Book contents
- Only in Africa
- Only in Africa
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Abbreviations
- Part I The Physical Cradle: Land Forms, Geology, Climate, Hydrology and Soils
- Part II The Savanna Garden: Grassy Vegetation and Plant Dynamics
- Part III The Big Mammal Menagerie: Herbivores, Carnivores and Their Ecosystem Impacts
- Part IV Evolutionary Transitions: From Primate Ancestors to Modern Humans
- Appendix Scientific Names of Extant Animal and Plant Species Mentioned in the Book Chapters (Ecologically Conservative with Regard to Species Recognition)
- Index
- References
Part IV - Evolutionary Transitions: From Primate Ancestors to Modern Humans
Published online by Cambridge University Press: 09 September 2021
Book contents
- Only in Africa
- Only in Africa
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Abbreviations
- Part I The Physical Cradle: Land Forms, Geology, Climate, Hydrology and Soils
- Part II The Savanna Garden: Grassy Vegetation and Plant Dynamics
- Part III The Big Mammal Menagerie: Herbivores, Carnivores and Their Ecosystem Impacts
- Part IV Evolutionary Transitions: From Primate Ancestors to Modern Humans
- Appendix Scientific Names of Extant Animal and Plant Species Mentioned in the Book Chapters (Ecologically Conservative with Regard to Species Recognition)
- Index
- References
Summary
Primates (order Primata) are basically herbivores, but are mostly not so large and mainly forest-dwelling. They are represented by a dazzling diversity of species throughout tropical forests where fruits are produced and trees retain foliage almost year-round. The platyrrhine (‘flat-nosed’) monkeys found in South America split off from the haplorhine (‘simple-nosed’) suborder inhabiting the ‘Old World’ tropics early in the Eocene ~50 Ma. Prosimians (bushbabies, lemurs and allies) diverged even earlier during the late Cretaceous 74 Ma, based on genetic evidence, and are most diverse in Madagascar. The monkeys inhabiting Africa and Asia (Cercopithecoidea) are separated from the apes (Hominoidea), which lack tails, at superfamily level. Among apes, the gibbons, found solely in Asia, are placed in a different family (Hylobatidae) from the remainder (Hominidae). Humans are allied with chimpanzees (Pan troglodytes and P. paniscus) and gorillas (Gorilla gorilla) in the latter family, but allocated to a distinct subfamily, the Homininae. Ecologically, we have diverged from other apes in habitat, locomotion and diet.
- Type
- Chapter
- Information
- Only in AfricaThe Ecology of Human Evolution, pp. 247 - 343Publisher: Cambridge University PressPrint publication year: 2021
References
Suggested Further Reading
Jablonski, N; Frost, S. (2010) Cercopithecoidea. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 393–428.Google Scholar
References
Jablonski, NG; Frost, S. (2010) Cercopithecoidea. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 393–428.Google Scholar
Harrison, T. (2010) Dendropithecoidea, proconsuloidea, and hominoidea. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 429–469.Google Scholar
MacLatchy, LM. (2010) Hominini. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 471–540.Google Scholar
Benefit, BR. (1999) Biogeography, dietary specialization, and the diversification of African Plio–Pleistocene monkeys. In Bromage, TG; Schrenk, F (eds) African Biogeography, Climate Change, and Human Evolution. Oxford University Press, Oxford, pp. 172–188.CrossRefGoogle Scholar
Suwa, G, et al. (2007) A new species of great ape from the late Miocene epoch in Ethiopia. Nature 448:921–924.CrossRefGoogle ScholarPubMed
Fischer, J, et al. (2019) The natural history of model organisms: insights into the evolution of social systems and species from baboon studies. Elife 8:e50989.Google Scholar
Suggested Further Reading
Boesch, C; Boesch-Achermann, H. (2000) The Chimpanzees of the Taï Forest: Behavioural Ecology and Evolution. Oxford University Press, Oxford.CrossRefGoogle Scholar
Hohmann, G, et al. (eds). (2006) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge.Google Scholar
References
Copeland, SR. (2009) Potential hominin plant foods in northern Tanzania: semi-arid savannas versus savanna chimpanzee sites. Journal of Human Evolution 57:365–378.CrossRefGoogle ScholarPubMed
Marshall, AJ, et al. (2009) Defining fallback foods and assessing their importance in primate ecology and evolution. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 140:603–614.Google Scholar
O’Brien, EM; Peters, CR (1999) Landforms, climate, ecogeographic mosaics, and the potential for hominid diversity in Pliocene Africa. In Bromage, TG; Schrenk, F (eds) African Biogeography, Climate Change and Human Evolution. Oxford University Press, Oxford, pp. 115–137.CrossRefGoogle Scholar
Uwimbabazi, M, et al. (2019) Influence of fruit availability on macronutrient and energy intake by female chimpanzees. African Journal of Ecology 57:454–465.CrossRefGoogle ScholarPubMed
Van Schaik, CP; Pfannes, KR. (2005) Tropical climates and phenology: a primate perspective. In Brockmann, DK; Van Schaik, CP (eds) Seasonality in Primates. Cambridge University Press, Cambridge, pp. 23–54.CrossRefGoogle Scholar
Oates, JF. (1977) The guereza and its food. In Clutton-Brock, TH (ed.) Primate Ecology: Studies of Feeding and Ranging Behaviour in Lemurs, Monkeys, and Apes. Academic Press, London, pp. 275–321.Google Scholar
Danish, L, et al. (2006) The role of sugar in diet selection in redtail and red colobus monkeys. In Hahmann, MM, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 473–487.Google Scholar
Poulsen, JR, et al. (2001) Seasonal variation in the feeding ecology of the grey‐cheeked mangabey (Lophocebus albigena) in Cameroon. American Journal of Primatology: Official Journal of the American Society of Primatologists 54:91–105.Google Scholar
Doran-Sheehy, DM, et al. (2006) Sympatric western gorilla and mangabey diet: re-examination of ape and monkey foraging strategies. In Hohmann, G, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 49–72.Google Scholar
Wrangham, RW; Waterman, PG. (1981) Feeding behaviour of vervet monkeys on Acacia tortilis and Acacia xanthophloea: with special reference to reproductive strategies and tannin production. The Journal of Animal Ecology 50:715–731.CrossRefGoogle Scholar
Isbell, LA. (1998) Diet for a small primate: insectivory and gummivory in the (large) patas monkey (Erythrocebus patas pyrrhonotus). American Journal of Primatology 45:381–398.3.0.CO;2-S>CrossRefGoogle ScholarPubMed
Nakagawa, N. (2000) Seasonal, sex, and interspecific differences in activity time budgets and diets of patas monkeys (Erythrocebus patas) and tantalus monkeys (Cercopithecus aethiops tantalus), living sympatrically in northern Cameroon. Primates 41:161.Google Scholar
Nakagawa, N. (2003) Difference in food selection between patas monkeys (Erythrocebus patas) and tantalus monkeys (Cercopithecus aethiops tantalus) in Kala Maloue National Park, Cameroon, in relation to nutrient content. Primates 44:3–11.Google Scholar
