Elliptical Fourier analysis of molar outlines in Late Pliocene Parapapio whitei from Makapansgat Limeworks, South Africa

Alexander C. Kim; Frank L’Engle Williams

doi:10.18778/1898-6773.87.4.03

Authors

Alexander C. Kim Hagerman Fossil Beds National Monument Idaho, Minidoka National Historic Site, Craters of the Moon National Monument and Preserve, National Park Service, Hagerman, ID 83332 USA https://orcid.org/0009-0005-1263-9922
Frank L’Engle Williams Dental Microwear Laboratory, Department of Anthropology, College of Arts and Sciences, Georgia State University, Atlanta, GA 30303 USA https://orcid.org/0000-0003-3649-3989

DOI:

https://doi.org/10.18778/1898-6773.87.4.03

Keywords:

MP 221, MP 223, Cercocebus agilis, Colobus angolensis, Papio anubis, Australopithecus africanus

Abstract

Introduction: Alongside Australopithecus africanus at Makapansgat South Africa, dated to nearly 3 million years before present, are remnants of Parapapio (Cercopithecinae). The extreme variability of this fossil assemblage has stymied efforts to specify the taxon parameters for Parapapio, which are attributed to at least three species.

Study aims: The first maxillary molar occlusal outlines of the two most complete fossils attributed to Parapapio whitei are compared. The degree of group cohesion in Parapapio whitei is evaluated using three extant cercopithecoid taxa.

Methods and Materials: The fossil crania from Makapangsat Members 3–4, MP 221 and MP 223, both referred to Parapapio whitei, are compared to three extant cercopithecoid taxa including Cercocebus agilis (n=8), Colobus angolensis (n=8) and Papio anubis (n=8). Molar shape is captured using elliptical Fourier analysis of occlusal outlines and molar size dimensions are estimated from measuring software.

Results: MP 223 is larger than MP 221 in occlusal area and the minimum buccolingual length of M1 although the variability between the two Parapapio whitei fossils is commensurate with that observed in Papio anubis. MP 221 and MP 223 are more similar to one another in occlusal outline shape than to any other taxon. However, MP 223 falls consistently closer to Papio anubis whereas MP 221 resembles Papio anubis in some respects and Cercocebus agilis in others.

Conclusion: MP 221 and MP 223 likely belong to a single species with no clear affinity to any of the extant taxa examined. The differences in molar size characterizing Parapapio whitei, a terrestrial forager, is potentially indicative of male bimaturatism or ecological variability which may also characterize Australopithecus africanus at Makapansgat.

Downloads

Download data is not yet available.

References

Aguirre E. 1970. Identificacion de “Paranthropus” en Makapansgat. In: Anonymous XI Congreso Nacional de Arqueología. Zaragoza: Octavio y Féliz. 98–124.
View in Google Scholar

Arbor T. 2010. The Makapansgat hominins: a descriptive and comparative morphological study. Ph.D. dissertation, Washington University, St. Louis.
View in Google Scholar

Benefit BR. 1999. Biogeography, dietary specialization and the diversification of African Plio-Pleistocene monkeys. In: TG Bromage and F. Schrenk, editors. African Biogeography, Climate Change, and Human Evolution. Oxford: Oxford University Press. 172–188.
View in Google Scholar

Brain CK. 1981. The Hunters or the Hunted? An Introduction to African Cave Taphonomy. Chicago: University of Chicago Press.
View in Google Scholar

Broom R, Jensen JS. 1946. A new fossil baboon from the caves at Potgietersrust. Ann Transvaal Mus 20:337–340.
View in Google Scholar

Brophy JK, de Ruiter DJ, Athrey AS, de Witt TJ. 2014. Quantitative morphological analysis of bovid teeth and implications for paleoenvironmental reconstruction of Plovers Lake, Gauteng Province, South Africa. J Archaeol Sci 41:376–388. http://doi.org/10.1016/j.jas.2013.08.005
View in Google Scholar

Bryan BC, Williams FL. 2021. Comparing maxillary first molar crown shape using elliptical Fourier analysis in the Late Neolithic cave burials of Belgium. Anthropol Rev 84(1):1–15. http://doi.org/10.2478/anre-2021-0001
View in Google Scholar

