Microbiology and Molecular Genetics Department, University of Texas Health Science Center-Houston, Houston, Texas 77030, USA.
Department of Chemistry and Biochemistry, University of St. Thomas, Houston, Texas 77006, USA.
RNA. 2020 Oct;26(10):1464-1480. doi: 10.1261/rna.075655.120. Epub 2020 Jul 6.
Many eukaryotes use RNA processing, including alternative splicing, to express multiple gene products from the same gene. The budding yeast has been successfully used to study the mechanism of splicing and the splicing machinery, but alternative splicing in yeast is relatively rare and has not been extensively studied. Alternative splicing of is widely conserved, but yeast and a few other eukaryotes have replaced this one alternatively spliced gene with a pair of duplicated, unspliced genes as part of a whole genome doubling (WGD). We show that other examples of alternative splicing known to have functional consequences are widely conserved within Saccharomycotina. A common mechanism by which alternative splicing has disappeared is by replacement of an alternatively spliced gene with duplicate unspliced genes. This loss of alternative splicing does not always take place soon after duplication, but can take place after sufficient time has elapsed for speciation. Saccharomycetaceae that diverged before WGD use alternative splicing more frequently than , suggesting that WGD is a major reason for infrequent alternative splicing in yeast. We anticipate that WGDs in other lineages may have had the same effect. Having observed that two functionally distinct splice-isoforms are often replaced by duplicated genes allowed us to reverse the reasoning. We thereby identify several splice isoforms that are likely to produce two functionally distinct proteins because we find them replaced by duplicated genes in related species. We also identify some alternative splicing events that are not conserved in closely related species and unlikely to produce functionally distinct proteins.
许多真核生物利用 RNA 加工,包括可变剪接,从同一个基因表达多个基因产物。 budding yeast 已成功用于研究剪接机制和剪接机制,但酵母中的可变剪接相对较少,尚未得到广泛研究。 的可变剪接广泛保守,但酵母和其他少数真核生物已将这个可变剪接基因替换为一对未剪接的重复基因,作为全基因组加倍 (WGD) 的一部分。我们表明,其他具有功能后果的已知可变剪接的例子在 Saccharomycotina 中广泛保守。可变剪接消失的常见机制是通过用重复的未剪接基因替换可变剪接基因。这种可变剪接的丧失并不总是在复制后立即发生,而是可以在足够的时间过去以发生物种形成之后发生。在 WGD 之前分化的 Saccharomycetaceae 比 更频繁地使用可变剪接,这表明 WGD 是酵母中可变剪接不频繁的主要原因。我们预计其他谱系中的 WGD 可能产生了相同的效果。观察到两种功能不同的剪接异构体通常被重复基因取代,这使我们能够反向推理。因此,我们确定了几种剪接异构体,它们很可能产生两种功能不同的蛋白质,因为我们发现它们在相关物种中被重复基因取代。我们还鉴定了一些在密切相关的物种中没有保守的可变剪接事件,并且不太可能产生具有不同功能的蛋白质。
