James J. Cali

Luminogenic cytochrome P450 assays

Luminogenic cytochrome P450 (CYP) assays couple CYP enzyme activity to firefly luciferase luminescence in a technology called P450-GloTM (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. Induction or inhibition of CYP activities in cultured hepatocytes is measured in a nonlytic approach that leaves cells intact for additional analysis. Luminogenic CYP assays offer advantages of speed and safety over HPLC and radiochemical-based methods. Compared with fluorogenic methods the approach offers advantages of improved sensitivity and decreased interference between optical properties of test compound and CYP substrate. These homogenous assays are sensitive and robust tools for high-throughput CYP screening in early drug discovery.

Bioluminescent assays for ADMET.

Bioluminescent assays couple a limiting component of a luciferase-catalyzed photon-emitting reaction to a variable parameter of interest, while holding the other components constant or non-limiting. In this way light output varies with the parameter of interest. This review describes three bioluminescent assay types that use firefly luciferase to measure properties of drugs and other xenobiotics which affect their absorption, distribution, metabolism, elimination and toxicity. First, levels of the luciferase enzyme itself are measured in gene reporter assays that place a luciferase cDNA under the control of regulatory sequences from ADMET-related genes. This approach identifies activators of nuclear receptors that regulate expression of genes encoding drug-metabolizing enzymes and drug transporters. Second, drug effects on enzyme activities are monitored with luminogenic probe substrates that are inactive derivatives of the luciferase substrate luciferin. The enzymes of interest convert the substrates to free luciferin, which is detected in a second reaction with luciferase. This approach is used with the drug-metabolizing CYP and monoamine oxidase enzymes, apoptosis-associated caspase proteases, a marker protease for non-viable cells and with glutathione-S-transferase to measure glutathione levels in cell lysates. Third, ATP concentration is monitored as a marker of cell viability or cell death and as a way of identifying substrates for the ATP-dependent drug transporter, P-glycoprotein. Luciferase activity is measured in the presence of a sample that supplies the requisite luciferase substrate, ATP, so that light output varies with ATP concentration. The bioluminescent ADMET assays are rapid and sensitive, amenable to automated high-throughput applications and offer significant advantages over alternative methods.

Validation of a HTS-amenable assay to detect drug-induced mitochondrial toxicity in the absence and presence of cell death.

Drug-induced mitochondrial dysfunction is known to contribute to late stage compound attrition. Recently, assays that identify mitochondrial dysfunction have been developed but many require expensive reagents, specialized equipment, or specialized expertise such as isolation of mitochondria. Here, we validate a new 384-well format cell-based dual parameter assay that uses commonly available detection methods to measure both mitochondrial toxicity and cytotoxicity. In our initial evaluation, antimycin A, CCCP, nefazodone, flutamide, and digitonin were tested in K562 cells in both glucose- and galactose-supplemented media with a 2h incubation. The assay was able to correctly differentiate these compounds into mitochondrial toxicants and non-mitochondrial toxicants, and had excellent reproducibility. We next tested 74 compounds in K562 cells in both types of media and show that the assay was able to correctly identify some of the compounds as mitochondrial toxicants. Moreover, the assay could be simplified, without loss of information, by using K562 cells in galactose-containing medium alone. This simple, robust assay can be positioned as a rapid, early readout of mitochondrial and cellular toxicity. However, since the assay fails to identify some mitochondrial toxicants, further assays may be required to detect mitochondrial toxicity once lead compounds have been selected.

Bioluminescent, Nonlytic, Real-Time Cell Viability Assay and Use in Inhibitor Screening

Abstract Real-time continuous monitoring of cellular processes offers distinct advantages over traditional endpoint assays. A comprehensive representation of the changes occurring in live cells over the entire length of an experiment provides information about the biological status of the cell and informs decisions about the timing of treatments or the use of other functional endpoint assays. We describe a homogeneous, nonlytic, bioluminescent assay that measures cell viability in real time. This time-dependent measurement allowed us to monitor cell health for 72 h from the same test samples, distinguish differential cell growth, and investigate drug mechanism of action by analyzing time- and dose-dependent drug effects. The real-time measurements also allowed us to detect cell death immediately (>75% signal decrease within 15 min of digitonin addition), analyze drug potency versus efficacy, and identify cytostatic versus toxic drug effects. We screened an oncology compound library (Z′ = 0.7) and identified compounds with varying activity at different time points (1.6% of the library showed activity within 3 h, whereas 35.4% showed a response by 47 h). The assay compared well with orthogonal endpoint cell viability assays and additionally provided data at multiple time points and the opportunity to multiplex assays on the same cells. To test the advantage of time-dependent measurements to direct optimal timing of downstream applications, we used the real-time cell viability assay to determine the ideal time to measure caspase activity by monitoring the onset of cell death and multiplexing a luminescent caspase activation assay on the same test samples.

