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Chloroidium phycobionts (Watanabeales, Trebouxiophyceae) partner with lecanoralean mycobionts in foliicolous lichen communities of Tenerife (Canary Islands) and Navarra (Iberian Peninsula), Spain

Published online by Cambridge University Press:  26 March 2024

William B. Sanders Open the ORCID record for William B. Sanders [Opens in a new window] ,
Asunción de los Ríos Open the ORCID record for Asunción de los Ríos [Opens in a new window]  and
Sergio Pérez-Ortega Open the ORCID record for Sergio Pérez-Ortega [Opens in a new window]
William B. Sanders*
Affiliation:
Department of Biological Sciences, Florida Gulf Coast University, Ft Myers, FL 33965-6565, USA
Asunción de los Ríos
Affiliation:
Departamento de Biogeoquímica y Ecología Microbiana, Museo Nacional de Ciencias Naturales (CSIC), E-28006, Madrid, Spain
Sergio Pérez-Ortega
Affiliation:
Real Jardín Botánico (CSIC), E-28014, Madrid, Spain
*
Corresponding author: William B. Sanders; Email: wsanders@fgcu.edu
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Abstract

While the diversity of foliicolous lichen-forming fungi has been explored in substantial depth, relatively little attention has been paid to their algal symbionts. We studied the unicellular green phycobionts of the lecanoralean lichens Bacidina (Ramalinaceae), Byssoloma, Fellhanera and Tapellaria (Pilocarpaceae) and graphidalean Gyalectidium (Gomphillaceae) from two extratropical foliicolous communities in continental Spain and the Canary Islands. We examined the pyrenoids of algal symbionts within thalli using TEM, and obtained several algal nrSSU and rbcL sequences from whole thalli, and also from cultures isolated from some of these lichens. Pyrenoid structure and molecular sequence data provided support for recognizing Chloroidium (Watanabeales, Trebouxiophyceae) as phycobiont in thalli of Byssoloma subdiscordans and Fellhanera bouteillei (Pilocarpaceae) in both communities. Bacidina apiahica (Ramalinaceae) and Tapellaria epiphylla (Pilocarpaceae) likewise appeared to partner with Chloroidium based on the presence of the same pyrenoid type, although we were able to obtain a phycobiont sequence only from a culture isolate of the latter. These results contrast with those obtained previously from a foliicolous lichen community in southern Florida, which revealed only strains of Heveochlorella (Jaagichlorella) as phycobiont of foliicolous Pilocarpaceae and Gomphillaceae. On the other hand, the pyrenoid we observed in the phycobionts associated with Gyalectidium setiferum and G. minus corresponded to that of Heveochlorella (Jaagichlorella). However, the poor quality of the phycobiont sequence data obtained from G. minus, probably due to the presence of epibiontic algae, could not provide additional perspective on the pyrenoid structure observations. Nonetheless, clear differences in pyrenoid ultrastructure can allow Chloroidium and Heveochlorella phycobionts to be distinguished from each other in TEM. Our results indicate a greater diversity of unicellular green-algal symbionts in foliicolous communities from Spain than previously observed in other geographical areas, and suggest that further studies focused on symbiont pairing in these communities might reveal distinctive and varied patterns of phycobiont preference.

Keywords

HeveochlorellaJaagichlorellaphotobiontphycobiontsymbiosis
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The Lichenologist , First View , pp. 1 - 13
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
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Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of The British Lichen Society

Introduction

The leaf-colonizing (foliicolous) lichens of the humid tropics and subtropics are specialists whose distinctive features are related to the unique conditions associated with their microhabitat and their ephemeral, living substratum (Lücking Reference Lücking2001). Significant attention has been given to the lichen-forming fungi of foliicolous communities (Santesson Reference Santesson1952; Lücking Reference Lücking2008), particularly in the Neotropics, but their algal symbionts remain little studied. The filamentous Trentepohliaceae (Trentepohlia, Phycopeltis, Cephaleuros) are clearly important phycobionts in many of these communities (Lücking Reference Lücking2008). However, the two principal families of foliicolous lichen-forming fungi, the Pilocarpaceae (Lecanorales) and the Gomphillaceae (Graphidales), associate with unicellular green algae whose identities have only recently been subjected to any scrutiny. In a foliicolous community of southern Florida, all sampled species of both Pilocarpaceae and Gomphillaceae were found to partner with the alga Heveochlorella (Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016). This recently described trebouxiophycean genus first contained non-lichenized bark colonists from South-East Asia (Zhang et al. Reference Zhang, Huss, Sun, Chang and Pang2008; Ma et al. Reference Ma, Huss, Tan, Sun, Chun, Xie and Zhang2013) but has since been found to include lichen symbionts worldwide (Dal Grande et al. Reference Dal Grande F, Beck, Cornejo, Singh, Cheenacharoen, Nelsen and Scheidegger2014; Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016; Lindgren et al. Reference Lindgren, Moncada, Lücking, Magain, Simon, Goffinet, Sérusiaux, Nelsen, Mercado-Díaz and Widhelm2020). Heveochlorella is one of c. 10 rather new genera within the recently recognized order Watanabeales, in which many new taxa are being described (Darienko et al. Reference Darienko, Lukešova and Pröschold2018; Li et al. Reference Li, Tan, Liu, Zhu, Hu and Liu2021). Darienko & Pröschold (Reference Darienko and Pröschold2019) combine Heveochlorella and the related Heterochlorella (Neustupa et al. Reference Neustupa, Němcová, Eliáš and Škaloud2009) into the genus Jaagichlorella. We accept their arguments for uniting the two genera but continue to refer to Heveochlorella for the purposes of the present study, since a consistent pyrenoid type is associated with those taxa ascribed to Heveochlorella, whereas the type culture of Heterochlorella apparently has a pyrenoid structure (Neustupa et al. Reference Neustupa, Němcová, Eliáš and Škaloud2009, figs. 26 & 27) completely different from that reported in all other strains of both genera examined with TEM, an oddity that deserves further investigation. For the type species of Jaagichlorella (J. geometrica), a pyrenoid structure is not known.

Although Heveochlorella was the only phycobiont genus found in Gomphillaceae and Pilocarpaceae from the foliicolous community studied in Florida, two Brazilian specimens of Gomphillaceae collected from bark substratum partnered with Chloroidium (Watanabeales), while the phycobiont of one foliicolous member of Pilocarpaceae from Panama fell within an unidentified clade close to Chloroidium (Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016). Those results suggested that foliicolous members of the two fungal families in question might well associate with a more diverse range of phycobionts in other localities. Since foliicolous members of Pilocarpaceae and Gomphillaceae occur throughout the humid tropics, extending into the subtropics and even some habitats within temperate latitudes (van den Boom Reference van den Boom2020), their relationships with algal symbionts may be of considerable importance in understanding their ecological success. In the present study, we examine thallus phycobionts in two rather isolated extratropical communities of foliicolous lichens in Macaronesian and continental Spain.

