A fluorescence lifetime-based assay for serine and threonine kinases that is suitable for high-throughput screening

We describe the development of a novel method for the assay of serine/threonine protein kinases based on fluorescence lifetime. The assay consists of three generic peptides (which have been used by others in the assay of >140 protein kinases in various assay formats) labeled with a long lifetime fluorescent dye (14 or 17 ns) that act as substrates for protein kinases and an iron(III) chelate that modulates the fluorescence lifetime of the peptide only when it is phosphorylated. The decrease in average fluorescence lifetime as measured in a recently developed fluorescence lifetime plate reader (Edinburgh Instruments) is a measure of the degree of phosphorylation of the peptide. We present data showing that the assay performs as well as, and in some cases better than, the “gold standard” radiometric kinase assays with respect to Z′ values, demonstrating its utility in high-throughput screening applications. We also show that the assay gives nearly identical results in trial screening to those obtained by radiometric assays and that it is less prone to interference than simple fluorescence intensity measurements.     

An ultrasensitive high-throughput electrochemiluminescence immunoassay for the Cdc42-associated protein tyrosine kinase ACK1

Several drugs inhibiting protein kinases have been launched successfully, demonstrating the attractiveness of protein kinases as therapeutic targets. Functional genomics research within both academia and industry has led to the identification of many more kinases as potential drug targets. Although a number of well-known formats are used for measuring protein kinase activity, some less well-characterized protein kinases identified through functional genomics present particular challenges for existing assay formats when there is limited knowledge of the endogenous substrates or activation mechanisms for these novel kinase targets. This is especially the case when a very sensitive assay is required to differentiate often highly potent inhibitors developed by late-stage medicinal chemistry programs. ACK1 is a non-receptor tyrosine kinase that has been shown to be involved in tumorigenesis and metastasis. Here we describe the development of an extremely sensitive high-throughput assay for ACK1 capable of detecting 240 fmol per well of the kinase reaction product employing a BV-tag-based electrochemiluminescence assay. This assay is universally applicable to protein tyrosine kinases using a BV-tag-labeled monoclonal antibody against phosphotyrosine. Furthermore, this assay can be extended to the evaluation of Ser/Thr kinases in those cases where an antibody recognizing the phospho-product is available.     

Immunoassays based on electrochemical detection using microelectrode arrays

We show that CombiMatrix's VLSI arrays of individually addressable electrodes, using conventional CMOS integrated circuitry, can be used in detecting various analytes via immunoassay protocols. These microarrays provide over 1000 electrodes per square centimeter. The chips are coated with a porous material on which specific affinity tags are synthesized proximate to selected electrode sites. CombiMatrix microarrays are used to develop spatially multiplexed assay formats for biological entities over a wide range of sizes, from small molecules to cells. Antibodies are tagged with coded affinity labels and then allowed to self-assemble on the appropriate electrode assay sites. Each analyte-specific antibody is chaperoned to individual, predetermined locations by the self-assembly process. The resulting chip can perform numerous different analyte-specific immunoassays, simultaneously. We present new detection technologies based upon the use of the active individually addressable microelectrodes on the chip: redox enzyme amplified electrochemical detection. The results for human alpha1 acid glycoprotein, ricin, M13 phage, Bacillus globigii spores, and fluorescein indicate that this method is one of the most sensitive available, with limits of detection in the attomole range. The detection range is 4-5 logs of analyte concentration, with an assay volume of 50 microl or less. The system provides for a host of multiplexed immunoassays because of the large number of electrodes available. We show how the assays can be optimized for maximum performance on the CombiMatrix microarray platform.     

