Structural features of a superfamily of zinc-endopeptidases: the metzincins

Latent LytM at 1.3A resolution

LytM, an autolysin from Staphylococcus aureus, is a Zn(2+)-dependent glycyl-glycine endopeptidase with a characteristic HxH motif that belongs to the lysostaphin-type (MEROPS M23/37) of metallopeptidases. Here, we present the 1.3A crystal structure of LytM, the first structure of a lysostaphin-type peptidase. In the LytM structure, the Zn(2+) is tetrahedrally coordinated by the side-chains of N117, H210, D214 and H293, the second histidine of the HxH motif. Although close to the active-site, H291, the first histidine of the HxH motif, is not directly involved in Zn(2+)-coordination, and there is no water molecule in the coordination sphere of the Zn(2+), suggesting that the crystal structure shows a latent form of the enzyme. Although LytM has not previously been considered as a proenzyme, we show that a truncated version of LytM that lacks the N-terminal part with the poorly conserved Zn(2+) ligand N117 has much higher specific activity than full-length enzyme. This observation is consistent with the known removal of profragments in other lysostaphin-type proteins and with a prior observation of an active LytM degradation fragment in S.aureus supernatant. The "asparagine switch" in LytM is analogous to the "cysteine switch" in pro-matrix metalloproteases.

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.

L-selectin shedding does not regulate constitutive T cell trafficking but controls the migration pathways of antigen-activated T lymphocytes

L-selectin mediates rolling of lymphocytes in high endothelial venules (HEVs) of peripheral lymph nodes (PLNs). Cross-linking of L-selectin causes proteolytic shedding of its ectodomain, the physiological significance of which is unknown. To determine whether L-selectin shedding regulates lymphocyte migration, a mutant form that resists shedding (LdDeltaP-selectin) was engineered. Transgenic mice expressing either LDeltaP or wild-type (WT) L-selectin on T cells were crossed with L-selectin knockout (KO) mice. The cellularity and subset composition of secondary lymphoid organs did not differ between LDeltaP and WT mice, however, they were different from C57BL/6. Plasma levels of soluble L-selectin in LDeltaP mice were reduced to <5% of WT and C57BL/6 mice. The rolling properties of T lymphocytes from LDeltaP and WT mice on immobilized L-selectin ligands were similar. Furthermore, similar numbers of LDeltaP and WT T lymphocytes were recruited from the bloodstream into PLNs in mice, although LDeltaP T cells transmigrated HEVs more slowly. WT, but not LDeltaP-selectin, underwent rapid, metalloproteinase-dependent shedding after TCR engagement, and LDeltaP T cells retained the capacity to enter PLNs from the bloodstream. These results suggest that the ability to shed L-selectin is not required for T cell recirculation and homing to PLNs. However, L-selectin shedding from antigen-activated T cells prevents reentry into PLNs.

The LZT proteins; the LIV-1 subfamily of zinc transporters

Zinc is an essential ion for cells with a vital role to play in controlling the cellular processes of the cell, such as growth, development and differentiation. Specialist proteins called zinc transporters control the level of intracellular zinc in cells. In mammals, the ZIP family of zinc transporters has a pivotal role in maintaining the correct level of intracellular zinc by their ability to transport zinc into cells from outside, although they may also transport metal ions other than zinc. There are now recognised to be four subfamilies of the ZIP transporters, including the recently discovered LIV-1 subfamily which has similarity to the oestrogen-regulated gene LIV-1, previously implicated in metastatic breast cancer. We call this new subfamily LZT, for LIV-1 subfamily of ZIP zinc Transporters. Here we document current knowledge of this previously uncharacterised group of proteins, which includes the KE4 proteins. LZT proteins are similar to ZIP transporters in secondary structure and ability to transport metal ions across the plasma membrane or intracellular membranes. However, LZT proteins have a unique motif (HEXPHEXGD) with conserved proline and glutamic acid residues, unprecedented in other zinc transporters. The localisation of LZT proteins to lamellipodiae mirrors cellular location of the membrane-type matrix metalloproteases. These differences to other zinc transporters may be consistent with an alternative role for LZT proteins in cells, particularly in diseases such as cancer.

Matrix metalloproteinases: old dogs with new tricks

The matrix metalloproteinase family in humans comprises 23 enzymes, which are involved in many biological processes and diseases. It was previously thought that these enzymes acted only to degrade components of the extracellular matrix, but this view has changed with the discovery that non-extracellular-matrix molecules are also substrates.

The metalloprotease disintegrin ADAM8. Processing by autocatalysis is required for proteolytic activity and cell adhesion

ADAMs (a disintegrin and metalloprotease domains) are metalloprotease and disintegrin domain-containing transmembrane glycoproteins with proteolytic, cell adhesion, cell fusion, and cell signaling properties. ADAM8 was originally cloned from monocytic cells, and its distinct expression pattern indicates possible roles in both immunology and neuropathology. Here we describe our analysis of its biochemical properties. In transfected COS-7 cells, ADAM8 is localized to the plasma membrane and processed into two forms derived either by prodomain removal or as remnant protein comprising the extracellular region with the disintegrin domain at the N terminus. Proteolytic removal of the ADAM8 propeptide was completely blocked in mutant ADAM8 with a Glu(330) to Gln exchange (EQ-A8) in the Zn(2+) binding motif (HE(330)LGHNLGMSHD), arguing for autocatalytic prodomain removal. In co-transfection experiments, the ectodomain but not the entire MP domain of ADAM8 was able to remove the prodomain from EQ-ADAM8. With cells expressing ADAM8, cell adhesion to a substrate-bound recombinant ADAM8 disintegrin/Cys-rich domain was observed in the absence of serum, blocked by an antibody directed against the ADAM8 disintegrin domain. Soluble ADAM8 protease, consisting of either the metalloprotease domain or the complete ectodomain, cleaved myelin basic protein and a fluorogenic peptide substrate, and was inhibited by batimastat (BB-94, IC(50) approximately 50 nm) but not by recombinant tissue inhibitor of matrix metalloproteinases 1, 2, 3, and 4. Our findings demonstrate that ADAM8 processing by autocatalysis leads to a potential sheddase and to a form of ADAM8 with a function in cell adhesion.

