Inhibition of guanidinobenzoatase: evidence for multiple forms of this protease on different tumour cells

Guanidinobenzoatase is a proteolytic enzyme capable of degrading fibronectin and is a tumour associated enzyme. 9-Aminoacridine is a competitive inhibitor of this enzyme and has been used to locate cells possessing this enzyme in wax embedded sections by means of fluorescent microscopy. Naturally occurring inhibitors of guanidinobenzoatase can be extracted from different tissues. These inhibitors show selectivity in their ability to inhibit the binding of 9-aminoacridine to different types of tumour cells which have invaded human liver tissue. Inhibition is non-competitive and reversible. The results indicate that guanidinobenzoatase exists in a number of different forms on the surface of different tumour cells. These different forms of the enzyme were recognised by inhibitors obtained from different organs. It is suggested that these inhibitors may have a regulatory role in tumour cell migration.     

Fluorescent location of human colonic tumour cells by means of an enzyme-inhibitor complex

We studied the enzymic status of the tumour cell surface protease, guanidinobenzoatase (GB) in frozen sections of a human colonic tumour grown in nude mice and also in human colons. Active enzyme was demonstrated by the binding of a synthetic fluorescent probe for the active centre of guanidinobenzoatase (GB). It was observed that tissue derived inhibitors of GB blocked the binding of this fluorescent probe and that enzyme inhibitor complex formation could be controlled by lowering the pH of the medium with lactic acid. The presence of an inhibitor of GB in the mouse tumour extract was taken advantage of by making two fluorescent derivatives of this inhibitor; both of which located GB on colonic tumour cells in frozen sections of human colon.     

Fluorescent Location of Human Colonic Tumour Cells by Means of an Enzyme-Inhibitor Complex

Abstract

We studied the enzymic status of the tumour cell surface protease, guanidinobenzoatase (GB) in frozen sections of a human colonic tumour grown in nude mice and also in human colons. Active enzyme was demonstrated by the binding of a synthetic fluorescent probe for the active centre of guanidinobenzoatase (GB). It was observed that tissue derived inhibitors of GB blocked the binding of this fluorescent probe and that enzyme inhibitor complex formation could be controlled by lowering the pH of the medium with lactic acid. The presence of an inhibitor of GB in the mouse tumour extract was taken advantage of by making two fluorescent derivatives of this inhibitor; both of which located GB on colonic tumour cells in frozen sections of human colon.     

Cell-surface and secreted proteinases and guanidinobenzoatase activity

Hydrolysis of p-nitrophenyl guanidinobenzoate is characteristic of a tumour cell surface proteinase. We found this activity in three transformed or tumour cell lines, but not in two normal fibroblast strains. Immunochemical inhibition of plasminogen activator activity did not affect guanidinobenzoatase activity.     

Inhibition of a cell surface protease after cisplatin chemotherapy.

The epithelial cells in squamous carcinoma and leukoplakia of the oral cavity possess the cell surface protease, guanidinobenzoatase (GB), in an active form. GB is closely similar to plasminogen activator, a protease associated with both transformed cells and tumour cells. The active centre of GB binds the fluorescent probe 9-aminoacridine (9-AA) enabling cells containing active GB to be visualised by fluorescent microscopy. It was observed that chemotherapy with cisplatin resulted in a marked decrease in cell surface GB activity and this decrease was due to the formation of an enzyme-inhibitor complex. One of the results of chemotherapy was shown to be the suppression of a cell surface protease which is known to be associated with migration and malignancy of cells in vivo.     

Evidence for inhibitors of the cell surface protease guanidinobenzoatase

Guanidinobenzoatase is a protease present on the surface of tumour cells. The present study describes the isolation of a protein inhibitor of guanidinobenzoatase obtained from extracts of liver and pancreas and purified by affinity techniques. Pancreatic acinar cells have been shown to possess a latent form of guanidinobenzoatase and this latency is due to complex formation with the inhibitor. A fluorescent marker has been employed to demonstrate the presence or absence of the inhibitor on sections of pancreatic tissue. The inhibitor has been shown to be exchangeable with liver and pancreatic inhibitors obtained from different species. It is postulated that these inhibitors may play a role in enzyme control.     

