Sodium absorption, volume control and potassium channels: in tribute to a great biologist.

It is well established, for all Na-absorbing epithelia, that an increase in the rate of transcellular Na+ absorption is accompanied by an increase in the conductance of the basolateral membrane to K+. For the case of small intestinal epithelial cells from the salamander Necturus maculosus, where the rate of transcellular Na+ absorption can be increased manyfold by the addition of sugars or amino acids to the luminal bathing solution, it appears that this parallelism between Na-K pump rate and basolateral membrane K+ conductance is closely related to volume regulation by the enterocyte. Recent studies have disclosed the presence of stretch-activated K+ channels, in a highly enriched basolateral membrane fraction isolated from these epithelial cells, whose activity is increased by an increase in vesicle volume and inhibited by a decrease in vesicle volume or ATP. The activity of this channel also appears to be regulated by the degree of organization of the cortical actin cytoskeleton; activity is increased by depolymerization of the actin cytoskeleton and decreased by repolymerization of that structure. We postulate that the inhibitory effect of ATP is related to its role in promoting the polymerization of G-actin to form F-actin. We propose that enterocyte swelling that results from the intracellular accumulation of sugars or amino acids in osmotically active forms brings about disorganization of the cortical actin cytoskeleton and activates these channels and is, at least in part, responsible for the "pump-leak parallelism" in this amphibian.

Potassium channels in basolateral membrane vesicles from necturus enterocytes: stretch and ATP sensitivity.

We have previously reported that ATP-inhibitable K(+) channels, in vesicles derived from the basolateral membrane of Necturus maculosus small intestinal cells, exhibit volume regulatory responses that resemble those found in the intact tissue after exposure to anisotonic solutions. We now report that increases in K(+) channel activity can also be elicited by exposure of these vesicles to isotonic solutions containing glucose or alanine that equilibrate across these membranes. We also demonstrate that swelling after exposure to a hypotonic solution or an isotonic solution containing alanine or glucose reduces inhibition of channel activity by ATP and that this finding cannot be simply attributed to dilution of intravesicular ATP. We conclude that ATP-sensitive, stretch-activated K(+) channels may be responsible for the well-established increase in basolateral membrane K(+) conductance of Necturus small intestinal cells after the addition of sugars or amino acids to the solution perfusing the mucosal surface, and we propose that increases in cell volume, resulting in membrane stretch, decreases the sensitivity of these channels to ATP.

Murine colonic mucosa hyperproliferation. I. Elevated CFTR expression and enhanced cAMP-dependent Cl(-) secretion.

Fluid transport in the large intestine is mediated by the cystic fibrosis gene product and cAMP-dependent anion channel cystic fibrosis transmembrane conductance regulator (CFTR). cAMP-mediated Cl(-) secretion by gastrointestinal cell lines in vitro has been positively correlated with the insertion of CFTR into the apical membrane of differentiated senescent colonocytes and negatively correlated with the failure of CFTR to insert into the plasma membrane of their undifferentiated proliferating counterparts. In native tissues, this relationship remains unresolved. We demonstrate, in a transmissible murine colonic hyperplasia (TMCH) model, that (8-fold) colonocyte proliferation was accompanied by increased cellular CFTR mRNA and protein expression (8.3- and 2.4-fold, respectively) and enhanced mucosal cAMP-dependent Cl(-) secretion (2. 3-fold). By immunofluorescence microscopy, cellular CFTR expression was restricted to the apical pole of cells at the base of the epithelial crypt. In contrast, increased cellular proliferation in vivo led to increases in both the cellular level and the total number of cells expressing this anion channel, with cellular CFTR staining extending into the crypt neck region. Hyperproliferating colonocytes accumulated large amounts of CFTR in apically oriented subcellular perinuclear compartments. This novel mode of CFTR regulation may explain why high endogenous levels of cellular CFTR mRNA and protein within the TMCH epithelium were not matched with larger increases in transmucosal CFTR Cl(-) current.

