A continuous fluorescence assay for protein kinase C

A 6-acryloyl-2-dimethylaminonapthalene (acrylodan)-labeled 25-amino acid peptide (acrylodan-CKK-KKRFSFKKSFKLSGFSFKKNKK-COO-), containing the protein kinase C (PKC) phosphorylation sites of brain myristoylated alanine-rich kinase C substrate protein, undergoes a 20% fluorescence decrease when it is phosphorylated by phospholipid/calcium-dependent protein kinase (PKC). This fluorescence decrease is dependent on the presence of PKC, calcium (half-maximal stimulation at pCa = 6.2), phosphatidylserine, diacylglycerol, or phorbol-12-myristate-13-acetate (half-maximal stimulation at 2 nM) and ATP, and correlates well (r = 0.997) with [32P]phosphate incorporation into the peptide. This fluorescence assay allows detection of 0.02 nM PKC, while similar concentrations of cyclic AMP-dependent or type II calmodulin-dependent protein kinases produced no change in peptide fluorescence. The method can be used to assay purified PKC as well as activity in crude brain homogenates. Incubation of PKC with staurosporine inhibits the fluorescence decrease with an IC50 of 2 nM. Thus the fluorescence decrease that occurs in the acrylodan-peptide provides a continuous fluorescence assay for PKC activity.     

A high-throughput, homogeneous, fluorescence polarization assay for inhibitors of hedgehog protein autoprocessing

Hedgehog (Hh) signaling plays an important role in embryonic patterning and adult stem cell renewal but has recently been found also to be involved in certain stem cell cancers. One of the first steps in Hh signaling is the autoprocessing of Hh protein, in which the C-terminal domain (Hh-C) catalyzes a cholesterol-dependent autocleavage reaction that leads to the production of the cholesterol ester of the N-terminal Hh domain (Hh-N), thereby yielding a signaling molecule that activates the Hh pathway by binding to the Patched receptor. This article describes an in vitro, homogeneous assay system that measures changes in fluorescence polarization that accompany the cholesterol-dependent autocleavage of Hh protein. The assay system makes use of a modified Hh protein in which Hh-N, which is not essential for autocleavage, is replaced by a 25-residue peptide containing a tetracysteine motif, complexed with a bisarsenical fluorophore. The assay is quite robust and easily adapted to high-throughput screening in 384-well plates with Z' factors above 0.8. It has been used to screen the National Institutes of Health Clinical Collection, which has led to the identification of 2 compounds that inhibit the cholesterol-dependent autocleavage of Hh protein at micromolar concentrations.     

Monitoring 14-3-3 protein interactions with a homogeneous fluorescence polarization assay

The 14-3-3 proteins mediate phosphorylation-dependent protein-protein interactions. Through binding to numerous client proteins, 14-3-3 controls a wide range of physiological processes and has been implicated in a variety of diseases, including cancer and neurodegenerative disorders. To better understand the structure and function of 14-3-3 proteins and to develop small-molecule modulators of 14-3-3 proteins for physiological studies and potential therapeutic interventions, the authors have designed and optimized a highly sensitive fluorescence polarization (FP)-based 14-3-3 assay. Using the interaction of 14-3-3 with a fluorescently labeled phosphopeptide from Raf-1 as a model system, they have achieved a simple 1-step "mix-and-measure" method for analyzing 14-3-3 proteins. This is a solution-based, versatile method that can be used to monitor the binding of 14-3-3 with a variety of client proteins. The 14-3-3 FP assay is highly stable and has achieved a robust performance in a 384-well format with a demonstrated signal-to-noise ratio greater than 10 and a Z' factor greater than 0.7. Because of its simplicity and high sensitivity, this assay is generally applicable to studying 14-3-3/client-protein interactions and especially valuable for high-throughput screening of 14-3-3 modulators.     

