Stromelysin, a connective tissue-degrading metalloendopeptidase secreted by stimulated rabbit synovial fibroblasts in parallel with collagenase. Biosynthesis, isolation, characterization, and substrates

Rabbit synovial fibroblasts induced to undergo a specific switch in gene expression by agents that alter cell morphology secreted the neutral proteinase precursor procollagenase (apparent Mr of 53,000 and 57,000). A major Mr = 51,000 polypeptide that was always induced coordinately with procollagenase has now been identified as the proenzyme form of a metal-dependent proteinase active at neutral pH. We have named this proteinase stromelysin. Prostromelysin and procollagenase were the most prominent [35S]methionine-labeled secreted proteins of the induced fibroblasts. By the use of casein degradation as an assay for enzyme activity, stromelysin was isolated with high yield from the conditioned culture medium of 12-O-tetradecanoylphorbol 13-acetate-treated fibroblasts and migrated as an active form of Mr = 21,000 that was immunologically identical to the proteoglycan-degrading proteinase purified from rabbit bone. Immunoglobulin G from antiserum raised to purified rabbit bone proteoglycanase immunoprecipitated the Mr = 51,000 proenzyme form from conditioned medium of induced rabbit cells and also immunoprecipitated an Mr = 55,000 polypeptide from induced human fibroblasts. When rabbit prostromelysin was activated by trypsin or 4-aminophenylmercuric acetate, the proenzyme was converted to an active form of Mr = 41,000. During the course of the purification, prostromelysin was converted to an additional activatable form of Mr = 35,000 and additional active forms of Mr = 21,000-25,000, which had related peptide maps distinct from collagenase. All of these forms were immunologically cross-reactive. Purified stromelysin degraded casein, cartilage proteoglycans, fibronectin, alpha 1-proteinase inhibitor, and immunoglobulin G2a and had limited activity on laminin, elastin, type IV collagen, and gelatin, but did not degrade type I collagen. Stromelysin was inhibited by EDTA, 1,10-phenanthroline, and the specific glycoprotein tissue inhibitor of metalloproteinases isolated from human amniotic fluid and was therefore classified as a metalloproteinase.     

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.     

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.     

The enzymatic evaluation of procollagenase and collagenase inhibitors in crude biological media

The validity of the enzymatic assay of procollagenase within crude biological media containing also the collagenase inhibitor TIMP (tissue inhibitor of metalloproteinases) as well as other (pro)metalloproteinases and sometimes, metalloproteinase-TIMP complexes, has been reevaluated. To be enzymatically assayed, procollagenase has to be activated. The standard activation procedures by either trypsin or 4-aminophenylmercuric acetate (APMA) both allow an optimal recovery of collagenase from procollagenase when the media do not contain free TIMP. However, they do not destroy TIMP nor do they reactivate the collagenase present in enzyme-inhibitor complexes. Therefore, the collagenase formed by the activation of procollagenase in the presence of free TIMP is immediately inactivated by binding to the inhibitor. As a result, both the bound collagenase and TIMP can no longer be assayed by enzymatic methods. An optimal recovery of collagenase can, however, be obtained if free TIMP is neutralized by the binding of other tissue metalloproteinases (such as those present in culture media of rabbit bone marrow-derived macrophages) prior to the activation and assay of procollagenase. Similarly, it is possible to recover under an active free form a large part of the TIMP present in collagenase- (or other metalloproteinase-)TIMP complexes by heating the complexes at acid pH under conditions which inactivate the collagenase.     

Neutral metallo-proteinases of rabbit bone. Separation in latent forms of distinct enzymes that when activated degrade collagen, gelatin and proteoglycans.

Rabbit bones in culture produce specific collagenase and neutral metallo-proteinase activity in latent forms that can be activated by either 4-aminophenylmercuric acetate or trypsin. Latent neutral metallo-proteinase activity was resolved by gel filtration into two enzymes, distinct from collagenase, that degrade gelatin and cartilage proteoglycans.     

