ATP‐sensitive K+ channels and cellular K+ loss in hypoxic and ischaemic mammalian ventricle.

1. The contribution of ATP‐sensitive K+ (K+ATP) channels to the rapid increase in cellular K+ efflux and shortening of action potential duration (APD) during early myocardial ischaemia and hypoxia remains controversial, because for the first 10 min of ischaemia or hypoxia in intact hearts cytosolic [ATP] remains about two orders of magnitude greater than the [ATP] causing half‐maximal blockade of K+ATP channels in excised membrane patches. The purpose of this study was to investigate this apparent discrepancy. 2. During substrate‐free hypoxia, total, diastolic and systolic unidirectional K+ efflux rates increased by 43, 26 and 103% respectively after 8.3 min in isolated arterially perfused rabbit interventricular septa loaded with 42K+. APD shortened by 39%. From the Goldman‐Hodgkin‐Katz equation, the relative increases in systolic and diastolic K+ efflux rates were consistent with activation of a voltage‐independent K+ conductance. 3. During total global ischaemia, [K+]o measured with intramyocardial valinomycin K(+)‐sensitive electrodes increased at a maximal rate of 0.68 mM min‐1, which could be explained by a less than 26% increase in unidirectional K+ efflux rate (assuming no change in K+ influx), less than the increase during hypoxia. APD shortened by 23% over 10 min. 4. During hypoxia and ischaemia, cytosolic [ATP] decreased by about one‐third from 6.8 +/‐ 0.5 to 4.3 +/‐ 0.3 and 4.6 +/‐ 0.4 mM respectively, and free cytosolic [ADP] increased from 15 to 95 and approximately 63 microM respectively. 5. To estimate the percentage of activation of current through K+ATP channels (IK,ATP) necessary to double the systolic K+ efflux rate (comparable to the increase during hypoxia), K+ efflux during a single simulated action potential was measured by blocking non‐K+ currents under control conditions and after IK,ATP was fully activated by metabolic inhibitors. Activation of 0.41 +/‐ 0.07% of maximal IK,ATP was sufficient to double the systolic K+ efflux rate. The equivalent amount of constant hyperpolarizing current also shortened the APD in the isolated myocytes by 41 +/‐ 5%, compared to the 39% APD shortening observed during hypoxia in the intact heart. 6. The degree of activation of IK,ATP expected to occur during hypoxia and ischaemia was estimated by characterizing the ATP sensitivity of K+ATP channels in the presence of 2 mM‐free Mgi2+ and 0, 10, 100 and 300 microM‐ADPi in inside‐out membrane patches excised from guinea‐pig ventricular myocytes.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  D. Hearse Oxygen deprivation and early myocardial contractile failure: a reassessment of the possible role of adenosine triphosphate. , 1979, The American journal of cardiology.

[2]  A. Wilde,et al.  The Combined Effects of Hypoxia, High K+, and Acidosis on the Intracellular Sodium Activity and Resting Potential in Guinea Pig Papillary Muscle , 1986, Circulation research.

[3]  F. Ashcroft Adenosine 5'-triphosphate-sensitive potassium channels. , 1988, Annual review of neuroscience.

[4]  A. Noma,et al.  ATP-regulated K+ channels in cardiac muscle , 1983, Nature.

[5]  M. Janse,et al.  Electrophysiological mechanisms of ventricular arrhythmias resulting from myocardial ischemia and infarction. , 1989, Physiological reviews.

[6]  K I Shine,et al.  [K+]o accumulation and electrophysiological alterations during early myocardial ischemia. , 1982, The American journal of physiology.

[7]  J. Weiss,et al.  Functional compartmentation of glycolytic versus oxidative metabolism in isolated rabbit heart. , 1985, The Journal of clinical investigation.

[8]  G. Langer,et al.  Potassium exchange and mechanical performance in anoxic mammalian myocardium. , 1977, The American journal of physiology.

[9]  W. Lederer,et al.  Nucleotide modulation of the activity of rat heart ATP‐sensitive K+ channels in isolated membrane patches. , 1989, The Journal of physiology.

[10]  H. Lux,et al.  Kinetics and selectivity of a low‐voltage‐activated calcium current in chick and rat sensory neurones. , 1987, The Journal of physiology.

[11]  M. Rovetto,et al.  Comparison of the Effects of Anoxia and Whole Heart Ischemia on Carbohydrate Utilization in Isolated Working Rat Hearts , 1973, Circulation research.

