Miniaturization of intracellular calcium functional assays to 1536-well plate format using a fluorometric imaging plate reader

The measurement of intracellular calcium response transients in living mammalian cells is a popular functional assay for identification of agonists and antagonists to receptors or channels of pharmacological interest. In recent years, advances in fluorescence-based detection techniques and automation technologies have facilitated the adaptation of this assay to 384-well microplate format high-throughput screening (HTS) assays. However, the cost and time required performing the intracellular calcium HTS assays in the 384-well format can be prohibitive for HTS campaigns of greater than 1 x 10(6) wells. For these reasons, it is attractive to miniaturize intracellular calcium functional assays to the 1536-well microplate format, where assay volumes and plate throughput can be decreased by several fold. The focus of the research described in this article is the miniaturization of an intracellular calcium assay to 1536-well plate format. This was accomplished by modifying the hardware and software of a fluorometric imaging plate reader (FLIPR) to enable transfer of nanoliters of test compound directly to a 1536-well assay plate, and measure the resulting calcium response from all 1536 wells simultaneously. An intracellular calcium functional assay against the rat muscarinic acetylcholine receptor subtype 1 (rmAchR1) G-protein coupled receptor (GPCR) was miniaturized and executed on this modified instrument. In experiments measuring the activity of known muscarinic receptor agonists and antagonists, the miniaturized FLIPR assay gave EC(50) and IC(50) values and rank order potency comparable to the 384-well format assays. Calculated Z' factors for the miniaturized agonist and antagonist assays were, respectively, 0.56 +/- 0.21 and 0.53 +/- 0.22, which were slightly higher (Z'(agonist) = 0.55 +/- 0.33) and lower (Z'(antagonist) = 0.70 +/- 0.18) than the corresponding values in the 384-well assays. A mock agonist HTS campaign against the muscarinic receptor in miniaturized format was able to identify all wells spiked with the rmAchR1 agonist carbachol.     

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.     

A Novel Control System for Polymerase Chain Reaction Using a RIKEN GS384 Thermalcycler

We have developed a novel high-throughput thermalcycler, theRIKEN GS384, which has a maximum of 1536 wells and whose temperaturecan be controlled accurately and simultaneously for a very smallvolume of a reaction mixture. In practice, the reaction is carriedout using four 384-well (3.5 mm in diameter) plate formats whichcan be automatically moved using a robotic arm. To achieve accuratetemperature control with high thermo-conductivity, we adoptedTeflon-coated aluminum well plates closely sandwiched betweensilicon sheet-covered lids on top and a graphite sheet below.The lids were kept at a higher temperature (2 to 5°C) thanthe reaction wells. The temperature of the 1536 sample wellswas controlled accurately without temperature variability amongthe wells or evaporation, even for samples of very small volume(minimum 2 µl). We also developed a new type of plateformat which is similar to the 384-well place in terms of platesize, shape, and material, but which differs in the number (1536)and size (1.6 mm in diameter) of the wells. Since the amplificationreactions could be done precisely as well, a total of 6144 reactionscan potentially be carried out simultaneously using the GS384thermalcycler. This is very promising for DNA microfabricationtechnology. This thermalcycler offers the advantage of high-throughputDNA analysis which should be useful for DNA diagnoses or forthe human genome project.     

Detection of p56(lck) kinase activity using scintillation proximity assay in 384-well format and imaging proximity assay in 384- and 1536-well format

p56(lck) is a lymphocyte-specific tyrosine kinase that plays an important role in both T-cell maturation and activation. We have developed a homogeneous assay in which p56(lck) catalyzes the transfer of the gamma-phosphate group from [gamma-(33)P]ATP to a biotinylated peptide substrate. The labeled peptide is then captured on a streptavidin-coated scintillation proximity assay (SPA) bead or imaging proximity bead. The SPA is counted in a microplate scintillation counter and the imaging proximity assay is counted in a charge-coupled device-based imaging system called LEADseekertrade mark, recently launched as a homogeneous imaging system by Amersham Pharmacia Biotech. We show, via time-dependence assays and inhibitor studies, that this assay can be performed in 1536-well microplate format using imaging proximity as the method of detection. The results compare favorably with the same assay performed in 384-well microplate format using both SPA and imaging proximity as the detection methods. From this study, we conclude that a kinase assay can be performed in 384- and 1536-well format using imaging as the detection method, with significant time savings over standard scintillation counting. In addition, we show cost saving advantages of 1536- over 384-well format in terms of reagent usage, higher throughput, and waste disposal.     

