Museum genomics: low‐cost and high‐accuracy genetic data from historical specimens

Rowe, Kevin C.; Singhal, Sonal; MacManes, Matthew D.; Ayroles, Julien F.; Morelli, Toni Lyn; Rubidge, Emily; Bi, Ke; Moritz, Craig

doi:10.1111/j.1755-0998.2011.03052.x

Cited by 129 publications

(143 citation statements)

References 78 publications

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“…Where in the pre-NGS, polymerase chain reaction (PCR), era fragmented template DNA represented a major roadblock to successful amplification, the opposite is now true. Indeed next-generation sequencing has opened up tremendous possibilities for sequencing museum specimens, not only because of its increased output and power, but also because of the ever-decreasing costs (Millar et al 2008;Metzker 2010;Glenn 2011;Rowe et al 2011;Buerki and Baker 2016).…”

Section: Open Accessmentioning

confidence: 99%

Herbarium genomics: skimming and plastomics from archival specimens

Bakker¹

2017

Webbia

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Section: Open Accessmentioning

confidence: 99%

Herbarium genomics: skimming and plastomics from archival specimens

Bakker¹

2017

Webbia

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“…Another comparison (102) found similar phylogeographic resolution between exons (drawn randomly from transcriptomes) vs. anchored hybrid enrichment (AHE) loci, which mostly target conserved exons (96,97). Exon capture has been effectively used to study diverging lineages of both vertebrates and invertebrates (e.g., 12, 98, 103) and is particularly appropriate for retrieving genomic data from museum specimens (80,104,105). Arguably, most UCE, AHE, or exon capture loci that have been used thus far for next-generation phylogeography are under mild or even strong purifying selection.…”

Section: Reconstructing Processes Of Divergence and Reticulationmentioning

confidence: 99%

Reticulation, divergence, and the phylogeography–phylogenetics continuum

Edwards

Potter

Schmitt

et al. 2016

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

138

105

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Phylogeography, and its extensions into comparative phylogeography, have their roots in the layering of gene trees across geography, a paradigm that was greatly facilitated by the nonrecombining, fast evolution provided by animal mtDNA. As phylogeography moves into the era of next-generation sequencing, the specter of reticulation at several levels-within loci and genomes in the form of recombination and across populations and species in the form of introgression-has raised its head with a prominence even greater than glimpsed during the nuclear gene PCR era. Here we explore the theme of reticulation in comparative phylogeography, speciation analysis, and phylogenomics, and ask how the centrality of gene trees has fared in the next-generation era. To frame these issues, we first provide a snapshot of multilocus phylogeographic studies across the Carpentarian Barrier, a prominent biogeographic barrier dividing faunas spanning the monsoon tropics in northern Australia. We find that divergence across this barrier is evident in most species, but is heterogeneous in time and demographic history, often reflecting the taxonomic distinctness of lineages spanning it. We then discuss a variety of forces generating reticulate patterns in phylogeography, including introgression, contact zones, and the potential selection-driven outliers on next-generation molecular markers. We emphasize the continued need for demographic models incorporating reticulation at the level of genomes and populations, and conclude that gene trees, whether explicit or implicit, should continue to play a role in the future of phylogeography.monsoon tropics | introgression | comparative phylogeography | species trees | coalescent theory

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“…While the degraded nature of historical DNA poses a particular set of challenges and requires stringent data quality control and validation, a number of different methods can be used to obtain reliable high-throughput sequence or genotype data from ancient and historical samples (see Rizzi et al, 2012). We now have the technology to fully sequence the entire genome of samples that are thousands of years old (e.g., Rasmussen et al, 2010;Prüfer et al, 2014), and recent studies with archived fish samples or other museum specimens have generated high-quality data through minor methodological modifications using standard genotyping assays of 100s or 1000s of SNPs (e.g., Johnston et al, 2013;Therkildsen et al, 2013a, b), sequence capture methodology (Bi et al, 2012;Carpenter et al, 2013), or whole-genome sequencing (Rowe et al, 2011;Staats et al, 2013).…”

Section: Spatio-temporal Population Genomicsmentioning

confidence: 99%