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

Alabdullah, Abdul Kader; Borrill, Philippa; Martín, Azahara C.; Ramírez-González, Ricardo H.; Hassani‐Pak, Keywan; Uauy, Cristóbal; Shaw, Peter; Moore, Graham

doi:10.1101/695759

Cited by 5 publications

(4 citation statements)

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“…Thus, on the polyploidisation of wheat, and despite the pre-existence of three ZIP4 copies, duplication and divergence of TaZIP4-B2 was required to promote homologous pairing-synapsis and prevent a potential 50% loss of grain number. These observations contrast with previous studies of polyploid brassicas, which exhibited more extensive chromosome rearrangements and loss of gene content upon polyploidisation [35,36] than is observed in wheat [9]. The absence of the main locus limiting homoeologous recombination in brassicas, BnaPh1 [37], reveals the importance of homoeologous CO suppression for preservation of genome stability in other polyploids.…”

Section: Homoeologous Crossover Suppression By Zip4 Is Not Essential To Maintain Wheat Fertilitycontrasting

confidence: 94%

“…Previous studies have revealed extensive chromosome rearrangements in some polyploids leading to changes in gene content and/or expression [3,5,6,7]. However, recent large-scale genome sequencing and RNA analysis has revealed that homoeologous (related) chromosomes of hexaploid wheat ( Triticum aestivum L.) did not exhibit extensive gene loss or expression changes following polyploidisation [8,9]. This suggests that a major factor rapidly evolved upon wheat polyploidisation to control the behaviour of its multiple genomes during meiosis, hence preserving fertility.…”

Section: Introductionmentioning

confidence: 99%

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A separation-of-functionZIP4wheat mutant allows crossover between related chromosomes and is meiotically stable

Martín

Alabdullah

Moore

2021

Preprint

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Many species, including most flowering plants, are polyploid, possessing multiple genomes. During polyploidisation, fertility is preserved via the evolution of mechanisms to control the behaviour of these multiple genomes during meiosis. On the polyploidisation of wheat, the major meiotic gene ZIP4 duplicated and diverged, with the resulting new gene TaZIP4-B2 being inserted into chromosome 5B. Previous studies showed that this TaZIP4-B2 promotes pairing and synapsis between wheat homologous chromosomes, whilst suppressing crossover between related (homoeologous) chromosomes. Moreover, in wheat, the presence of TaZIP4-B2 preserves up to 50% of grain number. The present study exploits a ′separation-of-function′ wheat Tazip4-B2 mutant named zip4-ph1d, in which the Tazip4-B2 copy still promotes correct pairing and synapsis between homologues (resulting in the same pollen profile and fertility normally found in wild type wheat), but which also allows crossover between the related chromosomes in wheat haploids of this mutant. This suggests an improved utility for the new zip4-ph1d mutant line during wheat breeding exploitation, compared to the previously described CRISPR Tazip4-B2 and ph1 mutant lines. The results also reveal that loss of suppression of homoeologous crossover between wheat chromosomes does not in itself reduce wheat fertility when promotion of homologous pairing and synapsis by TaZIP4-B2 is preserved.

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Section: Homoeologous Crossover Suppression By Zip4 Is Not Essential To Maintain Wheat Fertilitycontrasting

confidence: 94%

Section: Introductionmentioning

confidence: 99%

A separation-of-functionZIP4wheat mutant allows crossover between related chromosomes and is meiotically stable

Martín

Alabdullah

Moore

2021

Preprint

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“…This manuscript has been released as a pre-print at (Alabdullah et al, 2019). The authors would like to acknowledge the UK biotechnology and Biological Sciences Research Council (BBSRC; ) for supporting this work.…”

