Endocrine-metabolic decoupling drives stress vulnerability in dystrophin deficiency

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Abstract

Skeletal muscle orchestrates systemic metabolism, dynamically coordinating glucose uptake and fuel use to match energy demand. In Duchenne muscular dystrophy, loss of dystrophin is associated with altered metabolic regulation. In the mdx mouse, we show that physiological stress reveals impaired coordination between insulin and stress responses: glucocorticoid signalling increases without a proportional rise in insulin secretion, resulting in systemic hyperglycaemia despite preserved capacity for muscle glucose uptake. These data support a multi-tissue dystrophinopathy associated with altered endocrine-metabolic coordination. Skeletal muscle glycogen is elevated and incompletely mobilised under stress. The heart maintains high glucose uptake, whereas the brain exhibits reduced uptake, highlighting tissue specific differences in metabolic response. Acute insulin supplementation improves systemic glucose control and restores stress-induced behavioural deficits. Likewise, empagliflozin-mediated glucose offloading reduces stress-associated blood glucose spikes and is associated with improved muscle function to levels comparable with standard care prednisolone. These findings identify impaired coordination of endocrine and metabolic responses during stress as a contributor to metabolic vulnerability in DMD and suggest that modulating insulin availability or glucose flux can improve systemic metabolic control.
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Abstract Skeletal muscle orchestrates systemic metabolism, dynamically coordinating glucose uptake and fuel use to match energy demand. In Duchenne muscular dystrophy, loss of dystrophin derails this control, exposing a hidden metabolic weakness. In the mdx mouse, we show that physiological stress exposes a primary failure in insulin-stress axis integration: unchecked glucocorticoid signalling outpaces insulin secretion, driving systemic hyperglycaemia despite preserved muscle insulin sensitivity. These data support multi-tissue dystrophinopathy driving endocrine-metabolic decoupling. Skeletal muscle glycogen accumulates excessively and resists mobilisation under stress. The heart maintains high glucose uptake, whereas the brain remains glucose-limited, defining tissue-specific vulnerabilities. Acute insulin supplementation normalises systemic glucose uptake and rescues stress-induced behavioural deficits. Likewise, empagliflozin-mediated glucose offloading stabilises blood glucose and enhances muscle function to levels comparable with standard care prednisolone. These findings identify endocrine-metabolic decoupling as a central driver of metabolic fragility in DMD, correctable though insulin restoration or targeted glucose redirection. Competing Interest Statement The authors have declared no competing interest.

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last seen: 2026-05-20T01:45:00.602351+00:00