Protein vicinal thiols as intrinsic probes of brain redox states in health, aging, and ischemia.

The nature of brain redox metabolism in health, aging, and disease remains to be fully established. Reversible oxidations, to disulfide bonds, of closely spaced (vicinal) protein thiols underlie the catalytic maintenance of redox homeostasis by redoxin enzymes, including thioredoxin peroxidases (peroxiredoxins), and have been implicated in redox buffering and regulation. We propose that non-peroxidase proteins containing vicinal thiols that are responsive to physiological redox perturbations may serve as intrinsic probes of brain redox metabolism. Using redox phenylarsine oxide (PAO)-affinity chromatography, we report that PAO-binding vicinal thiols on creatine kinase B and alpha-enolase from healthy rat brains were preferentially oxidized compared to other selected proteins, including neuron-specific (gamma) enolase, under conditions designed to trap in vivo protein thiol redox states. Moreover, measures of the extents of oxidations of vicinal thiols on total protein, and on creatine kinase B and alpha-enolase, showed that vicinal thiol-linked redox states were stable over the lifespan of rats and revealed a transient reductive shift in these redox couples following decapitation-induced global ischemia. Finally, formation of disulfide-linked complexes between peroxiredoxin-2 and brain proteins was demonstrated on redox blots, supporting a link between protein vicinal thiol redox states and the peroxidase activities of peroxiredoxins. The implications of these findings with respect to underappreciated aspects of brain redox metabolism in health, aging, and ischemia are discussed.

The Reducible Disulfide Proteome of Synaptosomes Supports a Role for Reversible Oxidations of Protein Thiols in the Maintenance of Neuronal Redox Homeostasis.

The mechanisms by which neurons maintain redox homeostasis, disruption of which is linked to disease, are not well known. Hydrogen peroxide, a major cellular oxidant and neuromodulator, can promote reversible oxidations of protein thiols but the scope, targets, and significance of such oxidations occurring in neurons, especially in vivo, are uncertain. Using redox phenylarsine oxide (PAO)-affinity chromatography, which exploits the high-affinity of trivalent arsenicals for protein dithiols, this study investigated the occurrence of reducible and, therefore, potentially regulatory, protein disulfide bonds in Triton X-100-soluble protein fractions from isolated nerve-endings (synaptosomes) prepared from rat brains. Postmortem oxidations of protein thiols were limited by rapidly freezing the brains following euthanasia and, later, homogenizing them in the presence of the N-ethylmaleimide to trap reduced thiols. The reducible disulfide proteome comprised 5.4% of the total synaptosomal protein applied to the immobilized PAO columns and was overrepresented by pathways underlying ATP synaptic supply and demand including synaptic vesicle trafficking. The alpha subunits of plasma membrane Na+, K+-ATPase and the mitochondrial ATP synthase were particularly abundant proteins of the disulfide proteome and were enriched in this fraction by 3.5- and 6.7-fold, respectively. An adaptation of the commonly used "biotin-switch" method provided additional support for selective oxidation of thiols on the alpha subunit of the ATP synthase. We propose that reversible oxidations of protein thiols may underlie a coordinated metabolic response to hydrogen peroxide, serving to both control redox signaling and protect neurons from oxidant stress.

Reductive Reprogramming: A Not-So-Radical Hypothesis of Neurodegeneration Linking Redox Perturbations to Neuroinflammation and Excitotoxicity.

Free radical-mediated oxidative stress, neuroinflammation, and excitotoxicity have long been considered insults relevant to the progression of Alzheimer's disease and other aging-related neurodegenerative disorders (NDD). Among these phenomena, the significance of oxidative stress and, more generally, redox perturbations, for NDD remain ill-defined and unsubstantiated. Here, I argue that (i) free radical-mediated oxidations of biomolecules can be dissociated from the progression of NDD, (ii) oxidative stress fails as a descriptor of cellular redox states under conditions relevant to disease, and (iii) aberrant upregulation of compensatory reducing activities in neural cells, resulting in reductive shifts in thiol-based redox potentials, may be an overlooked and paradoxical contributor to disease progression. In particular, I summarize evidence which supports the view that reductive shifts in the extracellular space can occur in response to oxidant and inflammatory signals and that these have the potential to reduce putative regulatory disulfide bonds in exofacial domains of the N-methyl-D-aspartate receptor, leading potentially to aberrant increases in neuronal excitability and, if sustained, excitotoxicity. The novel reductive reprogramming hypothesis of neurodegeneration presented here provides an alternative view of redox perturbations in NDD and links these to both neuroinflammation and excitotoxicity.

