Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.24.27 (thermolysin)
1,894 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Adamalysin II, a 24 kDa zinc endopeptidase from the snake venom of Crotalus adamanteus, is a member of a large family of metalloproteinases isolated as small proteinases or proteolytic domains of mosaic haemorrhagic proteins from various snake venoms. Homologous domains have recently been detected in multimodular mammalian reproductive tract proteins. The 2.0 A crystal structure of adamalysin II reveals an ellipsoidal molecule with a shallow active-site cleft separating a relatively irregularly folded subdomain from the calcium-binding main molecular body composed of a five-stranded beta-sheet and four alpha-helices. The folding of the peptide fragment containing the zinc-binding motif HExxHxxGxxH bears only a distant resemblance to thermolysin, but is identical to that found in astacin, with the three histidines and a water molecule (linked to the glutamic acid) likewise constituting the zinc ligand; adamalysin II lacks a fifth (tyrosine) zinc ligand, however, leaving its zinc ion tetrahedrally co-ordinated. Furthermore, adamalysin II and astacin share an identical active-site basement formed by a common Metturn. Due to their virtually identical active-site environment and similar folding topology, the snake venom metalloproteinases (hitherto called adamalysins) and the astacins (and presumably also the matrix metalloproteinases/mammalian collagenases and the Serratia proteinase-like large bacterial proteinases) might be grouped into a common superfamily with distinct differences from the thermolysin family.
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PMID:First structure of a snake venom metalloproteinase: a prototype for matrix metalloproteinases/collagenases. 822 30

Bacillus neutral proteases (NPs) form a group of well-characterized homologous enzymes, that exhibit large differences in thermostability. The three-dimensional (3D) structures of several of these enzymes have been modelled on the basis of the crystal structures of the NPs of B. thermoproteolyticus (thermolysin) and B. cereus. Several new techniques have been developed to improve the model-building procedures. Also a 'model-building by mutagenesis' strategy was used, in which mutants were designed just to shed light on parts of the structures that were particularly hard to model. The NP models have been used for the prediction of site-directed mutations aimed at improving the thermostability of the enzymes. Predictions were made using several novel computational techniques, such as position-specific rotamer searching, packing quality analysis and property-profile database searches. Many stabilizing mutations were predicted and produced: improvement of hydrogen bonding, exclusion of buried water molecules, capping helices, improvement of hydrophobic interactions and entropic stabilization have been applied successfully. At elevated temperatures NPs are irreversibly inactivated as a result of autolysis. It has been shown that this denaturation process is independent of the protease activity and concentration and that the inactivation follows first-order kinetics. From this it has been conjectured that local unfolding of (surface) loops, which renders the protein susceptible to autolysis, is the rate-limiting step. Despite the particular nature of the thermal denaturation process, normal rules for protein stability can be applied to NPs. However, rather than stabilizing the whole protein against global unfolding, only a small region has to be protected against local unfolding. In contrast to proteins in general, mutational effects in proteases are not additive and their magnitude is strongly dependent on the location of the mutation. Mutations that alter the stability of the NP by a large amount are located in a relatively weak region (or more precisely, they affect a local unfolding pathway with a relatively low free energy of activation). One weak region, that is supposedly important in the early steps of NP unfolding, has been determined in the NP of B. stearothermophilus. After eliminating this weakest link a drastic increase in thermostability was observed and the search for the second-weakest link, or the second-lowest energy local unfolding pathway is now in progress. Hopefully, this approach can be used to unravel the entire early phase of unfolding.
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PMID:Prediction and analysis of structure, stability and unfolding of thermolysin-like proteases. 822 92

