细胞之前的重大进化转变:从分子到生物的旅程。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Francisco Prosdocimi , Sávio Torres de Farias
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引用次数: 0

摘要

基于生物进化过程中复杂化的逻辑假设和必要步骤,我们在此提出了从分子到细胞的进化路径,即四个时代和三个主要转变。在第一个时代,基本生物大分子形成并变得丰富。第一个转变发生在核酸和肽世界的化学共生事件中,这标志着生命和有机编码过程的出现。FUCA 是第一个生命过程,由自我复制的 RNA 组成,它们与氨基酸相连,能够催化氨基酸的结合。从 FUCA 时代到原生生物时代的第二次过渡涉及原基因组的复制和重组,导致蛋白质生产的专业化,并探索前生物汤中蛋白质与代谢物之间的相互作用。酶和代谢途径从没有化学催化剂的原生物反应中一步步融入生物界。然后,第四个时代带来了生物体和生物系的起源,这是由能够叠加在一起的特定蛋白质促进了肽壳的形成而发生的。LUCA是一种能够实现细胞基本代谢功能的原生生物,但仍无法与脂质分子相互作用。我们提出的证据表明,脂质相互作用途径的进化至少发生了两次,分别是类细菌膜和类古细菌膜的形成。此外,文献数据还表明,DNA 生物合成的出现至少有两条途径,这使得病毒、古细菌和细菌的早期生命策略得以稳定。20 亿年后,真核生物出现了,经过 15 亿年的进化,它们终于学会了如何通过组织特化来进化多细胞性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Major evolutionary transitions before cells: A journey from molecules to organisms

Basing on logical assumptions and necessary steps of complexification along biological evolution, we propose here an evolutionary path from molecules to cells presenting four ages and three major transitions. At the first age, the basic biomolecules were formed and become abundant. The first transition happened with the event of a chemical symbiosis between nucleic acids and peptides worlds, which marked the emergence of both life and the process of organic encoding. FUCA, the first living process, was composed of self-replicating RNAs linked to amino acids and capable to catalyze their binding. The second transition, from the age of FUCA to the age of progenotes, involved the duplication and recombination of proto-genomes, leading to specialization in protein production and the exploration of protein to metabolite interactions in the prebiotic soup. Enzymes and metabolic pathways were incorporated into biology from protobiotic reactions that occurred without chemical catalysts, step by step. Then, the fourth age brought origin of organisms and lineages, occurring when specific proteins capable to stackle together facilitated the formation of peptidic capsids. LUCA was constituted as a progenote capable to operate the basic metabolic functions of a cell, but still unable to interact with lipid molecules. We present evidence that the evolution of lipid interaction pathways occurred at least twice, with the development of bacterial-like and archaeal-like membranes. Also, data in literature suggest at least two paths for the emergence of DNA biosynthesis, allowing the stabilization of early life strategies in viruses, archaeas and bacterias. Two billion years later, the eukaryotes arouse, and after 1,5 billion years of evolution, they finally learn how to evolve multicellularity via tissue specialization.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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