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

Darrier, Benoît; Rimbert, Hélène; Balfourier, François; Pingault, Lise; Josselin, Ambre-Aurore; Servin, Bertrand; Navarro, J. Alberto Romero; Choulet, Frédéric; Paux, Etienne; Sourdille, Pierre

doi:10.1534/genetics.116.196014

Cited by 75 publications

(115 citation statements)

References 117 publications

(208 reference statements)

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“…Using the 35K array we see the characteristic normal distribution of CO frequency, with an average of 41-52 COs per RIL, and a non-random distribution of COs between RILs and along the chromosomes (Huang et al, 2012;Esch et al, 2007;Darrier et al, 2017). There is a positive correlation between the number of genes in the CO interval and the number of RILs with the CO suggesting that perhaps recombination in gene rich regions leads to favourable phenotypes that are under selective pressure.…”

Section: Discussionmentioning

confidence: 93%

“…It is therefore important for us to understand recombination and GC if we are to alter their rates to accelerate the induction of novel allelic combinations or to generate stable cultivars. This is particularly important in bread wheat where recombination frequency is low and skewed toward the ends of chromosomes (Darrier et al, 2017). Wheat has a large (16Gb) complex allohexaploid genome and, in the light of recent advances in the wheat's genomic and genetic resources, it presents an excellent model crop (Brenchley et al, 2012;Clavijo et al, 2017;Krasileva et al, 2017;IWGSC et al 2018.…”

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confidence: 99%

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Analysis of the recombination landscape of hexaploid bread wheat reveals genes controlling recombination and gene conversion frequency

Gardiner

Wingen

Bailey

et al. 2019

Preprint

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Sequence exchange between homologous chromosomes through crossing over and gene conversion is highly conserved among eukaryotes, contributing to genome stability and genetic diversity. Lack of recombination limits breeding efforts in crops, therefore increasing recombination rates can reduce linkage-drag and generate new genetic combinations. We use computational analysis of 13 recombinant inbred mapping populations to assess crossover and gene conversion frequency in the hexaploid genome of wheat (Triticum aestivum). We observe that high frequency crossover sites are shared between populations and that closely related parental founders lead to populations with more similar crossover patterns. We demonstrate that gene conversion is more prevalent and covers more of the genome in wheat than in other plants, making it a critical process in the generation of new haplotypes, particularly in centromeric regions where crossovers are rare. We have identified QTL for altered gene conversion and crossover frequency and confirm functionality for a novel RecQ helicase gene that belongs to an ancient clade that is missing in some plant lineages including Arabidopsis. This is the first gene to be demonstrated to be involved in gene conversion in wheat. Harnessing the RecQ helicase has the potential to break linkage-drag utilizing widespread gene conversions. Main Text:There is an evolutionary requirement for genetic diversity across a species. Shuffling of material between homologous chromosomes, or genetic recombination, breaks linkage between genes resulting in offspring that have combinations of alleles that differ from those found in either of the parents. During meiosis, double-strand breaks (DSBs) can generate sequence variation in gametes via the DSB repair model (Szostak et al., 1983). DSBs are resolved either by homologous recombination as crossovers (COs) i.e. the reciprocal exchange of large regions between chromosomes, or otherwise as non-crossovers (NCOs). A minimum of one CO per chromosome during meiosis is a requirement for proper chromosome segregation (Pardo-Manuel De Villena and Sapienza, 2001). When both COs and NCOs are resolved, they can also give rise to gene conversions (GCs) as a mechanism of DSB repair involving the non-reciprocal transfer of short DNA segments between homologous non-sister chromatids (Sun et al., 2012;Halldorsson et al., 2016). GCs can be

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Section: Discussionmentioning

confidence: 93%

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confidence: 99%

Analysis of the recombination landscape of hexaploid bread wheat reveals genes controlling recombination and gene conversion frequency

Gardiner

Wingen

Bailey

et al. 2019

Preprint

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“…At this point, we can only speculate about the possible impact of meiotic recombination as a driving force towards maintaining a stable chromosome organization. Previous studies have shown that recombination in highly repetitive genomes occurs mainly in or near genes [39]. Thus, it might be important that spacing of genes is preserved for proper expression regulation or proper pairing during meiosis.…”