Mechanisms of activation of tissue procollagenase by matrix metalloproteinase 3 (stromelysin)

The mechanism of activation of tissue procollagenase by matrix metalloproteinase 3 (MMP-3)/stromelysin was investigated by kinetic and sequence analyses. MMP-3 slowly activated procollagenase by cleavage of the Gln80-Phe81 bond to generate a fully active collagenase of Mr = 41,000. The specific collagenolytic activity of this species was 27,000 units/mg (1 unit = 1 microgram of collagen digested in 1 min at 37 degrees C). Treatment of procollagenase with plasmin or plasma kallikrein gave intermediates of Mr = 46,000. These intermediates underwent rapid autolytic activation, via cleaving the Thr64-Leu65 bond, to give a collagenase species of Mr = 43,000 that exhibited only about 15% of the maximal specific activity. Similarly, (4-aminophenyl)mercuric acetate (APMA) activated procollagenase by intramolecular cleavage of the Val67-Met68 bond to generate a collagenase species of Mr = 43,000, but with only about 25% of the maximal specific activity. Subsequent incubation of the 43,000-Mr species with MMP-3 resulted in rapid, full activation and generated the 41,000-Mr collagenase by cleaving the Gln80-Phe81 bond. In the case of the proteinase-generated 43,000-Mr species, the action of MMP-3 was approximately 24,000 times faster than that on the native procollagenase. This indicates that the removal of a portion of the propeptide of procollagenase induces conformational changes around the Gln80-Phe81 bond, rendering it readily susceptible to MMP-3 activation. Prolonged treatment of procollagenase with APMA in the absence of MMP-3 also generated a 41,000-Mr collagenase, but this species had only 40% of the full activity and contained Val82 and Leu83 as NH2 termini. Thus, cleavage of the Gln80-Phe81 bond by MMP-3 is crucial for the expression of full collagenase activity. These results suggest that the activation of procollagenase by MMP-3 is regulated by two pathways: one with direct, slow activation by MMP-3 and the other with rapid activation in conjunction with tissue and/or plasma proteinases. The latter event may explain an accelerated degradation of collagens under certain physiological and pathological conditions.     

The activation of latent pig synovial collagenase

Latent pig synovial collagenase (EC 3.4.24.7) can be activated by a variety of different treatments to give an active enzyme form of lower molecular weight which rapidly degrades collagen. Trypsin and plasmin effectively activated the latent collagenase whilst elastase and cathepsin G degraded most of the latent enzyme before it was activated. A number of mercurials were compared and maximum activation was achieved using 4-aminophenylmercuric acetate and phenylmercuric chloride. The latent collagenase bound to a mercurial-Sepharose column and was eluted in the active form with NaCl. The latent collagenase also activated spontaneously and the conditions which encouraged and prevented this activation were studied. High NaCl concentration, diisopropylphosphofluoridate, soybean trypsin inhibitor, low Zn2+ concentration and high and low pH all prevented the spontaneous activation of latent pig synovial collagenase.     

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.     

Matrix metalloproteinase 2 from human rheumatoid synovial fibroblasts. Purification and activation of the precursor and enzymic properties

