Binding of the cysteine proteinases papain and cathepsin B-like to coated laminin: use of synthetic peptides from laminin and from the laminin binding region of the beta 1 integrin subunit to characterize the binding site.

Cysteine proteinases of the papain superfamily, i.e., papain and cathepsin B-like proteinase, were found to be able to bind to laminin-coated wells. When papain and cathepsin B-like proteinase were used, saturable binding curves were found. The characterization of the binding site was carried out using synthetic peptides which corresponded to the most relevant functional sites of laminin and an octapeptide from the laminin binding region of the beta1 integrin subunit. In binding experiments, the decapeptide RNIAEIIKDI and the pentapeptide YIGSR were able to displace papain and cathepsin B-like proteinase from coated laminin. Nevertheless, the integrin beta1 peptide DLYYLMDL was the most powerful in the same experimental system. From these results, the C-terminal region of this cross-shaped protein, i.e., the end of the long arm, and the region including the YIGSR sequence of the short arm of the beta chain would be the cysteine proteinase binding site. This binding site is probably the result of the network organization of laminin which brings two regions, separated on a single laminin molecule, into proximity. In previous work, digestion of basement membranes has been found to be associated with the binding of cysteine proteinases to these supramolecular structures [N. Guinec, V. Dalet-Fumeron, and M. Pagano (1992) FEBS Lett. 308, 305-308]. The present report demonstrates that laminin is the cysteine proteinase binding protein of basement membranes. This property of laminin could be associated with tumor invasion and other tissue remodeling processes linked to proteolysis of basement membranes and extracellular matrices.

Expression of collagenase/gelatinase activity from basement-membrane fibronectin--isolation after limited proteolysis of a bovine lens capsule and molecular definition of this thiol-dependent zinc metalloproteinase.

We have isolated the collagenase/gelatinase activity of fibronectin from a bovine lens capsule hydrolysate, using heparin-agarose, gelatin-agarose, immunopurification with polyclonal antibodies directed against bovine plasma fibronectin, and immunopurification with a monoclonal antibody directed against the extra-domain A of cellular fibronectin. The expression of collagenase/gelatinase activity by the purified fibronectin fragment was dependent on the incubation time at 37 degrees C and the addition of gelatin to the purified sample. Under these conditions, the purified fibronectin fragment exhibited collagenase/gelatinase activity, as measured by means of gelatin zymography and the intramolecularly quenched fluorogenic substrate of collagenases (7-methoxycoumarin-4-yl)-acetylprolylleucylglycylleucyl-[3-(2,4-di nitrophenyl)-L-2,3-diaminopropionyl]-alanylarginylamide. This activity was due to proteins of 47 kDa and 37 kDa, as indicated by the gelatin-zymography pattern. When the processing was analyzed, by means of SDS/PAGE under reducing conditions, purified starting material of 66 kDa and 55 kDa was observed, and molecular masses of 45, 30 and 27 kDa were found for the processed samples. Under these conditions, the processing was more significant when a substrate, i.e the fluorogenic peptide or gelatin, was added to the processing mixture. An inhibition-profile study showed a zinc-dependent collagenase activity. Using the 45-kDa chymotryptic fragment from human plasma fibronectin, which contains the collagen-binding site, the same results were obtained. These results allow us to define a thiol-dependent zinc metalloproteinase expressed after limited proteolysis of both basement membrane and plasma fibronectins. This proteinase contains a collagen-binding domain, a zinc-binding sequence, and a cysteine involved in catalysis. This enzyme is a member of the thimet family of zinc metalloproteinases.

Competition between plasminogen and procathepsin B as a probe to demonstrate the in vitro activation of procathepsin B by the tissue plasminogen activator.

The tissue plasminogen activator (tPA) was found to activate in vitro the procathepsin B purified from malignant ascitic fluids. This activation was time and dose dependent, and was associated with the processing of procathepsin B. The present study shows that tPA is a fast activator of procathepsin B in a neutral pH range, such that generation of cathepsin B activity and processing of procathepsin B are achieved after a 5-min incubation time at 37 degrees C, pH 7.4. In contrast, competition between plasminogen and procathepsin B was observed for the activation and processing by tPA. From these findings, a plasminogen activator pathway for procathepsin B activation related to the plasminogen concentration may exist. In vivo this pathway may be involved in a proteolytic cascade linked to invasion and metastasis.

