Impaired posthypoxic relaxation in single cardiac myocytes: role of intracellular pH and inorganic phosphate

Abstract

Objective: The aim was to examine the effects of alterations in intracellular pH and inorganic phosphate concentration (known to influence myofilament kinetics and to change rapidly during hypoxia) on cell contraction, relaxation, and the Ca²⁺ transient in normoxic and hypoxic myocytes. Methods: Single adult rat ventricular myocytes were electrically stimulated (0.2 Hz) and cell length (photodiode array), intracellular Ca²⁺ (indo-1 fluorescence), or intracellular pH (SNARF-1 fluorescence) measured. Hypoxia was induced in a special open chamber in which a laminar layer of argon prevented the back diffusion of atmospheric oxygen. Results: Electrically stimulated contraction was preserved during exposure to hypoxia. At reoxygenation 10 minutes later the time from the stimulus to the peak of contraction (TPK) increased by 30(SEM 9)% and the time from the peak of contraction to 50% recovery of cell length (RT₅₀) increased by 59(13)% relative to prehypoxic values (n = 8). These changes were not accompanied by a change in the kinetics of the Ca²⁺ transient. pH_i fell from a baseline of 7.33(0.04) to 7.25(0.03) during hypoxia and then overshot to 7.44(0.03) at reoxygenation (n = 5). Since an intracellular alkalosis can slow myofilament relaxation, proton extrusion routes were blocked to examine posthypoxic relaxation in the absence of an alkalosis. Despite inhibition of the pH_i overshoot, posthypoxic relaxation remained impaired. Intracellular inorganic phosphate levels were manipulated in two protocols (2-deoxyglucose to “trap” phosphate and Tris(hydroxymethyl)-aminomethane to buffer phosphate) and both TPK and RT₅₀ increased in normoxic cells. Having established that these two interventions, which would be expected to decrease intracellular inorganic phosphate, result in a slowing of relaxation, myocytes were first phosphate loaded (exposed to 5.0 mM phosphate) and then made hypoxic and reoxygenated after 10 min to blunt the expected fall in phosphate accompanying reoxygenation. This led to a reduction in the slowing of contraction and relaxation following reoxygenation [TPK increased by 7(5)% and RT₅₀ by 17(9)%, n = 8; p < 0.05 v cells studied in control buffer]. Conclusions: Impaired posthypoxic relaxation is not the result of changes in pH_i but is attenuated by phosphate loading of cells and may be due to a rapid decrease in intracellular phosphate accompanying the resynthesis of high energy phosphates at reoxygenation. Cardiovascular Research 1993;27:1983-1990