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.
Published Version
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