Prehistory of nakedness and clothing

Nakedness and clothing use are characteristics of humans related by evolutionary and social prehistory. The major loss of body hair distinguishes humans from other primates. Current evidence indicates that anatomically modern humans were naked in prehistory for at least 90,000 years before they invented clothing. Today, isolated Indigenous peoples in tropical climates continue to be without clothing in many everyday activities.

Evolution of hairlessness

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Humans' closest living relatives have both extensive areas of fur and also bare patches

The general hairlessness of humans in comparison to related species may be due to loss of functionality in the pseudogene KRT41P (which helps produce keratin) in the human lineage about 240,000 years ago.[1] On an individual basis, mutations in the gene HR can lead to complete hair loss, though this is not typical in humans.[2] Humans may also lose their hair as a result of hormonal imbalance due to drugs or pregnancy.[3]

In order to comprehend why humans have significantly less body hair than other primates, one must understand that mammalian body hair is not merely an aesthetic characteristic; it protects the skin from wounds, bites, heat, cold, and UV radiation.[4] Additionally, it can be used as a communication tool and as a camouflage.[5]

The first member of the genus Homo to be hairless was Homo erectus, originating about 1.6 million years ago.[6] The dissipation of body heat remains the most widely accepted evolutionary explanation for the loss of body hair in early members of the genus Homo, the surviving member of which is modern humans.[7][8][9] Less hair, and an increase in sweat glands, made it easier for their bodies to cool when they moved from living in shady forest to open savanna. This change in environment also resulted in a change in diet, from largely vegetarian to hunting. Pursuing game on the savanna also increased the need for regulation of body heat.[10][11]

Anthropologist and paleo-biologist Nina Jablonski posits that the ability to dissipate excess body heat through eccrine sweating helped make possible the dramatic enlargement of the brain, the most temperature-sensitive human organ.[12] Thus the loss of fur was also a factor in further adaptations, both physical and behavioral, that differentiated humans from other primates. Some of these changes are thought to be the result of sexual selection. By selecting more hairless mates, humans accelerated changes initiated by natural selection. Sexual selection may also account for the remaining human hair in the pubic area and armpits, which are sites for pheromones, while hair on the head continued to provide protection from the sun.[13] Anatomically modern humans, whose traits include hairlessness, evolved 260,000 to 350,000 years ago.[14]

Phenotypic changes

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Humans are the only primate species that have undergone significant hair loss and of the approximately 5000 extant species of mammal, only a handful are effectively hairless. This list includes elephants, rhinoceroses, hippopotamuses, walruses, some species of pigs, whales and other cetaceans, and naked mole rats.[5] Most mammals have light skin that is covered by fur, and biologists believe that early human ancestors started out this way also. Dark skin probably evolved after humans lost their body fur, because the naked skin was vulnerable to the strong UV radiation as explained in the Out of Africa hypothesis. Therefore, evidence of the time when human skin darkened has been used to date the loss of human body hair, assuming that the dark skin was needed after the fur was gone.

With the loss of fur, darker, high-melanin skin evolved as a protection from ultraviolet radiation damage.[15] As humans migrated outside of the tropics, varying degrees of depigmentation evolved in order to permit UVB-induced synthesis of previtamin D3.[16][17] The relative lightness of female compared to male skin in a given population may be due to the greater need for women to produce more vitamin D during lactation.[18]

The sweat glands in humans could have evolved to spread from the hands and feet as the body hair changed, or the hair change could have occurred to facilitate sweating. Horses and humans are two of the few animals capable of sweating on most of their body, yet horses are larger and still have fully developed fur. In humans, the skin hairs lie flat in hot conditions, as the arrector pili muscles relax, preventing heat from being trapped by a layer of still air between the hairs, and increasing heat loss by convection.

Sexual selection hypothesis

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Another hypothesis for the thick body hair on humans proposes that Fisherian runaway sexual selection played a role (as well as in the selection of long head hair), (see terminal and vellus hair), as well as a much larger role of testosterone in men. Sexual selection is the only theory thus far that explains the sexual dimorphism seen in the hair patterns of men and women. On average, men have more body hair than women. Males have more terminal hair, especially on the face, chest, abdomen, and back, and females have more vellus hair, which is less visible. The halting of hair development at a juvenile stage, vellus hair, would also be consistent with the neoteny evident in humans, especially in females, and thus they could have occurred at the same time.[19] This theory, however, has significant holdings in today's cultural norms. There is no evidence that sexual selection would proceed to such a drastic extent over a million years ago when a full, lush coat of hair would most likely indicate health and would therefore be more likely to be selected for, not against.

