A dual-readout F2 assay that combines fluorescence resonance energy transfer and fluorescence polarization for monitoring bimolecular interactions

F?rster (fluorescence) resonance energy transfer (FRET) and fluorescence polarization (FP) are widely used technologies for monitoring bimolecular interactions and have been extensively used in high-throughput screening (HTS) for probe and drug discovery. Despite their popularity in HTS, it has been recognized that different assay technologies may generate different hit lists for the same biochemical interaction. Due to the high cost of large-scale HTS campaigns, one has to make a critical choice to employee one assay platform for a particular HTS. Here we report the design and development of a dual-readout HTS assay that combines two assay technologies into one system using the Mcl-1 and Noxa BH3 peptide interaction as a model system. In this system, both FP and FRET signals were simultaneously monitored from one reaction, which is termed "Dual-Readout F(2) assay" with F(2) for FP and FRET. This dual-readout technology has been optimized in a 1,536-well ultra-HTS format for the discovery of Mcl-1 protein inhibitors and achieved a robust performance. This F(2) assay was further validated by screening a library of 102,255 compounds. As two assay platforms are utilized for the same target simultaneously, hit information is enriched without increasing the screening cost. This strategy can be generally extended to other FP-based assays and is expected to enrich primary HTS information and enhance the hit quality of HTS campaigns.     

High capacity homogeneous non-radioactive cortisol detection assays for human 11beta-hydroxysteroid dehydrogenase type 1

11beta-Hydroxysteroid dehydrogenase type 1 (11beta-HSD1) catalyzes the interconversion of inert glucocorticoid (cortisone) to the active glucocorticoid (cortisol) and is enriched in liver and fat tissues. Increasing evidence suggests that selective inhibition of 11beta-HSD1 may reduce the excess glucocorticoid levels that underlie the etiology of many common disorders that constitute the metabolic syndrome. Measurement of 11beta-HSD1 activity has historically involved the detection of cortisol by methods unfavorable for large-scale screening, such as high performance liquid chromatography or thin layer chromatography. Here we describe the development and validation of novel homogeneous time-resolved fluorescence resonance energy transfer (TR-FRET) and electrochemiluminescence assays for the measurement of cortisol. These non-radioactive assays were easy to perform and produced robust results with reference compound values comparable to those obtained by conventional methods. The TR-FRET assay was easily automated and was successfully employed for the high-throughput screening of a large compound library for inhibitors of purified human recombinant 11beta-HSD1.     

New fluorescence techniques for high-throughput drug discovery

The rapid increase of compound libraries as well as new targets emerging from the Human Genome Project require constant progress in pharmaceutical research. An important tool is High-Throughput Screening (HTS), which has evolved as an indispensable instrument in the pre-clinical target-to-IND (Investigational New Drug) discovery process. HTS requires machinery, which is able to test more than 100,000 potential drug candidates per day with respect to a specific biological activity. This calls for certain experimental demands especially with respect to sensitivity, speed, and statistical accuracy, which are fulfilled by using fluorescence technology instrumentation. In particular the recently developed family of fluorescence techniques, FIDA (Fluorescence Intensity Distribution Analysis), which is based on confocal single-molecule detection, has opened up a new field of HTS applications. This report describes the application of these new techniques as well as of common fluorescence techniques--such as confocal fluorescence lifetime and anisotropy--to HTS. It gives experimental examples and presents advantages and disadvantages of each method. In addition the most common artifacts (auto-fluorescence or quenching by the drug candidates) emerging from the fluorescence detection techniques are highlighted and correction methods for confocal fluorescence read-outs are presented, which are able to circumvent this deficiency.     

