Voltage dependent anion channel and its interaction with N-acetyl-L-Cysteine (NAC) under oxidative stress on planar lipid bilayer.

Mitochondria are the major source of Hydrogen Peroxide (H2O2), a reactive oxygen species, in the cells. The reactive oxygen species generated by the mitochondria oxidize major proteins including Voltage Dependent Anion Channel (VDAC). We were interested to know how the effect of H2O2 is countered by antioxidants present around the mitochondria. N-Acetyl-l-Cysteine (NAC) is a naturally existing antioxidant in the cells. Keeping this in view, the modulatory effect of antioxidant NAC on H2O2 oxidized VDAC has been investigated through in vitro electrophysiological studies. First, the effect of H2O2 and NAC was studied on independently incorporated single-channel VDAC. It was observed that NAC suppresses VDAC conductance with a half-maximal inhibitory concentration (IC50) of ∼1.04 µM. In contrast, H2O2 enhances VDAC conductance. Later, oxidative stress was induced by H2O2 on VDAC increased conductance with half-maximal effective concentration (EC50) of ∼302 nM. An application of 1 µM NAC on H2O2 treated (300 nM) VDAC reversed the effect of oxidation. In the next step, NAC and H2O2 were added in reverse order. When oxidative stress was induced using H2O2, reduction in conductance by NAC was 4.5 ± 0.404 nS. The change in conductance is nearly 6.3%. However, if antioxidant NAC was incubated first followed by H2O2 treatment, the conductance of VDAC was 3.09 ± 0.27 nS. The change in conductance is near 33%. Both H2O2 and NAC also affected various conducting states of VDAC. In-silico studies indicated the binding of NAC at Lysine and Glutamic acid of VDAC. Hence, NAC was found to be effective in protection of VDAC against H2O2-induced oxidative stress due to its strong binding.

A mutation in the S6 segment of the KvAP channel changes the secondary structure and alters ion channel activity in a lipid bilayer membrane.

The peptide segment S6 is known to form the inner lining of the voltage-gated K+ channel KvAP (potassium channel of archaea-bacterium, Aeropyrum pernix). In our previous work, it has been demonstrated that S6 itself can form an ion channel on a bilayer lipid membrane (BLM). In the present work, the role of a specific amino acid sequence 'LIG' in determining the secondary structure of S6 has been investigated. For this purpose, 22-residue synthetic peptides named S6-Wild (S6W) and S6-Mutant (S6M) were used. Sequences of these peptides are similar except that the two amino acids isoleucine and glycine of the wild peptide interchanged in the mutant peptide. Channel forming capabilities of both the peptides were checked electro-physiologically on BLM composed of DPhPC and cholesterol. Bilayer electrophysiological experiments showed that the conductance of S6M is higher than that of S6W. Significant differences in the current versus voltage (I-V) plot, open probability, and gating characteristics were observed. Interestingly, two sub-types of channels, S6M Type 1 and Type 2, were identified in S6M differing in conductances and open probability patterns. Circular dichroism (CD) spectroscopy indicated that the secondary structures of the two peptides are different in phosphatidyl choline/asolectin liposomes and 1% SDS detergent. Reduced helicity of S6M was also noticed in membrane mimetic liposomes and 1% SDS detergent micelles. These results are interpreted in view of the difference in hydrophobicity of the two amino acids, isoleucine and glycine. It is concluded that the 'LIG' stretch regulates the structure and pore-forming ability of the S6 peptide.

Extracellular Signal-Regulated Kinase1 (ERK1)-Mediated Phosphorylation of Voltage-Dependent Anion Channel (VDAC) Suppresses its Conductance.

ERK1 is one of the members of the mitogen-activated protein kinases that regulate important cellular functions. VDAC is located at the outer membrane of mitochondria. Here, an interaction between VDAC and ERK1 has been studied on an artificial planar lipid bilayer using in vitro electrophysiology experiments. We report that VDAC is phosphorylated by ERK1 in the presence of Mg2+-ATP and its single-channel currents are inhibited on the artificial bilayer membrane. Treatment of Alkaline phosphatase on ERK1 phosphorylated VDAC leads to partial recovery of the single-channel VDAC currents. Later, phosphorylation of VDAC was demonstrated by Pro-Q diamond dye. Mass Spectrometric studies indicate phosphorylation of VDAC at Threonine 33, Threonine 55, and Serine 35. In a nutshell, phosphorylation of VDAC leads to the closure of the channel.

