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Heparanase: Busy at the cell surface

Heparanase activity is strongly implicated in structural remodeling of the extracellular matrix, a process which can lead to invasion by tumor cells. In addition, heparanase augments signaling cascades leading to enhanced phosphorylation of selected protein kinases and increased gene transcription associated with aggressive tumor progression. This function is apparently independent of heparan sulfate and enzyme activity, and is mediated by a novel protein domain localized at the heparanase C-terminus. Moreover, the functional repertoire of heparanase is expanded by its regulation of syndecan clustering, shedding, and mitogen binding. Recent reports indicate that modified glycol-split heparin, which inhibits heparanase activity, can profoundly inhibit the progression of tumor xenografts produced by myeloma and carcinoma cells, thus moving anti-heparanase therapy closer to reality.

Structure-Function Approach Identifies a COOH-Terminal Domain That Mediates Heparanase Signaling

Heparanase is an endo-beta-d-glucuronidase capable of cleaving heparan sulfate, activity that is strongly implicated in cellular invasion associated with tumor metastasis, angiogenesis, and inflammation. In addition, heparanase was noted to exert biological functions apparently independent of its enzymatic activity, enhancing the phosphorylation of selected protein kinases and inducing gene transcription. A predicted three-dimensional structure of constitutively active heparanase clearly delineates a TIM-barrel fold previously anticipated for the enzyme. Interestingly, the model also revealed the existence of a COOH-terminal domain (C-domain) that apparently is not an integral part of the TIM-barrel fold. We provide evidence that the C-domain is critical for heparanase enzymatic activity and secretion. Moreover, the C-domain was found to mediate nonenzymatic functions of heparanase, facilitating Akt phosphorylation, cell proliferation, and tumor xenograft progression. These findings support the notion that heparanase exerts enzymatic activity-independent functions, and identify, for the first time, a protein domain responsible for heparanase-mediated signaling. Inhibitors directed against the C-domain, combined with inhibitors of heparanase enzymatic activity, are expected to neutralize heparanase functions and to profoundly affect tumor growth, angiogenesis, and metastasis.

Large-scale production of pharmaceutical proteins in plant cell culture-the Protalix experience.

Protalix Biotherapeutics develops recombinant human proteins and produces them in plant cell culture. Taliglucerase alfa has been the first biotherapeutic expressed in plant cells to be approved by regulatory authorities around the world. Other therapeutic proteins are being developed and are currently at various stages of the pipeline. This review summarizes the major milestones reached by Protalix Biotherapeutics to enable the development of these biotherapeutics, including platform establishment, cell line selection, manufacturing process and good manufacturing practice principles to consider for the process. Examples of the various products currently being developed are also presented.

Heparanase enhances the generation of activated factor X in the presence of tissue factor and activated factor VII.

Background Heparanase is an endo-β-D-glucuronidase dominantly involved in tumor metastasis and angiogenesis. Recently, we demonstrated that heparanase is involved in the regulation of the hemostatic system. Our hypothesis was that heparanase is directly involved in activation of the coagulation cascade. Design and Methods Activated factor X and thrombin were studied using chromogenic assays, immunoblotting and thromboelastography. Heparanase levels were measured by enzyme-linked immunosorbent assay. A potential direct interaction between tissue factor and heparanase was studied by co-immunoprecipitation and far-western assays. Results Interestingly, addition of heparanase to tissue factor and activated factor VII resulted in a 3- to 4-fold increase in activation of the coagulation cascade as shown by increased activated factor X and thrombin production. Culture medium of human embryonic kidney 293 cells over-expressing heparanase and its derivatives increased activated factor X levels in a non-enzymatic manner. When heparanase was added to pooled normal plasma, a 7- to 8-fold increase in activated factor X level was observed. Subsequently, we searched for clinical data supporting this newly identified role of heparanase. Plasma samples from 35 patients with acute leukemia at presentation and 20 healthy donors were studied for heparanase and activated factor X levels. A strong positive correlation was found between plasma heparanase and activated factor X levels (r=0.735, P=0.001). Unfractionated heparin and an inhibitor of activated factor X abolished the effect of heparanase, while tissue factor pathway inhibitor and tissue factor pathway inhibitor-2 only attenuated the procoagulant effect. Using co-immunoprecipitation and far-western analyses it was shown that heparanase interacts directly with tissue factor. Conclusions Overall, our results support the notion that heparanase is a potential modulator of blood hemostasis, and suggest a novel mechanism by which heparanase increases the generation of activated factor X in the presence of tissue factor and activated factor VII.

Establishment of a tobacco BY2 cell line devoid of plant specific xylose and fucose as a platform for the production of biotherapeutic proteins.