Miniaturized GPCR Signaling Studies in 1536-Well Format

G protein-coupled receptors (GPCRs) are involved in various physiological processes, such as behavior changes, mood alteration, and regulation of immune-system activity. Thus, GPCRs are popular targets in drug screening, and a well-designed assay can speed up the discovery of novel drug candidates. The Promega cAMP-Glo Assay is a homogenous bioluminescent assay to monitor changes in intracellular cyclic adenosine monophosphate (cAMP) concentrations in response to the effect of an agonist, antagonist, or test compound on GPCRs. Together with the Labcyte Echo 555 acoustic liquid handler and the Deerac Fluidics Equator HTS reagent dispenser, this setup can screen compounds in 96-, 384-, and 1536-well formats for their effects on GPCRs. Here, we describe our optimization of the cAMP-Glo assay in 1536-well format, validate the pharmacology, and assess the assay robustness for HTS. We have successfully demonstrated the use of the assay in primary screening applications of known agonist and antagonist compounds, and confirmed the primary hits via secondary screening. Implementing a high-throughput miniaturized GPCR assay as demonstrated here allows effective screening for potential drug candidates.     

TR-FRET cellular assays for interrogating posttranslational modifications of histone H3

Posttranslational modifications such as phosphorylation, acetylation, and methylation play important roles in regulating the structures and functions of histones, which in turn regulate gene expression and DNA repair and replication. Histone-modifying enzymes, such as deacetylases, methyltransferases and demethylases, have been pursued as therapeutic targets for various diseases. However, detection of the activities of these enzymes in high-throughput cell-based formats has remained challenging. The authors have developed high-throughput LanthaScreen cellular assays for Histone H3 site-specific modifications. These assays use cells expressing green fluorescence protein-tagged Histone H3 transiently delivered via BacMam and terbium-labeled anti-Histone H3 modification-specific antibodies. Robust time-resolved F?rster resonance energy transfer signals were detected for H3 lysine-9 acetylation and dimethylation (H3K9me2), serine-10 phosphorylation, K4 di- and trimethylation, and K27 trimethylation. Consistent with previous reports, hypoxic stress increased K4 methylation levels, and methyltransferase G9a inhibitor UNC-0638 decreased K9me2 levels significantly, with little effects on other modifications. To demonstrate the utility of this assay platform in screening, the K9 acetylation assay was used to profile the Enzo Epigenetics Library. Twelve known HDAC inhibitors were identified as hits and followed up in a dose-response format. In conclusion, this assay platform enables high-throughput cell-based analysis of diverse types of posttranslational modifications of Histone H3.     

A robust screen for inhibitors and enhancers of phosphoinositide-3 kinase (PI3K) activities by ratiometric fluorescence superquenching

Aberrant regulation of phosphoinositide 3-kinase (PI3K) activity is implicated in various diseases such as cancer and diabetes. Thus, high-throughput screening (HTS) of small-molecule inhibitors for PI3 kinases is an appealing strategy for drug development. Despite the attractiveness of lipid kinases as drug targets, screening for inhibitors for PI3K activities has been hampered by limited assay formats adaptable for HTS. The authors describe a homogeneous, direct, and nonradioactive assay for highly sensitive detection of PI3Kalpha, beta, delta, and gamma activities, which is suitable for HTS. The assay is based on fluorescence superquenching of a conjugated polymer upon metal-ion-mediated association of phosphorylated and dye-labeled substrates. As a result of phosphorylation, quencher and polymer are brought into proximity, and fluorescent energy transfer occurs. This event can be monitored as either fluorescence quench of the polymer or as enhanced emission from the quencher. Ratiometric analysis of the wavelengths eliminates interferences from autofluorescing compounds, which are present in HTS libraries. The platform has been adapted for the 384-well microplate format and delivers Z factors of > 0.6 at substrate conversions as low as 7%. Using this assay platform, several unreported inhibitors and activators of PI3Ks were identified in an 84- compound screen.     

A novel and robust homogeneous fluorescence-based assay using nanoparticles for pharmaceutical screening and diagnostics

We have established a new type of homogeneous immunoassay based on nanoparticles (nanoparticle immunoassay, or NPIA) being analyzed using fluorescence intensity distribution analysis (FIDA). This method allows the characterization of single fluorescently labeled molecules or particles with respect to their molecular brightness and concentration. Upon binding of conjugates to molecules coupled to the nanoparticle surface, the brightness of the complex scales with the number of bound conjugates. The complexes can then be distinguished accurately from free conjugate and concentrations of free and bound molecules can be determined reliably. In this study we present various examples of NPIAs where capture antibodies were linked to the nanoparticles, which were either artificial beads or bacteria. Two assay formats have been developed; first, direct labeling of the conjugate was used to quantitate free antigen through competition experiments, and second, an antigen-directed antibody was labeled to establish an assay similar to a sandwich ELISA setup. The major advantages of a NPIA are the robustness and high signal-to-noise ratio at short measurement times, as demonstrated with a miniaturized experiment in a Nanocarriertrade mark holding a volume of 1 microl/well. In addition to the good data quality, NPIAs are straightforward to perform because they require no washing steps. NPIAs open new dimensions for high throughput pharmaceutical screening and diagnostics. Assay development times can be reduced significantly because of a simple toolbox principle that is applicable to most types of assays.     

