Sinodonty and Sundadonty

In anthropology, Sinodonty and Sundadonty are two patterns of features widely found in the dentitions of different populations in East Asia and Southeast Asia. These two patterns were identified by anthropologist Christy G. Turner II as being within the greater "Mongoloid dental complex".[2] Sundadonty is regarded as having a more generalised, proto-Mongoloid morphology and having a longer ancestry than its offspring, Sinodonty.

Distribution of sinodonts and sundadonts in Asia, shown by yellow and red. Also shown are australoids, indicated by A, and negritos, indicated by N.[1]

The combining forms Sino- and Sunda- refer to China and Sundaland, respectively, while -dont refers to teeth.

Proto-sundadonty hypothesis

Tsunehiko Hanihara (1993) believed that the dental features of Aboriginal Australians have the characteristic of high frequencies of "evolutionarily conservative characteristics," which he called the "proto-sundadont" pattern, as he believed that the dental pattern of Aboriginal Australians was ancestral to that of Southeast Asians.[3]

C.G Turner II shows with his analysis of 2016 that sundadonty is the proto-East Eurasian dental morphology and is not connected to the Australian dental morphology, debunking the hypothesis that the Australian dental morphology is the "proto-sundadont" dental pattern. He also shows that sinodonty is predominant in Native Americans.[4]

Super-Sinodont

Analysis on the Sinodonty and Sundadonty of New world groups by G.R. Sott et al. (2016) shows the distinction between East Asians and Southeast Asians is not nearly as dramatic as the difference between all Asians and all New World groups. Other researchers like Stojanowski et al., 2013; Stojanowski and Johnson, (2015) suggest New World groups may be neither Sinodont nor Sundadont and in most regards, could be viewed as super-Sinodont. A clear dental morphology not only ties New World groups to Asians, particularly northeast Asians, but it also exhibits a pattern largely consistent with the Beringian Standstill model (BSM) based on a Sinodont source population.[5]

Mongoloid dental complex

Turner defined the Sinodont and Sundadont dental complexes in contrast to a broader Mongoloid dental complex.[6] Hanihara defined the Mongoloid dental complex in 1966. In 1984, Turner separated the Mongoloid dental complex into the Sinodont and Sundadont dental complexes.[7]

Ryuta Hamada, Shintaro Kondo and Eizo Wakatsuki (1997) said that, based on dental traits, Mongoloids are separated into sinodonts and sundadonts, which is supported by Christy G. Turner II (1989).[8][9]

Sundadont

Turner found the Sundadont pattern in the skeletal remains of Jōmon people of Japan, and in living populations of Taiwanese aborigines, Filipinos, Indonesians, Borneans, and Malaysians.

In 1996, Rebecca Haydenblit of the Hominid Evolutionary Biology Research Group at Cambridge University did a study on the dentition of four pre-Columbian Mesoamerican populations and compared their data to other Eastern Eurasian populations.[10] She found that "Tlatilco", "Cuicuilco", "Monte Albán" and "Cholula" populations followed an overall "Sundadont" dental pattern "characteristic of Southeast Asia" rather than a "Sinodont" dental pattern "characteristic of Northeast Asia".[10]

Sinodont

Turner found the Sinodont pattern in the Han Chinese, in the inhabitants of Mongolia and eastern Siberia, in the Native Americans, and in the Yayoi people of Japan.

Sinodonty is a particular pattern of teeth characterized by the following features:

  • The upper first incisors and upper second incisors are shovel-shaped, and they are "not aligned with the other teeth".[11]
  • The upper first premolar has one root (whereas the upper first premolar in Caucasians normally has two roots), and the lower first molar in Sinodonts has three roots (3RM1) whereas it has two roots in Caucasoid teeth.[11][6]

Associated traits

The EDAR gene causes the Sinodont tooth pattern, and also affects hair texture,[12] jaw morphology,[13] and perhaps the nutritional profile of breast milk.[14]

Applicability

In the 1990s, Turner's dental morphological traits were frequently mentioned as one of three new tools for studying origins and migrations of human populations. The other two were linguistic methods such as Joseph Greenberg's mass comparison of vocabulary or Johanna Nichols's statistical study of language typology and its evolution, and genetic studies pioneered by Cavalli-Sforza.

Today, the largest number of references to Turner's work are from discussions of the origin of Paleo-Amerindians and modern Native Americans, including the Kennewick Man controversy. Turner found that the dental remains of both ancient and modern Amerindians are more similar to each other than they are to dental complexes from other continents, but that the Sinodont patterns of the Paleo-Amerindians identify their ancestral homeland as north-east Asia. Some later studies[which?] have questioned this and found Sundadont features in some American peoples.