Volume regulatory responses of basolateral membrane vesicles from Necturus enterocytes: role of the cytoskeleton.

Previous studies from this laboratory have demonstrated that basolateral membrane vesicles isolated from Necturus maculosus small intestinal epithelial cells possess a K(+) channel that is inhibited by ATP. In the present studies, we demonstrate that these vesicles, which are essentially devoid of soluble cytoplasmic contaminants, exhibit volume regulatory responses that parallel those of intact epithelial cells. Thus, suspension of these vesicles in a solution that is hypotonic to the intravesicular solution increases channel activity whereas suspension in a solution that is hypertonic to the intravesicular solution decreases, and may abolish, channel activity. These volume regulatory responses appear to be mediated by the same K(ATP) channel and depend on an intact actin cytoskeletal network. The responses to both hypotonic and hypertonic challenge are abolished by cytochalasin D or by incubating the vesicles under conditions that are known to depolymerize actin. Phalloidin, which is known to stabilize actin filaments, partially prevents the action of cytochalasin D. Thus, the present results indicate that the K(ATP) channel activity of basolateral membrane vesicles from Necturus basolateral membranes respond to hypo- and hypertonic challenge monotonically around an isotonic "set point" and that these responses depend on an intact actin cytoskeleton.

Colocalization of glycolytic enzyme activity and KATP channels in basolateral membrane of Necturus enterocytes.

86Rb fluxes through ATP-regulated K+ (KATP) channels in membrane vesicles derived from basolateral membranes of Necturus small intestinal epithelial cells as well as the activity of single KATP channels reconstituted into planar phospholipid bilayers are inhibited by the presence of ADP plus phosphoenolpyruvate in the solution bathing the inner surface of these channels. This inhibition can be prevented by pretreatment of the membranes with 2, 3-butanedione, an irreversible inhibitor of pyruvate kinase (PK) and reversed by the addition of 2-deoxyglucose plus hexokinase. The results of additional studies indicate that PK activity appears to be tightly associated with this membrane fraction. These results, together with considerations of the possible ratio of Na+-K+ pumps to KATP channels in the basolateral membrane, raise the possibility that "cross talk" between those channels and pumps (i.e., the "pump-leak parallelism") may be mediated by local, functionally compartmentalized ATP-to-ADP ratios that differ from those in the bulk cytoplasm.

Reversal of glibenclamide and voltage block of an epithelial KATP channel.

K+ channels present in basolateral membrane vesicles isolated from Necturus maculosa small intestinal cells and reconstituted into planar phospholipid bilayers are inhibited by MgATP and sulfonylurea derivatives, such as tolbutamide and glibenclamide, when these agents are added to the solution bathing the inner mouth of the channel. In addition, these channels possess an intrinsic "voltage gate" and are blocked when the electrical potential difference across the channel is oriented so that the inner solution is electrically positive with respect to the outer solution. We now show that increasing the concentration of permeant ions such as K+ or Rb+ in the outer solution reverses channel inhibition resulting from the addition of 50 microM glibenclamide to the inner solution and also inhibits intrinsic voltage gating; these effects are not elicited by increasing the concentrations of the relatively impermeant ions, Na+ or choline, in the outer solution. Furthermore, increasing the K+ concentration in the outer solution in the absence of glibenclamide inhibits voltage gating, and, under these conditions, the subsequent addition of glibenclamide to the inner solution is ineffective. These results are consistent with a model in which the voltage gate is an open-channel blocker whose action is directly reversed by elevating the external concentration of relatively permeant cations and where the action of glibenclamide is to stabilize the inactivated state of the channel, possibly through hydrophobic interactions.

Reconstitution of a KATP channel from basolateral membranes of Necturus enterocytes.

