The structure of unliganded reverse transcriptase from the human immunodeficiency virus type 1.

Rodgers, David W.; Gamblin, Steven J.; Harris, Bruce A.; Ray, Soumya S.; Culp, Jeffrey S.; Hellmig, Brian D.; Woolf, Deborah J.; Debouck, Christine; Harrison, Stephen C.

doi:10.1073/pnas.92.4.1222

Cited by 359 publications

(364 citation statements)

References 13 publications

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“…From the results obtained, we conclude that the ␤ and Pol subunits fulfill mainly a structural function similar to that of the p51 subunits of HIV-1 RT and EIAV RT (13,14,19,21,29,32). However, we cannot completely exclude the possibility that the large subunit fulfills some minor function in catalysis, since mutations in Asp 181 or Asp 505 of the ␤ subunit appear to have some impact on the polymerase or RNase H activities.…”

Section: Discussionmentioning

confidence: 62%

“…amino acid residues of the polymerase and RNase H active sites of RTs are highly conserved (2,3,15). In addition, comparison of the crystal structures of HIV-1 RT and the finger and palm domains of murine leukemia virus RT indicates that the geometry of the polymerase active sites of RTs is highly conserved (6,14,19,29). We used this information for selecting the amino acids to be mutated in RSV RT to obtain enzymes impaired in their polymerase or RNase H activities.…”

Section: Mutagenesis Of Baculovirus Transfer Vectorsmentioning

confidence: 99%

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Asymmetric Subunit Organization of Heterodimeric Rous Sarcoma Virus Reverse Transcriptase αβ: Localization of the Polymerase and RNase H Active Sites in the α Subunit

Werner

Wöhrl

2000

J Virol

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The genes encoding the ␣ (63-kDa) and ␤ (95-kDa) subunits of Rous sarcoma virus (RSV) reverse transcriptase (RT) or the entire Pol polypeptide (99 kDa) were mutated in the conserved aspartic acid residue Asp 181 of the polymerase active site (YMDD) or in the conserved Asp 505 residue of the RNase H active site. We have analyzed heterodimeric recombinant RSV ␣␤ and ␣Pol RTs within which one subunit was selectively mutated. When ␣␤ heterodimers contained the Asp 1813Asn mutation in their ␤ subunits, about 42% of the wild-type polymerase activity was detected, whereas when the heterodimers contained the same mutation in their ␣ subunits, only 7.5% of the wild-type polymerase activity was detected. Similar results were obtained when the conserved Asp 505 residue of the RNase H active site was mutated to Asn. RNase H activity was clearly detectable in ␣␤ heterodimers mutated in the ␤ subunit but was lost when the mutation was present in the ␣ subunit. In summary, our data imply that the polymerase and RNase H active sites are located in the ␣ subunit of the heterodimeric RSV RT ␣␤. Reverse transcriptase (RT) of Rous sarcoma virus (RSV) is a component of the Gag-Pol precursor protein.Pol is composed of polymerase, RNase H, and integrase domains and an additional short 4.1-kDa protein located at the C terminus of the protein. Pol is processed into polypeptides of various lengths by the viral protease; its ␣ polypeptide (63 kDa) contains the polymerase and RNase H domains, and its ␤ polypeptide (95 kDa) consists of the polymerase, RNase H, and integrase domains but lacks the C-terminal 4.1-kDa protein (1,7,8,17,28,30). In addition, the integrase domain (32 kDa) is also present and active as a separate enzyme (9, 30). Three forms of RT have been isolated from avian sarcoma and leukosis viruses (ASLV): ␣, ␤, and ␣␤, with the major form being the heterodimer (8,11,16). We have shown previously that the different forms of RSV RT can be expressed and purified from insect cells using the baculovirus expression system (37). In order to examine the subunit organization of RSV RT, the technique of subunit-selective mutagenesis was used (13,21) to analyze the effect of RSV RTs carrying a mutation in only one of the two subunits constituting the ␣␤ or ␣Pol heterodimer.It has been shown previously by biochemical and crystallographic data that heterodimeric human immunodeficiency virus type 1 (HIV-1) RT p66-p51 reveals an asymmetric subunit organization. The polymerase active site is present only in the larger p66 subunit of the heterodimer (13,14,19,36), while the p51 subunit, which is identical in sequence to p66 but lacks the RNase H domain, is not directly involved in catalysis (21). However, p51 has to fulfill an important stabilizing function since the monomeric subunits are inactive (26,27). Recent kinetic analyses we performed with homodimeric p51 RT from equine infectious anemia virus (EIAV) lacking the RNase H domain indicated an asymmetric subunit organization similar to that of heterodimeric p66-p51 RT, with the polymera...