Methods and Materials

Sampling, isolation and culture of photobionts

Foliicolous lichens were collected with their leaf substratum from two localities in Spain: the Foz de Arbayún gorge in Navarra (42.68°N, 1.19°W, c. 460 m; Gyalectidium setiferum Vězda & Sérus., Fellhanera bouteillei (Desm.) Vězda and Byssoloma subdiscordans (Nyl.) P. James), and the Anaga laurisilva forest in Tenerife, Canary Islands (28.53°–28.58°N, 16.17°–16.18°W, 100–900 m; Gyalectidium minus Sérus., Bacidina apiahica (Müll. Arg.) Vězda, Byssoloma kakouettae (Sérus.) Lücking & Sérus., B. subdiscordans and Fellhanera bouteillei). Gyalectidium spp. are members of Gomphillaceae (Graphidales), while the remaining genera belong in Pilocarpaceae (Byssoloma, Fellhanera, Tapellaria) and Ramalinaceae (Bacidina) within the Lecanorales. Identifications were made with reference to Lücking (Reference Lücking2008). Foliicolous thalli were peeled from drying leaves with sterile forceps or scraped with a sterile razor blade and placed in a centrifuge tube for direct PCR or DNA extraction. Several thalli or thallus areolae from the same or neighbouring leaves were often included within the same sample to ensure sufficient material for analysis, usually judged as enough when clearly visible in the tube with the naked eye. For culturing, a small thallus or thallus areola was peeled from the leaf and pressed underside down onto 1× BBM agar. Special care was taken to avoid thalli with an obvious presence of epiphytic algae or lichenicolous fungi. Culture plates were maintained at room temperature in the laboratory near to windows but without exposure to direct sunlight. Other thalli were cut out with thin strips of their leaf substratum using a razor blade and processed for TEM as indicated below.

TEM processing

Fresh material was misted with distilled water a few hours prior to hand-sectioning with a thin razor blade. Sections were placed immediately into tubes with 3% glutaraldehyde in phosphate buffer for c. 3 h, then washed three times in buffer, post-fixed with 1% osmium tetroxide in phosphate buffer for c. 5 h, washed again, and dehydrated in a graded ethanol series. Specimens were then infiltrated with Spurr's low viscosity resin (initially diluted with propylene oxide) and polymerized (de los Ríos & Ascaso Reference de los Ríos, Ascaso, Kranner, Beckett and Varma2002). Specimen blocks (1–2 per lichen species in each community) were sectioned with an Ultracut ultramicrotome, stained with uranyl acetate and lead citrate, and imaged with a JEOL transmission electron microscope at the Centro Nacional de Biotecnología (CNB-CSIC).

DNA extraction and amplification

Thallus fragments in microcentrifuge tubes were stored at −80 °C and, after 1 h of freezing, were pulverized using a Qiagen TissueLyser II and glass beads. DNA was extracted using E.Z.N.A.® Forensic DNA Kit (Omega Bio-Tek) according to the manufacturer's instructions, with final eluting of extracted DNA in water (50 μl). DNA from phycobiont cultures was extracted using a SpeedTools Tissue DNA extraction kit according to the manufacturer's protocol. A fragment of the nuclear ribosomal small subunit (nrSSU) gene was amplified using the primer pair 232F (Thüs et al. Reference Thüs, Muggia, Pérez-Ortega, Favero-Longo, Joneson, O'Brien, Nelsen, Duque-Thüs, Grube and Friedl2011) and SR7R (R. Vilgalys, unpublished data; http://www.botany.duke.edu/fungi/mycolab). A fragment of the gene that encodes the large subunit of ribulose-1,5 bisphosphate carboxylase (rbcL) was amplified using the primer pair RH1 (Manhart Reference Manhart1994) and rbcL 530R (Verbruggen et al. Reference Verbruggen, Ashworth, LoDuca, Vlaeminck, Cocquyt, Sauvage, Zechman, Littler, Littler and Leliaert2009). Amplification reactions using DNA extracted from the thallus were prepared for a 15 μl final volume containing 7.5 μl of MyTaq™ Red Mix (Bioline), 0.5 μl of each of the primers at 10 μM, 5.5 μl of H2O, and 1 μl of template. Reactions using DNA extracted from cultures were prepared for a 25 μl final volume using GE Healthcare Illustra™ PuReTaq Ready-To-Go PCR Beads (Amersham Biosciences), 0.5 μl of each of the primers at 10 μM, 21 μl of H2O, and 3 μl of DNA template. PCR conditions for amplification of the nrSSU and rbcL were as follows: 5 min at 94 °C; 34 cycles of 45 s at 95 °C, 45 s at 57 °C (nrSSU) or 50 °C (rbcL), 1 min 30 s at 72 °C, and a final extension step of 5 min at 72 °C. Due to a lack of success in amplifying the selected regions from DNA extractions, we employed a different strategy using direct PCR. Direct PCR reactions were carried out using KAPA3 G Plant PCR Kit (KAPA Biosystems), which contains the KAPA3 G Plant DNA Polymerase (2.5 U μl−1) and KAPA Plant PCR Buffer with dNTPs (2×, with 1.5 mM MgCl2 and 0.2 mM of each dNTP at 1×), following the manufacturer's instructions. PCR reactions were prepared in a 50 μl final volume containing the tiny fragment of lichen thallus (c. 1 mm2), 25 μl of the KAPA Plant PCR Buffer, 1.5 μl of each primer at 10 μM and 0.4 μl of the KAPA3 G Plant DNA Polymerase, and sterile water to complete the volume. The following cycling protocol was used: 3 min at 95 °C, 35 cycles of 20 s at 95 °C, 15 s at 57 °C (nrSSU) or 50 °C (rbcL), 30 s at 72 °C, and a final extension of 1 min at 72 °C. Both complementary strands were sequenced by Macrogen Inc. (Madrid, Spain) using the same primer set as for PCR amplification. Sequences were inspected and contigs assembled using Geneious Prime® v. 2020.0.3. Curated sequences were used as a template for BLAST searches (Altschul et al. Reference Altschul, Madden, Schäffer, Zhang, Zhang, Miller and Lipman1997).

