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:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In search of potential inhibitors of integration of retroviral DNA into host cells genome, we have investigated the effect of the external DNA binder netropsin on the in vitro insertion of long terminal repeat (LTR) ends of Moloney murine leukemia virus (M.MuLV) as catalysed by integrase purified from baculovirus strain expression vector. In agreement with the preferential binding of netropsin to A+T rich sequences, footprinting experiments have shown that this drug selectively binds to the 5'-TTTCAT LTR end sequence which is included in the DNA binding site of integrase. This feature results in the potent inhibition of both reactions involved in the insertion process, namely, nucleolytic cleavage and strand transfer. The relation between netropsin binding to A+T rich region of M.MuLV LTR end and inhibition of insertion is strongly suggested from the inability of the drug to inhibit the insertion of HIV U3 LTR end which displays a G+C rich sequence. Selective inhibition of integration of viral DNA appears to be feasible using drugs recognizing LTR end sequences.
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PMID:Inhibition of the in vitro integration of Moloney murine leukemia virus DNA by the DNA minor groove binder netropsin. 820 98

The disintegration activity of Moloney murine leukemia virus (M-MuLV) integrase (IN) was investigated through structural and sequence modifications of a Y substrate that resembles an integration intermediate. The Y substrates, constructed from individual oligonucleotides, contain a single viral long terminal repeat (LTR) joined to a nicked target DNA. Truncation of the double-stranded LTR sequences distal to the conserved 5'-CA-3' dinucleotide progressively diminished disintegration activity. M-MuLV IN was also able to catalyze disintegration of a heterologous double-stranded LTR sequence. Significantly, the activity of M-MuLV IN on single-stranded LTR Y substrates was more dependent on the sequence and length of the LTR strand than that reported for human immunodeficiency virus type 1 (HIV-1) IN. Modifications introduced at the Y-substrate junction demonstrated that the 3'-hydroxyl group at the terminus of the target strand was necessary for efficient joining of the target DNA strands. The presence of a 2'-hydroxyl group at the 3' end of the target strand, as well as a single-nucleotide gap at the LTR-target junction, reduced disintegration activity. The absence of hydroxyl groups on the terminal nucleotide abolished joining of the target strands. The results presented here suggest that M-MuLV IN disintegration activity is dependent on substantially different LTR sequence requirements than those reported for HIV-1 IN and may be mediated primarily through a structural recognition event.
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PMID:Influence of substrate structure on disintegration activity of Moloney murine leukemia virus integrase. 823 Apr 31

The human immunodeficiency virus type 1 (HIV-1) vif gene encodes a 23-kDa protein of unknown function, also produced by most other known lentiviruses. Vif was found to be essential for the spread of HIV-1 in peripheral blood lymphocytes and in primary macrophages, as well as in some but not all established T-cell lines. Vif was required at the stage of viral particle formation, for cell-to-cell as well as for cell-free transmission of HIV-1. Accordingly, vif-defective viruses could be complemented by the expression of vif in the producer but not in the target cell. vif-defective virions contained wild-type amounts of Gag and Env proteins, reverse transcriptase, integrase, genomic RNA, and partial reverse transcripts. Most importantly, they could enter cells normally, and the vif defect could not be rescued through the use of HIV(MLV [murine leukemia virus]) pseudotypes. Instead, vif-mutant viruses were severely impaired in their ability to complete the synthesis of proviral DNA, once internalized in the target cell. These results suggest that Vif plays a role which is novel for a retroviral protein, in allowing the processing and/or the transport of the internalized HIV core.
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PMID:Vif is crucial for human immunodeficiency virus type 1 proviral DNA synthesis in infected cells. 833 34

