Short communication: rapid preparation of preventive and therapeutic whole-killed retroviral vaccines using the microbicide taurine chloramine.

A current urgent priority is to develop microbicides and vaccines to combat retroviruses like human immunodeficiency virus (HIV). We show that the cysteine-selective natural compound, taurine chloramine (T-NCl), can be effective in this task. A number of proteins in all retroviruses contain highly conserved cysteine-rich regions that are essential for infection and replication. Our data show that by targeting these essential cysteine residues, T-NCl (2 or 5 mM) acts as a highly effective and safe microbicide that fully blocks the infectivity of high HIV-1 titers (10(6) TCID(50) units/ml) but is not injurious to eukaryotic cells. We also demonstrate that T-NCl can be used to prepare a highly effective whole-killed vaccine against murine AIDS (MAIDS) that shows both preventive and therapeutic efficacy. The vaccine consists of a T-NCl-inactivated retrovirus suspension in host cell lysate. The novelty of our approach lies in the ease and speed of vaccine preparation and its avoidance of harsh inactivation or purification steps that can alter native viral conformation. Our approach is therefore likely to overcome a number of intractable obstacles to the preparation of an effective whole-killed HIV vaccine, such as surviving infective viral particles, rapid viral mutation rates, numerous viral strains, and harsh purification steps. Our approach may also permit the rapid preparation of autologous, or custom-made, vaccines for individual patients.

Important role of energy-dependent mitochondrial pathways in cultured rat cardiac myocyte apoptosis.

Recent studies have suggested that apoptosis and necrosis share common features in their signaling pathway and that apoptosis requires intracellular ATP for its mitochondrial/apoptotic protease-activating factor-1 suicide cascade. The present study was, therefore, designed to examine the role of intracellular energy levels in determining the form of cell death in cardiac myocytes. Neonatal rat cardiac myocytes were first incubated for 1 h in glucose-free medium containing oligomycin to achieve metabolic inhibition. The cells were then incubated for another 4 h in similar medium containing staurosporine and graded concentrations of glucose to manipulate intracellular ATP levels. Under ATP-depleting conditions, the cell death caused by staurosporine was primarily necrotic, as determined by creatine kinase release and nuclear staining with ethidium homodimer-1. However, under ATP-replenishing conditions, staurosporine increased the percentage of apoptotic cells, as determined by nuclear morphology and DNA fragmentation. Caspase-3 activation by staurosporine was also ATP dependent. However, loss of mitochondrial transmembrane potential (DeltaPsi(m)), Bax translocation, and cytochrome c release were observed in both apoptotic and necrotic cells. Moreover, cyclosporin A, an inhibitor of mitochondrial permeability transition, attenuated staurosporine-induced apoptosis and necrosis through the inhibition of DeltaPsi(m) reduction, cytochrome c release, and caspase-3 activation. Our data therefore suggest that staurosporine induces cell demise through a mitochondrial death signaling pathway and that the presence of intracellular ATP favors a shift from necrosis to apoptosis through caspase activation.

Neuronal apoptosis inhibitory protein expression after traumatic brain injury in the mouse.

Apoptosis of brain cells is triggered by traumatic brain injury (TBI) and is blocked by caspase inhibitors. The neuronal apoptosis inhibitor protein (NAIP), which has been shown to inhibit apoptosis by both caspase-dependant and caspase-independent mechanisms, is neuroprotective in rat models of cerebral ischemia and axotomy. In order to gain a better appreciation of CNS apoptosis following head injury in general and the possible involvement of NAIP specifically, we have configured a mouse model of TBI. In addition to demonstrating apoptosis, the spatiotemporal expression or levels of a number of proteins with apoptosis modulating effects have been determined. Apoptosis of neurons and oligodendrocytes following TBI was observed in brain sections which were triple-stained with in situ end labeling, bisbenzimide and immunofluorescent stain for neuron specific nuclear protein and myelin-associated glycoprotein, respectively. Further evidence for apoptosis following TBI in this model was obtained in brain samples using ligation-mediated PCR amplification of DNA fragments and gel electrophoresis. The temporal profile of apoptosis was similar to the temporal profile of microglial activation determined by CD11b staining and TNFa expression induced by TBI. NAIP staining in sections of cerebral cortex and subcortical white matter increased at 6 h and decreased towards control levels at 24 h post-TBI. Temporal changes in the expression of NAIP were also observed using Western blot analysis of brain samples removed from injured cortex and sub-cortical white matter. At the time that NAIP expression decreased markedly (24 h post-TBI), procaspase-3 levels also decreased, PARP cleavage increased, and the highest levels of apoptosis were observed. These findings have implications in our understanding of traumatically induced programmed cell death and may be useful in the configuration of therapies for this common injury state.

