Rabbit distal colon epithelium: III. Ca2(+)-activated K+ channels in basolateral plasma membrane vesicles of surface and crypt cells

Potassium channels in intestinal epithelial cells and their pharmacological modulation: a systematic review

Several potassium channels (KCs) have been described throughout the gastrointestinal tract. Notwithstanding, their contribution to both physiologic and pathophysiologic conditions, as inflammatory bowel disease (IBD), remains underexplored. Therefore, we aim to systematically review, for the first time, the evidence on the characteristics and modulation of KCs in intestinal epithelial cells (IECs). PubMed, Scopus, and Web of Science were searched to identify studies focusing on KCs and their modulation in IECs. The included studies were assessed using a reporting inclusiveness checklist. From the 745 identified records, 73 met the inclusion criteria; their reporting inclusiveness was moderate-high. Some studies described the physiological role of KCs, while others explored their importance in pathological settings. Globally, in IBD animal models, apical K_Ca1.1 channels, responsible for luminal secretion, were upregulated. In human colonocytes, basolateral K_Ca3.1 channels were downregulated. The pharmacological inhibition of K_2P and K_v influenced intestinal barrier function, promoting inflammation. Evidence suggests a strong association between KCs expression and secretory mechanisms in human and animal IECs. Further research is warranted to explore the usefulness of KC pharmacological modulation as a therapeutic target.

The KCNQ1 potassium channel: from gene to physiological function

The voltage-gated KCNQ1 (KvLQT1, Kv7.1) potassium channel plays a crucial role in shaping the cardiac action potential as well as in controlling the water and salt homeostasis in several epithelial tissues. KCNQ1 channels in these tissues are tightly regulated by auxiliary proteins and accessory factors, capable of modulating the properties of the channel complexes. This paper reviews the current knowledge about the KCNQ1 channel with a major focus on interacting proteins and physiological functions.

Class I antiarrhythmics inhibit Na+ absorption and Cl− secretion in rabbit descending colon epithelium

To clarify the mechanism of the diarrhea associated with the clinical use of antiarrhythmic drugs we assessed the effects of these agents on transepithelial Na+ absorption and Cl- secretion, on basolateral K+ conductance, and on the properties of single basolateral K+ channels of rabbit colon epithelium. Quinidine and propafenone, both at 10 microM, inhibited Na+ absorption by 27 and 38% respectively, compared with 50% with 5 mM Ba2+. The other tested class I antiarrhythmics disopyramide, mexiletine, lidocaine, and flecainide decreased Na+ current by 9-13%. Procainamide and the class III antiarrhythmics N-acetylprocainamide, sotalol, ibutilide, and amiodarone were no or were very weak inhibitors of Na+ absorption. Cl- secretion, stimulated with the adenosine analogue NECA (5'-N-ethylcarboxamide-adenosine), was reduced by 54% with quinidine and by 29% with propafenone compared with 100% with Ba2+. Mexiletine, lidocaine, and flecainide inhibited Cl- secretion by 10-23%, whereas the class III antiarrhythmics were no or were weak inhibitors. Those antiarrhythmics that inhibited Na+ and Cl- transport also reduced basolateral K+ conductance, determined in amphotericin B permeabilized epithelia. The activity of the high-conductance, Ca2+-activated, voltage-dependent K+ (BK(Ca)) channel, which is primarily responsible for basolateral K+ recycling during Na+ absorption, was inhibited by 10-30 microM quinidine or propafenone in the form of a rapidly dissociating block. Mexiletine and flecainide inhibited the single channel conductance at higher concentrations; disopyramide, lidocaine, and procainamide were ineffective. In conclusion, the present evidence suggests that the diarrhea caused by class I antiarrhythmic drugs such as quinidine and propafenone is a result of a reduction in basolateral K+ conductance and inhibition of BK(Ca) channels, thereby impeding transepithelial Na+ and water absorption.

