Solution structure of the His12 --> Cys mutant of the N-terminal zinc binding domain of HIV-1 integrase complexed to cadmium.

The solution structure of His12 --> Cys mutant of the N-terminal zinc binding domain (residues 1-55; IN(1-55)) of HIV-1 integrase complexed to cadmium has been solved by multidimensional heteronuclear NMR spectroscopy. The overall structure is very similar to that of the wild-type N-terminal domain complexed to zinc. In contrast to the wild-type domain, however, which exists in two interconverting conformational states arising from different modes of coordination of the two histidine side chains to the metal, the cadmium complex of the His12 --> Cys mutant exists in only a single form at low pH. The conformation of the polypeptide chain encompassing residues 10-18 is intermediate between the two forms of the wild-type complex.     

Structural implications of spectroscopic characterization of a putative zinc finger peptide from HIV-1 integrase.

The N-terminal domain of human immunodeficiency virus (HIV-1) integrase (IN) contains the sequence motif His-Xaa3-His-Xaa23-Cys-Xaa2-Cys, which is strongly conserved in all retroviral and retrotransposon IN proteins. This structural motif constitutes a putative zinc finger in which a metal ion may be coordinately bound by the His and Cys residues. A recombinant peptide, IN(1-55), composed of the N-terminal 55 amino acids of HIV-1 IN was expressed in Escherichia coli and purified. Utilizing a combination of techniques including UV-visible absorption, circular dichroism, Fourier transform infrared, and fluorescence spectroscopies, we have demonstrated that metal ions (Zn2+, Co2+, and Cd2+) are bound with equimolar stoichiometry by IN(1-55). The liganded peptide assumes a highly ordered structure with increased alpha-helical content and exhibits remarkable thermal stability. UV-visible difference spectra of the peptide-Co2+ complexes directly implicate thiols in metal coordination, and Co2+ d-d transitions in the visible range indicate that Co2+ is tetrahedrally coordinated. Mutant peptides containing conservative substitutions of one of the conserved His or either of the Cys residues displayed no significant Zn(2+)-induced conformational changes as monitored by CD and fluorescence spectra. We conclude that the N terminus of HIV-1 IN contains a metal-binding domain whose structure is stabilized by tetrahedral coordination of metal by histidines 12 and 16 and cysteines 40 and 43. A preliminary structural model for this zinc finger is presented.     

An inhibitory monoclonal antibody binds at the turn of the helix-turn-helix motif in the N-terminal domain of HIV-1 integrase

With the increase in our understanding of its structure and enzymatic mechanism, HIV-1 integrase (IN) has become a promising target for designing drugs to treat patients with AIDS. To investigate the structure and function of IN, a panel of monoclonal antibodies (mAbs) directed against HIV-1 IN was raised and characterized previously in this laboratory. Among them, mAbs17, -4, and -33 were found to inhibit IN activity in vitro. In this study, we investigated the interaction of N-terminal-specific mAb17 and its isolated Fab fragment with full-length HIV-1 IN(1-288) and its isolated N-terminal, Zn(2+)-binding domain IN(1-49). Our results show that binding of Zn(2+) to IN(1-49) stabilizes the mAb17-IN complex and that dimer dissociation is not required for binding of the Fab. To identify the epitope recognized by mAb17, we developed a protein footprinting technique based on controlled proteolysis and matrix-assisted laser desorption ionization time-of-flight mass spectrometry. Binding was mapped to a region within amino acids Asp(25)-Glu(35). This peptide corresponds to the end of a helix-turn-helix motif in the IN(1-55) NMR structure and contributes to the dimerization of the N-terminal domain. Antibody binding also appears to destabilize the N-terminal helix in this domain. A molecular model of the [IN(1-49)](2).(Fab)(1) complex shows Fab binding across the dimer protein and suggests a potential target for drug design. These data also suggest that mAb17 inhibits integrase activity by blocking critical protein-protein interactions and/or by distorting the orientation of the N-terminal alpha-helix. The relevance of our results to an understanding of IN function is discussed.     