Time-Resolved Fluorescence Energy Transfer DNA Helicase Assays for High Throughput Screening

DNA helicases are responsible for the unwinding of double-stranded DNA, facilitated by the binding and hydrolysis of 5'-nucleoside triphosphates. These enzymes represent an important class of targets for the development of novel anti-infective agents particularly because opportunity exists for synergy with existing therapies targeted at other enzymes involved in DNA replication. Unwinding reactions are conventionally monitored by low throughput, gel-based radiochemical assays; to overcome the limitations of low throughput to achieve comprehensive characterization of adenosine triphosphate (ATP)-dependent unwinding by viral and bacterial helicases and the screening for unwinding inhibitors, we have developed and validated homogeneous time-resolved fluorescence energy transfer (TRET) assays. Rapid characterization and screening of DNA helicase has been performed in 96- and 384-well plate densities, and the ability to assay in 1536-well format also demonstrated. We have successfully validated and are running full high throughput runs using 384-well TRET helicase assays, culminating in the identification of a range of chemically diverse inhibitors of viral and bacterial helicases. For screening in mixtures, we used a combination of quench correction routines and confirmatory scintillation proximity (SP) assays to eliminate false-positives due to the relatively high levels of compound quenching (unlike other Ln(3+)-based assays). This strategy was successful yet emphasised the need for further improvements in helicase assays.     

Optimization procedure for small interfering RNA transfection in a 384-well format

High-throughput screening of RNAi libraries has become an essential part of functional analysis in academic and industrial settings. The transition of a cell-based RNAi assay into a 384-well format requires several optimization steps to ensure the phenotype being screened is appropriately measured and that the signal-to-background ratio is above a certain quantifiable threshold. Methods currently used to assess small interfering RNA (siRNA) efficacy after transfection, including quantitative PCR or branch DNA analysis, face several technical limitations preventing the accurate measurement of mRNA levels in a 384-well format. To overcome these difficulties, the authors developed an approach using a viral-based transfection system that measures siRNA efficacy in a standardized 384-well assay. This method allows measurement of siRNA activity in a phenotypically neutral manner by quantifying the knockdown of an exogenous luciferase gene delivered by a lentiviral vector. In this assay, the efficacy of a luciferase siRNA is compared to a negative control siRNA across many distinct assay parameters including cell type, cell number, lipid type, lipid volume, time of the assay, and concentration of siRNA. Once the siRNA transfection is optimized as a 384-well luciferase knockdown, the biologically relevant phenotypic analysis can proceed using the best siRNA transfection conditions. This approach provides a key technology for 384-well assay development when direct measurement of mRNA knockdown is not possible. It also allows for direct comparison of siRNA activity across cell lines from almost any mammalian species. Defining optimal conditions for siRNA delivery into mammalian cells will greatly increase the speed and quality of large-scale siRNA screening campaigns.     

Microplate orbital mixing improves high-throughput cell-based reporter assay readouts

Reporter assays are commonly used for high-throughput cell-based screening of compounds, cDNAs, and siRNAs due to robust signal, ease of miniaturization, and simple detection and analysis. Among the most widely used reporter genes is the bioluminescent enzyme luciferase, which, when exposed to its substrate luciferin upon cell lysis, yields linear signal over a dynamic range of several orders of magnitude. Commercially available luciferase assay formulations have been developed permitting homogeneous, single-step cell lysis and reporter activity measurements. Assay conditions employed with these formulations are typically designed to minimize well-to-well luminescence variability due to variability in dispensing, evaporation, and incomplete sample mixing. The authors demonstrate that incorporating a microplate orbital mixing step into 96- and 384-well microplate cell-based luciferase reporter assays can greatly improve reporter readouts. They have found that orbital mixing using commercially available mixers facilitates maximal luciferase signal generation from high cell density-containing samples while minimizing variability due to partial cell lysis, thereby improving assay precision. The authors fully expect that widespread availability of mixers with sufficiently small orbits and higher speed settings will permit gains in signal and precision in the 1536-well format as well.     

