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.     

Cleavage specificity of type IV collagenase (gelatinase) from human skin. Use of synthetic peptides as model substrates

Type IV collagenase (gelatinase) has a marked substrate specificity for denatured collagen (gelatin). Cleavage site specificity of type IV collagenase from human skin was determined using small collagenous peptides with varied sequences around Gly-Leu or Gly-Ile. Type IV collagenase showed essentially the same order of preference for the peptide substrates as did interstitial collagenase. Both required a peptide with a minimum of six amino acid residues to demonstrate significant gelatinolytic activity and were able to cleave uncharged molecules more rapidly than charged molecules. the repeating Gly-X-Y-Gly sequence of collagen is not an absolute requirement for either enzyme since both digested AcPro-Leu-Gly-Ile-Leu-Ala-Ala-OC2H5 at 70% of the rate of the best substrate peptide, AcPro-Leu-Gly-Leu-Leu-Gly-OC2H5. Km and kcat (Vmax) values were determined for several of the peptides and for the native substrate. Turnover numbers with type IV collagenase were similar to those with interstitial collagenase (Weingarten, H., Martin, R., and Feder, J. (1985) Biochemistry 24, 6730-6734). However, the Km for all peptides investigated was approximately 10-fold lower for type IV collagenase than for interstitial collagenase. Because type IV collagenase does not cleave helical interstitial collagens, the data support the conclusion that secondary structure determines whether the peptide bond can be hydrolyzed at any potential cleavage site.     

H-ras oncogene-transformed human bronchial epithelial cells (TBE-1) secrete a single metalloprotease capable of degrading basement membrane collagen

H-ras-transformed human bronchial epithelial cells (TBE-1) secrete a single major extracellular matrix metalloprotease which is not found in the normal parental cells. The enzyme is secreted in a latent form of 72 kDa, which can be activated to catalyze the cleavage of the basement membrane macromolecule type IV collagen. The substrates in their order of preference are: gelatin, type IV collagen, type V collagen, fibronectin, and type VII collagen; but the enzyme does not cleave the interstitial collagens or laminin. This protease is identical to gelatinase isolated from normal human skin explants, normal human skin fibroblasts, and SV40-transformed human lung fibroblasts. Based on its ability to initiate the degradation of type IV collagen in a pepsin-resistant portion of the molecule, it will be referred to as type IV collagenase. This enzyme is most likely the human analog of type IV collagenase detected in several rodent tumors, which has the same molecular mass and has been linked to their metastatic potential. Type IV collagenase consists of three domains. Two of them, the amino-terminal domain and the carboxyl-terminal domain, are homologous to interstitial collagenase and human and rat stromelysin. The middle domain, of 175 residues, is organized into three 58-residue head-to-tail repeats which are homologous to the type II motif of the collagen-binding domain of fibronectin. Type IV collagenase represents the third member of a newly recognized gene family coding for secreted extracellular matrix metalloproteases, which includes interstitial fibroblast collagenase and stromelysin.     

The collagen substrate specificity of rat uterus collagenase

The collagen substrate specificity of rat uterus collagenase was studied as a function of both collagen type and species of substrate origin. For each collagen examined, values for the basic kinetic parameters, Km and Vmax (kcat), were determined on collagen in solution at 25 degrees C. In all cases, Lineweaver-Burk plots were linear and rat uterus collagenase behaved as a normal Michaelis-Menten enzyme. Collagen types I, II, and III of all species tested were degraded by rat uterus collagenase. Collagen types IV and V were resistant to enzymatic attack. Both enzyme-substrate affinity and catalytic rates were very similar for all susceptible collagens (types I-III). Values for Km ranged from 0.9 to 2.5 X 10(-6) M. Values for kcat varied from 10.7 to 28.1 h-1. The homologous rat type I collagen was no better a substrate than the other animal species type I collagens. The ability of rat uterus collagenase to degrade collagen types I, II, and III with essentially the same catalytic efficiency is unlike the action of human skin fibroblast collagenase or any other interstitial collagenase reported to date. The action of rat uterus collagenase on type I collagen was compared to that of human skin fibroblast collagenase, with regard to their capacity to cleave collagen as solution monomers versus insoluble fibrils. Both enzymes had essentially equal values for kcat on monomeric collagen, yet the specific activity of the rat uterus collagenase was 3- to 6-fold greater on collagen fibrils than the skin fibroblast enzyme. Thus, in spite of their similar activity on collagen monomers in solution, the rat uterus collagenase can degrade collagen aggregated into fibrils considerably more readily than can human skin fibroblast collagenase.     