Mechanism of inhibition of HIV-1 integrase by G-tetrad-forming oligonucleotides in Vitro

The G-tetrad-forming oligonucleotides and have been identified as potent inhibitors of human immunodeficiency virus type 1 integrase (HIV-1 IN) activity (Rando, R. F., Ojwang, J., Elbaggari, A., Reyes, G. R., Tinder, R., McGrath, M. S., and Hogan, M. E. (1995) J. Biol. Chem. 270, 1754-1760; Mazumder, A., Neamati, N., Ojwang, J. O., Sunder, S., Rando, R. F., and Pommier, Y. (1996) Biochemistry 35, 13762-13771; Jing, N., and Hogan, M. E. (1998) J. Biol. Chem. 273, 34992-34999). To understand the inhibition of HIV-1 IN activity by the G-quartet inhibitors, we have designed the oligonucleotides and, composed of three and four G-quartets with stem lengths of 19 and 24 A, respectively. The fact that increasing the G-quartet stem length from 15 to 24 A kept inhibition of HIV-1 IN activity unchanged suggests that the binding interaction occurs between a GTGT loop domain of the G-quartet inhibitors and a catalytic site of HIV-1 IN, referred to as a face-to-face interaction. Docking the NMR structure of (Jing and Hogan (1998)) into the x-ray structure of the core domain of HIV-1 IN, HIV-1 IN-(51-209) (Maignan, S., Guilloteau, J.-P. , Qing, Z.-L., Clement-Mella, C., and Mikol, V. (1998) J. Mol. Biol. 282, 359-368), was performed using the GRAMM program. The statistical distributions of hydrogen bonding between HIV-1 IN and were obtained from the analyses of 1000 random docking structures. The docking results show a high probability of interaction between the GTGT loop residues of the G-quartet inhibitors and the catalytic site of HIV-1 IN, in agreement with the experimental observation.     

D77, one benzoic acid derivative, functions as a novel anti-HIV-1 inhibitor targeting the interaction between integrase and cellular LEDGF/p75

Integration of viral-DNA into host chromosome mediated by the viral protein HIV-1 integrase (IN) is an essential step in the HIV-1 life cycle. In this process, Lens epithelium-derived growth factor (LEDGF/p75) is discovered to function as a cellular co-factor for integration. Since LEDGF/p75 plays an important role in HIV integration, disruption of the LEDGF/p75 interaction with IN has provided a special interest for anti-HIV agent discovery. In this work, we reported that a benzoic acid derivative, 4-[(5-bromo-4-{[2,4-dioxo-3-(2-oxo-2-phenylethyl)-1,3-thiazolidin-5-ylidene]methyl}-2-ethoxyphenoxy)methyl]benzoic acid (D77) could potently inhibit the IN-LEDGF/p75 interaction and affect the HIV-1 IN nuclear distribution thus exhibiting antiretroviral activity. Molecular docking with site-directed mutagenesis analysis and surface plasmon resonance (SPR) binding assays has clarified possible binding mode of D77 against HIV-1 integrase. As the firstly discovered small molecular compound targeting HIV-1 integrase interaction with LEDGF/p75, D77 might supply useful structural information for further anti-HIV agent discovery.     

Characterization of a DNA binding domain in the C-terminus of HIV-1 integrase by deletion mutagenesis.

