Collagenase and collagenolytic cathepsin in normal and fibrotic rat liver

Collagenase and collagenolytic cathepsin activities in normal and carbon tetrachloride-induced fibrotic livers of rats were simultaneously determined at 35 and 25 degrees C for 18 h, using the same 14C-labeled neutral soluble collagen as a substrate. Collagenolytic cathepsin had higher activity under the assay conditions at both 35 and 25 degrees C than collagenase in normal and fibrotic livers. On sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis, the collagen was visibly degraded by collagenolytic cathepsin, but not by collagenase. These results indicate that, unlike collagenase, collagenolytic cathepsins exist as active forms in the rat liver, and can participate in the degradation of collagens, especially of soluble collagens including procollagens.     

Collagenolytic activity of bacteria

Actively growing aerobic and anaerobic bacteria were screened by a plate assay, with reconstituted guinea pig collagen as a substrate, for their ability to produce a collagenolytic factor. Collagenolytic activity was not demonstrated among the aerobic organisms tested, with the exception of one strain of Staphylococcus aureus (only when grown under anaerobic conditions). Collagenolytic activity, however, was detected in cultures of Clostridium tetani and Bacteroides species other than B. melaninogenicus. Collagenolytic activity of these organisms could be confirmed by measuring the amount of hydroxyproline liberated from the collagen gel during growth. Although collagenase production by Pseudomonas aeruginosa has been suggested in previous reports, our results were negative. An extracellular fraction of P. aeruginosa was able to hydrolyze a synthetic hexapeptide Cbz-glycyl-l-prolyl-glycyl-glycyl-l-prolyl-l- alanine, but was without detectable effect on reconstituted collagen.     

Nereis cuticle collagen. Proteolysis by marine vibrial and clostridial collagenases

Proteolysis of Nereis cuticle collagen by two bacterial collagenases was investigated using viscosimetry, enzyme kinetics, sodium dodecyl sulfate polyacrylamide gel electrophoresis, and ion exchange chromatography of collagenolytic peptides. Collagenase of the marine Vibrio B-30 completely degrades native cuticle collagen at 7 degress C with a turnover number 50 times greater than that of the clostridial collagenase. Although turnover numbers for the two enzymes are comparable when using denatured cuticle collagen as substrate, the vibrial collagenase appears to cleave twice as many peptide bonds per mg of cuticle collagen as does the clostridial enzyme. Sodium dodecyl sulfate gel electrophoresis of collagenase-digested native cuticle collagen reflects the resistance of the collagen to clostridial collagenase; however, the vibrial enzyme completely degrades the cuticle collagen with the formation of one transient intermediate (Mr 400,000). Peptide analysis of fully digested denatured cuticle collagen reveals that the two enzymes have a number of qualitative and quantitative similarities. Despite these, however, only the vibrial collagenase seems capable of extensively degrading native cuticle collagen.     

A simple vertebrate collagenase assay using soluble radioactive collagen substrate

A highly sensitive assay for vertebrate collagenase has been developed using [14C]proline- or [3H]proline-labeled collagen as soluble substrate. The substrate was easy to prepare, gave high specific activity (1.4 X 10(6) cpm/mg collagen), and was stable at -20 degrees C for a long period. The digestion reaction for the assay was done at 21 degrees C to minimize the cleavage of collagen by proteases other than collagenase and to protect the 3/4 and 1/4 cleavage fragments of collagen from being further attacked by proteases. The cleaved products were denatured and then separated from undigested native collagen by precipitation with 1 M NaCl at pH 3.5. The conditions selected for denaturation and separation gave better discrimination between the cleaved products and uncleaved substrate than did conditions used in some other assays. The digestion products can be examined further by gel electrophoresis at the end of the assay to confirm the activity of vertebrate collagenase. This assay can also be adapted to assess telopeptidase activity independently of collagenase activity.     