Further inhibition studies on guanidinobenzoatase, a trypsin-like enzyme associated with tumour cells

Guanidinobenzoatase is a proteolytic enzyme capable of degrading fibronectin and is a tumour associated enzyme. Guanidinobenzoatase has been shown to be an arginine selective protease and is distinct from trypsin, plasminogen activator, plasmin, thrombin and a newly described tumour associated enzyme specific for guanidino phenylalanine residues. These conclusions have been derived from inhibition studies employing 4-methyl-p-guanidinobenzoate as substrate. Three active site titrants for trypsin have been shown to be good substrates for guanidinobenzoatase. A new active site titrant for trypsin, rhodamine bisguanidinobenzoate, can also be used to assay guanidinobenzoatase in a stoichiometric manner. This active site titrant can be employed to label guanidinobenzoate on the surface of leukaemia cells.     

The inhibitor reacting with a tumour cell surface protease can be exchanged with plasminogen activator inhibitor (PAI-1)

Tumour cells possess the cell surface protease guanidinobenzoatase (GB) which can be located by the fluorescent probe 9-amino acridine (9-AA). Frozen sections and formaldehyde fixed sections of tumour tissue were used to demonstrate the interactions between GB, 9-AA and two protein inhibitors of GB. A cytoplasmic extract from the tumour tissue, and a purified inhibitor of plasminogen activator (PAI-1) were shown to be exchangeable components of the enzyme-inhibitor complex on the fixed tumour cell surfaces. The evidence suggests that GB is functionally very similar to plasminogen activator and that this enzyme can be regulated by protein inhibitors in vivo and also by changes in the redox potential at the cell surface.     

The role of inhibitors in the fluorescent staining of benign naevus and malignant melanoma cells with 9-amino acridine and acridine orange

Guanidinobenzoatase is a trypsin-like protease capable of degrading fibronectin. An inactive form of guanidinobenzoatase is present on the surface of benign naevus cells and these cells stain very weakly with 9-aminoacridine, a known competitive inhibitor of guanidinobenzoatase. Malignant melanoma and metastatic malignant melanoma cells exhibit strong surface staining with 9-aminoacridine and also exhibit strong staining of cytoplasmic RNA with acridine orange. These simple fluorescent techniques have been used to distinguish benign naevus cells from malignant melanoma cells in human skin sections. This difference in cell surface staining with 9-aminoacridine has been demonstrated to be caused by the presence or absence of an inhibitor. The inhibitor can be displaced from the cell surface enzyme and then replaced by an affinity purified inhibitor obtained from fresh liver homogenates. It is proposed that the inhibition or control of cell surface guanidinobenzoatase may be one of the regulatory mechanisms by which benign naevus cells are prevented from developing into malignant melanoma cells.     

The Role of Inhibitors in the Fluorescent Staining of Benign Naevus and Malignant Melanoma Cells with 9-Amino Acridine and Acridine Orange

Abstract

Guanidinobenzoatase is a trypsin-like protease capable of degrading fibronectin. An inactive form of guanidinobenzoatase is present on the surface of benign naevus cells and these cells stain very weakly with 9-aminoacridine, a known competitive inhibitor of guanidinobenzoatase. Malignant melanoma and metastatic malignant melanoma cells exhibit strong surface staining with 9-aminoacridine and also exhibit strong staining of cytoplasmic RNA with acridine orange. These simple fluorescent techniques have been used to distinguish benign naevus cells from malignant melanoma cells in human skin sections. This difference in cell surface staining with 9-aminoacridine has been demonstrated to be caused by the presence or absence of an inhibitor. The inhibitor can be displaced from the cell surface enzyme and then replaced by an affinity purified inhibitor obtained from fresh liver homogenates. It is proposed that the inhibition or control of cell surface guanidinobenzoatase may be one of the regulatory mechanisms by which benign naevus cells are prevented from developing into malignant melanoma cells.     

