Abstract

SKELETAL MUSCLES adjust their contractile output over an exceptionally wide dynamic range, as needed to produce movements ranging from sitting and standing, to athletics and dance. At the single fiber level, the force generated by skeletal muscles is determined, ultimately, by the formation of cycling cross bridges between actin and myosin. This interaction requires Ca 2 and is governed by the simple relationship: force is proportional to intracellular ionized Ca 2 . Cross-bridge formation is inhibited in resting muscle when Ca 2 is sequestered within the sarcoplasmic reticulum (SR); it is activated when stored Ca 2 is released into the cytosol, allowing actin-myosin interactions to proceed. Contraction stops as Ca 2 is actively resequestered by the Ca 2 -ATPase of the SR (SERCA1). Thus Ca 2 is the central messenger in muscle activation, and the amplitude and time course of the intracellular Ca 2 change is the major determinant of contractile output. The key mechanisms that activate Ca 2 release from the SR are now well defined. This sequence, termed excitation-contraction coupling, begins when an excitatory input from the motor nerve triggers a propagating action potential on the muscle membrane. The action potential rapidly depolarizes the entire sarcolemma, including transverse tubules, which invaginate from the surface membrane and form specialized junctions (triads) with the SR along much of their length. The triad junction serves as a platform for assembling sarcolemmal calcium

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