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与CLF1的遗传相互作用鉴定出了其他前体mRNA剪接因子以及酵母囊泡运输激活因子与剪接之间的联系。

Genetic interactions with CLF1 identify additional pre-mRNA splicing factors and a link between activators of yeast vesicular transport and splicing.

作者信息

Vincent Kevin, Wang Qiang, Jay Steven, Hobbs Kathryn, Rymond Brian C

机构信息

Department of Biology, University of Kentucky, Lexington, Kentucky 40506-0225, USA.

出版信息

Genetics. 2003 Jul;164(3):895-907. doi: 10.1093/genetics/164.3.895.

DOI:10.1093/genetics/164.3.895
PMID:12871902
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1462608/
Abstract

Clf1 is a conserved spliceosome assembly factor composed predominately of TPR repeats. Here we show that the TPR elements are not functionally equivalent, with the amino terminus of Clf1 being especially sensitive to change. Deletion and add-back experiments reveal that the splicing defect associated with TPR removal results from the loss of TPR-specific sequence information. Twelve mutants were found that show synthetic growth defects when combined with an allele that lacks TPR2 (i.e., clf1Delta2). The identified genes encode the Mud2, Ntc20, Prp16, Prp17, Prp19, Prp22, and Syf2 splicing factors and four proteins without established contribution to splicing (Bud13, Cet1, Cwc2, and Rds3). Each synthetic lethal with clf1Delta2 (slc) mutant is splicing defective in a wild-type CLF1 background. In addition to the splicing factors, SSD1, BTS1, and BET4 were identified as dosage suppressors of clf1Delta2 or selected slc mutants. These results support Clf1 function through multiple stages of the spliceosome cycle, identify additional genes that promote cellular mRNA maturation, and reveal a link between Rab/Ras GTPase activation and the process of pre-mRNA splicing.

摘要

Clf1是一种主要由TPR重复序列组成的保守剪接体组装因子。我们在此表明,TPR元件在功能上并非等同,Clf1的氨基末端对变化尤为敏感。缺失和回补实验表明,与TPR去除相关的剪接缺陷是由于TPR特异性序列信息的丧失所致。发现有12个突变体,当与缺乏TPR2的等位基因(即clf1Delta2)结合时表现出合成生长缺陷。所鉴定的基因编码Mud2、Ntc20、Prp16、Prp17、Prp19、Prp22和Syf2剪接因子以及四种尚未确定对剪接有作用的蛋白质(Bud13、Cet1、Cwc2和Rds3)。每个与clf1Delta2合成致死(slc)的突变体在野生型CLF1背景下均存在剪接缺陷。除了剪接因子外,SSD1、BTS1和BET4被鉴定为clf1Delta2或选定的slc突变体的剂量抑制因子。这些结果支持Clf1在剪接体循环的多个阶段发挥作用,鉴定出促进细胞mRNA成熟的其他基因,并揭示了Rab/Ras GTPase激活与前体mRNA剪接过程之间的联系。

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