Cytokine-induced nitric oxide production inhibits mitochondrial energy production and impairs contractile function in rat cardiac myocytes.

OBJECTIVES: The present study examined whether nitric oxide (NO) produced by inducible nitric oxide synthase (iNOS) can directly inhibit aerobic energy metabolism and impair cell function in interleukin (IL)-1beta,-stimulated cardiac myocytes. BACKGROUND: Recent reports have indicated that excessive production of NO induced by cytokines can disrupt cellular energy balance through the inhibition of mitochondrial respiration in a variety of cells. However, it is still largely uncertain whether the NO-induced energy depletion affects myocardial contractility. METHODS: Primary cultures of rat neonatal cardiac myocytes were prepared, and NO2-/NO3- (NOx) in the culture media was measured using Griess reagent. RESULTS: Treatment with IL-1beta (10 ng/ml) increased myocyte production of NOx in a time-dependent manner. The myocytes showed a concomitant significant increase in glucose consumption, a marked increase in lactate production, and a significant decrease in cellular ATP (adenosine 5'-triphosphate). These metabolic changes were blocked by co-incubation with N(G)-monomethyl-L-arginine (L-NMMA), an inhibitor of NO synthesis. Sodium nitroprusside (SNP), a NO donor, induced similar metabolic changes in a dose-dependent manner, but 8-bromo-cyclic guanosine 3',5'-monophosphate (8-bromo-cGMP), a cGMP donor, had no effect on these parameters. The activities of the mitochondrial iron-sulfur enzymes, NADH-CoQreductase and succinate-CoQreductase, but not oligomycin-sensitive ATPase, were significantly inhibited in the IL-1beta, or SNP-treated myocytes. Both IL-1beta and SNP significantly elevated maximum diastolic potential, reduced peak calcium current (I(Ca)), and lowered contractility in the myocytes. KT5823, an inhibitor of cGMP-dependent protein kinase, did not block the electrophysiological and contractility effects. CONCLUSIONS: These data suggest that IL-1beta-induced NO production in cardiac myocytes lowers energy production and myocardial contractility through a direct attack on the mitochondria, rather than through cGMP-mediated pathways.

Inhaled nitric oxide protects against hyperoxia-induced apoptosis in rat lungs.

Inhaled nitric oxide (NO), frequently administered in combination with hyperoxic gas mixtures, was recently shown to protect against the injurious consequences of prolonged hyperoxia. We investigated the possibility that this protective effect is attributable to the ability of NO to block pulmonary apoptosis. We show that rats exposed to 100% O2 for 60 h develop severe lung injury consisting of pronounced vascular leak and alveolar apoptosis as inferred from the presence of positive terminal deoxynucleotidyltransferase-mediated dUTP nick end labeling and DNA ladders in agarose gels and a decrease in constitutive procaspase-3 levels. However, the inclusion of NO (20 parts/million) in the hyperoxic gas mixture significantly attenuated both the vascular leak and apoptosis. NO reversed the hyperoxia-associated changes in the activity of the redox-sensitive transcription factors nuclear factor-kappaB, activator protein-1, and Sp1 after 24 h, lowered intercellular adhesion molecule-1 levels, and increased glutathione content. We therefore show, for the first time, that NO can protect against both hyperoxia-induced apoptosis and inflammation. The data suggest that this protection may occur at the transcriptional and caspase-activation levels.

