Specific cleavage of human type III collagen by human polymorphonuclear leukocyte elastase

Purified polymorphonuclear leukocyte elastase degraded native human liver type III collagen at 27 degrees C by making a cleavage through the triple helix. The enzyme had no effect on human type I collagen. The reaction was inhibited by phenylmethanesulfonyl fluoride (PhCH2SO2F) but not by EDTA. The collagen reaction products were identical with those generated by human rheumatoid synovial collagenase when analyzed by polyacrylamide gel electrophoresis and gel filtration. NH2-trminal sequence analysis indicated that the enzyme cleaved at an isoleucyl-threonyl bond located 4 residues on the carboxyl side of the established cleavage site for animal collagenases. Therefore, it is likely that in pathologic states, type III collagen can be selectively depleted from the matrix by this enzyme.     

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.     

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.     

Chemical and enzymatic characterization of the collagenase from the insect Hypoderma lineatum.

The collagenase from the larvae Hypoderma lineatum, with a molecular weight of 24 000 and isoelectric point of 4.1, was obtained in homogeneous form by ion-exchange chromatography. It is stoichiometrically inhibited by diisopropylfluorophosphate. On the other hand it is unaffected by ethylenediaminetetraacetate, p-chloromercuribenzoate, dithiothreitol, N-tosyllysine chloromethyl ketone, N-tosylphenylalanine chloromethyl ketone and ovomucoid trypsin inhibitor. The enzyme which degrades native collagen in its helical parts, has a specific activity on thermally reconstituted collagen fibrils of 150 micrograms collagen degraded x min-1 x (mg enzyme)-1 at 37 degrees C. It hydrolyses casein but has no esterolytic activity characteristic of trypsin, chymotrypsin nor elastase. It has no action on the synthetic peptide 4-phenylazobenzyloxycarbonyl-L-prolyl-L-leucyl-L-glycyl-L-prolyl-D-arginine. The amino acid composition of Hypoderma collagenase indicates a distinct similarity with the serine proteinases of the trypsin family and with another athropode serine collagenase, that of the fiddler crab Uca pugilator. This suggests that eucaryotic collagenases with digestive rather than morphogenic function represent a new category of members of the trypsin family.     

A component of normal human serum which enhances the activity of vertebrate collagenases.

The activity of vertebrate collagenase is increased by approximately 3-fold in the presence of saturating amounts of a macromolecule found in normal human serum. The activities of collagenases from human skin, rat skin, and tadpole tailfin are all markedly enhanced in the presence of this molecule, but activities of bacterial collagenase, trypsin, chymotrypsin, thermolysin, and a gelatin-specific neutral protease from human skin are unchanged. The enhancer itself has no proteolytic activity and does not change the normal cleavage products of human skin collagenase. The collagenase enhancer is an extremely stable molecule. It is resistant to heat, to extremes of pH at physiological temperature, and appears to be protein in nature. Of particular interest is the requirement that the collagen substrate be in fibrillar form in order for the enhancer to be effective.     

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.     

Purification of rabbit bone inhibitor of collagenase.

1. Rabbit bones in tissue culture synthesize an inhibitor of collagenase during the first 4 days of culture. 2. The inhibitor was purified by a combination of gel filtration, concanavalin A--Sepharose chromatography, ion-exchange chromatography and zinc-chelate affinity chromatography. 3. The purified inhibitor migrated as a single band on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and had a mol.wt. of 28000. 4. The inhibitor blocked the activity of the metalloproteinases collagenase, gelatinase, neutral proteinase III (proteoglycanase), human leucocyte collagenase and gelatinase, but not thermolysin or bacterial collagenase. The serine proteinases plasmin and trypsin were not inhibited. 5. The inhibitor interacted with purified rabbit bone collagenase with 1:1 stoichiometry. 6. The inhibitory activity was lost after incubation for 1 h at 90 degrees C, after treatment with trypsin (250 micrograms/ml) at 37 degrees C for 30 min and after reduction and alkylation.     

Susceptibility of cartilage collagens type II, IX, X, and XI to human synovial collagenase and neutrophil elastase

