Substrate specificity of the collagenolytic serine protease from Uca pugilator: studies with collagenous substrates

The collagenolytic protease from Uca pugilator was studied with respect to its catalytic properties on collagen types I-V. The crab protease degraded all five collagen types, producing multiple cleavages in the triple helix of each native collagen at 25 degrees C. The major early cleavage in the alpha 1 polypeptide chain of collagen types I-III occurred at a 3/4:1/4 locus, resulting in fragments electrophoretically similar to the TCA and TCB products of mammalian collagenase action. Interestingly, a propensity toward this same cleavage was observed even following thermal denaturation of the substrates. The ability of the crab protease to degrade all native collagen types and to catalyze cleavages at multiple loci in the triple helix distinguishes its action from that of mammalian collagenases. The collagenolytic activity of the crab protease was also examined on fibrillar collagen and compared to that of human skin fibroblast collagenase. Enzyme concentrations of fibroblast collagenase which resulted in the saturation of available substrate sites failed to show such an effect in the case of the crab protease. Binding studies of the crab protease to fibrillar collagen likewise indicated substantially reduced levels of enzyme binding in comparison to fibroblast collagenase. These data suggest that the affinity of the crab protease for native collagen is considerably less than the affinity of mammalian collagenase for this substrate.     

A collagenase assay using [3H-methyl]collagen

A new assay procedure for collagenase is presented. Highly radioactive substrate is prepared by methylation of native collagen. The ³H-labelled protein is readily attacked by bacterial as well as by mammalian collagenase and resistant to other proteinases. The sensitivity of this assay is higher than that of the enzymic methods hitherto available.     

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.     

Differences in the degradation of native collagen by two microbial collagenases.

The early stages of degradation of native collagen by two bacterial collagenases were studied by electron microscopy and by automatic Edman degradation. The purified collagenase from Clostridium histolyticum was shown to cleave native collagen at several sites, but not progressively from the N-terminus, as had been previously suggested. The homogeneous collagenase from Achromobacter iophagus cleaves native collagen preferentially at two sites corresponding to the interbands 33-34 and 41-42. The latter lies within the region cleaved by the eukaryotic collagenases.     

The gelatinolytic activity of human skin fibroblast collagenase

The gelatinolytic activity of human skin fibroblast collagenase was examined on denatured collagen types I-V. All denatured substrates were cleaved, including types IV and V, which are resistant to collagenase in native form. Interestingly, the earliest major cleavage in denatured collagen types I-III occurred at a 3/4-1/4 locus, resulting in products electrophoretically identical with TCA and TCB fragments of mammalian collagenase action on these native collagens. However, in the denatured substrates, multiple additional proteolytic cleavages followed. The propensity for cleavage at a 3/4-1/4 site in denatured collagen, where sequence is the major specifier of enzymatic action, would seem to indicate that the most favorable amino acid sequence of gamma chains for catalysis is located in this region. The peptide bond specificity of human fibroblast collagenase on gelatin was examined by amino acid sequencing of extensively cleaved denatured type I collagen. Analysis of the NH2-terminal amino acid residues from the resultant gelatin peptides showed sequences of "-H2N-Ile-Y-Gly" and "H2N-Leu-Y-Gly" only (where Y indicates that any amino acid can be found in that position), indicating that Gly-Ile and Gly-Leu bonds are the only sites of collagenase cleavage in this substrate. Whereas the gamma1 chains of denatured collagen types I-III were cleaved at similar rates, fibroblast collagenase was a much better gamma2-gelatinase than gamm1-gelatinase on denatured type 1 collagen. This preference for the cleavage of gamma2(I) was the result of both a higher kcat (750 versus 230 h-1) and lower Km (3.7 versus 7.0 microM) than for a gamma1(1), resulting in an overall selectivity (kcat/Km) of greater than 6-fold. Compared to such kinetic parameters on native collagen, these values indicate that gelatinolysis is somewhat slower than collagenolysis.     

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.     

