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:3.4.23.16 (HIV-1 protease)
2,107 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The Rous sarcoma virus (RSV) protease S9 variant has been engineered to exhibit high affinity for HIV-1 protease substrates and inhibitors in order to verify the residues deduced to be critical for the specificity differences. The variant has 9 substitutions (S38T, I42D, I44V, M73V, A100L, V104T, R105P, G106V, and S107N) of structurally equivalent residues from HIV-1 protease. Unlike the wild-type enzyme, RSV S9 protease hydrolyzes peptides representing the HIV-1 protease polyprotein cleavage sites. The crystal structure of RSV S9 protease with the inhibitor, Arg-Val-Leu-r-Phe-Glu-Ala-Nle-NH2, a reduced peptide analogue of the HIV-1 CA-p2 cleavage site, has been refined to an R factor of 0.175 at 2.4-A resolution. The structure shows flap residues that were not visible in the previous crystal structure of unliganded wild-type enzyme. Flap residues 64-76 are structurally similar to residues 47-59 of HIV-1 protease. However, residues 61-63 form unique loops at the base of the flaps. Mutational analysis indicates that these loop residues are essential for catalytic activity. Side chains of flap residues His 65 and Gln 63' make hydrogen bond interactions with the inhibitor P3 amide and P4' carbonyl oxygen, respectively. Other interactions of RSV S9 protease with the CA-p2 analogue are very similar to those observed in the crystal structure of HIV-1 protease with the same inhibitor. This is the first crystal structure of an avian retroviral protease in complex with an inhibitor, and it verifies our knowledge of the molecular basis for specificity differences between RSV and HIV-1 proteases.
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PMID:Structural basis for specificity of retroviral proteases. 952 72

A quantitative structure-activity relationship study has been performed on some cyclic cyanoguanidines that inhibit the enzyme HIV-1 protease (HIV-1-PR) and exhibit antiviral potency, and the results have been compared with those of cyclic urea derivatives. Both the enzyme inhibition activity and antiviral potency in cyclic cyanoguanidines as well as in cyclic urea derivatives are found to be primarily governed by hydrophobic property of substituents attached to nitrogen (P2/P2') and further enhanced by OH or NH2 group, if any, present in the substituents. However, aromatic substituents are found to be unfavourable to both the activities of cyclic cyanoguanidines but not to any activity of cyclic urea derivatives. Cyclic urea derivatives are indicated to be more potent than cyclic cyanoguanidines. A model for the interaction of cyclic cyanoguanidines with the receptor is proposed.
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PMID:Quantitative structure-activity relationship studies on cyclic cyanoguanidines acting as HIV-1 protease inhibitors. 1063 65

The basic principles of multichannel devices with an array of electrospray tips for high-throughput infusion electrospray ionization mass spectrometry (ESI-MS) have been developed. The prototype plastic devices were fabricated by casting from a solvent-resistant resin. The sample wells on the device were arranged in the format of the standard 96-microtiter well plate, with each sample well connected to an independent electrospray exit port via a microchannel with imbedded electrode. A second plastic plate with distribution microchannels was employed as a cover plate and pressure distributor. Nitrogen gas was used to pressurize individual wells for transport of sample into the electrospray exit port. The design of independent microchannels and electrospray exit ports allowed very high throughput and duty cycle, as well as elimination of any potential sample carryover. The device was placed on a computer-controlled translation stage for precise positioning of the electrospray exit ports in front of the mass spectrometer sampling orifice. High-throughput ESI-MS was demonstrated by analyzing 96 peptide samples in 480 s, corresponding to a potential throughput of 720 samples/h. As a model application, the device was used for the MS determination of inhibition constants of several inhibitors of HIV-1 protease.
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PMID:Development of multichannel devices with an array of electrospray tips for high-throughput mass spectrometry. 1093 4

High concentrations of salts dramatically affect the interaction of small ligands with HIV-1 protease. For instance, the Km and kcat values for Abz-Thr-Ile-Nle-p-nitro-Phe-Gln-Arg-NH2 (S) increased 120-fold and 3-fold, respectively, as the NaCl concentration in the assay decreased from 4.0 to 0.5 M. The Kd value for the competitive inhibitor amprenavir increased 12-fold over this concentration range of NaCl. The bimolecular rate constant for association of enzyme with amprenavir was independent of NaCl concentration, whereas the dissociation rate constant decreased with increasing NaCl concentration. Polyanionic polymers such as heparin or poly A substituted for NaCl. For example, the value of kcat/Km for S was 0.18 microM(-1) x s(-1) when the enzyme (<10 nM) was assayed in the standard buffer supplemented with 5 mM NaCl. If 0.01% poly A were included, the value of kcat/Km increased to 8.6 microM(-1) x s(-1). A DNA oligomer (23-mer) with an hexachlorofluoresceinyl moiety linked to the 5' end was studied as a model polyanionic polymer. The enzyme bound HF23 (Kd < 1 nM) with concomitant quenching of the hexachlorofluoresceinyl fluorescence. The stoichiometry for binding was 3 mol of enzyme per mol of oligomer. The hydrolytic activity of the enzyme with this oligomer was similar to that observed with poly A or high salt concentration when the molar ratio of oligomer to enzyme was greater than one. The results presented herein demonstrate that polyanionic polymers substitute for salts as effectors of HIV protease.
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PMID:Effectors of HIV-1 protease peptidolytic activity. 1155 Dec 11

