Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-27T17:23:19.510Z Has data issue: false hasContentIssue false

Cooking in caves: Palaeolithic carbonised plant food remains from Franchthi and Shanidar

Published online by Cambridge University Press:  23 November 2022

Ceren Kabukcu*
Affiliation:
Department of Archaeology, Classics and Egyptology, University of Liverpool, UK
Chris Hunt
Affiliation:
Research Centre in Evolutionary Anthropology and Palaeoecology, Liverpool John Moores University, UK
Evan Hill
Affiliation:
School of Natural and Built Environment, Queen's University Belfast, UK
Emma Pomeroy
Affiliation:
Department of Archaeology, University of Cambridge, UK
Tim Reynolds
Affiliation:
Department of History, Classics and Archaeology, Birkbeck University of London, UK
Graeme Barker
Affiliation:
Department of Archaeology, University of Cambridge, UK
Eleni Asouti
Affiliation:
Department of Archaeology, Classics and Egyptology, University of Liverpool, UK
*
*Author for correspondence ✉ [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Research on Palaeolithic hunter-gatherer diet has focused on the consumption of animals. Evidence for the use of plant foods is comparatively limited but is rapidly expanding. The authors present an analysis of carbonised macro-remains of processed plants from Franchthi Cave in the Aegean Basin and Shanidar Cave in the north-west Zagros Mountains. Microscopic examination of the charred food remains reveals the use of pounded pulses as a common ingredient in cooked plant foods. The results are discussed in the context of the regional archaeobotanical literature, leading the authors to argue that plants with bitter and astringent tastes were key ingredients of Palaeolithic cuisines in South-west Asia and the Eastern Mediterranean.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of Antiquity Publications Ltd

Introduction

The dietary choices and food preparation technologies of Palaeolithic hunter-gatherers are the subject of much debate. Palaeolithic peoples have been portrayed, for example, as specialist hunters focusing on large mammals (Richards & Trinkhaus Reference Richards and Trinkaus2009) or as generalist foragers targeting easy-to-gather resources out of necessity, due to pressures on the availability of preferred animal prey (Stiner et al. Reference Stiner, Munro and Surovell2000; Speth Reference Speth2010). In this article, we focus on the dietary contribution of plant foods. In a calorie-driven interpretation of Palaeolithic diet, plants are categorised as ‘low-ranked’ resources, due to the time- and labour-intensive nature of gathering and processing them. Consequently, scholarly emphasis has focused on the significance of the more carbohydrate-rich plant foods that were easy to collect and prepare as potential dietary staples (Prado-Nóvoa et al. Reference Prado-Nóvoa2017; Hardy et al. Reference Hardy, Bocherens, Miller and Copeland2022).

Archaeobotanical data from pre-agricultural sites in South-west Asia and the Eastern Mediterranean, however, indicate a reliance on a much wider range of plant foods than just starch-rich tubers and grasses (e.g. Martinoli Reference Martinoli2004; Weiss et al. Reference Weiss, Kislev, Simchoni and Nadel2004; Lev et al. Reference Lev, Kislev and Bar-Yosef2005; Asouti et al. Reference Asouti, Ntinou and Kabukcu2018, Reference Asouti2020; Caracuta et al. Reference Caracuta2021). Almost all sites from these regions dating to the Middle and Upper Palaeolithic and the Epipalaeolithic/Mesolithic periods, for example, provide evidence for the use of wild almonds, which contain high levels of cyanogenic metabolites that can produce hydrogen cyanide (Asouti et al. Reference Asouti2020; Caracuta et al. Reference Caracuta2021). Several other plants also feature prominently in the regional archaeobotanical record, including tannin-rich wild pistachios (terebinth), wild pulses (some containing neuro-toxic compounds) and astringent wild mustards. Most of these plants require several preparation steps to leach out unpalatable and/or toxic compounds prior to consumption. The long-term and widespread use of almonds, terebinths and pulses therefore suggests that Palaeolithic foragers developed processing technologies and associated food preparation practices that enabled their routine safe consumption.

In this article, we report new evidence concerning the long-term histories of Palaeolithic plant food use and associated food preparation practices from two multi-period sites: Franchthi Cave (Greece) and Shanidar Cave (Iraqi Kurdistan). We focus on the analysis of amorphous, charred plant aggregates retrieved from flotation samples from the two sites; some of these materials represent the earliest remains of their kind discovered to date in South-west Asia and Europe. Such remains, often representing the charred residues of food preparation (hereafter ‘food remains’), can provide direct evidence for the plant species consumed, often combined in multi-component foods, as well as preparation methods (Carretero et al. Reference Carretero, Wollstonecroft and Fuller2017; Heiss et al. Reference Heiss2017; Arranz-Otaegui et al. Reference Arranz-Otaegui2018; Valamoti et al. Reference Valamoti2021). Our results highlight the early exploitation of a diverse range of plant foods that required specialised processing techniques, bringing to the fore the significance of food preparation and cooking practices in ancient human dietary practices.

Materials and methods

Franchthi Cave is located in the Argolid peninsula of southern mainland Greece. It was excavated between 1969 and 1976 by T.W. Jacobsen of Indiana University and M.H. Jameson of Pennsylvania University, under the auspices of the American School of Classical Studies in Athens and in collaboration with the Greek Archaeological Service (Farrand Reference Farrand2000). Occupation at the site spans the Upper and Final Palaeolithic, Mesolithic and Neolithic (c. 38 000–6000 cal BP) (Farrand Reference Farrand2000; Asouti et al. Reference Asouti, Ntinou and Kabukcu2018). Sampling for archaeobotanical remains was carried out by machine-assisted water flotation. The non-wood charred plant macro-remains were previously studied and published by Julie Hansen (Reference Hansen1991). The presence of charred, amorphous plant aggregates that potentially represent food remains was noticed during anthracological analyses conducted by Eleni Asouti and Ceren Kabukcu at the University of Liverpool in 2017 (Asouti et al. Reference Asouti, Ntinou and Kabukcu2018). The four charred plant aggregates from Franchthi Cave examined here originate from two chrono-cultural phases: stratum T3, which is assigned to the later phases of the Upper Palaeolithic (Mediterranean Gravettian), corresponding to the Bølling-Allerød warm period (Franchthi General Phase (FGP) V, c. 13 100–12 900 cal BP), and the Final Palaeolithic (Epigravettian) strata, which are dated to the Younger Dryas (FGP VI, c. 12 900–11 700 cal BP) and the start of the Holocene (FGP VI/VII, c. 11 700–11 400 cal BP) (Hansen Reference Hansen1991; Farrand Reference Farrand2000; Asouti et al. Reference Asouti, Ntinou and Kabukcu2018) (Table 1).

