Binding Mode Prediction of Strand Transfer HIV-1 Integrase Inhibitors Using Tn5 Transposase as a Plausible Surrogate Model for HIV-1 Integrase

The crystal structure of Tn5 transposase-DNA complex was used in docking experiments to predict binding modes of HIV-1 integrase strand transfer inhibitors (INSTIs). In fact, the identification of HIV-1 integrase inhibitors from an in vitro screen using Tn5 transposase as the target has been recently reported. Our results suggest the utility of this protein as a useful surrogate model for IN and also for in silico screening, in the search for new potential INSTIs.

Novel bifunctional quinolonyl diketo acid derivatives as HIV-1 integrase inhibitors: design, synthesis, biological activities, and mechanism of action

The virally encoded integrase protein is an essential enzyme in the life cycle of the HIV-1 virus and represents an attractive and validated target in the development of therapeutics against HIV infection. Drugs that selectively inhibit this enzyme, when used in combination with inhibitors of reverse transcriptase and protease, are believed to be highly effective in suppressing the viral replication. Among the HIV-1 integrase inhibitors, the beta-diketo acids (DKAs) represent a major lead for anti-HIV-1 drug development. In this study, novel bifunctional quinolonyl diketo acid derivatives were designed, synthesized, and tested for their inhibitory ability against HIV-1 integrase. The compounds are potent inhibitors of integrase activity. Particularly, derivative 8 is a potent IN inhibitor for both steps of the reaction (3'-processing and strand transfer) and exhibits both high antiviral activity against HIV-1 infected cells and low cytotoxicity. Molecular modeling studies provide a plausible mechanism of action, which is consistent with ligand SARs and enzyme photo-cross-linking experiments.

Synthetic approaches to nuclease-resistant, nonnatural dinucleotides of anti-HIV integrase interest

New, nonnatural dinucleotide 5'-monophosphates with a surrogate isonucleoside component of L-related stereochemistry, have been synthesized. Structures of the target compounds were confirmed by multinuclear NMR spectra (1H, 13C, 31P, COSY), UV hypochromicity, FAB HRMS data and X-ray crystallography. These compounds are totally resistant to cleavage by 3'- and 5'-exonucleases. Dinucleotides of this study with a terminal L-isonucleoside component showed remarkable selectivity for inhibition of the strand transfer step of HIV-1 integrase. To the best of our knowledge, these compounds represent only the second example of this type of selectivity of inhibition of the strand transfer step.

Division of labor within human immunodeficiency virus integrase complexes: determinants of catalysis and target DNA capture

Following the completion of reverse transcription, the human immunodeficiency virus integrase (IN) enzyme covalently links the viral cDNA to a host cell chromosome. An IN multimer carries out this reaction, but the roles of individual monomers within the complex are mostly unknown. Here we analyzed the distribution of functions for target DNA capture and catalysis within the IN multimer. We used forced complementation between pairs of IN deletion derivatives in vitro as a tool for probing cis-trans relationships and analyzed amino acid substitutions affecting either catalysis or target site selection within these complementing complexes. This allowed the demonstration that the IN variant contributing the active catalytic domain was also responsible for recognition of the integration target DNA. We were further able to establish that a single monomer is responsible for both functions by use of assay mixtures containing three different IN genotypes. These data specify the ligands bound at the catalytically relevant IN monomer and allow more-specific modeling of the mechanism of inhibitors that also bind this surface of IN.

The Endonuclease Domain of Bacteriophage Terminases Belongs to the Resolvase/Integrase/Ribonuclease H Superfamily

Bacteriophage terminases are essential molecular motors involved in the encapsidation of viral DNA. They are hetero-multimers whose large subunit encodes both ATPase and endonuclease activities. Although the ATPase domain is well characterized from sequence and functional analysis, the C-terminal region remains poorly defined. We describe sequence-structure comparisons of the endonuclease region of various bacteriophages that revealed new sequence similarities shared by this region and the Holliday junction resolvase RuvC and to a lesser extent the HIV integrase and the ribonuclease H. Extensive sequence comparison and motif refinement led to a common signature of terminases and resolvases with three conserved acidic residues engaged in catalytic activity. Sequence analyses were validated by in vivo and in vitro functional assays showing that the nuclease activity of the endonuclease domain of bacteriophage T5 terminase was abolished by mutation of any of the three predicted catalytic aspartates. Overall, these data suggest that the endonuclease domains of terminases operate autonomously and that they adopt a fold similar to that of resolvases and share the same divalent cation-dependent enzymatic mechanism.