The action of purified rheumatoid synovial collagenase and human neutrophil elastase on the cartilage collagen types II, IX, X and XI was examined. At 25 degrees C, collagenase attacked type II and type X (45-kDa pepsin-solubilized) collagens to produce specific products reflecting one and at least two cleavages respectively. At 35 degrees C, collagenase completely degraded the type II collagen molecule to small peptides whereas a large fragment of the type X molecule was resistant to further degradation. In contrast, collagen type IX (native, intact and pepsin-solubilized type M) and collagen type XI were resistant to collagenase attack at both 25 degrees C and 35 degrees C even in the presence of excess enzyme. Mixtures of type II collagen with equimolar amounts of either type IX or XI did not affect the rate at which the former was degraded by collagenase at 25 degrees C. Purified neutrophil elastase, shown to be functionally active against soluble type III collagen, had no effect on collagen type II at 25 degrees C or 35 degrees C. At 25 degrees C collagen types IX (pepsin-solubilized type M) and XI were also resistant to elastase, but at 35 degrees C both were susceptible to degradation with type IX being reduced to very small peptides. Collagen type X (45-kDa pepsin-solubilized) was susceptible to elastase attack at 25 degrees C and 35 degrees C as judged by the production of specific products that corresponded closely with those produced by collagenase. Although synovial collagenase failed to degrade collagen types IX and XI, all the cartilage collagen species examined were degraded at 35 degrees C by conditioned culture medium from IL1-activated human articular chondrocytes. Thus chondrocytes have the potential to catabolise each cartilage collagen species, but the specificity and number of the chondrocyte-derived collagenase(s) has yet to be resolved.     

Binding of latent rheumatoid synovial collagenase to collagen fibrils.

Collagenase released from rheumatoid synovial cells in culture is in a latent form. Subsequently, it may be activated by limited proteolysis. This study was designed to determine whether latent enzyme could bind to collagen fibrils and await activation. The data showed that latent collagenase bound to fibrils equally well at 24 degrees C and 37 degrees C, but that this represented little more than half the binding achieved by active enzyme at temperatures lower than that at which fibrils can be degraded. Binding was not inhibited by the presence of alpha2 macroglobulin, the principal proteinase inhibitor of plasma which cannot complex with inactive or latent collagenase but readily complexes with active species of enzyme. The data support the hypotheses that inactive forms of collagenase accumulate in tissues by binding to substrate, and that activation by proteases such as plasmin initiates collagen breakdown.     

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.     

Accurate, quantitative assays for the hydrolysis of soluble type I, II, and III 3H-acetylated collagens by bacterial and tissue collagenases

Accurate and quantitative assays for the hydrolysis of soluble 3H-acetylated rat tendon type I, bovine cartilage type II, and human amnion type III collagens by both bacterial and tissue collagenases have been developed. The assays are carried out at any temperature in the 1-30 degrees C range in a single reaction tube and the progress of the reaction is monitored by withdrawing aliquots as a function of time, quenching with 1,10-phenanthroline, and quantitation of the concentration of hydrolysis fragments. The latter is achieved by selective denaturation of these fragments by incubation under conditions described in the previous paper of this issue. The assays give percentages of hydrolysis of all three collagen types by neutrophil collagenase that agree well with the results of gel electrophoresis experiments. The initial rates of hydrolysis of all three collagens are proportional to the concentration of both neutrophil or Clostridial collagenases over a 10-fold range of enzyme concentrations. All three assays can be carried out at collagen concentrations. that range from 0.06 to 2 mg/ml and give linear double reciprocal plots for both tissue and bacterial collagenases that can be used to evaluate the kinetic parameters Km and kcat or Vmax. The assay developed for the hydrolysis of rat type I collagen by neutrophil collagenase is shown to be more sensitive by at least one order of magnitude than comparable assays that use rat type I collagen fibrils or gels as substrate.     

Constituents of connective tissue around the capillary of chick pecten oculi

The constituents of the connective tissues around the capillary of the chick pecten oculi were examined electron microscopically by HCl-collagenase and HCl-elastase methods. The basal lamina like membrane below the endothelial cell of the pecten capillary was digested by collagenases I, II and IV and elastase, and may be a false basal lamina. The basal lamina of cells with pigment granules which surround the capillary was digested by collagenase IV and elastase, and contained type IV collagen. Fibrils between the basal lamina like membrane of the pecten capillary endothelium and the basal lamina of the cells with pigment granules were digested by collagenases I, II and IV, and elastase. Thus, these fibrils are composed of many kinds of collagen. Elastase may be responsible for the breakdown of most collagens as well as elastin.     

Properties of a collagenolytic enzyme from Bipalium kewense

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

Solar Ultraviolet Irradiation Induces Decorin Degradation in Human Skin Likely via Neutrophil Elastase

