Myostatin and ecdysteroid signaling in crustacean skeletal muscle
Colorado State University, Fort Collins CO
Investigators
Abstract
Crustaceans must shed their shells periodically in order to grow, a process called molting. Many crabs and lobsters have large claws, which must be pulled through the small joints that connect the appendage to the body when the animal molts. A reduction, or atrophy, in the claw muscle facilitates the withdrawal of the claws at molt. The PI hypothesizes that myostatin (Mstn), a negative regulator of muscle growth in mammals, mediates claw muscle atrophy that is under the control of steroid molting hormones (ecdysteroids). The specific aims of the project are to (1) determine the regulation of Mstn/Smad signaling by ecdysteroid in the land crab and (2) determine the interaction of fiber type and ecdysteroid on claw muscle atrophy in lobster. The experiments on land crab take advantage of their ability to manipulate the molt cycle and to culture claw muscle. The experiments on lobster take advantage of their ability to quantify mRNAs and proteins in muscles that differ in fiber type composition in the dimorphic claws. An advantage of both species is that only the claw muscles are responsive to the atrophy-inducing signal. Muscles that do not respond to ecdysteroid (thoracic muscle in land crab and abdominal muscles in lobster) serve as internal controls, as they are exposed to the same hormonal environment. The discovery of Mstn in crustacean muscles suggests that the regulation of muscle mass is highly conserved between vertebrates and invertebrates. It constitutes an entirely novel and exciting area of investigation. As crustacean muscles have few stem cells, they are an ideal model to determine the direct effects of Mstn on differentiated fibers in adults and therefore can provide insights into Mstn action in humans. Understanding the signaling pathway(s) regulating skeletal muscle mass could have significant impacts on crustacean aquaculture. For example, blocking Mstn signaling could enhance growth and improve product quality. The project will provide training in modern biochemical and molecular technologies for a Native American postdoctoral fellow, 2 graduate students, and 4-6 undergraduates.
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