Demonstration of LanthaScreen™ TR-FRET-based nuclear receptor coactivator recruitment assay using PHERAstar, a multi-detection HTS microplate reader

An attempt was made to demonstrate the possibility of performing LanthaScreen™ TR-FRET based nuclear receptor coactivator recruitment assay using PHERAstar, a multi-detection HTS microplate reader. LanthaScreen™ nuclear receptor coactivator recruitment assay (M/s Invitrogen corporation, USA) was performed using PPAR-gamma receptor preparation in the agonist mode. TR-FRET measurements were done on PHERAstar, a multimode microplate reader (BMG LABTECH, Germany). The Lanthascreen PPAR gamma coactivator recruitment assay was successfully performed in the PHERAstar, multimode microplate reader. This was evidenced by an assay robustness score (Z'') of 0.71. The current work demonstrates the suitability of using PHERAstar, a multi-detection HTS microplate reader.for performing LanthaScreen™ TR-FRET based nuclear receptor coactivator recruitment assays.     

Fluorescence spectroscopic profiling of compound libraries

Chromo/fluorophoric properties often accompany the heterocyclic scaffolds and impurities that comprise libraries used for high-throughput screening (HTS). These properties affect assay outputs obtained with optical detection, thus complicating analysis and leading to false positives and negatives. Here, we report the fluorescence profile of more than 70,000 samples across spectral regions commonly utilized in HTS. The quantitative HTS paradigm was utilized to test each sample at seven or more concentrations over a 4-log range in 1,536-well format. Raw fluorescence was compared with fluorophore standards to compute a normalized response as a function of concentration and spectral region. More than 5% of library members were brighter than the equivalent of 10 nM 4-methyl umbelliferone, a common UV-active probe. Red-shifting the spectral window by as little as 100 nm was accompanied by a dramatic decrease in autofluorescence. Native compound fluorescence, fluorescent impurities, novel fluorescent compounds, and the utilization of fluorescence profiling data are discussed.     

An in vitro Förster resonance energy transfer-based high-throughput screening assay for inhibitors of protein-protein interactions in SUMOylation pathway

F?rster resonance energy transfer (FRET) is a powerful tool in biological research and has been widely used in the study of biomolecular interactions. SUMOylation is an important post-translational modification that is involved in many key biological processes. As a multi-step cascade reaction, SUMOylation involves multiple enzymes and protein-protein interactions. Here, we report the development of an in vitro FRET-based high-throughput screening (HTS) assay in SUMOylation. This assay is based on steady state and high efficiency of the fluorescent energy transfer between CyPet and YPet fused to SUMO1 and Ubc9, respectively. We optimized the assay and performed a small-scale pilot study to validate the screening platform. Carried out in 384-well plate format, our FRET-based HTS provides a powerful tool for large-scale and high-throughput applications.     

Cellular HTS assays for pharmacological characterization of Na(V)1.7 modulators

Ion channels are challenging targets in the early phases of the drug discovery process, especially because of the lack of technologies available to screen large numbers of compounds in functionally relevant assays. The electrophysiological patch-clamp technique, which is the gold standard for studying ion channels, has low throughput and is not amenable to screening large numbers of compounds. However, for random high-throughput screening (HTS) of compounds against ion channel targets, a number of functional cellular assays have become available during the last few years. Here we use the sodium channel NaV1.7 stably expressed in human embryonic kidney 293 cells and compare three HTS assays-a Li flux atomic absorption spectroscopy (AAS) assay, a fluorescent imaging plate reader (FLIP, Molecular Devices, Sunnyvale, CA) membrane potential assay, and a fluorescence resonance energy transfer (FRET)-based membrane potential assay-to an automated electrophysiological assay (the Ionworks HT [Molecular Devices] platform) and characterize 11 known NaV inhibitors. Our results show that all three HTS assays are suitable for identification of NaV1.7 inhibitors, but as an HTS assay the Li-AAS assay is more robust with higher Z' values than the FLIPR and FRET-based membrane potential assays. Furthermore, there was a better correlation between the Ionworks assay and the Li-AAS assay regarding the potency of the NaV inhibitors investigated. This paper describes the first comparison between all the HTS assays available today to study voltage-gated NaVs, and the results suggest that the Li-AAS assay is more suited as a first HTS assay when starting an NaV drug discovery campaign.     

