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酿酒酵母cyc1基因座翻译起始缺陷的顺式和反式作用抑制因子。

cis- and trans-acting suppressors of a translation initiation defect at the cyc1 locus of Saccharomyces cerevisiae.

作者信息

Pinto I, Na J G, Sherman F, Hampsey M

机构信息

Department of Biochemistry and Molecular Biology, Louisiana State University Medical Center, Shreveport 71130.

出版信息

Genetics. 1992 Sep;132(1):97-112. doi: 10.1093/genetics/132.1.97.

DOI:10.1093/genetics/132.1.97
PMID:1327957
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1205134/
Abstract

The cyc1-362 mutant of Saccharomyces cerevisiae is deficient in iso-1-cytochrome c as a consequence of an aberrant ATG codon that initiates a short open reading frame (uORF) in the cyc1 transcribed leader region. We have isolated and characterized functional revertants of cyc1-362 in an effort to define cis- and trans-acting factors that can suppress the effect of the uORF. Genetic and DNA sequence analyses have defined three classes of revertants: (i) those that acquired point mutations in the upstream ATG (uATG), restoring iso-1-cytochrome c to its normal level; (ii) substitution of the normal A residue at position -1 relative to the uATG by either C or T, enhancing iso-1-cytochrome c production from approximately 2% to 6% (C) or 10% (T) of normal, indicating that the nucleotide immediately preceding the initiator codon can affect the efficiency of AUG start codon recognition and that purines are preferred over pyrimidines at this site; and (iii) extragenic suppressors that enhance iso-1-cytochrome c expression to 10-40% of normal while retaining the uATG. These suppressors are represented by five different genes, designated sua1-sua4 and sua6. In contrast to the previously described sua7 and sua8 suppressors, they do not compensate for the uATG by affecting cyc1 transcription start site selection. Potential suppressor mechanisms are discussed.

摘要

酿酒酵母的cyc1 - 362突变体缺乏同工型-1-细胞色素c,这是由于一个异常的ATG密码子导致的,该密码子在cyc1转录前导区启动了一个短开放阅读框(uORF)。我们分离并鉴定了cyc1 - 362的功能回复突变体,以确定能够抑制uORF效应的顺式和反式作用因子。遗传和DNA序列分析确定了三类回复突变体:(i)那些在上游ATG(uATG)中获得点突变的突变体,使同工型-1-细胞色素c恢复到正常水平;(ii)将相对于uATG的-1位正常A残基替换为C或T,使同工型-1-细胞色素c的产量从正常水平的约2%提高到6%(C)或10%(T),这表明起始密码子前的核苷酸会影响AUG起始密码子的识别效率,并且在此位点嘌呤比嘧啶更受青睐;(iii)基因外抑制子,可将同工型-1-细胞色素c的表达提高到正常水平的10 - 40%,同时保留uATG。这些抑制子由五个不同的基因代表,命名为sua1 - sua4和sua6。与先前描述的sua7和sua8抑制子不同,它们不会通过影响cyc1转录起始位点的选择来补偿uATG。文中讨论了潜在的抑制机制。

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