Rivka Ishai-Michaeli

Mammalian heparanase: gene cloning, expression and function in tumor progression and metastasis.

Heparan sulfate proteoglycans interact with many extracellular matrix constituents, growth factors and enzymes. Degradation of heparan sulfate by endoglycosidic heparanase cleavage affects a variety of biological processes. We have purified a 50-kDa heparanase from human hepatoma and placenta, and now report cloning of the cDNA and gene encoding this enzyme. Expression of the cloned cDNA in insect and mammalian cells yielded 65-kDa and 50-kDa recombinant heparanase proteins. The 50-kDa enzyme represents an N-terminally processed enzyme, at least 100-fold more active than the 65-kDa form. The heparanase mRNA and protein are preferentially expressed in metastatic cell lines and specimens of human breast, colon and liver carcinomas. Low metastatic murine T-lymphoma and melanoma cells transfected with the heparanase cDNA acquired a highly metastatic phenotype in vivo, reflected by a massive liver and lung colonization. This represents the first cloned mammalian heparanase, to our knowledge, and provides direct evidence for its role in tumor metastasis. Cloning of the heparanase gene enables the development of specific molecular probes for early detection and treatment of cancer metastasis and autoimmune disorders.

Heparanase as mediator of angiogenesis: mode of action

Extracellular matrix (ECM) and basement membranes (BMs) present a physical barrier that requires enzymatic degradation during endothelial cell (EC) sprouting at early stages of angiogenesis. These multimolecular structures also serve as a storage depot for heparin‐binding angiogenic factors. Heparan sulfate proteoglycans (HSPGs) are responsible for the self‐assembly and integrity of the ECM and BM structure, as well as for sequestration of growth and differentiation factors. Recently, we reported the cloning of heparanase, an endo‐β‐d‐glucuronidase degrading heparan sulfate (HS), and provided direct evidence for its role in tumor metastasis. We now demonstrate that heparanase is intimately involved in angiogenesis and elucidate its mode of action. Apart from its direct involvement in ECM degradation and EC migration (vascular sprouting), heparanase releases active basic fibroblast growth factor (bFGF) from the subendothelial ECM, as well as bFGF‐stimulating HS degradation fragments from the EC surface. Interestingly, ECM‐derived HS fragments induced little or no potentiation of the growth‐promoting activity of bFGF. The angiogenic effect of heparanase was demonstrated in vivo (via the Matrigel plug assay) by showing a three‐ to fourfold increase in neovascularization induced by murine T‐lymphoma cells after stable transfection with the heparanase gene. Increased tissue vascularity was also observed in a mouse wound‐healing model in response to topical administration of recombinant heparanase. Immunohistochemical staining of human colon carcinoma tissue revealed a high expression of the heparanase protein in the endothelium of sprouting capillaries and small vessels, but not of mature quiescent blood vessels. The ability of heparanase to promote tumor angiogenesis and its involvement in tumor metastasis make it a promising target for cancer therapy.

Extracellular matrix-resident growth factors and enzymes: possible involvement in tumor metastasis and angiogenesis

SummaryNeoplastic cells require an appropriate pericellular environment and new formation of stroma and blood vessels in order to constitute a soilid tumor. Tumor progression also involves degradation of various extracellular matrix (ECM) constituents. In this review we have focused on the possible involvement of ECM-resident growth factors and enzymes in neovascularization and cell invasion. We demonstrate that the pluripotent angiogenic factor, basic fibroblast growth factor (bFGF) is an ECM component required for supporting cell proliferation and differentiation. Basic FGF has been identified in the subendothelial ECM producedin vitro and in basement membranes of the cornea and blood vesselsin vivo. Despite the ubiquitous presence of bFGF in normal tissues, endothelial cell (EC) proliferation in these tissues is usually very low, suggesting that bFGF is somehow sequestered from its site of action. Our results indicate that bFGF is bound to heparan sulfate (HS) in the ECM and is released in an active form when the ECM-HS is degraded by cellular heparanase. We propose that restriction of bFGF bioavailability by binding to ECM and local regulation of its release, provides a novel mechanism for regulation of capillary blood vessel growth in normal and pathological situations. Heparanase activity correlates with the metastatic potential of various tumor cells and heparanase inhibiting molecules markedly reduce the incidence of lung metastasis in experimental animals. Heparanase may therefore participate in both tumor cell invasion and angiogenesis through degradation of the ECM-HS and mobilization of ECM-resident EC growth factors. The subendothelial ECM contains also tissue type- and urokinase type- plasminogen activators (PA), as well as PA inhibitor which may regulate cell invasion and tissue remodeling. Heparanase and the ECM-resident PA participate synergistically in sequential degradation of HS-proteoglycans in the ECM. These results together with similar observations on the properties of other ECM-immobilized enzymes and growth factors, suggest that the ECM provides a storage depot for biologically active molecules which are thereby stabilized and protected. This may allow a more localized, regulated and persistent mode of action, as compared to the same molecules in a fluid phase.

Degradation of heparan sulfate in the subendothelial extracellular matrix by a readily released heparanase from human neutrophils. Possible role in invasion through basement membranes.