Section: A Stable Genome Structure Despite the Massive Reshuffling Ofmentioning

confidence: 99%

Impact of transposable elements on genome structure and evolution in bread wheat

Wicker¹,

Gundlach

Spannagl

et al. 2018

Preprint

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Background: Transposable elements (TEs) are ubiquitous components of genomes and they are the main contributors to genome evolution. The reference sequence of the hexaploid 2 bread wheat (Triticum aestivum L.) genome enabled for the first time a comprehensive genomewide view of the dynamics of TEs that have massively proliferated in the A, B, and D subgenomes.Results: TEs represent 85% of the genome. We traced back TE amplification dynamics in the evolutionary history of wheat and did not find large bursts in the wake of either the tetraor the hexaploidization. Despite the massive turnover of TEs since A, B, and D diverged, 76% of TE families are present in similar proportions in the three subgenomes. Moreover, spacing between homeologous genes was also conserved. TE content around genes is very different from the TE space comprising large intergenic regions and families that are enriched or depleted from gene promoters are the same in the three subgenomes. Conclusions:The chromosome-scale assembly of the wheat genome provided an unprecedented genome-wide view of the organization and impact of TEs in such a complex genome. Our results suggest that TEs play a role at the structural level and that the overall chromatin structure is likely under selection pressure.The genome of bread wheat (Triticum aestivum L.), one of the most important crop species, has also undergone massive TE amplification with over 85% of it being derived from such repeat elements. It is an allohexaploid comprised of three subgenomes (termed A, B, and D) that have diverged from a common ancestor around 2-3 million years ago (according to molecular dating of chloroplast DNA [16]) and hybridized within the last half million years. This led to the formation of a complex, redundant, and allohexaploid genome. These characteristics make the wheat genome by far the largest and most complex genome that has been sequenced and assembled into near complete chromosomes so far. They, however, also make wheat a unique system to study the impact of TE activity on genome structure, function and organization.Previously only one reference sequence quality wheat chromosome was available which we annotated using our automated TE annotation pipeline (CLARITE) [17,18]. However, it was unknown whether the TE content of chromosome 3B was typical of all wheat chromosomes and how TE content varied between the A, B, and D subgenomes. Therefore, in this study, we address the contribution of TEs to wheat genome evolution at a chromosome-wide scale. We report on the comparison of the three A-B-D subgenomes in terms of TE content and proliferation dynamics. We show that, although TEs have been completely reshuffled since A-B-D diverged, their proportions are quite conserved between subgenomes. In addition, the TE landscape in the direct vicinity of genes is very similar between the three subgenomes. Our results strongly suggest that TEs play a role at the structural level, and that the overall chromatin structure is likely under selection pressure. We also identified TE fa...

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“…Rht‐B1c ( Rht3 ), Rht‐D1c ( Rht10 ), Rht‐B1e ( Rht11 ) and Rht‐B1p ( Rht17 ) are orthologs of Rht‐B1b or Rht‐D1b (Bazhenov et al ., ; Wu et al ., ; Divashuk et al ., ; Li et al ., ,b, ). Fine mapping and map‐based cloning in wheat have become easier following the release of the Chinese Spring (CS, a wheat variety) genomic sequences by IWGSC (Darrier et al ., ), but to date no Rht gene has been isolated by map‐based cloning.…”

Section: Introductionmentioning

confidence: 99%

A wheat dominant dwarfing line with Rht12, which reduces stem cell length and affects gibberellic acid synthesis, is a 5AL terminal deletion line

Sun

Yang

et al. 2019

The Plant Journal

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These authors contributed equally to this work. SUMMARYDwarfing and semi-dwarfing are important agronomic traits that have great potential for the improvement of wheat yields. Rht12, a dominant gibberellic acid (GA)-responsive dwarfing gene from the gamma-rayinduced wheat mutant Karcagi 522M7K, is located in the long arm of chromosome 5A, which is closely linked with the locus Xwmc410. Rht12 is likely an ideal gene for GA biosynthesis and deactivation research in common wheat. However, information on the Rht12 locus and sequence is lacking. In this study, Rht12 significantly shortened stem cell length and decreased GA biosynthetic components. Using bulked segregant RNA-Seq, wheat 660k single nucleotide polymorphism chip detection, and newly developed simple sequence repeat markers, Rht12 was mapped to a 11.21-Mb region at the terminal end of chromosome 5AL, and was found to be closely linked with the Xw5ac207 SSR marker with a 10.73-Mb fragment deletion in all of the homologous dwarfing plants. Transcriptome analyses of the remaining 483-kb region showed significantly higher expression of the TraesCS5A01G543100 gene encoding the GA metabolic enzyme GA 2-b-dioxygenase in dwarfing plants than in high stalk plants, suggesting that Rht12 reduces plant height by activating TaGA2ox-A14. Taken together, our findings will promote cloning and functional studies of Rht12 in common wheat.

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

Cited by 75 publications

References 117 publications

Analysis of the recombination landscape of hexaploid bread wheat reveals genes controlling recombination and gene conversion frequency

Analysis of the recombination landscape of hexaploid bread wheat reveals genes controlling recombination and gene conversion frequency

Impact of transposable elements on genome structure and evolution in bread wheat

A wheat dominant dwarfing line with Rht12, which reduces stem cell length and affects gibberellic acid synthesis, is a 5AL terminal deletion line

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