Nathalie Rouleau

The Use of AlphaScreen Technology in HTS: Current Status

AlphaScreen (Amplified Luminescent Proximity Homogeneous Assay Screen) is versatile assay technology developed to measuring analytes using a homogenous protocol. This technology is an example of a bead-based proximity assay and was developed from a diagnostic assay technology known as LOCI (Luminescent Oxygen Channeling Assay). Here, singlet oxygen molecules, generated by high energy irradiation of Donor beads, travel over a constrained distance (approx. 200 nm) to Acceptor beads. This results in excitation of a cascading series of chemical reactions, ultimately causing generation of a chemiluminescent signal. In the past decade, a wide variety of applications has been reported, ranging from detection of analytes involved in cell signaling, including protein:protein, protein:peptide, protein:small molecule or peptide:peptide interactions. Numerous homogeneous HTS-optimized assays have been reported using the approach, including generation of second messengers (such as accumulation of cyclic AMP, cyclic GMP, inositol [1, 4, 5] trisphosphate or phosphorylated ERK) from liganded GPCRs or tyrosine kinase receptors, post-translational modification of proteins (such as proteolytic cleavage, phosphorylation, ubiquination and sumoylation) as well as protein-protein and protein-nucleic acid interactions. Recently, the basic AlphaScreen technology was extended in that the chemistry of the Acceptor bead was modified such that emitted light is more intense and spectrally defined, thereby markedly reducing interference from biological fluid matrices (such as trace hemolysis in serum and plasma). In this format, referred to as AlphaLISA, it provides an alternative technology to classical ELISA assays and is suitable for high throughput automated fluid dispensing and detection systems. Collectively, AlphaScreen and AlphaLISA technologies provide a facile assay platform with which one can quantitate complex cellular processes using simple no-wash microtiter plate based assays. They provide the means by which large compound libraries can be screened in a high throughput fashion at a diverse range of therapeutically important targets, often not readily undertaken using other homogeneous assay technologies. This review assesses the current status of the technology in drug discovery, in general, and high throughput screening (HTS), in particular.

Development of a Versatile Platform for Nuclear Receptor Screening Using AlphaScreen

The interaction between nuclear receptors (NRs) and their coactivators, a key step in transcription regulation, requires a short consensus sequence called the LXXLL motif found in the coactivators’ structure. Using the AlphaScreen™ technology, the authors have taken advantage of this receptor-coactivator interaction to develop a highly sensitive assay to identify and characterize compounds modulating NR activity. Estrogen and retinoic acid receptors were chosen as models to demonstrate the versatility of the AlphaScreen technology: (1) the assay can be designed using different antibodies to capture either full-length receptors or receptor domains that have been tagged, (2) the assay can differentiate between ligands that act as agonists or antagonists because only agonists will allow recruitment of the coactivator sequence–derived peptide, and (3) the assay gives the opportunity to screen for antagonists targeting the ligand-binding site or the dimerization interface between the receptor and the coactivator. Titration of the receptor and biotinylated peptide indicates that AlphaScreen is highly sensitive, requiring nanomolar concentration of reagents. Competition isotherms performed with known receptor antagonists demonstrate that the assay is a useful tool to rank the antagonists according to their order of potency. Overall, the results presented here indicate that the versatility, sensitivity, robustness, and ease of execution of the AlphaScreen NR assay will allow for efficient screening of NR modulators. (Journal of Biomolecular Screening 2003:191-197)

Development of homogeneous nonradioactive methyltransferase and demethylase assays targeting histone H3 lysine 4.

Histone posttranslational modifications are among the epigenetic mechanisms that modulate chromatin structure and gene transcription. Histone methylation and demethylation are dynamic processes controlled respectively by histone methyltransferases (HMTs) and demethylases (HDMs). Several HMTs and HDMs have been implicated in cancer, inflammation, and diabetes, making them attractive targets for drug therapy. Hence, the discovery of small-molecule modulators for these two enzyme classes has drawn significant attention from the pharmaceutical industry. Herein, the authors describe the development and optimization of homogeneous LANCE Ultra and AlphaLISA antibody-based assays for measuring the catalytic activity of two epigenetic enzymes acting on lysine 4 of histone H3: SET7/9 methyltransferase and LSD1 demethylase. Both the SET7/9 and LSD1 assays were designed as signal-increase assays using biotinylated peptides derived from the N-terminus of histone H3. In addition, the SET7/9 assay was demonstrated using full-length histone H3 protein as substrate in the AlphaLISA format. Optimized assays in 384-well plates are robust (Z′ factors ≥0.7) and sensitive, requiring only nanomolar concentrations of enzyme and substrate. All assays allowed profiling of known SET7/9 and LSD1 inhibitors. The results demonstrate that the optimized LANCE Ultra and AlphaLISA assay formats provide a relevant biochemical screening approach toward the identification of small-molecule inhibitors of HMTs and HDMs that could lead to novel epigenetic therapies.