Identification of amino acids in HIV-1 and avian sarcoma virus integrase subsites required for specific recognition of the long terminal repeat Ends

A tetramer model for HIV-1 integrase (IN) with DNA representing 20 bp of the U3 and U5 long terminal repeats (LTR) termini was assembled using structural and biochemical data and molecular dynamics simulations. It predicted amino acid residues on the enzyme surface that can interact with the LTR termini. A separate structural alignment of HIV-1, simian sarcoma virus (SIV), and avian sarcoma virus (ASV) INs predicted which of these residues were unique. To determine whether these residues were responsible for specific recognition of the LTR termini, the amino acids from ASV IN were substituted into the structurally equivalent positions of HIV-1 IN, and the ability of the chimeras to 3 ' process U5 HIV-1 or ASV duplex oligos was determined. This analysis demonstrated that there are multiple amino acid contacts with the LTRs and that substitution of ASV IN amino acids at many of the analogous positions in HIV-1 IN conferred partial ability to cleave ASV substrates with a concomitant loss in the ability to cleave the homologous HIV-1 substrate. HIV-1 IN residues that changed specificity include Val(72), Ser(153), Lys(160)-Ile(161), Gly(163)-Val(165), and His(171)-Leu(172). Because a chimera that combines several of these substitutions showed a specificity of cleavage of the U5 ASV substrate closer to wild type ASV IN compared with chimeras with individual amino acid substitutions, it appears that the sum of the IN interactions with the LTRs determines the specificity. Finally, residues Ser(153) and Val(72) in HIV-1 IN are among those that change in enzymes that develop resistance to naphthyridine carboxamide- and diketo acid-related inhibitors in cells. Thus, amino acid residues involved in recognition of the LTRs are among these positions that change in development of drug resistance.

Dynamic Pharmacophore Model Optimization: Identification of Novel HIV-1 Integrase Inhibitors

We extended the previously described dynamic pharmacophore model studies of HIV-1 integrase (IN) by considering more key residues in the active site, including Mg2+. First, we applied a Monte Carlo sampling method to map the complementary features of the IN binding surface. Two types of dynamic pharmacophore models were generated. One considers Mg2+ as part of the IN and therefore as an excluded volume, and the other treats Mg2+ as a positively charged feature, representing a new type of pharmacophore model aimed to identify compounds potentially preventing Mg2+ binding. Second, we validated the models with 385 known active (IC50 < 20 microM) and 235 (IC50 > 100 microM) inactive IN inhibitors. Third, we used the derived models to screen our small molecule database. Twenty-two structurally novel compounds were tested in an in vitro assay specific for IN, and two of them showed IC50 < or = 10 microM for strand transfer reaction.

Diketo acid pharmacophore. 2. Discovery of structurally diverse inhibitors of HIV-1 integrase

Because of its unique role in the viral replication process, HIV-1 integrase (IN) is an important antiretroviral drug target. The beta-diketo acid class of IN inhibitors has played a major role in validating IN as a legitimate target for antiretroviral drug design. S-1360 (1) and L-870,810 (2) are examples of beta-diketo acid related compounds to enter clinical trials. With an aim to discover novel lead compounds with diverse structural scaffolds, we employed common feature pharmacophore models using four known beta-diketo acid analogues including S-1360 (J. Med. Chem. 2005, 1, 111-120). The best-ranked pharmacophore model (Hypo1) contained a hydrophobic (HYA), an H-bond acceptor (HBA), and two H-bond donor (HBD) features. A search of a 3D database containing approximately 150,000 small molecules using Hypo1 found 1700 compounds that satisfied all the features of the pharmacophore query. Of the 1700 compounds, 110 were selected for in vitro screening studies on the basis of their docking scores, predicted binding location inside the active site of IN, and their druglike properties. Forty-eight compounds inhibited IN catalytic activities with an IC50 value less than 100 microM. Twenty-seven structurally diverse inhibitors are reported here. Out of the 27 compounds, 13 compounds inhibited strand transfer activity of IN with an IC50 value less than 30 microM. These compounds are novel, druglike, and readily amenable for synthetic optimization.

