Paul Negulescu

Correction of the F508del-CFTR protein processing defect in vitro by the investigational drug VX-809

Cystic fibrosis (CF) is caused by mutations in the CF transmembrane conductance regulator (CFTR) gene that impair the function of CFTR, an epithelial chloride channel required for proper function of the lung, pancreas, and other organs. Most patients with CF carry the F508del CFTR mutation, which causes defective CFTR protein folding and processing in the endoplasmic reticulum, resulting in minimal amounts of CFTR at the cell surface. One strategy to treat these patients is to correct the processing of F508del-CFTR with small molecules. Here we describe the in vitro pharmacology of VX-809, a CFTR corrector that was advanced into clinical development for the treatment of CF. In cultured human bronchial epithelial cells isolated from patients with CF homozygous for F508del, VX-809 improved F508del-CFTR processing in the endoplasmic reticulum and enhanced chloride secretion to approximately 14% of non-CF human bronchial epithelial cells (EC50, 81 ± 19 nM), a level associated with mild CF in patients with less disruptive CFTR mutations. F508del-CFTR corrected by VX-809 exhibited biochemical and functional characteristics similar to normal CFTR, including biochemical susceptibility to proteolysis, residence time in the plasma membrane, and single-channel open probability. VX-809 was more efficacious and selective for CFTR than previously reported CFTR correctors. VX-809 represents a class of CFTR corrector that specifically addresses the underlying processing defect in F508del-CFTR.

Cell-based assays and instrumentation for screening ion-channel targets

Ion channels are an important class of drug targets. They comprise the molecular basis for essential physiological functions including fluid secretion, electrolyte balance, bioenergetics and membrane excitability. High-throughput screening for ion-channel function requires sensitive, simple assays and instrumentation that will report ion channel activity in living cells. This article will review relevant assay technologies for ion channels and describe voltage-sensitive probes and instruments based on fluorescence resonance energy transfer (FRET) that enable ion-channel drug discovery.

Miniaturized FRET assays and microfluidics: key components for ultra-high-throughput screening.

Assay miniaturization applicable across a wide range of target classes, along with automation and process integration, are well-recognized goals for ultra-high-throughput screening on an industrial scale. This report summarizes the implementation of fluorescence resonance energy transfer (FRET)-based biochemical and cell-based assays in 3456-well NanoWelltrade mark assay plates using key components of Auroras ultra-high-throughput screening system.

Characterization of voltage-gated sodium-channel blockers by electrical stimulation and fluorescence detection of membrane potential

Voltage-gated ion channels regulate many physiological functions and are targets for a number of drugs. Patch-clamp electrophysiology is the standard method for measuring channel activity because it fulfils the requirements for voltage control, repetitive stimulation and high temporal resolution, but it is laborious and costly. Here we report an electro-optical technology and automated instrument, called the electrical stimulation voltage ion probe reader (E-VIPR), that measures the activity of voltage-gated ion channels using extracellular electrical field stimulation and voltage-sensitive fluorescent probes. We demonstrate that E-VIPR can sensitively detect drug potency and mechanism of block on the neuronal human type III voltage-gated sodium channel expressed in human embryonic kidney cells. Results are compared with voltage-clamp and show that E-VIPR provides sensitive and information-rich compound blocking activity. Furthermore, we screened ∼400 drugs and observed sodium channel–blocking activity for ∼25% of them, including the antidepressants sertraline (Zoloft) and paroxetine (Paxil).

A genome-wide functional assay of signal transduction in living mammalian cells.

We describe a genome-wide functional assay for rapid isolation of cell clones and genetic elements responsive to specific stimuli. A promoterless β-lactamase reporter gene was transfected into a human T-cell line to generate a living library of reporter-tagged clones. When loaded with a cell-permeable fluorogenic substrate, the cell library simultaneously reports the expression of a large number of endogenous genes. Flow cytometry was used to recover individual clones whose reporter-tagged genes were either induced or repressed following T-cell activation. Responsive clones were expanded and analyzed pharmacologically to identify patterns of regulation associated with specific genes. Although demonstrated using T cells, the genomic assay could be applied to map downstream transcriptional consequences for any propagating cell line in response to any stimulus of interest.