Cerebral ischemia produces laddered DNA fragments distinct from cardiac ischemia and archetypal apoptosis.

The electrophoretic pattern of laddered DNA fragments which has been observed after cerebral ischemia is considered to indicate that neurons are dying by apoptosis. Herein the authors directly demonstrate using ligation-mediated polymerase chain reaction methods that 99% of the DNA fragments produced after either global or focal ischemia in adult rats, or produced after hypoxia-ischemia in neonatal rats, have staggered ends with a 3' recess of approximately 8 to 10 nucleotides. This is in contrast to archetypal apoptosis in which the DNA fragments are blunt ended as seen during developmental programmed cell death in dying cortical neurons, neuroblastoma, or thymic lymphocytes. It is not simply ischemia that results in staggered ends in DNA fragments because ischemic myocardium is similar to archetypal apoptosis with a vast majority of blunt-ended fragments. It is concluded that the endonucleases that produce this staggered fragmentation of the DNA backbone in ischemic brain must be different than those of classic or type I apoptosis.

Oxidants increase intracellular free Zn2+ concentration in rabbit ventricular myocytes.

Oxidative stress may alter cardiac function by affecting intracellular free Zn2+ concentrations ([Zn2+]i). Rabbit ventricular myocytes loaded with fura 2 were used to fluorometrically measure resting [Zn2+]i (0.23 +/- 0.03 nM) and intracellular Ca2+ concentration ([Ca2+]i) (36 +/- 7 nM). Fluorescence quenching by the heavy metal chelator N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine was used to quantitate [Zn2+]i. The thiol-reactive oxidants hypochlorous acid (0.1 mM) and selenite (1 mM) increased [Zn2+]i to 7.7 +/- 1.7 and 6.1 +/- 1.7 nM, respectively, within 5 min. Dithiothreitol (0.5 mM), a disulfide-reducing agent, rapidly restored normal [Zn2+]i. The oxidants did not affect [Ca2+]i. However, depolarization-induced Ca2+ transients and Ca2+ currents were zinc dependent. [Zn2+]i-associated fluorescence was substantial and, if ignored, it led to overestimation of [Ca2+]i by approximately twofold before oxidant treatment and by approximately eightfold after oxidants. The results demonstrate that [Zn2+]i 1) can be greatly increased by thiol-reactive oxidants; 2) may contribute to oxidant-induced alterations of excitation-contraction coupling; and 3) has strong fura 2 fluorescence which, if overlooked, can lead to significant overestimation of [Ca2+]i.

Early apoptosis in human myocardial infarcts.

Myocardial apoptosis has previously been observed in human acute myocardial infarcts. We examined the time of appearance and extent of apoptosis in human acute myocardial infarcts, and compared these with necrotic cell death. Because nuclear internucleosomal DNA fragmentation is a hallmark of apoptosis, autopsied tissue from cases of acute myocardial infarct of varying histological ages was subjected to two tests that identify such fragmentation: in situ end-labeling (ISEL) and DNA electrophoresis on agarose gels. Both tests showed widespread apoptosis in infarcts only a few hours in age before the appearance of coagulative necrosis. No apoptosis was detected in normal myocardium. ISEL in recent infarcts was visible primarily in myocytes containing contraction bands, which occur predominantly in regions of reperfused myocardium. During the next 1 to 2 days, ISEL remained extensive but increasingly appeared in cells with morphological features of coagulative necrosis, representative of nonreperfused myocardium. In older infarcts, the incidence of apoptosis declined in myocytes, but increased in invading inflammatory cells. These data suggest that apoptosis is the early and predominant form of cell death in infarcted human myocardium, and that its appearance is accelerated in reperfused myocardium. Therapies directed at early rescue of apoptotic myocytes may, therefore, prove valuable.

Subtle neuronal death in striatum after short forebrain ischemia in rats detected by in situ end-labeling for DNA damage.

