During myocardial ischemia, connexin 43 (Cx43) is dephosphorylated in vitro, and the subsequent opening of gap junctions formed by two opposing Cx43 hexamers was suggested to propagate ischemia/reperfusion injury. Reduction of infarct size (IS) by ischemic preconditioning (IP) involves activation of protein kinase C (PKC) and p38 mitogen activated protein kinase (MAPK), both of which can phosphorylate Cx43. We now studied in anesthetized pigs whether IP impacts on Cx43 phosphorylation by measuring the density of non-phosphorylated and total Cx43 (confocal laser) during normoperfusion and 90-min ischemia in non-preconditioned and preconditioned hearts. Co-localization of PKCalpha, p38MAPKalpha, and p38MAPKbeta with Cx43 and the activity of p38MAPK were assessed. IP by 10 min ischemia and 15 min reperfusion reduced IS. Non-phosphorylated Cx43 remained unchanged during ischemia in preconditioned hearts, while it increased from 35+/-3 to 75+/-8 AU (P<0.05) in non-preconditioned hearts. Co-localization of PKCalpha, p38MAPKalpha, and p38MAPKbeta with Cx43 during ischemia increased only in preconditioned hearts. While the ischemia-induced increase in p38MAPKalpha activity was comparable in preconditioned and non-preconditioned hearts, p38MAPKbeta activity was increased only in preconditioned hearts. Blockade of p38MAPK by SB203580 attenuated the IS-reduction and the increased p38MAPK-Cx43 co-localization by IP. We conclude that IP increases co-localization of protein kinases with Cx43 and preserves phosphorylation of Cx43 during ischemia.
The importance of the activation of mitogen-activated protein kinases (MAPK) for the cardioprotection achieved by ischemic preconditioning (IP) is still controversial. We therefore measured infarct size and p38, extracellular signal-regulated kinase (ERK), and c-Jun NH(2)-terminal kinase (JNK) MAPK phosphorylation (by biopsies) in enflurane-anesthetized pigs. After 90 min low-flow ischemia and 120 min reperfusion, infarct size averaged 18.3 +/- 12.4 (SD)% (group 1, n = 14). At similar subendocardial blood flows, IP by 10 min ischemia and 15 min reperfusion (group 2, n = 14) reduced infarct size to 6.2 +/- 5.1% (P < 0.05). An inconsistent increase in p38, ERK, and p54 JNK phosphorylation (by Western blot) was found during IP; p46 JNK phosphorylation increased with the subsequent reperfusion. At 8 min of the sustained ischemia, p38, ERK, and p54 JNK phosphorylation were increased with no difference between groups (medians: p38: 207% of baseline in group 1 vs. 153% in group 2; ERK: 142 vs. 144%; p54 JNK: 171 vs. 155%, respectively). MAPK phosphorylation and reduction of infarct size by IP were not correlated, thus not supporting the concept of a causal role of MAPK in mediating cardioprotection by IP.
Ischemic preconditioning (IP) and prior exposure to lipopolysaccharides (LPS) reduce infarct size (IS) and serum tumor necrosis factor-alpha (TNF-alpha) concentration resulting from myocardial ischemia-reperfusion in rabbits. The decrease in TNF-alpha might relate to an induced TNF-alpha inhibitory serum activity (TNF-alpha-ISA). We analyzed TNF-alpha and TNF-alpha-ISA during 30 and 180 min ischemia and reperfusion, respectively, in anesthetized rabbits either untreated (group 1, n = 7), preconditioned (5 and 10 min ischemia and reperfusion, respectively, group 2, n = 9), or exposed to LPS 72 h before ischemia (group 3, n = 9). TNF-alpha-ISA was assessed by coincubating LPS-stimulated rabbit blood with serum of groups 1-3 and measuring TNF-alpha (WEHI assay). With a comparable area at risk, IS in group 1 was 36.9 +/- 11.1 (SD)%, and it was reduced to 13.1 +/- 11.6% and 17.3 +/- 11.3% (both P < 0.05) in groups 2 and 3, respectively. TNF-alpha was increased during ischemia-reperfusion in group 1 but remained unchanged in rabbits subjected to IP or LPS. TNF-alpha-ISA was detected during ischemia-reperfusion in group 2 (29% and 38% of maximum inhibition, respectively) and during baseline, ischemia and reperfusion in group 3 (51%, 46%, 48% of maximum inhibition, respectively) but was absent in group 1. Cardioprotection by IP and LPS is associated with a reduced TNF-alpha and an induced TNF-alpha-ISA during ischemia-reperfusion.