Phylogenetic analyses

A BLAST search was carried out in GenBank to ensure that the sequences obtained belonged to groups that included phycobionts rather than likely contaminants. For the rbcL sequences, all BLAST search results retrieved members of Chloroidium, so we compiled sequences from representative members of genera in the Watanabeales following Darienko & Pröschold (Reference Darienko and Pröschold2019) and Li et al. (Reference Li, Tan, Liu, Zhu, Hu and Liu2021) (see Supplementary Material Table S1, available online). Members of Diplosphaera, Stichococcus and Symbiochloris were used as outgroup. Regarding nrSSU sequences, in addition to Chloroidium, we also obtained sequences from other genera of Trebouxiophyceae, so we compiled a larger dataset with data of representative genera of the group based on Li et al. (Reference Li, Tan, Liu, Zhu, Hu and Liu2021), focusing on the groups retrieved from the BLAST search (Supplementary Material Table S2, available online). Sequences from Chlorophyceae species Oedogonium cardiacum, Chaetopeltis orbicularis and Floydiella terrestris were used as outgroup.

Alignments for each locus were carried out using MAFFT v. 7.490 (Katoh et al. Reference Katoh, Misawa, Kuma and Miyata2002) as implemented in the software Geneious Prime® v. 2022.2.2 (https://www.geneious.com) using default parameters. Alignments were visually inspected and introns were removed using Gblocks v. 0.91b (Castresana Reference Castresana2000) (at http://phylogeny.lirmm.fr/phylo_cgi/one_task.cgi?task_type=gblocks) applying all the options available for the least stringent selection. The alignments were analyzed using maximum likelihood (ML) phylogenetic inference methods. Analyses were performed in RAxML v. 8.2.11 (Stamatakis Reference Stamatakis2014) as implemented in Geneious Prime® v. 2022.2, using the GTRGAMMA substitution model. We conducted the search of the best-scoring ML tree and rapid bootstrapping with 1000 pseudoreplicates to evaluate nodal support in one single run. We considered supported nodes (depicted in bold in Figs 7 & 8) to be those with bootstrap values ≥ 70%. Trees were visualized using FigTree v. 1.4.4 (available at https://github.com/rambaut/figtree/releases) and Adobe Illustrator CS5 was used for artwork.

Results

Pyrenoid ultrastructure

TEM observations of phycobionts within foliicolous lichen thalli revealed three different pyrenoid types, two well-defined and one diffuse, present among algal symbionts of the two communities studied. The most common type was typically prominent, central, roughly round in section, and penetrated by one or a small number of slender, membranous plates that meandered sinuously through the pyrenoid, which they appeared to fully traverse while passing in and out of the plane of section (Figs 1–3). The penetrating membranes were continuous with chloroplast thylakoids outside the pyrenoid and each maintained the approximate width of a single thylakoid (Fig. 3D). Pyrenoglobuli were generally abundant and arranged at the outer periphery of the pyrenoid; they were not associated with the penetrating membranes or any part of the pyrenoid interior. Often, starch deposits were also seen at the pyrenoid periphery (Figs 1 & 3). This type of pyrenoid was observed in thalli of Byssoloma subdiscordans and Fellhanera bouteillei from both Navarra and Tenerife (Figs 1 & 2), as well as in those of Bacidina apiahica (Fig. 2A) and Tapellaria epiphylla (Müll. Arg.) R. Sant. (Fig. 3) from Tenerife.

Figure 1. TEM images of pyrenoid of phycobiont associated with two foliicolous lichens from Navarra. Arrow indicates sinuous thylakoid traversing the pyrenoid; p = pyrenoglobule. A & B, Byssoloma subdiscordans. C & D, Fellhanera bouteillei. Scales: A = 1 μm; B–D = 250 nm.

Figure 2. TEM images of pyrenoid of phycobiont associated with three foliicolous lichens from Tenerife. A, Bacidina apiahica; arrow = thylakoid penetrating pyrenoid; p = pyrenoglobule. B & C, Byssoloma subdiscordans; f = contacting fungal cell. D, Fellhanera bouteillei. Scales: A = 100 nm; B = 1 μm; C & D = 250 nm.

Figure 3. A–D, TEM images of phycobiont within the thallus of Tapellaria epiphylla from Tenerife. Arrows indicate continuity of pyrenoid-penetrating thylakoids with stacked thylakoids outside pyrenoid; a = algal symbiont; f = fungal symbiont; p = plastoglobule; s = starch. Scales: A = 1 μm; B = 500 nm; C & D = 250 nm.

The second type of pyrenoid observed was penetrated by membranous tubules arising from the outermost membranes of a stack of several thylakoids; the tubules often maintained the approximate width of the entire stack rather than that of a single thylakoid (Fig. 4A & B). The penetrating tubules were oriented centripetally, appearing in both longitudinal and transverse view; their trajectories appeared to end near the centre of the pyrenoid, with no individual tubule seen to fully traverse it (Fig. 4). Pyrenoglobuli lined the exterior surfaces of these penetrating tubules. Surrounding starch deposits were not seen. This type of pyrenoid was observed in Gyalectidium setiferum from Navarra and G. minus from Tenerife (Fig. 4).

Figure 4. TEM images of phycobiont pyrenoids in Gyalectidium. A & B, G. setiferum (Navarra). C & D, G. minus (Tenerife). B, tubule arising from outer membranes of thylakoid stack (arrowed); p = pyrenoglobule. Scales: A = 500 nm; B & D = 100 nm; C = 250 nm.

A third, diffuse type of pyrenoid was represented by smallish, dilated areas of modest electron density between thylakoid stacks; they included pyrenoglobuli, often at the periphery but with no discernible regularity in arrangement (Figs 5, 6A & B). This poorly defined pyrenoid might be confused with peripheral, tangential sections of a larger, central pyrenoid that has pyrenoglobuli at its perimeter (e.g. Fig. 2D). However, examination of numerous sectioned phycobiont cells suggested that this was a distinct type. It was observed in phycobionts within thalli of Byssoloma leucoblepharum (Nyl.) Vain. (Fig. 5) and B. kakouettae (Fig. 6A & B) from Tenerife, although an algal culture isolated from thalli of B. kakouettae clearly showed the first type of pyrenoid described above (Fig. 6C & D).

Figure 5. TEM images of phycobiont within the thallus of Byssoloma leucoblepharum. A, alga with contacting mycobiont cells. B & C, diffuse pyrenoidal areas with pyrenoglobuli. Scales: A = 500 nm; B & C = 250 nm.