Table 1. Summary of provenance, phasing and corresponding radiometric dates for the analysed food fragments.

Shanidar Cave, located on the western flanks of the Zagros Mountains of Iraqi Kurdistan, was originally excavated between 1951 and 1960 by Ralph and Rose Solecki of Columbia University and colleagues (Solecki Reference Solecki1971). Since 2015, a team led by Graeme Barker has conducted systematic excavations at the site (Reynolds et al. Reference Reynolds2015), during which the fragments analysed in this study were collected. Five charred plant aggregates were recovered from Upper Palaeolithic (Baradostian) and one further fragment from the Middle Palaeolithic (Mousterian) deposits. Although the full radiometric dating programme is ongoing, the Baradostian strata date to c. 42 000–35 000 years ago (Reynolds et al. Reference Reynolds2018), which corresponds to the later part of Marine Isotope Stage 3 (MIS 3). Regionally, the Baradostian techno-cultural industry is interpreted as coeval with the Aurignacian of the European Upper Palaeolithic, which is associated with Homo sapiens (Reynolds et al. Reference Reynolds2018; Shidrang Reference Shidrang, Nishiaki and Akazawa2018). In Iran, the Baradostian industry has been associated with anatomically modern humans at the cave site of Eshkaft-e Gavi (Scott & Marean Reference Scott and Marean2009), where it has been dated to c. 42 000–30 000 years ago—somewhat later than the Baradostian assemblage of Kaldar Cave, which is dated to 54 400–46 050 cal BP (Bazgir et al. Reference Bazgir2017). Meanwhile, the samples recovered from the Mousterian strata at Shanidar Cave probably date to >70 000–75 000 years ago, based on their broad stratigraphic association with the well-known Neanderthal ‘flower burial’ and the recently discovered ‘Shanidar Z’ articulated skeletal remains, dated to c. 73 000 BP (Pomeroy et al. Reference Pomeroy2017, Reference Pomeroy2020).

Charred plant aggregates may take the form of large, recognisable items of food (Heiss et al. Reference Heiss2017), carbonised crusts adhering to the walls of pottery vessels (Kubiak-Martens et al. Reference Kubiak-Martens, Brinkkemper and Oudemans2015) or amorphous lumps, some of which could represent accidentally charred food remains (Valamoti et al. Reference Valamoti2021; Bates et al. Reference Bates, Black and Morrison2022); microscopic examination is required to confirm their interpretation as food remains and to identify their plant components. The charred amorphous plant aggregates recovered at Franchthi and Shanidar were sorted using a Leica S8 APO stereo-zoom microscope (magnification ×7–80). Under the stereo-zoom microscope, the fragments under study here appeared as discrete, non-friable masses, sometimes with visible seed fragment inclusions.

As carbonised dung is frequently found in archaeobotanical samples, it was important to exclude the possibility that the charred, amorphous plant aggregates might be faecal remains. During microscopic examination, charred dung fragments often appear fibrous, with matted/layered stems included in a dense matrix that often contains spherulites (Smith et al. Reference Smith, Proctor, Hart and Stein2019; Bates et al. Reference Bates, Black and Morrison2022). None of the Franchthi and Shanidar fragments contain spherulites, or inclusions of grass stems and leaf fragments and we therefore interpret these amorphous plant aggregates as likely food remains. In addition, they mostly contain fragments of seeds and grain-derived plant cells, and are irregular in form and porous in texture, with voids and cracks of variable sizes. Similar items, interpreted as carbonised food remains and matched by experimentally reproduced examples, have previously been reported in recent archaeobotanical literature (Carretero et al. Reference Carretero, Wollstonecroft and Fuller2017; Valamoti et al. Reference Valamoti2021; Bates et al. Reference Bates, Black and Morrison2022).

All of the charred food remains were further examined under a Meiji MT6500 darkfield/brightfield incident light microscope (magnification ×50–500) and subsequently mounted on SEM aluminium stubs and gold sputter coated (to a thickness of 20nμ) to allow for more detailed observation (following established analytical protocols: Carretero et al. Reference Carretero, Wollstonecroft and Fuller2017; Heiss et al. Reference Heiss2017; Valamoti et al. Reference Valamoti2021). Identification of plant constituents, including specific plant cell types and patterns, made use of the published literature on plant cell identification, including comprehensive guides on specific genera and families, and comparisons to modern specimens held in the University of Liverpool Archaeobotany Laboratory plant reference collection.

