Comparison of cathepsin L synthesized by normal and transformed cells at the gene, message, protein, and oligosaccharide levels

The major excreted protein of transformed mouse fibroblasts (MEP) has recently been identified as the lysosomal cysteine protease, cathepsin L. The synthesis and intracellular trafficking of this protein in mouse fibroblasts are regulated by growth factors and malignant transformation. To further define the basis for this regulation, a cDNA encoding MEP/cathepsin L was isolated from a mouse liver cDNA library and used to compare cathepsin L of normal and Kirsten sarcoma virus-transformed NIH 3T3 fibroblasts. Although cathepsin L message levels were elevated 20-fold in the transformed fibroblasts, normal and transformed cells displayed similar cathepsin L genomic DNA digest patterns and gene copy numbers, and cathepsin L mRNA sequences appeared identical by RNase protection analysis. These findings indicate that (i) cathepsin L is synthesized from the same gene in normal and transformed cells and (ii) cathepsin L polypeptides made by these cells are translated with the same primary sequence. Cathepsin L polypeptides synthesized by quiescent, growing, and transformed cells displayed similar isoelectric focusing patterns, suggesting similar post-translational modification. Site-directed mutagenesis of the mouse liver cDNA and expression in COS monkey cells was used to examine the glycosylation of mouse cathepsin L. The results indicated that only one of the two potential N-linked glycosylation sites (the one at Asn221) is glycosylated. Analysis by ion exchange chromatography on QAE-Sephadex, and affinity chromatography on mannose 6-phosphate receptor-Affi-Gel 10, indicated that the cathepsin L oligosaccharide was phosphorylated similarly in normal and transformed cells. Although several phosphorylated oligosaccharide species were observed, the major species contained two phosphomonoester moieties and bound efficiently to the receptor. These findings suggest that cathepsin L made by normal and transformed mouse fibroblasts are identical and substantiate the hypothesis that trafficking of cathepsin L in these cells is regulated by growth-induced changes in the lysosomal protein transport system.     

The N-terminal amino acid sequences of the heavy and light chains of human cathepsin L. Relationship to a cDNA clone for a major cysteine proteinase from a mouse macrophage cell line.

Human liver cathepsin L consists of a heavy chain and a light chain with Mr values of 25,000 and 5000 respectively. The chains have been purified and their N-terminal amino acid sequences have been determined. The 40 amino acids determined from the heavy chain and 42 amino acids sequenced in the light chain are homologous with the N-terminal and C-terminal regions respectively of the superfamily of cysteine proteinases. Therefore it is likely that the two chains of cathepsin L are derived by proteolysis of a single polypeptide precursor. Of the amino acids sequenced, 81% are identical with the homologous portions of a protein sequence for a major cysteine proteinase predicted from a cDNA clone from a mouse macrophage cell line. This is the closest relative amongst the known sequences in the superfamily and strongly indicates that the protein encoded by this mRNA is cathepsin L. The mouse protein is also probably the major excreted protein of a transformed cell line [Gal & Gottesman (1986) Biochem. Biophys. Res. Commun. 139, 156-162]. The heavy chain is identical in only 71% of its residues with the sequence of ox cathepsin S, providing further evidence that this latter enzyme is probably not a species variant of cathepsin L. The relationship with a second unidentified cathepsin cDNA clone from a bovine library is much weaker (41% identity), and so this clone remains unidentified.     

Biosynthesis and processing of lysosomal cathepsin L in primary cultures of rat hepatocytes

