Lakshmi P. Kotra

Matrix metalloproteinases: structures, evolution, and diversification

A comprehensive sequence alignment of 64 members of the family of matrix metalloproteinases (MMPs) for the entire sequences, and subsequently the catalytic and the hemopexin‐like domains, have been performed. The 64 MMPs were selected from plants, invertebrates, and vertebrates. The analyses disclosed that as many as 23 distinct subfamilies of these proteins are known to exist. Information from the sequence alignments was correlated with structures, both crystallographic as well as computational, of the catalytic domains for the 23 representative members of the MMP family. A survey of the metal binding sites and two loops containing variable sequences of amino acids, which are important for substrate interactions, are discussed. The collective data support the proposal that the assembly of the domains into multidomain enzymes was likely to be an early evolutionary event. This was followed by diversification, perhaps in parallel among the MMPs, in a subsequent evolutionary time scale. Analysis indicates that a retrograde structure simplification may have accounted for the evolution of MMPs with simple domain constituents, such as matrilysin, from the larger and more elaborate enzymes.—Massova, I., Kotra, L. P., Fridman, R., Mobashery, S. Matrix metalloproteinases: structures, evolution, and diversification. FASEB J. 12, 1075–1095 (1998)

Substrate Hydrolysis by Matrix Metalloproteinase-9*

The catalytic clefts of all matrix metalloproteinases (MMPs) have a similar architecture, raising questions about the redundancy in substrate recognition across the protein family. In the present study, an unbiased phage display strategy was applied to define the substrate recognition profile of MMP-9. Three groups of substrates were identified, each occupying a distinct set of subsites within the catalytic pocket. The most prevalent motif contains the sequence Pro-X-X-Hy-(Ser/Thr) at P3 through P2′. This sequence is similar to the MMP cleavage sites within the collagens and is homologous to substrates the have been selected for other MMPs. Despite this similarity, most of the substrates identified here are selective for MMP-9 over MMP-7 and MMP-13. This observation indicates that substrate selectivity is conferred by key subsite interactions at positions other than P3 and P1′. This study shows that MMP-9 has a unique preference for Arg at both P2 and P1, and a preference for Ser/Thr at P2′. Substrates containing the consensus MMP-9 recognition motif were used to query the protein data bases. A surprisingly limited list of putative physiologic substrates was identified. The functional implications of these proteins lead to testable hypotheses regarding physiologic substrates for MMP-9.

Characterization of the Monomeric and Dimeric Forms of Latent and Active Matrix Metalloproteinase-9 DIFFERENTIAL RATES FOR ACTIVATION BY STROMELYSIN 1

Matrix metalloproteinase-9 (MMP-9) is a member of the MMP family that has been associated with degradation of the extracellular matrix in normal and pathological conditions. A unique characteristic of MMP-9 is its ability to exist in a monomeric and a disulfide-bonded dimeric form. However, there exists a paucity of information on the properties of the latent (pro-MMP-9) and active MMP-9 dimer. Here we report the purification to homogeneity of the monomer and dimer forms of pro-MMP-9 and the characterization of their biochemical properties and interactions with tissue inhibitor of metalloproteinase (TIMP)-1 and TIMP-2. Gel filtration and surface plasmon resonance analyses demonstrated that the pro-MMP-9 monomeric and dimeric forms bind TIMP-1 with similar affinities. In contrast, TIMP-2 binds only to the active forms. After activation, the two enzyme forms exhibited equal catalytic competence in the turnover of a synthetic peptide substrate with comparable kinetic parameters for the onset of inhibition with TIMPs and for dissociation of the inhibited complexes. Kinetic analyses of the activation of monomeric and dimeric pro-MMP-9 by stromelysin 1 revealed K m values in the nanomolar range and relative low k catvalues (1.9 × 10−3 and 4.1 × 10−4s−1, for the monomer and dimer, respectively) consistent with a faster rate (1 order of magnitude) of activation of the monomeric form by stromelysin 1. This suggests that the rate-limiting event in the activation of pro-MMP-9 may be a requisite slow unfolding of pro-MMP-9 near the site of the hydrolytic cleavage by stromelysin 1.

