Sarcoplasmic ATP-sensitive potassium channel blocker HMR1098 protects the ischemic heart: implication of calcium, complex I, reactive oxygen species and mitochondrial ATP-sensitive potassium channel.

The aim of this study was to investigate the effects of HMR1098, a selective blocker of sarcolemmal ATP-sensitive potassium channel (sarcK(ATP)), in Langendorff-perfused rat hearts submitted to ischemia and reperfusion. The recovery of heart hemodynamic and mitochondrial function, studied on skinned fibers, was analyzed after 30-min global ischemia followed by 20-min reperfusion. Infarct size was quantified on a regional ischemia model after 2-h reperfusion. We report that the perfusion of 10 microM HMR1098 before ischemia, delays the onset of ischemic contracture, improves recovery of cardiac function upon reperfusion, preserves the mitochondrial architecture, and finally decreases infarct size. This HMR1098-induced cardioprotection is prevented by 1 mM 2-mercaptopropionylglycine, an antioxidant, and by 100 nM nifedipine, an L-type calcium channel blocker. Concomitantly, it is shown that HMR1098 perfusion induces (i) a transient and specific inhibition of the respiratory chain complex I and, (ii) an increase in the averaged intracellular calcium concentration probed by the in situ measurement of indo-1 fluorescence. Finally, all the beneficial effects of HMR1098 were strongly inhibited by 5-hydroxydecanoate and abolished by glibenclamide, two mitoK(ATP) blockers. This study demonstrates that the HMR1098-induced cardioprotection occurs indirectly through extracellular calcium influx, respiratory chain complex inhibition, reactive oxygen species production and mitoK(ATP) opening. Taken together, these data suggest that a functional interaction between sarcK(ATP) and mitoK(ATP) exists in isolated rat heart ischemia model, which is mediated by extracellular calcium influx.

Ouabain protects rat hearts against ischemia-reperfusion injury via pathway involving src kinase, mitoKATP, and ROS.

We showed recently that mitochondrial ATP-dependent K(+) channel (mitoK(ATP)) opening is required for the inotropic response to ouabain. Because mitoK(ATP) opening is also required for most forms of cardioprotection, we investigated whether exposure to ouabain was cardioprotective. We also began to map the signaling pathways linking ouabain binding to Na(+)-K(+)-ATPase with the opening of mitoK(ATP). In Langendorff-perfused rat hearts, 10-80 microM ouabain given before the onset of ischemia resulted in cardioprotection against ischemia-reperfusion injury, as documented by an improved recovery of contractile function and a reduction of infarct size. In skinned cardiac fibers, a ouabain-induced protection of mitochondrial outer membrane integrity, adenine nucleotide compartmentation, and energy transfer efficiency was evidenced by a decreased release of cytochrome c and preserved half-saturation constant of respiration for ADP and adenine nucleotide translocase-mitochondrial creatine kinase coupling, respectively. Ouabain-induced positive inotropy was dose dependent over the range studied, whereas ouabain-induced cardioprotection was maximal at the lowest dose tested. Compared with bradykinin (BK)-induced preconditioning, ouabain was equally efficient. However, the two ligands clearly diverge in the intracellular steps leading to mitoK(ATP) opening from their respective receptors. Thus BK-induced cardioprotection was blocked by inhibitors of cGMP-dependent protein kinase (PKG) or guanylyl cyclase (GC), whereas ouabain-induced protection was not blocked by either agent. Interestingly, however, ouabain-induced inotropy appears to require PKG and GC. Thus 5-hydroxydecanoate (a selective mitoK(ATP) inhibitor), N-(2-mercaptopropionyl)glycine (MPG; a reactive oxygen species scavenger), ODQ (a GC inhibitor), PP2 (a src kinase inhibitor), and KT-5823 (a PKG inhibitor) abolished preconditioning by BK and blocked the inotropic response to ouabain. However, only PP2, 5-HD, and MPG blocked ouabain-induced cardioprotection.

Mitochondrial PKC epsilon and mitochondrial ATP-sensitive K+ channel copurify and coreconstitute to form a functioning signaling module in proteoliposomes.

