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Query: EC:3.1.26.4 (
RNase H
)
2,751
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Alanine scanning mutagenesis was undertaken to evaluate the structural significance of Met230-His235 of the 66 kDa subunit of p66/
p51
human immunodeficiency virus reverse transcriptase (HIV-1 RT). Together with Glu224-Trp229, these residues provide the framework of the p66 "primer grip", whose proposed role is maintaining the primer terminus in an orientation appropriate for nucleophilic attack on an incoming dNTP. Of these residues, altering Leu234 results in a p66 subunit incapable of associating into heterodimer. The remaining selectively mutated enzymes were successfully reconstituted and purified to homogeneity for evaluation of RT-associated activities. We show here that alterations to any residue within the p66-Trp229-Met230-Gly231-Tyr232-quartet alter functions associated with both the DNA polymerase and
ribonuclease H
(
RNase H
) domains. Detailed analysis of mutant p66Y232A/
p51
with an intact or a model "precleaved" RNA-DNA hybrid suggests an altered
RNase H
phenotype could result from relocation of template-primer in the nucleic acid binding cleft. As a consequence, template nucleotide-8 is positioned in the immediate vicinity of the
RNase H
catalytic center rather than nucleotide-17.
...
PMID:Alterations to the primer grip of p66 HIV-1 reverse transcriptase and their consequences for template-primer utilization. 867 16
The Human Immunodeficiency Virus type 1 (HIV-1) is a retrovirus and a causative agent of the Acquired Immuno Deficiency Syndrome (AIDS). Retroviruses are distinct from other viruses in their ability to encode an enzyme called reverse transcriptase (RT). The RT is the enzyme mainly involved in replication. It performs RNA- as well as DNA-dependent DNA synthesis in order to convert the single-stranded viral RNA genome into double-stranded DNA. The double-stranded DNA is stably integrated into the host cell genome and is used as a template for the production of a new viral generation. The HIV-1 RT is partially encoded by the POL open reading frame of the HIV-1 genome and consists of two subunits of 66 kDa (p66) and 51 kDa (
p51
). The p66 polypeptide encodes the reverse transcriptase and the
RNase H
domain. Half of the p66 molecules are further processed to generate the
p51
protein with an identical N-terminus, but lacking the C-terminus which encodes the
RNase H
domain. In vivo both polypeptides are found in equimolar amounts thus forming a heterodimer. This dimerization is critical for the enzymatic activity. In this review we summarize (i) the replication cycle of HIV-1, (ii) the enzymatic properties of HIV-1 RT and (iii) the structure-function relationship of the HIV-1 RT in view of the known three dimensional structure.
...
PMID:Human Immunodeficiency Virus type 1 reverse transcriptase. 886 66
Alterations to the highly conserved Asp549 of the retroviral
ribonuclease H
(
RNase H
) domain were evaluated in the heterodimeric (p66/
p51
) reverse transcriptases of human immunodeficiency and equine infectious anemia viruses. In addition to the polymerization-dependent and -independent modes of template hydrolysis, mutants were evaluated via their ability to select and extend the 3' polypurine tract (PPT) primers of these two lentiviruses into (+) strand DNA. Concerted and two-step reactions were designed to evaluate (+) strand priming, the latter of which allows discrimination between selection end extension events. In contrast to enzyme mutated at the highly conserved Glu478, substitution of Asp549 with Asn or Ala reduces, rather than completely eliminates,
RNase H
activity. When the requirement for
RNase H
function becomes more stringent, differences in activity are readily evident, most notably in the cleavage events liberating the 5' terminus of the PPT primer. PPT selection thus appears to represent a specialized form of
RNase H
activity that is more sensitive to minor structural alterations within this domain and may provide a novel therapeutic target.
...
PMID:Substituting a conserved residue of the ribonuclease H domain alters substrate hydrolysis by retroviral reverse transcriptase. 907 91
Treatment of human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) with N-ethylmaleimide (NEM) selectively inhibits the
RNase H
activity. The cysteine residue at position 280 (C280) is the target for NEM; HIV-1 RT carrying the mutation C280S is resistant to NEM. Since HIV-1 RT is composed of two related subunits (p66 and
p51
) that play distinct roles, we asked whether the C280 in
p51
or the C280 in p66 is responsible for the sensitivity of the enzyme to NEM. HIV-1 RT versions were prepared that had one mutant and one wild-type subunit. When these chimeric enzymes were tested, both the
p51
and p66 subunits were found to contribute to the sensitivity of the enzyme to NEM. The implications of these results are discussed in the context of the structure of the enzyme.
...
