T-cell line for HIV drug screening using EGFP as a quantitative marker of HIV-1 replication

The rapid increase of viral strains that are resistant to the currently available antiretroviral drugs is a threat to the success of current human immunodeficiency virus type 1 (HIV-1) treatment and emphasizes the importance of developing novel anti-HIV-1 compounds. To improve the current abilities to screen for novel HIV-1 inhibitors, here we introduce a T-cell-based reporter cell line (JLTRG-RS) that expresses both HIV-1 coreceptors, CXCR4 and CCRS, and provides the convenience of using enhanced green fluorescent protein (EGFP) as a direct and quantitative marker. Unlike previous EGFP-based reporter cell lines, JLTRG-RS cells have an unusually high dynamic signal range, sufficient for plate reader detection using a 384-well format. In this format, JLTRG-R5 cell-based infectivity assays have a Z'-factor of 0.78, which defines the assay as extremely robust and clearly amenable to high-throughput screening. The functional similarity of the JLTRG-R5 cell line and peripheral blood mononuclear cells (PBMCs) was demonstrated through the identity of the inhibitory concentrations, 50% (IC50s) for four antiretroviral compounds or neutralizing antibodies. Because EGFP can be directly and continuously quantified in cell culture, the reporter cell line requires no manipulation during assay preparation or analysis. In addition, the EGFP marker allows for data acquisition at an optimal time point by prescreening selected positive control wells using fluorescent microscopy. These characteristics make the system extremely flexible, rapid, and inexpensive. Due to its intrinsic flexibility, the JLTRG-R5 cell-based reporter system provides a powerful tool to greatly facilitate future screening for HIV-1 inhibitors.     

Rapid Screening of HIV Reverse Transcriptase and Integrase Inhibitors

Although a number of anti HIV drugs have been approved, there are still problems with toxicity and drug resistance. This demonstrates a need to identify new compounds that can inhibit infection by the common drug resistant HIV-1 strains with minimal toxicity. Here we describe an efficient assay that can be used to rapidly determine the cellular cytotoxicity and efficacy of a compound against WT and mutant viral strains.The desired target cell line is seeded in a 96-well plate and, after a 24 hr incubation, serially dilutions of the compounds to be tested are added. No further manipulations are necessary for cellular cytotoxicity assays; for anti HIV assays a predetermined amount of either a WT or drug resistant HIV-1 vector that expresses luciferase is added to the cells. Cytotoxicity is measured by using an ATP dependent luminescence assay and the impact of the compounds on infectivity is measured by determining the amount of luciferase in the presence or the absence of the putative inhibitors.This screening assay takes 4 days to complete and multiple compounds can be screened in parallel. Compounds are screened in triplicate and the data are normalized to the infectivity/ATP levels in absence of target compounds. This technique provides a quick and accurate measurement of the efficacy and toxicity of potential anti HIV compounds.     

Homogeneous high-throughput screening assays for HIV-1 integrase 3beta-processing and strand transfer activities

HIV-1 integrase (HIV-IN) is a well-validated antiviral drug target catalyzing a multistep reaction to incorporate the HIV-1 provirus into the genome of the host cell. Small molecule inhibitors of HIV-1 integrase that specifically target the strand transfer step have demonstrated efficacy in the suppression of virus propagation. However, only few specific strand transfer inhibitors have been identified to date, and the need to screen for novel compound scaffolds persists. Here, the authors describe 2 homogeneous time-resolved fluorescent resonance energy transfer-based assays for the measurement of HIV-1 integrase 3'-processing and strand transfer activities. Both assays were optimized for high-throughput screening formats, and a diverse library containing more than 1 million compounds was screened in 1536-well plates for HIV-IN strand transfer inhibitors. As a result, compounds were found that selectively affect the enzymatic strand transfer reaction over 3beta processing. Moreover, several bioactive molecules were identified that inhibited HIV-1 reporter virus infection in cellular model systems. In conclusion, the assays presented herein have proven their utility for the identification of mechanistically interesting and biologically active inhibitors of HIV-1 integrase that hold potential for further development into potent antiviral drugs.     