Mitochondria are key mediators of the cardioprotective signal and the mitochondrial ATP-sensitive K+ channel (mitoK(ATP)) plays a crucial role in originating and transmitting that signal. Recently, protein kinase C epsilon (PKC epsilon) has been identified as a component of the mitoK(ATP) signaling cascade. We hypothesized that PKC epsilon and mitoK(ATP) interact directly to form functional signaling modules in the inner mitochondria membrane. To examine this possibility, we studied K+ flux in liposomes containing partially purified mitoK(ATP). The reconstituted proteins were obtained after detergent extraction of isolated mitochondria, 200-fold purification by ion exchange chromatography, and reconstitution into lipid vesicles. Immunoblot analysis revealed the presence of PKC epsilon in the reconstitutively active fraction. Addition of the PKC activators 12-phorbol 13-myristate acetate, hydrogen peroxide, and the specific PKC epsilon peptide agonist, psi epsilonRACK, each activated mitoK(ATP)-dependent K+ flux in the reconstituted system. This effect of PKC epsilon was prevented by chelerythrine, by the specific PKC epsilon peptide antagonist, epsilonV(1-2), and by the specific mitoK(ATP) inhibitor 5-hydroxydecanoate. In addition, the activating effect of PKC agonists was reversed by exogenous protein phosphatase 2A. These results demonstrate persistent, functional association of mitochondrial PKC epsilon and mitoK(ATP).

The mechanism by which the mitochondrial ATP-sensitive K+ channel opening and H2O2 inhibit the mitochondrial permeability transition.

Myocardial infarction is a manifestation of necrotic cell death as a result of opening of the mitochondrial permeability transition (MPT). Receptor-mediated cardioprotection is triggered by an intracellular signaling pathway that includes phosphatidylinositol 3-kinase, endothelial nitric-oxide synthase, guanylyl cyclase, protein kinase G (PKG), and the mitochondrial K(ATP) channel (mitoK(ATP)). In this study, we explored the pathway that links mitoK(ATP) with the MPT. We confirmed previous findings that diazoxide and activators of PKG or protein kinase C (PKC) inhibited MPT opening. We extended these results and showed that other K(+) channel openers as well as the K(+) ionophore valinomycin also inhibited MPT opening and that this inhibition required reactive oxygen species. By using isoform-specific peptides, we found that the effects of K(ATP) channel openers, PKG, or valinomycin were mediated by a PKCepsilon. Activation of PKCepsilon by phorbol 12-myristate 13-acetate or H(2)O(2) resulted in mitoK(ATP)-independent inhibition of MPT opening, whereas activation of PKCepsilon by PKG or the specific PKCepsilon agonist psiepsilon receptor for activated C kinase caused mitoK(ATP)-dependent inhibition of MPT opening. Exogenous H(2)O(2) inhibited MPT, because of its activation of PKCepsilon, with an IC(50) of 0.4 (+/-0.1) microm. On the basis of these results, we propose that two different PKCepsilon pools regulate this signaling pathway, one in association with mitoK(ATP) and the other in association with MPT.

The direct physiological effects of mitoK(ATP) opening on heart mitochondria.

The mitochondrial ATP-sensitive K+ channel (mitoK(ATP)) has been assigned multiple roles in cell physiology and in cardioprotection. Each of these roles must arise from basic consequences of mitoK(ATP) opening that should be observable at the level of the mitochondrion. MitoK(ATP) opening has been proposed to have three direct effects on mitochondrial physiology: an increase in steady-state matrix volume, respiratory stimulation (uncoupling), and matrix alkalinization. Here, we examine the evidence for these hypotheses through experiments on isolated rat heart mitochondria. Using perturbation techniques, we show that matrix volume is the consequence of a steady-state balance between K+ influx, caused either by mitoK(ATP) opening or valinomycin, and K+ efflux caused by the mitochondrial K+/H+ antiporter. We show that increasing K+ influx with valinomycin uncouples respiration like a classical uncoupler with the important difference that uncoupling via K+ cycling soon causes rupture of the outer mitochondrial membrane and release of cytochrome c. By loading the potassium binding fluorescent indicator into the matrix, we show directly that K+ influx is increased by diazoxide and inhibited by ATP and 5-HD. By loading the fluorescent probe BCECF into the matrix, we show directly that increasing K+ influx with either valinomycin or diazoxide causes matrix alkalinization. Finally, by comparing the effects of mitoK(ATP) openers and blockers with those of valinomycin, we show that four independent assays of mitoK(ATP) activity yield quantitatively identical results for mitoK(ATP)-mediated K+ transport. These results provide decisive support for the hypothesis that mitochondria contain an ATP-sensitive K+ channel and establish the physiological consequences of mitoK(ATP) opening for mitochondria.

