The future is now: Amplicon sequencing and sequence capture usher in the conservation genomics era

Meek, Mariah H.; Larson, Wesley A.

doi:10.1111/1755-0998.12998

Cited by 112 publications

(125 citation statements)

References 44 publications

(83 reference statements)

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“…Protocols that combine targeted sequence capture with restriction site-associated DNA sequencing (Ali et al, 2016;Hoffberg et al, 2016) and highly multiplexed amplicon sequencing protocols (GT-Seq; Campbell et al, 2015) are beginning to be widely used for conservation genomic applications (Meek & Larson, 2019). Greater understanding of sea lamprey mating ecology and movement dynamics of sibling groups prior to metamorphosis could greatly aid sea lamprey control efforts.…”

Section: Introductionmentioning

confidence: 99%

RAPTURE (RAD capture) panel facilitates analyses characterizing sea lamprey reproductive ecology and movement dynamics

Sard

Smith

Homola

et al. 2020

Ecology and Evolution

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Genomic tools are lacking for invasive and native populations of sea lamprey (Petromyzon marinus). Our objective was to discover single nucleotide polymorphism (SNP) loci to conduct pedigree analyses to quantify reproductive contributions of adult sea lampreys and dispersion of sibling larval sea lampreys of different ages in Great Lakes tributaries. Additional applications of data were explored using additional geographically expansive samples. We used restriction site‐associated DNA sequencing (RAD‐Seq) to discover genetic variation in Duffins Creek (DC), Ontario, Canada, and the St. Clair River (SCR), Michigan, USA. We subsequently developed RAD capture baits to genotype 3,446 RAD loci that contained 11,970 SNPs. Based on RAD capture assays, estimates of variance in SNP allele frequency among five Great Lakes tributary populations (mean FST 0.008; range 0.00–0.018) were concordant with previous microsatellite‐based studies; however, outlier loci were identified that contributed substantially to spatial population genetic structure. At finer scales within streams, simulations indicated that accuracy in genetic pedigree reconstruction was high when 200 or 500 independent loci were used, even in situations of high spawner abundance (e.g., 1,000 adults). Based on empirical collections of larval sea lamprey genotypes, we found that age‐1 and age‐2 families of full and half‐siblings were widely but nonrandomly distributed within stream reaches sampled. Using the genomic scale set of SNP loci developed in this study, biologists can rapidly genotype sea lamprey in non‐native and native ranges to investigate questions pertaining to population structuring and reproductive ecology at previously unattainable scales.

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Section: Introductionmentioning

confidence: 99%

RAPTURE (RAD capture) panel facilitates analyses characterizing sea lamprey reproductive ecology and movement dynamics

Sard

Smith

Homola

et al. 2020

Ecology and Evolution

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“…The step-by-step guide for marker discovery and the pipeline designed for amplicon-sequencing can be used to isolate informative SNPs and rapidly genotype any non-model species. Amplicon-sequencing can not only speed-up the genotyping of endangered species but also facilitate the transition from conservation genetics to genomics (Meek & Larson, 2019;Taylor et al, 2017). The pipeline is flexible enough for amplicon-sequencing with different degrees of amplicons and samples, and can also be used to prepare the data of low-coverage ampliconsequencing experiments that incorporate some error (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…Most important information for population and conservation genetic studies can be achieved with traditional molecular methods that do not require whole genome sequencing of populations (Allendorf, 2017;Bowden et al, 2012;Fischer et al, 2017;Peterson et al, 2012). Targeted enrichment protocols are alternatives to whole-genome re-sequencing (WGR) (Henriques et al, 2018;Meek & Larson, 2019;Milano et al, 2013). These protocols enable amplification of specific genomic regions that contain previously discovered variation.…”

Section: Introductionmentioning

confidence: 99%

Leveraging targeted sequencing for non-model species: a step-by-step guide to obtain a reduced SNP set and a pipeline to automate data processing in the Antarctic Midge, Belgica antarctica