Characterization of gelatinase from pig polymorphonuclear leucocytes. A metalloproteinase resembling tumour type IV collagenase.

The metalloproteinase 'gelatinase' stored in the granules of pig polymorphonuclear leucocytes has been purified in the latent form. The enzyme is secreted as an Mr 97,000 proenzyme that can be activated in the presence of 4-aminophenylmercuric acetate (APMA) by self-cleavage to generate lower-Mr species, of which an Mr 88,000 form was the most active. Trypsin-initiated activation generated different Mr gelatinases of much lower specific activity. Activation was slowed but not prevented by the presence of the tissue inhibitor of metalloproteinases, TIMP. The activated gelatinase formed a stable complex (Mr 144,000) with TIMP, in a Zn2+- and Ca2+-dependent manner, and complex formation was inhibited by the presence of the substrate gelatin. Similar to the human granulocyte gelatinase, the organomercurial-activated pig enzyme degraded gelatin and TCA and TCB fragments of type I collagen, as well as elastin and types IV and V collagen. The degradation of type IV collagen was shown, both by polyacrylamide-gel electrophoresis and by electron microscopic analysis, to generate 3/4 and 1/4 fragments as described for mouse tumour type IV collagenase. Furthermore, an antiserum raised to mouse type IV collagenase recognized the pig granulocyte gelatinase. An antiserum to the pig polymorphonuclear leucocyte gelatinase recognized other high-Mr gelatinases, including those from human granulocytes, pig monocytes and rabbit connective tissue cells, but not the Mr 72,000 enzyme from connective tissue cells. These data suggest that there are two distinct major forms of gelatinolytic activity that also cause specific cleavage of type IV collagen. These enzymes are associated with a wide variety of normal connective tissue and haemopoietic cells, as well as many tumour cells.     

Anchoring fibrils contain the carboxyl-terminal globular domain of type VII procollagen, but lack the amino-terminal globular domain

Type VII procollagen has been characterized as a product of epithelial cell lines. As secreted, it contains a large triple-helical domain terminated by a multi-globular-domained carboxyl terminus (NC-1), and a smaller amino-terminal globule (NC-2). The triple helix and the NC-1 domain have previously been identified in anchoring fibril-containing tissues by biochemical and immunochemical means, leading to the conclusion that type VII collagen is a major component of anchoring fibrils. In order to better characterize the tissue form of type VII collagen, we have produced a panel of monoclonal antibodies which recognize the NC-1 domain. Peptide mapping of these epitopes indicate that they are independent and span approximately 125,000 kDa of the total 150,000 kDa of each alpha chain contained in NC-1. All these antibodies elicit immunofluorescent staining of the basement membrane zone in tissues. Type VII collagen has been extracted from tissues. As previously reported, it is smaller than type VII procollagen, (Woodley, D. T., Burgeson, R. E., Lunstrum, G. P., Bruckner-Tuderman, L., and Briggaman, R. A., submitted for publication), and we now find that it predominantly occurs as a dimer. Following clostridial collagenase digestion, intact NC-1 has been recognized, indicating that the difference in apparent Mr between the tissue form of the molecule and type VII procollagen results from modification of the amino terminus. The size of the amino-terminal globule has been determined to be between approximately 96 and 102 kDa. Rotary shadowing analyses of extracted molecules indicate that dimeric molecules contain the NC-1 domain, but are missing intact NC-2. We propose that the tissue form monomer, Mr = 960,000, be referred to as "type VII collagen." These studies strongly suggest that anchoring fibrils contain dimeric molecules with intact NC-1 domains. The data also support the previous suggestion that the NC-2 domain is involved in the formation of disulfide bond-stabilized type VII collagen dimers, and is subsequently removed by physiological proteolytic processing.     