We have characterized an in vitro skin model consisting of neonatal keratinocytes and fibroblasts grown on a nylon mesh. To produce a dermal model, fibroblasts were seeded onto nylon mesh and grown for 4 weeks until a physiologic dermal-like matrix was formed. This matrix was found to consist of collagens I and III, fibronectin, and glycosaminoglycans. Keratinocytes were then seeded onto the dermal model and the co-culture was grown at the air/liquid interface. A differentiated epidermis with distinct basal, spinous, granular, and stratum corneum layers was formed. When incubated in the presence of keratinocytes, fibronectin immunofluorescence increased throughout the dermis compared to cultures incubated similarly in the absence of keratinocytes. A basement membrane zone rich in laminin, collagen IV, and heparan sulfate proteoglycan was detected. The epidermis, isolated from the co-culture by thermolysin digestion, was analyzed for differentiation markers. K1 keratin (67-kDa) and involucrin were detected by immunologic techniques. Ceramide lipids (types III and IV), thought to be important in barrier function, were detected by thin-layer chromatography. The permeability of the co-culture to a panel of compounds, including [3H]-water, was determined using Franz and side-by-side diffusion cells. The permeability coefficient for water was of the same order of magnitude as that determined for neonatal foreskin. The co-culture also showed selective permeability to a panel of compounds of differing lipid solubility. This co-culture metabolized [3H]-testosterone to a profile of metabolites similar to that of neonatal foreskin. We believe that this in vitro skin model will be useful for the study of drug permeability and metabolism.
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PMID:Characterization, barrier function, and drug metabolism of an in vitro skin model. 842 93

The propensity of the peptide fragments 233-248, 245-260, 258-276, 279-298 and 299-316 from the thermolysin C-terminal domain to form non-random structures has been examined by CD and two-dimensional NMR spectroscopy. The conformational properties of these fragments have been studied in aqueous solution and in the mixed solvent trifluoroethanol/H2O (3:7 by vol.). Small but detectable populations of helical structures (up to 10-20%) in aqueous solution have been found for the fragments 233-248, 279-298 and 299-316. These populations are remarkably enhanced (50-70%) in the more hydrophobic mixed solvent, where the fragment 258-276 also forms a comparable helical population. These four fragments are helical in the native crystal structure and the spanning of the corresponding helices in the isolated peptides in solution matches very closely the ones in the native structure. In contrast, the fragment 245-260, an omega-loop in the crystal, remains unstructured in both solvents. Medium-range NOE between protons in sidechains indicate the adoption of preferred sidechain conformations accompanying helix formation. Results are in agreement with the framework model of folding, in which native elements of secondary structure are formed first and folding follows from the collapse of these structural elements.
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PMID:CD and 1H-NMR studies on the conformational properties of peptide fragments from the C-terminal domain of thermolysin. 843 16

Astacin, a 200 residue digestive zinc-endopeptidase from the crayfish Astacus astacus L., is the prototype of the "astacin family", which comprises several membrane-bound mammalian endopeptidases and developmentally implicated regulatory proteins. Large trigonal crystals of astacin were grown, and X-ray reflection data to 1.8 A resolution were collected. The astacin structure has been solved by multiple isomorphous replacement using six heavy-atom derivatives, and refined to a crystallographic R-value of 0.158 applying stringent constraints. All 200 residues are clearly defined by electron density; 181 solvent molecules have been localized. Besides the native structure, the structures of Hg-astacin (with a mercury ion replacing the zinc) and of the apoenzyme were also refined. The astacin molecule exhibits a kidney-like shape. It consists of an amino-terminal and a carboxy-terminal domain, with a deep active-site cleft in between. The zinc ion, located at the bottom of this cleft, is co-ordinated in a novel trigonal-bipyramidal geometry by three histidine residues, a tyrosine and by a water molecule, which is also bound to the carboxylate side-chain of Glu93. The amino-terminal domain of astacin consists mainly of two long alpha-helices, one centrally located and one more peripheral, and of a five-stranded pleated beta-sheet. The amino terminus protrudes into an internal, water-filled cavity of the lower domain and forms a buried salt bridge with Glu103; amino-terminally extended pro-forms of astacin are thus not compatible with this structure. The carboxy-terminal domain of astacin is mainly organized in several turns and irregular structures. Because they share sequence identity of about 35%, the structures of the proteolytic domains of the other "astacin" members must be quite similar to astacin. Only a few very short deletions and insertions quite distant from the active-site distinguish their structures from astacin. The five-stranded beta-sheet and the two helices of the amino-terminal domain of astacin are topologically similar to the structure observed in the archetypal zinc-endopeptidase thermolysin; the rest of the structures are, in contrast, completely unrelated in astacin and thermolysin. The zinc ion, the central alpha-helix and the zinc-liganding residues His92, Glu93 and His96 of astacin are nearly superimposable with the respective groups of thermolysin, namely with the zinc ion, the "active-site helix", and His142TL, Glu143TL and His146TL of the zinc-binding consensus motif His-Glu-Xaa-Xaa-His (where Xaa is any amino acid residue).(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Refined 1.8 A X-ray crystal structure of astacin, a zinc-endopeptidase from the crayfish Astacus astacus L. Structure determination, refinement, molecular structure and comparison with thermolysin. 844 58

