Journal of Archaeological Science
Volume 51, November 2014, Pages 174–180
Collective burials among agro-pastoral societies in later Neolithic Germany: perspectives from ancient DNA
Esther J. Lee et al.
Ancient DNA research has focused on the genetic patterns of the earliest farmers during the European Neolithic, especially with regards to the demographic changes in the transition from hunting and gathering to agriculture. However, genetic data is relatively lacking after this earliest transition period, when societies had fully adapted to new agrarian lifestyles specific to their local environment. During the later central European Neolithic (ca. 3600–2800 cal BC), large-scale collective burials and monumental architecture appeared within the landscape of many agricultural societies. This phenomenon has been argued to represent the emergence of a “collective” identity. With the aim of exploring genetic-based relations among individuals collectively buried, we obtained human skeletal remains of nearly 200 individuals from four later Neolithic collective burial sites in Germany: Calden, Odagsen, Groβenrode, and Panker. We successfully reproduced reliable mitochondrial DNA (mtDNA) haplotypes from eight Neolithic individuals, which were assigned to haplogroups H, HV0, and X2. Shared haplotypes observed among individuals within Calden and Odagsen suggest that genetic relations may have shaped the arrangement of the deceased within later Neolithic agricultural groups.
Link
Showing posts with label HV0. Show all posts
Showing posts with label HV0. Show all posts
January 23, 2015
December 14, 2013
Ancient mtDNA from Rössen culture in Wittmar, Germany
Archaeological and Anthropological Sciences December 2013
Ancient DNA insights from the Middle Neolithic in Germany
Esther J. Lee et al.
Genetic studies of Neolithic groups in central Europe have provided insights into the demographic processes that have occurred during the initial transition to agriculture as well as in later Neolithic contexts. While distinct genetic patterns between indigenous hunter-gatherers and Neolithic farmers in Europe have been observed, it is still under discussion how the genetic diversity changed during the 5,000-year span of the Neolithic period. In order to investigate genetic patterns after the earliest farming communities, we carried out an ancient mitochondrial DNA (mtDNA) analysis of 34 individuals from Wittmar, Germany representing three different Neolithic farming groups (ca. 5,200–4,300 cal bc) including Rössen societies. Ancient DNA analysis was successful for six individuals associated with the Middle Neolithic Rössen and observed haplotypes were assigned to mtDNA haplogroups H5, HV0, U5, and K. Our results offer perspectives on the genetic composition of individuals associated with the Rössen culture at Wittmar and permit insights into genetic landscapes in central Europe at a time when regional groups first emerged during the Middle Neolithic.
Link
Ancient DNA insights from the Middle Neolithic in Germany
Esther J. Lee et al.
Genetic studies of Neolithic groups in central Europe have provided insights into the demographic processes that have occurred during the initial transition to agriculture as well as in later Neolithic contexts. While distinct genetic patterns between indigenous hunter-gatherers and Neolithic farmers in Europe have been observed, it is still under discussion how the genetic diversity changed during the 5,000-year span of the Neolithic period. In order to investigate genetic patterns after the earliest farming communities, we carried out an ancient mitochondrial DNA (mtDNA) analysis of 34 individuals from Wittmar, Germany representing three different Neolithic farming groups (ca. 5,200–4,300 cal bc) including Rössen societies. Ancient DNA analysis was successful for six individuals associated with the Middle Neolithic Rössen and observed haplotypes were assigned to mtDNA haplogroups H5, HV0, U5, and K. Our results offer perspectives on the genetic composition of individuals associated with the Rössen culture at Wittmar and permit insights into genetic landscapes in central Europe at a time when regional groups first emerged during the Middle Neolithic.
Link
September 11, 2012
Ancient mtDNA from late Neolithic collective burials in Germany
Journal of Archaeological Science doi:10.1016/j.jas.2012.08.037
Collective burials among agro-pastoral societies in later Neolithic Germany: Perspectives from ancient DNA
Esther J. Lee et al.
Abstract
Ancient DNA research has focused on the genetic patterns of the earliest farmers during the European Neolithic, especially with regards to the demographic changes in the transition from hunting and gathering to agriculture. However, genetic data is relatively lacking after this earliest transition period, when societies had fully adapted to new agrarian lifestyles specific to their local environment. During the later central European Neolithic (ca. 3600 - 2800 cal BC), large-scale collective burials and monumental architecture appeared within the landscape of many agricultural societies. This phenomenon has been argued to represent the emergence of a “collective” identity. With the aim of exploring genetic-based relations among individuals collectively buried, we obtained human skeletal remains of nearly 200 individuals from four later Neolithic collective burial sites in Germany: Calden, Odagsen, Großenrode, and Panker. We successfully reproduced reliable mitochondrial DNA (mtDNA) haplotypes from eight Neolithic individuals, which were assigned to haplogroups H, HV0, and X2. Shared haplotypes observed among individuals within Calden and Odagsen suggest genetic relations may have shaped the arrangement of the deceased within later Neolithic agricultural groups.
Link
Collective burials among agro-pastoral societies in later Neolithic Germany: Perspectives from ancient DNA
Esther J. Lee et al.
