Ca2+-Activated Force Production and Calcium Handling by the Sarcoplasmic Reticulum of Crustacean Muscles During Molt-Induced Atrophy

Growth in crustaceans is an intermittent process centered aroundthe principal event of ecdysis. A major problem facing decapodcrustaceans at the time of ecdysis is the withdrawal of thelarge muscle mass of the chelae through the narrow basi-ischialjoints. To overcome this problem the muscle undergoes an atrophytriggered by the molt, which reduces the muscle mass. Once theanimal is freed from the old exoskeleton, the muscle fibers,must elongate to accommodate the new larger exoskeleton. Despitethis major myofibrillar remodification, the muscles are thoughtto remain functional over the molt cycle. Studies using skinnedmuscle fibers have shown that long-sarcomere fibers maintaintheir function over the molt cycle while the contractile propertiesof the short-sarcomere fibers are modified, as fibers couldnot withstand maximal activation with Ca²⁺ during the premoltstage. In this study the maximum Ca²⁺-activated force productionand the ability of the sarcoplasmic reticulum (SR) to releaseaccumulated Ca²⁺ has been investigated in the two major fibertypes in the claw muscle of Cherax destructor, in the stagesjust prior to ecdysis and during inter molt. In both long- andshort-sarcomere fibers, the amount of Ca²⁺ released by the SRwas not different in premolt and intermolt stages. However,the maximum releasing capacity of the SR was reached in a shortertime during the premolt suggesting that Ca²⁺ is being accumulatedat a faster rate. The force production was greatly reduced andwas graded during the premolt in both fiber types. This modulationof force appears to be the most likely candidate regulatingthe magnitude of the force development in the periods when fibersare undergoing myofibrillar remodification and thus may serveto prevent fiber damage.