We have previously reported that basolateral membrane vesicles isolated from Necturus maculosa small intestinal epithelial cells and incorporated into planar phospholipid bilayers display a highly selective "maxi"-conductance K+ channel whose open-time probability is affected by voltage. We now report that this channel is inhibited by MgATP in the solution bathing the intracellular face of the channel but not by Mg2+ or the Na+ or K+ salts of ATP; the effects of MgATP can be prevented or reversed by MgADP. The channel is also inhibited by the nonhydrolyzable ATP analogue magnesium adenosine 5'-O-(3-thiotriphosphate) and the sulfonylurea derivatives tolbutamide and glibenclamide; all of these agents are effective in the intracellular compartment but not when added to the extracellular compartment alone. Channel activity is stimulated by the "K+ channel opener," diazoxide, which also reverses the effect of glibenclamide but not of MgATP. The possible role of this channel as a mediator of the parallelism between basolateral membrane Na(+)-K+ pump activity and the macroscopic K+ conductance of that barrier is discussed.

Apical nonspecific cation conductances in rabbit cecum.

Rabbit cecum exhibits electrogenic Na absorption in vitro. However, because this transport process is not inhibited by amiloride nor does it demonstrate saturation kinetics typical of the amiloride-inhibitable Na channel, we considered whether the cecal transporter represented one of a recently described family of nonselective cation conductances or channels (NSCC). Both transepithelial and vesicle studies demonstrated that K, Cs, and Rb were transported via an apical conductance. Electrogenic transport was inhibited by divalent cations including Ca, Mg, and Ba but was unaffected by either lanthanum or gadolinium. Parallel studies in distal colon did not exhibit a similar response to either K substitution or Ba inhibition. Phenamil, verapamil, and nicardipine significantly inhibited the short-circuit current (Isc). stimulated by nominal Ca- and Mg-free conditions. Flux studies demonstrated a correlation between changes in Isc and Na transport. Microelectrode impalement studies suggested that there may be both NSCC and K conductance in the apical membrane. Planar bilayer studies identified a 190-pS cation channel that may correlate with the macroscopic transport properties of this epithelium. These studies are consistent with a model of cecal Na absorption mediated by a NSCC in the apical membrane; this may be the mechanism underlying the distinct epithelial transport characteristics of this intestinal segment.

A role for annexin IV in epithelial cell function. Inhibition of calcium-activated chloride conductance.

The cellular function of annexin IV was evaluated by correlating tissue expression, cellular localization, and whole-cell electrophysiology. Immunolocalization and biochemical data demonstrate that annexin IV is concentrated along the apical membranes of many epithelia. Introduction of purified exogenous annexin IV into colonic T84 cells through a patch pipette specifically prevented Ca(2+)-dependent Cl- current activation. Affinity-purified antibody against annexin IV applied in the same manner enhanced the activation. Reduction of the endogenous level of annexin IV with a derivatized oligodeoxynucleotide antisense to annexin IV mRNA lowered the threshold for the Ca(2+)-induced current response, mimicking the enhancement of current activation exerted by anti-annexin IV antibody. The inhibitory effect of annexin IV on Ca(2+)-dependent Cl- conductance represents a novel mechanism by which Ca(2+)-binding proteins modulate membrane channel activity.

Effects of a Shaker K+ channel peptide and trypsin on a K+ channel in Necturus enterocytes.

We have previously demonstrated that a synthetic peptide composed of the first 22 amino acids from the NH2-terminus of the Shaker B K+ channel protein deactivates a voltage-dependent K+ channel present in basolateral membrane of Necturus small intestinal epithelial cells reconstituted into planar lipid bilayers (Dubinsky et al. Proc. Natl. Acad. Sci. USA 89: 1770-1774, 1992). We now demonstrate that this peptide interacts with the inner surface of the Necturus channel only when it is in the open or conducting configuration and that this interaction is hindered by tetraethylammonium ion, a well-established blocker of this and other K+ channels. We conclude that this peptide is an open-pore blocker of the Necturus K+ channel as it appears to be in the case of the Shaker B K+ channel. We further demonstrate that trypsin, which abolishes the ability of this peptide to block both the Necturus and the Shaker K+ channels and inhibits spontaneous inactivation of the Shaker K+ channel, also impairs the voltage-gate of the Necturus K+ channel. These findings, and others to be reported in a companion paper, suggest structural homologies between the "inactivation peptide" of the Shaker B K+ channel and the voltage-gate of the Necturus K+ channel.

