To understand the biologic function of TIMP-2, a member of the tissue inhibitors of metalloproteinases family, an inactivating mutation was introduced in the mouse Timp-2 gene by homologous recombination. Outbred homozygous mutants developed and procreated indistinguishably from wild type littermates, suggesting that fertility, development, and growth are not critically dependent on TIMP-2. Lack of functional TIMP-2, however, dramatically altered the activation of proMMP-2 both in vivo and in vitro. Fully functional TIMP-2 is essential for efficient activation of proMMP-2 in vivo. No evidence of successful functional compensation was observed. The results illustrate the duality of TIMP-2 function, i.e. at low concentrations, TIMP-2 exerts a "catalytic" or enhancing effect on cell-mediated proMMP-2 activation, whereas at higher concentrations, TIMP-2 inhibits the activation and/or activity of MMP-2.
Tissue inhibitor of metalloproteinase-I (TIMP-1) is a slow, tight-binding inhibitor of fibroblast-type collagenase. Time-course data from inhibition experiments were analyzed by graphic analysis, by nonlinear regression of the analytic integrals of the rate equations and by nonlinear regression with numeric integration of the rate equations. With the same assumptions, approximations and data, all three methods of analysis produced the same model preferences and values for the kinetic parameters. The time-course data for the inhibition of fibroblast-type collagenase by TIMP-1 are best described by the equations for a noncompetitive two-step mechanism, in which an inactive, rapidly formed, reversible complex slowly forms an inactive, tight complex. However, from the analysis of data from experiments at concentrations of TIMP-1 comparable to that of collagenase, it is apparent that free TIMP-1 also functions in the breakdown of the tight complex. The rapidly formed complex has a dissociation constant of 8 nM and reacts to the tight complex with a first-order rate constant of 0.003 s-1. The back reaction of the tight complex to the rapid complex has a second-order rate constant of 5 x 10(4) M-1 s-1. The resulting global dissociation constant of the tight complex is 0.1 nM at 3 nM TIMP-1 and collagenase concentration. Collagenase without the carboxyl-terminal domain (mini-collagenase) is inhibited by TIMP-1 according to a mechanism, in which the rapidly formed complex has such a high dissociation constant (247 nM) that it effectively constitutes a one-step mechanism, in which TIMP-1 binds with an apparent second-order rate constant of 9.6 x 10(4) mol-1 s-1 and the enzyme-TIMP-1 complex dissociates with a first order rate constant of 0.00026 s-1. The apparent global dissociation constant for the tight complex (2.7 nM) is higher than that for the fibroblast-type collagenase. Participation of TIMP-1 in the dissociation is not demonstrable. Therefore, the carboxyl-terminal domain of fibroblast-type collagenase is important for the initial, rapid binding of TIMP-1 and the initial complex contributes to the overall binding.
Tissue inhibitor of metalloproteinases-1 (TIMP-1) is resistant to extremes of temperature and pH. This is thought to be due in part to the presence of six sulfhydryl bridges presumed to maintain the structural integrity of the molecule. As part of a study looking at structure-function relationships, a number of the conserved cysteine residues in TIMP-1 were targeted for replacement with serine. Single and double replacements of these conserved cysteines, as well as replacements around these cysteines, were expressed using a vaccinia virus system and analyzed for functional and structural competence. Analysis by circular dichroism indicated that these mutants maintained secondary structures similar to those of wild-type TIMP-1. Trypsin susceptibility experiments indicated that the tertiary structure of the mutants had not been drastically changed. Analysis of functional competence demonstrated that there were significant changes in some of these mutants. Assays using collagen fibrils or gelatin as substrates indicated that the double mutant C1S/C70S, but not C3S/ C99S, had lost inhibitory activity against human fibroblast-type collagenase (FIB-CL) and at high concentrations only had slight activity against M r 72,000 gelatinase (M r 72,000 gelatinase). Kinetic analysis of TIMP-1 inhibition of FIB-CL cleavage of a peptide substrate indicated that mutants C1S/C70S, C3S/C99S, and CEEC 3 CQQC retained their ability to inhibit FIB-CL in a manner similar to wild-type TIMP-1, while mutants C1S and C70S showed little inhibitory activity. The mutants C99S and C137S could also inhibit FIB-CL cleavage of the peptide substrate. The results indicated that the degree of inhibition by the TIMP-1 mutants varied somewhat depending on the choice of substrates. Interestingly, replacing both cysteines from a disulfide bond in the wild-type molecule resulted in a more competent inhibitor than either of the single site "parent" mutations. Taken together, these experiments indicate that TIMP-1 can be rendered inactive by the loss of a single cysteine.
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