Dunbar, RIM. (1977) Feeding ecology of gelada baboons: a preliminary report. In Clutton-Brock, TH (ed.) Primate Ecology. Academic Press, London, pp. 251–273.Google Scholar
Norton, GW, et al. (1987) Baboon diet: a five-year study of stability and variability in the plant feeding and habitat of the yellow baboons (Papio cynocephalus) of Mikumi National Park, Tanzania. Folia Primatologica 48:78–120.CrossRefGoogle Scholar
Whiten, A, et al. (1991) Dietary and foraging strategies of baboons. Philosophical Transactions of the Royal Society of London Series B: Biological Sciences 334:187–197.Google Scholar
Whiten, A, et al. (1987) The behavioral ecology of mountain baboons. International Journal of Primatology 8:367–388.CrossRefGoogle Scholar
Barton, RA; Whiten, A. (1994) Reducing complex diets to simple rules: food selection by olive baboons. Behavioral Ecology and Sociobiology 35:283–293.Google Scholar
Alberts, SC, et al. (2005). Seasonality and long term change in a savannah environment. In Brockmann, DK; Van Schaik, CP (eds) Seasonality in Primates. Vol. 16. Cambridge University Press, Cambridge, pp. 157–195.Google Scholar
Kunz, BK; Linsenmair, KE. (2008) The disregarded west: diet and behavioural ecology of olive baboons in the Ivory Coast. Folia Primatologica 79:31–51.Google Scholar
Codron, D, et al. (2008) What insights can baboon feeding ecology provide for early hominin niche differentiation? International Journal of Primatology 29:757–772.Google Scholar
Wrangham, RW, et al. (1998) Dietary response of chimpanzees and cercopithecines to seasonal variation in fruit abundance. I. Antifeedants. International Journal of Primatology 19:949–970.CrossRefGoogle Scholar
Newton‐Fisher, NE. (1999) The diet of chimpanzees in the Budongo Forest Reserve, Uganda. African Journal of Ecology 37:344–354.Google Scholar
Morgan, D; Sanz, CM. (2006) Chimpanzee feeding ecology and comparisons with sympatric gorillas in the Goualougo Triangle, Republik of Congo. In Hohmann, G, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 97–122.Google Scholar
McGrew, WC, et al. (1988) Diet of wild chimpanzees (Pan troglodytes verus) at Mt. Assirik, Senegal: I. Composition. American Journal of Primatology 16:213–226.Google Scholar
Pruetz, JD. (2006) Feeding ecology of savanna chimpanzees (Pan troglodytes verus) at Fongoli, Senegal. In Hohmann, G, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 161–182.Google Scholar
Wrangham, RW. (1977) Feeding behaviour of chimpanzees in Gombe national park, Tanzania. In Clutton-Brock, TH (ed.) Primate Ecology: Studies of Feeding and Ranging Behaviour in Lemurs, Monkeys and Apes. Academic Press, London, pp. 503–538.Google Scholar
Malenky, RK; Stiles, EW. (1991) Distribution of terrestrial herbaceous vegetation and its consumption by Pan paniscus in the Lomako Forest, Zaire. American Journal of Primatology 23:153–169.CrossRefGoogle Scholar
Rogers, ME, et al. (2004) Western gorilla diet: a synthesis from six sites. American Journal of Primatology: Official Journal of the American Society of Primatologists 64:173–192.CrossRefGoogle Scholar
Doran‐Sheehy, D, et al. (2009) Male and female western gorilla diet: preferred foods, use of fallback resources, and implications for ape versus old world monkey foraging strategies. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 140:727–738.Google Scholar
Robbins, MM, et al. (2006) Variability of the feeding ecology of eastern gorillas. In Hohmann, G, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 25–48.Google Scholar
Yamagiwa, J; Basabose, AK. (2006) Effects of fruit scarcity on foraging strategies of sympatric gorillas and chimpanzees. In Hohmann, G, et al. (eds) Feeding Ecology in Apes and Other Primates. Cambridge University Press, Cambridge, pp. 73–96.Google Scholar
Rothman, JM, et al. (2011) Nutritional geometry: gorillas prioritize non-protein energy while consuming surplus protein. Biology Letters 7:847–849.CrossRefGoogle ScholarPubMed
Altmann, SA. (2009) Fallback foods, eclectic omnivores, and the packaging problem. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 140:615–629.CrossRefGoogle ScholarPubMed
Dunbar, RIM. (1987) Habitat quality, population dynamics, and group composition in colobus monkeys (Colobus guereza). International Journal of Primatology 8:299–329.Google Scholar
De Vos, A; Omar, A. (1971) Territories and movements of Sykes monkeys (Cercopithecus mitis kolbi Neuman) in Kenya. Folia Primatologica 16:196–205.Google Scholar
Lawes, MJ. (1991) Diet of samango monkeys (Cercopithecus mitis erythrarchus) in the Cape Vidal dune forest, South Africa. Journal of Zoology 224:149–173.CrossRefGoogle Scholar
Barrett, AS, et al. (2010) A floristic description and utilisation of two home ranges by vervet monkeys in Loskop Dam Nature Reserve, South Africa. Koedoe 52:1–12.CrossRefGoogle Scholar
Pasternak, G, et al. (2013) Population ecology of vervet monkeys in a high latitude, semi-arid riparian woodland. Koedoe 55:1–9.Google Scholar
Waser, P. (1977) Feeding, ranging and group size in the mangabey (Cercocebus albigena). In Clutton-Brock, TH (ed.) Primate Ecology. Academic Press, London, pp. 183–221.Google Scholar
Nakagawa, N. (1999) Differential habitat utilization by patas monkeys (Erythrocebus patas) and tantalus monkeys (Cercopithecus aethiops tantalus) living sympatrically in northern Cameroon. American Journal of Primatology: Official Journal of the American Society of Primatologists 49:243–264.3.0.CO;2-4>CrossRefGoogle ScholarPubMed
Hall, KR. (1966) Behaviour and ecology of the wild patas monkey, Erythrocebus patas, in Uganda. Journal of Zoology 148:15–87.Google Scholar
Yamagiwa, J; Basabose, AK. (2009) Fallback foods and dietary partitioning among Pan and Gorilla. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 140:739–750.CrossRefGoogle ScholarPubMed
Cheney, DL, et al. (2004) Factors affecting reproduction and mortality among baboons in the Okavango Delta, Botswana. International Journal of Primatology 25:401–428.CrossRefGoogle Scholar
Cowlishaw, G. (1994) Vulnerability to predation in baboon populations. Behaviour 131:293–304.Google Scholar
Isbell, LA, et al. (2018) GPS-identified vulnerabilities of savannah-woodland primates to leopard predation and their implications for early hominins. Journal of Human Evolution 118:1–13.Google Scholar
Anderson, JR. (1998) Sleep, sleeping sites, and sleep‐related activities: awakening to their significance. American Journal of Primatology 46:63–75.3.0.CO;2-T>CrossRefGoogle ScholarPubMed
Isbell, LA, et al. (2009) Demography and life histories of sympatric patas monkeys, Erythrocebus patas, and vervets, Cercopithecus aethiops, in Laikipia, Kenya. International Journal of Primatology 30:103–124.Google Scholar
Stanford, CB. (2002) Avoiding predators: expectations and evidence in primate antipredator behavior. International Journal of Primatology 23:741–757.CrossRefGoogle Scholar
