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

Gardiner, Laura‐Jayne; Wingen, Luzie U.; Bailey, Paul; Joynson, Ryan; Brabbs, Thomas; Wright, Jonathan; Higgins, James D.; Hall, Neil; Griffiths, Simon; Clavijo, Bernardo; Hall, Anthony

doi:10.1186/s13059-019-1675-6

Cited by 66 publications

(60 citation statements)

References 52 publications

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“…The mean number of bivalents per cell was 20.97 6 0.03 (n 5 36) and the total number of chiasmata per cell was 40 6 0.28 (n 5 36), which are predominantly distally distributed (76.5%). This is consistent with a computational analysis of 13 recombinant inbred mapping populations, which gave values of 40.8 to 51.9 COs per line, typically clustered toward the ends of chromosomes (Gardiner et al, 2019).…”

Section: Hexaploid Wheat Maintains the Obligate Chiasma Despite Losssupporting

confidence: 89%

MutS homologue 4 and MutS homologue 5 Maintain the Obligate Crossover in Wheat Despite Stepwise Gene Loss following Polyploidization

et al. 2020

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Crossovers (COs) ensure accurate chromosome segregation during meiosis while creating novel allelic combinations. Here, we show that allotetraploid (AABB) durum wheat (Triticum turgidum ssp. durum) utilizes two pathways of meiotic recombination. The class I pathway requires MSH4 and MSH5 (MutSg) to maintain the obligate CO/chiasma and accounts for ;85% of meiotic COs, whereas the residual ;15% are consistent with the class II CO pathway. Class I and class II chiasmata are skewed toward the chromosome ends, but class II chiasmata are significantly more distal than class I chiasmata. Chiasma distribution does not reflect the abundance of double-strand breaks, detected by proxy as RAD51 foci at leptotene, but only ;2.3% of these sites mature into chiasmata. MutSg maintains the obligate chiasma despite a 5.4-kb deletion in MSH5B rendering it nonfunctional, which occurred early in the evolution of tetraploid wheat and was then domesticated into hexaploid (AABBDD) common wheat (Triticum aestivum), as well as an 8-kb deletion in MSH4D in hexaploid wheat, predicted to create a nonfunctional pseudogene. Stepwise loss of MSH5B and MSH4D following hybridization and whole-genome duplication may have occurred due to gene redundancy (as functional copies of MSH5A, MSH4A, and MSH4B are still present in the tetraploid and MSH5A, MSH5D, MSH4A, and MSH4B are present in the hexaploid) or as an adaptation to modulate recombination in allopolyploid wheat.

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Section: Hexaploid Wheat Maintains the Obligate Chiasma Despite Losssupporting

confidence: 89%

MutS homologue 4 and MutS homologue 5 Maintain the Obligate Crossover in Wheat Despite Stepwise Gene Loss following Polyploidization

et al. 2020

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“…Thus, in comparison to model plants (Arabidopsis and rice), few MGs have been functionally characterized in wheat. Characterised wheat MGs include TaASY1 [ 54,55 ], TaMSH7 [ 56 ], TaRAD51 [ 57,58 ], TaDMC1 [ 57,58 ], TaPSH1 [ 59 ], TaZIP4 [ 31-33 ] and RecQ-7 [ 60 ]. Given that, the assessment of whether the three modules contain known MGs was undertaken using orthology informed approaches.…”

Section: Resultsmentioning

confidence: 99%

A co-expression network in hexaploid wheat reveals mostly balanced expression and lack of significant gene loss of homeologous meiotic genes upon polyploidization

