断裂基因的结构限制

Architectural limits on split genes.

作者信息

Sterner D A, Carlo T, Berget S M

机构信息

Verna and Marrs McLean Department of Biochemistry, Baylor College of Medicine, Houston, TX 77030, USA.

出版信息

Proc Natl Acad Sci U S A. 1996 Dec 24;93(26):15081-5. doi: 10.1073/pnas.93.26.15081.

DOI:10.1073/pnas.93.26.15081

PMID:8986767

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC26359/

Abstract

Exon/intron architecture varies across the eukaryotic kingdom with large introns and small exons the rule in vertebrates and the opposite in lower eukaryotes. To investigate the relationship between exon and intron size in pre-mRNA processing, internally expanded exons were placed in vertebrate genes with small and large introns. Both exon and intron size influenced splicing phenotype. Intron size dictated if large exons were efficiently recognized. When introns were large, large exons were skipped; when introns were small, the same large exons were included. Thus, large exons were incompatible for splicing if and only if they were flanked by large introns. Both intron and exon size became problematic at approximately 500 nt, although both exon and intron sequence influenced the size at which exons and introns failed to be recognized. These results indicate that present-day gene architecture reflects at least in part limitations on exon recognition. Furthermore, these results strengthen models that invoke pairing of splice sites during recognition of pre-mRNAs, and suggest that vertebrate consensus sequences support pairing across either introns or exons.

摘要

外显子/内含子结构在真核生物界中各不相同，在脊椎动物中，大内含子和小外显子是常见的，而在低等真核生物中则相反。为了研究前体mRNA加工过程中外显子和内含子大小之间的关系，将内部扩展的外显子置于含有大小不同内含子的脊椎动物基因中。外显子和内含子的大小都影响剪接表型。内含子大小决定了大外显子是否能被有效识别。当内含子较大时，大外显子会被跳过；当内含子较小时，相同的大外显子则会被保留。因此，只有当大外显子两侧都有大内含子时，它们才不适合进行剪接。尽管外显子和内含子序列都会影响外显子和内含子无法被识别的大小，但当长度约为500个核苷酸时，内含子和外显子的大小都会出现问题。这些结果表明，当今的基因结构至少部分反映了外显子识别的局限性。此外，这些结果强化了在前体mRNA识别过程中涉及剪接位点配对的模型，并表明脊椎动物的共有序列支持跨内含子或外显子的配对。

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本文引用的文献

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