Glutamine deficiency enhances nuclear localization of TCA cycle enzymes and epigenetic modifications, impairing myogenesis
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Objective
Skeletal muscle myogenesis, during development and regeneration, are primarily facilitated by the progeny of resident muscle stem cells, the muscle progenitor cells (MPCs). Intriguingly, extracellular glutamine (Gln) is required by MPCs. Disruptions in Gln availability or metabolism, impair MPC function and hinder skeletal muscle regeneration. Gln, a nutritionally non-essential amino acid (NEAA), which is most abundant in skeletal muscle, becomes conditionally essential during advancing age and catabolic states like sepsis, trauma, and strenuous situations. The intracellular mechanisms through which extracellular Gln availability affects MPC proliferation are poorly understood. Therefore, this study was aimed to examine how extracellular supply of Gln influences myogenesis through the spatial distribution of TCA-cycle enzymes.
Methods
Human primary muscle myoblasts (HSKM2) and murine MPCs (C2C12) were utilized for in-vitro experiments. To investigate the impact of Gln availability on MPC proliferation, proliferation assays, confocal imaging, succinyl-proteomics, and single-cell nuclei ATAC sequencing were used.
Results
Gln (2 mM) significantly enhanced MPC viability and cell cycle progression, while Gln depletion (0 mM) reduced cell number and induced G0/G1 arrest. Gln deficiency downregulated MyoD expression, impairing myogenic potential. Inhibiting intracellular Gln metabolism also limited proliferation, indicating the necessity of Gln catabolism for cell proliferation. Gln deficiency increased nuclear localization of TCA cycle enzymes (DLST, OGDH), elevated histone succinylation, and restricted chromatin accessibility of the myogenic regulatory factor, MyoD1, highlighting a Gln dependent metabolic-epigenetic nexus in myogenic regulation.
Conclusion
These findings demonstrate that extracellular Gln availability is a key regulator of myogenesis through its influence on metabolism, epigenetic modifications, and chromatin accessibility.
