizing Martian resources for life support. In Resources of Near Earth Space, ed. Lewis, J.S., Matthews, M.S. & Guerrieri, M.L., pp. 819843. The Arizona Board of Regents, Tucson, AZ.Google Scholar
McKay, D.S. & Allen, C.C. (1996). Concrete – a practical construction material for Mars. In Proc. of the Fifth International Conf. on Engineering, Construction, and Operations in Space, Albuquerque, NM, pp. 566570.Google Scholar
McLennan, S.M. et al. (2014). Elemental geochemistry of sedimentary rocks at Yellowknife Bay, Gale crater, Mars. Science 343, 1244734.Google Scholar
McMahon, S., Parnell, J., Ponicka, J., Hole, M. & Boyce, A. (2013). The habitability of vesicles in Martian basalt. Astron. Geophys. 54, 1721.Google Scholar
McSween, H.Y. (1994). What we have learned about Mars from SNC meteorites. Meteoritics 29, 757779.Google Scholar
McSween, H.Y., Taylor, G.J. & Wyatt, M.B. (2009). Elemental composition of the Martian crust. Science 324, 7367373679.Google Scholar
Menezes, A.A., Cumbers, J., Hogan, J.A. & Arkin, A.P. (2014). Towards synthetic biological approaches to resource utilization on space missions. J. R. Soc. Interface 12, 20140715.Google Scholar
Meyer, T.R. & McKay, C.P. (1984). The atmosphere of Mars-resources for the exploration and settlement of Mars. In The Case for Mars, ed. Boston, P.J., pp. 209232. Univelt, San Diego, CA.Google Scholar
Meyer, T.R. & McKay, C.P. (1989). The resources of Mars for human settlement. J. Br. Interplanet. Soc. 42, 147160.Google Scholar
Meyer, T.R. & McKay, C.P. (1996). Using the resources of Mars for human settlement. In Strategies for Mars: A Guide to Human Exploration, ed. Stoker, C.R. & Emmart, C., pp. 393442. Univelt, San Diego, CA.Google Scholar
Miao, X., Wu, Q., Wu, G. & Zhao, N. (2003). Sucrose accumulation in salt-stressed cells of agp gene deletion-mutant in cyanobacterium Synechocystis sp. PCC 6803. FEMS Microbiol. Lett. 218, 7177.Google Scholar
Ming, D.W. et al. (2014). Volatile and organic compositions of sedimentary rocks in Yellowknife Bay, Gale crater, Mars. Science 343, 124526.Google Scholar
Möllers, K.B., Cannella, D., Jørgensen, H. & Frigaard, N.-U. (2014). Cyanobacterial biomass as carbohydrate and nutrient feedstock for bioethanol production by yeast fermentation. Biotechnol. Biofuels 7, 64.Google Scholar
Montague, M., McArthur, G.H., Cockell, C.S., Held, J., Marshall, W., Sherman, L.A., Wang, N., Nicholson, W.L., Tarjan, D.R. & Cumbers, J. (2012). The role of synthetic biology for in situ resource utilization (ISRU). Astrobiology 12, 11351142.Google Scholar
Mori, K., Ohya, H., Matsumoto, K. & Furune, H. (1987). Sunlight supply and gas exchange systems in the microalgal bioreactor. Adv. Space Res. 7, 4752.Google Scholar
Morris, R.V. et al. (2004). Mineralogy at Gusev Crater from the Mössbauer spectrometer on the Spirit Rover. Science 305, 833836.Google Scholar
Mueller, R.P. & Van Susante, P.J. (2011). A review of Lunar regolith excavation robotic device prototypes. In American Institute of Aeronautics and Astronautics Space 2011 Conf., Long Beach, CA, Paper # 1073752.Google Scholar
Muhlestein, D.J., Hooten, T.M., Koenig, R., Grossl, P. & Bugbee, B. (1999). Is nitrate necessary to biological life support? In The Int. Conf. on Environmental Systems (ICES) Meeting, Denver, CO, pp. 25.Google Scholar
Murphy, R.C., Gasparich, G.E., Bryant, D.A. & Porter, R.D. (1990). Nucleotide sequence and further characterization of the Synechococcus sp. strain PCC 7002 recA gene: complementation of a cyanobacterial recA mutation by the Escherichia coli recA gene. J. Bacteriol. 172, 967976.Google Scholar