Aminoglycosides Modified by Resistance Enzymes Display Diminished Binding to the Bacterial Ribosomal Aminoacyl-tRNA Site

Understanding the basic principles that govern RNA binding by aminoglycosides is important for the design of new generations of antibiotics that do not suffer from the known mechanisms of drug resistance. With this goal in mind, we examined the binding of kanamycin A and four derivatives (the products of enzymic turnovers of kanamycin A by aminoglycoside-modifying enzymes) to a 27 nucleotide RNA representing the bacterial ribosomal A site. Modification of kanamycin A functional groups that have been directly implicated in the maintenance of specific interactions with RNA led to a decrease in affinity for the target RNA. Overall, the products of reactions catalyzed by aminoglycoside resistance enzymes exhibit diminished binding to the A site of bacterial 16S rRNA, which correlates well with a loss of antibacterial ability in resistant organisms that harbor these enzymes.

Insights into Class D β-Lactamases Are Revealed by the Crystal Structure of the OXA10 Enzyme from Pseudomonas aeruginosa

BACKGROUNDnbeta-lactam antibiotic therapies are commonly challenged by the hydrolytic activities of beta-lactamases in bacteria. These enzymes have been grouped into four classes: A, B, C, and D. Class B beta-lactamases are zinc dependent, and enzymes of classes A, C, and D are transiently acylated on a serine residue in the course of the turnover chemistry. While class A and C beta-lactamases have been extensively characterized by biochemical and structural methods, class D enzymes remain the least studied despite their increasing importance in the clinic.nnnRESULTSnThe crystal structure of the OXA10 class D beta-lactamase has been solved to 1.66 A resolution from a gold derivative and MAD phasing. This structure reveals that beta-lactamases from classes D and A, despite very poor sequence similarity, share a similar overall fold. An additional beta strand in OXA10 mediates the association into dimers characterized by analytical ultracentrifugation. Major differences are found when comparing the molecular details of the active site of this class D enzyme to the corresponding regions in class A and C beta-lactamases. In the native structure of the OXA10 enzyme solved to 1.8 A, Lys-70 is carbamylated.nnnCONCLUSIONSnSeveral features were revealed by this study: the dimeric structure of the OXA10 beta-lactamase, an extension of the substrate binding site which suggests that class D enzymes may bind other substrates beside beta-lactams, and carbamylation of the active site Lys-70 residue. The CO2-dependent activity of the OXA10 enzyme and the kinetic properties of the natural OXA17 mutant protein suggest possible relationships between carbamylation, inhibition of the enzyme by anions, and biphasic behavior of the enzyme.

β-Lactam antibiotics, β-lactamases and bacterial resistance

β-Lactams are the most prescribed antibacterials for the treatment of bacterial infections. Bacteria have developed mechanisms to resist the action of β-lactam drugs, of which the catalytic function of β-lactamase is the most important. These enzymes catalyse hydrolysis of β-lactam antibiotics, whereby the drug is destroyed. This review offers a perspective on the function of these enzymes and their clinical implications.

N-Glycosylation pattern of the zymogenic form of human matrix metalloproteinase-9.

Glycosylation of proteins has profound consequences on the activities of macromolecules and their interactions with inhibitors/substrates. Matrix metalloproteinase-9 (MMP-9, also known as gelatinase B) is a member of the MMP family of zinc-dependent endopeptidases, with critical functions in both physiological and pathological processes. MMP-9, a glycosylated MMP, is implicated in inflammation, angiogenesis and tumor metastasis. We have determined by the use of mass spectrometry that of the three possible N-glycosylation sites in human MMP-9 only two are glycosylated. The N-glycosylation sites are at asparagines in positions 38 and 120, the first site within the propeptide domain of the zymogenic form (pro-MMP-9) of the enzyme and the second in the catalytic domain. The chemical nature of the sugar attachments to both these sites was determined by mass spectrometry. Both N-glycosylation sites have NeuAcalpha(1,2)-Galbeta(1,4)-GlcNAcbeta(1,2)-Manalpha(1,3)-[NeuAcalpha(1,2)-Galbeta(1,4)-GlcNAcbeta(1,2)-Manalpha(1,6)-]Manbeta(1,4)-GlcNAcbeta(1,4)-[Fucalpha(1,6)-]GlcNAcbeta oligosaccharide chains. A computational model of glycosylated pro-MMP-9 was generated and it was studied by dynamics simulations