Results

Franchthi Cave

Four charred food fragments, recovered from four flotation samples from Franchthi Cave, were analysed. Three of these contain fused pulse seed, seed coat and other tissue fragments such as macrosclereids, set in a fully or partially gelatinised matrix (Figures 1–3). There is evidence for starch and protein cell deformation, alongside areas of vitrification most commonly associated with the effects of soaking and heating. The smooth edges of the seed fragments embedded in the charred matrix indicate fragmentation before carbonisation. The seed fragment sizes are generally variable and might indicate coarse grinding and/or pounding (as opposed to finely ground flour-like mixtures). The formation of the gelatinised matrix around the fragments of the seeds with adhering seed coats further suggests that preparation of the food item might have started with soaking whole dry seeds, or with the use of fresh seeds that had a high moisture content. The interpretation of pounding prior to charring, as indicated by the smooth edges of the seed fragments and their variable sizes, is based on recent experimental and archaeobotanical research on cereal food preparations, which has established criteria for detecting this sequence of events (Valamoti et al. Reference Valamoti2021). Further experimental work focusing on pulse processing, including grinding, mashing and soaking, is needed to provide additional reference data for the interpretation of pulse-rich archaeological food remains. The food fragments (Figures 1–3) also contain abundant remains of the papillose seed coat pattern and macrosclereid cells characteristic of the tribe Fabeae (limited to lentil, vetch and grass pea; Butler Reference Butler1990; see also Figures S1 & S2 in the online supplementary materials (OSM)). The food fragment in Figure 1D, for example, is sufficiently well preserved to permit the identification of bitter vetch (Vicia ervilia) (Butler Reference Butler1990: 493–95, pls 5–7; see also Figure S2). Our observations regarding the presence of pulse species are further supported by previous studies, which report the abundance of charred lentil, vetch and pea seeds in the archaeobotanical assemblage from Franchthi Cave (Hansen Reference Hansen1991; see also Asouti et al. Reference Asouti, Ntinou and Kabukcu2018).

Figure 1. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 167, Final Palaeolithic, Epigravettian): A) overview; B) close-up of pulse seed coat and seed fragment; C) close-up of pulse seed coat surface; D) view of Vicia ervilia seed coat papillose cells; E) close-up of pulse seed coat surface (SEM micrographs taken by C. Kabukcu).

Figure 2. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 168, Final Palaeolithic, Epigravettian): A) overview; B–D) close-ups of pulse seed fragments and seed coat remains (SEM micrographs taken by C. Kabukcu).

Figure 3. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 177, Upper Palaeolithic, Mediterranean Gravettian): A) overview; B–C) close-up of pulse seed fragments and seed coat (SEM micrographs taken by C. Kabukcu).

Unlike the food fragments described above, the fourth fragment of food remains is close-textured and lacks seed fragments, observable seed coat or epidermal cells (Figure 4). Its matrix contains voids and cracks of varying sizes, indicating a heat-affected, expanded starch-rich matrix. This structure strongly resembles experimental preparations and archaeobotanical examples of charred bread-like foods or finely ground cereal meals, such as those reported from various Neolithic and later prehistoric settlements (Valamoti et al. Reference Valamoti, Samuel, Bayram and Marinova2008; Carretero et al. Reference Carretero, Wollstonecroft and Fuller2017). Probably as a result of the advanced state of vitrification and gelatinisation, the food fragment does not preserve identifiable plant cells or other characteristic components that would permit identification of specific plant species. The presence of starch-rich plant food sources at Franchthi Cave, however, is well established, including grasses (oats and barley) and nuts (almonds and Pistacia) documented in the archaeobotanical assemblage (Hansen Reference Hansen1991; Asouti et al. Reference Asouti, Ntinou and Kabukcu2018).

Figure 4. Charred plant food remains from Franchthi Cave, with a homogenised matrix (context no. H1A 172, Upper Palaeolithic, Mediterranean Gravettian): A) overview; B) close-up showing variable sizes of voids (SEM micrographs taken by C. Kabukcu).

Shanidar Cave

Five charred food fragments from the Upper Palaeolithic (Baradostian) layers at Shanidar Cave were analysed in detail (Figures 5–9). All contain crushed and fused remains of pulses, including of the genera Lathyrus and Pisum. The mounded-papillose seed coat pattern (Figure 3C–D) is frequently observed in medium-sized Lathyrus species (Butler Reference Butler1990). The height of the macrosclereids suggests that they probably belong to L. cassius, L. hirsutus or L. nissolia (Butler Reference Butler1990: 550–51, pls 62–63; Güneş Reference Güneş2013; see also Figure S3).

Figure 5. Pulse-rich charred plant food remains from Shanidar Cave (context no. 1812, Upper Palaeolithic, Baradostian): A) overview; B–D) close-up of pulse seed coat surface and mounded-papillose seed coat pattern of Lathyrus sp. (likely Lathyrus cassius, L. hirsutus or L. nissolia) (SEM micrographs taken by C. Kabukcu).

Figure 6. Charred plant food fragment from Shanidar Cave (context no. 1866, Upper Palaeolithic, Initial Baradostian): A) overview; B–C) close-up of wild pea (Pisum fulvum or P. sativum subsp. elatius) seed coat (SEM micrographs taken by C. Kabukcu).

Figure 7. Charred plant food remains from Shanidar Cave (context no. 1823, Upper Palaeolithic, Baradostian) containing wild mustard: A) overview; B–C) close-up of mustard seed fragment and seed coat pattern (SEM micrographs taken by C. Kabukcu).

Figure 8. Charred plant food remains from Shanidar Cave (context no. 1866, Upper Palaeolithic, Initial Baradostian): A) overview; B) & D) close-up of cf. Pistacia nutshell/pericarp remain; C) close-up of pulse seed coat pattern (Fabeae) (SEM micrographs taken by C. Kabukcu).

Figure 9. Charred plant food fragment from Shanidar Cave (context no. 636, Upper Palaeolithic, Baradostian): A) overview; B–D) close-up of cf. Pistacia nutshell/pericarp fragment (SEM micrographs taken by C. Kabukcu).

Based on the height of the macrosclereid layer and the mounded-papillose pattern, the food fragment shown in Figure 6B–C closely resembles pea (Pisum fulvum and P. sativum subsp. elatius) (Werker et al. Reference Werker, Marbach and Mayer1979; Zablatzká et al. Reference Zablatzká2021; see also Figure S4). Additionally, the fragments with well-preserved reticulate seed coats and globular-shaped cotyledons (e.g. Tantawy et al. Reference Tantawy, Khalifa, Hassan and Al-Rabiai2004; Gabr Reference Gabr2018) are probably wild mustards (Brassicaceae). Two of the charred food fragments also contain plant tissues resembling Pistacia nutshell and pericarp fragments; these appear heavily deformed, possibly due to the effects of food preparation and/or post-depositional taphonomic processes on the morphology of the plant tissues (see Figures 8B, 8D and 9C–D). SEM images of carbonised modern reference Pistacia specimens are included in the OSM (Figure S5).