Diversity,Structures, and Collagen-Degrading Mechanisms of Bacterial Collagenolytic Proteases

Bacterial collagenolytic proteases are important because of their essential role in global collagen degradation and because of their virulence in some human bacterial infections. Bacterial collagenolytic proteases include some metalloproteases of the M9 family from Clostridium or Vibrio strains, some serine proteases distributed in the S1, S8, and S53 families, and members of the U32 family. In recent years, there has been remarkable progress in discovering new bacterial collagenolytic proteases and in investigating the collagen-degrading mechanisms of bacterial collagenolytic proteases. This review provides comprehensive insight into bacterial collagenolytic proteases, especially focusing on the structures and collagen-degrading mechanisms of representative bacterial collagenolytic proteases in each family. The roles of bacterial collagenolytic proteases in human diseases and global nitrogen cycling, together with the biotechnological and medical applications for these proteases, are also briefly discussed.     

A rapid sensitive collagenase assay.

A rapid, sensitive collagenase assay has been developed using¹⁴C-acetylated collagen as a substrate. Acid-soluble calfskin collagen was labeled with [1-¹⁴C]acetic anhydride at pH 8. The acetylated collagen had a specific activity of 6.25 × 10⁵ dpm/mg protein. Collagen was not denatured as evidenced by its resistance to nonspecific proteolysis and sensitivity to bacterial collagenase. Polyacrylamide gel electrophoresis of the acetylated protein showed that the radioactivity was present in the three bands corresponding to the α, β, and γ components of collagen. The rate of release of ¹⁴C from labeled collagen by Clostridium histolyticum collagenase was proportional to enzyme and substrate concentration.     

Demonstration of collagenase activity in adult Strongyloides ratti (Nematoda:Strongyloididae) and its absence in the infective larvae

Larvae and adults of Strongyloides ratti were examined for collagenolytic activity on 14C proline-labelled, native, guinea-pig skin collagen substrate. The activity was measured by determining either the amount of hydroxyproline released or the amount of radioactivity in the solubilized fraction of the collagen substrate. Bacterial collagenase was used for enzyme control and trypsin served as substrate control. No collagenolytic activity was found in living larvae, their extracts or metabolites. The collagenolytic activity of the metabolites of adult worms appeared weak, whereas that of the extracts of the adults was pronounced. It is suggested that collagenase is active in the adult females at the time of migration in the intestinal mucosa during oviposition.     

Collagenolytic Activity of Cured Hide Bacteria

S ummary : The aerobic and anaerobic collagenolytic activities of bacterial populations from 1 Australian and 2 South African cured hide samples at 0·85, 2·34, 7·0 and 10·0% of NaCl are described. The rate of denaturation of pure, undegraded collagen was determined by the release of amino acids and considerable collagenolysis was demonstrated. Collagenolytic activity was highest under aerobic conditions. Australian hides which produce uniformly good leather with little or no decay lacked collagenolytic bacteria.     

A polyphasic approach to the exploration of collagenolytic activity in the bacterial community associated with the marine sponge Cymbastela concentrica

Collagen is an important, extracellular structural protein for metazoans and provides a rich nutrient source for bacteria that possess collagen-degrading enzymes. In a symbiotic host system, collagen degradation could benefit the bacteria, but would be harmful for the eukaryotic host. Using a polyphasic approach, we investigated the presence of collagenolytic activity in the bacterial community hosted by the marine sponge Cymbastela concentrica. Functional screening for collagenase activity using metagenomic library clones (227 Mbp) and cultured isolates of sponge's bacterial community, as well as bioinformatic analysis of metagenomic shotgun-sequencing data (106,679 predicted genes) were used. The results show that the abundant members of the bacterial community contain very few genes encoding for collagenolytic enzymes, while some low-abundance sponge isolates possess collagenolytic activities. These findings indicate that collagen is not a preferred nutrient source for the majority of the members of the bacterial community associated with healthy C. concentrica, and that some low-abundance bacteria have collagenase activities that have the potential to harm the sponge through tissue degradation.     