The cysteine-rich domain regulates ADAM protease function in vivo

ADAMs are membrane-anchored proteases that regulate cell behavior by proteolytically modifying the cell surface and ECM. Like other membrane-anchored proteases, ADAMs contain candidate "adhesive" domains downstream of their metalloprotease domains. The mechanism by which membrane-anchored cell surface proteases utilize these putative adhesive domains to regulate protease function in vivo is not well understood. We address this important question by analyzing the relative contributions of downstream extracellular domains (disintegrin, cysteine rich, and EGF-like repeat) of the ADAM13 metalloprotease during Xenopus laevis development. When expressed in embryos, ADAM13 induces hyperplasia of the cement gland, whereas ADAM10 does not. Using chimeric constructs, we find that the metalloprotease domain of ADAM10 can substitute for that of ADAM13, but that specificity for cement gland expansion requires a downstream extracellular domain of ADAM13. Analysis of finer resolution chimeras indicates an essential role for the cysteine-rich domain and a supporting role for the disintegrin domain. These and other results reveal that the cysteine-rich domain of ADAM13 cooperates intramolecularly with the ADAM13 metalloprotease domain to regulate its function in vivo. Our findings thus provide the first evidence that a downstream extracellular adhesive domain plays an active role in regulating ADAM protease function in vivo. These findings are likely relevant to other membrane-anchored cell surface proteases.

Determinants of the inhibition of a Taiwan habu venom metalloproteinase by its endogenous inhibitors revealed by X-ray crystallography and synthetic inhibitor analogues

Venoms from crotalid and viperid snakes contain several peptide inhibitors which regulate the proteolytic activities of their snake-venom metalloproteinases (SVMPs) in a reversible manner under physiological conditions. In this report, we describe the high-resolution crystal structures of a SVMP, TM-3, from Taiwan habu (Trimeresurus mucrosquamatus) cocrystallized with the endogenous inhibitors pyroGlu-Asn-Trp (pENW), pyroGlu-Gln-Trp (pEQW) or pyroGlu-Lys-Trp (pEKW). The binding of inhibitors causes some of the residues around the inhibitor-binding environment of TM-3 to slightly move away from the active-site center, and displaces two metal-coordinated water molecules by the C-terminal carboxylic group of the inhibitors. This binding adopts a retro-manner principally stabilized by four possible hydrogen bonds. The Trp indole ring of the inhibitors is stacked against the imidazole of His143 in the S-1 site of the proteinase. Results from the study of synthetic inhibitor analogues showed the primary specificity of Trp residue of the inhibitors at the P-1 site, corroborating the stacking effect observed in our structures. Furthermore, we have made a detailed comparison of our structures with the binding modes of other inhibitors including batimastat, a hydroxamate inhibitor, and a barbiturate derivative. It suggests a close correlation between the inhibitory activity of an inhibitor and its ability to fill the S-1 pocket of the proteinase. Our work may provide insights into the rational design of small molecules that bind to this class of zinc-metalloproteinases.

Exploring the interface between metallo-proteinase activity and growth factor and cytokine bioavailability

Metallo-proteinases are implicated in many processes involved in tissue remodeling, cell motility, morphogenesis, and cell and organ growth and differentiation. Recent data suggest that several members of the metzincin family including the matrix metallo-proteinases (MMPs), adamalysin-related proteinases, and the newly described pappalysins, are intimately involved in the activation and/or release of cytokines and growth factors. We review how metzincins, working through unique mechanisms, influence the extracellular milieu of several important cytokines and growth factors including transforming growth factor-beta (TGF-beta), TNF-alpha, IGFs and HB-epidermal growth factor (EGF). Because metzincins can modulate the bioavailability of these peptides, they may serve as unique target molecules to control cytokine and growth factor action in the extracellular environment.

Expression of recombinant murine pregnancy-associated plasma protein-A (PAPP-A) and a novel variant (PAPP-Ai) with differential proteolytic activity

Murine pregnancy-associated plasma protein-A (PAPP-A) cDNA encoding a 1545 amino-acid protein has been cloned. We have also identified and cloned cDNA that encodes a novel variant of PAPP-A, PAPP-Ai, carrying a 29-residue highly basic insert. The point of insertion corresponds to a junction between two exons in the human PAPP-A gene. The human intron flanked by these exons does not encode a homologous corresponding insert, which is unique to the mouse. The overall sequence identity between murine and human PAPP-A is 91%, and murine PAPP-A contains sequence motifs previously described in the sequence of human PAPP-A. Through expression in mammalian cells, we show that murine PAPP-A and PAPP-Ai are active metalloproteinases, both capable of cleaving insulin-like growth factor binding protein (IGFBP)-4 and -5. Cleavage of IGFBP-4 is dramatically enhanced by the addition of IGF, whereas cleavage of IGFBP-5 is slightly inhibited by IGF, as previously established with human PAPP-A. Surprisingly, however, quantitative analyses demonstrate that the murine PAPP-Ai cleaves IGFBP-4 very slowly compared to PAPP-A, even though its ability to cleave IGFBP-5 is unaffected by the presence of the insert. By RT-PCR analysis, we find that both variants are expressed in several tissues. The level of mRNA in the murine placenta does not exceed the levels of other tissues analyzed. Furthermore, the IGFBP-4-proteolytic activity of murine pregnancy serum is not elevated. This is in striking contrast to the increase seen in human pregnancy serum, and the expression of PAPP-A in the human placenta, which exceeds other tissues at least 250-fold. Interestingly, the position of the insert of PAPP-Ai, within the proteolytic domain, lies in close proximity to the cysteine residue, which in human PAPP-A forms a disulfide bond with the proform of eosinophil major basic protein (proMBP). ProMBP functions as a proteinase inhibitor in the PAPP-A-proMBP complex, but whether any mechanistic parallel on regulation of proteolytic activity can be drawn between the insert of PAPP-Ai and the linkage to proMBP is not known. Importantly, these data support the development of the mouse as a model organism for the study of PAPP-A, which must take into account the differences between the mouse and the human.