Claude M. 2013. Log-shape ratios, Procrustes superimposition, Elliptic Fourier Analysis: three worked examples in R. Hystrix 24(1):94–102. https://doi.org/10.4404/hystrix-24.1-6316
View in Google Scholar

Codron D, Luyt J, Lee-Thorp JA, Sponheimer M, De Ruiter D, Codron J. 2005. Utilization of savanna-based resources by Plio-Pleistocene baboons. S Afri J Sci 101(5–6):245–248. https://doi.org/10.5167/uzh-25352
View in Google Scholar

Corny J, Détroit F. 2014. Technical Note: Anatomic identification of isolated modern human molars: testing Procrustes aligned outlines as a standardization procedure for elliptic Fourier analysis. Am J Phys Anthropol 153(2):314–322. https://doi.org/10.1002/ajpa.22428
View in Google Scholar

Delson E. 1984. Cercopithecid biochronology of the African Plio-Pleistocene: correlations among eastern and southern hominid-bearing locaties. Cour Forsch-Inst Seneckenberg 69:199–218.
View in Google Scholar

Delson E. 1988. Chronology of South African Australopith site units. In: FE Grine, editor. Evolutionary History of the Robust Australopithecines. New York: Aldine. 317–324.
View in Google Scholar

Delson E. 1992. Evolution of Old World monkeys. In: JS Jones, RD Martin, D Pilbeam and S Bunney, editors. The Cambridge Encyclopedia of Human Evolution. Cambridge: Cambridge University Press. 217–222.
View in Google Scholar

Delson E, Terranova CJ, Jungers WL, Sargis EJ, Jablonski NG, Dechow PC. 2000. Body Mass in Cercopithecidae (Primates, Mammalia): Estimation and Scaling in Extinct and Extant Taxa. New York: Anthropological Papers of the American Museum of Natural History (Vol. 83).
View in Google Scholar

Elton E. 2007. Environmental correlates of the cercopithecoid radiations. Folia Primatol 78:244–364. http://doi.org/10.1159/000105149
View in Google Scholar

Eisenhart WL. 1974. The fossil cercopithecoids of Makapansgat and Sterkfontein. Unpublished B.A. Thesis, Harvard University.
View in Google Scholar

El-Zaatari S, Grine FE, Teaford MF, Smith HF. 2005. Molar microwear and dietary reconstructions of fossil cercopithecoidea from the Plio-Pleistocene deposits of South Africa. J Hum Evol 49(2):180–205. https://doi.org/10.1016/j.jhevol.2005.03.005
View in Google Scholar

Ferrario VF, Sforza C, Tartaglia GM, Colombo A, Serrao G. 1999. Size and shape of the human first permanent molar: a Fourier analysis of the occlusal and equatorial outlines. Am J Phys Anthropol 108:281–294. http://doi.org/10.1002/(SICI)1096-8644(199903)108:3<281::AIDAJPA4>3.0.CO;2-#
View in Google Scholar

Fourie NH, Lee-Thorp JA, Ackermann RR. 2008. Biogeochemical and craniometric investigation of dietary ecology, niche separation, and taxonomy of Plio-Pleistocene cercopithecoids from the Makapansgat limeworks. Am J Phys Anthropol 135:121–135. http://doi.org/10.1002/ajpa.20713
View in Google Scholar

Freedman L. 1957. The fossil cercopithecoidea of South Africa. Ann Transvaal Mus 23:122–262.
View in Google Scholar

Freedman L. 1960. Some new fossil cercopithecoid specimens from Makapansgat, South Africa. Palaeont Afr 7:7–45.
View in Google Scholar

Freedman L. 1976. South African fossil Ceropithecoidea: a reassessment including a description of new material from Makapansgat, Sterkfontein and Taung. J Hum Evol 5:297–315.
View in Google Scholar

Freedman L, Stenhouse NS. 1972. The Parapapio specimens of Sterkfontein, Transvaal, South Africa. Palaeont Afr 14:93–111.
View in Google Scholar

