Cell Surface Proteome of Dental Pulp Stem Cells Identified by Label-Free Mass Spectrometry.

Multipotent mesenchymal stromal cells (MSCs) are promising tools for regenerative medicine. They can be isolated from different sources based on their plastic-adherence property. The identification of reliable cell surface markers thus becomes the Holy Grail for their prospective isolation. Here, we determine the cell surface proteomes of human dental pulp-derived MSCs isolated from single donors after culture expansion in low (2%) or high (10%) serum-containing media. Cell surface proteins were tagged on intact cells using cell impermeable, cleavable sulfo-NHS-SS-biotin, which allows their enrichment by streptavidin pull-down. For the proteomic analyses, we first compared label-free methods to analyze cell surface proteomes i.e. composition, enrichment and proteomic differences, and we developed a new mathematical model to determine cell surface protein enrichment using a combinatorial gene ontology query. Using this workflow, we identified 101 cluster of differentiation (CD) markers and 286 non-CD cell surface proteins. Based on this proteome profiling, we identified 14 cell surface proteins, which varied consistently in abundance when cells were cultured under low or high serum conditions. Collectively, our analytical methods provide a basis for identifying the cell surface proteome of dental pulp stem cells isolated from single donors and its evolution during culture or differentiation. Our data provide a comprehensive cell surface proteome for the precise identification of dental pulp-derived MSC populations and their isolation for potential therapeutic intervention.

Liposome-based assays to study membrane-associated protein networks.

Transport carriers regulate the bidirectional flow of membrane between the compartments of the secretory and endocytic pathways. Their biogenesis relies on the recruitment of a number of cytosolic proteins and protein complexes on specific membrane microdomains with defined protein and lipid compositions. The timely assembly of these cellular machines onto membranes involves multiple protein-protein and protein-lipid interactions and is necessary to select membrane proteins and lipids into nascent carriers, to bend the flat membrane of the donor compartment, to change the shape of this nascent carrier into a tubular-vesicular structure, and to operate its scission from the donor compartment. A challenge in this field of membrane cell biology has been to identify these machineries and to understand their precise function, in particular by studying their spatial and temporal dynamics during carrier biogenesis. During the past years, liposome-based synthetic biology fully recapitulating the fidelity of carrier biogenesis as seen in vivo has proved to be instrumental to identify these key cytosolic components using mass spectrometry and their dynamics using fluorescence microscopy. We describe here the methods to isolate on synthetic membranes the protein networks needed for carrier biogenesis, to identify them using label-free quantitative proteomics, and to visualize their dynamics on giant unilamellar vesicles.