Regionalized autosomal STR profiles among Armenian groups suggest disparate genetic influences.

The archeology and ethnology of Armenia suggest that this region has acted as a crossroads for human migrations from Europe and the Middle East since at least the Neolithic. Near continual foreign influx has, in turn, led to the supposition that the gene pools of geographically separated Armenian populations may have diverged as differing historical influences potentially left distinct genetic traces in the various regions of the Armenian plateau. In this study, we seek to address whether any evidence for such genetic regional partitioning in Armenians exists by analyzing, for the first time, 15 autosomal short tandem repeat (STR) loci in 404 Armenians from four geographically well-characterized collections (Ararat Valley, Gardman, Sasun, and Lake Van) that represent distinct communities from across Historical Armenia. In addition, to determine whether genetic differences among these four Armenian populations are the result of differential affinities to populations of known historical influence in Armenia, we utilize 27 biogeographically targeted reference populations for phylogenetic and admixture analyses. From these examinations, we find that while close genetic affiliations exist between the two easternmost Armenian groups analyzed, Ararat Valley and Gardman, the remaining two populations display substantial distinctions. In particular, Sasun is distinguished by evidence for genetic contributions from Turkey, while a stronger Balkan component is detected in Lake Van, potentially suggestive of remnant genetic influences from ancient Greek and Phrygian populations in this region.

Insights on human evolution: an analysis of Alu insertion polymorphisms.

We analyzed the genetic profile of 563 individuals from 12 geographically targeted human populations from Europe, Asia and Africa using 27 human-specific polymorphic Alu insertions. Phylogenetic analyses indicated a clear correspondence between genetic profiles and historical patterns of gene flow and genetic drift. Sub-Saharan African populations (Benin, Cameroon, Kenya and Rwanda) formed a visibly differentiated cluster, indicating the role of the Sahara desert as a strong natural barrier to gene flow. Moreover, a higher than expected genetic affinity between populations from Europe, North Africa and Asia was detected, probably reflecting the homogenizing effects of bidirectional migratory processes between Eurasia and North Africa during the Plio-Pleistocene and Neolithic periods or the insensitivity of these markers in discriminating between these groups. The Ami aborigines of Formosa present a distinctive degree of genetic uniqueness from all the other groups, consistent with a pattern of isolation by distance, small population size and, accordingly, substantial genetic drift. We further tested all 27 Alu loci for their potential usefulness as ancestry informative markers (AIMs). On the basis of differences between weighted allelic frequencies (delta-values) and F(ST) values, we propose that 11 of the 27 Alu elements could be useful as part of the current AIM panels to assess phylogenetic relationships.

Sub-population structure evident in forensic Y-STR profiles from Armenian geographical groups.

Over the course of its long history, Armenia has acted as both a source of numerous indigenous cultures and as a recipient of foreign invasions. As a result of this complex history among populations, the gene pool of the Armenian population may contain traces of historically well-documented ancient migrations. Furthermore, the regions within the historical boundaries of Armenia possess unique demographic histories, having hosted both autochthonous and specific exogenous genetic influences. In the present study, we analyze the Armenian population sub-structure utilizing 17 Y-chromosome short tandem repeat (Y-STR) loci of 412 Armenians from four geographically and anthropologically well-defined groups (Ararat Valley, Gardman, Lake Van and Sasun). To place the genetic composition of Armenia in a regional and historic context, we have compared the Y-STR profiles from these four Armenian collections to 18 current-day Eurasian populations and two ancient DNA collections. Our results illustrate regional trends in Armenian paternal lineages and locale-specific patterns of affinities with neighboring regions. Additionally, we observe a phylogenetic relationship between the Northern Caucasus and the group from Sasun, which offers an explanation for the genetic divergence of this group from other three Armenian collections. These findings highlight the importance of analyzing both general populations as well as geographically defined sub-populations when utilizing Y-STRs for forensic analyses and population genetics studies.

Neanderthal and Denisova genetic affinities with contemporary humans: introgression versus common ancestral polymorphisms.