Modulation of the mitochondrial voltage-dependent anion channel (VDAC) by hydrogen peroxide and its recovery by curcumin.

The Voltage-Dependent Anion Channel (VDAC) plays a vital role in mitochondria-mediated transport of ions and metabolites. It is well established that mitochondria are a site for production of hydrogen peroxide (H2O2). Excess production of H2O2 is toxic to the cell and causes oxidative stress. Therefore, the effect of H2O2 on the single-channel conductance of VDAC was investigated. In vitro bilayer electrophysiology experiments were performed on VDAC isolated from rat brain mitochondria, which consists predominately of the isoform VDAC1. VDAC was treated with H2O2 on a planar bilayer membrane (BLM). The conductance of VDAC increased upon H2O2 treatment, whereas the same concentration of H2O2 was unable to affect the BLM (without protein) over a long period of time. Subsequently, the sequential addition of curcumin to H2O2-treated VDAC reduced the conductance. Experimental results (bilayer electrophysiology) demonstrate the role of curcumin in the restoration of the activity of VDAC affected by H2O2. In silico docking studies enables identification of the probable binding site of H2O2 on VDAC. We further find that the oligomerization of VDAC that results in its increased conductance is an effect of lipid oxidation by H2O2.

Regulation of Single-Channel Conductance of Voltage-Dependent Anion Channel by Mercuric Chloride in a Planar Lipid Bilayer.

The existence of mercury in various forms, e.g., elemental, organic, and inorganic has been known for decades. In any of these forms, it is poisonous to metabolism. In this, an investigation about the effect of the inorganic form of mercury, i.e., mercuric chloride (HgCl2) to the mitochondrial voltage-dependent anion channel (VDAC), has been done after isolation from the cardiac and brain tissues of Wistar rats. In vitro electrophysiology experiments were performed in Cardiolipin planar lipid bilayer membrane (BLM) to study the change in the conductance, selectivity, and gating charge of VDAC post HgCl2 treatment. A reduction in mean conductance of VDAC from 4.3 ± 0.18 to 1.66 ± 0.11 nS was observed. Further, the Gating charge calculated before (± 3.5) and after HgCl2 treatment (± 2.3) showed significant difference. Later, VDAC's behavior was studied at different concentrations of HgCl2 ranging from 0.1 µM to 1 mM. The Inhibitory concentration (IC50) was calculated from the linear regression plot. The IC50 was found to be 488.1 µM. In the asymmetrical HgCl2 (5:1), a permeability ratio of cation to anion was found to be 4.2. It is interpreted that VDAC functioning is affected due to the application of 4 mM HgCl2 and a reduction in the conductance, gating charge, and permeability of VDAC was detected. The results provide clues to HgCl2-induced toxicity mediated through VDAC in the Cardiolipin BLM.

Quinidine partially blocks mitochondrial voltage-dependent anion channel (VDAC).

Quinidine is an antiarrhythmic drug commonly used for the treatment of cardiac ailments. It affects oxidative phosphorylation, calcium uptake, and ion channels of mitochondria. We have investigated the interaction of Quinidine and mitochondrial voltage-dependent anion channel (VDAC). VDAC was purified from neuronal tissue of Wistar rats and in vitro bilayer electrophysiology experiments were performed on it. 50-mM Quinidine treatment on VDAC leads to a sudden drop in its conductance. The dose of Quinidine leading to a half-maximal current through a single-channel VDAC was calculated using Quinidine at different concentrations. In silico molecular docking studies using Autodock-4.2 software indicate interaction between Quinidine and VDAC. Docking results demonstrate the interaction of Quinidine and VDAC on its Glutamic acid residue (Glu-206 of VDAC). Fluorescence spectroscopy results on Quinidine and Glutamic acid interaction show an increase in the intensity and wavelength of Quinidine fluorescence, whereas no interaction between Quinidine and Cysteine was observed. This further supports the Glutamic acid and Quinidine interaction. In conclusion, we report Quinidine partially blocks VDAC due to the interaction of Glutamic acid and Quinidine in the channel pore.