Figure 6. A & B, TEM images of phycobiont within the thallus of Byssoloma kakouettae (Tenerife), showing diffuse pyrenoidal areas. C & D, TEM images of pyrenoid in alga isolated into culture from the thallus of Byssoloma kakouettae (Tenerife). C, with numerous electron-dense pyrenoglobuli and some starch deposits at periphery. D, with large starch deposits and few pyrenoglobuli at periphery; p = pyrenoglobule; s = starch. Scales: A = 1 μm; B–D = 500 nm.

Molecular sequencing

Many attempts to amplify selected regions of foliicolous phycobiont DNA resulted in sequences showing clear double or even triple peaks in parts of the electropherograms. Clean nrSSU (11) and rbcL (9) algal sequences were obtained from thalli of Byssoloma subdiscordans and Fellhanera bouteillei from both localities, and B. leucoblepharum and Gyalectidium minus from Tenerife. In addition, we obtained clean nrSSU (4) and rbcL (4) sequences from the phycobionts of Byssoloma kakouettae, B. subdiscordans, Fellhanera bouteillei and Tapellaria epiphylla from Tenerife isolated into culture (Table 1). We were unsuccessful in obtaining clean sequences from the thalli of Bacidina apiahica, Byssoloma kakouettae and Tapellaria epiphylla. All recovered rcbL sequences, both from thalli and cultures from Tenerife and Navarra, formed a well-supported clade within the genus Chloroidium, sister to C. angustoellipsoideum although this relationship was not supported (Fig. 7). The sequences were identical except for Arb49 and Arb50 (both from Fellhanera bouteillei from Navarra) and E135 (Byssoloma subdiscordans from Tenerife), which differed in three positions. Regarding nrSSU, most of the obtained sequences formed two clades within Chloroidium. One clade contained all sequences obtained from lichen thalli (Byssoloma subdiscordans from Navarra and Tenerife, Fellhanera bouteillei from Navarra, and Gyalectidium minus from Tenerife) together with sequences of C. ellipsoideum, C. lichenum and C. angustoellipsoideum obtained from GenBank (Fig. 8). The sister group to this clade consisted of all sequences obtained from phycobionts in culture. In addition, two sequences from Byssoloma leucoblepharum (A31 and A32 from Tenerife) were found to be related to species of the genus Symbiochloris, while one sequence from Fellhanera bouteillei (Arb42 from Navarra) belonged to the genus Trebouxia and one sequence from Byssoloma subdiscordans (A2 from Navarra) was recovered within Coccomyxa (Fig. 8). The common presence of epibionts, including some that resembled Coccomyxa, was evident in TEM images of the lichen thallus exterior and particularly in the cultured isolates.

Figure 7. Most-likely tree inferred by maximum likelihood (ML) analysis of the rbcL region, showing the relationships of photobionts of the studied foliicolous species with members of the Watanabeales. Thick branches indicate nodes with bootstrap values ≥ 70%. Locality: (N) = Navarra; (T) = Tenerife.

Figure 8. Most-likely tree inferred by maximum likelihood (ML) analysis of the nrSSU region, showing the relationships of photobionts of the studied foliicolous species with members of the Trebouxiophyceae. Thick branches indicate nodes with phylogenetic support in both analyses (bootstrap values ≥ 70% and posterior probability ≥ 0.95). Locality: (N ) = Navarra; (T) = Tenerife.

Table 1. GenBank Accession numbers corresponding to the rbcL and nrSSU sequences obtained during this study. Locality: N = Navarra; T = Tenerife. Culture: Y = Yes; N = No.

Discussion

The pyrenoid type observed within thalli of Byssoloma subdiscordans, Fellhanera bouteillei, Bacidina apiahica and Tapellaria epiphylla corresponds in structure to that observed in the alga Chloroidium saccharophilum (Ikeda & Takeda Reference Ikeda and Takeda1995; González et al. Reference González, Pröschold, Palacios, Aguayo, Ibostroza and Gómez2013), the type species of that genus (Darienko et al. Reference Darienko, Gustavs, Mudimu, Menendez, Schumann, Karsten, Friedl and Pröschold2010). For C. lichenum, we found no images or descriptions of pyrenoid ultrastructure in the literature. The presence of Chloroidium phycobionts associated with B. subdiscordans and F. bouteillei in both foliicolous communities studied here was supported by nrSSU and/or rbcL sequence data (Figs 7 & 8). Although attempts to obtain sequences from Bacidina apiahica and T. epiphylla thalli were unsuccessful, TEM observation of within-thallus phycobionts showing the same kind of pyrenoid strongly suggests that these lichens also partner with Chloroidium. This appears to be the first published report of the algal genus Chloroidium occurring as symbiont in foliicolous communities. Elsewhere, species of Chloroidium have been reported as phycobionts of diverse lichen-forming fungi, such as certain species of crustose Trapelia (Tschermak-Woess Reference Tschermak-Woess and Galun1988; Beck Reference Beck2002; Peršoh et al. Reference Peršoh, Beck and Rambold2004) and Verrucaria (Thüs et al. Reference Thüs, Muggia, Pérez-Ortega, Favero-Longo, Joneson, O'Brien, Nelsen, Duque-Thüs, Grube and Friedl2011; Voytsekhovitch & Beck Reference Voytsekhovich and Beck2016), squamulose Psora (Ruprecht et al. Reference Ruprecht, Brunauer and Türk2014), foliose Sticta (Lindgren et al. Reference Lindgren, Moncada, Lücking, Magain, Simon, Goffinet, Sérusiaux, Nelsen, Mercado-Díaz and Widhelm2020), and fruticose Stereocaulon (Vančurová et al. Reference Vančurová, Muggia, Peksa, Řídká and Škaloud2018), as well as occurring as non-lichenized members of aquatic and terrestrial communities (Darienko et al. Reference Darienko, Gustavs, Mudimu, Menendez, Schumann, Karsten, Friedl and Pröschold2010; González et al. Reference González, Pröschold, Palacios, Aguayo, Ibostroza and Gómez2013; Metz et al. Reference Metz, Singer, Domaizon, Unrein and Lara2019; Li et al. Reference Li, Tan, Liu, Zhu, Hu and Liu2021). The presence of Chloroidium as symbiont in the specialized phyllosphere community further highlights the considerable ecological range of this genus.

