Molecular variants of KCNQ channels expressed in murine portal vein myocytes: a role in delayed rectifier current.

We have analyzed the expression of KCNQ genes in murine portal vein myocytes and determined that of the 5 known KCNQ channels, only KCNQ1 was expressed. In addition to the full-length KCNQ1 transcript, a novel spliced form (termed KCNQ1b) was detected that had a 63 amino acid truncation at the C-terminus. KCNQ1b was not detected in heart or brain but represented approximately half the KCNQ1 transcripts expressed in PV. Antibodies specific for KCNQ1a stained cell membranes from portal vein myocytes and HEK cells expressing the channel. However, because the antibodies were generated against an epitope in the deleted, C-terminal portion of the protein, these antibodies did not stain HEK cells expressing KCNQ1b. In murine portal vein myocytes, in the presence of 5 mmol/L 4-aminopyridine, an outwardly rectifying K+ current was recorded that was sensitive to linopirdine, a specific blocker of KCNQ channels. Currents produced by the heterologous expression of KCNQ1a or KCNQ1b were inhibited by similar concentrations of linopirdine, and linopirdine prolonged the time-course of the action potential in isolated portal vein myocytes. Our data suggest that these two KCNQ1 splice forms are expressed in murine portal vein and contribute to the delayed rectifier current in these myocytes.

Conductances responsible for slow wave generation and propagation in interstitial cells of Cajal.

Interstitial cells of Cajal (ICC) are a fundamental component of the pacemaker apparatus of the gastrointestinal (GI) tract. ICC generate pacemaker currents that are the basis for slow wave activity in GI muscles. ICC form a network of cells connected by gap junctions that run around and along the phasic regions of the GI tract. ICC possess specialized conductances that allow them to generate pacemaker activity and serve as the pathway for active propagation of slow waves. Pacemaker currents are attributed to a Ca(2+)-inhibited, voltage-independent, non-selective cation conductance that has similar properties to the conductance elicited by expression of transient receptor potential-C4. Propagation occurs through a voltage-dependent mechanism, and data suggest that the factor coupling pacemaker units in ICC is Ca(2+) entry. ICC express a dihydropyridine-resistant, voltage-dependent Ca(2+) conductance that is important in slow wave propagation. Work is underway to determine the molecular identities of these conductances.

Microarray comparison of normal and W/Wv mice in the gastric fundus indicates a supersensitive phenotype.

Interstitial cells of Cajal (ICC) have been identified in specific areas throughout the smooth musculature of the gastrointestinal (GI) tract. Located within the circular and longitudinal muscle layers of the gastric fundus lies a specific type of ICC, termed "intramuscular" ICC or IC-IM. The principal function of this cell type is to act as "mediators of excitatory and inhibitory enteric neurotransmission." The functional role of these cells has been investigated using W/W(v) mutant mice that specifically lack IC-IM, resulting in disrupted enteric neurotransmission. The aim of the present study was to investigate differential gene expression in W/W(v) mutant mice, from the tunica muscularis of the gastric fundus using a mouse cDNA microarray containing 1,081 known genes. Verification of the microarray data was attained using real-time "quantitative" PCR (qPCR). Of the 1,081 arrayed genes, 36 demonstrated differential expression by >2-fold in the W/W(v) mice. An agreement rate of 50% (7 of 14 tested) was obtained using qPCR. Of the seven confirmed changes in expression, several were indicative of a supersensitive phenotype, observed in denervation models. Expression of several putative neurotransmitter receptors including P2Y, the receptor for the inhibitory neurotransmitter ATP, was upregulated. The functional role of the P2Y receptor was also investigated using electrophysiological recordings. These results offer a new insight into the molecular changes that occur in W/W(v) fundic smooth muscle and may also provide novel information with regard to the importance of IC-IM in enteric neurotransmission.

Nucleotide regulation of the voltage-dependent nonselective cation conductance in murine colonic myocytes.