Analyses of the genetic relationships among modern humans, Neanderthals and Denisovans have suggested that 1-4% of the non-Sub-Saharan African gene pool may be Neanderthal derived, while 6-8% of the Melanesian gene pool may be the product of admixture between the Denisovans and the direct ancestors of Melanesians. In the present study, we analyzed single nucleotide polymorphism (SNP) diversity among a worldwide collection of contemporary human populations with respect to the genetic constitution of these two archaic hominins and Pan troglodytes (chimpanzee). We partitioned SNPs into subsets, including those that are derived in both archaic lineages, those that are ancestral in both archaic lineages and those that are only derived in one archaic lineage. By doing this, we have conducted separate examinations of subsets of mutations with higher probabilities of divergent phylogenetic origins. While previous investigations have excluded SNPs from common ancestors in principal component analyses, we included common ancestral SNPs in our analyses to visualize the relative placement of the Neanderthal and Denisova among human populations. To assess the genetic similarities among the various hominin lineages, we performed genetic structure analyses to provide a comparison of genetic patterns found within contemporary human genomes that may have archaic or common ancestral roots. Our results indicate that 3.6% of the Neanderthal genome is shared with roughly 65.4% of the average European gene pool, which clinally diminishes with distance from Europe. Our results suggest that Neanderthal genetic associations with contemporary non-Sub-Saharan African populations, as well as the genetic affinities observed between Denisovans and Melanesians most likely result from the retention of ancient mutations in these populations.

Neolithic patrilineal signals indicate that the Armenian plateau was repopulated by agriculturalists.

Armenia, situated between the Black and Caspian Seas, lies at the junction of Turkey, Iran, Georgia, Azerbaijan and former Mesopotamia. This geographic position made it a potential contact zone between Eastern and Western civilizations. In this investigation, we assess Y-chromosomal diversity in four geographically distinct populations that represent the extent of historical Armenia. We find a striking prominence of haplogroups previously implicated with the Agricultural Revolution in the Near East, including the J2a-M410-, R1b1b1(*)-L23-, G2a-P15- and J1-M267-derived lineages. Given that the Last Glacial Maximum event in the Armenian plateau occured a few millennia before the Neolithic era, we envision a scenario in which its repopulation was achieved mainly by the arrival of farmers from the Fertile Crescent temporally coincident with the initial inception of farming in Greece. However, we detect very restricted genetic affinities with Europe that suggest any later cultural diffusions from Armenia to Europe were not associated with substantial amounts of paternal gene flow, despite the presence of closely related Indo-European languages in both Armenia and Southeast Europe.

To what extent did Neanderthals and modern humans interact?

Neanderthals represent an extinct hominid lineage that existed in Europe and Asia for nearly 400,000 years. They thrived in these regions for much of this time, but declined in numbers and went extinct around 30,000 years ago. Interestingly, their disappearance occurred subsequent to the arrival of modern humans into these areas, which has prompted some to argue that Neanderthals were displaced by better suited and more adaptable modern humans. Still others have postulated that Neanderthals were assimilated into the gene pool of modern humans by admixture. Until relatively recently, conclusions about the relationships between Neanderthals and contemporary humans were based solely upon evidence left behind in the fossil and archaeological records. However, in the last decade, we have witnessed the introduction of metagenomic analyses, which have provided novel tools with which to study the levels of genetic interactions between this fascinating Homo lineage and modern humans. Were Neanderthals replaced by contemporary humans through dramatic extinction resulting from competition and/or hostility or through admixture? Were Neanderthals and modern humans two independent, genetically unique species or were they a single species, capable of producing fertile offspring? Here, we review the current anthropological, archaeological and genetic data, which shed some light on these questions and provide insight into the exact nature of the relationships between these two groups of humans.

Ancient retroviral insertions among human populations.

Human endogenous retroviruses (HERVs) represent vestiges of ancient infections that resulted in stable integration of the viral genome. These insertional elements of viral origin are in fact molecular fossils and, as such, a source of evolutionary information. A family of HERV insertions designated HERV-K includes members that are still polymorphic for the original insertional event. The goal of this report is to describe a novel genetic marker system based on polymorphic retroviral insertions (PRVIs) and to assess its potential usefulness in human population genetic analyses. The allelic frequencies of four insertionally polymorphic HERV-K loci were analyzed in nine geographically targeted, worldwide populations. A polymerase chain reaction assay was employed to examine the frequencies of the provirus and/or solo long terminal repeat insertions at these four loci. Several statistical and phylogenetic analyses were performed based on the frequency data. The phylogenetic relationships observed among the nine populations based on the four retroviral HERV-K loci are consistent not only with prior genetic analyses with other traditional marker systems but also with reported historical and biogeographical data. These polymorphic endogenous retroviral sequences display features that make them excellent tools for forensic and population genetic studies.