Computational study of the catalytic domain of human neutrophil collagenase. specific role of the S3 and S'3 subsites in the interaction with a phosphonate inhibitor

Human neutrophil collagenase (HNC, MMP-8) is one of the target enzymes for drug treatment of pathologic extracellular matrix degradation. Peptidomimetic inhibitors bind in the S'-side of the enzyme active site occupying the S'1 primary specificity pocket by their large hydrophobic side-chains. The crystal structure of the complex between the catalytic domain of MMP-8 and Pro-Leu-L-TrpP(OH)2 (PLTP) showed that this phosphonate inhibitor binds in the S side of the active site. This finding was unexpected since it represents the first example of accommodation of the bulky Trp indolyl chain in the S1 rather than in the S'1 subsite. Dynamical and structural factors favouring this uncommon mode of binding were therefore investigated. MD simulations performed on the uncomplexed enzyme show that its structure in aqueous solution is only slightly different from the crystal structure found in the complex with PLTP. ED analysis of the MD simulations, performed on PLTP alternatively interacting with the S- or S'-side of the active site, shows that the enzyme fluctuation increases in both cases. The main contribution to the overall enzyme fluctuation is given by the loop 164-173. The fluctuation of this loop is spread over more degrees of freedom when PLTP interacts with the S-side. This dynamical factor can enhance the preference of PLTP for the S subsites of MMP-8. MD simulations also show that ligation of PLTP in the S subsites is further favoured by better zinc chelation, a cation-pi interaction at the S3 subsite and unstrained binding conformations. The role of the S3, S'3 and S'1 subsites in determining the inhibitor binding is discussed.

Mutation of the matrix metalloproteinase At2-MMP inhibits growth and causes late flowering and early senescence in Arabidopsis

This study characterizes the expression and functional significance of the member of the matrix metalloproteinase (MMP) family At2-MMP from Arabidopsis. By transcript analysis, expression of At2-MMP was found in leaves and roots of juvenile Arabidopsis and leaves, roots, and inflorescences of mature flowering plants showing strong increase of transcript abundance with aging. Cell specificity of expression of At2-MMP was studied by in situ hybridizations in leaves and flowers of Arabidopsis. In leaves, the gene was expressed in the phloem, in developing xylem elements, epidermal cells, and neighboring mesophyll cell layers. In flowers, signals were localized in pistils, ovules, and receptacles. In an Arabidopsis mutant (at2-mmp-1) carrying a tDNA insertion in At2-MMP, neither germination nor development of plants was modified in comparison to the wild type in the juvenile rosette stage. Starting with the onset of shoots, growth of roots, leaves, and shoots was inhibited compared with the wild type, and the plants were characterized by late flowering. Besides the flowering, at2-mmp-1 plants showed fast degradation of chlorophyll in leaves and early senescence. These results demonstrate the involvement of At2-MMP in plant growth, morphogenesis, and development with particular relevance for flowering and senescence.

A conserved sequence within the propeptide domain of membrane type 1 matrix metalloproteinase is critical for function as an intramolecular chaperone

The propeptide domain of secreted matrix metalloproteinases (MMPs) is responsible for maintaining the latency of these proteinases. Recently, the propeptide domain of the prototype membrane type matrix metalloproteinase (MT1-MMP) was demonstrated to act as an intramolecular chaperone (Cao, J., Hymowitz, M., Conner, C., Bahou, W. F., and Zucker, S. (2000) J. Biol. Chem. 275, 29648-29653). In the current study, the role of an unique four-amino acid sequence in the propeptide domain of MT1-MMP was examined. The sequence (42)YGYL(45) is conserved in the propeptide domain of all six members of the MT-MMP subfamily, but not in secreted MMPs. Mutant MT1-MMP cDNAs coding for alanine substitutions (single and double amino acid sequences) in this conserved propeptide region were transfected into COS-1 cells deficient in endogenous MT1-MMP. As demonstrated by immunofluorescence, mutant MT1-MMP protein was synthesized and displayed on the plasma membrane of transfected cells. Alanine substitutions within the (42)YGYL(45) sequence proved to be detrimental for enzyme function in terms of activation of proMMP-2 and binding TIMP-2 to the cell surface (MT1-MMP serves as a cell surface receptor for TIMP-2). In contrast to wild-type MT1-MMP-transfected cells, mutant MT1-MMP-transfected cells were incapable of degrading and migrating on a fibronectin substrate. These data indicate that the conserved (42)YGYL(45) sequence within the propeptide domain of MT-MMPs is required for intramolecular chaperone function of these intrinsic membrane proteinases.

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.

The function of leak and kuzbanian during growth cone and cell migration

Axonal growth cones require an evolutionary conserved repulsive guidance system to ensure proper crossing of the CNS midline. In Drosophila, the Slit protein is a repulsive signal secreted by the midline glial cells. It binds to the Roundabout receptors, which are expressed on CNS axons in the longitudinal tracts but not in the commissural tracts. Here we present an analysis of the genes leak and kuzbanian and show that both genes are involved in the repulsive guidance system operating at the CNS midline. Mutations in leak, which encodes the Roundabout-2 Slit receptor, were first recovered by Nüsslein-Volhard and co-workers based on defects in the larval cuticle. Analysis of the head phenotype suggests that slit may be able to act as an attractive guidance cue while directing the movements of the dorsal ectodermal cell sheath. kuzbanian also regulates midline crossing of CNS axons. It encodes a metalloprotease of the ADAM family and genetically interacts with slit. Expression of a dominant negative Kuzbanian protein in the CNS midline cells results in an abnormal midline crossing of axons and prevents the clearance of the Roundabout receptor from commissural axons. Our analyses support a model in which Kuzbanian mediates the proteolytic activation of the Slit/Roundabout receptor complex.