Freshly isolated human neutrophils were investigated for their ability to degrade heparan sulfate proteoglycans in the subendothelial extracellular matrix (ECM) produced by cultured corneal and vascular endothelial cells. The ECM was metabolically labeled with Na2(35S)O4 and labeled degradation products were analyzed by gel filtration over Sepharose 6B. More than 90% of the released radioactivity consisted of heparan sulfate fragments 5-6 times smaller than intact heparan sulfate side chains released from the ECM by either papain or alkaline borohydride. These fragments were sensitive to deamination with nitrous acid and were not produced in the presence of either heparin or serine protease inhibitors. In contrast, degradation of soluble high molecular weight heparan sulfate proteoglycan, which was first released from the ECM, was inhibited by heparin but there was no effect of protease inhibitors. These results indicate that interaction of human neutrophils with the subendothelial ECM is associated with degradation of its heparan sulfate by means of a specific, newly identified, heparanase activity and that this degradation is facilitated to a large extent by serine proteases. The neutrophil heparanase was readily and preferentially released (15-25% of the cellular content in 60 min) by simply incubating the cells at 4 degrees C in the absence of added stimuli. Under these conditions, less than 5% of the cellular content of lactate dehydrogenase, lysozyme, and globin degrading proteases was released. Further purification of the neutrophil heparanase was achieved by its binding to heparin-Sepharose and elution at 1 M NaCl. It is suggested that heparanase activity is involved in the early events of extravasation and diapedesis of neutrophils in response to a threshold signal from an extravascular inflamed organ.

Inhibition of heparanase activity and tumor metastasis by laminarin sulfate and synthetic phosphorothioate oligodeoxynucleotides.

Heparanase activity correlates with the metastatic potential of tumor cells. Moreover, the anti‐metastatic effect of non‐anti‐coagulant species of heparin and certain sulfated polysaccharides was attributed to their heparanase‐inhibiting activity. We investigated the effect of a chemically sulfated polysaccharide (laminarin), consisting primarily of beta‐1,3 glucan (sodium laminarin), and of synthetic phosphorothioate oligodeoxynucleotides, primarily phosphorothioate homopolymer of cytidine (SdC28), on heparanase activity and tumor metastasis. Investigation of the ability of tumor cells to degrade heparan sulfate in intact extracellular matrix revealed that heparanase activity expressed by B16‐BL6 mouse melanoma cells and 13762 MAT rat mammary adenocarcinoma cells was effectively inhibited by LS (50% inhibition at 0.2–1 μg/ml), but there was no inhibition by sodium laminarin up to a concentration of 50 μg/ml. Complete inhibition of the melanoma heparanase was obtained in the presence of 0.1 μM SdC28. A single i.p. injection of laminarin sulfate, but not of sodium laminarin, before i.v. inoculation of the melanoma or breast‐carcinoma cells inhibited the extent of lung colonization by the tumor cells by 80 to 90%. Similar inhibition was exerted by 0.1 μM SdC28. At the effective concentrations, both compounds had a small effect on proliferation of the tumor cells and on growth of the primary tumors in vivo. These results further emphasize the involvement of heparanase in tumor metastasis and the potential clinical application of diverse heparanase‐inhibiting molecules such as sulfated polysaccharides and synthetic polyanionic molecules. Int. J. Cancer 83:424–431, 1999.

Heparanase powers a chronic inflammatory circuit that promotes colitis-associated tumorigenesis in mice.

Ulcerative colitis (UC) is a chronic inflammatory bowel disease that is closely associated with colon cancer. Expression of the enzyme heparanase is clearly linked to colon carcinoma progression, but its role in UC is unknown. Here we demonstrate for what we believe to be the first time the importance of heparanase in sustaining the immune-epithelial crosstalk underlying colitis-associated tumorigenesis. Using histological specimens from UC patients and a mouse model of dextran sodium sulfate-induced colitis, we found that heparanase was constantly overexpressed and activated throughout the disease. We demonstrate, using heparanase-overexpressing transgenic mice, that heparanase overexpression markedly increased the incidence and severity of colitis-associated colonic tumors. We found that highly coordinated interactions between the epithelial compartment (contributing heparanase) and mucosal macrophages preserved chronic inflammatory conditions and created a tumor-promoting microenvironment characterized by enhanced NF-κB signaling and induction of STAT3. Our results indicate that heparanase generates a vicious cycle that powers colitis and the associated tumorigenesis: heparanase, acting synergistically with the intestinal flora, stimulates macrophage activation, while macrophages induce production (via TNF-α-dependent mechanisms) and activation (via secretion of cathepsin L) of heparanase contributed by the colon epithelium. Thus, disruption of the heparanase-driven chronic inflammatory circuit is highly relevant to the design of therapeutic interventions in colitis and the associated cancer.

