The specificity of TIMP-2 for matrix metalloproteinases can be modified by single amino acid mutations.

Residues 1-127 of human TIMP-2 (N-TIMP-2), comprising three of the disulfide-bonded loops of the TIMP-2 molecule, is a discrete protein domain that folds independently of the C-terminal domain. This domain has been shown to be necessary and sufficient for metalloproteinase inhibition and contains the major sites of interaction with the catalytic N-terminal domain of active matrix metalloproteinases (MMPs). Residues identified as being involved in the interaction with MMPs by NMR chemical shift perturbation studies and TIMP/MMP crystal structures have been altered by site-directed mutagenesis. We show, by measurement of association rates and apparent inhibition constants, that the specificity of these N-TIMP-2 mutants for a range of MMPs can be altered by single site mutations in either the TIMP "ridge" (Cys1-Cys3 and Ser68-Cys72) or the flexible AB loop (Ser31-Ile41). This work demonstrates that it is possible to engineer TIMPs with altered specificity and suggests that this form of protein engineering may be useful in the treatment of diseases such as arthritis and cancer where the selective inhibition of key MMPs is desirable.

Human tissue inhibitor of metalloproteinases 3 interacts with both the N- and C-terminal domains of gelatinases A and B. Regulation by polyanions.

We compared the association constants of tissue inhibitor of metalloproteinases (TIMP)-3 with various matrix metalloproteinases with those for TIMP-1 and TIMP-2 using a continuous assay. TIMP-3 behaved more like TIMP-2 than TIMP-1, showing rapid association with gelatinases A and B. Experiments with the N-terminal domain of gelatinase A, the isolated C-terminal domain, or an inactive progelatinase A mutant showed that the hemopexin domain of gelatinase A makes an important contribution to the interaction with TIMP-3. The exchange of portions of the gelatinase A hemopexin domain with that of stromelysin revealed that residues 568-631 of gelatinase A were required for rapid association with TIMP-3. The N-terminal domain of gelatinase B alone also showed slower association with TIMP-3, again implying significant C-domain interactions. The isolation of complexes between TIMP-3 and progelatinases A and B on gelatin-agarose demonstrated that TIMP-3 binds to both proenzymes. We analyzed the effect of various polyanions on the inhibitory activity of TIMP-3 in our soluble assay. The association rate was increased by dextran sulfate, heparin, and heparan sulfate, but not by dermatan sulfate or hyaluronic acid. Because TIMP-3 is sequestered in the extracellular matrix, the presence of certain heparan sulfate proteoglycans could enhance its inhibitory capacity.

Kinetic analysis of the mechanism of interaction of full-length TIMP-2 and gelatinase A: evidence for the existence of a low-affinity intermediate.

We have undertaken a detailed analysis of the mechanism of inhibition of matrix metalloproteinase-2 (gelatinase A) by tissue inhibitor of metalloproteinase-2 (TIMP-2). Quenched fluorescent substrates have been used to analyze the rate of inhibition of gelatinase A by TIMP-2 over a wide range of TIMP-2 concentrations. When the values of the observed rate constant for the inhibition are plotted against TIMP-2 concentration, saturation is observed at high concentrations, providing evidence for formation of an intermediate in the pathway. Rate constants for the formation and dissociation of the intermediate are 5.9 x 10(6) M-1 s-1 and 6.3 s-1 respectively, giving a Ki for the initial step of approximately 1 microM. The rate constant for the association of the final complex is 33 s-1. By studying the dissociation of 125I-labeled TIMP-2 from a gelatinase A-TIMP-2 complex using ligand exchange experiments, we obtained a rate constant for the dissociation of the final stable complex of 2 x 10(-)8 s-1. This gives a value for the overall dissociation constant of approximately 0.6 fM.

Evidence for the importance of weakly bound water for matrix metalloproteinase activity.

The effects of organic cosolvents on the kinetic characteristics of two matrix metalloproteinases, gelatinase A and stromelysin 1, were investigated. In each case, addition of the cosolvent resulted in a decrease in the apparent kcat/Km for the catalyzed hydrolysis of fluorogenic peptide substrates. Two factors were identified as being responsible for this decrease in catalytic activity: hydrophobic partitioning of the substrate in favor of the bulk solvent and decrease in the water content of the enzyme. The former reflects the hydrophobic nature of the enzyme-substrate interaction and the effect can be corrected for by using the solvent to water partition coefficient of the substrate in the mixed solvent systems. The catalyzed hydrolysis of substrate, corrected for the effect of hydrophobic partitioning, was demonstrated to be sixth order in water for gelatinase A and third order in water for stromelysin 1. Variation in water concentration did not produce saturation even at concentrations close to 55.5 M. The results indicate that weakly bound water molecules are essential to mediate the interaction between substrate and enzyme. The sensitivity of these enzymes to water concentration could be an important mechanism for regulating catalytic activity in vivo.

