Hypothiocyanite and host–microbe interactions

The pseudohypohalous acid hypothiocyanite/hypothiocyanous acid (OSCN⁻/HOSCN) has been known to play an antimicrobial role in mammalian immunity for decades. It is a potent oxidant that kills bacteria but is non-toxic to human cells. Produced from thiocyanate (SCN⁻) and hydrogen peroxide (H₂O₂) in a variety of body sites by peroxidase enzymes, HOSCN has been explored as an agent of food preservation, pathogen killing, and even improved toothpaste. However, despite the well-recognized antibacterial role HOSCN plays in host–pathogen interactions, little is known about how bacteria sense and respond to this oxidant. In this work, we will summarize what is known and unknown about HOSCN in innate immunity and recent advances in understanding the responses that both pathogenic and non-pathogenic bacteria mount against this antimicrobial agent, highlighting studies done with three model organisms, Escherichia coli, Streptococcus spp., and Pseudomonas aeruginosa.     

Exposure of aconitase to smoking-related oxidants results in iron loss and increased iron response protein-1 activity: potential mechanisms for iron accumulation in human arterial cells

Smokers have an elevated risk of cardiovascular disease, but the origin(s) of this increased risk are incompletely defined. Evidence supports an accumulation of the oxidant-generating enzyme myeloperoxidase (MPO) in the inflamed artery wall, and smokers have high levels of SCN^?, a preferred MPO substrate, with this resulting in HOSCN formation. We hypothesised that HOSCN, a thiol-specific oxidant may target the iron-sulphur cluster of aconitase (both isolated, and within primary human coronary artery endothelial cells; HCAEC) resulting in enzyme dysfunction, release of iron, and conversion of the cytosolic isoform to iron response protein-1, which regulates intracellular iron levels. We show that exposure of isolated aconitase to increasing concentrations of HOSCN releases iron from the aconitase [Fe-S]₄ cluster, and decreases enzyme activity. This is associated with protein thiol loss and modification of specific Cys residues in, and around, the [Fe-S]₄ cluster. Exposure of HCAEC to HOSCN resulted in increased intracellular levels of chelatable iron, loss of aconitase activity and increased iron response protein-1 (IRP-1) activity. These data indicate HOSCN, an oxidant associated with oxidative stress in smokers, can induce aconitase dysfunction in human endothelial cells via Cys oxidation, damage to the [Fe-S]₄ cluster, iron release and generation of IRP-1 activity, which modulates ferritin protein levels and results in dysregulation of iron metabolism. These data may rationalise, in part, the presence of increased levels of iron in human atherosclerotic lesions and contribute to increased oxidative damage and endothelial cell dysfunction in smokers. Similar reactions may occur at other sites of inflammation.     

Selective Metabolism of Hypothiocyanous Acid by Mammalian Thioredoxin Reductase Promotes Lung Innate Immunity and Antioxidant Defense

The endogenously produced oxidant hypothiocyanous acid (HOSCN) inhibits and kills pathogens but paradoxically is well tolerated by mammalian host tissue. Mammalian high molecular weight thioredoxin reductase (H-TrxR) is evolutionarily divergent from bacterial low molecular weight thioredoxin reductase (L-TrxR). Notably, mammalian H-TrxR contains a selenocysteine (Sec) and has wider substrate reactivity than L-TrxR. Recombinant rat cytosolic H-TrxR1, mouse mitochondrial H-TrxR2, and a purified mixture of both from rat selectively turned over HOSCN (k_cat = 357 ± 16 min⁻¹; K_m = 31.9 ± 10.3 μm) but were inactive against the related oxidant hypochlorous acid. Replacing Sec with Cys or deleting the final eight C-terminal peptides decreased affinity and turnover of HOSCN by H-TrxR. Similarly, glutathione reductase (an H-TrxR homologue lacking Sec) was less effective at HOSCN turnover. In contrast to H-TrxR and glutathione reductase, recombinant Escherichia coli L-TrxR was potently inhibited by HOSCN (IC₅₀ = 2.75 μm). Similarly, human bronchial epithelial cell (16HBE) lysates metabolized HOSCN, but E. coli and Pseudomonas aeruginosa lysates had little or no activity. HOSCN selectively produced toxicity in bacteria, whereas hypochlorous acid was nonselectively toxic to both bacteria and 16HBE. Treatment with the H-TrxR inhibitor auranofin inhibited HOSCN metabolism in 16HBE lysates and significantly increased HOSCN-mediated cytotoxicity. These findings demonstrate both the metabolism of HOSCN by mammalian H-TrxR resulting in resistance to HOSCN in mammalian cells and the potent inhibition of bacterial L-TrxR resulting in cytotoxicity in bacteria. These data support a novel selective mechanism of host defense in mammals wherein HOSCN formation simultaneously inhibits pathogens while sparing host tissue.     

