Summary
The role of phospholipase (PLase) in the development of heart mitochondrial dysfunction following reperfusion was studied together with the effects of dilazep on the action of PLases and reperfusion injury.
In vivo experiment: Seventy six adult mongrel dogs were divided into 3 groups; the control group (n=36), the dilazep 0.5 mg group (n=17) and the dilazep 1 mg group (n=23). Fifteen min after premedication with physiological saline or dilazep (0.5 mg/kg or 1 mg/kg), the left anterior descending coronary artery was occluded for 15 min and then reperfused for 5 min. Each group was further divided into two subgroups depending on the presence or absence of reperfusion arrhythmia. Immediately after 5 min of reperfusion, myocardial mitochondria were prepared from the normal and the reperfused areas. Pretreatment with dilazep induced a dose-dependent decrease in the incidence of reperfusion arrhythmia from 31% of the control to 24% (0.5 mg/kg) and 9% (1 mg/kg). In the arrhythmia cases in each group, functional deterioration of mitochondria from the reperfused area was observed with the increase in free fatty acids and the decrease in phospholipids in the reperfused mitochondria.
In vitro experiment: Using L-α-dimyristoyl phosphatidylcholine as a substrate, myristic acid released by PLase A2 or by PLase C with or without pretreatment by dilazep was quantitatively determined. Dilazep inhibited the release of myristic acid by PLase A2 or by PLase C in a concentration-dependent manner.
These results suggest that decomposition of mitochondrial membrane phospholipids caused by PLase activation following reperfusion was primarily responsible for the development of mitochondrial dysfunction, and that dilazep showed beneficial effects against reperfusion injury by inhibiting the action of PLases.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Allen RJL (1940) The estimation of phosphorus. Biochem J 34B:858–865
Barker SA, Monti JA, Christian ST, Benington F, Morin RD (1980) 9-Diazomethylanthracene as a new fluorescence and ultraviolet label for the spectrometric detection of picomole quantities of fatty acids by high-pressure liquid chromatography. Anal Biochem 107:116–123
Bresnahan GF, Roberts R, Shell WE, Ross J Jr, Sobel BE (1974) Deleterious effects due to hemorrhage after myocardial reperfusion. Am J Cardiol 33:82–86
Chien KR, Pfau RG, Farber JL (1979) Ischemic myocardial cell injury. Prevention by chlorpromazine of an accelerated phospholipid degradation and associated membrane dysfunction. Am J Pathol 97:505–530
Chien KR, Reeves JP, Buja LM, Bonte F, Parkey RW, Willerson JT (1981) Phospholipid alterations in canine ischemic myocardium. Temporal and topographical correlations with Tc-99m-PPi accumulation and an in vitro sarcolemmal Ca2+ permeability defect. Circ Res 48:711–719
Folch J, Lees M, Sloane Stanley GH (1957) A simple method for the isolation and purification of total lipides from animal tissues. J Biol Chem 226:497–509
Gornall AG, Bardawill CJ, David MM (1949) Determination of the serum proteins by means of biuret reaction. J Biol Chem 177:751–766
Hatefi Y, Jurtshuk P, Haavik AG (1961) Studies on the electron transport system. XXXII. Respiratory control in beef heart mitochondria. Arch Biochem Biophys 94:148–155
Hattori M, Miyazaki Y, Nagai S, Sugiyama S, Ozawa T (1984) The effect of dilazep on mitochondrial function — as a phospholipase inhibitor. Eur Heart J 5 (Abstr Supple 1):61
Hearse DJ (1977) Reperfusion of the ischemic myocardium. J Mol Cell Cardiol 9:605–616
Higgins TJC, Bailey PJ, Allsopp D (1981) The influence of ATP depletion on the action of phospholipase C on cardiac myocyte membrane phospholipids. J Mol Cell Cardiol 13:1027–1030
Hirsh PD, Hillis LD, Campbell WB, Firth BG, Willerson JT (1981) Release of prostaglandins and thromboxane into the coronary circulation in patients with ischemic heart disease. N Engl J Med 304:685–691
