Finding the Genomic Basis of Local Adaptation: Pitfalls, Practical Solutions, and Future Directions

Hoban, Sean; Kelley, Joanna L.; Lotterhos, Katie E.; Antolin, Michael F.; Bradburd, Gideon S.; Lowry, David B.; Poss, Mary; Reed, Laura K.; Storfer, Andrew; Whitlock, Michael C.

doi:10.1086/688018

Cited by 732 publications

(922 citation statements)

References 228 publications

(252 reference statements)

Supporting

Mentioning

911

Contrasting

Unclassified

Order By: Relevance

“…Some missing data and artefacts are caused by structural differences (insertions, deletions, inversions, etc. ) between resequenced individuals and the reference genome to which they are aligned (Tiffin & Ross-Ibarra 2014;Hoban et al 2016). Finally, it is important that researchers retain invariant sites in their data sets to accurately calculate population genetic summary statistics and demographic parameters.…”

Section: Beyond Radmentioning

confidence: 99%

“…Other reviews have outlined these problems, which include the confounding effects of population structure, demographic history and issues with analytical methods (Lotterhos & Whitlock 2014;Tiffin & Ross-Ibarra 2014;Rellstab et al 2015;Hoban et al 2016). However, the problem with RADseq is with the marker data sets themselves, which are often far too sparse to have a reasonable chance of detecting the loci involved in adaptation.…”

Section: Conclusion and Closing Remarksmentioning

confidence: 99%

See 1 more Smart Citation

Breaking RAD: An evaluation of the utility of restriction site associated DNA sequencing for genome scans of adaptation

et al. 2016

Self Cite

View full text Add to dashboard Cite

Understanding how and why populations evolve is of fundamental importance to molecular ecology. Restriction site-associated DNA sequencing (RADseq), a popular reduced representation method, has ushered in a new era of genome-scale research for assessing population structure, hybridization, demographic history, phylogeography and migration. RADseq has also been widely used to conduct genome scans to detect loci involved in adaptive divergence among natural Correspondence: David B. Lowry, Fax: 517-353-1926; dlowry@msu.edu. Correction noteThe original advance online paper contained two errors associated with the calculation of the median density of RAD-seq tags in the survey of recent RAD-seq genome scan studies (Table S1). The first error was in the size of the assembled stickleback genome, which was reported as 0.53 Gbp, but should have been 0.46 Gbp. The second error was an accidental inversion of terms. These two mistakes contributed to an erroneous statement in the original abstract that the median density of RAD-tags across recent studies "was one marker per 3.96 megabases." The statement has been revised to read: "was 4.08 RAD-tag markers per megabase." Following these corrections, changes were made in the abstract and elsewhere in the paper to reflect a modified interpretation of the results, though we note the main arguments in the article are unaffected. Other minor modifications to the paper were made based upon suggestions by the editors of Molecular Ecology Resources. This version of the article, published as an "accepted article" on 12 November 2016 under DOI 10.1111/1755-0998.12635 replaces the original version of the article published on 12 September 2016 under DOI 10.1111/1755-0998.12596.The idea for the manuscript was conceived collectively by all authors during an NSF National Institute for Mathematical and Biological Synthesis (NIMBioS) working group. All authors contributed to the writing of the manuscript.Supporting Information Additional Supporting Information may be found in the online version of this article: Appendix S1 Supplementary R scripts for Breaking RAD. Table S1 Recent (January 2015 to April 2016) genome scan studies, which used RAD-seq for genotyping. Andrews et al. (2016). Generally, RADseq methods produce DNA libraries for high-throughput sequencing using restriction enzymes that cut at specific motifs throughout the genome. RADseq markers come in the form of RAD-tags, which are short-read sequences adjacent to restriction enzyme cut sites. Because many polymorphic markers are produced by RADseq, it has frequently been used successfully for population genetic analyses, including assessment of population structure, hybridization, demographic history, phylogeography and migration (Catchen et al. 2013;Cavender-Bares et al. 2015;Combosch & Vollmer 2015;Qi et al. 2015). Markers generated by RADseq have also been quite useful for constructing linkage maps and identifying quantitative trait loci (QTL;Pfender et al. 2011;Houston et al. 2012;Weber et al. 2013;Laporte et al. 2015...

