Properties of soluble cyclic AMP-dependent protein kinase activity of renal inner medulla

Studies of the chromatographic distribution of soluble protein kinase in rat kidney demonstrated that the type I isoenzyme predominates in cortex, whereas activity in outer and inner medulla is almost exclusively the type II form. The type II isoenzyme also predominates (95% or greater) in human, canine, bovine, porcine and rabbit inner medulla. Compared to soluble type I activities from rat renal cortex or medulla, type II activity of inner medulla demonstrates a marked resistance to activation by NaCl and/or urea in subcellular preparations. However, with respect to solute activation, the resistance of the type II enzyme of inner medulla does not differ from that of type II activities from other tissues. In contrast to the effects on basal activity, NaCl and urea potentiated inner medullary type II activation by cyclic AMP and also delayed the rate of subunit reassociation after chromatographic removal of cyclic AMP. Incubation of inner medullary slices in high osmolality buffer (NaCl and urea) did not alone activate soluble protein kinase, an observation which implied that the enzyme was also resistant to solute activation in the intact cell system. Moreover, at 1650 mosM, vasopressin activation of soluble protein kinase was enhanced compared to responses at 750 mosM despite comparabel levels of cyclic AMP accumulation at the two osmolalities. However, a cyclic AMP-independent action of high osmolality to reduce the rate of inactivation of arginine vasopressin-stimulated protein kinase was not demonstrable in inner medullary slices.The present data suggest the possibility that the resistance of inner medullary protein kinase to solute activation could be related to the isomeric form of enzyme (type II) present in this tissue. The high concentrations of NaCl and urea routinely found in inner medulla during hydropenia also influenced protein kinase responses to arginine vasopressin, and may do so in part by directly potentiating the action of cyclic AMP on subunit dissociation.