HIV integrase inhibitors with nucleobase scaffolds: discovery of a highly potent anti-HIV agent

HIV integrase is essential for HIV replication. However, there are currently no integrase inhibitors in clinical use for AIDS. We have discovered a conceptually new beta-diketo acid that is a powerful inhibitor of both the 3'-processing and strand transfer steps of HIV-1 integrase. The in vitro anti-HIV data of this inhibitor were remarkable as exemplified by its highly potent antiviral therapeutic efficacy against HIV(TEKI) and HIV-1(NL4)(-)(3) replication in PBMC (TI >4,000 and >10,000, respectively).

Preferential inhibition of the magnesium-dependent strand transfer reaction of HIV-1 integrase by alpha-hydroxytropolones

Integration is a crucial step in the life cycle of human immunodeficiency virus type 1 (HIV-1); therefore, inhibitors of HIV-1 integrase are candidates for antiretroviral therapy. Two 7-hydroxytropolone derivatives (alpha-hydroxytropolones) were found to inhibit HIV-1 integrase. A structure-activity relationship investigation with several tropolone derivatives from The National Cancer Institute compound repository demonstrated that the 7-hydroxy group is essential for integrase inhibition. alpha-Hydroxytropolones preferentially inhibit strand transfer and are inhibitory both in the presence of magnesium or manganese. Lack of inhibition of disintegration in the presence of magnesium coupled with results from different cross-linking assays suggests alpha-hydroxytropolones as interfacial inhibitors. We propose that alpha-hydroxytropolones chelate the divalent metal (Mg2+ or Mn2+) in the enzyme active site. The most active compound against HIV-1 integrase in biochemical assays [2,4,6-cycloheptatrien-1-one, 2,7-dihydroxy-4-isopropyl (NSC 18806) IC50 = 4.8 +/- 2.5 microM] exhibits weak cytoprotective activity against HIV-1(IIIB) in a cell-based assay. alpha-Hydroxytropolones represent a new family of inhibitors for the development of novel drugs against HIV infection.

Active site binding modes of curcumin in HIV-1 protease and integrase

Structure models for the interaction of curcumin with HIV-1 integrase (IN) and protease (PR) were investigated using computational docking. Curcumin was found to bind preferentially in similar ways to the active sites of both IN and PR. For IN, the binding site is formed by residues Asp64, His67, Thr66, Glu92, Thr93, Asp116, Ser119, Asn120, and Lys159. Docked curcumin contacts the catalytic residues adjacent to Asp116 and Asp64, and near the divalent metal (Mg2+). In the PR docking, the curcumin structure fitted well to the active site, interacting with residues Asp25, Asp29, Asp30, Gly27', Asp29', and Asp30'. The results suggest that o-hydroxyl and/or keto-enol structures are important for both IN and PR inhibitory actions. The symmetrical structure of curcumin seems to play an important role for binding to the PR protein, whereas the keto-enol and only one side of the terminal o-hydroxyl showed tight binding to the IN active site.

Design and synthesis of specific inhibitors of the 3'-processing step of HIV-1 integrase

The novel dinucleotide 5'-phosphate, [(L,D)-pIsodApdC], discovered in our laboratory, is a strong inhibitor of HIV-1 integrase for both the 3'-processing and the strand transfer steps. The rationale used in this molecular design was that residues immediately upstream of the dinucleotide cleavage site in the 3'-processing step might provide critical recognition/binding sites on integrase. The rationale for the second type of inhibitors was based on the elimination products (linear and cyclic dinucleotides) of 3'-processing. However, while the linear dinucleotide 5'-phosphate (pdGpdT) was active, its cyclic counterpart was inactive against both wild-type and mutant HIV integrase.

Molecular dynamics studies of the full-length integrase-DNA complex

We have carried out a molecular dynamics (MD) simulation of full-length HIV-1 integrase (IN) dimer complexed with viral DNA with the aim of gaining information about the enzyme motion and investigating the movement of the catalytic flexible loop (residues 140-149) thought to be essential in the catalytic mechanism of IN. During the simulation, we observed quite a different behavior of this region in the presence or absence of the viral DNA. In particular, the MD results underline the crucial role of the residue Tyr143 in the mechanism of integration of viral DNA into the host chromosome. The present findings confirm the experimental data (e.g., site-directed mutagenesis experiments) showing that the loop is involved in the integration reactions and its mobility is correlated with the catalytic activity of HIV-1 integrase.

