How ATP and dATP Act as Molecular Switches to Regulate Enzymatic Activity in the Prototypical Bacterial Class Ia Ribonucleotide Reductase.

IF 2.9 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochemistry Biochemistry Pub Date : 2024-10-01 Epub Date: 2024-08-20 DOI:10.1021/acs.biochem.4c00329

Michael A Funk, Christina M Zimanyi, Gisele A Andree, Allison E Hamilos, Catherine L Drennan

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Abstract

Class Ia ribonucleotide reductases (RNRs) are allosterically regulated by ATP and dATP to maintain the appropriate deoxyribonucleotide levels inside the cell for DNA biosynthesis and repair. RNR activity requires precise positioning of the β₂ and α₂ subunits for the transfer of a catalytically essential radical species. Excess dATP inhibits RNR through the creation of an α-β interface that restricts the ability of β₂ to obtain a position that is capable of radical transfer. ATP breaks the α-β interface, freeing β₂ and restoring enzyme activity. Here, we investigate the molecular basis for allosteric activity regulation in the well-studied Escherichia coli class Ia RNR through the determination of six crystal structures and accompanying biochemical and mutagenesis studies. We find that when dATP is bound to the N-terminal regulatory cone domain in α, a helix unwinds, creating a binding surface for β. When ATP displaces dATP, the helix rewinds, dismantling the α-β interface. This reversal of enzyme inhibition requires that two ATP molecules are bound in the cone domain: one in the canonical nucleotide-binding site (site 1) and one in a site (site 2) that is blocked by phenylalanine-87 and tryptophan-28 unless ATP is bound in site 1. When ATP binds to site 1, histidine-59 rearranges, prompting the movement of phenylalanine-87 and trytophan-28, and creating site 2. dATP hydrogen bonds to histidine-59, preventing its movement. The importance of site 2 in the restoration of RNR activity by ATP is confirmed by mutagenesis. These findings have implications for the design of bacterial RNR inhibitors.

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ATP 和 dATP 如何作为分子开关调节原型细菌 Ia 类核糖核苷酸还原酶的酶活性？

Ia 类核糖核苷酸还原酶（RNR）受 ATP 和 dATP 的异构调节，以维持细胞内 DNA 生物合成和修复所需的适当脱氧核苷酸水平。RNR 的活性需要 β2 和 α2 亚基的精确定位，以便转移催化必需的自由基物种。过量的 dATP 会产生一个 α-β 接口，限制 β2 获得自由基转移位置的能力，从而抑制 RNR。ATP 可打破 α-β 界面，释放 β2 并恢复酶的活性。在这里，我们通过测定六种晶体结构以及相应的生化和诱变研究，研究了大肠杆菌 Ia 类 RNR 异构活性调节的分子基础。我们发现，当 dATP 与 α 中的 N 端调节锥结构域结合时，螺旋会松开，为 β 创造一个结合表面。这种酶抑制作用的逆转需要在锥体结构域中结合两个 ATP 分子：一个在典型的核苷酸结合位点（位点 1），另一个在一个位点（位点 2），除非 ATP 与位点 1 结合，否则位点 2 会被苯丙氨酸-87 和色氨酸-28 阻断。当 ATP 与位点 1 结合时，组氨酸-59 重新排列，促使苯丙氨酸-87 和色氨酸-28 移动，形成位点 2。突变证实了位点 2 在 ATP 恢复 RNR 活性中的重要性。这些发现对设计细菌 RNR 抑制剂具有重要意义。

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来源期刊

Biochemistry Biochemistry 生物-生化与分子生物学

CiteScore

5.50

自引率

3.40%

发文量

336

审稿时长

1-2 weeks

期刊介绍： Biochemistry provides an international forum for publishing exceptional, rigorous, high-impact research across all of biological chemistry. This broad scope includes studies on the chemical, physical, mechanistic, and/or structural basis of biological or cell function, and encompasses the fields of chemical biology, synthetic biology, disease biology, cell biology, nucleic acid biology, neuroscience, structural biology, and biophysics. In addition to traditional Research Articles, Biochemistry also publishes Communications, Viewpoints, and Perspectives, as well as From the Bench articles that report new methods of particular interest to the biological chemistry community.