The biosynthesis and proteolytic processing of lysosomal cathepsin L was studied using in vitro translation system and in vivo pulse-chase analysis with [35S]methionine and [32P]phosphate in primary cultures of rat hepatocytes. Messenger RNA prepared from membrane-bound but not free polysomes directed the synthesis of a primary translation product of an immunoprecipitable 37.5-kDa cathepsin L in vitro. The 37.5-kDa form was converted to the 39-kDa form when translated in the presence of dog pancreas microsomes. During pulse-chase experiments with [35S]methionine in cultured rat hepatocytes, cathepsin L was first synthesized as a 39-kDa protein, presumably the proform, after a short time of labeling, and was subsequently processed into the mature forms of 30 and 25 kDa in the cell. On the other hand, considerable amounts of the proenzyme were found to be secreted into the culture medium without further proteolytic processing during the chase. The precursor and mature enzymes were N-glycosylated with high-mannose-type oligosaccharides, and the proenzyme molecule contained phosphorylated oligosaccharides. The effects of tunicamycin and chloroquine were also investigated. In the presence of tunicamycin, a 36-kDa unglycosylated polypeptide appeared in the cell and this protein was exclusively secreted from the cells without undergoing proteolytic processing. These results suggest that cathepsin L is initially synthesized on membrane-bound polysomes as a 37.5-kDa prepropeptide and that the cotranslational cleavage of the 1.5-kDa signal peptide and the core glycosylation convert the precursor to the 39-kDa proform, which is subsequently processed to the mature form during biosynthesis. Thus, the biosynthesis and secretion of lysosomal cathepsin L in rat hepatocytes seem to be analogous to those of the major excreted protein of transformed mouse fibroblasts [S. Gal, M. C. Willingham, and M. M. Gottesman (1985) J. Cell Biol. 100, 535-544] and the mouse cysteine proteinase of activated macrophages [D.A. Portnoy, A. H. Erickson, J. Kochan, J. V. Ravetch, and J. C. Unkeless (1986) J. Biol. Chem. 261, 14697-14703].     

Use of a cloned multidrug resistance gene for coamplification and overproduction of major excreted protein, a transformation-regulated secreted acid protease.

Malignantly transformed mouse fibroblasts synthesize and secrete large amounts of major excreted protein (MEP), a 39,000-dalton precursor to an acid protease (cathepsin L). To evaluate the possible role of this protease in the transformed phenotype, we transfected cloned genes for mouse or human MEP into mouse NIH 3T3 cells with an expression vector for the dominant, selectable human multidrug resistance (MDR1) gene. The cotransfected MEP sequences were efficiently coamplified and transcribed during stepwise selection for multidrug resistance in colchicine. The transfected NIH 3T3 cell lines containing amplified MEP sequences synthesized as much MEP as did Kirsten sarcoma virus-transformed NIH 3T3 cells. The MEP synthesized by cells transfected with the cloned mouse and human MEP genes was also secreted. Elevated synthesis and secretion of MEP by NIH 3T3 cells did not change the nontransformed phenotype of these cells.     

Expression of mouse cathepsin L cDNA in Saccharomyces cerevisiae: evidence that cathepsin L is sorted for targeting to yeast vacuole.

To investigate the intracellular transport mechanism of lysosomal cathepsin L in yeast cells, we attempted to produce mouse cathepsin L in Saccharomyces cerevisiae by placing the coding region under the control of the promoter of the yeast glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene. Immunoblotting analysis by the use of an antibody specific for rat cathepsin L revealed that the yeast cells carrying the cathepsin L coding sequence produced 39- and 30-kDa products, which correspond to the rat procathepsin L and the single-chain form of mature cathepsin L, respectively. The precursor polypeptide showed sensitivity toward endoglycosidase H treatment. Cell fractionation experiments demonstrated that the processed form of 30-kDa cathepsin L was found to be colocalized to the yeast vacuole with the marker enzyme carboxypeptidase Y in a Ficoll step gradient. In the prepared vacuolar fraction, a considerable amount of cathepsin L was revealed to be cofractionated with the vacuolar membranes. Furthermore, the phase separation experiments with Triton X-114 provide the first evidence showing that the mature form of cathepsin L polypeptide is strongly associated with the vacuolar membranes. Therefore, the present results suggest that the mouse cathepsin L precursor polypeptide is initially synthesized as the proenzyme in the yeast cells and then correctly delivered to the vacuole. During the intracellular sorting pathway, the procathepsin L would undergo the post-translational proteolytic processing step to generate the mature enzyme. Based on these lines of evidence, we propose that cathepsin L is recognized by mechanisms similar to those for the intracellular sorting and processing of vacuolar proteins in the yeast cells.     