BACKGROUND AND PURPOSE: Neuronal cell death after global brain ischemia occurs predominantly by necrosis, whereas only a minor fraction of cell death may occur through apoptosis. Brief or moderate insults are thought to facilitate apoptosis, which is associated with DNA fragmentation. After 10 minutes of four-vessel occlusion in rats, conventional neuropathological analysis shows neuronal cell death in hippocampal CA1 but not in the striatum. Thus, we compared hippocampus and striatum for occurrence of cells with DNA fragmentation. METHODS: A brief insult of 10 minutes of forebrain ischemia was induced in rats using four-vessel occlusion, and groups of brains were studied at 1, 3, 6, and 12 hours and at 1, 3, and 7 days after ischemia. In situ end-labeling (ISEL) was used to detect neurons undergoing DNA fragmentation. The hippocampal CA1 area was compared with the striatum. Conventional staining and immunohistochemical markers served to exclude ischemic neuronal cell death in the striatum. RESULTS: Hippocampal CA1 neurons were ISEL-positive by 3 days after ischemia. In contrast, positive cells became evident in the striatum between 3 hours to 3 days after ischemia. The ISEL-positive cells were scattered throughout the striatum with a preference for the dorsomedial areas and accounted for about 0.2% of the neurons per striatal area at 1 day. Conventional staining and immunohistochemical markers failed to reveal areas of overt cell damage in the striatum. CONCLUSIONS: The scattered cell damage in the striatum after brief forebrain ischemia suggests the occurrence of an apoptotic process. The striatum therefore may be prone to subtle cell death due to metabolic insults.

Apoptosis in ischemic and reperfused rat myocardium.

Apoptosis has been observed previously in hearts subjected to either continuous ischemia or ischemia followed by reperfusion. The purpose of this study was to compare the timing and extent of apoptosis in both continuously ischemic and reperfused myocardium. We show that rats subjected to continuous coronary artery occlusion display characteristic signs of apoptosis solely in the ischemic myocardium after only 2.25 hours of ischemia, as illustrated by positive in situ end labeling (ISEL) of apoptotic cardiomyocyte nuclei in tissue sections and/or the presence of DNA "ladders" in agarose gels. In contrast, reperfusion after a 45-minute occlusion accelerated the process, with apoptosis becoming evident solely in the reperfused myocardium after only 1 hour of reperfusion. ISEL and DNA ladder intensity increased with duration of ischemia or reperfusion. The volume of myocardium in which ISEL was observed was smaller in the reperfused hearts, and the ISEL-stained nuclei represented 23% and 33% of the total nuclei in the reperfused and permanently occluded myocardium, respectively. Therefore, the data suggest that reperfusion lowers the extent of apoptosis in ischemic myocardium but, paradoxically, accelerates the residual apoptosis, possibly because of reperfusion injury. A large accumulation of neutrophils was observed in both the permanently occluded and reperfused myocardium, suggesting that the inflammatory response may have contributed to apoptosis in both settings. This study therefore confirms that both ischemic and reperfused rat myocardium can undergo apoptotic cell death. However, the data suggest that although reperfusion lowers the number of myocytes undergoing apoptosis, it accelerates apoptosis in the nonsalvageable cells.

Rapid neutrophil accumulation and protein oxidation in irradiated rat lungs.

Exposure of lungs to high doses of ionizing radiation can initiate an injurious acute inflammatory response. We show that neutrophil content in the lungs of rats exposed to 10 Gy whole body gamma radiation increased threefold 4.5 h after irradiation and returned to normal by 24 h. Oxidized methionine in the proteins of the lungs, heart, liver, kidney, and jejunum increased significantly in 2 h. Treatment with the antioxidant dithiothreitol immediately after irradiation prevented methionine oxidation. Methionine oxidation was also observed after intrabronchial instillation of phorbol myristate acetate, a model of neutrophil oxidant-mediated pulmonary injury, as well as in isolated lungs perfused with hypochlorous acid, confirming the ability of neutrophil oxidants to cause protein oxidation in lungs. No change in glutathione or protein sulfhydryl content was detected in irradiated lungs 4.5 h after irradiation, possibly as a result of protection by the observed increase in pulmonary glutathione reductase. We therefore show that the acute pulmonary inflammatory response to radiation involves rapid neutrophil accumulation, oxidant production, and protein oxidation.

