Theories of the origin of the genetic code: Strong corroboration for the coevolution theory

IF 2 4区 生物学 Q2 BIOLOGY
Massimo Di Giulio
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Abstract

I analyzed all the theories and models of the origin of the genetic code, and over the years, I have considered the main suggestions that could explain this origin. The conclusion of this analysis is that the coevolution theory of the origin of the genetic code is the theory that best captures the majority of observations concerning the organization of the genetic code. In other words, the biosynthetic relationships between amino acids would have heavily influenced the origin of the organization of the genetic code, as supported by the coevolution theory. Instead, the presence in the genetic code of physicochemical properties of amino acids, which have also been linked to the physicochemical properties of anticodons or codons or bases by stereochemical and physicochemical theories, would simply be the result of natural selection. More explicitly, I maintain that these correlations between codons, anticodons or bases and amino acids are in fact the result not of a real correlation between amino acids and codons, for example, but are only the effect of the intervention of natural selection. Specifically, in the genetic code table we expect, for example, that the most similar codons - that is, those that differ by only one base - will have more similar physicochemical properties. Therefore, the 64 codons of the genetic code table ordered in a certain way would also represent an ordering of some of their physicochemical properties. Now, a study aimed at clarifying which physicochemical property of amino acids has influenced the allocation of amino acids in the genetic code has established that the partition energy of amino acids has played a role decisive in this. Indeed, under some conditions, the genetic code was found to be approximately 98% optimized on its columns. In this same work, it was shown that this was most likely the result of the action of natural selection. If natural selection had truly allocated the amino acids in the genetic code in such a way that similar amino acids also have similar codons - this, not through a mechanism of physicochemical interaction between, for example, codons and amino acids - then it might turn out that even different physicochemical properties of codons (or anticodons or bases) show some correlation with the physicochemical properties of amino acids, simply because the partition energy of amino acids is correlated with other physicochemical properties of amino acids. It is very likely that this would inevitably lead to a correlation between codons (or anticodons or bases) and amino acids. In other words, since the codons (anticodons or bases) are ordered in the genetic code, that is to say, some of their physicochemical properties should also be ordered by a similar order, and given that the amino acids would also appear to have been ordered in the genetic code by selection natural, then it should inevitably turn out that there is a correlation between, for example, the hydrophobicity of anticodons and that of amino acids. Instead, the intervention of natural selection in organizing the genetic code would appear to be highly compatible with the main mechanism of structuring the genetic code as supported by the coevolution theory. This would make the coevolution theory the only plausible explanation for the origin of the genetic code.

遗传密码起源理论:共同进化论的有力佐证
我分析了遗传密码起源的所有理论和模型,多年来,我考虑了可以解释这一起源的主要建议。分析的结论是,遗传密码起源的共同进化理论是最能体现有关遗传密码组织的大多数观察结果的理论。换句话说,氨基酸之间的生物合成关系会在很大程度上影响遗传密码组织的起源,这一点得到了共同进化理论的支持。相反,遗传密码中存在的氨基酸理化性质(立体化学和物理化学理论也将其与反密码子、密码子或碱基的理化性质联系起来)将只是自然选择的结果。更明确地说,我认为密码子、反密码子或碱基与氨基酸之间的这些相关性实际上并不是氨基酸与密码子等之间真正相关的结果,而只是自然选择干预的结果。举例来说,在遗传密码表中,我们希望最相似的密码子(即只有一个碱基不同的密码子)具有更相似的理化性质。因此,遗传密码表中以某种方式排序的 64 个密码子也代表了它们的某些理化性质的排序。现在,一项旨在明确氨基酸的哪种物理化学特性影响了遗传密码中氨基酸的分配的研究确定,氨基酸的分配能在其中起到了决定性的作用。事实上,在某些条件下,遗传密码在其列上的优化率约为 98%。同一研究还表明,这很可能是自然选择作用的结果。如果自然选择真的以相似的氨基酸也有相似的密码子的方式来分配遗传密码中的氨基酸--而不是通过密码子和氨基酸等之间的理化相互作用机制--那么结果可能是,即使密码子(或反密码子或碱基)的不同理化性质也会与氨基酸的理化性质显示出某种相关性,原因很简单,因为氨基酸的分配能与氨基酸的其他理化性质相关。这很可能必然导致密码子(或反密码子或碱基)与氨基酸之间的相关性。换句话说,既然密码子(反密码子或碱基)在遗传密码中是有序的,也就是说,它们的某些理化性质也应该是按类似的顺序排列的,而且,鉴于氨基酸似乎也是通过自然选择在遗传密码中有序排列的,那么,反密码子的疏水性与氨基酸的疏水性等之间就必然会产生相关性。相反,自然选择对组织遗传密码的干预似乎与共同进化论所支持的遗传密码结构的主要机制高度一致。这将使共同进化论成为遗传密码起源的唯一合理解释。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biosystems
Biosystems 生物-生物学
CiteScore
3.70
自引率
18.80%
发文量
129
审稿时长
34 days
期刊介绍: BioSystems encourages experimental, computational, and theoretical articles that link biology, evolutionary thinking, and the information processing sciences. The link areas form a circle that encompasses the fundamental nature of biological information processing, computational modeling of complex biological systems, evolutionary models of computation, the application of biological principles to the design of novel computing systems, and the use of biomolecular materials to synthesize artificial systems that capture essential principles of natural biological information processing.
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