Murukesan, G., Leino, H., Mäenpää, P., Stahle, K., Raksajit, W., Lehto, H., Allahverdiyeva-Rinne, Y. & Lehto, K. (2015). Pressurized Martian-like pure CO2 atmosphere supports strong growth of cyanobacteria, and causes significant changes in their metabolism. Orig. Life Evol. Biosph., in press.Google Scholar
Mustard, J.F. et al. (2008). Hydrated silicate minerals on Mars observed by the Mars Reconnaissance Orbiter CRISM instrument. Nature 454, 305309.Google Scholar
Nakamura, T., Van Pelt, A.D., Yorio, N.C., Drysdale, A.E., Wheeler, R.M. & Sager, J.C. (2009). Transmission and distribution of Photosynthetically Active Radiation (PAR) from solar and electric light sources. Habitation 12, 103117.Google Scholar
Näsholm, T., Kielland, K. & Ganeteg, U. (2009). Uptake of organic nitrogen by plants. New Phytol. 182, 3148.Google Scholar
Navarrete, J.U., Cappelle, I.J., Schnittker, K. & Borrok, D.M. (2012). Bioleaching of ilmenite and basalt in the presence of iron-oxidizing and iron-scavenging bacteria. Int. J. Astrobiol. 12, 123134.Google Scholar
Nelson, M., Dempster, W.F. & Allen, J.P. (2008). Integration of lessons from recent research for “Earth to Mars” life support systems. Adv. Space Res. 41, 675683.Google Scholar
Nelson, M., Pechurkin, N.S., Allen, J.P., Somova, L.A. & Gitelson, J.I. (2010). Closed ecological systems, space life support and biospherics. In Handbook of Environmental Engineering, Volume 10: Environmental Biotechnology, ed. Wang, L.K., Ivanov, V., Tay, J.-H. & Hung, Y.-T., pp. 517565. Humana Press, New York.Google Scholar
Nicholson, W.L., Fajardo-Cavazos, P., Fedenko, J., Ortíz-Lugo, J.L., Rivas-Castillo, A., Waters, S.M. & Schuerger, A.C. (2010). Exploring the low-pressure growth limit: evolution of Bacillus subtilis in the laboratory to enhanced growth at 5 kilopascals. Appl. Environ. Microbiol. 76, 75597565.Google Scholar
Nicholson, W.L., Krivushin, K., Gilichinsky, D. & Schuerger, A.C. (2013). Growth of Carnobacterium spp. from permafrost under low pressure, temperature, and anoxic atmosphere has implications for Earth microbes on Mars. Proc. Natl. Acad. Sci. U.S.A. 110, 666671.Google Scholar
Nickerson, C.A., Mark Ott, C., Mister, S.J., Morrow, B.J., Burns-Keliher, L. & Pierson, D.L. (2000). Microgravity as a novel environmental signal affecting Salmonella enterica serovar Typhimurium virulence. Infect. Immun. 68, 31473152.Google Scholar
Niederholtmeyer, H., Wolfstädter, B.T., Savage, D.F., Silver, P.A. & Way, J.C. (2010). Engineering cyanobacteria to synthesize and export hydrophilic products. Appl. Environ. Microbiol. 76, 34623466.Google Scholar
Nixon, S.L., Cousins, C.R. & Cockell, C.S. (2013). Plausible microbial metabolisms on Mars. Astron. Geophys. 54, 1316.Google Scholar
Olsson-Francis, K. & Cockell, C.S. (2010). Use of cyanobacteria for in-situ resource use in space applications. Planet. Space Sci. 58, 12791285.Google Scholar
Olsson-Francis, K., de la Torre, R., Towner, M.C. & Cockell, C.S. (2009). Survival of akinetes (resting-state cells of cyanobacteria) in low Earth orbit and simulated extraterrestrial conditions. Orig. Life Evol. Biosph. 39, 565579.Google Scholar
Olsson-Francis, K., de la Torre, R. & Cockell, C.S. (2010). Isolation of novel extreme-tolerant cyanobacteria from a rock-dwelling microbial community by using exposure to low Earth orbit. Appl. Environ. Microbiol. 76, 21152121.Google Scholar
