Striated muscle MLCP is regulated by MYPT2 to limit baseline cardiac myosin phosphorylation.

Abstract

Cardiac myosin is a hexameric protein comprised of two protamers that each have a heavy chain, a regulatory light chain (RLC), and an essential light chain. Constitutive phosphorylation of cardiac myosin in beating hearts at 0.4 mol phosphate/mol RLC is necessary for normal function. This level is maintained by balanced activities of the cardiac myosin light chain kinase (cMLCK) and myosin light chain phosphatase (MLCP). The canonical MLCP is well-studied in smooth muscles, and is defined as a trimeric holoenzyme comprised of a myosin target regulatory subunit MYPT1, a type-1 catalytic subunit PP1cβ, and an accessory protein M21. In striated muscles, the dominantly expressed regulatory subunit is MYPT2. There is limited information on the localization and regulatory contributions of MYPT2. Studies of regulation of cardiac myosin dephosphorylation is hindered by the fact that myosin dephosphorylation occurs rapidly in isolated cardiac myocytes, and cultured “cardiac” cell lines do not express the regulatory proteins at levels comparable to those of freshly isolated cardiac myocytes. We generated a floxed MYPT2 mouse line and conditionally knocked out nearly all detectable MYPT2 protein in cardiac myocytes, and used this model to determine that: 1) MYPT2 localizes to myosin in vivo, 2) MYPT1 expression does not compensate for the reduction in MYPT2 in the cardiac muscle, 3) the cardiac MLCP holoenzyme expression level is partly regulated by stabilization of the catalytic subunit by MYPT2, 4) without MYPT2-regulated MLCP activity, baseline cardiac RLC phosphorylation is increased to 0.6 mol phosphate/mol RLC, and 5) MYPT2 knockout animals have reduced responses to pressure-overload induced cardiac hypertrophy. These findings help to fill knowledge-gaps about the fundamental properties of the cardiac muscle MLCP.