Redox Sensor Research Articles

P-130 - The conserved cysteine residue of type III intermediate filaments serves as a structural element and redox sensor

Glial fibrillary acidic protein (GFAP) along with vimentin, desmin and peripherin constitutes the type III class of intermediate filament proteins, which are expressed in a cell type-dependent manner. GFAP and vimentin play a role in organelle positioning, cell migration and mechanical resistance and possess a conserved cysteine residue (cys328 in vimentin and cys294 in GFAP). We previously showed that cys328 of vimentin is critical for stress sensing, since mutants lacking this residue are resistant to vimentin reorganization induced by oxidants and electrophilic lipids. We have observed that GFAP cys294 is also a target for lipoxidation, which induces a drastic filament rearrangement in cells. Therefore, the conserved cysteine residues of type III intermediate filaments emerge as important players in cellular responses to oxidative damage. Interestingly, cysteine to serine mutations compromise assembly and copolymerization of GFAP and vimentin, showing that these residues are important for the structure of the intermediate filament network. This raises the hypothesis that modifications of cysteine residues of intermediate filaments may contribute to cellular dysfunction under pathophysiological conditions.

H 2 O 2 as a central redox signaling molecule in physiological oxidative stress

In 1818, Louis Jacques Thenard (1777–1857) in Paris discovered and synthesized hydrogen peroxide, so we can celebrate a Bicentennial1. Using near-infrared organ spectroscopy of catalase Compound I, hydrogen peroxide was identified as a normal oxygen metabolite in the intact cell non-invasively, almost 50 years ago2. Hydrogen peroxide now is considered as a central redox signaling molecule by targeting specific redox sensors in physiological oxidative stress, “oxidative eustress”3. While large gradients exist towards the outside of cells as well as between different compartments within cells, an overall range of cellular hydrogen peroxide concentrations in the physiological steady-state is estimated to be 1–100 nM. Higher concentrations elicit oxidative stress responses for adaptation, using molecular redox switches such as Nrf2 and NF-kB. If overburdened by exposure to even higher concentrations of hydrogen peroxide, in “oxidative distress”, unspecific damage to biomolecules ensues, ultimately leading to growth arrest and cell death.

Ultrafast Trap State-Mediated Electron Transfer for Quantum Dot Redox Sensing

Quantum dots (QDs) conjugated to electron acceptor ligands are useful as redox sensors in applications ranging from chemical detection to bioimaging. We aimed to improve effectiveness of these redox-sensing QD conjugates, which depends on the initial charge separation and on the competing mechanisms of recombination, including luminescence and electron transfer to the conjugated redox molecules. In this study, ultrafast laser measurements were used to study the excited state dynamics in CdTe/CdS core/shell QDs with quinone/quinol acceptor (Q2NS) ligands attached to the surface (up to 40 per QD). Detailed analysis, along with computational modeling of the system, showed multiple electron-transfer pathways and identified an ultrafast electron transfer from a surface electron trap state to the quinone ligands (2–8 ps). We propose that this leads to high, redox-dependent, quenching efficiencies (98.7% with an average of 10 quinone/quinols on the surface). As only low populations of redox ligands are required,...

PhoPR Positively Regulates whiB3 Expression in Response to Low pH in Pathogenic Mycobacteria.

During infection, Mycobacterium tuberculosis colonizes macrophages or necrotic granulomas, in which low pH is one of the major challenges. The PhoPR two-component regulatory system and the cytosolic redox sensor WhiB3 both play important roles in the response to low pH by M. tuberculosis However, whether close association exists between PhoPR and WhiB3 remains unclear. In this study, the positive regulation of whiB3 by PhoPR in mycobacteria was characterized. We observed that the expression patterns of the whiB3 gene under acidic conditions are different among mycobacterial species, suggesting that the regulation of whiB3 differs among mycobacteria. A sequence analysis of the whiB3 promoters (whiB3p) from M. tuberculosis and two closely related species, namely, M. marinum and M. smegmatis, showed that the whiB3p regions from M. tuberculosis and M. marinum contain a new type of PhoP box that is absent in the M. smegmatiswhiB3p Direct binding of PhoP to whiB3p from M. tuberculosis and M. marinum but not that from M. smegmatis was validated by in vitro protein-DNA binding assays. The direct activation of whiB3 by PhoPR under acidic conditions was further verified by reverse transcription-quantitative PCR (qRT-PCR) analysis in M. marinum Moreover, mutating the residues important for the phosphorylation pathway of PhoPR in M. marinum abolished the activation of whiB3 expression by PhoPR under acidic conditions, suggesting that low pH triggers the phosphorylation of PhoPR, which in turn activates the transcription of whiB3 Since the PhoP box was only identified in whiB3p of pathogenic mycobacteria, we suggest that the PhoPR-whiB3 regulatory pathway may have evolved to facilitate mycobacterial infection.IMPORTANCE The low pH in macrophages is an important barrier for infection by microbes. The PhoPR two-component regulatory system is required for the response to low pH and plays a role in redox homeostasis in Mycobacterium tuberculosis WhiB3, a cytosolic redox-sensing transcriptional regulator, is also involved in these processes. However, there is no direct evidence to demonstrate the regulation of WhiB3 by PhoPR. In this study, we found that PhoPR directly activates whiB3 expression in response to low pH. An atypical PhoP box in the whiB3 promoters has been identified and is only found in pathogenic mycobacteria, which suggests that the PhoPR-whiB3 regulatory pathway may facilitate mycobacterial infection. This study provides novel information for further characterization of the PhoPR regulon.

