The stoichiometric activation of human skin fibroblast pro-collagenase by factors present in human skin and rat uterus

Purified human skin fibroblast collagenase zymogen was used as a substrate for activators partially purified from the medium of cultured human skin and rat uterus. Analysis of the activated enzyme by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that these activators do not produce measurable changes in the molecular weight of the zymogen. Kinetic analysis indicated a noncatalytic mechanism of action for these activators, since zymogen activation was independent of incubation time, and dependent only upon the concentration of the activator fractions. These results are consistent with a Stoichiometric mechanism of procollagenase activation by these macromolecules.     

Human lung mast cell tryptase fails to activate procollagenase or degrade proteoglycan

Pig synovial and human skin fibroblast procollagenases were treated with highly purified tryptase, the major proteinase of human mast cells, to determine whether this trypsin-like proteinase could activate the latent form of collagenase and so be involved in connective tissue breakdown. No significant activation of either human or pig procollagenase was found, but the highest concentration of tryptase partially destroyed procollagenase. Tryptase did not degrade type I collagen or proteoglycan. These data indicate that human mast cell tryptase does not contribute to connective tissue breakdown via procollagenase activation or via proteoglycan degradation.     

Evidence that human rheumatoid synovial matrix metalloproteinase 3 is an endogenous activator of procollagenase

The treatment of crude culture medium from human rheumatoid synovial cells with 4-aminophenylmercuric acetate (APMA) or trypsin results in the activation of procollagenase. This process was shown to be dependent on the presence of matrix metalloproteinase 3 (MMP-3). MMP-3 can directly activate procollagenase without changing the apparent molecular weight of procollagenase. This activity was accelerated in the presence of APMA. We propose that MMP-3 plays an important role in connective tissue destruction through the activation of procollagenase in addition to its direct action on components of the extracellular matrix.     

Activation of fibroblast procollagenase by mast cell proteases.

Proteases capable of activating procollagenase from gingiva and from fibroblast and macrophage monolayer cultures were harvested from homogenates of canine tumor mast cells. The mast cell proteases lysed casein and Azocoll but not native collagen. In low salt concentrations the enzymes existed at high molecular weight complexes, which were dissociated by increasing the salt concentration above 1.0 M (NaCl, KCl). Gel filtration in 1.4 M KCl separated the protease activity into three peaks, all of which activated procollagenase. Two of the enzymes showed substrate specificities (hydrolysis of p-tosyl-L-arginine methyl ester and benzoyl-tyrosine ethyl ester) and reactive center reactivities similar to pancreatic trypsin and chymotrypsin. Based on gel filtration, apparent molecular weights of 160 000 (p-tosyl-L-arginine methyl ester esterase), 90 000 (main procollagenase activator) and 36 000 benzoyl-tyrosine ethyl ester esterase) were determined. Activation of procollagenase resulted in a 18-20 000 decrease of the molecular weight. The activation was directly related to the amount of activator added within certain limits. Further addition of activator resulted in proteolytic inactivation of collagenase.     

Secretion of metalloproteinases by stimulated capillary endothelial cells. I. Production of procollagenase and prostromelysin exceeds expression of proteolytic activity

We have characterized the biosynthesis of two metalloproteinases, procollagenase and prostromelysin, by rabbit brain capillary endothelial cells (RBCE) by means of immunochemical, biosynthetic, and functional assays. Unstimulated RBCE secreted no detectable metalloproteinases. Secretion of both procollagenase and prostromelysin was induced within 6 h by treating the cells with 50 ng/ml 12-O-tetradecanoylphorbol-13-acetate. In treated cells, the two proenzymes accounted for up to 20% of the [35S]methionine-labeled secreted proteins; about 15 micrograms of each protein was secreted in 48 h by 10(6) RBCE. Although RBCE secreted approximately as much procollagenase and prostromelysin as did rabbit fibroblasts, virtually no enzyme activity could be measured in RBCE-conditioned medium, even after activation of the proenzymes by trypsin or an organomercurial agent.     

Human skin collagenase: isolation of precursor and active forms from both fibroblast and organ cultures.

