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 activity of the avian myeloblastosis virus (AMV) or the human immunodeficiency virus type 1 (HIV-1) protease on peptide substrates which represent cleavage sites found in the gag and gag-pol polyproteins of Rous sarcoma virus (RSV) and HIV-1 has been analyzed. Each protease efficiently processed cleavage site substrates found in their cognate polyprotein precursors. Additionally, in some instances heterologous activity was detected. The catalytic efficiency of the RSV protease on cognate substrates varied by as much as 30-fold. The least efficiently processed substrate, p2-p10, represents the cleavage site between the RSV p2 and p10 proteins. This peptide was inhibitory to the AMV as well as the HIV-1 and HIV-2 protease cleavage of other substrate peptides with Ki values in the 5-20 microM range. Molecular modeling of the RSV protease with the p2-p10 peptide docked in the substrate binding pocket and analysis of a series of single-amino acid-substituted p2-p10 peptide analogues suggested that this peptide is inhibitory because of the potential of a serine residue in the P1' position to interact with one of the catalytic aspartic acid residues. To open the binding pocket and allow rotational freedom for the serine in P1', there is a further requirement for either a glycine or a polar residue in P2' and/or a large amino acid residue in P3'. The amino acid residues in P1-P4 provide interactions for tight binding of the peptide in the substrate binding pocket.
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PMID:Mechanism of inhibition of the retroviral protease by a Rous sarcoma virus peptide substrate representing the cleavage site between the gag p2 and p10 proteins. 133 Oct 99

Retroviruses encode proteinases necessary for the proteolytic processing of the viral gag and gag-pol precursor proteins. These enzymes have been shown to be structurally and functionally related to aspartyl proteinases such as pepsin and renin. Cerulenin is a naturally occurring antibiotic, commonly used as an inhibitor of fatty acid synthesis. Cerulenin has been observed to inhibit production of Rous sarcoma virus and murine leukaemia virus by infected cells, possibly by interfering with proteolytic processing of viral precursor proteins. We show here that cerulenin inhibits the action of the HIV-1 proteinase in vitro, using 3 substrates: a synthetic heptapeptide (SQNYPIV) which corresponds to the sequence at the HIV-1 gag p17/p24 junction, a bacterially expressed gag precursor, and purified 66 kDa reverse transcriptase. Inhibition of cleavage by HIV-1 proteinase required preincubation with cerulenin. Cerulenin also inactivates endothiapepsin, a well-characterised fungal aspartyl proteinase, suggesting that the action of cerulenin is a function of the common active site structure of the retroviral and aspartic proteinases. Molecular modelling suggests that cerulenin possesses several of the necessary structural features of an inhibitor of aspartyl proteinases and retroviral proteinases. Although cerulenin itself is cytotoxic and inappropriate for clinical use, it may provide leads for the rational design of inhibitors of the HIV proteinase which could have application in the chemotherapy of AIDS.
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PMID:In vitro inhibition of HIV-1 proteinase by cerulenin. 169 Jan 52

The model of human immunodeficiency virus (HIV-1) protease which was based on the crystal structure of Rous sarcoma virus (RSV) protease has been compared to the recently determined crystal structure of chemically synthesized HIV-1 protease. The overall difference between the model and crystal structure was 1.4 A root mean square (rms) deviation for 86 superimposed C alpha atoms. The position of the flexible flap differs in the model and six residues at the amino terminus were incorrectly placed. With these exceptions, all atoms of the model and crystal structure agree to 2.1 A rms deviation. The conformation of some surface bends in the model agrees less well with the crystal structure. Identical amino acids in RSV and HIV proteases were modeled more reliably than different types of amino acids. The amino acids which form the substrate binding site were modeled most accurately to 1.2 A rms deviation for all atoms compared to the crystal structure. This suggests that functionally significant regions of related proteins can be modeled with high accuracy. The model gave correct predictions for residues making interactions with the substrate, and therefore could be used to design inhibitors. The model based on the RSV protease structure is more similar to the experimental structure than are previous models based on the structures of non-viral aspartic proteases.
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PMID:Evaluation of homology modeling of HIV protease. 215 92

In avian cells, the product of the gag gene of Rous sarcoma virus, Pr76gag, has been shown to be targeted to the plasma membrane, to form virus particles, and then to be processed into mature viral gag proteins. To explore how these phenomena may be dependent upon cellular (host) factors, we expressed the Rous sarcoma virus gag gene in a lower eucaryote, Saccharomyces cerevisiae, and studied the behavior of the gag gene product. We show here that Pr76gag is processed in yeast cells and that this processing is specific, since it is abolished in a mutant in which the active site of the gag protease has been destroyed. In this mutant, the uncleaved precursor is found associated with the yeast plasma membrane, yet no virus particles were detected in cells or in the culture medium. From our results, we can speculate either that in yeast cells, a host protease initiates Pr76gag processing in the cytosol or that in avian cells, an inhibitor prevents the processing until the viral particle is formed.
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PMID:Rous sarcoma virus expression in Saccharomyces cerevisiae: processing and membrane targeting of the gag gene product. 217 Jun 88

