Random PCR‐based genotyping by sequencing technology GRAS‐Di (genotyping by random amplicon sequencing, direct) reveals genetic structure of mangrove fishes

Hosoya, S.; Hirase, Shotaro; Kikuchi, Kiyoshi; Nanjo, Kishio; Nakamura, Yohei; Kohno, Hiroyoshi; Sano, Mitsuhiko

doi:10.1111/1755-0998.13025

Cited by 58 publications

(51 citation statements)

References 52 publications

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“…nipponica from four different populations (Table S1.1 in Appendix S1). The DNA samples were used for genotyping by sequencing (GBS) by genotyping by random amplicon sequencing‐direct (GRAS‐Di; Hosoya et al., 2019), which was performed at the Bioengineering Laboratory (Sagamihara, Japan). Briefly, DNA samples were directly amplified using 63 random primers (Table S2.2 in Appendix S2), in which each individual was tagged with independent adapter sequences.…”

Section: Methodsmentioning

confidence: 99%

“…All amplicons were sequenced using Illumina NextSeq. Compared to other GBS methods such as RADseq, GRAS‐Di does not require a large amount of high‐quality DNA (Davey et al., 2011; Hosoya et al., 2019). Following the methodology described in a previous study (Fujii et al., 1999), Primula farinosa L. (formerly P. modesta Bisset & S. Moore) was included as an outgroup.…”

Section: Methodsmentioning

confidence: 99%

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East Asian origin of the widespread alpine snow‐bed herb, Primula cuneifolia (Primulaceae), in the northern Pacific region

Ikeda

Yakubov

Barkalov

et al. 2020

Journal of Biogeography

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Aim: The evolutionary importance of southern mountain ranges has been noted for alpine as well as arctic-alpine plants. However, it remains unclear whether these isolated marginal populations of cold-adapted species have contributed to the establishment of their current widespread distribution. We aim to explore the molecular evidence for the recent northward migration of alpine snow-bed species in the northern Pacific region.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

East Asian origin of the widespread alpine snow‐bed herb, Primula cuneifolia (Primulaceae), in the northern Pacific region

Ikeda

Yakubov

Barkalov

et al. 2020

Journal of Biogeography

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“…However, these techniques require specialized equipment and are typically prohibitively expensive for the large sample sizes needed for wildlife population monitoring (Andrews, Barba, Russello, & Waits, 2018; Carroll et al., 2018). A potential cost‐effective alternative involves amplifying many SNPs together in multiplex PCR followed by high‐throughput sequencing (Campbell, Harmon, & Narum, 2015; Hosoya, Hirase, Kikuchi, & Nanjo, 2019; Meek & Larson, 2019; Suyama & Matsuki, 2015). Such genotyping by amplicon sequencing is highly flexible with respect to the number of samples and SNPs processed, affordable, amenable to high throughput, and requires no proprietary kits for library preparation and only standard laboratory equipment.…”

Section: Introductionmentioning

confidence: 99%

More affordable and effective noninvasive single nucleotide polymorphism genotyping using high‐throughput amplicon sequencing

Eriksson

Ruprecht

Levi

2020

Molecular Ecology Resources

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Noninvasive genotyping methods have become key elements of wildlife research over the last two decades, but their widespread adoption is limited by high costs, low success rates and high error rates. The information lost when genotyping success is low may lead to decreased precision in animal population densities, which could misguide conservation and management actions. Single nucleotide polymorphisms (SNPs) provide a promising alternative to traditionally used microsatellites as SNPs allow amplification of shorter DNA fragments, are less prone to genotyping errors and produce results that are easily shared among laboratories. Here, we outline a detailed protocol for cost-effective and accurate noninvasive SNP genotyping using multiplexed amplicon sequencing optimized for degraded DNA. We validated this method for individual identification by genotyping 216 scats, 18 hairs and 15 tissues from coyotes (Canis latrans) using 26 SNPs. Our genotyping success rate for scat samples was 93%, and 100% for hair and tissue, representing a substantial increase compared to previous microsatellite-based studies while remaining at a low cost of under $5 per PCR replicate (excluding labour). The accuracy of the genotypes was further corroborated in that genotypes from scats matching known, GPS-collared coyotes were always located within the territory of the known individual. We also show that different levels of multiplexing produced similar results, but that PCR product cleanup strategies can have substantial effects on genotyping success. By making noninvasive genotyping more affordable, accurate and efficient, this research may allow for a substantial increase in the use of noninvasive methods to monitor and conserve free-ranging wildlife populations.

