Function from within: Autophagy induction by HPSE/heparanase—new possibilities for intervention

HPSE (heparanase) is the predominant enzyme in mammals capable of cleaving heparan sulfate, an activity highly implicated in cellular invasion and tumor metastasis. HPSE expression is induced in many types of cancer and increased HPSE levels are most often associated with increased tumor metastasis and reduced patient survival post operation. In addition, HPSE induction is associated with progression of the primary tumors but the mechanism(s) underlying tumor expansion by HPSE have not been sufficiently resolved. Our results establish a role for heparanase in modulating autophagy in normal and malignant cells, thereby conferring growth advantages as well as resistance to chemotherapy.     

Genomic organization and chromosome localization of the newly identified human heparanase gene

Heparanase (HPSE), which we have recently isolated, is an endo-beta-D-glucuronidase capable of cleaving heparan sulfate and has been implicated in inflammation and tumor angiogenesis and metastasis. In this report, the genomic organization and chromosome localization of the human heparanase gene is described. Polymerase chain reaction, subcloning and DNA sequencing analysis of a bacterial artificial chromosome (BAC) clone revealed that the 3.7 kb human heparanase cDNA is spread over about 50 kb and contains 14 exons and 13 introns. The heparanase gene is expressed as two mRNA species containing the same open reading frame, HPSE 1a (5 kb) (GenBank Data Library under accession number: AF155510); and HPSE 1b (1.7 kb) (GenBank Data Library under accession number: AF144325), generated by alternative splicing. The HPSE 1a-form contains all 14 exons, whereas in the HPSE 1b-form the first and fourteenth exons (5'- and 3'-untranslated region) have been spliced out. All splice sites conform to the GT-AG rule, except for the splice donor site of intron 13 (which is GA instead of GT), and the splice acceptor of intron 13 (which is GG instead of AG). Fluorescence in situ hybridization and radiation hybrid mapping suggest that the heparanase gene is located on human chromosome 4q22. This report regarding the structure of the human heparanase gene will aid in understanding the genetic contribution of this gene to normal physiology as well as to disease states. A possible involvement of heparanase in neuronal degeneration is discussed.     

Immunomagnetic DNA aptamer assay

DNA aptamers, oligonucleotides with antibody-like binding properties, are easy to manufacture and modify. As a class of molecules, they represent the biggest revolution to immunodiagnostics since the discovery of monoclonal antibodies. To demonstrate that DNA aptamers are versatile reagents for use as in vitro diagnostic tools, we developed a hybrid immunobead assay based on a 5'-biotinylated DNA thrombin aptamer (5'-GGTTGGTGTGGTTGG-3') and an anti-thrombin antibody (EST-7). Our results show that the thrombin DNA aptamer is capable of binding to its target molecule under stringent in vitro assay conditions and at physiological concentrations. These findings also support the view that DNA aptamers have potential value as complementary reagents in diagnostic assays.     

Production of heparanase constructs suitable for nuclear magnetic resonance and drug discovery studies

Heparanase is an endo‐β‐D‐glucosidase capable of specifically degrading heparan sulphate, one of the main components of the extracellular matrix. This 65 kDa polypeptide is implicated in cancer processes such as tumour formation, angiogenesis and metastasis, making it a very attractive target in antitumour treatments. Structure‐based approaches to find inhibitors of heparanase have been historically hampered by the lack of success in crystallizing the protein. With the aim to undertake the NMR structural characterisation of heparanase, we have designed and produced, using recombinant methods, smaller constructs of heparanase containing the catalytically active glutamic acids and the two binding sites for heparan sulphate. An extensive range of expression and purification conditions were evaluated to alleviate the intrinsic low solubility and aggregation propensity of heparanase, allowing the obtention of the enzyme in milligram quantities, both unlabelled and ¹⁵N‐labelled for NMR studies. Using the smallest of the designed constructs and applying NMR and SPR methodologies, we have demonstrated that known inhibitors of heparanase bind to this construct specifically and selectively with K_D values in the range of those reported for human heparanase, validating it for future drug discovery projects focused on the identification of novel inhibitors of this enzyme. © 2010 Wiley Periodicals, Inc. Biopolymers 95: 151–160, 2011.     

