Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
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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)
J Mol Biol 1993 Feb 20
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

Insulin-degrading enzyme is a nonlysosomal metalloprotease that initiates degradation of internalized insulin in some cells. We previously identified a potential catalytic site containing an inversion of the Zn(2+)-binding domain of the thermolysin family (Kuo, W.-L., Gehm, B. D., and Rosner, M. R. (1991) Mol. Endocrinol. 4, 1580-1591). The role of this site in catalysis was examined by mutating one of the presumptive Zn(2+)-coordinating histidines (His108) in human insulin-degrading enzyme to leucine or glutamine, which were predicted to reduce or eliminate Zn2+ binding without substantially altering secondary structure. cDNAs for the mutant and wild-type enzymes were incorporated into an expression vector and transfected into COS cells. Expression of the transfected genes was confirmed by Northern and Western blots. In contrast to the wild-type gene, which increased insulin degradation by cell extracts and intact cells several-fold, the mutated genes had no effect on insulin degradation, indicating a loss of catalytic activity. However, the mutants' ability to bind substrate was unimpaired, as affinity labeling with 125I-insulin was increased compared to the wild type. These results suggest that an intact Zn(2+)-binding domain in human insulin-degrading enzyme is required for catalytic activity and can affect, but is not required for, substrate binding.
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PMID:Mutations in a zinc-binding domain of human insulin-degrading enzyme eliminate catalytic activity but not insulin binding. 846 15

A backbone-dependent rotamer library for amino acid side-chains is developed and used for constructing protein side-chain conformations from the main-chain co-ordinates. The rotamer library is obtained from 132 protein chains in the Brookhaven Protein Database. A grid of 20 degrees by 20 degrees blocks for the main-chain angles phi, psi is used in the rotamer library. Significant correlations are found between side-chain dihedral angle probabilities and backbone phi, psi values. These probabilities are used to place the side-chains on the known backbone in test applications for six proteins for which high-resolution crystal structures are available. A minimization scheme is used to reorient side-chains that conflict with the backbone or other side-chains after the initial placement. The initial placement yields 59% of both chi 1 and chi 2 values in the correct position (to within 40 degrees) for thermolysin to 81% for crambin. After refinement the values range from 61% (lysozyme) to 89% (crambin). It is evident from the results that a single protein does not adequately test a prediction scheme. The computation time required by the method scales linearly with the number of side-chains. An initial prediction from the library takes only a few seconds of computer time, while the iterative refinement takes on the order of hours. The method is automated and can easily be applied to aid experimental side-chain determinations and homology modeling. The high degree of correlation between backbone and side-chain conformations may introduce a simplification in the protein folding process by reducing the available conformational space.
J Mol Biol 1993 Mar 20
PMID:Backbone-dependent rotamer library for proteins. Application to side-chain prediction. 846 64

A program is described that searches three-dimensional, structural databases, given a user-defined query, in order to retrieve all structures that contain any combination of a user-specified minimum number of matching elements. Queries consist of three-dimensional coordinates of atoms and/or bonds. Numerous query constraints are described which allow the investigator to define the chemical nature of the desired structures as well as the environment within which these structures must reside. They include: (1) Bonded vs. isolated atom distinction; (2) Atom type designation; (3) Definition of subsets with occupancy specification (>, =, < X atoms); (4) RMS-fit; (5) Active site volume accessibility of atoms linking query elements; (6) Number, atom type, and cyclic structure constraints for atoms linking pharmacophoric elements; (7) Automatic error boundary adjustment--ad infinitum constraint. To illustrate the capabilities of this program, queries based on the crystal structure of a thermolysin-inhibitor complex were tested against a subset of the Cambridge Crystallographic Database. Several compounds were returned which satisfied various aspects of the query, including fitting within the active site. Combination of segments of compounds which satisfy partial queries should provide a method for generating unique compounds with affinity for sites of known three-dimensional structure.
J Comput Aided Mol Des 1993 Feb
PMID:FOUNDATION: a program to retrieve all possible structures containing a user-defined minimum number of matching query elements from three-dimensional databases. 847 17

Proteases with trypsin-, chymotrypsin- and thermolysin-like specificity were detected in Culex quinquefasciatus larval midguts. Their activities were monitored by N-terminal amino acid sequence analysis of the Bacillus thuringiensis subsp. israelensis CryIVD toxin proteolytic fragments. These proteases are located in the larval midgut and in different fractions obtained during the preparation of brush border membrane vesicles. The activity of the midgut proteases increased with an increase in pH. Both the chymotrypsin- and thermolysin-like activities are involved in the processing of solubilized CryIVD toxin, whereas an additional trypsin-like protease is necessary for the CryIVD parasporal inclusion processing. The solubilized CryIVD toxin was first cleaved between Thr347 and Phe348 and between Phe348 and Tyr349, generating a 40-kDa N-terminal fragment and a 32.5-kDa C-terminal fragment. The C-terminal domain was resistant to further processing, with only a small amount of a 31-kDa product appearing due to the action of a thermolysin-like protease. However, the N-terminal domain was very unstable, and was further degraded to about 30 kDa. Unlike the solubilized CryIVD toxin, the processing of the CryIVD parasporal inclusion was very slow at neutral pH. Three protease-resistant products were detected at pHs higher than 9.5 with an overnight incubation at 37 degrees C. The 30- and 28.5-kDa C-terminal peptides are proteolytic products of trypsin- and chymotrypsin-like proteases, respectively; while the 28-kDa N-terminal peptide has 27 amino acids deleted from the N-terminal end by a thermolysin-like protease.
Insect Biochem Mol Biol 1993 Mar
PMID:In vitro and in vivo proteolysis of the Bacillus thuringiensis subsp. israelensis CryIVD protein by Culex quinquefasciatus larval midgut proteases. 848 24