Monoclonal antibodies to type IV collagenase recognize a protein with limited sequence homology to interstitial collagenase and stromelysin

Type IV collagenase is a metalloproteinase associated with metastatic tumor cells. It specifically cleaves the triple helical basement membrane (type IV) collagen molecule at a single site. Monoclonal antibodies which block the activity of the human type IV collagenase were developed and used to purify this antigen. The purified type IV collagenase was partially sequenced following cyanogen bromide and trypsin cleavage. The amino acid sequence of the human type IV collagenase fragments revealed a region homologous to the human interstitial collagenase and stromelysin. However, several sequences in type IV collagenase were identified which are distinct from the latter. Polyclonal antibodies were raised against a synthetic peptide derived from such a sequence. Following affinity purification, the antibodies recognized the denatured human type IV collagenase in Western immunoblotting. These data indicate that type IV collagenase is a distinct member of a general family of metalloproteinases.     

Type VII collagen forms an extended network of anchoring fibrils

Type VII collagen is one of the newly identified members of the collagen family. A variety of evidence, including ultrastructural immunolocalization, has previously shown that type VII collagen is a major structural component of anchoring fibrils, found immediately beneath the lamina densa of many epithelia. In the present study, ultrastructural immunolocalization with monoclonal and monospecific polyclonal antibodies to type VII collagen and with a monoclonal antibody to type IV collagen indicates that amorphous electron-dense structures which we term "anchoring plaques" are normal features of the basement membrane zone of skin and cornea. These plaques contain type IV collagen and the carboxyl-terminal domain of type VII collagen. Banded anchoring fibrils extend from both the lamina densa and from these plaques, and can be seen bridging the plaques with the lamina densa and with other anchoring plaques. These observations lead to the postulation of a multilayered network of anchoring fibrils and anchoring plaques which underlies the basal lamina of several anchoring fibril-containing tissues. This extended network is capable of entrapping a large number of banded collagen fibers, microfibrils, and other stromal matrix components. These observations support the hypothesis that anchoring fibrils provide additional adhesion of the lamina densa to its underlying stroma.     

Characteristics of 92 kDa type IV collagenase/gelatinase produced by granulocytic leukemia cells: structure,expression of cDNA in E. coli and enzymatic properties

Human neutrophils can be triggered to release the collagenolytic metalloenzymes, interstitial collagenase and 92 kDa type IV collagenase/gelatinase. We have isolated and sequenced a 2.3 kb cDNA from a chronic granulocytic leukemia cDNA library that encodes for human neutrophil type IV collagenase. With the exception of one amino-acid substitution at position 280 (Arg → Gln), the deduced amino-acid sequences of neutrophil gelatinase are identical to the amino-acid sequences of the enzyme isolated from fibrosarcoma cells. Expression of the cDNA in E. coli yielded a 72 kDa protein having a gelatinolytic activity on zymogram gel. The recombinant enzyme was activated with APMA and trypsin. The activation was accompanied by a reduction in molecular weight of ≈ 10 kDa; such a reduction is characteristic of matrix metalloproteinases. The recombinant gelatinase cleaved native type V and XI collagens. Native type I collagen was not a substrate for the enzyme. These data suggest that native and recombinant 92 kDa type IV collagenase produced in E. coli have similar biochemical properties. The successful expression of the collagenase in a prokaryotic system will greatly facilitate the structure-function characterization of the enzyme and allow a more precise analysis of its physiological and pathological roles.     