High throughput drug screening for human immunodeficiency virus type 1 reactivating compounds

The ability of human immunodeficiency virus type 1 (HIV-1) to persist in a latent stage in memory T cells in the presence of antiretroviral therapy poses a major obstacle to the development of an HIV-1 therapy with curative intent. As latently infected cells are phenotypically not distinguishable from uninfected cells, therapeutic reactivation of the latent infection, followed by the death of the host cell induced by viral cytopathicity, is considered the only means to eliminate this viral reservoir. To identify compounds with the potential to reactivate latent HIV-1, we have developed a series of latently HIV-1-infected reporter cell lines that allow for high throughput drug screening (HTS) in a 384-well plate-based format. The latent reporter cell lines use enhanced green fluorescence protein (eGFP) as a direct and quantitative marker of HIV-1 expression. To aid identification of specific compounds, the cells are engineered to constitutively express a second, red fluorescent protein that has no spectral overlap with eGFP, which allows for the simultaneous quantification of cell viability (inversely correlated to compound toxicity). Thus, these reporters enable prioritization of compounds most likely to have a favorable therapeutic window. The high dynamic signal range and the excellent reproducibility of the primary screening assay result in a Z' -factor of 0.89, which characterizes the HTS system as very robust. The assay has been implemented for automated drug screening, and we here discuss the advantages and limitations of the HTS system based on the data obtained for 1,600 compounds during a limited proof-of-concept drug screen.     

荧光检测技术在蛋白酪氨酸激酶抑制剂高通量筛选中的应用

介绍荧光共振能量转移技术、荧光偏振免疫分析技术、荧光素酶-激酶检测技术和毛细管电泳-激光诱导荧光技术在酪氨酸激酶抑制剂高通量筛选模型中的应用情况。蛋白酪氨酸激酶与多种疾病的发生和发展密切相关,通过高通量筛选寻找其抑制剂已成为新药研发的热点之一。荧光检测技术因具有灵敏、易于检测、适于微量化和安全性高等优势,在药物的高通量筛选中被广泛使用。     

Assay in high throughput screening

HTS (High Throughput Screening) has been put into practice in recent years. HTS is aiming to discover lead compounds for medicinal drugs. High efficiency must be achieved in all the processes including sample preparation, assay procedure, automation and data management. This review will focus on the aspects concerned with the assay technology and the efficiency in HTS. One of the major trends in HTS is assay miniaturization using high-density microplates with 384 and 1536 wells. This allows us to increase the throughput and to decrease the cost. The so-called "mix and measure" or "homogeneous" assay system, which has no separation steps such as washing or filtration, is effective for this purpose. The homogeneous assays, such as scintillation proximity assay (SPA), fluorescence energy transfer (HTRF, LANCE) and fluorescence polarization (FP), are frequently used. The reporter gene assay or the cell proliferation assay can be adapted for the homogeneous assay using high-density plates. In addition, HTS measuring the intracellular Ca2+ influx is also possible using a CCD Imager. The assay quality as well as the efficiency is also important especially in HTS. The Z'-factor provides a good tool for evaluating the quality of assays.     

High-throughput screening for reactive oxygen species scavengers targeting mitochondria

A high-throughput screening (HTS) method for reactive oxygen species (ROS) scavengers was established to explore compounds protecting mitochondria. Freshly prepared rat liver mitochondria and the ROS fluorescent probe, 2',7'-dichlorofluorescin diacetate (DCFH-DA), were coincubated for 90 min to establish the assay in 384-well plates. The fluorescence of DCF values was monitored with a microplate reader. The Z' factor value for HTS was 0.81. A sample library containing 75,230 compounds was screened, and 10 compounds with high ROS scavenging activity were identified, among which the compound, 5061, with the strongest ROS scavenging activity was reevaluated. 5061 showed potent free radical scavenging activity both in cell-free models and cell models, which were in good accordance with the HTS assay. The established fluorescent HTS assay was simple, sensitive, stable, highly reproducible and robust and suitable for the HTS assay for ROS scavengers targeting mitochondria.     

