Plausible Emergence and Self Assembly of a Primitive Phospholipid from Reduced Phosphorus on the Primordial Earth.

IF 1.9 4区物理与天体物理 Q2 BIOLOGY Origins of Life and Evolution of Biospheres Pub Date : 2021-09-01 Epub Date: 2021-07-19 DOI:10.1007/s11084-021-09613-4

Michael O Gaylor, Pere Miro, Bess Vlaisavljevich, Ashen Anuradha Suduweli Kondage, Laura M Barge, Arthur Omran, Patrick Videau, Vaille A Swenson, Lucas J Leinen, Nathaniel W Fitch, Krista L Cole, Chris Stone, Samuel M Drummond, Kayli Rageth, Lillian R Dewitt, Sarah González Henao, Vytis Karanauskus

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引用次数: 5

Abstract

How life arose on the primitive Earth is one of the biggest questions in science. Biomolecular emergence scenarios have proliferated in the literature but accounting for the ubiquity of oxidized (+ 5) phosphate (PO₄^3-) in extant biochemistries has been challenging due to the dearth of phosphate and molecular oxygen on the primordial Earth. A compelling body of work suggests that exogenous schreibersite ((Fe,Ni)₃P) was delivered to Earth via meteorite impacts during the Heavy Bombardment (ca. 4.1-3.8 Gya) and there converted to reduced P oxyanions (e.g., phosphite (HPO₃^2-) and hypophosphite (H₂PO₂^-)) and phosphonates. Inspired by this idea, we review the relevant literature to deduce a plausible reduced phospholipid analog of modern phosphatidylcholines that could have emerged in a primordial hydrothermal setting. A shallow alkaline lacustrine basin underlain by active hydrothermal fissures and meteoritic schreibersite-, clay-, and metal-enriched sediments is envisioned. The water column is laden with known and putative primordial hydrothermal reagents. Small system dimensions and thermal- and UV-driven evaporation further concentrate chemical precursors. We hypothesize that a reduced phospholipid arises from Fischer-Tropsch-type (FTT) production of a C8 alkanoic acid, which condenses with an organophosphinate (derived from schreibersite corrosion to hypophosphite with subsequent methylation/oxidation), to yield a reduced protophospholipid. This then condenses with an α-amino nitrile (derived from Strecker-type reactions) to form the polar head. Preliminary modeling results indicate that reduced phospholipids do not aggregate rapidly; however, single layer micelles are stable up to aggregates with approximately 100 molecules.

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原始地球上还原磷的原始磷脂的可能出现和自组装。

生命是如何在原始地球上出现的是科学界最大的问题之一。生物分子出现的场景在文献中已经激增，但由于原始地球上缺乏磷酸盐和分子氧，在现有生物化学中氧化(+ 5)磷酸盐(PO43-)的普遍存在一直具有挑战性。一项令人信服的研究表明，外源性schreibersite ((Fe,Ni)3P)是在重轰炸(约4.1-3.8 Gya)期间通过陨石撞击传递到地球的，并在那里转化为还原的P氧离子(例如，亚磷酸盐(HPO32-)和次磷酸盐(H2PO2-))和磷酸盐。受这一想法的启发，我们回顾了相关文献，以推断出可能出现在原始热液环境中的现代磷脂酰胆碱的似是而非的还原磷脂类似物。设想一个浅碱性湖盆，由活跃的热液裂缝和陨石状的片闪岩、粘土和富含金属的沉积物组成。水柱中装满了已知的和假定的原始热液试剂。小系统尺寸和热和紫外线驱动蒸发进一步浓缩化学前体。我们假设还原磷脂源于费托-托法(FTT)生产C8烷烃酸，该烷烃酸与有机磷酸酯(由schreibersite腐蚀生成次磷酸酯，随后发生甲基化/氧化)缩合，生成还原的原磷脂。然后与α-氨基腈缩合(源自斯特雷克反应)形成极性头。初步模拟结果表明，还原磷脂不会迅速聚集;然而，单层胶束在大约100个分子聚集时是稳定的。

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.