Native thermolysin binds a single catalytically essential zinc ion that is tetrahedrally coordinated by three protein ligands and a water molecule. During catalysis the zinc ligation is thought to change from fourfold to fivefold. Substitution of the active-site zinc with Cd2+, Mn2+, Fe2+, and Co2+ alters the catalytic activity (Holmquist B, Vallee BL, 1974, J Biol Chem 249:4601-4607). Excess zinc inhibits the enzyme. To investigate the structural basis of these changes in activity, we have determined the structures of a series of metal-substituted thermolysins at 1.7-1.9 A resolution. The structure of the Co(2+)-substituted enzyme is shown to be very similar to that of wild type except that two solvent molecules are liganded to the metal at positions that are thought to be occupied by the two oxygens of the hydrated scissile peptide in the transition state. Thus, the enhanced activity toward some substrates of the cobalt-relative to the zinc-substituted enzyme may be due to enhanced stabilization of the transition state. The ability of Zn2+ and Co2+ to accept tetrahedral coordination in the Michaelis complex, as well as fivefold coordination in the transition state, may also contribute to their effectiveness in catalysis. The Cd(2+)- and Mn(2+)-substituted thermolysins display conformational changes that disrupt the active site to varying degrees and could explain the associated reduction of activity. The conformational changes involve not only the essential catalytic residue, Glu 143, but also concerted side-chain rotations in the adjacent residues Met 120 and Leu 144. Some of these side-chain movements are similar to adjustments that have been observed previously in association with the "hinge-bending" motion that is presumed to occur during catalysis by the zinc endoproteases. In the presence of excess zinc, a second zinc ion is observed to bind at His 231 within 3.2 A of the zinc bound to native thermolysin, explaining the inhibitory effect.
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PMID:Structural analysis of zinc substitutions in the active site of thermolysin. 853 32

Perturbed angular correlation of gamma-rays (PAC) spectroscopy has been used to investigate the angiotensin-I-converting enzyme (ACE) of rabbit lung. By substituting the zinc ions in ACE with excited 111mCd2+ ions, analysis of PAC spectra gave directly the percentage of cadmium ions bound to ACE. The result of the analysis was a dissociation constant of about 1 microM for the cadmium-ACE complex, and a stoichiometry of two moles cadmium/mole enzyme. Cadmium binding is thus about two orders of magnitude weaker than zinc binding to ACE but two orders of magnitude stronger than cobalt binding. PAC spectra monitor the nuclear quadrupole interaction (NQI) for 111mCd. The NQI for ACE exhibits very low frequencies in the PAC spectra with a rather large spectral broadening. In the presence of the inhibitor ramiprilat, the frequencies increase but the spectral broadening is about the same as for ACE without inhibitor. When the inhibitor captopril is added, very high frequencies are obtained consistent with sulfur binding, but now with a narrower distribution of NQI's. A simple molecular orbital analysis of the obtained NQI's has been performed, using a coordination sphere of two His, one Glu residue and a solvent ligand, equivalent to the zinc ligands in thermolysin and carboxypeptidase. The calculated spectral parameters could be modelled with the measured parameters if the solvent ligand is H2O in free ACE, carboxylate from ramiprilat in the ACE-ramiprilat complex and a mercapto group in the ACE-captopril complex. The coordination geometry for cadmium carboxypeptidase obtained by X-ray diffraction gives a calculated set of NQI parameters consistent with the measured parameters for cadmium in the captopril-ACE complex using a mercapto group as the solvent ligand. However, for ACE and its complex with ramiprilat, a significant distortion of the cadmium geometry for carboxypeptidase A had to be adopted in order to calculate NQI's close to the experimental values.
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PMID:Effect of inhibitors on the coordination geometries of cadmium at the metal sites in angiotensin-I-converting enzyme. 857 35