Anti-Heparanase Aptamers as Potential Diagnostic and Therapeutic Agents for Oral Cancer

Heparanase is an endoglycosidase enzyme present in activated leucocytes, mast cells, placental tissue, neutrophils and macrophages, and is involved in tumour metastasis and tissue invasion. It presents a potential target for cancer therapies and various molecules have been developed in an attempt to inhibit the enzymatic action of heparanase. In an attempt to develop a novel therapeutic with an associated diagnostic assay, we have previously described high affinity aptamers selected against heparanase. In this work, we demonstrated that these anti-heparanase aptamers are capable of inhibiting tissue invasion of tumour cells associated with oral cancer and verified that such inhibition is due to inhibition of the enzyme and not due to other potentially cytotoxic effects of the aptamers. Furthermore, we have identified a short 30 bases aptamer as a potential candidate for further studies, as this showed a higher ability to inhibit tissue invasion than its longer counterpart, as well as a reduced potential for complex formation with other non-specific serum proteins. Finally, the aptamer was found to be stable and therefore suitable for use in human models, as it showed no degradation in the presence of human serum, making it a potential candidate for both diagnostic and therapeutic use.     

抗人肝素酶单克隆抗体的制备与鉴定

目的:肝素酶在白细胞游走和恶性肿瘤转移的过程中发挥重要作用,肝素酶抗体的制备对于自身免疫病和肿瘤的良恶性鉴别诊断具有重要意义。制备抗人肝素酶单克隆抗体,用于肝素酶的研究及临床恶性肿瘤的鉴别诊断。方法:通过杂交瘤技术将分泌抗人肝素酶单抗的小鼠B细胞与小鼠骨髓瘤细胞Sp2/0融合,获得稳定分泌抗人肝素酶单抗的杂交瘤细胞;用有限稀释法获得单克隆,以重组人肝素酶及含肝素酶的血小板裂解液对抗体进行Western印迹检测。结果:Western印迹结果显示制备的单抗与人肝素酶具有特异性免疫识别特性。结论:获得了能够特异性免疫识别人肝素酶的分泌性抗人肝素酶单克隆抗体。     

Pre-clinical and clinical significance of heparanase in Ewing's sarcoma

Heparanase is an endoglycosidase that specifically cleaves heparan sulphate side chains of heparan sulphate proteoglycans, activity that is strongly implicated in cell migration and invasion associated with tumour metastasis, angiogenesis and inflammation. Heparanase up-regulation was documented in an increasing number of human carcinomas, correlating with reduced post-operative survival rate and enhanced tumour angiogenesis. Expression and significance of heparanase in human sarcomas has not been so far reported. Here, we applied the Ewing's sarcoma cell line TC71 and demonstrated a potent inhibition of cell invasion in vitro and tumour xenograft growth in vivo upon treatment with a specific inhibitor of heparanase enzymatic activity (compound SST0001, non-anticoagulant N-acetylated, glycol split heparin). Next, we examined heparanase expression and cellular localization by immunostaining of a cohort of 69 patients diagnosed with Ewing's sarcoma. Heparanase staining was noted in all patients. Notably, heparanase staining intensity correlated with increased tumour size (P = 0.04) and with patients' age (P = 0.03), two prognostic factors associated with a worse outcome. Our study indicates that heparanase expression is induced in Ewing's sarcoma and associates with poor prognosis. Moreover, it encourages the inclusion of heparanase inhibitors (i.e. SST0001) in newly developed therapeutic modalities directed against Ewing's sarcoma and likely other malignancies.     

Translocation of active heparanase to cell surface regulates degradation of extracellular matrix heparan sulfate upon transmigration of mature monocyte-derived dendritic cells

After Ag capture and exposure to danger stimuli, maturing dendritic cells (DCs) migrate to regional lymph nodes, where antigenic peptides are presented to T lymphocytes. To migrate from peripheral tissue such as the epidermis to regional lymph nodes, Ag-bearing epidermal Langerhans cells must move through an extracellular matrix (ECM) of various compositions. The nature of their capacity to transmigrate via ECM is not well understood, although MIP-3beta and CCR7 play critical roles. We were interested in verifying whether heparanase, a heparan sulfate-degrading endo-beta-d-glucuronidase that participates in ECM degradation and remodeling, is expressed and functional in monocyte-derived DCs. Using immunohistochemistry, confocal microscopy, RT-PCR, Western blot analysis, assays for heparanase activity, and Matrigel transmigration, we show that heparanase is expressed in both nuclei and cytoplasm of immature DCs, and that gene expression and synthesis take place mainly in monocytes and early immature DCs. We also found that both nuclear and cytoplasm fractions show heparanase activity, and upon LPS-induced maturation, heparanase translocates to the cell surface and degrades ECM heparan sulfate. Matrigel transmigration assays showed a MIP-3beta-comparable role for heparanase. Because heparan sulfate glycosaminoglycans play a key role in the self-assembly, insolubility, and barrier properties of the ECM, the results of this study suggest that heparanase is a key enzyme in DC transmigration through the ECM.     