Purification and characterization of Clostridium perfringens 120-kilodalton collagenase and nucleotide sequence of the corresponding gene.

Clostridium perfringens type C NCIB 10662 produced various gelatinolytic enzymes with molecular masses ranging from approximately 120 to approximately 80 kDa. A 120-kDa gelatinolytic enzyme was present in the largest quantity in the culture supernatant, and this enzyme was purified to homogeneity on the basis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme was identified as the major collagenase of the organism, and it cleaved typical collagenase substrates such as azocoll, a synthetic substrate (4-phenylazobenzyloxy-carbonyl-Pro-Leu-Gly-Pro-D-Arg [Pz peptide]), and a type I collagen fibril. In addition, a gene (colA) encoding a 120-kDa collagenase was cloned in Escherichia coli. Nested deletions were used to define the coding region of colA, and this region was sequenced; from the nucleotide sequence, this gene encodes a protein of 1,104 amino acids (M(r), 125,966). Furthermore, from the N-terminal amino acid sequence of the purified enzyme which was found in this reading frame, the molecular mass of the mature enzyme was calculated to be 116,339 Da. Analysis of the primary structure of the gene product showed that the enzyme was produced with a stretch of 86 amino acids containing a putative signal sequence. Within this stretch was found PLGP, the amino acid sequence constituting the Pz peptide. This sequence may be implicated in self-processing of the collagenase. A consensus zinc-binding sequence (HEXXH) suggested for vertebrate Zn collagenases is present in this bacterial collagenase. Vibrio alginolyticus collagenase and Achromobacter lyticus protease I showed significant homology with the 120-kDa collagenase of C. perfringens, suggesting that these three enzymes are evolutionarily related.     

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.     

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.     

The relationship of the biophysical and biochemical characteristics of type VII collagen to the function of anchoring fibrils

Type VII collagen is a major component of anchoring fibrils, which are 800-nm-long centrosymmetrically cross-banded fibrils that are believed to secure the attachment of certain epithelial basement membranes to the underlying stromal matrix. The ultrastructure of the anchoring fibrils is highly variable, suggesting that the fibrils are flexible. Flexibility measurements along the length of the triple-helical domain of type VII procollagen indicate that major flexible sites correlate well with known discontinuities in the (Gly-X-Y)n repeating sequence. Therefore, the helical disruptions may account for the tortuous shapes of anchoring fibrils observed ultrastructurally. The centrosymmetrical banding pattern observed for anchoring fibrils results from the unstaggered lateral packing of antiparallel type VII collagen dimers that form these structures. This antiparallel arrangement is specified by disulfide bonds formed at the margins of a 60-nm overlap of the amino termini. As long as these disulfide bonds remain intact, they protect the amino-terminal overlapping triple helices from collagenase digestion. This disulfide-bonded pair of triple helices is termed C-1. Large nonhelical domains (NC-1) extend from both ends of the anchoring fibrils and are believed to interact with the basement membrane or with anchoring plaques. Rotary shadowing of the NC-1 domains showed trident-like shapes, suggesting that a single alpha-chain contributed the structure of each arm and that the three arms were extended. Biochemical and biophysical analyses of NC-1 domains independently confirm these suggestions and imply that the arms of NC-1 domains are identical and individually capable of interactions with basement membrane components, potentially allowing trivalent interaction of type VII collagen with various macromolecules.     

