从生命前到生命：化学动力学如何成为进化动力学。

From prelife to life: how chemical kinetics become evolutionary dynamics.

机构信息

FAS Center for Systems Biology, Department of Mathematics, Harvard University, Cambridge, Massachusetts, USA.

出版信息

Acc Chem Res. 2012 Dec 18;45(12):2088-96. doi: 10.1021/ar2002683. Epub 2012 Feb 15.

DOI:10.1021/ar2002683

PMID:22335792

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4610729/

Abstract

Life is that which evolves. Living systems are the products of evolutionary processes and can undergo further evolution. A crucial question for the origin of life is the following: when do chemical kinetics become evolutionary dynamics? In this Account, we review properties of "prelife" and discuss the transition from prelife to life. We describe prelife as a chemical system where activated monomers can copolymerize into macromolecules such as RNA. These macromolecules carry information, and their physical and chemical properties depend to a certain extent on their particular sequence of monomers. We consider prelife as a logical precursor of life, where macromolecules are formed by copolymerization, but they cannot replicate. Prelife can undergo "prevolutionary dynamics", including processes such as mutation, selection, and cooperation. Prelife selection, however, is blunt: small differences in rate constants lead to small differences in abundance. Life emerges with the ability of replication. In the resulting evolutionary dynamics, selection is sharp: small differences in rate constants can lead to large differences in abundance. We also study the competition of different "prelives" and find that there can be selection for those systems that ultimately give rise to replication. The transition from prelife to life can occur over an extended period of time. Instead of a single moment that marks the origin of life, prelife may have seeded many attempts for the origin of life. Eventually life takes over and destroys prelife.

摘要

生命是进化的产物。生命系统是进化过程的产物，并且可以进一步进化。生命起源的一个关键问题是：化学动力学何时成为进化动力学？在本综述中，我们回顾了“前生命”的特性，并讨论了从前生命到生命的转变。我们将前生命描述为一个化学系统，其中激活的单体可以共聚成大分子，如 RNA。这些大分子携带信息，其物理和化学性质在一定程度上取决于它们特定的单体序列。我们将前生命视为生命的逻辑前体，其中大分子通过共聚形成，但不能复制。前生命可以经历“前进化动力学”，包括突变、选择和合作等过程。然而，前生命的选择是迟钝的：速率常数的微小差异只会导致丰度的微小差异。生命的出现伴随着复制能力。在由此产生的进化动力学中，选择是敏锐的：速率常数的微小差异可能导致丰度的巨大差异。我们还研究了不同“前生命”之间的竞争，并发现那些最终导致复制的系统可能会受到选择。从前生命到生命的转变可能需要很长时间。前生命可能已经为生命的起源进行了多次尝试，而不是一个单一的时刻标志着生命的起源。最终，生命接管并摧毁了前生命。

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从生命前到生命：化学动力学如何成为进化动力学。

From prelife to life: how chemical kinetics become evolutionary dynamics.

机构信息

FAS Center for Systems Biology, Department of Mathematics, Harvard University, Cambridge, Massachusetts, USA.

出版信息

Acc Chem Res. 2012 Dec 18;45(12):2088-96. doi: 10.1021/ar2002683. Epub 2012 Feb 15.

DOI:10.1021/ar2002683

PMID:22335792

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4610729/

Abstract

摘要

从生命前到生命：化学动力学如何成为进化动力学。

From prelife to life: how chemical kinetics become evolutionary dynamics.

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从生命前到生命：化学动力学如何成为进化动力学。

From prelife to life: how chemical kinetics become evolutionary dynamics.

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出版信息