酿酒酵母中分支点-3'剪接位点间距及内含子末端核苷酸之间的相互作用在3'剪接位点选择中的作用

The role of branchpoint-3' splice site spacing and interaction between intron terminal nucleotides in 3' splice site selection in Saccharomyces cerevisiae.

作者信息

Luukkonen B G, Séraphin B

机构信息

European Molecular Biology Laboratory, Heidelberg, Germany.

出版信息

EMBO J. 1997 Feb 17;16(4):779-92. doi: 10.1093/emboj/16.4.779.

DOI:10.1093/emboj/16.4.779

PMID:9049307

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1169679/

Abstract

A conserved 3' splice site YAG is essential for the second step of pre-mRNA splicing but no trans-acting factor recognizing this sequence has been found. A direct, non-Watson-Crick interaction between the intron terminal nucleotides was suggested to affect YAG selection. The mechanism of YAG recognition was proposed to involve 5' to 3' scanning originating from the branchpoint or the polypyrimidine tract. We have constructed a yeast intron harbouring two closely spaced 3' splice sites. Preferential selection of a wild-type site over mutant ones indicated that the two sites are competing. For two identical sequences, the proximal site is selected. As previously observed, an A at the first intron nucleotide spliced most efficiently with a 3' splice site UAC. In this context, UAA or UAU were also more efficient 3' splice sites than UAG and competed more efficiently than the wild-type sequence with a 3' splice site UAC. We observed that a U at the first intron nucleotide is used for splicing in combination with 3' splice sites UAG, UAA or UAU. Our data indicate that the 3' splice site is not primarily selected through an interaction with the first intron nucleotide. Selection of the 3' splice site depends critically on its distance from the branchpoint but does not occur by a simple leaky scanning mechanism.

摘要

保守的3'剪接位点YAG对于前体mRNA剪接的第二步至关重要，但尚未发现识别该序列的反式作用因子。有人提出内含子末端核苷酸之间直接的非沃森-克里克相互作用会影响YAG的选择。有人提出YAG识别机制涉及从分支点或多嘧啶序列起始的5'到3'扫描。我们构建了一个含有两个紧密间隔的3'剪接位点的酵母内含子。野生型位点相对于突变位点的优先选择表明这两个位点存在竞争。对于两个相同的序列，近端位点被优先选择。如先前观察到的，第一个内含子核苷酸处的A与3'剪接位点UAC的剪接效率最高。在这种情况下，UAA或UAU也是比UAG更有效的3'剪接位点，并且与3'剪接位点UAC竞争时比野生型序列更有效。我们观察到第一个内含子核苷酸处的U与3'剪接位点UAG、UAA或UAU结合用于剪接。我们的数据表明，3'剪接位点并非主要通过与第一个内含子核苷酸的相互作用来选择。3'剪接位点的选择关键取决于其与分支点的距离，但并非通过简单的漏扫描机制发生。

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