Water-dwelling hypothesis

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The aquatic ape hypothesis (AAH) includes hair loss as one of several characteristics of modern humans that could indicate adaptations to an aquatic environment. Serious consideration may be given by contemporary anthropologists to some hypotheses related to AAH, but hair loss is not one of them.[20]

Parasite hypothesis

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A divergent explanation of humans' relative hairlessness holds that ectoparasites (such as ticks) residing in fur became problematic as humans became hunters living in larger groups with a "home base".[21][22] Nakedness would also make the lack of parasites apparent to prospective mates.[23] However, this theory is inconsistent with the abundance of parasites that continue to exist in the remaining patches of human hair.[24]

The "ectoparasite" explanation of modern human nakedness is based on the principle that a hairless primate would harbor fewer parasites. When our ancestors adopted group-dwelling social arrangements roughly 1.8 mya, ectoparasite loads increased dramatically. Early humans became the only one of the 193 primate species to have fleas, which can be attributed to the close living arrangements of large groups of individuals. While primate species have communal sleeping arrangements, these groups are always on the move and thus are less likely to harbor ectoparasites.

It was expected that dating the split of the ancestral human louse into two species, the head louse and the pubic louse, would date the loss of body hair in human ancestors. However, it turned out that the human pubic louse does not descend from the ancestral human louse, but from the gorilla louse, diverging 3.3 million years ago. This suggests that humans had lost body hair (but retained head hair) and developed thick pubic hair prior to this date, were living in or close to the forest where gorillas lived, and acquired pubic lice from butchering gorillas or sleeping in their nests.[25][26] The evolution of the body louse from the head louse, on the other hand, places the date of clothing much later, some 100,000 years ago.[27][28]

Fire hypothesis

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Another hypothesis is that humans' use of fire caused or initiated the reduction in human hair.[29]

Childrearing hypothesis

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Another view is proposed by James Giles, who attempts to explain hairlessness as evolved from the relationship between mother and child, and as a consequence of bipedalism. Giles also connects romantic love to hairlessness.[30][31]

The last common ancestor of humans and chimpanzees was only partially bipedal, often using their front legs for locomotion. Other primate mothers do not need to carry their young because there is fur for them to cling to, but the loss of fur encouraged full bipedalism, allowing the mothers to carry their babies with one or both hands.[32] The combination of hairlessness and upright posture may also explain the enlargement of the female breasts as a sexual signal.[9] Giles' theory is that the loss of fur also promoted mother-child attachment based upon the pleasure of skin-to-skin contact. This may explain the more extensive hairlessness of female humans and infants compared to adult males. Nakedness also affects sexual relationships as well, the duration of human intercourse being many times the duration of any other primates.[24]

Origin of clothing

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A necklace reconstructed from perforated sea snail shells from Upper Palaeolithic Europe, dated between 39,000 and 25,000 BCE. The practice of body adornment is associated with the emergence of behavioral modernity.

A 2010 study published in Molecular Biology and Evolution indicates that the habitual wearing of clothing began at some point in time between 83,000 years ago and 170,000 years ago based upon a genetic analysis indicating when clothing lice diverged from their head louse ancestors. This information suggests that the use of clothing likely originated with anatomically modern humans in Africa prior to their migration to colder climates, allowing them to do so.[33]

Some of the technology for what is now called clothing may have originated to make other types of adornment, including jewelry, body paint, tattoos, and other body modifications, "dressing" the naked body without concealing it.[34][35] According to Mark Leary and Nicole R. Buttermore, body adornment is one of the changes that occurred in the late Paleolithic (40,000 to 60,000 years ago) in which humans became not only anatomically modern, but also behaviorally modern and capable of self-reflection and symbolic interaction.[36] More recent studies place the use of adornment at 77,000 years ago in South Africa, and 90,000—100,000 years ago in Israel and Algeria.[37] While modesty may be a factor, often overlooked purposes for body coverings are camouflage used by hunters, body armor, and costumes used to impersonate "spirit-beings".[38]

The origin of complex, fitted clothing required the invention of fine stone knives for cutting skins into pieces, and the eyed needle for sewing. This was done by Cro-Magnons, who migrated to Europe around 35,000 years ago.[39] The Neanderthal occupied the same region, but became extinct in part because they could not make fitted garments, but draped themselves with crudely cut skins—based upon their simple stone tools—which did not provide the warmth needed to survive as the climate grew colder in the Last Glacial Period.[40] In addition to being less functional, the simple wrappings would not have been habitually worn by Neanderthal due to their being more cold-tolerant than Homo sapiens, and would not have acquired the secondary functions of decoration and promoting modesty.[41]

The earliest archeological evidence of fabric clothing is inferred from representations in figurines in the southern Levant dated between 11,700 and 10,500 years ago.[42] The surviving examples of woven cloth are linen from Egypt dated 5,000 BCE, although knotted or twisted flax fibers have been found as early as 7000 BCE.[43]

While adults are rarely completely naked in modern societies, covering at least their genitals, adornments and clothing often emphasize, enhance, or otherwise call attention to the sexuality of the body.[44]