Frost SR, White FJ, Reda HG, Gilbert CC. 2022. Biochronology of South African hominin-bearing sites: a reassessment using cercopithecid primates. Proc Natl Acad Sci USA 119(45):e2210627119. http://doi.org/10.1073/pnas.2210627119
View in Google Scholar

Gear JHS. 1926. A preliminary account of the baboon remains from Taungs. S Afr J Sci 23:731–747.
View in Google Scholar

Gilbert CC. 2007. Craniomandibular morphology supporting the diphyletic origin of mangabeys and new genus of the Cercocebus/Mandrillus clade, Procercocebus. J Hum Evol 53(1):69–102. https://doi.org//10.1016/j.jhevol.2007.03.004
View in Google Scholar

Gilbert CC. 2013. Cladistic analysis of extant and fossil African papionins using craniodental data. J Hum Evol 64(5):399–433. https://doi.org/10.1016/j.jhevol.2013.01.013
View in Google Scholar

Gilbert CC, Frost SR, Pugh KD, Anderson M, Delson E. 2018. Evolution of the modern baboon (Papio hamadryas): a reassessment of the African Plio-Pleistocene record. J Hum Evol 122:38–69. https://doi.org/10.1016/j.jhevol.2018.04.012
View in Google Scholar

Gómez-Robles A, Marinón-Torres M, Bermúdez de Castro JM. 2007. A geometric morphometric analysis of hominin upper first molar shape. J Hum Evol 53:272–285. http://doi.org/10.1016/j.jhevol.2007.02.002
View in Google Scholar

Granger DE, Stratford D, Bruxelles L, Heaton JL, Pickering TR, Kuman K, Clarke RJ. 2023. Monkey fossils do not negate cosmogenic dating at Sterkfontein. Proc Natl Acad Sci USA. 120(13):e2300314120. http://doi.org/10.1073/pnas.2300314120
View in Google Scholar

Heaton JL. 2006. Taxonomy of the Sterkfontein fossil Cercopithecinae: the Papionini of Members 2 and 4 (Guateng, South Africa). Ph.D. dissertation, Indiana University, Bloomington.
View in Google Scholar

Herries AIR, Pickering R, Adams JW, Curnoe D, Warr G, Latham AG, et al. 2013. A multi-disciplinary perspective on the age of Australopithecus in southern Africa. In: K Reed, J Fleagle and R Leakey, editors. The Paleobiology of Australopithecus. Vertebrate Paleobiology and Paleoanthropology. Dordrecht: Springer. 21–40. http://doi.org/10.1007/978-94-007-5919-0_3
View in Google Scholar

Hlusko LJ, Do N, Mahaney MC. 2006. Genetic correlations between mandibular molar cusp areas in baboons. Yearb Phys Anthropol 49:2–48. https://doi.org/10.1002/ajpa
View in Google Scholar

Hlusko LJ, Weiss KM, Mahaney MC. 2002. Statistical genetic comparison of two techniques for assessing molar crown size in pedigreed baboons. Am J Phys Anthropol 117(2):182–189. https://doi.org/10.1002/ajpa.10022
View in Google Scholar

Iwata H, Ukai Y. 2002. SHAPE: A computer program package for quantitative evaluation of biological shapes based on elliptic Fourier descriptors. J Heredity 93:384–385. http://doi.org/10.1093/jhered/93.5.384
View in Google Scholar

Jablonski NG. 2002. Fossil Old World monkeys: the Late Neogene radiation. In: WC Harwig, editor. The Primate Fossil Record. Cambridge: Cambridge University Press. 225–300.
View in Google Scholar

Jones TR. 1937. A new fossil primate from Sterkfontein, Krugersdorp, Transvaal. S Afr J Sci 33:709–728.
View in Google Scholar

Kuhl FP, Giardina CR. 1982. Elliptic Fourier features of a closed contour. Comput Gr Image Process 18:236–258.
View in Google Scholar

Latham AG, McKee JK, Tobias PV. 2007. Bone breccias, bone dumps, and sedimentary sequences of the western Limeworks, Makapansgat, South Africa. J Hum Evol 52(4):388–400. http://doi.org/10.1016/j.jhevol.2006.10.005
View in Google Scholar

Lestrel PE. 1974. Some problems in the assessment of morphological shape differences. Yearb Phys Anthropol 18:140–162.
View in Google Scholar