A study done by Stojonowski et al in 2015 found a "significant interobserver error" in the earlier studies and their statistical analysis of matched wear and morphology scores suggests trait downgrading for some traits.[15]

gollark: A lot of people somehow can't even uninstall potatOS.
gollark: You would be *amazed*.
gollark: I don't want just new features for the sake of new features.
gollark: It seems like we've mostly avoided having cursors, fortunately.
gollark: *Is* everyone doing that?

See also

References

  1. Howells, William W. (1997). Getting Here: the story of human evolution. ISBN 0-929590-16-3
  2. G. Richard Scott, Christy G. Turner, (2000). The Anthropology of Modern Human Teeth: Dental Morphology and Its Variation in Recent Human Populations. Cambridge University Press. ISBN 0521784530
  3. Hanihara, Tsunehiko. (1993). Craniofacial Features of Southeast Asians and Jomonese: A Reconsideration of Their Microevolution Since the Late Pleistocene. Anthropological Science, 101(1). Page 26. Retrieved March 8, 2018, from link to the PDF document.
  4. Pilloud, Marin; Heim, Kelly; Schmitz, Kirk; Paul, Kathleen. "Sinodonty, Sundadonty, and the Beringian Standstill model: Issues of timing and migrations into the New World". Cite journal requires |journal= (help)
  5. Pilloud, Marin; Heim, Kelly; Schmitz, Kirk; Paul, Kathleen. "Sinodonty, Sundadonty, and the Beringian Standstill model: Issues of timing and migrations into the New World". Cite journal requires |journal= (help)
  6. Scott, R.G. (1997). Encyclopedia of Human Biology. Second Edition. Volume 3. Pages 175-190. Retrieved December 14, 2016, from link.
  7. Díaz, E. et al. (2014). Frequency and variability of dental morphology in deciduous and permanent dentition of a Nasa indigenous group in the municipality of Morales, Cauca, Colombia. In Colombia Médica, 45(1). Pages 15–24. Retrieved December 14, 2016, from link.
  8. Hamada, Ryuta, Kondo, Shintaro & Wakatsuki, Eizo. (1997). Odontometrical Analysis of Filipino Dentition. The Journal of Showa University Dental Society, 17. Page 197. Retrieved March 8, 2018, from link to the PDF document.
  9. SAO/NASA Astrophysics Data System. Teeth and Prehistory in Asia. Retrieved March 9, 2018, from link to the web page.
  10. Haydenblit, R. (1996), Dental variation among four prehispanic Mexican populations. American Journal of Physical Anthropology, 100: 225–246. doi: 10.1002/(SICI)1096-8644(199606)100:2<225::AID-AJPA5>3.0.CO;2-W
  11. Kimura, R. et al. (2009). A Common Variation in EDAR Is a Genetic Determinant of Shovel-Shaped Incisors. In American Journal of Human Genetics, 85(4). Page 528. Retrieved December 24, 2016, from link.
  12. Kamberov YG, Wang S, Tan J, Gerbault P, Wark A, Tan L, Yang Y, Li S, Tang K, Chen H, Powell A, Itan Y, Fuller D, Lohmueller J, Mao J, Schachar A, Paymer M, Hostetter E, Byrne E, Burnett M, McMahon AP, Thomas MG, Lieberman DE, Jin L, Tabin CJ, Morgan BA, Sabeti PC (Feb 2013). "Modeling recent human evolution in mice by expression of a selected EDAR variant". Cell. 152 (4): 691–702. doi:10.1016/j.cell.2013.01.016. PMC 3575602. PMID 23415220.
  13. Adhikari, K., Fuentes-Guajardo, M., Quinto-Sánchez, M., Mendoza-Revilla, J., Chacón-Duque, J. C., Acuña-Alonzo, V., Gómez-Valdés, J. (2016). "A genome-wide association scan implicates DCHS2, RUNX2, GLI3, PAX1 and EDAR in human facial variation". Nature Communications. 7: 11616. Bibcode:2016NatCo...711616A. doi:10.1038/ncomms11616. PMC 4874031. PMID 27193062.CS1 maint: uses authors parameter (link)
  14. Lozovschi, Alexandra (24 April 2018). "Ancient Teeth Reveal Breastfeeding-Related Gene Helped Early Americans Survive The Ice Age [Study]". Inquisitr. Retrieved 25 April 2018.
  15. Stojanowski, Christopher M.; Johnson, Kent M. (March 2015). "Observer error, dental wear, and the inference of new world sundadonty". American Journal of Physical Anthropology. 156 (3): 349–362. doi:10.1002/ajpa.22653. ISSN 1096-8644. PMID 25363296.
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