The integrase (IN) protein of human immunodeficiency virus type 1 (HIV-1) catalyzes site-specific cleavage of 2 bases from the viral long terminal repeat (LTR) sequence yet it binds DNA with little DNA sequence specificity. We have previously demonstrated that the C-terminal half of IN (amino acids 154-288) possesses a DNA binding domain. In order to further characterize this region, a series of clones expressing truncated forms of IN as N-terminal fusion proteins in E.coli were constructed and analyzed by Southwestern blotting. Proteins containing amino acids 1-263, 1-248 and 170-288 retained the ability to bind DNA, whereas a protein containing amino acids 1-180 showed no detectable DNA binding. This defines a DNA binding domain contained within amino acids 180-248. This region contains an arrangement of 9 lysine and arginine residues each separated by 2-4 amino acids (KxxxKxxxKxxxxRxxxRxxRxxxxKxxxKxxxK), spanning amino acids 211-244, which is conserved in all HIV-1 isolates. A clone expressing full-length IN with a C-terminal fusion of 16 amino acids was able to bind DNA comparably to a cloned protein with a free C-terminus, and an IN-specific monoclonal antibody which recognizes an epitope contained within amino acids 264-279 was unable to block DNA binding, supporting the evidence that a region necessary for binding lies upstream of amino acid 264.     

Structure of a two-domain fragment of HIV-1 integrase: implications for domain organization in the intact protein.

Retroviral integrase, an essential enzyme for replication of human immunodeficiency virus type-1 (HIV-1) and other retroviruses, contains three structurally distinct domains, an N-terminal domain, the catalytic core and a C-terminal domain. To elucidate their spatial arrangement, we have solved the structure of a fragment of HIV-1 integrase comprising the N-terminal and catalytic core domains. This structure reveals a dimer interface between the N-terminal domains different from that observed for the isolated domain. It also complements the previously determined structure of the C-terminal two domains of HIV-1 integrase; superposition of the conserved catalytic core of the two structures results in a plausible full-length integrase dimer. Furthermore, an integrase tetramer formed by crystal lattice contacts bears structural resemblance to a related bacterial transposase, Tn5, and exhibits positively charged channels suitable for DNA binding.     

A novel short peptide is a specific inhibitor of the human immunodeficiency virus type 1 integrase

The retroviral encoded protein integrase (IN) is required for the insertion of the human immunodeficiency virus type 1 (HIV-1) proviral DNA into the host genome. In spite of the crucial role played by IN in the retroviral life cycle, which makes this enzyme an attractive target for the development of new anti-AIDS agents, very few inhibitors have been described and none seems to have a potential use in anti-HIV therapy. To obtain potent and specific IN inhibitors, we used the two-hybrid system to isolate short peptides. Using HIV-1 IN as a bait and a yeast genomic library as the source of inhibitory peptides (prey), we isolated a 33-mer peptide (I33) that bound tightly to the enzyme. I33 inhibited both in vitro IN activities, i.e. 3' end processing and strand transfer. Further analysis led us to select a shorter peptide, EBR28, corresponding to the N-terminal region of I33. Truncated variants showed that EBR28 interacted with the catalytic domain of IN interfering with the binding of the DNA substrate. Alanine single substitution of each EBR28 residue (alanine scanning) allowed the identification of essential amino acids involved in the inhibition. The EBR28 NMR structure shows that this peptide adopts an alpha-helical conformation with amphipathic properties. Additionally, EBR28 showed a significant antiviral effect when assayed on HIV-1 infected human cells. Thus, this potentially important short lead peptide may not only be helpful to design new anti-HIV agents, but also could prove very useful in further studies of the structural and functional characteristics of HIV-1 IN.     

Differential contribution of basic residues to HIV-1 nucleocapsid protein’s nucleic acid chaperone function and retroviral replication