Synthesis of collagenase and collagenase inhibitors by osteoblast-like cells in culture

A rat osteosarcoma cell clone (ROS 17/2), and osteoblast-enriched populations from rat calvaria cultured in the presence of concanavalin A, have been shown to produce latent collagenase and collagenase inhibitors. The enzymes and inhibitor activities from the ROS 17/2 cells were concentrated by ammonium sulphate precipitation and separated by gel filtration on AcA 54 resin. The size of the latent collagenase (Mr approximately equal to 58000) was reduced on conversion to active enzyme (Mr approximately equal to 48000) by p-aminophenylmercuric acetate. Latent and active forms of gelatinase activity, similar in size to the corresponding forms of collagenase, were also resolved. The collagenase inhibitor activity, which was sensitive to organomercurials, was recovered in two peaks (Mr approximately equal to 68000 and 30000). The active collagenase cleaved interstitial collagens (type I = III greater than II) producing typical 3/4 and 1/4 fragments. This activity was inhibited by the metal ion chelators ethylenediaminetetraacetic acid and o-phenanthroline. Additional specific cleavages of native collagen were also observed which, from the susceptibility of this activity to phenylmethylsulphonyl fluoride, leupeptin and antipain, suggested the presence of a second collagenolytic enzyme. This synthesis of collagenolytic enzymes by these osteoblast-like cells suggests that individual osteoblasts, like fibroblasts, are capable of both synthesizing and degrading their respective organic matrices in vivo.     

Properties of a collagenolytic enzyme from Bipalium kewense

A collagenolytic enzyme from the land planarian Bipalium kewense has been purified by preparative isoelectric focusing. The enzyme has a molecular weight of 47,000 +/- 2,000 and appears to be dimeric. It has an isoelectric point of 4.6 +/- 0.1 and a high content of acidic amino acids. The amino acid composition of the Bipalium collagenase is similar to that of human skin fibroblast collagenases but clearly different from previously reported collagenolytic proteases from other invertebrates, Uca pugilator and Hypoderma lineatum. In its action on guinea-pig collagen, the enzyme produces distinct products, at low incubation temperatures, different from those produced by vertebrate and other invertebrate collagenolytic enzymes. These products have glycine as their N-terminal amino acids. As determined by viscosity measurements, the Bipalium collagenase is more active on invertebrate, earthworm, collagen than it is on the vertebrate, Type I guinea-pig skin, collagen. The Bipalium collagenase differs from both bacterial and vertebrate collagenases as well as from invertebrate, collagenolytic serine proteases.     

Bovine spleen cathepsin B1 and collagenolytic cathepsin. A comparative study of the properties of the two enzymes in the degradation of native collagen.

Bovine spleen cathepsin B1 and collagenolytic cathepsin were separated by chromatography on Amberlite IRC-50 and collagenolytic cathepsin was partially purified by chromatography on DEAE-Sephadex (A-50). 2. Collagenolytic cathepsin degraded insoluble tendon collagen maximally at pH 3.5 and 28 degrees C; mainly alpha-chain components were released into solution. At 28 degrees C the telopeptides in soluble skin collagen were also cleaved to yield alpha-chain components. Collagenolytic cathepsin was thus similar to cathepsin B1 in its action against native collagen, but mixtures of these two enzymes exhibited a synergistic effect. 3. The addition of thiol-blocking compounds produced similar inhibition of collagenolytic cathepsin and cathepsin B1. The enzyme responded similarly to all other compounds tested except to 6-aminohexanoic acid, when collagenolytic cathepsin was slightly activated and cathepsin B1 was almost unaffected. 4. Leupeptin, which is a structural analogue of arginine-containing synthetic substrates, inhibited collagenolytic cathepsin as effectively as cathepsin B1. Collagenolytic cathepsin was shown to retain a low residual activity against alpha-N-benzoyl-DL-arginine p-nitroanilide during purification which was equivalent to 0.2% of the activity of cathepsin B1. 5. Cathepsin B1 and collagenolytic cathepsin could not be separated by affinity chromatography on organomercurial-Sepharose 4B. The two enzymes could be resolved on DEAE-Sephadex (A-50) and by isoelectric focusing in an Ampholine pH gradient. The pI of the major cathepsin B1 isoenzyme was 4.9 and the pI of collagenolytic cathepsin was 6.4. 6. From chromatography on Sephadex G-75 (superfine grade) the molecular weights were calculated to be 26000 for cathepsin B1 and 20000 for collagenolytic cathepsin. The difference in molecular weight was confirmed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis.     