S6 peptide derived from KvAP channel shows cooperativity in gating on bilayer lipid membrane.

Collective behavior of S6 peptide channels derived from KvAP (a bacterial potassium channel) incorporated in lipid bilayer membrane, has been investigated at various applied potentials through multi-channel electrophysiological experiments. The current versus time traces at any particular membrane potential show clear steps for sequential opening of the multi-channels. The minimum current (representing one-channel current) was found out from the amplitude histograms. Accordingly, the number of open channels corresponding to a particular open state was calculated. It was observed that the above-mentioned one channel current is higher than the corresponding single-channel current at most of the applied membrane potentials. Moreover, the difference between the single and one channel conductances is a nonlinear function of the membrane potential. We conclude that the S6 multi-channels show co-operative gating. Voltage relaxation studies support the above-mentioned conclusion.

A synthetic S6 segment derived from KvAP channel self-assembles, permeabilizes lipid vesicles, and exhibits ion channel activity in bilayer lipid membrane.

KvAP is a voltage-gated tetrameric K(+) channel with six transmembrane (S1-S6) segments in each monomer from the archaeon Aeropyrum pernix. The objective of the present investigation was to understand the plausible role of the S6 segment, which has been proposed to form the inner lining of the pore, in the membrane assembly and functional properties of KvAP channel. For this purpose, a 22-residue peptide, corresponding to the S6 transmembrane segment of KvAP (amino acids 218-239), and a scrambled peptide (S6-SCR) with rearrangement of only hydrophobic amino acids but without changing its composition were synthesized and characterized structurally and functionally. Although both peptides bound to the negatively charged phosphatidylcholine/phosphatidylglycerol model membrane with comparable affinity, significant differences were observed between these peptides in their localization, self-assembly, and aggregation properties onto this membrane. S6-SCR also exhibited reduced helical structures in SDS micelles and phosphatidylcholine/phosphatidylglycerol lipid vesicles as compared with the S6 peptide. Furthermore, the S6 peptide showed significant membrane-permeabilizing capability as evidenced by the release of calcein from the calcein-entrapped lipid vesicles, whereas S6-SCR showed much weaker efficacy. Interestingly, although the S6 peptide showed ion channel activity in the bilayer lipid membrane, despite having the same amino acid composition, S6-SCR was significantly inactive. The results demonstrated sequence-specific structural and functional properties of the S6 wild type peptide. The selected S6 segment is probably an important structural element that could play an important role in the membrane interaction, membrane assembly, and functional property of the KvAP channel.

Myoangiogenesis after cell patch cardiomyoplasty and omentopexy in a patient with ischemic cardiomyopathy.

We describe a procedure to promote angiogenesis and impregnation of skeletal myoblast into infarcted myocardium. At the completion of coronary artery bypass surgery, the midline sternotomy incision was extended to open the abdomen, and the greater omentum was tailored to reach the myocardium. Four pieces of autologous rectus muscle were applied to the infarcted left ventricle. This implantation was reinforced by the greater omentum. Incisions were closed in the usual manner. Postoperatively, the patient showed significant improvements in left ventricular ejection fraction (from 0.15 to 0.40) and in exercise tolerance (from 3 METs to 6 METs, or 100%). Computed tomographic angiography and positron emission tomography demonstrated improved myocardial viability and vascularity in the ischemic segments of the left ventricle. Omentopexy and cell patch cardiomyoplasty in conjunction with coronary artery bypass surgery may stimulate myogenesis and angiogenesis in avascular, dyskinetic scar tissue of left ventricle; in this preliminary study, this procedure appeared to improve the functional capacity of the left ventricle.