The recombination landscape of the zebra finch <i>Taeniopygia guttata</i> genome

Backström, Niclas; Forstmeier, Wolfgang; Schielzeth, Holger; Mellenius, Harriet; Nam, Kiwoong; Bolund, Elisabeth; Webster, Matthew T.; Öst, Torbjörn; Schneider, Melanie; Kempenaers, Bart; Ellegren, Hans

doi:10.1101/gr.101410.109

Cited by 221 publications

(362 citation statements)

References 83 publications

(111 reference statements)

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“…To our knowledge, all analytical analyses and most of the simulations so far have assumed a uniform distribution of crossovers along chromosomes (see, for example, Franklin, 1977;Stam, 1980;Hill and Weir, 2011;Kardos et al, 2015;Wang, 2016; but see Suarez et al, 1979 andLibiger andSchork, 2007 for Monte Carlo simulations on relatedness). Although this assumption holds more or less for the human genome (Matise et al, 2007), linkage maps from other species have shown that the distribution of recombination along chromosomes can be highly biased toward the telomeres (Gore et al, 2009;Backström et al, 2010). We and others predicted that this results in a more block-like inheritance pattern of genomic segments on a given chromosome which in turn increases the Mendelian noise (Risch and Lange, 1979;Guo, 1995;Forstmeier et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Similarly, it has been predicted that the distribution of crossovers along chromosomes will influence the amount of variance in IBD (see, for example, Risch and Lange, 1979;Rasmuson, 1993;Guo, 1995;Forstmeier et al, 2012), but to our knowledge it has never received attention in a modeling framework. Here we show that the variance in IBD is much larger in zebra finches than in humans, because in the former almost half of the genome is inherited in only six segments (that is, the interiors of chromosomes Tgu1, Tgu1A, Tgu2, Tgu3, Tgu4 and Tgu5) that only rarely break up by crossovers (Backström et al, 2010). Hill and Weir (2011) provide a formula to calculate the expected s.d.…”

Section: Mendelian Noise In Gwibdmentioning

confidence: 99%

“…Microsatellites used in that study were spread across nine chromosomes, including the macrochromosomes Tgu1, Tgu1A, Tgu2, Tgu3, Tgu5, Tgu6 and Tgu9, that together sum up to half the physical zebra finch genome and rarely break up in meiosis (Backström et al, 2010). Thus, they are potentially more informative than a random set of 'ideal markers' (as considered here).…”

Section: Effects Of Meiotic Recombination On Pedigree-based Estimatesmentioning

confidence: 99%

“…For the zebra finch, we used the sex-averaged linkage map described in Backström et al (2010) based on 1395 SNPs and covering 33 chromosomes (data accessible from Schielzeth et al, 2011Schielzeth et al, , 2012. We excluded the sex chromosome and 10 microchromosomes covered by o10 markers (see Supplementary Information for details).…”

Section: Empirical Linkage and Physical Mapsmentioning

confidence: 99%

“…Our expectation is based on the fact that although the zebra finch genome consists of 39 autosomes compared with only 22 in humans, about half of its autosomal genome is made up of only 6 chromosomes (Tgu1, Tgu1A, Tgu2, Tgu3, Tgu4 and Tgu5) and shows extremely low recombination rates in the centers of these chromosomes (Backström et al, 2010), whereas in humans recombination is distributed quite uniformly on the megabase scale along chromosomes (Matise et al, 2007). We follow the genomes of 159 diploid pedigree founders, who we assume to be unrelated, through an empirical 7-generation pedigree of 3404 individuals.…”