Human rheumatoid synovial cells in culture secrete at least three related metalloproteinases that digest extracellular matrix macromolecules. One of them, termed matrix metalloproteinase 2 (MMP-2), has been purified as an inactive zymogen (proMMP-2). The final product is homogeneous on SDS/PAGE with Mr = 72,000 under reducing conditions. The NH2-terminal sequence of proMMP-2 is Ala-Pro-Ser-Pro-Ile-Ile-Lys-Phe-Pro-Gly-Asp-Val-Ala-Pro-Lys-Thr, which is identical to that of the so-called '72-kDa type IV collagenase/gelatinase'. The zymogen can be rapidly activated by 4-aminophenylmercuric acetate to an active form of MMP-2 with Mr = 67,000, and the new NH2-terminal generated is Tyr-Asn-Phe-Phe-Pro-Arg-Lys-Pro-Lys-Trp-Asp-Lys-Asn-Gln-Ile. However, following 4-aminophenylmercuric acetate activation, MMP-2 is gradually inactivated by autolysis. Nine endopeptidases (trypsin, chymotrypsin, plasmin, plasma kallikrein, thrombin, neutrophil elastase, cathepsin G, matrix metalloproteinase 3, and thermolysin) were tested for their abilities to activate proMMP-2, but none had this ability. This contrasts with the proteolytic activation of proMMP-1 (procollagenase) and proMMP-3 (prostromelysin). The optimal activity of MMP-2 against azocoll is around pH 8.5, but about 50% of activity is retained at pH 6.5. Enzymic activity is inhibited by EDTA, 1,10-phenanthroline or tissue inhibitor of metalloproteinases, but not by inhibitors of serine, cysteine or aspartic proteinases. MMP-2 digests gelatin, fibronectin, laminin, and collagen type V, and to a lesser extent type IV collagen, cartilage proteoglycan and elastin. Comparative studies on digestion of collagen types IV and V by MMP-2 and MMP-3 (stromelysin) indicate that MMP-3 degrades type IV collagen more readily than MMP-2, while MMP-2 digests type V collagen effectively. Biosynthetic studies of MMPs using cultured human rheumatoid synovial fibroblasts indicated that the production of both proMMP-1 and proMMP-3 is negligible but it is greatly enhanced by the treatment with rabbit-macrophage-conditioned medium, whereas the synthesis of proMMP-2 is constitutively expressed by these cells and is not significantly affected by the treatment. This suggests that the physiological and/or pathological role of MMP-2 and its site of action may be different from those of MMP-1 and MMP-3.     

Collagenase, procollagenase and bone resorption. Effects of heparin, parathyroid hormone and calcitonin.

1. The addition of heparin to the culture fluid of mouse tibiae or calvaria did not cause any significant resorption of bone collagen or mineral. However, heparin (or analogue sulfated polyanions), enhanced greatly the amount of latent, trypsin-activatable collagenase (i.e. procollagenase) released by the bones in the medium without influencing that of directly active collagenase which was always very low. Heparin appeared to act by increasing the production of the enzyme which is immediately excreted. Procollagenase and collagenase are not stored in bone tissue, even under conditions where it is in active resorption. 2. Parathyroid hormone induced in the explants a resorption of both mineral and collagen that was inhibited by calcitonin. These hormones, however, had no influence on the release of procollagenase or collagenase either in the presence or in the absence of heparin. 3. Once activated, bone collagenase digested the collagen of the bone explants, and more extensively after their demineralization. Thus the latent collagenase that accumulates around non-resorbing bones has to be considered as a precursor, (and not as a residue), of active enzyme. 4. Active collagenase added to incipient cultures of bones disappeared with a half-life of 24 h. The lost enzyme could, however, not be reactivated by trypsin and thus was not transformed into latent procollagenase.     

Pump-1 cDNA codes for a protein with characteristics similar to those of classical collagenase family members

Pump-1 cDNA has recently been isolated by screening a human tumor cDNA library with a transin (rat stromelysin) probe under low-stringency hybridization conditions. The cDNA codes for a potential protein with significant sequence similarity to the metalloproteinases collagenase and stromelysin, but which lacks the hemopexin-like domain characteristic of these enzymes. Expression of pump-1 cDNA in cos cells using an expression vector leads to secretion of a protein of Mr 28,000 with latent, organomercurial-activatable proteinase activity. Cos cells transfected with a partial pump-1 cDNA in the vector pPROTA secrete a fusion protein between the IgG-binding domains of staphylococcal protein A and pump-1. The fusion protein binds to IgG-Sepharose, and the bound fusion protein undergoes apparent autocleavage in the presence of 4-aminophenylmercuric acetate with elution of active pump-1 species of Mr 21,000 and 19,000. Active pump-1 degrades casein, gelatins of types I, III, IV, and V, and fibronectin and can activate collagenase. Active pump-1 is inhibited by EDTA, 1,10-phenanthroline, and the tissue inhibitor of metalloproteinases. These results show that, despite the absence of a hemopexin-like domain, pump-1 is a latent secreted metalloproteinase. Postpartum rat uteri contain elevated levels of rat pump-1 mRNA. On the basis of this observation, its size, and its substrate specificity, we suggest that pump-1 might correspond to a previously described uterine metalloproteinase, matrix metalloproteinase 7.     

