Danuta H. Malinowska

Sites of Protein Kinase A Activation of the Human ClC-2 Cl– Channel

Human ClC-2 Cl– (hClC-2) channels are activated by protein kinase A (PKA) and low extracellular pHo. Both of these effects are prevented by the PKA inhibitor, myristoylated PKI. The aims of the present study were to identify the PKA phosphorylation site(s) important for PKA activation of hClC-2 at neutral and low pHo and to examine the relationship between PKA and low pHo activation. Recombinant hClC-2 with point mutations of consensus phosphorylation sites was prepared and stably expressed in HEK-293 cells. The responses to forskolin plus isobutylmethylxanthine at neutral and acidic pHo were studied by whole cell patch clamp in the presence and absence of phosphatase inhibitors. The double phosphorylation site (RRAT655(A) plus RGET691(A)) mutant hClC-2 lost PKA activation and low pHo activation. Either RRAT or RGET was sufficient for PKA activation of hClC-2 at pHo 7.4, as long as phosphatase inhibitors (cyclosporin A or endothal) were present. At pHo 6 only RGET was needed for PKA activation of hClC-2. Low pHo activation of hClC-2 Cl– channel activity was PKA-dependent, retained in RGET(A) mutant hClC-2, but lost in RRAT(A) mutant hClC-2. RRAT655(D) mutant hClC-2 was constitutively active and was further activated by PKA at pHo 7.4 and 6.0, consistent with the above findings. These results show that activation of hClC-2 is differentially regulated by PKA at two sites, RRAT655 and RGET691. Either RRAT655 or RGET691 was sufficient for activation at pHo 7.4. RGET, but not RRAT, was sufficient for activation at pHo 6.0. However, in the RGET691(D) mutant, there was PKA activation at pHo 6.0.

Identification of the pH sensor and activation by chemical modification of the ClC-2G Cl- channel.

Rabbit and human ClC-2G Cl- channels are voltage sensitive and activated by protein kinase A and low extracellular pH. The objective of the present study was to investigate the mechanism involved in acid activation of the ClC-2G Cl- channel and to determine which amino acid residues play a role in this acid activation. Channel open probability ( P o) at ±80 mV holding potentials increased fourfold in a concentration-dependent manner with extracellular H+concentration (that is, extracellular pH, pH trans ), with an apparent acidic dissociation constant of pH 4.95 ± 0.27. 1-Ethyl-3(3-dimethylaminopropyl)carbodiimide-catalyzed amidation of the channel with glycine methyl ester increased P o threefold at pH trans 7.4, at which the channel normally exhibits low P o. With extracellular pH reduction (protonation) or amidation, increased P o was due to a significant increase in open time constants and a significant decrease in closed time constants of the channel gating, and this effect was insensitive to applied voltage. With the use of site-directed mutagenesis, the extracellular region EELE (amino acids 416-419) was identified as the pH sensor and amino acid Glu-419 was found to play the key or predominant role in activation of the ClC-2G Cl- channel by extracellular acid.

Gastric H+ secretion: histamine (cAMP-mediated) activation of protein phosphorylation

Activation of H+ secretion by the gastric parietal cell involves major changes in morphology, metabolic activity and ion pathways of the secretory membrane. These changes are elicited by histamine binding to the H2 receptor, raising cAMP levels and presumably activating cAMP-dependent protein kinase. Concomitantly, the intracellular free Ca2+ concentration, [Ca2+]i, increases. Studies were performed to determine whether cAMP-mediated protein phosphorylation accompanies histamine activation of H+ secretion and to catalogue the major protein species serving as substrates for cAMP-dependent protein kinase in the parietal cell. 80% pure rabbit parietal cells, prepared by Nycodenz bouyant density centrifugation, were used. To investigate only cAMP-mediated effects, histamine-dependent changes in [Ca2+]i in these cells were abolished by depleting intracellular Ca2+ stores and performing experiments under Ca2+-free conditions. Acid secretion and steady-state levels of protein phosphorylation were then measured in unstimulated (cimetidine-treated) and histamine-stimulated cells. In intact parietal cells, concommitant with histamine stimulation of H+ secretion, increases in the level of protein phosphorylation were observed. Significantly changing phosphoproteins found in supernatant fractions showed apparent subunit sizes of approx. 148, 130, 47 and 43 kDa, and in microsomal fractions included those at approx. 130, 51 and 47 kDa. In parietal cell homogenates, using [gamma-32P]ATP, cAMP elicited significant phosphorylation of eight supernatant proteins and twelve microsomal proteins, which included the histamine-dependent phosphoproteins found in the intact parietal cell, except for the 51 kDa microsomal protein. As a working hypothesis, these proteins are involved in stimulus-secretion coupling in the parietal cell.

Melittin inhibition of the gastric (H+ + K+) ATPase and photoaffinity labeling with [125I]azidosalicylyl melittin.