PMID:Subunit-specific mutagenesis of the cysteine 280 residue of the reverse transcriptase of human immunodeficiency virus type 1: effects on sensitivity to a specific inhibitor of the RNase H activity. 918 46
Structural studies of authentic HIV reverse transcriptase (RT) suggest a role for the
p51
carboxyl terminus in forming an active
RNase H
conformation [Rodgers, D. W., Gamblin, S. J., Harris, B. A., Ray, S., Culp, J. S., Hellmig, B., Woolf, D. J., Debouck, C. & Harrison, S. C. (1995) Proc. Natl. Acad. Sci. USA 92, 1222-1226]. We have purified mutant RT heterodimers containing deletion of 5, 9, or 13 amino acids from the
p51
carboxyl terminus. These "selectively deleted" heterodimers have been analyzed for changes in RNA-dependent DNA polymerase activity,
RNase H
activity, and the ability to catalyze DNA strand transfer. As deletions extended into the
p51
subunit, a decrease in the stability of the RT-DNA complex was apparent. The largest effect was observed for p66/p51Delta13 RT, which showed a 3-fold decrease relative to wild-type RT.
RNase H
activity was measured by digestion of the RNA in a 5' 32P-labeled RNA/DNA hybrid. Deletion of 5 or 9 amino acids from
p51
had little effect on synthesis-dependent and synthesis-independent
RNase H
activities. In contrast, deletion of 13 amino acids from
p51
increased the length of the hydrolysis products of both
RNase H
activities by 8-10 bp, thus changing the spatial relationship between the polymerase and
RNase H
active sites from a distance of 17-18 bp to 26-27 bp. The Delta13 derivative was also incapable of efficient DNA strand transfer. This defect in strand transfer could be suppressed by the 71-amino acid form of HIV nucleocapsid protein (NC) but not by the 55-amino acid form (NC55) or by equine infectious anemia virus NC. These results provide evidence for the existence of a specific complex between RT and NC and are discussed in terms of the role of this complex in proviral DNA synthesis.
...
PMID:Mutations in HIV reverse transcriptase which alter RNase H activity and decrease strand transfer efficiency are suppressed by HIV nucleocapsid protein. 919 28
Recently, tRNALys-3 was cross-linked via its anticodon loop to human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) between residues 230 and 357 (Mishima, Y., and Steitz, J. A. (1995) EMBO J. 14, 2679-2687). Scanning the surface of this region identified three basic amino acids Lys249, Arg307, and Lys311 flanking a small crevice on the p66 thumb subdomain outside the primer-template binding cleft. To assess an interaction of this region with the tRNA anticodon loop, these p66 residues were altered to Glu or Gln. p66 subunits containing K249Q, K311Q, K311E, and a dual R307E/K311E mutation formed a stable dimer with wild type
p51
. All mutants showed reduced affinity for tRNALys-3 and supported significantly less (-)-strand DNA synthesis from this primer than the parental heterodimer. In contrast, these variants efficiently synthesized HIV-1 (-)-strand strong-stop DNA from oligonucleotide primers and had minimal effect on
RNase H
activity, retaining endonucleolytic and directed cleavage of an RNA/DNA hybrid. Structural features of binary RT.tRNALys-3 complexes were examined by in situ footprinting, via susceptibility to 1, 10-phenanthroline-copper-mediated cleavage. Unlike wild type RT, mutants p66(K311Q)/
p51
and p66(K311E)/
p51
failed to protect the tRNA anticodon domain from chemical cleavage, indicating a significant structural alteration in the binary RT.tRNA complex. These results suggest a crevice in the p66 thumb subdomain of HIV-1 RT supports an interaction with the tRNALys-3 anticodon loop critical for efficient (-)-strand DNA synthesis.
...
PMID:Mutating a region of HIV-1 reverse transcriptase implicated in tRNA(Lys-3) binding and the consequences for (-)-strand DNA synthesis. 960 66
The reverse transcriptase (RT) of HIV-1 and feline immunodeficiency virus (FIV) consist of two subunits of 51 kDa (
p51
) and 66 kDa (p66). In order to elucidate the role of
p51
in the heterodimer, chimeric HIV-1/FIV RT heterodimers were constructed and characterized. The FIV RT
p51
/HIV-1 RT p66 chimera showed a 2.5-fold higher
RNase H
activity than the natural HIV-1 RT, a 50% lower strand displacement DNA synthesis activity and resistance to the two RT inhibitors 3'-azido-3'-deoxythymidine triphosphate (AZTTP) and Nevirapine. The HIV-1 RT
p51
/FIV RT p66 chimera on the other hand had very similar properties to the natural FIV RT. The differences observed upon exchange of the
p51
subunits suggest that the three-dimensional structure of the
p51
subunit in the RT heterodimers is not completely conserved between the human and the feline lentiviruses. Finally, our data suggest an important role for the
p51
subunit in maintaining the optimal structural integrity of the RT heterodimer. The different effects of the small subunits on the sensitivity to known RT inhibitors might be of importance in the development of novel drugs against HIV-1 RT.
...