The human immunodeficiency virus type 1 (HIV-1) nucleocapsid (NC) protein contains 15 basic residues located throughout its 55-amino acid sequence, as well as one aromatic residue in each of its two CCHC-type zinc finger motifs. NC facilitates nucleic acid (NA) rearrangements via its chaperone activity, but the structural basis for this activity and its consequences in vivo are not completely understood. Here, we investigate the role played by basic residues in the N-terminal domain, the N-terminal zinc finger and the linker region between the two zinc fingers. We use in vitro ensemble and single-molecule DNA stretching experiments to measure the characteristics of wild-type and mutant HIV-1 NC proteins, and correlate these results with cell-based HIV-1 replication assays. All of the cationic residue mutations lead to NA interaction defects, as well as reduced HIV-1 infectivity, and these effects are most pronounced on neutralizing all five N-terminal cationic residues. HIV-1 infectivity in cells is correlated most strongly with NC’s NA annealing capabilities as well as its ability to intercalate the DNA duplex. Although NC’s aromatic residues participate directly in DNA intercalation, our findings suggest that specific basic residues enhance these interactions, resulting in optimal NA chaperone activity.     

E92A是HIV-1整合酶耐药突变N155S的活性回复突变

HIV-1整合酶是目前抗艾滋病药物研发的重要靶点之一,整合酶的耐药突变是导致整合酶抑制剂类药物治疗失败的主要原因,但突变产生耐药性的机理仍不清楚.本工作通过人工构建突变型整合酶,测试其活性和耐药性,对整合酶的耐药机理进行初步探索.构建整合酶的突变型包括E92A、N155S两种单突变及E92A/N155S双突变.通过基因工程操作引入突变、构建质粒、表达纯化得到整合酶蛋白.用基于磁珠的整合酶链转移ELISA测试整合酶的链转移活性,用S-1360和Raltegravir两种抑制剂测试整合酶的耐药性.另外,用Autodock软件做了S-1360和整合酶核心区(包括野生型和突变型)的分子对接.结果表明,N155S突变使整合酶链转移活性下降约80%,而E92A/N155S双突变仅使活性下降约42%,这表明N155S突变基础上的E92A突变可使整合酶的活性大幅回复.E92A和E92A/N155S对不同的抑制剂可产生不同的耐药性,它们对Raltegravir的耐药性强于对S-1360.突变对整合酶活性和耐药性的影响主要是通过改变整合酶活性中心结构实现的,E92A突变可能导致其与周围残基静电相互作用减弱,间接影响到D64和D116残基,产生活性回复作用.     

Dissecting the role of the N-terminal domain of human immunodeficiency virus integrase by trans-complementation analysis

The human immunodeficiency virus (HIV) integrase protein (IN) catalyzes two reactions required to integrate HIV DNA into the human genome: 3' processing of the viral DNA ends and integration. IN has three domains, the N-terminal zinc-binding domain, the catalytic core, and the C-terminal SH3 domain. Previously, it was shown that IN proteins mutated in different domains could complement each other. We now report that this does not require any overlap between the two complementing proteins; an N-terminal domain, provided in trans, can restore IN activity of a mutant lacking this domain. Only the zinc-coordinating form of the N-terminal domain can efficiently restore IN activity of an N-terminal deletion mutant. This suggests that interaction between different domains of IN is needed for functional multimerization. We find that the N-terminal domain of feline immunodeficiency virus IN can support IN activity of an N-terminal deletion mutant of HIV type 2 IN. These cross-complementation experiments indicate that the N-terminal domain contributes to the recognition of specific viral DNA ends.     

Identification of HIV-1 integrase inhibitors via three-dimensional database searching using ASV and HIV-1 integrases as targets

