The cache of coupled reduction-oxidation (i.e. redox) reactions in mammals is ultimately enabled by the cellular nicotinamide currency, i.e. the NAD+/NADH and NADP+/NADPH redox couples. Oxidative metabolism, which results in the capture of reducing equivalents primarily as NADH, represents capital investment, whereas biosynthetic reactions, which utilize NADPH, represent expenditures. From the central nicotinamide warehouse, conversion to alternative currencies diversifies the cellular energy portfolio. The mitochondrial membrane is the site of currency conversion to ATP, which occurs via the electron transfer chain and involves a four-electron reduction of oxygen to water. The oxidative phosphorylation process is, however, leaky, and reactive oxygen species (ROS),2 representing incomplete oxidation products of this pathway, are side products. ROS are also generated at other loci, such as NADPH oxidase, by metabolic enzymes, such as lipoxygenase, and in response to extracellular signals, such as growth hormones and cytokines. Long viewed as noxious, ROS are produced in a controlled manner that is now recognized as critical for signaling within and between cells. ROS are crucial for regulating such processes as cell division, circadian rhythms, and the immune response. On the other hand, uncontrolled ROS levels spell death. The intracellular redox “climate” is varied and influenced by multiple regulators. In the cytoplasm, protein regulators, such as thioredoxin, and small molecule antioxidants, such as glutathione and cysteine, maintain distinct redox potentials, revealing that the various redox nodes are not in equilibrium with each other (1). Within organelles, the potentials of the very same redox couples vary; the redox poise setting is more oxidizing in the endoplasmic reticulum but more reducing in the mitochondrion, for instance. Outside the cellular “box,” i.e. in the extracellular space, the redox environment is far from fully oxidized and inert as commonly supposed. Instead, it is dynamically shaped by intracellular redox metabolism and is the subject of the minireview by Ruma Banerjee (2). Redox changes are sensed and relayed by various cellular transducers. Protein redox sensors, such as thioredoxin and peroxiredoxin, play important roles in this regard and are responsive to redox changes by virtue of reactive cysteines. A conserved cysteine in peroxiredoxins is oxidized by hydrogen peroxide to form a sulfenic acid. Although the peroxidase activity confers an antioxidant function, interactions with other proteins that are intrinsically less sensitive to oxidation, e.g. those involved in oxidative protein folding in the endoplasmic reticulum, confer a peroxide sensor function to peroxiredoxins. The minireview by Sue Goo Rhee et al. (3) discusses the role of peroxiredoxins in peroxide regulation and signaling. The modification of reactive cysteine residues with nitric oxide gives S-nitrosocysteine. This reversible post-translational modification has pleiotropic effects in cellular signaling pathways and overlaps in some instances with other central mechanisms for signal transmission, e.g. phosphorylation and ubiquitylation. Regulation of protein function by S-nitrosylation is the subject of the minireview by Douglas T. Hess and Jonathan S. Stamler (4). Cysteines are not particularly abundant in proteins and are not particularly reactive at physiological pH. Hence, the use of cysteines for sensing and signaling changes in the cellular redox state relies on mechanisms for modulating their reactivity in protein microenvironments. The physicochemical properties of and computational methods for identifying reactive cysteines at a genome-wide level are the subject of the minireview by Stefano M. Marino and Vadim N. Gladyshev (5). The article also includes a discussion of bioinformatics approaches for identifying reactive cysteines and predicting their functions in metal binding, structure stabilization, regulation, or catalysis. Finally, two minireviews focus on aspects of redox regulation in the mitochondrion. The majority of mitochondrial proteins synthesized in the cytosol and destined for the intermembrane space lack an N-terminal leader sequence. Instead, these proteins are imported by an oxidation-driven mitochondrial disulfide relay reaction. This disulfide relay apparatus is functionally related to the disulfide bond system of the bacterial periplasm but is structurally distinct and is the subject of the minireview by Johannes M. Herrmann and Jan Riemer (6). The mitochondrion is a hotbed of ROS production used for signaling and regulation of diverse biological activities. Toren Finkel (7) reviews the role of mitochondrial oxidants in the hypoxic response, in regulation of autophagy, in stem cell self-renewal capacity, and in innate immunity. In summary, the six minireviews in this thematic series provide glimpses into the field of redox sensing and regulation. They illustrate how redox potential setting at a compartmental level is important for enabling/disabling cellular functions and reveal at a molecular level that a battery of sensors and carriers convey redox information within signaling networks.
Thematic Minireview Series on Redox Sensing and Regulation*
Published 2011 in Journal of Biological Chemistry
ABSTRACT
PUBLICATION RECORD
- Publication year
2011
- Venue
Journal of Biological Chemistry
- Publication date
2011-12-06
- Fields of study
Biology, Medicine, Chemistry
- Identifiers
- External record
- Source metadata
Semantic Scholar, PubMed
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