Immunoisolation of a K+ channel from basolateral membranes of Necturus enterocytes.

We have reported that a peptide composed of the NH2-terminal 22 amino acids of the Drosophila Shaker B K+ channel protein, which is responsible for the inactivation of this A-type channel, blocks the inner, open mouth of a voltage-gated K+ channel present in the basolateral membrane of Necturus maculosa small intestinal enterocytes. We now demonstrate that antibodies to this "inactivating" peptide interact with proteins in solubilized and intact basolateral membranes from Necturus enterocytes. Asolectin vesicles reconstituted with the full complement of solubilized basolateral membrane proteins display 86Rb+ uptake that is inhibited by tetraethylammonium ion and abolished by immunoprecipitation with these antibodies. Furthermore, asolectin vesicles containing protein eluted from an antibody-affinity column display 86Rb+ uptake that is abolished by boiling. Finally, reconstitution of the immunoisolated protein into planar phospholipid bilayers disclosed a K+ channel whose single-channel properties are identical to those of the voltage-gated channel in the native basolateral membranes. Our data are consistent with the notion that a 150-kDa protein present in basolateral membranes of Necturus enterocytes possesses inwardly rectifying K+ channel activity and that this protein is antigenically similar to the type A K+ channel present in the flight muscles of Drosophila melanogaster and encoded by the Shaker B locus.

Characterization of an apical sodium conductance in rabbit cecum.

Rabbit cecum in vitro exhibits electrogenic Na+ absorption not blocked by amiloride but inhibited by the amiloride analogue phenamil, suggesting transport mediated by modified Na+ channels in the apical membrane. To further characterize the mechanism(s) of Na+ absorption, microelectrode impalements of single epithelial cells were performed to measure intracellular potential difference (psi mc) and fractional resistance of the apical membrane, to characterize ionic conductances of the apical and basolateral membranes, and to determine the response to phenamil. The electrical potential profile of cecum (psi mc = -31 +/- 2 mV, fractional resistance = 0.71 +/- 0.03) was qualitatively similar to distal colon. The apical membrane exhibited responses suggesting both Na+ and K+ conductances, whereas the basolateral membrane appeared to have a predominant K+ conductance. Phenamil elicited a depolarization of psi mc and a decrease in fractional resistance; neither response is consistent with inhibition of an apical Na+ conductance. Studies were performed in apical membrane vesicles to characterize ionic conductances by a second independent methodology. These additional studies confirmed the presence of an apical Na+ conductance not inhibited by either amiloride or phenamil. Thus both microelectrode impalement and vesicle studies demonstrated an apical membrane Na+ conductance in rabbit cecum; this is the likely mechanism of electrogenic Na+ absorption in this epithelium. However, the anomalous response to phenamil suggests that the inhibitory effect of this agent is not directly on the conductance. The cecal transporter may be one of a family of cation channels related to, but significantly different from, the classic Na+ channel found in distal colon and other tight epithelia.

Immunolocalization of chloride-transporting membrane vesicles in tracheal epithelial cells.

A membrane fraction eluted from a phenyl Sepharose column (MPS) was isolated from renal cortex and bovine tracheal epithelia that is enriched in a single type of Cl- channel [C. L. Preston, M. A. Calenzo, and W. P. Dubinsky. Am. J. Physiol. 263 (Cell Physiol. 32): C879-C887, 1992]. A 200-kDa membrane protein that copurifies with and appears to be specific to this fraction was purified and used to raise antisera for immunological characterization of these membranes. The antisera reacted in immunoblots with a 200-kDa protein in homogenates of bovine trachea, kidney, pancreas, lung, and intestine. There was also cross-reactivity with a 200-kDa protein in immunoblots in rat stomach, pancreas, and lung. There was no cross-reaction with rat skeletal muscle, cardiac muscle, or aorta. Thus this protein appears to be preferentially enriched in epithelial tissues. Examination of each major fraction during the purification of MPS membranes from trachea shows no enrichment of the 200-kDa protein in plasma, mitochondrial, or nuclear membrane fractions. The only significant enrichment was observed in MPS that is purified by hydrophobic chromatography. In frozen sections, antisera and monospecific immunoaffinity-purified antibodies localize the protein primarily to the apical domain of tracheal columnar epithelial cells with small punctate structures throughout the cytoplasmic compartment.