The second zinc atom in the matrix metalloproteinase catalytic domain is absent in the full-length enzymes: a possible role for the C-terminal domain.

Domain deletion mutants of the matrix metalloproteinases consisting of the catalytic domain only contain two zinc atoms per molecule. One is essential for catalysis, while the other may fulfil a structural role. We have analysed the zinc contents of both the full-length and the truncated mutants of prostromelysin-1 and progelatinase A and report that the second zinc atom is not present in the full-length form of the proenzymes. Thus it seems likely that the role proposed for this zinc atom in maintaining the structure of the enzyme catalytic domain is performed by the C-terminal domain in the full-length enzyme.

Structure-function relationships in the tissue inhibitors of metalloproteinases.

The tissue inhibitors of metalloproteinases (TIMPs) are proteins that specifically inhibit the matrix metalloproteinases. They consist of two distinct structural and functional domains. In order to elucidate the role of these domains, we have prepared mutants of TIMP-1 and TIMP-2 that lack a C-terminal domain. The N-terminal domain alone is an efficient inhibitor of all the matrix metalloproteinases through interaction with the enzyme catalytic domain. The C-terminal domain has at least two separate enzyme binding sites, one for gelatinase A and the other for stromelysin-1. The rate of inhibition of either enzyme is increased by interaction with the TIMP C-terminal domain. As no conformational change is observed, we propose that the rate enhancement is due to an anchoring effect in which binding of the TIMP C-terminal domain aligns the TIMP N-terminal domain with the enzyme active site. Site-directed mutagenesis of TIMP-1 has demonstrated that the N-terminal amino acids, His7 and Gln9, are important for inhibition.

Analysis of the role of the COOH-terminal domain in the activation, proteolytic activity, and tissue inhibitor of metalloproteinase interactions of gelatinase B.

Recombinant human progelatinase B and a COOH terminally truncated version, pro-delta426-688 gelatinase B have been prepared from a myeloma cell expression system. Both proenzymes could be processed to active forms by stromelysin-1 to give an NH2 terminus of Phe88, or by treatment with 4-aminophenylmercuric acetate resulting in an NH2-terminal Met75. The kinetics of activation using either treatment was not affected by removal of the enzyme COOH-terminal domain. The specific activities of both gelatinase B and delta426-688 gelatinase B, activated using either method, were found to be similar using either a quenched fluorescent peptide or gelatin as the substrate. Fibroblast monolayers were shown to mediate processing of both progelatinases at similar rates in the presence of either plasminogen or prostromelysin-1. Active wild-type gelatinase B was inhibited by tissue inhibitor of metalloproteinase (TIMP) -1 at a much faster rate than TIMP-2. COOH-terminal truncation of either enzyme or inhibitor gave a marked reduction in the rate constant for TIMP-1 inhibition but had no effect on the rate of TIMP-2 binding. It can be concluded that the COOH-terminal domain of progelatinase B is not involved in autolytic or cellular activation and does not affect the catalytic activity of the enzyme. However, COOH-terminal domain interactions between active gelatinase B and TIMP-1 significantly enhance the rate of complex formation.

Mutation of the active site glutamic acid of human gelatinase A: effects on latency, catalysis, and the binding of tissue inhibitor of metalloproteinases-1.

Human gelatinase A, a member of the matrix metalloproteinase family, is secreted from cells as the M(r) 72,000 latent precursor, progelatinase A. The autolytic removal of an N-terminal propeptide generates the M(r) 66,000 active form. Mutants of recombinant progelatinase A, altered such that the proposed active site glutamic acid residue (E375) was replaced by either an aspartic acid (proE375-->D), an alanine (proE375-->A) or a glutamine (proE375-->Q), were purified from medium conditioned by transfected NS0 mouse myeloma cells. Like wild-type progelatinase A, the mutant proenzymes were inactive and could bind tissue inhibitor of metalloproteinases (TIMP)-2 but not TIMP-1 to their C-terminal domains. Their rates of autolytic processing induced by the organomercurial (4-aminophenyl) mercuric acetate, however, were markedly slower and, of the three M(r) 66,000 forms so produced, only E375-->D displayed any proteolytic activity against either a synthetic substrate (kcat/Km = 10% that of the wild-type enzyme) or denatured type I collagen (specific activity = 0.9% that of the wild-type enzyme). ProE375-->A and proE375-->Q could be more rapidly processed to their M(r) 66,000 forms by incubation with a deletion mutant of gelatinase A that has full catalytic activity but lacks the C-terminal domain [delta (418-631) gelatinase A]. These two M(r) 66,000 forms displayed low activity on a gelatin zymogram (approximately 0.01% that of the wild-type enzyme) but, like E375-->D were able to bind TIMP-1 with an affinity equal to that of the activated wild-type enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Assessment of the role of the fibronectin-like domain of gelatinase A by analysis of a deletion mutant.

