Equilibrium and Non-equilibrium Reaction Schemes for Prebiotic Polymerization of Ribonucleotides

IF 3.1 Q2 CHEMISTRY, MULTIDISCIPLINARY ChemSystemsChem Pub Date : 2023-09-21 DOI:10.1002/syst.202300033
Varun Kitson, Quentin Sanders, Dr. Avinash V. Dass, Prof. Paul G. Higgs
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Abstract

The RNA World theory for the origin of life requires polymers to be generated initially by abiotic reactions. Experiments have studied polymerization of 5′-monophosphates, 2′,3′-cyclic phosphates, and 5′-triphosphates. We consider theoretical models of polymerization in solution illustrating the differences between these cases. We consider (i) a basic model where all monomers undergo reversible joining and breaking; (ii) a model where 2′,3′-cyclic phosphates can join, and breaking regenerates the cyclic phosphate; (iii) a model where 5′-triphosphates can join irreversibly, in addition to the joining and breaking of 2′,3′-cyclic phosphates. In cases (i) and (ii) there is an equilibrium steady state with balance between making and breaking bonds. In case (iii) there is a circular reaction flux in which monomers are activated by an external phosphate source, activated monomers form polymers, and polymers break to release non-activated monomers. The mean length can be calculated as a function of concentration. In case (iii), the mean length switches from a low-concentration regime controlled by the 5′-triphosphates to a high-concentration regime controlled by the 2′,3′-cyclic phosphates. The circular reaction flux is reminiscent of a metabolism. If formation of 5’-triphosphates was already in place for RNA synthesis, ATP could subsequently been coopted for metabolism.

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核糖核苷酸前生物聚合的平衡和非平衡反应方案
生命起源的 RNA 世界理论要求聚合物最初由非生物反应生成。实验研究了 5′-单磷酸盐、2′,3′-环状磷酸盐和 5′-三磷酸盐的聚合反应。我们考虑了溶液聚合的理论模型,以说明这些情况之间的差异。我们考虑了(i)所有单体都进行可逆连接和断裂的基本模式;(ii)2′,3′-环状磷酸盐可以连接,断裂后环状磷酸盐再生的模式;(iii)除了 2′,3′-环状磷酸盐的连接和断裂外,5′-三磷酸酯可以不可逆连接的模式。在(i)和(ii)的情况下,生成键和断开键之间处于平衡稳定状态。在情况(iii)中,单体被外部磷酸源激活,激活的单体形成聚合物,聚合物断裂释放出未激活的单体,在此过程中存在循环反应通量。平均长度可作为浓度的函数来计算。在情况(iii)中,平均长度从由 5′-三磷酸酯控制的低浓度状态转变为由 2′,3′-环磷酸酯控制的高浓度状态。循环反应通量让人联想到新陈代谢。如果 5'-三磷酸盐的形成已经用于 RNA 合成,那么 ATP 随后可能被用于新陈代谢。
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