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(Circulation Research. 2008;103:983.)
© 2008 American Heart Association, Inc.

Cellular Biology

Glycogen Synthase Kinase 3 Inhibition Slows Mitochondrial Adenine Nucleotide Transport and Regulates Voltage-Dependent Anion Channel Phosphorylation

Samarjit Das, Renee Wong, Nishadi Rajapakse, Elizabeth Murphy, Charles Steenbergen

From the Department of Pathology (S.D., C.S.), Johns Hopkins University, Baltimore, Md; Cardiac Physiology Section (R.W., E.M.), Vascular Medicine Branch, National Heart, Lung, and Blood Institute, NIH, Bethesda, Md; and Laboratory of Signal Transduction (N.R.), National Institute of Environmental Health Sciences, NIH, Research Triangle Park, NC.

Correspondence to Charles Steenbergen, MD, PhD, Department of Pathology, Johns Hopkins University, 632N Ross Research Building, 720 Rutland St, Baltimore, MD 21205. E-mail csteenb1{at}jhmi.edu

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
Inhibition of glycogen synthase kinase (GSK)-3 reduces ischemia/reperfusion injury by mechanisms that involve the mitochondria. The goal of this study was to explore possible molecular targets and mechanistic basis of this cardioprotective effect. In perfused rat hearts, treatment with GSK inhibitors before ischemia significantly improved recovery of function. To assess the effect of GSK inhibitors on mitochondrial function under ischemic conditions, mitochondria were isolated from rat hearts perfused with GSK inhibitors and were treated with uncoupler or cyanide or were made anoxic. GSK inhibition slowed ATP consumption under these conditions, which could be attributable to inhibition of ATP entry into the mitochondria through the voltage-dependent anion channel (VDAC) and/or adenine nucleotide transporter (ANT) or to inhibition of the F₁F₀-ATPase. To determine the site of the inhibitory effect on ATP consumption, we measured the conversion of ADP to AMP by adenylate kinase located in the intermembrane space. This assay requires adenine nucleotide transport across the outer but not the inner mitochondrial membrane, and we found that GSK inhibitors slow AMP production similar to their effect on ATP consumption. This suggests that GSK inhibitors are acting on outer mitochondrial membrane transport. In sonicated mitochondria, GSK inhibition had no effect on ATP consumption or AMP production. In intact mitochondria, cyclosporin A had no effect, indicating that ATP consumption is not caused by opening of the mitochondrial permeability transition pore. Because GSK is a kinase, we assessed whether protein phosphorylation might be involved. Therefore, we performed Western blot and 1D/2D gel phosphorylation site analysis using phos-tag staining to indicate proteins that had decreased phosphorylation in hearts treated with GSK inhibitors. Liquid chromatographic–mass spectrometric analysis revealed 1 of these proteins to be VDAC2. Taken together, we found that GSK-mediated signaling modulates transport through the outer membrane of the mitochondria. Both proteomics and adenine nucleotide transport data suggest that GSK regulates VDAC and that VDAC may be an important regulatory site in ischemia/reperfusion injury.

Key Words: mitochondria • GSK-3 • VDAC • adenine nucleotide transport

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
Ischemic heart disease is a major cause of morbidity and mortality worldwide. This has motivated a search for new approaches to reduce ischemic injury, propelled by the discovery of ischemic preconditioning (IPC).¹ Considerable data suggest that IPC leads to the release of adenosine, opioids, or bradykinin,^2,3 which bind to G protein–coupled receptors and initiate a signaling cascade that involves activation of phosphatidylinositol-3 kinase and downstream kinases such as Akt, endothelial nitric oxide synthase, protein kinase C, mTOR (mammalian target of rapamycin), p70S6 kinase, extracellular signal-regulated kinase, and glycogen synthase kinase (GSK)-3β.^4–6

GSK-3, first identified as a regulator of glycogen metabolism, is also an important regulator of cell function, including gene expression and cell cycle, survival, and apoptosis.⁷ GSK-3 belongs to the serine/threonine kinase family of proteins, and the 2 known isoforms are GSK-3 (51 kDa) and GSK-3β (47 kDa), which share 98% homology and similar substrate specificities.

The activity of GSK-3β is regulated by phosphorylation.⁷ GSK-3β is active under normal resting conditions when it is not phosphorylated, and phosphorylation at serine 9 leads to its inactivation. The activity of GSK-3β is regulated by several signaling pathways as a number of kinases (Akt, protein kinase C, protein kinase A, and others) can phosphorylate GSK-3β on serine 9 and inactivate it.

In addition to its role in cell survival, proliferation, and differentiation, GSK-3β has been proposed to be involved in the cardioprotective effects of IPC^8,9 and various forms of pharmacological cardioprotection.^10–14 Our laboratory⁸ previously demonstrated that the cardioprotection elicited by IPC is mediated by the inhibition of GSK via phosphatidylinositol (PI)3-kinase. It has also been reported that opioid-induced cardioprotection occurs via inactivation of GSK-3β by phosphorylation at serine 9 through PI3-kinase and TOR-dependent pathways.¹¹ Protective effects have been observed when GSK-3β inhibitors were administered immediately before ischemia,⁸ 24 hours before ischemia,¹³ or immediately on reperfusion.^11,14 GSK inhibition is also protective during heart failure.¹⁵

Recently GSK-3β has been described in mitochondria, and GSK inhibition is thought to block opening of the mitochondrial permeability transition pore (mPTP) in cardiomyocytes.¹⁰ However, the molecular targets of GSK-3β in mitochondria and the precise physiological effects of GSK-3β inhibition on mitochondrial function have not been fully elucidated.