Intracellular detection assays for high-throughput screening

New optical assay methods promise to accelerate the use of living cells in screens for drug discovery. Most of these methods employ either fluorescent or luminescent read-outs and allow cell-based assays for most targets, including receptors, ion channels and intracellular enzymes. Furthermore, genetically encoded probes offer the possibility of custom-engineered biosensors for intracellular biochemistry, specifically localized targets, and protein-protein interactions.

Cellular biosensors for drug discovery

Recent advances in cell biology, fluorescent probe chemistry, miniaturization and automation have allowed the use of mammalian cells in a variety of medical and industrial applications. Here we describe the generation of cell-based biosensors, engineered to optically report specific biological activity. Cellular biosensors are comprised of living cells and can be used in various applications, including screening chemical libraries for drug discovery and environmental sensing. Panels of biosensors may also be useful for elucidating the function of novel genes. Here we describe two examples of the construction and use of engineered cell lines as biosensors for drug discovery.

Identification of signal transduction pathways used by orphan g protein-coupled receptors.

The superfamily of GPCRs have diverse biological roles, transducing signals from a range of stimuli, from photon recognition by opsins to neurotransmitter regulation of neuronal function. Of the many identified genes encoding GPCRs, >130 are orphan receptors ( i.e., their endogenous ligands are unknown), and this subset represents putative novel therapeutic targets for pharmaceutical intervention in a variety of diseases. As an initial step toward drug discovery, determining a biological function for these newly identified receptors is of vital importance, and thus identification of a natural ligand(s) is a primary aim. There are several established methods for doing this, but many have drawbacks and usually require some in-depth knowledge about how the receptor functions. The technique described here utilizes a transcription-based reporter assay in live cells. This allows the determination of the signal transduction pathway any given oGPCR uses, without any prior knowledge of the endogenous ligand. This can therefore reduce the redundancy of effort involved in screening ligands at a given receptor in multiple formats (i.e., Galpha(s), Galpha(i/0), and Galpha(q) assays), as well as ensuring that the receptor targeted is capable of signaling if appropriately activated. Such knowledge is often laboriously obtained, and for almost all oGPCRs, this kind of information is not yet available. This technology can also be used to develop inverse agonist as well as agonist sensitive high throughput assays for oGPCRs. The veracity of this approach is demonstrated, using a number of known GPCRs. The likely signaling pathways of the GPR3, GPR12, GPR19, GPR21, and HG55 oGPCRs are shown, and a high throughput assay for GPR26 receptors developed. The methods outlined here for elucidation of the signal transduction pathways for oGPCRs and development of functional assays should speed up the process of identification of ligands for this potentially therapeutically useful group of receptors.

Detection of β-lactamase reporter gene expression by flow cytometry

Flow cytometry of gene expression in living cells requires accurate, sensitive, nontoxic fluorescent indicators capable of detecting transcription of specific genes. This is typically achieved by using genes that encode fluorescent proteins or enzymes coupled to promoters of interest. The most commonly used reporters are green fluorescent protein and β‐galactosidase (lacZ). In this study, we characterized the performance of a cell‐permeant, ratiometric, β‐lactamase substrate, coumarin cephalosporin fluorescein (CCF2/AM). We compared its characteristics with that of the β‐galactosidase/fluorescein di‐β‐D‐galactopyranoside reporter system.

A Fluorescent Reporter Assay for the Detection of Ligands Acting Through GI Protein-Coupled Receptors

Abstract Accompanying the advances in basic biology of G protein-coupled receptors (GPCRs) is the practical need among biopharmaceutical companies for sensitive assays to assess GPCR function, particularly formats that are compatible with high-throughput drug screening. Here we describe a novel cell-based assay format for the high-throughput detection of ligands for G, protein-coupled receptors. Two Gi-GPCRs, μ-opioid receptor (μ-OPR) and 5-hydroxytryptamine receptor la (5HTlaR) are employed as model receptor targets. The key feature of this assay system is the isolation of stable, clonal Chinese hamster ovary (CHO) cell lines that carry three separate expression plasmids: (1) a chimeric Gq/i5 protein (which re-directs a negative Gi-type signal to a positive Gq-type response), (2) a given Gi-GPCR, and (3) a β-lactamase (βla) reporter gene responsive to Gi-GPCR signaling. Cell-based assays built using this format show appropriate rank order of potency among a reference set of receptor agonist and antagonist compounds. Such assays are also robust, reliable, and can be used for industrial-scale applications such as high-throughput screening for drug leads.