Retroviral integrases mediate site-specific endonuclease and transesterification reactions in the absence of exogenous energy. The basis for the sequence specificity in these integrase-viral DNA recognition processes is unknown. Structural analogs of the disintegration substrate were made to analyze the disintegration reaction mechanism for the Moloney murine leukemia virus (M-MuLV) integrase (IN). Modifications in the target DNA portion of the disintegration substrate decreased enzymatic activity, while substitution of the highly conserved CA in the viral long terminal repeat portion had no effect on activity. The role of the His-Cys finger region in catalysis was addressed by N-ethylmaleimide (NEM) modification of the cysteine residues of M-MuLV IN as well as by mutations. Both integration activities, 3' processing, and strand transfer, were completely inhibited by NEM modification of M-MuLV IN, while disintegration activity was only partially sensitive. However, structural analogs of the disintegration substrates that were modified in the target DNA and had the conserved CA removed were not active with NEM-treated M-MuLV IN. In addition, mutants made in the His-Cys region of M-MuLV IN were examined and found to also be completely blocked in integration but not disintegration activity. These data suggest that the domains of M-MuLV IN that are required for the forward integration reaction substrate differ from those required for the reverse disintegration reaction substrate.
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PMID:Role of the His-Cys finger of Moloney murine leukemia virus integrase protein in integration and disintegration. 835 Apr 12

The insertion of retroviral DNA into the genome of the infected cell to form the integrated provirus requires the presence of short inverted repeat (IR) sequences at the viral DNA termini. To examine the sequence requirements at the IRs for integration of the Moloney murine leukemia virus, we generated a series of mutants with deletion and substitution mutations and tested their ability to replicate and form proviruses in vivo. The experiments did not detect evidence of a requirement for sequences outside the IRs, and only a very loose requirement for the IR sequences, with many point mutations well tolerated. Examination of the mutants suggests that bases very near the terminus and those approximately one turn of the DNA helix away from the terminus are important for recognition by the integrase function.
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PMID:Mutational analysis of the sequences at the termini of the Moloney murine leukemia virus DNA required for integration. 839 34

The forward and reverse reactions for integration were characterized for the Moloney murine leukemia virus integrase (M-MuLV IN) protein. The M-MuLV IN was recombinantly produced in Escherichia coli, and was purified to greater than 90% homogeneity by a one-step affinity purification scheme. M-MuLV IN was highly active for integration as measured by in vitro cleavage and strand transfer assays. Furthermore, the integration of a model viral substrate into lambda concatamers by IN correctly produced the flanking 4-base pair duplications characteristic of M-MuLV IN. The reverse reaction of integration, disintegration, was also catalyzed by the recombinant M-MuLV IN. Two products were generated, a 3'-recessed long terminal repeat and a ligated target DNA, from a model integration-intermediate substrate in the presence of M-MuLV IN. The requirements and optimal conditions for maximal integration and disintegration activity for M-MuLV IN were determined. The forward and reverse reactions required different concentrations of manganese ion and reductant. Salt was also titrated for the forward and reverse reactions. Sodium chloride inhibited integration, but had little affect on disintegration. Low concentrations of potassium chloride enhanced integration, but had no affect on disintegration. The dinucleotide cleavage, strand transfer, and the disintegration reactions each had a unique pH profile of activity.
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PMID:Characterization of the forward and reverse integration reactions of the Moloney murine leukemia virus integrase protein purified from Escherichia coli. 841 46

SIV/Mne circle junctions were amplified by the polymerase chain reaction (PCR) and cloned in a bacterial plasmid. Sequence analysis of clones isolated from 11 independent PCRs reveals that the start site for plus DNA synthesis is 5' ACTG. . ., and thus an asymmetric cleavage must occur during viral integration. In addition, most of the sequences found resulted from the ligation of aberrant proviral DNA ends that were apparently generated by priming errors, primer removal errors, or integrase processing errors. The results suggest that in this virus, as in Moloney murine leukemia virus, two good ends may be required for efficient integration.
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PMID:The majority of simian immunodeficiency virus/mne circle junctions result from ligation of unintegrated viral DNA ends that are aberrant for integration. 850 90