An improved beta-lactamase reporter assay: multiplexing with a cytotoxicity readout for enhanced accuracy of hit identification

A problem inherent to the use of cellular assays for drug discovery is their sensitivity to cytotoxic compounds, which can result in false hits from certain compound screens. To alleviate the need to follow-up hits from a reporter assay with a separate cytotoxicity assay, the authors have developed a multiplexed assay that combines the readout of a beta-lactamase reporter with that of a homogeneous cytotoxicity indicator. Important aspects to the development of the multiplexed format are addressed, including results that demonstrate that the IC(50) values of 40 select compounds in a beta-lactamase reporter assay for nuclear factor kappa B and SIE pathway antagonists are not affected by the addition of the cytotoxicity indicator. To demonstrate the improvement in hit confirmation, the multiplexed assay was used to perform a small-library screen (7728 compounds) for serotonin 5HT1A receptor antagonists. Hits identified from analysis of the beta-lactamase reporter data alone were compared to those hits determined when the reporter and cytotoxicity data generated from the multiplexed assay were combined. Confirmation rates were determined from compound follow-up using dose-response analysis of the potential antagonist hits identified by the initial screen. In this representative screen, the multiplexed assay approach yielded a 19% reduction in the number of compounds flagged for follow-up, with a 37% decrease in the number of false hits, demonstrating that multiplexing a beta-lactamase reporter assay with a cytotoxicity readout is a highly effective strategy for reducing false hit rates in cell-based compound screening assays.     

Assay concordance between SPA and TR-FRET in high-throughput screening

High-throughput screening (HTS) of large chemical libraries has become the main source of new lead compounds for drug development. Several specialized detection technologies have been developed to facilitate the cost- and time-efficient screening of millions of compounds. However, concerns have been raised, claiming that different HTS technologies may produce different hits, thus limiting trust in the reliability of HTS data. This study was aimed to investigate the reliability of the authors most frequently used assay techniques: scintillation proximity assay (SPA) and homogeneous time-resolved fluorescence resonance energy transfer (TR-FRET). To investigate the data concordance between these 2 detection technologies, the authors screened a large subset of the Schering compound library consisting of 300,000 compounds for inhibitors of a nonreceptor tyrosine kinase. They chose to set up this study in realistic HTS scale to ensure statistical significance of the results. The findings clearly demonstrate that the choice of detection technology has no significant impact on hit finding, provided that assays are biochemically equivalent. Data concordance is up to 90%. The little differences in hit findings are caused by threshold setting but not by systematic differences between the technologies. The most significant difference between the compared techniques is that in the SPA format, more false-positive primary hits were obtained.     

Expression of the human immunodeficiency virus type 1 (HIV-1) nef gene during HIV-1 production increases progeny particle infectivity independently of gp160 or viral entry.

The nef gene product of human immunodeficiency virus type 1 (HIV-1) promotes more-rapid kinetics of viral replication in primary peripheral blood mononuclear cells. We have previously shown that these enhancing effects of Nef on HIV-1 replication reflect an increase in viral infectivity detectable both in limiting dilution assays and through a single-cycle infection of the HeLa-CD4-long terminal repeat-beta-galactosidase indicator cell line. We now demonstrate that nef-defective HIV-1 can be rescued to near wild-type levels of infectivity by coexpressing Nef in trans in the cell line producing the virus. This observation indicates that HIV-1 virions produced in the presence of Nef are intrinsically different. However, we show that the major viral structural proteins are quantitatively similar in purified viral preparations. We also demonstrate the functional equivalence of the gp120-gp41 envelope glycoprotein complexes of Nef+ and Nef- HIV-1 through an assay for viral entry. Finally, we show that env-defective Nef+ HIV-1 pseudotyped with an amphotropic envelope is also more infectious than similarly pseudotyped Nef- HIV-1. Thus, the production of HIV-1 in the presence of Nef results in viral particles that are more infectious, and this increased infectivity is manifested at a stage after viral entry but prior to or coincident with HIV-1 gene expression.     

