DNA Takes Over on the Control of the Morphology of the Composite Self-Organized Structures of Barium and Calcium Silica–Carbonate Biomorphs, Implications for Prebiotic Chemistry on Earth

Earth Pub Date : 2024-07-24 DOI:10.3390/earth5030016

M. Cuéllar-Cruz, S. R. Islas, Abel Moreno

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Abstract

The origin of life is associated with the existing environmental factors of the Precambrian Era of the Earth. The minerals rich in sodium silicates, in aluminum and in other chemical elements, such as kaolinite, were among the factors present at that time. Kaolinite is an abundant mineral on our planet, which indicates that it possibly had an essential role in the origin of the first blocks that constructed life on Earth. Evidence of this is the cherts, which are rocks with a high concentration of silica that retain the vestiges of the most ancient life on our planet. There are also inorganic structures called biomorphs that are like the cherts of the Precambrian, which take on a morphology and crystalline structure depending on the chemical molecules that make up the reaction mixture. To evaluate the interaction of kaolinite with DNA, the objective of this work is to synthesize biomorphs in the presence of kaolinite and genomic DNA that comes from a prokaryote and a eukaryote microorganism. Our results show that the difference between the prokaryote DNA and the eukaryote DNA favors the morphology and the crystalline phase of the calcium silica–carbonate biomorphs, while in the case of the barium silica–carbonate biomorphs, the environmental factors participate directly in the morphology but not in the crystalline phase. Results show that when a mineral such as kaolinite is present in genomic DNA, it is precisely the DNA that controls both the morphology and the crystalline phase as well as the chemical composition of the structure. This fact is relevant as it shows that, independently of the morphology or the of size of the organism, it is the genomic DNA that controls all the chemical elements toward the most stable structure, therefore allowing the perpetuation, conservation and maintenance of life on our planet (since the origin of the genomic DNA in the Precambrian Era to the present day).

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DNA 接管钡和硅钙-碳酸钙生物形态的复合自组织结构的形态控制，对地球前生物化学的启示

生命的起源与地球前寒武纪的现有环境因素有关。富含硅酸钠、铝和其他化学元素的矿物，如高岭石，就是当时存在的因素之一。高岭石是地球上一种丰富的矿物质，这表明它可能在地球上构建生命的第一批物质的起源过程中发挥了至关重要的作用。这一点的证据就是白垩岩，这种含有高浓度二氧化硅的岩石保留了地球上最古老生命的遗迹。还有一种被称为生物形态的无机结构，就像前寒武纪的白垩岩一样，其形态和晶体结构取决于组成反应混合物的化学分子。为了评估高岭石与 DNA 的相互作用，这项工作的目的是在高岭石和来自原核细胞和真核细胞的基因组 DNA 的存在下合成生物形态。我们的研究结果表明，原核生物 DNA 和真核生物 DNA 之间的差异有利于硅碳酸钙生物形态的形态和结晶相，而在硅碳酸钡生物形态中，环境因素直接参与形态的形成，但不参与结晶相的形成。结果表明，当基因组 DNA 中含有高岭石等矿物时，正是 DNA 控制着形态和结晶相以及结构的化学成分。这一事实具有重要意义，因为它表明，无论生物体的形态或大小如何，基因组 DNA 都控制着所有化学元素，使其趋向于最稳定的结构，从而使我们星球上的生命得以延续、保护和维持（自基因组 DNA 诞生于前寒武纪至今）。

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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