Inactivation of thiol-dependent enzymes by hypothiocyanous acid: role of sulfenyl thiocyanate and sulfenic acid intermediates

Myeloperoxidase (MPO) forms reactive oxidants including hypochlorous and hypothiocyanous acids (HOCl and HOSCN) under inflammatory conditions. HOCl causes extensive tissue damage and plays a role in the progression of many inflammatory-based diseases. Although HOSCN is a major MPO oxidant, particularly in smokers, who have elevated plasma thiocyanate, the role of this oxidant in disease is poorly characterized. HOSCN induces cellular damage by targeting thiols. However, the specific targets and mechanisms involved in this process are not well defined. We show that exposure of macrophages to HOSCN results in the inactivation of intracellular enzymes, including creatine kinase (CK) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). In each case, the active-site thiol residue is particularly sensitive to oxidation, with evidence for reversible inactivation and the formation of sulfenyl thiocyanate and sulfenic acid intermediates, on treatment with HOSCN (less than fivefold molar excess). Experiments with DAz-2, a cell-permeable chemical trap for sulfenic acids, demonstrate that these intermediates are formed on many cellular proteins, including GAPDH and CK, in macrophages exposed to HOSCN. This is the first direct evidence for the formation of protein sulfenic acids in HOSCN-treated cells and highlights the potential of this oxidant to perturb redox signaling processes.     

Caffeine induces Ca2+ release by reducing the threshold for luminal Ca2+ activation of the ryanodine receptor

Myeloperoxidase, released by activated phagocytes, forms reactive oxidants by catalysing the reaction of halide and pseudo-halide ions with H(2)O(2). These oxidants have been linked to tissue damage in a range of inflammatory diseases. With physiological levels of halide and pseudo-halide ions, similar amounts of HOCl (hypochlorous acid) and HOSCN (hypothiocyanous acid) are produced by myeloperoxidase. Although the importance of HOSCN in initiating cellular damage via thiol oxidation is becoming increasingly recognized, there are limited data on the reactions of HOSCN with other targets. In the present study, the products of the reaction of HOSCN with proteins has been studied. With albumin, thiols are oxidized preferentially forming unstable sulfenyl thiocyanate derivatives, as evidenced by the reversible incorporation of (14)C from HOS(14)CN. On consumption of the HSA (human serum albumin) free thiol group, the formation of stable (14)C-containing products and oxidation of tryptophan residues are observed. Oxidation of tryptophan residues is observed on reaction of HOSCN with other proteins (including myoglobin, lysozyme and trypsin inhibitor), but not free tryptophan, or tryptophan-containing peptides. Peptide mass mapping studies with HOSCN-treated myoglobin, showed the addition of two oxygen atoms on either Trp(7) or Trp(14) with equimolar or less oxidant, and the addition of a further two oxygen atoms to the other tryptophan with higher oxidant concentrations (> or = 2-fold). Tryptophan oxidation was observed on treating myoglobin with HOSCN in the presence of glutathione and ascorbate. Thus tryptophan residues are likely to be favourable targets for the reaction in biological systems, and the oxidation products formed may be useful biomarkers of HOSCN-mediated protein oxidation.     

High plasma thiocyanate levels are associated with enhanced myeloperoxidase-induced thiol oxidation and long-term survival in subjects following a first myocardial infarction

Abstract

Elevated levels of myeloperoxidase (MPO) are associated with poor cardiovascular outcomes. MPO uses H₂O₂ to generate oxidants including HOCl and HOSCN, from chloride and thiocyanate (SCN^?) ions, respectively. SCN^? is the preferred substrate. Elevation of this anion decreases HOCl generation and increases HOSCN formation, a thiol-specific oxidant. Such changes are of potential relevance to people with elevated SCN^? levels, such as smokers. In this retrospective study, we examined whether elevated plasma MPO and SCN^? levels increased thiol oxidation as a result of increased HOSCN formation, and impacted on long-term survival in 176 subjects (74 non-smokers, 46 smokers, and 56 previous smokers) hospitalized after a first myocardial infarction. Plasma thiols were not significantly altered in smokers compared to non-smokers or past smokers. However, significant positive correlations were detected between SCN^? levels and MPO-induced thiol loss in the total population (r = 0.19, P = 0.020) and smokers alone (r = 0.58, P < 0.0001). Twelve-year all-cause mortality data indicate that above median MPO is significantly associated with higher mortality, but below-median MPO and above-median SCN^? results in increased survival, compared to below-median SCN^?. Cox proportional hazard analysis showed a significant decrease in mortality for each 1 μM increase in SCN^? (0.991; P = 0.040). Subject age was, as expected, a strong predictor of subject survival. Overall these data suggest that subjects with below-median MPO and above-median SCN^? have better long-term survival, and that elevated plasma levels of SCN^? might be protective in at least some populations.     