Summary Plant‐produced glycoproteins contain N‐linked glycans with plant‐specific residues of β(1,2)‐xylose and core α(1,3)‐fucose, which do not exist in mammalian‐derived proteins. Although our experience with two enzymes that are used for enzyme replacement therapy does not indicate that the plant sugar residues have deleterious effects, we made a conscious decision to eliminate these moieties from plant‐expressed proteins. We knocked out the β(1,2)‐xylosyltranferase (XylT) and the α(1,3)‐fucosyltransferase (FucT) genes, using CRISPR/Cas9 genome editing, in Nicotiana tabacum L. cv Bright Yellow 2 (BY2) cell suspension. In total, we knocked out 14 loci. The knocked‐out lines were stable, viable and exhibited a typical BY2 growing rate. Glycan analysis of the endogenous proteins of these lines exhibited N‐linked glycans lacking β(1,2)‐xylose and/or α(1,3)‐fucose. The knocked‐out lines were further transformed successfully with recombinant DNaseI. The expression level and the activity of the recombinant protein were similar to that of the protein produced in the wild‐type BY2 cells. The recombinant DNaseI was shown to be totally free from any xylose and/or fucose residues. The glyco‐engineered BY2 lines provide a valuable platform for producing potent biopharmaceutical products. Furthermore, these results demonstrate the power of the CRISPR/Cas9 technology for multiplex gene editing in BY2 cells.

Targeting heparanase to the mammary epithelium enhances mammary gland development and promotes tumor growth and metastasis

Heparanase is an endoglucuronidase that uniquely cleaves the heparan sulfate side chains of heparan sulfate proteoglycans. This activity ultimately alters the structural integrity of the ECM and basement membrane that becomes more prone to cellular invasion by metastatic cancer cells and cells of the immune system. In addition, enzymatically inactive heparanase was found to facilitate the proliferation and survival of cancer cells by activation of signaling molecules such as Akt, Src, signal transducer and activation of transcription (Stat), and epidermal growth factor receptor. This function is thought to be executed by the C-terminal domain of heparanase (8c), because over expression of this domain in cancer cells accelerated signaling cascades and tumor growth. We have used the regulatory elements of the mouse mammary tumor virus (MMTV) to direct the expression heparanase and the C-domain (8c) to the mammary gland epithelium of transgenic mice. Here, we report that mammary gland branching morphogenesis is increased in MMTV-heparanase and MMTV-8c mice, associating with increased Akt, Stat5 and Src phosphorylation. Furthermore, we found that the growth of tumors generated by mouse breast cancer cells and the resulting lung metastases are enhanced in MMTV-heparanase mice, thus supporting the notion that heparanase contributed by the tumor microenvironment (i.e., normal mammary epithelium) plays a decisive role in tumorigenesis. Remarkably, MMTV-8c mice develop spontaneous tumors in their mammary and salivary glands. Although this occurs at low rates and requires long latency, it demonstrates decisively the pro-tumorigenic capacity of heparanase signaling.

Molecular and Cellular Aspects of Heparanase

Heparanase is an endoglycosidase involved in cleavage of heparan sulfate and hence in degradation and remodeling of the basement membrane and extracellular matrix (ECM). Heparanase activity facilitates cell invasion associated with cancer metastasis, angiogenesis, autoimmunity and inflammation. The enzyme is preferentially expressed in human tumors and its over-expression in tumor cells confers an invasive phenotype. Heparanase also releases angiogenic factors from the ECM and thereby induces an angiogenic response in vivo. Heparanase upregulation correlates with increased tumor vascularity and poor postoperative survival of cancer patients. Moreover, heparanase levels in the urine and plasma of cancer patients often correlate with the severity of the disease and response to anti-cancer treatments. These observations, the anti-cancerous effect of heparanase gene silencing and of heparanase-inhibiting molecules, as well as the unexpected identification of a single functional heparanase, suggest that the enzyme is a valid target for anti-cancer drug development and a promising tumor marker. Heparanase also exhibits non-enzymatic activities, stimulating, among other effects, cell adhesion, Akt signaling and PI3K-dependent endothelial cell migration and invasion. It also promotes VEGF expression via the Src pathway and hence may activate endothelial cells and elicit angiogenic and survival responses. Studies with heparanase over-expressing transgenic mice revealed that the enzyme functions in normal processes (i.e., wound healing) involving cell mobilization, HS turnover, tissue vascularization and remodeling. Inhibitors directed against domains critical for heparanase secretion and signaling, combined with inhibitors of heparanase enzymatic activity (i.e., nonanticoagulant glycol-split heparin) are being developed to halt tumor growth, angiogenesis and metastasis. In this review, we summarize the current status of heparanase’ research, emphasizing molecular and cellular aspects of the enzyme, including its mode of processing and activation, control of heparanase gene expression, cytoplasmic vs. nuclear localization, enzymatic and non-enzymatic functions, causal involvement in cancer metastasis and angiogenesis, and strategies for the development of heparanase inhibitors.