Mechanisms that regulate PKCδ‐dependent phosphorylation of cardiac troponin I: the role of the C2 domain and ATP‐binding loop phosphorylation S357 (1081.2)

Abstract

PKCδ's diverse roles in cell growth, survival, and injury have been attributed to stimulus‐specific differences in PKCδ‐dependent signaling responses. PKCδ exerts membrane‐delimited actions following activation by agonists that stimulate phosphoinositide hydrolysis. PKCδ is released from membranes as a Y311‐phosphorylated enzyme that displays a high level of lipid‐independent activity and altered substrate specificity during oxidative stress. We previously showed that PKCδ phosphorylates cardiac troponin I (cTnI) at S23/S24 when it is allosterically‐activated by lipid‐cofactors and that PKCδ acquires activity toward an additional site on cTnI (T144) during oxidative stress when it is Y311‐phosphorylated by Src. This study identifies an interaction between PKCδ’s phosphotyrosine‐binding C2 domain and the Y311‐phosphorylated hinge region (which resides in a C2 domain consensus‐binding motif) that controls PKCδ's enzymology indirectly by regulating ATP‐positioning loop phosphorylation at S357. Mutagenesis studies show that PKCδ‐S357A is a lipid‐independent enzyme that displays high levels of cTnI‐S23/S24 and T141 kinase activity. In contrast, phosphomimetic or bulky substitutions at S357 prevent cTnI phosphorylation at T141 (but not S23/S24) due to an effect on the enzyme’s phosphoacceptor site selectivity. S‐A substitutions at cognate sites in the highly‐conserved ATP‐binding loops of PKCα and PKA increase catalytic activity, but do not alter phosphoacceptor site selectivity. The C2 domain‐pY311 docking interaction that controls ATP‐binding loop phosphorylation represents a novel structural determinant of PKCδ catalytic activity.Grant Funding Source: Supported by HL77860