A homogeneous assay of kinase activity that detects phosphopeptide using fluorescence polarization and zinc

Homogeneous antibody-free assays of protein kinase activity have great utility in high-throughput screening in support of drug discovery. In an effort to develop such an assay, we have used a pair of fluorescein-labeled peptides of identical amino acid sequence with and without phosphorylation on serine to mimic the substrate and product, respectively, of a kinase. Using fluorescence polarization (FP), we have demonstrated that a mixture of zinc sulfate, phosphate-buffered saline, and bovine serum albumin added to the peptides dramatically and differentially increased the fluorescence polarization of the phosphorylated peptide over its nonphosphorylated derivative. A similar FP differential was observed using different peptide pairs, though the magnitude varied. The FP values obtained using this method were directly proportional to the fraction of phosphopeptide present. Therefore, an FP assay was developed using a proprietary kinase. Using this FP method, linear reaction kinetics were obtained in enzyme titration and reaction time course experiments. The IC(50) values for a panel of inhibitors of kinase activity were determined using this FP method and a scintillation proximity assay. The IC(50) values were comparable between the two methods, suggesting that the zinc FP assay may be useful as an inexpensive high-throughput assay for identifying inhibitors of kinase activity.     

A homogeneous fluorescence polarization assay adaptable for a range of protein serine/threonine and tyrosine kinases

Recently, a new technology for high-throughput screening has been developed, called IMAP(patent pending). IMAP technology has previously been implemented in an assay for cyclic nucleotide phosphodiesterases (PDE). The authors describe the development of a homogeneous, non-antibody-based fluorescence polarization (FP) assay for a variety of protein kinases. In this assay, fluorescently labeled peptide substrate phosphorylated by the kinase is captured on modified nanoparticles through interactions with immobilized metal (M(III)) coordination complexes, resulting in a change from low to high polarization values. This assay is applicable to protein kinases that phosphorylate serine, threonine, or tyrosine residues. The IMAP platform is very compatible with high-throughput robotics and can be applied to the 1536-well format. As there are hundreds of different kinases coded for in the human genome, the assay platform described in this report is a valuable new tool in drug discovery.     

Development of a homogeneous high throughput fluorescence polarization assay for G protein-coupled receptor binding

Traditional methods that follow receptor ligand interactions are competitive assays in which the test compound displaces a radiolabeled molecule. These assays require either a time-consuming step for separation of free ligands from bound ligands or immobilization of receptors and the scintillant on a solid-phase support. In this report, we describe the development of a homogeneous binding assay for a G protein-coupled receptor in the fluorescence polarization format. This homogeneous fluorescence polarization binding assay format is superior to the traditional binding methods because no radioisotope, separation step, or solid-phase support is required. The elimination of the separation step enhances detection of low-affinity ligands and enables a real-time, continuous readout of the binding activity in a high throughput 384-well microplate format.     

An affinity-based fluorescence polarization assay for protein tyrosine phosphatases

Protein tyrosine phosphatases (PTPs) are important signaling enzymes that control such fundamental processes as proliferation, differentiation, survival/apoptosis, as well as adhesion and motility. Potent and selective PTP inhibitors serve not only as powerful research tools, but also as potential therapeutics against a variety illness including cancer and diabetes. PTP activity-based assays are widely used in high throughput screening (HTS) campaigns for PTP inhibitor discovery. These assays suffer from a major weakness, in that the reactivity of the active site Cys can cause serious problems as highly reactive oxidizing and alkylating agents may surface as hits. We describe the development of a fluorescence polarization (FP)-based displacement assay that makes the use of an active site Cys to Ser mutant PTP (e.g., PTP1B/C215S) that retains the wild-type binding affinity. The potency of library compounds is assessed by their ability to compete with the fluorescently labeled active site ligand for binding to the Cys to Ser PTP mutant. Finally, the substitution of the active site Cys by a Ser renders the mutant PTP insensitive to oxidation and alkylation and thus will likely eliminate "false" positives due to modification of the active site Cys that destroy the phosphatase activity.     