Olsson-Francis, K., Simpson, A.E., Wolff-Boenisch, D. & Cockell, C.S. (2012). The effect of rock composition on cyanobacterial weathering of crystalline basalt and rhyolite. Geobiology 10, 434444.Google Scholar
Patnaik, R., Louie, S., Gavrilovic, V., Perry, K., Stemmer, W.P.C., Ryan, C.M. & del Cardayré, S. (2002). Genome shuffling of Lactobacillus for improved acid tolerance. Nat. Biotechnol. 20, 707712.Google Scholar
Paul, J.H., Jeffrey, W.H., David, A.W., Deflaun, M.F. & Cazares, L.H. (1989). Turnover of extracellular DNA in eutrophic and oligotrophic freshwater environments of southwest Florida. Appl. Environ. Microbiol. 55, 18231828.Google Scholar
Paungfoo-Lonhienne, C., Lonhienne, T.G.A., Rentsch, D., Robinson, N., Christie, M., Webb, R.I., Gamage, H.K., Carroll, B.J., Schenk, P.M. & Schmidt, S. (2008). Plants can use protein as a nitrogen source without assistance from other organisms. Proc. Natl. Acad. Sci. U.S.A. 105, 45244529.Google Scholar
Pavlov, A.A., Vasilyev, G., Ostryakov, V.M., Pavlov, A.K. & Mahaffy, P. (2012). Degradation of the organic molecules in the shallow subsurface of Mars due to irradiation by cosmic rays. Geophys. Res. Lett. 39, L13202.Google Scholar
Perchonok, M.H., Cooper, M.R. & Catauro, P.M. (2012). Mission to Mars: Food Production and Processing for the Final Frontier, NASA Spec. ed, Annual Review of Food Science and Technology. NASA, Lyndon B. Johnson Space Center, Lyndon B. Johnson Space Center, Houston, TX.Google Scholar
Peters, G.A. & Meeks, J.C. (1989). The Azolla–Anabaena symbiosis: basic biology. Annu. Rev. Plant Physiol. Plant Mol. Biol. 40, 193210.Google Scholar
Pollard, E.C. (1965). Theoretical studies on living systems in the absence of mechanical stress. J. Theor. Biol. 8, 113123.Google Scholar
Pollard, E.C. (1967). Physical determinants of receptor mechanisms. In Gravity and the Organism, ed. Gordon, S.A. & Cohen, M.J., pp. 2534. The University of Chicago Press, Chicago, IL.Google Scholar
Poughon, L., Farges, B., Dussap, C.G., Godia, F. & Lasseur, C. (2009). Simulation of the MELiSSA closed loop system as a tool to define its integration strategy. Adv. Space Res. 44, 13921403.Google Scholar
Pulz, O. & Gross, W. (2004). Valuable products from biotechnology of microalgae. Appl. Microbiol. Biotechnol. 65, 635648.Google Scholar
Qiang, H., Zarmi, Y. & Richmond, A. (1998). Combined effects of light intensity, light-path and culture density on output rate of Spirulina platensis (Cyanobacteria). Eur. J. Phycol. 33, 165171.Google Scholar
Qin, L., Qingni, Y., Weidang, A., Yongkang, T., Jin, R. & Shuangsheng, G. (2014). Response of cyanobacteria to low atmospheric pressure. Life Sci. Space Res. 3, 5562.Google Scholar
Quintana, N., Van der Kooy, F., Van de Rhee, M.D., Voshol, G.P. & Verpoorte, R. (2011). Renewable energy from cyanobacteria: energy production optimization by metabolic pathway engineering. Appl. Microbiol. Biotechnol. 91, 471490.Google Scholar
Rapp, D. (2007). Human Missions to Mars: Enabling Technologies for Exploring the Red Planet. Springer, Heidelberg, New York, Dordrecht and London, and Praxis Publishing Ltd, Chichester, UK.Google Scholar
Rapp, D. (2013). Use of Extraterrestrial Resources for Human Space Missions to Moon or Mars. Springer, Heidelberg, New York, Dordrecht and London, and Praxis Publishing Ltd, Chichester, UK.Google Scholar
Raven, J.A., Wollenweber, B. & Handley, L.L. (1992). A comparison of ammonium and nitrate as nitrogen sources for photolithotrophs. New Phytol. 121, 1932.Google Scholar