A handy assay for collagenase using reconstituted fluorescein-labeled collagen fibrils

This report describes an assay for measuring the activity of collagenases using reconstituted fibrils of fluorescein-labeled soluble collagen as substrate. The labeling of commercially available material is easy and not expensive. The assay is very sensitive, reproducible, and is linear with collagenase concentration up to 100% consumption of the reconstituted fibrils. Readings of collagenolytic activity can be determined directly by measuring the fluorescence of the released labeled peptides without further processing of the data.     

Gas Chromatographic Analysis of Volatile Esters in Wines

We isolated a new aerobic gram negative collagenolytic bacterium, strain CRZV₁. This strain is yellow pigmented, non motile; it poorly degrades the sugars and its proteolytic activity corresponds to one enzyme, a collagenase which is produced in media with collagen, or collagen like substrates. The strain CRZV_l, presents many similarities with Flavobacteria. However, the GC content of the DNA, which is 65%, excludes our collagenolytic strain from the genus Flavobacterium, where all the species have GC content between 30 and 42%. All the strains, already described as Flavobacteria, the GC contents of which are situated between 55 and 70%, are actually unclassified. They could be included in the genus Empedobacter. This genus is not in the approved list of bacterial names, so we only consider this new collagenolytic bacteria as a gram negative, aerobic, yellow pigmented bacteria.     

Matrix metalloproteinase-1 takes advantage of the induced fit mechanism to cleave the triple-helical type I collagen molecule

The collagenases are members of the matrix metalloproteinase family (MMP) that degrade native triple-helical type I collagen. To understand the mechanism by which these enzymes recognize and cleave this substrate, we studied the substrate specificity of a modified form of MMP-1 (FC) in which its active site region (amino acids 212-254) had been replaced with that of MMP-9 (amino acids 395-437). Although this substitution increased the activity of the enzyme toward gelatin and the peptide substrate Mca-PLGL(Dpa)AR-NH2 by approximately 3- and approximately 11-fold, respectively, it decreased the type I collagenolytic activity of the enzyme to 0.13%. The replacement of Gly233, the only amino acid in this region of FC that is conserved in all collagenase family members, with the corresponding Glu residue in MMP-9 resulted in a substantial decrease in the type I collagenolytic activity of the enzyme without affecting its general proteolytic activities. The kinetic parameters of the FC/G233E mutant for the collagen substrate were similar to those of the chimeric enzyme. In addition, substituting Gly233 for Glu in the chimera increased the collagenolytic activity of the enzyme by 12-fold. Interestingly, replacing Glu415 in MMP-9 with Gly, its corresponding residue in FC, endowed the enzyme with type I collagenolytic activity. The catalytic activity of the MMP-9 mutant toward triple-helical type I collagen was 2-fold higher than that of the collagenase chimera. These data in conjunction with the X-ray crystal structure of FC indicate that Gly233 provides the flexibility necessary for the enzyme active site to change conformation upon substrate binding. The flexibility provided by the Gly residue is essential for type I collagenolytic activity.     