A Homogenous 384-Well High Throughput Screen for Novel Tumor Necrosis Factor Receptor: Ligand Interactions Using Time Resolved Energy Transfer

The herpes virus entry mediator (HVEM) receptor and its ligand, HVEM-L, are involved in both herpes simplex virus type-1 (HSV-1) herpes simplex virus type-2 (HSV-2) infection, and in T-cell activation such that antagonists of this interaction are expected to have utility in viral and inflammatory diseases. In this report we describe the configuration of a homogeneous 384-well assay based on time-resolved energy transfer from a europium chelate on the HVEM receptor to an allophycocyanin (APC) acceptor on the ligand. Specific time resolved emission from the acceptor is observed on receptor:ligand complex formation. The results of various direct and indirect labeling strategies are described. Several assay optimization experiments were necessary to obtain an assay that was robust to automation and file compound interference while sensitive to the effect of potential inhibitors. The signal was stable for more than 24 h at room temperature using the Eu(3+) chelates, suggesting no dissociation of the lanthanide ion. The 384-well assay was readily automated and was able to identify more than 99.5% of known positive controls in the validation studies successfully. Screening identified both a series of known potent inhibitors and several structural classes of hits that readily deconvoluted to yield single compound inhibitors with the desired functional activity in secondary biological assays. The equivalence of the data in 384- and 1536-well formats indicates that routine implementation of 1536-well chelate-based energy transfer screening appears to be primarily limited by liquid handling rather than detection issues.     

Quantification of folate in fruits and vegetables: A fluorescence-based homogeneous assay

A high-throughput, homogeneous, fluorescence polarization, and fluorescence intensity assay has been developed for the measurement of folate in fruits and vegetables. This assay is based on the competitive displacement of the fluorescent folate ligands Alexa Fluor (Alexa) 594-folate and Alexa 660-folate from bovine milk folate-binding protein by folates in fruit and vegetable extracts. These fluorescent ligands are employed because their excitation and emission maxima are in regions of the spectrum with minimal autofluorescence in many extracts. Folate-binding protein and Alexa-folate were typically used at concentrations of 0.5 μg/ml and 5 nM, respectively, in 20-μl volumes in 384-well microplates. The assay is complete within 100 min. The folate estimate is unaffected by the heterogeneity of polyglutamyl residues that complicates the liquid chromatography-mass spectrometry (LC-MS)-based methods of quantification. In this assay, folic acid had an apparent affinity 2.5-fold greater than 5-methyltetrahydrofolate (5MTHF); therefore, it cannot be used to quantify folate when both natural and synthetic folate are present. 5MTHF-equivalent values were measured in broccoli (240 μg/100 g), strawberry (113 μg/100 g), white grape (32 μg/100 g), orange (44 μg/100 g), tomato (12 μg/100 g), raspberry (31 μg/100 g), banana (29 μg/g), and kiwifruit (36 μg/100 g). These data are similar to published values. However, the assay will not detect 5-formyltetrahydrofolate which is a significant constituent of the total folate in lettuce, spinach, carrot, and peppers.     

A visible wavelength spectrophotometric assay suitable for high-throughput screening of 3-hydroxy-3-methylglutaryl-CoA synthase

3-Hydroxy-3-methylglutaryl-CoA (HMG-CoA) synthase catalyzes the first physiologically irreversible step in biosynthesis of isoprenoids and sterols from acetyl-CoA. Inhibition of enzyme activity by β-lactone-containing natural products correlates with substantial diminution of sterol synthesis, identifying HMG-CoA synthase as a potential drug target and suggesting that identification of effective inhibitors would be valuable. A visible wavelength spectrophotometric assay for HMG-CoA synthase has been developed. The assay uses dithiobisnitrobenzoic acid (DTNB) to detect coenzyme A (CoASH) release on acetylation of enzyme by the substrate acetyl-CoA, which precedes condensation with acetoacetyl-CoA to form the HMG-CoA product. The assay method takes advantage of the stability of recombinant enzyme in the absence of a reducing agent. It can be scaled down to a 60 μl volume to allow the use of 384-well microplates, facilitating high-throughput screening of compound libraries. Enzyme activity measured in the microplate assay is comparable to values measured by using conventional scale spectrophotometric assays with the DTNB method (412 nm) for CoASH production or by monitoring the use of a second substrate, acetoacetyl-CoA (300 nm). The high-throughput assay method has been successfully used to screen a library of more than 100,000 drug-like compounds and has identified both reversible and irreversible inhibitors of the human enzyme.     

