Maxime Coutant, Kevin Lepot, Alexandre Fadel, Ahmed Addad, Elodie Richard, David Troadec, Sandra Ventalon, Kenichiro Sugitani, Emmanuelle J. Javaux
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引用次数: 3
Abstract
The morphogenesis of most carbonaceous microstructures that resemble microfossils in Archean (4–2.5 Ga old) rocks remains debated. The associated carbonaceous matter may even—in some cases—derive from abiotic organic molecules. Mineral growths associated with organic matter migration may mimic microbial cells, some anatomical features, and known microfossils—in particular those with simple spheroid shapes. Here, spheroid microstructures from a chert of the ca. 3.4 Ga Strelley Pool Formation (SPF) of the Pilbara Craton (Western Australia) were imaged and analyzed with a combination of high-resolution in situ techniques. This provides new insights into carbonaceous matter distributions and their relationships with the crystallographic textures of associated quartz. Thus, we describe five new types of spheroids and discuss their morphogenesis. In at least three types of microstructures, wall coalescence argues for migration of carbonaceous matter onto abiotic siliceous spherulites or diffusion in poorly crystalline silica. The nanoparticulate walls of these coalescent structures often cut across multiple quartz crystals, consistent with migration in/on silica prior to quartz recrystallization. Sub-continuous walls lying at quartz boundaries occur in some coalescent vesicles. This weakens the “continuous carbonaceous wall” criterion proposed to support cellular inferences. In contrast, some clustered spheroids display wrinkled sub-continuous double walls, and a large sphere shows a thick sub-continuous wall with pustules and depressions. These features appear consistent with post-mortem cell alteration, although abiotic morphogenesis remains difficult to rule out. We compared these siliceous and carbonaceous microstructures to coalescent pyritic spheroids from the same sample, which likely formed as “colloidal” structures in hydrothermal context. The pyrites display a smaller size and only limited carbonaceous coatings, arguing that they could not have acted as precursors to siliceous spheroids. This study revealed new textural features arguing for abiotic morphogenesis of some Archean spheroids. The absence of these features in distinct types of spheroids leaves open the microfossil hypothesis in the same rock. Distinction of such characteristics could help addressing further the origin of other candidate microfossils. This study calls for similar investigations of metamorphosed microfossiliferous rocks and of the products of in vitro growth of cell-mimicking structures in presence of organics and silica.
在太古宙(4-2.5 Ga)岩石中,大多数类似微化石的碳质微结构的形态成因仍存在争议。在某些情况下,伴生的碳质物质甚至可能来自非生物有机分子。与有机物迁移相关的矿物生长可能模仿微生物细胞、一些解剖特征和已知的微化石,特别是那些简单的球形化石。在这里,来自皮尔巴拉克拉通(西澳大利亚)约3.4 Ga Strelley池组(SPF)的一块燧石的球形显微结构被成像并结合高分辨率原位技术进行了分析。这为碳质物质分布及其与伴生石英晶体结构的关系提供了新的见解。因此,我们描述了五种新的球体类型,并讨论了它们的形态发生。在至少三种类型的微观结构中,壁聚结表明碳质物质迁移到非生物硅质球晶或在低结晶二氧化硅中扩散。这些聚结结构的纳米颗粒壁经常穿过多个石英晶体,与石英再结晶之前在二氧化硅上的迁移一致。位于石英边界的次连续壁出现在一些聚结囊泡中。这削弱了支持细胞推断的“连续碳质壁”标准。相反,一些聚集的球体显示皱褶的次连续双壁,大球体显示厚的次连续壁,有脓疱和凹陷。这些特征似乎与死后细胞改变一致,尽管非生物形态发生仍然难以排除。我们将这些硅质和碳质微观结构与来自同一样品的聚结黄铁矿球体进行了比较,后者可能是在热液环境中形成的“胶体”结构。黄铁矿显示出较小的尺寸,只有有限的碳质涂层,认为它们不可能作为硅质球体的前体。该研究揭示了一些太古宙球状体的非生物形态发生的新结构特征。在不同类型的球体中缺乏这些特征,使得同一块岩石中的微化石假说成为可能。区分这些特征有助于进一步确定其他候选微化石的来源。这项研究要求对变质的微化石岩石和在有机物和二氧化硅存在下体外生长的细胞模拟结构的产物进行类似的研究。
期刊介绍:
The field of geobiology explores the relationship between life and the Earth''s physical and chemical environment. Geobiology, launched in 2003, aims to provide a natural home for geobiological research, allowing the cross-fertilization of critical ideas, and promoting cooperation and advancement in this emerging field. We also aim to provide you with a forum for the rapid publication of your results in an international journal of high standing. We are particularly interested in papers crossing disciplines and containing both geological and biological elements, emphasizing the co-evolutionary interactions between life and its physical environment over geological time.
Geobiology invites submission of high-quality articles in the following areas:
Origins and evolution of life
Co-evolution of the atmosphere, hydrosphere and biosphere
The sedimentary rock record and geobiology of critical intervals
Paleobiology and evolutionary ecology
Biogeochemistry and global elemental cycles
Microbe-mineral interactions
Biomarkers
Molecular ecology and phylogenetics.