Degradation of collagen substrates by a trypsin-like serine protease from the fiddler crab Uca pugilator

The collagenolytic properties of a trypsin-like protease from the hepatopancreas of the fiddler crab Uca pugilator have been examined. All collagen types, I-V, were attacked by this enzyme. Types III and IV were degraded much more rapidly than types I, II, and V. Crab protease produced multiple cleavages in the triple helix of each collagen at 25 degrees C; only in the case of type III collagen, however, was a major cleavage observed at a 3/4:1/4 locus that corresponded to the region of collagen susceptibility to mammalian collagenase action. Additionally, both the affinity and the specific activity of the crab protease for native collagen were lower than those which characterize mammalian collagenase. The results of this study, in conjunction with a previous report on the collagenolytic activity of another serine protease from the fiddler crab [Welgus, H. G., Grant, G. A., Jeffrey, J. J., & Eisen, A. Z. (1982) Biochemistry 21, 5183], suggest that the following properties distinguish the action of these invertebrate collagenolytic enzymes from the metalloenzyme collagenases of mammals: (1) broad substrate specificity, including both noncollagenous proteins and collagen types I-V; (2) ability to cleave the native triple helix of collagen at multiple loci; (3) reduced affinity or higher Km for collagen; and (4) lower specific activity on collagen fibrils.     

A spectroscopic collagenase assay using peroxidase-labeled collagen

A quantitative collagenase assay detecting soluble collagen fragments is described in this paper. Using the reagent N-succinimidyl 3-(2-pyridyldithio)propionate (SPDP) type I collagen was conjugated with horseradish peroxidase (POD) which was employed as a reporter enzyme. POD was preferentially linked to the TC B fragment in a ratio of 1.4 mol POD/mol collagen. The conjugation product was immobilized on AH-Sepharose via carbodiimide coupling to form the final collagenase substrate used in the assay. POD activity in the supernatants caused by liberated TC B fragments exhibited a linear relationship for collagenase concentrations up to 100 micrograms/ml bacterial collagenase. Over an incubation period of 4 h the lowest detection limits found were 20 ng/100 microliters for bacterial collagenase and 60 ng/100 microliters for human leukocyte collagenase. Incubation of the assay mixture with 5 micrograms trypsin resulted in 3.8% of the activity released by the equivalent amount of leukocyte collagenase. The assay developed here has been shown to be sensitive and specific for collagenase, with the additional advantage that this method is suited for simple and economic handling.     

Further evidence for a possible role of trypsin-like activity in the adherence of Porphyromonas gingivalis.

The present study was undertaken to evaluate a possible correlation between the level of trypsin-like activity and the adherence properties of Porphyromonas gingivalis. It was demonstrated that strains with high cell-associated trypsin-like activity attach in higher numbers to human epithelial cells than strains with low levels of trypsin-like activity. To a lesser extent, the same tendency was also noted for the agglutination of human erythrocytes. The ability of P. gingivalis to attach to erythrocytes and epithelial cells was found to be affected by the presence of arginine and thiol protease inhibitors (leupeptin, p-chloromercuriphenylsulfonic acid). The inhibition profile was partially dependent on the age of the bacterial cells used in the adherence assay. It is suggested that adherence of mid-log P. gingivalis cells involves primarily trypsin-like proteases, whereas 2-day-old cells possess additional specific attachment mechanism(s).     

The isolation and properties of collagenolytic proteases from crab hepatopancreas

A mixture of collagenolytic proteases has been isolated from the Kamchatka crab hepatopancreas. The four individual enzymes were further separated with FPLC and partially characterized. Crab collagenolytic proteases possess a high activity against different types of collagen, especially against calf skin collagen Type III and bovine lens capsule collagen Type IV, which is resistant to the microbial Clostridium sp. collagenases. In contrast with microbial collagenases the crab enzymes are good general proteases, able to cleave standard synthetic and protein substrates and possess a chymotrypsin-, trypsin- and elastase-like specificity. N-Terminal sequence analysis revealed that crab collagenolytic proteases had evolved from a trypsin-like ancestor. Crab proteases, structurally belonging to the trypsin-like enzymes, nevertheless, possess the unique ability, among this class of enzymes, to cleave the native insoluble collagen. It seems that crab collagenolytic proteases and true metalloenzyme vertebrate and microbial collagenases have certain common structural features particularly in the regions of their substrate binding site.