Epithelial sodium channel silencing as a strategy to correct the airway surface fluid deficit in cystic fibrosis.

In the respiratory system, Na(+) absorption and Cl(-) secretion are balanced to maintain an appropriate airway surface fluid (ASF) volume and ensure efficient mucociliary clearance. In cystic fibrosis (CF), this equilibrium is disrupted by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene, resulting in the absence of functional CFTR-dependent Cl(-) secretion. The consequences of defective Cl(-) transport are worsened by the persistence of Na(+) absorption, which contributes to airway surface dehydration.

Modulation of cystic fibrosis transmembrane conductance regulator (CFTR) activity and genistein binding by cytosolic pH.

Potentiators are molecules that increase the activity of the cystic fibrosis transmembrane conductance regulator (CFTR). Some potentiators can also inhibit CFTR at higher concentrations. The activating binding site is thought to be located at the interface of the dimer formed by the two nucleotide-binding domains.

Analysis of ion transport in the airway epithelium using RNA interference.

Knowledge of the physiology of airway epithelium had been limited by the lack of potent and selective inhibitors of the ion channels, transporters and regulators involved in transepithelial electrolyte and fluid transport. The use of siRNA technology to downregulate the expression of a given gene represents a useful method for studying the function of proteins in both native cells and tissues, enabling a more precise assessment of the contribution of single proteins to the general transport process in the airway epithelium and an evaluation of the contribution of these proteins in various respiratory conditions. This review focuses on recent research involving siRNA-based silencing of proteins implicated in ion transport through the airway epithelium, illustrating how this technology has increased our understanding of the function and regulation of the transport pathway, and has helped to identify new targets for drugs and to uncover the function of newly identified proteins.

Epithelial sodium channel inhibition in primary human bronchial epithelia by transfected siRNA.

Na(+) absorption and Cl(-) secretion are in equilibrium to maintain an appropriate airway surface fluid volume and ensure appropriate mucociliary clearance. In cystic fibrosis, this equilibrium is disrupted by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene resulting in the absence of functional CFTR protein, which in turn results in deficient cAMP-dependent Cl(-) secretion and predominant Na(+) absorption. It has been suggested that down-regulation of the epithelial sodium channel, ENaC, might help to restore airway hydration and reverse the airway phenotype in patients with cystic fibrosis.

Block of CFTR-dependent chloride currents by inhibitors of multidrug resistance-associated proteins.

The cystic fibrosis transmembrane conductance regulator (CFTR) is a membrane protein that belongs to the same family as multidrug resistance-associated proteins whose main function is to expel xenobiotics and physiological organic anions from the cell interior. Despite the overall structural similarity with these membrane proteins, CFTR is not an active transporter but is instead a Cl- channel. We have tested the ability of known inhibitors of multidrug resistance-associated proteins to affect CFTR Cl- currents.

Growth arrest-inducing genes are activated in Dbl-transformed mouse fibroblasts.

The Dbl oncogene is a guanine nucleotide exchange factor for Rho GTPases and its activity has been linked to the regulation of gene transcription. Dbl oncogene expression in NIH3T3 cells leads to changes in morphological and proliferative properties of these cells, inducing a highly transformed phenotype. To gain insights into Dbl oncogene-induced transformation we compared gene expression profiles between Dbl oncogene-transformed and parental NIH3T3 cells by cDNA microarray.

Detection of electrophysiological indicators of neurotoxicity in human and rat brain slices by a three-dimensional microelectrode array.

Electrophysiological techniques for the assessment of in vitro neurotoxicology have several advantages over other currently-used methods (for example, morphological techniques), including the ability to detect damage at a very early stage. Novel recording techniques based on microelectrode arrays are available, and could improve recording power. In this study, we investigated how a three-dimensional microelectrode array detects the electrophysiological endpoints of neurotoxicity.

Changes in extracellular action potential detect kainic acid and trimethyltin toxicity in hippocampal slice preparations earlier than do MAP2 density measurements.

In vitro electrophysiological techniques for the assessment of neurotoxicity could have several advantages over other methods in current use, including the ability to detect damage at a very early stage, and could further assist in replacing animal experimentation in vivo. We investigated how an electrophysiological parameter, the extracellularly-recorded compound action potential ("population spike", PS) could be used as a marker of in vitro neurotoxicity in the case of two well-known toxic compounds, kainic acid (KA) and trimethyltin (TMT). We compared the use of this electrophysiological endpoint with changes in immunoreactivity for microtubule-associated protein 2 (MAP2), a standard histological test for neurotoxicity.