Role of slowed Ca(2+) transient decline in slowed relaxation during myocardial ischemia.

The goal of this study was to test the hypothesis that during myocardial ischemia, slowing of the Ca(2+) transient decline causes slowed relaxation. Our approach was to monitor pressure and Ca(2+) transients in isovolumic rat hearts during control and low flow ischemia conditions. In addition, we experimentally slowed the decline of the Ca(2+) transient using cyclopiazonic acid (CPA) to inhibit the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA, the most important pump for rapidly transporting Ca(2+) out of the cytosol). Using 9 microm CPA during normoxia, we were able to reproduce the slowed Ca(2+) transient decline and slowed relaxation found during low flow ischemia. The time constants of cytosolic [Ca(2+)] decline and pressure decline (tau(Ca) and tau(P) respectively) with CPA (78+/-5 ms and 64+/-3 ms) were similar to those found with ischemia (89+/-12 ms and 72+/-10 ms, mean+/-SEM, n=7) and were considerably greater than for controls (41+/-3 and 25+/-2 ms, mean+/-SEM, n=14, P<0.01). Furthermore, the relationship of tau(P) v tau(Ca) with CPA was similar to that found with ischemia. These findings are consistent with the hypothesis that the slowed Ca(2+) transient decline with both CPA and ischemia causes slowed relaxation. Consistent with this conclusion, a simple mathematical model to relate cytosolic [Ca(2+)] and pressure also suggests that slowed pressure relaxation can be explained by slowing of the Ca(2+) transient decline. This study suggests that impaired Ca(2+) uptake is a major injury causing slowed relaxation during ischemia.

Thermodynamic limitation for Ca2+ handling contributes to decreased contractile reserve in rat hearts.

The free energy release from ATP hydrolysis (|DeltaG approximately p|) is decreased by inhibiting the creatine kinase (CK) reaction, which may limit the thermodynamic driving force for the sarcoplasmic reticulum (SR) Ca2+ pumps and thereby cause a decrease in contractile reserve. To determine whether a decrease in |DeltaG approximately p| results in decreased contractile reserve by impairing Ca2+ handling, we measured left ventricular pressure and cytosolic Ca2+concentration ([Ca2+]c; by indo 1 fluorescence) in isolated perfused rat hearts, with >95% inhibition of CK with 90 micromol iodoacetamide. Iodoacetamide did not directly alter SR Ca2+-ATPase activity, baseline left ventricular developed pressure, or baseline [Ca2+]c. When perfusate Ca2+ concentration was increased from 1.2 to 3.3 mM, LV developed pressure increased from 67 +/- 6 to 119 +/- 8 mmHg in control hearts (P < 0.05) but did not significantly increase in CK-inhibited hearts. Similarly, the amplitude of the [Ca2+]c transient increased from 548 +/- 54 to 852 +/- 140 nM in control hearts (P < 0.05) but did not significantly increase in CK-inhibited hearts. We conclude that decreased |DeltaG approximately p| limits intracellular Ca2+ handling and thereby limits contractile reserve.

Role of MgADP in the development of diastolic dysfunction in the intact beating rat heart.

Sarcomere relaxation depends on dissociation of actin and myosin, which is regulated by a number of factors, including intracellular [MgATP] as well as MgATP hydrolysis products [MgADP] and inorganic phosphate [Pi], pHi, and cytosolic calcium concentration ([Ca2+]c). To distinguish the contribution of MgADP from the other regulators in the development of diastolic dysfunction, we used a strategy to increase free [MgADP] without changing [MgATP], [Pi], or pHi. This was achieved by applying a low dose of iodoacetamide to selectively inhibit the creatine kinase activity in isolated perfused rat hearts. [MgATP], [MgADP], [Pi], and [H+] were determined using 31P NMR spectroscopy. The [Ca2+]c and the glycolytic rate were also measured. We observed an approximately threefold increase in left ventricular end diastolic pressure (LVEDP) and 38% increase in the time constant of pressure decay (P < 0.05) in these hearts, indicating a significant impairment of diastolic function. The increase in LVEDP was closely related to the increase in free [MgADP]. Rate of glycolysis was not changed, and [Ca2+]c increased by 16%, which cannot explain the severity of diastolic dysfunction. Thus, our data indicate that MgADP contributes significantly to diastolic dysfunction, possibly by slowing the rate of cross-bridge cycling.

Response of normal and reperfused livers to glucagon stimulation: NMR detection of blood flow and high-energy phosphates.

The effects of glucagon on blood flow and high-energy phosphates in control and in rat livers damaged by ischemia were studied using in vivo nuclear magnetic resonance (NMR) spectroscopy. Normal livers and livers which had been made ischemic for 20, 40, and 60 min followed by 60 min of reperfusion were studied. Ischemia led to a loss in adenosine triphosphate (ATP) within 30 min. Reperfusion after 20 min of ischemia led to complete recovery of ATP. 60 min of reperfusion after 40 or 60 min of ischemia led to only a 76% and 48% recovery of ATP, respectively. Glucagon, at doses up to 2.5 mg/kg body weight, caused no changes in the inorganic phosphate (P(i)) to ATP ratio in normal livers as measured by 31P-NMR spectroscopy. In livers which had been made ischemic for 20, 40, or 60 min, glucagon caused an increase in the P(i)/ATP ratio of 18%, 40%, and 40%, respectively. 19F-NMR detection of the washout of trifluoromethane from liver was used to measure blood flow. Glucagon-stimulated flow in the normal liver in a dose-dependent manner, with 2.5 mg glucagon/kg body weight leading to a 95% increase in flow. Ischemia for 20, 40, and 60 min followed by 60 min of reperfusion led to hepatic blood flows which were 63%, 68%, and 58% lower than control liver. In reperfused livers, blood flow after glucagon-stimulation was reduced to 56%, 43%, and 48% of control glucagon-stimulated flow after 20, 40, and 60 min of ischemia. These results indicate that ischemia followed by reperfusion leads to decreases in hepatic blood flow prior to alterations in ATP and the response of the liver to glucagon is altered in the reperfused liver.