Human skin procollagenase has been isolated, in pure form, from the medium of fibroblasts cultured in the presence or absence of added serum. Purification was achieved using a combination of cation-exchange (phosphocellulose or carboxymethylcellulose) and gel-filtration chromatography. Two forms (60 000 and 55 000 daltons) of the procollagenase were detected by electrophoresis in sodium dodecyl sulfatepolyacrylamide gels and could be separated by chromatography on Ultrogel AcA-44. Each form was converted to active enzyme by trypsin, producing species of 50 000 and 45 000 daltons, respectively. An autoactivation process also occurred, which yielded active enzyme without a detectable change in molecular weight. Procollagenase also was found in organ cultures of human skin but only when serum was added to the medium. This suggests that a serum-inhibitable proteolytic system is present in these cultures which, like trypsin, converts procollagenase to the active enzyme forms that can be isolated from serum-free organ culture medium. The collagenase species obtained from either fibroblast or organ culture medium were chromatographically and electrophoretically identical.     

Serine proteinase activation of latent human skin collagenase

Latent and active collagenase were demonstrated following direct extraction from normal skin homogenates with 0.1M calcium chloride at 60 degrees C. 83% of the collagenase activity was in latent form and could be maximally activated with trypsin. Partial activation of the latent enzyme could also be demonstrated by incubation of the skin extract without added trypsin. This endogenous activation was inhibited by the addition of soya bean trypsin inhibitor, trasylol, di-isopropylphosphofluoridate and phenylmethanesulphonylfluoride, none of which inhibited collagenase directly. This suggests that the skin extracts contain a collagenase activating enzyme with the inhibition profile of a serine proteinase. A chymotryptic proteinase with a similar inhibition profile was extracted from normal human skin and partially purified. This enzyme activated fibroblast procollagenase derived from tissue culture of normal skin. The procollagenase was also partially activated by plasmin and chymotrypsin. This is the first demonstration of a collagenase activating enzyme in human skin and raises the possibility that collagenase activation by this mechanism may be responsible for collagen degradation in some disease processes.     

Stromelysin is an activator of procollagenase. A study with natural and recombinant enzymes.

The latent forms of stromelysin and collagenase from human gingival fibroblasts were purified to homogeneity. These latent proenzymes underwent serial small reductions in Mr upon activation by treatment with either 4-aminophenylmercuric acetate or trypsin. Similar shifts in Mr and activation kinetics were observed upon identical treatments of either recombinant prostromelysin or procollagenase. Prostromelysin showed a lag between activation and Mr fall, suggesting an initial activation by conformational change. Collagenase activity was enhanced up to 12-fold by either natural or recombinant stromelysin in the presence of trypsin or 4-aminophenylmercuric acetate. Stromelysin caused a further apparent decrease in the Mr of procollagenase. Since these important connective-tissue-degrading enzymes are usually co-ordinately produced by cells, a cascade mechanism is proposed in which collagenase is activated by stromelysin.     

The activation of human skin fibroblast procollagenase. Sequence identification of the major conversion products

Human skin collagenase is secreted by cultured fibroblasts in a proenzyme form and can be activated to a catalytically competent enzyme by a number of processes. All modes of activation studied lead to conversion of the proenzyme to a stable 42-kDa active enzyme, concomitant with removal of an 81-amino acid peptide from the amino-terminal end of the molecule. The sequence of events leading to the formation of this enzyme form has been determined by analyzing the primary structure of the conversion intermediates. Trypsin-induced activation of procollagenase occurs as a result of the initial cleavage of the peptide bond between Arg-55 and Asn-56, generating a major intermediate of 46 kDa. Treatment of the proenzyme with organomercurials, which have no intrinsic ability to cleave peptide bonds, initially results in activation of the enzyme without loss of molecular weight. This is followed by conversion to two lower molecular weight species of 44 and 42 kDa, the latter corresponding to the stable active enzyme form. The final cleavage producing this form of collagenase is not restricted to a single polypeptide bond but can occur on the amino-terminal side of any one of three contiguous hydrophobic residues, Phe-100, Val-101, Leu-102. The data suggest that both trypsin and organomercurials activate procollagenase by initiating an intramolecular autoproteolytic reaction resulting in the formation of a stable 42-kDa active enzyme species.     

