Douglas Y Smith scite author profile

Hereditary muscle diseases are disabling disorders lacking effective treatments. UDP-N-acetylglucosamine-2-epimerase/N-acetylmannosamine kinase (GNE) myopathy (GNEM) is an autosomal recessive distal myopathy with rimmed vacuoles typically manifesting in late adolescence/early adulthood. GNE encodes the rate-limiting enzyme in sialic acid biosynthesis, which is necessary for the proper function of numerous biological processes. Outside of the causative gene, very little is known about the mechanisms contributing to the development of GNE myopathy. In the present study, we aimed to address this knowledge gap by querying the underlying mechanisms of GNE myopathy using a patient-derived induced pluripotent stem-cell (iPSC) model. Control and patient-specific iPSCs were differentiated down a skeletal muscle lineage, whereby patient-derived GNEM iPSC clones were able to recapitulate key characteristics of the human pathology and further demonstrated defects in myogenic progression. Single-cell RNA sequencing time course studies revealed clear differences between control and GNEM iPSC-derived muscle precursor cells (iMPCs), while pathway studies implicated altered stress and autophagy signaling in GNEM iMPCs. Treatment of GNEM patient-derived iMPCs with an autophagy activator improved myogenic differentiation. In summary, we report an in vitro, iPSC-based model of GNE myopathy and implicate defective myogenesis as a contributing mechanism to the etiology of GNE myopathy.

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Myogenesis defects in a patient-derived iPSC model of hereditary GNE myopathy

Schmitt

Smith

Cho

et al. 2021

Preprint

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Hereditary muscle diseases are disabling disorders lacking effective treatments. UDP-N-acetylglucosamine-2-epimerase/N-acetylmannosamine kinase (GNE) myopathy is an autosomal recessive distal myopathy with rimmed vacuoles that typically manifests in late adolescence/early adulthood. GNE encodes an enzyme that is the rate-limiting step in sialic acid biosynthesis which is necessary for proper function of numerous biological processes. Outside of the causative gene, very little is known about the mechanisms contributing to the development of GNE myopathy. In the present study we aimed to address this knowledge gap by querying underlying mechanisms of GNE myopathy using a patient-derived induced pluripotent stem cell (iPSC) model. Muscle and skin biopsies were acquired from two patients with GNE myopathy that presented with distinct histopathological features. Control and patient-specific iPSCs were derived from skin fibroblasts and differentiated down a skeletal muscle lineage in a three-stage process analogous to muscle development and muscle regeneration. Initial studies revealed: 1) the ability of patient-derived GNE iPSC clones to recapitulate key characteristics of the human pathology including TDP-43 accumulation and evidence of dysregulated autophagy, and 2) a striking defect in myogenic progression of the more severe GNE iPSC clone. Single-cell RNA sequencing time course studies were then performed to more rigorously explore myogenesis defects. Cluster-based bioinformatics analyses revealed clear differences between control and GNE iPSC-derived muscle precursor cells (iMPCs). On a transcriptional level, late stage GNE iMPCs resembled that of early stage control iMPCs, confirming stalled myogenic progression on a molecular level. Comparative expression and pathway studies revealed EIF2 signaling as a top signaling pathway altered in GNE iMPCs. In summary, we report a novel in vitro, iPSC-based model of GNE myopathy and implicate defective myogenesis as a likely novel contributing mechanism to the etiology of GNE myopathy.SUMMARY STATEMENTDevelopment of a novel cell-based model of GNE myopathy, utilizing GNE patient-derived samples, which recapitulates human disease characteristics, uncovered myogenic differentiation defects, and can elucidate possible mechanistic contributors to the disease.

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Douglas Y Smith

Myogenesis defects in a patient-derived iPSC model of hereditary GNE myopathy

Myogenesis defects in a patient-derived iPSC model of hereditary GNE myopathy

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