The single fragment of charred food remain from a Mousterian layer at Shanidar Cave (Figure 10) contains pulse seed and seed coat fragments. Unlike the Baradostian food fragments, however, it also includes the long cells characteristic of grasses (Poaceae) (Figure 10D).

Figure 10. Charred plant food remains from Shanidar Cave containing pulses and grasses (context no. 1924, Middle Palaeolithic, Mousterian): A) overview; B–C) close-up of pulse seed coat and seed fragments; D) close-up of long cells of Poaceae seed (SEM micrographs taken by C. Kabukcu).

Discussion

The food remains from Upper/Final Palaeolithic strata at Franchthi Cave and Middle/Upper Palaeolithic strata at Shanidar Cave reported here currently represent the earliest direct macro-botanical evidence of Palaeolithic plant food processing in the Eastern Mediterranean and South-west Asia. They represent a significant addition to an accumulating body of archaeobotanical data from these regions that points to selective plant foraging by Palaeolithic hunter-gatherers. At Middle Palaeolithic Kebara Cave (Mount Carmel, Israel), for example, pulse seeds (vetches, grass pea and lentils) constitute the majority of the charred plant macrofossils (Lev et al. Reference Lev, Kislev and Bar-Yosef2005). The Epipalaeolithic occupation at El Wad (also in Mount Carmel) similarly contains an archaeobotanical assemblage dominated by pulses, with a significant proportion of vetches (Caracuta et al. Reference Caracuta2016). Epipalaeolithic Palegawra Cave (Iraqi Kurdistan) provides evidence for a more diverse range of foraged plants, including wild pulses, grasses, nuts, tubers and mustards (Asouti et al. Reference Asouti2020). In the Levantine Epipalaeolithic, there is also increasing evidence for the use of tubers (e.g. Shubayqa I, Jordan; Arranz-Otaegui et al. Reference Arranz-Otaegui2018) and mustards (e.g. Kharaneh IV, Jordan; Bode et al. Reference Bode, Livarda and Jones2022). The remarkably well-preserved assemblage from Ohalo II (Israel) also provides evidence for the use of wild grasses during this period (Weiss et al. Reference Weiss, Kislev, Simchoni and Nadel2004).

Other notable Epipalaeolithic sites in South-west Asia from which archaeobotanical data are available, including the Karain and Öküzini Caves (Martinoli Reference Martinoli2004) and the Pınarbaşı rockshelter (Baird et al. Reference Baird2013) in Anatolia, demonstrate an emphasis on nuts (almonds and terebinth), pulses and various wild fruits. The broadly contemporaneous occupation at Haua Fteah in north-east Libya similarly provides evidence for the use of pine nuts and wild vetches (Barker et al. Reference Barker2010). Several European Upper Palaeolithic sites attest to the use of wild grasses and tubers. At Klisoura 1 Cave in Peloponnese (Greece), phytolith and micromorphological data from Upper Palaeolithic clay-lined hearths indicate grass seed roasting (Karkanas et al. Reference Karkanas2004). Starch and ground stone use-wear data from the Gravettian occupation at Grotta Paglicci in southern Italy suggest the cooking and processing (grinding/crushing) of wild oats and the processing of tannin-rich oak acorns (Lippi et al. Reference Lippi2015). Similarly, starch and use-wear evidence on grinding stones from the Late Stone Age occupation at Haua Fteah, dated to c. 31 000 years ago, point to the regular processing of goat grass (Aegilops sp.) (Barton et al. Reference Barton2018).

Most of the carbonised food remains reported here contain variously sized fragments of pulse seeds, probably representing processing by coarse grinding, cracking and/or pounding. This type of preparation differs from the finer grinding required for flour and does not necessitate the use of flat grinding stones. It could have been undertaken using only percussive tools and/or perishable implements. Use-wear data from the Acheulian site of Gesher Benot Ya'aqov (Israel) point to the early use of stone tools for nut cracking and plant food preparation (Goren-Inbar et al. Reference Goren-Inbar, Sharon, Alperson-Afil and Herzlinger2015). In the Upper Palaeolithic starch-rich charred food fragment from Franchthi Cave (Figure 4), the absence of large particles and the high degree of homogenisation of the matrix suggest that the plants were processed via fine grinding and/or boiling and mashing. Similar charred plant aggregates comprising fine-ground starch plant tissue and occasionally no identifiable plant cells have also been reported from Epipalaeolithic, Mesolithic and Neolithic contexts in South-west Asia and Europe, and have been interpreted as ‘breads’ or ‘porridges’ (Kubiak-Martens et al. Reference Kubiak-Martens, Brinkkemper and Oudemans2015; Carretero et al. Reference Carretero, Wollstonecroft and Fuller2017; Arranz-Otaegui et al. Reference Arranz-Otaegui2018).

Pulse seeds, especially bitter vetch (Vicia ervilia) and grass pea (Lathyrus cassius, L. hirsutus and L. nissolia), contain notable quantities of alkaloids and tannins, resulting in a bitter and astringent taste. These compounds are concentrated in the seed coats. While cooking techniques, such as soaking and boiling, can remove a large portion of tannins and other bitter, astringent and toxic compounds (Ressler et al. Reference Ressler, Tatake, Kaizer and Putnam1997), hulling (the removal of the seed coat) would have been a far more efficient method. This technique is commonly practised today (Ressler et al. Reference Ressler, Tatake, Kaizer and Putnam1997), as well as in the past (Melamed et al. Reference Melamed, Plitmann and Kislev2008; Valamoti et al. Reference Valamoti, Moniaki and Karathanou2011), for processing vetches and grass pea. The soaking of wild pulses, as indicated by the Franchthi and Shanidar charred food fragments, would have enabled their safe consumption and improved their palatability by removing most of the bitter-tasting compounds. The presence of seed coat fragments, however, suggests that a low level of plant chemicals, including some tannins and alkaloids, may have been intentionally retained in plant food preparations. This evidence adds to an increasing body of archaeobotanical studies suggesting a persistent reliance on, and tolerance of, bitter- and astringent-tasting plant foods such as pulses, mustards, almonds and terebinths, from as early as the Middle Palaeolithic through to the later prehistoric periods. Beyond the Eastern Mediterranean and South-west Asia, archaeobotanical studies at sites such as Niah Cave (Sarawak, Borneo) have revealed evidence for the processing of the highly toxic Dioscorea (yam) and Pangium edule nuts from as early as 50 000 years ago, underscoring the complexity and deep ancestry of such food preparation practices (Barker et al. Reference Barker2007; Barton et al. Reference Barton, Paz, Carlos, Barker and Farr2016).