References

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  1. ^ Winter, H.; Langbein, L.; Krawczak, M.; Cooper, D.N.; Jave-Suarez, L.F.; Rogers, M.A.; Praetzel, S.; Heidt, P.J.; Schweizer, J. (2001). "Human type I hair keratin pseudogene phihHaA has functional orthologs in the chimpanzee and gorilla: Evidence for recent inactivation of the human gene after the Pan-Homo divergence". Human Genetics. 108 (1): 37–42. doi:10.1007/s004390000439. PMID 11214905. S2CID 21545865.
  2. ^ Abbasi, A.A. (2011). "Molecular evolution of HR, a gene that regulates the postnatal cycle of the hair follicle". Scientific Reports. 1: 32. Bibcode:2011NatSR...1E..32A. doi:10.1038/srep00032. PMC 3216519. PMID 22355551.
  3. ^ "Women and Hair Loss: Possible Causes". WebMD. Retrieved 22 April 2020.
  4. ^ Rantala, M.J. (1999). "Human nakedness: Adaptation against ectoparasites?". International Journal for Parasitology. 29 (12): 1987–1989. doi:10.1016/S0020-7519(99)00133-2. PMID 10961855.
  5. ^ a b Jablonski, N.G.; Chaplin, G. (2010). "Human skin pigmentation as an adaptation to UV radiation". Proceedings of the National Academy of Sciences of the United States of America. 107 (Supplement 2): 8962–8968. Bibcode:2010PNAS..107.8962J. doi:10.1073/pnas.0914628107. PMC 3024016. PMID 20445093.
  6. ^ Hermansen 2018, pp. 278–281.
  7. ^ Kushlan 1980.
  8. ^ Wheeler 1985.
  9. ^ a b Sutou 2012.
  10. ^ Daley 2018.
  11. ^ Jarrett & Scragg 2020.
  12. ^ Jablonski 2012.
  13. ^ Wade 2003.
  14. ^ Schlebusch 2017.
  15. ^ Zukerman 2011.
  16. ^ Jablonski & Chaplin 2000, pp. 57–106.
  17. ^ Jablonski & Chaplin 2017.
  18. ^ Jarrett & Scragg 2020, p. 7.
  19. ^ Dixson, A.F. (2009). Sexual selection and the origins of human mating systems (1 ed.). Oxford University Press, USA. ISBN 978-0-19-955942-8.
  20. ^ Rae & Koppe 2014.
  21. ^ Pagel, Mark; Bodmer, Walter (2003). "A naked ape would have fewer parasites". Proceedings of the Royal Society B: Biological Sciences. 270 (Suppl 1): S117–S119. doi:10.1098/rsbl.2003.0041. PMC 1698033. PMID 12952654.
  22. ^ Rantala, M.J. (1999). "Human nakedness: Adaptation against ectoparasites?" (PDF). International Journal for Parasitology. 29 (12): 1987–1989. doi:10.1016/S0020-7519(99)00133-2. PMID 10961855. Archived from the original (PDF) on 5 February 2011. Retrieved 14 December 2010.
  23. ^ Rantala 2007, pp. 1–7.
  24. ^ a b Giles 2010.
  25. ^ "Gorillas gave pubic lice to humans, DNA study reveals". National Geographic. 28 October 2010. Archived from the original on 16 December 2014. Retrieved 18 February 2015.
  26. ^ Weiss RA (10 February 2009). "Apes, lice and prehistory". J Biol. 8 (2): 20. doi:10.1186/jbiol114. PMC 2687769. PMID 19232074.
  27. ^ Kittler, R.; Kayser, M.; Stoneking, M. (2004). "Molecular Evolution of Pediculus humanus and the Origin of Clothing". Current Biology. 14 (24): 1414–7. Bibcode:2004CBio...14.2309K. doi:10.1016/j.cub.2004.12.024. PMID 12932325.
  28. ^ Toups, M.A.; Kitchen, A.; Light, J.E.; Reed, D.L. (2011). "Origin of clothing lice indicates early clothing use by anatomically modern humans in Africa". Molecular Biology and Evolution. 28 (1): 29–32. doi:10.1093/molbev/msq234. PMC 3002236. PMID 20823373.
  29. ^ Couch, Alan (3 February 2016). "Fur or fire: Was the use of fire the initial selection pressure for fur loss in ancestral hominins?". PeerJ Preprints. 4: e1702v1. doi:10.7287/peerj.preprints.1702v1. Retrieved 10 February 2016.
  30. ^ Giles, James (20 March 2015) [2010]. "Naked love: The evolution of human hairlessness". Biological Theory. 5 (4): 326–336. doi:10.1162/BIOT_a_00062. S2CID 84164968.
  31. ^ Shea, Christopher (12 July 2011). "Human hairlessness: The naked love explanation". Ideas Market blog. The Wall Street Journal. Retrieved 18 February 2015.
  32. ^ Brown 2021.
  33. ^ Toups et al. 2010, pp. 29–32.
  34. ^ Hollander 1978, p. 83.
  35. ^ Hogenboom 2016.
  36. ^ Leary & Buttermore 2003.
  37. ^ Nowell 2010.
  38. ^ Buckner 2021.
  39. ^ Gilligan 2010.
  40. ^ Hermansen 2018, pp. 103–104.
  41. ^ Gilligan 2007a, pp. 500–502.
  42. ^ Levy 2020, Ch. 7.
  43. ^ Barber 1991, pp. 9–11.
  44. ^ Davies 2020, p. 168.

Works cited

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