快速爆发与缓慢衰退:论酶可能的进化轨迹
Rapid bursts and slow declines: on the possible evolutionary trajectories of enzymes.
作者信息
Newton Matilda S, Arcus Vickery L, Patrick Wayne M
机构信息
Department of Biochemistry, University of Otago, Dunedin, New Zealand.
School of Biology, University of Waikato, Hamilton, New Zealand.
出版信息
J R Soc Interface. 2015 Jun 6;12(107). doi: 10.1098/rsif.2015.0036.
Abstract
The evolution of enzymes is often viewed as following a smooth and steady trajectory, from barely functional primordial catalysts to the highly active and specific enzymes that we observe today. In this review, we summarize experimental data that suggest a different reality. Modern examples, such as the emergence of enzymes that hydrolyse human-made pesticides, demonstrate that evolution can be extraordinarily rapid. Experiments to infer and resurrect ancient sequences suggest that some of the first organisms present on the Earth are likely to have possessed highly active enzymes. Reconciling these observations, we argue that rapid bursts of strong selection for increased catalytic efficiency are interspersed with much longer periods in which the catalytic power of an enzyme erodes, through neutral drift and selection for other properties such as cellular energy efficiency or regulation. Thus, many enzymes may have already passed their catalytic peaks.
摘要
酶的进化通常被视为遵循一条平稳且稳定的轨迹,从功能微弱的原始催化剂发展到我们如今所观察到的高活性且特异性强的酶。在本综述中,我们总结了表明不同实际情况的实验数据。现代实例,如水解人造农药的酶的出现,证明进化可能极其迅速。推断和复活古代序列的实验表明,地球上最早出现的一些生物很可能拥有高活性酶。综合这些观察结果,我们认为,对提高催化效率的强烈选择的快速爆发,穿插着更长的时期,在此期间酶的催化能力通过中性漂变以及对其他特性(如细胞能量效率或调节)的选择而受到侵蚀。因此,许多酶可能已经过了它们的催化峰值。
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