The properties of a deletion mutant delta V191-Q364 of gelatinase A, which represents the removal of the fibronectin-like type II repeats defined by exons 5-7, were compared with those of full-length gelatinase A. Both enzymes underwent self-activation over a similar time course in the presence of 4-aminophenylmercuric acetate. The fully active enzymes had similar kcat/Km values for the cleavage of an octapeptide substrate, but the deletion mutant had 50% of the activity of wild type gelatinase A against beta-casein and 10% of the activity against gelatin. The cleavage pattern for gelatin was similar for both enzymes but differed for type IV collagen. Comparison of the rates of association of the tissue inhibitors of metalloproteinase (TIMP)-1 and TIMP-2 and their N-terminal domains to both forms of gelatinase indicated that the fibronectin-like domain plays little role in TIMP binding. The deletion mutant failed to bind to collagen, while the wild type gelatinase bound tightly, indicating that the fibronectin-like domain is the sole site of collagen binding. Both gelatinases could be activated by concanavalin A-activated fibroblasts, suggesting that the fibronectin-like domain is not required for the membrane-mediated activation process.

Different domain interactions are involved in the binding of tissue inhibitors of metalloproteinases to stromelysin-1 and gelatinase A.

The matrix metalloproteinases gelatinase A and stromelysin-1 have definable N-terminal (catalytic) and C-terminal domains. In order to analyze their interactions with the N- and C-terminal domains of the tissue inhibitors of metalloproteinases TIMP-1 and -2, mutants of both the enzymes and the inhibitors were prepared in which the C-terminal domains had been deleted. Since the Ki values for TIMP inhibition of the matrix metalloproteinases are in the picomolar range, it was not possible to measure these accurately within the sensitivity of available activity assays. Rate constants for the association of the wild-type proteins were therefore determined and systematically compared with those for the deletion mutants. It was found that TIMP-1 binds more rapidly than TIMP-2 to stromelysin-1 and that the C-terminal domain of the enzyme does not affect the rate of association of enzyme and inhibitor. This is in contrast to gelatinase A, where the C-terminal domain has been shown to play an important role in increasing the rate of complex formation with the TIMPs (Willenbrock et al., 1993). The TIMPs are also comprised of an N- and C-terminal domain. By deletion mutagenesis, we found that the C-terminal domain of both TIMPs contributed less to the rate of complex formation with stromelysin-1 than to that with gelatinase A. Hybrids of the N- and C-terminal domains of gelatinase A and stromelysin-1 were prepared and used to analyze further the differences in domain interactions with the TIMPs. They demonstrated that the interactions between the C-terminal domains of enzyme and inhibitor can occur irrespective of the nature of the N-terminal domain. We can conclude that the TIMPs have two major binding regions which associate in different ways with the domains of the enzymes gelatinase A and stromelysin-1. The N-terminal domains of the TIMPs bind to the enzyme catalytic domains to inhibit activity. The TIMP C-terminal domain acts to increase the association rate constant by binding to the N-terminal domain of stromelysin or the C-terminal domain of gelatinase A.

The activity of the tissue inhibitors of metalloproteinases is regulated by C-terminal domain interactions: a kinetic analysis of the inhibition of gelatinase A.

The cloning and expression of the full-length tissue inhibitor of metalloproteinase 2 (TIMP-2), delta 187-194TIMP-2, and delta 128-194TIMP-2 and the purification of these inhibitors and a cleaved version of TIMP-2 lacking nine C-terminal amino acids (delta 186-194TIMP-2) are described. The mechanism of inhibition of gelatinase A by the TIMPs was investigated by comparing the kinetics of association of TIMP-1, TIMP-2, the C-terminal deletions, and the mutants of both TIMPs which consisted of the N-terminal domain only. The full-length TIMPs inhibited gelatinase A rapidly with association constants of 3.2 x 10(6) M-1 s-1 for TIMP-1 and 2.1 x 10(7) M-1 s-1 for TIMP-2 at I = 0.2. The C-terminal peptide of TIMP-2 is proposed to exist as an exposed "tail" responsible for binding to progelatinase A and for increasing the rate of inhibition of active gelatinase A through electrostatic interactions with the C-terminal domain of the enzyme. The C-terminal domains of both TIMP-1 and TIMP-2 participate in low-affinity interactions with the C-terminal domain of gelatinase A which increase the rate of association by a factor of about 100 in both cases.