Monitoring cellular redox state under hypoxia using a fluorescent sensor based on eel fluorescent protein

Genetically encoded fluorescent sensors are widely used to visualize secondary messengers, metabolites and dynamic events in living cells. However, almost all of these sensors are based on Aequorea GFPs or GFP-like proteins, which do not correctly maturate and fluoresce under hypoxia or anoxic conditions, greatly limiting their application in biomedical research. Herein, we provide a novel strategy for design of sensors and report a series of thiol redox-sensitive sensor based on a recently discovered oxygen-independent fluorescent protein UnaG from Japanese eel. These redox sensors have large dynamic range, rapid responsiveness, a flexible "switch", and pH-independence, are particularly compatible with hypoxia conditions, and therefore represent a substantial improvement for live-cell redox measurement. We further demonstrated the versatility of these redox sensors, by simultaneously monitoring redox changes and hypoxia state in living cells, thereby proving its capability as a powerful and flexible tool for indexing multidimensional metabolism data in the context of physiological stressors and pathological states. These redox sensors are not only the first case of UnaG-based functional sensors, but also the first case of functional sensors based on non GFP-like proteins. Based on this strategy, more oxygen-independent biosensors could be developed, hence, provide new opportunities for bioimaging.

Romo1 is a mitochondrial nonselective cation channel with viroporin-like characteristics.

Reactive oxygen species (ROS) modulator 1 (Romo1) is a nuclear-encoded mitochondrial inner membrane protein known to regulate mitochondrial ROS production and to act as an essential redox sensor in mitochondrial dynamics. Although its physiological roles have been studied for a decade, the biophysical mechanisms that explain these activities of Romo1 are unclear. In this study, we report that Romo1 is a unique mitochondrial ion channel that differs from currently identified eukaryotic ion channels. Romo1 is a highly conserved protein with structural features of class II viroporins, which are virus-encoded nonselective cation channels. Indeed, Romo1 forms a nonselective cation channel with its amphipathic helical transmembrane domain necessary for pore-forming activity. Notably, channel activity was specifically inhibited by Fe2+ ions, an essential transition metal ion in ROS metabolism. Using structural bioinformatics, we designed an experimental data-guided structural model of Romo1 with a rational hexameric structure. We propose that Romo1 establishes a new category of viroporin-like nonselective cation channel in eukaryotes.

Cys Site-Directed Mutagenesis of the Human SLC1A5 (ASCT2) Transporter: Structure/Function Relationships and Crucial Role of Cys467 for Redox Sensing and Glutamine Transport.

The human plasma membrane transporter ASCT2 is responsible for mediating Na- dependent antiport of neutral amino acids. New insights into structure/function relationships were unveiled by a combined approach of recombinant over-expression, site-directed mutagenesis, transport assays in proteoliposomes and bioinformatics. WT and Cys mutants of hASCT2 were produced in P. pastoris and purified for functional assay. The reactivity towards SH reducing and oxidizing agents of WT protein was investigated and opposite effects were revealed; transport activity increased upon treatment with the Cys reducing agent DTE, i.e., when Cys residues were in thiol (reduced) state. Methyl-Hg, which binds to SH groups, was able to inhibit WT and seven out of eight Cys to Ala mutants. On the contrary, C467A loses the sensitivity to both DTE activation and Methyl-Hg inhibition. The C467A mutant showed a Km for Gln one order of magnitude higher than that of WT. Moreover, the C467 residue is localized in the substrate binding region of the protein, as suggested by bioinformatics on the basis of the EAAT1 structure comparison. Taken together, the experimental data allowed identifying C467 residue as crucial for substrate binding and for transport activity modulation of hASCT2.