The present study was designed to identify downstream targets of GSK-3 and to link the phosphorylation of downstream targets to physiological effects on mitochondrial function. We propose that cardioprotection resulting from inhibition of GSK-3 is partly mediated by modulation of mitochondrial bioenergetics.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
Animals
Male Sprague–Dawley rats were used in this study. All experimental procedures were approved by the Institutional Animal Care and Use Committee of Johns Hopkins University.

Langendorff Rat Heart Preparation
Hearts were perfused as described previously.¹⁶ Details are provided in the online data supplement, available at http://circres.ahajournals.org.

Isolated Mitochondria Protocols
Mitochondria were isolated as described previously.¹⁶ The online data supplement provides details of the assays.

Proteomics
Details of the Western blots, 1D/2D gel electrophoresis, and phospho-protein detection are provided in the online data supplement.

	Results

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
GSK-3 Inhibitors Increase Recovery of Contractile Function After Ischemia
We previously reported that GSK-3 inhibitors improved recovery of function and reduced necrosis following ischemia. In this study, we examined the mechanisms involved, after confirming the protective effects of 2 GSK-3 inhibitors SB216763 and SB415286. Dose–response experiments were performed to establish effective concentrations. As shown in Figure 1, either 3 µmol/L SB216763 or 10 µmol/L SB415286 significantly enhanced recovery of left ventricular developed pressure during reperfusion, to 48.9±6.2% and 56.8±8.1% of baseline compared with 34.7±7.5% in control hearts (P<0.05). Previous work from our laboratory⁸ and others^11,13–14 has shown that GSK-3 inhibitors also reduce necrosis.

View larger version (57K): [in this window] [in a new window]   Figure 1. Hearts were perfused for 15 minutes with control buffer, followed by 15 minutes of perfusion with GSK inhibitor or vehicle, 20 minutes of global ischemia, and 40 minutes of reperfusion. Results are means±SEM (n=6). *P<0.05 vs control.

GSK-3 Inhibitors Reduce the Rate of ATP Consumption in Isolated Mitochondria
We previously found that addition of recombinant Bcl-2 to mitochondria resulted in reduced breakdown of ATP under deenergized conditions when the mitochondrial F₁F₀-ATPase runs in reverse.¹⁶ This reduced rate of ATP consumption was attributed to altered ATP transport into the mitochondria. To determine whether GSK-3 inhibitors also decreased ATP consumption under deenergized conditions, we studied mitochondria rapidly deenergized using the uncoupler dinitrophenol. Under these conditions, mitochondria from hearts treated with GSK inhibitors consumed less ATP than control mitochondria (Figure 2A). Similarly, GSK inhibitors significantly reduced ATP consumption when sodium cyanide was used to stop mitochondrial respiration (Figure 2B). In the physiologically relevant model of mitochondrial deenergization, mitochondria were allowed to consume all of the oxygen in an oxygraph chamber, and then the consumption of ATP during the ensuing anoxic period was measured. ATP consumption was linear in both control- and GSK inhibitor–treated mitochondria, and after 60 minutes of anoxia, the amount of ATP consumed was significantly less in the GSK inhibitor–treated mitochondria (Figure 2C). Mitochondria from ischemically preconditioned myocardium showed a similar slowing of ATP consumption (Figure I in the online data supplement). This slowing of ATP consumption could be accomplished by attenuating ATP entry into the mitochondria through the voltage-dependent anion channel (VDAC) and/or the adenine nucleotide transporter (ANT) or by inhibition of the mitochondrial F₁F₀-ATPase.

View larger version (44K): [in this window] [in a new window]   Figure 2. GSK inhibitors slow ATP consumption. A, Mitochondria were deenergized with dinitrophenol for 5 minutes. B, Mitochondria were treated with cyanide for 20 minutes. C, Mitochondria were anoxic for 60 minutes. Both GSK inhibitors significantly decrease the rate of ATP hydrolysis. Results are means±SEM (n=6). *P<0.05 vs control.

To determine whether this effect is caused by inhibition of the mitochondrial F₁F₀-ATPase, mitochondria were sonicated to disrupt the mitochondria and expose the F₁F₀-ATPase. We found (Figure 3A) that ATPase activity in the sonicated mitochondrial fragments was similar in the presence or absence of uncoupler, as expected, if we had fully disrupted the mitochondria, and GSK inhibitors had no effect on ATP consumption by the sonicated mitochondrial fragments. Only in the intact mitochondria was there an inhibitory effect of GSK inhibitors. Thus, the effect of GSK inhibitors does not appear to be attributable to direct inhibition of F₁F₀-ATPase activity.

View larger version (60K): [in this window] [in a new window]   Figure 3. Effect of GSK inhibition on mitochondrial adenine nucleotide metabolism. A, Mitochondria were deenergized using dinitrophenol, and ATP remaining after 2.5 minutes of incubation was measured. GSK inhibitors have no effect on ATPase activity in sonicated mitochondria. B, CsA (200 µmol/L) was added to deenergized mitochondria; this had no effect on ATP hydrolysis, either in control and GSK inhibitor groups. Results are means±SEM (n=6). *P<0.05 vs intact control; #P<0.05 vs intact SB216763 treated; P<0.05 vs intact+DNP, SB 216763-treated.

