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: UMLS:C0021051 (immunodeficiency)
71,517 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Reverse transcriptases (RTs) of retroviruses and long terminal repeat (LTR)-retrotransposons possess DNA polymerase and RNase H activities. During reverse transcription these activities are necessary for the programmed sequence of events that include template switching and primer processing. Integrase then inserts the completed cDNA into the genome of the host cell. The RT of the LTR-retrotransposon Tf1 was subjected to random mutagenesis, and the resulting transposons were screened with genetic assays to test which mutations reduced reverse transcription and which inhibited integration. We identified a cluster of mutations in the RNase H domain of RT that were surprising because they blocked integration without reducing cDNA levels. The results of immunoblots demonstrated that these mutations did not reduce levels of RT or integrase. DNA blots showed that the mutations did not lower the amounts of full-length cDNA. The sequences of the 3' ends of the cDNA revealed that mutations within the cluster in RNase H specifically reduced the removal of the polypurine tract (PPT) primer from the ends of the cDNA. These results indicate that primer removal is not a necessary component of reverse transcription. The residues mutated in Tf1 RNase H are conserved in human immunodeficiency virus type 1 and make direct contact with DNA opposite the PPT. Thus, our results identify a conserved element in RT that contacts the PPT and is specifically required for PPT removal.
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PMID:Specific recognition and cleavage of the plus-strand primer by reverse transcriptase. 1628 86

To achieve productive infection, the reverse transcribed cDNA of human immunodeficiency virus type 1 (HIV-1) is inserted in the host cell genome. The main protein responsible for this reaction is the viral integrase. However, studies indicate that the virus is assisted by cellular proteins, or co-factors, to achieve integration into the infected cell. The barrier-to-autointegration factor (BAF) might prevent autointegration. Its ability to bridge DNA and the finding that the nuclear lamina-associated polypeptide-2alpha interacts with BAF suggest a role in nuclear structure organization. Integrase interactor 1 was found to directly interact with HIV-1 integrase and to activate its DNA-joining activity, and the high mobility group chromosomal protein A1 might approximate both long terminal repeat (LTR) ends and facilitate integrase binding by unwinding the LTR termini. Furthermore, the lens-epithelium-derived growth factor (LEDGF; also known as p75) seems to tether HIV-1 integrase to the chromosomes. Although a direct role in integration has only been demonstrated for LEDGF/p75, to date, each validated cellular co-factor for HIV-1 integration could constitute a promising new target for antiviral therapy.
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PMID:Cellular co-factors of HIV-1 integration. 1640 35

The specific activity of the human immunodeficiency virus, type 1 (HIV-1), integrase on the viral long terminal repeat requires the binding of the enzyme to certain sequences located in the U3 and U5 regions at the ends of viral DNA, but the determinants of this specific DNA-protein recognition are not yet completely understood. We synthesized DNA duplexes mimicking the U5 region and containing either 2'-modified nucleosides or 1,3-propanediol insertions and studied their interactions with HIV-1 integrase, using Mn2+ or Mg2+ ions as integrase cofactors. These DNA modifications had no strong effect on integrase binding to the substrate analogs but significantly affected 3'-end processing rate. The effects of nucleoside modifications at positions 5, 6, and especially 3 strongly depended on the cationic cofactor used. These effects were much more pronounced in the presence of Mg2+ than in the presence of Mn2+. Modifications of base pairs 7-9 affected 3'-end processing equally in the presence of both ions. Adenine from the 3rd bp is thought to form at least two hydrogen bonds with integrase that are crucial for specific DNA recognition. The complementary base, thymine, is not important for integrase activity. For other positions, our results suggest that integrase recognizes a fine structure of the sugar-phosphate backbone rather than heterocyclic bases. Integrase interactions with the unprocessed strand at positions 5-8 are more important than interactions with the processed strand for specific substrate recognition. Based on our results, we suggest a model for integrase interaction with the U5 substrate.
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PMID:Probing of HIV-1 integrase/DNA interactions using novel analogs of viral DNA. 1650 Aug 99

