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Query: UMLS:C0019693 (
HIV
)
170,526
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Human immunodeficiency virus type 1 (HIV-1) and other lentiviridae demonstrate a strong preference for the A-nucleotide, which can account for up to 40% of the viral RNA genome. The biological mechanism responsible for this nucleotide bias is currently unknown. The increased A-content of these viral genomes corresponds to the typical use of synonymous codons by all members of the lentiviral family (
HIV
, SIV, BIV, FIV, CAEV, EIAV, visna) and the human spuma retrovirus, but not by other retroviruses like the human T-cell leukemia viruses HTLV-1 and HTLV-II. In this article, we analyzed A-bias for all codon groups in all open reading frames of several lentiviruses. The extent of lentiviral codon bias could be related to host cellular translation. By calculating codon bias indices (CBIs), we were able to demonstrate an inverse correlation between the extent of codon bias and the rate of translation of individual reading frames in these viruses. Specifically, the shift toward A-rich codons is more pronounced in pol than in gag lentiviral genes. Since it is known that Gag synthesis exceeds Pol synthesis by a factor of 20 due to infrequent ribosomal frame-shifting during translation of the gap-pol mRNA molecule, we propose that the aminoacyl-
tRNA
availability in the host cell restricts the lentiviral preference for A-rich codons. In addition, less A-nucleotides were found in regions of the viral genome encoding multiple functions; e.g., overlapping reading frames (tat-rev-env) or in genes that overlap regulatory sequences (nef-LTR region).(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:The tendency of lentiviral open reading frames to become A-rich: constraints imposed by viral genome organization and cellular tRNA availability. 766 42
Six affinity reagents containing chemically reactive groups, either on the phosphate residue at the 5'-end or on the 5'- or 3'-end internucleoside phosphate linkages of the oligothymidylate primers, were used to covalently modify the human immunodeficiency virus type 1 reverse transcriptase (
HIV
-1 RT). After covalent binding of these modified primer analogs to the enzyme, the addition of [alpha-32P]dTTP, in the presence of a complementary template, led to elongation of the primer. This reaction was catalyzed by the active site of the enzyme carrying the covalently bound primer. The relative efficiency of labeling of the p66/p51 heterodimer compared to the p66/p66 and p51/p51 homodimers of
HIV
-1 RT was in agreement with the previously determined affinity of the various enzyme forms toward different primers. The analogues preferentially modified the p66 subunit of the
HIV
-1 RT heterodimer. The labeling of all RT forms by synthetic primer analogues showed significant and specific competition by the natural primer of
HIV
-1 RT,
tRNA
(Lys). In addition, the kinetics of inactivation of RT by primer analogues was studied. The affinity of the enzyme to those derivatives in the presence of poly(A) template was about 5-10 times higher than in the absence of template. Moreover, the maximal rates of
HIV
-1 RT inactivation by analogues in the absence of template were 3-4 times higher. Our results suggest that the mechanism of oligonucleotide primer binding to
HIV
-1 RT is different in the presence or absence of template.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Affinity labeling and functional analysis of the primer binding domain of HIV-1 reverse transcriptase. 768 10
The ability of iron(II).bleomycin to mediate RNA degradation was further characterized. At micromolar concentrations, FeII.BLM was shown to effect cleavage of Escherichia coli
tRNA
(1His) and a Schizosaccharomyces pombe amber suppressor
tRNA
construct in an efficient fashion. In contrast, E. coli
tRNA
(Cys) and yeast mitochondrial
tRNA
(Asp) and
tRNA
(fMet) precursors were not substrates for FeII.BLM. Also shown to be a good substrate for cleavage by FeII.BLM was yeast 5S ribosomal RNA. Since
HIV
-1 reverse transcriptase mRNA has previously been shown to be degraded by Fe.BLM (Carter et al., 1990a), members of the three major classes of RNA have now been shown to undergo Fe.BLM-mediated strand scission. For each of the substrate RNAs, cleavage occurred at sites unique to that substrate. Although RNA cleavage occurred at numerous sequences, 5'-G-pyr-3' sites were prominent. Likewise, while cleavage was noted in regions anticipated to be double-stranded, as well as in single-stranded regions, a disproportionate number of cleavages were noted at the junction between single- and double-stranded regions. As found in earlier studies, RNA cleavage was much more selective than DNA cleavage. Further, when RNA cleavage was carried out in the presence of reagents such as Mg2+, spermidine, and NaCl, the selectivity of cleavage was further enhanced. The highly selective and efficient cleavage of a number of RNA molecules reinforces our earlier suggestion that RNA may constitute a therapeutically relevant target for bleomycin.
...
