STEM-02. IN VIVO PHAGE DISPLAY IDENTIFIES PEPTIDE TARGETING N-CADHERIN ON GLIOMA STEM CELLS

Abstract

Abstract Glioblastoma (GBM) is the most aggressive primary brain tumor with high mortality rates and resistance to conventional therapy. Glioma stem cells (GSCs) comprise a sub-population of glioma tumor cells with the ability of self-renewal and tumor recapitulation, and may be responsible for GBM’s treatment resistant properties. Identification of surface receptors that are novel and specific to GSCs may be the key to the development of effective therapeutic strategies. We have selected a GSC specific targeting peptide isolated through in vitro and in vivo phage display biopanning. This screening technique allowed us to determine a peptide (GBM-IC2) which binds specifically to GSCs in vitro, and to GBM tissue in vivo. Although this screening process allows for isolation of cell specific targeting peptides, it does so without identification of the cellular binding partner. Given the specificity of the peptide, identification of the cellular receptor may allow for discovery of novel markers to identify GSCs. To identify the peptide binding partner of GBM-IC2, the biotinylated peptide was incubated with GSC protein lysate. The peptide, along with its binding partner, was isolated using streptavidin agarose resin. The binding partner protein was then identified using mass spectroscopy. This revealed N-cadherin (CDH2) as a potential binding partner for the GBM-IC2 peptide. GBM-IC2 demonstrated specificity for targeting CDH2 compared to control peptide using ELISA. Lentiviral induced overexpression of CDH2 in HEK293 cells allowed for GBM-IC2 peptide binding. Competition assay was performed by applying anti-CDH2 antibody to GBM-IC2 peptide and GSCs in culture. Application of anti-CDH2 antibody decreased peptide binding to GSCs, confirming CDH2 as the binding partner for GBM-IC2. These results demonstrate that cell specific targeting peptides isolated through phage display may lead to the isolation of novel cell specific proteins through immunoprecipitation isolation and mass spectroscopy analysis.