Integrase is actively studied as an antiviral target, but many inhibitors selected from biochemical screens fail to inhibit human immunodeficiency virus (HIV) replication or primarily affect off-site targets. Here we develop and validate a replication-competent, simian virus 40-HIV integrase mutant chimera as a novel tool to classify the mechanism of action of potential integrase inhibitors. Whereas the mutant was more susceptible than the wild type to entry, reverse transcriptase, and protease inhibitors, it specifically resisted the action of integrase inhibitor L-870,810. We furthermore demonstrate inhibition of integration by GS-9137 and GS-9160 and off-site targeting by the 6-aminoquinolone antibiotic WM-5.
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PMID:Characterization of a replication-competent, integrase-defective human immunodeficiency virus (HIV)/simian virus 40 chimera as a powerful tool for the discovery and validation of HIV integrase inhibitors. 1728 85

Retroviruses, such as human immunodeficiency virus type 1 (HIV-1), are plus-sense RNA viruses that require reverse transcription and then DNA integration to establish a chromosomal provirus as an obligate replication intermediate. The viral enzyme reverse transcriptase synthesises linear double-stranded cDNA, which is the template for the viral enzyme integrase. Integrase catalyses two separate chemical reactions: an initial 3' processing of the nascent cDNA ends, which is followed in the cell nucleus by their covalent attachment to the 5' phosphates of a double-stranded staggered cut in chromosomal DNA. As integrase activity is essential for productive retroviral infection, there is intense interest in developing small-molecule inhibitors of the HIV-1 enzyme to increase the breadth of the antiviral arsenal used to fight HIV/AIDS. Purified integrase protein displays the 3' processing and DNA-strand-transfer activities essential for cDNA integration in integration assays in vitro, but numerous studies indicate that cellular proteins play important roles during integration in infected cells. This review highlights the molecular mechanisms behind HIV-1 integration, focusing on recent insights into functions of human cellular cofactors. The progress towards developing integrase inhibitors for their use in the clinic is also reviewed.
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PMID:Molecular mechanisms of HIV integration and therapeutic intervention. 1732 2

Integrase (IN) is one of the three human immunodeficiency virus type 1 (HIV-1) enzymes essential for effective viral replication. S-1360 is a potent and selective inhibitor of HIV-1 IN. In this work, we have carried out molecular dynamics (MD) simulations using a hybrid Quantum Mechanics/Molecular Mechanics (QM/MM) approach, to determine the protein-ligand interaction energy for S-1360 and two analogues. Analysis of the MD trajectories reveals that the strongest protein-inhibitor interactions, observed in the three studied complexes, are established with Lys-159 residue and Mg(2+) cation. Calculations of binding energy using BLYP/MM level of theory reveal that there is a direct relationship between this theoretical computed property and the experimental determined anti-HIV activity.
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PMID:Calculation of binding energy using BLYP/MM for the HIV-1 integrase complexed with the S-1360 and two analogues. 1742 Jan 31

Human immunodeficiency virus (HIV) integrase enzyme is required for the integration of viral DNA into the host cell chromosome. Integrase complex assembly and subsequent strand transfer catalysis are mediated by specific interactions between integrase and bases at the end of the viral long terminal repeat (LTR). The strand transfer reaction can be blocked by the action of small molecule inhibitors, thought to bind in the vicinity of the viral LTR termini. This study examines the contributions of the terminal four bases of the nonprocessed strand (G(2)T(1)C(-1)A(-2)) of the HIV LTR on complex assembly, specific strand transfer activity, and inhibitor binding. Base substitutions and abasic replacements at the LTR terminus provided a means to probe the importance of each nucleotide on the different functions. An approach is described wherein the specific strand transfer activity for each integrase/LTR variant is derived by normalizing strand transfer activity to the concentration of active sites. The key findings of this study are as follows. 1) The G(2):C(2) base pair is necessary for efficient assembly of the complex and for maintenance of an active site architecture, which has high affinity for strand transfer inhibitors. 2) Inhibitor-resistant enzymes exhibit greatly increased sensitivity to LTR changes. 3) The strand transfer and inhibitor binding defects of a Q148R mutant are due to a decreased affinity of the complex for magnesium. 4) Gln(148) interacts with G(2), T(1), and C(-1) at the 5' end of the viral LTR, with these four determinants playing important and overlapping roles in assembly, strand transfer catalysis and high affinity inhibitor binding.
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PMID:Changes to the HIV long terminal repeat and to HIV integrase differentially impact HIV integrase assembly, activity, and the binding of strand transfer inhibitors. 1771 37