Pro domain peptide of HGCP-Iv cysteine proteinase inhibits nematode cysteine proteinases

Cysteine proteinases (CPs) are synthesized as zymogens and converted to mature proteinase forms by proteolytic cleavage and release of their pro domain peptides. A cDNA encoding a papain-like CP, called hgcp-Iv, was isolated from a Heterodera glycines J2 cDNA library, expressed and utilized to assess the ability of its propeptide to inhibit proteinase in its active form. The hgcp-Iv cDNA sequence encodes a polypeptide of 374 amino acids with the same domain organization as other cathepsin L-like CPs, including a hydrophobic signal sequence and a pro domain region. HGCP-Iv, produced in Escherichia coli as a fusion protein with thioredoxin, degrades the synthetic peptide benzyloxycarbonyl-Phe-Arg-7-amido-4-methylcoumarin and is inhibited by E-64, a substrate and inhibitor commonly used for functional characterization of CPs. Recombinant propeptides of HGCP-Iv, expressed in E. coli, presented high inhibitory activity in vitro towards its cognate enzyme and proteinase activity of Meloidogyne incognita females, suggesting its usefulness in inhibiting nematode CPs in biological systems. Cysteine proteinases from other species produced no noticeable activity.     

Modulation of the transport of a lysosomal enzyme by PDGF

The major excreted protein (MEP) of transformed mouse fibroblasts is the lysosomal protease, cathepsin L. MEP is also secreted by untransformed mouse cells in response to growth factors and tumor promoters, and is thought to play a role in cell growth and transformation. To determine the relationship between MEP synthesis and MEP secretion, we have examined these events in PDGF-treated NIH 3T3 cells. PDGF enhanced MEP synthesis and caused the diversion of MEP from the lysosomal delivery pathway to a secretory pathway. These two effects were found to be regulated independently at various times after growth factor addition. Short PDGF treatments (0.5 or 1 h) resulted in quantitative secretion of MEP although synthesis was near the control level. High levels of both synthesis and secretion occurred between 2 and 14 h of PDGF treatment. Between 18 and 30 h, the amount of secreted MEP returned to the low control level even though synthesis remained elevated. The secretion was specific for MEP; other lysosomal enzymes were not found in the media from PDGF-treated cells. PDGF-induced secretion of MEP was inhibited 84% by cycloheximide, suggesting that protein synthesis is required to elicit this effect. PDGF also caused a time-dependent increase in mannose 6-phosphate (Man-6-P) receptor-mediated endocytosis. These data support a model in which PDGF alters the distribution of Man-6-P receptors such that the Golgi concentration of receptors becomes limiting, thereby causing the selective secretion of the low affinity ligand, MEP.     

Rat procathepsin B. Proteolytic processing to the mature form in vitro.

Expression of rat procathepsin B in yeast led to the secretion of both the latent and mature forms of the enzyme. Culture in the presence of a cysteine proteinase inhibitor prevented this processing. We have expressed and purified a mutant form of rat procathepsin B whose active-site cysteine residue has been changed to a serine, and which also lacks the glycosylation site in the mature region of the protein. This non-active mutant protein was secreted essentially in an unprocessed form. The purified protein has been incubated with a variety of proteinases, and results indicate that cathepsins D and L, as well as mature cathepsin B itself, can produce a processed (single-chain) form of cathepsin B from this precursor. Amino-terminal sequencing of these processed forms has revealed that they are all elongated by a few residues with respect to the mature form found in vivo. The action of a combination of cathepsin B with dipeptidylpeptidase I produced a single-chain form of cathepsin B with the correct amino terminus. This work has also shown that the processing of procathepsin B to a single-chain form can be an autocatalytic process, in at least an intermolecular manner.     

Molecular cloning and characterization of onchocystatin, a cysteine proteinase inhibitor of Onchocerca volvulus.