Heveochlorella, the sole phycobiont found associated with Gomphillaceae and Pilocarpaceae in the Floridian foliicolous community studied previously (Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016), also appeared to be a symbiont in the Spanish foliicolous communities studied here. Its characteristic pyrenoid type (Zhang et al. Reference Zhang, Huss, Sun, Chang and Pang2008; Ma et al. Reference Ma, Huss, Tan, Sun, Chun, Xie and Zhang2013; Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016) was observed in thalli of G. setiferum (Navarra) and G. minus (Tenerife), predominant elements in their respective leaf communities. However, molecular sequence data were somewhat less supportive in the case of the former, and contradictory in the case of the latter. For G. setiferum, all obtained sequences showed a number of double peaks; in BLAST searches, they returned Heveochlorella/Jaagichlorella sequences, albeit with low percentage identity (data not shown). Of more problematic interpretation were the sequences obtained from G. minus, the one clean sequence pointing to Chloroidium lichenum, which is clearly at odds with the pyrenoid type observed. Based on the TEM observations, we are fairly confident that Heveochlorella was the phycobiont present in at least the thallus we sectioned, but we cannot rule out the possibility that Chloroidium was phycobiont in the thalli we sequenced, particularly since it occurs as phycobiont in other lichens of the same community. We are considerably more doubtful that the Coccomyxa sequence obtained from Byssoloma subdiscordans and the Trebouxia sequence obtained from Fellhanera bouteillei thalli represent phycobionts of the thalli in question. Coccomyxa lacks pyrenoids and has a rather distinctive chloroplast ultrastructure that was not seen among phycobionts within any foliicolous thalli examined in the present or previous studies. And while the pyrenoids present in Chloroidium and Heveochlorella each have counterparts within the genus Trebouxia, the typical autospore packet of 8–16 cells that is characteristic of Trebouxia was not observed in any foliicolous lichen thallus. Epibiontic algae may well have been responsible for the sequence ambiguities, but it is also plausible that more than one phycobiont genus might associate with a particular mycobiont in these communities. The minute size of foliicolous lichens, particularly Gyalectidium species, introduces several difficulties in obtaining accurate sequences from their phycobionts. Epibionts may be abundant in these communities, particularly where older leaves and thalli are concerned, but cannot be cleaned from the surfaces of such tiny thalli. Furthermore, to obtain sufficient DNA, several neighbouring thalli are needed, while yet others must be processed for TEM observation, introducing the possibility that DNA sequences, even when they accurately reflect the phycobiont of the thallus sampled, might not always correspond to the one present in the separate sample from which TEM images are obtained. These same uncertainties also apply to the algal cultures established in this study since the thallus areolae or fragments used as inoculum were too small to clean or surface-sterilize. It is furthermore possible that individual thalli contain more than one photobiont species, as has been reported in a number of lichens colonizing other substrata (e.g. Piercey-Normore Reference Piercey-Normore2006; Muggia et al. Reference Muggia, Pérez-Ortega, Kopun, Zellnig and Grube2014; Park et al. Reference Park, Kim, Elvebakk, Kim, Jeong and Hong2015; Dal Grande et al. Reference Dal Grande, Rolshausen, Divakar, Crespo, Otte, Schleuning and Schmitt2018; Osyczka et al. Reference Osyczka, Lenart-Boroń, Boroń and Rola2021). The ontogeny of the foliicolous thallus can offer many opportunities for multiple photobionts to be incorporated into a single thallus (Sanders Reference Sanders2014), although we have not observed algal cells with clearly different pyrenoid types occurring as phycobiont within the same thallus.

The distinct pyrenoid types characteristic of Chloroidium and Heveochlorella phycobionts are compared and contrasted in Table 2. It should be noted that other taxa of Chloroidium are said to lack pyrenoids (Darienko et al. Reference Darienko, Gustavs, Mudimu, Menendez, Schumann, Karsten, Friedl and Pröschold2010), and it is also conceivable that species not yet examined with TEM might be found to have a type of pyrenoid different from those reported so far. At least five or six different pyrenoid types are known in the single phycobiont genus Trebouxia s. str. (Friedl Reference Friedl1989; Bordenave et al. Reference Bordenave, Muggia, Chiva, Leavitt, Carrasco and Barreno2022). Remarkably, the two pyrenoid morphologies observed here in the Watanabeales correspond rather closely to two of the pyrenoid types known from Trebouxia (Trebouxiales): the pyrenoid of Heveochlorella is very similar to the [Trebouxia] impressa-type, while that of the Chloroidium specimens is similar to the corticola-type, as discussed above. The Trebouxiales and Watanabeales are not closely related within Trebouxiophyceae. There is evidence linking pyrenoids to mechanisms of concentrating CO2 in the vicinity of Rubisco (Palmqvist et al. Reference Palmqvist, de los Ríos, Ascaso and Samuelsson1997). Penetrating membranes appear to lack O2-generating photosystem II and are thought to play a role in CO2 delivery (Meyer et al. Reference Meyer, Whittaker and Griffiths2017), but the functional significance of pyrenoid structural diversity is largely unknown. The remarkable convergence of pyrenoid types among distantly related genera suggests that substantial selection pressures act upon functional morphology, with a relatively limited range of structural solutions available.

Table 2. A comparison of pyrenoid characteristics of Heveochlorella and Chloroidium strains.

In contrast with those of Heveochlorella and Chloroidium, the pyrenoids seen in the phycobiont of Byssoloma leucoblepharum were much less clearly delimited and lacked any specialized penetrating membranes (Fig. 5). A BLAST search with two clean nrSSU sequences from this lichen indicated Symbiochloris, an algal genus not known to have pyrenoids (Škaloud et al. Reference Škaloud, Friedl, Hallmann, Beck and Dal2016). It is conceivable that the poorly differentiated pyrenoids were overlooked previously, or not judged to be true pyrenoids, but the chloroplast morphology we observed in B. leucoblepharum phycobionts does not appear to show the reticulate structure characteristic of Symbiochloris and Dictyochloropsis. It is possible that surface epibionts were amplified, or that the thallus observed in TEM contained an alga different from those genetically sampled. Although Symbiochloris partners with a considerable diversity of lichen-forming fungi (Sanders & Masumoto Reference Sanders and Masumoto2021) and appears to occur abundantly in phyllosphere communities of tropical Asia (Zhu et al. Reference Zhu, Li, Hu and Liu2018), it has not been reported as a foliicolous lichen symbiont. For the lichen Byssoloma kakouettae, while TEM images of a cultured isolate point to Chloroidium as phycobiont, the pyrenoid type observed within the thallus was diffuse and poorly differentiated. Thus, we were not able to adequately resolve the algal partner identities for Byssoloma kakouettae and B. leucoblepharum in the communities examined, nor confirm the status of Symbiochloris as a potential foliicolous lichen symbiont. Our results highlight both the strengths and limitations of using in-thallus TEM images of phycobionts to help determine their identities. Where distinctive pyrenoids characterize the strains involved, such as those of Chloroidium versus Heveochlorella, the TEM images can provide an important check against molecular sequence data that might actually correspond to an epibiont rather than the true thallus symbiont. This is particularly helpful with foliicolous lichens, whose thalli are generally too small to effectively clean of epibionts. In other cases, however, obvious differences in pyrenoid ultrastructure may not be apparent between candidate phycobionts of even quite different genera. Nonetheless, further TEM studies may provide additional details that help resolve some ambiguities. For example, while the pyrenoid observed in Heveochlorella largely corresponds to the impressa-type found in some Trebouxia species (Friedl Reference Friedl1989; Barreno et al. Reference Barreno, Muggia, Chiva, Molina, Bordenave, García-Brejo and Moya2022), the ultrastructure of the chloroplast near the pyrenoid periphery looks quite different in Trebouxia species with this type of pyrenoid. Dilation of thylakoids with electron-transparent lumina is evident in the Trebouxia chloroplast well before the membranes enter the pyrenoid as tubules, and they do not appear to arise from the outermost membranes of a multi-thylakoid stack (Barreno et al. Reference Barreno, Muggia, Chiva, Molina, Bordenave, García-Brejo and Moya2022; Bordenave et al. Reference Bordenave, Muggia, Chiva, Leavitt, Carrasco and Barreno2022) as they do in Heveochlorella (Fig. 4B; Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016, fig. 3D & F).