基于极化荧光方法的人LOX-1配体高通量筛选

目的建立以极化荧光为检测方法的高通量筛选技术，通过大规模筛选发现氧化型低密度脂蛋白受体-1(LOX-1)的天然配体。方法密度梯度超速离心获得正常人血中低密度脂蛋白(LDL)，然后用CuSO₄(5 μmol·L^-1)修饰为氧化型低密度脂蛋白(oxLDL)。FITC标记hLOX-1，以受体(LOX-1)和配体(oxLDL)的相互作用为基础建立筛选模型，用极化荧光检测方法，在激发光485 nm、发射光525 nm,对3 200个样品进行高通量筛选，并用Z′因子值评价实验。结果Z′因子值为0.75，根据建立的基于极化荧光的高通量筛选实验方法，发现3个化合物与hLOX-1有较高的结合活性，IC₅₀值小于31.6 μmol·L^-1。结论极化荧光检测方法适合于高通量筛选技术，具有较高的稳定性、灵敏性和可重复性。     

Large-scale SNP scoring from unamplified genomic DNA

Discoveries from the Human Genome Project (HGP) continue to spur changes in medical technology that will lead to new diagnostic procedures in the clinical lab. As more single nucleotide polymorphisms (SNPs) are discovered and correlated to human diseases, demands for genetic tests will increase. The enormity of the number of SNPs makes developing inexpensive and reliable high-throughput methods for SNP scoring imperative. High-throughput screening (HTS) means, at a minimum, a production rate of thousands of assays per day. Ideally, the technology will be easy, inexpensive and amenable to automation. The Invader assay offers a simple diagnostic platform to detect single nucleotide changes with high specificity and sensitivity from unamplified, genomic DNA. The Invader assay uses a structure-specific 5' nuclease (or flap endonuclease) to cleave sequence-specific structures in each of two cascading reactions. The cleavage structure forms when two synthetic oligonucleotide probes hybridise in tandem to a target. One of the probes cycles on and off the target and is cut by the nuclease only when the appropriate structure forms. These cleaved probes then participate in a second Invader reaction involving a dye-labelled fluorescence resonance energy transfer (FRET) probe. Cleavage of this FRET probe generates a signal, which can be readily analysed by fluorescence microtitre plate readers. The two cascading reactions amplify the signal significantly; each original target molecule can lead to more than 10(6) cleaved signal probes in one hour. This signal amplification permits identification of single base changes directly from genomic DNA without prior target amplification. The sequences of the oligonucleotide components of the secondary reaction are independent of the target of interest and permit the development of universal secondary reaction components useful to identify any target.     

High-throughput screening with immobilized metal ion affinity-based fluorescence polarization detection, a homogeneous assay for protein kinases

Protein kinases are one of the most important target classes in high-throughput screening today. The use of generic assay technologies facilitates assay development for new targets and decreases the time needed for implementation of assays in robotic screening. For tyrosine kinases, several generic assay technology platforms are available. These technologies make use of high-affinity antibodies that discriminate between phosphorylated tyrosines and non-phosphorylated tyrosines. Similar generic antibodies specific for phosphoserine or phosphothreonine are lacking. Recently, a non-antibody-based fluorescence polarization assay for protein kinases has become available, called IMAP (Molecular Devices, Sunnyvale, CA). In this assay, a fluorescently labeled peptide substrate that is phosphorylated by kinase is captured on metal-derivatized nanoparticles. We have evaluated IMAP in high-throughput screening, and compared this technology with a competition fluorescence polarization immunoassay based on an antibody specific for a phosphorylated peptide substrate. A random collection of >250000 compounds was screened with the two assays. Fluorescent library compounds were identified by calculation of fluorescence intensity values from the screening data, and by assaying in the absence of fluorescent reagents. Fluorescence polarization artifacts were filtered out further by testing in an ELISA-based kinase assay. Our data show that IMAP is a robust technology for high-throughput screening of kinase targets, and suggest that it is less susceptible to fluorescence polarization artifacts than the competition fluorescence polarization immunoassay.     