Owen-Smith, N; Mills, MGL. (2008) Shifting prey selection generates contrasting herbivore dynamics within a large‐mammal predator–prey web. Ecology 89:1120–1133.Google Scholar
Boesch, C; Boesch-Achermann, H. (2000) The Chimpanzees of the Taï Forest: Behavioural Ecology and Evolution. Oxford University Press, Oxford.Google Scholar
Fay, JMR. (1995) Leopard attack on and consumption of gorillas in the Central African Republic. Journal of Human Evolution 29:93–99.Google Scholar
Ross, C. (1998) Primate life histories. Evolutionary Anthropology: Issues, News, and Reviews 6:54–63.Google Scholar
Ross, C. (2003). Life history, infant care strategies, and brain size in primates. In Kappeler, P, et al. (eds) Primate Life Histories and Socioecology. University of Chicago Press, Chicago, pp. 54–63.Google Scholar
Harvey, PH; Clutton‐Brock, TH. (1985) Life history variation in primates. Evolution 39:559–581.Google Scholar
Nakagawa, N, et al. (2003) Life-history parameters of a wild group of West African patas monkeys (Erythrocebus patas patas). Primates 44:281–290.Google Scholar
Cords, M; Chowdhury, S. (2010) Life history of Cercopithecus mitis stuhlmanni in the Kakamega Forest, Kenya. International Journal of Primatology 31:433–455.Google Scholar
Altmann, J, et al. (1977) Life history of yellow baboons: physical development, reproductive parameters, and infant mortality. Primates 18:315–330.Google Scholar
Hill, RA, et al. (2000) Ecological and social determinants of birth intervals in baboons. Behavioral Ecology 11:560–564.CrossRefGoogle Scholar
Alberts, SC. (2019) Social influences on survival and reproduction: insights from a long‐term study of wild baboons. Journal of Animal Ecology 88:47–66.Google Scholar
Rhine, RJ, et al. (1988) Eight‐year study of social and ecological correlates of mortality among immature baboons of Mikumi National Park, Tanzania. American Journal of Primatology 16:199–212.Google Scholar
Hill, K, et al. (2001) Mortality rates among wild chimpanzees. Journal of Human Evolution 40:437–450.Google Scholar
Muller, MN; Wrangham, RW. (2014) Mortality rates among Kanyawara chimpanzees. Journal of Human Evolution 66:107–114.CrossRefGoogle ScholarPubMed
Owen-Smith, RN. (1988) Megaherbivores: The Influence of Very Large Body Size on Ecology. Cambridge University Press, Cambridge.Google Scholar
Robbins, MM; Robbins, AM. (2004) Simulation of the population dynamics and social structure of the Virunga mountain gorillas. American Journal of Primatology: Official Journal of the American Society of Primatologists 63:201–223.CrossRefGoogle ScholarPubMed
Robbins, MM, et al. (2009) Population dynamics of the Bwindi mountain gorillas. Biological Conservation 142:2886–2895.Google Scholar
Altmann, J, et al. (1985) Demography of Amboseli baboons, 1963–1983. American Journal of Primatology 8:113–125.CrossRefGoogle ScholarPubMed
Samuels, A; Altmann, J. (1991) Baboons of the Amboseli basin: demographic stability and change. International Journal of Primatology 12:1.CrossRefGoogle Scholar
Dunbar, RIM, et al. (2018) Trade-off between fertility and predation risk drives a geometric sequence in the pattern of group sizes in baboons. Biology Letters 14:20170700.Google Scholar
Isbell, LA, et al. (1990) Costs and benefits of home range shifts among vervet monkeys (Cercopithecus aethiops) in Amboseli National Park, Kenya. Behavioral Ecology and Sociobiology 27:351–358.Google Scholar
Lee, PC; Hauser, MD. (1998) Long-term consequences of changes in territory quality on feeding and reproductive strategies of vervet monkeys. Journal of Animal Ecology 67:347–358.Google Scholar
Dunbar, RIM; Mac Carron, P. (2019) Does a trade‐off between fertility and predation risk explain social evolution in baboons? Journal of Zoology 308:9–15.CrossRefGoogle Scholar
Suggested Further Reading
Klein, RG. (2009) The Human Career: Human Biological and Cultural Origins, 3rd ed. University of Chicago Press, Chicago.Google Scholar
Thompson, JC, et al. (2019) Origins of the human predatory pattern: the transition to large-animal exploitation by early humans. Current Anthropology 60:1–23.Google Scholar
Wood, B; Leakey, M. (2011) The Omo–Turkana basin fossil hominins and their contribution to our understanding of human evolution in Africa. Evolutionary Anthropology 20:264–292.Google Scholar
References
MacLatchy, LM. (2010) Hominini. In Werdelin, L; Sanders, WJ (eds) Cenozoic Mammals of Africa. University of California Press, Berkeley, pp. 471–540.Google Scholar
Bobe, R, et al. (2020) The ecology of Australopithecus anamensis in the early Pliocene of Kanapoi, Kenya. Journal of Human Evolution 140:102717.Google Scholar
Wynn, JG. (2000) Paleosols, stable carbon isotopes, and paleoenvironmental interpretation of Kanapoi, Northern Kenya. Journal of Human Evolution 39:411–432.Google Scholar
Reed, KE. (2008) Paleoecological patterns at the Hadar hominin site, Afar regional state, Ethiopia. Journal of Human Evolution 54:743–768.Google Scholar
Sponheimer, M, et al. (2013) Isotopic evidence of early hominin diets. Proceedings of the National Academy of Sciences of the United States of America 110:10513–10518.Google Scholar
Wood, B; Leakey, M. (2011) The Omo–Turkana Basin fossil hominins and their contribution to our understanding of human evolution in Africa. Evolutionary Anthropology: Issues, News, and Reviews 20:264–292.CrossRefGoogle ScholarPubMed
Bobe, R; Carvalho, S. (2019) Hominin diversity and high environmental variability in the Okote Member, Koobi Fora Formation, Kenya. Journal of Human Evolution 126:91–105.Google Scholar
Clarke, RJ; Kuman, K. (2019) The skull of StW 573, a 3.67 Ma Australopithecus prometheus skeleton from Sterkfontein caves, South Africa. Journal of Human Evolution 134:102634.Google Scholar
Crompton, RH, et al. (2018) Functional anatomy, biomechanical performance capabilities and potential niche of StW 573: an Australopithecus skeleton (circa 3.67 Ma) from Sterkfontein Member 2, and its significance for the last common ancestor of the African apes and for Hominin origins. bioRxiv:481556.Google Scholar
Pickering, R, et al. (2019) U–Pb-dated flowstones restrict South African early hominin record to dry climate phases. Nature 565:226–229.Google Scholar
Berger, LR, et al. (2010) Australopithecus sediba: a new species of Homo-like australopith from South Africa. Science 328:195–204.CrossRefGoogle ScholarPubMed
de Ruiter, DJ, et al. (2017) Late australopiths and the emergence of Homo. Annual Review of Anthropology 46:99–115.CrossRefGoogle Scholar
Villmoare, B, et al. (2015) Early Homo at 2.8 Ma from Ledi-Geraru, Afar, Ethiopia. Science 347:1352–1355.Google Scholar
DiMaggio, EN, et al. (2015) Late Pliocene fossiliferous sedimentary record and the environmental context of early Homo from Afar, Ethiopia. Science 347:1355–1359.Google Scholar
Robinson, JR; Rowan, J. (2017) Holocene paleoenvironmental change in southeastern Africa (Makwe Rockshelter, Zambia): implications for the spread of pastoralism. Quaternary Science Reviews 156:57–68.Google Scholar
