Recombining without Hotspots: A Comprehensive Evolutionary Portrait of Recombination in Two Closely Related Species of Drosophila

Heil, Caiti Smukowski; Dubin, Matthew E.; Noor, Mohamed A. F.

doi:10.1101/016972

Cited by 13 publications

(17 citation statements)

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“…P-values are 0.05 (*) and 0.01 (**). (Hellsten et al 2013), or Drosophila (Smukowski Heil et al 2015). Specific recombination intensities were different depending on the collection used which could be attributed to the difference in LD patterns at fine scale in the two populations, or differences arising from the complex evolutionary histories of the two genetic pools we used.…”

Section: Discussionmentioning

confidence: 99%

“…This switch can be detected by genotyping the progenies derived from biparental or multi-parental crosses (for a review see Huang et al 2015) but is limited by a constrained number of COs (Darvasi et al 1993). Statistical approaches were also developed to estimate the population recombination parameter, r, and to computationally infer genome-wide, population-averaged recombination rates (McVean et al 2002(McVean et al , 2004Li and Stephens 2003;Slatkin 2008;Hellsten et al 2013;Smukowski Heil et al 2015). These approaches, also termed "coalescent analysis," rely on linkage disequilibrium (LD) patterns in populations which represent a nonrandom association of alleles at different loci (Lewontin and Kojima 1960).…”

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confidence: 99%

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High-Resolution Mapping of Crossover Events in the Hexaploid Wheat Genome Suggests a Universal Recombination Mechanism

et al. 2017

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During meiosis, crossovers (COs) create new allele associations by reciprocal exchange of DNA. In bread wheat (Triticum aestivum L.), COs are mostly limited to subtelomeric regions of chromosomes, resulting in a substantial loss of breeding efficiency in the proximal regions, though these regions carry 60-70% of the genes. Identifying sequence and/or chromosome features affecting recombination occurrence is thus relevant to improve and drive recombination. Using the recent release of a reference sequence of chromosome 3B and of the draft assemblies of the 20 other wheat chromosomes, we performed fine-scale mapping of COs and revealed that 82% of COs located in the distal ends of chromosome 3B representing 19% of the chromosome length. We used 774 SNPs to genotype 180 varieties representative of the Asian and European genetic pools and a segregating population of 1270 F 6 lines. We observed a common location for ancestral COs (predicted through linkage disequilibrium) and the COs derived from the segregating population. We delineated 73 small intervals (,26 kb) on chromosome 3B that contained 252 COs. We observed a significant association of COs with genic features (73 and 54% in recombinant and nonrecombinant intervals, respectively) and with those expressed during meiosis (67% in recombinant intervals and 48% in nonrecombinant intervals). Moreover, while the recombinant intervals contained similar amounts of retrotransposons and DNA transposons (42 and 53%), nonrecombinant intervals had a higher level of retrotransposons (63%) and lower levels of DNA transposons (28%). Consistent with this, we observed a higher frequency of a DNA motif specific to the TIR-Mariner DNA transposon in recombinant intervals. KEYWORDS recombination; meiosis; bread wheat; linkage disequilibrium; transposon; hotspot; sequence motif M EIOTIC recombination is a process that allows reshuffling of diversity by the reciprocal exchange of DNA called a crossover (CO). This phenomenon is conserved in most eukaryotes (for a review see Mercier et al. 2015) and follows the formation of a double-strand break (DSB) of DNA generated by the topoisomerase SPO11 complex. However, the number of DSBs is at least 10-to 50-fold greater than the number of COs which rarely exceeds three per bivalent chromosome per meiosis (Mercier et al. 2015). This paucity of COs per meiosis with regards to the number of DSBs suggests the existence of a tight control and regulation of recombination in plants that promote DSB repair in a manner that does not lead to COs. For example, the study of the two helicases AtFANCM and RECQ4 (AtRECQ4A and AtRECQ4B) (Crismani et al. 2012;Knoll et al. 2012;Girard et al. 2014;Séguéla-Arnaud et al. 2015) revealed three-and sixfold CO frequency increases in the Atfancm single mutant and the Atrecq4a/Atrecq4b double mutant, respectively, compared to the wild type. These increases result from additional COs from the class-II pathway which suggests that FANCM and RECQ4 prevent CO formation and direct recombination intermediates towar...

