生命变化的可能性：单核苷酸替换中的氨基酸变化。

Probability of change in life: Amino acid changes in single nucleotide substitutions.

机构信息

Antibody & Product Development Lab, BII, A(∗)STAR, 138671, Singapore.

Antibody & Product Development Lab, BII, A(∗)STAR, 138671, Singapore; P53 Laboratory, A(∗)STAR, Singapore; Experimental Drug Development Centre, A(∗)STAR, Singapore.

出版信息

Biosystems. 2020 Jun;193-194:104135. doi: 10.1016/j.biosystems.2020.104135. Epub 2020 Apr 4.

DOI:10.1016/j.biosystems.2020.104135

PMID:32259562

Abstract

Mutations underpin the processes in life, be it beneficial or detrimental. While mutations are assumed to be random in the bereft of selection pressures, the genetic code has underlying computable probabilities in amino acid phenotypic changes. With a wide range of implications including drug resistance, understanding amino acid changes is important. In this study, we calculated the probabilities of substitutions mutations in the genetic code leading to the 20 amino acids and stop codons. Our calculations reveal an enigmatic in-built self-preserving organization of the genetic code that averts disruptive changes at the physicochemical properties level. These changes include changes to start, aromatic, negative charged amino acids and stop codons. Our findings thus reveal a statistical mechanism governing the relationship between amino acids and the universal genetic code.

摘要

突变是生命过程的基础，无论是有益的还是有害的。虽然在没有选择压力的情况下，突变被认为是随机的，但遗传密码在氨基酸表型变化方面具有潜在的可计算概率。由于包括耐药性在内的广泛影响，了解氨基酸变化很重要。在这项研究中，我们计算了导致 20 种氨基酸和终止密码子的遗传密码中替换突变的概率。我们的计算揭示了遗传密码内在的神秘自我保护组织，避免了物理化学性质水平的破坏性变化。这些变化包括起始、芳香族、带负电荷的氨基酸和终止密码子的变化。因此，我们的发现揭示了一种统计机制，该机制控制着氨基酸和通用遗传密码之间的关系。

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生命变化的可能性：单核苷酸替换中的氨基酸变化。

Probability of change in life: Amino acid changes in single nucleotide substitutions.

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