Apart from detoxification, food preparation practices such as soaking and pounding would also have improved the bioavailability of bulk nutrients. Multi-proxy data from Early Upper Palaeolithic sites in the Pontic steppe, derived from starch residue extraction, spectroscopic and spectrometric techniques, point to the processing by pounding of a diverse group of tubers, possibly with the aim of tenderising them for consumption (including some less commonly observed C4 carbon-fixing plant species; see Longo et al. Reference Longo2021). Other aspects of plant resource choice and use, including raw materials and medicinal uses, have also been highlighted with regard to Lower and Middle Palaeolithic foraging (Hardy et al. Reference Hardy2012, Reference Hardy, Bocherens, Miller and Copeland2022; Hardy Reference Hardy2018).

Conclusion

The evidence presented here supports previous hypotheses regarding the diversity and complexity of Palaeolithic plant use. It provides direct evidence for previously undocumented food preparation practices and brings into focus the diversity of specialised cooking practices developed by Middle and Upper Palaeolithic hunter-gatherers, which involved multiple preparation steps and different plant components (sensu Jones Reference Jones, Hublin and Richards2009). Our results reinforce current understanding that the use of plants in the Palaeolithic regularly relied on starch-rich tubers and grasses (Henry et al. Reference Henry, Brooks and Piperno2011; Hardy et al. Reference Hardy, Bocherens, Miller and Copeland2022) and further demonstrate that the labour-intensive processing of a broad spectrum of plant foods, including bitter, astringent and potentially toxic plants for human consumption, was an integral part of hunter-gatherer resource management strategies. The use of plant food preparation techniques was prevalent across the Eastern Mediterranean and South-west Asia from as early as the Middle Palaeolithic and appears to be independent of fluctuations in forage and prey ceilings due to climatic conditions (Hardy Reference Hardy2018; Power & Williams Reference Power and Williams2018). Crucially, our results demonstrate that food choices and preparation practices traditionally associated with the intensification of plant resource use that is linked to climatic amelioration at the Pleistocene–Holocene boundary and the origin of farming (Smith & Zeder Reference Smith and Zeder2013) clearly have a deep history that precedes the earliest evidence for plant cultivation by several tens of thousands of years.

Acknowledgements

C.K. designed the study, carried out the analysis and produced the original draft. All authors contributed to writing, review and editing of the final draft. E.A. provided access to the Franchthi Cave samples; E.H., C.H., E.P., T.R. and G.B. designed and carried out sampling for archaeobotanical remains at Shanidar Cave and provided access to the samples. We thank the Kurdistan Regional Government for inviting G.B. to plan and direct new excavations at Shanidar Cave, and the Kurdistan General Directorate of Antiquities for granting excavation permits and permission to analyse the finds. Additional modern plant reference materials were made available to C.K. by the USDA Agricultural Research Service, Plant Germplasm Introduction and Testing Unit.

Supplementary materials

To view supplementary material for this article, please visit https://doi.org/10.15184/aqy.2022.143.

Funding statement

C.K. acknowledges funding from the Leverhulme Trust (Early Career Fellowship, ECF–284); G.B., E.P., C.H. and T.R. acknowledge funding from the Leverhulme Trust (Research Grant RPG–2013–105), Rust Family Foundation, British Academy, Wenner-Gren Foundation, Society of Antiquaries, McDonald Institute of Archaeological Research at the University of Cambridge and Natural Environment Research Council's Oxford Radiocarbon Dating Facility (grant NF/2016/2/14).

Data statement

Archaeological and modern plant reference specimens are archived at the University of Liverpool Archaeobotany Laboratory, Department of Archaeology, Classics and Egyptology. All data are available in the main text and the OSM.

