Inducible nitric oxide synthase expression and cardiomyocyte dysfunction during sustained moderate ischemia in pigs.

In acute myocardial ischemia, regional blood flow and function are proportionally reduced. With prolongation of ischemia, function further declines at unchanged blood flow. We studied the involvement of an inflammatory signal cascade in such progressive dysfunction and whether dysfunction is intrinsic to cardiomyocytes. In 10 pigs, ischemia was induced by adjusting inflow into the cannulated left anterior coronary artery to reduce coronary arterial pressure to 45 mm Hg (ISCH); 4 pigs received the inducible nitric oxide synthase (iNOS) inhibitors aminoguanidine or L-N(6)-(1-iminoethyl)-lysine during ISCH (ISCH+iNOS-Inhib); 6 pigs served as controls (SHAM). Anterior (AW) and posterior (PW) systolic wall thickening (sonomicrometry) were measured. After 6 hours, nitric oxide (NO) synthase (NOS) protein expression, NOS activity, and NO metabolites (nitrite/nitrate/nitroso species) were quantified in biopsies isolated from AW and PW. Cardiomyocyte shortening and intracellular calcium (Indo-1 acetoxymethyl ester) were measured without and with the NOS substrate L-arginine (100 micromol/L). In ISCH, AW wall thickening decreased from 42+/-4% (baseline) to 16+/-3% (6 hours). Wall thickening remained unchanged in ISCH-PW and SHAM-AW/PW. NOS2 (iNOS) protein expression and activity, but not NOS3 (endothelial NO synthase), were increased in ISCH-AW and ISCH-PW. iNOS expression correlated with increased nitrite contents. Cardiomyocyte shortening was reduced in ISCH-AW versus SHAM-AW (4.4+/-0.3% versus 5.6+/-0.3%). L-Arginine reduced cardiomyocyte shortening further in ISCH-AW (to 2.8+/-0.2%) and ISCH-PW (3.4+/-0.4% versus 5.4+/-0.4%) but not in SHAM or in ISCH+iNOS-Inhib; intracellular [Ca(2+)] remained unchanged. With L-arginine, in vitro AW cardiomyocyte shortening correlated with in vivo AW wall thickening (r=0.72). In conclusion, sustained regional ischemia induces myocardial iNOS expression in pigs, which contributes to contractile dysfunction at the cardiomyocyte level.

Glucocorticoid treatment prevents progressive myocardial dysfunction resulting from experimental coronary microembolization.

BACKGROUND: The frequency and importance of microembolization in patients with acute coronary syndromes and during coronary interventions have recently been appreciated. Experimental microembolization induces immediate ischemic dysfunction, which recovers within minutes. Subsequently, progressive contractile dysfunction develops over several hours and is not associated with reduced regional myocardial blood flow (perfusion-contraction mismatch) but rather with a local inflammatory reaction. We have now studied the effect of antiinflammatory glucocorticoid treatment on this progressive contractile dysfunction. METHODS AND RESULTS: Microembolization was induced by injecting microspheres (42-microm diameter) into the left circumflex coronary artery. Anesthetized dogs were followed up for 8 hours and received placebo (n=7) or methylprednisolone 30 mg/kg IV either 30 minutes before (n=7) or 30 minutes after (n=5) microembolization. In addition, chronically instrumented dogs received either placebo (n=4) or methylprednisolone (n=4) 30 minutes after microembolization and were followed up for 1 week. In acute placebo dogs, posterior systolic wall thickening was decreased from 20.0+/-2.1% (mean+/-SEM) at baseline to 5.8+/-0.6% at 8 hours after microembolization. Methylprednisolone prevented the progressive myocardial dysfunction. Increased leukocyte infiltration in the embolized myocardium was prevented only when methylprednisolone was given before microembolization. In chronic placebo dogs, progressive dysfunction recovered from 5.0+/-0.7% at 4 to 6 hours after microembolization back to baseline (19.1+/-1.6%) within 5 days. Again, methylprednisolone prevented the progressive myocardial dysfunction. CONCLUSIONS: Methylprednisolone, even when given after microembolization, prevents progressive contractile dysfunction.

Serum but not myocardial TNF-alpha concentration is increased in pacing-induced heart failure in rabbits.

