Complete mitochondrial genome sequence of a Middle Pleistocene cave bear reconstructed from ultrashort DNA fragments

Dabney, Jesse; Knapp, Michael; Glocke, Isabelle; Gansauge, Marie-Theres; Weihmann, Antje; Nickel, Birgit; Valdiosera, Cristina; Garcı́a, Nuria; Pääbo, Svante; Arsuaga, Juan Luís; Meyer, Matthias

doi:10.1073/pnas.1314445110

Cited by 1,118 publications

(1,088 citation statements)

References 45 publications

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“…Post-capture median fragment lengths in dental calculus were approximately 9 bp longer than prior to capture, while post-capture median fragment lengths in dentine samples were 27–102 bp longer than prior to capture, a substantial increase. In-solution capture enrichment is known to bias towards the recovery of longer DNA fragments (Dabney et al 2013a), and the length differences in captured DNA observed between calculus and dentine is likely related to the fact that the dentine samples started with a higher endogenous content in the pre-capture libraries.…”

Section: Resultsmentioning

confidence: 99%

“…For dentine samples, the digestion buffer solution was refreshed after 48 hours and the two supernatants were combined for subsequent analyses. After digestion, DNA was extracted by a previously described phenol-chloroform separation protocol and purified by silica adsorption (Qiagen MinElute PCR Purification kit) (Warinner et al 2014b) using a modified protocol to increase binding buffer volume (Dabney et al 2013a). DNA was eluted into 30 μl of EB buffer and 1 μl of each extract was quantified using a Qubit High Sensitivity dsDNA assay (Life Technologies) (Table 1).…”

Section: Methodsmentioning

confidence: 99%

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Successful enrichment and recovery of whole mitochondrial genomes from ancient human dental calculus

Ozga

Nieves-Colón

Honap

et al. 2016

American J Phys Anthropol

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Objectives Archaeological dental calculus is a rich source of host-associated biomolecules. Importantly, however, dental calculus is more accurately described as a calcified microbial biofilm than a host tissue. As such, concerns regarding destructive analysis of human remains may not apply as strongly to dental calculus, opening the possibility of obtaining human health and ancestry information from dental calculus in cases where destructive analysis of conventional skeletal remains is not permitted. Here we investigate the preservation of human mitochondrial DNA (mtDNA) in archaeological dental calculus and its potential for full mitochondrial genome (mitogenome) reconstruction in maternal lineage ancestry analysis. Materials and Methods Extracted DNA from six individuals at the 700-year-old Norris Farms #36 cemetery in Illinois was enriched for mtDNA using in-solution capture techniques, followed by Illumina high-throughput sequencing. Results Full mitogenomes (7-34x) were successfully reconstructed from dental calculus for all six individuals, including three individuals who had previously tested negative for DNA preservation in bone using conventional PCR techniques. Mitochondrial haplogroup assignments were consistent with previously published findings, and additional comparative analysis of paired dental calculus and dentine from two individuals yielded equivalent haplotype results. All dental calculus samples exhibited damage patterns consistent with ancient DNA, and mitochondrial sequences were estimated to be 92–100% endogenous. DNA polymerase choice was found to impact error rates in downstream sequence analysis, but these effects can be mitigated by greater sequencing depth. Discussion Dental calculus is a viable alternative source of human DNA that can be used to reconstruct full mitogenomes from archaeological remains.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Successful enrichment and recovery of whole mitochondrial genomes from ancient human dental calculus

Ozga

Nieves-Colón

Honap

et al. 2016

American J Phys Anthropol

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“…DNA was extracted from bones and teeth (34)(35)(36); DNA extracts were converted into blunt-end Illumina libraries (37). All samples were prepared in dedicated ancient DNA (aDNA) facilities at the Evolutionary Biology Center in Uppsala, Sweden.…”