Gene architecture and expression analyses provide insights into the role of glutathione peroxidases (GPXs) in bread wheat (Triticum aestivum L.)

Glutathione peroxidases (GPXs) are redox sensor proteins that maintain a steady-state of H2O2 in plant cells. They exhibit distinct sub-cellular localization and have diverse functionality in response to different stimuli. In this study, a total of 14 TaGPX genes and three splice variants were identified in the genome of Triticum aestivum and evaluated for various physicochemical properties. The TaGPX genes were scattered on the various chromosomes of the A, B, and D sub-genomes and clustered into five homeologous groups based on high sequence homology. The majority of genes were derived from the B sub-genome and localized on chromosome 2. The intron-exon organization, motif and domain architecture, and phylogenetic analyses revealed the conserved nature of TaGPXs. The occurrence of both development-related and stress-responsive cis-acting elements in the promoter region, the differential expression of these genes during various developmental stages, and the modulation of expression in the presence of biotic and abiotic stresses suggested their diverse role in T. aestivum. The majority of TaGPX genes showed higher expression in various leaf developmental stages. However, TaGPX1-A1 was upregulated in the presence of each abiotic stress treatment. A co-expression analysis revealed the interaction of TaGPXs with numerous development and stress-related genes, which indicated their vital role in numerous biological processes. Our study revealed the opportunities for further characterization of individual TaGPX proteins, which might be useful in designing future crop improvement strategies.

Novel ferrocene-containing organosilicon polymers and uniform microspheres prepared by free radical copolymerization: Precursors for magnetic Si-C-Fe-(O) nanomaterials

Ferrocene-containing organosilicon polymers demonstrate wide applications in catalysts, redox sensors, ceramic nanomaterials and nanolithography fields. However, most synthesis methods for ferrocene-containing organosilicon polymers require either strict water-free and oxygen-free conditions or the presence of platinum complex catalysts. In this contribution, the free radical copolymerization of 1, 1′‑bis(dimethylvinylsilyl)ferrocene (DVFc) and trimethylolpropane trimethacrylate (TMPTMA) was achieved to construct either soluble branched ferrocene-containing organosilicon polymers or uniform cross-linked microspheres only through the feed ratio tuning of the two monomers. The structures of copolymer and cross-linked microspheres have been characterized by one-dimensional nuclear magnetic resonance (1D NMR) and two-dimensional (2D) NMR measurements. Furthermore, the novel organosilicon polymers could be employed as preceramic precursors to prepare magnetic Si-C-Fe-(O) ceramics with favorable ceramic yield at high temperature. The nanocrystals-containing ceramics magnetism could be tuned through copolymer nature or pyrolysis condition variations.

Redox Sensing within the Genus Shewanella.

A novel bacterial behavior called congregation was recently described in Shewanella oneidensis MR-1 as the accumulation of cells around insoluble electron acceptors (IEA). It is the result of a series of “run-and-reversal” events enabled by modulation of swimming speed and direction. The model proposed that the swimming cells constantly sense their surroundings with specialized outer membrane cytochromes capable of extracellular electron transport (EET). Up to this point, neither the congregation nor attachment behavior have been studied in any other strains. In this study, the wild type of S. oneidensis MR-1 and several deletion mutants as well as eight other Shewanella strains (Shewanella putrefaciens CN32, S. sp. ANA-3, S. sp. W3-18-1, Shewanella amazonensis SB2B, Shewanella loihica PV-4, Shewanella denitrificans OS217, Shewanella baltica OS155, and Shewanella frigidimarina NCIMB400) were screened for the ability to congregate. To monitor congregation and attachment, specialized cell-tracking techniques, as well as a novel cell accumulation after photo-bleaching (CAAP) confocal microscopy technique were utilized in this study. We found a strong correlation between the ability of strain MR-1 to accumulate on mineral surface and the presence of key EET genes such as mtrBC/omcA (SO_1778, SO_1776, and SO_1779) and gene coding for methyl-accepting protein (MCPs) with Ca+ channel chemotaxis receptor (Cache) domain (SO_2240). These EET and taxis genes were previously identified as essential for characteristic run and reversal swimming around IEA surfaces. CN32, ANA-3, and PV-4 congregated around both Fe(OH)3 and MnO2. Two other Shewanella spp. showed preferences for one oxide over the other: preferences that correlated with the metal content of the environments from which the strains were isolated: e.g., W3-18-1, which was isolated from an iron-rich habitat congregated and attached preferentially to Fe(OH)3, while SB2B, which was isolated from a MnO2-rich environment, preferred MnO2.

