Structural basis for matrix metalloproteinase-2 (MMP-2)-selective inhibitory action of β-amyloid precursor protein-derived inhibitor

Unlike other synthetic or physiological inhibitors for matrix metalloproteinases (MMPs), the β-amyloid precursor protein-derived inhibitory peptide (APP-IP) having an ISYGNDALMP sequence has a high selectivity toward MMP-2. Our previous study identified amino acid residues of MMP-2 essential for its selective inhibition by APP-IP and demonstrated that the N to C direction of the decapeptide inhibitor relative to the substrate-binding cleft of MMP-2 is opposite that of substrate. However, detailed interactions between the two molecules remained to be clarified. Here, we determined the crystal structure of the catalytic domain of MMP-2 in complex with APP-IP. We found that APP-IP in the complex is indeed embedded into the substrate-binding cleft of the catalytic domain in the N to C direction opposite that of substrate. With the crystal structure, it was first clarified that the aromatic side chain of Tyr(3) of the inhibitor is accommodated into the S1' pocket of the protease, and the carboxylate group of Asp(6) of APP-IP coordinates bidentately to the catalytic zinc of the enzyme. The Ala(7) to Pro(10) and Tyr(3) to Ile(1) strands of the inhibitor extend into the nonprime and the prime sides of the cleft, respectively. Therefore, the decapeptide inhibitor has long range contact with the substrate-binding cleft of the protease. This mode of interaction is probably essential for the high MMP-2 selectivity of the inhibitor because MMPs share a common architecture in the vicinity of the catalytic center, but whole structures of their substrate-binding clefts have sufficient variety for the inhibitor to distinguish MMP-2 from other MMPs.     

Crystal structure of human macrophage elastase (MMP-12) in complex with a hydroxamic acid inhibitor

Human macrophage elastase (MMP-12) is a member of the family of matrix metalloproteinases (MMPs) that plays, like other members of the family, an important role in inflammatory processes contributing to tissue remodelling and destruction. In particular, a prominent role of MMP-12 in the destruction of elastin in the lung alveolar wall and the pathogenesis of emphysema has been suggested. It is therefore an attractive therapeutic target. We describe here the crystal structure of the catalytic domain of MMP-12 in complex with a hydroxamic acid inhibitor, CGS27023A. MMP-12 adopts the typical MMP fold and binds a structural zinc ion and three calcium ions in addition to the catalytic zinc ion. The enzyme structure shows an ordered N terminus close to the active site that is identical in conformation with the superactivated form of MMP-8. The S1'-specificity pocket is large and extends into a channel through the protein, which puts MMP-12 into the class of MMPs 3, 8 and 13 with large and open specificity pockets. The two crystallographically independent molecules adopt different conformations of the S1'-loop and its neighbouring loop due to differing crystal packing environments, suggesting that flexibility or the possibility of structural adjustments of these loop segments are intrinsic features of the MMP-12 structure and probably a common feature for all MMPs. The inhibitor binds in a bidentate fashion to the catalytic zinc ion. Its polar groups form hydrogen bonds in a substrate-like manner with beta-strand sIV of the enzyme, while the hydrophobic substituents are either positioned on the protein surface and are solvent-exposed or fill the upper part of the specificity pocket. The present structure enables us to aid the design of potent and selective inhibitors for MMP-12.     

Substrate specificity determinants of human macrophage elastase (MMP-12) based on the 1.1 A crystal structure