Cleavage specificity of human skin type IV collagenase (gelatinase). Identification of cleavage sites in type I gelatin, with confirmation using synthetic peptides

Type IV collagenase (gelatinase) readily cleaves denatured collagen into very small peptides. Large cyanogen bromide fragments (25 kDa) of type I collagen are degraded at the same rate as the complete alpha-chain. A number of the gelatinolytic cleavage sites of alpha 1(I)CB7 and alpha 1(I)CB8, representing 50% of the collagen alpha-chain, were determined by sequence analysis of product peptides. In addition to the expected cleavage between glycine and hydrophobic residues, several other cleavage sites were identified. These sites were Gly-Glu, Gly-Asn, and Gly-Ser. Basic residues were found adjacent to the cleavage site in several cases. Hexapeptides containing these unexpected cleavage sites were synthesized, and Km and kcat values were determined. All but one of the Km values were in the submillimolar range, and turnover numbers for the peptides uncharged at the carboxyl terminus were on the order of 10,000/h. Of particular significance was the finding that hydroxyproline occurs 5 residues from the cleavage site in all carboxyl-terminal product peptides and also occurs 5 residues from the cleavage site in seven of nine amino-terminal product peptides. A requirement for hydroxyproline may be of importance in determining the specificity of this enzyme for denatured collagenous substrates.     

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.     

The recombinant expression of full-length type VII collagen and characterization of molecular mechanisms underlying dystrophic epidermolysis bullosa.

Type VII collagen is a major component of anchoring fibrils, attachment structures that mediate dermal-epidermal adherence in human skin. Dystrophic epidermolysis bullosa (DEB) is an inherited mechano-bullous disorder caused by mutations in the type VII collagen gene and perturbations in anchoring fibrils. In this study, we produced recombinant human type VII collagen in stably transfected human 293 cell clones and purified large quantities of the recombinant protein from culture media. The recombinant type VII collagen was secreted as a correctly folded, disulfide-bonded, helical trimer resistant to protease degradation. Purified type VII collagen bound to fibronectin, laminin-5, type I collagen, and type IV collagen and also supported human dermal fibroblast adhesion. In an attempt to establish genotype-phenotype relationships, we generated two individual substitution mutations that have been associated with recessive DEB, R2008G and G2749R, and purified the recombinant mutant proteins. The G2749R mutation resulted in mutant type VII collagen with increased sensitivity to protease degradation and decreased ability to form trimers. The R2008G mutation caused the intracellular accumulation of type VII collagen. We conclude that structural and functional studies of in vitro generated type VII collagen mutant proteins will aid in correlating genetic mutations with the clinical phenotypes of DEB patients.     

Activation of the 92 kDa type IV collagenase by tissue kallikrein

Type IV collagenases are secreted as latent 92 and 72 kDa proenzymes which are then activated extracellularly. The mechanisms by which they are activated in vivo are not clear. We have studied the activation of porcine endothelial cell type IV collagenases by tissue and plasma kallikrein, and found that tissue kallikrein was a very efficient activator of the 92 kDa type IV collagenase. Enzyme cleavage was observed at concentrations of tissue kallikrein as low as 0.1 μg/ml. Plasma kallikrein had no effect. By comparison, plasmin, which has been proposed to be the physiological activator of interstitial collagenase and stromelysin, and elastase were much less effective, and high concentrations (plasmin at 100–200 μg/ml and elastase at 20 μg/ml) were required to cause only a limited cleavage which was not associated with an increase in activity, as observed by the gelatin-gel lysis assay. In addition tissue kallikrein was found by immunohistochemistry to be present in the extracellular matrix of the intima of porcine aortic vessel wall. These findings suggest that tissue kallikrein can be a potential activator of the 92 kDa type IV collagenase in vivo. © 1993 Wiley-Liss, Inc.     

Some properties of latent collagenase from human synovial fluid

Latent collagenase has been isolated in pure form from the rheumatoid synovial fluid. The final preparation, activated by trypsin, yielded a collagenase of specific activity 2,227 units/mg. Electrophoresis in sodium dodecyl sulfate polyacrylamide gels revealed a protein doublet of 54 and 50 kDa. Trypsin or HgCl2 activation resulted in disappearance of the doublet and emergence of a new doublet of 47 and 43 kDa. The latent collagenase could also be activated by leucocyte cathepsin G or plasmin. Neither the latent nor the active collagenase from synovial fluid showed any cross-reactivity with the antibodies against leucocyte collagenase. The trypsin activated collagenase degraded collagen type I, II, III giving typical cleavage products but did not degrade type IV and V collagen.     

