来自甘氨酸转运RNA的证据表明，在遗传密码诞生之初发生了一次冻结事故。

Evidence from glycine transfer RNA of a frozen accident at the dawn of the genetic code.

作者信息

Bernhardt Harold S, Tate Warren P

机构信息

Department of Biochemistry, Otago School of Medical Sciences, University of Otago, Dunedin, New Zealand.

出版信息

Biol Direct. 2008 Dec 17;3:53. doi: 10.1186/1745-6150-3-53.

DOI:10.1186/1745-6150-3-53

PMID:19091122

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2630981/

Abstract

BACKGROUND

Transfer RNA (tRNA) is the means by which the cell translates DNA sequence into protein according to the rules of the genetic code. A credible proposition is that tRNA was formed from the duplication of an RNA hairpin half the length of the contemporary tRNA molecule, with the point at which the hairpins were joined marked by the canonical intron insertion position found today within tRNA genes. If these hairpins possessed a 3'-CCA terminus with different combinations of stem nucleotides (the ancestral operational RNA code), specific aminoacylation and perhaps participation in some form of noncoded protein synthesis might have occurred. However, the identity of the first tRNA and the initial steps in the origin of the genetic code remain elusive.

RESULTS

Here we show evidence that glycine tRNA was the first tRNA, as revealed by a vestigial imprint in the anticodon loop sequences of contemporary descendents. This provides a plausible mechanism for the missing first step in the origin of the genetic code. In 448 of 466 glycine tRNA gene sequences from bacteria, archaea and eukaryote cytoplasm analyzed, CCA occurs immediately upstream of the canonical intron insertion position, suggesting the first anticodon (NCC for glycine) has been captured from the 3'-terminal CCA of one of the interacting hairpins as a result of an ancestral ligation.

CONCLUSION

That this imprint (including the second and third nucleotides of the glycine tRNA anticodon) has been retained through billions of years of evolution suggests Crick's 'frozen accident' hypothesis has validity for at least this very first step at the dawn of the genetic code.

REVIEWERS

This article was reviewed by Dr Eugene V. Koonin, Dr Rob Knight and Dr David H Ardell.

摘要

背景

转运RNA（tRNA）是细胞根据遗传密码规则将DNA序列翻译为蛋白质的媒介。一个可信的观点是，tRNA由当代tRNA分子长度一半的RNA发夹结构复制而来，发夹结构连接点由如今在tRNA基因中发现的典型内含子插入位置标记。如果这些发夹结构拥有带有不同茎核苷酸组合的3'-CCA末端（原始操作RNA密码），可能已经发生了特定的氨酰化作用以及或许参与了某种形式的非编码蛋白质合成。然而，首个tRNA的身份以及遗传密码起源的初始步骤仍然难以捉摸。

结果

我们在此展示证据，表明甘氨酸tRNA是首个tRNA，这由当代后代反密码子环序列中的残留印记揭示。这为遗传密码起源中缺失的第一步提供了一个合理的机制。在分析的来自细菌、古菌和真核生物细胞质的466个甘氨酸tRNA基因序列中的448个序列里，CCA紧挨着典型内含子插入位置的上游出现，这表明首个反密码子（甘氨酸的NCC）是由于一次祖先连接事件从一个相互作用发夹结构的3'-末端CCA捕获而来。

结论

这个印记（包括甘氨酸tRNA反密码子的第二个和第三个核苷酸）历经数十亿年的进化得以保留，这表明克里克的“冻结偶然”假说至少在遗传密码起源之初的这第一步是有效的。

评审人

本文由尤金·V·库宁博士、罗布·奈特博士和大卫·H·阿德尔博士评审。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7ac9/2630981/1382c4600df8/1745-6150-3-53-1.jpg

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来自甘氨酸转运RNA的证据表明，在遗传密码诞生之初发生了一次冻结事故。

Evidence from glycine transfer RNA of a frozen accident at the dawn of the genetic code.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

REVIEWERS

背景

结果

结论

评审人

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