Structure-based sequence alignment of type-II restriction endonucleases

The type-II restriction endonucleases generally do not share appreciable amino acid sequence homology. The crystal structures of restriction endonucleases EcoRI and BamHI have shown these enzymes to possess striking 3D-structural resemblance, i.e., they have a similar overall fold and similar active sites, though they possess <23% sequence identity. Structural superimposition of EcoRI, BamHI, EcoRV, and PvuII based on active site residues led to sequence alignments which showed nine possible sequence motifs. EcoRV and PvuII show a more similar pattern than EcoRI and BamHI suggesting that they belong to a different subgroup. The motifs are characterized by charged and/or hydrophobic residues. From other studies on the structure of these endonucleases, three of the motifs could be implicated in DNA binding, three in forming the active site and one in dimer formation. However, the motifs were not identifiable by regular sequence alignment methods. It is found that motif IX in BamHI is formed by reverse sequence order and the motif IX in PvuII is formed from the symmetry related monomer of the dimer. The inter-motif distance is also quite different in these cases. Of the nine motifs, motif III has been earlier identified as containing the PD motif involving one of the active site residues. These motifs were used in a modified profile analysis procedure to identify similar regions in eight other endonuclease sequences for which structures are not known.

Cellular localization of the disintegrin CRII-7/rMDC15 mRNA in rat PNS and CNS and regulated expression in postnatal development and after nerve injury

Disintegrins perform putative functions in cell adhesion, signaling and fusion. We have isolated a 2815-bp rat cDNA (CRII-7) representing a transcript that is differentially expressed during sciatic nerve regeneration. Nucleotide sequence comparison indicates that CRII-7 is the rat homologue to the recently cloned cDNAs MDC15 (ADAM 15) and metargidin (hMDC15) of mouse and human, respectively. The CRII-7 cDNA (rMDC15) encodes a membrane-anchored glycoprotein of approximately 85 kDa containing a disintegrin and a metalloprotease domain. Cellular metalloprotease disintegrins are a family of proteins (ADAMs or MDC proteins) with important roles, e.g., in cell-cell interactions during fertilization, muscle and nerve development, or tumor necrosis factor-alpha (TNF-alpha) cleavage. Northern blot analysis demonstrated a predominant expression of CRII-7/rMDC15 in the nervous system (PNS and CNS) and lung. Analysis of the CRII-7/rMDC15 transcript levels following peripheral nerve lesions demonstrated regulated mRNA expression during Wallerian degeneration and nerve regeneration. The steady-state levels of CRII-7/rMDC15 transcripts markedly increased within the first day after lesion and then steadily decreased for at least 4 weeks. CRII-7/rMDC15 mRNA expression was further examined during postnatal development and maturation of rat sciatic nerve and brain, as well as in cultured Schwann cells, meningeal fibroblasts, and astrocytes. In situ hybridization on paraffin sections showed the cellular localization of CRII-7/rMDC15 mRNA in Schwann cells and endothelial cells of peripheral nerve and in various neuronal populations in brain and spinal cord.

The roles of Glu93 and Tyr149 in astacin-like zinc peptidases

The catalytic zinc of astacin, a prototype of the astacin family and the metzincin superfamily of metalloproteinases is coordinated by three histidines, a glutamate bound water and a tyrosine. In order to assess the roles of active site key residues, two mutants, Glu93Ala-astacin and Tyr149Phe-astacin, were expressed in Escherichia coli, affinity-purified and renatured. While the Glu93Ala mutant was inactive, the Tyr149Phe mutant retained about 2. 5% residual activity toward Dns-Pro-Lys-Arg*Ala-Pro-Trp-Val, based on the k(cat)/K(m) value for recombinant wild-type astacin. These results support a model in which Glu93 is the general base in substrate hydrolysis, whereas Tyr149 contributes to transition state binding.

Structural characterization of the catalytic active site in the latent and active natural gelatinase B from human neutrophils

Matrix metalloproteinases are endopeptidases that have a leading role in the catabolism of the macromolecular components of the extracellular matrix in a variety of normal and pathological processes. Human gelatinase B is a zinc-dependent proteinase and a member of the matrix metalloproteinase family that is involved in inflammation, tissue remodeling, and cancer. We have conducted x-ray absorption spectroscopy, atomic emission, and quantum mechanics studies of natural and activated human gelatinase B. Our results show that the natural enzyme contains one catalytic zinc ion that is central to catalysis. In addition, upon enzyme activation, the catalytic zinc site exhibits a conformation change that results in the expansion of the bond distances around the zinc ion and the replacement of one sulfur with oxygen. Interestingly, quantum mechanics calculations show that oxygen ligation at the catalytic zinc ion exhibits a greater affinity to the binding of an oxygen from an amino acid residue rather than from an external water molecule. These results suggest that the catalytic zinc ion plays a key role in both substrate binding and catalysis.

