Miniaturization of fluorescence polarization receptor-binding assays using CyDye-labeled ligands.

Fluorescence polarization (FP) is an established technique for the study of biological interactions and is frequently used in the high-throughput screening (HTS) of potential new drug targets. This work describes the miniaturization of FP receptor assays to 1536-well formats for use in HTS. The FP assays were initially developed in 384-well microplates using CyDye-labeled nonpeptide and peptide ligands. Receptor expression levels varied from approximately 1 to 10 pmols receptor per mg protein, and ligand concentrations were in the 0.5- to 1.0-nM range. The FP assays were successfully miniaturized to 1536-well formats using Cy3B-labeled ligands, significantly reducing reagent consumption, particularly the receptor source, without compromising assay reliability. Z' factor values determined for the FP receptor assays in both 384- and 1536-well formats were found to be > 0.5, indicating the assays to be robust, reliable, and suitable for HTS purposes.

Evaluation of an imaging platform during the development of a FRET protease assay.

Synthetic peptide substrates labeled with a fluorescent donor and quenching moiety flanking an enzyme cleavage site provide a reliable method for monitoring enzyme activity. The dye pair Mca/Dnp has been widely used for this purpose, but poor solubility characteristics, combined with fluorescence emission in the region of the spectrum associated with interference from biologicals and library compounds, can limit the usefulness of Mca/Dnp substrates in a high-throughput screening (HTS) environment. Peptide Mca-Arg-Pro-Lys-Pro-Val-Glu-Nva-Trp-Arg-Lys(Dnp)-NH(2) is a matrix-metalloproteinase 3 (MMP-3) enzyme substrate that the authors have labeled with a CyDye pair, Cy3/Cy5Q. The Mca/Dnp- and CyDye-labeled substrates were compared during the development of an MMP-3 inhibitor assay. The results obtained showed that although the peptide substrates behaved similarly throughout the development of the MMP-3 assay, during a test screen of 934 compounds randomly selected from a collection of more than 70000 compounds, the CyDye substrate was considerably more reliable. Screen Z factor values of 0.84 and 0.15 were obtained using the CyDye and Mca/Dnp peptides respectively, and the authors found that although < 1% of the test compounds were auto-fluorescent at Cy3 wavelengths, > 10% could not be screened using the Mca/Dnp substrate because of compound auto-fluorescence and interference. During this study, the authors used a PMT-based fluorescence plate reader and at the same time evaluated a charged couple device (CCD)-based imaging platform specifically optimized for use with CyDye reagents. The imaging platform gave improved read accuracy and faster plate processing times compared with the PMT reader. Overall, the results presented here highlight the potential benefit of employing the red-shifted CyDye reagents and imaging technology during the development and execution of HTS protease screens.

Development of an assay suitable for high-throughput screening to measure matrix metalloprotease activity.

MMPs, part of a family of enzymes with >35 known members, play an important role in tissue remodeling and repair, in the biology of neoplasia, and during development. Hydroxamic and carboxylic acid inhibitors of these proteases have long been available, but their specificities are poor and there still exists a desire to find novel chemical structures, which could be modified to optimize specificity and biocompatibility. Established methods for measuring MMP activity are based on the cleavage of MCA-PLGL-A2pr(DNP)-AR, which provides a prompt fluorescent signal when cleaved; however, its absorption/emission properties (325/400 nm) are not best suited for HTS assays. We describe an HTS-compatible method using the peptide substrate PLGLAARK, labeled at N- and C-termini with CyDye fluors Cy3 and Cy5Q, respectively, which is cleavable by MMP-1, -2, -3, -7, -9, and -13. HTS assays for MMP-13 and MMP-9 inhibitors were set up in approximately 20 microl in 384-well plates as a prompt fluorescence readout (excitation/emission = 540/570 nm) using the LEADseeker homogenous imaging system. These assays yielded IC(50) values comparable to standard methods, but with a faster, very sensitive, and normalized readout, thus conserving compound, enzyme (approximately 1.5 ng/well), and time (20 s read/plate). Data quality (Z' approximately 0.9) was such that hit-picking to -25% change in primary screening could be performed with confidence, and the subsequent rate of confirmation and validation in IC(50) determinations of the picked compounds was >60%. Parallel screening of related proteases also permitted immediate specificity comparisons, including evaluation of inactive or weakly active compounds.