A novel transfection method for eukaryotic cells using polyethylenimine coated albumin microbubbles

Albumin microbubbles have been intensively studied for their application in gene delivery. However, with negative surface potential, albumin microbubbles hardly bind plasmid DNA, which might contribute to their low transgene efficiency. In this study, we developed polyethylenimine (PEI) coated albumin microbubbles (PAMB) which were prepared by sonicating the mixture of human albumin, PEI, polyethylene glycol and glucose. CHO cells, COS cells and 293T cells were transfected with PEI, PEI + albumin, PAMB and Lipofectamine 2000, respectively. Our results showed that the surface potential was elevated and PAMB could bind plasmid DNA. The transgene efficiency of PAMB was higher than PEI and PEI + albumin (P < 0.05), and PAMB performed the same transgene effect as Lipofectamine 2000 did but with lower cytotoxicity than Lipofectamine 2000. Albumin microbubbles modified by PEI has high transgene efficiency and low cytotoxicity even without ultrasound medication, making it a useful non-virus gene delivery method in vitro.     

AlphaLISA-based high-throughput screening assay to measure levels of soluble amyloid precursor protein α

Activation of nonamyloidogenic processing of amyloid precursor protein (APP) has been hypothesized to be a viable approach for Alzheimer’s disease drug discovery. However, until recently, the lack of HTS-compatible assay technologies precluded large scale screening efforts to discover molecules that potentiate nonamyloidogenic pathways. We have developed an HTS-compatible assay based on AlphaLISA technology that quantitatively detects soluble APPα (sAPPα), a marker of nonamyloidogenic processing of APP, released from live cells in low volume, 384-well plates. The assay exhibited good QC parameters (Z′ > 0.5, S/B > 2). A pilot screen of 801 compounds yielded a novel chemotype that increased the release of sAPPα 2-fold at 5 μM. These results suggest that the AlphaLISA-based HTS assay is robust and sensitive and can be used to screen large compound collections to discover molecules that potentiate the release of sAPPα. Additionally, we demonstrated that increase of APP processing by nonamyloidogenic pathways will result in decrease of release of amyloidogenic Aβ40 fragments.     

A high density assay format for the detection of novel cytotoxic agents in large chemical libraries

In response to the need for inexpensive high throughput assays for anti-cancer drug screening, a 1536-well microtiter plate based assay utilizing the Alamar Blue fluorescent dye as a measure of cellular growth was validated in 10 μL assay volume. Its robustness was assessed in a screen against a library of 2000 known bioactives; with an overall Z′ value of 0.89 for assay robustness, several known cytotoxic agents were identified including and not limited to anthracyclines, cardiac glycosides, gamboges, and quinones. To further test the sensitivity of the assay, IC₅₀ determinations were performed in both 384-well and 1536-well formats and the obtained results show a very good correlation between the two density formats. These findings demonstrate that this newly developed assay is simple to set up, robust, highly sensitive and inexpensive. It could potentially provide a rapid way to screen established and primary tumor cell lines against large chemical libraries.     