Immunopurification and characterization of a collagenase/gelatinase domain issued from basement membrane fibronectin.

The proteolytic potential of cellular fibronectin fragments issued from a basement membrane hydrolysate was investigated. Three different gelatinase activities (47, 43 and 37 kDa), located by gelatin zymography, were isolated using successively heparin-agarose, gelatin-agarose and immunopurification with polyclonal antibodies directed against bovine plasma fibronectin. These fragments were also characterized using a monoclonal antibody directed against the extra-domain EDA of cellular fibronectin as a probe. A collagenase activity, reliably indicated by the gelatin zymography pattern, was also found using MCA-Pro-Leu-Gly-Leu-DPA-Ala-Arg-NH2, the intramolecularly quenched fluorogenic substrate of collagenases. From these results, cellular fibronectin was found to be able to exhibit a proteolytic function after limited proteolysis. This MMP-like function could be associated with tissue remodeling in both normal and pathological states, such as metastasis, angiogenesis and tissue repair.

"In vitro" study of basement membrane degradation by the cysteine proteinases, cathepsins B, B-like and L. Digestion of collagen IV, laminin, fibronectin, and release of gelatinase activities from basement membrane fibronectin.

We have studied the soluble fragments obtained from bovine lens capsules after digestion by the cysteine proteinases cathepsins B, B-like and L. These proteinases liberated collagen IV, laminin and fibronectin fragments, as shown by immunoblotting. Sodium dodecyl sulfate treatment of digested capsules gave a soluble material used for subsequent fractionation and immunochemical study. Comparison of both results demonstrate the ability of these cathepsins to degrade a basement membrane at near neutral pH values. The differences observed in the size and the number of fragments suggest that the three proteinases exhibit similar specificities in basement membrane digestion, as shown previously. Nevertheless, cathepsin L seems to be more effective than cathepsins B and B-like. From this study, cysteine proteinases could be associated to basement membrane destruction. Soluble cysteine proteinase digests of bovine lens capsules showed several bands of gelatinolytic activity by gelatin zymography. Three major bands of 77, 60 and 45 kDa were seen whatever the cysteine proteinase used. These bands were identified as fibronectin fragments. Thus cysteine proteinases can activate the latent proteinase fibronectin from basement membrane leading to a new "metastatic cascade". This would be an important factor in the "in vivo" basement membrane dissolution observed during tumor invasion.

In vitro activation of pro-cathepsin B by three serine proteinases: leucocyte elastase, cathepsin G, and the urokinase-type plasminogen activator.

In vitro activation of pro-cathepsin B purified from ascitic fluid of ovarian carcinomas by serine proteinases was studied. Both elastase and cathepsin G from human leucocytes were found to be activators, on the basis of generation of cathepsin B activity and processing of the precursor. These results represent a new cooperative pathway between cancer cells and host cells. The urokinase-type plasminogen activator activated pro-cathepsin B faster than leucocyte proteinases. A new relationship is emerging between the cysteine proteinases and the plasmin-activation system. Both pathways suggest an important role of cathepsin B in the proteolytic cascade associated with tumour invasion.

[Quantitative binding of cysteine-proteinases to a basement membrane: role in their digestion during tumor invasion]. / Fixatíon quantitative des cystéine-protéinases sur une membrane basale: étape-clé de sa digestion au cours de l'invasion tumorale.

Binding of cysteine-proteinases of the papain-superfamily (papain and cathepsins B, B-like and L) to basement membranes was studied by using the enzymatic activity of these proteinases against their specific fluorogenic substrates. The basement membrane used for these experiments is the bovine lens capsule (weight approximately 50 mg). Papain inactivated by E64 was used in competition experiments, that made it possible to obtain the equilibrium constant, Kd and the number of substrate sites per capsule, n. Values were found around 10(-7) M for Kd, and in the 10(12) range for n. Such results would be of significant interest for the understanding of the biological role of cysteine-proteinases in tumour invasion and other types of tissue remodeling.

Quantitative study of the binding of cysteine proteinases to basement membranes.

Binding of cysteine proteinases of the papain superfamily (papain and cathepsins B, B-like and L) to basement membranes was studied by using the enzymatic activity of these proteinases against their specific fluorogenic substrates. Papain inactivated by E64 was used for Kd determination by competition experiments. The binding was characterized using the following parameters, the equilibrium constant, Kd, and the number of substrate sites, n, values of which were in the range of 10(-7) M and 10(12), respectively. Such results would be of significant interest for the understanding of the biological role of cysteine proteinases in tumour invasion and other types of tissue remodeling.