Structure of the zinc-binding site in the crystal structure of a zinc endoprotease from Streptomyces caespitosus at 1 A resolution

A zinc endoprotease produced by Streptomyces caespitosus (ScNP) contains a H83E84TGH87VLG90LPD93-Met103 sequence. Except for D93, this amino acid sequence is the same as a characteristic consensus HEXXHXXGXXH-M motif found in one class of zinc endoprotease called 'metzincins'. We analyzed the structural and functional role of the consensus sequence located around a catalytically essential zinc ion based on the crystal structure of ScNP. The structure was determined at the highest level on resolution (1 A resolution) and accuracy among crystal structures of zinc endoproteases ever determined. The zinc ion of ScNP is tetrahedrally coordinated by three amino acid side-chains (H83, H87 and D93) and a water molecule. The distances between the zinc ion and the coordinating atoms are 2.01, 2.01 and 1.95 A for H83N epsilon, H87N epsilon and D93O delta, respectively. These distances agree very well with those normally found in crystal structures of zinc-containing small molecules in the Cambridge Structural Database. On the other hand, the distance between the zinc ion and the coordinating water molecule (1.93 A) is slightly shorter than the typical value (2.01 A) found in the database. In addition, E84O epsilon makes a short hydrogen bond to this water molecule with the distance of 2.54 A. Two hydrogen bonds (H83N delta-L102O, H87N delta-L91O) and van der Waals interactions between the side-chain of M103 and the two imidazole rings of H83 and H87 are also observed. These interactions are probably important for the imidazole rings to construct the tetrahedral coordination arrangement toward the zinc ion.

Structural differences of matrix metalloproteinases. Homology modeling and energy minimization of enzyme-substrate complexes

Matrix metalloproteinases are extracellular enzymes taking part in the remodeling of extracellular matrix. The structures of the catalytic domain of MMP1, MMP3, MMP7 and MMP8 are known, but structures of enzymes belonging to this family still remain to be determined. A general approach to the homology modeling of matrix metalloproteinases, exemplified by the modeling of MMP2, MMP9, MMP12 and MMP14 is described. The models were refined using an energy minimization procedure developed for matrix metalloproteinases. This procedure includes incorporation of parameters for zinc and calcium ions in the AMBER 4.1 force field, applying a non-bonded approach and a full ion charge representation. Energy minimization of the apoenzymes yielded structures with distorted active sites, while reliable three-dimensional structures of the enzymes containing a substrate in active site were obtained. The structural differences between the eight enzyme-substrate complexes were studied with particular emphasis on the active site, and possible sites for obtaining selectivity among the MMP's are discussed. Differences in the P1' pocket are well-documented and have been extensively exploited in inhibitor design. The present work indicates that selectivity could be further improved by considering the P2 pocket as well.

Altered cell-matrix associated ADAM proteins in Alzheimer disease

Alterations in cell-matrix 'contact' are often related to a disruption of cell cycle regulation and, as such, occur variously in neoplasia. Given the recent findings showing cell cycle alterations in Alzheimer disease, we undertook a study of ADAM-1 and 2 (A Disintegrin And Metalloprotease), developmentally-regulated, integrin-binding, membrane-bound metalloproteases. Our results show that whereas ADAM-1 and 2 are found in susceptible hippocampal neurons in Alzheimer disease, these proteins were not generally increased in similar neuronal populations in younger or age-matched controls except in association with age-related neurofibrillary alterations. This increase in both ADAM-1 and 2 in cases of Alzheimer disease was verified by immunoblot analysis (P < 0.05). An ADAM-induced loss of matrix integration would effectively "reset" the mitotic clock and thereby stimulate re-entry into the cell cycle in neurons in Alzheimer disease. Furthermore, given the importance of integrins in maintaining short-term memory, alterations in ADAM proteins or their proteolytic activity could also play a proximal role in the clinico-pathological manifestations of Alzheimer disease.

Crystal structure of the stromelysin catalytic domain at 2.0 A resolution: inhibitor-induced conformational changes

Matrix metalloproteinases are believed to play an important role in pathological conditions such as osteoarthritis, rheumatoid arthritis and tumor invasion. Stromelysin is a zinc-dependent proteinase and a member of the matrix metalloproteinase family. We have solved the crystal structure of an active uninhibited form of truncated stromelysin and a complex with a hydroxamate-based inhibitor. The catalytic domain of the enzyme of residues 83-255 is an active fragment. Two crystallographically independent molecules, A and B, associate as a dimer in the crystals. There are three alpha-helices and one twisted, five-strand beta-sheet in each molecule, as well as one catalytic Zn, one structural Zn and three structural Ca ions. The active site of stromelysin is located in a large, hydrophobic cleft. In particular, the S1' specificity site is a deep and highly hydrophobic cavity. The structure of a hydroxamate-phosphinamide-type inhibitor-bound stromelysin complex, formed by diffusion soaking, has been solved as part of our structure-based design strategy. The most important feature we observed is an inhibitor-induced conformational change in the S1' cavity which is triggered by Tyr223. In the uninhibited enzyme structure, Tyr223 completely covers the S1' cavity, while in the complex, the P1' group of the inhibitor displaces the Tyr223 in order to fit into the S1' cavity. Furthermore, the displacement of Tyr223 induces a major conformational change of the entire loop from residue 222 to residue 231. This finding provides direct evidence that Tyr223 plays the role of gatekeeper of the S1' cavity. Another important intermolecular interaction occurs at the active sit of molecule A, in which the C-terminal tail (residues 251-255) from molecule B inserts. The C-terminal tail interacts extensively with the active site of molecule A, and the last residue (Thr255) coordinated to the catalytic zinc as the fourth ligand, much like a product inhibitor would. The inhibitor-induced conformational change and the intermolecular C-terminal-zinc coordination are significant in understanding the structure-activity relationships of the enzyme.