Homogeneous and Nonradioactive High-Throughput Screening Platform for the Characterization of Kinase Inhibitors in Cell Lysates

Protein kinases are directly implicated in many human diseases; therefore, kinase inhibitors show great promises as new therapeutic drugs. In an effort to facilitate the screening and the characterization of kinase inhibitors, a novel application of the AlphaScreen technology was developed to monitor JNK activity from (1) purified kinase preparations and (2) endogenous kinase from cell lysates preactivated with different cytokines. The authors confirmed that both adenosine triphosphate (ATP) competitive as well as peptide-based JNK inhibitors were able to block the activity of both recombinant and HepG2 endogenous JNK activity. Using the same luminescence technique adapted for binding studies, the authors characterized peptide inhibitor mechanisms by measuring the binding affinity of the inhibitors for JNK. Because of the versatility of the technology, this cell-based JNK kinase assay could be adapted to other kinases and would represent a powerful tool to evaluate endogenous kinase activity and test a large number of potential inhibitors in a more physiologically relevant environment.

AlphaScreen®-Based Characterization of the Bifunctional Kinase/RNase IRE1α A Novel and Atypical Drug Target

Assay technologies that were originally developed for high-throughput screening (HTS) have recently proven useful in drug discovery for activities located upstream (target identification and validation) and downstream (ADMET) of HTS. Here the authors investigated and characterized the biological properties of a novel target, IRE1α, a bifunctional kinase/RNase stress sensor of the endoplasmic reticulum (ER). They have developed a novel assay platform using the HTS technology AlphaScreen® to monitor the dimerization/oligomerization and phosphorylation properties of the cytosolic domain of IRE1α. They show in vitro that dimerization/oligomerization of the cytosolic domain of IRE1 correlated with the autophosphorylation ability of this domain and its endoribonuclease activity toward XBP1 mRNA. Using orthogonal in vitro and cell-based approaches, the authors show that the results obtained using AlphaScreen® were biologically relevant. Preliminary characterization of assay robustness indicates that both AlphaScreen® assays should be useful in HTS for the identification of IRE1 activity modulators.

Integrated Cell-Based Platform to Study EGFR Activation and Transactivation

The epidermal growth factor receptor (EGFR) pathway is one of the most deregulated molecular pathways in human epithelial cancers. Many approved drugs were optimized to directly target EGFR but yielded only modest clinical improvement in cancer patients due to low efficacy and drug resistance. Transactivation of EGFR by other cell surface receptors such as G-protein-coupled receptors (GPCRs) was proposed to explain this lack of efficacy. Even if direct EGFR activation and transactivation by GPCR contribute to the activation of the same signaling pathways, they are often studied as independent events resulting in partial investigation of a drugs mechanism of action. We present a novel high-throughput approach that integrates interrogation of direct activation of EGFR and its transactivation via GPCR activation. Using distinct technology platforms, three readouts were used to measure (1) direct activation of GPCR via cyclic adenosine monophosphate (cAMP) detection, (2) direct activation of EGFR through the release of intracellular Ca(2+), and (3) EGFR transactivation by GPCR using the detection of p-extracellular-signal-regulated kinases 1/2 (p-ERK1/2). In addition to being simple, quick, and homogenous, our methods were shown to be more sensitive than those in current use. These enabling tools should improve the knowledge pertaining to GPCRs and receptor tyrosine kinases trans-regulation and facilitate the design of more potent and better targeted new therapeutic strategies.

Abstract 3879: High-throughput, homogeneous in cyto assays to monitor histone H3 post-translational modifications

Histone proteins are an integral part of DNA packaging into chromatin, a dynamic process partly regulated by post-translation modification of histone N-terminal tails. Aberrant histone acetylation (ac) or methylation (me) levels is associated with a number of diseases. For example, histone deacetylases (HDACs and sirtuins) regulate the expression of many genes involved in neurodegeneration and can be aberrantly expressed in different tumors. In addition, deregulation of the methyl marks H3K4me3 and H3K27me3 are found associated with the development of several types of cancer. This work presents the development of high-throughput AlphaLISA® in cyto assays to monitor four specific histone marks: H3K9ac, H3K4me2, H3K27ac and H3K27me3. These assays were performed using an all-in-one well histone extraction protocol requiring no acid extraction or centrifugation steps. The level of each histone mark was first measured in cell titration experiments, seeding cells from 500 to 10 000 in 384 well plates. The chemical modulation of H3K4me2, H3K9ac and H3K27ac was monitored following overnight treatment of HeLa, HEK293, and Jurkat cells with the non-selective histone deacetylase inhibitors sodium butyrate and trichostatin A. Signal increases were all corroborated by Western blot analysis using the same antibodies as in the AlphaLISA detection assay. In the absence of chemical modulation, measurement of different H3K27me3 mark levels was performed in two B cell lymphoma cell lines: OCI-LY-19 and SU-DHL-6. OCI-LY-19 cells express wild-type EZH2 methyltransferase while SU-DHL-6 cells bear a heterozygous EZH2 mutation (Y641N) that alters its substrate selectivity, resulting in increased H3K27me3 levels. These novel cell-based assays showed suitability for high-throughput screening (HTS) protocols as demonstrated by Z’ factors superior to 0.6 for all four marks. In summary, these homogeneous cell-based AlphaLISA assays allow the simple and rapid monitoring of cellular histone H3 mark levels. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3879. doi:1538-7445.AM2012-3879