Defining requirements for collagenase cleavage in collagen type III using a bacterial collagen system

Degradation of fibrillar collagens is important in many physiological and pathological events. These collagens are resistant to most proteases due to the tightly packed triple-helical structure, but are readily cleaved at a specific site by collagenases, selected members of the matrix metalloproteinases (MMPs). To investigate the structural requirements for collagenolysis, varying numbers of GXY triplets from human type III collagen around the collagenase cleavage site were inserted between two triple helix domains of the Scl2 bacterial collagen protein. The original bacterial CL domain was not cleaved by MMP-1 (collagenase 1) or MMP-13 (collagenase 3). The minimum type III sequence necessary for cleavage by the two collagenases was 5 GXY triplets, including 4 residues before and 11 residues after the cleavage site (P4-P11'). Cleavage of these chimeric substrates was not achieved by the catalytic domain of MMP-1 or MMP-13, nor by full-length MMP-3. Kinetic analysis of the chimeras indicated that the rate of cleavage by MMP-1 of the chimera containing six triplets (P7-P11') of collagen III was similar to that of native collagen III. The collagenase-susceptible chimeras were cleaved very slowly by trypsin, a property also seen for native collagen III, supporting a local structural relaxation of the triple helix near the collagenase cleavage site. The recombinant bacterial-human collagen system characterized here is a good model to investigate the specificity and mechanism of action of collagenases.     

Identification and partial characterization of an inhibitor of collagenase from rabbit bone

Bone explants from foetal and newborn rabbits synthesize and release a collagenase inhibitor into culture media. Inhibitor production in the early days of culture is followed first by latent collagenase and subsequently active collagenase in the culture media. A reciprocal relationship exists between the amounts of free inhibitor and latent collagenase in culture media, suggesting strongly that the inhibitor is a component of the latent form of the enzyme. Over 90% of the inhibitory activity of culture media is associated with a fraction of apparent mol.wt. 30000 when determined by gel filtration on Ultrogel AcA 44. The inhibitor blocks the action of rabbit collagenase on both reconstituted collagen fibrils and collagen in solution. It inhibits the action of either active collagenase or latent collagenase activated by 4-aminophenylmercuric acetate. Latent collagenase activated by trypsin is usually much less susceptible to inhibition. The activity of the inhibitor is destroyed by heat, by incubation with either trypsin or chymotrypsin and by 4-aminophenylmercuric acetate. Collagenase activity can be recovered from complexes of enzyme (activated with 4-aminophenylmercuric acetate) with free inhibitor by incubation with either trypsin or 4-aminophenylmercuric acetate, at concentrations similar to those that activate latent collagenase from culture media. The rabbit bone inhibitor does not affect the activity of bacterial collagenase, but blocks the action of collagenases not only from a variety of rabbit tissues but also from other mammalian species.     

Definition of the Native and Denatured Type II Collagen Binding Site for Fibronectin Using a Recombinant Collagen System

Interaction of collagen with fibronectin is important for extracellular matrix assembly and regulation of cellular processes. A fibronectin-binding region in collagen was identified using unfolded fragments, but it is not clear if the native protein binds fibronectin with the same primary sequence. A recombinant bacterial collagen is utilized to characterize the sequence requirement for fibronectin binding. Chimeric collagens were generated by inserting the putative fibronectin-binding region from human collagen into the bacterial collagen sequence. Insertion of a sufficient length of human sequence conferred fibronectin affinity. The minimum sequence requirement was identified as a 6-triplet sequence near the unique collagenase cleavage site and was the same in both triple-helix and denatured states. Denaturation of the chimeric collagen increased its affinity for fibronectin, as seen for mammalian collagens. The fibronectin binding recombinant collagen did not contain hydroxyproline, indicating hydroxyproline is not essential for binding. However, its absence may account, in part, for the higher affinity of the native chimeric protein and the lower affinity of the denatured protein compared with type II collagen. Megakaryocytes cultured on chimeric collagen with fibronectin affinity showed improved adhesion and differentiation, suggesting a strategy for generating bioactive materials in biomedical applications.     

Chemical and kinetic characterization of tadpole back skin collagenase

The purified collagenase from tadpole (Rana catesbiana) back skin was studied with respect to its activation energy using soluble and fibrillar type I collagen, as well as a synthetic peptide substrate, DNP-Pro-Gln-Gly-Ile-Ala-Gly-Gln-D-Arg. The activation energy appeared to be independent of the nature of the substrate, ranging between 28 and 35 kcal/mol. The peptide was cleaved at the Gly-Ile bond and proved to be a poor substrate (kcat/Km, 1.21 h-1 microM-1) when compared with native type I collagen in solution (kcat/Km, 40.6 h-1 microM-1), consistent with the enzyme's low activity versus gelatin [T. A. Bicsak and E. Harper (1984) J. Biol. Chem. 259, 13145]. The amino acid composition of the collagenase was shown to be high in glycine and glutamic acid, and the preparation was shown not to be contaminated with collagen by digestion with bacterial collagenase. The enzyme was not inhibited by iodoacetic acid or 2-hydroxy-5-nitrobenzyl bromide, suggesting the lack of essential cysteinyl and tryptophanyl residues, but was inhibited by micromolar concentrations of ZnCl2, consistent with the presence of essential histidine(s). Ethoxyformic anhydride irreversibly inhibited the collagenase suggesting the presence of essential lysyl residues.     