Hypochlorous acid and chloramines increase endothelial permeability: possible involvement of cellular zinc.

The migration of neutrophils through the endothelium at sites of inflammation may be facilitated by oxidant-mediated disruption of cellular junctions. The present study examined the effects of noncytotoxic concentrations of the membrane-penetrating neutrophil oxidants hypochlorous acid (HOCI) and monochloramine (NH2Cl), or the membrane-impermeant taurine chloramine (taurine NCl), on cultured bovine aorta endothelial monolayers. HOCl (25 microM) or NH2Cl (10 microM), but not taurine NCl (100 microM), caused a reversible shortening of the cytoskeletal actin microfilaments, cell retraction, and increased permeability within 2 min. These effects were accompanied by an increase in intracellular zinc concentration as well as the oxidation of intracellular glutathione and protein sulfhydryls. The zinc ionophore pyrithione also increased permeability. HOCl or NH2Cl, but not taurine NCl, also rapidly increased microvascular permeability in isolated perfused rat lungs. The data suggest that HOCl and NH2Cl can increase endothelial permeability by causing very rapid cytoskeletal shortening and cell retraction, possibly as a result of the oxidation of intracellular sulfhydryls and mobilization of zinc.

Hypochlorous acid mobilizes intracellular zinc in isolated rat heart myocytes.

Neutrophil oxidants appear to cause contractile dysfunction in reperfused ischemic myocardium. This "reperfusion injury" may result from the intracellular mobilization of various metals. We examined the ability of hypochlorous acid (HOCl), a highly reactive neutrophil oxidant, to mobilize cellular zinc in cardiac tissue. To monitor cellular zinc concentrations, isolated rat heart myocytes were loaded with N-(6-methoxy-8-quinolyl)-p-toluenesulfonamide (TSQ), a zinc-specific fluorescent chelator. Superfusion of the TSQ-loaded cells with HOCl (50 microM) resulted in a two-fold increase in cellular fluorescence within 15 min, indicating an increase in free Zn2+ concentration. Superfusion of the HOCl-treated cells with ethylene glycol bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA), a non membrane-permeant zinc chelator, did not decrease cellular fluorescence. However, superfusion with N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN), or dithiothreitol (DTT), two membrane-permeant heavy metal chelators, rapidly diminished fluorescence, suggesting that the increase in TSQ fluorescence was caused by an intracellular increase in free Zn2+. The myocytes retained their rod-shaped morphology throughout these procedures. These data show, for the first time, that HOCl can mobilize intracellular zinc in viable cardiac myocytes. In view of the important intracellular role played by zinc, the mobilization of this metal by oxidants may contribute to the functional alterations observed in reperfused myocardium. Moreover, the ability of TPEN and DTT to complex the HOCl-mobilized zinc suggests that these chelators may be capable of attenuating or reversing these effects.

Role of catalase in myocardial protection against ischemia in heat shocked rats.