Pavinato

Wijeratne

Spacht

et al. 2019

Preprint

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The sequencing of whole or partial (e.g. reduced representation) genomes are commonly employed in molecular ecology and conservation genetics studies. However, due to sequencing costs, a trade-off between the number of samples and genome coverage can hinder research for non-model organisms. Furthermore, the processing of raw sequences requires familiarity with coding and bioinformatic tools that are not always available. Here, we present a guide for isolating a set of short, SNP-containing genomic regions for use with targeted amplicon sequencing protocols. We also present a python pipeline--PypeAmplicon--that facilitates processing of reads to individual genotypes. We demonstrate the applicability of our method by generating an informative set of amplicons for genotyping of the Antarctic midge, Belgica antarctica, an endemic dipteran species of the Antarctic Peninsula. Our pipeline analyzed raw sequences produced by a combination of high-multiplexed PCR and next-generation sequencing. A total of 38 out of 47 (81%) amplicons designed by our panel were recovered, allowing successful genotyping of 42 out of 55 (76%) targeted SNPs. The sequencing of ~150 bp around the targeted SNPs also uncovered 80 new SNPs, which complemented our analyses. By comparing overall patterns of genetic diversity and population structure of amplicon data with the low-coverage, whole-genome re-sequencing (lcWGR) data used to isolate the informative amplicons, we were able to demonstrate that amplicon sequencing produces information and results similar to that of lcWGR. Our methods will benefit other research programs where rapid development of population genetic data is needed but yet prevented due to high expense and a lack of bioinformatic experience.

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“…Collectively, these findings indicate that genomic approaches, such as RAD-seq, could be useful for identifying genetic differences between western and eastern basin Walleye populations. Once these differences are quantified, other, higher-throughput molecular resources (e.g., genotyping-in-thousands by sequencing [GT-seq] and RAD capture [Rapture] panels) could be developed to determine the relative contributions of western versus eastern basin stocks to Lake Erie's mixed-stock fisheries Ali et al 2016;Meek and Larson 2019).…”

Section: Genetic Structure Between Eastern and Western Basinsmentioning

confidence: 99%

“…Higher genomic coverage could be achieved by using alternate enzymes during RAD-seq preparation that increase the number of cut sites or by conducting full-genome resequencing (Fuentes-Pardo and Ruzzante 2017;McKinney et al 2017). Once the most informative loci for stock delineation are identified, they can be used to construct resources, such as GT-seq and Rapture panels, which can quickly and consistently genotype thousands of individuals and in turn greatly increase sample sizes and statistical confidence (Meek and Larson 2019). These panels could then be used independently (if the resolution is high enough) or in conjunction with other techniques, such as otolith microchemistry, to successfully delineate populations (Chen et al 2017).…”

Section: Improving Genomic Approaches For Great Lakes Fishery Managementmentioning

confidence: 99%

RAD‐Seq Refines Previous Estimates of Genetic Structure in Lake Erie Walleye

et al. 2020

Self Cite

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Delineating population structure helps fishery managers to maintain a diverse “portfolio” of local spawning populations (stocks), as well as facilitate stock‐specific management. In Lake Erie, commercial and recreational fisheries for Walleye Sander vitreus exploit numerous local spawning populations, which cannot be easily differentiated using traditional genetic data (e.g., microsatellites). Here, we used genomic information (12,264 polymorphic loci) generated using restriction site‐associated DNA sequencing to investigate stock structure in Lake Erie Walleye. We found low genetic divergence (genetic differentiation index FST = 0.0006–0.0019) among the four Lake Erie western basin stocks examined, which resulted in low classification accuracies for individual samples (40–60%). However, more structure existed between western and eastern Lake Erie basin stocks (FST = 0.0042–0.0064), resulting in greater than 95% classification accuracy of samples to a lake basin. Thus, our success in using genomics to identify stock structure varied with spatial scale. Based on our results, we offer suggestions to improve the efficacy of this new genetic tool for refining stock structure and eventually determining relative stock contributions in Lake Erie Walleye and other Great Lakes populations.

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The future is now: Amplicon sequencing and sequence capture usher in the conservation genomics era

Cited by 112 publications

References 44 publications

RAPTURE (RAD capture) panel facilitates analyses characterizing sea lamprey reproductive ecology and movement dynamics

RAPTURE (RAD capture) panel facilitates analyses characterizing sea lamprey reproductive ecology and movement dynamics

Leveraging targeted sequencing for non-model species: a step-by-step guide to obtain a reduced SNP set and a pipeline to automate data processing in the Antarctic Midge, Belgica antarctica

RAD‐Seq Refines Previous Estimates of Genetic Structure in Lake Erie Walleye

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