Lestrel PE. 1989. Method for analyzing complex two-dimensional forms: elliptical Fourier functions. Am J Hum Biol 1:149–164. http://doi.org/10.1002/ajhb.1310010204
View in Google Scholar

Maier W. 1970. New fossil Cercopithecoidea from the lower Pleistocene cave deposits of the Makapansgat limeworks, South Africa. Palaeont Afr 13:69–107.
View in Google Scholar

Monson TA, Hlusko LJ. 2014. Identification of a derived dental trait in the Papionini relative to other Old World monkeys. Am J Phys Anthropol 155(3):422–429. https://doi.org/10.1002/ajpa.22586
View in Google Scholar

Paul KS, Stojanowski CM. 2017. Comparative performance of deciduous and permanent dental morphology in detecting biological relatives. Am J Phys Anthropol 164:97–116. http://doi.org/10.1002/ajpa.23260
View in Google Scholar

Pilloud MA, Larsen CS. 2011. “Official” and “practical” kin: inferring social and community structure from dental phenotype at Neolithic Çatalhöyük, Turkey. Am J Phys Anthropol 145:519–530. http://doi.org/10.1002/ajpa.21520
View in Google Scholar

Reed KE. 1997. Early hominid evolution and ecological change through the African Plio-Pleistocene. J Hum Evol 32(2–3):289–322. http://doi.org/10.1006/jhev.1996.0106
View in Google Scholar

Reed KE, Kuykendall KL, Herries AIR, Hopley PJ, Sponheimer M, Werdelin L. 2022. Geology, fauna, and paleoenvironmental reconstructions of the Makapansgat Limeworks Australopithecus africanus-bearing paleo-cave. In: SC Reynolds and R Bobe, editors. African Paleoecology and Human Evolution. Cambridge: Cambridge University Press. 66–81.
View in Google Scholar

Scott GR, Irish JD. 2017. Human Tooth Crown and Root Morphology. Cambridge: Cambridge University Press.
View in Google Scholar

Szalay FS, Delson E. 1979. Evolutionary History of the Primates. New York: Academic Press.
View in Google Scholar

Tobias PV. 1980. “Australopithecus afarensis” and A. africanus: Critique and alternative hypothesis. Palaeontol Afr 23:1–17.
View in Google Scholar

Turner II, CG, Nichol C, Scott GR. 1991. Scoring procedures for key morphological traits of the permanent dentition: the Arizona State University Dental Anthropology System. In: MA Kelley and CS Larsen, editors. Advances in Dental Anthropology. New York: Wiley-Liss. 13–31.
View in Google Scholar

Vrba ES. 1996. Habitat theory in relation to the evolution in African Neogene biota and hominids. In: TG Bromage and F Schrenk, editors. African Biogeography, Climate Change, & Human Evolution. New York: Oxford University Press. 19–46.
View in Google Scholar

Vrba ES. 2000. Major features of Neogene mammalian evolution in Africa. In: TC Partridge and RR Maud, editors. The Cenozoic of Southern Africa. New York: Oxford University Press. 277–304.
View in Google Scholar

Warr GL. 2009. Chronology of the western Limeworks australopithecine site, Makapansgat, South Africa: magnetostratigraphy, biochronology and implications for hominin evolution. Ph.D. Thesis, University of Liverpool.
View in Google Scholar

Williams FL. 2014. Dietary reconstruction of Pliocene Parapapio whitei from Makapansgat, South Africa, using dental microwear texture analysis. Folia Primatol 85:21–37. http://doi.org/10.1159/000356029
View in Google Scholar

Williams FL, Ackermann RR, Leigh SR. 2007. Inferring Plio-Pleistocene southern African biochronology from facial affinities in Parapapio and other fossil papionins. Am J Phys Anthropol 132:163–174. https://doi.org/10.1002/ajpa
View in Google Scholar

Williams FL, Lane KM, Anderson WG. 2017. Comparison of maxillary first molar occlusal outlines of Neandertals from the Meuse River Basin of Belgium using elliptical Fourier analysis. Anthropol Rev 80:273–286. https://doi.org/10.1515/anre-2017-0018
View in Google Scholar