The discovery of ribozymes strengthened the RNA world hypothesis, which assumes that these precursors of modern life both stored information and acted as catalysts. For the first time among extensive studies on ribozymes, we have investigated the influence of hydrostatic pressure on the hairpin ribozyme catalytic activity. High pressures are of interest when studying life under extreme conditions and may help to understand the behavior of macromolecules at the origins of life. Kinetic studies of the hairpin ribozyme self-cleavage were performed under high hydrostatic pressure. The activation volume of the reaction (34 ± 5 ml/mol) calculated from these experiments is of the same order of magnitude as those of common protein enzymes, and reflects an important compaction of the RNA molecule during catalysis, associated to a water release. Kinetic studies were also carried out under osmotic pressure and confirmed this interpretation and the involvement of water movements (78 ± 4 water molecules per RNA molecule). Taken together, these results are consistent with structural studies indicating that loops A and B of the ribozyme come into close contact during the formation of the transition state. While validating baro-biochemistry as an efficient tool for investigating dynamics at work during RNA catalysis, these results provide a complementary view of ribozyme catalytic mechanisms.
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机译:核酶的发现加强了RNA世界的假说,该假说假定现代生命的这些前体既存储信息又充当催化剂。在关于核酶的广泛研究中,我们第一次研究了静水压力对发夹状核酶催化活性的影响。在极端条件下研究生命时,高压是令人感兴趣的,它可能有助于了解大分子在生命起源时的行为。发夹状核酶自我切割的动力学研究在高静水压力下进行。由这些实验计算出的反应的活化体积(34±5 ml / mol)与常见的蛋白质酶具有相同的数量级,反映出催化过程中RNA分子的重要压缩,这与水的释放有关。还在渗透压下进行了动力学研究,并证实了这种解释和水运动的参与(每个RNA分子78±4个水分子)。两者合计,这些结果与结构研究一致,表明核酶的环A和B在过渡态形成期间紧密接触。虽然验证了重生物化学是研究RNA催化过程中工作动力学的有效工具,但这些结果提供了核酶催化机制的补充观点。
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