Chronic administration of membrane sealant prevents severe cardiac injury and ventricular dilatation in dystrophic dogs
DeWayne Townsend, … , Joe N. Kornegay, Joseph M. Metzger
DeWayne Townsend, … , Joe N. Kornegay, Joseph M. Metzger
Published March 15, 2010
Citation Information: J Clin Invest. 2010;120(4):1140-1150. https://doi.org/10.1172/JCI41329.
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Research Article Muscle biology

Chronic administration of membrane sealant prevents severe cardiac injury and ventricular dilatation in dystrophic dogs

Abstract

Duchenne muscular dystrophy (DMD) is a fatal disease of striated muscle deterioration caused by lack of the cytoskeletal protein dystrophin. Dystrophin deficiency causes muscle membrane instability, skeletal muscle wasting, cardiomyopathy, and heart failure. Advances in palliative respiratory care have increased the incidence of heart disease in DMD patients, for which there is no cure or effective therapy. Here we have shown that chronic infusion of membrane-sealing poloxamer to severely affected dystrophic dogs reduced myocardial fibrosis, blocked increased serum cardiac troponin I (cTnI) and brain type natriuretic peptide (BNP), and fully prevented left-ventricular remodeling. Mechanistically, we observed a markedly greater primary defect of reduced cell compliance in dystrophic canine myocytes than in the mildly affected mdx mouse myocytes, and this was associated with a lack of utrophin upregulation in the dystrophic canine cardiac myocytes. Interestingly, after chronic poloxamer treatment, the poor compliance of isolated canine myocytes remained evident, but this could be restored to normal upon direct application of poloxamer. Collectively, these findings indicate that dystrophin and utrophin are critical to membrane stability–dependent cardiac myocyte mechanical compliance and that poloxamer confers a highly effective membrane-stabilizing chemical surrogate in dystrophin/utrophin deficiency. We propose that membrane sealant therapy is a potential treatment modality for DMD heart disease and possibly other disorders with membrane defect etiologies.

Authors

DeWayne Townsend, Immanuel Turner, Soichiro Yasuda, Joshua Martindale, Jennifer Davis, Michael Shillingford, Joe N. Kornegay, Joseph M. Metzger

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Figure 10

Model of the cellular basis for severe cardiomyopathy in GRMD animals.

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Model of the cellular basis for severe cardiomyopathy in GRMD animals. (...
(A) A schematic of membane-intact cardiac myocyte passive tension-extension curves. In the presence of dystrophin, myocytes show compliance throughout the working sarcomere length range (black line). In the absence of dystrophin, the cardiac myocytes become very noncompliant and resistant to passive extensions (gray line), as seen in GRMD myocytes. Upregulation of utrophin partially restores the passive extension-tension properties of the dystrophin-deficient myocytes (dotted line), as seen in the mdx myocytes. (B) Cellular model depicting the normal mechanical stabilizing function of dystrophin (blue) in wild-type animals. In wild-type cardiac myocytes, upon passive cell extension (lower scheme), dystrophin protects the membrane from damage. In the mdx myocytes, dystrophin is absent, but utrophin (red) is upregulated and partially replaces the mechanical buffering properties of dystrophin. This provides some, but not full protection of the membrane from mechanical damage. Hence, with cell extension, there is some membrane damage. In the dystrophin-deficient dog myocytes (GRMD), utrophin is not upregulated. Thus, upon cell extension, there is more damage to the membrane.