ATP is proposed to be a major inhibitory neurotransmitter in the gastrointestinal (GI) tract, causing hyperpolarization and smooth muscle relaxation. ATP activates small-conductance Ca(2+)-activated K(+) channels that are involved in setting the resting membrane potential and causing inhibitory junction potentials. No reports are available examining the effects of ATP on voltage-dependent inward currents in GI smooth muscle cells. We previously reported two types of voltage-dependent inward currents in murine proximal colonic myocytes: a low-threshold voltage-activated, nonselective cation current (I(VNSCC)) and a relatively high-threshold voltage-activated (L-type) Ca(2+) current (I(L)). Here we have investigated the effects of ATP on these currents. External application of ATP (1 mM) did not affect I(VNSCC) or I(L) in dialyzed cells. ATP (1 mM) increased I(VNSCC) and decreased I(L) in the perforated whole-cell configuration. UTP and UDP (1 mM) were more potent than ATP on I(VNSCC). ADP decreased I(L) but had no effect on I(VNSCC). The order of effectiveness was UTP = UDP > ATP > ADP. These effects were not blocked by pyridoxal phosphate-6-azo(benzene-2,4-disulfonic acid) (PPADS), but the phospholipase C inhibitor U-73122 reversed the effects of ATP on I(VNSCC). ATP stimulation of I(VNSCC) was also reversed by protein kinase C (PKC) inhibitors chelerythrine chloride or bisindolylmaleimide I. Phorbol 12,13-dibutyrate mimicked the effects of ATP. RT-PCR showed that P2Y(4) is expressed by murine colonic myocytes, and this receptor is relatively insensitive to PPADS. Our data suggest that ATP activates I(VNSCC) and depresses I(L) via binding of P2Y(4) receptors and stimulation of the phospholipase C/PKC pathway.

Functional characterization of novel alternatively spliced ClC-2 chloride channel variants in the heart.

A novel volume-regulated hyperpolarization-activated chloride inward rectifier channel (Cl.ir) was identified in mammalian heart. To investigate whether ClC-2 is the gene encoding Cl.ir channels in heart, ClC-2 cDNAs cloned from rat (rClC-2) and guinea pig (gpClC-2) hearts were functionally characterized. When expressed in NIH/3T3 cells, full-length rClC-2 yielded inwardly rectifying whole-cell currents with very slow activation kinetics (time constants > 1.7 s) upon hyperpolarization under hypotonic condition. The single-channel rClC-2 currents had a unitary slope conductance of 3.9 +/- 0.2 picosiemens. A novel variant with an in-frame deletion at the beginning of exon 15 that leads to a deletion of 45 bp (corresponding to 15 amino acids in alpha-helices O and P, rClC-2(Delta509-523)) was identified in rat heart. The relative transcriptional expression levels of full-length rClC-2 and rClC-2(Delta509-523) in rat heart were 0.018 +/- 0.003 and 0.028 +/- 0.006 arbitrary units, respectively, relative to glyceraldehyde-3-phosphate dehydrogenase (n = 5, p = nonsignificant). A similar partial exon 15 skipping with a deletion of 105 bp (35 amino acids in alpha-helices O-Q, gpClC-2(Delta509-543)) was also identified in guinea pig heart. Expression of both rClC-2(Delta509-523) and gpClC-2(Delta509-543) resulted in functional channels with phenotypic activation kinetics and many properties identical to those of endogenous Cl.ir channels in native rat and guinea pig cardiac myocytes, respectively. Intracellular dialysis of anti-ClC-2 antibody inhibited expressed ClC-2 channels and endogenous Cl.ir currents in native rat and guinea pig cardiac myocytes. These results demonstrate that novel deletion variants of ClC-2 due to partial exon 15 skipping may be expressed normally in heart and contribute to the formation of endogenous Cl.ir channels in native cardiac cells.