Crystal Structure of Green Fluorescent Protein Clover and Design of Clover-Based Redox Sensors

We have determined the crystal structure of Clover, one of the brightest fluorescent proteins, and found that its T203H/S65G mutations relative to wild-type GFP lock the critical E222 side chain in a fixed configuration that mimics the major conformer of that in EGFP. The resulting equilibrium shift to the predominantly deprotonated chromophore increases the extinction coefficient (EC), opposes photoactivation, and is responsible for the bathochromic shift. Clover's brightness can further be attributed to a π-π stacking interaction between H203 and the chromophore. Consistent with these observations, the Clover G65S mutant reversed the equilibrium shift, dramatically decreased the EC, and made Clover photoactivatable under conditions that activated photoactivatable GFP. Using the Clover structure, we rationally engineered a non-photoactivatable redox sensor, roClover1, and determined its structure as well as that of its parental template, roClover0.1. These high-resolution structures provide deeper insights into structure-function relationships in GFPs and may aid the development of excitation-improved ratiometric biosensors.

Mitochondrial Redox Sensor for Drosophila Female Germline Stem Cells.

Mitochondrial reactive oxygen species (mROS), a major source of ROS within cells, functions as an important signaling molecule and has the ability to damage cellular macromolecules including DNA and proteins. Monitoring mROS levels is therefore essential to understand cell-cell communication and programmed cell death in all types of cell including stem cells. Here, we describe generation and characterization of a redox sensor for mROS that is specifically expressed in the germline stem cells (GSCs) in Drosophila. This redox sensor can be used to monitor the production of mROS and mitophagy in the GSCs during oogenesis.

Development of Amplified Redox Sensor Suitable for Onsite Measurement

Development of Amplified Redox Sensor Suitable for Onsite Measurement

The role of DJ-1 complexes and catecholamine metabolism: relevance for familial and idiopathic Parkinson's disease.

Autosomal recessive mutations in the PARK7 gene, which encodes for the protein DJ-1, result in a loss of function and are a cause of familial Parkinson’s disease (PD), while increased wild-type DJ-1 protein levels are associated with some forms of cancer. Several functions of DJ-1 have been described, with the greatest evidence indicating that DJ-1 is a redox-sensitive protein involved in the regulation of oxidative stress and cell survival. We have recently reported that the levels of DJ-1 oxidized at cysteine 106 (C106) was decreased in the cortex of idiopathic PD brains (Piston et al., 2017). Furthermore we found that DJ-1 forms high molecular weight complexes in human brain and the dopaminergic SH-SY5Y neuroblastoma cell line, and that these complexes could be oxidized at C106. Proteomics indicated that proteins involved in RNA transcription/translation were associated with these DJ-1 complexes, and the composition of complexes was affected by oxidation of DJ-1. RNA sequencing highlighted that transcripts associated with the catecholamine system, including dopamine (DA) metabolism, tended to be increased when complexes contained DJ-1 mimicking oxidation at C106. DJ-1 knock down (KD) cells also had increased intracellular DA and noradrenaline (NA) levels. In this perspective we will discuss the implications of DJ-1 acting as a redox sensor directly affecting RNA metabolism, and with respect to PD, how dysregulation of catecholamine metabolism in both familial and idiopathic PD, might contribute to some prodromal features of the disease and the increased susceptibility of specific neuronal populations to neurodegeneration.

The desumoylating enzyme sentrin-specific protease 3 contributes to myocardial ischemia reperfusion injury