Site-directed mutations that alter the inhibitory activity of the tissue inhibitor of metalloproteinases-1: importance of the N-terminal region between cysteine 3 and cysteine 13.

The tissue inhibitor of metalloproteinases-1 (TIMP-1) was subjected to single-site mutations within the N-terminal three loops using an oligonucleotide-directed polymerase chain reaction method. All the histidines, and a number of other residues conserved between TIMP-1 and TIMP-2, were individually modified and the mutant TIMPs expressed in mammalian cells. Purified mutant TIMPs were shown to be correctly folded by measuring the effect of guanidine hydrochloride on intrinsic fluorescence. Kinetic analyses of mutants using a quenched fluorescent peptide substrate and the metalloproteinase PUMP indicated that mutation of His7 and Gln9 caused an increase in the apparent dissociation constant, largely due to an increase in the rate of dissociation of complexes. The data indicate that the anchored sequence between Cys 3 and Cys 13 is a key region for interaction of TIMP-1 with metalloproteinases.

Biochemical characterization of matrilysin. Activation conforms to the stepwise mechanisms proposed for other matrix metalloproteinases.

The latent precursor of matrilysin (EC 3.4.24.23; punctuated metalloproteinase (PUMP) was purified from transfected mouse myeloma cell conditioned medium and was found to contain one zinc atom per molecule which was essential for catalytic activity. Promatrilysin could be activated to the same specific activity by (4-aminophenyl)mercuric acetate, trypsin, and incubation at elevated temperatures (heat activation). Active matrilysin hydrolyzed the fluorescent substrate 2,4-dinitrophenyl-Pro-Leu-Gly-Leu-Trp-Ala-D-Arg-NH2 at the Gly-Leu bond with a maximum value for kcat/Km of 1.3 x 10(4) M-1 s-1 at the pH optimum of 6.5 and pKa values of 4.60 and 8.65. Activity is inhibited by the tissue inhibitor of metalloproteinases-1 in a 1:1 stoichiometric interaction. Analysis by sodium dodecyl sulfate polyacrylamide gel electrophoresis in conjunction with N-terminal sequencing revealed that, as with all other matrix metalloproteinases similarly studied, promatrilysin activation was accompanied by the stepwise proteolytic removal of an M(r) 9000 propeptide from the N-terminus. The intermediates generated were dependent on the mode of activation used but, in all cases studied, activation terminated with an autocatalytic cleavage at E77-Y78 to yield the final M(r) 19,000 active matrilysin. From an analysis of the stability of the various intermediates, we propose that the sequence L13-K33 is particularly important in protecting the E77-Y78 site from autocatalytic cleavage, thereby maintaining the latency of the proenzyme.

The C-terminal domain of 72 kDa gelatinase A is not required for catalysis, but is essential for membrane activation and modulates interactions with tissue inhibitors of metalloproteinases.

Recombinant 72 kDa gelatinase A and a truncated form lacking the C-terminal domain were shown to be activated by organomercurials and to possess similar activities towards a number of substrates. The truncated proenzyme differed from the full-length gelatinase in that it could not be activated by a membrane activator and did not bind tissue inhibitor of metalloproteinase (TIMP)-2. Kinetic studies also showed that the inhibition of the activated truncated enzyme, by both TIMP-1 and TIMP-2, was considerably decreased compared with the full-length enzyme. We conclude that the C-terminal domain plays an important role in the regulation of gelatinase A by a potential physiological activator and inhibitors.

The role of the C-terminal domain in collagenase and stromelysin specificity.

Recombinant human interstitial collagenase, an N-terminal truncated form, delta 243-450 collagenase, recombinant human stromelysin-1, and an N-terminal truncated form, delta 248-460 stromelysin, have been stably expressed in myeloma cells and purified. The truncated enzymes were similar in properties to their wild-type counterparts with respect to activation requirements and the ability to degrade casein, gelatin, and a peptide substrate, but truncated collagenase failed to cleave native collagen. Removal of the C-terminal domain from collagenase also modified its interaction with tissue inhibitor of metalloproteinases-1. Hybrid enzymes consisting of N-terminal (1-242) collagenase.C-terminal (248-460) stromelysin and N-terminal (1-233) stromelysin.C-terminal (229-450) collagenase, representing an exchange of the complete catalytic and C-terminal domains of the two enzymes, were expressed in a transient system using Chinese hamster ovary cells and purified. Both proteins showed similar activity to their N-terminal parent and neither was able to degrade collagen. Analysis of the ability of the different forms of recombinant enzyme to bind to collagen by ELISA showed that both pro and active stromelysin and N-terminal collagenase.C-terminal stromelysin bound to collagen equally well. In contrast, only the active forms of collagenase and N-terminal stromelysin.C-terminal collagenase bound well to collagen, as compared with their pro forms.