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“…Further, the advance of molecular genetics technology through next-generation sequencing (NGS) has made it possible to obtain extensive nucleotide sequences, enabling rapid and large-scale development of DNA markers. Moreover, more economical and efficient approaches using NGS have been developed, such as restriction site-associated DNA sequencing (RADSeq) [ 14 ], double digest RADSeq (ddRADSeq) [ 15 ], MIG-Seq (multiplexed ISSR genotyping by sequencing) [ 16 ], genotyping-in-thousands by sequencing (GT-Seq) [ 17 , 18 ], and genotyping by random amplicon sequencing, direct (GRAS-Di) [ 19 , 20 ]. These approaches enable simultaneous sequencing and genotyping of thousands of SNP markers, and they have been used in various species, including endangered species [ 18 , 21 ].…”

Section: Introductionmentioning

confidence: 99%

“…These approaches enable simultaneous sequencing and genotyping of thousands of SNP markers, and they have been used in various species, including endangered species [ 18 , 21 ]. Although GRAS-Di has few applications thus far, GRAS-Di is useful in characterizing wildlife because it can function with the available low-quality DNA in a polymerase chain reaction (PCR)-based method and does not require a reference genome, similar to MIG-seq [ 19 , 20 ]. GRAS-Di is a technology that produces a sequence library by two PCRs using random primers and adapter sequences, and detects SNPs using NGS.…”

Section: Introductionmentioning

confidence: 99%

Genetic Diversity and Genetic Structure of the Wild Tsushima Leopard Cat from Genome-Wide Analysis

Itô

Nakajima

Onuma

et al. 2020

Animals

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The Tsushima leopard cat (Prionailurus bengalensis euptilurus) lives on Tsushima Island in Japan and is a regional population of the Amur leopard cat; it is threatened with extinction. Its genetic management is important because of the small population. We used genotyping by random amplicon sequencing-direct (GRAS-Di) to develop a draft genome and explore single-nucleotide polymorphism (SNP) markers. The SNPs were analyzed using three genotyping methods (mapping de novo, to the Tsushima leopard cat draft genome, and to the domestic cat genome). We examined the genetic diversity and genetic structure of the Tsushima leopard cat. The genome size was approximately 2.435 Gb. The number of SNPs identified was 133–158. The power of these markers was sufficient for individual and parentage identifications. These SNPs can provide useful information about the life of the Tsushima leopard cat and the pairings and for the introduction of founders to conserve genetic diversity with ex situ conservation. We identified that there are no subpopulations of the Tsushima leopard cat. The identifying units will allow for a concentration of efforts for conservation. SNPs can be applied to the analysis of the leopard cat in other regions, making them useful for comparisons among populations and conservation in other small populations.

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Random PCR‐based genotyping by sequencing technology GRAS‐Di (genotyping by random amplicon sequencing, direct) reveals genetic structure of mangrove fishes

Cited by 58 publications

References 52 publications

East Asian origin of the widespread alpine snow‐bed herb, Primula cuneifolia (Primulaceae), in the northern Pacific region

East Asian origin of the widespread alpine snow‐bed herb, Primula cuneifolia (Primulaceae), in the northern Pacific region

More affordable and effective noninvasive single nucleotide polymorphism genotyping using high‐throughput amplicon sequencing

Genetic Diversity and Genetic Structure of the Wild Tsushima Leopard Cat from Genome-Wide Analysis

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