Bioluminescent Assays for Glucose and Glutamine Metabolism: High-Throughput Screening for Changes in Extracellular and Intracellular Metabolites.

Cancer cell metabolism is a complex, dynamic network of regulated pathways. Interrogation of this network would benefit from rapid, sensitive techniques that are adaptable to high-throughput formats, facilitating novel compound screening. This requires assays that have minimal sample preparation and are adaptable to lower-volume 384-well formats and automation.

Bioluminescent cell-based NAD(P)/NAD(P)H assays for rapid dinucleotide measurement and inhibitor screening.

Abstract The central role of nicotinamide adenine dinucleotides in cellular energy metabolism and signaling makes them important nodes that link the metabolic state of cells with energy homeostasis and gene regulation. In this study, we describe the implementation of cell-based bioluminescence assays for rapid and sensitive measurement of those important redox cofactors. We show that the sensitivity of the assays (limit of detection ∼0.

Self-immolative bioluminogenic quinone luciferins for NAD(P)H assays and reducing capacity-based cell viability assays.

Highly sensitive self-cleavable trimethyl lock quinone-luciferin substrates for diaphorase were designed and synthesized to measure NAD(P)H in biological samples and monitor viable cells via NAD(P)H-dependent cellular oxidoreductase enzymes and their NAD(P)H cofactors.

Proluciferin acetals as bioluminogenic substrates for cytochrome P450 activity and probes for CYP3A inhibition.

Cytochrome P450 (P450) assays use probe substrates to interrogate the influence of new chemical entities toward P450 enzymes. We report the synthesis and study of a family of bioluminogenic luciferin acetal substrates that are oxidized by P450 enzymes to form luciferase substrates. The luciferin acetals were screened against a panel of purified P450 enzymes.

Automated luminescence-based cytochrome P450 profiling using a simple, elegant robotic platform.

The determination of inhibitory effects that lead compounds have on cytochrome P450 (CYP) enzymes is an important part of today's drug discovery process. Assays can be performed early in the discovery process to predict adverse drug-drug interactions caused by CYP inhibition and to minimize the costs associated with terminating candidates in late stage development or worse, removing a drug from the market after launch. For early discovery work, testing substantial numbers of compounds is desirable, thus automated "mix and read" assays are beneficial.

The utility of semi-automating multiplexed assays for ADME/Tox applications.

ADME-Tox testing examines the effects of an organism, tissue or cell on a compound, as well as the effects that the compound has on an organism, tissue or cell, and has gained in importance in the overall drug discovery process over the past twenty years. This is due to the rising percentage of drug candidate attrition in the 1990s and early 2000s due to adverse ADME/Tox profiles. The increased importance placed upon ADME/Tox testing has brought about new types of in-vitro assay technologies utilizing microplates to deliver the most pharmacologically relevant data.

Luminogenic cytochrome P450 assays.

Luminogenic cytochrome P450 (CYP) assays couple CYP enzyme activity to firefly luciferase luminescence in a technology called P450-Glo(TM) (Promega). Luminogenic substrates are used in assays of human CYP1A1, -1A2, -1B1, -2C8, -2C9, -2C19, -2D6, -2J2, -3A4, -3A7, -4A11, -4F3B, -4F12 and -19. The assays detect dose-dependent CYP inhibition by test compounds against recombinant CYP enzymes or liver microsomes.