Exposure of human skin to solar ultraviolet (UV) irradiation induces matrix metalloproteinase-1 (MMP-1) activity, which degrades type I collagen fibrils. Type I collagen is the most abundant protein in skin and constitutes the majority of skin connective tissue (dermis). Degradation of collagen fibrils impairs the structure and function of skin that characterize skin aging. Decorin is the predominant proteoglycan in human dermis. In model systems, decorin binds to and protects type I collagen fibrils from proteolytic degradation by enzymes such as MMP-1. Little is known regarding alterations of decorin in response to UV irradiation. We found that solar-simulated UV irradiation of human skin in vivo stimulated substantial decorin degradation, with kinetics similar to infiltration of polymorphonuclear (PMN) cells. Proteases that were released from isolated PMN cells degraded decorin in vitro. A highly selective inhibitor of neutrophil elastase blocked decorin breakdown by proteases released from PMN cells. Furthermore, purified neutrophil elastase cleaved decorin in vitro and generated fragments with similar molecular weights as those resulting from protease activity released from PMN cells, and as observed in UV-irradiated human skin. Cleavage of decorin by neutrophil elastase significantly augmented fragmentation of type I collagen fibrils by MMP-1. Taken together, these data indicate that PMN cell proteases, especially neutrophil elastase, degrade decorin, and this degradation renders collagen fibrils more susceptible to MMP-1 cleavage. These data identify decorin degradation and neutrophil elastase as potential therapeutic targets for mitigating sun exposure-induced collagen fibril degradation in human skin.     

Some newly characterized collagenases from procaryotes and lower eucaryotes

Summary Chemical and enzymatic properties of four collagenases newly isolated from anaerobic Clostridium histolyticum, aerobic Achromobacter iophagus, and from two lower eucaryotes, the fungus Entomophthora coronata and the insect Hypoderma lineatum are reviewed.The problems of their biosynthesis and precursors, namely the effect of induction of collagenase and neutral proteinase in Achromobacter by their macromolecular substrates are discussed.The two bacterial collagenases are Zn-metallo-enzymes; the highly purified Clostridium collagenase contains cyst(e)ine, serine phosphate and tryptophan additionally to amino acids reported previously. Achromobacter collagenase has the highest specific activity of all collagenases; it yields by autolysis enzymatically active degraded forms. The active dimer is composed of two identical subunits of molecular weight 35,000. Similarities between Achromobacter collagenase, thermolysin and Bacillus subtilis neutral proteinase in molecular weight, amino acid composition, and amino acids important for the active sites are discussed.The two collagenases from low eucaryotes are serine proteinases; Hypoderma collagenase is homologous to the trypsin family in the amino terminal sequence.The initial cleavage of native collagen by highly purified bacterial collagenases occurs in the central helical part of the a chains and not progressively from the amino terminal end. One of the two initial cleavages produced by Achromobacter collagenase is situated in the region cleaved specifically by vertebrate collagenases, but with different bond specificity. The same is true for the insect collagenase. Entomophthora collagenase is a proteinase of broad specificity which also cleaves collagen in its helical parts. All four collagenases also degrade other proteins according to their bond specificity.     

A convenient fluorescent assay for vertebrate collagenases

A versatile, convenient assay for vertebrate collagenases has been developed using the fluorescent peptide substrate dansyl-Pro-Gln-Gly-Ile-Ala-Gly-D-Arg. This sequence resembles that of collagen at the site of cleavage but includes modifications designed to eliminate nonspecific hydrolysis by contaminating peptidases. Both human skin fibroblast and bovine corneal cell collagenases cleave the substrate specifically at the Gly-Ile bond. Plasmin, thrombin, trypsin, alpha-chymotrypsin, carboxypeptidase B, and bacterial collagenase do not cleave the substrate. Elastase and angiotensin converting enzyme display 20- and 400-fold less activity than the vertebrate collagenases, respectively, and cleave the peptide at different positions. The assay is performed by incubating a 5- to 25-microliters aliquot of trypsin-activated sample with an equal volume of 2 mM substrate overnight at 33 degrees C and pH 7.5. Thin-layer chromatography then separates the fluorescent product from the substrate in less than 20 min and allows the detection of subnanogram levels of collagenase. The assay is applicable to the screening of large numbers of samples under different conditions of pH and ionic strength and is readily adaptable for use in a variety of collagenase-dependent systems, such as assays for collagenase activating and/or inducing factors.     

Specificity of the collagenase from the insect Hypoderma lineatum

Specificity of the collagenase from the larvae Hypoderma lineatum, a serine protease related to trypsin, has been investigated by using native collagen and non-collagenous substrates. At 25 degrees C and neutral pH the degradation of collagen by the larval enzyme in solution results in a 52% loss of specific viscosity, without loss of helicity. Electron microscopy of segment-long-spacing crystallites of the digest shows the occurrence of one cleavage region between bands 41 and 44 whereas Edman degradation indicates several cleavage loci in this region. Hypoderma collagenase differs from proteinases I and II from the crab Uca pugilator, which catalyse cleavages in multiple regions of the collagen molecule, and also from vertebrate collagenases, which cleave collagen only between residues 775 and 776. Apart of specific action on collagen, Hypoderma collagenase degrades the oxidized chain B of insulin; the major cleavage occurs at the Leu15-Tyr16 bond followed by two minor cleavages at the Arg22-Gly23 and Lys29-Ala30 bonds. The larval enzyme has no action on synthetic peptide substrates of trypsin or chymotrypsin.     

