Cellular mechanisms of acute rhabdomyolysis in inherited metabolic diseases

Author:

de Calbiac Hortense1,Imbard Apolline234,de Lonlay Pascale14ORCID

Affiliation:

1. INSERM U1151, Institut Necker Enfants‐Malades (INEM) Université Paris Cité Paris France

2. Service de Biochimie, Hôpital Universitaire Necker‐Enfants Malades Assistance Publique‐Hôpitaux de Paris (AP‐HP) Paris France

3. Faculté de pharmacie LYPSIS, Université Paris Saclay Orsay France

4. Reference Center for Inherited Metabolic Diseases Necker‐Enfants‐Malades University Hospital, APHP, Imagine Institute, Filière G2M, MetabERN Paris France

Abstract

AbstractAcute rhabdomyolysis (RM) constitutes a life‐threatening emergency resulting from the (acute) breakdown of skeletal myofibers, characterized by a plasma creatine kinase (CK) level exceeding 1000 IU/L in response to a precipitating factor. Genetic predisposition, particularly inherited metabolic diseases, often underlie RM, contributing to recurrent episodes. Both sporadic and congenital forms of RM share common triggers. Considering the skeletal muscle's urgent need to rapidly adjust to environmental cues, sustaining sufficient energy levels and functional autophagy and mitophagy processes are vital for its preservation and response to stressors. Crucially, the composition of membrane lipids, along with lipid and calcium transport, and the availability of adenosine triphosphate (ATP), influence membrane biophysical properties, membrane curvature in skeletal muscle, calcium channel signaling regulation, and determine the characteristics of autophagic organelles. Consequently, a genetic defect involving ATP depletion, aberrant calcium release, abnormal lipid metabolism and/or lipid or calcium transport, and/or impaired anterograde trafficking may disrupt autophagy resulting in RM. The complex composition of lipid membranes also alters Toll‐like receptor signaling and viral replication. In response, infections, recognized triggers of RM, stimulate increased levels of inflammatory cytokines, affecting skeletal muscle integrity, energy metabolism, and cellular trafficking, while elevated temperatures can reduce the activity of thermolabile enzymes. Overall, several mechanisms can account for RMs and may be associated in the same disease‐causing RM.

Publisher

Wiley

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