Enhancement of Prebiotic Peptide Formation in Cyclic Environments.

IF 1.9 4区 物理与天体物理 Q2 BIOLOGY Origins of Life and Evolution of Biospheres Pub Date : 2023-12-01 Epub Date: 2023-10-28 DOI:10.1007/s11084-023-09641-2
Hayley Boigenzahn, Praful Gagrani, John Yin
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Abstract

The dynamic behaviors of prebiotic reaction networks may be critically important to understanding how larger biopolymers could emerge, despite being unfavorable to form in water. We focus on understanding the dynamics of simple systems, prior to the emergence of replication mechanisms, and what role they may have played in biopolymer formation. We specifically consider the dynamics in cyclic environments using both model and experimental data. Cyclic environmental conditions prevent a system from reaching thermodynamic equilibrium, improving the chance of observing interesting kinetic behaviors. We used an approximate kinetic model to simulate the dynamics of trimetaphosphate (TP)-activated peptide formation from glycine in cyclic wet-dry conditions. The model predicts that environmental cycling allows trimer and tetramer peptides to sustain concentrations above the predicted fixed points of the model due to overshoot, a dynamic phenomenon. Our experiments demonstrate that oscillatory environments can shift product distributions in favor of longer peptides. However, experimental validation of certain behaviors in the kinetic model is challenging, considering that open systems with cyclic environmental conditions break many of the common assumptions in classical chemical kinetics. Overall, our results suggest that the dynamics of simple peptide reaction networks in cyclic environments may have been important for the formation of longer polymers on the early Earth. Similar phenomena may have also contributed to the emergence of reaction networks with product distributions determined not by thermodynamics, but rather by kinetics.

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在循环环境中增强益生肽的形成。
益生元反应网络的动态行为对于理解更大的生物聚合物如何出现可能至关重要,尽管它们不利于在水中形成。在复制机制出现之前,我们专注于了解简单系统的动力学,以及它们在生物聚合物形成中可能发挥的作用。我们使用模型和实验数据专门考虑了循环环境中的动力学。循环环境条件阻止系统达到热力学平衡,从而提高了观察有趣动力学行为的机会。我们使用近似动力学模型来模拟循环干湿条件下甘氨酸形成三偏磷酸(TP)激活肽的动力学。该模型预测,由于超调(一种动态现象),环境循环允许三聚体和四聚体肽的浓度维持在模型预测的固定点以上。我们的实验表明,振荡环境可以改变产物分布,有利于更长的肽。然而,考虑到具有循环环境条件的开放系统打破了经典化学动力学中的许多常见假设,动力学模型中某些行为的实验验证具有挑战性。总的来说,我们的研究结果表明,循环环境中简单肽反应网络的动力学可能对早期地球上较长聚合物的形成很重要。类似的现象也可能导致反应网络的出现,其产物分布不是由热力学决定的,而是由动力学决定的。
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来源期刊
CiteScore
3.20
自引率
15.00%
发文量
12
审稿时长
>12 weeks
期刊介绍: The subject of the origin and early evolution of life is an inseparable part of the general discipline of Astrobiology. The journal Origins of Life and Evolution of Biospheres places special importance on the interconnection as well as the interdisciplinary nature of these fields, as is reflected in its subject coverage. While any scientific study which contributes to our understanding of the origins, evolution and distribution of life in the Universe is suitable for inclusion in the journal, some examples of important areas of interest are: prebiotic chemistry and the nature of Earth''s early environment, self-replicating and self-organizing systems, the theory of the RNA world and of other possible precursor systems, and the problem of the origin of the genetic code. Early evolution of life - as revealed by such techniques as the elucidation of biochemical pathways, molecular phylogeny, the study of Precambrian sediments and fossils and of major innovations in microbial evolution - forms a second focus. As a larger and more general context for these areas, Astrobiology refers to the origin and evolution of life in a cosmic setting, and includes interstellar chemistry, planetary atmospheres and habitable zones, the organic chemistry of comets, meteorites, asteroids and other small bodies, biological adaptation to extreme environments, life detection and related areas. Experimental papers, theoretical articles and authorative literature reviews are all appropriate forms for submission to the journal. In the coming years, Astrobiology will play an even greater role in defining the journal''s coverage and keeping Origins of Life and Evolution of Biospheres well-placed in this growing interdisciplinary field.
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