Mitochondrial connexin 43 impacts on respiratory complex I activity and mitochondrial oxygen consumption.

Connexin 43 (Cx43) is present at the sarcolemma and the inner membrane of cardiomyocyte subsarcolemmal mitochondria (SSM). Lack or inhibition of mitochondrial Cx43 is associated with reduced mitochondrial potassium influx, which might affect mitochondrial respiration. Therefore, we analysed the importance of mitochondrial Cx43 for oxygen consumption. Acute inhibition of Cx43 in rat left ventricular (LV) SSM by 18α glycyrrhetinic acid (GA) or Cx43 mimetic peptides (Cx43-MP) reduced ADP-stimulated complex I respiration and ATP generation. Chronic reduction of Cx43 in conditional knockout mice (Cx43(Cre-ER(T)/fl) + 4-OHT, 5-10% of Cx43 protein compared with control Cx43(fl/fl) mitochondria) reduced ADP-stimulated complex I respiration of LV SSM to 47.8 ± 2.4 nmol O(2)/min.*mg protein (n = 8) from 61.9 ± 7.4 nmol O(2)/min.*mg protein in Cx43(fl/fl) mitochondria (n = 10, P < 0.05), while complex II respiration remained unchanged. The LV complex I activities (% of citrate synthase activity) of Cx43(Cre-ER(T)/fl) +4-OHT mice (16.1 ± 0.9%, n = 9) were lower than in Cx43(fl/fl) mice (19.8 ± 1.3%, n = 8, P < 0.05); complex II activities were similar between genotypes. Supporting the importance of Cx43 for respiration, in Cx43-overexpressing HL-1 cardiomyocytes complex I respiration was increased, whereas complex II respiration remained unaffected. Taken together, mitochondrial Cx43 is required for optimal complex I activity and respiration and thus mitochondrial ATP-production.

Connexin43 in cardiomyocyte mitochondria contributes to mitochondrial potassium uptake.

AIMS: Connexin43 is present at the inner membrane of cardiomyocyte mitochondria (mCx43), but its function remains unknown. METHODS AND RESULTS: In this study we verified the presence of mCx43 by a mass spectrometry-based proteomic approach in purified mitochondrial preparations from mouse myocardium and determined by western blot analysis that the C-terminus of mCx43 is oriented towards the intermembrane space. Cross-linking studies with dimethylsuberimidate indicated the presence of Cx43 hexamers in mitochondrial membranes. The contribution of Cx43 to both mitochondrial dye uptake and K(+) flux was assessed in wild-type mice using hemichannel blockers and Cx43KI32 mice in which Cx43 had been replaced by Cx32. Uptake of the Cx43 hemichannel-permeant dye Lucifer Yellow was reduced in mitochondria from wild-type mice by two hemichannel blockers (carbenoxolone and heptanol) and in Cx43KI32 compared with wild-type mice. Mitochondrial K(+) influx (PBFI fluorescence) was decreased in digitonin-permeabilized cardiomyocytes from Cx32 mutants compared with wild-type mice, and addition of the Cx43 hemichannel blocker 18alpha-glycyrrhetinic acid had an inhibitory effect on mitochondrial K(+) influx in wild-type cardiomyocytes, but not in cardiomyocytes from Cx32 mutants. CONCLUSION: These results indicate that mCx43 contributes to mitochondrial K(+) flux in cardiomyocytes, potentially by forming hemichannel-like structures.

Intracoronary acid infusion as an alternative to ischemic postconditioning in pigs.

