Abstract
Reverse genetic techniques harnessing mutational approaches are powerful tools that can provide substantial insight into gene function in plants. However, as compared to diploid species, reverse genetic analyses in polyploid plants such as bread wheat can present substantial challenges associated with high levels of sequence and functional similarity amongst homoeologous loci. We previously developed a high-throughput method to identify deletions of genes within a physically mutagenized wheat population. Here we describe our efforts to combine multiple homoeologous deletions of three candidate disease susceptibility genes (TaWRKY11, TaPFT1 and TaPLDß1). We were able to produce lines featuring homozygous deletions at two of the three homoeoloci for all genes, but this was dependent on the individual mutants used in crossing. Intriguingly, despite extensive efforts, viable lines possessing homozygous deletions at all three homoeoloci could not be produced for any of the candidate genes. To investigate deletion size as a possible reason for this phenomenon, we developed an amplicon sequencing approach based on synteny to Brachypodium distachyon to assess the size of the deletions removing one candidate gene (TaPFT1) in our mutants. These analyses revealed that genomic deletions removing the locus are relatively large, resulting in the loss of multiple additional genes. The implications of this work for the use of heavy ion mutagenesis for reverse genetic analyses in wheat are discussed.
Highlights
Recent advances in high-throughput sequencing technologies have vastly increased understanding of gene content and variation within many plant species [1]
We observed an average frequency of candidate gene deletions within the heavy ion irradiation (HII) population of approximately 0.3% (i.e. 3 independent deletions in the same gene in 1000 lines) [15]
We developed an amplicon sequencing approach based on synteny to Brachypodium distachyon to investigate the size of the deletions removing TaPFT1 (Materials and Methods)
Summary
Recent advances in high-throughput sequencing technologies have vastly increased understanding of gene content and variation within many plant species [1]. For some plants such as Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa), completed genome sequences are available and re-sequencing of numerous accessions has been performed [2], [3]. Gene inactivation is a powerful approach for the study of gene function, and has contributed substantially to our current knowledge in this area [8]. In instances where the loss of function of a gene is known or predicted to confer a desirable agronomic or quality phenotype, gene inactivation has potential to be used as a tool for crop improvement, e.g. In instances where the loss of function of a gene is known or predicted to confer a desirable agronomic or quality phenotype, gene inactivation has potential to be used as a tool for crop improvement, e.g. [9]
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