Nereis cuticle collagen. Isolation and properties of a large fragment resistant to proteolysis by bacterial collagenase.

Native cuticle collagen, obtained from Nereis virens, was incubated with purified bacterial collagenase (EC 3.4.4.19). The kinetics of proteolysis were monitored by viscometry, in parallel with similar digestions of calf skin collagen. Comparison of the kinetics of digestion of the two collagens, at similar enzyme to substrate ratios (w/w), showed that the native cuticle collagen was relatively refractory to digestion by bacterial collagenase. Characterization of the cuticle collagen digest by sodium dodecyl sulfate-polyacrylamide electrophoresis and agarose gel filtration in CaCl2 showed a large polypeptide, of about 300,000 daltons, to be a major product. The native form of this product, a unique fragment, was isolated from the digest by ethanol precipitation. It was found to have an intrinsic viscosity of 120 dl/g, to have an optical rotary dispersion curve characteristic of collagen, to undergo a typical collagenous thermal transition with a Tm of 23.2 degrees, and to have a calculated molar mass of 900,000 g with molecular dimensions of 9,000 X 13 A. It had an amino acid composition which was similar, but not identical with the native cuticle collagen. Although the original substrate contained two dissimilar chains, A and B, in a molar ratio of 1:2, the collagenase-resistant product appeared to be composed of only one type of polypeptide fragment. Possibly, the original subunits contain similar, if not identical collagenase-resistant regions.     

Induction of collagenase production in U937 cells by phorbol ester and partial purification of the induced enzyme

The U937 cell line is a monoblast-like cell line that can be induced to differentiate when treated with phorbol ester or a variety of other agents. Collagenase was detected in the media of U937 cell cultures after treatment with phorbol myristate acetate (PMA) at concentrations of 5 ng/mL or greater. In general, no collagenase was detected in the media of untreated cells. The induced collagenase cleaved native type I collagen into the 3/4 and 1/4-length fragments and showed the inhibition by ethylenediaminetetraacetic acid characteristic of the action of mammalian collagenases. Collagenase activity could be detected in the media of treated cells 12-18 h after the addition of PMA. Secretion of collagenase continued for 2-3 days after PMA addition. The production of collagenase by PMA-treated U937 cells was inhibited by actinomycin D and cycloheximide, suggesting that the induction of the enzyme is the result of de novo synthesis. The collagenase secreted by U937 cells induced with PMA has been purified 12-fold by using DEAE-Sephacel followed by wheat germ agglutinin-agarose chromatography. The apparent molecular mass of this U937 collagenase, determined by gel filtration chromatography on the partially purified enzyme, was 29-36 kilodaltons.     

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.     

The gelatinolytic activity of rat uterus collagenase

The collagenase produced by rat uterine cells in culture has been examined for its ability to degrade denatured collagen. Acting as a gelatinase, rat uterus collagenase was able to successfully degrade the denatured chains of collagen types I through V. In addition, the enzyme produced multiple cleavages in these chains and displayed values for Km of 4-5 microM, compared to values of 1-2 microM when native collagen was used as substrate. Furthermore, rat uterus collagenase degraded the alpha 2 chain of denatured type I collagen at a significantly faster rate than the alpha 1 chain, as previously observed for human skin fibroblast collagenase. In contrast to the action of human skin collagenase, however, the rat uterus enzyme was found to be a markedly better gelatinase than a collagenase, degrading the alpha chains of denatured type I guinea pig skin collagen at rates some 7-15-fold greater than native collagen. Human skin collagenase degrades the same denatured chains at rates ranging from 13-44% of its rate on native collagen. Rat uterus collagenase, then, is approximately 50 times better a gelatinase than is human skin collagenase. In addition to its ability to cleave denatured collagen chains at greater rates than native collagen, the rat uterus collagenase also attacked a wider spectrum of peptide bonds in gelatin than does human skin collagenase. In addition to cleaving the Gly-Leu and Gly-Ile bonds characteristic of its action on native collagen, rat uterus collagenase readily catalyzed the cleavage of Gly-Phe bonds in gelatin. The rat enzyme was also capable of cleaving Gly-Ala and Gly-Val bonds, although these bonds were somewhat less preferred by the enzyme. The cleavage of peptide bonds other than Gly-Leu and Gly-Ile appears to be a property of the collagenase itself and not a contaminating protease. Thus, it appears that the collagenase responsible for the degradation of collagen during the massive involution of the uterus might also act as a gelatinase to further degrade the initial products of collagenolysis to small peptides suitable for further metabolism.     