The Effect of GSK-3 Inhibitors on Mitochondrial Adenine Nucleotide Metabolism Is Not Attributable to a Direct Effect on the mPTP
To examine whether the effect of GSK inhibitors on adenine nucleotide metabolism is caused by a direct effect on the mPTP, we examined the effect of cyclosporin A (CsA) on ATP consumption under deenergized conditions. To establish that an effective dose of CsA was being used, we measured mitochondrial swelling induced by calcium, and we found that 200 µmol/L CsA markedly reduced mitochondrial swelling in response to calcium compared to control. However, this concentration of CsA had no effect on adenine nucleotide transport (Figure 3B). Thus GSK inhibitors are inhibiting transport through physiological transport mechanisms, and there is no evidence that adenine nucleotide entry into the mitochondria during early anoxia is related to mPTP opening. However, inhibiting physiological transport could indirectly protect the mitochondria and reduce the probability of mPTP opening as injury progresses.

GSK-3 Inhibitors Reduce Adenine Nucleotide Transport Through the Outer Mitochondrial Membrane
To further explore the mechanism whereby GSK inhibitors slow ATP consumption under deenergized conditions, an assay was developed that isolated effects of outer mitochondrial membrane transport from effects on ANT or the F₁F₀-ATPase. This assay took advantage of adenylate kinase, which resides in the intermembrane space. Under deenergized conditions, comparable to the conditions used to measure mitochondrial ATP consumption but in the presence of oligomycin to block matrix adenine nucleotide metabolism, ADP was added to isolated mitochondria, and AMP generation was measured. This assay is independent of ANT or F₁F₀-ATPase activity; it relies solely on VDAC to transport ADP into the mitochondria, adenylate kinase to convert ADP into AMP and ATP, and VDAC to transport AMP out of the mitochondria. If the effect of GSK inhibitors is on adenine nucleotide transport across the outer mitochondrial membrane, then there should be less ADP consumed and less AMP produced in the mitochondria treated with GSK inhibitors compared to control. There is significantly less ADP consumed (Figure 4A) and less AMP produced (Figure 4B) in the GSK inhibitor–treated mitochondria, as compared to the untreated mitochondria. In a separate series of experiments, we assessed the effect of GSK inhibitors on adenylate kinase activity in sonicated mitochondria where the outer membrane would be disrupted, and GSK inhibitors had no effect on ADP consumption or AMP production (Figure 4A and 4B, right). The data suggest that GSK inhibitors do not inhibit adenylate kinase and that the ATP-sparing effect of GSK inhibitors is related to decreased adenine nucleotide transport across the outer mitochondrial membrane.

View larger version (42K): [in this window] [in a new window]   Figure 4. GSK inhibitors slow the rate of ADP consumption (A) and the rate of AMP production (B) by cyanide-treated mitochondria. Results are means±SEM (n=6). *P<0.05 vs control.

GSK-3 Inhibitors Reduce Phosphorylation of VDAC
Because the functional data suggest that GSK inhibitors are slowing adenine nucleotide transport through the outer mitochondrial membrane, and VDAC is the channel that is responsible for this transport, we explored the effect of GSK inhibitors on VDAC phosphorylation. We used several approaches. First, we used an antibody that recognizes proteins that are phosphorylated at serine/threonine residues of Akt substrates, and we performed Western blotting to determine whether GSK inhibition affects protein phosphorylation. We observed a dramatic change in a protein band at 32 kDa. As shown in Figure 5A (top), there is much less phosphorylation of this band when the hearts were treated with a GSK inhibitor than in untreated hearts. The molecular mass of VDAC is 32 kDa. The gel was stripped and reprobed with antibody to VDAC, and the phosphorylated protein overlaps with VDAC, and, as shown in Figure 5A (bottom), there is the same amount of VDAC in each lane. Next, we performed 2D gel electrophoresis to verify this finding when proteins are better separated. As shown in Figure 5B, the location of VDAC in the 2D gel was established with VDAC antibody (upper images), and phosphorylation was assessed using phospho-Akt substrate antibodies (lower images). The lower images show VDAC phosphorylation in the control extracts on the left but not in the GSK inhibitor–treated extracts on the right. To examine this further, we used Phos-tag to identify phosphorylated proteins, and we performed 1D and 2D gel electrophoresis. In the 1D gels, the GSK inhibitors significantly reduced protein phosphorylation in the 32-kDa region. To validate this finding, 2D gel electrophoresis was performed with narrow pH range strips that focused the VDAC region more clearly, and then we stained with Phos-tag. Figure 6 shows several spots that had high levels of phosphorylation in untreated heart extracts but very little phosphorylation in GSK inhibitor–treated heart extracts. Mass spectrometry demonstrated that VDAC2 is present in all 3 spots in the 2D gel.