Experimental/Theoretical Electrostatic Properties of a Styrylquinoline-Type HIV-1 Integrase Inhibitor and Its Progenitors

We have established that polyhydroxylated styrylquinolines are potent inhibitors of HIV-1 integrase (IN). Among them, we have identified (E)-8-hydroxy-2-[2-(4,5-dihydroxy-3-methoxyphenyl)-ethenyl]-7-quinolinecarboxylic acid (1) as a promising lead. Previous molecular dynamics simulations and docking procedures have shown that the inhibitory activity involves one or two metal cations (Mg2+), which are present in the vicinity of the active center of the enzyme. However, such methods are generally based on a force-field approach and still remain not as reliable as ab initio calculations with extended basis sets on the whole system. To go further in this area, the aim of the present study was to evaluate the predictive ability of the electron density and electrostatic properties in the structure-activity relationships of this class of HIV-1 antiviral drugs. The electron properties of the two chemical progenitors of 1 were derived from both high-resolution X-ray diffraction experiments and ab initio calculations. The twinning phenomenon and solvent disorder were observed during the crystal structure determination of 1. Molecule 1 exhibits a planar s-trans conformation, and a zwitterionic form in the crystalline state is obtained. This geometry was used for ab initio calculations, which were performed to characterize the electronic properties of 1. The electron densities, electrostatic potentials, and atomic charges of 1 and its progenitors are here compared and analyzed. The experimental and theoretical deformation density bond peaks are very comparable for the two progenitors. However, the experimental electrostatic potential is strongly affected by the crystal field and cannot straightforwardly be used as a predictive index. The weak difference in the theoretical electron densities between 1 and its progenitors reveals that each component of 1 conserves its intrinsic properties, an assumption reinforced by a 13C NMR study. This is also shown through an excellent correlation of the atomic charges for the common fragments. The electrostatic potential minima in zwitterionic and nonzwitterionic forms of 1 are discussed in relation with the localization of possible metal chelation sites.

A three-dimensional model of the human immunodeficiency virus type 1 integration complex

While the general features of HIV-1 integrase function are understood, there is still uncertainty about the composition of the integration complex and how integrase interacts with viral and host DNA. We propose an improved model of the integration complex based on current experimental evidence including a comparison with the homologous Tn5 transposase containing bound DNA and an analysis of DNA binding sites using Goodford's GRID. Our model comprises a pair of integrase dimers, two strands of DNA to represent the viral DNA ends and a strand of bent DNA representing the host chromosome. In our model, the terminal four base pairs of each of the viral DNA strands interact with the integrase dimer providing the active site, while bases one turn away interact with a flexible loop (residues 186-194) on the second integrase dimer. We propose that residues E152, Q148 and K156 are involved in the specific recognition of the conserved CA dinucleotide and that the active site mobile loop (residues 140-149) stabilises the integration complex by acting as a barrier to separate the two viral DNA ends. In addition, the residues responsible for DNA binding in our model show a high level of amino acid conservation.

Target flexibility in molecular recognition

Induced-fit effects are well known in the binding of small molecules to proteins and other macromolecular targets. Among other targets, protein kinases are particularly flexible proteins, so that such effects should be considered in attempts at structure-based inhibitor design for kinase targets. This paper outlines some recent progress in methods for including target flexibility in computational studies of molecular recognition. A focus is the "relaxed complex method," in which ligands are docked to an ensemble of conformations of the target, and the best complexes are re-scored to provide predictions of optimal binding geometries. Early applications of this method have suggested a new approach to the development of inhibitors of HIV-1 Integrase.