Integrase (IN) catalyzes insertion of the retroviral genome into the host via two sequential reactions. The processing activity cleaves the 3'-dinucleotides from the two ends of the viral DNA which are then inserted into the host DNA. Tetramers are required for the joining step. While dimers have been shown to catalyze processing, they do so inefficiently, and the oligomeric requirement for processing is unknown. We have replaced loop202-208 at the putative dimer-dimer interface of the avian sarcoma virus IN with its analogue, loop188-194, from human immunodeficiency virus IN. The mutation abolished disintegration activity and a 2 x 10(-2) s-1 fast phase during single-turnover processing. A 3 x 10(-4) s-1 slow processing phase was unaffected. Preincubation with a DNA substrate known to promote tetramerization increased products formed during the fast phase by 2.5-fold only for wild-type IN, correlating the fast and slow phases with processing by tetramers and dimers, respectively. We propose a novel tetramer model for coupling processing and integration based on efficient processing by the tetramer. We provide for the first time direct evidence of the functional relevance of a structural element, loop202-208, which appears to be required for mediating the interaction between dimer halves of the active tetramer.
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PMID:Loop202-208 in avian sarcoma virus integrase mediates tetramer assembly and processing activity. 1784 8

Integrase (IN), an essential enzyme of human immunodeficiency virus (HIV), is an attractive antiretroviral drug target. The antiviral activity and resistance profile in vitro of a novel IN inhibitor, elvitegravir (EVG) (also known as JTK-303/GS-9137), currently being developed for the treatment of HIV-1 infection are described. EVG blocked the integration of HIV-1 cDNA through the inhibition of DNA strand transfer. EVG inhibited the replication of HIV-1, including various subtypes and multiple-drug-resistant clinical isolates, and HIV-2 strains with a 50% effective concentration in the subnanomolar to nanomolar range. EVG-resistant variants were selected in two independent inductions, and a total of 8 amino acid substitutions in the catalytic core domain of IN were observed. Among the observed IN mutations, T66I and E92Q substitutions mainly contributed to EVG resistance. These two primary resistance mutations are located in the active site, and other secondary mutations identified are proximal to these primary mutations. The EVG-selected IN mutations, some of which represent novel IN inhibitor resistance mutations, conferred reduced susceptibility to other IN inhibitors, suggesting that a common mechanism is involved in resistance and potential cross-resistance. The replication capacity of EVG-resistant variants was significantly reduced relative to both wild-type virus and other IN inhibitor-resistant variants selected by L-870,810. EVG and L-870,810 both inhibited the replication of murine leukemia virus and simian immunodeficiency virus, suggesting that IN inhibitors bind to a conformationally conserved region of various retroviral IN enzymes and are an ideal drug for a range of retroviral infections.
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PMID:Broad antiretroviral activity and resistance profile of the novel human immunodeficiency virus integrase inhibitor elvitegravir (JTK-303/GS-9137). 1797 62

Integrase (IN) is one of the three human immunodeficiency virus type 1 (HIV-1) enzymes essential for effective viral replication. Recently, mutation studies have been reported that have shown that a certain degree of viral resistance to diketo acids (DKAs) appears when some amino acid residues of the IN active site are mutated. Mutations represent a fascinating experimental challenge, and we invite theoretical simulations for the disclosure of still unexplored features of enzyme reactions. The aim of this work is to understand the molecular mechanisms of HIV-1 IN drug resistance, which will be useful for designing anti-HIV inhibitors with unique resistance profiles. In this study, we use molecular dynamics simulations, within the hybrid quantum mechanics/molecular mechanics (QM/MM) approach, to determine the protein-ligand interaction energy for wild-type and N155S mutant HIV-1 IN, both complexed with a DKA. This hybrid methodology has the advantage of the inclusion of quantum effects such as ligand polarization upon binding, which can be very important when highly polarizable groups are embedded in anisotropic environments, for example in metal-containing active sites. Furthermore, an energy terms decomposition analysis was performed to determine contributions of individual residues to the enzyme-inhibitor interactions. The results reveal that there is a strong interaction between the Lys-159, Lys-156, and Asn-155 residues and Mg(2+) cation and the DKA inhibitor. Our calculations show that the binding energy is higher in wild-type than in the N155S mutant, in accordance with the experimental results. The role of the mutated residue has thus been checked as maintaining the structure of the ternary complex formed by the protein, the Mg(2+) cation, and the inhibitor. These results might be useful to design compounds with more interesting anti-HIV-1 IN activity on the basis of its three-dimensional structure.
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PMID:A quantum mechanic/molecular mechanic study of the wild-type and N155S mutant HIV-1 integrase complexed with diketo acid. 1798 9


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