A cDNA clone designated OV7 encodes a polypeptide that corresponds to a highly antigenic Onchocerca volvulus protein. OV7 has significant amino acid sequence homology to the cystatin superfamily of cysteine proteinase inhibitors. In this report we establish that the OV7 recombinant protein is active as a cysteine proteinase inhibitor, and we have named it onchocystatin. It contains a cystatin-like domain that inhibits the activity of cysteine proteinases at physiological concentrations. Recombinant glutathione S-transferase-OV7 (GST-OV7, 1 microM) and maltose-binding protein-OV7 (MBP-OV7, 4 microM) fusion polypeptides inhibit 50% of the enzymatic activity of the bovine cysteine proteinase cathepsin B. Neither fusion polypeptide inhibits serine or metalloproteinases activity. The Ki for GST-OV7 fusion polypeptide is 170 nM for cathepsin B and 70 pM or 25 nM for cysteine proteinases purified from a protozoan parasite Entamoeba histolytica or the free living nematode Caenorhabditis elegans, respectively. The 5' end of the OV7 clone was isolated by polymerase chain reaction and sequenced, thus extending the previous cDNA clone to 736 base pairs. This represents the complete coding sequence of the mature onchocystatin (130 amino acids). A hydrophobic leader sequence of 32 amino acids was found, indicating a possible extracellular function of the onchocerca cysteine proteinase inhibitor.     

Molecular cloning and structural and functional characterization of human cathepsin F, a new cysteine proteinase of the papain family with a long propeptide domain.

A cDNA encoding a new cysteine proteinase belonging to the papain family and called cathepsin F has been cloned from a human prostate cDNA library. This cDNA encodes a polypeptide of 484 amino acids, with the same domain organization as other cysteine proteinases, including a hydrophobic signal sequence, a prodomain, and a catalytic region. However, this propeptide domain is unusually long and distinguishes cathepsin F from other proteinases of the papain family. Cathepsin F also shows all structural motifs characteristic of these proteinases, including the essential cysteine residue of the active site. Consistent with these structural features, cathepsin F produced in Escherichia coli as a fusion protein with glutathione S-transferase degrades the synthetic peptide benzyloxycarbonyl-Phe-Arg-7-amido-4-methylcoumarin, a substrate commonly used for functional characterization of cysteine proteinases. Furthermore, this proteolytic activity is blocked by trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane, an inhibitor of cysteine proteinases. The gene encoding cathepsin F maps to chromosome 11q13, close to that encoding cathepsin W. Cathepsin F is widely expressed in human tissues, suggesting a role in normal protein catabolism. Northern blot analysis also revealed a significant level of expression in some cancer cell lines opening the possibility that this enzyme could be involved in degradative processes occurring during tumor progression.     

Cloning and characterization of a mouse cysteine proteinase

cDNA clones encoding a mouse cysteine proteinase were isolated from a cDNA library constructed from mRNA derived from the macrophage-like cell line J774. The DNA sequence predicts a protein that is closely related to, but distinct from, the lysosomal enzyme cathepsin H. Alignment of the predicted amino acid sequence with the known protein sequences for seven other cysteine proteinases suggests that the cloned DNA encodes a 334-residue protein containing both a 17-amino acid pre-region and a 96-amino acid pro-region. Consistent with this prediction, antiserum raised to a recombinant fusion protein expressed in Escherichia coli immunoprecipitated multiple forms of the cysteine proteinase in mouse peritoneal macrophages and fibroblasts. In pulse-chase experiments, a 36-kDa precursor, presumedly the pro-form, was converted intracellularly into a 28-kDa protein and subsequently into a 21-kDa protein. Indirect immunofluorescence microscopy results suggested that the cysteine proteinase was localized to lysosomes. Western blot analysis detected significantly more of the proteinase in thioglycolate-elicited peritoneal macrophages than in resident peritoneal macrophages. Northern blot analysis revealed that several cell lines failed to express mouse cysteine proteinase mRNA.     