Protein kinase G transmits the cardioprotective signal from cytosol to mitochondria.

Ischemic and pharmacological preconditioning can be triggered by an intracellular signaling pathway in which Gi-coupled surface receptors activate a cascade including phosphatidylinositol 3-kinase, endothelial nitric oxide synthase, guanylyl cyclase, and protein kinase G (PKG). Activated PKG opens mitochondrial KATP channels (mitoKATP) which increase production of reactive oxygen species. Steps between PKG and mitoKATP opening are unknown. We describe effects of adding purified PKG and cGMP on K+ transport in isolated mitochondria. Light scattering and respiration measurements indicate PKG induces opening of mitoKATP similar to KATP channel openers like diazoxide and cromakalim in heart, liver, and brain mitochondria. This effect was blocked by mitoKATP inhibitors 5-hydroxydecanoate, tetraphenylphosphonium, and glibenclamide, PKG-selective inhibitor KT5823, and protein kinase C (PKC) inhibitors chelerythrine, Ro318220, and PKC-epsilon peptide antagonist epsilonV(1-2). MitoKATP are opened by the PKC activator 12-phorbol 13-myristate acetate. We conclude PKG is the terminal cytosolic component of the trigger pathway; it transmits the cardioprotective signal from cytosol to inner mitochondrial membrane by a pathway that includes PKC-epsilon.

Functional distinctions between the mitochondrial ATP-dependent K+ channel (mitoKATP) and its inward rectifier subunit (mitoKIR).

The ATP-sensitive potassium channel from the inner mitochondrial membrane (mitoK(ATP)) is a highly selective conductor of K(+) ions. When isolated in the presence of nonionic detergent and reconstituted in liposomes, mitoK(ATP) is inhibited with high affinity by ATP (K((1/2)) = 20-30 microM). We have suggested that holo-mitoK(ATP) is a heteromultimer consisting of an inwardly rectifying K(+) channel (mitoKIR) and a sulfonylurea receptor (Grover, G. J., and Garlid, K. D. (2000) J. Mol. Cell. Cardiol. 32, 677-695). Here, we show that a 55-kDa protein isolated by ethanol extraction and reconstituted in bilayer lipid membranes and liposomes is the mitoKIR. This protein, which lacks the sulfonylurea receptor subunit, is inhibited with low affinity by ATP, with K(1/2) approximately 550 microM. ATP inhibition of both mitoKIR and holo-mitoK(ATP) is reversed by UDP (K((1/2))1/2 = 10-15 microM). Holo-mitoK(ATP) is and diazoxide, and the opened by cromakalim flux through the open channel is inhibited by glibenclamide and 5-hydroxydecanoate. None of these agents has any effect upon mitoKIR. We have identified two compounds that act specifically on mitoKIR. p-diethylaminoethylbenzoate reverses inhibition of mitoKIR by ATP and ADP at micromolar concentrations and also opens mitoK(ATP) in isolated mitochondria. Tetraphenylphosphonium inhibits K(+) flux through both mitoKIR and mitoK(ATP) with the same apparent affinity. These findings support the hypothesis that the 55-kDa mitoKIR is the channel component of mitoK(ATP).

Mechanisms of tetrahydroxy-1, 4-benzoquinone toxicity to V79 cells: involvement of free radicals produced by its autoxidation

The toxicity of a polyhydroxy derivative of p-benzoquinone, tetrahydroxy-l,4-benzoquinone (THQ), was investigated in Chinese hamster ribroblasts (V79-M8 line). The fast oxidative degradation of THQ, yielding reactive oxygen species, allowed its use as a suitable tool to study the mechanisms of cell injury under oxidative stress. Toxicity of THQ to V79 cells was evaluated by measuring its inhibitory effects on cell growth and upon DNA synthesis rate. Complete prevention of both effects by catalase implicated hydrogen peroxide as the central key in the mechanism of THQ cytotoxicity. The roles of the primary oxidative product of THQ, rhodizonic acid (RDZ), as well as that of calcium, were investigated. The dependence of THQ on hydrogen peroxide for cytotoxicity, together with the possibility of iron chelation by RDZ, led us to propose an intracellular Fenton-type reaction as the mediator of THQ toxicity toward V79 cells. The understanding of THQ toxicity mechanisms can help to gain insights into the way structurally related physiological compounds, such as catechol derivatives, produce their toxic effects on target cells.