Integration of viral DNA into the host cell genome is a critical step in the life cycle of HIV. This essential reaction is catalyzed by integrase (IN) through two steps, 3'-processing and DNA strand transfer. Integrase is an attractive target for drug design because there is no known cellular analogue and integration is essential for successful replication of HIV. A computational three-dimensional (3-D) database search was used to identify novel HIV-1 integrase inhibitors. Starting from the previously identified Y3 (4-acetylamino-5-hydroxynaphthalene-2,7-disulfonic acid) binding site on the avian sarcoma virus integrase (ASV IN), a preliminary search of all compounds in the nonproprietary, open part of the National Cancer Institute 3-D database yielded a collection of 3100 compounds. A more rigorous scoring method was used to rescreen the 3100 compounds against both ASV IN and HIV-1 IN. Twenty-two of those compounds were selected for inhibition assays against HIV-1 IN. Thirteen of the 22 showed inhibitory activity against HIV-1 IN at concentrations less than 200 microM and three of them showed antiviral activities in HIV-1 infected CEM cells with effective concentrations (EC50) ranging from 0.8 to 200 microM. Analysis of the computer-generated binding modes of the active compounds to HIV-1 IN showed that simultaneous interaction with the Y3 site and the catalytic site is possible. In addition, interactions between the active compounds and the flexible loop involved in the binding of DNA by IN are indicated to occur. The structural details and the unique binding motif between the HIV-1 IN and its inhibitors identified in the present work may contribute to the future development of IN inhibitors.     

Solution Conformation and Dynamics of the HIV-1 Integrase Core Domain

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) is a critical enzyme involved in infection. It catalyzes two reactions to integrate the viral cDNA into the host genome, 3′ processing and strand transfer, but the dynamic behavior of the active site during catalysis of these two processes remains poorly characterized. NMR spectroscopy can reveal important structural details about enzyme mechanisms, but to date the IN catalytic core domain has proven resistant to such an analysis. Here, we present the first NMR studies of a soluble variant of the catalytic core domain. The NMR chemical shifts are found to corroborate structures observed in crystals, and confirm prior studies suggesting that the α4 helix extends toward the active site. We also observe a dramatic improvement in NMR spectra with increasing MgCl₂ concentration. This improvement suggests a structural transition not only near the active site residues but also throughout the entire molecule as IN binds Mg²⁺. In particular, the stability of the core domain is linked to the conformation of its C-terminal helix, which has implications for relative domain orientation in the full-length enzyme. ¹⁵N relaxation experiments further show that, although conformationally flexible, the catalytic loop of IN is not fully disordered in the absence of DNA. Indeed, automated chemical shift-based modeling of the active site loop reveals several stable clusters that show striking similarity to a recent crystal structure of prototype foamy virus IN bound to DNA.     

Constructing HIV-1 integrase tetramer and exploring influences of metal ions on forming integrase-DNA complex

HIV-1 integrase (IN) is essential for the replication of HIV-1 in human cells. At present, the complete structure of complex IN-DNA has not been resolved. In this paper, a HIV-1 IN tetramer model was built with homology modeling and molecular dynamics simulation approach, in which two Mg2+ ions were reasonably located in each catalytic core domain. Moreover, it was found that the AB and CD chains of HIV-1 IN tetramer were different in the structures and metal ions of HIV-1 IN tetramer might have great influences on DNA locating on IN. These findings may provide a more complete structural basis for guiding drug discovery and revealing integration mechanism.     

Minimal Core Domain of HIV-1 Integrase for Biological Activity

The human immunodeficiency virus type-1 (HIV-1) integrase (IN) mediates insertion of viral DNA into human DNA, which is an essential step in the viral life cycle. In order to study minimal core domain in HIV-1 IN protein, we constructed nine deletion mutants by using PCR amplification. The constructs were expressed in Escherichia coli, and the proteins were subsequently purified and analyzed in terms of biological activity such as enzymatic and DNA-binding activities. The mutant INs with an N-terminal or C-terminal deletion showed strong disintegration activity though they failed to show endonucleolytic and strand transfer activities, indicating that the disintegration reaction does not require the fine structure of the HIV-1 IN protein. In the DNA-binding analysis using gel mobility shift assay and UV cross-linking method, it was found that both the central and C-terminal domains are essential for proper DNA-IN protein interaction although the central or C-terminal domain alone was able to be in close contact with DNA substrate. Therefore, our results suggest that the C-terminal domain act as a DNA-holding motive, which leads to proper interaction for enzymatic reaction between the IN protein and DNA.