保守二核苷酸的缺失会抑制II组内含子剪接的第二步。

Deletion of a conserved dinucleotide inhibits the second step of group II intron splicing.

作者信息

Mikheeva S, Murray H L, Zhou H, Turczyk B M, Jarrell K A

机构信息

Department of Pharmacology and Experimental Therapeutics, Boston University Medical Center, Massachusetts 02118, USA.

出版信息

RNA. 2000 Nov;6(11):1509-15. doi: 10.1017/s1355838200000972.

DOI:10.1017/s1355838200000972

PMID:11105751

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1370021/

Abstract

Few point mutations have been described that specifically inhibit the second step of group II intron splicing. Furthermore, the effects of such mutations are typically not apparent unless the mutations are studied in the context of a substrate that harbors a very short 5' exon. Truncation of the 5' exon slows the second step of splicing. Once the second step has been slowed, the effects of point mutations can be seen. We report the unexpected observation that the deletion of a conserved GA dinucleotide dramatically inhibits the second step of splicing, even when the mutation is studied in the context of a full-length substrate. In contrast, we find that this mutation does not significantly affect the first step of splicing, unless the mutation is studied in combination with a second point mutation that is known to inhibit the first step. Even in that context, the effect of the GA deletion mutation on the first step is modest. These observations, together with the inferred location of the GA dinucleotide in the three-dimensional structure of the intron, suggest that this dinucleotide plays a particularly important role in the second step of splicing.

摘要

很少有特定抑制II类内含子剪接第二步的点突变被描述。此外，除非在含有非常短的5'外显子的底物背景下研究这些突变，否则此类突变的影响通常并不明显。5'外显子的截短会减缓剪接的第二步。一旦第二步被减缓，点突变的影响就可以显现出来。我们报告了一个意外的观察结果，即保守的GA二核苷酸的缺失会显著抑制剪接的第二步，即使在全长底物背景下研究该突变也是如此。相比之下，我们发现该突变对剪接第一步没有显著影响，除非与已知抑制第一步的第二个点突变一起研究该突变。即使在那种情况下，GA缺失突变对第一步的影响也是适度的。这些观察结果，连同内含子三维结构中GA二核苷酸的推断位置，表明该二核苷酸在剪接的第二步中起特别重要的作用。

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