Bennett, MR, et al. (2009) Early hominin foot morphology based on 1.5-million-year-old footprints from Ileret, Kenya. Science 323:1197–1201.CrossRefGoogle ScholarPubMed
Antón, SC, et al. (2014) Evolution of early Homo: an integrated biological perspective. Science 345:1236828.Google Scholar
Herries, AIR, et al. (2020) Contemporaneity of Australopithecus, Paranthropus, and early Homo erectus in South Africa. Science 368:eaaw7293.Google Scholar
Teaford, MF; Ungar, PS. (2000) Diet and the evolution of the earliest human ancestors. Proceedings of the National Academy of Sciences of the United States of America 97:13506–13511.Google Scholar
Maslin, M. (2016) The Cradle of Humanity: How the Changing Landscape of Africa Made Us So Smart. Oxford University Press, Oxford.Google Scholar
Stringer, C. (2016) The origin and evolution of Homo sapiens. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150237.Google Scholar
Hublin, J-J, et al. (2017) New fossils from Jebel Irhoud, Morocco and the pan-African origin of Homo sapiens. Nature 546:289–292.Google Scholar
Grün, R, et al. (2020) Dating the skull from Broken Hill, Zambia, and its position in human evolution. Nature 580:372–375.Google Scholar
Rightmire, GP. (1983) The Lake Ndutu cranium and early Homo sapiens in Africa. American Journal of Physical Anthropology 61:245–254.Google Scholar
Dirks, PHGM, et al. (2017) The age of Homo naledi and associated sediments in the Rising Star Cave, South Africa. Elife 6:e24231.Google Scholar
Berthaume, MA, et al. (2018) Dental topography and the diet of Homo naledi. Journal of Human Evolution 118:14–26.Google Scholar
Owen-Smith, N. (1979) Assessing the foraging efficiency of a large herbivore, the kudu. South African Journal of Wildlife Research 9:102–110.Google Scholar
Owen-Smith, RN. (2002) Adaptive Herbivore Ecology: From Resources to Populations in Variable Environments. Cambridge University Press, Cambridge.CrossRefGoogle Scholar
Owen‐Smith, N; Cooper, SM. (1989) Nutritional ecology of a browsing ruminant, the kudu (Tragelaphus strepsiceros), through the seasonal cycle. Journal of Zoology 219:29–43.Google Scholar
Laden, G; Wrangham, R. (2005) The rise of the hominids as an adaptive shift in fallback foods: plant underground storage organs (USOs) and australopith origins. Journal of Human Evolution 49:482–498.Google Scholar
Marean, CW. (1997) Hunter–gatherer foraging strategies in tropical grasslands: model building and testing in the East African Middle and Later Stone Age. Journal of Anthropological Archaeology 16:189–225.Google Scholar
O’Brien, EM; Peters, CR. (1999) Landforms, climate, ecogeographic mosaics, and the potential for hominid diversity in Pliocene Africa. In Bromage, TG; Schrenk, F (eds) African Biogeography, Climate Change and Human Evolution. Oxford University Press, Oxford, pp. 115–137.Google Scholar
Ungar, PS. (2012) Dental evidence for the reconstruction of diet in African early Homo. Current Anthropology 53:S318–S329.Google Scholar
Sponheimer, M; Lee-Thorp, JA. (2003) Differential resource utilization by extant great apes and australopithecines: towards solving the C4 conundrum. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 136:27–34.Google Scholar
Van der Merwe, NJ, et al. (2008) Isotopic evidence for contrasting diets of early hominins Homo habilis and Australopithecus boisei of Tanzania. South African Journal of Science 104:153–155.Google Scholar
Scott, RS, et al. (2005) Dental microwear texture analysis shows within-species diet variability in fossil hominins. Nature 436:693–695.Google Scholar
Dominy, NJ, et al. (2008) Mechanical properties of plant underground storage organs and implications for dietary models of early hominins. Evolutionary Biology 35:159–175.Google Scholar
Sponheimer, M; Lee-Thorp, JA. (1999) Oxygen isotopes in enamel carbonate and their ecological significance. Journal of Archaeological Science 26:723–728.Google Scholar
Sponheimer, M, et al. (2006) Isotopic evidence for dietary variability in the early hominin Paranthropus robustus. Science 314:980–982.Google Scholar
Patterson, DB, et al. (2019) Comparative isotopic evidence from East Turkana supports a dietary shift within the genus Homo. Nature Ecology & Evolution 3:1048–1056.Google Scholar
Gibbon, RJ, et al. (2014) Cosmogenic nuclide burial dating of hominin-bearing Pleistocene cave deposits at Swartkrans, South Africa. Quaternary Geochronology 24:10–15.Google Scholar
Blumenschine, RJ, et al. (1987) Characteristics of an early hominid scavenging niche [and comments and reply]. Current Anthropology 28:383–407.Google Scholar
Blumenschine, RJ; Cavallo, JA. (1992) Scavenging and human evolution. Scientific American 267:90–97.Google Scholar
Domínguez-Rodrigo, M. (2001) A study of carnivore competition in riparian and open habitats of modern savannas and its implications for hominid behavioral modelling. Journal of Human Evolution 40:77–98.Google Scholar
Houston, DC. (1979) The adaptations of scavengers. In Sinclair, ARE; Norton-Griffiths, M (eds) Serengeti: Dynamics of an Ecosystem. University of Chicago Press, Chicago, pp. 263–286.Google Scholar
Schaller, GB; Lowther, GR. (1969) The relevance of carnivore behavior to the study of early hominids. Southwestern Journal of Anthropology 25:307–341.Google Scholar
Ogutu, JO, et al. (2012) Dynamics of ungulates in relation to climatic and land use changes in an insularized African savanna ecosystem. Biodiversity and Conservation 21:1033–1053.Google Scholar
Owen-Smith, N; Mills, MGL. (2006) Manifold interactive influences on the population dynamics of a multispecies ungulate assemblage. Ecological Monographs 76:73–92.Google Scholar
Teaford, MF, et al. (2002) Paleontological evidence for the diets of African Plio-Pleistocene hominins with special reference to early Homo. In Ungar, PS; Teaford, MF (eds) Human Diet: Its Origin and Evolution. Bergin & Garvey, Westport, pp. 143–166.Google Scholar
Thompson, JC, et al. (2019) Origins of the human predatory pattern: the transition to large-animal exploitation by early hominins. Current Anthropology 60:1–23.Google Scholar
Pobiner, BL. (2020) The zooarchaeology and paleoecology of early hominin scavenging. Evolutionary Anthropology: Issues, News, and Reviews 29:68–82.Google Scholar
Cooper, SM, et al. (1999) A seasonal feast: long‐term analysis of feeding behaviour in the spotted hyaena (Crocuta crocuta). African Journal of Ecology 37:149–160.Google Scholar
Bramble, DM; Lieberman, DE. (2004) Endurance running and the evolution of Homo. Nature 432:345–352.Google Scholar
Roach, NT, et al. (2013) Elastic energy storage in the shoulder and the evolution of high-speed throwing in Homo. Nature 498:483–486.Google Scholar
Bunn, HT; Gurtov, AN. (2014) Prey mortality profiles indicate that Early Pleistocene Homo at Olduvai was an ambush predator. Quaternary International 322:44–53.Google Scholar
