AJP - Endocrinology and Metabolism, Vol 240, Issue 3 340-E349, Copyright © 1981 by American Physiological Society
Regulation of guinea pig heart phosphorylase kinase by cAMP, protein kinase, and calcium
J. S. Hayes and S. E. Mayer
In skeletal muscle the activation of phosphorylase kinase (PK) associated
with phosphorylation of the enzyme can be measured as an increase in the pH
6.8:8.2 activity ratio. Phosphorylation leads to a 20- to 30-fold increase
in PK activity (PKA) at pH 6.8 and a large decrease in the Km for
phosphorylase. Perfused guinea pig hearts exposed to isoproterenol (0.3
microM) showed an increase in PKA, but without an increase in the pH
6.8:8.2 activity ratio. In a 10-fold dilution of guinea pig heart cytosol
exposed to cAMP + methylisobutylxanthine, PKA was stimulated twofold at pH
7.5. Addition of exogenous protein kinase stimulated PKA fourfold. Both
methods of activation were reversible and were blocked by the heat-stable
inhibitor of protein kinase. Guinea pig heart PK was Ca2+-dependent
requiring 0.6 microM Ca2+ for half-maximal activity. Kinetic studies
indicate that the Km of guinea pig heart PK for phosphorylase b at pH 6.8
is not markedly reduced after in vitro activation (35%). This could explain
the observed lack of increase in the pH 6.8:8.2 activity ratio after
exposure of hearts to isoproterenol. The time course for the activation of
inotropic state and the glycogenolytic pathway in perfused guinea pig
hearts by isoproterenol showed that these processes were maximally
activated within 25 s. However, PK remained activated for 2 min, long after
the other biochemical and physiological parameters had returned to control
values. These data suggest that Ca2+, not phosphorylation state, is
important in regulating the return of dP/dt to control levels after
beta-adrenergic stimulation.