While the presence of surrounding starch plates often figures as part of pyrenoid type descriptions, we found this to be a variable character in the present study. Surrounding starch plates were consistently present in the Heveochlorella phycobiont pyrenoids observed from Florida, even in cultured isolates (Sanders et al. Reference Sanders, Pérez-Ortega, Nelsen, Lücking and de los Ríos2016), but were absent from phycobionts of the two species of Gyalectidium observed in the two habitats of the present study (Fig. 4). Starch plates were clearly visible surrounding the pyrenoids of Chloroidium associated with Byssoloma subdiscordans and Fellhanera bouteillei from Navarra (Fig. 1) but were absent in the same two lichen species from Tenerife, as well as Bacidina apiahica from that locality (Fig. 2). TEM micrographs of Chloroidium sampled from free-living collections (Ikeda & Takeda Reference Ikeda and Takeda1995; González et al. Reference González, Pröschold, Palacios, Aguayo, Ibostroza and Gómez2013) did not show visible starch accumulations surrounding the pyrenoid. It seems likely that local or seasonal variability in resource accumulation and use might contribute to the presence or absence of starch plates observed in a sample at a given time. Within the same culture of Chloroidium isolated from Byssoloma kakouettae, some cells showed relatively abundant pyrenoglobuli and only limited starch deposits surrounding the pyrenoid, while others showed the opposite pattern (Fig. 6C & D). While the degree of usage and storage of these carbohydrate and lipid resources appears to vary from cell to cell, their location appears to be characteristic of the pyrenoid type, and in the case of the pyrenoglobuli, that location is distinctly different in the Chloroidium and Heveochlorella pyrenoids observed (Table 2).

Relatively few sequences are currently available for foliicolous lichen phycobionts, and most are from outside the principal centre of diversity of these communities in the Neo- and Paleotropics. Among the challenges involved are the apparent instability of the genetic material, and the difficulties in obtaining clean sequences from very tiny thalli growing among diverse microalgae of the phyllosphere. Nonetheless, further efforts are likely to prove rewarding if these technical difficulties can be resolved. The adaptations of foliicolous lichens to the unique conditions of the ephemeral leaf substratum, the diversity of their sexual and asexual means of reproduction, and their symbiotic as well as aposymbiotic dispersal of propagules pose many interesting questions worthy of further exploration, particularly in regard to symbiont selection and the generational continuity of genetic partnerships.

Acknowledgements

Ultrathin sections were prepared by Beatriz Martín Jouve (Centro Nacional de Biotecnología, CSIC, Madrid). The collection of foliicolous lichens at Anaga was facilitated by the Cabildo de Tenerife, Área de Sostenibilidad, Medio Ambiente y Seguridad (permit # O00006501s1900019469). WBS is grateful to Dr Javier Etayo and his wife Eva for their generous hospitality during a collecting trip to Navarra, and to Dr Israel Pérez Vargas for kindly providing laboratory facilities during a similar visit to Tenerife. Funding was provided by an FGCU Scholarship-Research Venture Capital Award. The manuscript benefited from peer review by Dr Pavel Škaloud and two anonymous referees.

Author ORCIDs

William B. Sanders, 0000-0001-9572-4244; Asunción de los Ríos, 0000-0002-0266-3516; Sergio Pérez-Ortega, 0000-0002-5411-3698.

Competing Interests

The authors declare none.

Supplementary Material

The supplementary material for this article can be found at https://doi.org/10.1017/S0024282924000069.