Sentrin-specific protease 3 (SENP3), a member of the desumoylating enzyme family, is known as a redox sensor and could regulate multiple cellular signaling pathways. However, its implication in myocardial ischemia reperfusion (MIR) injury is unclear. Here, we observed that SENP3 was expressed and upregulated in the mouse heart depending on reactive oxygen species (ROS) production in response to MIR injury. By utilizing siRNA-mediated cardiac specific gene silencing, SENP3 knockdown was demonstrated to significantly reduce MIR-induced infarct size and improve cardiac function. Mechanistic studies indicated that SENP3 silencing ameliorated myocardial apoptosis mainly via suppression of endoplasmic reticulum (ER) stress and mitochondrial-mediated apoptosis pathways. By contrast, adenovirus-mediated cardiac SENP3 overexpression significantly exaggerated MIR injury. Further molecular analysis revealed that SENP3 promoted mitochondrial translocation of dynamin-related protein 1 (Drp1) in reperfused myocardium. In addition, mitochondrial division inhibitor-1 (Mdivi-1), a pharmacological inhibitor of Drp1, significantly attenuated the exaggerated mitochondrial abnormality and cardiac injury by SENP3 overexpression after MIR injury. Taken together, we provide the first direct evidence that SENP3 upregulation pivotally contributes to MIR injury in a Drp1-dependent manner, and suggest that SENP3 suppression may hold therapeutic promise for constraining MIR injury.

Intracellular metal binding and redox behavior of human DJ-1.

DJ-1 is a conserved, ubiquitous protein associated to a large number of intracellular processes. Human DJ-1 has been linked to several pathologies, including hereditary forms of Parkinson's disease, cancer, and amyotrophic lateral sclerosis. Several cytoprotective functions of DJ-1 have been reported, however, its actual mechanisms of action remain elusive. In vitro, DJ-1 has been shown to bind zinc and copper(II) at its active site, which contains a conserved cysteine (C106), and copper(I) at a different binding site. C106 is essential to DJ-1 function, and is easily oxidized upon oxidative stress. Here, we investigated the metal-binding- and redox properties of DJ-1 in living human cells by in-cell NMR. Intracellular DJ-1 is surprisingly free from interactions with any other cellular components and as such is clearly detectable by NMR. Metal-bound forms of DJ-1 were not observed upon treating the cells with excess zinc or copper. No copper binding was observed when co-expressing DJ-1 with the copper chaperone for superoxide dismutase 1 (SOD1). Co-expression of DJ-1 with SOD1 itself did not promote copper binding to SOD1, excluding a previously suggested function of DJ-1 as a copper chaperone. Overall, our data do not support the role of DJ-1 as a metalloprotein. Conversely, oxidative treatment to the cells caused the complete and selective oxidation of C106 to sulfinic acid, consistent with the reported role of DJ-1 as a redox sensor.

Structural Characterization of Ferrous Ion Binding to Retinal Guanylate Cyclase Activator Protein 5 from Zebrafish Photoreceptors.

Sensory guanylate cyclases (zGCs) in zebrafish photoreceptors are regulated by a family of guanylate cyclase activator proteins (called GCAP1-7). GCAP5 contains two nonconserved cysteine residues (Cys15 and Cys17) that could in principle bind to biologically active transition state metal ions (Zn2+ and Fe2+). Here, we present nuclear magnetic resonance (NMR) and isothermal titration calorimetry (ITC) binding analyses that demonstrate the binding of one Fe2+ ion to two GCAP5 molecules (in a 1:2 complex) with a dissociation constant in the nanomolar range. At least one other Fe2+ binds to GCAP5 with micromolar affinity that likely represents electrostatic Fe2+ binding to the EF-hand loops. The GCAP5 double mutant (C15A/C17A) lacks nanomolar binding to Fe2+, suggesting that Fe2+ at this site is ligated directly by thiolate groups of Cys15 and Cys17. Size exclusion chromatography analysis indicates that GCAP5 forms a dimer in the Fe2+-free and Fe2+-bound states. NMR structural analysis and molecular docking studies suggest that a single Fe2+ ion is chelated by thiol side chains from Cys15 and Cys17 in the GCAP5 dimer, forming an [Fe(SCys)4] complex like that observed previously in two-iron superoxide reductases. Binding of Fe2+ to GCAP5 weakens its ability to activate photoreceptor human GC-E by decreasing GC activity >10-fold. Our results indicate a strong Fe2+-induced inhibition of GC by GCAP5 and suggest that GCAP5 may serve as a redox sensor in visual phototransduction.

Local redox environment beneath biological membranes probed by palmitoylated-roGFP

Production of reactive oxygen species (ROS) and consequent glutathione oxidation are associated with various physiological processes and diseases, including cell differentiation, senescence, and inflammation. GFP-based redox sensors provide a straight-forward approach to monitor ROS levels and glutathione oxidation within a living cell at the subcellular resolution. We utilized palmitoylated versions of cytosolic glutathione and hydrogen peroxide sensors (Grx1-roGFP2 and roGFP2-Orp1, respectively) and demonstrated a unique redox environment near biological membranes. In HeLa cells, cytosolic glutathione was practically completely reduced (EGSH/GSSG = − 333mV) and hydrogen peroxide level was under the detectable range. In contrast, the cytoplasmic milieu near membranes of intracellular vesicles exhibited significant glutathione oxidation (EGSH/GSSG > − 256mV) and relatively high H2O2 production, which was not observed for the plasma membrane. These vesicles colocalized with internalized EGFR, suggesting that H2O2 production and glutathione oxidation are characteristics of cytoplasmic surfaces of the endocytosed vesicles. The results visually illustrate local redox heterogeneity within the cytosol for the first time.