Regulation of Kv4.3 currents by Ca2+/calmodulin-dependent protein kinase II.

The voltage-dependent K+ channel 4.3 (Kv4.3) is one of the major molecular correlates encoding a class of rapidly inactivating K+ currents, including the transient outward current in the heart (Ito) and A currents (IA) in neuronal and smooth muscle preparations. Recent studies have shown that Ito in human atrial myocytes and IA in murine colonic myocytes are modulated by Ca2+/calmodulin-dependent protein kinase II (CaMKII); however, the molecular target of CaMKII in these studies has not been elucidated. We performed experiments to investigate whether CaMKII could regulate Kv4.3 currents directly. Inclusion of the autothiophosphorylated form of CaMKII in the patch pipette (10 nM) prolonged Kv4.3 currents such that the time required to reach 50% inactivation from peak more than doubled, with positive shifts in voltage dependence of both activation and inactivation. In contrast, the rate of recovery from inactivation was accelerated under these conditions. CaMKII-inhibitory peptide or KN-93 produced effects opposite to that above; thus the rate of inactivation was increased, and recovery from inactivation decreased. A number of mutagenesis experiments were conducted on the three candidate CaMKII consensus sequence sites on the channel. Mutations at S550A, located at the COOH-terminal region of the channel, resulted in currents that inactivated more rapidly but recovered from inactivation at a slower rate than that of wild-type controls. In addition, these currents were unaffected by dialysis with either autothiophosphorylated CaMKII or the specific inhibitory peptide of CaMKII, suggesting that CaMKII slows the inactivation and accelerates the rate of recovery from inactivation of Kv4.3 currents by a direct effect at S550A, located at the COOH-terminal region of the channel.

Differential transcriptional expression of Ca2+ BP superfamilies in murine gastrointestinal smooth muscles.

Calmodulin (Cal) plays important roles for contractile activity in smooth muscles. Recently, two distinct Ca(2+)-binding protein superfamilies with sequence similarities to Cal have been identified in neuronal cells: neuronal Ca(2+)-binding proteins (NCBPs) and Cal-like Ca(2+)-binding proteins (CaBPs). Some NCBPs and CaBPs play significant roles for Ca(2+)-dependent cellular signaling in the nervous system. In gastrointestinal smooth muscles (GISMs), Cal functions as the regulator of contractile behavior and electrical rhythmicity. However, the molecular identification of NCBPs and CaBPs has not been elucidated in GISMs. Here, we have identified NCBPs and CaBPs expressed in GISMs and determined the expression levels of their transcripts by quantitative RT-PCR. Of 12 NCBPs, the transcripts for neuronal Ca(2+) sensor 1, neural visinin-like proteins 1, 2, and 3, and K(+) channel-interacting proteins 1 and 3 were detected in proximal colon, gastric fundus, gastric antrum, and jejunum. On the other hand, of seven CaBPs including alternatively spliced variants, only CaBP1L transcripts were detected in GISMs.

Functional and molecular identification of ERG channels in murine portal vein myocytes.

Ion channels encoded by ether-à-go-go-related genes (ERG) have been implicated in repolarization of the cardiac action potential and also as components of the resting membrane conductance in various cells. The aim of the present study was to determine whether ERG channels were expressed in smooth muscle cells isolated from portal vein. RT-PCR demonstrated the expression of murine ERG (mERG), and real-time quantitative PCR showed that the mERG1b isoform predominated over the mERG1a, mERG2, and mERG3 in portal vein. Single myocytes from portal vein displayed membrane staining with an ERG1-specific antibody. Whole cell voltage-clamp experiments were performed to determine whether portal vein myocytes expressed functional ERG channels. Large inward currents with distinctive kinetics were elicited that were inhibited rapidly by E-4031 (mean amplitude of the E-4031-sensitive current at -120 mV was -205 +/- 24 pA; n = 14). Deactivation of the E-4031-sensitive current was voltage dependent (mean time constants at -80 and -120 mV were 103 +/- 9 and 33 +/- 2 ms, respectively; n = 13). Because of the rapid kinetics of mERG currents at more negative potentials, there was a substantial noninactivating "window" current that reached a maximum of -66 +/- 10 pA at -70 mV. Complete portal veins exhibited spontaneous contractile activity in isometric tension experiments, and this activity was modified significantly by E-4031. These data show that ERG channels are expressed in murine portal vein myocytes that may contribute to the resting membrane conductance.