References

Altschul, SF, Madden, TL, Schäffer, AA, Zhang, J, Zhang, Z, Miller, W and Lipman, DJ (1997) Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Research 25, 33893402.Google Scholar
Barreno, E, Muggia, L, Chiva, S, Molina, A, Bordenave, C, García-Brejo, F and Moya, P (2022) Trebouxia lynnae sp. nov. (former Trebouxia sp. TR9): biology and biogeography of an epitome lichen symbiotic microalga. Biology 11, 1196.Google Scholar
Beck, A (2002) Selektivität der symbionten schwermetalltoleranter Flechten. Ph.D. thesis, Ludwig Maximilian University of Munich.Google Scholar
Bordenave, CD, Muggia, L, Chiva, S, Leavitt, SD, Carrasco, P and Barreno, E (2022) Chloroplast morphology and pyrenoid ultrastructural analyses reappraise the diversity of the lichen phycobiont genus Trebouxia (Chlorophyta). Algal Research 61, 102561.Google Scholar
Castresana, J (2000) Selection of conserved blocks from multiple alignments for their use in phylogenetic analysis. Molecular Biology and Evolution 17, 540552.Google Scholar
Dal Grande F, , Beck, A, Cornejo, C, Singh, G, Cheenacharoen, S, Nelsen, MP and Scheidegger, C (2014) Molecular phylogeny and symbiotic selectivity of the green algal genus Dictyochloropsis s. l. (Trebouxiophyceae): a polyphyletic and widespread group forming phycobiont-mediated guilds in the lichen family Lobariaceae. New Phytologist 202, 455470.Google Scholar
Dal Grande, F, Rolshausen, G, Divakar, PK, Crespo, A, Otte, J, Schleuning, M and Schmitt, I (2018) Environment and host identity structure communities of green algal symbionts in lichens. New Phytologist 217, 277289.CrossRefGoogle ScholarPubMed
Darienko, T and Pröschold, T (2019) The genus Jaagichlorella Reisigl (Trebouxiophyceae, Chlorophyta) and its close relatives: an evolutionary puzzle. Phytotaxa 388, 4768.Google Scholar
Darienko, T, Gustavs, L, Mudimu, O, Menendez, CR, Schumann, R, Karsten, U, Friedl, T and Pröschold, T (2010) Chloroidium, a common terrestrial coccoid green alga previously assigned to Chlorella (Trebouxiophyceae, Chlorophyta). European Journal of Phycology 45, 7995.CrossRefGoogle Scholar
Darienko, T, Lukešova, A and Pröschold, T (2018) The polyphasic approach revealed new species of Chloroidium (Trebouxiophyceae, Chlorophyta). Phytotaxa 372, 5166.Google Scholar
de los Ríos, A and Ascaso, C (2002) Preparative techniques for transmission electron microscopy and confocal laser scanning microscopy of lichens. In Kranner, IC, Beckett, RP and Varma, AK (eds), Protocols in Lichenology. Berlin and Heidelberg: Springer-Verlag, pp. 87117.CrossRefGoogle Scholar
Friedl, T (1989) Comparative ultrastructure of pyrenoids in Trebouxia (Microthamniales, Chlorophyta). Plant Systematics and Evolution 164, 145159.CrossRefGoogle Scholar
González, MA, Pröschold, T, Palacios, Y, Aguayo, P, Ibostroza, I and Gómez, PI (2013) Taxonomic identification and lipid production of two Chilean Chlorella-like strains isolated from a marine and an estuarine coastal environment. AoB Plants 5, plt020.CrossRefGoogle Scholar
Ikeda, T and Takeda, H (1995) Species-specific differences of pyrenoids in Chlorella (Chlorophyta). Journal of Phycology 31, 813818.Google Scholar
Katoh, K, Misawa, K, Kuma, K I and Miyata, T (2002) MAFFT: a novel method for rapid multiple sequence alignment based on fast Fourier transform. Nucleic Acids Research 30, 30593066.CrossRefGoogle ScholarPubMed
Li, S, Tan, H, Liu, B, Zhu, H, Hu, Z and Liu, G (2021) Watanabeales ord. nov. and twelve novel species of Trebouxiophyceae (Chlorophyta). Journal of Phycology 57, 11671186.CrossRefGoogle ScholarPubMed
Lindgren, H, Moncada, B, Lücking, R, Magain, N, Simon, A, Goffinet, B, Sérusiaux, E, Nelsen, MP, Mercado-Díaz, JA, Widhelm, TJ, et al. (2020) Cophylogenetic patterns in algal symbionts correlate with repeated symbiont switches during diversification and geographic expansion of lichen-forming fungi in the genus Sticta (Ascomycota, Peltigeraceae). Molecular Phylogenetics and Evolution 150, 106860.Google Scholar
Lücking, R (2001) Lichens on leaves in tropical rainforests: life in a permanently ephemerous environment. Dissertationes Botanicae 346, 4177.Google Scholar
Lücking, R (2008) Foliicolous lichenized fungi. Flora Neotropica Monograph 103, 1866.Google Scholar
Ma, S, Huss, VAR, Tan, D, Sun, X, Chun, J, Xie, Y and Zhang, J (2013) A novel species in the genus Heveochlorella (Trebouxiophyceae, Chlorophyta) witnesses the evolution from an epiphytic into an endophytic lifestyle in tree-dwelling green algae. European Journal of Phycology 48, 200209.CrossRefGoogle Scholar
Manhart, JR (1994) Phylogenetic analysis of green plant rbcL sequences. Molecular Phylogenetics and Evolution 3, 114127.Google Scholar
Metz, S, Singer, D, Domaizon, I, Unrein, F and Lara, E (2019) Global distribution of Trebouxiophyceae diversity explored by high-throughput sequencing and phylogenetic approaches. Environmental Microbiology 21, 38853895.Google Scholar
Meyer, M, Whittaker, C and Griffiths, H (2017) The algal pyrenoid: key unanswered questions. Journal of Experimental Botany 68, 37393749.Google Scholar
Muggia, L, Pérez-Ortega, S, Kopun, T, Zellnig, G and Grube, M (2014) Photobiont selectivity leads to ecological tolerance and evolutionary divergence in a polymorphic complex of lichenized fungi. Annals of Botany 114, 463475.CrossRefGoogle Scholar
Neustupa, J, Němcová, Y, Eliáš, M and Škaloud, P (2009) Kalinella bambusicola gen. et sp. nov. (Trebouxiophyceae, Chlorophyta), a novel coccoid Chlorella-like subaerial alga from Southeast Asia. Phycological Research 57, 159169.Google Scholar
Osyczka, P, Lenart-Boroń, A, Boroń, P and Rola, K (2021) Lichen-forming fungi in postindustrial habitats involve alternative photobionts. Mycologia 113, 4355.CrossRefGoogle ScholarPubMed
Palmqvist, K, de los Ríos, A, Ascaso, C and Samuelsson, G (1997) Photosynthetic carbon acquisition in the lichen phycobionts Coccomyxa and Trebouxia (Chlorophyta). Physiologia Plantarum 101, 6776.CrossRefGoogle Scholar
Park, CH, Kim, KM, Elvebakk, A, Kim, O-S, Jeong, G and Hong, SG (2015) Algal and fungal diversity in Antarctic lichens. Journal of Eukaryotic Microbiology 62, 196205.Google Scholar
Peršoh, D, Beck, A and Rambold, G (2004) The distribution of ascus types and photobiontal selection in Lecanoromycetes (Ascomycota) against the background of a revised SSU nrDNA phylogeny. Mycological Progress 3, 103121.Google Scholar
Piercey-Normore, MD (2006) The lichen-forming ascomycete Evernia mesomorpha associates with multiple genotypes of Trebouxia jamesii. New Phytologist 169, 331344.Google Scholar
Ruprecht, U, Brunauer, G and Türk, R (2014) High phycobiont diversity in the common European soil crust lichen Psora decipiens. Biodiversity and Conservation 23, 17711785.Google Scholar
Sanders, WB (2014) Complete life cycle of the lichen fungus Calopadia puiggarii (Pilocarpaceae, Ascomycetes) documented in situ: propagule dispersal, establishment of symbiosis, thallus development, and formation of sexual and asexual reproductive structures. American Journal of Botany 101, 18361848.Google Scholar
Sanders, WB and Masumoto, H (2021) Lichen algae: the photosynthetic partners in lichen symbioses. Lichenologist 53, 347393.CrossRefGoogle Scholar
Sanders, WB, Pérez-Ortega, S, Nelsen, MP, Lücking, R and de los Ríos, A (2016) Heveochlorella (Trebouxiophyceae): a little-known genus of unicellular green algae outside the Trebouxiales emerges unexpectedly as a major clade of lichen phycobionts in foliicolous communities. Journal of Phycology 52, 840853.CrossRefGoogle Scholar
Santesson, R (1952) Foliicolous lichens I. Symbolae Botanicae Upsaliensis 12, 1590.Google Scholar
Škaloud, P, Friedl, T, Hallmann, C, Beck, A and Dal, Grande F (2016) Taxonomic revision and species delimitation of coccoid green algae currently assigned to the genus Dictyochloropsis (Trebouxiophyceae, Chlorophyta). Journal of Phycology 52, 599617.Google Scholar
Stamatakis, A (2014) RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics 30, 13121313.CrossRefGoogle ScholarPubMed
Thüs, H, Muggia, L, Pérez-Ortega, S, Favero-Longo, SE, Joneson, S, O'Brien, H, Nelsen, MP, Duque-Thüs, R, Grube, M, Friedl, T, et al. (2011) Revisiting phycobiont diversity in the lichen family Verrucariaceae (Ascomycota). European Journal of Phycology 46, 399415.Google Scholar
Tschermak-Woess, E (1988) The algal partner. In Galun, M (ed.), CRC Handbook of Lichenology. Bca Raton, Florida: CRC Press, pp. 3992.Google Scholar
van den Boom, PPG (2020) Foliicolous lichens and their lichenicolous fungi in Macaronesia and Atlantic Europe. Bibliotheca Lichenologica 111, 1197.Google Scholar
Vančurová, L, Muggia, L, Peksa, O, Řídká, T and Škaloud, P (2018) The complexity of symbiotic interactions influences the ecological amplitude of the host: a case study in Stereocaulon (lichenized Ascomycota). Molecular Ecology 27, 30163033.CrossRefGoogle Scholar
Verbruggen, H, Ashworth, M, LoDuca, ST, Vlaeminck, C, Cocquyt, E, Sauvage, T, Zechman, FW, Littler, DS, Littler, MM, Leliaert, F, et al. (2009) A multi-locus time-calibrated phylogeny of the siphonous green algae. Molecular Phylogenetics and Evolution 50, 642653.CrossRefGoogle ScholarPubMed
Voytsekhovich, A and Beck, A (2016) Lichen phycobionts of the rocky outcrops of Karadag massif (Crimean Peninsula). Symbiosis 68, 924.CrossRefGoogle Scholar
Zhang, J, Huss, VAR, Sun, X, Chang, K and Pang, D (2008) Morphology and phylogenetic position of a trebouxiophycean green alga (Chlorophyta) growing on the rubber tree, Hevea brasiliensis, with the description of a new genus and species. European Journal of Phycology 43, 185193.CrossRefGoogle Scholar
Zhu, H, Li, S, Hu, Z and Liu, G (2018) Molecular characterization of eukaryotic algal communities in the tropical phyllosphere based on real-time sequencing of the 18S rDNA gene. BMC Plant Biology 18, 365.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. TEM images of pyrenoid of phycobiont associated with two foliicolous lichens from Navarra. Arrow indicates sinuous thylakoid traversing the pyrenoid; p = pyrenoglobule. A & B, Byssoloma subdiscordans. C & D, Fellhanera bouteillei. Scales: A = 1 μm; B–D = 250 nm.