Abstract
Ancient DNA research has focused on the genetic patterns of the earliest farmers during the European Neolithic, especially with regards to the demographic changes in the transition from hunting and gathering to agriculture. However, genetic data is relatively lacking after this earliest transition period, when societies had fully adapted to new agrarian lifestyles specific to their local environment. During the later central European Neolithic (ca. 3600 - 2800 cal BC), large-scale collective burials and monumental architecture appeared within the landscape of many agricultural societies. This phenomenon has been argued to represent the emergence of a “collective” identity. With the aim of exploring genetic-based relations among individuals collectively buried, we obtained human skeletal remains of nearly 200 individuals from four later Neolithic collective burial sites in Germany: Calden, Odagsen, Großenrode, and Panker. We successfully reproduced reliable mitochondrial DNA (mtDNA) haplotypes from eight Neolithic individuals, which were assigned to haplogroups H, HV0, and X2. Shared haplotypes observed among individuals within Calden and Odagsen suggest genetic relations may have shaped the arrangement of the deceased within later Neolithic agricultural groups.
Link
May 12, 2010
mtDNA of Tatars from Volga-Ural region (Malyarchuk et al. 2010)
Wikipedia article on Volga Tatars. Some pictures of Kazan Tatars, which look just about what you would expect for 16% eastern Asian mtDNA, i.e., primarily Caucasoid but with visible traces of Mongoloid admixture
Molecular Biology and Evolution, doi:10.1093/molbev/msq065
Mitogenomic diversity in Tatars from the Volga-Ural region of Russia
B. Malyarchuk et al.
To investigate diversity of mitochondrial gene pool of Tatars inhabiting the territory of the middle Volga River basin, 197 individuals from two populations representing Kazan Tatars and Mishars were subjected for analysis of mitochondrial DNA (mtDNA) control region variation. In addition, 73 mitochondrial genomes of individuals from Mishar population were sequenced completely. It was found that mitochondrial gene pool of the Volga Tatars consists of two parts, but western Eurasian component prevails considerably (84% on average) over eastern Asian one (16%). Eastern Asian mtDNAs detected in Tatars belonged to a heterogeneous set of haplogroups (A, C, D, G, M7, M10, N9a, Y, Z), although only haplogroups A and D were revealed simultaneously in both populations. Complete mtDNA variation study revealed that the age of western Eurasian haplogroups (such as U4, HV0a and H) is less than 18,000 years, thus suggesting re-expansion of Eastern Europeans soon after the Last Glacial Maximum.
Link
Molecular Biology and Evolution, doi:10.1093/molbev/msq065
Mitogenomic diversity in Tatars from the Volga-Ural region of Russia
B. Malyarchuk et al.
To investigate diversity of mitochondrial gene pool of Tatars inhabiting the territory of the middle Volga River basin, 197 individuals from two populations representing Kazan Tatars and Mishars were subjected for analysis of mitochondrial DNA (mtDNA) control region variation. In addition, 73 mitochondrial genomes of individuals from Mishar population were sequenced completely. It was found that mitochondrial gene pool of the Volga Tatars consists of two parts, but western Eurasian component prevails considerably (84% on average) over eastern Asian one (16%). Eastern Asian mtDNAs detected in Tatars belonged to a heterogeneous set of haplogroups (A, C, D, G, M7, M10, N9a, Y, Z), although only haplogroups A and D were revealed simultaneously in both populations. Complete mtDNA variation study revealed that the age of western Eurasian haplogroups (such as U4, HV0a and H) is less than 18,000 years, thus suggesting re-expansion of Eastern Europeans soon after the Last Glacial Maximum.
Link
February 05, 2010
mtDNA in Iberian Northern Plateau
Am J Phys Anthropol doi:10.1002/ajpa.21252
Mitochondrial DNA patterns in the Iberian Northern plateau: Population dynamics and substructure of the Zamora province
Luis Alvarez et al.
ABSTRACT
Several studies have shown the importance of recent events in the configuration of the genetic landscape of a specific territory. In this context, due to the phenomena of repopulation and demographic fluctuations that took place in recent centuries, the Iberian Northern plateau is a very interesting case study. The main aim of this work is to check if recent population movements together with existing boundaries (geographical and administrative) have influenced the current genetic composition of the area. To accomplish this general purpose, mitochondrial DNA variations of 214 individuals from a population located in the Western region of the Iberian Northern plateau (the province of Zamora) were analyzed. Results showed a typical Western European mitochondrial DNA haplogroup composition. However, unexpected high frequencies of U5, HV0, and L haplogroups were found in some regions. The analyses of microdifferentiation showed that there are differences between regions, but no geographic substructure organization can be noticed. It can be stated that the differences observed in the genetic pool of the sampled area at regional level results from the mixture of different populations carrying new lineages into this area at different points in history.
Link
Mitochondrial DNA patterns in the Iberian Northern plateau: Population dynamics and substructure of the Zamora province
Luis Alvarez et al.
ABSTRACT
Several studies have shown the importance of recent events in the configuration of the genetic landscape of a specific territory. In this context, due to the phenomena of repopulation and demographic fluctuations that took place in recent centuries, the Iberian Northern plateau is a very interesting case study. The main aim of this work is to check if recent population movements together with existing boundaries (geographical and administrative) have influenced the current genetic composition of the area. To accomplish this general purpose, mitochondrial DNA variations of 214 individuals from a population located in the Western region of the Iberian Northern plateau (the province of Zamora) were analyzed. Results showed a typical Western European mitochondrial DNA haplogroup composition. However, unexpected high frequencies of U5, HV0, and L haplogroups were found in some regions. The analyses of microdifferentiation showed that there are differences between regions, but no geographic substructure organization can be noticed. It can be stated that the differences observed in the genetic pool of the sampled area at regional level results from the mixture of different populations carrying new lineages into this area at different points in history.
Link
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