Myoferlin is required for insulin-like growth factor response and muscle growth

Myoferlin is required for insulin-like growth factor response and muscle growth
The FASEB Journal. 2010;24:1284-1295
Alexis R. Demonbreun*, Avery D. Posey, Konstantina Heretis, Kayleigh A. Swaggart, Judy U. Earley, Peter Pytel|| and Elizabeth M. McNally*,,,,1
“nsulin-like growth factor (IGF) is a potent stimulus of muscle growth. Myoferlin is a membrane-associated protein important for muscle development and regeneration. Myoferlin-null mice have smaller muscles and defective myoblast fusion. To understand the mechanism by which myoferlin loss retards muscle growth, we found that myoferlin-null muscle does not respond to IGF1. In vivo after IGF1 infusion, control muscle increased myofiber diameter by 25%, but myoferlin-null muscle was unresponsive. Myoblasts cultured from myoferlin-null muscle and treated with IGF1 also failed to show the expected increase in fusion to multinucleate myotubes. The IGF1 receptor colocalized with myoferlin at sites of myoblast fusion. The lack of IGF1 responsiveness in myoferlin-null myoblasts was linked directly to IGF1 receptor mistrafficking as well as decreased IGF1 signaling. In myoferlin-null myoblasts, the IGF1 receptor accumulated into large vesicular structures. These vesicles colocalized with a marker of late endosomes/lysosomes, LAMP2, specifying redirection from a recycling to a degradative pathway. Furthermore, ultrastructural analysis showed a marked increase in vacuoles in myoferlin-null muscle. These data demonstrate that IGF1 receptor recycling is required for normal myogenesis and that myoferlin is a critical mediator of postnatal muscle growth mediated by IGF1

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Combined isometric, concentric, and eccentric resistance exercise prevents unloading-induced muscle atrophy in rats.

Appl Physiol. 2007 Nov;103(5):1644-54. Adams GR, Haddad F, Bodell PW, Tran PD, Baldwin KM.

“Previously, we reported that an isometric resistance training program that was effective in stimulating muscle hypertrophy in ambulatory rats could not completely prevent muscle atrophy during unloading (Haddad F, Adams GR, Bodell PW, Baldwin KM. J Appl Physiol 100: 433-441, 2006). These results indicated that preventing muscle atrophy does not appear to be simply a function of providing an anabolic stimulus. The present study was undertaken to determine if resistance training, with increased volume (3-s contractions) and incorporating both static and dynamic components, would be effective in preventing unloading-induced muscle atrophy. Rats were exposed to 5 days of muscle unloading via tail suspension. During that time one leg received electrically stimulated resistance exercise (RE) that included an isometric, concentric, and eccentric phase. The results of this study indicate that this combined-mode RE provided an anabolic stimulus sufficient to maintain the mass and myofibril content of the trained but not the contralateral medial gastrocnemius (MG) muscle. Relative to the contralateral MG, the RE stimulus increased the amount of total RNA (indicative of translational capacity) as well as the mRNA for several anabolic/myogenic markers such as insulin-like growth factor-I, myogenin, myoferlin, and procollagen III-alpha-1 and decreased that of myostatin, a negative regulator of muscle size. The combined-mode RE protocol also increased the activity of anabolic signaling intermediates such as p70S6 kinase. These results indicate that a combination of static- and dynamic-mode RE of sufficient volume provides an effective stimulus to stimulate anabolic/myogenic mechanisms to counter the initial stages of unloading-induced muscle atrophy.

Source: http://www.michaelgundill.com/blog/177

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