A proteomic view on the differential phenotype of Schwann cells derived from mouse sensory and motor nerves

Schwann cells (SCs) are myelin-forming glial cells of the peripheral nervous system. Recent studies suggested that SCs comprise two phenotypes: sensory SCs and motor SCs, which are associated with the modality-specific promotion of sensory and motor axon growth during peripheral neuronal regeneration. However, the molecular basis of the two phenotypic SCs is unclear. We established a workflow to obtain highly purified SCs derived from sensory nerve (SNdSCs) and motor nerve (MNdSCs) from B6; D2-Tg(s100B-EGFP)1Wjt/J mice. Subsequently, a quantitative proteomic analysis based on iTRAQ labeling was performed to compare the proteome of SNdSCs and MNdSCs. A total of 6,567 proteins were identified, of which 63 and 11 proteins were overexpressed in SNdSCs and MNdSCs, respectively. Three of the overexpressed proteins were further validated by western blot and immunocytochemistry: GMFB and CNPase, which were overexpressed in sensory SNdSCs, and histone H4, which was overexpressed in MNdSCs. The expression pattern of the three proteins was also validated in the dorsal roots and ventral roots. Bioinformatics analysis indicated that proteins highly expressed in SNdSCs are mainly involved in RNA processing and protein synthesis, while those overexpressed in MNdSCs are related to cell proliferation. Real-time cell analysis confirmed that the proliferation activity of MNdSCs is higher than that of SNdSCs. This study is the first to provide a proteomic view of the differential phenotype of mouse SNdSCs and MNdSCs. The data may serve as a valuable source for the study of the biological characteristics of these two SC phenotypes and their roles in nerve-specific regeneration.

Automated summary

This study provides a proteomic view of the differential phenotype of mouse SNdSCs and MNdSCs. The data may serve as a valuable source for studying the biological characteristics and roles of these two SC phenotypes in nerve-specific regeneration.