Identifying homomorphic sex chromosomes from wild‐caught adults with limited genomic resources

Brelsford, Alan; Lavanchy, Guillaume; Sermier, Roberto; Rausch, Anna; Perrin, Nicolas

doi:10.1111/1755-0998.12624

Cited by 52 publications

(81 citation statements)

References 35 publications

(55 reference statements)

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“…The library was sequenced on three Illumina HiSeq 2500 lanes (single read 125) and raw sequences were demultiplexed with Stacks v1.48 (Catchen, Hohenlohe, Bassham, Amores, & Cresko, ). We used the denovo.pl pipeline with default parameters ( –M 2, –m 3 and –n 2) to catalogue the tags sequenced in each sample, including additional RAD sequence reads from five individuals of R. arvalis (a close relative of R. temporaria ) obtained with the same protocol (Brelsford, Lavanchy, Sermier, Rausch, & Perrin, ), to be used as outgroups (Rarv49, Rarv70, Rarv92, Rarv66, Rarv81). For population genomic analyses across northern Spain, single nucleotide polymorphisms (SNPs) were called from RAD tags (118 bp sequences) sequenced in all populations (– p 33) and in all samples of each (– r 1), while discarding those bearing rare variants ( –min_maf 0.05) and those that were predominantly heterozygous ( –max_het_obs 0.75), which can represent overmerged paralogues.…”

Section: Methodsmentioning

confidence: 99%

Are glacial refugia hotspots of speciation and cytonuclear discordances? Answers from the genomic phylogeography of Spanish common frogs

et al. 2020

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Subdivided Pleistocene glacial refugia, best known as “refugia within refugia”, provided opportunities for diverging populations to evolve into incipient species and/or to hybridize and merge following range shifts tracking the climatic fluctuations, potentially promoting extensive cytonuclear discordances and “ghost” mtDNA lineages. Here, we tested which of these opposing evolutionary outcomes prevails in northern Iberian areas hosting multiple historical refugia of common frogs (Rana cf. temporaria), based on a genomic phylogeography approach (mtDNA barcoding and RAD‐sequencing). We found evidence for both incipient speciation events and massive cytonuclear discordances. On the one hand, populations from northwestern Spain (Galicia and Asturias, assigned to the regional endemic R. parvipalmata), are deeply‐diverged at mitochondrial and nuclear genomes (~4 My of independent evolution), and barely admix with northeastern populations (assigned to R. temporaria sensu stricto) across a narrow hybrid zone (~25 km) located in the Cantabrian Mountains, suggesting that they represent distinct species. On the other hand, the most divergent mtDNA clade, widespread in Cantabria and the Basque country, shares its nuclear genome with other R. temporaria s. s. lineages. Patterns of population expansions and isolation‐by‐distance among these populations are consistent with past mitochondrial capture and/or drift in generating and maintaining this ghost mitochondrial lineage. This remarkable case study emphasizes the complex evolutionary history that shaped the present genetic diversity of refugial populations, and stresses the need to revisit their phylogeography by genomic approaches, in order to make informed taxonomic inferences.

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Section: Methodsmentioning

confidence: 99%

Are glacial refugia hotspots of speciation and cytonuclear discordances? Answers from the genomic phylogeography of Spanish common frogs

et al. 2020

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“…Sex chromosome turnovers have also occurred multiple times in Ranid frogs, but only one has resulted in a change in the heterogametic sex (Sumida & Nishioka, 2000;Miura, 2008). Furthermore, the rate of turnovers that preserve the heterogamety pattern (XY to XY and ZW to ZW turnovers) is likely underappreciated in many taxa because of technical limitations (Brelsford et al, 2017). Some of the currently used methods to detect sex determination rely solely on the identification of sex-linked markers (which allow to distinguish between male and female heterogamety) but does not single out the sex chromosome pair, preventing the identification of turnovers within groups homogeneous for heterogamety (Gamble et al, 2015;Lambert et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Sex chromosome turnovers and genetic drift: a simulation study