[12]  J. Faivre,et al.  Effects of tolbutamide, glibenclamide and diazoxide upon action potentials recorded from rat ventricular muscle. , 1989, Biochimica et biophysica acta.

[13]  C. Moon,et al.  Continuous determination of extracellular space and changes of K+, Na+, Ca2+, and H+ during global ischaemia in isolated rat hearts. , 1990, Journal of molecular and cellular cardiology.

[14]  H A Krebs,et al.  Cytosolic phosphorylation potential. , 1979, The Journal of biological chemistry.

[15]  R. Case,et al.  Phosphate loss during reversible myocardial ischemia. , 1973, Journal of molecular and cellular cardiology.

[16]  J. Weiss,et al.  Enhanced utilization of exogenous glucose improves cardiac function in hypoxic rabbit ventricle without increasing total glycolytic flux. , 1990, The Journal of clinical investigation.

[17]  M. Morad,et al.  A uniform enzymatic method for dissociation of myocytes from hearts and stomachs of vertebrates. , 1985, The American journal of physiology.

[18]  J. Faivre,et al.  ATP‐sensitive K channels in heart muscle Spare channels , 1991, FEBS letters.

[19]  D. Kim,et al.  Regulation of K+ channels in cardiac myocytes by free fatty acids. , 1990, Circulation research.

[20]  L. Opie,et al.  Reduction of ischemic K+ loss and arrhythmias in rat hearts. Effect of glibenclamide, a sulfonylurea. , 1990, Circulation research.

[21]  J. Weiss,et al.  Sulfonylureas, ATP-sensitive K+ channels, and cellular K+ loss during hypoxia, ischemia, and metabolic inhibition in mammalian ventricle. , 1991, Circulation research.

[22]  A. Noma,et al.  Voltage‐dependent magnesium block of adenosine‐triphosphate‐sensitive potassium channel in guinea‐pig ventricular cells. , 1987, The Journal of physiology.

[23]  W. Lederer,et al.  ATP-sensitive potassium channel modulation of the guinea pig ventricular action potential and contraction. , 1991, Circulation research.

[24]  E. Marbán,et al.  23Na-NMR measurements of intracellular sodium in intact perfused ferret hearts during ischemia and reperfusion. , 1990, The American journal of physiology.

[25]  M. Sanguinetti,et al.  BRL 34915 (cromakalim) activates ATP-sensitive K+ current in cardiac muscle. , 1988, Proceedings of the National Academy of Sciences of the United States of America.

[26]  D. Clapham,et al.  Potassium channels in cardiac cells activated by arachidonic acid and phospholipids. , 1989, Science.

[27]  Bert Sakmann,et al.  Geometric parameters of pipettes and membrane patches , 1983 .

[28]  M. Boutjdir,et al.  Effects of glyburide on ischemia-induced changes in extracellular potassium and local myocardial activation: a potential new approach to the management of ischemia-induced malignant ventricular arrhythmias. , 1990, American heart journal.

[29]  A. Brown,et al.  Coupling of ATP-sensitive K+ channels to A1 receptors by G proteins in rat ventricular myocytes. , 1990, The American journal of physiology.

[30]  D. Allen,et al.  A nuclear magnetic resonance study of metabolism in the ferret heart during hypoxia and inhibition of glycolysis. , 1985, The Journal of physiology.

[31]  H. Irisawa,et al.  Intracellular Na+ activates a K+ channel in mammalian cardiac cells , 1984, Nature.

[32]  W. Lederer,et al.  The regulation of ATP‐sensitive K+ channel activity in intact and permeabilized rat ventricular myocytes. , 1990, The Journal of physiology.

[33]  Cellular K+ loss and anion efflux during myocardial ischemia and metabolic inhibition. , 1989, The American journal of physiology.

[34]  J. Keizer,et al.  ATP-sensitive potassium channel and bursting in the pancreatic beta cell. A theoretical study. , 1989, Biophysical journal.

[35]  R. Vaughan-Jones,et al.  Mechanism of potassium efflux and action potential shortening during ischaemia in isolated mammalian cardiac muscle. , 1990, The Journal of physiology.

[36]  A. Noma,et al.  Membrane current through adenosine‐triphosphate‐regulated potassium channels in guinea‐pig ventricular cells. , 1985, The Journal of physiology.

[37]  A. Kleber Extracellular potassium accumulation in acute myocardial ischemia. , 1984, Journal of molecular and cellular cardiology.