The macrophage elastase enzyme (MMP-12) expressed mainly in alveolar macrophages has been identified in the mouse lung as the main destructive agent associated with cigarette smoking, which gives rise to emphysema, both directly via elastin degradation and indirectly by disturbing the proteinase/antiproteinase balance via inactivation of the alpha1-proteinase inhibitor (alpha1-PI), the antagonist of the leukocyte elastase. The catalytic domain of human recombinant MMP-12 has been crystallized in complex with the broad-specificity inhibitor batimastat (BB-94). The crystal structure analysis of this complex, determined using X-ray data to 1.1 A and refined to an R-value of 0.165, reveals an overall fold similar to that of other MMPs. However, the S-shaped double loop connecting strands III and IV is fixed closer to the beta-sheet and projects its His172 side-chain further into the rather hydrophobic active-site cleft, defining the S3 and the S1-pockets and separating them from each other to a larger extent than is observed in other MMPs. The S2-site is planar, while the characteristic S1'-subsite is a continuous tube rather than a pocket, in which the MMP-12-specific Thr215 replaces a Val residue otherwise highly conserved in almost all other MMPs. This alteration might allow MMP-12 to accept P1' Arg residues, making it unique among MMPs. The active-site cleft of MMP-12 is well equipped to bind and efficiently cleave the AlaMetPhe-LeuGluAla sequence in the reactive-site loop of alpha1-PI, as occurs experimentally. Similarities in contouring and particularly a common surface hydrophobicity both inside and distant from the active-site cleft explain why MMP-12 shares many substrates with matrilysin (MMP-7). The MMP-12 structure is an excellent template for the structure-based design of specific inhibitors for emphysema therapy and for the construction of mutants to clarify the role of this MMP.     

Crystal structure of the catalytic domain of matrix metalloproteinase-1 in complex with the inhibitory domain of tissue inhibitor of metalloproteinase-1

The mammalian collagenases are a subgroup of the matrix metalloproteinases (MMPs) that are uniquely able to cleave triple helical fibrillar collagens. Collagen breakdown is an essential part of extracellular matrix turnover in key physiological processes including morphogenesis and wound healing; however, unregulated collagenolysis is linked to important diseases such as arthritis and cancer. The tissue inhibitors of metalloproteinases (TIMPs) function in controlling the activity of MMPs, including collagenases. We report here the structure of a complex of the catalytic domain of fibroblast collagenase (MMP-1) with the N-terminal inhibitory domain of human TIMP-1 (N-TIMP-1) at 2.54 A resolution. Comparison with the previously reported structure of the TIMP-1/stromelysin-1 (MMP-3) complex shows that the mechanisms of inhibition of both MMPs are generally similar, yet there are significant differences in the protein-protein interfaces in the two complexes. Specifically, the loop between beta-strands A and B of TIMP-1 makes contact with MMP-3 but not with MMP-1, and there are marked differences in the roles of individual residues in the C-D connector of TIMP-1 in binding to the two MMPs. Structural rearrangements in the bound MMPs are also strikingly different. This is the first crystallographic structure that contains the truncated N-terminal domain of a TIMP, which shows only minor differences from the corresponding region of the full-length protein. Differences in the interactions in the two TIMP-1 complexes provide a structural explanation for the results of previous mutational studies and a basis for designing new N-TIMP-1 variants with restricted specificity.     

The canonical methionine 392 of matrix metalloproteinase 2 (gelatinase A) is not required for catalytic efficiency or structural integrity: probing the role of the methionine-turn in the metzincin metalloprotease superfamily

Matrix metalloproteinases (MMPs) are an important family of extracellular proteases that process a variety of biologically significant molecules. MMPs are members of the metzincin superfamily of >770 zinc endopeptidases, which includes astacins, serralysins, adamalysins, leishmanolysins, and snapalysins. Metzincins are characterized by an absolutely conserved methionine residue COOH-terminal to the third histidine in the consensus sequence HEXXHXXGXX(H/D), where the histidine residues chelate a catalytic zinc ion. The canonical methionine is part of a tight 1,4-beta-turn that loops the polypeptide chain beneath the catalytic zinc ion, forming a hydrophobic floor to the Zn(2+) ion binding site. The role of this methionine is uncertain, but its absolute conservation indicates an essential catalytic or structural function. To investigate this hypothesis, we replaced Met-392 that forms the Met-turn of human MMP-2 (gelatinase A) by site-directed mutagenesis. The catalytic competence of leucine and serine mutants was assessed. (M392L)MMP-2 and (M392S)MMP-2 cleaved the physiological substrates gelatin, native type I collagen, and the chemokine monocyte chemoattractant protein-3 with similar efficiency to wild-type MMP-2. These mutants also cleaved two quenched fluorescent peptide substrates with a k(cat)/K(m) comparable to wild-type MMP-2 and underwent 4-aminophenylmercuric acetate-induced autoactivation with similar kinetics. (M392L)MMP-2 and (M392S)MMP-2 were inhibited by tissue inhibitor of metalloproteinases (TIMP)-1, -2, and -4 and by the zinc chelators 1,10-phenanthroline and a synthetic hydroxamate inhibitor, Batimastat, similar to the wild-type protein, indicating an unaltered active site topography. A tryptic susceptibility assay also suggested that (M392L)MMP-2 and (M392S)MMP-2 were correctly folded. These results challenge the dogma that this methionine residue and the Met-turn, which are absolutely conserved in all of the subfamilies of the metzincins, play an essential role in catalysis or active site structure.     

