Catherine M. Fuller scite author profile

We have isolated and cloned a novel epithelial Cl ؊ channel protein from a bovine tracheal cDNA expression library using an antibody probe. The antibody (␣p38) was raised against a 38-kDa component of a homopolymeric protein that behaves as a Ca 2؉ /calmodulin kinase II-, DIDS-, and dithiothreitol (DTT)-sensitive, anion-selective channel when incorporated into planar lipid bilayers. The full-length cDNA is 3001 base pairs long and codes for a 903-amino acid protein. The clone does not show any significant homology to any other previously reported Cl ؊ channel sequence. Northern analysis of bovine tracheal mRNA with a cDNA probe corresponding to the cloned sequence revealed a band at 3.1 kilobases, suggesting that close to the full-length sequence has been cloned. The full-length open reading frame (2712 base pairs) has been expressed in Xenopus oocytes and in mammalian COS-7 cells. In oocytes, expression of the clone was associated with the appearance of a novel DIDS-, and DTT-sensitive, anion-selective conductance that was outwardly rectified and exhibited a reversal potential close to 0 mV. Whole-cell patch clamp studies in COS-7 cells transfected with the clone identified an ionomycin-, and DTT-sensitive chloride conductance that was not apparent in mock-transfected or control cells. In vitro translation studies have shown that the primary transcript codes for a protein migrating at 140 kDa under reduced conditions, significantly larger than the polypeptide recognized by ␣p38. We therefore suggest that either the 140-kDa translated product is a prepro form of the 38-kDa subunit of the previously identified bovine tracheal anion channel and that the primary transcript is post-translationally cleaved to yield the final product, or that the cloned channel and the previously identified bovine tracheal anion channel protein share an epitope that is recognized by the ␣p38 antibody.

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Molecular and Functional Characterization of a Calcium-sensitive Chloride Channel from Mouse Lung

Gandhi

Elble

Gruber

et al. 1998

Journal of Biological Chemistry

133

182

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A protein (mCLCA1) has been cloned from a mouse lung cDNA library that bears strong sequence homology with the recently described bovine tracheal, Ca 2؉ -sensitive chloride channel protein (bCLCA1), bovine lung endothelial cell adhesion molecule-1 (Lu-ECAM-1), and the human intestinal Ca 2؉ -sensitive chloride channel protein (hCLCA1). In vitro, its 3.1-kilobase message translates into a 100-kDa protein that can be glycosylated

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Molecular cloning and transmembrane structure of hCLCA2 from human lung, trachea, and mammary gland

Gruber

Schreur

et al. 1999

American Journal of Physiology-Cell Physiology

142

138

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The CLCA family of Ca2+-activated Cl− channels has recently been discovered, with an increasing number of closely related members isolated from different species. Here we report the cloning of the second human homolog, hCLCA2, from a human lung cDNA library. Northern blot and RT-PCR analyses revealed additional expression in trachea and mammary gland. A primary translation product of 120 kDa was cleaved into two cell surface-associated glycoproteins of 86 and 34 kDa in transfected HEK-293 cells. hCLCA2 is the first CLCA homolog for which the transmembrane structure has been systematically studied. Glycosylation site scanning and protease protection assays revealed five transmembrane domains with a large, cysteine-rich, amino-terminal extracellular domain. Whole cell patch-clamp recordings of hCLCA2-transfected HEK-293 cells detected a slightly outwardly rectifying anion conductance that was increased in the presence of the Ca2+ ionophore ionomycin and inhibited by DIDS, dithiothreitol, niflumic acid, and tamoxifen. Expression in human trachea and lung suggests that hCLCA2 may play a role in the complex pathogenesis of cystic fibrosis.

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Cftr!

Fuller

Benos

1992

American Journal of Physiology-Cell Physiology

214

134

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Cystic fibrosis (CF) is a fatal genetic disease primarily affecting Caucasians, although cases have been reported from other ethnic groups. CF has a complex etiology, but it is chiefly a disease of electrolyte transport and is characterized by defects in fluid secretion by several epithelia, including the sweat duct, exocrine pancreas, and the pulmonary airways. The link between CF and a defect in cAMP-mediated Cl- transport in secretory epithelia was established in the early 1980s. Since then, numerous electrophysiological studies have focused on the characterization and regulation of individual Cl- channels underlying the macroscopic Cl- currents of secretory epithelia in the airways, sweat ducts, and gut. In this review the results of these studies in the light of current knowledge of the function of the CF gene product, the CF transmembrane conductance regulator (CFTR) protein, will be analyzed. The CFTR protein is a member of a family of ATP-binding proteins that act as unidirectional solute pumps. These proteins are membrane spanning, are found in both prokaryotic and eukaryotic cells, and have two ATP-binding domains. The family includes the p-glycoproteins that are involved with the expression of multidrug resistance in certain tumor cells. The majority of CF chromosomes (70%) have a single codon deletion that translates to a missing phenylalanine residue at position 508 (delta F508) of the protein. Unique for this family of proteins, the CFTR protein possesses an additional highly charged domain (the R domain) containing several consensus polypeptide sequences for kinase phosphorylation. Although CFTR bears structural resemblance to this family of ATP-dependent pumps, overexpression of the protein in a variety of different cell types is associated with the appearence of a cAMP-sensitive Cl- channel. We critically examine current information concerning the structure-function relationships of the CFTR protein obtained from both electrophysiological and biochemical approaches. We also summarize recent evidence suggesting that the CFTR protein may act as a pump and a channel, a hypothesis in keeping with the multifaceted nature of the disease.

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