Redox Regulation of Heme Oxygenase-2 and the Transcription Factor, Rev-Erb, Through Heme Regulatory Motifs.

Heme binds to and serves as a cofactor for a myriad of proteins that are involved in diverse biological processes. Hemoproteins also exhibit varying modes of heme binding, suggesting that the protein environment contributes to the functional versatility of this prosthetic group. The subject of this review is a subset of hemoproteins that contain at least one heme regulatory motif (HRM), which is a short sequence containing a Cys-Pro core that, in many cases, binds heme with the Cys acting as an axial ligand. Recent Advances: As more details about HRM-containing proteins are uncovered, some underlying commonalities are emerging, including a role in regulating protein stability. Further, the cysteines of some HRMs have been shown to form disulfide bonds. Because the cysteines must be in the reduced, dithiol form to act as a heme axial ligand, heme binds at these sites in a redox-regulated manner, as demonstrated for heme oxygenase-2 (HO2) and Rev-erbβ. HRM-containing proteins have wide variations in heme affinity, utilize different axial ligand schemes, and exhibit differences in the ability to act as a redox sensor-all while having a wide variety of biological functions. Here, we highlight HO2 and Rev-erbβ to illustrate the similarities and differences between two hemoproteins that contain HRMs acting as redox sensors. HRMs acting as redox sensors may be applicable to other HRM-containing proteins as many contain multiple HRMs and/or other cysteine residues, which may become more evident as the functional significance of HRMs is probed in additional proteins.

Abstract 21327: In vivo Reduction of Mitochondrial Oxidative Stress Abolishes Arrhythmic Sudden Cardiac Death (SCD) in Non-Ischemic Heart Failure

Intro: Reactive oxygen species (ROS) are central to SCD pathophysiology, but their effects depend on where and how ROS are generated. Insight into this has been limited by the lack of adequate experimental methods. Employing innovative approaches, we tested the hypothesis that elevated mitochondrial ROS (mROS) is a principal source of oxidative stress and in vivo reduction of mROS mitigates SCD in non-ischemic heart failure (HF). Methods: In a unique guinea pig model that mimics human non-ischemic HF with a high incidence of SCD, we performed a randomized 2x2 crossover study of vehicle (v) and MitoTEMPO therapies (vM/Mv). In the untreated HF model, we performed in vivo gene transfer with novel, genetically encoded ratiometric redox sensors targeted to the cytosol (cROS) or mitochondria of cardiomyocytes. In isolated left ventricular (LV) myocytes, we quantified ROS dynamics during field stimulation (1 Hz, 37°C) in the presence or absence of MitoTEMPO. Results: Over 4 weeks, 65% of the HF animals experienced SCD. MitoTEMPO therapy abolished SCD and LV dysfunction. Crossover to MitoTEMPO (vM) prevented SCD and improved LV function; the converse (Mv) worsened HF without increasing SCD for up to 5 weeks of follow up, suggesting distinct underlying mechanisms. EKG analysis revealed that MitoTEMPO therapy decreased PVC burden, reduced dispersion of repolarization and decreased QT variability in arrhythmogenic failing hearts. MitoTEMPO therapy also prevented many of the changes in expression proteome and phosphoproteome leading to contractile dysfunction, arrhythmia and SCD. In subcellular studies of LV myocytes, acute MitoTEMPO exposure strongly suppressed both mROS and cROS. Exogenous H 2 O 2 increased ROS in all intracellular compartments, but mROS scavenging was impaired more than cROS, consistent with downregulation of mitochondrial antioxidant enzymes. Conclusions: Mitochondria are a principal source of cellular oxidative stress in failing arrhythmogenic hearts, but also are the major sink of ROS. Impaired mROS scavenging cause failing hearts to become more vulnerable to demand-induced oxidative stress and promote arrhythmic SCD. Maintaining global redox balance by enhanced mROS scavenging may be an effective strategy for SCD therapy in HF.