Prebiotic Nucleoside Phosphorylation in a Simulated Deep-Sea Supercritical Carbon Dioxide-Water Two-Phase Environment.

IF 3.5 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Astrobiology Pub Date : 2024-11-18 DOI:10.1089/ast.2024.0016
Shotaro Tagawa, Ryota Hatami, Kohei Morino, Shohei Terazawa, Caner Akıl, Kristin Johnson-Finn, Takazo Shibuya, Kosuke Fujishima
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Abstract

Prebiotic synthesis of complex organic molecules in water-rich environments has been a long-standing challenge. In the modern deep sea, emission of liquid CO2 has been observed in multiple locations, which indicates the existence of benthic CO2 pools. Recently, a liquid/supercritical CO2 (ScCO2) hypothesis has been proposed that a two-phase ScCO2-water environment could lead to efficient dehydration and condensation of organics. To confirm this hypothesis, we conducted a nucleoside phosphorylation reaction in a hydrothermal reactor creating ScCO2-water two-phase environment. After 120 h of uridine, cytosine, guanosine, and adenosine phosphorylation at 68.9°C, various nucleoside monophosphates (NMPs), nucleotide diphosphates, and carbamoyl nucleosides were produced. The addition of urea enhanced the overall production of phosphorylated species with 5'-NMPs, the major products that reached over 10% yield. As predicted, phosphorylation did not proceed in the fully aqueous environment without ScCO2. Further, a glass window reactor was introduced for direct observation of the two-phase environment, where the escape of water into the ScCO2 phase was observed. These results are similar to those of a wet-dry cycle experiment simulating the terrestrial hot spring environment, indicating that the presence of ScCO2 can create a comparatively dry condition in the deep sea. In addition, the high acidity present in the aqueous phase further supports nucleotide synthesis by enabling the release of orthophosphate from the hydroxyapatite mineral solving the phosphate problem. Thus, the present study highlights the potential of the unique ScCO2-water two-phase environment to drive prebiotic nucleotide synthesis and likely induce condensation reactions of various organic and inorganic compounds in the deep-sea CO2 pool on Earth and potentially other ocean worlds.

模拟深海超临界二氧化碳-水两相环境中的前生物核苷磷酸化。
在富水环境中进行复杂有机分子的前生物合成是一项长期挑战。在现代深海中,多个地点都观测到液态二氧化碳的排放,这表明存在底栖二氧化碳池。最近,有人提出了液态/超临界二氧化碳(ScCO2)假说,认为ScCO2-水两相环境可导致有机物的高效脱水和冷凝。为了证实这一假设,我们在水热反应器中进行了核苷磷酸化反应,创造了 ScCO2-水两相环境。尿苷、胞嘧啶、鸟苷和腺苷在 68.9°C 下经过 120 小时的磷酸化反应后,产生了各种核苷单磷酸(NMPs)、核苷酸二磷酸盐和氨基甲酰基核苷。添加尿素可提高磷酸化产物的总体产量,其中 5'-NMPs 是产量超过 10% 的主要产物。正如预测的那样,磷酸化在没有 ScCO2 的全水环境中无法进行。此外,为了直接观察两相环境,还引入了一个玻璃窗反应器,观察到水逃逸到 ScCO2 相中。这些结果与模拟陆地温泉环境的干湿循环实验结果相似,表明 ScCO2 的存在可在深海中创造相对干燥的条件。此外,水相中存在的高酸度通过使羟基磷灰石矿物中的正磷酸盐释放出来,解决了磷酸盐问题,从而进一步支持了核苷酸的合成。因此,本研究强调了独特的 ScCO2-水两相环境在推动前生物核苷酸合成方面的潜力,并有可能诱导地球和其他海洋世界深海二氧化碳池中各种有机和无机化合物的缩合反应。
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
Astrobiology
Astrobiology 生物-地球科学综合
CiteScore
7.70
自引率
11.90%
发文量
100
审稿时长
3 months
期刊介绍: Astrobiology is the most-cited peer-reviewed journal dedicated to the understanding of life''s origin, evolution, and distribution in the universe, with a focus on new findings and discoveries from interplanetary exploration and laboratory research. Astrobiology coverage includes: Astrophysics; Astropaleontology; Astroplanets; Bioastronomy; Cosmochemistry; Ecogenomics; Exobiology; Extremophiles; Geomicrobiology; Gravitational biology; Life detection technology; Meteoritics; Planetary geoscience; Planetary protection; Prebiotic chemistry; Space exploration technology; Terraforming
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