ADAM-TS5, ADAM-TS6, and ADAM-TS7, novel members of a new family of zinc metalloproteases. General features and genomic distribution of the ADAM-TS family

We report the primary structure of three novel, putative zinc metalloproteases designated ADAM-TS5, ADAM-TS6, and ADAM-TS7. All have a similar domain organization, comprising a preproregion, a reprolysin-type catalytic domain, a disintegrin-like domain, a thrombospondin type-1 (TS) module, a cysteine-rich domain, a spacer domain without cysteine residues, and a COOH-terminal TS module. These genes are differentially regulated during mouse embryogenesis and in adult tissues, with Adamts5 highly expressed in the peri-implantation period in embryo and trophoblast. These proteins are similar to four other cognate gene products, defining a distinct family of human reprolysin-like metalloproteases, the ADAM-TS family. The other members of the family are ADAM-TS1, an inflammation-induced gene, the procollagen I/II amino-propeptide processing enzyme (PCINP, ADAM-TS2), and proteins predicted by the KIAA0366 and KIAA0688 genes (ADAM-TS3 and ADAM-TS4). Individual ADAM-TS members differ in the number of COOH-terminal TS modules, and some have unique COOH-terminal domains. The ADAM-TS genes are dispersed in human and mouse genomes.

Tumor targeting with a selective gelatinase inhibitor

Several lines of evidence suggest that tumor growth, angiogenesis, and metastasis are dependent on matrix metalloproteinase (MMP) activity. However, the lack of inhibitors specific for the type IV collagenase/gelatinase family of MMPs has thus far prevented the selective targeting of MMP-2 (gelatinase A) and MMP-9 (gelatinase B) for therapeutic intervention in cancer. Here, we describe the isolation of specific gelatinase inhibitors from phage display peptide libraries. We show that cyclic peptides containing the sequence HWGF are potent and selective inhibitors of MMP-2 and MMP-9 but not of several other MMP family members. Our prototype synthetic peptide, CTTHWGFTLC, inhibits the migration of human endothelial cells and tumor cells. Moreover, it prevents tumor growth and invasion in animal models and improves survival of mice bearing human tumors. Finally, we show that CTTHWGFTLC-displaying phage specifically target angiogenic blood vessels in vivo. Selective gelatinase inhibitors may prove useful in tumor targeting and anticancer therapies.

Structure of human pro-matrix metalloproteinase-2: activation mechanism revealed

Matrix metalloproteinases (MMPs) catalyze extracellular matrix degradation. Control of their activity is a promising target for therapy of diseases characterized by abnormal connective tissue turnover. MMPs are expressed as latent proenzymes that are activated by proteolytic cleavage that triggers a conformational change in the propeptide (cysteine switch). The structure of proMMP-2 reveals how the propeptide shields the catalytic cleft and that the cysteine switch may operate through cleavage of loops essential for propeptide stability.

Tetanus and botulinum neurotoxins: mechanism of action and therapeutic uses

The clostridial neurotoxins responsible for tetanus and botulism are proteins consisting of three domains endowed with different functions: neurospecific binding, membrane translocation and proteolysis for specific components of the neuroexocytosis apparatus. Tetanus neurotoxin (TeNT) binds to the presynaptic membrane of the neuromuscular junction, is internalized and transported retroaxonally to the spinal cord. The spastic paralysis induced by the toxin is due to the blockade of neurotransmitter release from spinal inhibitory interneurons. In contrast, the seven serotypes of botulinum neurotoxins (BoNTs) act at the periphery by inducing a flaccid paralysis due to the inhibition of acetylcholine release at the neuromuscular junction. TeNT and BoNT serotypes B, D, F and G cleave specifically at single but different peptide bonds, of the vesicle associated membrane protein (VAMP) synaptobrevin, a membrane protein of small synaptic vesicles (SSVs). BoNT types A, C and E cleave SNAP-25 at different sites located within the carboxyl-terminus, while BoNT type C additionally cleaves syntaxin. The remarkable specificity of BoNTs is exploited in the treatment of human diseases characterized by a hyperfunction of cholinergic terminals.

A three-dimensional construction of the active site (region 507-749) of human neutral endopeptidase (EC.3.4.24.11)

A three-dimensional model of the 507-749 region of neutral endopeptidase-24.11 (NEP; E.C.3.4.24.11) was constructed integrating the results of secondary structure predictions and sequence homologies with the bacterial endopeptidase thermolysin. Additional data were extracted from the structure of two other metalloproteases, astacin and stromelysin. The resulting model accounts for the main biological properties of NEP and has been used to describe the environment close to the zinc atom defining the catalytic site. The analysis of several thiol inhibitors, complexed in the model active site, revealed the presence of a large hydrophobic pocket at the S1' subsite level. This is supported by the nature of the constitutive amino acids. The computed energies of bound inhibitors correspond with the relative affinities of the stereoisomers of benzofused macrocycle derivatives of thiorphan. The model could be used to facilitate the design of new NEP inhibitors, as illustrated in the paper.

The propeptide domain of membrane type 1 matrix metalloproteinase is required for binding of tissue inhibitor of metalloproteinases and for activation of pro-gelatinase A

Activation of secreted latent matrix metalloproteinases (MMPs) is accompanied by cleavage of the N-terminal propeptide, thereby liberating the active zinc from binding to the conserved cysteine in the pro-domain. It has been assumed that an analogous mechanism is responsible for the activation of membrane type 1 MMP (MT1-MMP). Using recombinant wild-type MT1-MMP cDNA and mutant cDNAs transfected into COS-1 cells lacking endogenous MT1-MMP, we have examined the function of the propeptide domain of MT1-MMP. MT1-MMP was characterized by immunoblotting, surface biotinylation, gelatin substrate zymography, and 125I-tissue inhibitor of metalloproteinases 2 (TIMP-2) binding. In contrast to wild-type MT1-MMP-transfected COS-1 cells, transfected COS-1 cells containing a deletion of the N-terminal propeptide domain of MT1-MMP or a chimeric construction (substitution of the pro-domain of MT1-MMP with that of collagenase 3) were functionally inactive in terms of binding of 125I-labeled TIMP-2 to the cell surface and initiating the activation of pro-gelatinase A. These results support the concept that in its native plasma membrane-inserted form, the pro-domain of MT1-MMP plays an essential role in TIMP-2 binding and subsequent activation of pro-gelatinase A.

