Abstract

Abstract Introduction/Objective In Neurofibromatosis Type 1 (NF1), caused by mutations in the NF1 tumor-suppressor gene, children form fibrotic nonunions known as pseudarthroses following long bone fractures. Here, we integrate spatial transcriptomics of human and murine samples to investigate the pathogenesis underlying pseudoarthrosis development. Methods/Case Report We performed spatial transcriptomics on 10-day post-fracture calluses from control and periosteum-specific Nf1-deficient (Nf1Postn) mice as well as a human NF1 patient pseudarthrosis specimen. Differential gene expression and SpatialTime analyses were performed. BMP signaling was validated by immunohistochemical staining of tissues for phospho-SMAD1/5/8. Results (if a Case Study enter NA) Spatial transcriptomics detected eight cell clusters, including bone, cartilage, and muscle within mouse fracture calluses. In the control, clusters involved in fracture repair were enriched for genes associated with extracellular matrix and collagen formation (progenitor and cartilage clusters), cartilage and endochondral bone processes (ossifying perichondrium cluster), and bone remodeling (woven bone cluster). Expression of TGF-beta pathway genes was highest near the fracture plane, while BMP and Wnt pathways were activated further from the fracture. In the Nf1Postn fracture, healing was significantly delayed, lacking a robust callus and with a lower abundance of reparative skeletal cell clusters. While expression of TGF-beta pathway genes was similar to control, BMP pathway expression was minimal within the Nf1Postn fracture, which was further demonstrated by a lack of phospho-SMAD1/5/8 staining. In the human pseudarthrosis, while TGF-beta pathway genes were expressed near the fracture plane as expected, there was no enrichment of BMP pathway expression in the pseudarthrosis tissue and no significant phospho-SMAD1/5/8 staining. Conclusion Spatial transcriptomics allows for the simultaneous unbiased analysis of multiple signal transduction pathways within their native tissue environment. Our analyses 1) revealed the cellular diversity required for fracture healing, 2) demonstrated the spatially-restricted expression of key morphogenetic pathways within a fracture callus, and 3) provides in situ evidence for impaired BMP pathway activation associated with NF1 fracture pseudarthroses.

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