Isolation of a chloride channel-enriched membrane fraction from tracheal and renal epithelia.

A membrane fraction, enriched in Cl- channels, has been isolated from bovine tracheal epithelia and renal cortex homogenates by hydrophobic chromatography. The fraction (MPS) shows a 37-fold enrichment of Cl- channels over crude tracheal homogenates by net Cl- flux measurements. Alkaline phosphatase and Na(+)-K(+)-ATPase are not found in these membranes, suggesting that they are not apical or basolateral plasma membranes. Marker enzyme analysis for major subcellular membranes also proved negative. The MPS fraction exhibits a protein profile unlike that of other membrane fractions, with major proteins of 200 and 42 kDa, proteins of 30-35 kDa, and lesser amounts of other proteins. Reconstitution of MPS fractions from both trachea and kidney into planar lipid bilayers demonstrates the presence of a single type of anion channel. The current-voltage relationship of this channel is identical to that of the predominant anion channel observed in tracheal apical membranes under similar conditions (H. H. Valdivia, W. P. Dubinsky, and R. Coronado. Science Wash. DC 242: 1441-1444, 1988). In addition, the voltage dependence, selectivity sequence of Cl- > Br- > or = I-, and inhibition by low concentrations of 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid correspond to those of the predominant apical membrane channel. Thus, although the MPS appear to be of subcellular origin, they may be functionally related to an apical membrane Cl- permeability.

Effect of trypsin on a Ca(2+)-activated K+ channel reconstituted into planar phospholipid bilayers.

Exposure of the cytoplasmic side of calcium-activated, high (maxi)-conductance potassium [BK(Ca)] channels in basolateral membrane vesicles from rabbit colonocytes incorporated into planar phospholipid bilayers to trypsin rapidly reduces, but does not abolish, the sensitivity of this channel to activation by calcium without affecting its conductance or high selectivity for K+ over Cl-. The results of these studies also indicate that this BK(Ca) channel does not have intrinsic voltage-gating properties but that its voltage sensitivity is related to its ability to interact with calcium. This conclusion is consistent with the model proposed by Moczydlowski and Lattore (J. Gen. Physiol. 82: 511-542, 1983) for the role of membrane voltage in modulating the interaction between calcium and the BK(Ca) channel in rat skeletal muscle.

A peptide from the Drosophila Shaker K+ channel inhibits a voltage-gated K+ channel in basolateral membranes of Necturus enterocytes.

A synthetic peptide composed of the first 22 amino acid residues of the Drosophila Shaker K+ channel inhibits a voltage-gated K+ channel in basolateral membrane vesicles from Necturus enterocytes reconstituted in planar phospholipid bilayers when added to the solution bathing the inner surface of this channel but not when added to the solution bathing its outer surface. A modified peptide in which the leucine in the 7 position is replaced with phenylalanine is also an effective inhibitor, but replacement of the leucine-7 with lysine or glutamate, or digestion with trypsin, renders the peptide ineffective; replacement of the leucine-7 with glycine markedly reduces but does not abolish the effectiveness of the peptide as an inhibitor. These results are analogous to those reported for the Shaker K+ channel +ADHoshi, T., Zagotta, W.N. & Aldrich, R.W. (1990) Science 250, 533-538; and Zagotta, W.N., Hoshi, T. & Aldrich, R.W. (1990) Science 250, 568-571.+BD and suggest that the molecular anatomy of the receptor at the inner face of the Necturus K+ channel with which the peptide interacts to bring about inhibition of that channel may be similar to that of the Shaker K+ channel.