High-performance liquid chromatographic method for the simultaneous purification of cathepsins B, H and L from human liver.

A high-performance liquid chromatographic procedure for the isolation of the three cysteine proteinases, namely cathepsins B, H and L, is described. The method is based on the following four steps. (1) A classical AcA 44 gel permeation separation with a 30-70% ammonium sulphate fraction from the human liver homogenate is used to remove the non-enzymic high-molecular-mass components. (2) Preparative cation-exchange chromatography on a CM-SW TSK column can separate the three proteinases. (3) An anion-exchange step on a semi-preparative DEAE-SW TSK column for the cathepsin H fraction is used to remove a small amount of cathepsins B and L activities. (4) The three separated enzymes are purified on an analytical TSK gel 2000 SW column. The purity of each enzyme is assessed by sodium dodecyl sulphate polyacrylamide gel electrophoresis and electrofocusing on polyacrylamide gels. To check the activities of the purified proteinases, the kinetic constants [Michaelis constant (KM) and catalytic constant (Kcat)] and the ratio Kcat/KM against the fluorigenic substrates Arg-NH-Mec, Z-Arg-Arg-NH-Mec and Z-Phe-Arg-NH-Mec after active-site titration using E-64, were determined. Z-Phe-Phe-CNH2 was also used as a specific inhibitor of cathepsin L. This method requires only 6 g of human liver, and gives a high yield of the three lysosomal cysteine-proteinases: thus, about 150 micrograms of cathepsin B and 50 micrograms each of cathepsins L and H are obtained in a single run.

[Digestion in vitro of basal membrane, bovine lens capsule, by human liver lysosome cathepsins B, H and L and ascitic fluid tumor cathepsin B from ovarian adenocarcinoma]. / Digestion in vitro d'une membrane basale, la capsule de cristallin de boeuf, par les cathepsines B, H et L du lysosome de foie humain et la cathepsine B tumorale du liquide d'ascite d'adénocarcinome ovarien.

Lysosomal cysteine proteinases, cathepsins B, H and L, and tumor cathepsin-B-like protease, are capable of digesting bovine lens capsule, a typical basement membrane, in vitro. Cathepsins L and H proved most active in the pH range 5.0-7.0, whereas cathepsin B and cathepsin B-like protease showed greatest activity at pH 3.0. The process was slow and involved binding of the proteases to the basement membrane. These proteases, of which some are produced by malignant cells, may contribute to tumor spread and progression to metastatic disease.

"In vitro" digestion of intact bovine lens capsules by four human lysosomal cysteine-proteinases.

We have examined the biochemical degradation of an isolated basement membrane matrix (bovine lens capsule) by human liver cathepsins B, H and L and the cathepsin B-like proteinase from malignant ascitic fluid. This study was carried out using two different methods: The first strategy was to follow the liberation of soluble proteins and peptides as a function of time at different pHs. Then the digestion products were characterized, as collagen IV, fibronectin and laminin fragments, using monospecific polyclonal antibodies and a quantitative dot-blot analysis. From these results, the ability of the four proteinases to digest "in vitro" intact bovine lens capsule in the physiological pH range is demonstrated. Cathepsin L is the most powerful against the three membrane components studied. As shown by electroelution and immunochemical quantitation, the digestion would be a consequence of proteinases binding to the capsule. With intact basement membrane as a substrate a "in vitro" molecular analysis of this digestion process was possible by these methods. On this basis, the "in vivo" secretion of cysteine proteinases during malignancy would be related to the local basement membrane dissolution associated with tumor invasion.

The glycosylation state of the precursors of the cathepsin B-like proteinase from human malignant ascitic fluid: possible implication in the secretory pathway of these proenzymes.