Characterization of heparanase from a rat parathyroid cell line

Cell surface heparan sulfate proteoglycans undergo unique intracellular degradation pathways after they are endocytosed from the cell surface. Heparanase, an endo-beta-glucuronidase capable of cleaving heparan sulfate, has been demonstrated to contribute to the physiological degradation of heparan sulfate proteoglycans and therefore regulation of their biological functions. A rat parathyroid cell line was found to produce heparanase with an optimal activity at neutral and slightly acidic conditions suggesting that the enzyme participates in heparan sulfate proteoglycan metabolism in extralysosomal compartments. To elucidate the detailed properties of the purified enzyme, the substrate specificity against naturally occurring heparan sulfates and chemically modified heparins was studied. Cleavage sites of rat heparanase were present in heparan sulfate chains obtained from a variety of animal organs, but their occurrence was infrequent (average, 1-2 sites per chain) requiring recognition of both undersulfated and sulfated regions of heparan sulfate. On the other hand intact and chemically modified heparins were not cleaved by heparanase. The carbohydrate structure of the newly generated reducing end region of heparan sulfate cleaved by the enzyme was determined, and it represented relatively undersulfated structures. O-Sulfation of heparan sulfate chains also played important roles in substrate recognition, implying that rat parathyroid heparanase acts near the boundary of highly sulfated and undersulfated domains of heparan sulfate proteoglycans. Further elucidation of the roles of heparanase in normal physiological processes would provide an important tool for analyzing the regulation of heparan sulfate-dependent cell functions.     

CS-SELEX Generates High-Affinity ssDNA Aptamers as Molecular Probes for Hepatitis C Virus Envelope Glycoprotein E2

Currently, the development of effective diagnostic reagents as well as treatments against Hepatitis C virus (HCV) remains a high priority. In this study, we have described the development of an alive cell surface -Systematic Evolution of Ligands by Exponential Enrichment (CS-SELEX) technique and screened the functional ssDNA aptamers that specifically bound to HCV envelope surface glycoprotein E2. Through 13 rounds of selection, the CS-SELEX generated high-affinity ssDNA aptamers, and the selected ssDNA aptamer ZE2 demonstrated the highest specificity and affinity to E2-positive cells. HCV particles could be specifically captured and diagnosed using the aptamer ZE2. A good correlation was observed in HCV patients between HCV E2 antigen-aptamer assay and assays for HCV RNA quantities or HCV antibody detection. Moreover, the selected aptamers, especially ZE2, could competitively inhibit E2 protein binding to CD81, an important HCV receptor, and significantly block HCV cell culture (HCVcc) infection of human hepatocytes (Huh7.5.1) in vitro. Our data demonstrate that the newly selected ssDNA aptamers, especially aptamer ZE2, hold great promise for developing new molecular probes, as an early diagnostic reagent for HCV surface antigen, or a therapeutic drug specifically for HCV.     

Development of both colorimetric and fluorescence heparinase activity assays using fondaparinux as substrate

Because tumors and other diseases are characterized by increased heparanase levels, human heparanase is a promising drug target and diagnostic marker. Therefore, methods are needed to determine heparanase activity and to examine potential inhibitors. Because of substrate comparability, we used the bacterial enzyme heparinase II (heparinase) for the assay development. Usually the substrate of heparanase assays is heparan sulfate, which has several disadvantages. Because of that, we used fondaparinux, which is being cleaved by both heparanase and heparinase. Two concepts to detect its degradation were examined: measurement of anti-factor Xa activity of fondaparinux and its direct quantification with the fluorescent sensor polymer-H. Using fondaparinux as substrate, the anti-factor Xa assay was shsown to be appropriate to determine heparinase activity. The detection with polymer-H was easier and even faster to perform. Linearity was given with fondaparinux as well as heparan sulfate, and heparin as substrates, but fondaparinux turned out to be most suitable. By modifications (incubation time, fondaparinux concentration, and polymer-H concentration), the limit of quantification and the linear range can be adapted to the respective requirements. In conclusion, a simple, accurate, and robust heparinase assay was developed. It is suitable for heparinase quality control and testing heparinase inhibitors and could be adapted to heparanase.     

