A flexible linker of 8-amino acids between the membrane binding segment and the FMN domain of cytochrome P450 reductase is necessary for optimal activity

IF 3.8 2区化学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Inorganic Biochemistry Pub Date : 2024-07-16 DOI:10.1016/j.jinorgbio.2024.112667

Freeborn Rwere , Naw May P. Cartee , Yuting Yang , Lucy Waskell

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引用次数: 0

Abstract

The diflavin NADPH-cytochrome P450 reductase (CYPOR) plays a critical role in human cytochrome P450 (CYP) activity by sequentially delivering two electrons from NADPH to CYP enzymes during catalysis. Although electron transfer to forty-eight human CYP enzymes by the FMN hydroquinone of CYPOR is well-known, the role of the linker between the NH₂-terminus membrane-binding domain (MBD) and FMN domain in supporting the activity of P450 enzymes remains poorly understood. Here we demonstrate that a linker with at least eight residues is required to form a functional CYPOR-CYP2B4 complex. The linker has been shortened in two amino-acid increments from Phe44 to Ile57 using site directed mutagenesis. The ability of the deletion mutants to support cytochrome P450 2B4 (CYP2B4) catalysis and reduce ferric CYP2B4 was determined using an in vitro assay and stopped-flow spectrophotometry. Steady-state enzyme kinetics showed that shortening the linker by 8–14 amino acids inhibited (63–99%) the ability of CYPOR to support CYP2B4 activity and significantly increased the K_m of CYPOR for CYP2B4. In addition, the reductase mutants decreased the rate of reduction of ferric CYP2B4 (46–95%) compared to wildtype when the linker was shortened by 8–14 residues. These results indicate that a linker with a minimum length of eight residues is necessary to enable the FMN domain of reductase to interact with CYP2B4 to form a catalytically competent complex. Our study provides evidence that the length of the MBD-FMN domain linker is a major determinant of the ability of CYPOR to support CYP catalysis and drug metabolism by P450 enzymes.

Preamble

This manuscript is dedicated in memory of Dr. James R. Kincaid who was the doctoral advisor to Dr. Freeborn Rwere and a longtime collaborator and friend of Dr. Lucy Waskell. Dr. James R. Kincaid was a distinguished professor of chemistry specializing in resonance Raman (rR) studies of heme proteins. He inspired Dr. Rwere (a Zimbabwean native) and three other Zimbabweans (Dr. Remigio Usai, Dr. Daniel Kaluka and Ms. Munyaradzi E. Manyumwa) to use lasers to document subtle changes occurring at heme active site of globin proteins (myoglobin and hemoglobin) and cytochrome P450 enzymes. Dr. Rwere appreciate his contributions to the development of talented Black scientists from Africa.

Abstract Image

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细胞色素 P450 还原酶的膜结合片段和 FMN 结构域之间需要一个由 8 个氨基酸组成的柔性连接体，才能实现最佳活性

二黄素 NADPH-细胞色素 P450 还原酶（CYPOR）在催化过程中将两个电子从 NADPH 依次传递给 CYP 酶，从而在人类细胞色素 P450（CYP）活性中发挥关键作用。尽管 CYPOR 的 FMN 对苯二酚向 48 种人类 CYP 酶进行电子传递已众所周知，但 NH2 端膜结合结构域（MBD）和 FMN 结构域之间的连接物在支持 P450 酶活性方面的作用仍鲜为人知。在这里，我们证明了至少有八个残基的连接体是形成功能性 CYPOR-CYP2B4 复合物所必需的。利用定点突变技术，从 Phe44 到 Ile57，以两个氨基酸递增的方式缩短了连接体。利用体外试验和停流分光光度法测定了缺失突变体支持细胞色素 P450 2B4 (CYP2B4) 催化和还原 CYP2B4 铁的能力。稳态酶动力学显示，缩短 8-14 个氨基酸的连接体可抑制（63-99%）CYPOR 支持 CYP2B4 活性的能力，并显著提高 CYPOR 对 CYP2B4 的 Km。此外，与野生型相比，当连接体缩短 8-14 个残基时，还原酶突变体降低了 CYP2B4 铁的还原率（46-95%）。这些结果表明，要使还原酶的 FMN 结构域与 CYP2B4 相互作用以形成具有催化能力的复合物，至少需要 8 个残基长度的连接子。我们的研究提供了证据，证明 MBD-FMN 结构域连接体的长度是决定 CYPOR 支持 P450 酶催化 CYP 和药物代谢能力的主要因素。James R. Kincaid 博士是一位杰出的化学教授，专门从事血红素蛋白的共振拉曼 (rR) 研究。在他的启发下，Rwere 博士（津巴布韦人）和其他三位津巴布韦人（Remigio Usai 博士、Daniel Kaluka 博士和 Munyaradzi E. Manyumwa 女士）利用激光记录了球蛋白（肌红蛋白和血红蛋白）和细胞色素 P450 酶的血红素活性位点发生的微妙变化。鲁韦尔博士感谢他为培养非洲优秀黑人科学家所做的贡献。

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来源期刊

Journal of Inorganic Biochemistry 生物-生化与分子生物学

CiteScore

7.00

自引率

10.30%

发文量

336

审稿时长

41 days

期刊介绍： The Journal of Inorganic Biochemistry is an established international forum for research in all aspects of Biological Inorganic Chemistry. Original papers of a high scientific level are published in the form of Articles (full length papers), Short Communications, Focused Reviews and Bioinorganic Methods. Topics include: the chemistry, structure and function of metalloenzymes; the interaction of inorganic ions and molecules with proteins and nucleic acids; the synthesis and properties of coordination complexes of biological interest including both structural and functional model systems; the function of metal- containing systems in the regulation of gene expression; the role of metals in medicine; the application of spectroscopic methods to determine the structure of metallobiomolecules; the preparation and characterization of metal-based biomaterials; and related systems. The emphasis of the Journal is on the structure and mechanism of action of metallobiomolecules.