View larger version (34K): [in this window] [in a new window]   Figure 5. Effect of GSK inhibition on phosphorylation of a 32 kDa protein. A, Top, Representative 1D gel showing the amount of 32-kDa phosphorylated Akt substrate protein in control and GSK inhibitor–treated heart extracts. Middle, The gel reprobed with VDAC antibody, showing no significant difference in total VDAC expression. Gel densitometry was performed for quantitation, and the ratio of 32-kDa phospho-protein to total VDAC is plotted. *P<0.05 vs control. B, Whole heart homogenates were further separated using 2D gel electrophoresis. In the upper images, control homogenate (left) and GSK inhibitor–treated homogenate (right) were probed with VDAC antibody. Then, the membranes were stripped and reprobed for phosphorylated Akt substrate protein (lower images). There is phosphorylated protein in the VDAC region in control but not in GSK inhibitor–treated homogenate. The region of interest is circled and shown at higher magnification at the bottom.

View larger version (68K): [in this window] [in a new window]   Figure 6. Whole heart homogenate protein was separated by 2D gel electrophoresis and stained with phos-tag to detect phosphorylated proteins. Three spots showing marked differences in phosphorylation level, in the 32-kDa region (shown in higher magnification) were analyzed by light chromatography–mass spectrometry, and VDAC-2 was identified by at least 4 peptide fragments, in all 3 spots.

VDAC Can Be Phosphorylated by Either Akt or GSK-3β
To determine whether Akt or GSK-3β can phosphorylate VDAC in vitro, we partially purified VDAC and performed an in vitro kinase assay using recombinant active Akt and recombinant GSK-3β. VDAC was partially purified using a hydroxyapatite/celite column as used by others.¹⁷ We then performed an in vitro kinase assay and measured the extent of phosphorylation using Pro-Q Diamond staining. Although there was some endogenous phosphorylation, this was further increased by either Akt or GSK-3β (Figure 7A). We also examined the ability of recombinant active Akt to phosphorylate VDAC using isolated mitochondria. Recombinant Akt added to the medium, in the presence of ATP, increased phosphorylation of the 32-kDa protein band (Figure 7B). Thus external Akt can phosphorylate the protein, indicating that the phosphorylation site is on the outside of the mitochondria, consistent with the location of VDAC.

View larger version (56K): [in this window] [in a new window]   Figure 7. A, In vitro phosphorylation of semipurified VDAC by Akt and GSK-3β. B, Increased 32 kDa Akt substrate phosphorylation in isolated mitochondria following addition of recombinant Akt (rAkt). *P<0.05 vs control.

GSK-3 Inhibitors Increase Bcl-2 Binding to Mitochondria
Previous work¹⁶ had demonstrated that cardiac overexpression of Bcl-2 protects the heart from ischemia/reperfusion injury, and this protection is associated with inhibited mitochondrial ATP consumption under deenergized conditions and with binding of Bcl-2 to VDAC. To determine whether GSK inhibitors are protective, at least in part, by enhancing Bcl-2 binding to VDAC, cell fractionation experiments were performed, and the amount of Bcl-2 in the mitochondrial and cytosolic fractions were determined by Western blotting. GSK inhibition causes a significant loss of Bcl-2 from the cytosol and a significant increase in the mitochondrial fraction (Figure 8A). This indicates that binding of Bcl-2 to mitochondrial targets increases in the presence of GSK inhibitors. To test whether this increased binding of Bcl-2 to mitochondria is specific binding to VDAC, we added equal amounts of recombinant Bcl-2 to GSK inhibitor–treated mitochondria and untreated mitochondria, immunoprecipitated VDAC, and measured the amount of Bcl-2 that was bound to VDAC. As shown in Figure 8B, there was significantly more Bcl-2 bound to VDAC in the GSK inhibitor–treated mitochondria. Thus, phosphorylation of VDAC may affect the binding affinity for Bcl-2, which may regulate outer mitochondrial membrane transport.

View larger version (42K): [in this window] [in a new window]   Figure 8. A, The effect of GSK inhibition on Bcl-2 levels in cytosolic and mitochondrial fractions. B, The effect of GSK inhibition on the amount of Bcl-2 that is immunoprecipitated by VDAC antibodies. *P<0.05 vs control.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
Previously, our group has demonstrated that IPC results in phosphorylation and inactivation of GSK-3β and that this is mediated by the PI3-kinase pathway.⁸ Furthermore, pretreatment with GSK-3 inhibitors is approximately as protective as IPC. Others^11–14 have shown that GSK-3β is involved in a variety of forms of pharmacological preconditioning, and the GSK-3β inhibitors are protective when added at the start of reperfusion.^11,14 This suggests that GSK-3β may play a central role in a final pathway of cardioprotection, as suggested by Sollott and colleagues.¹⁰ Furthermore, previous work has suggested that the effects of GSK-3β inhibition are primarily focused on the mitochondria, although the molecular target has not been determined.