show abstract

Section: Beyond Radmentioning

confidence: 99%

Section: Conclusion and Closing Remarksmentioning

confidence: 99%

Breaking RAD: An evaluation of the utility of restriction site associated DNA sequencing for genome scans of adaptation

et al. 2016

Self Cite

View full text Add to dashboard Cite

show abstract

“…Technological and analytical advances now allow us to use many thousands of loci, gene expression, or epigenetics to address basic questions of relevance for conservation, such as identifying loci associated with local adaptation or adaptive potential in species face changing environments (Bernatchez, 2016; Flanagan, Forester, Latch, Aitken, & Hoban, 2017; Harrisson et al., 2014; Hoban et al., 2016; Hoffmann et al., 2015; Jensen, Foll, & Bernatchez, 2016; Le Luyer et al., 2017; Wade et al., 2016). As conservation genomics matures, new challenges are arising.…”

Section: Introductionmentioning

confidence: 99%

Recent advances in conservation and population genomics data analysis

Hendricks

Anderson

Antão

et al. 2018

Evolutionary Applications

View full text Add to dashboard Cite

New computational methods and next‐generation sequencing (NGS) approaches have enabled the use of thousands or hundreds of thousands of genetic markers to address previously intractable questions. The methods and massive marker sets present both new data analysis challenges and opportunities to visualize, understand, and apply population and conservation genomic data in novel ways. The large scale and complexity of NGS data also increases the expertise and effort required to thoroughly and thoughtfully analyze and interpret data. To aid in this endeavor, a recent workshop entitled “Population Genomic Data Analysis,” also known as “ConGen 2017,” was held at the University of Montana. The ConGen workshop brought 15 instructors together with knowledge in a wide range of topics including NGS data filtering, genome assembly, genomic monitoring of effective population size, migration modeling, detecting adaptive genomic variation, genomewide association analysis, inbreeding depression, and landscape genomics. Here, we summarize the major themes of the workshop and the important take‐home points that were offered to students throughout. We emphasize increasing participation by women in population and conservation genomics as a vital step for the advancement of science. Some important themes that emerged during the workshop included the need for data visualization and its importance in finding problematic data, the effects of data filtering choices on downstream population genomic analyses, the increasing availability of whole‐genome sequencing, and the new challenges it presents. Our goal here is to help motivate and educate a worldwide audience to improve population genomic data analysis and interpretation, and thereby advance the contribution of genomics to molecular ecology, evolutionary biology, and especially to the conservation of biodiversity.

show abstract

“…There is an urgent need to understand the underlying genetic basis of the traits that are currently being selected on wildlife ranches and to determine how allele frequencies differ between ranched and wild populations. This knowledge can be achieved through analysis of candidate genes, experiments and/or by using shared records on breeding outcomes from the ranchers, though we recognise that the genetic basis of some traits will be more difficult than others to document (Hoban et al 2016). There is now a broader knowledge base on the genetic underpinning of coat colour in wild and domestic animals (e.g.…”

Section: Decisionsmentioning

confidence: 99%

‘Intentional Genetic Manipulation’ as a conservation threat

Russo

Hoban

Bloomer

et al. 2018

Conservation Genet Resour

Self Cite

View full text Add to dashboard Cite

Wildlife ranching including the hunting, collection, sales and husbandry of wild animals in captivity, is practised worldwide and is advocated as an approach towards the conservation of wild species. While many authors have explored the biological impacts of intensive wild population management, primarily with respect to disease transmission (especially in ungulates and fish), the evolutionary and demographic effects of wildlife ranching have been examined less intensively. We discuss this issue through the case of intensive wildlife management in southern Africa. The genetic consequences of this global practice, with an emphasis on Africa, were addressed by a motion passed at the 2016 IUCN World Congress-'Management and regulation of intensive breeding and genetic manipulation of large mammals for commercial purposes'. Here, we highlight concerns regarding intensive breeding programs used to discover, enhance and propagate unusual physical traits, hereafter referred to as 'Intentional Genetic Manipulation'. We highlight how 'Intentional Genetic Manipulation' potentially threatens the viability of native species and ecosystems, via genetic erosion, inbreeding, hybridisation and unregulated translocation. Finally, we discuss the need for better policies in southern Africa and globally, regarding 'Intentional Genetic Manipulation', and the identification of key knowledge gaps.

show abstract

Finding the Genomic Basis of Local Adaptation: Pitfalls, Practical Solutions, and Future Directions

Cited by 732 publications

References 228 publications

Breaking RAD: An evaluation of the utility of restriction site associated DNA sequencing for genome scans of adaptation

Breaking RAD: An evaluation of the utility of restriction site associated DNA sequencing for genome scans of adaptation

Recent advances in conservation and population genomics data analysis

‘Intentional Genetic Manipulation’ as a conservation threat

Contact Info

Product

Resources

About