Anti-tumor activity of the novel angiogenesis inhibitor anginex.

Anginex is a novel cytokine-like peptide with potent anti-angiogenic activity, which operates specifically against angiogenically-activated endothelial cells via prevention of cell adhesion/migration on the extracellular matrix and subsequent induction of apoptosis. Here, we demonstrate that anginex inhibits tumor growth in vivo in mouse xenograft models. In the MA148 ovarian carcinoma model, tumor growth was inhibited dose-dependently by up to 80% when systemically administered via osmotic mini-pumps starting at the time of tumor cell inoculation. The optimal dose was found to be 10 mg/kg per day. When tested against established tumors, mini-pump-administered anginex demonstrated essentially the same effectivity at this optimal dose, whereas once or twice-daily injections were only half as effective. When anginex was conjugated to human serum albumin, effectivity was significantly improved, most likely due to increased bioavailability of the conjugate. Immunohistochemical analysis of microvessel density indicated that the anti-tumor activity of anginex is mediated by angiogenesis inhibition. This was confirmed in an in vitro angiogenesis assay based on tube formation in a collagen gel. Animals demonstrated no signs of toxicity as judged by unaltered behavior, normal weight gain, blood markers and macro- and microscopic morphology of internal organs upon autopsy. Overall, these in vivo studies indicate that anginex is an effective anti-tumor agent.

Beta-sheet is the bioactive conformation of the anti-angiogenic anginex peptide.

Anginex is a designed peptide 33mer that functions as a cytokine-like agent to inhibit angiogenesis. Although this short linear peptide has been shown by NMR and CD to form a nascent beta-sheet conformation in solution, the actual bioactive structure formed upon binding to its receptor on the surface of endothelial cells could be quite different. By using a series of double-cysteine disulphide-bridged analogues, we provide evidence in the present study that the beta-sheet is in fact the bioactive conformation of anginex. CD and NMR spectral analysis of the analogues indicate formation of a beta-sheet conformation. Three functional assays, endothelial cell proliferation, apoptosis and in vitro angiogenesis, were performed on all analogues. As long as the placement of disulphide bonds preserved the beta-strand alignment, as in the proposed bioactive conformation, bioactivities were preserved. Knowledge of the bioactive conformation of anginex will aid in the design of smaller molecule mimetics of this potent anti-angiogenic peptide.

Design of a partial peptide mimetic of anginex with antiangiogenic and anticancer activity.

Based on structure-activity relationships of the angiostatic beta-sheet-forming peptide anginex, we have designed a mimetic, 6DBF7, which inhibits angiogenesis and tumor growth in mice. 6DBF7 is composed of a beta-sheet-inducing dibenzofuran (DBF)-turn mimetic and two short key amino acid sequences from anginex. This novel antiangiogenic molecule is more effective in vivo than parent anginex. In a mouse xenograft model for ovarian carcinoma, 6DBF7 is observed to reduce tumor growth by up to 80%. It is suggested that the activity is based on antiangiogenesis, because in vitro tube formation is inhibited, and because treatment of tumor-bearing mice led to a significant reduction in microvessel density within the tumor. This partial peptide mimetic is the first endothelial cell-specific molecule designed as a substitute for an angiostatic inhibitory peptide.