Section: Methodsmentioning

confidence: 99%

Ancient genomes link early farmers from Atapuerca in Spain to modern-day Basques

Günther

Valdiosera

Malmström

et al. 2015

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

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The consequences of the Neolithic transition in Europe—one of the most important cultural changes in human prehistory—is a subject of great interest. However, its effect on prehistoric and modern-day people in Iberia, the westernmost frontier of the European continent, remains unresolved. We present, to our knowledge, the first genome-wide sequence data from eight human remains, dated to between 5,500 and 3,500 years before present, excavated in the El Portalón cave at Sierra de Atapuerca, Spain. We show that these individuals emerged from the same ancestral gene pool as early farmers in other parts of Europe, suggesting that migration was the dominant mode of transferring farming practices throughout western Eurasia. In contrast to central and northern early European farmers, the Chalcolithic El Portalón individuals additionally mixed with local southwestern hunter–gatherers. The proportion of hunter–gatherer-related admixture into early farmers also increased over the course of two millennia. The Chalcolithic El Portalón individuals showed greatest genetic affinity to modern-day Basques, who have long been considered linguistic and genetic isolates linked to the Mesolithic whereas all other European early farmers show greater genetic similarity to modern-day Sardinians. These genetic links suggest that Basques and their language may be linked with the spread of agriculture during the Neolithic. Furthermore, all modern-day Iberian groups except the Basques display distinct admixture with Caucasus/Central Asian and North African groups, possibly related to historical migration events. The El Portalón genomes uncover important pieces of the demographic history of Iberia and Europe and reveal how prehistoric groups relate to modern-day people.

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“…DNA hybridization capture (7) is a powerful method that can be used to recover large amounts of sequence data while requiring very small amounts of input DNA. Although this approach has successfully been used to assemble complete mitochondrial genomes from highly degraded ancient DNA (8,9), only a few studies have so far reported full mitochondrial genomes being obtained from museum specimens, and to our knowledge, none of these investigated archival fish specimens (10). Fishes account for more than one-half of the diversity of the vertebrate tree of life and the relationships among many major groups remain unresolved or are based on morphological interpretations alone.…”

Section: Significancementioning

confidence: 99%

DNA capture reveals transoceanic gene flow in endangered river sharks

Corrigan

Yang

et al. 2015

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

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For over a hundred years, the "river sharks" of the genus Glyphis were only known from the type specimens of species that had been collected in the 19th century. They were widely considered extinct until populations of Glyphis-like sharks were rediscovered in remote regions of Borneo and Northern Australia at the end of the 20th century. However, the genetic affinities between the newly discovered Glyphis-like populations and the poorly preserved, original museum-type specimens have never been established. Here, we present the first (to our knowledge) fully resolved, complete phylogeny of Glyphis that includes both archival-type specimens and modern material. We used a sensitive DNA hybridization capture method to obtain complete mitochondrial genomes from all of our samples and show that three of the five described river shark species are probably conspecific and widely distributed in Southeast Asia. Furthermore we show that there has been recent gene flow between locations that are separated by large oceanic expanses. Our data strongly suggest marine dispersal in these species, overturning the widely held notion that river sharks are restricted to freshwater. It seems that species in the genus Glyphis are euryhaline with an ecology similar to the bull shark, in which adult individuals live in the ocean while the young grow up in river habitats with reduced predation pressure. Finally, we discovered a previously unidentified species within the genus Glyphis that is deeply divergent from all other lineages, underscoring the current lack of knowledge about the biodiversity and ecology of these mysterious sharks.freshwater sharks | DNA | museum specimens

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Complete mitochondrial genome sequence of a Middle Pleistocene cave bear reconstructed from ultrashort DNA fragments

Cited by 1,118 publications

References 45 publications

Successful enrichment and recovery of whole mitochondrial genomes from ancient human dental calculus

Successful enrichment and recovery of whole mitochondrial genomes from ancient human dental calculus

Ancient genomes link early farmers from Atapuerca in Spain to modern-day Basques

DNA capture reveals transoceanic gene flow in endangered river sharks

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