HIV-1 encodes an aspartic protease, an enzyme crucial to viral maturation and infectivity. It is responsible for the cleavage of various protein precursors into viral proteins. Inhibition of this enzyme prevents the formation of mature, infective viral particles and therefore, it is a potential target for therapeutic intervention following infection. Several drugs that inhibit the action of this enzyme have been discovered. These include peptidomimetic inhibitors such as ABT-538 and saquinavir, and structure based inhibitors such as indinavir and nelfinavir. Several of these have been tested in human clinical trials and have demonstrated significant reduction in viral load. However, most of them have been found to be of limited clinical utility because of their poor pharmacological properties and also because the viral protease becomes rapidly resistant to these drugs on account of mutations in the enzyme. One way to overcome these limitations is to design an inhibitor that interacts mainly with the conserved residues of HIV-1 protease. By a rational drug design approach based on the high resolution X-ray crystal structure of the HIV-1 protease with--MVT 101 (a substrate based inhibitor) and the specific design principles of peptides containing dehydro-Alanine (delta Ala) derived from our earlier studies, we have designed a tetrapeptide with the sequence: NH2-Thr-delta Ala-delta Ala-Gln-COOH. Energy minimization and molecular modelling of the interaction of the designed tetrapeptide with the inhibitor binding site indicate that the inhibitor is in an extended conformation and makes excessive contacts with the viral enzyme at the interface between the protein subunits. The designed inhibitor has 33% of its interaction with the conserved region of HIV-1 protease which is of the same order as that of MVT 101 with the enzyme.
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PMID:A peptide inhibitor of HIV-1 protease using alpha, beta- dehydro residues: a structure based computer model. 1156 39

A complex structure of HIV-1 protease with a hydroxyethylamine-containing inhibitor Boc-Phe-Psi[(S)-CH(OH)CH2NH]-Phe-Gln-Phe-NH2 has been determined by X-ray diffraction to 1.8 A resolution. The inhibitor is bound in the active site of the protease dimer with its hydroxyethylamine isostere participating in hydrogen bonds to the catalytic aspartates 25 and 25' and glycine 27' of the active site triads via five hydrogen bonds. The isostere amine interactions with the catalytic aspartates result in a displacement of the isostere hydroxy group in comparison with the common position known for analogous hydroxyethylamine containing inhibitors. A comparison with another inhibitor of this series shows that the change of one atom of the P2' side chain (Glu/Gln) leads to an altered ability of creating hydrogen bonds to the active site and within the inhibitor molecule. The diffraction data collected at a synchrotron radiation source enabled a detailed analysis of the complex solvation and of alternative conformations of protein side chains.
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PMID:Hydroxyethylamine isostere of an HIV-1 protease inhibitor prefers its amine to the hydroxy group in binding to catalytic aspartates. A synchrotron study of HIV-1 protease in complex with a peptidomimetic inhibitor. 1190 84