Basolateral potassium channels of rabbit colon epithelium: role in sodium absorption and chloride secretion

In order to assess the role of different classes of K(+) channels in recirculation of K(+) across the basolateral membrane of rabbit distal colon epithelium, the effects of various K(+) channel inhibitors were tested on the activity of single K(+) channels from the basolateral membrane, on macroscopic basolateral K(+) conductance, and on the rate of Na(+) absorption and Cl(-) secretion. In single-channel measurements using the lipid bilayer reconstitution system, high-conductance (236 pS), Ca(2+)-activated K(+) (BK(Ca)) channels were most frequently detected; the second most abundant channel was a low-conductance K(+) channel (31 pS) that exhibited channel rundown. In addition to Ba(2+) and charybdotoxin (ChTX), the BK(Ca) channels were inhibited by quinidine, verapamil and tetraethylammonium (TEA), the latter only when present on the side of the channel from which K(+) flow originates. Macroscopic basolateral K(+) conductance, determined in amphotericin-permeabilised epithelia, was also markedly reduced by quinidine and verapamil, TEA inhibited only from the lumen side, and serosal ChTX was without effect. The chromanol 293B and the sulphonylurea tolbutamide did not affect BK(Ca) channels and had no or only a small inhibitory effect on macroscopic basolateral K(+) conductance. Transepithelial Na(+) absorption was partly inhibited by Ba(2+), quinidine and verapamil, suggesting that BK(Ca) channels are involved in basolateral recirculation of K(+) during Na(+) absorption in rabbit colon. The BK(Ca) channel inhibitors TEA and ChTX did not reduce Na(+) absorption, probably because TEA does not enter intact cells and ChTX is 'knocked off' its extracellular binding site by K(+) outflow from the cell interior. Transepithelial Cl(-) secretion was inhibited completely by Ba(2+) and 293B, partly by quinidine but not by the other K(+) channel blockers, indicating that the small (<3 pS) K(V)LQT1 channels are responsible for basolateral K(+) exit during Cl(-) secretion. Hence different types of K(+) channels mediate basolateral K(+) exit during transepithelial Na(+) and Cl(-) transport.

Quantification and distribution of Ca(2+)-activated maxi K(+) channels in rabbit distal colon

The Ca(2+)-activated maxi K(+) channel is an abundant channel type in the distal colon epithelium, but nothing is known regarding the actual number and precise localization of these channels. The aim of this study has therefore been to quantify the maxi K(+) channels in colon epithelium by binding of iberiotoxin (IbTX), a selective peptidyl ligand for maxi K(+) channels. In isotope flux measurements 75% of the total K(+) channel activity in plasma membranes from distal colon epithelium is inhibited by IbTX (K(0.5) = 4.5 pM), indicating that the maxi K(+) channel is the predominant channel type in this epithelium. Consistent with the functional studies, the radiolabeled double mutant (125)I-IbTX-D19Y/Y36F binds to the colon epithelium membranes with an equilibrium dissociation constant of approximately 10 pM. The maximum receptor concentration values (in fmol/mg protein) for (125)I-IbTX-D19Y/Y36F binding to colon epithelium are 78 for surface membranes and 8 for crypt membranes, suggesting that the maxi K(+) channels are predominantly expressed in the Na(+)-absorbing surface cells, as compared with the Cl(-)-secreting crypt cells. However, aldosterone stimulation of this tissue induced by a low-Na(+) diet does not change the total number of maxi K(+) channels.

Purification and characterization of epithelial Ca(2+)-activated K+ channels

Reabsorption of NaCl in the thick ascending limb of Henle's loop in the kidney and in the surface cells in the distal colon involves the integrated function of several membrane transport systems including ion channels, the Na,K,Cl-cotransport system and the Na,K-pump. To determine if their properties are consistent with a role in regulation of transepithelial transport, Ca(2+)-activated K+ channels from the luminal membrane of the TAL cells and from the basolateral membrane of the distal colon cells have been characterized by flux studies in plasma membrane vesicle preparations and by single channel measurements in lipid bilayers. The channels are found to be activated by Ca2+ in the physiological range of concentration with a strong dependence on intracellular pH and the membrane potential. The Ca(2+)-sensitivity of the K+ channels is modulated by phosphorylation and dephosphorylation and the K+ channel protein must be in a phosphorylated state to respond to intracellular concentrations of Ca2+. As a step towards purification of the K+ channel proteins, procedures for solubilization and reconstitution of the K+ channels have been developed. The observation that the epithelial Ca(2+)-activated K+ channels bind calmodulin in the presence of Ca2+ have allowed for partial purification of the K+ channel proteins by calmodulin affinity chromatography. In the sequences for the two cloned Ca(2+)-activated K+ channels, the mSlo channel and the slowpoke channel, putative calmodulin binding regions can be identified.