References

Arranz-Otaegui, A. et al. 2018. Archaeobotanical evidence reveals the origins of bread 14 400 years ago in northeastern Jordan. Proceedings of the National Academy of Sciences of the USA 115: 7925–30. https://doi.org/10.1073/pnas.1801071115CrossRefGoogle ScholarPubMed
Asouti, E., Ntinou, M. & Kabukcu, C.. 2018. The impact of environmental change on Palaeolithic and Mesolithic plant use and the transition to agriculture at Franchthi Cave, Greece. PLoS ONE 13: e0207805. https://doi.org/10.1371/journal.pone.0207805CrossRefGoogle ScholarPubMed
Asouti, E. et al. 2020. The Zagros Epipalaeolithic revisited: new excavations and 14C dates from Palegawra cave in Iraqi Kurdistan. PLoS ONE 15: e0239564. https://doi.org/10.1371/journal.pone.0239564CrossRefGoogle ScholarPubMed
Baird, D. et al. 2013. Juniper smoke, skulls and wolves’ tails: the Epipalaeolithic of the Anatolian plateau in its South-west Asian context: insights from Pınarbaşı. Levant 45: 175209. https://doi.org/10.1179/0075891413Z.00000000024CrossRefGoogle Scholar
Barker, G. et al. 2007. The ‘human revolution’ in lowland tropical Southeast Asia: the antiquity and behavior of anatomically modern humans at Niah Cave (Sarawak, Borneo). Journal of Human Evolution 52: 243–61. https://doi.org/10.1016/j.jhevol.2006.08.011CrossRefGoogle ScholarPubMed
Barker, G. et al. 2010. The Cyrenaican Prehistory Project 2010: the fourth season of investigations of the Haua Fteah cave and its landscape, and further results from the 2007–2009 fieldwork. Libyan Studies 41: 6388. https://doi.org/10.1017/S0263718900000273CrossRefGoogle Scholar
Barton, H., Paz, V. & Carlos, A.-J.. 2016. Plant food remains from the Niah Caves: macroscopic and microscopic approaches, in Barker, G. & Farr, L. (ed.) Archaeological investigations in the Niah Caves, Sarawak: volume 2: 455–68. Cambridge: McDonald Institute for Archaeological Research.Google Scholar
Barton, H. et al. 2018. Use of grass seed resources c. 31 ka by modern humans at the Haua Fteah cave, northeast Libya. Journal of Archaeological Science 99: 99111. https://doi.org/10.1016/j.jas.2018.08.013Google Scholar
Bates, J., Black, K. Wilcox & Morrison, K.D.. 2022. Millet bread and pulse dough from Early Iron Age south India: charred food lumps as culinary indicators. Journal of Archaeological Science 137: 105531. https://doi.org/10.1016/j.jas.2021.105531CrossRefGoogle Scholar
Bazgir, B. et al. 2017. Understanding the emergence of modern humans and the disappearance of Neanderthals: insights from Kaldar Cave (Khorramabad Valley, western Iran). Scientific Reports 7: 43460. https://doi.org/10.1038/srep43460CrossRefGoogle ScholarPubMed
Butler, E.A. 1990. Legumes in antiquity: a micromorphological investigation of seeds of the Vicieae. Unpublished PhD dissertation, University of London.Google Scholar
Bode, L.J.K., Livarda, A. & Jones, M.D.. 2022. Plant gathering and people-environment interactions at Epipalaeolithic Kharaneh IV, Jordan. Vegetation History and Archaeobotany 31: 8596. https://doi.org/10.1007/s00334-021-00839-wCrossRefGoogle Scholar
Caracuta, V. et al. 2016. 14 000-year-old seeds indicate the Levantine origin of the lost progenitor of faba bean. Scientific Reports 6: 37399. https://doi.org/10.1038/srep37399CrossRefGoogle ScholarPubMed
Caracuta, V. et al. 2021. The Marine Isotope Stage 3 landscape around Manot Cave (Israel) and the food habits of anatomically modern humans: new insights from the anthracological record and stable carbon isotope analysis of wild almond (Amygdalus sp.). Journal of Human Evolution 160: 102868. https://doi.org/10.1016/j.jhevol.2020.102868CrossRefGoogle ScholarPubMed
Carretero, L.G., Wollstonecroft, M. & Fuller, D.Q.. 2017. A methodological approach to the study of archaeological cereal meals: a case study at Çatalhöyük East (Turkey). Vegetation History and Archaeobotany 26: 415–32. https://doi.org/10.1007/s00334-017-0602-6CrossRefGoogle Scholar
Farrand, W.R. 2000. Depositional history of the Franchthi Cave: stratigraphy, sedimentology, and chronology. Bloomington: Indiana University Press.Google Scholar
Gabr, D.G. 2018. Significance of fruit and seed coat morphology in taxonomy and identification for some species of Brassicaceae. American Journal of Plant Sciences 9: 380402. https://doi.org/10.4236/ajps.2018.93030CrossRefGoogle Scholar
Goren-Inbar, N., Sharon, G., Alperson-Afil, N. & Herzlinger, G.. 2015. A new type of anvil in the Acheulian of Gesher Benot Ya‘aqov, Israel. Philosophical Transactions of the Royal Society B 370: 20140353. https://doi.org/10.1098/rstb.2014.0353CrossRefGoogle ScholarPubMed
Güneş, F. 2013. Seed characteristics and testa textures of Pratensis, Orobon, Lathyrus, Orobastrum and Cicercula sections from Lathyrus (Fabaceae) in Turkey. Plant Systematics and Evolution 299: 1935–53. http://doi.org/10.1007/s00606-013-0849-zCrossRefGoogle Scholar
Hansen, J.M. 1991. The palaeoethnobotany of Franchthi Cave. Bloomington: Indiana University Press.Google Scholar
Hardy, K. 2018. Plant use in the Lower and Middle Palaeolithic: food, medicine and raw materials. Quaternary Science Reviews 191: 393405. https://doi.org/10.1016/j.quascirev.2018.04.028CrossRefGoogle Scholar
Hardy, K. et al. 2012. Neanderthal medics? Evidence for food, cooking, and medicinal plants entrapped in dental calculus. Naturwissenschaften 99: 617–26. https://doi.org/10.1007/s00114-012-0942-0CrossRefGoogle ScholarPubMed
Hardy, K., Bocherens, H., Miller, J.B. & Copeland, L.. 2022. Reconstructing Neanderthal diet: the case for carbohydrates. Journal of Human Evolution 162: 103105. https://doi.org/10.1016/j.jhevol.2021.103105CrossRefGoogle ScholarPubMed
Heiss, A.G. et al. 2017. State of the (t)art: analytical approaches in the investigation of components and production traits of archaeological bread-like objects, applied to two finds from the Neolithic lakeshore settlement Parkhaus Opéra (Zurich, Switzerland). PLoS ONE 12: e0182401. https://doi.org/10.1371/journal.pone.0182401CrossRefGoogle ScholarPubMed
Henry, A.G., Brooks, A.S. & Piperno, D.R.. 2011. Microfossils in calculus demonstrate consumption of plants and cooked foods in Neanderthal diets (Shanidar III, Iraq; Spy I and II, Belgium). Proceedings of the National Academy of Sciences of the USA 108: 486–91. https://doi.org/10.1073/pnas.101686810CrossRefGoogle ScholarPubMed
Jones, M.K. 2009. Moving north: archaeobotanical evidence for plant diet in Middle and Upper Palaeolithic Europe, in Hublin, J.J. & Richards, M.P. (ed.) The evolution of hominin diets: 171–80. Dordrecht: Springer. https://doi.org/10.1007/978-1-4020-9699-0_12CrossRefGoogle Scholar
Karkanas, P. et al. 2004. The earliest evidence for clay hearths: Aurignacian features in Klisoura Cave 1, southern Greece. Antiquity 78: 513–25. https://doi.org/10.1017/S0003598X00113195CrossRefGoogle Scholar