Reconstitution of isolated Ca(2+)-activated K+ channel proteins from basolateral membranes of rabbit colonocytes.

Using calmodulin-affinity chromatography, we have isolated a fraction of proteins from solubilized basolateral membranes of rabbit colonocytes which when reconstituted into planar phospholipid bilayers disclosed Ca(2+)-activated single K+ channel activities. The properties of the reconstituted channels are identical to those of native membrane vesicles incorporated into these bilayers with respect to their high selectivity for K+ over C-, high ("maxi") conductance, voltage gating, and inhibition by trifluoperazine. Two-dimensional sodium dodecyl sulfate gel electrophoresis of these proteins revealed three major protein species with molecular masses of 120, 60, and 35 kDa, which constituted 70, 10, and 20%, respectively, of the total protein. The results of other studies strongly suggest that the 35-kDa protein may be the Ca(2+)-activated K+ channel protein in these membranes.

Effect of limited trypsin digestion on the renal Na+-H+ exchanger and its regulation by cAMP-dependent protein kinase.

The Na+-H+ exchanger from solubilized rabbit renal brush border membranes is inhibited by cAMP-dependent protein kinase (PKA) mediated protein phosphorylation. To characterize this inhibitory response and its sensitivity to limited proteolysis, the activity of the transporter was assayed after reconstitution of the proteins into artificial lipid vesicles. Limited trypsin digestion increased the basal rate of proton gradient-stimulated, amiloride-inhibitable sodium uptake in reconstituted proteoliposomes and blocked the inhibitory response to PKA-mediated protein phosphorylation. To determine if the inhibitory response to PKA-mediated protein phosphorylation could be restored to the trypsin-treated solubilized proteins, nontrypsinized solubilized brush border membrane proteins were separated by column chromatography. The addition of small molecular weight polypeptides, fractionated on Superose-12 FPLC (Ve = 0.7), to trypsinized solubilized brush border membrane proteins restored the inhibitory response to PKA-mediated protein phosphorylation. Similarly, the addition of the 0.1 M NaCl fraction from an anion exchange column, Mono Q-FPLC, also restored the inhibitory response to PKA. Both protein fractions contained a common 42-43 kDa protein which was preferentially phosphorylated by PKA. These results indicate that limited trypsin digestion dissociates the activity of the renal Na+-H+ exchanger from its regulation by PKA. It is suggested that trypsin cleaves an inhibitory component of the transporter and that this component is the site of PKA-mediated regulation. Phosphoprotein analysis of fractions that restored PKA regulation raises the possibility that a polypeptide of 42-43 kDa is involved in the inhibition of the renal Na+-H+ exchanger by PKA-mediated protein phosphorylation.

Reconstitution of an inwardly rectifying potassium channel from the basolateral membranes of Necturus enterocytes into planar lipid bilayers.

Basolateral membrane vesicles from Necturus enterocytes, highly (greater than 20-fold) enriched in Na+,K+-ATPase, were reconstituted into planar lipid bilayers. The principal channel activity observed is selective for K+ over Na+ and Cl-. This K+ channel is blocked by Ba2+ and Leiurus quinquestriatus venom but is not affected by Ca2+ over the range of 10(-3) to less than 10(-7) M and is not inhibited by charybdotoxin. L. quinquestriatus venom also markedly reduces the conductance of the basolateral membrane of intact villus cells of Necturus small intestine. The open-time probability (Po) of the channel displays a voltage-dependence characteristic of an "inward rectifier"; i.e., the channel inactivates when the basolateral membrane is depolarized and Po increases with increasing hyperpolarization of that barrier. Assuming that similar properties prevail under physiological conditions, this characteristic could provide, in part, an explanation for the parallelism between Na+-pump and K+-leak activities of the basolateral membrane observed in this epithelium. Thus, an increase in rheogenic Na+-pump activity at the basolateral membrane would hyperpolarize that barrier and, in turn, increase the open time of this K+ channel.