Integration of human immunodeficiency virus (HIV) DNA into the human genome requires the virus-encoded integrase (IN) protein, and therefore the IN protein is a suitable target for antiviral strategies. To find a potent HIV IN inhibitor, we screened a "synthetic peptide combinatorial library." We identified a hexapeptide with the sequence HCKFWW that inhibits IN-mediated 3'-processing and integration with an IC50 of 2 microM. The peptide is active on IN proteins from other retroviruses such as HIV-2, feline immunodeficiency virus, and Moloney murine leukemia virus, supporting the notion that a conserved region of IN is targeted. The hexapeptide was also tested in the disintegration reaction. This phosphoryl-transfer reaction can be carried out by the catalytic core of IN alone, and the peptide HCKFWW was found to inhibit this reaction, suggesting that the hexapeptide acts at or near the catalytic site of IN. Identification of an IN hexapeptide inhibitor provides proof of concept for the approach, and, moreover, this peptide may be useful for structure-function analysis of IN.
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PMID:Identification of a hexapeptide inhibitor of the human immunodeficiency virus integrase protein by using a combinatorial chemical library. 852 82

The entry and intracellular transport of Moloney-murine leukemia virions inside mouse NIH 3T3 cells have been followed by electron microscopy techniques. Five viral proteins--matrix (MA, p15), capsid (CA, p30), nucleocapsid (NC, p10), integrase (IN), and the envelope glycoprotein (SU, gp70)--were located by immunolabeling using gold probes. After entering the cells, viral particles were frequently detected inside cytoplasmic vesicles of variable size. Their viral envelope was apparently lost during intracytoplasmic transport. When the unenveloped viral cores reached the nuclear membrane or its vicinity, they were disrupted. Two of the immunolabeled proteins, NC and IN, were detected entering the nucleus of non-dividing cells, where both were targeted to the nucleolus. However, MA and CA were found only in the cytoplasm. NC is a nucleic acid-binding protein which contains potential nuclear localization signals. We suggest that NC could enter the nucleus as part of a nucleoprotein complex, associated with IN, and possibly, also with viral DNA.
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PMID:Intracellular transport of the murine leukemia virus during acute infection of NIH 3T3 cells: nuclear import of nucleocapsid protein and integrase. 853 43

The viral integrase (IN) protein is the only viral protein known to be required for integration of the human immunodeficiency virus type 1 (HIV-1) genome into the host cell DNA, a step in the viral life cycle that is essential for viral replication. To better understand the relationship between in vitro IN activity and IN-mediated integration of viral DNA in an infected cell, we characterized the effects of 13 IN mutations on viral replication in cultured cells. Using HIV-1 genomes that express the hygromycin resistance gene and do not express the HIV-1 env gene, we generated stocks of pseudotype virus coated with the murine leukemia virus amphotropic envelope glycoprotein, containing either wild-type or mutant HIV-1 IN. All mutants produced normal amounts of physical particles, as measured by reverse transcriptase activity and capsid protein (p24) concentration, but they formed three groups based on infectious titer and synthesis of viral DNA. Changes at the three highly conserved acidic residues in the IN core domain (D-64, D-116, and E-152) impair provirus formation without affecting viral DNA synthesis or the accumulation of viral DNA in the nucleus of the infected cell, a phenotype predicted by each mutant's lack of in vitro integrase activity. Mutations at positions N-120, R-199, and W-235 minimally affect in vitro integrase activity, but infectious titers are severely reduced, despite normal synthesis of viral DNA, implying a defect during integration in vivo. Mutations in the zinc binding region (H12C, H16V, and H16C), S81R, and a deletion of residues 32 through 275 yield noninfectious particles that synthesize little or no viral DNA following infection, despite wild-type levels of reverse transcriptase activity and viral RNA in the particles. The two latter classes of mutants suggest that IN can affect DNA synthesis or integration during infection in ways that are not appreciated from currently used assays in vitro.
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PMID:Human immunodeficiency virus type 1 integrase mutants retain in vitro integrase activity yet fail to integrate viral DNA efficiently during infection. 855 8


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