PMID:Characterization of iron (II).bleomycin-mediated RNA strand scission. 768 45
Packaging of the genomic RNA dimer and replication primer
tRNA
(Lys,3) into
HIV
virions are required for the production of infectious virus. The initiation of reverse transcription necessitates the annealing of
tRNA
(Lys,3) to the primer binding site (PBS) of
HIV
RNA by nucleocapsid (NC) protein. In this report the interactions of replication primer
tRNA
(Lys,3) with various forms of reverse transcriptase (RT) and nucleocapsid protein have been analyzed by ultraviolet light (UV) cross-linking and gel retardation assays. We show that of the three forms of RT studied, p66/p51, p66 and p51, only the heterodimer p66/p51 can tightly and stably interact with
tRNA
(Lys,3). Tight interactions between
tRNA
(Lys,3) and nucleocapsid protein, either NCp15 or NCp7, were found to take place within the anticodon domain. Interestingly enough, primer
tRNA
(Lys,3) can interact with RTp66/p51 and NCp15 to form a high molecular weight complex in which RTp66/p51 appears to enhance the binding of NCp15 to
tRNA
(Lys,3). These findings favor the notion that the RT enzyme and NC protein co-operate to select and package primer
tRNA
.
...
PMID:Analysis of the interactions of HIV1 replication primer tRNA(Lys,3) with nucleocapsid protein and reverse transcriptase. 768 91
We have expressed and purified from Escherichia coli a human immunodeficiency virus type 1 (HIV-1) RNase H domain consisting of amino acids 400 to 560 of reverse transcriptase with either an N- or C-terminal polyhistidine tag. The native protease cleavage site of
HIV
-1 reverse transcriptase is between amino acids 440 and 441. Purification on Ni(2+)-nitrilotriacetate agarose resulted in a highly active RNase H domain dependent on MnCl2 rather than MgCl2. Activity was unambiguously attributed to the purified proteins by an in situ RNase H gel assay. Residues 400 to 426, which include a stretch of tryptophans, did not contribute to RNase H activity, and the polyhistidine tag was essential for activity. Despite the requirement for a histidine tag, the recombinant RNase H proteins retained characteristics of the wild-type heterodimer, as determined by examining activity in the presence of several known inhibitors of
HIV
-1 RNase H, including ribonucleoside vanadyl complexes, dAMP, and a monoclonal antibody. Importantly, the isolated RNase H domain produced the same specific cleavage in
tRNA
(3Lys) removal as
HIV
-1 heterodimer, leaving the 3'-rA (adenosine 5' phosphate) residue of a model
tRNA
attached to the adjacent U5 sequence. This
HIV
-1 RNase H domain sedimented as a monomer in a glycerol gradient.
...
PMID:Purification and characterization of an active human immunodeficiency virus type 1 RNase H domain. 768 7
Nuclease footprinting has been used to probe features of binary complexes of type 1 human immunodeficiency virus reverse transcriptase (
HIV
-1 RT) with both natural and synthetic preparations of its cognate replication primer,
tRNA
(Lys-3). In addition to heterodimeric RT (p66/p51), ribonucleoprotein complexes containing either the p66 or p51 subunit were analyzed. Footprinting experiments employed both structure- and sequence-specific nucleases. Our results indicate a similar mode of interaction for the three RT preparations tested, suggesting contact with each loop of the
tRNA
primer (D, anticodon, and T psi C), as well as minor perturbation of the anticodon stem. Although there is little evidence for extensive disruption of the 3'-acceptor stem. RNase A footprinting data with natural and synthetic
tRNA
suggests that potential base pairing between the T psi C and D loops is disrupted in the presence of RT.
...
PMID:Nuclease footprinting of human immunodeficiency virus reverse transcriptase/tRNA(Lys-3) complexes. 768 66
Reverse transcription of human immunodeficiency virus type-1 (HIV-1) genomic RNA is primed by
tRNA
(3Lys), whose 3' end 18 nucleotides are complementary to the viral primer binding site (PBS). We used chemical and enzymatic probes to test the conformation of the viral RNA and
tRNA
(3Lys), in their free form and in the
HIV
-1 RNA/
tRNA
(3Lys) binary complex. Extensive reactivity changes were observed in both molecules upon formation of the binary complex. In the viral RNA, reactivity changes occurred up to 69 nucleotides upstream and 72 nucleotides downstream of the PBS. A secondary structure model of the
HIV
-1 RNA/
tRNA
(3Lys) complex accounting for all probing data has been constructed. It reveals an unexpectedly complex and compact pseudoknot-like structure in which most of the anticodon loop, the 3' strand of the anticodon stem and the 5' part of the variable loop of
tRNA
(3Lys) interact with viral sequences 12 to 39 nucleotides upstream of the PBS. The core of the binary complex is a complex junction formed by two single-stranded sequences of
tRNA
(3Lys), an intramolecular viral helix, an intramolecular
tRNA
helix, and two intermolecular helices formed by the template/primer interaction. This junction probably highly constrains the tertiary structure of the
HIV
-1 RNA/
tRNA
(3Lys) complex. Compared to the structure of the free molecules, only the D arm of
tRNA
(3Lys) and a small viral stem-loop downstream of the PBS are unaffected in the binary complex. Sequence comparison reveals that the main characteristics of the binary complex model are conserved among all
HIV
-1 isolates.