Previous studies suggested that prolongation of acidosis during reperfusion is protective and may be an important mechanism of postconditioning protection. The aim of this study was to analyze the therapeutic value of this intervention during in vivo coronary reperfusion, and to compare it with ischemic postconditioning. Pigs were submitted to 48 or 60 min of ischemia and 2 h of reperfusion. Animals were allocated to either intracoronary infusion of Krebs solution at dose and duration previously described as optimal in rat hears (pH 6.4 for the first 3 min of reperfusion), ischemic postconditioning (8 cycles of 30 s ischemia/reperfusion) or their respective control groups (n = 9-11 per group). Neither prolongation of acidosis nor postconditioning modified infarct size after 48 min of ischemia as compared to pooled controls. In contrast, in animals submitted to 60 min of coronary occlusion, infarct size was reduced both by infusion of acid Krebs and ischemic postconditioning (57.92 +/- 18.15% and 56.91 +/- 7.50 vs. 75.37 +/- 9.29% in controls, P < 0.01), despite having similar areas at risk. However, an increased incidence of ventricular fibrillation was observed in pigs reperfused with acid Krebs as compared to ischemic postconditioning (11 out of 20 vs. 3 out of 19 pigs, P < 0.05). In conclusion, in pigs submitted to coronary occlusion, intracoronary acid infusion and postconditioning offered protection against cell death only after prolonged coronary occlusion. Both interventions were equally effective, but intracoronary acid infusion was associated with high risk of ventricular fibrillation. These results are strongly against translation of acidic reperfusion to patients with acute myocardial infarction.

Acidic reoxygenation protects against endothelial dysfunction in rat aortic rings submitted to simulated ischemia.

Ischemia-reperfusion causes endothelial dysfunction. Prolongation of acidosis during initial cardiac reperfusion limits infarct size in animal models, but the effects of acidic reperfusion on vascular function are unknown. The present work analyzes the effects of acidic reoxygenation on vascular responses to different agonists in rat aortic rings. Arterial rings obtained from Sprague-Dawley rat aorta were placed in organ baths containing a Krebs solution oxygenated at 37 degrees C (pH 7.4). After equilibration (30 mN, 1 h), the effects of acidosis (pH 6.4) on aortic responses to acetylcholine and norepinephrine were initially assessed under normoxic conditions. Thereafter, the effects of acidosis during hypoxia (1 h) or reoxygenation on aortic responses to acetylcholine, norepinephrine, or sodium nitroprusside were analyzed and compared with those observed in control rings. Acidosis did not modify aortic responses to acetylcholine or adrenaline during normoxia. In contrast, rings submitted to hypoxia and reoxygenated at pH 7.4 showed a reduction in vasodilator responses to acetylcholine and in contractions to norepinephrine with no change in responses to sodium nitroprusside. Reoxygenation at pH 6.4 did not modify the depressed response to norepinephrine but enhanced the recovery of acetylcholine-induced vasorelaxation. Cumulative concentration-response curves to acetylcholine showed an increased responsiveness to this drug in rings reoxygenated at a low pH. This functional improvement was associated with the preservation of aortic cGMP content after stimulation of reoxygenated rings with acetylcholine. In conclusion, acidic reoxygenation preserves endothelial function in arterial rings submitted to simulated ischemia, likely through the preservation of cGMP signaling.

Mitochondrial connexin43 as a new player in the pathophysiology of myocardial ischaemia-reperfusion injury.

Connexins are transmembrane proteins whose best known function is to form gap junction channels. Ventricular cardiomyocytes express the connexin isoform Cx43 and are rich in gap junctions essential for the normal propagation of the action potential. In addition to this physiological role, cardiomyocyte gap junctions contribute to the pathophysiology of ischaemia-reperfusion injury, mainly by synchronizing the onset of rigour contracture during ischaemia and cell-to-cell propagation of hypercontracture during reperfusion. More recently, it has been recognized that Cx43 plays a role in protection during ischaemic and pharmacological preconditioning and that this role is independent from gap junction-mediated communication. It was demonstrated that Cx43 is localized in cardiomyocyte mitochondria, at least in part in the inner mitochondrial membrane, where it is imported by the general mitochondrial membrane translocase system. Interfering with this import system or genetic ablation of Cx43 abolishes diazoxide-induced protection, indicating that mitochondrial Cx43 participates in the preconditioning cascade. The role of mitochondrial Cx43 in preconditioning appears to be related to reactive oxygen species signalling, but its molecular mechanisms have not been elucidated in detail. The present article reviews available evidence on the localization of Cx43 in cardiomyocyte mitochondria, its role in protection by preconditioning, and the potential molecular mechanisms involved. These data may help to understand the pathophysiology of myocardial ischaemia-reperfusion and ischaemic preconditioning and to identify new strategies for cardioprotection, and they may be particularly relevant to situations such as aging in which total and mitochondrial Cx43 contents have been shown to be reduced.

