A novel membrane potential-sensitive fluorescent dye improves cell-based assays for ion channels

The study of ion channel-mediated changes in membrane potential using the conventional bisoxonol fluorescent dye DiBAC(4)(3) has several limitations, including a slow onset of response and multistep preparation, that limit both the fidelity of the results and the throughput of membrane potential assays. Here, we report the characterization of the FLIPR Membrane Potential Assay Kit (FMP) in cells expressing voltage- and ligand-gated ion channels. The steady-state and kinetics fluorescence properties of FMP were compared with those of DiBAC(4)(3), using both FLIPR and whole-cell patch-clamp recording. Our experiments with the voltage-gated K(+) channel, hElk-1, revealed that FMP was 14-fold faster than DiBAC(4)(3) in response to depolarization. On addition of 60 mM KCl, the kinetics of fluorescence changes of FMP using FLIPR were identical to those observed in the electrophysiological studies using whole-cell current clamp. In addition, KCl concentration-dependent increases in FMP fluorescence correlated with the changes of membrane potential recorded in whole-cell patch clamp. In studies examining vanilloid receptor-1, a ligand-gated nonselective cation channel, FMP was superior to DiBAC(4)(3) with respect to both kinetics and amplitude of capsaicin-induced fluorescence changes. FMP has also been used to measure the activation of K(ATP) and hERG. Thus this novel membrane potential dye represents a powerful tool for developing high-throughput screening assays for ion channels.     

A novel cell array technique for high-throughput,cell-based analysis

Summary Microarray technology has burgeoned over the past few years from nucleic acid-based arrays to tissue microarrays (TMAs). This study aimed to develop a technique to incorporate cell lines into an array and to demonstrate the usefulness of this technique by performing immunohistochemistry for β-catenin. Cell suspensions were prepared from 23 tumor cell lines. These were fixed in formalin, suspended in agar, and embedded in paraffin to produce a cell block. A “tissue microarrayer” was used to remove triplicate, 0.6 mm-cores from each cell block and to transfer these into a recipient paraffin block at precise coordinates. Immunohistochemistry was used to identify cell lines positive for β-catenin. Cultured cells were successfully incorporated into the microarray, with preservation of cell architecture and even distribution of cells within each core. A total of 18 of 69 cores (26%) were lost in processing. A total of 16 of 23 cell lines were identified as positive for membrane and cytoplasmic β-catenin, and 6 of 23 were negative. Only one cell line was unscorable because of complete core loss. We have developed a “cell microarray” technique for analyzing antigen expression by immunohistochemistry in multiple cell lines in a single expriment. This novel application of microarrays permits high-throughput, cost-efficient analysis, with the potential to rapidly identify markers with potential diagnostic and therapeutic implications in human disease.     

A simple electronic volume cell sorter for clonogenicity assays

A single-parameter electronic volume flow cell sorter that can be easily and inexpensively constructed using existing technology is described. The instrument is designed for ease and flexibility of operation, including such features as a large open area for recovering sorted cells into a variety of dishes or vessels; a remote, electrically activated fluidics system; a mechanism for heating or cooling samples during sorting; a simple arrangement for monitoring and adjusting the sorting control parameters; and an interface to a standard IBM personal computer for data acquisition, analysis, and control of the sorting windows. Several researchers in our laboratory now routinely use this sorter for plating precise numbers of cells directly into culture dishes in an aseptic manner for clonogenicity assays. The instrument can sort cells at rates of up to approximately 2,000 per second with greater than 80% sorting efficiency and no cytotoxicity. An advantage of this system is that the sorting windows can be set to exclude acellular debris and include either the entire cell volume distribution or a subset thereof. Applications of the instrument are detailed, including 1) precise cell plating for low-dose survival studies, 2) separation of cells into age compartments, and 3) rapid inoculation of single cells into multiwell dishes for cloning studies. Advantages of this technology for cell survival studies are detailed, along with some limitations to its applicability.     

Biochemical and cell-based assays for characterization of BACE-1 inhibitors

The deposition of beta-amyloid peptides (A beta42 and A beta40) in neuritic plaques is one of the hallmarks of Alzheimer's disease (AD). A beta peptides are derived from sequential cleavage of amyloid precursor protein (APP) by beta- and gamma-secretases. BACE-1 has been shown to be the major beta-secretase and is a primary therapeutic target for AD. In this article, two novel assays for the characterization of BACE-1 inhibitors are reported. The first is a sensitive 96-well HPLC biochemical assay that uses a unique substrate containing an optimized peptide cleavage sequence, NFEV, spanning from the P2-P2' positions This substrate was processed by BACE-1 approximately 10 times more efficiently than was the widely used substrate containing the Swedish (NLDA) sequence. As a result, the concentration of the enzyme required for the assay can be as low as 100 pM, permitting the evaluation of inhibitors with subnanomolar potency. The assay has also been applied to related aspartyl proteases such as cathepsin D (Cat D) and BACE-2. The second assay is a homogeneous electrochemiluminescence assay for the evaluation of BACE-1 inhibition in cultured cells that assesses the level of secreted amyloid EV40_NF from HEK293T cells stably transfected with APP containing the novel NFEV sequence. To illustrate the use of these assays, the properties of a potent, cell-active BACE-1 inhibitor are described.     

