Golgi and sarcolemmal neuronal NOS differentially regulate contraction-induced fatigue and vasoconstriction in exercising mouse skeletal muscle
Justin M. Percival, … , Marvin E. Adams, Stanley C. Froehner
Justin M. Percival, … , Marvin E. Adams, Stanley C. Froehner
Published February 1, 2010
Citation Information: J Clin Invest. 2010;120(3):816-826. https://doi.org/10.1172/JCI40736.
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Research Article Muscle biology

Golgi and sarcolemmal neuronal NOS differentially regulate contraction-induced fatigue and vasoconstriction in exercising mouse skeletal muscle

Abstract

Signaling via the neuronal NOS (nNOS) splice variant nNOSμ is essential for skeletal muscle health and is commonly reduced in neuromuscular disease. nNOSμ is thought to be the predominant source of NO in skeletal muscle. Here we demonstrate the existence of what we believe to be a novel signaling pathway, mediated by the nNOS splice variant nNOSβ, localized at the Golgi complex in mouse skeletal muscle cells. In contrast to muscles lacking nNOSμ alone, muscles missing both nNOSμ and nNOSβ were severely myopathic, exhibiting structural defects in the microtubule cytoskeleton, Golgi complex, and mitochondria. Skeletal muscles lacking both nNOSμ and nNOSβ were smaller in mass, intrinsically weak, highly susceptible to fatigue, and exhibited marked postexercise weakness. Our data indicate that nNOSβ is a critical regulator of the structural and functional integrity of skeletal muscle and demonstrate the existence of 2 functionally distinct nNOS microdomains in skeletal muscle, created by the differential targeting of nNOSμ to the sarcolemma and nNOSβ to the Golgi. We have previously shown that sarcolemmal nNOSμ matches the blood supply to the metabolic demands of active muscle. We now demonstrate that nNOSβ simultaneously modulates the ability of skeletal muscle to maintain force production during and after exercise. We conclude therefore that nNOS splice variants are critical regulators of skeletal muscle exercise performance.

Authors

Justin M. Percival, Kendra N.E. Anderson, Paul Huang, Marvin E. Adams, Stanley C. Froehner

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Figure 3

A nNOS splice variant localizes to the Golgi complex and regulates microtubule cytoskeleton integrity in skeletal muscle.

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A nNOS splice variant localizes to the Golgi complex and regulates micro...
(A) In WT gastrocnemius muscles, nNOS (red) colocalizes with GM130 (green). The inset overlay image emphasizes the high degree of overlap between GM130 and Golgi nNOS. In KN1 muscles, Golgi nNOS labeling is unaffected, indicating that the Golgi nNOS is not nNOSμ but nNOSβ and/or nNOSγ. Golgi nNOS immunolabeling is absent in KN2 muscles, demonstrating nNOS antibody specificity. The loss of all nNOS variants perturbs the distribution and morphology of the Golgi complex. Higher-magnification images are shown in the inset panels. (B) nNOS splice variants differentially regulate the structural integrity of the microtubule cytoskeleton. Microtubules were labeled with FITC-conjugated α-tubulin antibody. The characteristic microtubule lattice is evident in WT myofibers (left panel). Loss of nNOSμ has a minor impact on microtubule organization (middle panel), which was insufficient to disrupt Golgi distribution. The loss of all nNOS splice variants severely compromises the integrity of the microtubule cytoskeleton (right panel). Scale bar: 20 μm; 6 μm (insets). n ≥ 4.