Section: Acknowledgmentsmentioning

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

et al. 2019

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Polyploidization has played an important role in plant evolution. However, upon polyploidization, the process of meiosis must adapt to ensure the proper segregation of increased numbers of chromosomes to produce balanced gametes. It has been suggested that meiotic gene (MG) duplicates return to a single copy following whole genome duplication to stabilize the polyploid genome. Therefore, upon the polyploidization of wheat, a hexaploid species with three related (homeologous) genomes, the stabilization process may have involved rapid changes in content and expression of MGs on homeologous chromosomes (homeologs). To examine this hypothesis, sets of candidate MGs were identified in wheat using co-expression network analysis and orthology informed approaches. In total, 130 RNA-Seq samples from a range of tissues including wheat meiotic anthers were used to define co-expressed modules of genes. Three modules were significantly correlated with meiotic tissue samples but not with other tissue types. These modules were enriched for GO terms related to cell cycle, DNA replication, and chromatin modification and contained orthologs of known MGs. Overall, 74.4% of genes within these meiosis-related modules had three homeologous copies which was similar to other tissue-related modules. Amongst wheat MGs identified by orthology, rather than co-expression, the majority (93.7%) were either retained in hexaploid wheat at the same number of copies (78.4%) or increased in copy number (15.3%) compared to ancestral wheat species. Furthermore, genes within meiosis-related modules showed more balanced expression levels between homeologs than genes in non-meiosis-related modules. Taken together, our results do not support extensive gene loss nor changes in homeolog expression of MGs upon wheat polyploidization. The construction of the MG co-expression network allowed identification of hub genes and provided key targets for future studies.

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“…KnetMiner is being used extensively to drive gene-trait discovery research in the publicly funded 'Designing Future Wheat' programme (https://designingfuturewheat.org.uk/), see for example (Adamski et al, 2020;Alabdullah et al, 2019;Harrington et al, 2020). Wheat (Triticum aestivum) is the third most-grown cereal crop in the world after maize and rice, and has a hexaploid 15 Gb genome which is 5 times the size of the human genome (The International Wheat Genome Sequencing Consortium Figure 1 Diverse and heterogenous FAIR data sets are harmonized into a knowledge graph using the KnetBuilder software.…”

Section: Gene Network Discoverymentioning

confidence: 99%

KnetMiner: a comprehensive approach for supporting evidence‐based gene discovery and complex trait analysis across species

Hassani‐Pak

Singh

Brandizi

et al. 2021

Plant Biotechnology Journal

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The generation of new ideas and scientific hypotheses is often the result of extensive literature and database searches, but, with the growing wealth of public and private knowledge, the process of searching diverse and interconnected data to generate new insights into genes, gene networks, traits and diseases is becoming both more complex and more time-consuming. To guide this technically challenging data integration task and to make gene discovery and hypotheses generation easier for researchers, we have developed a comprehensive software package called KnetMiner which is open-source and containerized for easy use. KnetMiner is an integrated, intelligent, interactive gene and gene network discovery platform that supports scientists explore and understand the biological stories of complex traits and diseases across species. It features fast algorithms for generating rich interactive gene networks and prioritizing candidate genes based on knowledge mining approaches. KnetMiner is used in many plant science institutions and has been adopted by several plant breeding organizations to accelerate gene discovery. The software is generic and customizable and can therefore be readily applied to new species and data types; for example, it has been applied to pest insects and fungal pathogens; and most recently repurposed to support COVID-19 research. Here, we give an overview of the main approaches behind KnetMiner and we report plant-centric case studies for identifying genes, gene networks and trait relationships in Triticum aestivum (bread wheat), as well as, an evidence-based approach to rank candidate genes under a large Arabidopsis thaliana QTL.

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

Cited by 5 publications

References 145 publications

A separation-of-functionZIP4wheat mutant allows crossover between related chromosomes and is meiotically stable

A separation-of-functionZIP4wheat mutant allows crossover between related chromosomes and is meiotically stable

A Co-Expression Network in Hexaploid Wheat Reveals Mostly Balanced Expression and Lack of Significant Gene Loss of Homeologous Meiotic Genes Upon Polyploidization

KnetMiner: a comprehensive approach for supporting evidence‐based gene discovery and complex trait analysis across species

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