Modulating fast skeletal muscle contraction protects skeletal muscle in animal models of Duchenne muscular dystrophy
Alan J. Russell, Mike DuVall, Ben Barthel, Ying Qian, Angela K. Peter, Breanne L. Newell-Stamper, Kevin Hunt, Sarah Lehman, Molly Madden, Stephen Schlachter, Ben Robertson, Ashleigh Van Deusen, Hector M. Rodriguez, Carlos Vera, Yu Su, Dennis R. Claflin, Susan V. Brooks, Peter Nghiem, Alexis Rutledge, Twlya I. Juehne, Jinsheng Yu, Elisabeth R. Barton, Yangyi E. Luo, Andreas Patsalos, Laszlo Nagy, H. Lee Sweeney, Leslie A. Leinwand, Kevin Koch
Alan J. Russell, Mike DuVall, Ben Barthel, Ying Qian, Angela K. Peter, Breanne L. Newell-Stamper, Kevin Hunt, Sarah Lehman, Molly Madden, Stephen Schlachter, Ben Robertson, Ashleigh Van Deusen, Hector M. Rodriguez, Carlos Vera, Yu Su, Dennis R. Claflin, Susan V. Brooks, Peter Nghiem, Alexis Rutledge, Twlya I. Juehne, Jinsheng Yu, Elisabeth R. Barton, Yangyi E. Luo, Andreas Patsalos, Laszlo Nagy, H. Lee Sweeney, Leslie A. Leinwand, Kevin Koch
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Research Article Muscle biology

Modulating fast skeletal muscle contraction protects skeletal muscle in animal models of Duchenne muscular dystrophy

Abstract

Duchenne muscular dystrophy (DMD) is a lethal muscle disease caused by absence of the protein dystrophin, which acts as a structural link between the basal lamina and contractile machinery to stabilize muscle membranes in response to mechanical stress. In DMD, mechanical stress leads to exaggerated membrane injury and fiber breakdown, with fast fibers being the most susceptible to damage. A major contributor to this injury is muscle contraction, controlled by the motor protein myosin. However, how muscle contraction and fast muscle fiber damage contribute to the pathophysiology of DMD has not been well characterized. We explored the role of fast skeletal muscle contraction in DMD with a potentially novel, selective, orally active inhibitor of fast skeletal muscle myosin, EDG-5506. Surprisingly, even modest decreases of contraction (<15%) were sufficient to protect skeletal muscles in dystrophic mdx mice from stress injury. Longer-term treatment also decreased muscle fibrosis in key disease-implicated tissues. Importantly, therapeutic levels of myosin inhibition with EDG-5506 did not detrimentally affect strength or coordination. Finally, in dystrophic dogs, EDG-5506 reversibly reduced circulating muscle injury biomarkers and increased habitual activity. This unexpected biology may represent an important alternative treatment strategy for Duchenne and related myopathies.

Authors

Alan J. Russell, Mike DuVall, Ben Barthel, Ying Qian, Angela K. Peter, Breanne L. Newell-Stamper, Kevin Hunt, Sarah Lehman, Molly Madden, Stephen Schlachter, Ben Robertson, Ashleigh Van Deusen, Hector M. Rodriguez, Carlos Vera, Yu Su, Dennis R. Claflin, Susan V. Brooks, Peter Nghiem, Alexis Rutledge, Twlya I. Juehne, Jinsheng Yu, Elisabeth R. Barton, Yangyi E. Luo, Andreas Patsalos, Laszlo Nagy, H. Lee Sweeney, Leslie A. Leinwand, Kevin Koch

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Figure 2

Strength loss during eccentric contraction of dystrophic muscle is dependent upon contraction via myosin.

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Strength loss during eccentric contraction of dystrophic muscle is depen...
(A–E) WT and mdx mouse EDL muscle force ex vivo (n = 5–14). (A) Change in isometric and peak strain as a function of EDG-5506 concentration. Change in isometric force (circles) is represented as a percentage of initial force after 1-hour incubation with EDG-5506. Significance was calculated from the comparison of 5 μM EDG-5506 versus control. Peak strain (triangles) is represented as a percentage of peak strain obtained with vehicle treatment derived from the first eccentric contraction. Definitions of these metrics are provided in Supplemental Figure 2A. (B) Example force traces during 10 lengthening contractions of mdx and WT mouse EDL muscle ex vivo after incubation with the indicated concentrations of EDG-5506. (C) Normalized peak strain with each contraction of the injury protocol (n = 4–8). (D) Isometric force drop from the first to the last contraction as a function of EDG-5506 concentration. (E) Peak strain drop from the first to the last contraction as a function of EDG-5506 concentration. (F–H) WT and mdx mouse TA muscle force in situ (WT, n = 6; mdx vehicle, n = 17; mdx EDG-5506, n = 3–5 each). (F) Change in isometric force as a function of EDG-5506 dose, represented as a percentage of initial force 3 hours after oral gavage of vehicle or EDG-5506. (G) Isometric force drop 10 minutes after 2 lengthening contractions, represented as a percentage of preinjury force. All indicated comparisons were made again using 0 μM EDG-5506 (data not shown). (H) CK activity 1 hour after in situ injury (n = 7–11). Data are shown as the mean ± SEM. Significance was calculated by 1-way ANOVA with Dunnett’s multiple-comparison test. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001. All indicated comparisons were made against results obtained after treatment with vehicle (0 μM EDG-5506).