The human immunodeficiency virus (HIV-1) encodes a protease that is essential for viral replication and is a member of the aspartic protease family. The recently determined three-dimensional structure of the related protease from Rous sarcoma virus has been used to model the smaller HIV-1 dimer. The active site has been analyzed by comparison to the structure of the aspartic protease, rhizopuspepsin, complexed with a peptide inhibitor. The HIV-1 protease is predicted to interact with seven residues of the protein substrate. This information can be used to design protease inhibitors and possible antiviral drugs.
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PMID:Molecular modeling of the HIV-1 protease and its substrate binding site. 253 31

The rational design of drugs that can inhibit the action of viral proteases depends on obtaining accurate structures of these enzymes. The crystal structure of chemically synthesized HIV-1 protease has been determined at 2.8 angstrom resolution (R factor of 0.184) with the use of a model based on the Rous sarcoma virus protease structure. In this enzymatically active protein, the cysteines were replaced by alpha-amino-n-butyric acid, a nongenetically coded amino acid. This structure, in which all 99 amino acids were located, differs in several important details from that reported previously by others. The interface between the identical subunits forming the active protease dimer is composed of four well-ordered beta strands from both the amino and carboxyl termini and residues 86 to 94 have a helical conformation. The observed arrangement of the dimer interface suggests possible designs for dimerization inhibitors.
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PMID:Conserved folding in retroviral proteases: crystal structure of a synthetic HIV-1 protease. 254 79

Retroviral proteases belong to the class of aspartic proteases. A molecular model of HIV-1 protease has been built on the basis of the consensus template specific for the domains of these enzymes. The template region comprises more than a half of the HIV-1 protease monomer structure, it includes the active site, formed at the junction of the two monomers, binding pockets of the enzyme, and some other molecular segments. These regions can be more conveniently described than other parts of the structure. Some properties of the HIV-1 protease molecule are discussed, as well as of probable inhibitors. The properties of the model structure are in good agreement with the recent results of crystallographic studies of Rous sarcoma virus protease.
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PMID:Possible role of some groups in the structure and function of HIV-1 protease as revealed by molecular modeling studies. 265 Nov 58

HIV-1, the causative agent of AIDS, encodes a protease that processes the viral polyproteins into the structural proteins and replicative enzymes found in mature virions. Protease activity has been shown to be essential for the proper assembly and maturation of fully infectious HIV-1. Thus, the HIV-1 protease (HIV PR) has become an important target for the design of antiviral agents for AIDS. Analysis of the three-dimensional structures of related aspartic proteinases, and later of Rous sarcoma virus protease, indicated that the active site and extended substrate binding cleft exhibits two-fold (C2) symmetry at the atomic level. We therefore set out to test whether compounds that contained a C2 axis of symmetry, and that were structurally complementary to the active site region, could be potent and selective inhibitors of HIV PR. Two novel classes of C2 or pseudo-C2 symmetric inhibitors were designed, synthesized and shown to display potent inhibitory activity towards HIV PR, and one of these, A-77003, recently entered clinical trials. The structure of the complex with A-74704 was solved using X-ray crystallographic methods and revealed a highly symmetric mode of binding, confirming our initial design principles. These studies demonstrate that relatively simple symmetry considerations can give rise to novel compound designs, allowing access to imaginative new templates for synthesis that can be translated into experimental therapeutic agents.
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PMID:Structure-based design of symmetric inhibitors of HIV-1 protease. 803 50

Molecular models of Rous sarcoma virus (RSV) protease and 20 peptide substrates with single amino acid substitutions at positions from P4 to P3', where the scissile bond is between P1 and P1'. were built and compared with kinetic measurements. The unsubstituted peptide substrate. Pro-Ala-Val-Ser-Leu-Ala-Met-Thr, represents the NC-PR cleavage site of RSV protease. Models were built of two intermediates in the catalytic reaction, RSV protease with peptide substrate and with the tetrahedral intermediate. The energy minimization used an algorithm that increased the speed and eliminated a cutoff for nonbonded interactions. The calculated protease-substrate interaction energies showed correlation with the relative catalytic efficiency of peptide hydrolysis. The calculated interaction energies for the 8 RSV protease-substrate models with changes in P1 to P1' next to the scissile bond gave the highest correlation coefficient of 0.79 with the kinetic measurements, whereas all 20 substrates showed the lower, but still significant correlation of 0.46. Models of the tetrahedral reaction intermediates gave a correlation of 0.72 for the 8 substrates with changes next to the scissile bond, whereas a correlation coefficient of only 0.34 was observed for all 20 substrates. The differences between the energies calculated for the tetrahedral intermediate and the bound peptide gave the most significant correlation coefficients of 0.90 for models with changes in P1 and P1', and 0.56 for all substrates. These results are compared to those from similar calculations on HIV-1 protease and discussed in relation to the rate-limiting steps in the catalytic mechanism and the entropic contributions.
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PMID:Molecular mechanics calculations on Rous sarcoma virus protease with peptide substrates. 938 39

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


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