Rentsch, D., Schmidt, S. & Tegeder, M. (2007). Transporters for uptake and allocation of organic nitrogen compounds in plants. FEBS Lett. 581, 22812289.Google Scholar
Rieder, R. (1997). The chemical composition of Martian soil and rocks returned by the Mobile Alpha Proton X-ray Spectrometer: preliminary results from the X-ray mode. Science 278, 17711774.Google Scholar
Roach, L.H. et al. (2007). CRISM spectral signatures of the north polar gypsum dunes. In Lunar and Planetary Science XXXVIII, LPI Contribution No. 1338, League City, TX, id. 1970.Google Scholar
Rothschild, L.J. (2010). A powerful toolkit for synthetic biology: over 3.8 billion years of evolution. Bioessays 32, 304313.Google Scholar
Rothschild, L.J. & Mancinelli, R.L. (2001). Life in extreme environments. Nature 409, 10921101.Google Scholar
Salisbury, F., Gitelson, J. & Lisovsky, G. (1997). Bios-3: Siberian experiments in bioregenerative life support. Bioscience 47, 575585.Google Scholar
Scalzi, G., Selbmann, L., Zucconi, L., Rabbow, E., Horneck, G., Albertano, P. & Onofri, S. (2012). LIFE experiment: isolation of cryptoendolithic organisms from Antarctic colonized sandstone exposed to space and simulated Mars conditions on the International Space Station. Orig. Life Evol. Biosph. 42, 253262.Google Scholar
Schirmack, J., Böhm, M., Brauer, C., Löhmannsröben, H.-G., de Vera, J.-P., Möhlmann, D. & Wagner, D. (2014). Laser spectroscopic real time measurements of methanogenic activity under simulated Martian subsurface analog conditions. Planet. Space Sci. 98, 198204.Google Scholar
Schneegurt, M.A. & Sherman, L.A. (1996). A role for the diazotrophic cyanobacterium, Cyanothece sp. strain ATCC 51142, in nitrogen cycling for CELSS applications. Life Support Biosph. Sci. 3, 4752.Google Scholar
Schneegurt, M.A., Arieli, B., McKeehen, J.D., Stephens, S.D., Nielsen, S.S., Saha, P.R., Trumbo, P.R. & Sherman, L.A. (1995). Compositional and toxicological evaluation of the diazotrophic cyanobacterium, Cyanothece sp. strain ATCC 51142. Aquaculture 134, 339349.Google Scholar
Schneegurt, M.A., Arieli, B., Nielsen, S.S., Trumbo, P.R. & Sherman, L.A. (1996). Evaluation of Cyanothece sp. ATCC 51142 as a candidate for inclusion in a CELSS. Adv. Space Res. 18, 177180.Google Scholar
Schneider, M.A. & Bruckner, A.P. (2003). Extraction of water from the Martian atmosphere. In Space Technology and Applications International Forum – STAIF 2003, ed. El-Gen, M.S., pp. 11241132. American Institute of Physics, Melville, NY.Google Scholar
Schuerger, A.C., Mancinelli, R.L., Kern, R.G., Rothschild, L.J. & McKay, C.P. (2003). Survival of endospores of Bacillus subtilis on spacecraft surfaces under simulated Martian environments: implications for the forward contamination of Mars. Icarus 165, 253276.Google Scholar
Schuerger, A.C., Ulrich, R., Berry, B.J. & Nicholson, W.L. (2013). Growth of Serratia liquefaciens under 7 mbar, 0°C, and CO2-enriched anoxic atmospheres. Astrobiology 13, 115131.Google Scholar
Sezonov, G., Joseleau-Petit, D. & D'ari, R. (2007). Escherichia coli physiology in Luria–Bertani broth. J. Bacteriol. 189, 87468749.Google Scholar
Shields, L.M., Durrell, L.W. & Sparrow, A.H. (1961). Preliminary observations on radio-sensitivity of algae and fungi from soils of the Nevada test site. Ecology 42, 440441.Google Scholar
Shiloach, J. & Fass, R. (2005). Growing E. coli to high cell density – a historical perspective on method development. Biotechnol. Adv. 23, 345357.Google Scholar