Thiocyanate is the major substrate for eosinophil peroxidase in physiologic fluids. Implications for cytotoxicity

The potent cytotoxic capacity of eosinophils for parasites and host tissue has in part been attributed to the catalytic action of eosinophil peroxidase (EPO), which preferentially oxidizes Br- to the powerful bleaching oxidant HOBr in buffers that mimic serum halide composition (100 mM Cl-, 20-100 microM Br-, less than 1 microM I-). However, serum also contains 20-120 microM SCN-, a pseudohalide whose peroxidative product, HOSCN, is a weak, primarily sulfhydryl-reactive oxidant. Because of its relative abundance and high oxidation potential, we hypothesized that SCN-, not Br- or I-, is the major substrate for EPO in physiologic fluids. We find that in Earle's buffer (100 mM Cl-) supplemented with 100 microM Br- and varying concentrations of SCN-, HOBr production by activated eosinophils and purified EPO, assayed by conversion of fluorescein to dibromofluorescein, was 50% inhibited (ID50) by only 1 microM SCN-. SCN- also blocked (ID50 10 microM) EPO oxidation of I- to HOI, assayed as iodofluorescein, despite the presence of 100 microM (i.e. grossly supraphysiologic) I-. Thionitrobenzoic acid oxidation kinetics indicate that SCN- is the initial species oxidized by EPO in equimolar mixtures of SCN- and Br- and in human serum. EPO also catalyzed the covalent incorporation of [14C]SCN- into proteins in buffers regardless of Br- concentration and in human serum. Comparing the cytotoxicity of HOSCN and HOBr for host cells, we find that even subphysiologic concentrations of SCN- (3.3-10 microM) nearly completely abrogate the potent Br(-)-dependent toxicity of EPO for 51Cr-labeled aortic endothelial cells and isolated working rat hearts, recently developed models of eosinophilic endocarditis. Thus, HOSCN, hitherto best known as a bacteriostatic agent in saliva and milk, is likely also the major oxidant produced by EPO in physiologic fluids, and the presence of SCN- averts damage to EPO-coated host tissues that might otherwise accrue as a result of HOBr generation. In view of these findings, the potential role of HOSCN in eosinophil killing of parasitic pathogens deserves close examination.     

Reactions and reactivity of myeloperoxidase-derived oxidants: differential biological effects of hypochlorous and hypothiocyanous acids

Myeloperoxidase (MPO) is recognised to play important roles both in the immune system and during the development of numerous human pathologies. MPO is released by activated neutrophils, monocytes and some tissue macrophages, where it catalyses the conversion of hydrogen peroxide to hypohalous acids (HOX; X = Cl, Br, SCN) in the presence of halide and pseudo-halide ions. The major reactive species produced by MPO under physiological conditions are hypochlorous acid (HOCl) and hypothiocyanous acid (HOSCN), with the ratio of these oxidants critically dependent on the concentration of thiocyanate ions (SCN?). The reactivity and selectivity of HOCl and HOSCN for biological targets are markedly different, indicating that SCN? ions have the potential to modulate both the extent and nature of oxidative damage in vivo. This article reviews recent developments in our understanding of the role of SCN? in modulating the formation of MPO-derived oxidants, particularly in respect to the differences in reaction kinetics and targets of HOCl compared to HOSCN and the ability of these two oxidants to induce damage in biological systems.     

