The thrust of early drug discovery in recent years has been toward the configuration of homogeneous miniaturized assays. This has allowed organizations to contain costs in the face of exponential increases in the number of screening assays that need to be run to remain competitive. Miniaturization brings with it an increasing dependence on instrumentation, which over the past several years has seen the development of nanodispensing capability and sophisticated detection strategies. To maintain confidence in the data generated from miniaturized assays, it is critical to ensure that both compounds and reagents have been delivered as expected to the target wells. The authors have developed a standard operating procedure for liquid-handling quality control that has enabled them to evaluate performance on 2 levels. The first level provides for routine daily testing on existing instrumentation, and the second allows for more rigorous testing of new dispensing technologies. The procedure has shown itself to be useful in identifying both method programming and instrumentation performance shortcomings and has provided a means to harmonizing instrumentation usage by assay development and screening groups. The goal is that this type of procedure be used for facilitating the exchange of liquid handler performance data across the industry.
Fluorescence assay technologies used for miniaturized high throughput screening are broadly divided into two classes. Macroscopic fluorescence techniques (encompassing conventional fluorescence intensity, anisotropy [also often referred to as fluorescence polarization] and energy transfer) monitor the assay volume- and time-averaged fluorescence output from the ensemble of emitting fluorophores. In contrast, single-molecule detection (SMD) techniques and related approaches, such as fluorescence correlation spectroscopy (FCS), stochastically sample the fluorescence properties of individual constituent molecules and only then average many such detection events to define the properties of the assay system as a whole. Analysis of single molecular events is accomplished using confocal optics with an illumination/detection volume of -1 fl (10-15 L) such that the signal is insensitive to miniaturization of HTS assays to 1 A1 or below. In this report we demonstrate the general applicability of one SMD technique (FCS) to assay configuration for target classes typically encountered in HTS and confirm the equivalence of the rate/equilibrium constants determined by FCS and by macroscopic techniques. Advantages and limitations of the current FCS technology, as applied here, and potential solutions, particularly involving alternative SMD detection techniques, are also discussed.
Single-molecule detection technologies are becoming a powerful readout format to support ultra-high-throughput screening. These methods are based on the analysis of fluorescence intensity fluctuations detected from a small confocal volume element. The fluctuating signal contains information about the mass and brightness of the different species in a mixture. The authors demonstrate a number of applications of fluorescence intensity distribution analysis (FIDA), which discriminates molecules by their specific brightness. Examples for assays based on brightness changes induced by quenching/dequenching of fluorescence, fluorescence energy transfer, and multiple-binding stoichiometry are given for important drug targets such as kinases and proteases. FIDA also provides a powerful method to extract correct biological data in the presence of compound fluorescence. ( Journal of Biomolecular Screening 2003:19-33)
Investigation of the inhibition of LDL-associated phospholipase A2 by monocyclic beta-lactams has shown that LDL phospholipase A2 is capable of hydrolyzing monocyclic-beta-lactams by a mechanism which shares many similarities to the hydrolysis of beta-lactams by beta-lactamases. We believe that this is the first demonstration of a serine-dependent lipase being able to hydrolyze an amide bond. Although 4-(phenylthio)-N-(4-phenyl-2-oxobutyl)azetidin-2-one, SB-216477, and its enantiomers are relatively modest covalent inactivators with kobs/[I] = 46 M-1 s-1 for the R enantiomer, analysis of the kinetics of inactivation and reactivation shows that these compounds act as slow-turnover substrates, presumably via an acylation-deacylation mechanism. The detection of a suprastoichiometric burst indicates that the pathway must be branched with the branching giving rise to the slow reactivation via a more stable covalent intermediate. Study of the two enantiomers of SB-216477 shows that LDL-associated phospholipase A2 is sensitive to the beta-lactam stereochemistry at C4. However, a common achiral intermediate is formed along the turnover pathway, and this must be at or immediately prior to the branch point.
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