A homology identification method that combines protein sequence and structure information

A new method is presented for identifying distantly related homologous proteins that are unrecognizable by conventional sequence comparison methods. The method combines information about functionally conserved sequence patterns with information about structure context. This information is encoded in stochastic discrete state-space models (DSMs) that comprise a new family of hidden Markov models. The new models are called sequence-pattern-embedded DSMs (pDSMs). This method can identify distantly related protein family members with a high sensitivity and specificity. The method is illustrated with trypsin-like serine proteases and globins. The strategy for building pDSMs is presented. The method has been validated using carefully constructed positive and negative control sets. In addition to the ability to recognize remote homologs, pDSM sequence analysis predicts secondary structures with higher sensitivity, specificity, and Q3 accuracy than DSM analysis, which omits information about conserved sequence patterns. The identification of trypsin-like serine proteases in new genomes is discussed.

The crystal structure of the Leishmania major surface proteinase leishmanolysin (gp63)

BACKGROUND

Despite their medical importance, there is little available structural information for the surface antigens of infectious protozoa. Diseases caused by the protozoan parasite Leishmania are common in many developing countries. Human infection occurs during the bite of infected sandfilies, when Leishmania promastigote cells from the insect gut enter the bloodstream. Promastigotes in the blood parasitize macrophages, often causing serious disease. Leishmanolysin is the predominant protein surface antigen of promastigotes, and is assumed to have a key role during infection. Leishmanolysin is a membrane-bound zinc proteinase, active in situ. Similar molecules exist in other trypanomastid protozoa.

RESULTS

Two crystal forms of leishmanolysin were obtained from protein purified from promastigote membranes. A single lead derivative in both crystal forms was used to solve the structure. The structure reveals three domains, two of which have novel folds. The N-terminal domain has a similar structure to the catalytic modules of zinc proteinases. The structure clearly shows that leishmanolysin is a member of the metzincin class of zinc proteinases.

CONCLUSIONS

The unexpected metzincin features of the leishmanolysin structure suggest that the metzincin fold may be more widespread than indicated by sequence homologies amongst existing metzincin zinc proteinases. The similarity of the active-site structure to previously well characterized metzincin class zinc proteinases should aid the development of specific inhibitors. These inhibitors might be used to determine the function of leishmanolysin in the insect and during mammalian infection, and may aid the development of drugs for human leishmaniasis.

The metallo-disintegrin ADAM10 (MADM) from bovine kidney has type IV collagenase activity in vitro

The metallo-disintegrins (ADAMs) are a family of mammalian proteins with significant amino acid sequence identity and a domain organisation similar to the snake venom metalloproteinases (reprolysins). They have been implicated in a wide variety of processes such as cell-cell and cell matrix adhesion and proteolysis of the extracellular matrix in a wide variety of cell types. They may also be involved in events such as the processing of plasma membrane proteins, proteolysis in the secretory pathway and pro-cytokine conversion processes. Due to the close relationship of the ADAM proteins with snake venom enzymes which have been demonstrated to be type IV collagenases, we investigated whether purified bovine ADAM10 could cleave basement membrane type IV collagen. We show here that ADAM10 purified from bovine kidney can cleave a basement membrane collagen type IV preparation as assessed by SDS-PAGE analysis and novel epitope recognition with a specific antibody to type IV collagen. The demonstration that a metallo-disintegrin displays a type IV collagenase activity may be relevant to tumour metastasis and may have general relevance to extracellular re-modeling in renal pathology and a variety of other pathological states where compromise of the basement membrane is involved.

The Leu-3 residue of Serratia marcescens metalloprotease inhibitor is important in inhibitory activity and binding with Serratia marcescens metalloprotease

Serratia marcescens metalloprotease inhibitor (SmaPI) is a proteinase inhibitor toward Serratia marcescens metalloprotease (SMP). In sequential deletion analysis of the N-terminal region of the SmaPI, SmaPIs starting at Ser-2 and Leu-3 residues, respectively, had nearly a full inhibitory activity toward SMP. However, SmaPI starting at Ala-4 residue showed severely decreased inhibitory activity. Furthermore, kinetic analysis demonstrated that SmaPI starting at the Ala-4 residue had an inhibition constant for SMP approximately fourfold higher than that of wild-type SmaPI. The interactions of Leu-3 with SMP contribute 0.73 kcal mol-1 to the overall stability of the SMP-SmaPI complex (8.44 kcal mol-1). To elucidate the detailed role of the Leu-3 residue in inhibitory activity of SmaPI, several site-directed mutations were introduced. The inhibitory activities of Leu-3 mutants in which the Leu-3 has been converted to Ala, Asp, Gly, Ile, Lys, Phe, or Pro were correlated with the hydrophobicities of substituted amino acids. About 0.3 kcal mol-1 is attributable to the side chain of the Leu-3 residue in the binding with SMP. From these results, it is suggested that (i) in contrast with the Erwinia chrysanthemi inhibitor, Gly-1 and Ser-2 of SmaPI are not critical and (ii) the hydrophobicity of Leu-3 may be important in its inhibitory activity and binding with SMP.

ADAM 20 and 21; two novel human testis-specific membrane metalloproteases with similarity to fertilin-alpha

Two novel membrane disintegrin-metalloproteases, ADAM 20 and ADAM 21 were cloned from a human testis cDNA library. Their predicted translation products share 50% sequence identity with each other. Among previously characterized ADAMs, the best similarity was to sperm cell-specific fertilins-alpha and -beta, and meltrin-gamma (ADAM 9) which is ubiquitously expressed. Both ADAM 20 and 21 mRNAs are exclusively expressed in testis, presumably, in analogy to all other testis-specific ADAMs, on mature spermatocytes. Both cDNAs were mapped on the genome, and found to be tightly linked to the same marker (SHGC-36001) on chromosome 14q24.1. This region is not syntenic with the loci of mouse sperm-specific ADAMs 1-5. ADAM 20, but not 21, encodes a consensus Zn2+ binding site of active adamalysin metzincin metalloproteases, and both 20 and 21 encode putative cell-fusion peptides, required for sperm-egg fusion. Based on these characteristics it is possible that ADAM 20 and/or 21 is the functional equivalent of sperm fertilin-alpha, as it was recently reported that this gene is non-functional in humans.

