Decoding muscle-resident Schwann cell dynamics during neuromuscular junction remodeling
Steve D. Guzman, Ahmad Abu-Mahfouz, Carol S. Davis, Lloyd P. Ruiz, Peter C.D. Macpherson, Susan V. Brooks
Steve D. Guzman, Ahmad Abu-Mahfouz, Carol S. Davis, Lloyd P. Ruiz, Peter C.D. Macpherson, Susan V. Brooks
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Research Article Cell biology Muscle biology

Decoding muscle-resident Schwann cell dynamics during neuromuscular junction remodeling

Abstract

In this study, we used single-cell RNA sequencing to delineate the contributions of muscle-resident Schwann cells to neuromuscular junction (NMJ) remodeling by comparing a model of stable innervation with models of reinnervation following partial or complete denervation. We discovered multiple distinct Schwann cell subtypes, including a terminal Schwann cell subtype integral to the denervation-reinnervation cycle, identified by a transcriptomic signature indicative of cell migration and polarization. The data also characterize 3 myelin Schwann cell subtypes, which are distinguished based on enrichment of genes associated with myelin production, mesenchymal differentiation, or collagen synthesis. Importantly, SPP1 signaling emerged as a pivotal regulator of NMJ dynamics, promoting Schwann cell proliferation and muscle reinnervation across nerve injury models. These findings advance our understanding of NMJ maintenance and regeneration and underscore the therapeutic potential of targeting specific molecular pathways to treat neuromuscular and neurodegenerative disorders.

Authors

Steve D. Guzman, Ahmad Abu-Mahfouz, Carol S. Davis, Lloyd P. Ruiz, Peter C.D. Macpherson, Susan V. Brooks

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Figure 1

Characterization of muscle denervation in WT and Sod1–/– mice and muscle-resident Schwann cell subtypes across different denervation states via scRNA-Seq.

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Characterization of muscle denervation in WT and Sod1–/– mice and muscle...
(A and B) Maximum tetanic contraction forces (N/cm2) generated by nerve stimulation and direct muscle stimulation in WT mice 7 days post sciatic nerve crush injury (7 dpi) (A) and in S100GFP-tg Sod1–/– mice (B), compared to age-matched WT controls (n = 4 per genotype). (C) Comparison of maximum isometric force ratios elicited by nerve versus direct muscle stimulation across 1–3 months in S100GFP-tg Sod1–/– (n = 3–5) and control mice (n = 3–5). (D) Percentage of denervated NMJs in gastrocnemius muscles of S100GFP-tg and S100GFP-tg Sod1–/– mice aged 1–3 months. **P < 0.01; ***P < 0.001; ****P < 0.0001 by 2-way ANOVA with Tukey test for multiple testing correction. (E) Representative staining of NMJs showing Schwann cells (S100B; green), nerve terminals (NF/SV2; cyan), acetylcholine receptors (AChR; red), and nuclei (DAPI; blue) in 2-month-old S100GFP-tg control mice, S100GFP-tg mice 7 dpi and Sod1–/– mice without nerve injury. Scale bars: 25 μm. (F) Experimental workflow: Bilateral gastrocnemius (GTN) and tibialis anterior (TA) muscles were harvested from 2-month-old S100GFP-tg, S100GFP-tg Sod1–/–, and S100GFP-tg mice 7 dpi, followed by FACS to isolate GFP+ and GFP cells, then processed for scRNA-Seq using the 10X Chromium platform. (G) FACS plots showing gating strategies for GFP+PI single cells, with FMO (PI only) controls on the left. (H) UMAP plot visualizing 15 distinct cell clusters. (I) UMAP plots displaying transcript levels for myelin Schwann cell (mSC) markers (Mbp, Mpz), general Schwann cell markers (Sox10), Schwann cell repair phenotype (Ngfr), and terminal Schwann cells (tSC) (Cspg4, Kcnj10).