Catalytic domain of MMP20 (Enamelysin) - the NMR structure of a new matrix metalloproteinase

The solution structure of the catalytic domain of MMP-20, a member of the matrix metalloproteinases family not yet structurally characterized, complexed with N-Isobutyl-N-(4-methoxyphenylsulfonyl)glycyl hydroxamic acid (NNGH), is here reported and compared with other MMPs-NNGH adducts. The backbone dynamic has been characterized as well. We have found that, despite the same fold and very high overall similarity, the present structure experiences specific structural and dynamical similarities with some MMPs and differences with others, around the catalytic cavity. The present solution structure, not only contributes to fill the gap of structural knowledge on human MMPs, but also provides further information to design more selective and efficient inhibitors for a specific member of this class of proteins.     

Molecular dynamics simulations of matrix metalloproteinase 2: role of the structural metal ions

Herein we investigate the role played by the so-called "structural metal ions" in the catalytic domain of the matrix metalloproteinase 2 enzyme (MMP-2 or gelatinase A). We performed seven molecular dynamics simulations that differ in the number and position of the noncatalytic zinc and calcium ions bound to the MMP-2 catalytic domain. An additional simulation including the three fibronectin-type modules inserted into the catalytic domain was also carried out. The analysis of the trajectories confirms that the binding/removal of the structural ions does not perturb the secondary structure elements but influences the position of several solvent-exposed loop regions that are placed near the active site cleft. The position of these loops modulates the accessibility of important anchorage points for substrate binding that have been identified in the active site groove. On the basis of semiempirical quantum chemical calculations, we estimated the relative free energies of the MMP-2 models, obtaining thus that the binding of two zinc and two calcium ions to the MMP-2 catalytic domain is energetically favored. In this MMP-2 model, which shows the most compact structure, all of the substrate binding sites are readily accessible. Globally, our results help to rationalize at the atomic level the calcium and zinc dependence of the hydrolytic activity catalyzed by the MMPs.     

Structural Insights into the Catalytic Domains of Human Matrix Metalloprotease-2 and Human Matrix Metalloprotease-9: Implications for Substrate Specificities

Structural information for the gelatinases A (MMP-2) and B (MMP-9), two members of the matrix metalloprotease (MMP) family of enzymes, has been elusive. For the first time, computational structures for the catalytic domains of MMP-2 and MMP-9 are reported herein using the program COMPOSER and the reported three-dimensional structures of the fibroblast collagenase (MMP-1), neutrophil collagenase (MMP-8) and stromelysin-1 (MMP-3). The details of the structures of the catalytic domains of gelatinases and interactions with the protein substrate are discussed. The first analysis of the extent of hydrophobicity of surfaces in the active sites of six MMPs (including the two gelatinases reported herein) is presented to provide distinction for substrate specificity among these metalloproteases. The information from the extent of hydrophobicity/hydrophilicity analysis and general topology for these MMPs was utilized in the proposal of a method for categorization of MMPs of known three-dimensional fold. These efforts provide the first information useful to experimentalists working on the biochemical properties of these important members of the MMP family of enzymes, and provide for an opportunity to compare and contrast structures of gelatinases, collagenases and stromelysins.Electronic Supplementary Material available.     