Potential widespread denitrosylation of brain proteins following prolonged restraint: proposed links between stress and central nervous system disease.

The biochemical pathways by which aberrant psychophysiological stress promotes neuronal damage and increases the risks for central nervous system diseases are not well understood. In light of previous findings that psychophysiological stress, modeled by animal restraint, can increase the activities and expression levels of nitric oxide synthase isoforms in multiple brain regions, we examined the effects of restraint, for up to 6 h, on levels of S-nitrosylated proteins and NOx (nitrite + nitrate), a marker for high-level nitric oxide generation, in the brains of rats. Results identify functionally-diverse protein targets of S-nitrosylation in the brain, in vivo, and demonstrate the potential for widespread loss of protein nitrosothiols following prolonged restraint despite a concomitant increase in NOx levels. Since physiological levels of protein S-nitrosylation can protect neurons by maintaining redox homeostasis, by limiting excitatory neurotransmission, and by inhibiting apoptotic and inflammatory pathways, we propose that over-activation of protein denitrosylation pathways following sustained or repeated stress may facilitate neural damage and early stages of stress-related central nervous system disease.

Disulfide Stress Targets Modulators of Excitotoxicity in Otherwise Healthy Brains.

Oxidative stress is a long-hypothesized cause of diverse neurological and psychiatric disorders but the pathways by which physiological redox perturbations may detour healthy brain development and aging are unknown. We reported recently (Foley et al., Neurochem Res 39:2030-2039, 2014) that two-electron oxidations, to disulfides, of protein vicinal thiols can vary markedly in association with more modest oxidations of the glutathione redox couple in brains from healthy adolescent rats whereas levels of protein S-glutathionylation were low and unchanged. Here, we demonstrate that the selective oxidations of protein vicinal thiols, occurring only in the more oxidized brains under study, were linked specifically to a peroxide stress as evidenced by increased oxidations, to disulfides, of the presumed catalytic vicinal thiols of peroxiredoxins 1 and 2. Moreover, we identify the catalytic subunit(s) of Na+, K+-ATPase, tubulins, glyceraldehyde-3-phosphate dehydrogenase, and protein phosphatase 1, all of which can modulate glutamate neurotransmission and the vulnerability of neurons to excitotoxicity, as non-peroxidase proteins exhibiting prominent oxidations of vicinal thiols. The two-electron pathway, demonstrated here, linking physiological redox perturbations in otherwise healthy brains to protein determinants of excitotoxicity, suggests an alternative to free radical pathways by which oxidative stress may impact brain development and aging.

Protein vicinal thiol oxidations in the healthy brain: not so radical links between physiological oxidative stress and neural cell activities.

Reversible oxidations of protein thiols have emerged as alternatives to free radical-mediated oxidative damage with which to consider the impacts of oxidative stress on cellular activities but the scope and pathways of such oxidations in tissues, including the brain, have yet to be fully defined. We report here a characterization of reversible oxidations of glutathione and protein thiols in extracts from rat brains, from two sources, which had been (1) frozen quickly after euthanasia to preserve in vivo redox states and (2) subjected to alkylation upon tissue disruption to trap reduced thiols. Brains were defined, relatively, as Reduced and Moderately Oxidized based on measured ratios of reduced (GSH) to oxidized (GSSG) glutathione. Levels of protein disulfides formed by the cross-linking of closely-spaced (vicinal) protein thiols, but not protein S-glutathionylation, were higher in extracts from the Moderately Oxidized brains compared to the Reduced brains. Moreover, the oxidized vicinal thiol proteome contains proteins that impact cellular energetics, signaling, neurotransmission, and cytoskeletal dynamics among others. These findings argue that kinetically-competent pathways for reversible, two-electron oxidations, of protein vicinal thiols can be activated in healthy brains in response to physiological oxidative stresses. We propose that such oxidations may link oxidative stress to adaptive, but also potentially deleterious, changes in neural cell activities in otherwise healthy brains.

SNAP-25 contains non-acylated thiol pairs that can form intrachain disulfide bonds: possible sites for redox modulation of neurotransmission.