Mouse cathepsin F: cDNA cloning, genomic organization and chromosomal assignment of the gene

A murine cysteine protease of the papain family was identified by dbEST-database search. A 1.87kb full-length cDNA encoding a predicted polypeptide of 462 amino acids was sequenced. Since the encoded polypeptide shows more than 80% sequence identity with human cathepsin F, it is most likely that this cDNA represents the murine homologue of cathepsin F, and it was therefore named accordingly. Murine cathepsin F exhibits a domain structure typical for papain-like cysteine proteases, a 20 amino acid N-terminal hydrophobic signal sequence followed by an extraordinarily long propeptide of 228 amino acids and the domain of the mature protease comprising 214 amino acids. The mature region contains all features characteristic of a papain-like cysteine protease, including the highly conserved cysteine, histidine and asparagine residues of the 'catalytic triad'. Genomic clones covering the murine cathepsin F gene were isolated. The mouse cathepsin F gene consists of 14 exons and 13 introns and spans 5.8kb. Murine cathepsin F was mapped to chromosome 19, a region with synteny homology to a region of human chromosome 11 to which human cathepsin F has been mapped previously. Northern blot analysis of RNA from multiple tissues revealed a ubiquitous expression of cathepsin F in mouse and man.     

Influx of bivalent cations can be independent of receptor stimulation in human endothelial cells.

The major active forms of cathepsins B and L were identified in Kirsten-virus-transformed mouse fibroblasts by the use of a specific radiolabelled inhibitor, benzyloxycarbonyl-Tyr(-125I)-Ala-CHN2. No other proteins were labelled, demonstrating the specificity of this inhibitor for cysteine proteinases. Cathepsins B and L were distinguished by the use of specific antibodies. One active form of cathepsin B, Mr 33,000-35,000, and two active forms of cathepsin L, Mr 30,000 and 23,000, were identified. The intracellular precursors of these proteins had higher Mr values of 39,000 and 36,000 for cathepsins B and L respectively, as shown by pulse-chase experiments with [35S]methionine-labelled proteins. These did not react with the inhibitor under our culture conditions. The precursor of cathepsin L was secreted whereas the precursor of cathepsin B was not, demonstrating that secretions of the two enzymes are regulated differently. In contrast with results found previously for the purified protein [Mason, Gal & Gottesman (1987) Biochem. J. 248, 449-454], the secreted precursor form of cathepsin L did not react with the inhibitor either, indicating that it is not active and therefore, as such, cannot be directly involved in tumour invasion. The secreted protein did react with the inhibitor when incubated at pH 3.0, showing that the protein can be activated, although this did not occur under our culture conditions.     

Decreased activity of cathepsins L+B and decreased invasive ability of PC3 prostate cancer cells

Cancer metastasis involves multiple factors, one of which is the production and secretion of matrix degrading proteases by the cancer cells. Many metastasizing cancer cells secrete the lysosomal proteases, cathepsins L and B, which implicates them in the metastatic process. Cathepsins L and B are regulated by endogenous cysteine proteinase inhibitors (CPI) known as cystatins. An imbalance between cathepsin L and/or B and cystatin expression/activity may be a characteristic of the metastatic phenotype. To determine whether cystatins can attenuate the invasive ability of PC3 prostate cancer cells, cells were transfected with a cDNA coding for chicken cystatin. Expression of chicken cystatin mRNA was determined by PCR analysis. Total cysteine proteinase inhibitory activity, cathepsins L+B activity, and invasion through a Matrigel® matrix were assessed. Stably transfected cells expressed the chicken cystatin mRNA and exhibited a significant decrease in secreted cathepsin L+B activity and a small increase in secreted cysteine proteinase inhibitor activity. The ability of cystatin transfected cells to invade the reconstituted basement membrane, Matrigel®, was attenuated compared to nontransfected cells or cells transfected with vector alone. We have demonstrated that the cysteine proteinases cathepsins L and B participate in the invasive ability of the PC3 prostate cancer cell line, and we discuss here the potential of using cysteine proteinase inhibitors such as the cystatins as anti-metastatic agents.     

