Regulatory light chain phosphorylation increases eccentric contraction–induced injury in skinned fast‐twitch fibers

During contraction, activation of Ca 2+ /calmodulin–dependent myosin light chain kinase (MLCK) results in phosphorylation of myosin's regulatory light chain (RLC), which potentiates force and increases speed of force development over a wide range of [Ca 2+ ]. We tested the hypothesis that RLC phosphorylation by MLCK mediates the extent of eccentric contraction–induced injury as measured by force deficit in skinned fast‐twitch skeletal muscle fibers. Results indicated that RLC phosphorylation in single skinned rat psoas fibers significantly increased Ca 2+ sensitivity of isometric force; isometric force from 50 ± 16 to 59 ± 18 kN/m 2 during maximal Ca 2+ activation; peak absolute power output from 38 ± 15 to 48 ± 14 nW during maximal Ca 2+ activation; and the magnitude of contraction‐induced force deficit during maximal (pCa 4.5) activation from 26 ± 9.8 to 35 ± 9.6%. We conclude that RLC phosphorylation increases force deficits following eccentric contractions, perhaps by increasing the number of force‐generating cross‐bridges. Muscle Nerve 29: 313–317, 2004