Endogenous Basic Fibroblast Growth Factor Displaced by Heparin From the Lumenal Surface of Human Blood Vessels Is Preferentially Sequestered by Injured Regions of the Vessel Wall

BACKGROUND Proliferation of smooth muscle cells (SMCs) of the arterial wall in response to local injury is an important factor in vascular proliferative disorders. Among the growth factors that promote SMC proliferation is basic fibroblast growth factor (bFGF), which is characterized by a high affinity for heparin and is associated with heparan sulfate on cell surfaces and extracellular matrices. We investigated whether heparin can displace endogenous active bFGF from the lumenal surface of blood vessels, whether bFGF is preferentially bound to injured blood vessels, and whether a synthetic, polyanionic, heparin-mimicking compound (RG-13577) can prevent sequestration of bFGF by the vessel wall. METHODS AND RESULTS Injured and noninjured saphenous vein segments were perfused with or without heparin, in the absence or presence of 125I-bFGF and/or RG-13577 (a polymer of 4-hydroxyphenoxy acetic acid). Heparin displaced bFGF from the lumenal surface of the vein, and the released bFGF stimulated proliferation of SMCs. Likewise, systemic administration of heparin during open heart surgery resulted in a marked increase in plasma bFGF levels. Injured veins sequestered 125I-bFGF to a much higher extent than noninjured vein segments, both in the absence and presence of heparin. This sequestration was inhibited by compound RG-13577. CONCLUSIONS Despite its beneficial effects, heparin may displace active bFGF, which subsequently may be preferentially deposited on injured vessel walls, thus contributing to the pathogenesis of restenosis. This effect may be prevented by a synthetic heparin-mimicking compound.

Anti-heparanase monoclonal antibody enhances heparanase enzymatic activity and facilitates wound healing

Heparanase is a mammalian endo‐β‐D‐glucuronidase capable of cleaving HS side chains at a limited number of sites, activity that is strongly implicated in tumor metastasis, neovascularization, inflammation, and autoimmunity. Clinically, up‐regulation of heparanase mRNA and protein expression has been documented in a variety of primary human tumors, correlating with reduced postoperative survival and increased lymph node and distant metastasis, thus providing strong clinical support for the prometastatic feature of the enzyme and making it an attractive target for the development of anticancer and anti‐inflammatory drugs. Screening a panel of monoclonal antibodies for their ability to inhibit heparanase enzymatic activity, we noted that one hybridoma, 6F8, exhibited the opposite effect and significantly enhanced heparanase activity. Here, we provide evidence that antibody 6F8 enhances the activity of recombinant and cellular heparanase, facilitates invasion of tumor‐derived cells in vitro, and improves wound healing in a mouse punch model in vivo. These results support a role of hepara‐nase in the course of wound healing and, moreover, suggest that monoclonal antibodies can be applied clinically for the enhancement, rather than inhibition, of certain enzymes.— Gingis‐Velitski S., Ishai‐Michaeli, R., Vlodavsky, I., Ilan N. Anti‐heparanase monoclonal antibody enhances heparanase enzymatic activity and facilitates wound healing. FASEB J. 21, 3986–3993 (2007)

Structure–activity relationships of heparin‐mimicking compounds in induction of bFGF release from extracellular matrix and inhibition of smooth muscle cell proliferation and heparanase activity

A series of nine synthetic polyaromatic compounds were synthesized by polymerization of aromatic ring monomers with formaldehyde, which yield substantially ordered backbones with different functional anionic groups (hydroxyl and carboxyl) on the phenol ring. These compounds were tested for their heparin‐mimicking activity: (1) inhibition of heparanase activity; (2) inhibition of SMC proliferation; and (3) release of bFGF from the ECM. We demonstrate that compounds that have two hydroxyl groups para and ortho to the carboxylic group and a carboxylic group at a distance of two carbons from the phenol ring inhibit heparanase activity and SMC proliferation, as well as induced an almost complete release of bFGF from ECM. Addition of a methyl group next to the carboxylic group led to a preferential inhibition of heparanase activity. Similar results were obtained with a compound that contains one hydroxyl group para to the carboxylic group and an ether group near the carboxylic group on the phenol ring. Preferential inhibition of SMC proliferation was best achieved when the position of the hydroxyl group is para and ortho to the carboxylic group and the carboxylic group is at a distance of one carbon from the phenol ring. On the other hand, for maximal release of bFGF from ECM, the position of the carboxylic group should be three carbons away from the phenol ring. These new heparin‐mimicking compounds may have a potential use in inhibition of tumor metastasis, arteriosclerosis, and inflammation.

The extracellular matrix produced by bovine corneal endothelial cells contains progelatinase A

Progelatinase A is a matrix metalloproteinase involved in the turnover of extracellular matrix (ECM). We report that the ECM produced by bovine corneal endothelial (BCE) cells contains progelatinase A free of tissue inhibitor of metalloproteinase (TIMP2). The matrix‐bound progelatinase A can be activated by APMA to generate a 62 kDa and a 45 kDa species with enzymatic activity and is inhibited by TIMP2. The bound progelatinase can be released after treatment of the ECM with gelatinase B. These studies suggest that the ECM can function as a reservoir for progelatinase A which may be readily available for cells in processes such as metastasis, angiogenesis, inflammation and wound healing.