基因助手 GeneU

05/07/2024

In the ancient Ferghana Valley of Central Asia, there were thriving Greek settlements far away from their ancestors. How did these people come to be so far away from Asia Minor, and how did they end up being the kingmakers of the Silk Road?

In the ancient Ferghana Valley of Central Asia, there were thriving Greek settlements far away from their ancestors. How did these people come to be so far a...

09/05/2024

28/04/2024

This study re-examines the linguistic phylogeny of the South Caucasian linguistic family (aka the Kartvelian linguistic family) and attempts to identify its Urheimat. We apply Bayesian phylogenetics to infer a dated phylogeny of the South Caucasian languages. We infer the Urheimat and the reasons for the split of the Kartvelian languages by taking into consideration (1) the past distribution ranges of wildlife elements whose names can be traced back to proto-Kartvelian roots, (2) the distribution ranges of past cultures and (3) the genetic variations of past and extant human populations. Our best-fit Bayesian phylogenetic model is in agreement with the widely accepted topology suggested by previous studies. However, in contrast to these studies, our model suggests earlier mean split dates, according to which the divergence between Svan and Karto-Zan occurred in the early Copper Age, while Georgian and Zan diverged in the early Iron Age. The split of Zan into Megrelian and Laz is widely attributed to the spread of Georgian and/or Georgian speakers in the seventh-eighth centuries CE. Our analyses place the Kartvelian Urheimat in an area that largely intersects the Colchis glacial refugium in the South Caucasus. The divergence of Kartvelian languages is strongly associated with differences in the rate of technological expansions in relation to landscape heterogeneity, as well as the emergence of state-run communities. Neolithic societies could not colonize dense forests, whereas Copper Age societies made limited progress in this regard, but not to the same degree of success achieved by Bronze and Iron Age societies. The paper also discusses the importance of glacial refugia in laying the foundation for linguistic families and where Indo-European languages might have originated.

This study re-examines the linguistic phylogeny of the South Caucasian linguistic family (aka the Kartvelian linguistic family) and attempts to identify its Urheimat. We apply Bayesian phylogenetics to infer a dated phylogeny of the South Caucasian languages. We infer the Urheimat and the reasons fo...

08/04/2024

https://youtu.be/60qB5dkFf74?si=M4vG--iqqlXKwrsw

The Earliest Farmers of the Caucasus: A View from Masis BlurFirst lecture in Archaeology of Armenia: Early Settlements, Dragon Stones, and Gods of UrartuKris...

08/04/2024

https://www.youtube.com/watch?v=DdooJ7oO9AU

In this video, Dr. Mitchell Rothman Emeritus Professor of Anthropology and Archaeology, Widener University and Consulting Scholar at Penn Museum, talks about...

06/04/2024

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29/03/2024

Analysis of Beethoven’s DNA has revealed that he had a low genetic predisposition for beat synchronization, an ability that’s closely related to musicality. This is according to researchers who set out to show how making genetic predictions for individuals, including famous historical figures, c...

29/03/2024

The Saxon settlements in England, which emerged and evolved from around the 5th to the 11th centuries and shaped Britain to this day

28/03/2024

The Iranian plateau, strategically positioned as a corridor for population diffusion across Eurasia, holds a pivotal role in elucidating the dynamics of human migrations originating from Africa around 60,000 years ago. Both prehistoric and historic movements of populations between Africa, Asia, and Europe may have been influenced by the unique geographical features of the Iranian plateau. Iran boasts ancient cultures and urban settlements predating some of the earliest civilizations, including the Neolithic revolution in neighboring Mesopotamia. Spanning from the Balkans and Egypt in the west to the Indus Valley in Pakistan and northern India in the southeast, the Iranian plateau encompasses a vast area characterized by incredible ethnocultural diversity. This region served as the origin for numerous mt-DNA/Y-DNA haplogroups that expanded to West Asia, Europe, Siberia, Central Asia, and South Asia. By examining both maternal and paternal haplogroups within the Iranian context, we aim to contribute to the broader narrative of human dispersals and elucidate the role those specific regions, such as the Iranian plateau, played in shaping the observed genetic diversity today. Due to the lack of comprehensive studies on mt-DNA /Y-DNA haplogroups in the Iranian population, our study sought to uncover the distribution of haplogroups among Iranian peoples using a large sample size. Our analysis focused on the frequency of ancestral haplogroups in Iran through the examination of large-scale whole-exome sequencing (WES) and SNP microarray data from 18,184 individuals. In our study, we observed 24 mt-DNA super haplogroups in the Iranian population, with the most common haplogroups belonging to West-Eurasian lineages U (20.73%), H (18.84%), J (12.10%), HV (9.22%), and T (8.98%), collectively comprising 69.70% of all Iranian samples. Notably, subclades J1 and U7 emerged as the two most frequent subclades, with frequencies of 11.24% and 7.30%, respectively. We also revealed the presence of 14 distinct Y-DNA haplogroups, with J, R, G, T, and Q emerging as the five predominant lineages. Notably, J2 (including J-L26) exhibited the highest frequency at 35.64%, followed by R1a at 14.68%. also, The detected mtDNA and Y-chromosome haplogroups were clustered into distinct groups that confirmed the heterogenicity of the Iranian population because of various factors including geographic or linguistic ethnic groups.