Ligand perturbation effects on a pseudotetrahedral Co(II)(His)3-ligand site. A magnetic circular dichroism study of the Co(II)-substituted insulin hexamer

Magnetic circular dichroism (MCD) spectra of a series of adducts formed by the Co(II)-substituted R-state insulin hexamer are reported. The His-B10 residues in this hexamer form tris imidazole chelates in which pseudotetrahedral Co(II) centers are completed by an exogenous fourth ligand. This study investigates how the MCD signatures of the Co(II) center in this unit are influenced by the chemical and steric characteristics of the fourth ligand. The spectra obtained for the adducts formed with halides, pseudohalides, trichloroacetate, nitrate, imidazole, and 1-methylimidazole appear to be representative of near tetrahedral Co(II) geometries. With bulkier aromatic ligands, more structured spectra indicative of highly distorted Co(II) geometries are obtained. The MCD spectrum of the phenolate adduct is very similar to those of Co(II)-carbonic anhydrase (alkaline form) and Co(II)-beta-lactamase. The MCD spectrum of the Co(II)-R6-CN- adduct is very similar to the CN- adduct of Co(II)-carbonic anhydrase. The close similarity of the Co(II)-R6-pentafluorophenolate and Co(II)-R6-phenolate spectra demonstrates that the Co(II)-carbonic anhydrase-like spectral profile is preserved despite a substantial perturbation in the electron withdrawing nature of the coordinated phenolate oxygen atom. We conclude that this type of spectrum must arise from a specific Co(II) coordination geometry common to each of the Co(II) sites in the Co(II)-R6-phenolate, Co(II)-R6-pentafluorophenolate, Co(II)-beta-lactamase, and the alkaline Co(II)-carbonic anhydrase species. These spectroscopic results are consistent with a trigonally distorted tetrahedral Co(II) geometry (C3v), an interpretation supported by the pseudotetrahedral Zn(II)(His)3(phenolate) center identified in a Zn(II)-R6 crystal structure (Smith, G. D., and Dodson, G. G. (1992) Biopolymers 32, 441-445).

The mitochondrial processing peptidase: function and specificity

Targeting signals of mitochondrial precursors are cleaved in the matrix during or after import by the mitochondrial processing peptidase (MPP). This enzyme consists of two nonidentical alpha- and beta-subunits each of molecular weight of about 50 kDa. In mammals and fungi, MPP is soluble in the matrix, whereas in plants the enzyme is part of the cytochrome bc1 complex. MPP is a metalloendopeptidase which has been classified as a member of the pitrilysin family on the basis of the HXXEHX76E zinc-binding motif present in beta-MPP. Both subunits of MPP are required for processing activity. The alpha-subunit of MPP, which probably recognizes a three-dimensional motif adopted by the presequence, presents the presequence to beta-MPP, which carries the catalytic active site. MPP acts as an endoprotease on chemically synthesized peptides corresponding to mitochondrial presequences. Matrix-targeting signals and MPP cleavage signals seem to be distinct, although the two signals may overlap within a given presequence. The structural element helix-turn-helix, that cleavable presequences adopt in a membrane mimetic environment, may be required for processing but is not sufficient for proteolysis. Binding of the presequence by alpha-MPP tolerates a high degree of mutations of the presequence. alpha-MPP may present a degenerated cleavage site motif to beta-MPP in an accessible conformation for processing. The conformation of mitochondrial presequences bound to MPP remains largely unknown.

Regulated protein degradation in mitochondria

Various adenosine triphosphate (ATP)-dependent proteases were identified within mitochondria which mediate selective mitochondrial protein degradation and fulfill crucial functions in mitochondrial biogenesis. The matrix-localized PIM1 protease, a homologue of the Escherichia coli Lon protease, is required for respiration and maintenance of mitochondrial genome integrity. Degradation of non-native polypeptides by PIM1 protease depends on the chaperone activity of the mitochondrial Hsp70 system, posing intriguing questions about the relation between the proteolytic system and the folding machinery in mitochondria. The mitochondrial inner membrane harbors two ATP-dependent metallopeptidases, the m- and the i-AAA protease, which expose their catalytic sites to opposite membrane surfaces and cooperate in the degradation of inner membrane proteins. In addition to its proteolytic activity, the m-AAA protease has chaperone-like activity during the assembly of respiratory and ATP-synthase complexes. It constitutes a quality control system in the inner membrane for membrane-embedded protein complexes.

Structure and domain-domain interactions of the gelatin binding site of human 72-kilodalton type IV collagenase (gelatinase A, matrix metalloproteinase 2)

We have shown previously that all three fibronectin type II modules of gelatinase A contribute to its gelatin affinity. In the present investigation we have studied the structure and module-module interactions of this gelatin-binding domain by circular dichroism spectroscopy and differential scanning calorimetry. Comparison of the Tm values of the thermal transitions of isolated type II modules with those of bimodular or trimodular proteins has shown that the second type II module is significantly more stable in the trimodular protein coll 123 (Tm = 54 degrees C) than in the single-module protein coll 2 (Tm = 44 degrees C) or in the bimodular proteins coll 23 (Tm = 47 degrees C) and coll 12 (Tm = 48 degrees C). Analysis of the enthalpy changes associated with thermal unfolding of the second type II module suggests that it is stabilized by domain-domain interactions in coll 123. We propose that intimate contacts exist between the three tandem type 11 units and they form a single gelatin-binding site. Based on the three-dimensional structures of homologous metalloproteases and type II modules, a model is proposed in which the three type II units form an extension of the substrate binding cleft of gelatinase A.