NADPH oxidase 5: Where are we now and which way to proceed?

Redox Biochemistry and Chemistry Pub Date : 2024-08-01 DOI:10.1016/j.rbc.2024.100036

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Abstract

Since the incorporation of mitochondria in early eukaryotes cells struggle to keep the deleterious effects of reactive oxygen species (ROS), mainly originating from the respiratory chain, at bay. Evolutionary adaptation to ROS burden went so far that by acting as messenger and effector molecules, ROS became important in maintaining homeostasis. The evolutionary success of this phenomenon is underscored by the arising of professional ROS-generating enzymes, namely the family of NADPH oxidases (NOXes). NOXes, by shaping ROS levels at different subcellular locations and in extracellular space, are involved in such fundamental functions as proliferation, differentiation, apoptosis, host defense, fertilization, and hormone biosynthesis. NOX5, being a calcium-regulated professional ROS source exerts its function at the crossroad of these two fundamental but potentially deleterious intracellular signaling pathways (i.e. Ca²⁺ and ROS). The expression of NOX5 in the adult human body under unchallenged conditions is restricted to very few sites, among which the two major tissue groups are genital organs (mainly testis) and immune tissues (mainly spleen). In cases of increased cellular proliferation and protein synthesis (e.g., diverse tumors, cultured primary cells, or sites of tissue damage) the expression and activity of NOX5 is often upregulated in various tissues. This and the evolutionary conserved nature of NOX5 would imply a very fundamental role for this enzyme, but intriguingly the genomes of rodents essentially lack the NOX5 gene. The latter fact had been a major obstacle in determining the physiological roles of NOX5 in normal tissues until the very recent generation of a NOX5-deficient rabbit model.

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NADPH 氧化酶 5：我们现在在哪里？

自从线粒体在早期真核生物中出现以来，细胞就一直在努力抵御主要来自呼吸链的活性氧（ROS）的有害影响。进化过程中对 ROS 负担的适应发展到如此地步，ROS 通过充当信使和效应分子，成为维持体内平衡的重要物质。专业的 ROS 生成酶，即 NADPH 氧化酶（NOXes）家族的出现，凸显了这一现象在进化上的成功。NOXes 通过调节不同亚细胞位置和细胞外空间的 ROS 水平，参与增殖、分化、凋亡、宿主防御、受精和激素生物合成等基本功能。NOX5 是受钙调控的专业 ROS 源，在这两种基本但可能有害的细胞内信号通路（即 Ca2+ 和 ROS）的交叉路口发挥其功能。NOX5 在成人人体中的表达仅限于极少数部位，其中两个主要组织群是生殖器官（主要是睾丸）和免疫组织（主要是脾脏）。在细胞增殖和蛋白质合成增加的情况下（如各种肿瘤、培养的原代细胞或组织损伤部位），NOX5 的表达和活性往往在各种组织中上调。这一点以及 NOX5 的进化保守性意味着这种酶具有非常重要的作用，但有趣的是，啮齿类动物的基因组中基本上没有 NOX5 基因。这一事实一直是确定 NOX5 在正常组织中的生理作用的主要障碍，直到最近产生了一种 NOX5 缺陷兔模型。

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Redox Biochemistry and Chemistry

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