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.

Bioluminescent Assays for Cytochrome P450 Enzymes

The cytochrome P450 (CYP) family contains 57 enzymes in humans. The activity of CYPs against xenobiotics is a primary consideration in drug optimization efforts. Here we describe a series of bioluminescent assays that enable the rapid profiling of CYP activity against compound collections. The assays employ a coupled-enzyme format where firefly luciferase is used to measure CYP enzyme activity through metabolism of pro-luciferase substrates.

Bioluminescent assays for ADME evaluation: dialing in CYP selectivity with luminogenic substrates

Introduction: The cytochrome P450s (CYPs) are central to ADME studies because of their central role in drug metabolism. Proper CYP assay design and a correct understanding of CYP assay selectivity are critical for generating and interpreting biologically relevant data during drug development. Bioluminescent CYP assays use luminogenic probe substrates that have the unique property of producing photons in a second reaction with luciferase. Areas covered: This article presents the general design principles for in vitro CYP assays. Specifically, the article focuses on the bioluminescent approach that couples CYP activity with photon production. Expert opinion: Highly selective luminogenic substrates for CYP1A1, CYP1A2, CYP2C9, CYP3A4, CYP3A7, CYP4A and CYP4F have been developed with utility for interrogating the roles of these enzymes in biochemical and cell-based formats. These selective substrates are part of a larger collection of probes that deliver CYP inhibition and induction data that predict in vivo drug interactions. Furthermore, they support highly sensitive, rapid and scalable assays for cell-based and cell-free biochemical applications, which offer an alternative and often enabling option over conventional assay strategies.

A bioluminescent assay for the sensitive detection of proteases.

A bioluminescent general protease assay was developed using a combination of five luminogenic peptide substrates. The peptide-conjugated luciferin substrates were combined with luciferase to form a homogeneous, coupled-enzyme assay. This single-reagent format minimized backgrounds, gave stable signals, and reached peak sensitivity within 30 min. The bioluminescent assay was used to detect multiple proteases representing serine, cysteine, and metalloproteinase classes. The range of proteases detected was broader and the sensitivity greater, when compared with a standard fluorescent assay based on cleavage of the whole protein substrate casein. Fifteen of twenty proteases tested had signal-to-background ratios >10 with the bioluminescent method, compared with only seven proteases with the fluorescent approach. The bioluminescent assay also achieved lower detection limits (≤100 pg) than fluorescent methods. During protein purification processes, especially for therapeutic proteins, even trace levels of contamination can impact the proteins stability and activity. This sensitive, bioluminescent, protease assay should be useful for applications in which contaminating proteases are detrimental and protein purity is essential.

Automated Triplexed Hepatocyte-Based Viability and CYP1A and -3A Induction Assays:

Cytochrome P450 (CYP) enzymes are key players in drug metabolism. Therefore, it is essential to understand how these enzymes can be affected by xenobiotics with regards to induction and toxicity to avoid potential drug–drug interactions. Typically, information has been gathered by combining data from multiple experiments, which is time-consuming and labor intensive, and interassay variability may lead to misinterpretation. Monitoring CYP induction and cytotoxicity by xenobiotics using an automated, multiplexed format can decrease workload and increase data confidence. Here the authors demonstrate the ability to monitor CYP1A and CYP3A4 induction, combined with a cytotoxicity measurement, from a single microplate well using cryopreserved human hepatocytes. The assay procedure was automated in a 384-well format, including cell manipulations, compound titration and transfer, and reagent dispensing, using simple robotic instrumentation. EC50 and Emax values were derived for multiple known CYP1A and -3A4 inducers. Induction and toxicological responses in the triplex system were validated based on literature values from conventional single-parameter assays. Validation and pharmacology data confirm that multiplexed cell-based CYP assays can simplify workload, save time and effort, and generate biologically relevant data.

Molecular imaging of cytochrome P450 activity in mice

Detailed knowledge of drug metabolism is relevant information provided by preclinical drug development research. Oxidative enzymes such as those belonging to P450 family of cytochromes (CYP) play a prominent role in drug metabolism. Here, we propose an innovative method based on bioluminescence in vivo imaging which has the potential to simplify the in vivo measurement of CYP activity also providing a dynamic measure of the effects of a drug on a specific P450 enzyme complex in a living mouse. The method is based on a pro-luciferin which can be converted into the active luciferase substrate by a specific P450 activity. The pro-luciferin is administered to a luciferase reporter mouse which produces luminescent signals in relation to the cytochrome activity present in each tissue. The photon emission generated can be easily localized and quantified by optical imaging. To demonstrate the validity of the system, we pharmacologically induced hepatic Cyp3a in the reporter mouse and proved that pro-luciferin administration generates a Cyp3a selective signal in the chest area that can be efficiently detected by optical imaging. The kind of tool generated has the potential to be exploited for the study of additional CYPs.