It was recently reported that in rats exposure to heat shock leads to appearance of a myocardial heat shock protein (HSP 70) and to an increase in myocardial catalase activity. This correlated with an improvement in post-ischemic function either in Langendorff-perfused hearts after low-flow ischemia or in working hearts after short-term, no-flow ischemia. We investigated the effect of the same hyperthermic treatment on functional recovery from no-flow ischemia of various durations in isolated working rat hearts performing at high or low external workloads. Rats were heated to core temperature of 42 degrees C for 15 min. No significant protein oxidation (% oxidized methionine) was observed 2.5 hr after treatment. A protein with migration characteristics similar to HSP 70 was observed in hearts of heat shocked rats 24 hr after this treatment while their myocardial catalase activity was not increased. Hearts of similarly treated rats were excised 24 hr after hyperthermia and perfused in a working mode with Krebs-Henseleit buffer (1.25 mM Ca2+, 11 mM glucose). At 15 cm H2O preload and 100 cm H2O afterload after 30 min no-flow ischemia, control hearts recovered to 36.9%, 2%, 47.6%, and 21.5% of the preischemic values of heart rate-peak systolic pressure product (RPP), aortic output, coronary flow, and cardiac output, respectively. After only 25 min of ischemia the respective recovered values were 61.6%, 11.5%, 58.7%, and 33.5%. Throughout the recovery period these hemodynamic values were consistently higher in hearts of heat shocked animals than in those of control hearts but the differences were not statistically significant.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxidant-induced mobilization of zinc from metallothionein.

Neutrophils which accumulate at sites of inflammation secrete a number of injurious oxidants which are highly reactive with protein sulfhydryls. The present study examined the possibility that this reactivity with thiols may cause protein damage by mobilizing zinc from cellular metalloproteins in which the metal is bound to cysteine. The ability of the three principal neutrophil oxidants, hypochlorous acid (HOCl), superoxide (.O2-), and hydrogen peroxide (H2O2), to cleave thiolate bonds and mobilize complexed zinc was compared using two model compounds (2,3-dimercaptopropanol and metallothionein peptide fragment 56-61), as well as metallothionein. With all compounds, 50 microM HOCl caused high rates of Zn2+ mobilization as measured spectrophotometrically with the metallochromic indicator 4-(2-pyridylazo)resorcinol. Xanthine (500 microM) plus xanthine oxidase (30 mU), which produced a similar concentration of .O2-, also effected a rapid rate of Zn2+ mobilization which was inhibited by superoxide dismutase but not catalase, indicating that .O2- is also highly reactive with thiolate bonds. In contrast, H2O2 alone was much less reactive at comparable concentrations. These data suggest that HOCl and .O2- can cause damage to cellular metalloproteins through the mobilization of complexed zinc. In view of the essential role played by zinc in numerous cellular processes, Zn2+ mobilization by neutrophil oxidants may cause significant cellular injury at sites of inflammation.

Impairment of cardiac contractility and sarcoplasmic reticulum Ca2+ ATPase activity by hypochlorous acid: reversal by dithiothreitol.

Isolated rat hearts perfused with 100 microM hypochlorous acid (HOCl), a powerful oxidant produced by activated neutrophils, exhibited progressive impairment of contractile performance suggestive of a cytosolic Ca2+ overload (increased left ventricular end-diastolic pressure, increased aortic root perfusion pressure, and depressed pulse pressure). Sarcoplasmic reticulum (SR) enriched microsomal preparations isolated from HOCl-perfused hearts showed a significant decline, when compared with control hearts, in both Ca2+ ATPase activity (123 +/- 40 vs. 473 +/- 46 nmol Pi.mg-1 protein.min-1) and Ca2+ uptake (12 +/- 5 vs. 46 +/- 4 nmol Ca2+.mg-1 protein.min-1). The sulfhydryl content in Ca2+ ATPase and other proteins, as determined by [14C]iodoacetamide binding, was also progressively depleted in HOCl-perfused hearts. Perfusion of the HOCl-treated hearts with dithiothreitol (DTT), a disulfide reducing agent, resulted in a time-dependent attenuation, and eventual partial reversal, of the dysfunction in both contractility and SR Ca2+ ATPase activity. Protein thiol levels were concomitantly restored to near control values. The data indicate that HOCl-induced contractile dysfunction in heart is related to the inactivation of the SR Ca2+ ATPase as a result of thiol oxidation and suggest that DTT is capable of reversing this dysfunction in situ by reducing the oxidized sulfhydryls in the Ca2+ ATPase.

Hypochlorous acid mobilizes cellular zinc.