We have investigated the structure of the carbohydrate moiety of the precursors of the cathepsin B-like proteinase (PCBt). The largest precursor has an apparent molecular size (Mr) of 45-47 Kd and it contains 3 N-linked oligosaccharide chains which were Endo beta N acetylglucosaminidase H (Endo H)-resistant forms. On the other hand, these chains were sequentially removed by Endo beta N acetylglucosaminidase F (Endo F). Both results indicate a complex type structure for these oligosaccharides. As usual in these cases, sialic acids were also found. In the deglycosylated state, PCBt has a Mr value of 36 Kd closely related to the 35.9 Kd Mr for human Pro CB, deduced from the cDNa sequence. These findings may explain the extracellular location of PCBt in malignancy: complex oligosaccharides are in most cases associated with secretory or membrane bound glycoproteins. On the contrary, mannose-rich types are involved in the lysosomal routage.

Immunohistochemical and biochemical study of a cathepsin B-like proteinase in human colonic cancers.

An immunohistological study was carried out on 51 human colorectal adenocarcinomas and eight samples of histologically normal colonic mucosa removed far from tumors, using anti-rabbit cathepsin B and anti-human cathepsin B immunoglobulins. Positive reactions were obtained on tumor cells and macrophage-like cells. However, as these immunoglobulins could not discriminate between cathepsin B and cathepsin B-like proteinases, and as they cross-reacted with cathepsins H and L, a partial characterization of the proteinase activities was performed in order to identify the type of enzyme present in the positive cells. The levels of cathepsins H and L were very low in extracts of colorectal tumors and normal colonic mucosa. A peculiar cathepsin B-like proteinase activity with pH optimum at 6.8 was found in tumor extracts together with the lysosomal cathepsin B, whereas normal colonic mucosa showed only cathepsin B activity (pH optimum, 6.0). These results indicate that lysosomal cathepsin B is responsible for staining of macrophage-like cells found in the lamina propria of colonic mucosa and in the peritumoral stroma. Immunohistochemical staining of colonic tumor cells observed in 29/51 cases seems on the other hand to be primarily due to a cathepsin B-like proteinase. Three colonic tumor cell lines, Colo-205, HT-29, and SW-1116, were also studied using the same methods. These cells produced a latent cathepsin B-like proteinase which, after activation, was similar to that found in tumor extracts. This latent proteinase was detected mainly in the culture media. The cultured colonic tumor cells, after staining by anti-cathepsin B antibodies, showed strongly positive granules. In conclusion, this work demonstrates that malignant colonic cells are the source of a cathepsin B-like proteinase, with optimal activity near neutrality. Its secretion into the extracellular space indicates furthermore, that it may be an important component of the "proteinase cascade" associated with tumor invasion and metastasis.

Purification and characterization of two different precursor forms of the cathepsin B-like proteinase from human malignant ascitic fluid.

We have purified two different precursors of a cathepsin B-like proteinase (PCBT) from malignant ascitic fluid. The molecular mass of these proteins were 45-47 kDa and 36 kDa, respectively. This report is the first which shows cathepsin-B precursors as purified proteins. By using sheep immunoglobulins directed against denatured lysosomal cathepsin B, we have found that both precursors, together with the 33-kDa pepsin generated cathepsin B-like proteinase, reacted in immunoblotting: the three components are thus cathepsin B-related. These antibodies allow us the show that during pepsin activation the 45-47 kDa precursor is converted to the 33-kDa cathepsin B-like proteinase together with the 36-kDa PCBT. We have also prepared sheep immunoglobulins directed against the 36-kDa precursor. The generation of the cathepsin B-like proteinase by pepsin digestion of purified precursors followed a time and dose dependent process. This latter result argues for activation through peptide bond cleavages.

[Regulation of neoplasm-specific cathepsin B by cysteine-protease inhibitors present in cancerous exudates]. / Régulation de la cathepsine B spécifique du néoplasme par les inhibiteurs des cystéine-protéases présents dans les exsudats de cancéreux.

The Cathepsin B-like proteinase, a secretory form of lysosomal cathepsin B, is present in some cancerous exudates (i.e. pleural and ascitic fluids). It has been suggested that this enzyme may be involved in the invasive process, one of the most important aspects of cancer pathology. In the same fluids, two kinds of cysteine-proteinase inhibitors (C.P.I.'s) are found- HMr-CPI (90,000 daltons) and LMr-CPI's (11,000-13,000 daltons). The Cathepsin B-like enzyme is more strongly inhibited by the LMr-CPI's than by the HMr-CPI, the Ki values are 4.0 X 10(-9) M and 1.2 X 10(-7) M respectively. Theses results underline the similarity between this enzyme and the lysosomal Cathepsin B. On the other hand, the inhibitors could play a protective role against tumor invasion.