Heparanase is an endo-B-D-glucuronidase involved in cleavage of heparan sulfate moieties and hence participates in extracellular matrix (ECM) degradation and remodeling. Traditionally, heparanase activity was correlated with the metastatic potential of a variety of tumor-derived cell types. Cloning of the heparanase gene indicated that heparanase expression is up-regulated in a variety of primary human tumors. In some cases, heparanase up-regulation correlated with increased tumor vascularity, an angiogenic feature that could be recapitulated in a number of in vitro and in vivo models. The mechanism by which heparanase enhances angiogenic responses is not entirely clear but is thought to be mediated primarily by release of ECM-resident angiogenic growth factors such as basic fibroblast growth factor and vascular endothelial growth factor (VEGF). Here, we examined the possibility that heparanase directly participates in VEGF gene regulation. We provide evidence that heparanase overexpression in human embryonic kidney 293, MDA-MB-435 human breast carcinoma, and rat C6 glioma cells resulted in a 3-to 6-fold increase in VEGF protein and mRNA levels, which correlated with elevation of p38 phosphorylation. Moreover, heparanase down-regulation in B16 mouse melanoma cells by a specific siRNA vector was accompanied by a decrease in VEGF and p38 phosphorylation levels, suggesting that VEGF gene expression is regulated by endogenous heparanase. Interestingly, a specific p38 inhibitor did not attenuate VEGF up-regulation by heparanase whereas Src inhibitors completely abrogated this effect. These results indicate, for the first time, that heparanase is actively involved in the regulation of VEGF gene expression, mediated by activation of Src family
Heparanase is a heparan sulfate degrading endoglycosidase participating in extracellular matrix degradation and remodeling. Heparanase is synthesized as a 65 kDa non-active precursor that subsequently undergoes proteolytic cleavage, yielding 8 kDa and 50 kDa protein subunits that heterodimerize to form an active enzyme. The protease responsible for heparanase processing is currently unknown, as is the sub-cellular processing site. In this study, we characterize an antibody (733) that preferentially recognizes the active 50 kDa heparanase form as compared to the non-active 65 kDa heparanase precursor. We have utilized this and other anti-heparanase antibodies to study the cellular localization of the latent 65 kDa and active 50 kDa heparanase forms during uptake and processing of exogenously added heparanase. Interestingly, not only the processed 50 kDa, but also the 65 kDa heparanase precursor was localized to perinuclear vesicles, suggesting that heparanase processing occurs in lysosomes. Indeed, heparanase processing was completely inhibited by chloroquine and bafilomycin A1, inhibitors of lysosome proteases. Similarly, processing of membrane-targeted heparanase was also chloroquine-sensitive, further ruling out the plasma membrane as the heparanase processing site. Finally, we provide evidence that antibody 733 partially neutralizes the enzymatic activity of heparanase, suggesting that the N-terminal region of the molecule is involved in assuming an active conformation. Monoclonal antibodies directed to this region are likely to provide specific heparanase inhibitors and hence assist in resolving heparanase functions under normal and pathological conditions.
Heparanase is a mammalian endoglycosidase that degrades heparan sulfate (HS) at specific intra-chain sites. Blood-borne neutrophils, macrophages, mast cells, and platelets exhibit heparanase activity that is thought to be stored in specific granules. The degranulated heparanase is implicated in extravasation of metastatic tumor cells and activated cells of the immune system. Degranulation and heparanase release in response to an inflammatory stimulus or platelet activation would facilitate cellular extravasation directly, by altering the composition and structural integrity of the extracellular matrix, or indirectly, by releasing HS-bound proinflammatory cytokines and chemokines. We hypothesized that in addition to such indirect effect, the released heparanase may also locally affect and activate neighboring cells such as endothelial cells. Here, we provide evidence that addition of the 65-kDa latent heparanase to endothelial cells enhances Akt signaling. Heparanase-mediated Akt phosphorylation was independent of its enzymatic activity or the presence of cell membrane HS proteoglycans and was augmented by heparin. Moreover, addition of heparanase stimulated phosphatidylinositol 3-kinasedependent endothelial cell migration and invasion. These results suggest, for the first time, that heparanase activates endothelial cells and elicits angiogenic responses directly. This effect appears to be mediated by as yet unidentified heparanase receptor.Heparanase is an endo--D-glucuronidase capable of cleaving heparan sulfate (HS) 1 side chains at a limited number of sites, yielding HS fragments of still appreciable size (ϳ5-7 kDa) (1-3). Participating in extracellular matrix (ECM) degradation and remodeling, heparanase activity has been traditionally correlated with the metastatic potential of tumor-derived cells (4 -7). Similarly, heparanase has been shown to facilitate cell invasion associated with angiogenesis, autoimmunity, and inflammation (6 -9). Among the few cell types that express heparanase under normal physiological conditions, platelets possess a high heparanase activity and were used as a source for heparanase purification (2, 10). In fact, serum heparanase is mainly derived from activated platelets (11). Heparanase was localized to tertiary granules of neutrophils (12, 13) and mast cells (7) and was released upon tumor necrosis factor-␣ and calcium ionophore treatments, respectively. Heparanase release by degranulation has been implicated in diapedesis and extravasation of a number of immune cells, including neutrophils, macrophages, and lymphocytes (8, 14, 15), while heparanase inhibitors exhibited an anti-inflammatory activity (15). Cleavage of HS side chains by degranulated heparanase during inflammation may facilitate the passage of blood-borne normal and malignant cells into tissues by altering the composition and structural integrity of the subendothelial ECM (1,8,14). In addition, heparanase may facilitate the release of a multitude of HS-bound growth factors, cytokines and chemokines that would, in tu...
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