The modulatory effects of connexin 43 on cell death/survival beyond cell coupling.

Connexins form a diverse and ubiquitous family of integral membrane proteins. Characteristically, connexins are assembled into intercellular channels that aggregate into discrete cell-cell contact areas termed gap junctions (GJ), allowing intercellular chemical communication, and are essential for propagation of electrical impulses in excitable tissues, including, prominently, myocardium, where connexin 43 (Cx43) is the most important isoform. Previous studies have shown that GJ-mediated communication has an important role in the cellular response to stress or ischemia. However, recent evidence suggests that connexins, and in particular Cx43, may have additional effects that may be important in cell death and survival by mechanisms independent of cell to cell communication. Connexin hemichannels, located at the plasma membrane, may be important in paracrine signaling that could influence intracellular calcium and cell survival by releasing intracellular mediators as ATP, NAD(+), or glutamate. In addition, recent studies have shown the presence of connexins in cell structures other than the plasma membrane, including the cell nucleus, where it has been suggested that Cx43 influences cell growth and differentiation. In addition, translocation of Cx43 to mitochondria appears to be important for certain forms of cardioprotection. These findings open a new field of research of previously unsuspected roles of Cx43 intracellular signaling.

Prevention of the ischemia-induced decrease in mitochondrial Tom20 content by ischemic preconditioning.

Preserved mitochondrial function (respiration, calcium handling) and integrity (cytochrome c release) is central for cell survival following ischemia/reperfusion. Mitochondrial function also requires import of proteins from the cytosol via the translocase of the outer and inner membrane (TOM and TIM complexes). Since mitochondrial function following ischemia/reperfusion is better preserved by ischemic preconditioning (IP), we now investigated whether expression of parts of the import machinery is affected by ischemia/reperfusion without or with IP in vivo. We analyzed the mitochondrial content of the presequence receptor Tom20, the pore forming unit Tom40 and Tim23. Goettinger minipigs were subjected to 90 min of low-flow ischemia without or with preconditioning by 10 min ischemia and 15 min reperfusion. Mitochondria were isolated from the ischemic or preconditioned anterior wall of the left ventricle and from the control posterior wall. Infarct size was significantly reduced by IP (20.1 +/- 1.6% of area at risk (non-preconditioned) vs. 6.5 +/- 2.5% of area at risk (IP)). Using Western blot analysis, the ratio of Tom20 (normalized to Ponceau S) between mitochondria isolated from the anterior ischemic and posterior control wall was reduced (0.72 +/- 0.11, a.u., n = 8), whereas the mitochondrial Tom20 content was preserved by IP (1.17 +/- 0.16 a.u., n = 7, P < 0.05). The mitochondrial Tom40, Tim23 and adenine nucleotide transporter (ANT) contents were not significantly different between non-preconditioned and preconditioned myocardium. The preservation of the mitochondrial Tom20 protein level may contribute to the improved mitochondrial function after IP.

Translocation of connexin 43 to the inner mitochondrial membrane of cardiomyocytes through the heat shock protein 90-dependent TOM pathway and its importance for cardioprotection.