Thiocyanate supplementation decreases atherosclerotic plaque in mice expressing human myeloperoxidase

Abstract

Elevated levels of the heme enzyme myeloperoxidase (MPO) are associated with adverse cardiovascular outcomes. MPO predominantly catalyzes formation of the oxidants hypochlorous acid (HOCl) from Cl^?, and hypothiocyanous acid (HOSCN) from SCN^?, with these anions acting as competitive substrates. HOSCN is a less powerful and more specific oxidant than HOCl, and selectively targets thiols; such damage is largely reversible, unlike much HOCl-induced damage. We hypothesized that increased plasma SCN^?, and hence HOSCN formation instead of HOCl, may decrease artery wall damage. This was examined using high-fat fed atherosclerosis-prone LDLR^–/– mice transgenic for human MPO, with and without SCN^? (10 mM) added to drinking water. Serum samples, collected fortnightly, were analyzed for cholesterol, triglycerides, thiols, MPO, and SCN^?; study-long exposure was calculated by area under the curve (AUC). Mean serum SCN^? concentrations were elevated in the supplemented mice (200–320 μM) relative to controls (< 120 μM). Normalized aortic root plaque areas at sacrifice were 26% lower in the SCN^?-supplemented mice compared with controls (P = 0.0417), but plaque morphology was not appreciably altered. Serum MPO levels steadily increased in mice on the high-fat diet, however, comparison of SCN^?-supplemented versus control mice showed no significant changes in MPO protein, cholesterol, or triglyceride levels; thiol levels were decreased in supplemented mice at one time-point. Plaque areas increased with higher cholesterol AUC (r = 0.4742; P = 0.0468), and decreased with increasing SCN^? AUC (r = ? 0.5693; P = 0.0134). These data suggest that increased serum SCN^? levels, which can be achieved in humans by dietary manipulation, may decrease atherosclerosis burden.     

Oxidation of bovine serum albumin initiated by the Fenton reaction—effect of EDTA,tert-butylhydroperoxide and tetrahydrofuran

Oxidation of bovine serum albumin (BSA) was investigated using different oxidants: The water-soluble azo-initiator 2,2′azo-bis-(2-amidinopropane) hydrochloride (AAPH), a combination of FeCl₃ and ascorbate or the Fenton oxidant consisting of FeCl₂, H₂O₂ and EDTA. In addition, the effects of exogenous compounds such as tert-butyl hydroperoxide (tBuOOH) or solvents such as tetrahydrofuran (THF), often used in model systems, was evaluated. The extent of protein damage was studied by measuring protein carbonyl groups and protein hydroperoxides. The interaction between Fenton oxidant and EDTA, THF or tBuOOH was further characterized using spin trapping electron spin resonance (ESR) spectroscopy. The results showed that the extent of protein oxidation depended on the oxidant used. The Fenton oxidant was the most reactive of the initiators tested. However, in the absence of EDTA, the Fenton system produced protein carbonyl groups on BSA equivalent to that obtained with the other oxidants, however, significantly more protein hydroperoxide was produced. Surprisingly, it was also found that addition of tBuOOH or THF to BSA reduced protein damage when the oxidation was initiated with the Fenton oxidant. ESR investigation showed that EDTA played a key role in the generation of free radicals. It was also revealed that in an EDTA containing system both tBuOOH and THF were able to react with radicals without inducing protein damage in effect protecting BSA from oxidative damage.     

Predicting infestation parameters and impacts of caligid copepods in wild and cultured fish populations

Summary

The intensity and timing of infestation events of caligid copepods in wild or cultured fish populations may be predicted from previous local production of nauplius I of the parasite. However, this relationship is not well established, the spatial scales over which it operates are unclear, and the role of host reactions to the invading copepodid is unknown. Rate of development (and population structure), generation time and rate and actual reproductive output are temperature-dependent. In Ireland between five and seven generations of Lepeophtheirus salmonis (Krøyer) can develop annually and generation time varies from over 120 days in winter to 23 days in summer. Host reactions may affect the rate of development of the parasite but are less important than temperature. Host reactions may also cause parasite mortality, but this effect is specific for individual host parasite associations. The distribution of L. salmonis in cultured host populations is typically normal but is very over-dispersed in wild populations with heavy infestations. Parasiteinduced morphological damage to the host is correlated with physiological impacts. Physiological effects are present even when morphological damage is slight and so intermittent chemotherapeutic control of infestations cannot prevent some parasite impact from occurring.     

Protective Role of Sirtuin3 (SIRT3) in Oxidative Stress Mediated by Hepatitis B Virus X Protein Expression

Background/Aim

The hepatitis B virus (HBV) infection is accompanied by the induction of oxidative stress, especially mediated by HBV X protein (HBx). Oxidative stress has been implicated in a series of pathological states, such as DNA damage, cell survival and apoptosis. However, the host factor by which cells protect themselves under this oxidative stress is poorly understood.

