Epsilon protein kinase C in pathological myocardial hypertrophy. Analysis by combined transgenic expression of translocation modifiers and Galphaq.

The epsilon isoform of protein kinase C (PKC) has a critical cardiotrophic function in normal postnatal developing heart as demonstrated by cardiac-specific transgenic expression of epsilonPKC-selective translocation inhibitor (epsilonV1) and activator (psiepsilonRACK) peptides (Mochly-Rosen, D., Wu, G., Hahn, H., Osinska, H., Liron, T., Lorenz, J. N., Robbins, J., and Dorn, G. W., II (2000) Circ. Res. 86, 1173-1179). To define the role of epsilonPKC signaling in pathological myocardial hypertrophy, epsilonV1 or psiepsilonRACK were co-expressed in mouse hearts with Galpha(q), a PKC-linked hypertrophy signal transducer. Compared with Galpha(q) overexpression alone, co-expression of psiepsilonRACK with Galpha(q) increased epsilonPKC particulate partitioning by 30 +/- 2%, whereas co-expression of epsilonV1 with Galpha(q) reduced particulate-associated epsilonPKC by 22 +/- 1%. Facilitation of epsilonPKC translocation by psiepsilonRACK in Galpha(q) mice improved cardiac contractile function measured as left ventricular fractional shortening (30 +/- 3% Galpha(q) versus 43 +/- 2% psiepsilonRACK/Galpha(q), p < 0.05). Conversely, inhibition of epsilonPKC by epsilonV1 modified the Galpha(q) nonfailing hypertrophy phenotype to that of a lethal dilated cardiomyopathy. These opposing effects of epsilonPKC translocation activation and inhibition in Galpha(q) hypertrophy indicate that epsilonPKC signaling is a compensatory event in myocardial hypertrophy, rather than a pathological event, and support the possible therapeutic efficacy of selective epsilonPKC translocation enhancement in cardiac insufficiency.