Monocyte procollagenase and tissue inhibitor of metalloproteinases. Identification, characterization, and regulation of secretion

Alveolar macrophages have been shown to secrete a procollagenase and the tissue inhibitor of metalloproteinases (TIMP), which are similar or identical to the corresponding proteins of human skin fibroblasts. Little is known, however, about the collagenolytic activity of normal human monocytes. We have applied immunologic, biochemical, and molecular biologic tools to examine the collagenolytic profile of freshly isolated peripheral blood monocytes. Our studies indicate that: 1) monocytes are capable of producing both procollagenase and TIMP that are identical to the corresponding products of skin fibroblasts, alveolar macrophages, and U-937 cells; 2) unstimulated monocytes in vitro secrete high levels of TIMP, but little or no procollagenase; 3) an as yet unidentified component(s) of serum are required for in vitro production of TIMP (but not procollagenase) by monocytes; 4) even when stimulated, monocytes secrete much smaller quantities of procollagenase in comparison with macrophages; and 5) regulation of the secretion of procollagenase and TIMP by monocytes exhibits a high degree of individual variability, but is nevertheless subject to clearly different control mechanisms than our previous findings would indicate for alveolar macrophages. Monocytes thus express a macrophage-like, rather than a neutrophil-like, profile of proteins capable of mediating collagen turnover, the regulation of which is distinct from that of more differentiated alveolar macrophages. Further study of monocyte and macrophage collagenolytic activities may provide insights into both the cell biology of mononuclear phagocyte maturation and the mechanisms by which such cells mediate the turnover of interstitial collagens.     

A latent collagenase from embryonic human skin explants.

Collagenase released from embryonic and adult human skin explants has been studied with special reference to the latency of the enzyme. 1) Embryonic human skin explants showed a much higher capacity for collagenase production than did adult skin, on the basis of unit weight of tissue. 2) Culture medium from embryonic skin explants contained latent collagenase at almost twice the concentration of the active form. No appreciable amount of latent enzyme was observed in the adult skin system. 3) The molecular weights of active and latent collagenases were about 40,000 and 50,000, respectively. 4) The latent collagenase was found to be activated by simple passage through a Sephadex G-50 column after adding NaI to a final concentration of 3 M. The degree of activation produced by this treatment was as high as that by limited proteolysis with trypsin. It was concluded that no activating enzyme system was involved in the activation of latent collagenase during NaI treatment, and that the latent enzyme was composed of an enzyme-inhibitor complex. 5) The physiological significance of latent enzyme in the regulation of collagenase activity in vivo is discussed.     

Secretion of metalloproteinases by stimulated capillary endothelial cells. II. Expression of collagenase and stromelysin activities is regulated by endogenous inhibitors

Rabbit brain capillary endothelial cells treated with 12-O-tetradecanoylphorbol-13-acetate produce the metalloproteinases, procollagenase and prostromelysin, as up to 20% of their total secreted protein. However, little or no catalytic activity of these enzymes can be found after treatment with either trypsin or an organomercurial agent, which are able to activate the proenzymes in the medium from stimulated rabbit fibroblasts. We now have shown that enzyme activities of procollagenase and prostromelysin are revealed after conditioned medium is analyzed by gel filtration chromatography or by electrophoresis on sodium dodecyl sulfate-substrate gels. In both systems, the metalloproteinases were separated from metalloproteinase inhibitors. The major inhibitor of Mr = 30,000 from capillary endothelial cells was immunologically identical with the rabbit tissue inhibitor of metalloproteinases. Two additional inhibitors of metalloproteinases at Mr = 22,000 and 19,000 were also observed. Inhibitors were present in the conditioned medium from rabbit fibroblasts in much lower quantities and were also qualitatively different. When gel filtration chromatography was used to remove the tissue inhibitor of metalloproteinases from medium conditioned by stimulated capillary endothelial cells, both activatable procollagenase and prostromelysin were readily demonstrable. These data suggest that endogenous inhibitors regulate the expression of metalloproteinases secreted by endothelial cells.     