Melittin is a 26-amino acid amphipathic polypeptide toxin from bee venom which forms anion-selective ion channels in bilayers and biological membranes under the influence of membrane potential. Melittin has been shown to interact with a number of membrane proteins. We found that melittin inhibited K+-stimulated ATP hydrolysis by the (H+ + K+) ATPase in parietal cell apical membrane vesicles derived from histamine-stimulated rabbit gastric mucosa with a KIapp of 0.5 micron. Melittin also inhibited K+-stimulated p-nitrophenyl hydrolysis activity which is associated with the gastric (H+ + K+) ATPase in a dose-dependent manner with a KIapp of 0.95 micron. ATP-driven, K+-dependent H+ transport was inhibited over this same concentration range, even in the absence of a membrane potential. Melittin did not appear to increase the H+ leak from vesicle with preformed H+ gradients when the H+ pump was arrested by Mg2+ chelation, but all possible membrane perturbation effects were difficult to rule out. However, the data suggest that melittin exerts its inhibitory effect through interaction with the (H+ + K+) ATPase. In order to determine whether direct interactions between the (H+ + K+) ATPase and melittin occurred, a radioactive derivative of melittin, [125I]azidosalicylyl melittin, was prepared and photoreacted with sealed rabbit gastric membranes and highly purified hog gastric membrane containing the (H+ + K+) ATPase. In the purified hog preparation only a 95,000-Da band, the (H+ + K+) ATPase was labeled, while in the rabbit preparation a 95,000-Da band and one other membrane protein of 70,000 Da were labeled with this reagent. Label incorporation into the (H+ + K+) ATPase and the 70,000-Da band was greatly reduced by addition of excess unlabeled melittin, suggesting specificity of the interaction. Label incorporation occurred in the absence of ATP or added salts and was not reduced by SCH28080 (a K+ site inhibitor) suggesting that the melittin binding site was distinct from the luminal K+ site of action of SCH28080.

Contrasting effects of linaclotide and lubiprostone on restitution of epithelial cell barrier properties and cellular homeostasis after exposure to cell stressors.

BackgroundLinaclotide has been proposed as a treatment for the same gastrointestinal indications for which lubiprostone has been approved, chronic idiopathic constipation and irritable bowel syndrome with constipation. Stressors damage the epithelial cell barrier and cellular homeostasis leading to loss of these functions. Effects of active linaclotide on repair of barrier and cell function in pig jejunum after ischemia and in T84 cells after treatment with proinflammatory cytokines, interferon-γ and tumor necrosis factor-α were examined. Comparison with effects of lubiprostone, known to promote repair of barrier function was carried out.ResultsIn ischemia-damaged pig jejunum, using measurements of transepithelial resistance, 3H-mannitol fluxes, short-circuit current (Cl− secretion) and occludin localization, active linaclotide failed to effectively promote repair of the epithelial barrier or recovery of short-circuit current, whereas lubiprostone promoted barrier repair and increased short-circuit current. In control pig jejunum, 1 μM linaclotide and 1 μM lubiprostone both caused similar increases in short-circuit current (Cl− secretion). In T84 cells, using measurements of transepithelial resistance, fluxes of fluorescent macromolecules, occludin and mitochondrial membrane potential, active linaclotide was virtually ineffective against damage caused by interferon-γ and tumor necrosis factor-α, while lubiprostone protected or promoted repair of epithelial barrier and cell function. Barrier protection/repair by lubiprostone was inhibited by methadone, a ClC-2 inhibitor. Linaclotide, but not lubiprostone increased [cGMP]i as expected and [Ca2+]i and linaclotide depolarized while lubiprostone hyperpolarized the T84 plasma membrane potential suggesting that lubiprostone may lead to greater cellular stability compared to linaclotide. In T84 cells, as found with linaclotide but not with lubiprostone, transepithelial resistance was slightly but significantly decreased by guanylin, STa and 8-bromo cGMP and fluorescent dextran fluxes were increased by guanylin. However the physiological implications of these small but statistically significant changes remain unclear.ConclusionsConsidering the physiological importance of epithelial barrier function and cell integrity and the known impact of stressors, the finding that lubiprostone, but not active linaclotide, exhibits the additional distinct property of effective protection or repair of the epithelial barrier and cell function after stress suggests potential clinical importance for patients with impaired or compromised barrier function such as might occur in IBS.