Silverstone, S.E. & Nelson, M. (1996). Food production and nutrition in Biosphere 2: results from the first mission September 1991 to September 1993. Adv. Space Res. 18, 4961.Google Scholar
Silverstone, S., Nelson, M., Alling, A. & Allen, J. (2003). Development and research program for a soil-based bioregenerative agriculture system to feed a four person crew at a Mars base. Adv. Space Res. 31, 6975.Google Scholar
Silverstone, S., Nelson, M., Alling, A. & Allen, J.P. (2005). Soil and crop management experiments in the Laboratory Biosphere: an analogue system for the Mars on Earth® facility. Adv. Space Res. 35, 15441551.Google Scholar
Singh, S. (2014). A review on possible elicitor molecules of cyanobacteria: their role in improving plant growth and providing tolerance against biotic or abiotic stress. J. Appl. Microbiol. 117, 12211244.Google Scholar
Singh, H., Anurag, K. & Apte, S.K. (2013). High radiation and desiccation tolerance of nitrogen-fixing cultures of the cyanobacterium Anabaena sp. Strain PCC 7120 emanates from genome/proteome repair capabilities. Photosynth. Res. 118, 7181.Google Scholar
Singh, H., Fernandes, T. & Apte, S.K. (2010). Unusual radioresistance of nitrogen-fixing cultures of Anabaena strains. J. Biosci., 35, 427434.Google Scholar
Slade, D. & Radman, M. (2011). Oxidative stress resistance in Deinococcus radiodurans . Microbiol. Mol. Biol. Rev. 75, 133191.Google Scholar
Spiller, H. & Gunasekaran, M. (1990). Ammonia-excreting mutant strain of the cyanobacterium Anabaena variabilis supports growth of wheat. Appl. Environ. Microbiol. 33, 447480.Google Scholar
Spiller, H., Latorre, C., Hassan, M.E. & Shanmugam, K.T. (1986). Isolation and characterization of nitrogenase-derepressed mutant strains of cyanobacterium Anabaena variabilis . J. Bacteriol. 165, 412419.Google Scholar
Squyres, S.W. et al. (2012). Ancient impact and aqueous processes at Endeavour Crater, Mars. Science 336, 570576.Google Scholar
Stanford-Brown 2011 iGEM Team (2011). PowerCell (Introduction). http://2011.igem.org/Team:Brown-Stanford/PowerCell/Introduction (accessed 8 June 2014).Google Scholar
Stevenson, B. & Waterbury, J. (2006). Isolation and identification of an epibiotic bacterium associated with heterocystous Anabaena cells. Biol. Bull. 210, 7377.Google Scholar
Stoker, C.R., Gooding, J.L., Roush, T., Banin, A., Burt, D., Clark, B.C., Flynn, G. & Gwynne, O. (1993). The physical and chemical properties and resource potentials of Martian surface soils. In Resources of Near Earth Space, ed. Lewis, J.S., Matthews, M.S. & Guerrieri, M.L., pp. 659707. The Arizona Board of Regents, Tucson, AZ.Google Scholar
Subramanian, G. & Shanmugasundaram, S. (1986). Uninduced ammonia release by the nitrogen-fixing cyanobacterium Anabaena. FEMS Microbiol. Lett. 37, 151154.Google Scholar
Sychev, V.N., Shepelev, E.Y., Meleshko, G.I., Gurieva, T.S., Levinskikh, M.A., Podolsky, I.G., Dadasheva, O.A. & Popov, V.V. (2001). Main characteristics of biological components of developing life support system observed during the experiments aboard orbital complex MIR. Adv. Space Res. 27, 15291534.Google Scholar
Sychev, V.N., Levinskikh, M.A. & Shepelev, Y.Y. (2003). The biological component of the life support system for a Martian expedition. Adv. Space Res. 31, 16931698.Google Scholar
Takahama, K., Matsuoka, M., Nagahama, K. & Ogawa, T. (2003). Construction and analysis of a recombinant cyanobacterium expressing a chromosomally inserted gene for an ethylene-forming enzyme at the psbAI locus. J. Biosci. Bioeng. 95, 302305.Google Scholar