Production of procollagenase by cultured human keratinocytes

Using a collagen film assay utilizing 14C-labeled type I collagen, we demonstrated that cultured human keratinocytes produced a procollagenase after treatment with the tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA). Production of collagenase paralleled alterations in cellular morphology induced by TPA. When procollagenase was immunoprecipitated with antibody to human fibroblast collagenase and analyzed on sodium dodecyl sulfate-polyacrylamide gels, the zymogen was revealed as a 56- and 51-kDa doublet. The keratinocyte-derived collagenase was a neutral metalloprotease, required activation with trypsin for detection in the collagenase assay and produced the characteristic three-quarter and one-quarter length collagen cleavage products when incubated with type I collagen at 25 degrees C. The enzyme was inhibited by serum and cysteine and was largely unaffected by serine, thiol, and carboxyl protease inhibitors. Cycloheximide inhibited the TPA-induced production of collagenase, suggesting that the procollagenase was not stored preformed in the keratinocytes. Keratinocytes treated with a tumor-promoting analogue of TPA also produced collagenase, but cells treated with cytochalasin B, interleukin-1, or two non-tumor promoting phorbol esters did not. Keratinocyte-derived collagenase may play a role in wound healing and morphogenesis.     

Characterization and activation of procollagenase from human polymorphonuclear leucocytes. N-terminal sequence determination of the proenzyme and various proteolytically activated forms

Procollagenase of human polymorphonuclear leucocytes was purified to homogeneity using a rapid and reproducible method. The purification procedure included affinity chromatography on zinc chelate Sepharose, ion exchange chromatography on Q-Sepharose fast flow, followed by affinity chromatography on orange Sepharose and finally a gel-permeation step on Sephacryl S-300. It was shown by SDS/PAGE, under reducing conditions, that the latent collagenase of human polymorphonuclear leucocytes consists of a single polypeptide chain with an apparent relative molecular mass of 85,000. Upon deglycosylation by endoglycosidase F digestion, the apparent relative molecular mass of the procollagenase was reduced to 53,000 which is similar to that of the fibroblast enzyme, and indicates a close relationship between both enzymes. Sequence data were determined by direct automated Edman degradation of the purified polymorphonuclear leucocyte procollagenase. The complete sequence of the propeptide region (residue 1-120) was thereby established. The proteolytic activation of the polymorphonuclear leucocyte procollagenase by various enzymes was investigated by determining the N-terminal sequences of the intermediate and final activated forms. Activation by chymotrypsin and cathepsin G led to the active form (Mr 64,000) by cleaving 79 N-terminal residues from the proenzyme. Trypsin activates in a two-step process. Cleavage of 48 N-terminal residues led to a still latent Mr 70,000 species. The final active form (Mr 65,000) was obtained by splitting off 20 additional N-terminal residues.     

The simultaneous release by bone explants in culture and the parallel activation of procollagenase and of a latent neutral proteinase that degrades cartilage proteoglycans and denatured collagen.

1. A latent neutral proteinase was found in culture media of mouse bone explants. Its accumulation during the cultures is closely parallel to that of procollagenase; both require the presence of heparin in the media. 2. Latent neutral proteinase was activated by several treatments of the media known to activate procollagenase, such as limited proteolysis by trypsin, chymotrypsin, plasmin or kallikrein, dialysis against 3 M-NaSCN at 4 degrees C and prolonged preincubation at 25 degrees C. Its activation often followed that of the procollagenase present in the same media. 3. Activation of neutral proteinase (as does that of procollagenase) by trypsin or plasmin involved two successive steps: the activation of a latent endogenous activator present in the media followed by the activation of neutral proteinase itself by that activator. 4. The proteinase degrades cartilage proteoglycans, denatured collagen (Azocoll) and casein at neutral pH; it is inhibited by EDTA, cysteine or serum. Collagenase is not inhibited by casein or Azocoll and is less resistant to heat or to trypsin than is the proteinase. Partial separation of the two enzymes was achieved by gel filtration of the media but not by fractional (NH4)2SO4 precipitation, by ion exchange or by affinity chromatography on Sepharose-collagen. These fractionations did not activate latent enzymes. 5. Trypsin activation decreases the molecular weight of both latent enzymes (60 000-70 000) by 20 000-30 000, as determined by gel filtration of media after removal of heparin. 6. The latency of both enzymes could be due either to a zymogen or to an enzyme-inhibitor complex. A thermostable inhibitor of both enzymes was found in some media. However, combinations of either enzyme with that inhibitor were not reactivated by trypsin, indicating that this inhibitor is unlikely to be the cause of the latency.     