The present study suggests a possible molecular target for GSK-3β in the mitochondria that may be involved in cardioprotection and a possible mechanism whereby protection is achieved. The molecular target appears to be VDAC in the outer mitochondrial membrane and phosphorylation may be a mechanism for regulating VDAC activity, either directly or by altering the binding of Bcl-2. There are 3 VDAC isoforms in mammalian cells,^18–20 which are primarily responsible for transport of molecules up to 5000 kDa across the outer mitochondrial membrane. Transport of anions is highly voltage-sensitive, with high conductance at low voltages and low conductance when voltage is increased, either positively or negatively. In contrast, cation conductance is relatively voltage-insensitive. Nucleotides such as ATP are readily permeable when VDAC is in the open state and are virtually impermeant when VDAC is closed. Ablation of the mouse VDAC1 gene results in altered mitochondrial sensitivity for ADP in muscle, but because VDAC2 and VDAC3 are also present at high levels in the heart, the mice are viable.²¹ Mice deficient for VDAC3 are viable, but deficiency of VDAC2 is embryologically lethal. Our proteomic studies suggest that it is VDAC2 that is a primary GSK target in the outer mitochondrial membrane.

Several investigators have suggested that VDAC can be an important regulator of mitochondrial function. Under conditions of anoxia, there is evidence of inhibition of mitochondrial anion exchange.²² Others^23–24 have found evidence for VDAC regulation of mitochondrial function under conditions that stimulate apoptosis. In the apoptosis studies, it has been suggested that early in the apoptotic program, the outer mitochondrial membrane becomes impermeable to small molecules such as ATP and creatine phosphate and that this leads to the eventual loss of outer mitochondrial membrane integrity and cytochrome c release, which can be prevented by antiapoptotic Bcl-2 family members.^23–24 Although the conditions and mechanisms are different in our study, the findings support the concept that VDAC transport can be regulated, and plays a role in cell injury. Under conditions leading to apoptosis, there is some controversy concerning Bcl-2 regulation of VDAC. Some reports suggest that during apoptosis, VDAC closes and that Bcl-2 is protective by maintaining VDAC in an open configuration,^23–24 whereas others suggest that Bcl-2 promotes VDAC closure.²⁵ This could be related to the specific experimental conditions or the timing of the measurements. Regardless of the controversy, our data as well as the apoptosis literature support the concept that altered VDAC conductance can be involved in the evolution of cell injury.

Although our data suggest that VDAC phosphorylation under the control of GSK-3 is an important mechanism that alters mitochondrial function under energy deficient conditions, others²⁶ suggest that mitochondrial protein phosphorylation is not involved in the protective effect of IPC. One might expect that IPC and GSK inhibition would involve many of the same mechanisms because IPC inhibits GSK through phosphorylation. However, this thorough study by Clarke et al²⁶ was performed on extracts following mitochondrial purification, and we found that we had to use whole-tissue extracts, immediately placed in detergent, to see the phosphorylation clearly. If we purified the mitochondria and then prepared extracts, the phosphorylation was barely detectable. This suggests that the phosphorylation is highly labile, presumably because the phosphatases must be separated from the substrate rapidly to preserve the phosphorylated state. To minimize this problem, we used a rapid isolation procedure for preparing mitochondria and analyzing mitochondrial function. It is possible that even under these conditions, our mitochondrial functional assays are underestimating the magnitude of the effect that is present in situ.

Functional Consequences of GSK Signaling in the Mitochondria
One of the downstream effects of GSK inhibition is delayed opening of the mPTP in response to oxygen radicals,¹⁰ and opening of the mPTP has been suggested to be a causative event in cell death during myocardial ischemia/reperfusion injury.^27–28 This effect on mPTP opening could be a direct or indirect effect of GSK inhibition. Because VDAC does not appear to be necessary for mPTP formation,²⁹ it seems unlikely that altered phosphorylation of VDAC would necessarily prevent mPTP formation. Also, the studies of Sollott and colleagues show that mPTP opening occurs even in the presence of GSK inhibitors, just more slowly.¹⁰ In accordance with these observations, our present study has also revealed that CsA treatment does not change the rate of ATP hydrolysis following deenergization, indicating an effect independent of mPTP opening. Alternatively, GSK inhibitors could alter mitochondrial function in a way that makes the mPTP less likely to form or open, possibly by limiting the factors that are known to activate the mPTP, oxidant stress, and high calcium concentrations.³⁰ If GSK inhibitors either reduced mitochondrial calcium uptake, reduced endogenous oxygen radical production, or both, this could account for the ability of GSK inhibitors to slow mPTP opening. The importance of calcium loading in mPTP opening in situ has been questioned³¹ and ROS may be a more important factor in intact tissue.

One mechanism whereby GSK inhibitors could reduce mitochondrial calcium loading would be by inhibiting ATP influx through VDAC during ischemia. During ischemia, ATP is produced by anaerobic glycolysis, and this ATP can enter the mitochondria and be hydrolyzed by the matrix F₁F₀-ATPase. This is a significant ATP-consuming process; when ischemic myocardium is treated with oligomycin, ATP consumption slows,^16,32 by as much as 50%. Although inhibition of this process may be protective by preserving ATP, this is not likely to be its major effect. Rather, mitochondrial ATP hydrolysis is used to preserve the mitochondrial membrane potential (), and direct measurement of in isolated myocytes subjected to simulated ischemia³³ shows that falls much more rapidly in the presence of oligomycin than in its absence, indicating that the matrix F₁F₀-ATPase is using cytosolic ATP to slow the decay of . Because is the primary driving force for calcium uptake into the mitochondria, it is not surprising that there is virtually complete elimination of mitochondrial calcium uptake in isolated myocytes subjected to simulated ischemia in the presence of oligomycin, whereas mitochondrial calcium uptake is observed under similar conditions in the absence of oligomycin.³³ Although this calcium uptake may be transient and may not directly open the mPTP, it could facilitate mPTP opening in response to other stimuli.