Cleavage by thermolysin of N-(4-methoxyphenylazoformyl)-L-leucyl-L-leucine plus some congeneric peptides provides a highly sensitive new kinetic assay for proteolytic activity. The pH dependence of Michaelis-Menten parameters Kcat and Km establishes kinetically a reverse protonation catalytic mechanism for this metalloprotease [Mock, W.L., & Aksamawati, M. (1994) Biochem. J. 302, 57-68]. An acidified water molecule (pKa of 5, seen in Km) becomes displaced by substrate carboxamide from the hypercationic Zn2+ of the enzyme, yielding potent Lewis acid activation of the peptide linkage for subsequent hydrolysis. Conversion to product is induced by the side chain of enzymic residue His 231 (pKa of 8, seen in Kcat), which provides general base catalysis for addition of H2O to the zinc-activated scissile carboxamide of the bound substrate. A previously described "superactivation" through chemical modification of the enzyme with acetylphenylalanyl-N-hydroxysuccinimide is nonexistent in the case of the new substrates, which indicates that their binding to thermolysin is largely productive, unlike normal peptides. Correct assignment of kinetically observed pKa values to active site residues, along with recognition of a predominantly nonproductive binding mode for ordinary substrates and thermolysin, forces reinterpretation of previous mechanistic formulations for the enzyme.
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PMID:Arazoformyl dipeptide substrates for thermolysin. Confirmation of a reverse protonation catalytic mechanism. 865 13

Tetanus and botulinum neurotoxins constitute a new group of Zn-endopeptidases which has been recently actively investigated with the purpose of correlating their biochemical properties to their neurobiocytosis inhibitory capacity. Crystallographic data show that Zn-endopeptidases are characterized by an active site with a Zn atom coordinated to two histidines and glutamate-bound water molecule. The two histidines and glutamate resides belong to the HEXXH motif which is characteristic of most Zn-endopeptidases. A forth metal ligand is a glutamate in thermolysin-like proteinases, but it is an histidine in the astacin family of proteinases and in alkaline protease. Astacin and alkaline protease possess a tyrosine as fifth Zn ligand, whose position in the case of alkaline protease could not be determined by X-ray crystallography. Not much is known about the atom arrangement around the active site in tetanus neurotoxin. In this work X-ray absorption spectroscopy has been used to obtain information on the Zn coordination mode in tetanus neurotoxin. The near-edge and extended fine-structure absorption spectra of this toxin are compared with those of astacin, alkaline protease and thermolysin. The present data and sequence information suggest a new pattern of Zn coordination in tetanus neurotoxin with one water molecule and three aromatic residues as metal ligands. These residues are the two histidines of the characteristic motif and a tyrosine which is tentatively identified with Tyr242, on the basis of sequence comparison and mutagenesis experiments. The mean distances of the Zn from the nearest coordinated atoms is reported. Our results indicate that alkaline protease, like astacin, also possesses a tyrosine as a fifth ligand.
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PMID:X-ray absorption spectroscopy study of zinc coordination in tetanus neurotoxin, astacin, alkaline protease and thermolysin. 865 8

The thermostable sweet protein brazzein consists of 54 amino acid residues and has four intramolecular disulfide bonds, the location of which is unknown. We found that brazzein resists enzymatic hydrolysis at enzyme/substrate ratios (w/w) of 1:100-1:10 at 35-40 degrees C for 24-48 h. Brazzein was hydrolyzed using thermolysin at an enzyme/substrate ratio of 1:1 (w/w) in water, pH 5.5, for 6 h and at 50 degrees C. The disulfide bonds were determined, by a combination of mass spectrometric analysis and amino acid sequencing of cystine-containing peptides, to be between Cys4-Cys52, Cys16-Cys37, Cys22-Cys47, and Cys26-Cys49. These disulfide bonds contribute to its thermostability.
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PMID:Assignment of the disulfide bonds in the sweet protein brazzein. 886 15


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