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Section: Discussionmentioning

confidence: 62%

Section: Mutagenesis Of Baculovirus Transfer Vectorsmentioning

confidence: 99%

Asymmetric Subunit Organization of Heterodimeric Rous Sarcoma Virus Reverse Transcriptase αβ: Localization of the Polymerase and RNase H Active Sites in the α Subunit

Werner

Wöhrl

2000

J Virol

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“…4b) from the position that it occupies in DNA-bound HIV-1 RT complexes (51)(52)(53)(54)(55) and in unliganded HIV-1 RT structures crystallized in the absence of inhibitors (21,22,24). In other NNRTI complexes with HIV-1 RT, the displacement of Trp-229 is required for the rearrangements of Tyr-181 and Tyr-188 that occur upon inhibitor binding.…”

Section: Discussionmentioning

confidence: 99%

“…Subsequent structures of the enzyme with a number of different NNRTIs bound have demonstrated that these inhibitors bind to the same pocket, with only minor differences in protein conformation, and substantially overlap the site occupied by nevirapine (6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20). Comparison of these structures with those of the apoenzyme shows that the NNRTI-binding pocket is induced upon NNRTI binding (21)(22)(23)(24).…”

mentioning

confidence: 99%

Structure of HIV-1 reverse transcriptase bound to an inhibitor active against mutant reverse transcriptases resistant to other nonnucleoside inhibitors

Pata

Stirtan

Goldstein

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

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We have determined the crystal structure of the HIV type 1 reverse transcriptase complexed with CP-94,707, a new nonnucleoside reverse transcriptase inhibitor (NNRTI), to 2.8-Å resolution. In addition to inhibiting the wild-type enzyme, this compound inhibits mutant enzymes that are resistant to inhibition by nevirapine, efavirenz, and delaviridine. In contrast to other NNRTI complexes where tyrosines 181 and 188 are pointing toward the enzyme active site, the binding pocket in this complex has the tyrosines pointing the opposite direction, as in the unliganded protein structure, to accommodate CP-94,707. This conformation of the pocket has not been observed previously in NNRTI complexes and substantially alters the shape and surface features that are available for interactions with the inhibitor. One ring of CP-94,707 makes extensive stacking interactions with tryptophan 229, one of the few residues in the NNRTI-binding pocket that cannot readily mutate to give rise to drug resistance. In this conformation of the pocket, mutations of tyrosines 181 and 188 are less likely to disrupt inhibitor binding. Modeling the asparagine mutation of lysine 103 shows that a hydrogen bond between it and tyrosine 188 could form as readily in the CP-94,707 complex as it does in the apoenzyme structure, providing an explanation for the activity of this inhibitor against this clinically important mutant.

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“…Stammers et al, 1990;Unge et al, 1990;Lloyd et al, 1991;Kohlstaedt et al, 1992;Jones et al, 1993;Jacobo-Molina et al, 1993;Stammers et al, 1994;Rodgers et al, 1995), although few showed diffraction to high resolution. The structure was eventually described [for RT in complex with the NNI nevirapine (Merluzzi et al, 1990)] based on data to a minimum Bragg spacing of 3.4 A (Kohlstaedt et al, 1992), and was later extended to 2.9 A resolution .…”

Section: Introductionmentioning

confidence: 99%

Continuous and Discontinuous Changes in the Unit Cell of HIV-1 Reverse Transcriptase Crystals on Dehydration

et al. 1998

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A crystal form of HIV-1 reverse transcriptase (RT) complexed with inhibitors showed diffraction to a highresolution limit of 3.7 ,~. Instability in the unit-cell dimensions of these crystals was observed during soaking experiments, but the range of this variability and consequent change in lattice order was revealed by a chance observation of dehydration. Deliberately induced dehydration results in crystals having a variety of unit cells, the best-ordered of which show diffraction to a minimum Bragg spacing of 2.2,~. In order to understand the molecular basis for this phenomenon, the initial observation of dehydration, the data sets from dehydrated crystals, the crystal packing and the domain conformation of RT are analysed in detail here. This analysis reveals that the crystals undergo remarkable changes following a variety of possible dehydration pathways: some changes occur gradually whilst others are abrupt and require significant domain rearrangements. Comparison of domain arrangements in different crystal forms gives insight into the flexibility of RT which, in turn, may reflect the internal motions allowing this therapeutically important enzyme to fulfill its biological function.

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The structure of unliganded reverse transcriptase from the human immunodeficiency virus type 1.

Cited by 359 publications

References 13 publications

Asymmetric Subunit Organization of Heterodimeric Rous Sarcoma Virus Reverse Transcriptase αβ: Localization of the Polymerase and RNase H Active Sites in the α Subunit

Asymmetric Subunit Organization of Heterodimeric Rous Sarcoma Virus Reverse Transcriptase αβ: Localization of the Polymerase and RNase H Active Sites in the α Subunit

Structure of HIV-1 reverse transcriptase bound to an inhibitor active against mutant reverse transcriptases resistant to other nonnucleoside inhibitors

Continuous and Discontinuous Changes in the Unit Cell of HIV-1 Reverse Transcriptase Crystals on Dehydration

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