The designer anti-angiogenic peptide anginex targets tumor endothelial cells and inhibits tumor growth in animal models.

The de novo designed angiogenesis inhibitor anginex was tested in vitro and in vivo for its mechanism of action and antitumor activity. The data presented here demonstrate that anginex is a powerful antiangiogenic agent with significant antitumor activity. The mechanism of action of anginex was found to be the induction of anoikis leading to apoptosis in angiogenically activated endothelial cells, resulting in an up to 90% inhibition of migration in the wound assay. Anginex inhibited angiogenesis as demonstrated in the in vitro mouse aortic ring assay. In addition, tumor-induced angiogenesis in the chick chorioallantoic membrane was markedly inhibited. Anginex showed profound antitumor activity in the syngeneic mouse B16F10 melanoma model and in a xenograft human tumor model. Microvessel density determination as well as magnetic resonance imaging showed that the antitumor activity in these tumor models resulted from the antiangiogenic activity of anginex. A complete absence of toxicity was observed in these models. The data presented here demonstrate that anginex is a promising agent for further clinical development.

Design of nonpeptidic topomimetics of antiangiogenic proteins with antitumor activities.

The inhibition of angiogenesis is a promising avenue for cancer treatment. Although some angiostatic compounds are in the process of development and testing, these often prove ineffective in vivo or have unwanted side effects. We have designed, synthesized, and evaluated a small library of nonpeptidic, calixarene-based protein surface topomimetics that display chemical substituents to approximate the molecular dimensions and amphipathic features (hydrophobic and positively charged residues) of the antiangiogenic peptide anginex, which, like many antiangiogenic proteins, consists primarily of an antiparallel beta-sheet structure as the functional unit. Two of the topomimetics (0118 and 1097) were potent angiogenesis inhibitors in vitro, as determined by endothelial cell proliferation, migration, and chick embryo chorioallantoic membrane assays. Moreover, both compounds were highly effective at inhibiting tumor angiogenesis and growth in two mouse models (MA148 human ovarian carcinoma and B16 murine melanoma). Our results demonstrate the feasibility of designing nonpeptidic protein surface topomimetics as novel pharmaceutical agents for clinical intervention against cancer through angiostatic or other mechanisms.

Platelet factor 4 and interleukin-8 CXC chemokine heterodimer formation modulates function at the quaternary structural level.

The apparent complexity of biology increases as more biomolecular interactions that mediate function become known. We have used NMR spectroscopy and molecular modeling to provide direct evidence that tetrameric platelet factor-4 (PF4) and dimeric interleukin-8 (IL8), two members of the CXC chemokine family, readily interact by exchanging subunits and forming heterodimers via extension of their antiparallel beta-sheet domains. We further demonstrate using functional assays that PF4/IL8 heterodimerization has a direct and significant consequence on the biological activity of both chemokines. Formation of heterodimers enhances the anti-proliferative effect of PF4 on endothelial cells in culture, as well as the IL8-induced migration of CXCR2 vector-transfected Baf3 cells. These results suggest that CXC chemokine biology, and perhaps cytokine biology in general, may be functionally modulated at the molecular level by formation of heterodimers. This concept, in turn, has implications for designing chemokine/cytokine variants with modified biological properties.

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.

Vascular targeting effect of combretastatin A-4 phosphate dominates the inherent angiogenesis inhibitory activity.

The current research aimed to define hypothesis-based anti-angiogenic properties of the vascular targeting agent combretastatin A-4 phosphate (combreAp). The in vitro wound assay indicated that combreAp potently inhibited migration of endothelial cells (EC). A significant inhibition of migration could already be measured after 2 hr of treatment. In a three-dimensional (3D) tube formation assay, combreAp inhibited sprout formation at concentrations that did not inhibit the proliferation of EC. At sub-ng concentrations the half-maximal response was reached. Interestingly, although combreAp is considered a vascular targeting agent, the human tumor cell lines tested were found to be 20-30 times more sensitive for combreAp than the human umbilical vein endothelial cells (HUVEC). A similar response difference between rat EC and R1 rat rhabdomyosarcoma tumor cells was observed. The growth inhibition in EC was only in part mediated by induction of apoptosis. The growth delay results obtained with the in vivo rodent tumor models involving repeat dosing of combreAp can partly be explained by anti-angiogenic activity of the compound. The results obtained with the various in vitro and in vivo assays substantiate an anti-angiogenic profile of combreAp, largely at the level of EC migration. This mechanism may operate to a different extent in different tumor types.