Hong SL, Deykin D (1982) Activation of phospholipases A2 and C in pig aortic endothelial cells synthesizing prostacyclin. J Biol Chem 257:7151–7154
Hostetler KY, Matsuzawa Y (1981) Studies on the mechanism of drug-induced lipidosis. Cationic amphiphilic drug inhibition of lysosomal phospholipases A and C. Biochem Pharmacol 30:1121–1126
Kane JJ, Murphy ML, Bissett JK, de Soyza N, Doherty JE, Straub KD (1975) Mitochondrial function, oxygen extraction, epicardial S-T segment changes and tritiated digoxin distribution after reperfusion of ischemic myocardium. Am J Cardiol 36:218–224
Katz AM, Messineo FC (1981) Lipid-membrane interactions and the pathogenesis of ischemic damage in the myocardium. Circ Res 48:1–16
Kurioka S, Matsuda M (1976) Phospholipase C assay usingp-nitrophenylphosphorylcholine together with sorbitol and its application to studying the metal and detergent requirement of the enzyme. Anal Biochem 75:281–289
Lang TW, Corday E, Gold H, Meerbaum S, Rubins S, Costantini C, Hirose S, Osher J, Rosen V (1974) Consequences of reperfusion after coronary occlusion. Effects on hemodynamic and regional myocardial metabolic function. Am J Cardiol 33:69–81
Lucy JA (1975) The fusion of cell membranes. In: Weissmann G, Claiborne R (eds) Cell membranes. HP Publishing, New York, 75–83
Michell RH (1975) Inositol phospholipids and cell surface receptor function. Biochim Biophys Acta 415:81–147
Oliva PB, Breckinridge JC (1977) Arteriographic evidence of coronary arterial spasm in acute myocardial infarction. Circulation 56:366–374
Philipson KD, Bers DM, Nishimoto AY (1980) The role of phospholipids in the Ca2+ binding of isolated cardiac sarcolemma. J Mol Cell Cardiol 12:1159–1173
Samuelsson B, Goldyne M, Granström E, Hamberg M, Hammarström S, Malmsten C (1978) Prostaglandins and thromboxanes. Ann Rev Biochem 47:997–1029
Samuelsson B, Hammarström S (1982) Leukotrienes: a novel group of biologically active compounds. Vitam Horm 39:1–30
Sano N, Katsuki S, Kawada M (1972) Enhancement of coronary vasodilator action of adenosine by 1,4-bis-[3-(3,4,5-trimethoxybenzoyl-oxy)-propyl]-perhydro-1,4-diazepine (Dilazep I.N.N.). Arzneim Forsch 22:1655–1658
Shaikh NA, Downar E (1981) Time course of changes in porcine myocardial phospholipid levels during ischemia. A reassessment of the lysolipid hypothesis. Circ Res 49:316–325
Shimomura Y, Taniguchi K, Sugie T, Murakami M, Sugiyama S, Ozawa T (1984) Analysis of the fatty acid composition of human serum lipids by high performance liquid chromatography. Clin Chim Acta 143:361–366
Sobel BE, Corr PB, Robison AK, Goldstein RA, Witkowski FX, Klein MS (1978) Accumulation of lysophosphoglycerides with arrhythmogenic properties in ischemic myocardium. J Clin Invest 62:546–553
Sugiyama S, Ozawa T, Kato T, Suzuki S (1980) Recovery time course of ventricular vulnerability after coronary reperfusion in relation to mitochondrial function in ischemic myocardium. Am Heart J 100:829–837
Sugiyama S, Miyazaki Y, Kotaka K, Ozawa T (1983) The effects of verapamil on mitochondrial dysfunction associated with coronary reperfusion. Jpn Circ J 47:830–836
Tada M, Kuzuya T, Inoue M, Kodama K, Mishima M, Yamada M, Inui M, Abe H (1981) Elevation of thromboxane B2 levels in patients with classic and variant angina pectoris. Circulation 64:1107–1115
Tyson CA, Zande HV, Green DE (1976) Phospholipids as ionophores. J Biol Chem 251:1326–1332
Van Handel E (1961) Suggested modifications of the micro determination of triglycerides. Clin Chem 7:249–251
Wenzel DG, Innis JD (1983) Arrhythmogenic and antiarrhythmic effects of lipolytic factors on cultured heart cells. Res Comm Chem Pathol Pharmacol 41:383–396
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hattori, M., Ogawa, K., Satake, T. et al. Depletion of membrane phospholipid and mitochondrial dysfunction associated with coronary reperfusion. Basic Res Cardiol 80, 241–250 (1985). https://doi.org/10.1007/BF01907900
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF01907900