Domínguez-Rodrigo, M, et al. (2014) On meat eating and human evolution: a taphonomic analysis of BK4b (Upper Bed II, Olduvai Gorge, Tanzania), and its bearing on hominin megafaunal consumption. Quaternary International 322:129–152.Google Scholar
Domínguez-Rodrigo, M. (2002) Hunting and scavenging by early humans: the state of the debate. Journal of World Prehistory 16:1–54.Google Scholar
Domínguez‐Rodrigo, M; Pickering, TR. (2003) Early hominid hunting and scavenging: a zooarcheological review. Evolutionary Anthropology: Issues, News, and Reviews 12:275–282.Google Scholar
Parkinson, JA. (2018) Revisiting the hunting-versus-scavenging debate at FLK Zinj: a GIS spatial analysis of bone surface modifications produced by hominins and carnivores in the FLK 22 assemblage, Olduvai Gorge, Tanzania. Palaeogeography, Palaeoclimatology, Palaeoecology 511:29–51.Google Scholar
Pante, MC, et al. (2018) The carnivorous feeding behavior of early Homo at HWK EE, Bed II, Olduvai Gorge, Tanzania. Journal of Human Evolution 120:215–235.Google Scholar
Pobiner, BL, et al. (2008) New evidence for hominin carcass processing strategies at 1.5 Ma, Koobi Fora, Kenya. Journal of Human Evolution 55:103–130.Google Scholar
Oliver, JS, et al. (2019) Bovid mortality patterns from Kanjera South, Homa Peninsula, Kenya and FLK-Zinj, Olduvai Gorge, Tanzania: evidence for habitat mediated variability in Oldowan hominin hunting and scavenging behavior. Journal of Human Evolution 131:61–75.Google Scholar
Organista, E, et al. (2019) Taphonomic analysis of the level 3b fauna at BK, Olduvai Gorge. Quaternary International 526:116–128.Google Scholar
Pickering, TR, et al. (2008) Testing the ‘shift in the balance of power’ hypothesis at Swartkrans, South Africa: hominid cave use and subsistence behavior in the Early Pleistocene. Journal of Anthropological Archaeology 27:30–45.Google Scholar
Kuman, K, et al. (2018) The Oldowan industry from Swartkrans cave, South Africa, and its relevance for the African Oldowan. Journal of Human Evolution 123:52–69.Google Scholar
Ferraro, JV, et al. (2013) Earliest archeological evidence of persistent hominin carnivory. PLoS One 8:e62174.Google Scholar
Patterson, DB, et al. (2017) Ecosystem evolution and hominin paleobiology at East Turkana, northern Kenya between 2.0 and 1.4 Ma. Palaeogeography, Palaeoclimatology, Palaeoecology 481:1–13.Google Scholar
Van Pletzen-Vos, L, et al. (2019) Revisiting Klasies River: a report on the large mammal remains from the Deacon excavations of Klasies River main site, South Africa. South African Archaeological Bulletin 74:127–137.Google Scholar
Organista, E, et al. (2016) Did Homo erectus kill a Pelorovis herd at BK (Olduvai Gorge)? A taphonomic study of BK5. Archaeological and Anthropological Sciences 8:601–624.Google Scholar
De Heinzelin, J, et al. (1999) Environment and behavior of 2.5-million-year-old Bouri hominids. Science 284:625–629.Google Scholar
Domínguez-Rodrigo, M, et al. (2005) Cutmarked bones from Pliocene archaeological sites at Gona, Afar, Ethiopia: implications for the function of the world’s oldest stone tools. Journal of Human Evolution 48:109–121.Google Scholar
McPherron, SP, et al. (2010) Evidence for stone-tool-assisted consumption of animal tissues before 3.39 million years ago at Dikika, Ethiopia. Nature 466:857–860.Google Scholar
Sahle, Y, et al. (2017) Hominid butchers and biting crocodiles in the African Plio–Pleistocene. Proceedings of the National Academy of Sciences of the United States of America 114:13164–13169.Google Scholar
Dominguez-Rodrigo, M. (2009) Are all Oldowan sites palimpsests? If so, what can they tell us about hominin carnivory? In Hovers, E; Braun, DR (eds) Interdisciplinary Approaches to the Oldowan. Springer, Berlin, pp. 129–147.Google Scholar
Antón, SC; Snodgrass, J. (2012) Origins and evolution of genus Homo: new perspectives. Current Anthropology 53:S479–S496.Google Scholar
Aiello, LC; Wheeler, P. (1995) The expensive-tissue hypothesis: the brain and the digestive system in human and primate evolution. Current Anthropology 36:199–221.Google Scholar
Isler, K; van Schaik, CP. (2009) The expensive brain: a framework for explaining evolutionary changes in brain size. Journal of Human Evolution 57:392–400.Google Scholar
Schwartz, GT. (2012) Growth, development, and life history throughout the evolution of Homo. Current Anthropology 53:S395–S408.Google Scholar
Kaplan, H, et al. (2000) A theory of human life history evolution: diet, intelligence, and longevity. Evolutionary Anthropology: Issues, News, and Reviews 9:156–185.Google Scholar
Hawkes, K, et al. (1998) Grandmothering, menopause, and the evolution of human life histories. Proceedings of the National Academy of Sciences of the United States of America 95:1336–1339.Google Scholar
Hawkes, K, et al. (2003) Human life histories: primate tradeoffs, grandmothering socioecology, and the fossil record. In Kappela, P; Pereira, ME (eds) Primate Life Histories and Socioecology. University of Chicago Press, Chicago, pp. 204–227.Google Scholar
Meindl, RS, et al. (2018) Early hominids may have been weed species. Proceedings of the National Academy of Sciences of the United States of America 115:1244–1249.Google Scholar
Owen‐Smith, N, et al. (2005) Correlates of survival rates for 10 African ungulate populations: density, rainfall and predation. Journal of Animal Ecology 74:774–788.Google Scholar
Packer, C, et al. (2011) Fear of darkness, the full moon and the nocturnal ecology of African lions. PLoS One 6:e22285.Google Scholar
Wrangham, RW, et al. (1999) The raw and the stolen: cooking and the ecology of human origins. Current Anthropology 40:567–594.Google Scholar
Wrangham, R. (2017) Control of fire in the Paleolithic: evaluating the cooking hypothesis. Current Anthropology 58:S303–S313.Google Scholar
Hlubik, S, et al. (2019) Hominin fire use in the Okote member at Koobi Fora, Kenya: new evidence for the old debate. Journal of Human Evolution 133:214–229.Google Scholar
Brain, CK; Sillent, A. (1988) Evidence from the Swartkrans cave for the earliest use of fire. Nature 336:464–466.Google Scholar
Bellomo, RV. (1994) Methods of determining early hominid behavioral activities associated with the controlled use of fire at FxJj 20 Main, Koobi Fora, Kenva. Journal of Human Evolution 27:173–195.Google Scholar
Gowlett, JAJ. (2016) The discovery of fire by humans: a long and convoluted process. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150164.Google Scholar
Berna, F, et al. (2012) Microstratigraphic evidence of in situ fire in the Acheulean strata of Wonderwerk Cave, Northern Cape province, South Africa. Proceedings of the National Academy of Sciences of the United States of America 109:E1215–E1220.Google Scholar
Suggested Further Reading
Barham, L; Mitchell, P. (2008) The First Africans. African Archaeology from the Earliest Toolmakers to the Most Recent Foragers. Cambridge University Press, Cambridge.Google Scholar