Structural Insights into the Catalytic Domains of Human Matrix Metalloprotease-2 and Human Matrix Metalloprotease-9: Implications for Substrate Specificities

Structural information for the gelatinases A (MMP-2) and B (MMP-9), two members of the matrix metalloprotease (MMP) family of enzymes, has been elusive. For the first time, computational structures for the catalytic domains of MMP-2 and MMP-9 are reported herein using the program COMPOSER and the reported three-dimensional structures of the fibroblast collagenase (MMP-1), neutrophil collagenase (MMP-8) and stromelysin-1 (MMP-3). The details of the structures of the catalytic domains of gelatinases and interactions with the protein substrate are discussed. The first analysis of the extent of hydrophobicity of surfaces in the active sites of six MMPs (including the two gelatinases reported herein) is presented to provide distinction for substrate specificity among these metalloproteases. The information from the extent of hydrophobicity/hydrophilicity analysis and general topology for these MMPs was utilized in the proposal of a method for categorization of MMPs of known three-dimensional fold. These efforts provide the first information useful to experimentalists working on the biochemical properties of these important members of the MMP family of enzymes, and provide for an opportunity to compare and contrast structures of gelatinases, collagenases and stromelysins.     

Engineering of tissue inhibitor of metalloproteinases TIMP-1 for fine discrimination between closely related stromelysins MMP-3 and MMP-10

Matrix metalloproteinases (MMPs) have long been known as key drivers in the development and progression of diseases, including cancer and neurodegenerative, cardiovascular, and many other inflammatory and degenerative diseases, making them attractive potential drug targets. Engineering selective inhibitors based upon tissue inhibitors of metalloproteinases (TIMPs), endogenous human proteins that tightly yet nonspecifically bind to the family of MMPs, represents a promising new avenue for therapeutic development. Here, we used a counter-selective screening strategy for directed evolution of yeast-displayed human TIMP-1 to obtain TIMP-1 variants highly selective for the inhibition of MMP-3 in preference over MMP-10. As MMP-3 and MMP-10 are the most similar MMPs in sequence, structure, and function, our results thus clearly demonstrate the capability for engineering full-length TIMP proteins to be highly selective MMP inhibitors. We show using protein crystal structures and models of MMP-3-selective TIMP-1 variants bound to MMP-3 and counter-target MMP-10 how structural alterations within the N-terminal and C-terminal TIMP-1 domains create new favorable and selective interactions with MMP-3 and disrupt unique interactions with MMP-10. While our MMP-3-selective inhibitors may be of interest for future investigation in diseases where this enzyme drives pathology, our platform and screening strategy can be employed for developing selective inhibitors of additional MMPs implicated as therapeutic targets in disease.     

Molecular dynamics simulations of the active matrix metalloproteinase-2: positioning of the N-terminal fragment and binding of a small peptide substrate

Herein we use different computational methods to study the structure and energetic stability of the catalytic domain of the active MMP-2 enzyme considering two different orientations of its N-terminal coil. The first orientation is largely solvent accessible and corresponds to that observed in the 1CK7 crystal structure of the proenzyme. In the second orientation, the N-terminal coil is packed against the Omega-loop and the alpha3-helix of the MMP-2 enzyme likewise in the so-called "superactivated" form of other MMPs. Binding to the MMP-2 catalytic domain of a short peptide substrate, which mimics the sequence of the alpha1 chain of collagen type I, is also examined considering again the two configurations of the N-terminal coil. All these MMP-2 models are subject to 20 ns molecular dynamics (MD) simulations followed by MM-PBSA (Molecular Mechanics Poisson-Boltzmann Surface Area) calculations. The positioning of the N-terminal coil in the "superactivated" form is found to be energetically favored for the MMP-2 enzyme. Moreover, this configuration of the N-terminal moiety can facilitate the binding of peptide substrates. Globally, the results obtained in this study could be relevant for the structural-based design of specific MMP inhibitors.     

