Abstract
BackgroundThe proteasome subunit RPT5, which is essential for gametophyte development, is encoded by two genes in Arabidopsis thaliana; RPT5a and RPT5b. We showed previously that RPT5a and RPT5b are fully redundant in the Columbia (Col-0) accession, whereas in the Wassilewskia accession (Ws-4), RPT5b does not complement the effect of a strong rpt5a mutation in the male gametophyte, and only partially complements rpt5a mutation in the sporophyte. RPT5bCol-0 and RPT5bWs-4 differ by only two SNPs, one located in the promoter and the other in the seventh intron of the gene.ResultsBy exploiting natural variation at RPT5b we determined that the SNP located in RPT5b intron seven, rather than the promoter SNP, is the sole basis of this lack of redundancy. In Ws-4 this SNP is predicted to create a new splicing branchpoint sequence that induces a partial mis-splicing of the pre-mRNA, leading to the introduction of a Premature Termination Codon. We characterized 5 accessions carrying this A-to-T substitution in intron seven and observed a complete correlation between this SNP and both a 10 to 20% level of the RPT5b pre-mRNA mis-splicing and the lack of ability to complement an rpt5a mutant phenotype.ConclusionThe accession-dependent unequal redundancy between RPT5a and RPT5b genes illustrates an example of evolutionary drifting between duplicated genes through alternative splicing.
Highlights
The proteasome subunit RPT5, which is essential for gametophyte development, is encoded by two genes in Arabidopsis thaliana; RPT5a and RPT5b
Evolution through alternative splicing may contribute to the creation of new functions through exon sliding [11], it has mainly been described as inducing Premature Termination Codon (PTC)
We presumed that the two SNPs highlighted between the RPT5bCol-0 and RPT5bWs-4 alleles were responsible for their different abilities to complement the male gametophyte lethal phenotype in a rpt5a background
Summary
The proteasome subunit RPT5, which is essential for gametophyte development, is encoded by two genes in Arabidopsis thaliana; RPT5a and RPT5b. Gene evolution can be assessed by studying natural variation in a single species. Alternative splicing, that creates multiple mRNA from the same gene unit, has been described recently as a source of variation among natural accessions. This process alters FLC function in the Arabidopsis accession Bur-0 [9] as well as in some Brassica rapa accessions [10]. Evolution through alternative splicing may contribute to the creation of new functions through exon sliding [11], it has mainly been described as inducing Premature Termination Codon (PTC). The extent of variation in alternative splicing among accessions in a single species is not known
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