Application of Extrinsic Fluorescence Spectroscopy for the High Throughput Formulation Screening of Aluminum-Adjuvanted Vaccines

High throughput screening (HTS) of excipients for proteins in solution can be achieved by several analytical techniques. The screening of stabilizers for proteins adsorbed onto adjuvants, however, may be difficult due to the limited amount of techniques that can measure stability of adsorbed protein in high throughput mode. Here, we demonstrate that extrinsic fluorescence spectroscopy can be successfully applied to study the physical stability of adsorbed antigens at low concentrations in 96-well plates, using a real-time polymerase chain reaction (RT-PCR) instrument. HTS was performed on three adjuvanted pneumococcal proteins as model antigens in the presence of a standard library of stabilizers. Aluminum hydroxide appeared to decrease the stability of all three proteins at relatively high and low pH values, showing a bell-shaped curve as the pH was increased from 5 to 9 with a maximum stability at near neutral pH. Nonspecific stabilizers such as mono- and disaccharides could increase the conformational stability of the antigens. In addition, those excipients that increased the melting temperature of adsorbed antigens could improve antigenicity and chemical stability. To the best of our knowledge, this is the first report describing an HTS technology amenable for low concentration of antigens adsorbed onto aluminum-containing adjuvants.     

Development of a 384-well colorimetric assay to quantify hydrogen peroxide generated by the redox cycling of compounds in the presence of reducing agents

We report here the development and optimization of a simple 384-well colorimetric assay to measure H(2)O(2) generated by the redox cycling of compounds incubated with reducing agents in high-throughput screening (HTS) assay buffers. The phenol red-horseradish peroxidase (HRP) assay readily detected H(2)O(2) either added exogenously or generated by the redox cycling of compounds in dithiothreitol (DTT). The generation of H(2)O(2) was dependent on the concentration of both the compound and DTT and was abolished by catalase. Although both DTT and tris(2-carboxyethyl) phosphine sustain the redox cycling generation of H(2)O(2) by a model quinolinedione, 6-chloro-7-(2-morpholin-4-yl-ethylamino)-quinoline-5,8-dione (NSC 663284; DA3003-1), other reducing agents such as beta-mercaptoethanol, glutathione, and cysteine do not. The assay is compatible with HTS. Once terminated, the assay signal was stable for at least 5 h, allowing for a reasonable throughput. The assay tolerated up to 20% dimethyl sulfoxide, allowing a wide range of compound concentrations to be tested. The assay signal window was robust and reproducible with average Z-factors of > or =0.8, and the redox cycling generation of H(2)O(2) by DA3003-1 in DTT exhibited an average 50% effective concentration of 0.830 +/- 0.068 microM. Five of the mitogen-activated protein kinase phosphatase (MKP) 1 inhibitors identified in an HTS were shown to generate H(2)O(2) in the presence of DTT, and their inhibition of MKP-1 activity was shown to be time dependent and was abolished or significantly reduced by either 100 U of catalase or by higher DTT levels. A cross-target query of the PubChem database with three structurally related pyrimidotriazinediones revealed active flags in 36-39% of the primary screening assays. Activity was confirmed against a number of targets containing active site cysteines, including protein tyrosine phosphatases, cathepsins, and caspases, as well as a number of cellular cytotoxicity assays. Rather than utilize resources to conduct a hit characterization effort involving several secondary assays, the phenol red-HRP assay provides a simple, rapid, sensitive, and inexpensive method to identify compounds that redox cycle in DTT or tris(2-carboxyethyl)phosphine to produce H(2)O(2) that may indirectly modulate target activity and represent promiscuous false-positives from a primary screen.     

