通过两种类型的双联体密码子实现遗传三联体密码的进化。

Evolution of the genetic triplet code via two types of doublet codons.

作者信息

Wu Huan-Lin, Bagby Stefan, van den Elsen Jean M H

机构信息

Department of Biology and Biochemistry, University of Bath, 4 South, Claverton Down, Bath BA2 7AY, UK.

出版信息

J Mol Evol. 2005 Jul;61(1):54-64. doi: 10.1007/s00239-004-0224-3. Epub 2005 Jul 19.

DOI:10.1007/s00239-004-0224-3

PMID:16059752

Abstract

Explaining the apparent non-random codon distribution and the nature and number of amino acids in the 'standard' genetic code remains a challenge, despite the various hypotheses so far proposed. In this paper we propose a simple new hypothesis for code evolution involving a progression from singlet to doublet to triplet codons with a reading mechanism that moves three bases each step. We suggest that triplet codons gradually evolved from two types of ambiguous doublet codons, those in which the first two bases of each three-base window were read ('prefix' codons) and those in which the last two bases of each window were read ('suffix' codons). This hypothesis explains multiple features of the genetic code such as the origin of the pattern of four-fold degenerate and two-fold degenerate triplet codons, the origin of its error minimising properties, and why there are only 20 amino acids.

摘要

尽管目前已经提出了各种假说，但解释“标准”遗传密码中明显的非随机密码子分布以及氨基酸的性质和数量仍然是一个挑战。在本文中，我们提出了一个关于密码子进化的简单新假说，该假说涉及从单联体密码子到双联体密码子再到三联体密码子的演变过程，其阅读机制是每步移动三个碱基。我们认为三联体密码子逐渐从两种模糊的双联体密码子进化而来，一种是读取每个三个碱基窗口的前两个碱基的双联体密码子（“前缀”密码子），另一种是读取每个窗口后两个碱基的双联体密码子（“后缀”密码子）。这一假说解释了遗传密码的多个特征，例如四重简并和二重简并三联体密码子模式的起源、其错误最小化特性的起源，以及为什么只有20种氨基酸。

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通过两种类型的双联体密码子实现遗传三联体密码的进化。

Evolution of the genetic triplet code via two types of doublet codons.

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