Intrachain disulfide bond formation among the cysteine thiols of SNAP-25, a component of the SNARE protein complex required for neurotransmitter release, has been hypothesized to link oxidative stress and inhibition of synaptic transmission. However, neither the availability in vivo of SNAP-25 thiols, which are known targets of S-palmitoylation, nor the tendency of these thiols to form intrachain disulfide bonds is known. We have examined, in rat brain extracts, both the availability of closely spaced, or vicinal, thiol pairs in SNAP-25 and the propensity of these dithiols toward disulfide bond formation using a method improved by us recently that exploits the high chemoselectivity of phenylarsine oxide (PAO) for vicinal thiols. The results show for the first time that a substantial fraction of soluble and, to a lesser extent, particulate SNAP-25 contain non-acylated PAO-binding thiol pairs and that these thiols in soluble SNAP-25 in particular have a high propensity toward disulfide bond formation. Indeed, disulfide bonds were detected in a small fraction of soluble SNAP-25 even under conditions designed to prevent or greatly limit protein thiol oxidation during experimental procedures. These results provide direct experimental support for the availability, in a subpopulation of SNAP-25, of vicinal thiols that may confer on one or more isoforms of this family of proteins a sensitivity to oxidative stress.

Phenylarsine oxide binding reveals redox-active and potential regulatory vicinal thiols on the catalytic subunit of protein phosphatase 2A.

Our earlier finding that the activity of protein phosphatase 2A from rat brain is inhibited by micromolar concentrations of the dithiol cross-linking reagent phenylarsine oxide (PAO) has encouraged the hypothesis that the catalytic subunit (PP2Ac) of PP2A contains one or more pairs of closely-spaced (vicinal) thiol pairs that may contribute to regulation of the enzyme. The results of the present study demonstrate using immobilized PAO-affinity chromatography that PP2Ac from rat brain formed stable DTT-sensitive adducts with PAO with or without associated regulatory subunits. In addition, a subset of the PAO-binding vicinal thiols of PP2Ac was readily oxidized to disulfide bonds in vitro. Importantly, a small fraction of PP2Ac was still found to contain disulfide bonds after applying stringent conditions designed to prevent protein disulfide bond formation during homogenization and fractionation of the brains. These findings establish the presence of potentially regulatory and redox-active PAO-binding vicinal thiols on the catalytic subunit of PP2A and suggest that a population of PP2Ac may contain disulfide bonds in vivo.

An improved phenylarsine oxide-affinity method identifies triose phosphate isomerase as a candidate redox receptor protein.

Reversible oxidation on proteins of vicinal thiols to form intraprotein disulfides is believed to be an important means by which redox sensitivity is conferred on cellular signaling and metabolism. Affinity chromatography using immobilized phenylarsine oxide (PAO), which binds preferentially to vicinal thiols over monothiols, has been used in very limited studies to isolate the fraction of cellular proteins that exhibit reversible oxidation of vicinal thiols to presumed disulfide bonds. A challenge to the use of PAO-affinity chromatography for isolation of readily oxidizable vicinal thiol proteins (VTPs) has been the lack of a disulfide reducing agent that reverses oxidation of the PAO-binding protein thiols and maintains these in the reduced state necessary to bind PAO but does not also compete with the VTPs for binding to the immobilized PAO. The present study demonstrates that the capture from a detergent-soluble rat brain extract of VTPs by PAO-affinity chromatography was improved greatly by use of the reducing agent tris(2-carboxyethyl)-phosphine which, unlike more traditional disulfide-reducing agents, does not contain a thiol group. Moreover, we show that, while a substantial fraction of total brain proteins contain PAO-binding thiols, only a fraction of these were readily and reversibly oxidized. The two most abundant of these redox-active proteins were identified as albumin and triose phosphate isomerase (TPI). We propose that TPI is a candidate intracellular redox receptor protein. The improved PAO-affinity method detailed here should enable the discovery of lower abundance novel redox-active regulatory proteins.

Oxidative inhibition of protein phosphatase 2A activity: role of catalytic subunit disulfides.

