关于遗传编码相互作用中模糊性的物理基础。

On the physical basis for ambiguity in genetic coding interactions.

作者信息

Grosjean H J, de Henau S, Crothers D M

出版信息

Proc Natl Acad Sci U S A. 1978 Feb;75(2):610-4. doi: 10.1073/pnas.75.2.610.

DOI:10.1073/pnas.75.2.610

PMID:273223

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC411305/

Abstract

We report the relative stabilities, in the form of complex lifetimes, of complexes between the tRNAs complementary, or nearly so, in their anticodons. The results show striking parallels with the genetic coding rules, including the wobble interaction and the role of modified nucleotides S2U and V (a 5-oxyacetic acid derivative of U). One important difference between the genetic code and the pairing rules in the tRNA-tRNA interaction is the stability in the latter of the short wobble pairs, which the wobble hypothesis excludes. We stress the potential of U for translational errors, and suggest a simple stereochemical basis for ribosome-mediated discrimination against short wobble pairs. Surprisingly, the stability of anticodon-anticodon complexes does not vary systematically on base sequence. Because of the close similarity to the genetic coding rules, it is tempting to speculate that the interaction between two RNA loops may have been part of the physical basis for the evolutionary origin of the genetic code, and that this mechanism may still be utilized by folding the mRNA on the ribosome into a loop similar to the anticodon loop.

摘要

我们报告了反密码子互补或近乎互补的tRNA之间复合物的相对稳定性，以复合物寿命的形式呈现。结果显示与遗传编码规则有惊人的相似之处，包括摆动相互作用以及修饰核苷酸S2U和V（U的5-氧乙酸衍生物）的作用。遗传密码与tRNA-tRNA相互作用中的配对规则之间的一个重要区别是短摆动对在后者中的稳定性，而摆动假说排除了这种稳定性。我们强调U导致翻译错误的可能性，并提出了核糖体介导的对短摆动对歧视的简单立体化学基础。令人惊讶的是，反密码子-反密码子复合物的稳定性在碱基序列上并没有系统地变化。由于与遗传编码规则非常相似，人们不禁推测两个RNA环之间的相互作用可能是遗传密码进化起源的物理基础的一部分，并且这种机制可能仍然通过将核糖体上的mRNA折叠成类似于反密码子环的环来发挥作用。

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本文引用的文献

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