Figure 1

Figure 2. TEM images of pyrenoid of phycobiont associated with three foliicolous lichens from Tenerife. A, Bacidina apiahica; arrow = thylakoid penetrating pyrenoid; p = pyrenoglobule. B & C, Byssoloma subdiscordans; f = contacting fungal cell. D, Fellhanera bouteillei. Scales: A = 100 nm; B = 1 μm; C & D = 250 nm.

Figure 2

Figure 3. A–D, TEM images of phycobiont within the thallus of Tapellaria epiphylla from Tenerife. Arrows indicate continuity of pyrenoid-penetrating thylakoids with stacked thylakoids outside pyrenoid; a = algal symbiont; f = fungal symbiont; p = plastoglobule; s = starch. Scales: A = 1 μm; B = 500 nm; C & D = 250 nm.

Figure 3

Figure 4. TEM images of phycobiont pyrenoids in Gyalectidium. A & B, G. setiferum (Navarra). C & D, G. minus (Tenerife). B, tubule arising from outer membranes of thylakoid stack (arrowed); p = pyrenoglobule. Scales: A = 500 nm; B & D = 100 nm; C = 250 nm.

Figure 4

Figure 5. TEM images of phycobiont within the thallus of Byssoloma leucoblepharum. A, alga with contacting mycobiont cells. B & C, diffuse pyrenoidal areas with pyrenoglobuli. Scales: A = 500 nm; B & C = 250 nm.

Figure 5

Figure 6. A & B, TEM images of phycobiont within the thallus of Byssoloma kakouettae (Tenerife), showing diffuse pyrenoidal areas. C & D, TEM images of pyrenoid in alga isolated into culture from the thallus of Byssoloma kakouettae (Tenerife). C, with numerous electron-dense pyrenoglobuli and some starch deposits at periphery. D, with large starch deposits and few pyrenoglobuli at periphery; p = pyrenoglobule; s = starch. Scales: A = 1 μm; B–D = 500 nm.

Figure 6

Figure 7. Most-likely tree inferred by maximum likelihood (ML) analysis of the rbcL region, showing the relationships of photobionts of the studied foliicolous species with members of the Watanabeales. Thick branches indicate nodes with bootstrap values ≥ 70%. Locality: (N) = Navarra; (T) = Tenerife.

Figure 7

Figure 8. Most-likely tree inferred by maximum likelihood (ML) analysis of the nrSSU region, showing the relationships of photobionts of the studied foliicolous species with members of the Trebouxiophyceae. Thick branches indicate nodes with phylogenetic support in both analyses (bootstrap values ≥ 70% and posterior probability ≥ 0.95). Locality: (N ) = Navarra; (T) = Tenerife.

Figure 8

Table 1. GenBank Accession numbers corresponding to the rbcL and nrSSU sequences obtained during this study. Locality: N = Navarra; T = Tenerife. Culture: Y = Yes; N = No.

Figure 9

Table 2. A comparison of pyrenoid characteristics of Heveochlorella and Chloroidium strains.

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