Changes to the HIV Long Terminal Repeat and to HIV Integrase Differentially Impact HIV Integrase Assembly, Activity, and the Binding of Strand Transfer Inhibitors

Dicker, Ira B.; Samanta, Himadri; Li, Zhufang; Hong, Yang; Tian, Yuan; Banville, Jacques; Remillard, Roger; Walker, Michael; Langley, David R.; Krystal, Mark

doi:10.1074/jbc.m704935200

Cited by 47 publications

(58 citation statements)

References 66 publications

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“…The apparent equilibrium dissociation constant, K d (apparent), was 21 nM, as previously reported (16 up to 643 nM). After equilibrium was reached, the kinetics of dissociation were monitored after adding a large molar excess of unlabeled 1.…”

Section: Methodssupporting

confidence: 82%

“…PVT scintillation proximity assay (SPA) beads were from Amersham Biosciences. The d-spacer and aminadenosine monomers were from Glen Research, Sterling, VA. Recombinant IN enzymes were purified from an NL4-3 clone, as previously described (16 (16). LTR duplexes were prepared such that the 5′ end of the plus strand was synthesized with a biotin linker attached.…”

Section: Methodsmentioning

confidence: 99%

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The Terminal (Catalytic) Adenosine of the HIV LTR Controls the Kinetics of Binding and Dissociation of HIV Integrase Strand Transfer Inhibitors

et al. 2008

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Specific HIV integrase strand transfer inhibitors are thought to bind to the integrase active site, positioned to coordinate with two catalytic magnesium atoms in a pocket flanked by the end of the viral LTR. A structural role for the 3′ terminus of the viral LTR in the inhibitor-bound state has not previously been examined. This study describes the kinetics of binding of a specific strand transfer inhibitor to integrase variants assembled with systematic changes to the terminal 3′ adenosine. Kinetic experiments are consistent with a two-step binding model in which there are different functions for the terminal adenine base and the terminal deoxyribose sugar. Adenine seems to act as a "shield" which retards the rate of inhibitor association with the integrase active site, possibly by acting as an internal competitive inhibitor. The terminal deoxyribose is responsible for retarding the rate of inhibitor dissociation, either by sterically blocking inhibitor egress or by a direct interaction with the bound inhibitor. These findings further our understanding of the details of the inhibitor binding site of specific strand transfer inhibitors.

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Section: Methodssupporting

confidence: 82%

Section: Methodsmentioning

confidence: 99%

The Terminal (Catalytic) Adenosine of the HIV LTR Controls the Kinetics of Binding and Dissociation of HIV Integrase Strand Transfer Inhibitors

et al. 2008

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“…Viral DNA 3Ј end processing by IN is proposed to create a hydrophobic drug binding pocket in the space vacated by the removal of 3Ј-GT, bounded by the flexible active site loop (30) and the 5Ј-CA overhang of the viral DNA (32). Inhibitor binding is attenuated when either the flexibility of the active site loop is impaired (33) or the 5Ј-CA overhang of the viral DNA is deleted (32). Although the thiol group on the 5Ј-CA overhang cross-links efficiently to either K160C or Y143C, only cross-linked Y143C binds IN inhibitor.…”

Section: Dna Tethering Overcomes In Requirement Of the Ntd For Strandmentioning

confidence: 99%

Catalytically-active complex of HIV-1 integrase with a viral DNA substrate binds anti-integrase drugs