乙酰肝素酶重组慢病毒转基因和siRNA干扰质粒的构建及鉴定

目的：构建乙酰肝素酶重组慢病毒转基因和siRNA干扰质粒,为探讨HPSE在在肿瘤浸润转移过程中的分子机理奠定基础。方法：乙酰肝素酶cDNA全长扩增和最佳siRNA干扰片段筛选分别采用PCR和Real-time PCR方法,慢病毒系统载体分别使用pWPI和siRNA pSico系统,采用限制性内切酶快速连接方法联接目的基因和最佳最佳siRNA干扰片段,表达载体鉴定均采用核苷酸序列测定,HPSE重组慢病毒表达质粒和siRNA片段细胞转染采用脂质体转染法。结果：成功扩增乙酰肝素酶全长并连接入pWPI载体构建成重组表达载体HPSE-pWPI,重组质粒测序结果显与HPSE基因的同源性达99%。转染293T后有HPSE基因的表达。筛选出最佳siRNA干扰片段为HPSE-1222并成功插入pSico载体,构建成重组表达载体HPSE-siRNA pSico,重组载体测序显示与构建的shRNA结构序列完全一致。结论：成功采用慢病毒载体系统构建了乙酰肝素酶重组慢病毒转基因和siRNA干扰质粒,为探讨HPSE在在肿瘤浸润转移过程中的分子机理奠定基础。     

Heparanase expression in invasive trophoblasts and acute vascular damage

Heparan sulfate proteoglycans play a pivotal role in tissue function, development, inflammation, and immunity. We have identified a novel cDNA encoding human heparanase, an enzyme thought to cleave heparan sulfate in physiology and disease, and have located the HEP gene on human chromosome 4q21. Monoclonal antibodies against human heparanase located the enzyme along invasive extravillous trophoblasts of human placenta and along endothelial cells in organ xenografts targeted by hyperacute rejection, both sites of heparan sulfate digestion. Heparanase deposition was evident in arterial walls in normal tissues; however, vascular heparan sulfate cleavage was coincident with heparanase enzyme during inflammatory episodes. These findings suggest that heparanase elaboration and control of catalytic activity may contribute to the development and pathogenesis of vascular disease and suggest that heparanase intervention might be a useful therapeutic target.     

Heparanase activates the syndecan-syntenin-ALIX exosome pathway

Exosomes are secreted vesicles of endosomal origin involved in signaling processes. We recently showed that the syndecan heparan sulfate proteoglycans control the biogenesis of exosomes through their interaction with syntenin-1 and the endosomal-sorting complex required for transport accessory component ALIX. Here we investigated the role of heparanase, the only mammalian enzyme able to cleave heparan sulfate internally, in the syndecan-syntenin-ALIX exosome biogenesis pathway. We show that heparanase stimulates the exosomal secretion of syntenin-1, syndecan and certain other exosomal cargo, such as CD63, in a concentration-dependent manner. In contrast, exosomal CD9, CD81 and flotillin-1 are not affected. Conversely, reduction of endogenous heparanase reduces the secretion of syntenin-1-containing exosomes. The ability of heparanase to stimulate exosome production depends on syntenin-1 and ALIX. Syndecans, but not glypicans, support exosome biogenesis in heparanase-exposed cells. Finally, heparanase stimulates intraluminal budding of syndecan and syntenin-1 in endosomes, depending on the syntenin-ALIX interaction. Taken together, our findings identify heparanase as a modulator of the syndecan-syntenin-ALIX pathway, fostering endosomal membrane budding and the biogenesis of exosomes by trimming the heparan sulfate chains on syndecans. In addition, our data suggest that this mechanism controls the selection of specific cargo to exosomes.     

Identification and characterization of heparin/heparan sulfate binding domains of the endoglycosidase heparanase

The endo-beta-glucuronidase, heparanase, is an enzyme that cleaves heparan sulfate at specific intra-chain sites, yielding heparan sulfate fragments with appreciable size and biological activities. Heparanase activity has been traditionally correlated with cell invasion associated with cancer metastasis, angiogenesis, and inflammation. In addition, heparanase up-regulation has been documented in a variety of primary human tumors, correlating with increased vascular density and poor postoperative survival, suggesting that heparanase may be considered as a target for anticancer drugs. In an attempt to identify the protein motif that would serve as a target for the development of heparanase inhibitors, we looked for protein domains that mediate the interaction of heparanase with its heparan sulfate substrate. We have identified three potential heparin binding domains and provided evidence that one of these is mapped at the N terminus of the 50-kDa active heparanase subunit. A peptide corresponding to this region (Lys(158)-Asp(171)) physically associates with heparin and heparan sulfate. Moreover, the peptide inhibited heparanase enzymatic activity in a dose-responsive manner, presumably through competition with the heparan sulfate substrate. Furthermore, antibodies directed to this region inhibited heparanase activity, and a deletion construct lacking this domain exhibited no enzymatic activity. NMR titration experiments confirmed residues Lys(158)-Asn(162) as amino acids that firmly bound heparin. Deletion of a second heparin binding domain sequence (Gln(270)-Lys(280)) yielded an inactive enzyme that failed to interact with cell surface heparan sulfate and hence accumulated in the culture medium of transfected HEK 293 cells to exceptionally high levels. The two heparin/heparan sulfate recognition domains are potentially attractive targets for the development of heparanase inhibitors.