X-ray absorption studies of human matrix metalloproteinase-2 (MMP-2) bound to a highly selective mechanism-based inhibitor. comparison with the latent and active forms of the enzyme

Malignant tumors express high levels of zinc-dependent endopeptidases called matrix metalloproteinases (MMPs), which are thought to facilitate tumor metastasis and angiogenesis by hydrolyzing components of the extracellular matrix. Of these enzymes, gelatinases A (MMP-2) and B (MMP-9), have especially been implicated in malignant processes, and thus, they have been a target for drugs designed to block their activity. Therefore, understanding their molecular structure is key for a rational approach to inhibitor design. Here, we have conducted x-ray absorption spectroscopy of the full-length human MMP-2 in its latent, active, and inhibited states and report the structural changes at the zinc ion site upon enzyme activation and inhibition. We have also examined the molecular structure of MMP-2 in complex with SB-3CT, a recently reported novel mechanism-based synthetic inhibitor that was designed to be highly selective in gelatinases. It is shown that SB-3CT directly binds the catalytic zinc ion of MMP-2. Interestingly, the novel mode of binding of the inhibitor to the catalytic zinc reconstructs the conformational environment around the active site metal ion back to that of the proenzyme.     

Isolation and characterization of human monoclonal antibodies specific to MMP-1A, MMP-2 and MMP-3

Matrix metalloproteinases (MMPs), a group of more than 20 zinc-containing endopeptidases, are up-regulated in many diseases, but the use of MMP inhibitors for therapeutic purposes has often been disappointing, possibly for the limited specificity of the drugs used in clinical trials. In principle, individual MMPs could be specifically drugged by monoclonal antibodies, either by inhibition of their catalytic activity or by antibody-based pharmacodelivery strategies. In this article we describe the isolation and affinity maturation of recombinant antibodies (SP1, SP2, SP3) specific to the murine catalytic domains of MMP-1A, MMP-2 and MMP-3. These novel reagents allowed a systematic comparative immunofluorescence analysis of the expression patterns of their cognate antigens in a variety of healthy, cancerous and arthritic murine tissues. While all three MMPs were strongly expressed in tumor and arthritis specimens, MMP-1A was completely undetectable in the normal tissues tested, while MMP-2 and MMP-3 exhibited a weak expression in certain normal tissues (e.g., liver). The new antibodies may serve as building blocks for the development of antibody-based therapy strategies in mouse models of pathology.     

Dynamic interdomain interactions contribute to the inhibition of matrix metalloproteinases by tissue inhibitors of metalloproteinases

Because of their important function, matrix metalloproteinases (MMPs) are promising drug targets in multiple diseases, including malignancies. The structure of MMPs includes a catalytic domain, a hinge, and a hemopexin domain (PEX), which are followed by a transmembrane and cytoplasmic tail domains or by a glycosylphosphatidylinositol linker in membrane-type MMPs (MT-MMPs). TIMPs-1, -2, -3, and -4 are potent natural regulators of the MMP activity. These are the inhibitory N-terminal and the non-inhibitory C-terminal structural domains in TIMPs. Based on our structural modeling, we hypothesized that steric clashes exist between the non-inhibitory C-terminal domain of TIMPs and the PEX of MMPs. Conversely, a certain mobility of the PEX relative to the catalytic domain is required to avoid these obstacles. Because of its exceedingly poor association constant and, in contrast with TIMP-2, TIMP-1 is inefficient against MT1-MMP. We specifically selected an MT1-MMP·TIMP-1 pair to test our hypothesis, because any improvement of the inhibitory potency would be readily recorded. We characterized the domain-swapped MT1-MMP chimeras in which the PEX of MMP-2 (that forms a complex with TIMP-2) and of MMP-9 (that forms a complex with TIMP-1) replaced the original PEX in the MT1-MMP structure. In contrast with the wild-type MT1-MMP, the diverse proteolytic activities of the swapped-PEX chimeras were then inhibited by both TIMP-1 and TIMP-2. Overall, our studies suggest that the structural parameters of both domains of TIMPs have to be taken into account for their re-engineering to harness the therapeutic in vivo potential of the novel TIMP-based MMP antagonists with constrained selectivity.     