Plummer, T. (2004) Flaked stones and old bones. Biological and cultural evolution at the dawn of technology. Yearbook of Physical Anthropology 47:118–164.Google Scholar
References
Rightmire, GP. (2004) Brain size and encephalization in early to mid‐Pleistocene Homo. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 124:109–123.Google Scholar
Braun, DR, et al. (2019) Earliest known Oldowan artifacts at >2.58 Ma from Ledi-Geraru, Ethiopia, highlight early technological diversity. Proceedings of the National Academy of Sciences of the United States of America 116:11712–11717.Google Scholar
Semaw, S, et al. (1997) 2.5-million-year-old stone tools from Gona, Ethiopia. Nature 385:333–336.Google Scholar
Villmoare, B, et al. (2015) Early Homo at 2.8 Ma from Ledi-Geraru, Afar, Ethiopia. Science 347:1352–1355.Google Scholar
Kuman, K. (2014) Oldowan industrial complex. In Smith, C (ed.) Encyclopedia of Global Archaeology. Springer, New York, pp. 5560–5569.Google Scholar
Chazan, M, et al. (2012) The Oldowan horizon in Wonderwerk Cave (South Africa): archaeological, geological, paleontological and paleoclimatic evidence. Journal of Human Evolution 63:859–866.Google Scholar
Kuman, K, et al. (2018) The Oldowan industry from Swartkrans cave, South Africa, and its relevance for the African Oldowan. Journal of Human Evolution 123:52–69.Google Scholar
Sahnouni, M, et al. (2018) 1.9-million- and 2.4-million-year-old artifacts and stone tool-cutmarked bones from Ain Boucherit, Algeria. Science 362:1297–1301.Google Scholar
Harmand, S, et al. (2015) 3.3-million-year-old stone tools from Lomekwi 3, West Turkana, Kenya. Nature 521:310–315.Google Scholar
Dominguez-Rodrigo, M; Alcalá, L. (2019) Pliocene archaeology at Lomekwi 3? New evidence fuels more skepticism. Journal of African Archaeology 17:173–176.Google Scholar
Archer, W, et al. (2020) What is ‘in situ’? A reply to Harmand et al. (2015). Journal of Human Evolution 142:102740.Google Scholar
Panger, MA, et al. (2002) Older than the Oldowan? Rethinking the emergence of hominin tool use. Evolutionary Anthropology: Issues, News, and Reviews 11:235–245.Google Scholar
Boesch, C; Boesch-Achermann, H. (2000) The Chimpanzees of the Taï Forest: Behavioural Ecology and Evolution. Oxford University Press, Oxford.Google Scholar
Stammers, RC, et al. (2018) The first bone tools from Kromdraai and stone tools from Drimolen, and the place of bone tools in the South African Earlier Stone Age. Quaternary International 495:87–101.Google Scholar
Plummer, T. (2004) Flaked stones and old bones: biological and cultural evolution at the dawn of technology. American Journal of Physical Anthropology 125:118–164.Google Scholar
Chazan, M, et al. (2008) Radiometric dating of the Earlier Stone Age sequence in excavation I at Wonderwerk Cave, South Africa: preliminary results. Journal of Human Evolution 55:1–11.Google Scholar
Kuman, K. (2014) The Acheulean industrial complex. In Smith, C (ed.) Encyclopedia of Global Archaeology. Springer, New York, pp. 7–18.Google Scholar
De la Torre, I. (2016) The origins of the Acheulean: past and present perspectives on a major transition in human evolution. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150245.Google Scholar
Uribelarrea, D, et al. (2019) A geoarchaeological reassessment of the co-occurrence of the oldest Acheulean and Oldowan in a fluvial ecotone from lower middle Bed II (1.7 ma) at Olduvai Gorge (Tanzania). Quaternary International 526:39–48.Google Scholar
Dominguez-Rodrigo, M; Pickering, TR. (2017) The meat of the matter: an evolutionary perspective on human carnivory. Azania: Archaeological Research in Africa 52:4–32.Google Scholar
Organista, E, et al. (2019) Taphonomic analysis of the level 3b fauna at BK, Olduvai Gorge. Quaternary International 526:116–128.Google Scholar
Smith, GM, et al. (2019) Subsistence strategies throughout the African Middle Pleistocene: faunal evidence for behavioral change and continuity across the Earlier to Middle Stone Age transition. Journal of Human Evolution 127:1–20.Google Scholar
Tryon, CA; McBrearty, S. (2002) Tephrostratigraphy and the Acheulian to Middle Stone Age transition in the Kapthurin formation, Kenya. Journal of Human Evolution 42:211–235.Google Scholar
Potts, R, et al. (2020) Increased ecological resource variability during a critical transition in hominin evolution. Science Advances 6:eabc8975.Google Scholar
Basell, LS. (2008) Middle Stone Age (MSA) site distributions in eastern Africa and their relationship to Quaternary environmental change, refugia and the evolution of Homo sapiens. Quaternary Science Reviews 27:2484–2498.Google Scholar
Blinkhorn, J; Grove, M. (2018) The structure of the Middle Stone Age of eastern Africa. Quaternary Science Reviews 195:1–20.Google Scholar
Scerri, EML. (2017) The North African Middle Stone Age and its place in recent human evolution. Evolutionary Anthropology: Issues, News, and Reviews 26:119–135.Google Scholar
Lahr, MM;Foley, RA. (2016) Human evolution in late Quaternary eastern Africa. In Jones, SC; Stewart, BA (eds) Africa from MIS 6-2. Springer, Dordrecht, pp. 215–231.Google Scholar
Kusimba, SB. (1999) Hunter–gatherer land use patterns in Later Stone Age East Africa. Journal of Anthropological Archaeology 18:165–200.Google Scholar
Kuman, K, et al. (2020) The Fauresmith of South Africa: a new assemblage from Canteen Kopje and significance of the technology in human and cultural evolution. Journal of Human Evolution 148:102884.Google Scholar
Wilkins, J, et al. (2012) Evidence for early hafted hunting technology. Science 338:942–946.CrossRefGoogle ScholarPubMed
Robbins, LH, et al. (2016) The Kalahari during MIS 6-2 (190–12 ka): archaeology, paleoenvironment, and population dynamics. In Jones, SC; Stewart, BA (eds) Africa from MIS 6-2. Springer, Dordrecht, pp. 175–193.Google Scholar
Barham, L; Mitchell, P. (1992) The First Africans: African Archaeology from the Earliest Toolmakers to Most Recent Foragers. Cambridge University Press, Cambridge.Google Scholar
Marean, CW, et al. (2007) Early human use of marine resources and pigment in South Africa during the Middle Pleistocene. Nature 449:905–908.Google Scholar
Wurz, S. (2016) Development of the archaeological record during the middle stone age. In Knight, J; Grab, SW (eds) Quaternary Environmental Change in Southern Africa: Physical and Human Dimensions. Cambridge University Press, Cambridge, pp. 371–384.Google Scholar
Marean, CW. (2015) An evolutionary anthropological perspective on modern human origins. Annual Review of Anthropology 44:533–556.Google Scholar
Marean, CW. (2016) The transition to foraging for dense and predictable resources and its impact on the evolution of modern humans. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150239.Google Scholar
Reynard, JP; Henshilwood, CS. (2019) Environment versus behaviour: zooarchaeological and taphonomic analyses of fauna from the Still Bay layers at Blombos Cave, South Africa. Quaternary International 500:159–171.Google Scholar
