Meiotic recombination shapes precision of pedigree- and marker-based estimates of inbreeding

Knief, Ulrich; Kempenaers, Bart; Forstmeier, Wolfgang

doi:10.1038/hdy.2016.95

Cited by 20 publications

(42 citation statements)

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“…Genomic approaches capture variation in realized inbreeding that is missed by pedigree analysis due to the stochastic effects of linkage and unknown common ancestors of parents (Franklin, 1977; Thompson, 2013). Thus, while deep and accurate pedigrees can often precisely measure individual inbreeding in species with many chromosomes and/or high recombination rates (Kardos et al., 2018; Knief, Kempenaers, & Forstmeier, 2017; Nietlisbach et al., 2017), genomic approaches are expected to more reliably measure inbreeding and inbreeding depression (Kardos, Luikart, & Allendorf, 2015a; Kardos et al., 2018; Keller, Visscher, & Goddard, 2011; Wang, 2016). Given that many studies have used only shallow pedigrees or few DNA markers, it is possible that power to detect inbreeding depression has been low; therefore, inbreeding depression could be more common, widespread, and severe than previously thought.…”

Section: Improving Downstream Computational Analysesmentioning

confidence: 99%

Recent advances in conservation and population genomics data analysis

Hendricks

Anderson

Antão

et al. 2018

Evolutionary Applications

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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.

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Section: Improving Downstream Computational Analysesmentioning

confidence: 99%

Recent advances in conservation and population genomics data analysis

Hendricks

Anderson

Antão

et al. 2018

Evolutionary Applications

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“…identical-by-state (IBS) rather than IBD, and hence not predict the probability of IBD at adjacent chromosomal regions (i.e. IBD-IBS discrepancy) [25,29].…”

Section: Introductionmentioning

confidence: 99%

“…Thereby they capture variation in IBD introduced by stochasticity inherent to Mendelian segregation and recombination [21][22][23][24]. For example, the standard deviation in realized IBD among offspring of full sibling matings (pedigree F ¼ 0.25) is 0.044 in humans (Homo sapiens) [23] and 0.084 in zebra finches (Taeniopygia guttata) [25]. Third, markers can capture variation in inbreeding that is not captured because of shallow, incomplete or erroneous pedigree data (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…In practice however, a finite number of chromosomes and reduced recombination among markers located on the same chromosome introduces Mendelian noise, which causes realized IBD at the marker loci to differ from its pedigreebased expectation, weakening the association between F and fitness ( [25]; figure 1). Mendelian noise can be accounted for by dividing the right side of equation (1.1) by the squared correlation coefficient between F and realized IBD (r 2 realized IBD,F ), which following [25] Note that in these equations, F is defined as the pedigreebased expectation of IBD [18] and that it is assumed that loci are physically unlinked [30].…”

Section: Introductionmentioning

confidence: 99%

“…Mendelian noise can be accounted for by dividing the right side of equation (1.1) by the squared correlation coefficient between F and realized IBD (r 2 realized IBD,F ), which following [25] Note that in these equations, F is defined as the pedigreebased expectation of IBD [18] and that it is assumed that loci are physically unlinked [30]. Equations (1.4) and (1.5) remain valid (with F as pedigree-based inbreeding) when loci are linked because the reduction in r F,H and b F,H due to increased Mendelian noise is accounted for by dividing by the variance in H, which is higher for linked loci.…”

Section: Introductionmentioning

confidence: 99%

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Pedigree-based inbreeding coefficient explains more variation in fitness than heterozygosity at 160 microsatellites in a wild bird population

et al. 2017

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Although the pedigree-based inbreeding coefficient F predicts the expected proportion of an individual's genome that is identical-by-descent (IBD), heterozygosity at genetic markers captures Mendelian sampling variation and thereby provides an estimate of realized IBD. Realized IBD should hence explain more variation in fitness than their pedigree-based expectations, but how many markers are required to achieve this in practice remains poorly understood. We use extensive pedigree and life-history data from an island population of song sparrows ( Melospiza melodia ) to show that the number of genetic markers and pedigree depth affected the explanatory power of heterozygosity and F , respectively, but that heterozygosity measured at 160 microsatellites did not explain more variation in fitness than F . This is in contrast with other studies that found heterozygosity based on far fewer markers to explain more variation in fitness than F . Thus, the relative performance of marker- and pedigree-based estimates of IBD depends on the quality of the pedigree, the number, variability and location of the markers employed, and the species-specific recombination landscape, and expectations based on detailed and deep pedigrees remain valuable until we can routinely afford genotyping hundreds of phenotyped wild individuals of genetic non-model species for thousands of genetic markers.

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