Human 92- and 72-kilodalton type IV collagenases are elastases.

Elastin is critical to the structural integrity of a variety of connective tissues. Only a select group of enzymes has thus far been identified capable of cleaving insoluble elastin. Recently, we observed that human alveolar macrophages secrete elastase activity that is largely inhibited by the tissue inhibitor of metalloproteinases (TIMP). This finding suggested that one or more of the metalloproteinases released by alveolar macrophages has elastase activity. Accordingly, we tested pure human interstitial collagenase, stromelysin, 92-kDa type IV collagenase, and 72-kDa type IV collagenase for elastolytic activity using kappa-elastin zymography and insoluble 3H-labeled elastin. The 92- and 72-kDa type IV collagenases were found to be elastolytic in both assay systems. A recombinant preparation of 92-kDa type IV collagenase with gelatinolytic activity was also found to be elastolytic. Organomercurial activation was essential to detect elastolytic activity of the native 92- and 72-kDa type IV collagenases and enhanced the elastase activity of the recombinant 92-kDa enzyme. On a molar basis the recombinant 92-kDa type IV collagenase was approximately 30% as active as human leukocyte elastase in solubilizing 3H-labeled elastin. Exogenously added TIMP in significant molar excess abolished the elastase activity of the 92- and 72-kDa type IV collagenases. Stromelysin and interstitial collagenase showed no significant elastolytic activity, although both were catalytically active against susceptible substrates. Conditioned media from cultures of human mononuclear phagocytes containing the 92-kDa enzyme produced a distinct zone of lysis in the kappa-elastin zymograms at this molecular mass. These results definitively extend the spectrum of human proteinases with elastolytic activity to metalloproteinases and suggest the enzymatic basis for elastase activity observed with certain cell types such as human alveolar macrophages.     

Degradation of monomeric and fibrillar type III collagens by human skin collagenase. Kinetic constants using different animal substrates

Human skin collagenase activity was examined against type III collagens, in both soluble and fibrillar form, from different animal species. In either form, human, dog, and cat type III were degraded 10- to 30-fold faster than was that from guinea pig and nearly 100-fold more readily than chick type III. These differences in susceptibility were mirrored by essentially identical differences in the rate of trypsin cleavage of the same substrates. Human, dog, and cat type III were cleaved most rapidly by trypsin, guinea pig III more slowly, and chick III was completely resistant to the serine protease. Arrhenius plots, relating enzyme activity to temperature, revealed differences in the various type III substrates consistent with their collagenase and trypsin susceptibilities. Human, dog, and cat type III collagens yielded nonlinear plots, with accompanying activation energies which decreased at temperatures above 26 degrees C; guinea pig type III displayed a plot which deviated only slightly from linearity while the plot for chick type III was completely linear. These data strongly suggest that type III collagens display substantial variability in the stability of the helix at or near the collagenase cleavage site. The susceptibility of these type III substrates as reconstituted fibrils was also examined. The relative rates of degradation of these substrates by collagenase, and by trypsin, were the same as those observed in solution. The absolute rates of degradation of collagen in fibrillar form, however, were massively lower than predicted by extrapolation from solution values. This reduction in rate is even greater for type III than for type I collagens. Thus, whereas in solution type III substrates are cleaved much faster than type I collagens, in fibrillar form these differences are less than 2-fold. These data, together with values for activation energies and deuterium isotope effects on type III fibrillar substrates, reinforce the concept that helical integrity near the collagenase cleavage site is a major specifier of the rate of collagenase activity. Furthermore, the data suggest that the exclusion of water accompanying the tight packing of monomers into fibrils presents a major energy barrier to collagenase activity, which is particularly large for type III collagen.