A molecular basis for the inhibition of brain protein phosphatase 2A (PP2A) activity by oxidative stress was examined in a high-speed supernatant (HSS) fraction from rat cerebral cortex. PP2A activity was subject to substantial disulfide reducing agent-reversible inhibition in the HSS fraction. Results of gel electrophoresis support the conclusions that inhibition of PP2A activity was associated with the both the disulfide cross-linking of the catalytic subunit (PP2A(C)) of the enzyme to other brain proteins and with the formation of an apparent novel intramolecular disulfide bond in PP2A(C). Additional findings that the vicinal dithiol cross-linking reagent phenylarsine oxide (PAO) produced a potent dithiothreitol-reversible inhibition of PP2A activity suggest that the cross-linking of PP2A(C) vicinal thiols to form an intramolecular disulfide bond may be sufficient to inhibit PP2A activity under oxidative stress. We propose that the dithiol-disulfide equilibrium of a vicinal thiol pair of PP2A(C) may confer redox sensitivity on cellular PP2A.

Brain PP2A is modified by thiol-disulfide exchange and intermolecular disulfide formation.

The regulation of protein phosphatase 2A (PP2A) activity by thiol-disulfide exchange and resulting formation of an intermolecular disulfide was examined following exposure of a rat brain soluble fraction to a biotinylated derivative of the model disulfide HPDP (HPDP-biotin) which would be expected to label reactive protein thiols with a disulfide-linked biotin. The results show that a low concentration (500 microM) of HPDP-biotin produced substantial inhibition of PP2A activity and promoted the binding of the catalytic subunit of PP2A to an immobilized avidin-affinity column. Both the inhibition of PP2A activity and the binding of PP2A to the avidin column were reversed by treatment with the disulfide reducing agent dithiothreitol (DTT). Furthermore, the specific activity of PP2A was up to 7-fold higher in the DTT-eluted fractions from the avidin-affinity column than in the soluble fraction. These findings demonstrate directly that PP2A is susceptible to reversible inhibitory modification by thiol-disulfide exchange and provide mechanistic support for the emerging view that PP2A is an oxidant-sensitive protein phosphatase.

Identification and H2O2 sensitivity of the major constitutive MAPK phosphatase from rat brain.

The present study examined in subcellular fractions from rat brain the nature and sensitivity to hydrogen peroxide of constitutively expressed mitogen-activated protein kinase (MAPK) phosphatase activity. MAPK phosphatase activity was defined as the activity directed towards a dual-phosphorylated (pT/pY) peptide corresponding to the activation domain of the extracellular-regulated kinase (ERK) subtype of the MAPKs. The use of phosphatase inhibitors and biochemical analyses demonstrate that the MAPK phosphatase activity, which was highest in the microsomal membrane and soluble fractions, was attributable mainly, if not entirely, to protein phosphatase 2A (PP2A). Moreover, hydrogen peroxide (in the absence and presence of reduced glutathione) and glutathione disulfide inhibited the MAPK phosphatase activity by a dithiothreitol-reversible mechanism. These results provide direct support for mounting evidence that PP2A is a major regulator of MAPK phosphorylation in brain and suggest that inhibition of PP2A activity via reversible oxidation of a cysteine thiol(s) may underlie at least in part the activation of MAPKs occurring in response to hydrogen peroxide and oxidative stress.

Superoxide activates constitutive nitric oxide synthase in a brain particulate fraction.

Nitric oxide (*NO) can act as an antioxidant by directly scavenging reactive free radicals, inhibiting the oxidative chemistry of iron, and signaling the up-regulation of antioxidant enzymes. However, the cellular utility of *NO as an antioxidant requires that constitutive nitric oxide synthase (NOS) be activated rapidly by a signal(s) for oxidant formation. We report here that superoxide (O2*-), added directly as potassium superoxide (KO2), produced a superoxide dismutase-sensitive and hydrogen peroxide-independent stimulation of NOS activity, measured by the conversion of [3H]arginine to [3H]citrulline and nitrite formation, in a synaptic particulate fraction from rat brain cerebral cortex. O2*- produced maximal activation of NOS in the presence of the antioxidant urate and ATP. Stimulation of NOS activity by O2*- was abolished by N-monomethyl-L-arginine and by the Ca2+ chelator EGTA but not by 7-nitroindazole, which would be expected to inhibit neuronal NOS. We propose that limited activation of NOS by O2*- may be an important contributor to brain oxidant defenses and, more generally, a signal for cellular adaptation and survival, although excessive generation of nitrogen oxides would be expected to produce neurotoxicity.