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核糖核酸酶J旁系同源物催化效率各异的物理化学原理。

A physicochemical rationale for the varied catalytic efficiency in RNase J paralogues.

作者信息

Singh Ankur Kumar, Chinnasamy Kalaiarasi, Pahelkar Nikhil Ramachandra, Gopal Balasubramanian

机构信息

Division of Biological Sciences, Indian Institute of Science, Bangalore, Karnataka, India.

Division of Biological Sciences, Indian Institute of Science, Bangalore, Karnataka, India.

出版信息

J Biol Chem. 2025 Feb;301(2):108152. doi: 10.1016/j.jbc.2024.108152. Epub 2024 Dec 30.

DOI:10.1016/j.jbc.2024.108152
PMID:39742998
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11815676/
Abstract

Paralogs of the bifunctional nuclease, Ribonuclease J (RNase J), demonstrate varied catalytic efficiencies despite extensive sequence and structural similarity. Of the two Staphylococcus aureus RNase J paralogues, RNase J1 is substantially more active than RNase J2. Mutational analysis of active site residues revealed that only H80 and E166 were critical for nuclease activity. Electronic properties of active site residues were further evaluated using density functional theory in conjunction with molecular mechanics. This analysis suggested that multiple residues at the active site can function as Lewis bases or acids in RNase J2. The bond dissociation energy, on the other hand, suggested that the Mn ion in RNase J2, located at a structurally identical location to that in RNase J1, is crucial for overall structural integrity. Structures of mutant enzymes lacking the metal ion were seen to adopt a different orientation between the substrate binding and catalytic domain than wild-type RNase J2. A surprising finding was that the RNase J2 H78 A mutant was five-fold more active than the wild-type enzyme. Structural and biochemical experiments performed in light of this observation revealed that the RNase J2 catalytic mechanism is distinct from both two-metal ion and one-metal ion reaction mechanisms proposed for RNase J nucleases. Different activity levels in RNase J paralogues can thus be ascribed to the diversity in catalytic mechanisms.

摘要

双功能核酸酶核糖核酸酶J(RNase J)的旁系同源物,尽管在序列和结构上有广泛的相似性,但催化效率各不相同。在金黄色葡萄球菌的两种RNase J旁系同源物中,RNase J1的活性明显高于RNase J2。对活性位点残基的突变分析表明,只有H80和E166对核酸酶活性至关重要。结合分子力学,使用密度泛函理论进一步评估了活性位点残基的电子性质。该分析表明,RNase J2活性位点的多个残基可作为路易斯碱或酸发挥作用。另一方面,键解离能表明,RNase J2中位于与RNase J1结构相同位置的锰离子对整体结构完整性至关重要。与野生型RNase J2相比,缺乏金属离子的突变酶结构在底物结合域和催化域之间呈现出不同的取向。一个惊人的发现是,RNase J2 H78A突变体的活性比野生型酶高五倍。根据这一观察结果进行的结构和生化实验表明,RNase J2的催化机制不同于为RNase J核酸酶提出的双金属离子和单金属离子反应机制。因此,RNase J旁系同源物中不同的活性水平可归因于催化机制的多样性。

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