Structural basis for the recognition between HIV-1 integrase and transcriptional coactivator p75

Integrase (IN) is an essential retroviral enzyme, and human transcriptional coactivator p75, which is also referred to as lens epithelium-derived growth factor (LEDGF), is the dominant cellular binding partner of HIV-1 IN. Here, we report the crystal structure of the dimeric catalytic core domain of HIV-1 IN complexed to the IN-binding domain of LEDGF. Previously identified LEDGF hotspot residues anchor the protein to both monomers at the IN dimer interface. The principal structural features of IN that are recognized by the host factor are the backbone conformation of residues 168-171 from one monomer and a hydrophobic patch that is primarily comprised of alpha-helices 1 and 3 of the second IN monomer. Inspection of diverse retroviral primary and secondary sequence elements helps to explain the apparent lentiviral tropism of the LEDGF-IN interaction. Because the lethal phenotypes of HIV-1 mutant viruses unable to interact with LEDGF indicate that IN function is highly sensitive to perturbations of the structure around the LEDGF-binding site, we propose that small molecule inhibitors of the protein-protein interaction might similarly disrupt HIV-1 replication.

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.

Integration requires a specific interaction of the donor DNA terminal 5'-cytosine with glutamine 148 of the HIV-1 integrase flexible loop

Integration is essential for retroviral replication and gene therapy using retroviral vectors. Human immunodeficiency virus, type 1 (HIV-1), integrase specifically recognizes the terminal sequences of each long terminal repeat (LTR) and cleaves the 3'-end terminal dinucleotide 5'-GT. The exposed 3'-hydroxyl is then positioned for nucleophilic attack and subsequent strand transfer into another DNA duplex (target or chromosomal DNA). We report that both the terminal cytosine at the protruding 5'-end of the long terminal repeats (5'-C) and the integrase residue Gln-148 are critical for strand transfer. Proximity of the 5'-C and Gln-148 was demonstrated by disulfide cross-linking. Cross-linking is inhibited by the inhibitor 5CITEP 1-(5-chloroindol-3-yl)-3-hydroxy-3-(2H-tetrazol-5-yl)-propenone. We propose that strand transfer requires a conformational change of the integrase-viral (donor) DNA complex with formation of an H-bond between the N-3 of the 5'-C and the amine group of Gln-148. These findings have implications for the molecular mechanisms coupling 3'-processing and strand transfer as well as for the molecular pharmacology of integrase inhibitors.

Lys-34, dispensable for integrase catalysis, is required for preintegration complex function and human immunodeficiency virus type 1 replication

Retroviral integrases (INs) function in the context of preintegration complexes (PICs). Two conserved Lys residues in the N-terminal domain of human immunodeficiency virus type 1 (HIV-1) IN were analyzed here for their roles in integration and virus replication. Whereas HIV-1(K46A) grew like the wild type, HIV-1(K34A) was dead. Yet recombinant IN(K34A) protein functioned in in vitro integration assays, and Vpr-IN(K34A) efficiently transcomplemented the infectivity defect of an IN active site mutant virus in cells. HIV-1(K34A) was therefore similar to a number of previously characterized mutant viruses that failed to replicate despite encoding catalytically competent IN. To directly analyze mutant PIC function, a sensitive PCR-based integration assay was developed. HIV-1(K34A) and related mutants failed to support detectable levels (<1% of wild type) of integration. We therefore concluded that mutations like K34A disrupted higher-order interactions important for PIC function/maturation compared to the innate catalytic activity of IN enzyme.

Contribution of the C-terminal tri-lysine regions of human immunodeficiency virus type 1 integrase for efficient reverse transcription and viral DNA nuclear import

Background

In addition to mediating the integration process, HIV-1 integrase (IN) has also been implicated in different steps during viral life cycle including reverse transcription and viral DNA nuclear import. Although the karyophilic property of HIV-1 IN has been well demonstrated using a variety of experimental approaches, the definition of domain(s) and/or motif(s) within the protein that mediate viral DNA nuclear import and its mechanism are still disputed and controversial. In this study, we performed mutagenic analyses to investigate the contribution of different regions in the C-terminal domain of HIV-1 IN to protein nuclear localization as well as their effects on virus infection.