We designed and synthesized a series of water-soluble prodrugs of the HIV-1 protease inhibitor KNI-727 (1), which is a sparingly water-soluble drug with a water solubility of 5.5 microg/mL. These prodrugs, which contain a water-soluble auxiliary with two tandem-linked units, i.e., a self-cleavable spacer and a solubilizing moiety with an ionized amino function, exhibited a marked increase in water solubility (>10(4)-fold) compared with the parent drug 1. The mechanism of conversion to the parent drug 1 is not enzymatic but through a chemical cleavage at the spacer via an intramolecular cyclization-elimination reaction through an imide formation under physiological conditions. To diversify the conversion time for the parent drug regeneration, chemical modification of the auxiliary was carried out focusing on the introduction of cyclic tertiary amines, which can modify the basicity and/or conformational flexibility of the terminal amino function at the solubilizing moiety, and the change in bond length, which can attenuate the five-membered ring intermediate formation in the cleavage. These newly synthesized water-soluble prodrugs exhibited a practical water solubility with values greater than 50 mg/mL and enabled the constant regeneration of the parent drug 1 with diversified conversion times ranging from 4 min to 34 h as t(1/2) values under physiological conditions. All the water-soluble prodrugs tested regenerated the parent drug 1 in vivo as well as in vitro. A clear increase in the gastrointestinal absorption was observed in prodrugs 8, 12, and 13 with bioavailability (BA) values of 23%, 26%, and 29%, respectively. These BA values were 1.5-1.9-fold higher than that in the administration of the parent drug 1 alone. Other prodrugs showed only a similar or decreased BA compared to the parent drug 1. From these results, we found that not only a high water solubility but also an appropriate conversion time of the prodrug with a relatively narrow limit of around 35 min via intraduodenal administration was necessary for significant improvement of the gastrointestinal absorption in water-soluble prodrugs based on the spontaneous chemical cleavage. This is the first successful water-soluble prodrug that suggests an increased BA value greater than the parent drug in HIV-1 protease inhibitors and is the first study to show the importance of optimal conversion time in water-soluble prodrugs. Consequently, a water-soluble strategy that can control the conversion time would be extensively applicable to improve the gastrointestinal absorption of sparingly water-soluble drugs. The present information is an intriguing discovery and is one of the key factors that will contribute to the future design of practical water-soluble prodrugs.
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PMID:Development of water-soluble prodrugs of the HIV-1 protease inhibitor KNI-727: importance of the conversion time for higher gastrointestinal absorption of prodrugs based on spontaneous chemical cleavage. 1295 64

The crystal structure of the complex between human immunodeficiency virus type 1 (HIV-1) protease and a peptidomimetic inhibitor of ethyleneamine type has been refined to R factor of 0.178 with diffraction limit 2.5 A. The peptidomimetic inhibitor Boc-Phe-Psi[CH2CH2NH]-Phe-Glu-Phe-NH2 (denoted here as OE) contains the ethyleneamine replacement of the scissile peptide bond. The inhibitor lacks the hydroxyl group which is believed to mimic tetrahedral transition state of proteolytic reaction and thus is suspected to be necessary for good properties of peptidomimetic HIV-1 protease inhibitors. Despite the missing hydroxyl group the inhibition constant of OE is 1.53 nm and it remains in the nanomolar range also towards several available mutants of HIV-1 protease. The inhibitor was found in the active site of protease in an extended conformation with a unique hydrogen bond pattern different from hydroxyethylene and hydroxyethylamine inhibitors. The isostere nitrogen forms a hydrogen bond to one catalytic aspartate only. The other aspartate forms two weak hydrogen bridges to the ethylene group of the isostere. A comparison with other inhibitors of this series containing isostere hydroxyl group in R or S configuration shows different ways of accommodation of inhibitor in the active site. Special attention is devoted to intermolecular contacts between neighbouring dimers responsible for mutual protein adhesion and for a special conformation of Met46 and Phe53 side chains not expected for free protein in water solution.
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PMID:Role of hydroxyl group and R/S configuration of isostere in binding properties of HIV-1 protease inhibitors. 1556 Jul 86

Icosahedral heteroboranes and especially metallacarboranes, which have recently been shown to act as potent HIV-1 protease inhibitors, are a unique class of chemical compounds with unusual properties, one of which is the formation of dihydrogen bonds with biomolecules. In this study, we investigate the effect of various metal vertices and exo-substitutions on several series of heteroboranes, including 11-vertex carborane cages [nido-7,8-C2B9Hn]n-13(n= 11,12,13), closo-1-SB11H11, closo-1-NB11H12, metal bis(dicarbollides)[3,3'-M (1,2-C2B9H11)2]n(M/n=Fe/2-, Co/1-, Ni/0) and fluoro (F), amino (NH2) and hydroxo (OH) derivatives of the metal bis(dicarbollides). Besides the properties of isolated systems (geometries, electronic properties and hydration), we study their interactions with a tetrapeptide, which models their biomolecular partner. Calculations have confirmed that the extra hydrogen in [nido-7,8-C2B9H12]- forms a bridge, which fluctuates between two stationary states. Using RESP-derived charges, it was ascertained that the negative charge of heteroboranes is located mainly on boron-bound hydrogens. An increase of the negative total charge (from 0 to -1 or -2) of heteroboranes yields an increase in the stabilisation energies of heteroborane[dot dot dot]peptide complexes and also a substantial increase in the hydration free energies of heteroboranes. Compared to the substitutions of metal vertices, the exo-substitutions of metallacarboranes cause a larger increase in stabilisation energies and a smaller increase in desolvation penalties. These two terms, stabilisation energies and desolvation penalties, contribute in opposite directions to the total heteroborane-biomolecule binding energy and must both be taken into account when designing new HIV-1 protease inhibitors.
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PMID:Interaction of heteroboranes with biomolecules. Part 2. The effect of various metal vertices and exo-substitutions. 1746 89


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