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‘Forest Moss’: no part of the European Neanderthal diet

Published online by Cambridge University Press:  20 September 2017

James H. Dickson ,
Klaus Oeggl  and
Daniel Stanton
James H. Dickson*
Affiliation:
School of Biology, University of Glasgow, Glasgow G12 8QQ, UK
Klaus Oeggl
Affiliation:
Institut für Botanik, University of Innsbruck, Sternwartestrasse 15, Innsbruck 6020, Austria
Daniel Stanton
Affiliation:
Department of Ecology, Evolution and Behavior, University of Minnesota-Twin Cities, Saint Paul, MN 55108, USA
*
*Author for correspondence (Email: prof.j.h.dickson@gmail.com)
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In recent years, the study of Palaeolithic people has been a vigorous, productive topic, with the increasing knowledge of diet contributing significantly to the debate's liveliness (e.g. Richards 2009; Henry et al. 2010; Hardy et al. 2012, 2016; El Zaatari et al. 2016).

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Antiquity , Volume 91 , Issue 359 , October 2017 , e3
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Copyright © Antiquity Publications Ltd, 2017 

In recent years, the study of Palaeolithic people has been a vigorous, productive topic, with the increasing knowledge of diet contributing significantly to the debate's liveliness (e.g. Richards Reference Saatkamp, Guyon and Philippe2009; Henry et al. Reference Henry, Brooks and Piperno2010; Hardy et al. Reference Hardy, Buckley, Collins, Estalrrich, Brothwell, Copeland, García-Taberno, García-Vargas, de la Rasilla, Lalueza-Fox, Huguet, Bastir, Santamaría, Madella, Wilson, Fernández Cortés and Rosas2012, Reference Hardy, Buckley and Huffman2016; El Zaatari et al. Reference El Zaatari, Grine, Ungar and Hublin2016).

While Weyrich et al. (Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017) present an exciting insight into prehistoric diet through their application of shotgun sequencing and metagenomic analysis, they also betray some striking limitations of those same techniques, to the point of over interpretation. Even in this age of increasing availability of whole genomes, many taxonomic groups are vastly undersampled, and identifying organisms based on short fragments of DNA is still fraught with false attributions. These should not be fatal when used with considerable caution to identify broader clades, but are deeply misleading when combined with unwarranted speculation. The latter is the case with the claims advanced by Weyrich et al. (Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017) concerning the plant and fungal components of the Neanderthal diet. Based on their genomic data from Neanderthal calculus, these Eurasian late Pleistocene hominins show a high variety in nutritional habits. According to Weyrich et al. (Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017), in north-western Europe, the Neanderthal diet relied strongly on meat (e.g. woolly rhinoceros, wild sheep), whereas in southern Europe, they fed only on plants and fungi (e.g. mushroom, pine nuts, mosses). Upon closer inspection of the species list, however, hardly any of the taxa identified through metagenomics are plausible dietary candidates. They are instead often model organisms that have been speculatively linked to misleadingly detailed dietary claims. Pinus koraiensis, although a source of possible edible ‘pine nuts’, is endemic to East Asia. Schizophyllum commune is not, itself, considered an ‘edible mushroom’, being of the consistency of cardboard. In both of these cases, however, one can at least suggest plausible dietary items that might be phylogenetically somewhat close, even if this still requires unacknowledged speculation. Yet more problematic is the purported consumption of ‘forest moss’, which is a concocted name.

The ‘forest moss’ in question is Physcomitrella patens (Hedw.)Bruch & Schimp. (Figure 1). An accepted common name for this is Spreading Earth-moss. It is a moss with no special connection to woodlands, and so the common name used by Weyrich et al. is inappropriate, misleading and tendentious. Its usual habitat is the mud at the edges of pools and rivers, and in muddy fields. It is a very small moss, reaching a mere 2.5mm or so; for that reason, it is a very improbable food source.

Figure 1. Physcomitrella patens is a diminutive moss only a few millimetres in length, and is unknown in archaeological contexts; Knivista, Sweden (photographs by Michael Lüth and Tomas Hallingbäck).

Regarding plant diet, humankind depends totally on flowering plants (seeds, fruits, stems, leaves, tubers) as staples. Also consumed to greater or lesser extent are algae (seaweeds), ferns (rhizomes, young fronds), conifers (seeds) and even cycads (tubers and stem starch). Mosses are conspicuous absentees from this list. The authors know of no evidence from anywhere in the world at any time, present, recent or distant past, which shows that mosses are or have been used as food on a regular basis. Mosses are not staples, and a good reason that they are not consumed as food (except in the most minor ways) is that they are neither palatable nor nutritious. There is very little early ethnographical literature mentioning the use of mosses as food, although there are slight indications of the use of mosses as famine food (Glime Reference Glime2006). There is also only slight evidence for mosses being used as internal medical treatments, but never in the case of Physcomitrella patens. By contrast, the use of the Sphagnum (Bogmoss; Figure 2) species as wound dressings is well documented. The Tyrolean Iceman, for example, had a badly cut right palm (Dickson et al. Reference Dickson, Hofbauer, Porley, Schmidl, Kofler and Oeggl2009; Dickson Reference Dickson2011). The two tiny pieces of Sphagnum recovered from the alimentary tract have been interpreted as accidental ingestions, remnants of the dressing adhering to bloody fingers.