Ca2+ regulates muscle contraction by reversible binding to troponin C (TnC), the Ca(2+)-binding subunit of troponin complex. In order to identify acidic amino acids exposed on its surface, carboxyl groups in TnC were activated with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide, then labeled with dinitrophenylethylenediamine. Labeled protein was then digested with trypsin and thermolysin, and the resulting peptides were purified by HPLC. Modified peptides were detected by their specific absorbance at 360 nm, and labeled amino acids in these peptides were identified by sequence analysis. Although the total incorporation of label into TnC was only 2.6 mol/mol, we found that 14 of the 46 carboxyl groups of TnC were partially labeled. The labeled carboxyl groups were located in surface regions of the known three-dimensional structure of TnC which may interact with other components of the troponin complex.
Biochem Mol Biol Int 1996 Mar
PMID:Identification of reactive carboxyl groups in troponin C. 882 5

Escherichia coli peptide deformylase, a member of the zinc metalloproteases family, is made up of an active core domain composed of 147 residues and of an additional and dispensable C-terminal tail of 21 residues. The three-dimensional structure of the catalytic core could be studied by NMR. 1H and 15N NMR resonances assignments were obtained by two-dimensional and three-dimensional heteronuclear spectroscopy. The structure could be calculated using a set of 1015 restraints for the 147 residues of the enzyme. The overall structure is composed of a series of antiparallel beta-strands which surround two perpendicular alpha-helices. The C-terminal helix contains the HEXXH motif, which is crucial for activity. This helical arrangement and the way the histidines bind the zinc ion clearly are structurally reminiscent of the other members of the metalloprotease family, such as thermolysin or metzincins. Nevertheless, the overall arrangement of secondary and tertiary structures of peptide deformylase and the positioning of its third zinc ligand (a cysteine) are quite different from those of the other members of the family. These discrepancies, together with several biochemical differences, lead us to propose that peptide deformylase is the first example of a new class of the zinc-metalloproteases family. Studies of the interaction of peptide deformylase with either an inhibitor of the reaction or a product of the catalysed reaction, Met-Ala-Ser, as well as comparisons with the structures of other enzymes of the family, have enabled us to delineate the area corresponding to their binding site. The structural basis of the specificity of recognition of the formyl group is discussed in the context of the protease superfamily.
J Mol Biol 1996 Sep 27
PMID:A new subclass of the zinc metalloproteases superfamily revealed by the solution structure of peptide deformylase. 884 3

The computer program LUDI for the de novo design of protein ligands was extended so that it is now able to take into account the synthetic accessibility of the constructed molecules. As an example, the design of peptides, amides and peptidomimetics using amino acids as building blocks is described. Two new libraries containing natural and non-natural amino acids were constructed for this purpose. Conformational flexibility is taken into account by using multiple conformers for each amino acid. The program was applied to the design of ligands for the enzymes elastase, renin and thermolysin.
J Comput Aided Mol Des 1996 Aug
PMID:Towards the automatic design of synthetically accessible protein ligands: peptides, amides and peptidomimetics. 887 98

We report a theoretical characterization of the intermolecular transferred NOESY (inter-TrNOESY) between ligands and receptor macromolecules that bind reversibly, using a COmplete Relaxation and Conformational Exchange MAtrix (CORCEMA) theory developed in our laboratory. We examine the dependence of inter-TrNOESY on the dissociation constant, off-rate, ligand-to-receptor ratio, and distance variations between protons of interacting species within the complex. These factors are analyzed from simulations on two model systems: (i) neuraminidase complexed to a transition-state analogue; and (ii) thermolysin complexed to a leucine-based inhibitor. The latter case utilizes a three-state model of interaction to simulate the effect of hinge-bending motions on the inter-TrNOESY. Our calculations suggest a potential role for inter-TrNOESY (when observable) and CORCEMA analysis in properly docking the ligand within the active site, and in refining the conformation of the ligand-receptor (active-site) complex. These findings have implications on the structure-based design of ligands (e.g., inhibitors) reversibly binding to receptors (e.g., enzymes).
J Comput Aided Mol Des 1996 Oct
PMID:CORCEMA evaluation of the potential role of intermolecular transferred NOESY in the characterization of ligand-receptor complexes. 895 48

We show here that limited proteolysis can probe the structural and dynamic differences between the holo and apo form of horse myoglobin (Mb). Initial nicking of the polypeptide chain of apoMb (153 amino acid residues, no disulfide bonds) by several proteases (subtilisin, thermolysin, chymotrypsin and trypsin) occurs at the level of chain segment 89-96. In contrast, holoMb is resistant to proteolytic digestion when reacted under identical experimental conditions. Such selective proteolysis implies that the F-helix of native holoMb (residues 82 to 97) is disordered in apoMb, thus enabling binding and adaptation of this chain segment at the active site of the proteolytic enzymes for an efficient peptide bond fission. That essentially only the F-helix in apoMb is largely disrupted was earlier inferred from spectroscopic measurements and molecular dynamics simulations. The results of this study provide direct experimental evidence for this and emphasize therefore that limited proteolysis is a useful and reliable method for probing structure and dynamics of proteins, complementing other experimental techniques such as NMR and X-ray crystallography.
J Mol Biol 1997 Feb 21
PMID:Probing the conformational state of apomyoglobin by limited proteolysis. 904 59


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