Alian¹,

Griner²,

Chiang³

et al. 2009

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

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IN consists of 3 functional domains: the N-terminal domain (NTD; residues 1-51) that contains a conserved ''HH-CC'' zincbinding motif, the catalytic core domain (CCD; residues 52-210) with the catalytic residues (D64, D116, and E152), and the Cterminal domain (CTD; residues 210-288) that contributes to DNA binding (2). In solution, recombinant IN exists in a dynamic equilibrium between monomers, dimers, tetramers, and higherorder oligomers (3, 4). Monomers are reportedly inactive in vitro, whereas dimers are able to catalyze 3Ј processing and integration of 1 viral end (4-9). Tetramers, which have also been isolated from human cells expressing HIV-1 IN (10), can catalyze integration of 2 viral DNA ends into target DNA (7, 11), but the exact nature of the IN complex mediating 3Ј processing and strand transfer reactions remains to be determined. The integration step is an attractive drug target given its essential role in the viral life cycle and the lack of a cellular IN homologue. Strand transfer inhibitors appear to bind significantly better to IN when it is assembled on its DNA substrate than to IN alone (12). To date there is only 1 structure of an inhibitor bound to IN (13), and that is in the absence of DNA. The compound binds at the active site; however, it dimerizes across a crystallographic 2-fold axis and therefore might not be in its bioactive configuration.Structure-based understanding of the mechanisms of the action of IN inhibitors and optimization of compounds as potential drugs targeting HIV-1 IN have been hampered by the inability to capture and crystallize IN-DNA complexes. Two key factors have contributed to this problem: first, the high salt concentration (Ϸ1 M NaCl) required to maintain full-length IN in solution interferes with DNA binding; second, IN has intrinsically low affinity for DNA. To overcome these 2 obstacles, we used disulfide cross-linking to generate soluble, catalytically-active, covalent IN-DNA complexes. A similar strategy, covalent disulfide cross-linking between HIV-1 reverse transcriptase (RT) and DNA, mediated crystallization of the .Previous cross-linking from cysteinal mutations in the CTD (6) and CCD (15) Here, we describe an IN cysteine mutant, IN Y143C , which is able to form IN-DNA complexes efficiently. The IN Y143C -DNA complexes form stable tetramers in solution, retain single-end strand transfer activity, show increased resistance to protease and nuclease digestion, and bind a strand transfer inhibitor. This IN-DNA complex can serve as an in vitro platform to identify and evolve strand transfer inhibitors of HIV integration and as a means of understanding the basis for a key part of the integration reaction.

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“…Compared with the wild type (WT) enzyme, all variant enzymes were impaired with respect to assembly and multimerization into active complexes and their subsequent in vitro strand transfer abilities. Reduced susceptibility to one STI, STI 1, (23), was shown to be a result of decreased affinity of the inhibitor for the integrase enzymes containing the selected mutations. In addition, isogenic viruses harboring these resistance mutations showed defects in integration in cells.…”

Section: Hiv-1mentioning

confidence: 99%

“…The details of the assay have been reported previously (23). Briefly, viral LTR DNA is attached, via a biotin linker, to streptavidin-coated SPA PVT beads, after which the enzyme is added to form active complexes.…”

Section: Scintillation Proximity Assay (Spa) For Determination Of Kinmentioning

confidence: 99%

Biochemical Analysis of HIV-1 Integrase Variants Resistant to Strand Transfer Inhibitors

Dicker

Terry

Lin

et al. 2008

Journal of Biological Chemistry

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In this study, eight different HIV-1 integrase proteins containing mutations observed in strand transfer inhibitor-resistant viruses were expressed, purified, and used for detailed enzymatic analyses. All the variants examined were impaired for strand transfer activity compared with the wild type enzyme, with relative catalytic efficiencies (k p /K m ) ranging from 0.6 to 50% of wild type. The origin of the reduced strand transfer efficiencies of the variant enzymes was predominantly because of poorer catalytic turnover (k p ) values. However, smaller secondorder effects were caused by up to 4-fold increases in K m values for target DNA utilization in some of the variants. All the variants were less efficient than the wild type enzyme in assembling on the viral long terminal repeat, as each variant required more protein than wild type to attain maximal activity. In addition, the variant integrases displayed up to 8-fold reductions in their catalytic efficiencies for 3-processing. The Q148R variant was the most defective enzyme. The molecular basis for resistance of these enzymes was shown to be due to lower affinity binding of the strand transfer inhibitor to the integrase complex, a consequence of faster dissociation rates. In the case of the Q148R variant, the origin of reduced compound affinity lies in alterations to the active site that reduce the binding of a catalytically essential magnesium ion. Finally, except for T66I, variant viruses harboring the resistance-inducing substitutions were defective for viral integration.

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Changes to the HIV Long Terminal Repeat and to HIV Integrase Differentially Impact HIV Integrase Assembly, Activity, and the Binding of Strand Transfer Inhibitors

Cited by 47 publications

References 66 publications

The Terminal (Catalytic) Adenosine of the HIV LTR Controls the Kinetics of Binding and Dissociation of HIV Integrase Strand Transfer Inhibitors

The Terminal (Catalytic) Adenosine of the HIV LTR Controls the Kinetics of Binding and Dissociation of HIV Integrase Strand Transfer Inhibitors

Catalytically-active complex of HIV-1 integrase with a viral DNA substrate binds anti-integrase drugs

Biochemical Analysis of HIV-1 Integrase Variants Resistant to Strand Transfer Inhibitors

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