Another possible mechanism whereby inhibition of VDAC transport by GSK inhibitors may be protective under anoxic conditions is by reducing oxygen radical production during early reperfusion.³⁴ Agents that reduce by a small amount are cardioprotective, such as mitochondrial K-ATP channel openers, presumably because production of oxygen radicals is enhanced when the electrochemical proton gradient is high.³⁵ However, there is no consensus that a decrease in is critical for the protective effect of K-ATP channel openers. A decrease in during ischemia could result in less oxygen radical production during early reperfusion, which would reduce the probability of mPTP opening. Therefore, GSK inhibitors could be protective by allowing to decrease during ischemia, reducing mitochondrial calcium loading during ischemia and reducing oxygen radical production during reperfusion, both of which would tend to reduce the probability of mPTP opening and thereby be protective. Others have suggested that the protective effect of IPC involves suppression of oxidant stress.²⁶ These effects on calcium and oxidant stress would not be direct effects on the mPTP but rather effects on mPTP activators.

One interesting aspect of this study is that we found that GSK inhibitors reduced VDAC phosphorylation using an antibody that detects proteins phosphorylated at Akt sites. This could be because the antibody is not entirely specific for Akt phosphorylation sites and also recognizes other serine/threonine phosphorylations. However, it is also possible that VDAC is phosphorylated at multiple sites. GSK-3β is known to prefer substrates that have already been phosphorylated by other kinases.^9,36–37 Thus, it is possible that physiological regulation of VDAC is achieved through a dual phosphorylation mechanism involving Akt as the priming kinase and GSK-3β as the secondary kinase that is required for regulation of VDAC function. An alternative possibility is that VDAC is phosphorylated by Akt and that GSK-3β regulates the phosphatase that dephosphorylates VDAC. If GSK-3β inactivates the phosphatase that dephosphorylates VDAC, then GSK inhibitors could decrease VDAC phosphorylation by increasing the activity of the phosphatase. Further characterization of the phosphorylation sites of VDAC will be necessary to resolve this issue.

Although dephosphorylation of VDAC by GSK inhibition may be protective by altering channel conductance directly, an alternative mechanism would involve differential protein binding to the phosphorylated versus dephosphorylated VDAC. In a previous study,¹⁶ we found that Bcl-2 overexpression inhibited mitochondrial ATP consumption under deenergized conditions, similar to what we report here with GSK inhibitors. One possible explanation for the similar effect of Bcl-2 overexpression and GSK inhibition is that an important mechanism of VDAC regulation involves Bcl-2 binding, and this binding can be increased either by overexpression or by altering affinity, and 1 mechanism for altering affinity may be through phosphorylation. The data presented here suggest that Bcl-2 affinity for mitochondria, and for VDAC specifically, is increased by GSK inhibitors, consistent with a regulatory role for VDAC phosphorylation. Others have provided convincing evidence that Bcl-2 binding to a component of the mPTP is critical for cardioprotection and that GSK-3β is a critical regulator of this interaction.³¹ Another possibility is that binding of hexokinase to VDAC could have important regulatory properties.³⁸ The binding of hexokinase to VDAC appears to require activated Akt,³⁹ although it is not clear whether phosphorylation plays a role.

	Conclusions

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
The data suggest that VDAC is an important site of regulation of mitochondrial metabolism and function under deenergized conditions. GSK inhibition decreases adenine nucleotide entry through the outer mitochondrial membrane, most likely through VDAC, under anoxic or similar conditions. This reduction in adenine nucleotide transport is likely to result in a decrease in , less mitochondrial calcium loading during anoxic conditions, and less endogenous oxygen radical production during reoxygenation/reperfusion. Furthermore, GSK inhibitors alter the phosphorylation status of VDAC and alter the affinity for Bcl-2, which may also contribute to the decrease in transport through VDAC. All of these factors, less calcium loading, less oxidant stress, and more Bcl-2 binding, likely contribute to the cardioprotective effect of GSK inhibitors.

	Acknowledgments

 
Sources of Funding

Supported in part by NIH grant HL39752. R.W., N.R., and E.M. were supported by the NIH intramural program.

Disclosures

None.

	Footnotes

 
This manuscript was sent to Stephen F. Vatner, Consulting Editor, for review by expert referees, editorial decision, and final disposition.

Original received May 7, 2008; revision received August 30, 2008; accepted September 4, 2008.

	References

Top Abstract Introduction Materials and Methods Results Discussion Conclusions References

 
1. Murry CE, Jennings RB, Reimer KA. Preconditioning with ischemia: a delay of lethal cell injury in ischemic myocardium. Circulation. 1986; 74: 1124–1136.[Abstract/Free Full Text]

2. Gross ER, Gross GJ. Ligand triggers of classical preconditioning and postconditioning. Cardiovasc Res. 2006; 70: 212–221.[Abstract/Free Full Text]

3. Downey JM, Davis AM, Cohen MV. Signaling pathways in ischemic preconditioning. Heart Fail Rev. 2007; 12: 181–188.[CrossRef][Medline] [Order article via Infotrieve]