Section: Introductionmentioning

confidence: 99%

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

2016

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The proportion of an individual's genome that is identical by descent (GWIBD) can be estimated from pedigrees (inbreeding coefficient 'Pedigree F') or molecular markers ('Marker F'), but both estimators come with error. Assuming unrelated pedigree founders, Pedigree F is the expected proportion of GWIBD given a specific inbreeding constellation. Meiotic recombination introduces variation around that expectation (Mendelian noise) and related pedigree founders systematically bias Pedigree F downward. Marker F is an estimate of the actual proportion of GWIBD but it suffers from the sampling error of markers plus the error that occurs when a marker is homozygous without reflecting common ancestry (identical by state). We here show via simulation of a zebra finch and a human linkage map that three aspects of meiotic recombination (independent assortment of chromosomes, number of crossovers and their distribution along chromosomes) contribute to variation in GWIBD and thus the precision of Pedigree and Marker F. In zebra finches, where the genome contains large blocks that are rarely broken up by recombination, the Mendelian noise was large (nearly twofold larger s.d. values compared with humans) and Pedigree F thus less precise than in humans, where crossovers are distributed more uniformly along chromosomes. Effects of meiotic recombination on Marker F were reversed, such that the same number of molecular markers yielded more precise estimates of GWIBD in zebra finches than in humans. As a consequence, in species inheriting large blocks that rarely recombine, even small numbers of microsatellite markers will often be more informative about inbreeding and fitness than large pedigrees.

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Section: Introductionmentioning

confidence: 99%

Section: Mendelian Noise In Gwibdmentioning

confidence: 99%

Section: Effects Of Meiotic Recombination On Pedigree-based Estimatesmentioning

confidence: 99%

Section: Empirical Linkage and Physical Mapsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

2016

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GC‐biased gene conversion links the recombination landscape and demography to genomic base composition

Mugal

Weber²,

Ellegren

2015

BioEssays

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The origin and evolutionary dynamics of the spatial heterogeneity in genomic base composition have been debated since its discovery in the 1970s. With the recent availability of numerous genome sequences from a wide range of species it has been possible to address this question from a comparative perspective, and similarities and differences in base composition between groups of organisms are becoming evident. Ample evidence suggests that the contrasting dynamics of base composition are driven by GC-biased gene conversion (gBGC), a process that is associated with meiotic recombination. In line with this hypothesis, base composition is associated with the rate of recombination and the evolutionary dynamics of the recombination landscape, therefore, governs base composition. In addition, and at first sight perhaps surprisingly, the relationship between demography and genomic base composition is in agreement with the gBGC hypothesis: organisms with larger populations have higher GC content than those with smaller populations.

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Extensive introgressive hybridization within the northern oriole group (Genus Icterus) revealed by three‐species isolation with migration analysis

Jacobsen

Omland

2012

Ecology and Evolution

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Until recently, studies of divergence and gene flow among closely-related taxa were generally limited to pairs of sister taxa. However, organisms frequently exchange genes with other non-sister taxa. The “northern oriole” group within genus Icterus exemplifies this problem. This group involves the extensively studied hybrid zone between Baltimore oriole (Icterus galbula) and Bullock's oriole (I. bullockii), an alleged hybrid zone between I. bullockii and black-backed oriole (I. abeillei), and likely mtDNA introgression between I. galbula and I. abeillei. Here, we examine the divergence population genetics of the entire northern oriole group using a multipopulation Isolation-with-Migration (IM) model. In accordance with Haldane's rule, nuclear loci introgress extensively beyond the I. galbula–I. bullockii hybrid zone, while mtDNA does not. We found no evidence of introgression between I. bullockii and I. abeillei or between I. galbula and I. abeillei when all three species were analyzed together in a three-population model. However, traditional pairwise analysis suggested some nuclear introgression from I. abeillei into I. galbula, probably reflecting genetic contributions from I. bullockii unaccounted for in a two-population model. Thus, only by including all members of this group in the analysis was it possible to rigorously estimate the level of gene flow among these three closely related species.

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The recombination landscape of the zebra finch Taeniopygia guttata genome

Cited by 221 publications

References 83 publications

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

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

GC‐biased gene conversion links the recombination landscape and demography to genomic base composition

Extensive introgressive hybridization within the northern oriole group (Genus Icterus) revealed by three‐species isolation with migration analysis

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