Synthesis of a collagenase inhibitor by smooth muscle cells in culture.

Serum-free medium that was incubated for 24 hours with confluent cultures of smooth muscle cells contains a potent inhibitor of mammalian collagenase but not of bacterial collagenase. Synthesis of this inhibitor by these cultures is blocked by cycloheximide. The inhibitor is sensitive to trypsin but is stable to heating at 60° for 10 minutes and to acid treatment. Reduction with mercaptoethanol followed by alkylation destroys the inhibitory activity. This inhibitor may play a physiological role in the slow turnover of collagen that is observed in the vasculature.     

Binding of soluble type I collagen to fibroblasts: effects of thermal activation of ligand, ligand concentration, pinocytosis, and cytoskeletal modifiers

Efficient binding of native, soluble 125I-labeled type I rat collagen to mouse 3T3 fibroblast monolayers requires prior warming of the ligand to 35-37 degrees C for 10-30 min. Decreased binding at high ligand concentrations is ascribed to ligand-ligand interactions rather than to negative cooperativity. Addition of bacterial collagenase to monolayers labeled with the 125I-ligand releases a constant fraction (80%) of the bound ligand over a 2-h interval at 37 degrees C, indicating that little of the ligand becomes inaccessible by pinocytosis. Colchicine (10(-7) M) and vinblastine (5 X 10(-8) M) do not inhibit binding by morphologically intact monolayers. Cytochalasins and concanavalin A show dose-related inhibition of binding by intact monolayers that is due to a reduction in the number of available binding sites rather than to a change in binding site affinity. The collagen binding site on the fibroblast surface is proposed as an organizing center for the assembly of periodic type I collagen fibrils.     

Degradation of type I collagen by rat mucosal keratinocytes. Evidence for secretion of a specific epithelial collagenase

Feeder-cell-independent serially propagating keratinocytes from rat oral mucosa (tongue) dissolved reconstituted type I [3H]collagen fibrils, although rather slowly. Analysis of the conditioned medium from such cultures revealed secretion of a Mr = 65,000 collagenase which remained almost entirely latent in the absence of exogenous protease activity. Addition of trypsin (0.1-1.0 microgram/ml) or plasmin (1.0-4.0 micrograms/ml) resulted in substantial acceleration of the collagenolytic process in stimulated secretion of latent collagenase and, at higher concentrations, in conversion of the latent enzyme to the catalytic form. The keratinocyte collagenase was indistinguishable from interstitial, fibroblast-type collagenases by several criteria including: cleavage of native type I collagen in solution at the characteristic collagenase-sensitive locus at 22 degrees C and dissolution of reconstituted type I collagen fibrils at 35 degrees C; activation by trypsin and by organomercurials and inhibition by Zn2+ and Ca2+ chelators; and cross-reaction with antibody to fibroblast-type procollagenase. Expression of collagenolytic activity in keratinocyte cultures was effectively regulated by cell density. The activity (on a per cell basis) was maximal at 10-20% confluence and was more than 95% "contact-inhibited" at subconfluent and early confluent densities (2-4 X 10(5)/cm2). Our findings show that mucosal keratinocytes possess a potent enzymatic apparatus for degradation of interstitial collagen fibrils which includes a classical vertebrate collagenase.     