The design of fluorescent probes which bind to the active centre of guanidinobenzoatase. Application to the location of cells possessing this enzyme

Cells possessing a known enzymic activity may be located by fluorescent probes designed to act as competitive inhibitors of this enzyme. We have prepared a series of dansyl N-substituted guanidino derivatives which bind to the active centre of guanidinobenzoatase. 9-Aminoacridine also acts as a competitive inhibitor and behaves similarly to these guanidino derivatives. These fluorescent probes have been used to locate tumour cells possessing this enzyme in thin sections of fixed tissue by employing fluorescent microscopy.     

The protective role of a natural inhibitor in the fluorescent location of cells possessing a latent form of cell surface protease.

Leukaemia cells possess a latent form of a cell surface protease referred to as guanidinobenzoatase. Latency is due to complex formation between an inhibitor protein and the cell surface enzyme which is stable under acid conditions but is dissociated with formaldehyde treatment. The latent form of the cell surface protease has been used as a protecting mechanism during a preliminary step to stain all the nuclei of cells with haematoxylin. The enzyme-inhibitor complex was then dissociated and a combination of 9-amino acridine and propidium iodide employed to enable the fluorescent location of cells possessing active guanidinobenzoatase. We were thus able to visualise the nuclei by conventional light microscopy and simultaneously visualise the cell surface of leukaemia cells by fluorescent microscopy. This simple model system has provided technology applicable to the more complex analysis of neoplastic cells in cervical smears.     

Fluorescent inhibitors of a cell surface protease used to locate leukaemia cells in kidney sections

Guanidinobenzoatase is a trypsin-like protease on the surface of cells capable of migration, for example leukaemia cells. We have used a number of fluorescent probes that are competitive inhibitors of guanidinobenzoatase to locate leukaemia cells in resin sections of kidney tissue obtained from leukaemic rats. We have demonstrated how this competitive inhibition system can be used to direct desired molecules (such as cytotoxic drugs) to these cells and to monitor the arrival of such compounds at the active site of guanidinobenzoatase. The principles developed in this study could equally well be applied to other enzymes on other cells provided suitable competitive inhibitors were designed. The presence of an enzyme on the surface of a cell can be used to direct molecules to that cell provided that these molecules contain a functional group that acts as an inhibitor for the chosen enzyme.     

Inhibition of guanidinobenzoatase by a substrate for trypsin-like enzymes

Guanidinobenzoatase is a proteolytic enzyme capable of degrading fibronectin and is a tumour associated enzyme. Guanidinobenzoatase has been shown to be an arginine selective protease and is distinct from trypsin, plasmin and thrombin, the latter enzymes can be assayed with bis(carbobenzyloxycarbonyl-L-argininamido)-Rhodamine or BZAR. Guanidinobenzoatase is inhibited by BZAR when the enzyme is assayed in free solution and when the enzyme is cell-bound in frozen sections of tumour containing tissues. It is proposed that BZAR and its analogues may be of value in inhibiting tumour cell invasion in vivo and also that the selectivity of BZAR may be used to direct cytotoxic drugs to tumour cells possessing active guanidinobenzoatase.     

Direct evidence for the cell surface location of a protease-inhibitor complex on intact leukaemia cells

The interaction of a protease with two fluorescent inhibitors has been studied using intact fixed leukaemia cells as the source of the membrane bound enzyme. Fresh rat leukaemia cells were disrupted and the cytosol collected; this extract was known to contain a protein inhibitor of guanidinobenzoatase (GB) associated with leukaemia cells. All the cytosolic proteins were derivatised with Texas red acid chloride. Leukaemia cells with latent GB failed to bind the Texas red inhibitor protein but did so after activation of GB. Competition experiments with 9-amino acridine (a fluorescent marker for the active site of GB) demonstrated that the Texas red-inhibitor protein could only bind to intact leukaemia cells when the active centre of GB was not already occupied by 9-amino acridine. This competition between these two fluorescent inhibitors demonstrated their specificity for GB. The use of intact leukaemia cells and the high molecular weight of the inhibitor protein precludes the possibility of any interaction between GB and inhibitor within the cells. It is concluded that GB and the GB-inhibitor complex of latent GB are located on the external surface of intact leukaemia cells.     