Production of anti-idiotype antibodies for deoxynivalenol and their evaluation with three immunoassay platforms

Immunoassays for deoxynivalenol (DON) that involve binding to DON-specific antibodies have been widely developed. In such assays, the responses of samples are generally compared with calibration curves generated by using DON in competition with labeled reagents such as enzymatic or fluorescent conjugates of the toxin. However, materials that mimic the toxin can also be used, provided that they compete effectively with the labeled reagents for the DON-specific antibodies. Examples include certain types of anti-idiotype antibodies, obtained by the immunization of animals with toxin-specific antibodies. In the present work, anti-idiotype antibodies were developed which mimicked DON in the ability to bind to a DON-specific monoclonal antibody (Mab). Fab fragments of the Mab (Ab1) were used to immunize rabbits. Sera were screened by competitive direct enzyme linked immunosorbent assay (CD-ELISA) for the presence of anti-idiotype antibodies (Ab2). In order to determine the most effective screening format and also the potential efficacy in various forms of biosensors, the sera were further evaluated in biolayer interferometry (BLI) and fluorescence polarization immunoassay (FPIA) formats. All three formats were used to demonstrate the presence of anti-idiotypes capable of binding to the paratope of the DON antibody (subtypes Ab2β or Ab2γ). Such materials have the potential to replace DON as calibrants in immunoassays for this toxin.     

The assay design used for measurement of therapeutic antibody concentrations can affect pharmacokinetic parameters

To interpret pharmacokinetic (PK) data of biotherapeutics, it is critical to understand which drug species is being measured by the PK assay. For therapeutic antibodies, it is generally accepted that “free” circulating antibodies are the pharmacologically active form needed to determine the PK/ pharmacodynamic (PD) relationship, safety margin calculations, and dose projections from animals to humans and the eventual characterization of the exposure in the clinic. However, “total” drug may be important in evaluating the dynamic interaction between the drug and the target, as well as the total drug exposure. In the absence of or with low amounts of soluble ligand /shed receptor, total and free drug species are often equivalent and their detection is less sensitive to assay formats or reagent choices. In contrast, in the presence of a significant amount of ligand, assay design and characterization of assay reagents are critical to understanding the PK profiles. Here, we present case studies where different assay formats affected measured PK profiles and data interpretation. The results from reagent characterizations provide a potential explanation for the observed discrepancies and highlight the importance of reagent characterization in understanding which drug species are being measured to accurately interpret PK parameters.     

The assay design used for measurement of therapeutic antibody concentrations can affect pharmacokinetic parameters: Case studies

To interpret pharmacokinetic (PK) data of biotherapeutics, it is critical to understand which drug species is being measured by the PK assay. For therapeutic antibodies, it is generally accepted that “free” circulating antibodies are the pharmacologically active form needed to determine the PK/ pharmacodynamic (PD) relationship, safety margin calculations, and dose projections from animals to humans and the eventual characterization of the exposure in the clinic. However, “total” drug may be important in evaluating the dynamic interaction between the drug and the target, as well as the total drug exposure. In the absence of or with low amounts of soluble ligand /shed receptor, total and free drug species are often equivalent and their detection is less sensitive to assay formats or reagent choices. In contrast, in the presence of a significant amount of ligand, assay design and characterization of assay reagents are critical to understanding the PK profiles. Here, we present case studies where different assay formats affected measured PK profiles and data interpretation. The results from reagent characterizations provide a potential explanation for the observed discrepancies and highlight the importance of reagent characterization in understanding which drug species are being measured to accurately interpret PK parameters.     