...
PMID:Initiation of reverse transcription of HIV-1: secondary structure of the HIV-1 RNA/tRNA(3Lys) (template/primer). 770 72
Replication of the human immunodeficiency virus type 1 (HIV-1) and other retroviruses involves reverse transcription of the viral RNA genome into a double-stranded DNA. This reaction is primed by the cellular
tRNA
(3Lys) molecule, which binds to a complementary sequence in the viral genome, referred to as the primer-binding site (PBS). In order to study the specificity of primer usage, we constructed a set of
HIV
-1 mutants with altered PBS sites corresponding to other
tRNA
species (
tRNA
(Ile),
tRNA
(1,2Lys),
tRNA
(Phe),
tRNA
(Pro),
tRNA
(Trp)). These mutant viruses were able to replicate, although with delayed replication kinetics compared with wild-type
HIV
-1. Identification of the
tRNA
species associated with the genomic RNA demonstrated binding of tRNAs complementary to the new PBS sites. However, the occupancy of the mutant PBS sites by these new primers was reduced and correlated well with the replication potential of the mutant viruses. These results suggest that the PBS sequence is not sufficient for annealing of the
tRNA
primer. Upon prolonged culturing, all mutants reverted to the wild-type PBS(3Lys) sequence. Minor sequence changes in the nucleotides flanking the PBS site indicate that these reversions resulted from annealing of the wild-type
tRNA
(3Lys) primer onto the mutant PBS sites, followed by copying of part of the
tRNA
(3Lys) sequence during reverse transcription. Furthermore, the reversion efficiency of the different PBS mutants was found to correlate with their
tRNA
(Lys)3 binding capacity. A remarkable reversion pathway was observed for the PBSPro variant (PBSPro-->PBSIle-->PBSwt). This pathway can be explained by efficient base pairing of
tRNA
(Ile) to PBSPro, followed by annealing of
tRNA
(3Lys) onto the PBSIle intermediate. These results demonstrate that
HIV
-1 is dedicated to the
tRNA
(3Lys) primer and that factors other than the PBS sequence determine the selective primer usage of this retrovirus.
...
PMID:Reduced replication of human immunodeficiency virus type 1 mutants that use reverse transcription primers other than the natural tRNA(3Lys). 770 37
The human immunodeficiency virus type-1 (HIV-1) Tat activation response (TAR) region is essential for Tat-mediated trans-activation of the
HIV
-1 long terminal repeat (LTR). The TAR element is present on the 5' and 3' ends of all
HIV
-1 transcripts and is relatively conserved among different
HIV
-1 isolates. These properties make it an attractive target for anti-
HIV
-1 gene therapy strategies. We have constructed a Moloney murine leukemia-based retroviral vector that expresses a chimeric
tRNA
(iMet)-antisense TAR fusion transcript complementary to the
HIV
-1 TAR region. The potential of this anti-TAR retroviral vector to inhibit
HIV
-1 was initially tested by transient transfections with an
HIV
-1-LTR-Tat expression plasmid into HeLa-CAT cells. Anti-TAR inhibited Tat-mediated
HIV
-1 LTR-driven CAT reporter gene expression in a dose-dependent fashion. The antisense-TAR vector was then used to transduce the human SupT1 T cell line. Cotransfection of these SupT1 cells with a Tat expression plasmid plus an
HIV
-1 LTR-CAT reporter plasmid resulted in decreased CAT gene expression in comparison to control transduced SupT1 cells. The antisense-TAR engineered SupT1 cell line was then challenged with
HIV
-1MN.
HIV
-1 viral production was inhibited in SupT1 cells transduced with the antisense-TAR retroviral vector. Greater inhibition of
HIV
-1 was observed with antisense-TAR as compared to antisense-Tat expressing retroviral vector. These observations suggest that antisense-TAR retroviral vectors are potentially useful for clinical anti-
HIV
-1 gene therapy.
...
PMID:Inhibition of human immunodeficiency virus type-1 by retroviral vectors expressing antisense-TAR. 771 Nov 39
Anticodon nuclease is a bacterial restriction enzyme directed against
tRNA
(Lys). We report that anticodon nuclease also cleaves mammalian
tRNA
(Lys) molecules, with preference and site specificity shown towards the natural substrate. Expression of the anticodon nuclease core polypeptide PrrC in HeLa cells from a recombinant vaccinia virus elicited cleavage of intracellular
tRNA
(Lys),3. The data justify an inquiry into the possible application of anticodon nuclease as an inhibitor of
tRNA
(Lys),3-primed
HIV
replication. They also indicate that the anticodon region of
tRNA
(Lys) is a substrate recognition site and suggest that PrrC harbors the enzymatic activity.
...
PMID:Cleavage of the HIV replication primer tRNALys,3 in human cells expressing bacterial anticodon nuclease. 778 79
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