Metallopeptidase,neurolysin, as a novel molecular tool for analysis of properties of cancer-producing matrix metalloproteinases-2 and -9

To compare the substrate preferences of rat brain neurolysin and cancer-producing matrix metalloproteinases (MMPs), which have the same architecture in their catalytic domains, the cleavage activity of neurolysin toward MMP-specific fluorescence-quenching peptides was quantitatively measured. The results show that neurolysin effectively cleaved MOCAc [(7-methoxy coumarin-4-yl) acetyl]-RPKPYANvaWMK(Dnp[2,4-dinitrophenyl])-NH₂, a specific substrate of MMP-2 and MMP-9, but hardly cleaved MOCAc-RPKPVENvaWRK(Dnp)-NH₂, a specific substrate of MMP-3, suggesting that neurolysin has a similar substrate preference to MMP-2 and MMP-9. A structural comparison between neurolysin and MMP-9 showed the similar key amino acid residues for substrate recognition. The possible application of neurolysin displayed on the yeast cell surface, as a safe protein alternative to MMP-2 and MMP-9 which induce cancer cell growth, invasion, and metastasis, to analysis of properties of the MMPs, including the screening of inhibitors and analysis of inhibition mechanism etc., are also discussed.     

Phage display of tissue inhibitor of metalloproteinases-2 (TIMP-2): identification of selective inhibitors of collagenase-1 (metalloproteinase 1 (MMP-1))

Tissue inhibitor of metalloproteinases-2 (TIMP-2) is a broad spectrum inhibitor of the matrix metalloproteinases (MMPs), which function in extracellular matrix catabolism. Here, phage display was used to identify variants of human TIMP-2 that are selective inhibitors of human MMP-1, a collagenase whose unregulated action is linked to cancer, arthritis, and fibrosis. Using hard randomization of residues 2, 4, 5, and 6 (L1) and soft randomization of residues 34-40 (L2) and 67-70 (L3), a library was generated containing 2 × 10(10) variants of TIMP-2. Five clones were isolated after five rounds of selection with MMP-1, using MMP-3 as a competitor. The enriched phages selectively bound MMP-1 relative to MMP-3 and contained mutations only in L1. The most selective variant (TM8) was used to generate a second library in which residues Cys(1)-Gln(9) were soft-randomized. Four additional clones, selected from this library, showed a similar affinity for MMP-1 as wild-type TIMP-2 but reduced affinity for MMP-3. Variants of the N-terminal domain of TIMP-2 (N-TIMP-2) with the sequences of the most selective clones were expressed and characterized for inhibitory activity against eight MMPs. All were effective inhibitors of MMP-1 with nanomolar K(i) values, but TM8, containing Ser(2) to Asp and Ser(4) to Ala substitutions, was the most selective having a nanomolar K(i) value for MMP-1 but no detectable inhibitory activity toward MMP-3 and MMP-14 up to 10 μM. This study suggests that phage display and selection with other MMPs may be an effective method for discovering tissue inhibitor of metalloproteinase variants that discriminate between specified MMPs as targets.     

Structural basis for potent slow binding inhibition of human matrix metalloproteinase-2 (MMP-2)

The zinc-dependent gelatinases belong to the family of matrix metalloproteinases (MMPs), enzymes that have been shown to play a key role in angiogenesis and tumor metastasis. These enzymes are capable of hydrolyzing extracellular matrix (ECM) components under physiological conditions. Specific and selective inhibitors aimed at blocking their activity are highly sought for use as potential therapeutic agents. We report herein on a novel mode of inhibition of gelatinase A (MMP-2) by the recently characterized inhibitors 4-(4-phenoxphenylsulfonyl)butane-1,2-dithiol (inhibitor 1) and 5-(4-phenoxphenylsulfonyl) pentane-1,2-dithiol (inhibitor 2). These synthetic inhibitors are selective for MMP-2 and MMP-9. We show that the dithiolate moiety of these inhibitors chelates the catalytic zinc ion of MMP-2 via two sulfur atoms. This mode of binding results in alternation of the coordination number of the metal ion and the induction of conformational changes at the microenvironment of the catalytic zinc ion; a set of events that is likely to be at the root of the potent slow binding inhibition behavior exhibited by these inhibitors. This study demonstrates a distinct approach for the understanding of the structural mechanism governing the molecular interactions between potent inhibitors and catalytic sites of MMPs, which may aid in the design of effective inhibitors.     