The effect of short-chain fatty acids on Cl- and K+ conductance in rat colonic crypts

The effect of butyrate on membrane potential and membrane currents of colonic enterocytes was studied with the whole-cell patch-clamp method. Superfusion of crypts from the rat distal colon with butyrate-containing solutions induced a membrane depolarization of 16.5 +/- 2.3 mV. This response was only observed in the upper third of the crypt. The depolarization was dependent on the presence of Cl- and was accompanied by an increase in membrane inward current, indicating that it is caused by an increase in Cl- conductance. Membrane outward current, however, behaved inconsistently. Whereas in most cells an increase was observed, about 25% of the cells responded with a decrease. This unexpected inhibition of the outward current probably represents a decrease of K+ conductance caused by the cellular acidification in the presence of butyrate. Manoeuvres carried out to acidify the cell interior, like perfusion with acid buffer solutions or inhibition of the Na+/H+ exchanger by amiloride, mimicked this inhibition of the K+ conductance. Orientating cell-attached patch-clamp recordings performed in parallel revealed an activation of previously silent basolateral Cl- channels by butyrate. They had a linear current/voltage relationship and a single-channel conductance of 20-30 pS. The butyrate-induced depolarization was not dependent on intracellular adenosine 5'-triphosphate (ATP) and was also observed when the buffer capacity of the pipette for Ca2+ was increased. It was also not inhibited by guanosine-5'-O(2-thiodiphosphate) (GDP[beta S]).(ABSTRACT TRUNCATED AT 250 WORDS)

Compartmentation of intestinal drug sulphoconjugation. Incorporation of luminal and contraluminal [35S]sulphate into 1-naphthol by the isolated mucosa of guinea pig jejunum and colon

Compartmentation of 1-naphthol metabolism was inferred from the metabolite pattern and distribution in the isolated mucosa of guinea pig intestine mounted in a flux chamber (Sund and Lauterbach, Arch Pharmacol Toxicol 58: 74-83, 1986). To verify the existence of these compartments the dependence of [35S]sulphate incorporation into 1-naphthol sulphate on the side of administration of 1-naphthol and [35S]sulphate was determined. Isolated mucosae were pre-equilibrated with [35S]-sulphate (5 x 10(6) cpm/mumol, 1 mM) for 30 min and subsequently incubated for 15 min with 50 microM 1-naphthol. The three 1-naphthol sulphate fractions (luminal side, blood side and tissue) were assayed by HPLC and liquid scintillation counting; their specific activity was calculated as percentage of the specific activity of the inorganic sulphate administered. 1-Naphthol glucuronide was also measured. In jejunal experiments: after luminal administration of 1-naphthol, 1-naphthol sulphate appeared almost exclusively in the luminal solution; its specific activity approached 70% and 3%, when [35S]sulphate was added to the luminal and blood side, respectively. After introducing 1-naphthol and [35S]sulphate on the blood side, a high and similar specific activity of 50-60% was observed in all three 1-naphthol sulphate fractions (luminal and blood side, tissue) though adding [35S]sulphate to the lumen side decreased the specific activity to 10-20%. In experiments on colonic mucosa: a specific activity both of luminal and blood side 1-naphthol sulphate of more than 50% was observed with blood side [35S]sulphate irrespective of the side of 1-naphthol administration. When [35S]sulphate was placed on the luminal side the specific activity of blood side 1-naphthol sulphate dropped to only 3%, and that of luminal 1-naphthol sulphate ranged between 6% and 20%. Supplementary experiments in which mucosae were exposed to 1-naphthol and [35S]sulphate for 45 min without preincubation showed a tendency to decrease the lumen: blood distribution ratio of 1-naphthol sulphate. However, the general pattern of 1-naphthol sulphate specific activity remained unchanged. The experiments provide further evidence that the jejunal conjugation of phenolic drugs is being performed in two major compartments, which are accessible from the lumen ("luminal compartment") and blood ("systemic compartment") side. The luminal compartment seems practically inaccessible to blood side sulphate as is the systemic compartment for luminal 1-naphthol. In the colonic mucosa, a major "systemic compartment" receiving its sulphate from the blood side is the site for most of the events, but a minor "luminal compartment" seems to be involved as well.