Fluorescent studies directed towards the location of abnormal epithelial cells in cervical smears

Cervical screening is concerned with the search for abnormal epithelial cells in smears prepared from scrapings from the uterine cervix. It is a highly skilled labour intensive operation and automated methods of detecting dyskariotic cells in cervical smears would be helpful. We report a fluorescence method of detecting abnormal cervical cells in smears and biopsies using a probe for guanidinobenzoatase. This approach has the potential for automation.     

Inhibition of tumour cell adhesion by anti-metastatic polypeptide containing a repetitive Arg-Gly-Asp sequence

Anti-cell adhesive activity was examined by the synthetic polypeptide, containing repetitive Arg-Gly-Asp sequence of cell attachment site from fibronectin, poly (Arg-Gly-Asp). The attachment of tumour cells to fibronectin substrate was specifically inhibited by adding poly (Arg-Gly-Asp) in cell surface receptor-mediated and divalent cation-dependent manners, but not by unrelated peptides. In our previous study, the lung metastatic formation of tumour cells was dramatically reduced by intravenous co-injection of anti-cell adhesive poly (Arg-Gly-Asp) with B16-BL6 melanoma cells. These findings suggest that polypeptide-mediated inhibition of pulmonary metastasis is partly due to interference with tumour cell adhesion to the substrates including fibronectin in target organs or tissues.     

Effects of luteolin on arylamine N-acetyltransferase activity in human liver tumour cells

The human liver tumour cell line (J5) was selected in order to evaluate whether or not luteolin affected arylamine N-acetyltransferase (NAT) activity. Using high performance liquid chromatography, the NAT activity for acetylation of arylamine substrates (2-aminofluorene and p-aminobenzoic acid) was determined. The cytosolic NAT activity in human liver tumour cells was 2.74+/-0.26 and 1.68+/-0.20 nmol/min/mg of protein for 2-aminofluorene and p-aminobenzoic acid, respectively. Luteolin displayed a dose-dependent inhibition to cytosolic NAT activity and intact human liver tumour cells. Time-course experiments showed that NAT activity measured from intact human liver tumour cells was inhibited by luteolin for up to 24 h. Using standard steady-state kinetic analysis, it was shown that luteolin was a possible noncompetitive inhibitor to NAT activity in cytosols. This report is the first to show how luteolin affects NAT activity in human liver tumour cells.     

Comparative immunogenicity of irradiated and nonirradiated syngeneic and xenogeneic tumor cells containing a common specific transplantation antigen]

The authors compared the immunogenic activity for Syrian hamsters of native and irradiated syngeneic and xenogeneic tumour cells bearing on their surface common and SV40-specific transplantational antigen. The results obtained showed syngeneic tumour cells to be more immunogenic for the recipient than the xenogeneic tumour cells containing an antigen of the same specificity. Irradiation renders tumour cells, including the xenogeneic ones, more immunogenic, this possibly being associated with the capacity of nonirradiated cells to escape from immune recognition through their ability to divide.     

Contact-activated migration of melanoma B16 and sarcoma XC cells.

During migration, tumour cells interact with neighbouring neoplastic and normal host cells, and such interaction may influence their motile activity. We investigated the effect of homotypic collisions on the motile activity of two tumour cell lines, mouse melanoma B16 and rat sarcoma XC, and nontransformed human skin fibroblasts. It was found that the tumour cells show only limited motile activity when moving as single cells without contact with neighbours. At a higher density of the culture (and also at a greater number of cell to cell contacts) the activation of motility of investigated tumour cells was observed. On the other hand, the normal human skin fibroblasts showed a typical reaction of density-dependent inhibition of motility. The motile activity of tumour cells was not affected by conditioned media and was visibly dependent on a direct physical contact among colliding cells. The activation of cell movement was observed about 40-50 min after the initial contact between tumour cells. Contact-activated migration of neoplastic cells was inhibited by 50 microM verapamil (a selective voltage-gated calcium channel inhibitor) and 10 microM gadolinium chloride (a nonspecific blocker of mechanosensitive ion channels) but not by pertussis toxin. The observation that homotypic collisions among tumour cells strongly increase their motile activity suggests that contact-activated migration may play a significant role in tumour invasion and metastasis.