Takahama, K., Matsuoka, M., Nagahama, K. & Ogawa, T. (2004). High-frequency gene replacement in cyanobacteria using a heterologous rps12 gene. Plant Cell Physiol. 45, 333339.Google Scholar
Taylor, S.R. & McLennan, S.M. (2009). Planetary Crusts: Their Composition, Origin and Evolution, Moon. Cambridge University Press, Cambridge.Google Scholar
Thomas, D., Sullivan, S., Sprice, A. & Zimmerman, S. (2005). Common freshwater cyanobacteria grow in 100% CO2 . Astrobiology 5, 6674.Google Scholar
Thomas, D.J., Boling, J., Boston, P.J., Campbell, K.A., McSpadden, T., McWilliams, L. & Todd, P. (2006). Extremophiles for ecopoiesis: desirable traits for and survivability of pioneer Martian organisms. Gravit. Space Biol. 19, 91104.Google Scholar
Trautmann, D., Voß, B., Wilde, A., Al-Babili, S. & Hess, W.R. (2012). Microevolution in cyanobacteria: re-sequencing a motile substrain of Synechocystis sp. PCC 6803. DNA Res. 19, 435448.Google Scholar
Tikhomirov, A.A., Ushakova, S.A., Kovaleva, N.P., Lamaze, B., Lobo, M. & Lasseur, C. (2007). Biological life support systems for a Mars mission planetary base: problems and prospects. Adv. Space Res. 40, 17411745.Google Scholar
Tokano, T. (ed.) (2005). Water on Mars and Life. Springer, Berlin.Google Scholar
Tokusoglu, Ö. & Unal, M.K. (2003). Biomass nutrient profiles of three microalgae: Spirulina platensis, Chlorella vulgaris and Isochrysis galbana . J. Food Sci. 68, 11441148.Google Scholar
Toprak, E., Veres, A., Yildiz, S. & Pedraza, J. (2013). Building a morbidostat: an automated continuous-culture device for studying bacterial drug resistance under dynamically sustained drug inhibition. Nat. Protoc. 8, 555567.Google Scholar
Vaniman, D.T. et al. (2014). Mineralogy of a mudstone at Yellowknife Bay, Gale crater, Mars. Science 343, 1243480.Google Scholar
Verseux, C., Paulino-Lima, I.G., Baqué, M., Rothschild, L.J. & Billi, D. (2016). Synthetic biology for space exploration: promises and societal implications. In Ambivalences of Creating Life. Societal and Philosophical dimensions of Synthetic Biology, ed. Hagen, K., Engelhard, M. & Toepfer, G., Springer-Verlag, Berlin and Heidelberg.Google Scholar
Wainwright, M., Wickramasinghe, N.C., Narlikar, J.V. & Rajaratnam, P. (2003). Microorganisms cultured from stratospheric air samples obtained at 41 km. FEMS Microbiol. Lett. 218, 161165.Google Scholar
Wamelink, G.W.W., Frissel, J.Y., Krijnen, W.H.J., Verwoert, M.R. & Goedhart, P.W. (2014). Can plants grow on Mars and the moon: a growth experiment on Mars and moon soil simulants. PLoS ONE 9, e103138.Google Scholar
Wang, B., Wang, J., Zhang, W. & Meldrum, D.R. (2012). Application of synthetic biology in cyanobacteria and algae. Front. Microbiol. 3, 344.Google Scholar
Wang, G., Li, G., Li, D., Liu, Y., Song, L., Tong, G., Liu, X. & Cheng, E. (2004). Real-time studies on microalgae under microgravity. Acta Astronaut. 55, 131137.Google Scholar
Wang, G., Chen, H., Li, G., Chen, L., Li, D., Hu, C., Chen, K. & Liu, Y. (2006). Population growth and physiological characteristics of microalgae in a miniaturized bioreactor during space flight. Acta Astronaut. 58, 264269.Google Scholar
Wang, H.H., Isaacs, F.J., Carr, P.A., Sun, Z.Z., Xu, G., Forest, C.R. & Church, G.M. (2009). Programming cells by multiplex genome engineering and accelerated evolution. Nature 460, 894898.Google Scholar