Establishment of a new cell line inducibly expressing HIV-1 protease for performing safe and highly sensitive screening of HIV protease inhibitors

The human immunodeficiency virus type 1 (HIV-1) protease (PR) plays an essential role in processing viral polyproteins into mature proteins. As a result, it is a major target for the development of drugs against AIDS. However, due to the rapid emergence of drug-resistant HIV, the development of novel HIV PR inhibitors is urgently needed. We recently established a new cell line E-PR293 which can be used as a safe, convenient and highly efficient assay system to screen HIV-1 PR inhibitors. In the cells, the HIV-1 PR is expressed in a chimeric protein with the green fluorescence protein (GFP). This assay measures the PR activity as a function of either the fluorescence of GFP or the cytotoxic activity of HIV-1 PR which is expressed in the cell. E-PR293 cells were maintained in the presence of doxycycline, which suppresses the expression of HIV-1 PR. The removal of doxycycline induces the expression of HIV-1 PR, which is used to screen HIV-1 PR inhibitors. In E-PR293 cells, the 50% inhibitory concentration of the cytotoxic effects by nelfinavir and saquinavir were as low as nanomolar levels, almost equal to those found in the HIV-infection assay.     

Enhanced infectivity of HIV-1 by X4 HIV-1 coinfection

Two strains of human immunodeficiency virus type 1 (HIV-1) expressing different reporters, human placental alkaline phosphatase (PLAP) and murine heat stable antigen (HSA, CD24), were used for dual infection. Flow cytometric analysis enabled us to distinguish cells not only infected with individual reporter virus but also superinfected with both reporter viruses. When the CD4 positive T cell line, PM1, was dually infected by both reporter viruses with different coreceptor utilization, coinfection with CXCR4-tropic HIV-1 (X4 HIV-1) expressing one reporter increased the rate of cells infected with HIV-1 expressing another reporter. This enhancement was accompanied by an increased level of p24 antigen Gag in culture supernatant, indicating that infectivity of HIV-1 was augmented by X4 HIV-1 coinfection. The CXCR4 antagonist, T140 eliminated this enhancement, suggesting the role of X4 envelope via CXCR4. These results imply the role of X4 HIV-1 at the late stage of infection.     

Identifying nonselective hits from a homogeneous calcium assay screen

The authors used a homogeneous calcium dye kit with a cell line transfected using a recombinant protein construct to screen a 50,000 compound library for G-protein coupled receptor (GPCR) agonists. Only 1 of the 365 primary hits activated Gq-coupled GPCRs, as shown using IP-ONE HTRF. Furthermore, an agonist screen against the entire compound library and same heterologous cell line using AequoScreen technology generated no false positives and identified the same positive hit. Next, a multiplex assay composed of both Fluo-3 and Fura-2-loaded cells identified 1 false positive and the same true-positive hit out of the 365 primary hits. Finally, rescreening the 365 primary hits against the parental cell line loaded using the homogeneous calcium dye kit confirmed the specificity of the same true-positive hit only. In summary, the results suggest that AequoScreen technology, IP-ONE HTRF, and multiplex assays are unique, orthogonal technologies to identify nonspecific hits.     

Potential high-throughput assay for screening inhibitors of West Nile virus replication

Prevention and treatment of infection by West Nile virus (WNV) and other flaviviruses are public health priorities. We describe a reporting cell line that can be used for high-throughput screening of inhibitors against all targets involved in WNV replication. Dual reporter genes, encoding Renilla luciferase (Rluc) and neomycin phosphotransferase (Neo), were engineered into a WNV subgenomic replicon, resulting in Rluc/NeoRep. Geneticin selection of BHK-21 cells transfected with Rluc/NeoRep yielded a stable cell line that contains persistently replicating replicons. Incubation of the reporting cells with known WNV inhibitors decreased Rluc activity, as well as the replicon RNA level. The efficacies of the inhibitors, as measured by the depression of Rluc activity in the reporting cells, are comparable to those derived from authentic viral infection assays. Therefore, the WNV reporting cell line can be used as a high-throughput assay for anti-WNV drug discovery. A similar approach should be applicable to development of genetics-based antiviral assays for other flaviviruses.     

