Histidine Self-assembly and Stability on Mineral Surfaces as a Model of Prebiotic Chemical Evolution: An Experimental and Computational Approach.

IF 1.9 4区物理与天体物理 Q2 BIOLOGY

Origins of Life and Evolution of Biospheres Pub Date : 2021-06-01 Epub Date: 2021-03-31 DOI:10.1007/s11084-021-09606-3

D Madrigal-Trejo, P S Villanueva-Barragán, R Zamudio-Ramírez, K E Cervantes-de la Cruz, I Mejía-Luna, E Chacón-Baca, A Negrón-Mendoza, S Ramos-Bernal, A Heredia-Barbero

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引用次数: 7

Abstract

The abiotic synthesis of histidine under experimental prebiotic conditions has proven to be chemically promising and plausible. Within this context, the present results suggest that histidine amino acid may function as a simple prebiotic catalyst able to enhance amino acid polymerization. This work describes an experimental and computational approach to the self-assembly and stabilization of DL-histidine on mineral surfaces using antigorite ((Mg, Fe)₃Si₂O₅(OH)₄), pyrite (FeS₂), and aragonite (CaCO₃) as representative minerals of prebiotic scenarios, such as meteorites, and subaerial and submarine hydrothermal systems. Experimental results were obtained through polarized-light microscopy, IR spectroscopy (ATR-FTIR), and differential scanning calorimetry (DSC). Molecular dynamics was performed through computational simulations with the MM + method in HyperChem software. IR spectra suggest the presence of peptide bonds in the antigorite-histidine and aragonite-histidine assemblages with the presence of amide I and amide II vibration bands. The FTIR second derivative inspection supports this observation. Moreover, DSC data shows histidine stabilization in the presence of antigorite and aragonite by changes in histidine thermodynamic properties, particularly an increase in histidine decomposition temperature (272ºC in antigorite and 275ºC in aragonite). Results from molecular dynamics are consistent with DSC data, suggesting an antigorite-histidine closer interaction with decreased molecular distances (cca. 5.5 Å) between the amino acid and the crystal surface. On the whole, the experimental and computational outcomes support the role of mineral surfaces in prebiotic chemical evolution as enhancers of organic stability.

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组氨酸在矿物表面的自组装和稳定性作为益生元化学进化的模型:实验和计算方法。

在实验的益生元条件下，组氨酸的非生物合成已被证明在化学上是有前途的和合理的。在这种情况下，目前的结果表明，组氨酸氨基酸可能作为一种简单的益生元催化剂，能够促进氨基酸聚合。本研究采用反长辉石((Mg, Fe)3Si2O5(OH)4)、黄铁矿(FeS2)和文石(CaCO3)作为益生元场景的代表性矿物，如陨石、陆上和海底热液系统，描述了dl -组氨酸在矿物表面的自组装和稳定的实验和计算方法。实验结果通过偏振光显微镜、红外光谱(ATR-FTIR)和差示扫描量热法(DSC)得到。利用HyperChem软件中的MM +方法进行分子动力学计算模拟。红外光谱显示在反长辉石-组氨酸和文石-组氨酸组合中存在肽键，并存在酰胺I和酰胺II振动带。FTIR二阶导数检验支持这一观察结果。此外，DSC数据显示，在反长石和文石存在时，组氨酸的热力学性质发生了变化，特别是组氨酸分解温度的升高(反长石中为272℃，文石中为275℃)，从而实现了组氨酸的稳定。分子动力学结果与DSC数据一致，表明反长辉石-组氨酸的相互作用随着分子距离的减小而密切(cca)。5.5 Å)在氨基酸和晶体表面之间。总的来说，实验和计算结果支持矿物表面作为有机稳定性增强剂在益生元化学演化中的作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Origins of Life and Evolution of Biospheres 生物-生物学

CiteScore

3.20

自引率

15.00%

发文量

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.