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Section: Discussionmentioning

confidence: 99%

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High-Resolution Mapping of Crossover Events in the Hexaploid Wheat Genome Suggests a Universal Recombination Mechanism

et al. 2017

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“…Interestingly, DSB hotspots are well conserved between the Schizosaccharomyces species S. pombe and S. kambucha (~0.5% sequence divergence) (34) despite mapping to sites without known function (35). In contrast, in Drosophila , which lacks a PRDM9-like system but also does not preferentially target recombination to promoters or known functional elements, the fine-scale distribution of recombination appears to evolve rapidly (36). …”

Section: Discussionmentioning

confidence: 99%

Nonparadoxical evolutionary stability of the recombination initiation landscape in yeast

Lam

Keeney

2015

Science

122

141

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The nonrandom distribution of meiotic recombination shapes heredity and genetic diversification. Theoretically, hotspots — favored sites of recombination initiation — either evolve rapidly toward extinction or are conserved, especially if they are chromosomal features under selective constraint, such as promoters. We tested these theories by comparing genome-wide recombination initiation maps from widely divergent Saccharomyces species. We find that hotspots frequently overlap with promoters in the species tested and, consequently, hotspot positions are well conserved. Remarkably, the relative strength of individual hotspots is also highly conserved, as are larger-scale features of the distribution of recombination initiation. This stability, not predicted by prior models, suggests that the particular shape of the yeast recombination landscape is adaptive, and helps in understanding evolutionary dynamics of recombination in other species.

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“…We downloaded population genomic datasets including 11 D. pseudoobscura individuals from seven different populations and 12 D. miranda individuals from two studies (McGaugh and Noor 2012;Zhou and Bachtrog 2012;Smukowski Heil et al 2015; NCBI accession numbers in Table S6). After trimming with Trim Galore (v0.4.0; http://www.bioinformatics.babraham.ac.uk/projects/trim_galore/), we mapped all reads to the genome using a pipeline modified from Lack et al (2015; https://github.com/justin-lack/Drosophila-Genome-Nexus/blob/master/round1_assembly.pl).…”

Section: Discussionmentioning

confidence: 99%

Genomic changes following the reversal of a Y chromosome to an autosome inDrosophila pseudoobscura

Chang

Larracuente

2017

Evolution

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Robertsonian translocations resulting in fusions between sex chromosomes and autosomes shape karyotype evolution by creating new sex chromosomes from autosomes. These translocations can also reverse sex chromosomes back into autosomes, which is especially intriguing given the dramatic differences between autosomes and sex chromosomes. To study the genomic events following a Y chromosome reversal, we investigated an autosome-Y translocation in Drosophila pseudoobscura. The ancestral Y chromosome fused to a small autosome (the dot chromosome) approximately 10–15 Mya. We used single molecule real-time sequencing reads to assemble the D. pseudoobscura dot chromosome, including this Y-to-dot translocation. We find that the intervening sequence between the ancestral Y and the rest of the dot chromosome is only ~78 Kb and is not repeat-dense, suggesting that the centromere now falls outside, rather than between, the fused chromosomes. The Y-to-dot region is 100 times smaller than the D. melanogaster Y chromosome, owing to changes in repeat landscape. However, we do not find a consistent reduction in intron sizes across the Y-to-dot region. Instead, deletions in intergenic regions and possibly a small ancestral Y chromosome size may explain the compact size of the Y-to-dot translocation.

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Recombining without Hotspots: A Comprehensive Evolutionary Portrait of Recombination in Two Closely Related Species of Drosophila

Cited by 13 publications

References 109 publications

High-Resolution Mapping of Crossover Events in the Hexaploid Wheat Genome Suggests a Universal Recombination Mechanism

High-Resolution Mapping of Crossover Events in the Hexaploid Wheat Genome Suggests a Universal Recombination Mechanism

Nonparadoxical evolutionary stability of the recombination initiation landscape in yeast

Genomic changes following the reversal of a Y chromosome to an autosome inDrosophila pseudoobscura

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