Results

Our analysis showed that replacing lysine residues in two highly conserved tri-lysine regions, which are located within previously described Region C (²³⁵WKGPAKLLWKGEGAVV) and sequence Q (²¹¹KELQKQITK) in the C-terminal domain of HIV-1 IN, impaired protein nuclear accumulation, while mutations for RK_263,4 had no significant effect. Analysis of their effects on viral infection in a VSV-G pseudotyped RT/IN trans-complemented HIV-1 single cycle replication system revealed that all three C-terminal mutant viruses (KK215,9AA, KK240,4AE and RK263,4AA) exhibited more severe defect of induction of β-Gal positive cells and luciferase activity than an IN class 1 mutant D64E in HeLa-CD4-CCR5-β-Gal cells, and in dividing as well as non-dividing C8166 T cells, suggesting that some viral defects are occurring prior to viral integration. Furthermore, by analyzing viral DNA synthesis and the nucleus-associated viral DNA level, the results clearly showed that, although all three C-terminal mutants inhibited viral reverse transcription to different extents, the KK240,4AE mutant exhibited most profound effect on this step, whereas KK215,9AA significantly impaired viral DNA nuclear import. In addition, our analysis could not detect viral DNA integration in each C-terminal mutant infection, even though they displayed various low levels of nucleus-associated viral DNA, suggesting that these C-terminal mutants also impaired viral DNA integration ability.

Conclusion

All of these results indicate that, in addition to being involved in HIV-1 reverse transcription and integration, the C-terminal tri-lysine regions of IN also contribute to efficient viral DNA nuclear import during the early stage of HIV-1 replication.

Pharmacophore-Based Design of HIV-1 Integrase Strand-Transfer Inhibitors

Using a training set of diketo-like acid HIV-1 integrase (IN) strand-transfer inhibitors, a 3D pharmacophore model was derived having quantitative predictive ability in terms of activity. The best statistical hypothesis consisted of four features (one hydrophobic aromatic region, two hydrogen-bond acceptors, and one hydrogen-bond donor) with r of 0.96. The resulting pharmacophore model guided the rational design of benzylindoles as new potent IN inhibitors, whose microwave-assisted synthesis and biological evaluation are reported.

Synthesis and biological evaluation of geminal disulfones as HIV-1 integrase inhibitors

Integration of HIV-1 viral DNA into the host genome is carried out by HIV-integrase (IN) and is a critical step in viral replication. Although several classes of compounds have been reported to inhibit IN in enzymatic assays, inhibition is not always correlated with antiviral activity. Moreover, potent antiviral IN inhibitors such as the chicoric acids do not act upon the intended enzymatic target but behave as entry inhibitors instead. The charged nature of the chicoric acids contributes to poor cellular uptake, and these compounds are further plagued by rapid ester hydrolysis in vivo. To address these critical deficiencies, we designed neutral, nonhydrolyzable analogues of the chicoric acids. Herein, we report the synthesis, enzyme inhibition studies, and cellular antiviral data for a series of geminal disulfones. Of the 10 compounds evaluated, 8 showed moderate to high inhibition of IN in purified enzyme assays. The purified enzyme data correlated with antiviral assays for all but two compounds, suggesting alternative modes of inhibition. Time-of-addition studies were performed on these analogues, and the results indicate that they inhibit an early stage in the replication process, perhaps entry. In contrast, the most potent member of the correlative group shows behavior consistent with IN being the cellular target.

Development and application of a high-throughput screening assay for HIV-1 integrase enzyme activities

Integrase (IN) mediates the covalent insertion of the retroviral genome into its host chromosomal DNA. This enzymatic activity can be reconstituted in vitro with short DNA oligonucleotides, which mimic a single viral DNA end, and purified IN. Herein we report a highly efficient and sensitive high-throughput screen, HIV Integrase Target SRI Assay (HITS), for HIV-1 IN activity using 5' biotin-labeled DNA (5' BIO donor) and 3' digoxygenin-labeled DNA (3' DIG target). Following 3' processing of the 5' BIO donor, strand transfer proceeds with integration of the 5' BIO donor into the 3' DIG target. Products were captured on a streptavidin-coated microplate and the amount of DIG retained in the well was measured. The end point values, measured as absorbance, ranged from 0.9 to 1.5 for IN-mediated reactions as compared with background readings of 0.05 to 0.12. The Z factor for the assay ranged from 0.7 to 0.85. The assay was used to screen drugs in a high-throughput format, and furthermore, we adapted the assay to study mechanistic questions regarding the integration process. For example, using variations of the assay format, we showed high preference of E strand of the long terminal repeat (LTR) viral DNA as a target strand compared with its complementary A strand. The E strand is the strand processed by IN. Furthermore, we explored the reported inhibitory effect of reverse transcriptase on integration.