Spatiotemporal mapping of immune and stem cell dysregulation after volumetric muscle loss
Jacqueline A. Larouche, Emily C. Wallace, Bonnie D. Spence, Eric Buras, Carlos A. Aguilar
Jacqueline A. Larouche, Emily C. Wallace, Bonnie D. Spence, Eric Buras, Carlos A. Aguilar
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Resource and Technical Advance Muscle biology Stem cells

Spatiotemporal mapping of immune and stem cell dysregulation after volumetric muscle loss

Abstract

Volumetric muscle loss (VML) is an acute trauma that results in persistent inflammation, supplantation of muscle tissue with fibrotic scarring, and decreased muscle function. The cell types, nature of cellular communication, and tissue locations that drive the aberrant VML response have remained elusive. Herein, we used spatial transcriptomics on a mouse model of VML and observed that VML engenders a unique spatial profibrotic pattern driven by crosstalk between fibrotic and inflammatory macrophages and mesenchymal-derived cells. The dysregulated response impinged on muscle stem cell–mediated repair, and targeting this circuit resulted in increased regeneration and reductions in inflammation and fibrosis. Collectively, these results enhance our understanding of the cellular crosstalk that drives aberrant regeneration and provides further insight into possible avenues for fibrotic therapy exploration.

Authors

Jacqueline A. Larouche, Emily C. Wallace, Bonnie D. Spence, Eric Buras, Carlos A. Aguilar

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Figure 2

Signaling pathways between macrophages, mesenchymal-derived cells, and muscle stem cells after VML are predominantly profibrotic at 7 dpi.

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Signaling pathways between macrophages, mesenchymal-derived cells, and m...
(A) Chord diagram displaying all significant interactions between macrophages, mesenchymal-derived cells, and muscle stem cells determined using CellChat on the scRNA-Seq reference data set. Interactions with P < 0.05 based on CellChat’s permutation test were considered significant. (B) Representative gene module overlays for the ligands and receptors predicted to be involved in significant cell-to-cell interactions show spatial proximity in the defect and transition zones. (C) Average ligand and receptor module scores across zones demonstrates higher scores for Mø and MDC signaling molecules in the defect zone, increased mesenchymal-derived signaling molecules in the transition zone compared with the intact zone, and higher MuSC module scores in the transition and intact zones. ***P < 0.001, **P < 0.01, *P < 0.05, by 1-way ANOVA with Tukey’s post hoc analysis. n = 4 tissues from 2 male and 2 female mice. Magnification, 20×.