Development of a microplate-based, electrophoretic fluorescent protein kinase a assay: comparison with filter-binding and fluorescence polarization assay formats

A microplate-based electrophoretic assay has been developed for the serine/threonine kinase protein kinase A (PKA). The ElectroCapture PKA assay developed uses a positively charged, lissamine-rhodamine-labeled kemptide peptide substrate for the kinase reaction and Nanogen's ElectroCapture HTS Workstation and 384-well laminated membrane plates to electrophoretically separate the negatively charged phosphorylated peptide product from the kinase reaction mix. After the electrophoretic separation, the amount of rhodamine-labeled phosphopeptide product was quantified using a Tecan Ultra384 fluorescence reader. The ElectroCapture PKA assay was validated with both known PKA inhibitors and library compounds. The pK(iapp) results obtained in the ElectroCapture PKA assay were comparable to those generated with current radioactive filter-binding assay and antibody-based competitive fluorescence polarization PKA assay formats.     

A fluorescence polarization assay for native protein substrates of kinases

Protein phosphorylation is the mediator of many important cellular processes of signal transduction and cell regulation. Phosphorylation often occurs on multiple sites within a single protein, whereby the results of individual phosphorylations are not well defined. This is partially due to the lack of tools for analyzing specific phosphorylation states in a quantitative manner. We have developed a high-throughput, rapid, and quantitative method for the determination of the phosphorylation status of peptides and, more importantly, native protein substrates of kinases using a competitive fluorescence-based approach. We have applied our method to measuring the phosphorylation activity of the Wee1 and Myt1 kinases. Our technique allows one to monitor the bis-phosphorylation status of the Cdk2 protein using an antibody specific for bis-phosphorylated Cdk2 and a fluorescently labeled bis-phosphorylated Cdk2 peptide. We have used this assay to screen a library of 16 general kinase inhibitors against Wee1 and Myt1 activity. None of the inhibitors inhibited Wee1, but both staurosporine and K-252a inhibited Myt1, with IC(50) values of 9.2+/-3.6 and 4.0+/-1.3 microM, respectively.     

A simple theoretical model for fluorescence polarization binding assay development

Fluorescence polarization is a screening technology that is radioactivity free, homogeneous, and ratiometric. The signal measured with this technology is a weighted value of free and bound ligand. As a consequence, saturation curves are accessible only after calculation of the corresponding concentrations of free and bound ligand. To make this technology more accessible to assay development, the authors propose a simple mathematical model that predicts fluorescence polarization values from ligand and receptor total concentrations, depending on the corresponding dissociation constant. This model was validated using data of Bodipy-NDP-alphaMSH binding to MC(5), obtained after either ligand saturation of a receptor preparation or, conversely, receptor saturation of a ligand solution. These experimental data were also used to calculate the actual concentration of free and bound ligand and receptor and to obtain pharmacological constants by Scatchard analysis. A general method is proposed, which facilitates the design of fluorescence polarization binding assays by relying on the representation of theoretical polarization values. This approach is illustrated by the application to 2 systems of very different affinities.     

Development and validation of a competitive AKT serine/threonine kinase fluorescence polarization assay using a product-specific anti-phospho-serine antibody.

A competitive fluorescence polarization (FP) assay has been developed for the serine/threonine kinase, AKT. The FP assay has been formatted in a 384-well microtiter plate and automated using a pipeting workstation with performance suitable for high-throughput screening. The assay design utilizes a fluorescent phosphorylated peptide complexed to a product-specific anti-phospho-serine antibody. When unlabeled substrate is phosphorylated, by the kinase, the product competes with the fluorescent phosphorylated peptide for the antibody. The fluorescent phosphorylated peptide is then released from the antibody into solution resulting in a loss in polarization signal. Seven fluorescent phosphorylated peptides and 19 antibodies were evaluated for this assay. RARTSpSFAEPGK-Fl peptide and anti-phospho-GSK-3alpha Ser21 antibody gave the best affinity and change in polarization signal. The apparent kinetic constants were calculated for the FP assay and were consistent with reported values. The FP assay was validated with known inhibitors and the results compared to a radioactive Flashplate transfer assay, utilizing [(33)P]ATP and a biotinylated substrate, also developed in our laboratory. The IC(50) values generated were comparable between the two methods suggesting the competitive FP assay and Flashplate assay have similar sensitivities and abilities to identify inhibitors during screening.     

