Justin Tackney scite author profile

Ancient DNA (aDNA) analyses have proven to be important tools in understanding human population dispersals, settlement patterns, interactions between prehistoric populations, and the development of regional population histories. Here, we review the published results of sixty-three human populations from throughout the Americas and compare the levels of diversity and geographic patterns of variation in the ancient samples with contemporary genetic variation in the Americas in order to investigate the evolution of the Native American gene pool over time. Our analysis of mitochondrial haplogroup frequencies and prehistoric population genetic diversity presents a complex evolutionary picture. Although the broad genetic structure of American prehistoric populations appears to have been established relatively early, we nevertheless identify examples of genetic discontinuity over time in select regions. We discuss the implications this finding may have for our interpretation of the genetic evidence for the initial colonization of the Americas and its subsequent population history.

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Paternal and grandpaternal ages at conception and descendant telomere lengths in chimpanzees and humans

Eisenberg

Tackney

Cawthon

et al. 2016

American J Phys Anthropol

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Telomeres are repeating DNA at chromosome ends. Telomere length (TL) declines with age in most human tissues, and shorter TL is thought to accelerate senescence. In contrast, older men have sperm with longer TL; correspondingly, older paternal age at conception (PAC) predicts longer TL in offspring. This PAC-effect could be a unique form of transgenerational genetic plasticity that modifies somatic maintenance in response to cues of recent ancestral experience. The PAC-effect has not been examined in any non-human mammals. Objectives Here we examine the PAC-effect in chimpanzees (Pan troglodytes). The PAC-effect on TL is thought to be driven by continual production of sperm—the same process that drives increased de novo mutations with PAC. Since chimpanzees have both greater sperm production and greater sperm mutation rates with PAC than humans, we predict that the PAC-effect on TL will be more pronounced in chimpanzees. Additionally we examine whether PAC predicts TL of grandchildren. Materials and Methods TL were measured using qPCR from DNA from blood samples from 40 captive chimpanzees and 144 humans. Results Analyses showed increasing TL with PAC in chimpanzees (p=0.009) with a slope six times that in humans (p=0.026). No associations between TL and grandpaternal ages were found in humans or chimpanzees—although statistical power was low. Discussion These results suggest that sperm production rates across species may be a determinant of the PAC-effect on offspring TL. This raises the possibility that sperm production rates within species may influence the TL passed on to offspring.

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Blood cell telomere lengths and shortening rates of chimpanzee and human females

Tackney

Cawthon

Coxworth

et al. 2014

American J Hum Biol

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Objectives Slower rates of aging distinguish humans from our nearest living cousins. Chimpanzees rarely survive their forties while large fractions of women are postmenopausal even in high-mortality hunter–gatherer populations. Cellular and molecular mechanisms for these somatic aging differences remain to be identified, though telomeres might play a role. To find out, we compared telomere lengths across age-matched samples of female chimpanzees and women. Methods We used a monochrome multiplex quantitative polymerase chain reaction to assay canonical telomere repeats in blood cells from captive female chimpanzees (65 individuals; age: 6.2–56.7 years) and compared them to the same measure in human females (43 individuals; age: 7.4–57.3 years). Results Our samples showed little difference in attrition rates between the species (~0.022 T/S per year for chimpanzees and ~0.012 T/S per year for humans with overlapping 95% confidence intervals), but telomeres were twice as long in chimpanzees as in humans (T/S ratios = 2.70 and 1.26, respectively). Conclusions Based on the longevity differences, we initially hypothesized that telomere shortening rates would be faster in chimpanzees than in humans. Instead, it is shorter telomere length that appears to be the derived state in humans. This comparison indicates that better characterization of physiological aging in our closest living relatives will be indispensable for understanding the evolution of distinctive human longevity.

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Mitochondrial diversity of Iñupiat people from the Alaskan North Slope provides evidence for the origins of the Paleo‐ and Neo‐Eskimo peoples

Raff

Rzhetskaya

Tackney

et al. 2015

American J Phys Anthropol

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Two contemporaneous mitogenomes from terminal Pleistocene burials in eastern Beringia

Tackney

Potter

Raff

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Pleistocene residential sites with multiple contemporaneous human burials are extremely rare in the Americas. We report mitochondrial genomic variation in the first multiple mitochondrial genomes from a single prehistoric population: two infant burials (USR1 and USR2) from a common interment at the Upward Sun River Site in central Alaska dating to ∼11,500 cal B.P. Using a targeted capture method and next-generation sequencing, we determined that the USR1 infant possessed variants that define mitochondrial lineage C1b, whereas the USR2 genome falls at the root of lineage B2, allowing us to refine younger coalescence age estimates for these two clades. C1b and B2 are rare to absent in modern populations of northern North America. Documentation of these lineages at this location in the Late Pleistocene provides evidence for the extent of mitochondrial diversity in early Beringian populations, which supports the expectations of the Beringian Standstill Model.

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Justin Tackney

Ancient DNA perspectives on American colonization and population history

Paternal and grandpaternal ages at conception and descendant telomere lengths in chimpanzees and humans

Blood cell telomere lengths and shortening rates of chimpanzee and human females

Mitochondrial diversity of Iñupiat people from the Alaskan North Slope provides evidence for the origins of the Paleo‐ and Neo‐Eskimo peoples

Two contemporaneous mitogenomes from terminal Pleistocene burials in eastern Beringia

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