Reynard, JP; Wurz, S. (2020) The palaeoecology of Klasies River, South Africa: an analysis of the large mammal remains from the 1984–1995 excavations of Cave 1 and 1A. Quaternary Science Reviews 237:106301.Google Scholar
Larbey, C, et al. (2019) Cooked starchy food in hearths ca. 120 kya and 65 kya (MIS 5e and MIS 4) from Klasies River Cave, South Africa. Journal of Human Evolution 131:210–227.Google Scholar
d’Errico, F, et al. (2017) Identifying early modern human ecological niche expansions and associated cultural dynamics in the South African Middle Stone Age. Proceedings of the National Academy of Sciences 114:7869–7876.Google Scholar
Backwell, L, et al. (2008) Middle stone age bone tools from the Howiesons Poort layers, Sibudu Cave, South Africa. Journal of Archaeological Science 35:1566–1580.Google Scholar
Lombard, M. (2011) Quartz-tipped arrows older than 60 ka: further use-trace evidence from Sibudu, KwaZulu-Natal, South Africa. Journal of Archaeological Science 38:1918–1930.Google Scholar
Bradfield, J, et al. (2020) Further evidence for bow hunting and its implications more than 60 000 years ago: results of a use-trace analysis of the bone point from Klasies River Main site, South Africa. Quaternary Science Reviews 236:106295.Google Scholar
Grün, R; Beaumont, P. (2001) Border Cave revisited: a revised ESR chronology. Journal of Human Evolution 40:467–482.Google Scholar
Bousman, CB; Brink, JS. (2018) The emergence, spread, and termination of the Early Later Stone Age event in South Africa and southern Namibia. Quaternary International 495:116–135.Google Scholar
d’Errico, F, et al. (2012) Early evidence of San material culture represented by organic artifacts from Border Cave, South Africa. Proceedings of the National Academy of Sciences of the United States of America 109:13214–13219.Google Scholar
Klein, RG. (1979) Stone Age exploitation of animals in southern Africa: Middle Stone Age people living in southern Africa more than 30,000 years ago exploited local animals less effectively than the Later Stone Age people who succeeded them. American Scientist 67:151–160.Google Scholar
Mitchell, PJ. (2016) Later Stone Age hunter-gatherers and herders. In Knight, J; Grab, SW (eds) Quaternary Environmental Change in Southern Africa. Cambridge University Press, Cambridge, pp. 385–396.Google Scholar
Bae, CJ, et al. (2017) On the origin of modern humans: Asian perspectives. Science 358:eaai9067.Google Scholar
Henn, BM, et al. (2011) Hunter-gatherer genomic diversity suggests a southern African origin for modern humans. Proceedings of the National Academy of Sciences of the United States of America 108:5154–5162.Google Scholar
Klein, RG. (2019) Population structure and the evolution of Homo sapiens in Africa. Evolutionary Anthropology: Issues, News, and Reviews 28:179–188.Google Scholar
O’Driscoll, CA; Thompson, JC. (2018) The origins and early elaboration of projectile technology. Evolutionary Anthropology: Issues, News, and Reviews 27:30–45.Google Scholar
Shea, JJ; Sisk, ML. (2010) Complex projectile technology and Homo sapiens dispersal into western Eurasia. PaleoAnthropology 2010:100–122.Google Scholar
Rito, T, et al. (2019) A dispersal of Homo sapiens from southern to eastern Africa immediately preceded the out-of-Africa migration. Scientific Reports 9:1–10.Google Scholar
Garcea, EAA. (2012) Successes and failures of human dispersals from North Africa. Quaternary International 270:119–128.Google Scholar
Langley, MC, et al. (2016) Poison arrows and bone utensils in late Pleistocene eastern Africa: evidence from Kuumbi Cave, Zanzibar. Azania: Archaeological Research in Africa 51:155–177.Google Scholar
Shipton, C, et al. (2018) 78,000-year-old record of Middle and Later Stone Age innovation in an East African tropical forest. Nature Communications 9:1–8.Google Scholar
Faith, JT, et al. (2018) Plio–Pleistocene decline of African megaherbivores: No evidence for ancient hominin impacts. Science 362:938–941.Google Scholar
Owen-Smith, N. (1999) The interaction of humans, megaherbivores, and habitats in the late Pleistocene extinction event. In MacPhee, RDE (ed.) Extinctions in Near Time. Kluwer, New York, pp. 57–69.Google Scholar
Delegorgue, A. (1990) Adulphe Delegorgue’s Travels in Southern Africa. University of Natal Press, Durban.Google Scholar
Tryon, CA. (2019) The Middle/Later Stone Age transition and cultural dynamics of late Pleistocene East Africa. Evolutionary Anthropology: Issues, News, and Reviews 28:267–282.Google Scholar
Leakey, M. (1983) Africa’s Vanishing Art. The Rock Paintings of Tanzania. Doubleday, New York.Google Scholar
Scally, A; Durbin, R. (2012) Revising the human mutation rate: implications for understanding human evolution. Nature Reviews Genetics 13:745–753.Google Scholar
Fu, Q, et al. (2013) A revised timescale for human evolution based on ancient mitochondrial genomes. Current Biology 23:553–559.Google Scholar
Fan, S, et al. (2019) African evolutionary history inferred from whole genome sequence data of 44 indigenous African populations. Genome Biology 20:1–14.Google Scholar
Yost, CL, et al. (2018) Subdecadal phytolith and charcoal records from Lake Malawi, East Africa imply minimal effects on human evolution from the ∼74 ka Toba supereruption. Journal of Human Evolution 116:75–94.Google Scholar
Campbell, MC; Tishkoff, SA. (2010) The evolution of human genetic and phenotypic variation in Africa. Current Biology 20:R166–R173.Google Scholar
Schlebusch, CM, et al. (2017) Southern African ancient genomes estimate modern human divergence to 350,000 to 260,000 years ago. Science 358:652–655.Google Scholar
Chan, EKF, et al. (2019) Human origins in a southern African palaeo-wetland and first migrations. Nature 575:185–189.Google Scholar
Blome, MW, et al. (2012) The environmental context for the origins of modern human diversity: a synthesis of regional variability in African climate 150,000–30,000 years ago. Journal of Human Evolution 62:563–592.Google Scholar
Rito, T, et al. (2013) The first modern human dispersals across Africa. PLoS One 8:e80031.Google Scholar
Marlowe, FW; Berbesque, JC. (2009) Tubers as fallback foods and their impact on Hadza hunter‐gatherers. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 140:751–758.Google Scholar
Marlowe, F. (2010) The Hadza: Hunter-Gatherers of Tanzania. University of California Press, Berkeley.Google Scholar
Antón, SC; Josh Snodgrass, J. (2012) Origins and evolution of genus Homo: new perspectives. Current Anthropology 53:S479–S496.Google Scholar
Smith, B. (2006) The rock art of sub-Saharan Africa. In Blundell, G (ed.) Origins. The Story of the Emergence of Humans and Humanity in Africa. Double Storey Books, Cape Town, pp. 93–101.Google Scholar
Henshilwood, CS, et al. (2018) An abstract drawing from the 73,000-year-old levels at Blombos Cave, South Africa. Nature 562:115–118.Google Scholar