Development of a fluorescence polarization bead-based coupled assay to target different activity/conformation states of a protein kinase

Most of the protein kinase inhibitors being developed are directed toward the adenosine triphosphate (ATP) binding site that is highly conserved in many kinases. A major issue with these inhibitors is the specificity for a given kinase. Structure determination of several kinases has shown that protein kinases adopt distinct conformations in their inactive state, in contrast to their strikingly similar conformations in their active states. Hence, alternative assay formats that can identify compounds targeting the inactive form of a protein kinase are desirable. The authors describe the development and optimization of an Immobilized Metal Assay for Phosphochemicals (IMAP)-based couple d assay using PDK1 and inactive Akt-2 enzymes. PDK1 phosphorylates Akt-2 at Thr 309 in the catalytic domain, leading to enzymatic activation. Activation of Akt by PDK1 is measured by quantitating the phosphorylation of Akt-specific substrate peptide using the IMAP assay format. This IMAP-coupled assay has been formatted in a 384-well microplate format with a Z' of 0.73 suitable for high-throughput screening. This assay was evaluated by screening the biologically active sample set LOPAC trade mark and validated with the protein kinase C inhibitor staurosporine. The IC(50) value generated was comparable to the value obtained by the radioactive (33)P-gamma-ATP flashplate transfer assay. This coupled assay has the potential to identify compounds that target the inactive form of Akt and prevent its activation by PDK1, in addition to finding inhibitors of PDK1 and activated Akt enzymes.     

Development of a fluorescence polarization assay for peptidyl-tRNA hydrolase

Peptidyl-tRNA hydrolase (Pth) activity ensures the rapid recycling of peptidyl-tRNAs that result from premature termination of translation. Historically, the hydrolyzing activity of Pth has been assayed with radiolabeled N-blocked aminoacyl-tRNAs in assay systems that require the separation of radiolabeled amino acid from the N-blocked aminoacyl-tRNA complex. In the present study, we describe the development of a kinetic fluorescence polarization (FP) assay that enables measurements of Pth activity without the need to separate bound and free tracer. The hydrolyzing activity of Pth was determined by measuring the change in polarization values that resulted from the cleavage of a fluorescently labeled substrate (BODIPY-Lys-tRNA(Lys)). The data were analyzed using an equation describing first-order dissociation and the results showed that the experimental data correlated well with the theoretical curve. A runs test of the residuals showed that the experimental data did not significantly differ from the first-order model. The assay is adaptable to a multiwell format and is sensitive enough to detect Pth-like activity in bacterial cell lysate. The Pth FP assay provides a homogeneous and kinetic format for measuring Pth activity in vitro.     

A homogeneous,nonradioactive high-throughput fluorogenic protein kinase assay

Protein kinases play an important role in many cellular processes and mediate cellular responses to a variety of extracellular stimuli. They have been identified by many pharmaceuticals as valid targets for drug discovery. Because of the large number of protein kinases, and the large number of compounds to be screened, it is important to develop assay systems that are not only sensitive but also homogeneous, fast, simple, nonradioactive, and cost-effective. Here we present a novel, rapid, robust assay to measure the enzyme activity of low concentrations of several serine/threonine and tyrosine protein kinases. It is based on the use of fluorogenic peptide substrates (Rhodamine 110, bis peptide amide) that are cleaved before phosphorylation to release the free Rhodamine 110; upon phosphorylation, cleavage is hindered, and the compound remains as a nonfluorescent peptide conjugate. The assay can be carried out in single- as well as multiwell plate formats such as 96- and 384-well plates. The signal-to-noise ratio is very high (40), the Z(') is over 0.8, and the signal is stable for at least 4h. Finally, the assay is easily adapted to a robotic system for drug discovery programs targeting protein kinases.     