Abstract-Coronary microembolization results in progressive myocardial dysfunction, with causal involvement of tumor necrosis factor-␣ (TNF-␣). TNF-␣ uses a signal transduction involving nitric oxide (NO) and/or sphingosine. Therefore, we induced coronary microembolization in anesthetized dogs and studied the role and sequence of NO, TNF-␣, and sphingosine for the evolving contractile dysfunction. Four sham-operated dogs served as controls (group 1). Eleven dogs received placebo (group 2), 6 dogs received the NO synthase inhibitor N G -nitro-L-arginine methyl ester (L-NAME, group 3), and 6 dogs received the ceramidase inhibitor N-oleoylethanolamine (NOE, group 4) before microembolization was induced by infusion of 3000 microspheres (42-m diameter) per milliliter inflow into the left circumflex coronary artery. Posterior systolic wall thickening (PWT) remained unchanged in group 1 but decreased progressively in group 2 from 20.6Ϯ4.9% (meanϮSD) at baseline to 4.1Ϯ3.7% at 8 hours after microembolization. Leukocyte count, TNF-␣, and sphingosine contents were increased in the microembolized posterior myocardium. In group 3, PWT remained unchanged (20.3Ϯ2.6% at baseline) with intracoronary administration of L-NAME (20.8Ϯ3.4%) and 17.7Ϯ2.3% at 8 hours after microembolization; TNF-␣ and sphingosine contents were not increased. In group 4, PWT also remained unchanged (20.7Ϯ4.6% at baseline) with intravenous administration of NOE (19.5Ϯ5.7%) and 16.4Ϯ6.3% at 8 hours after microembolization; TNF-␣, but not sphingosine content, was increased. In all groups, systemic hemodynamics, anterior systolic wall thickening, and regional myocardial blood flow remained unchanged throughout the protocols. A signal transduction cascade of NO, TNF-␣, and sphingosine is causally involved in the coronary microembolizationinduced progressive contractile dysfunction.
In hearts with chronic left ventricular (LV) systolic dysfunction secondary to hypertension or myocardial infarction, MAPK phosphorylation and/or activity are increased. Whether other settings of LV dysfunction not associated with ischemia-reperfusion are also characterized by increased MAPK phosphorylation or activity is unknown. After 3 wk of rapid LV pacing (400 beats/min), eight rabbits displayed clinical signs of heart failure (HF), and echocardiography revealed an increase in LV end-diastolic diameter from 15.6 +/- 0.7 (means +/- SE) to 18.8 +/- 0.7 mm and a reduced shortening fraction from 31 +/- 1to10 +/- 2% (both P < 0.05). Morphological alterations in HF included increased numbers of terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling (TUNEL)-positive cardiomyocytes, extent of fibrosis, and cross-sectional cardiomyocyte area. Total p38 MAPK did not differ between failing and normal hearts (n = 8). However, p38 MAPK phosphorylation [164,488 +/- 29,323 vs. 43,565 +/- 14,817 arbitrary units (AU), P < 0.05, densitometry] and the activities of p38 MAPK-alpha and -beta were increased in failing compared with normal hearts (149,441 +/- 38,381 and 170,430 +/- 32,952 vs. 68,815 +/- 28,984 and 81,788 +/- 22,774 AU, respectively, both P < 0.05). In failing compared with normal hearts, total and phosphorylated JNK46 and JNK54 MAPK were increased, whereas total and phosphorylated ERK MAPK remained unchanged. In pacing-induced HF, p38 and JNK MAPK phosphorylation as well as p38 MAPK activity was increased. Further studies will have to define whether or not chronic specific blockade of MAPK activity can interfere with apoptosis/fibrosis and thereby attenuate the progression of HF.
Pretreatment with tumor necrosis factor-α (TNF-α) antibodies abolishes myocardial infarct size reduction by late ischemic preconditioning (IP). Whether or not TNF-α is also important for myocardial infarct size reduction by classic IP is unknown. Anesthetized rabbits were untreated ( group 1, n = 7), classically preconditioned by 5 min left coronary artery occlusion/10 min reperfusion ( group 2, n = 6), or pretreated with TNF-α antibodies without ( group 3, n = 6) or with IP ( group 4, n = 6) before undergoing 30 min of occlusion and 180 min of reperfusion. Infarct size in group 1 was 44 ± 11 (means ± SD)% of the area at risk. With a comparable area at risk, infarct size was reduced to 13 ± 7%, 23 ± 8%, and 19 ± 12% (all P < 0.05) in groups 2, 3, and 4, respectively. The circulating TNF-α concentration was increased during ischemia in group 1 from 752 ± 403 to 1,542 ± 482 U/ml ( P < 0.05) but remained unchanged in all other groups. Circulating TNF-α concentration during ischemia and infarct size correlated in all groups ( r = 0.76). IP, TNF-α antibodies, and the combined approach reduced infarct size to a comparable extent. Therefore, the question of whether or not TNF-α is causally involved in the infarct size reduction by IP in rabbits could not be answered.
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