NOX4 inhibition promotes the remodeling of dystrophic muscle
David W. Hammers
David W. Hammers
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Research Article Muscle biology Therapeutics

NOX4 inhibition promotes the remodeling of dystrophic muscle

Abstract

The muscular dystrophies (MDs) are genetic muscle diseases that result in progressive muscle degeneration followed by the fibrotic replacement of affected muscles as regenerative processes fail. Therapeutics that specifically address the fibrosis and failed regeneration associated with MDs represent a major unmet clinical need for MD patients, particularly those with advanced-stage disease progression. The current study investigated targeting NAD(P)H oxidase 4 (NOX4) as a potential strategy to reduce fibrosis and promote regeneration in disease-burdened muscle that models Duchenne muscular dystrophy (DMD). NOX4 was elevated in the muscles of dystrophic mice and DMD patients, localizing primarily to interstitial cells located between muscle fibers. Genetic and pharmacological targeting of NOX4 significantly reduced fibrosis in dystrophic respiratory and limb muscles. Mechanistically, NOX4 targeting decreased the number of fibrosis-depositing cells (myofibroblasts) and restored the number of muscle-specific stem cells (satellite cells) localized to their physiological niche, thereby rejuvenating muscle regeneration. Furthermore, acute inhibition of NOX4 was sufficient to induce apoptotic clearing of myofibroblasts within dystrophic muscle. These data indicate that targeting NOX4 is an effective strategy to promote the beneficial remodeling of disease-burdened muscle representative of DMD and, potentially, other MDs and muscle pathologies.

Authors

David W. Hammers

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Figure 3

Targeting NOX4 reduces fibrosis in dystrophic muscle.

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Targeting NOX4 reduces fibrosis in dystrophic muscle. (A) Representative...
(A) Representative picrosirius red staining and image quantification of (B) diaphragm and (C) gastrocnemius muscles from 6-month-old D2.WT (n = 6), NOX4 wild-type (NOX4-WT), and knockout (NOX4-KO) littermates from a NOX4-KO line generated on the D2.mdx background (Nox4KO:mdx; n = 12), and D2.mdx mice that received vehicle or GK831 (GKT) treatments beginning at 3 months of age (n = 12–14). Fibrosis quantifications for 3-month-old D2.mdx mice are included to show baseline values for GKT treatment groups. Scale bars: 100 μm. Muscle function was assessed for the (D) diaphragm and (E) extensor digitorum longus (EDL) muscles of NOX4-WT (+/+) and NOX4-KO (–/–) littermates of the Nox4KO:mdx mouse line (n = 6). (F) Biochemical quantification of collagen content was performed on gastrocnemius muscles of vehicle- and GKT-treated D2.mdx mice (n = 9–12). Data are presented as box-and-whisker plots, with whiskers representing minimum and maximum values. In DF, percentage values indicate the difference between mean values of the 2 groups. Data were analyzed using (B and C) ANOVA followed by Tukey’s post hoc test (α = 0.05; effect size is reported as η2) or (DF) unpaired, 2-tailed Welch’s t test (α = 0.05; effect size is reported as Cohen’s d). “ANOVA P < 0.0001” in B and C refers to the significance level of the entire data set, consisting of D2.WT, D2.mdx (3 mo), Nox4-WT, Nox4-KO, vehicle, and GKT groups. *P < 0.05 vs. D2.WT values; #P < 0.05 vs. 3-month-old D2.mdx values; $P < 0.05 vs. respective control group values.