Real-time immuno-polymerase chain reaction in a 384-well format: Detection of vascular endothelial growth factor and epidermal growth factor-like domain 7

Immuno-polymerase chain reaction (immuno-PCR) combines the specificity of antibodies with the amplification power of PCR to detect low levels of proteins. Here, we describe the development of a 384-well immuno-PCR method that uses streptavidin coated on a PCR plate to capture complexes of biotinylated capture antibody, antigen, and DNA-labeled detection antibody. Unbound molecules are removed by a wash step using a standard plate washer. Antibody–DNA molecules in bound complexes are then detected directly on the plate using real-time PCR. Circulating human vascular endothelial growth factor concentrations measured by this method correlated with measurements obtained from enzyme-linked immunosorbent assay (ELISA). Using this method, we developed an assay for human epidermal growth factor-like domain 7 (EGFL7), an extracellular matrix-bound angiogenic factor. EGFL7 is expressed at a higher level in certain cancers, although endogenous EGFL7 concentrations have not been reported. Our 384-well EGFL7 immuno-PCR assay can detect 0.51 pM EGFL7 in plasma, approximately 16-fold more sensitive than the ELISA, utilizing the same antibodies. This assay detected EGFL7 in lysates of non-small-cell lung cancer and hepatocellular carcinoma cell lines and also hepatocellular carcinoma, breast cancer, and ovarian cancer tissues. This 384-well immuno-PCR method can be used to develop high-throughput biomarker assays.     

Digital Imaging as a Detection Method for a Fluorescent Protease Assay in 96-Well and Miniaturized Assay Plate Formats

The demand to increase throughput in HTS programs, without a concomitant addition to costs, has grown significantly during the past few years. One approach to handle this demand is assay miniaturization, which can provide greater throughput, as well as significant cost savings through reduced reagent costs. Currently, one of the major challenges facing assay miniaturization is the ability to detect the assay signal accurately and rapidly in miniaturized formats. Digital imaging is a detection method that can measure fluorescent or luminescent signals in these miniaturized formats. In this study, an imaging system capable of detecting the signal from a fluorescent protease assay in multiple plate formats was used to evaluate this detection method in an HTS environment. A direct comparison was made between the results obtained from the imaging system and a fluorescent plate reader by screening 8,800 compounds in a 96-well plate format. The imaging system generated similar changes in relative signal for each well in the screen, identified the same active compounds, and yielded similar IC(50) values as compared to the plate reader. When a standard protease inhibitor was evaluated in 96-, 384-, 864-, and 1536-well plates using imaging detection, similar IC(50) values were obtained. Furthermore, similar dose-response curves were generated for the compound in 96- and 384-well assay plates read in a plate reader. These results provide support for digital imaging as an accurate and rapid detection method for high-density microtiter plates.     

Activation of transgene expression in skeletal muscle by focused ultrasound

To correlate thermal dose from focused ultrasound (FUS) with gene expression and tissue injury, a temperature plateau strategy was employed. Plasmids encoding luciferase gene under the control of hsp70B promoter were transfected into the right gastrocnemius muscle in a rat via electroporation. One day after transfection, hind limbs were treated with 3.3-MHz focused ultrasound, using one of four different temperature plateaus with spatial-peak time-average focal temperatures (T_SPTA) of 46 °C, 48 °C, 51 °C and 62 °C. The treatment duration at the plateau temperature was varied from 0 to 30 s. Gene expression was analyzed in vivo one day following FUS treatment, and H&E staining was employed to assess tissue injury. Gene activation and tissue damage correlated closely with thermal dose. The highest level of gene activation was induced by FUS at T_SPTA = 51 °C for 20 s, which was found to be statistically equivalent to that produced by water-bath hyperthermia.     

A high density assay format for the detection of novel cytotoxic agents in large chemical libraries

In response to the need for inexpensive high throughput assays for anti-cancer drug screening, a 1536-well microtiter plate based assay utilizing the Alamar Blue fluorescent dye as a measure of cellular growth was validated in 10 microL assay volume. Its robustness was assessed in a screen against a library of 2000 known bioactives; with an overall Z' value of 0.89 for assay robustness, several known cytotoxic agents were identified including and not limited to anthracyclines, cardiac glycosides, gamboges, and quinones. To further test the sensitivity of the assay, IC50 determinations were performed in both 384-well and 1536-well formats and the obtained results show a very good correlation between the two density formats. These findings demonstrate that this newly developed assay is simple to set up, robust, highly sensitive and inexpensive. It could potentially provide a rapid way to screen established and primary tumor cell lines against large chemical libraries.