Hydrolytic Mechanism of OXA-58 Enzyme, a Carbapenem-hydrolyzing Class D β-Lactamase from Acinetobacter baumannii

Background: OXA-58 is a carbapenem-hydrolyzing class D β-lactamase (CHDL) found in Acinetobacter baumannii. Results: OXA-58 exploits a carbamylated lysine in its catalysis. The deacylating water molecule comes from the α-face. Conclusion: CHDLs employ the same hydrolytic machinery as oxacillinases. Structural changes in the active site may lead to imipenem hydrolysis. Significance: This study provides insights for the design of CHDL inactivators. Carbapenem-hydrolyzing class D β-lactamases (CHDLs) represent an emerging antibiotic resistance mechanism encountered among the most opportunistic Gram-negative bacterial pathogens. We report here the substrate kinetics and mechanistic characterization of a prominent CHDL, the OXA-58 enzyme, from Acinetobacter baumannii. OXA-58 uses a carbamylated lysine to activate the nucleophilic serine used for β-lactam hydrolysis. The deacylating water molecule approaches the acyl-enzyme species, anchored at this serine (Ser-83), from the α-face. Our data show that OXA-58 retains the catalytic machinery found in class D β-lactamases, of which OXA-10 is representative. Comparison of the homology model of OXA-58 and the recently solved crystal structures of OXA-24 and OXA-48 with the OXA-10 crystal structure suggests that these CHDLs have evolved the ability to hydrolyze imipenem, an important carbapenem in clinical use, by subtle structural changes in the active site. These changes may contribute to tighter binding of imipenem to the active site and removal of steric hindrances from the path of the deacylating water molecule.

Structural insight into the binding motifs for the calcium ion and the non-catalytic zinc in matrix metalloproteases

The binding motifs for the structural zinc and calcium ions in matrix metalloproteases (MMPs) were investigated by analyzing the three-dimensional structural models of 23 representative MMPs.

Inhibition of the broad spectrum nonmetallocarbapenamase of class A (NMC-A) beta-lactamase from Enterobacter cloacae by monocyclic beta-lactams.

β-Lactamases hydrolyze β-lactam antibiotics, a reaction that destroys their antibacterial activity. These enzymes, of which four classes are known, are the primary cause of resistance to β-lactam antibiotics. The class A β-lactamases form the largest group. A novel class A β-lactamase, named the nonmetallocarbapenamase of class A (NMC-A) β-lactamase, has been discovered recently that has a broad substrate profile that included carbapenem antibiotics. This is a serious development, since carbapenems have been relatively immune to the action of these resistance enzymes. Inhibitors for this enzyme are sought. We describe herein that a type of monobactam molecule of our design inactivates the NMC-A β-lactamase rapidly, efficiently, and irreversibly. The mechanism of inactivation was investigated by solving the x-ray structure of the inhibited NMC-A enzyme to 1.95 Å resolution. The structure shed light on the nature of the fragmentation of the inhibitor on enzyme acylation and indicated that there are two acyl-enzyme species that account for enzyme inhibition. Each of these inhibited enzyme species is trapped in a distinct local energy minimum that does not predispose the inhibitor species for deacylation, accounting for the irreversible mode of enzyme inhibition. Molecular dynamics simulations provided evidence in favor of a dynamic motion for the acyl-enzyme species, which samples a considerable conformational space prior to the entrapment of the two stable acyl-enzyme species in the local energy minima. A discussion of the likelihood of such dynamic motion for turnover of substrates during the normal catalytic processes of the enzyme is presented.