Further studies on the activation of procollagenase, the latent precursor of bone collagenase. Effects of lysosomal cathepsin B, plasmin and kallikrein, and spontaneous activation.

1. Cathepsin B, a tissue (lysosomal) proteinase, and two humoral proteinases, plasmin and kallikrein, activate the latent collagenase ('procollagenase') which is released by mouse bone explants in culture. Other lysosomal proteinases (carboxypeptidase B, cathepsin C and D) and thrombin did not activate the procollagenase. Dialysis of the culture fluids against 3M-NaSCN at 4 degrees C and, for some culture fluids, prolonged preincubation at 25 degrees C also caused the activation of procollagenase. 2. In all these cases, activation of procollagenase involved at least two successive steps: the activation of an endogenous latent activator present in the culture fluids and the activation of procollagenase itself. 3. An assay method was developed for the endogenous activator. Human serum, bovine serum albumin, casein and cysteine inhibited the endogenous activator at concentrations that did not influence the collagenase activity. N-Ethylmaleimide and 4-hydroxy-mercuribenzoate stimulated the endogenous activator, but iodoacetate had no effect. 4. It is proposed that cathepsin B, kallikrein and plasmin may play a role in the physiological activation of latent collagenase and thus initiate degradation of collagen in vivo. This may occur whatever the molecular nature of procollagenase (zymogen or enzyme-inhibitor complex) might be.     

Procollagenase activator produced by rabbit uterine cervical fibroblasts.

Culture medium from rabbit uterine cervical fibroblasts contained a procollagenase and a neutral proproteinase which acts as a procollagenase activator. These two proenzymes have been purified by a combination of ion-exchange, affinity and gel chromatographies. The purified neutral proproteinase showed Mr 60,000 with sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. This neutral proproteinase was activated by trypsin, 4-aminophenylmercuric acetate (APMA) and plasmin, and the active species of the proteinase had Mr 53,000 when activated by APMA; kallikrein and urokinase did not activate this proproteinase. The purified neutral proteinase was inhibited by EDTA, 1,10-phenanthroline and rabbit plasma, but not by serine proteinase inhibitors, suggesting that this proteinase is a metal-dependent proteinase. The purified enzyme could also degrade gelatin, casein, proteoglycan and type IV procollagen. The purified procollagenase had Mr 55,000 and was activated by trypsin, APMA and the active neutral proteinase. These activations were accompanied by decrease in Mr, and the activated species had an Mr which was approx. 10,000 less than that of the procollagenase. In particular, procollagenase activation with neutral proteinase depended on incubation time and proteolytic activity of proteinase. These results indicate that activation of procollagenase by the rabbit uterine neutral proteinase is related to limited proteolysis in the procollagenase molecule.     

Mercurial activation of human polymorphonuclear leucocyte procollagenase.

The mechanism of human polymorphonuclear leucocyte (PMNL) procollagenase activation by HgCl2 was investigated by kinetic and sequence analysis of the reaction products. HgCl2 activated PMNL procollagenase by intramolecular autoproteolytic cleavage of the Asn53-Val54 peptide bond to generate a collagenase species of Mr 65000, which was immediately converted into a second intermediate collagenase form by further autoproteolytic cleavage of the Asp64-Met65 peptide bond within the propeptide domain. This intermediate form (Met65 N-terminus) reached maximum concentrations after 45 min and displayed only about 40% of the maximum available enzymatic activity. Final activation was obtained after autoproteolytic cleavage of either Phe79-Met80 or Met80-Leu81 peptide bonds. Furthermore, activation in the presence of TIMP-1 did not suppress the intramolecular autoproteolytic cleavage of the Asn53-Val54 peptide bond. Complete inhibition of further autoproteolytic decay of the enzyme or generated peptides was observed, which was obviously due to complex formation between the intermediate collagenase form (Val54 N-terminus) and inhibitor, which was visualized using the Western blot technique. Thus PMNL procollagenase activation by HgCl2 followed a three-step activation mechanism which is entirely different from the known activation mechanisms of the fibroblast matrix metalloproteinases.