Warren-Rhodes, K.A., Rhodes, K.L., Pointing, S.B., Ewing, S.A., Lacap, D.C., Gómez-Silva, B., Amundson, R., Friedmann, E.I. & McKay, C.P. (2006). Hypolithic cyanobacteria, dry limit of photosynthesis, and microbial ecology in the hyperarid Atacama Desert. Microb. Ecol. 52, 389398.Google Scholar
Wassmann, M., Moeller, R., Reitz, G. & Rettberg, P. (2010). Adaptation of Bacillus subtilis cells to Archean-like UV climate: relevant hints of microbial evolution to remarkably increased radiation resistance. Astrobiology 10, 605615.Google Scholar
Way, J.C., Silver, P.A. & Howard, R.J. (2011). Sun-driven microbial synthesis of chemicals in space. Int. J. Astrobiol. 10, 359364.Google Scholar
Wheeler, R.M. (2004). Horticuture for Mars. In ISHS Acta Horticulturae 642, ed. Looney, N.E., pp. 201–15. ISHS, Toronto, Canada.Google Scholar
Wiens, J., Bommarito, F., Blumenstein, E., Ellsworth, M., Cisar, T., McKinney, B. & Knecht, B. (2001). Water extraction from Martian soil. In Fourth Annual HEDS-UP Forum, LPI Contribution No. 1106, Houston, TX.Google Scholar
Wierzchos, J., Ascaso, C. & McKay, C.P. (2006). Endolithic cyanobacteria in halite rocks from the hyperarid core of the Atacama Desert. Astrobiology 6, 415422.Google Scholar
Wijffels, R.H., Kruse, O. & Hellingwerf, K.J. (2013). Potential of industrial biotechnology with cyanobacteria and eukaryotic microalgae. Curr. Opin. Biotechnol. 24, 405413.Google Scholar
Williams, J.D., Coons, S.C. & Bruckner, A.P. (1995). Design of a water vapor adsorption reactor for Martian in situ resource utilization. J. Br. Interplanet. Soc. 48, 347354.Google Scholar
Wilson, J.W. et al. (2007). Space flight alters bacterial gene expression and virulence and reveals a role for global regulator Hfq. Proc. Natl. Acad. Sci. U.S.A. 104, 1629916304.Google Scholar
Xiao, Y., Liu, Y., Wang, G., Hao, Z. & An, Y. (2010). Simulated microgravity alters growth and microcystin production in Microcystis aeruginosa (cyanophyta). Toxicon 56, 17.Google Scholar
Yang, C., Liu, H., Li, M., Yu, C. & Yu, G. (2008). Treating urine by Spirulina platensis . Acta Astronaut. 63, 10491054.Google Scholar
Zaets, I., Burlak, O., Rogutskyy, I., Vasilenko, A., Mytrokhyn, O., Lukashov, D., Foing, B. & Kozyrovska, N. (2011). Bioaugmentation in growing plants for lunar bases. Adv. Space Res. 47, 10711078.Google Scholar
Zhou, Y., Zhang, Y., Wang, X., Cui, J., Xia, X., Shi, K. & Yu, J. (2011). Effects of nitrogen form on growth, CO assimilation, chlorophyll fluorescence, and photosynthetic electron allocation in cucumber and rice plants. J. Zhejiang Univ. B 12, 126134.Google Scholar
Zhukov-Verezhnikov, N.N. et al. (1962). Results of first microbiological and cytological experiments on Earth satellites in space. Artif. Earth Satell. 11, 4771.Google Scholar
Zisk, S.H. & Mouginis-Mark, P.J. (1980). Anomalous region on Mars – implications for near-surface liquid water. Nature 288, 126129.CrossRefGoogle Scholar
Zubrin, R. & Wagner, R. (2011). The Case for Mars: The Plan to Settle the Red Planet and Why We Must, 2011 edn. Free Press, New York.Google Scholar
Zubrin, R., Brian, F. & Tomoko, K. (1997). Mars in-situ resource utilization based on the reverse water gas shift – experiments and mission applications. In 33rd Joint Propulsion Conf. and Exhibit, Seattle, WA, AIAA 97–2767.Google Scholar
Zubrin, R.M., Baker, D.A. & Gwynne, O. (1991). Mars Direct: a simple, robust, and cost effective architecture for the space exploration initiative. In 29th Aerospace Sciences Meeting, Reno, NV, AIAA 91–0329.Google Scholar
Figure 0

