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The evolution of the human trophic level during the Pleistocene - PubMed

. 2021 Aug:175 Suppl 72:27-56.

doi: 10.1002/ajpa.24247. Epub 2021 Mar 5.

Affiliations

PMID: 33675083
DOI: 10.1002/ajpa.24247

The evolution of the human trophic level during the Pleistocene

Miki Ben-Dor et al. Am J Phys Anthropol. 2021 Aug.

Abstract

The human trophic level (HTL) during the Pleistocene and its degree of variability serve, explicitly or tacitly, as the basis of many explanations for human evolution, behavior, and culture. Previous attempts to reconstruct the HTL have relied heavily on an analogy with recent hunter-gatherer groups' diets. In addition to technological differences, recent findings of substantial ecological differences between the Pleistocene and the Anthropocene cast doubt regarding that analogy's validity. Surprisingly little systematic evolution-guided evidence served to reconstruct HTL. Here, we reconstruct the HTL during the Pleistocene by reviewing evidence for the impact of the HTL on the biological, ecological, and behavioral systems derived from various existing studies. We adapt a paleobiological and paleoecological approach, including evidence from human physiology and genetics, archaeology, paleontology, and zoology, and identified 25 sources of evidence in total. The evidence shows that the trophic level of the Homo lineage that most probably led to modern humans evolved from a low base to a high, carnivorous position during the Pleistocene, beginning with Homo habilis and peaking in Homo erectus. A reversal of that trend appears in the Upper Paleolithic, strengthening in the Mesolithic/Epipaleolithic and Neolithic, and culminating with the advent of agriculture. We conclude that it is possible to reach a credible reconstruction of the HTL without relying on a simple analogy with recent hunter-gatherers' diets. The memory of an adaptation to a trophic level that is embedded in modern humans' biology in the form of genetics, metabolism, and morphology is a fruitful line of investigation of past HTLs, whose potential we have only started to explore.

Keywords: carnivore; diet; ethnography; paleobiology; paleolithic.

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References

REFERENCES

1. Adler, C. J., Dobney, K., Weyrich, L. S., Kaidonis, J., Walker, A. W., Haak, W., Bradshaw, C. J. A., Townsend, G., Sołtysiak, A., Alt, K. W., Parkhill, J., & Cooper, A. (2013). Sequencing ancient calcified dental plaque shows changes in oral microbiota with dietary shifts of the Neolithic and Industrial revolutions. Nature Genetics, 45(4), 450-455.
1. Agam, A., & Barkai, R. (2018). Elephant and mammoth hunting during the Paleolithic: A review of the relevant archaeological, ethnographic and ethno-historical records. Quaternary, 1(1), 3.
1. Aiello, L. C., & Wheeler, P. (1995). The expensive-tissue hypothesis: The brain and the digestive system in human and primate evolution. Current Anthropology, 36(2), 199-221.
1. Akkaoui, M., Cohen, I., Esnous, C., Lenoir, V., Sournac, M., Girard, J., & Prip-Buus, C. (2009). Modulation of the hepatic malonyl-CoA-carnitine palmitoyltransferase 1A partnership creates a metabolic switch allowing oxidation of de novo fatty acids1. Biochemical Journal, 420(3), 429-438.
1. Ames, K. M. (2004). Supposing hunter-gatherer variability. American Antiquity, 69(2), 364-374.

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The evolution of the human trophic level during the Pleistocene - PubMed

The evolution of the human trophic level during the Pleistocene

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