PMID:Chimeric HIV-1 and feline immunodeficiency virus reverse transcriptases: critical role of the p51 subunit in the structural integrity of heterodimeric lentiviral DNA polymerases. 961 40
Homodimeric EIAV
p51
/51 and heterodimeric EIAV p66/51 reverse transcriptase were purified in order to compare the different modes of DNA synthesis supported by the enzymes. Analysis of the dimerization behavior of the EIAV enzymes indicates that the dimer stability of EIAV reverse transcriptase enzymes is higher than that of their HIV-1 reverse transcriptase counterparts. EIAV
p51
/51 polymerizes DNA distributively whereas DNA synthesis by EIAV p66/51 is processive. Steady-state and pre-steady-state kinetic analyses of primer/template binding and nucleotide incorporation were performed with both enzymes to determine the reasons for the different polymerization behavior. Equilibrium fluorescence titrations demonstrated that the Kd values of EIAV
p51
/51 for binding of DNA/DNA and DNA/RNA substrates are increased 10-fold and 28-fold, respectively, as compared to EIAV p66/51. Stopped-flow measurements with DNA/DNA show that the increase in the Kd is in part due to a 17. 4-fold higher dissociation rate constant (k-1) for EIAV
p51
/51. Additionally, with EIAV
p51
/51, kdiss is increased 7-fold for DNA/DNA and 14-fold for DNA/RNA primer/template substrates, respectively. The lack of the
RNase H
domain in EIAV
p51
/51 leads to differences in the pre-steady-state kinetics of nucleotide incorporation on DNA/DNA and DNA/RNA templates. The burst of both enzymes is composed of two phases for both substrates, and the values for the corresponding pre-steady-state burst rates, kpol1 and kpol2, are similar for both enzymes, implying the formation of identical polymerase active sites. However, the amplitudes of the two phases differ with DNA/DNA templates, indicating a different distribution between two states varying greatly in their kinetic competence.
...
PMID:Analysis of the polymerization kinetics of homodimeric EIAV p51/51 reverse transcriptase implies the formation of a polymerase active site identical to heterodimeric EIAV p66/51 reverse transcriptase. 972 26
In order to study the inferences of structure for mechanism, the collective motions of the retroviral reverse transcriptase HIV-1 RT (RT) are examined using the Gaussian network model (GNM) of proteins. This model is particularly suitable for elucidating the global dynamic characteristics of large proteins such as the presently investigated heterodimeric RT comprising a total of 982 residues. Local packing density and coordination order of amino acid residues is inspected by the GNM to determine the type and range of motions, both at the residue level and on a global scale, such as the correlated movements of entire subdomains. Of the two subunits, p66 and
p51
, forming the RT, only p66 has a DNA-binding cleft and a functional polymerase active site. This difference in the structure of the two subunits is shown here to be reflected in their dynamic characteristics: only p66 has the potential to undergo large-scale cooperative motions in the heterodimer, while
p51
is essentially rigid. Taken together, the global motion of the RT heterodimer is comprised of movements of the p66 thumb subdomain perpendicular to those of the p66 fingers, accompanied by anticorrelated fluctuations of the
RNase H
domain and
p51
thumb, thus providing information about the details of one processivity mechanism. A few clusters of residues, generally distant in sequence but close in space, are identified in the p66 palm and connection subdomains, which form the hinge-bending regions that control the highly concerted motion of the subdomains. These regions include the catalytically active site and the non-nucleoside inhibitor binding pocket of p66 polymerase, as well as sites whose mutations have been shown to impair enzyme activity. It is easily conceivable that this hinge region, indicated by GNM analysis to play a critical role in modulating the global motion, is locked into an inactive conformation upon binding of an inhibitor. Comparative analysis of the dynamic characteristics of the unliganded and liganded dimers indicates severe repression of the mobility of the p66 thumb in RT's global mode, upon binding of non-nucleoside inhibitors.
...
PMID:Collective motions in HIV-1 reverse transcriptase: examination of flexibility and enzyme function. 988 65
The human immunodeficiency virus (HIV) reverse transcriptase (RT) is a heterodimeric enzyme composed of a 66 kDa (p66) and a 51 kDa (
p51
) subunit. Recently we showed that
p51
plays an important role in the conformation of p66 within the HIV-1 RT heterodimer and hence appears to influence its catalytic activities [Amacker, M., and H ubscher, U. (1998) J. Mol. Biol. 278, 757-765]. This was further investigated here via construction of three intramolecular chimeras of HIV-1 and FIV RTs. The first 25 and 112 amino acids of the N terminus, respectively, as well as the last 22 amino acids of the C terminus in the
p51
subunit of HIV-1 RT were exchanged with the corresponding regions of the FIV RT and combined with the wild-type HIV-1 p66. Characterization of these chimeric RT heterodimers demonstrated significant biochemical differences in (i) DNA-dependent DNA synthesis, (ii) strand displacement DNA synthesis, and (iii)
RNase H
activity. Our results indicate that both the N and C termini of HIV-1 RT
p51
appear to be important in stabilizing the RT heterodimer for enzymatic functions.
...
PMID:Intramolecular chimeras of the p51 subunit between HIV-1 and FIV reverse transcriptases suggest a stabilizing function for the p66 subunit in the heterodimeric enzyme. 993 Oct 31
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