Glioma cell integrin expression and their interactions with integrin antagonists

Summary A panel of human glioma cell explants was screened for integrin expression by flow cytometry using ανβ-specific antibodies. A lower percentage of the glioma cells were positive for the ανβ3 (mean % positive = 20.8%) integrin, whereas higher percentages were positive for the ανβ5 (mean % positive = 72.7%), VLA5α (mean % positive = 87%) and VLAβ1 (mean % positive = 41.7%) integrins. A series of RGD peptides was designed, synthesized and tested for binding to integrin receptors. Based on the results of the binding to the isolated integrin receptors and the expression of integrins on glioma cell lines, a peptide that binds potently to the ανβ3, ανβ5 and α5β1 was selected for further investigations with regards to its effect on glioma cells. The peptide, Ac-c[(Pen)-Tyr(Me)-Ala-ArgGly-Asp-Asn-Tic-Cys]NH2 (RGD peptide), exhibited high potential for use in clinical intracranial administration since it had good stability in rat brain cell homogenates placed into artificial cerebrospinal fluid. Using an HPLC method for quantification of peptides in rat brain cell homogenates, we could demonstrate the half-life of the RGD peptide approximated 20 hr. Relative to a scrambled peptide control (non-RGD sequence, same amino acids), the experimental RGD peptide significantly decreased glioma cell proliferation of the entire panel of rat and human glioma cells tested. Adhesion of recently passaged glioma cells to glioma-derived extracellular matrix protein-coated plates was inhibited significantly by the RGD peptide. The peptide also reversed attachment of plated glioma cells. The RGD peptide caused some, but not substantial, glioma cell injury, as evidenced by a quantitative in vitro nuclear DNA morphologic assay and by a flow cytometric assay employing 7-amino actinomycin D (7AAD). We histologically monitored for toxicity caused by various doses of the RGD peptide infused repeatedly into normal cannulated rat brain. At safe doses, the experimental RGD peptide-treated brains did not show significant differences from those infused with scrambled peptide or buffer-treated controls. In tumor-bearing brains, slightly smaller tumor areas were measured with a higher necrotic-to-tumor index in the RGD peptide treated relative to the scrambled peptide-treated controls. This was obtained with intracranial peptide administrations or combined intracranial and intraperitoneal injections. From this in vitro work, we conclude that the anti-glioma effects of the RGD peptide tested resulted from lowered glioma proliferation and adhesion/mobility, rather than from significant glioma cell injury in the timeframe analyzed. Although other mechanisms not discerned from our limited histopathological observations may be operational, from our in vivo work, we conclude that repeated administration of RGD peptide into brain is safe but that better delivery of the peptides to infiltrating tumor cells is necessary.