Saunders

Neuenschwander

Perrin

2018

J of Evolutionary Biology

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The recent advances of new genomic technologies have enabled the identification and characterization of sex chromosomes in an increasing number of nonmodel species, revealing that many plants and animals undergo frequent sex chromosome turnovers. What evolutionary forces drive these turnovers remains poorly understood, but it was recently proposed that drift might play a more important role than generally assumed. We analysed the dynamics of different types of turnovers using individual-based simulations and show that when mediated by genetic drift, turnovers are usually easier to achieve than substitutions at neutral markers, but that their dynamics and relative likelihoods vary with the type of the resident and emergent sex chromosome system (XY and/or ZW) and the dominance relationships among the sex-determining factors. Focusing on turnovers driven by epistatically dominant mutations, we find that drift-mediated turnovers that preserve the heterogamety pattern are 2-4× more likely than those along which the heterogametic sex changes. This ratio nevertheless decreases along with effective population size and can even reverse in case of extreme polygyny. This can be attributed to a 'drift-induced' selective force, known to influence transitions between male and female heterogamety, but which according to our study does not affect turnovers that preserve the heterogametic sex.

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“…These strategies can potentially allow sex-linked regions to be discovered by cheaper reduced-representation sequencing (RRS) methods such as RAD-seq (Baird et al 2008;Elshire et al 2011;Peterson et al 2012), although the gained information will remain incomplete, because typically only a few percent of a genome is covered. Nevertheless, the discovery of sex-linked markers by RRS has been successful in organisms such as Crustaceans (Carmichael et al 2013), Anolis lizards (Gamble and Zarkower 2014), geckos (Gamble et al 2015a), and frogs (Brelsford et al 2017;Jeffries et al 2018).…”

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confidence: 99%

“…A major problem faced by approaches that use population polymorphism to infer sex-linkage, and sex specificity in particular, is error in the measurement of locus presence and absence (Text S4). Presence-absence error has long been recognized as a problem in fragment length genotyping methods, but it is exacerbated in RRS data, in which missing loci occur in a highly stochastic manner (Mastretta-Yanes et al 2015;Bresadola et al 2019), and can make sex-specific sequences appear in both sexes (Bewick et al 2013;Gamble and Zarkower 2014;Heikrujam et al 2015;Brelsford et al 2017), and probably represent false positive results. One suggested solution to reduce the number of false positives is to compare increasing numbers of males and females (Gamble and Zarkower 2014;Gamble et al 2015b).…”

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confidence: 99%

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

et al. 2019

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Species with separate sexes (dioecy) are a minority among flowering plants, but dioecy has evolved multiple times independently in their history. The sex‐determination system and sex‐linked genomic regions are currently identified in a limited number of dioecious plants only. Here, we study the sex‐determination system in a genus of dioecious plants that lack heteromorphic sex chromosomes and are not amenable to controlled breeding: Nepenthes pitcher plants. We genotyped wild populations of flowering males and females of three Nepenthes taxa using ddRAD‐seq and sequenced a male inflorescence transcriptome. We developed a statistical tool (privacy rarefaction) to distinguish true sex specificity from stochastic noise in read coverage of sequencing data from wild populations and identified male‐specific loci and XY‐patterned single nucleotide polymorphsims (SNPs) in all three Nepenthes taxa, suggesting the presence of homomorphic XY sex chromosomes. The male‐specific region of the Y chromosome showed little conservation among the three taxa, except for the essential pollen development gene DYT1 that was confirmed as male specific by PCR in additional Nepenthes taxa. Hence, dioecy and part of the male‐specific region of the Nepenthes Y‐chromosomes likely have a single evolutionary origin.

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Identifying homomorphic sex chromosomes from wild‐caught adults with limited genomic resources

Cited by 52 publications

References 35 publications

Are glacial refugia hotspots of speciation and cytonuclear discordances? Answers from the genomic phylogeography of Spanish common frogs

Are glacial refugia hotspots of speciation and cytonuclear discordances? Answers from the genomic phylogeography of Spanish common frogs

Sex chromosome turnovers and genetic drift: a simulation study

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

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