科学家重现约40亿年前RNA与氨基酸的“第一次连接”—— 蛋白质合成，探索生命起源之谜（国际科技前沿）

Core Insights - A breakthrough study by a research team from University College London successfully demonstrated the chemical connection between RNA and amino acids under enzyme-free conditions, addressing a long-standing question in the origin of life research [1][3][4] - The research integrates the "RNA world" and "thioester world" theories, suggesting that the origin of life may not have a single starting point but rather a collaborative evolution of metabolic and genetic systems through simple chemical reactions [6][8] Molecular Evolution - The study falls within the realm of molecular evolution, focusing on the self-assembly and functional evolution of biological macromolecules like RNA and proteins, as well as the formation of "primitive cells" [2][6] - The research highlights the importance of understanding how RNA connects with amino acids, which is crucial for comprehending the mechanisms of protein synthesis and the origin of life [3][4] Methodology and Findings - The research team utilized thioesters to activate amino acids, allowing them to connect with RNA in a controlled manner, which was previously unattainable with high-energy molecules that would decompose in water [4][5] - The findings suggest that these reactions likely occurred in early Earth's lakes or small pools rather than in the ocean, providing a more specific direction for scientists searching for the "cradle" of life [5][6] Implications for Future Research - The study opens avenues for further exploration into how RNA sequences preferentially bind to specific amino acids, which is essential for understanding the origin of the genetic code [7][8] - The research may also contribute to the development of artificial life systems, in situ protein synthesis, and targeted drug delivery, highlighting its potential applications in biotechnology and medicine [7][8] Broader Impact - The findings could bridge the gap between chemical evolution and biological evolution, offering a reasonable chemical basis for the transition from non-living chemical substances to living biological systems [6][8] - The research emphasizes the importance of the chemical microenvironment within cells, suggesting that imbalances may lead to molecular interactions abnormalities and metabolic disorders, which could inform new strategies for disease prevention [7][8]