Stewart, BA, et al. (2016) Follow the Senqu: Maloti–Drakensberg paleoenvironments and implications for early human dispersals into mountain systems. In Jones, SC; Stewart, BA (eds) Africa from MIS 6-2. Springer, Dordrecht, pp. 247–271.Google Scholar
Oliveira, S, et al. (2018) Matriclans shape populations: insights from the Angolan Namib Desert into the maternal genetic history of southern Africa. American Journal of Physical Anthropology 165:518–535.Google Scholar
Eastwood, EB; Eastwood, C. (2006) Capturing the Spoor: An Exploration of Southern African Rock Art. New Africa Books, Claremont.Google Scholar
Faith, JT, et al. (2015) Paleoenvironmental context of the Middle Stone Age record from Karungu, Lake Victoria Basin, Kenya, and its implications for human and faunal dispersals in East Africa. Journal of Human Evolution 83:28–45.Google Scholar
Brass, M. (2018) Early North African cattle domestication and its ecological setting: a reassessment. Journal of World Prehistory 31:81–115.Google Scholar
Mitchell, P. (2006) Rediscovering Africa. In Blundell, G (ed.) Origins. The Story of the Emergence of Humans and Humanity in Africa. Double Storey Books, CapeTown, pp. 116–165.Google Scholar
Marshall, F; Hildebrand, E. (2002) Cattle before crops: the beginnings of food production in Africa. Journal of World Prehistory 16:99–143.Google Scholar
Chritz, KL, et al. (2019) Climate, ecology, and the spread of herding in eastern Africa. Quaternary Science Reviews 204:119–132.Google Scholar
Prendergast, ME, et al. (2019) Ancient DNA reveals a multistep spread of the first herders into sub-Saharan Africa. Science 365:eaaw6275.Google Scholar
Gifford-Gonzalez, D. (2000) Animal disease challenges to the emergence of pastoralism in sub-Saharan Africa. African Archaeological Review 17:95–139.CrossRefGoogle Scholar
Li, S, et al. (2014) Genetic variation reveals large-scale population expansion and migration during the expansion of Bantu-speaking peoples. Proceedings of the Royal Society B: Biological Sciences 281:20141448.Google Scholar
Sadr, K. (2015) Livestock first reached southern Africa in two separate events. PLoS One 10:e0134215.Google Scholar
Lander, F; Russell, T. (2018) The archaeological evidence for the appearance of pastoralism and farming in southern Africa. PLoS One 13:e0198941.Google Scholar
Breton, G, et al. (2014) Lactase persistence alleles reveal partial East African ancestry of southern African Khoe pastoralists. Current Biology 24:852–858.Google Scholar
Robinson, JR; Rowan, J. (2017) Holocene paleoenvironmental change in southeastern Africa (Makwe Rockshelter, Zambia): implications for the spread of pastoralism. Quaternary Science Reviews 156:57–68.Google Scholar
Suggested Further Reading
Potts, R. (2012) Environmental and behavioural evidence pertaining to the evolution of early Homo. Current Anthropology 53(Suppl. 6):S299–S317.Google Scholar
Scerri, EML., et al. (2018) Did our species evolve in subdivided populations across Africa, and why does it matter? Trends in Ecology and Evolution 33:582–592.Google Scholar
Stringer, C. (2016) The origin and evolution of Homo sapiens. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150237Google Scholar
References
Wood, BK; Boyle, E. (2016) Hominin taxic diversity: fact or fantasy? American Journal of Physical Anthropology 159:37–78.Google Scholar
Bobe, R; Carvalho, S. (2019) Hominin diversity and high environmental variability in the Okote Member, Koobi Fora Formation, Kenya. Journal of Human Evolution 126:91–105.Google Scholar
Stringer, C. (2016) The origin and evolution of Homo sapiens. Philosophical Transactions of the Royal Society B: Biological Sciences 371:20150237.Google Scholar
Klein, RG. (2019) Population structure and the evolution of Homo sapiens in Africa. Evolutionary Anthropology: Issues, News, and Reviews 28:179–188.Google Scholar
Scerri, EML, et al. (2018) Did our species evolve in subdivided populations across Africa, and why does it matter? Trends in Ecology & Evolution 33:582–594.Google Scholar
Arnold, ML. (2009) Reticulate Evolution and Humans: Origins and Ecology. Oxford University Press, Oxford.Google Scholar
Winder, IC; Winder, NP. (2014) Reticulate evolution and the human past: an anthropological perspective. Annals of Human Biology 41:300–311.Google Scholar
Wood, B. (2010) Reconstructing human evolution: achievements, challenges, and opportunities. Proceedings of the National Academy of Sciences of the United States of America 107:8902–8909.Google Scholar
Fischer, J, et al. (2019) The natural history of model organisms: insights into the evolution of social systems and species from baboon studies. Elife 8:e50989.Google Scholar
Potts, R. (1998) Environmental hypotheses of hominin evolution. American Journal of Physical Anthropology: The Official Publication of the American Association of Physical Anthropologists 107:93–136.Google Scholar
Potts, R. (2013) Hominin evolution in settings of strong environmental variability. Quaternary Science Reviews 73:1–13.Google Scholar
Ogutu, JO; Owen‐Smith, N. (2003) ENSO, rainfall and temperature influences on extreme population declines among African savanna ungulates. Ecology Letters 6:412–419.Google Scholar
Reznick, DN, et al. (2019) From low to high gear: there has been a paradigm shift in our understanding of evolution. Ecology Letters 22:233–244.Google Scholar
Grant, PR, et al. (2017) Evolution caused by extreme events. Philosophical Transactions of the Royal Society B: Biological Sciences 372:20160146.Google Scholar
Reznick, DN, et al. (1997) Evaluation of the rate of evolution in natural populations of guppies (Poecilia reticulata). Science 275:1934–1937.Google Scholar
Young, TP. (1994) Natural die‐offs of large mammals: implications for conservation. Conservation Biology 8:410–418.Google Scholar
Dublin, HT; Ogutu, JO. (2015) Population regulation of African buffalo in the Mara–Serengeti ecosystem. Wildlife Research 42:382–393.Google Scholar
Smit, IPJ; Bond, WJ. (2020) Observations on the natural history of a savanna drought. African Journal of Range & Forage Science 37:119–136.Google Scholar
Spinage, CA; Matlhare, JM. (1992) Is the Kalahari cornucopia fact or fiction? A predictive model. Journal of Applied Ecology 29:605–610.Google Scholar
Walker, BH, et al. (1987) To cull or not to cull: lessons from a southern African drought. Journal of Applied Ecology 24:381–401.Google Scholar
Owen-Smith, RN. (2002) Adaptive Herbivore Ecology: From Resources to Populations in Variable Environments. Cambridge University Press, Cambridge.Google Scholar
Gani, MR; Gani, NDS. (2008) Tectonic hypotheses of human evolution. Geotimes 53:34–39.Google Scholar
Owen‐Smith, N. (2013) Contrasts in the large herbivore faunas of the southern continents in the late Pleistocene and the ecological implications for human origins. Journal of Biogeography 40:1215–1224.Google Scholar
Reference
Veldhuis, MP, et al. (2019) Cross-boundary human impacts compromise the Serengeti–Mara ecosystem. Science 363:1424–1428.Google Scholar