Evaluation of a high-throughput fluorescence assay method for HERG potassium channel inhibition

The number of projects in drug development that fail in late phases because of cardiac side effects such as QT prolongation can impede drug discovery and development of projects. The molecular target responsible for QT prolongation by a wide range of pharmaceutical agents is the myocardial hERG potassium channel. It is therefore desirable to screen for compound interactions with the hERG channel at an early stage of drug development. Here, the authors report a cell-based fluorescence assay using membrane potential-sensitive fluorescent dyes and stably transfected hERG channels from CHO cells. The assay allows semiautomated screening of compounds for hERG activity on 384-well plates and is sufficiently rapid for testing a large number of compounds. The assay is robust as indicated by a Z' factor larger than 0.6. The throughput is in the range of 10,000 data points per day, which is significantly higher than any other method presently available for hERG. The data obtained with the fluorescence assay were in qualitative agreement with those from patch-clamp electrophysiological analysis. There were no false-positive hits, and the rate of false-negative compounds is currently 12% but might be further reduced by testing compounds at higher concentration. Quantitative differences between fluorescence and electrophysiological methods may be due to the use- or voltage-dependent activity of the antagonists.     

Arsenic counteracts human immunodeficiency virus type 1 restriction by various TRIM5 orthologues in a cell type-dependent manner

Arsenic trioxide (As(2)O(3)) increased human immunodeficiency virus type 1 (HIV-1) infectivity when particular Homo sapiens and Cercopithecus aethiops cell lines were used as targets. Knockdown of human TRIM5alpha by RNA interference eliminated the As(2)O(3) effect, demonstrating that the drug acts by modulating the activity of this retroviral restriction factor. In contrast, HIV-1 infectivity in target cell lines from other primate species (Cercopithecus tantalus, Macaca mulatta, and Aotus trivirgatus) was not increased by As(2)O(3), despite the potent TRIM5-dependent HIV-1 restriction activity that these cells exhibit. To determine if As(2)O(3) responsiveness is characteristic of particular TRIM5 orthologues and not others, TRIM5 cDNAs from these five primate species were transduced into cat fibroblasts, which lack endogenous HIV-1 restriction activity and, therefore, responsiveness to As(2)O(3). In this context, the HIV-1 restriction activity conferred by all TRIM5 orthologues was largely eliminated by As(2)O(3). The effect of As(2)O(3) on HIV-1 restriction is thus shared by different TRIM5 orthologues but dependent on factors specific to the cell line in which TRIM5 is expressed.     

High-throughput identification of inhibitors of human mitochondrial peptide deformylase

The human mitochondrial peptide deformylase (HsPDF) provides a potential new target for broadly acting antiproliferative agents. To identify novel nonpeptidomimetic and nonhydroxamic acid-based inhibitors of HsPDF, the authors have developed a high-throughput screening (HTS) strategy using a fluorescence polarization (FP)-based binding assay as the primary assay for screening chemical libraries, followed by an enzymatic-based assay to confirm hits, prior to characterization of their antiproliferative activity against established tumor cell lines. The authors present the results and performance of the established strategy tested in a pilot screen of 2880 compounds and the identification of the 1st inhibitors. Two common scaffolds were identified within the hits. Furthermore, cytotoxicity studies revealed that most of the confirmed hits have antiproliferative activity. These findings demonstrate that the designed strategy can identify novel functional inhibitors and provide a powerful alternative to the use of functional assays in HTS and support the hypothesis that HsPDF inhibitors may constitute a new class of antiproliferative agent.