Second messengers and ion channels in acetylcholine-induced chloride secretion in hen trachea

1. Hen tracheal epithelium can be stimulated by serosal application of acetylcholine (ACh) to secrete Cl- equal to approximately 60-90 microA/cm2. 2. Radio-ligand-displacement for IP3, cAMP and cGMP and ion channel selective drugs in voltage clamp set-ups were employed to characterize second messengers and Cl-, K+ and Ca2+ channels involved in the ACh response. 3. ACh induced a significant rise in IP3 in isolated tracheocytes, while ACh did not influence the production of cAMP in whole tissue, isolated tracheocytes or basolateral cell membrane vesicles. Further ACh desensitization did not effect cAMP level in tracheocytes. In addition neither ACh stimulation nor desensitization interfered with cAMP production in presence of 4.5 microM forskolin in tracheocytes, a level of forskolin rising base level cAMP by around five fold. 4. Around 35% of ACh Cl- secretion depends on Ca2+ mobilization from internal stores and about 65% on Ca2+ influx over basolateral membrane. The activated Ca2+ channel is insensitive to class I, II, III and IV Ca2+ antagonists. 5. A 23187 can mimic the ACh effect although 30% is indomethacin-sensitive demonstrating a prostaglandin activated adenylyl cyclase. 6. Two K+ channels are involved in ACh secretion, one sensitive to Ba2+ and quinine and both insensitive to 4-aminopyridine, apamin, charybdotoxin and TEA. 7. Flufenamate and triaminopyrimidine block a non-selective ion channel likely involved in the ACh response. An ACh activated apical Cl- channel is NPPB-sensitive.

Small and maxi K+ channels in the basolateral membrane of isolated crypts from rat distal colon: single-channel and slow whole-cell recordings

The patch-clamp technique was used to characterize K+ channel activity in the basolateral membrane of isolated crypts from rat distal colon. In cell-attached patches with KCl in the pipette, channels with conductances ranging from 6 pS to 80 pS appeared. With NaCl in the pipette and KCl in the bath in excised inside-out membrane patches a small-conductance channel with a mean conductance of 12 +/- 6 pS (n = 18) was observed. The channel has been identified as K+ channel by its selectivity for K+ over Na+ and by its sensitivity to conventional K+ channel blockers, Ba2+ and tetraethylammonium (TEA+). Changes of cytosolic pH did not attenuate channel activity. Activity of the 12-pS channel was increased by membrane depolarization and elevated cytosolic Ca2+ concentration. In addition, a maxi K+ channel with a mean conductance of 187 +/- 15 pS (n = 4) in symmetrical KCl solutions was only occasionally recorded. The maxi K+ channel could be blocked by Ba2+ (5 mmol/l) on the cytosolic side. Using the slow-whole cell recording technique under control conditions, a cell membrane potential of -70 +/- 10 mV (n = 18) was measured. By application of various K+ channel blockers such as glibenclamide, charybdotoxin, apamin, risotilide, Ba2+ and TEA+ in the bath, only Ba2+ and TEA+ depolarized the cell membrane. The present data suggest that the small K+ channel (12 pS) is involved in the maintenance of the cell membrane resting potential.

Activation of ion transport pathways by changes in cell volume

Swelling-activated K+ and Cl- channels, which mediate RVD, are found in most cell types. Prominent exceptions to this rule include red cells, which together with some types of epithelia, utilize electroneutral [K(+)-Cl-] cotransport for down-regulation of volume. Shrinkage-activated Na+/H+ exchange and [Na(+)-K(+)-2 Cl-] cotransport mediate RVI in many cell types, although the activation of these systems may require special conditions, such as previous RVD. Swelling-activated K+/H+ exchange and Ca2+/Na+ exchange seem to be restricted to certain species of red cells. Swelling-activated calcium channels, although not carrying sufficient ion flux to contribute to volume changes may play an important role in the activation of transport pathways. In this review of volume-activated ion transport pathways we have concentrated on regulatory phenomena. We have listed known secondary messenger pathways that modulate volume-activated transporters, although the evidence that volume signals are transduced via these systems is preliminary. We have focused on several mechanisms that might function as volume sensors. In our view, the most important candidates for this role are the structures which detect deformation or stretching of the membrane and the skeletal filaments attached to it, and the extraordinary effects that small changes in concentration of cytoplasmic macromolecules may exert on the activities of cytoplasmic and membrane enzymes (macromolecular crowding). It is noteworthy that volume-activated ion transporters are intercalated into the cellular signaling network as receptors, messengers and effectors. Stretch-activated ion channels may serve as receptors for cell volume itself. Cell swelling or shrinkage may serve a messenger function in the communication between opposing surfaces of epithelia, or in the regulation of metabolic pathways in the liver. Finally, these transporters may act as effector systems when they perform regulatory volume increase or decrease. This review discusses several examples in which relatively simple methods of examining volume regulation led to the discovery of transporters ultimately found to play key roles in the transmission of information within the cell. So, why volume? Because it's functionally important, it's relatively cheap (if you happened to have everything else, you only need some distilled water or concentrated salt solution), and since it involves many disciplines of experimental biology, it's fun to do.