The latent collagenase and gelatinase of human polymorphonuclear neutrophil leucocytes.

Two metallo-proteinases of human neutrophil leucocytes, collagenase and gelatinase, were studied. Collagenase specifically cleaved native collagen into the TCA and TCB fragments, whereas gelatinase degraded denatured collagen, i.e. gelatin, and the TCA fragments produced by collagenase. On subcellular fractionation by zonal sedimentation, collagenase was found to be localized in the specific granules, separate from gelatinase, which was recovered in smaller subcellular organelles known as C-particles. Neither enzyme was present in the azurophil granules, which contain the two major serine proteinases of neutrophils, elastase and cathepsin G. Collagenase and gelatinase were separated by gel filtration from extracts of partially purified granules. Both enzymes were found to occur in latent forms and were activated either by trypsin or by 4-aminophenylmercuric acetate. Gelatinase was also activated by cathepsin G, which, however, destroyed collagenase. Both enzymes were destroyed by neutrophil elastase. Activation resulted in a decrease by 25 000 in the apparent mol. wt. of both latent metallo-proteinases.     

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.     

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.     

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.     

An inhibitor of collagenase from human amniotic fluid. Purification, characterization and action on metalloproteinases.

1. An inhibitor of collagenase of apparent mol.wt. 28000 was isolated from term human amniotic fluid. 2. It is active against mammalian collagenases from a number of species and tissues as well as other mammalian metalloproteinases, but has no activity against bacterial metalloproteinases. 3. Activity is destroyed by treatment with either trypsin or 4-aminophenylmercuric acetate, by heat, and by reduction and carboxymethylation. 4. All the properties observed suggest that it is similar to the synthesized tissue inhibitor of metalloproteinases.     

Purification of a metalloproteinase inhibitor from human rheumatoid synovial fluid.

A metalloproteinase inhibitor present in human rheumatoid synovial fluid was purified by a combination of heparin-Sepharose chromatography, concanavalin A-Sepharose chromatography, ion-exchange chromatography and gel filtration. The Mr of the purified inhibitor was 28000 by SDS/polyacrylamide-gel electrophoresis and 30000 by gel filtration. The inhibitor blocked the activity of the metalloproteinases collagenase, gelatinase and proteoglycanase, but not thermolysin or bacterial collagenase. The serine proteinase trypsin was not inhibited. The inhibitory activity was lost after treatment with trypsin (0.5 micrograms/ml) at 37 degrees C for 30 min, 4-aminophenylmercuric acetate (1 mM) at 37 degrees C for 3 h, after incubation for 30 min at 90 degrees C and by reduction and alkylation. These properties suggest that the inhibitor closely resembles the tissue inhibitor of metalloproteinases ('TIMP') recently purified from connective-tissue culture medium.     

Evidence that latent collagenases are enzyme-inhibitor complexes.

Specific collagenase from the culture media of various rabbit tissues and cells exists in active and latent forms. Latent collagenase is most effectively activated with 4-aminophenylmercuric acetate, a thiol-blocking reagent, strongly suggesting that latent forms are enzyme-inhibitor complexes. A collagenase inhibitor from bone cultures, which may be closely related to the inhibitor of such latent enzyme complexes, was partially characterized.