Two subunits of the insect 26/29-kDa proteinase are probably derived from a common precursor protein

We previously identified the 26/29-kDa proteinase in the hemocytes of Sarcophaga peregrina (flesh fly) that appears to participate in elimination of foreign proteins in this insect [Eur. J. Biochem. 209, 939-944 (1992)]. Here, we report the cDNA cloning of this proteinase. The cDNA encodes a protein which includes both the 26- and 29-kDa subunit, strongly suggesting that the both subunits are derived from a single precursor protein. The 26- and 29-kDa subunit located at the amino-terminal and carboxyl-terminal of the precursor protein. The 29-kDa subunit itself appeared to be a proteinase, for this subunit had 52% sequence identity with Sarcophaga cathepsin L, while 26-kDa subunit had no significant similarity. We also showed that 26/29-kDa proteinase was insensitive to specific inhibitors of cathepsin L. These results indicate that this proteinase is a novel member of the papain family. We isolated similar cDNAs from Drosophila melanogaster and Periplaneta americana (cockroach), suggesting that this proteinase is conserved in a wide variety of insects and participates in their defense mechanisms.     

Decreased activity of cathepsins L+B and decreased invasive ability of PC3 prostate cancer cells

Cancer metastasis involves multiple factors, one of which is the production and secretion of matrix degrading proteases by the cancer cells. Many metastasizing cancer cells secrete the lysosomal proteases, cathepsins L and B, which implicates them in the metastatic process. Cathepsins L and B are regulated by endogenous cysteine proteinase inhibitors (CPI) known as cystatins. An imbalance between cathepsin L and/or B and cystatin expression/activity may be a characteristic of the metastatic phenotype. To determine whether cystatins can attenuate the invasive ability of PC3 prostate cancer cells, cells were transfected with a cDNA coding for chicken cystatin. Expression of chicken cystatin mRNA was determined by PCR analysis. Total cysteine proteinase inhibitory activity, cathepsins L+B activity, and invasion through a Matrigel® matrix were assessed. Stably transfected cells expressed the chicken cystatin mRNA and exhibited a significant decrease in secreted cathepsin L+B activity and a small increase in secreted cysteine proteinase inhibitor activity. The ability of cystatin transfected cells to invade the reconstituted basement membrane, Matrigel®, was attenuated compared to nontransfected cells or cells transfected with vector alone. We have demonstrated that the cysteine proteinases cathepsins L and B participate in the invasive ability of the PC3 prostate cancer cell line, and we discuss here the potential of using cysteine proteinase inhibitors such as the cystatins as anti-metastatic agents.     

A cysteine proteinase secreted from human breast tumours is immunologically related to cathepsin B.

The stable cathepsin B-like cysteine (thiol) proteinase secreted from human breast tumours in culture was shown to be destabilized by mercurial compounds. After such treatment the enzyme cross-reacts in a radioimmunoassay with a monospecific antiserum to human liver cathepsin B. It is suggested that the secreted enzyme may be a precursor form of lysosomal cathepsin B.     

Molecular cloning of cDNA for rat cathepsin C. Cathepsin C, a cysteine proteinase with an extremely long propeptide

A cDNA for rat cathepsin C (dipeptidylaminopeptidase I) was isolated. The deduced amino acid sequence of cathepsin C comprises 462 amino acid residues: 28 NH2-terminal residues corresponding to the signal peptide, 201 residues corresponding to the propeptide, and 233 COOH-terminal residues corresponding to the mature enzyme region. Four potential glycosylation sites were found, three located in the propeptide region, and one in the mature enzyme region. The amino acid sequence of mature cathepsin C has 39.5% identity to that of cathepsin H, 35.1% to that of cathepsin L, 30.1% to that of cathepsin B, and 33.3% to that of papain. Cathepsin C, therefore, is a member of the papain family, although its propeptide region is much longer than those of other cysteine proteinases and shows no significant amino acid sequence similarity to any other cysteine proteinase.