Formation of tight junctions in epithelial cells. I. Induction by proteases in a human colon carcinoma cell line

The experimental modulation of tight junctions (TJ) was studied in the human adenocarcinoma cell line HT 29 by freeze-fracture electron microscopy. The cell line has virtually no TJ when grown in culture. TJ could be induced by mild treatment with a variety of endopeptidases (trypsin, chymotrypsin, collagenase, elastase, plasmin, thrombin, papain, and pronase). Pronase induced the formation of TJ at low (but not at high) concentrations. All exopeptidases studied were unable to induce the formation of TJ. At 0 degree C the trypsin-induced formation of TJ was greatly slowed down although not entirely inhibited. However, when cells were briefly treated with trypsin at 0 degree C and subsequently transferred to 37 degrees C in the presence of protease inhibitors, TJ were rapidly assembled. Thus an induction phase at low temperature and an assembly phase at high temperature could be experimentally separated. When cells were briefly trypsinized at 0 degrees and subsequently kept at 0 degree C without trypsin for several hours, TJ still formed abundantly upon incubation at 37 degrees C. It appears therefore that the effect produced by the protease is retained for long periods in the cold.     

Studies on the activation energy and deuterium isotope effect of human skin collagenase on homologous collagen substrates

The activation energy (EA) and solvent-deuterium kinetic isotope effect (kH/kD) of human skin fibroblast collagenase were studied on the homologous human type I, II, and III collagens in both native and denatured states. Values for EA on human type I and II collagens in solution were 47,000 and 61,000 cal, respectively. The Arrhenius plot for type III collagen, unlike that for the other types, was characterized by a break in EA at approximately 26 degrees C. At temperatures below this point, EA was 42,500 cal; at higher temperatures, EA fell to 29,500 cal. This latter value, intermediate between type I collagen monomers and denatured random gelatin alpha chains, appears to result from a further opening in the already loosened helix of the type III collagen molecule in the region of the 3/4:1/4 collagenase cleavage site. The EA of trypsin on native human type III collagen was also measured and found to be 70,000 cal. This high value calls into question the role of serine proteases in the physiologic degradation of this substrate; a much higher energy expenditure was required for trypsin to cleave type III collagen than for the fibroblast collagenase. Reaction velocity on human collagen types I-III in solution was slowed 15-35% (kH/kD = 1.2-1.5) by the substitution of deuterium for hydrogen in the solvent buffer. This value was far lower than that observed following the aggregation of solution monomers into insoluble fibrils (kH/kD = 9). Denaturation of triple helical monomers into random gelatin alpha chains eliminated any slowing by deuterium, and kH/kD was 1.0 in all cases. Since the same peptide bond hydrolysis accompanies the cleavage of all these forms of the collagen substrate, it would appear that the role of water at the rate-limiting step of collagen degradation may not reside in the hydrolysis of a peptide bond per se, but rather may reflect the difficulty in transporting water molecules to the site of such catalysis, especially following fibril aggregation.     

Collagen dissolution by keratinocytes requires cell surface plasminogen activation and matrix metalloproteinase activity

Matrix metalloproteinase-14 is required for degradation of fibrillar collagen by mesenchymal cells. Here we show that keratinocytes use an alternative plasminogen and matrix metalloproteinase-13-dependent pathway for dissolution of collagen fibrils. Primary keratinocytes displayed an absolute requirement for serum to dissolve collagen. Dissolution of collagen was abolished in plasminogen-depleted serum and could be restored by the exogenous addition of plasminogen. Both plasminogen activator inhibitor-1 and tissue inhibitor of metalloproteinase blocked collagen dissolution, demonstrating the requirement of both plasminogen activation and matrix metalloproteinase activity for degradation. Cell surface plasmin activity was critical for the degradation process as aprotinin, but not alpha(2)-antiplasmin, prevented collagen dissolution. Keratinocytes with single deficiencies in either urokinase or tissue plasminogen activator retained the ability to dissolve collagen. However, collagen fibril dissolution was abolished in keratinocytes with a combined deficiency in both urokinase and tissue plasminogen activator. Combined, but not single, urokinase and tissue plasminogen activator deficiency also completely blocked the activation of the fibrillar collagenase, matrix metalloproteinase-13, by keratinocytes. The activation of matrix metalloproteinase-13 in normal keratinocytes was prevented by plasminogen activator inhibitor-1 and aprotinin but not by tissue inhibitor of metalloproteinase-1 and -2, suggesting that plasmin activates matrix metalloproteinase-13 directly. We propose that plasminogen activation facilitates keratinocyte-mediated collagen breakdown via the direct activation of matrix metalloproteinase-13 and possibly other fibrillar collagenases.