Investigation of leucine-rich repeat kinase 2 : enzymological properties and novel assays.

Mutations in leucine-rich repeat kinase 2 (LRRK2) comprise the leading cause of autosomal dominant Parkinson's disease, with age of onset and symptoms identical to those of idiopathic forms of the disorder. Several of these pathogenic mutations are thought to affect its kinase activity, so understanding the roles of LRRK2, and modulation of its kinase activity,may lead to novel therapeutic strategies for treating Parkinson's disease. In this study, highly purified, baculovirus-expressed proteins have been used,for the first time providing large amounts of protein that enable a thorough enzymatic characterization of the kinase activity of LRRK2.Although LRRK2 undergoes weak autophosphorylation, it exhibits high activity towards the peptidic substrate LRRKtide, suggesting that it is a catalytically efficient kinase. We have also utilized a time-resolved fluorescence resonance energy transfer (TR-FRET) assay format (Lantha-ScreenTM) to characterize LRRK2 and test the effects of nonselective kinase inhibitors. Finally, we have used both radiometric and TR-FRETassays to assess the role of clinical mutations affecting LRRK2's kinase activity. Our results suggest that only the most prevalent clinical mutation,G2019S, results in a robust enhancement of kinase activity with LRRKtideas the substrate. This mutation also affects binding of ATP to LRRK2,with wild-type binding being tighter (Km,app of 57 lm) than with theG2019S mutant (Km,app of 134 lm). Overall, these studies delineate the catalytic efficiency of LRRK2 as a kinase and provide strategies by which a therapeutic agent for Parkinson's disease may be identified.

Fluorescent cascade and direct assays for characterization of RAF signaling pathway inhibitors.

RAF kinases are part of a conserved signaling pathway that impacts cell growth, differentiation, and survival, and RAF pathway dysregulation is an attractive target for therapeutic intervention. We describe two homogeneous fluorescent formats that distinguish RAF pathway inhibitors from direct RAF kinase inhibitors, using B-RAF, B-RAF V599E, and C-RAF. A Förster-resonance energy transfer (FRET) based method was used to develop RAF and MEK cascade assays as well as a direct ERK kinase assay. This method uses a peptide substrate, that is terminally labeled with a FRET-pair of fluorophores, and that is more sensitive to proteolysis relative to the phosphorylated peptide. A second time-resolved FRET-based assay using fluorescently labeled MEK substrate was used to detect direct inhibitors of RAF kinase activity. The cascade assays detect compounds that interact with activated and unactivated kinases within the recapitulated RAF pathway, and the direct assays isolate the point of action for an inhibitor.

Overcoming compound interference in fluorescence polarization-based kinase assays using far-red tracers.

Kinase-mediated phosphorylation of proteins is critical to the regulation of many biological processes, including cell growth, apoptosis, and differentiation. Because of the central role that kinases play in processes that can lead to disease states, the targeting of kinases with small-molecule inhibitors is a validated strategy for therapeutic intervention. Classic methods for assaying kinases include nonhomogenous enzyme-linked immunosorbent assays or scintillation-based formats using [gamma-(32)P]ATP. However, homogenous fluorescence-based assays have gained in popularity in recent years due to decreased costs in reagent usage through miniaturization, increased throughput, and avoidance of regulatory costs associated with the use of radiation. Whereas the readout signal from a nonhomogenous or radioactive assay is largely impervious to interferences from matrix components (such as library compounds), all homogenous fluorescent assay formats are subject to such interferences. Interference from intrinsically fluorescent compounds or from scattered light due to precipitated compounds can interfere with assays that depend on a fluorescence intensity (or fluorescence quenching), fluorescence resonance energy transfer, or fluorescence polarization-based readout. Because these interfering factors show a greater effect at lower wavelengths, one strategy to overcome such interferences is to develop fluorescent assays using longer wavelength (red-shifted) fluorescent probes. In this article, we describe the PanVera PolarScreen far-red fluorescence polarization assay format, which mitigates assay interference from autofluorescent compounds or scattered light through the use of a far-red tracer. The tracer shows substantially less interference from light scatter or autofluorescent library compounds than do fluorescein-based tracers, and gives rise to a larger assay window than the popular far-red fluorophore Cy5.

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.