We have previously shown that connexin 43 (Cx43) is present in mitochondria, that its genetic depletion abolishes the protection of ischemia- and diazoxide-induced preconditioning, and that it is involved in reactive oxygen species (ROS) formation in response to diazoxide. Here we investigated the intramitochondrial localization of Cx43, the mechanism of Cx43 translocation to mitochondria and the effect of inhibiting translocation on the protection of preconditioning. Confocal microscopy of mitochondria devoid of the outer membrane and Western blotting on fractionated mitochondria showed that Cx43 is located at the inner mitochondrial membrane, and coimmunoprecipitation of Cx43 with Tom20 (Translocase of the outer membrane 20) and with heat shock protein 90 (Hsp90) indicated that it interacts with the regular mitochondrial protein import machinery. In isolated rat hearts, geldanamycin, a blocker of Hsp90-dependent translocation of proteins to the inner mitochondrial membrane through the TOM pathway, rapidly (15 minutes) reduced mitochondrial Cx43 content by approximately one-third in the absence or presence of diazoxide. Geldanamycin alone had no effect on infarct size, but it ablated the protection against infarction afforded by diazoxide. Geldanamycin abolished the 2-fold increase in mitochondrial Cx43 induced by 2 preconditioning cycles of ischemia/reperfusion, but this effect was not associated with reduced protection. These results demonstrate that Cx43 is transported to the inner mitochondrial membrane through translocation via the TOM complex and that a normal mitochondrial Cx43 content is important for the diazoxide-related pathway of preconditioning.

The end-effectors of preconditioning protection against myocardial cell death secondary to ischemia-reperfusion.

Our understanding of the end-effectors involved in preconditioning protection is still very limited. This is partially due to an incomplete knowledge of the mechanisms responsible for acute sarcolemmal rupture and cell death during the first minutes of reperfusion, including the relative roles of hypercontracture-mediated sarcolemmal rupture and mitochondrial permeability transition pore (MPTP) opening-mediated cell death. In the present article, the role of proposed end-effectors of preconditioning protection, defined as molecules directly involved in cell death that are modified by ischemic preconditioning (IP), is examined. IP attenuates hypercontracture-mediated cell death, probably through several mechanisms, including attenuated calpain activation during reperfusion leading to preserved cytoskeletal integrity and accelerated recovery of Na+/K+-ATPase function, but probably also protein kinase G (PKG)-mediated improved calcium handling. The potential role of gap junctions in preconditioning protection is controversial, but the recently discovered mitochondrial localisation of connexin43 seems to play an important role in protection that has not yet been completely defined. Several recent studies suggest that IP can reduce MPTP opening during reperfusion and limit infarct size through this mechanism, although the contribution of this widely accepted mechanism to the infarct size reduction induced by IP in the intact heart needs to be established.

Connexin 43 in cardiomyocyte mitochondria and its increase by ischemic preconditioning.

OBJECTIVE: Connexin 43 (Cx43) is involved in infarct size reduction by ischemic preconditioning (IP); the underlying mechanism of protection, however, is unknown. Since mitochondria have been proposed to be involved in IP's protection, the present study analyzed whether Cx43 is localized at mitochondria of cardiomyocytes and whether such localization is affected by IP. METHODS AND RESULTS: Western blot analysis on mitochondrial preparations isolated from rat, mouse, pig, and human hearts showed the presence of Cx43. The preparations were not contaminated with markers for other cell compartments. The localization of Cx43 to mitochondria was also confirmed by FACS sorting (double staining with MitoTracker Red and Cx43) and immuno-electron and confocal microscopy. To study the role of Cx43 in IP, mitochondria were isolated from the ischemic anterior wall (AW) and the control posterior wall (PW) of pig myocardium at the end of 90 min low-flow ischemia without (n=13) or with (n=13) a preceding preconditioning cycle of 10 min ischemia and 15 min reperfusion. With IP, the mitochondrial Cx43/adenine nucleotide transporter ratio was 3.4+/-0.7 fold greater in AW than in PW, whereas the ratio remained unchanged in non-preconditioned myocardium (1.1+/-0.2, p<0.05). The enhancement of the mitochondrial Cx43 protein level occurred rapidly, since an increase of mitochondrial Cx43 was already detected with two cycles of 5 min ischemia/reperfusion in isolated rat hearts to 262+/-63% of baseline. CONCLUSION: These data demonstrate that Cx43 is localized at cardiomyocyte mitochondria and that IP enhances such mitochondrial localization.