Identification of small molecule inhibitors of the mitotic kinase haspin by high-throughput screening using a homogeneous time-resolved fluorescence resonance energy transfer assay

Haspin/Gsg2 is a kinase that phosphorylates histone H3 at Thr-3 (H3T3ph) during mitosis. Its depletion by RNA interference results in failure of chromosome alignment and a block in mitosis. Haspin, therefore, is a novel target for development of antimitotic agents. We report the development of a high-throughput time-resolved fluorescence resonance energy transfer (TR-FRET) kinase assay for haspin. Histone H3 peptide was used as a substrate, and a europium-labeled H3T3ph phosphospecific monoclonal antibody was used to detect phosphorylation. A library of 137632 small molecules was screened at K(m) concentrations of ATP and peptide to allow identification of diverse inhibitor types. Reconfirmation of hits and IC( 50) determinations were carried out with the TR-FRET assay and by a radiometric assay using recombinant histone H3 as the substrate. A preliminary assessment of specificity was made by testing inhibition of 2 unrelated kinases. EC( 50) values in cells were determined using a cell-based ELISA of H3T3ph. Five compounds were selected as leads based on potency and chemical structure considerations. These leads form the basis for the development of specific inhibitors of haspin that will have clear utility in basic research and possible use as starting points for development of antimitotic anticancer therapeutics.     

A microtiter plate assay for protein kinase C

We report the development of a microtiter plate assay for protein kinase C. Reaction components and enzyme samples (protein kinase C purified by phosphatidylserine/cholesterol affinity or DEAE-Sephacel ion-exchange chromatography) were added to wells of a 96-well microtiter plate. The assay was started by the addition of [gamma-32P]ATP with a repeating pipet. After a 3-min incubation at 30 degrees C the wells were sampled six at a time with a 12-channel pipet and spotted onto phosphocellulose filter paper rectangles which were washed with tap water and acetone and counted for radioactivity. The microtiter plate method was more rapid than but gave results similar to those of a standard assay performed in plastic test tubes individually incubated in a 30 degrees C water bath. The microtiter plate procedure gave an intraassay (within one plate) variation of less than 9% and an interassay (between plates) variation of less than 5%. It was linear with time of incubation for 20 min and with amount of enzyme. This method can be used to expedite the assaying of column chromatography fractions for protein kinase C (and other kinase) activity.     

Development of a fluorescence polarization binding assay for asialoglycoprotein receptor

Asialoglycoprotein receptor (ASGP-R) has been actively investigated for targeted delivery of therapeutic agents into hepatocytes because this receptor is selectively and highly expressed in liver and has a high internalization rate. Synthetic cluster glycopeptides (e.g., triGalNAc) bind with high affinity to ASGP-R and, when conjugated to a therapeutic agent, can drive receptor-mediated uptake in liver. We developed a novel fluorescent polarization (FP) ASGP-R binding assay to determine the binding affinities of ASGP-R-targeted molecules. The assay was performed in 96-well microplates using membrane preparations from rat liver as a source of ASGP-R and Cy5 fluorophore-labeled triGalNAc synthetic ligand as a tracer. This high-throughput homogeneous assay demonstrates advantages over existing multistep methods in that it minimizes both time and resources spent in determining binding affinities to ASGP-R. At the optimized conditions, a Z' factor of 0.73 was achieved in a 96-well format.     

A multiplexed homogeneous fluorescence-based assay for protein kinase activity in cell lysates

New methods to quantify protein kinase activities directly from complex cellular mixtures are critical for understanding biological regulatory pathways. Herein, a fluorescence-based chemosensor strategy for the direct measurement of kinase activities in crude mammalian cell lysates is described. We first designed a new fluorescent peptide reporter substrate for each target kinase. These kinase chemosensors were readily phosphorylated by recombinant target enzyme and underwent a several-fold fluorescence increase upon phosphorylation. Then, using unfractionated cell lysates, a homogeneous kinase assay was developed that was reproducible, linear and highly preferential for monitoring changes in cellular activity of the target kinase. The general protocol was developed for the kinase Akt and then easily extended to measure protein kinase A (PKA) and mitogen-activated protein kinase-associated protein kinase 2 (MK2) activities. This assay platform is immediately useful for studying protein kinase signaling in crude cellular extracts.     

Fluoresceinated FKBP12 ligands for a high-throughput fluorescence polarization assay

Several fluoresceinated FKBP12 ligands have been prepared for a high-throughput fluorescence polarization assay. K(i)s for FKBP12 rotamase inhibition by these ligands range from 1.3 microM to 32 nM, and their design is based on X-ray crystal structures of FKBP12 complexed with known immunophilin ligands.