Figure 2. Up to many centimetres in length, Sphagnum palustre is a bogmoss known from two Bronze Age cists in Britain (photograph by J.H.D.).

There are many instances of mosses recovered from both historic and prehistoric European archaeological sites, but never from contexts unequivocally indicative of their consumption as food (Dickson Reference Dickson1973, Reference Dickson2011; Frahm & Wiethold Reference Frahm and Wiethold2004). No remains of mosses have ever been recovered from the numerous Palaeolithic occupation sites excavated in Europe. At such sites (often comprising caves in limestone cliffs), the usually sparse macroscopic plant remains are carbonised. Little organic material survives, other than bone and charcoal—the latter of which often survives in very small pieces. Being mainly thin plants with little or no hard tissue, mosses rarely carbonise. While there can be little doubt that Palaeolithic people used mosses (for whatever purposes they may have had), there is no current proof of any use.

Mosses recovered from archaeological contexts of whatever period are overwhelmingly large species—at least several centimetres in length such as Hylocomium splendens (Figure 3)—gathered for purposes such as caulking, packing, wrapping, insulation or hygienic wiping (Harris Reference Harris2008; Dickson Reference Dickson2011; Saatkamp et al. Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2011). Small mosses do occur but always very sparsely; this indicates not deliberate collection but accidental gathering among the larger species. Physcomitrella patens has never been found as a macrofossil. That such a species could have been a food plant comes as a completely unexpected surprise to the bryologist or ethnobotanist. It seems odd that the tiny Physcomitrella patens—being that very moss with the most studied genome—should appear in Neanderthal dental calculus.

Figure 3. Frequently 100mm or more in length, Hylocomium splendens is often recovered from archaeological contexts (photograph by J.H.D.).

The presence of moss in dental calculus does not prove deliberate ingestion as food, but only the presence of the moss in the mouth. There are potentially crucial problems, which must be considered, such as contamination and taphonomy, also demonstrated by Birks and Birks (Reference Birks and Birks2015) in assessing DNA data. The moss DNA was not only in El Sidrón I, but also in Spy I from Belgium—yet Weyrich et al. (Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017: 359) dismiss that as “probably the results of contamination”. Even the very presence of fragments of mosses in the human gut does not necessarily prove their ingestion as food. The sparse submicroscopic fragments of several mosses—mainly Neckera complanata (Figure 4)—recovered from the intestines of the Tyrolean Iceman, has been interpreted as remnants of food wrapping (Dickson Reference Dickson, Bortenschlager and Oeggl2000, Reference Dickson2011).

Figure 4. Up to several centimetres or more in length, Neckera complanata is often found in archaeological contexts (photograph by J.H.D.).

The recognition of moss DNA in the dental calculus is one thing, but deduction about the plant's significance in the diet is another. No quantification is possible and therefore the statement that “dietary components” included “moss” (Weyrich et al. Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017: 357) is not justifiable. The work of Weyrich et al. (Reference Weyrich, Duchene, Soubrier, Arriola, Llamas, Breen, Morris, Alt, Caramelli, Dresely, Farrell, Farrer, Francken, Gully, Haak, Hardy, Harvati, Held, Holmes, Kaidonis, Lalueza-Fox, de la Rasilla, Rosas, Semal, Soltysiak, Townsend, Usai, Wahl, Hudson, Dobney and Cooper2017) does not show that Neanderthals ate moss in whatever quantity—if any.

This criticism is not intended to undermine the impressive capabilities of the methods used, but rather to insist that these do not replace the need for due caution and for applying taxonomic and ecological expertise.

References

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Figure 0

Figure 1. Physcomitrella patens is a diminutive moss only a few millimetres in length, and is unknown in archaeological contexts; Knivista, Sweden (photographs by Michael Lüth and Tomas Hallingbäck).

Figure 1

Figure 2. Up to many centimetres in length, Sphagnum palustre is a bogmoss known from two Bronze Age cists in Britain (photograph by J.H.D.).

Figure 2

Figure 3. Frequently 100mm or more in length, Hylocomium splendens is often recovered from archaeological contexts (photograph by J.H.D.).

Figure 3

Figure 4. Up to several centimetres or more in length, Neckera complanata is often found in archaeological contexts (photograph by J.H.D.).