In animals and patients with severe heart failure (HF), the serum tumor necrosis factor-alpha (TNF-alpha) concentration is increased. It is, however, still controversial whether or not such increased serum TNF-alpha originates from the heart itself or is of peripheral origin secondary to gastrointestinal congestion and increased endotoxin concentration. We therefore now examined TNF-alpha in serum, myocardium, and liver of sham-operated and HF rabbits. In nine rabbits in which HF was induced by left ventricular (LV) pacing at 400 beats/min for 3 wk, LV end-diastolic diameter was increased and systolic shortening fraction (9.4 +/- 1.0 vs. 28.5 +/- 1.3%, echocardiography, P < 0.05) was reduced. Serum TNF-alpha was higher in HF than in sham-operated rabbits (240 +/- 24 vs. 150 +/- 22 U/ml, WEHI-cell assay, P < 0.05). In the heart, TNF-alpha was located mainly in the vascular endothelium (immunohistochemistry), and TNF-alpha protein (920 +/- 160 vs. 900 +/- 95 U/g) did not differ between groups. In the liver of HF rabbits, hepatocytes expressed TNF-alpha, and TNF-alpha protein was increased compared with sham-operated rabbits (2,390 +/- 310 vs. 1,220 +/- 135 U/g, P < 0.05) and correlated to the number of hepatic leukocytes (r = 0.85) and serum TNF-alpha (r = 0.69). The intestinal endotoxin concentration was 24.5 +/- 1.2 vs. 17.0 +/- 3.1 endotoxin units/g wet wt (P < 0.05) in HF compared with sham-operated rabbits. In this HF model, serum but not myocardial TNF-alpha is increased. The increased serum TNF-alpha originates from peripheral sources.

Ischemic preconditioning preserves connexin 43 phosphorylation during sustained ischemia in pig hearts in vivo.

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.

TNF-alpha antibodies are as effective as ischemic preconditioning in reducing infarct size in rabbits.

Pretreatment with tumor necrosis factor-alpha (TNF-alpha) antibodies abolishes myocardial infarct size reduction by late ischemic preconditioning (IP). Whether or not TNF-alpha 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-alpha 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-alpha 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-alpha concentration during ischemia and infarct size correlated in all groups (r = 0.76). IP, TNF-alpha antibodies, and the combined approach reduced infarct size to a comparable extent. Therefore, the question of whether or not TNF-alpha is causally involved in the infarct size reduction by IP in rabbits could not be answered.

Plasma nitrosothiols contribute to the systemic vasodilator effects of intravenously applied NO: experimental and clinical Study on the fate of NO in human blood.

Higher doses of inhaled NO exert effects beyond the pulmonary circulation. How such extrapulmonary effects can be reconciled with the presumed short half-life of NO in the blood is unclear. Whereas erythrocytes have been suggested to participate in NO transport, the exact role of plasma in NO delivery in humans is not clear. Therefore, we investigated potential routes of NO decomposition and transport in human plasma. NO consumption in plasma was accompanied by a concentration-dependent increase in nitrite and S-nitrosothiols (RSNOs), with no apparent saturation limit up to 200 micro mol/L. The presence of red blood cells reduced the formation of plasma RSNOs. Intravenous infusion of 30 micro mol/min NO in healthy volunteers increased plasma levels of RSNOs and induced systemic hemodynamic effects at the level of both conduit and resistance vessels, as reflected by dilator responses in the brachial artery and forearm microvasculature. Intravenous application of S-nitrosoglutathione, a potential carrier of bioactive NO, mimicked the vascular effects of NO, whereas nitrite and nitrate were inactive. Changes in plasma nitrosothiols were correlated with vasodilator effects after intravenous application of S-nitrosoglutathione and NO. These findings demonstrate that in humans the pharmacological delivery of NO solutions results in the transport and delivery of NO as RSNOs along the vascular tree.

No ischemic preconditioning in heterozygous connexin43-deficient mice.

Protein kinase Cepsilon (PKCepsilon) plays a central role in ischemic preconditioning (IP) in mice and rabbits, and activated PKCepsilon colocalizes with and phosphorylates connexin43 (Cx43) in rats and humans. Whether or not Cx43 contributes to the mechanism(s) of IP in vivo is yet unknown. Therefore, wild-type (n = 8) and heterozygous Cx43-deficient mice (n = 8) were subjected to 30 min occlusion and 120 min reperfusion of the left anterior descending coronary artery. IP was induced by one cycle of 5 min occlusion and 10 min reperfusion (n = 8/8 mice) before the sustained occlusion. Infarct size was reduced by IP in wild-type mice [11.3 +/- 3.4% vs. 23.7 +/- 7.2% of the left ventricle (LV), P < 0.05] but not in Cx43-deficient mice (26.0 +/- 6.0% vs. 25.1 +/- 3.8% of LV). Also, three cycles of 5 min occlusion and 10 min reperfusion (n = 5) did not induce protection in Cx43-deficient mice (27.6 +/- 5.5 % of LV). Thus Cx43 contributes to the protection of IP in mice in vivo.