Methodology/Principal Findings

In this study, we first confirmed that HBV infection significantly induced oxidative stress. Moreover, viral protein HBx plays a major role in the oxidative stress induced by HBV. Importantly, we found that mitochondrial protein SIRT3 overexpression could decrease reactive oxygen species (ROS) induced by HBx while SIRT3 knockdown increased HBx-induced ROS. Importantly, SIRT3 overexpression abolished oxidative damage of HBx-expressing cells as evidenced by γH₂AX and AP sites measurements. In contrast, SIRT3 knockdown promoted HBx-induced oxidative damage. In addition, we also observed that oxidant H₂O₂ markedly promoted HBV replication while the antioxidant N-acetyl-L-cysteine (NAC) inhibited HBV replication. Significantly, SIRT3 overexpression inhibited HBV replication by reducing cellular ROS level.

Conclusions/Significance

Collectively, these data suggest HBx expression induces oxidative stress, which promotes cellular oxidative damage and viral replication during HBV pathogenesis. Mitochondrial protein SIRT3 protected HBx expressing-cells from oxidative damage and inhibited HBV replication possibly by decreased cellular ROS level. These studies shed new light on the physiological significance of SIRT3 on HBx-induced oxidative stress, which can contribute to the liver pathogenesis.     

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Summary

Myeloperoxidase plays a fundamental role in oxidant production by neutrophils. This heme enzyme uses hydrogen peroxide and chloride to catalyze the production of hypochlorous acid, which is the major strong oxidant generated by neutrophils in appreciable amounts. In addition to chlorination, myeloperoxidase displays several other activities. It readily oxidizes thiocyanate to hypothiocyanite, converts a myriad of organic substrates to reactive free radicals, and hydroxylates aromatic compounds. Depending on the concentration of its competing substrates and the conditions of the local environment, myeloperoxidase could substantially affect oxidant production by neutrophils. Superoxide is undoubtedly a physiological substrate for myeloperoxidase. Its interactions with the enzyme are key factors in determining how neutrophils use superoxide to kill pathogens and promote inflammatory tissue damage. Superoxide modulates the chlorination and peroxidation activities of myeloperoxidase. It also reacts with the enzyme to form oxymyeloperoxidase which is catalytically active and hydroxylates phenolic substrates. Myeloperoxidase reacts rapidly with nitric oxide and peroxynitrite so that at sites of inflammation there is a strong possibility that these reactions will impact on oxidative damage caused by neutrophils. Under certain conditions, many substrates of myeloperoxidase act as inhibitors and regulate oxidant production by the enzyme. Given the numerous reactions of myeloperoxidase, all its activities should be considered when assessing the injurious oxidants produced by neutrophils.     

The role of oxidant injury in the pathophysiology of human thalassemias

Abstract

The anemia in β-thalassemia major is caused by a combination of hemolysis and ineffective erythropoiesis, with the latter being more important. Studies of the underlying cause of the hemolysis have indicated that oxidant injury to circulating red blood cells (RBCs) was of critical importance, with evidence of oxidant damage to RBC membrane proteins 4.1 and band 3. Therefore, it seemed reasonable that oxidant damage to thalassemic erythroid precursors would cause their accelerated apoptosis and ineffective erythropoiesis. However, direct analysis showed that the apoptotic programs turned on in thalassemics were not those triggered by oxidative damage but were dependent on activation of FAS/FAS-Ligand interaction. Thus, destruction of thalassemic erythroid precursors may involve different mechanisms from those that cause RBC hemolysis.     

Myeloperoxidase-generated oxidants and atherosclerosis

Atherosclerosis is a chronic inflammatory process where oxidative damage within the artery wall is implicated in the pathogenesis of the disease. Mononuclear phagocytes, an inflammatory cell capable of generating a variety of oxidizing species, are early components of arterial lesions. Their normal functions include host defense and surveillance through regulated generation of diffusible radical species, reactive oxygen or nitrogen species, and HOCl (hypochlorous acid). However, under certain circumstances an excess of these oxidizing species can overwhelm local antioxidant defenses and lead to oxidant stress and oxidative tissue injury, processes implicated in the pathogenesis of atherosclerosis. This review focuses on oxidation reactions catalyzed by myeloperoxidase (MPO), an abundant heme protein secreted from activated phagocytes which is present in human atherosclerotic lesions. Over the past several years, significant evidence has accrued demonstrating that MPO is one pathway for protein and lipoprotein oxidation during the evolution of cardiovascular disease. Multiple distinct products of MPO are enriched in human atherosclerotic lesions and LDL recovered from human atheroma. However, the biological consequences of these MPO-catalyzed reactions in vivo are still unclear. Here we discuss evidence for the occurrence of MPO-catalyzed oxidation reactions in vivo and the potential role MPO plays in both normal host defenses and inflammatory diseases like atherosclerosis.     