Kubiak-Martens, L., Brinkkemper, O. & Oudemans, T.F.M.. 2015. What's for dinner? Processed food in the coastal area of the northern Netherlands in the Late Neolithic. Vegetation History and Archaeobotany 24: 4762. https://doi.org/10.1007/s00334-014-0485-8CrossRefGoogle Scholar
Lev, E., Kislev, M.E. & Bar-Yosef, O.. 2005. Mousterian vegetal food in Kebara Cave, Mt Carmel. Journal of Archaeological Science 32: 475–84. https://doi.org/10.1016/j.jas.2004.11.006CrossRefGoogle Scholar
Lippi, M.M. et al. 2015. Multistep food plant processing at Grotta Paglicci (southern Italy) around 32 600 cal BP. Proceedings of the National Academy of Sciences of the USA 112: 12080. https://doi.org/10.1073/pnas.1505213112Google Scholar
Longo, L. et al. 2021. A multi-dimensional approach to investigate use-related biogenic residues on Palaeolithic ground stone tools. Environmental Archaeology. First View. https://doi.org/10.1080/14614103.2021.1975252CrossRefGoogle Scholar
Martinoli, D. 2004. Food plant use, temporal changes and site seasonally at Epipalaeolithic Öküzini and Karain B caves. Paléorient 30: 6180. https://doi.org/10.3406/paleo.2004.1011CrossRefGoogle Scholar
Melamed, Y., Plitmann, U. & Kislev, M.E.. 2008. Vicia peregrina: an edible Early Neolithic legume. Vegetation History and Archaeobotany 17: 2934. https://doi.org/10.1007/s00334-008-0166-6CrossRefGoogle Scholar
Pomeroy, E. et al. 2017. Newly discovered Neanderthal remains from Shanidar Cave, Iraqi Kurdistan, and their attribution to Shanidar 5. Journal of Human Evolution 111: 102–18. https://doi.org/10.1016/j.jhevol.2017.07.001CrossRefGoogle ScholarPubMed
Pomeroy, E. et al. 2020. New Neanderthal remains associated with the ‘flower burial’ at Shanidar Cave. Antiquity 94: 1126. https://doi.org/10.15184/aqy.2019.207CrossRefGoogle Scholar
Power, R.C. & Williams, F.L.. 2018. Evidence of increasing intensity of food processing during the Upper Paleolithic of western Eurasia. Journal of Paleolithic Archaeology 1: 281301. https://doi.org/10.1007/s41982-018-0014-xCrossRefGoogle Scholar
Prado-Nóvoa, O. et al. 2017. Efficiency of gathering and its archaeological implications for a European Early Palaeolithic population. Journal of Anthropological Archaeology 45: 131–41. https://doi.org/10.1016/j.jaa.2016.12.002CrossRefGoogle Scholar
Reynolds, T. et al. 2015. New investigations at Shanidar Cave, Iraqi Kurdistan. Antiquity Project Gallery 348. https://doi.org/10.2307/j.ctvxrq0m8.38Google Scholar
Reynolds, T. et al. 2018. Shanidar Cave and the Baradostian: a Zagros Aurignacian industry. L'Anthropologie 122: 737–48. https://doi.org/10.1016/j.anthro.2018.10.007CrossRefGoogle Scholar
Ressler, C., Tatake, J.G., Kaizer, E. & Putnam, D.H.. 1997. Neurotoxins in a vetch food: stability to cooking and removal of γ-glutamyl-β-cyanoalanine and β-cyanoalanine and acute toxicity from common vetch (Vicia sativa L.) legumes. Journal of Agricultural Food Chemistry 45: 189–94. https://doi.org/10.1021/jf9603745CrossRefGoogle Scholar
Richards, M.P. & Trinkaus, E.. 2009. Isotopic evidence for the diets of European Neanderthals and early modern humans. Proceedings of the National Academy of Sciences of the USA 106: 16034–39. https://doi.org/10.1073/pnas.0903821106CrossRefGoogle ScholarPubMed
Scott, J.E. & Marean, C.W.. 2009. Paleolithic hominin remains from Eshkaft-e Gavi (southern Zagros Mountains, Iran): description, affinities, and evidence for butchery. Journal of Human Evolution 57: 248–59. https://doi.org/10.1016/j.jhevol.2009.05.012CrossRefGoogle ScholarPubMed
Shidrang, S. 2018. The Middle to Upper Paleolithic transition in the Zagros: the appearance and evolution of the Baradostian, in Nishiaki, Y. & Akazawa, T. (ed.) The Middle and Upper Paleolithic archeology of the Levant and beyond: 133–56. Singapore: Springer. https://doi.org/10.1007/978-981-10-6826-3_10CrossRefGoogle Scholar
Smith, A., Proctor, L., Hart, T.C. & Stein, G.. 2019. The burning issue of dung in archaeobotanical samples: a case-study integrating macro-botanical remains, dung spherulites, and phytoliths to assess sample origin and fuel use at Tell Zeidan, Syria. Vegetation History and Archaeobotany 28: 229–46. https://doi.org/10.1007/s00334-018-0692-9CrossRefGoogle Scholar
Smith, B.D. & Zeder, M.A.. 2013. The onset of the Anthropocene. Anthropocene 4: 813. https://doi.org/10.1016/j.ancene.2013.05.001CrossRefGoogle Scholar
Solecki, R. 1971. Shanidar, the first flower people. New York: Knopf.Google Scholar
Speth, J.D. 2010. The paleoanthropology and archaeology of big-game hunting: protein, fat, or politics? Springer: New York. https://doi.org/10.1007/978-1-4419-6733-6CrossRefGoogle Scholar
Stiner, M.C., Munro, N.D. & Surovell, T.A.. 2000. The tortoise and the hare: small-game use, the broad-spectrum revolution and Paleolithic demography. Current Anthropology 41: 3973. https://doi.org/10.1086/300102CrossRefGoogle ScholarPubMed
Tantawy, M.E., Khalifa, S.F., Hassan, S.A. & Al-Rabiai, G.T.. 2004. Seed exomorphic characters of some Brassicaceae (LM and SEM study). International Journal of Agriculture and Biology 6: 821–30.Google Scholar
Valamoti, S.M., Samuel, D., Bayram, M. & Marinova, E.. 2008. Prehistoric cereal foods from Greece and Bulgaria: investigation of starch microstructure in experimental and archaeological charred remains. Vegetation History and Archaeobotany 17: 265–76. https://doi.org/10.1007/s00334-008-0190-6CrossRefGoogle Scholar
Valamoti, S.M., Moniaki, A. & Karathanou, A.. 2011. An investigation of processing and consumption of pulses among prehistoric societies: archaeobotanical, experimental and ethnographic evidence from Greece. Vegetation History and Archaeobotany 20: 381–96. https://doi.org/10.1007/s00334-011-0302-6CrossRefGoogle Scholar
Valamoti, S.M. et al. 2021. Deciphering ancient ‘recipes’ from charred cereal fragments: an integrated methodological approach using experimental, ethnographic and archaeological evidence. Journal of Archaeological Science 128: 105347. https://doi.org/10.1016/j.jas.2021.105347CrossRefGoogle Scholar
Weiss, E., Kislev, M.E., Simchoni, O. & Nadel, D.. 2004. Small-grained wild grasses as staple food at the 23 000-year-old site of Ohalo II, Israel. Economic Botany 58: S125–34. https://doi.org/10.1663/0013-0001(2004)58[S125:SWGASF]2.0.CO;2CrossRefGoogle Scholar
Werker, E., Marbach, I. & Mayer, A.M.. 1979. Relation between the anatomy of the testa, water permeability and the presence of phenolics in the genus Pisum. Annals of Botany 43: 765–71. https://doi.org/10.1093/oxfordjournals.aob.a085691CrossRefGoogle Scholar
Zablatzká, L. et al. 2021. Anatomy and histochemistry of seed coat development of wild (Pisum sativum subsp. elatius (M. Bieb.) Asch. et Graebn and domesticated pea (Pisum sativum subsp. sativum L.). International Journal of Molecular Sciences 22: 4602. https://doi.org/10.3390/ijms22094602Google ScholarPubMed
Figure 0

