Protein kinase C activates the respiratory burst of fertilization, but not cortical granule exocytosis, in ionophore-stimulated sea urchin eggs.

In a "respiratory burst", fertilized sea urchin eggs consume oxygen to produce H2O2 as an extracellular oxidant to crosslink their protective surface envelopes. The egg generates H2O2 via a NADPH-specific oxidase that requires protein kinase C for activation. To further study the physiological regulation of the respiratory burst and cortical granule exocytosis, we have measured azide-insensitive oxygen uptake and fertilization envelope assembly in ionophore-stimulated eggs. Procaine, trifluoperazine, staurosporine, and H-7, which inhibit protein kinase C by different mechanisms, suppressed egg oxygen consumption without affecting fertilization envelope assembly. In contrast, both exocytosis and oxygen uptake were blocked in N-ethylmaleimide-treated eggs. When the eggs were stimulated with ionophore in Na-free artificial seawater, which prevents the increase in pHi, oxidase activity was inhibited. This effect was reversed by elevation of cytoplasmic pH with the membrane-permeant base NH4Cl. We conclude that protein kinase C was not involved in the events downstream from the ionophore-dependent elevation of Ca2+ which induced cortical granule exocytosis. However, the respiratory burst was inhibited despite the increase in Ca2+ that triggered exocytosis. The likely target for inhibition of the burst was protein kinase C. Cytoplasmic alkalinization was necessary for optimal rates of H2O2 synthesis, further implicating pHi as a regulator of the egg oxidase.