Serine 68 phosphorylation of phospholemman: acute isoform-specific activation of cardiac Na/K ATPase.

OBJECTIVE: The mechanism by which the cardiac Na/K ATPase (NKA) is regulated by phosphorylation is controversial. We have used the perforated-patch technique to limit cell dialysis and maintain conditions as near physiological as possible. METHODS: NKA pump current (I(p)) was measured in isolated guinea pig ventricular myocytes, and its components (I(alpha 1) and I(alpha 2)) defined by their differing dihydroouabain sensitivities. RESULTS: Treatment with 1 micromol/l forskolin for 4 min at 35 degrees C caused a significant increase in I(alpha1) of 36+/-15% (P<0.05, n=6), but no change in I(alpha2). The presence of the PKA selective inhibitor H89 (50 micromol/l) throughout the protocol blocked the effect of the forskolin on I(alpha1). Treatment with H89 alone did not change I(alpha 1) or I(alpha 2). Isoelectric focusing gels of the NKA alpha1 subunit demonstrated six charge states, which were unaltered following treatment with forskolin. Western blots using an antibody specific for the PKA phosphorylation consensus site on the alpha1 subunit showed no change in the phosphorylation status of this residue following forskolin treatment. The sarcolemmal protein phospholemman (PLM) was found associated with NKA alpha 1 but not alpha 2 subunits by immunoprecipitation and immunofluorescence. PLM was phosphorylated at serine 68, but not 63, following treatment with forskolin. CONCLUSIONS: PKA-dependent, alpha 1-specific NKA activation may be mediated through phosphorylation of the accessory protein PLM, rather than direct alpha1 subunit phosphorylation.

Is there a transient rise in sub-sarcolemmal Na and activation of Na/K pump current following activation of I(Na) in ventricular myocardium?

OBJECTIVE: The primary aim of this study was to investigate whether activation of Na influx via voltage-gated Na channels can elevate sub-sarcolemmal ('fuzzy-space') [Na] and transiently activate Na/K pump current (I(p)). METHODS AND RESULTS: Initially, Na/K pump activity was characterised in whole-cell voltage-clamped single guinea-pig ventricular myocytes. I(p) was activated by intracellular Na with a K(m) of 15.5 mM and a Hill coefficient of 1.7. Extracellular K activated I(p) with a K(m) of 1.6 mM. In these experiments, a finite ouabain-sensitive I(p) was measured when the pipette [Na] was zero. This suggests that there is an accumulation of Na in a sub-sarcolemmal space that is not in equilibrium with the bulk cytosol (which is assumed to be efficiently dialysed by the low-resistance patch-pipettes used). Such a sub-sarcolemmal Na gradient was observed in separate experiments in intact rabbit papillary muscles using electron probe X-ray microanalysis. In these studies, a fuzzy-space of limited Na diffusion was observed 100-200 nm below the sarcolemmal membrane. This sub-sarcolemmal Na gradient was similar whether muscles were frozen at peak-systole or end-diastole suggesting that the fuzzy-space Na does not change over the course of the contractile cycle. This was further investigated in isolated guinea pig myocytes where evidence for a transient activation of I(p) was sought immediately after the activation of voltage-gated Na channels. A single clamp step from -80 to 0 mV activated Na influx but, in the 10-2000 ms immediately following the initial Na influx no evidence for a transient activation of I(p) was observed. Similarly, no activation of I(p) could be detected immediately following a train of 20 rapid (5-Hz) pulses designed to maximise Na influx. CONCLUSIONS: These studies provide evidence for the existence of a maintained sub-sarcolemmal elevation of [Na] in ventricular myocardium; however, this fuzzy-space [Na] did not change immediately after the activation of Na influx via voltage-gated Na channels or throughout the contractile cycle.