4. Tong H, Rockman HA, Koch WJ, Steenbergen C, Murphy E. G protein-coupled receptor internalization signaling is required for cardioprotection in ischemic preconditioning. Circ Res. 2004; 94: 1133–1141.[Abstract/Free Full Text]

5. Hausenloy DJ, Yellon DM. Reperfusion injury salvage kinase signaling: taking a RISK for cardioprotection. Heart Fail Rev. 2007; 12: 217–234.[CrossRef][Medline] [Order article via Infotrieve]

6. Liem DA, Honda MH, Zhang J, Woo D, Ping P. Past and present course of cardioprotection against ischemia-reperfusion injury. J Appl Physiol. 2007; 103: 2129–2136.[Abstract/Free Full Text]

7. Kockeritz L, Doble B, Patel S, Woodgett JR. Glycogen synthase kinase-3 – an overview of an over-achieving protein kinase. Curr Drug Targets. 2006; 7: 1377–1388.[Medline] [Order article via Infotrieve]

8. Tong H, Imahashi K, Steenbergen C, Murphy E. Phosphorylation of glycogen synthase kinase-3β during preconditioning through a phosphatidylinositol-3-kinase-dependent pathway is cardioprotective. Circ Res. 2002; 90: 377–379.[Abstract/Free Full Text]

9. Murphy E, Steenbergen C. Inhibition of GSK-3β as a target for cardioprotection: the importance of timing, location, duration, and degree of inhibition. Expert Opin Ther Targets. 2005; 9: 447–456.[CrossRef][Medline] [Order article via Infotrieve]

10. Juhaszova M, Zorov DB, Kim SH, Pepe S, Fu Q, Fishbein KW, Ziman BD, Wang S, Ytrehus K, Antos CL, Olson EN, Sollott SJ. Glycogen synthase kinase-3β mediates convergence of protection signaling to inhibit the mitochondrial permeability transition pore. J Clin Invest. 2004; 113: 1535–1549.[CrossRef][Medline] [Order article via Infotrieve]

11. Gross ER, Hsu AK, Gross GJ. Opioid-induced cardioprotection occurs via glycogen synthase kinase β inhibition during reperfusion in intact rat hearts. Circ Res. 2004; 94: 960–966.[Abstract/Free Full Text]

12. Nishihara M, Miura T, Miki T, Sakamoto J, Tanno M, Kobayashi H, Ikeda Y, Ohori K, Takahashi A, Shimamoto K. Erythropoietin affords additional cardioprotection to preconditioned hearts by enhanced phosphorylation of glycogen synthase kinase-3β. Am J Physiol Heart Circ Physiol. 2006; 291: H748–H755.[Abstract/Free Full Text]

13. Gross ER, Hsu AK, Gross GJ. Delayed cardioprotection afforded by the glycogen synthase kinase 3 inhibitor SB-216763 occurs via a K_ATP- and MPTP-dependent mechanism at reperfusion. Am J Physiol. 2008; 294: H1497–H1500.

14. Gross ER, Hsu AK, Gross GJ. GSK3β inhibition and K_ATP channel opening mediate acute opioid-induced cardioprotection at reperfusion. Bas Res Cardiol. 2007; 102: 341–349.[CrossRef][Medline] [Order article via Infotrieve]

15. Hirotani S, Zhai P, Tomita H, Galeotti J, Marquez JP, Go S, Hong C, Yatani A, Avila J, Sadoshima J. Inhibition of glycogen synthase kinase 3β during heart failure is protective. Circ Res. 2007; 101: 1164–1174.[Abstract/Free Full Text]

16. Imahashi K, Schneider MD, Steenbergen C, Murphy E. Transgenic expression of Bcl-2 modulates energy metabolism, prevents cytosolic acidification during ischemia, and reduces ischemia/reperfusion injury. Circ Res. 2004; 95: 734–741.[Abstract/Free Full Text]

17. Lai JC, Tan W, Benimetskaya L, Miller P, Colombini M, Stein CA. A pharmacologic target of G3139 in melanoma cells may be the mitochondrial VDAC. Proc Natl Acad Sci U S A. 2006; 103: 7494–7499.[Abstract/Free Full Text]

18. Columbini M. VDAC: the channel at the interface between mitochondria and the cytosol. Mol Cell Biochem. 2004; 256/257: 107–115.

19. Blachly-Dyson E, Zambronicz EB, Yu WH, Adams V, McCabe ERB, Adleman J, Columbini M, Forte M. Cloning and functional expression in yeast of two human isoforms of the outer mitochondrial membrane channel, the voltage-dependent anion channel. J Biol Chem. 1993; 268: 1835–1841.[Abstract/Free Full Text]

20. Sampson MJ, Lovell RS, Davison DB, Craigen WJ. A novel mouse mitochondrial voltage-dependent anion channel gene localizes to chromosome 8. Genomics. 1996; 36: 192–196.[CrossRef][Medline] [Order article via Infotrieve]

21. Anflous K, Armstrong DD, Craigen WJ. Altered mitochondrial sensitivity for ADP and maintenance of creatine-stimulated respiration in oxidative striated muscles from VDAC1-deficient mice. J Biol Chem. 2001; 276: 1954–1960.[Abstract/Free Full Text]

22. Lemasters JJ, Holmuhamedov E. Voltage-dependent anion channel (VDAC) as mitochondrial governator–thinking outside the box. Biochim Biophys Acta. 2006; 1762: 181–190.[Medline] [Order article via Infotrieve]