A homogeneous G protein-coupled receptor ligand binding assay based on time-resolved fluorescence resonance energy transfer

Abstract: Fluorescence resonance energy transfer (FRET) has emerged as a powerful tool to the study of protein-protein interactions, such as receptor-ligand binding. However, the application of FRET to the study of G protein-coupled receptors (GPCRs) has been limited by the method of labeling receptor with fluorescence probes. Here we described a novel time-resolved (TR)-FRET method to study GPCR-ligand binding by using human complement 5a (C5a) receptor (C5aR) as a model system. Human C5aR was expressed in human embryonic kidney 293 cells with a hemagglutinin (HA) epitope at the N-terminus. Purified human C5a was labeled with terbium chelate and used as the fluorescence donor. Monoclonal anti-HA antibody conjugated with Alexa Fluor 488 was used as the fluorescence acceptor. Robust FRET signal was observed when the labeled ligand and C5aR membrane were mixed in the presence of the conjugated anti-HA antibody. This FRET signal was specific and saturable. C5a binding affinity to C5aR measured by the FRET assay was consistent with the data as determined by competition binding analysis using radiolabeled C5a. The FRET assay was also used to determine affinity of C5aR antagonists by competition binding analysis, and the data are similar to those from radioligand binding studies. Compared to the commonly used radioligand binding assay, this TR-FRET-based assay provides a nonradioactive, faster, and sensitive homogeneous assay format that could be easily adapted to high-throughput screening. The principle of this assay should also be applicable to other GPCRs, especially to those receptors with peptide or protein ligands.     

Evaluation of micro-parallel liquid chromatography as a method for HTS-coupled actives verification

The identification of biologically active compounds from high-throughput screening (HTS) can involve considerable postscreening analysis to verify the nature of the sample activity. In this study we evaluated the performance of micro-parallel liquid chromatography (microPLC) as a separation-based enzyme assay platform for follow-up of compound activities found in quantitative HTS of two different targets, a hydrolase and an oxidoreductase. In an effort to couple secondary analysis to primary screening we explored the application of microPLC immediately after a primary screen. In microPLC, up to 24 samples can be loaded and analyzed simultaneously via high-performance liquid chromatography within a specially designed cartridge. In a proof-of-concept experiment for screen-coupled actives verification, we identified, selected, and consolidated the contents of "active" wells from a 1,536-well format HTS experiment into a 384-well plate and subsequently analyzed these samples by a 24-channel microPLC system. The method utilized 0.6% of the original 6-microl 1,536-well assay for the analysis. The analysis revealed several non-biological-based "positive" samples. The main examples included "false" enzyme activators resulting from an increase in well fluorescence due to fluorescent compound or impurity. The microPLC analysis also provided a verification of the activity of two activators of glucocerebrosidase. We discuss the benefits of microPLC and its limitations from the standpoint of ease of use and integration into a seamless postscreen workflow.     

Development of a high throughput equilibrium dialysis method

The identification of large numbers of biologically active chemical entities during high throughput screening (HTS) necessitates the incorporation of new strategies to identify compounds with drug-like properties early during the lead prioritization and development processes. One of the major steps in lead prioritization is an assessment of compound binding to plasma proteins, because it affects both the pharmacokinetics and pharmacodynamics of the compound in vivo. Equilibrium dialysis is the preferred method to determine the free drug fraction, because it is less susceptible to experimental artifacts. However, even low-volume standard equilibrium dialysis is currently not amenable to the HTS format. Those considerations dictate the development of a high throughput equilibrium dialysis device, without compromising the analytical quality of the data. The present paper demonstrates successful development of a 96-well format equilibrium dialysis plate. Plasma protein binding of three drugs, propranolol, paroxetine, and losartan, with low, intermediate, and high binding properties, respectively, were chosen for assay validation. The data indicate that the apparent free fraction obtained by this method correlates with the published values determined by the traditional equilibrium dialysis techniques.