Synthesis of bicyclic molecular scaffolds (BTAa): an investigation towards new selective MMP-12 inhibitors

Starting from 3-aza-6,8-dioxa-bicyclo[3.2.1]octane scaffold (BTAa) a virtual library of molecules was generated and screened in silico against the crystal structure of the Human Macrophage Metalloelastase (MMP-12). The molecules obtaining high score were synthesized and the affinity for the catalytic domain of MMP-12 was experimentally proved by NMR experiments. A BTAa scaffold 20 having a N-hydroxyurea group in position 3 and a p-phenylbenzylcarboxy amide in position 7 showed a fair inhibition potency (IC50 = 149 microM) for MMP-12 and some selectivity towards five different MMPs. These results, taken together with the X-ray structure of the adduct between MMP-12, the inhibitor 20 and the acetohydroxamic acid (AHA), suggest that bicyclic scaffold derivatives may be exploited for the design of new selective matrix metalloproteinase inhibitors (MMPIs).     

Matrix metalloproteinase 1 interacts with neuronal integrins and stimulates dephosphorylation of Akt

Several studies have demonstrated that matrix metalloproteinases (MMPs) are cytotoxic. The responsible mechanisms, however, are not well understood. MMPs may promote cytotoxicity through their ability to disrupt or degrade matrix proteins that support cell survival, and MMPs may also cleave substrates to generate molecules that stimulate cell death. In addition, MMPs may themselves act on cell surface receptors that affect cell survival. Among such receptors is the alpha(2)beta(1) integrin, a complex that has previously been linked to leukocyte death. In the present study we show that human neurons express alpha(2)beta(1) and that pro-MMP-1 interacts with this integrin complex. We also show that stimulation of neuronal cultures with MMP-1 is associated with a rapid reduction in the phosphorylation of Akt, a kinase that can influence caspase activity and cell survival. Moreover, MMP-1-associated dephosphorylation of Akt is inhibited by a blocking antibody to the alpha(2) integrin, but not by batimastat, an inhibitor of MMP-1 enzymatic activity. Such dephosphorylation is also stimulated by a catalytic mutant of pro-MMP-1. Additional studies show that MMP-1 causes neuronal death, which is significantly diminished by both a general caspase inhibitor and anti-alpha(2) but not by batimastat. Together, these results suggest that MMP-1 can stimulate dephosphorylation of Akt and neuronal death through a non-proteolytic mechanism that involves changes in integrin signaling.     

Pronounced diversity in electronic and chemical properties between the catalytic zinc sites of tumor necrosis factor-alpha-converting enzyme and matrix metalloproteinases despite their high structural similarity

The metalloproteinase tumor necrosis factor-alpha-converting enzyme (TACE) is involved in the regulation of several key physiological and pathological processes. Therefore, potent and selective synthetic inhibitors are highly sought for the study of the physiological roles of TACE as well as for therapeutic purposes. Because of the high structural similarities between the active site of TACE and those of other related zinc endopeptidases such as disintegrin (ADAMs) and matrix metalloproteinases (MMPs), the design of such tailor-made inhibitors is not trivial. To obtain new insights into this problem, we have used a selective MMP inhibitor as a probe to examine the structural and kinetic effects occurring at the active site of TACE upon inhibition. Specifically, we used the selective MMP mechanism-based inhibitor SB-3CT to characterize the fine structural and electronic differences between the catalytic zinc ions within the active sites of TACE and MMP-2. We show that SB-3CT directly binds the metal ion of TACE as observed before with MMP-2. However, in contrast to MMP-2, the binding mode of SB-3CT to the catalytic zinc ion of TACE is different in the length of the Zn-S(SB-3CT) bond distance and the total effective charge of the catalytic zinc ion. In addition, SB-3CT inhibits TACE in a non-competitive fashion by inducing significant conformational changes in the structure. For MMP-2, SB-3CT behaved as a competitive inhibitor and no significant conformational changes were observed. An examination of the second shell amino acids surrounding the catalytic zinc ion of these enzymes indicated that the active site of TACE is more polar than that of MMP-2 and of other MMPs. On the basis of these results, we propose that although there is a seemingly high structural similarity between TACE and MMP-2, these enzymes are significantly diverse in the electronic and chemical properties within their active sites.