Alabdullah

Borrill

Martín

et al. 2019

Preprint

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14Polyploidization has played an important role in plant evolution. However, upon polyploidization the 15 process of meiosis must adapt to ensure the proper segregation of increased numbers of chromosomes 16 to produce balanced gametes. It has been suggested that meiotic gene (MG) duplicates return to a 17 single copy following whole genome duplication to stabilise the polyploid genome. Therefore, upon 18 the polyploidization of wheat, a hexaploid species with three related (homeologous) genomes, the 19 stabilization process may have involved rapid changes in content and expression of MGs on 20 homeologous chromosomes (homeologs). To examine this hypothesis, sets of candidate MGs were 21 identified in wheat using co-expression network analysis and orthology informed approaches. In total, 22 130 RNA-Seq samples from a range of tissues including wheat meiotic anthers were used to define 23 co-expressed modules of genes. Three modules were significantly correlated with meiotic tissue 24 samples but not with other tissue types. These modules were enriched for GO terms related to cell 25 cycle, DNA replication and chromatin modification, and contained orthologs of known MGs. Overall 26 74.4 % of genes within these meiosis-related modules had three homeologous copies which was 27 similar to other tissue-related modules. Amongst wheat MGs identified by orthology, rather than co-28 expression, the majority (93.7 %) were either retained in hexaploid wheat at the same number of 29 copies (78.4 %) or increased in copy number (15.3%) compared to ancestral wheat species. 30 Furthermore, genes within meiosis-related modules showed more balanced expression levels between 31 homeologs than genes in non-meiosis-related modules. Taken together our results do not support 32 extensive gene loss nor changes in homeolog expression of MGs upon wheat polyploidization. The 33 construction of the MG co-expression network allowed identification of hub genes and provided key 34 targets for future studies. 35 36 Author summary 37 All flowering plants have undergone a polyploidization event(s) during their evolutionary history. One 38of the biggest challenges faced by a newly-formed polyploid is meiosis, an essential event for sexual 39 reproduction and fertility. This process must adapt to discriminate between multiple related 40 chromosomes and to ensure their proper segregation to produce fertile gametes. The meiotic 41 mechanisms responsible for the stabilisation of the extant polyploids remain poorly understood except 42 in wheat, where there is now a better understanding of these processes. It has been proposed that 43 meiotic adaptation in established polyploids could involve meiotic gene loss following the event of 44 polyploidization. To test this hypothesis in hexaploid wheat, we have computationally predicted sets 45 of hexaploid wheat meiotic genes based on expression data from different tissue types, including 46 meiotic anther tissue, and orthology informed approaches. We have calculated homeolog expression 47 patterns and numbe...

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“…Until now, only a dozen of genes (TaRAD51,TaRAD51C,TaRAD51D,TaDMC1,TaMRE11,TaRAD50,TaASY1,TaZYP1,TaPHS1,TaPh1,, among more than 100 known as involved in meiotic recombination in plants, have been cloned and significantly analysed in wheat. These analyses have mainly been limited to comparisons of sequences of homoeologous copies, expression analyses and immunolocalization (Boden et al, 2007;de Bustos et al, 2007;Boden et al, 2009;Devisetty et al, 2010;Perez et al, 2011;Khoo et al, 2012a;Khoo et al, 2012b;Ma et al, 2018;Gardiner et al, 2019). TaPh1, which controls homoeologous recombination in wheat, remains the best-defined locus involved in meiosis in wheat (Griffiths et al, 2006;Moore, 2014;Martin et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Bread wheat TaSPO11‐1 exhibits evolutionarily conserved function in meiotic recombination across distant plant species

et al. 2020

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SUMMARY The manipulation of meiotic recombination in crops is essential to develop new plant varieties rapidly, helping to produce more cultivars in a sustainable manner. One option is to control the formation and repair of the meiosis‐specific DNA double‐strand breaks (DSBs) that initiate recombination between the homologous chromosomes and ultimately lead to crossovers. These DSBs are introduced by the evolutionarily conserved topoisomerase‐like protein SPO11 and associated proteins. Here, we characterized the homoeologous copies of the SPO11‐1 protein in hexaploid bread wheat (Triticum aestivum). The genome contains three SPO11‐1 gene copies that exhibit 93–95% identity at the nucleotide level, and clearly the A and D copies originated from the diploid ancestors Triticum urartu and Aegilops tauschii, respectively. Furthermore, phylogenetic analysis of 105 plant genomes revealed a clear partitioning between monocots and dicots, with the seven main motifs being almost fully conserved, even between clades. The functional similarity of the proteins among monocots was confirmed through complementation analysis of the Oryza sativa (rice) spo11‐1 mutant by the wheat TaSPO11‐1‐5D coding sequence. Also, remarkably, although the wheat and Arabidopsis SPO11‐1 proteins share only 55% identity and the partner proteins also differ, the TaSPO11‐1‐5D cDNA significantly restored the fertility of the Arabidopsis spo11‐1 mutant, indicating a robust functional conservation of the SPO11‐1 protein activity across distant plants. These successful heterologous complementation assays, using both Arabidopsis and rice hosts, are good surrogates to validate the functionality of candidate genes and cDNA, as well as variant constructs, when the transformation and mutant production in wheat is much longer and more tedious.

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

Cited by 66 publications

References 52 publications

MutS homologue 4 and MutS homologue 5 Maintain the Obligate Crossover in Wheat Despite Stepwise Gene Loss following Polyploidization

MutS homologue 4 and MutS homologue 5 Maintain the Obligate Crossover in Wheat Despite Stepwise Gene Loss following Polyploidization

A co-expression network in hexaploid wheat reveals mostly balanced expression and lack of significant gene loss of homeologous meiotic genes upon polyploidization

Bread wheat TaSPO11‐1 exhibits evolutionarily conserved function in meiotic recombination across distant plant species

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