Table 1. Summary of provenance, phasing and corresponding radiometric dates for the analysed food fragments.

Figure 1

Figure 1. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 167, Final Palaeolithic, Epigravettian): A) overview; B) close-up of pulse seed coat and seed fragment; C) close-up of pulse seed coat surface; D) view of Vicia ervilia seed coat papillose cells; E) close-up of pulse seed coat surface (SEM micrographs taken by C. Kabukcu).

Figure 2

Figure 2. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 168, Final Palaeolithic, Epigravettian): A) overview; B–D) close-ups of pulse seed fragments and seed coat remains (SEM micrographs taken by C. Kabukcu).

Figure 3

Figure 3. Pulse-rich charred plant food fragment from Franchthi Cave (context no. H1A 177, Upper Palaeolithic, Mediterranean Gravettian): A) overview; B–C) close-up of pulse seed fragments and seed coat (SEM micrographs taken by C. Kabukcu).

Figure 4

Figure 4. Charred plant food remains from Franchthi Cave, with a homogenised matrix (context no. H1A 172, Upper Palaeolithic, Mediterranean Gravettian): A) overview; B) close-up showing variable sizes of voids (SEM micrographs taken by C. Kabukcu).

Figure 5

Figure 5. Pulse-rich charred plant food remains from Shanidar Cave (context no. 1812, Upper Palaeolithic, Baradostian): A) overview; B–D) close-up of pulse seed coat surface and mounded-papillose seed coat pattern of Lathyrus sp. (likely Lathyrus cassius, L. hirsutus or L. nissolia) (SEM micrographs taken by C. Kabukcu).

Figure 6

Figure 6. Charred plant food fragment from Shanidar Cave (context no. 1866, Upper Palaeolithic, Initial Baradostian): A) overview; B–C) close-up of wild pea (Pisum fulvum or P. sativum subsp. elatius) seed coat (SEM micrographs taken by C. Kabukcu).

Figure 7

Figure 7. Charred plant food remains from Shanidar Cave (context no. 1823, Upper Palaeolithic, Baradostian) containing wild mustard: A) overview; B–C) close-up of mustard seed fragment and seed coat pattern (SEM micrographs taken by C. Kabukcu).

Figure 8

Figure 8. Charred plant food remains from Shanidar Cave (context no. 1866, Upper Palaeolithic, Initial Baradostian): A) overview; B) & D) close-up of cf. Pistacia nutshell/pericarp remain; C) close-up of pulse seed coat pattern (Fabeae) (SEM micrographs taken by C. Kabukcu).

Figure 9

Figure 9. Charred plant food fragment from Shanidar Cave (context no. 636, Upper Palaeolithic, Baradostian): A) overview; B–D) close-up of cf. Pistacia nutshell/pericarp fragment (SEM micrographs taken by C. Kabukcu).

Figure 10

Figure 10. Charred plant food remains from Shanidar Cave containing pulses and grasses (context no. 1924, Middle Palaeolithic, Mousterian): A) overview; B–C) close-up of pulse seed coat and seed fragments; D) close-up of long cells of Poaceae seed (SEM micrographs taken by C. Kabukcu).

Supplementary material: PDF

Kabukcu et al. supplementary material

Kabukcu et al. supplementary material

Download Kabukcu et al. supplementary material(PDF)
PDF 1.1 MB