Neutrophil oxidants, in particular hypochlorous acid (HOCl), can cause injury to healthy tissues at sites of inflammation. Some of this injury may be caused by oxidant-induced mobilization of metals. We examined the ability of HOCl to mobilize Zn2+ in target tissues. Arterial endothelial cell cultures and heart tissue sections were incubated for 90 s in buffered saline, pH 7.3, containing a suspension of N-(6-methoxy-8-quinolyl)-p-toluenesulfonamide (100 nmol/mL), a Zn(2+)-specific fluorescent chelator, and were subsequently exposed to 200 microM HOCl for 5 min. The cellular fluorescence was analyzed histologically and showed a marked increase in intensity after HOCl treatment, which was indicative of an increase in cellular free Zn2+ concentration. Incubation of HOCl-treated tissues with dithiothreitol, a membrane-permeable metal chelator, caused a sharp decline in cellular fluorescence. This study shows for the first time that HOCl can mobilize cellular Zn2+. In view of the multiple cellular roles played by Zn2+, its mobilization by oxidants at sites of inflammation may contribute to the observed injury. The ability of dithiothreitol to chelate the mobilized Zn2+ suggests that it may be able to reverse Zn(2+)-mediated injury.

Calcium homeostasis in rabbit ventricular myocytes. Disruption by hypochlorous acid and restoration by dithiothreitol.

Hypochlorous acid (HOCl) is a toxic oxidant produced by neutrophils at sites of cardiac inflammation. To examine the effect of this oxidant on Ca2+ homeostasis in the heart, isolated rabbit ventricular myocytes were iontophoretically loaded with the Ca2+ indicator fura 2 and superfused with 100 microM HOCl under voltage-clamp conditions. Ca2+ transients and the corresponding Ca2+ currents were elicited by 300-msec depolarizing pulses from -40 to 0 mV. Within 200 seconds after HOCl addition, the amplitude of the Ca2+ transients was reduced from 402 +/- 89 to 82 +/- 29 nM (p less than 0.01) while intracellular free ([Ca2+]i increased from 78 +/- 16 to 265 +/- 48 nM (p less than 0.01). During this time, the amplitude of the slow inward currents increased by 10%, while steady-state holding current remained stable. This sustained steady-state rise in [Ca2+]i occurred even in the absence of extracellular Ca2+ but was virtually abolished by a 20-second preexposure to 10 mM caffeine, suggesting that the major source of this Ca2+ was the sarcoplasmic reticulum. Although washout of HOCl failed to induce recovery, subsequent exposure to the dithiol reducing agent dithiothreitol caused a rapid restoration of both the steady-state [Ca2+]i and Ca2+ transient amplitude. We conclude that 1) HOCl caused a rise of [Ca2+]i by inducing the release of Ca2+ from internal stores and impairing cellular extrusion mechanisms and 2) these effects occur through alteration of protein thiol redox status.

Hypochlorous acid-induced mobilization of zinc from metalloproteins.

Hypochlorous acid (HOCl), a neutrophil oxidant, can contribute to tissue injury at sites of inflammation by its reactivity with protein sulfhydryls. The present study shows that physiological concentrations (50-200 microM) of HOCl can displace Zn2+ from metalloproteins, such as metallothionein and alcohol dehydrogenase, in which the metal is bound to sulfhydryls by means of thiolate (S-Zn) bonds. No mobilization of Zn2+ was observed from superoxide dismutase in which the metal is not bound to cysteine, suggesting that HOCl reacts selectively with thiolate bonds. Zn2+ mobilization, measured spectrophotometrically with the metallochromic indicator 4-(2-pyridylazo)resorcinol, was also observed from complexes of this metal with other thiol-containing compounds such as 2,3-dimercaptopropanol and metallothionein fragment 56-61. HOCl cleavage of the thiolate bonds was confirmed by the decrease in absorbance at 250 nm. This study shows for the first time that HOCl can mobilize protein-bound Zn2+ and suggests that neutrophil oxidant injury may be partially mediated by the mobilization of cellular Zn2+.