23. Vander Heiden MG, Li XX, Gottleib E, Hill RB, Thompson CB, Colombini M. Bcl-x_L promotes the open configuration of the voltage-dependent anion channel and metabolite passage through the outer mitochondrial membrane. J Biol Chem. 2001; 276: 19414–19419.[Abstract/Free Full Text]

24. Vander Heiden MG, Chandel NS, Li XX, Schumacker PT, Colombini M, Thompson CB. Outer mitochondrial membrane permeability can regulate coupled respiration and cell survival. Proc Nat Acad Sci USA. 2000; 97: 4666–4671.[Abstract/Free Full Text]

25. Shimizu S, Narita M, Tsujimoto Y. Bcl-2 family proteins regulate the release of apoptogenic cytochrome c by the mitochondrial channel VDAC. Nature. 1999; 399: 483–487.[CrossRef][Medline] [Order article via Infotrieve]

26. Clarke SJ, Khaliulin I, Das M, Parker JE, Heesom KJ, Halestrap AP. Inhibition of mitochondrial permeability transition pore opening by ischemic preconditioning is probably mediated by reduction of oxidative stress rather than mitochondrial protein phosphorylation. Circ Res. 2008; 102: 1082–1090.[Abstract/Free Full Text]

27. Di Lisa F, Menabò R, Canton M, Barile M, Bernardi P. Opening of the mitochondrial permeability transition port causes depletion of mitochondrial and cytosolic NAD⁺ and is a causative event in the death of myocytes in postischemic reperfusion of the heart. J Biol Chem. 2001; 276: 2571–2575.[Abstract/Free Full Text]

28. Halestrap AP, Clarke SJ, Javadov SA. Mitochondrial permeability transition pore opening during myocardial reperfusion – a target for cardioprotection. Cardiovasc Res. 2004; 61: 372–385.[Abstract/Free Full Text]

29. Baines CP, Kaiser RA, Sheiko T, Craigen WJ, Molkentin JD. Voltage-dependent anion channels are dispensable for mitochondrial-dependent cell death. Nat Cell Biol. 2007; 9: 550–555.[CrossRef][Medline] [Order article via Infotrieve]

30. Griffiths EJ, Halestrap AP. Mitochondrial non-specific pores remain closed during cardiac ischaemia, but open upon reperfusion. Biochem J. 1995; 307: 93–98.[Medline] [Order article via Infotrieve]

31. Juhaszova M, Wang S, Zorov DB, Nuss HB, Gleichmann M, Mattson MP, Sollott SJ. The identity and regulation of the mitochondrial permeability transition pore. Where the known meets the unknown. Ann N Y Acad Sci. 2008; 1123: 197–212.[CrossRef][Medline] [Order article via Infotrieve]

32. Jennings RB, Reimer KA, Steenbergen C. Effect of inhibition of the mitochondrial ATPase on net myocardial ATP in total ischemia. J Mol Cell Cardiol. 1991; 23: 1383–1395.[CrossRef][Medline] [Order article via Infotrieve]

33. Ruiz-Meana M, Garcia-Dorado D, Miró-Casas E, Abellán A, Soler-Soler J. Mitochondrial Ca2+ uptake during simulated ischemia does not affect permeability transition pore opening upon simulated reperfusion. Cardiovasc Res. 2006; 71: 715–724.[Abstract/Free Full Text]

34. Holmuhamedov EL, Jahangir A, Oberlin A, Komarov A, Colombini M, Terzic A. Potassium channel openers are uncoupling protonophores: implication in cardioprotection. FEBS Lett. 2004; 568: 167–170.[CrossRef][Medline] [Order article via Infotrieve]

35. Korshunov SS, Skulachev VP, Starkov AA. High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria. FEBS Lett. 1997; 416: 15–18.[CrossRef][Medline] [Order article via Infotrieve]

36. Fiol CJ, Mahrenholz AM, Wang Y, Roeske RW, Roach PJ. Formation of protein kinase recognition sites by covalent modification of the substrate. Molecular mechanism for the synergistic action of casein kinase II and glycogen synthase kinase 3. J Biol Chem. 1987; 262: 14042–14048.[Abstract/Free Full Text]

37. Fiol CJ, Williams JS, Chou CH, Wang QM, Roach PJ, Andrisani OM. A secondary phosphorylation of CREB³⁴¹ at Ser¹²⁹ is required for the cAMP-mediated control of gene expression. A role for glycogen synthase kinase-3 in the control of gene expression. J Biol Chem. 1994; 269: 32187–32193.[Abstract/Free Full Text]

38. Pastorino JG, Shulga N, Hoek JB. Mitochondrial binding of hexokinase II inhibits Bax-induced cytochrome C release and apoptosis. J Biol Chem. 2002; 277: 7610–7618.[Abstract/Free Full Text]

39. Majewski N, Nogueira V, Bhaskar P, Coy PE, Skeen JE, Gottlob K, Chandel NS, Thompson CB, Robey RB, Hay N. Hexokinase-mitochondria interaction mediated by Akt is required to inhibit apoptosis in the presence or absence of Bax and Bak. Mol Cell. 2004; 16: 819–830.[CrossRef][Medline] [Order article via Infotrieve]

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