Covalent structure of collagen: amino acid sequence of alpha 1 (III)-CB5 from type III collagen of human liver

Type III collagen was prepared from human liver by limited pepsin digestion, differential salt precipitation, and carboxymethylcellulose chromatography. Ten distinct peptides were obtained by cyanogen bromide digestion. The peptide alpha 1 (III)-CB5 was further purified by carboxymethylcellulose chromatography, and its amino acid sequence was determined. Automatic Edman degradation of intact alpha 1 (III)-CB5, tryptic and thermolytic peptides, and hydroxylamine-derived fragments was used to establish the total sequence. The mammalian collagenase site contained in the alpha 1 (III)-CB5 sequence was ascertained by digestion of native type III collagen with purified rheumatoid synovial collagenase. Collagenase cleavage occurred at a single Gly--Ile bond, one triplet before the corresponding specific cleavage site of type I collagen. The present work brings the known sequence of human liver type III collagen to include alpha 1 (III)-CB3-7-6-1-8-10-2-4-5. These correspond to the homologous region of alpha 1 (I)-CB0-1-2-4-5-8-3-7 residues 11--804.     

Differential susceptibility of type X collagen to cleavage by two mammalian interstitial collagenases and 72-kDa type IV collagenase

We have studied the degradation of type X collagen by human skin fibroblast and rat uterus interstitial collagenases and human 72-kDa type IV collagenase. The interstitial collagenases attacked the native type X helix at two loci, cleaving residues Gly92-Leu93 and Gly420-Ile421, both scissions involving Gly-X bonds of Gly-X-Y-Z-A sequences. However, the human and rat interstitial enzymes displayed an opposite and substantial selectivity for each of these potential sites, with the uterine enzyme catalyzing the Gly420-Ile421 cleavage almost 20-fold faster than the Gly92-Leu93 locus. Values for enzyme-substrate affinity were approximately 1 microM indistinguishable from the corresponding Km values against type I collagen. Interestingly, in attacking type X collagen, both enzymes manifested kinetic properties intermediate between those characterizing the degradation of native and denatured collagen substrates. Thus, energy dependence of reaction velocity revealed a value of EA of 45 kcal, typical of native interstitial collagen substrates. However, the substitution of D2O for H2O in solvent buffer failed to slow type X collagenolysis significantly (kH/kD = 1.1), in contrast to the 50-70% slowing (kH/kD = 2-3) observed with native interstitial collagens. Since this lack of deuterium isotope effect is characteristic of interstitial collagenase cleavage of denatured collagens, we investigated the capacity of another metalloproteinase with substantial gelatinolytic activity, 72-kDa type IV collagenase, to degrade type X collagen. The 72-kDa type IV collagenase cleaved type X collagen at both 25 and 37 degrees C, and at loci in close proximity to those attacked by the interstitial enzymes. No further cleavages were observed at either temperature with type IV collagenase, and although values for kcat were not determined (due to associated tissue inhibitor of metalloproteinases-2), catalytic rates appeared to be substantial in comparison to the interstitial enzymes. In contrast, type X collagen was completely resistant to proteolysis by stromelysin. Type X collagen thus appears to be highly unusual in its susceptibility to degradation by both interstitial collagenase and another member of the metalloproteinase gene family.     

Digestion of native collagen, denatured collagen, and collagen fragments by extracts of rat liver lysosomes.

Extracts of highly purified lysosomes from rat liver were examined for their ability to degrade native collagen and thermally denatured collagen at pH values between 3.5 and 7.0. After a 24-h digestion at 36 degrees with the lysosomal extract at a pH of 5.5 or lower (collagen/lysosomal protein; 2/1 or 8/1), both native and denatured collagen were degraded to an extent equivalent to 60 to 70% of that observed upon total acid hydrolysis in 6 N HCl as measured by the ninhydrin reaction (570 nm). At a pH of 6.0, native collagen and denatured collagen were degraded by the mixture of lysosomal proteinases to 11% and 40% of total acid hydrolysis, respectively. At pH 6.5 AND 7.0, the corresponding values were 3% versus 33% and 0.3% versus 11%, respectively. Fragments of collagen (TCA and TCB) are produced when mammalian collagenase degrades native collagen at 25 degrees. These fragments were degraded by the lysosomal extract at 36 degrees to an extent equivalent to 28% and 8% of total acid hydrolysis at pH 6.5 and 7.0, respectively. The experiments at pH 6.5 and 7.0 were done using a collagen/lysosomal protein ratio of 2/1. At pH 5.0 (a pH which is found within secondary lysosomes), the lysosomal extracts degraded collagen to a mixture of free amino acids and small peptides. Amino acid analysis established that approximately 30% of the amino acid residues of the collagen appeared in the lysosomal hydrolysate as free amino acids. Hydroxyproline and perhaps hydroxylysine were the only amino acids found in collagen which did not appear at least to some extent as the free amino acid in this hydrolysate.