The 72-kd type IV collagenase is a member of the collagenase enzyme family that has been closely linked with the invasive phenotype of cancer cells. Previous studies have shown that both normal cells and highly invasive tumor cells produce the 72-kd type IV procollagenase enzyme in a complexed form consisting of the proenzyme and a novel tissue inhibitor of metalloproteinases, TIMP-2. The balance between activated enzyme and available inhibitor is thought to be a critical determinant of the matrix proteolysis associated with a variety of pathologic processes, including tumor cell invasion. In the present study, we demonstrate that alteration of the metalloproteinase-metalloproteinase-inhibitor balance in favor of excess inhibitor blocks human fibrosarcoma HT-1080 tumor cell invasion of a reconstituted basement membrane. The HT-1080 cell line produces both the 72-kd and the 92-kd type IV collagenases. Alteration of the type IV collagenase-inhibitor balance was achieved by addition of free TIMP-2 or antibodies to 72-kd type IV collagenase. Native, purified TIMP-2 was inhibitory in the range of 1-25 micrograms/mL. Addition of specific antiserum against the 72-kd type IV collagenase, which did not cross-react with the 92-kd type IV collagenase, inhibited HT-1080 cell invasion to the same extent. These results suggest that metalloproteinases, in particular the 72-kd type IV collagenase, are critical for tumor cell invasion of the reconstituted basement membrane. Our findings demonstrate that addition of the endogenous inhibitor TIMP-2 is able to block invasion. Thus, we recommend initiation of in vivo studies of the therapeutic potential of TIMP-2 to block tumor cell invasion and intravasation into the circulation.
Angiostatin effectively blocks tumor angiogenesis through still poorly understood mechanisms. Given the close association between immune and vascular regulation, we investigated the effects of angiostatin on angiogenesis-associated leukocytes. Angiostatin inhibited the migration of monocytes and, even more markedly, neutrophils. Angiostatin blocked chemotaxis of neutrophils to CXCR2 chemokine receptor agonists (IL-8, MIP-2, and GROalpha), formyl-Met-Leu-Phe (fMLP), and 12-O-tetradecanoylphorbol 13-acetate, and repressed fMLP-induced mitochondrial activity. Two different angiostatin forms (kringles 1-4 and 1-3) were effective, whereas whole plasminogen had no effect. IL-8, MIP-2, and GROalpha induced intense angiogenic reactions in vivo, but no angiogenic response to these factors was observed in neutropenic mice, demonstrating an essential role for neutrophils. Angiostatin potently inhibited chemokine-induced angiogenesis in vivo, and consistent with in vitro observations, both angiostatin forms were active and whole plasminogen had little effect. Angiostatin inhibition of angiogenesis in vivo was accompanied by a striking reduction in the number of recruited leukocytes. In vivo, the inflammatory agent lipopolysaccharide also induced extensive leukocyte infiltration and angiogenesis that were blocked by angiostatin. Neutrophils expressed mRNAs for ATP synthase and angiomotin, two known angiostatin receptors. These data show that angiostatin directly inhibits neutrophil migration and neutrophil-mediated angiogenesis and indicate that angiostatin might inhibit inflammation.
We developed an in vivo gene therapy approach to characterize and optimize the anti-angiogenic activity of class I interferons (IFNs), using packaging cell lines producing an amphotropic LXSN-based retrovirus expressing either IFN-alpha1 (alpha1Am12), IFN-beta (betaAm12) murine cDNAs, or the vector alone (neoAm12). Pretreatment of endothelial-like Eahy926 cells in vitro with conditioned media (CM) from alpha1Am12 or betaAm12 cells for 48 hours significantly inhibited their migration and invasion as compared to neoAm12-CM-treated cells. betaAm12-CM also inhibited the formation of capillary-like structures on Matrigel by EAhy926 cells. In vivo, inclusion of the betaAm12 cells strongly inhibited, and alpha1Am12 partially inhibited, the angiogenic response in the Matrigel sponge model in both immune-competent and athymic nude mice. Electron microscopy showed a reduction of host cell infiltration in alpha1Am12- and betaAm12-containing sponges and reduction of invading tubular clefts of host cells as compared to controls. Finally, inoculation of either alpha1Am12 or betaAm12 cells (10%) along with a highly angiogenic Kaposi's sarcoma cell line (90%) resulted in a powerful reduction of tumor growth in nude mice in vivo, as did infection with the interferon-alpha-producing retroviruses. These data suggest that a gene therapy approach using class I interferons can effectively inhibit tumor angiogenesis and growth of vascular tumors.
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