A modified protein assay from microgram to low nanogram levels in dilute samples

In this article, we present a modified and improved protein assay that was previously described as “amidoschwarz assay” by Schaffner and Weissmann [13]. Our improved protein assay is user-friendly and 30–40 times more sensitive than the earlier method. The assay was developed into three formats (macro-, micro-, and nanoassay) with trichloroacetic acid (TCA) as protein precipitating agent, measuring up to 96 samples. The macro and micro formats of this assay require a single reagent staining with amido black of protein dots bound to nitrocellulose membrane with lowest protein measurements to 1 and 0.1 μg, respectively. On the other hand, the nanoassay, with combination staining of amido black followed by colloidal gold, can extend the detection limit to 2.5 ng of protein. Protein concentrations were determined by densitometry and/or spectrophotometry. This assay is compatible with many ionic and non-ionic detergents. This improved protein assay provides an additional choice to researchers in measuring total protein concentration accurately in dilute biological samples as low as 0.125 μg/ml prior to their biochemical analysis such as in comparative proteomics.     

Further comparison of primary hit identification by different assay technologies and effects of assay measurement variability

High-throughput screening (HTS) has grown rapidly in the past decade, with many advances in new assay formats, detection technologies, and laboratory automation. Recently, several studies have shown that the choice of assay technology used for the screening process is particularly important and can yield quite different primary screening outcomes. However, because the screening assays in these previous studies were performed in a single-point determination, it is not clear to what extent the difference observed in the screening results between different assay technologies is attributable to inherent assay variability and day-to-day measurement variation. To address this question, a nuclear receptor coactivator recruitment assay was carried out in 2 different assay formats, namely, AlphaScreen and time-resolved fluorescence resonance energy transfer, which probed the same biochemical binding events but with different detection technologies. For each assay format, 4 independent screening runs in a typical HTS setting were completed to evaluate the run-to-run screening variability. These multiple tests with 2 assay formats allow an unambiguous comparison between the discrepancies of different assay formats and the effects of the variability of assay and screening measurements on the screening outcomes. The results provide further support that the choice of assay format or technology is a critical factor in HTS assay development.     

(7-Diethylaminocoumarin-4-yl)methyl ester of suberoylanilide hydroxamic acid as a caged inhibitor for photocontrol of histone deacetylase activity

Histone deacetylases (HDACs) are involved in epigenetic control of the expression of various genes by catalyzing deacetylation of ε-acetylated lysine residues. Here, we report the design, synthesis and evaluation of the (7-diethylaminocoumarin-4-yl)methyl ester of suberoylanilide hydroxamic acid (AC-SAHA) as a caged HDAC inhibitor, which releases the known pan-HDAC inhibitor SAHA upon cleavage of the photolabile (7-diethylaminocoumarin-4-yl)methyl protecting group in response to photoirradiation. A key advantage of AC-SAHA is that the caged derivative itself shows essentially no HDAC-inhibitory activity. Upon photoirradiation, AC-SAHA decomposes to SAHA and a 7-diethylaminocoumarin derivative, together with some minor products. We confirmed that AC-SAHA inhibits HDAC in response to photoirradiation in vitro by means of chemiluminescence assay. AC-SAHA also showed photoinduced inhibition of proliferation of human colon cancer cell line HCT116, as determined by MTT assay. Thus, AC-SAHA should be a useful tool for spatiotemporally controlled inhibition of HDAC activity, as well as a candidate chemotherapeutic reagent for human colon cancer.     

Non-isotopic dual parameter competition assay suitable for high-throughput screening of histone deacetylases

Histone deacetylases reside among the most important and novel target classes in oncology. Selective lead structures are intensively developed to improve efficacy and reduce adverse effects. The common assays used so far to identify new lead structures suffer from many false positive hits due to auto-fluorescence of compounds or triggering undesired signal transduction pathways. These drawbacks are eliminated by the dual parameter competition assay reported in this study. The assay involves a new fluorescent inhibitor probe that shows an increase in both, fluorescence anisotropy and fluorescence lifetime upon binding to the enzyme. The assay is well suited for high-throughput screening.