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

We present for the first time a microfluidic cell culture array for long-term cellular monitoring. The 10 x 10 array could potentially assay 100 different cell-based experiments in parallel. The device was designed to integrate the processes used in typical cell culture experiments on a single self-contained microfluidic system. Major functions include repeated cell growth/passage cycles, reagent introduction, and real-time optical analysis. The single unit of the array consists of a circular microfluidic chamber, multiple narrow perfusion channels surrounding the main chamber, and four ports for fluidic access. Human carcinoma (HeLa) cells were cultured inside the device with continuous perfusion of medium at 37 degrees C. The observed doubling time was 1.4 +/- 0.1 days with a peak cell density of approximately 2.5*10(5) cells/cm(2). Cell assay was demonstrated by monitoring the fluorescence localization of calcein AM from 1 min to 10 days after reagent introduction. Confluent cell cultures were passaged within the microfluidic chambers using trypsin and successfully regrown, suggesting a stable culture environment suitable for continuous operation. The cell culture array could offer a platform for a wide range of assays with applications in drug screening, bioinformatics, and quantitative cell biology.     

A simple image analysis program for quantitative dot assays

Summary Dot assays are versatile, and are widely used for determining antigens and proteins. Because they require expensive equipment to be quantitative, often only qualitative dot results are reported. However, because the dot pattern is so regular, a simple image analysis program can determine mean dot grey levels, while handling irregular dot outlines, radial variations in colour within a dot, and varying or noisy sheet backgrounds. We describe a dot analysis program that runs on PCs under Windows, and permits quantitative dot assays to be run with inexpensive grayscale scanner input. The program is available from us as source and executable files. We present demonstration results for antigen and protein determinations.     

Quantitative, high-throughput cell-based assays for inhibitors of trkA receptor

Two quantitative, high-throughput cell-based assays for evaluating inhibitors of NGF-stimulated trkA phosphorylation in trkA-transfected NIH3T3 cells have been established. Both assays involve capture of the trkA receptor from cell lysates in microtiter plates coated with an anti-trk antibody. The amount of trkA phosphorylation is then measured using either an anti-phosphotyrosine antibody with a colorimetric readout or a lanthanide (europium)-labeled anti-phosphotyrosine antibody with a fluorometric detection. The two assay formats exhibited at least a fivefold increase in phosphorylated trkA signal in trkA-transfected cells compared to vector control. Inhibition plots generated for trkA kinase inhibitors using the two detection systems yielded comparable IC(50) values. Overall, the two assays represent a marked improvement over the standard gel-based/western blot method in terms of throughput, quantitation, and amenability to automation.     

A model for simple cells as optimal edge detectors

Simple cells have often been characterised as edge detectors. This paper proposes a specific neural wiring for simple cells that operate as optimal edge detectors. The proposed simple cell is also selective for the edge contrast. Responses of this model simple cell to edges, bars, sinusoids, and flashed lights are simulated and are similar to real nondirectional simple cell responses.     

A simple technique for endotracheal intubation in rabbits

A technique for endotracheal intubation in rabbits, which eliminates the need for tracheostomies, special devices, laryngoscopes and guide wires, is described. Inhalation anaesthesia with controlled ventilation for major surgical procedures in rabbits is easier to perform than previous reports in the literature suggest.     

Microwell bioreactor system for cell-based high throughput proliferation and cytotoxicity assays

Cell-based high throughput proliferation and cytotoxicity assays are increasingly used in drug screening and bioprocess development. However, online monitoring of cell proliferation, pH, and dissolved oxygen (DO) has been a challenge in 3D cell-based assays. In this work, a 40-microwell bioreactor (40-MBR) system was developed from a 384-well plate for real-time, noninvasive monitoring of pH, DO, and cell proliferation in 3D microenvironments. Chinese hamster ovary (CHO) and MCF-07 breast cancer cells cultured in 40-MBR confirmed that the 40-MBR was capable of simultaneously monitoring DO and cell proliferation based on culture fluorescence and pH by measuring the absorbance of phenol red. Cytotoxicity studies of sodium butyrate on CHO cells demonstrated that 40-MBR with dynamic background fluorescence correction gave more reliable and highly reproducible growth kinetic data compared to conventional multiwells with static background correction. Furthermore, the dosage effects of two new anticancer drug candidates, 5,7-dihydroxy-2-(4-hydroxyphenyl)-8-[(E)-2-phenylethenyl]-3,4-dihydro-2H-1-benzopyran-4-one (DH-8P-DB) and 5,7-dihydroxy-2-(4-hydroxyphenyl)-6-[(E)-2-phenylethenyl]-3,4-dihydro-2H-1-benzopyran-4-one (DH-6P-DB), on HT-29 colon cancer cells were assessed using the 40-MBR, and the results indicated that DH-6P-DB would be a more potent drug in treating colon cancer than DH-8P-DB. These studies demonstrated that 40-MBR could serve as a high throughput platform for screening potential cancer drugs in early-stage drug discovery.     

A simple, versatile and sensitive cell-based assay for prions from various species

Detection and quantification of prion infectivity is a crucial step for various fundamental and applied aspects of prion research. Identification of cell lines highly sensitive to prion infection led to the development of cell-based titration procedures aiming at replacing animal bioassays, usually performed in mice or hamsters. However, most of these cell lines are only permissive to mouse-adapted prions strains and do not allow titration of prions from other species. In this study, we show that epithelial RK13, a cell line permissive to mouse and bank vole prion strains and to natural prion agents from sheep and cervids, enables a robust and sensitive detection of mouse and ovine-derived prions. Importantly, the cell culture work is strongly reduced as the RK13 cell assay procedure designed here does not require subcultivation of the inoculated cultures. We also show that prions effectively bind to culture plastic vessel and are quantitatively detected by the cell assay. The possibility to easily quantify a wider range of prions, including rodent experimental strains but also natural agents from sheep and cervids, should prompt the spread of cell assays for routine prion titration and lead to valuable information in fundamental and applied studies.