Your search keyword '"Kind CJ"' showing total 2 results

1. Nuclear DNA from two early Neandertals reveals 80,000 years of genetic continuity in Europe.

Author

Peyrégne S, Slon V, Mafessoni F, de Filippo C, Hajdinjak M, Nagel S, Nickel B, Essel E, Le Cabec A, Wehrberger K, Conard NJ, Kind CJ, Posth C, Krause J, Abrams G, Bonjean D, Di Modica K, Toussaint M, Kelso J, Meyer M, Pääbo S, and Prüfer K

Subjects

Animals, Cell Lineage genetics, Europe, Evolution, Molecular, Fossils, Genome genetics, Germany, Mitochondria genetics, Cell Nucleus genetics, DNA genetics, Neanderthals genetics

Abstract

Little is known about the population history of Neandertals over the hundreds of thousands of years of their existence. We retrieved nuclear genomic sequences from two Neandertals, one from Hohlenstein-Stadel Cave in Germany and the other from Scladina Cave in Belgium, who lived around 120,000 years ago. Despite the deeply divergent mitochondrial lineage present in the former individual, both Neandertals are genetically closer to later Neandertals from Europe than to a roughly contemporaneous individual from Siberia. That the Hohlenstein-Stadel and Scladina individuals lived around the time of their most recent common ancestor with later Neandertals suggests that all later Neandertals trace at least part of their ancestry back to these early European Neandertals.

Published

2019

2. Deeply divergent archaic mitochondrial genome provides lower time boundary for African gene flow into Neanderthals.

Author

Posth C, Wißing C, Kitagawa K, Pagani L, van Holstein L, Racimo F, Wehrberger K, Conard NJ, Kind CJ, Bocherens H, and Krause J

Subjects

Animals, Femur, Genome, Human genetics, Germany, Humans, Time Factors, Black People genetics, DNA, Mitochondrial genetics, Evolution, Molecular, Gene Flow, Genome, Mitochondrial, Hominidae genetics, Neanderthals genetics

Abstract

Ancient DNA is revealing new insights into the genetic relationship between Pleistocene hominins and modern humans. Nuclear DNA indicated Neanderthals as a sister group of Denisovans after diverging from modern humans. However, the closer affinity of the Neanderthal mitochondrial DNA (mtDNA) to modern humans than Denisovans has recently been suggested as the result of gene flow from an African source into Neanderthals before 100,000 years ago. Here we report the complete mtDNA of an archaic femur from the Hohlenstein-Stadel (HST) cave in southwestern Germany. HST carries the deepest divergent mtDNA lineage that splits from other Neanderthals ∼270,000 years ago, providing a lower boundary for the time of the putative mtDNA introgression event. We demonstrate that a complete Neanderthal mtDNA replacement is feasible over this time interval even with minimal hominin introgression. The highly divergent HST branch is indicative of greater mtDNA diversity during the Middle Pleistocene than in later periods.

Published

2017