Fig. 1. Artist's rendering of a cyanobacterium-based biological life-support system on Mars. Figure design: Cyprien Verseux and Sean McMahon (Yale University). Layout: Sean McMahon.

Figure 1

Fig. 2. Visual table of contents.

Figure 2

Fig. 3. Using cyanobacteria to process Martian resources into substrates for other organisms. In this scheme, cyanobacteria are fed with various nutrients obtained from the regolith, gaseous carbon and nitrogen from the atmosphere, energy from solar radiation, and water from various possible sources including ice caps, subsurface ice, atmosphere and hydrated minerals. Additional organic material, CO2 and water could be provided from metabolic and manufacturing waste resulting from human activity. Products from cyanobacterial cultures are then used as a substrate for heterotrophic microorganisms and plants.

Figure 3

Fig. 4. Anabaena sp. PCC7120 growing in distilled water containing JSC Mars-1A regolith simulant, in Lynn Rothschild's laboratory.

Figure 4

Fig. 5. Underpressurized culture vials used in Kirsi Lehto's laboratory (at the University of Turku, Finland) to grow cyanobacteria in low-pressure/high pCO2 atmospheres.

Figure 5

Table 1. Environmental parameters on Mars and Earth surfaces (adapted from Graham [2004] and Kanervo et al. [2005])

Figure 6

Fig. 6. Simplified overview of the potential roles of synthetic biology in the development of Mars-specific, cyanobacterium-based BLSS.

Figure 7

Fig. 7. Two examples of cyanobacteria: Anabaena sp. PCC7120 and Chroococcidiopsis sp. CCMEE 029.

Figure 8

Table 2. Examples of cyanobacterial genera of relevance for Mars-specific BLSS