Interaction of polypeptides with the gastric (H+ + K+)ATPase : melittin, synthetic analogs, and a potential intracellular regulatory protein

The 26 amino acid bee venom toxin, melittin, is an amphipathic helical polypeptide which inhibits the gastric (H+ + K+)ATPase. The site of interaction with the (H+ + K+)ATPase was shown to be the alpha subunit of the (H+ + K+)ATPase in studies using [125I]azidosalicylyl melittin, a radioactive photoaffinity analog of melittin. A synthetic amphipathic polypeptide (Trp3) containing tryptophan, which exhibits a structure similar to that of melittin, also inhibited the gastric (H+ + K+)ATPase, and prevented labeling by [125I]azidosalicylyl melittin. These findings suggested that melittin and the synthetic amphipathic helical polypeptide were bound to the same or overlapping site(s). In the present studies, novel tritiated photoaffinity analogs of Trp3 containing benzoylphenylalanine (in place of tryptophan) were used to photoaffinity label the (H+ + K+)ATPase. These studies help to establish that the (H+ + K+)ATPase contains a binding site for polypeptides which exhibit an amphipathic helical motif. The precise amino acid sequence of the polypeptide appears to be of secondary importance for interaction with the (H+ + K+)ATPase as long as the alpha helical motif is present. The benzoylphenylalanine containing polypeptides are ideal for mapping the binding site on the (H+ + K+)ATPase. Using an antibody which recognizes this amphipathic helical (‘melittin-like’) motif, we have demonstrated that the gastric parietal cell contains a 67 kDa ‘melittin-like’ protein. This protein was associated with the gastric parietal cell apical membrane in the stimulated (secreting) state, but not in the resting (non-secreting) state. The binding site for the gastric ‘melittin-like’ protein appears to overlap with the melittin binding site on the alpha subunit of the (H+ + K+)ATPase. The potential physiological significance of the melittin binding site and the overlapping binding site for this newly identified endogenous ‘melittin-like’ protein on the (H+ + K+)ATPase to regulated HCl secretion by the parietal cell is presently under investigation. Evidence is presented which demonstrates that melittin binds to other E1-E2 ion pumps, raising the possibility that there might exist similar intracellular proteins which interact with other ion pumps.

Activation Of Human Clc-2 Cl– Channels: Implications For Cystic Fibrosis

1. The ClC‐2 Cl– channels are present in the adult human lung epithelia and, therefore, are a potential target for therapy in cystic fibrosis.

Genetic Ablation of the ClC-2 Cl- Channel Disrupts Mouse Gastric Parietal Cell Acid Secretion.

The present studies were designed to examine the effects of ClC-2 ablation on cellular morphology, parietal cell abundance, H/K ATPase expression, parietal cell ultrastructure and acid secretion using WT and ClC-2-/- mouse stomachs. Cellular histology, morphology and proteins were examined using imaging techniques, electron microscopy and western blot. The effect of histamine on the pH of gastric contents was measured. Acid secretion was also measured using methods and secretagogues previously established to give maximal acid secretion and morphological change. Compared to WT, ClC-2-/- gastric mucosal histological organization appeared disrupted, including dilation of gastric glands, shortening of the gastric gland region and disorganization of all cell layers. Parietal cell numbers and H/K ATPase expression were significantly reduced by 34% (P<0.05) and 53% (P<0.001) respectively and cytoplasmic tubulovesicles appeared markedly reduced on electron microscopic evaluation without evidence of canalicular expansion. In WT parietal cells, ClC-2 was apparent in a similar cellular location as the H/K ATPase by immunofluorescence and appeared associated with tubulovesicles by immunogold electron microscopy. Histamine-stimulated [H+] of the gastric contents was significantly (P<0.025) lower by 9.4 fold (89%) in the ClC-2-/- mouse compared to WT. Histamine/carbachol stimulated gastric acid secretion was significantly reduced (range 84–95%, P<0.005) in ClC-2-/- compared to WT, while pepsinogen secretion was unaffected. Genetic ablation of ClC-2 resulted in reduced gastric gland region, reduced parietal cell number, reduced H/K ATPase, reduced tubulovesicles and reduced stimulated acid secretion.

Ion Channels of the Epithelia of the Gastrointestinal Tract

The cystic fibrosis transmembrane regulator (CFTR), calcium-activated potassium channels, and amiloride-sensitive sodium channels (ENaC) are known to be present in gastrointestinal epithelia. However, in the case of potassium and chloride channels, there may be multiple channels in apical or basolateral membranes controlled by the same or different second messengers. While there is a great deal known of the physiological role of some of these channels, many controversies and unknowns remain. This chapter attempts to point out where further research is needed. Regulation of ion channels by second messengers and phosphorylation is discussed, as well as the need to take species differences into account when addressing regulation. Best practices for studies of short circuit current measurements are addressed. This chapter also addresses the need for caution and careful testing when using effectors of ion channels such as activators or inhibitors, which generally affect multiple cellular components.

Ca2+-activated Cl−channels Focus on “Molecular cloning and transmembrane structure of hCLCA2 from human lung, trachea, and mammary gland”

chloride channels, widely distributed in nature, play roles as diverse as maintaining membrane potential in muscle and movement of Cl− for fluid and electrolyte transport in epithelial tissues. The importance of Cl− channels to human health and disease is clear in myotonia and cystic fibrosis,