Efficacy and site specificity of hydrogen abstraction from DNA 2-deoxyribose by carbonate radicals

The carbonate radical anion CO₃^?? is a potent reactive oxygen species (ROS) produced in vivo through enzymatic one-electron oxidation of bicarbonate or, mostly, via the reaction of CO₂ with peroxynitrite. Due to the vitally essential role of the carbon dioxide/bicarbonate buffer system in regulation of physiological pH, CO₃^?? is arguably one of the most important ROS in biological systems. So far, the studies of reactions of CO₃^?? with DNA have been focused on the pathways initiated by oxidation of guanines in DNA. In this study, low-molecular products of attack of CO₃^?? on the sugar–phosphate backbone in vitro were analyzed by reversed phase HPLC. The selectivity of damage in double-stranded DNA (dsDNA) was found to follow the same pattern C4′ > C1′ > C5′ for both CO₃^?? and the hydroxyl radical, though the relative contribution of the C1′ damage induced by CO₃^?? is substantially higher. In single-stranded DNA (ssDNA) oxidation at C1′ by CO₃^?? prevails over all other sugar damages. An approximately 2000-fold preference for 8-oxoguanine (8oxoG) formation over sugar damage found in our study identifies CO₃^?? primarily as a one-electron oxidant with fairly low reactivity toward the sugar–phosphate backbone.     

Estimation of phylogenetic relationships among some Hypericum (Hypericaceae) species using internal transcribed spacer sequences

Abstract

Reactive oxygen species (ROS, partially reduced or activated derivatives of oxygen), are highly reactive and toxic and can lead to oxidative destruction of the cell. ROS production increases when plants are exposed to different kinds of stresses. The chief toxic effect of O₂ ^? and H₂O₂ resides in their ability to initiate cascade reactions that result in the production of the hydroxyl radical and other destructive species such as lipid peroxides. These dangerous cascades are prevented by efficient operation of the cell's antioxidant defenses. However, in addition to their role as toxic byproducts of aerobic metabolism, recently, a new role for ROS has been identified, i.e. the control and regulation of biological processes, such as growth, cell cycle, programmed cell death, hormone signaling, biotic and abiotic stress responses, and development. This review discusses the biochemical properties and sources and sites of ROS production, ROS-scavenging systems, and the role of ROS as signaling molecules.     

Reevaluation of the rate constants for the reaction of hypochlorous acid (HOCl) with cysteine,methionine, and peptide derivatives using a new competition kinetic approach

Activated white cells use oxidants generated by the heme enzyme myeloperoxidase to kill invading pathogens. This enzyme utilizes H₂O₂ and Cl⁻, Br⁻, or SCN⁻ to generate the oxidants HOCl, HOBr, and HOSCN, respectively. Whereas controlled production of these species is vital in maintaining good health, their uncontrolled or inappropriate formation (as occurs at sites of inflammation) can cause host tissue damage that has been associated with multiple inflammatory pathologies including cardiovascular diseases and cancer. Previous studies have reported that sulfur-containing species are major targets for HOCl but as the reactions are fast the only physiologically relevant kinetic data available have been extrapolated from data measured at high pH (>10). In this study these values have been determined at pH 7.4 using a newly developed competition kinetic approach that employs a fluorescently tagged methionine derivative as the competitive substrate (k(HOCl + Fmoc-Met), 1.5×10⁸ M⁻¹ s⁻¹). This assay was validated using the known k(HOCl + NADH) value and has allowed revised k values for the reactions of HOCl with Cys, N-acetylcysteine, and glutathione to be determined as 3.6×10⁸, 2.9×10⁷, and 1.24×10⁸ M⁻¹ s⁻¹, respectively. Similar experiments with methionine derivatives yielded k values of 3.4×10⁷ M⁻¹ s⁻¹ for Met and 1.7×10⁸ M⁻¹ s⁻¹ for N-acetylmethionine. The k values determined here for the reaction of HOCl with thiols are up to 10-fold higher than those previously determined and further emphasize the critical importance of reactions of HOCl with thiol targets in biological systems.