Constitutive expression and function of cyclooxygenase-2 in murine gastric muscles.

BACKGROUND & AIMS: Cyclooxygenase enzymes (COX) generate intermediates in the prostaglandin (PG) cascade. COX-1 is constitutively expressed in many cells, and COX-2 is typically thought to be an inducible isoform. METHODS: We evaluated constitutive expression and function of COX-2 in murine gastric muscles. RESULTS: Immunohistochemistry showed COX-2-like immunoreactivity (COX-2-LI) in myenteric neurons. Half the neurons with COX-2-LI expressed nitric oxide synthase (NOS). COX-2-LI was not observed in smooth muscle cells. Interstitial cells of Cajal within muscle layers (IC-IM) expressed COX-2-LI, suggesting a novel role for IC-IM. Molecular studies verified expression of COX-2 in gastric muscles. Quantitative polymerase chain reaction (PCR) showed equal expression of COX-1 and COX-2 in the antrum. COX-2 was more abundant in fundus. Indomethacin and GR253035X, a COX-2 inhibitor, increased antral phasic contractions and potentiated responses to ACh. Indomethacin, but not GR253035X, increased contractions and potentiated responses in tissues of COX-2 knockout mice. Indomethacin and GR253035X reduced tone in the fundus. CONCLUSIONS: COX-2 is constitutively expressed by IC-IM and neurons in the stomach and at levels similar to COX-1. Prostanoids produced by COX-2 regulate mechanical activities of fundus and antral muscles.

The large conductance potassium channel beta-subunit can interact with and modulate the functional properties of a calcium-activated chloride channel, CLCA1.

We have recently compared the biophysical and pharmacological properties of native Ca(2+)-activated Cl(-) currents in murine portal vein with mCLCA1 channels cloned from murine portal vein myocytes (Britton, F. C., Ohya, S., Horowitz, B., and Greenwood, I. A. (2002) J. Physiol. (Lond.) 539, 107-117). These channels shared a similar relative permeability to various anions, but the expressed channel current lacked the marked time dependence of the native current. In addition, the expressed channel showed a lower Ca(2+) sensitivity than the native channel. As non-pore-forming regulatory beta-subunits alter the kinetics and increase the Ca(2+) sensitivity of Ca(2+)-dependent K(+) channels (BK channels) we investigated whether co-expression of beta-subunits with CLCA1 would alter the kinetics/Ca(2+) sensitivity of mCLCA1. Internal dialysis of human embryonic kidney cells stably expressing CLCA1 with 500 nM Ca(2+) evoked a significantly larger current when the beta-subunit KCNMB1 was co-expressed. In a small number of co-transfected cells marked time dependence to the activation kinetics was observed. Interaction studies using the mammalian two-hybrid technique demonstrated a physical association between CLCA1 and KCNMB1 when co-expressed in human embryonic kidney cells. These data suggest that activation of CLCA1 can be modified by accessory subunits.

TRPC4 currents have properties similar to the pacemaker current in interstitial cells of Cajal.

Interstitial cells of Cajal (ICC) are the pacemaker cells responsible for the generation and propagation of electrical slow waves in phasic muscles of the gastrointestinal (GI) tract. The pacemaker current that initiates each slow wave derives from a calcium-inhibited, voltage-independent, nonselective cation channel. This channel in ICC displays properties similar to that reported for the transient receptor potential (TRP) family of nonselective cation channels, particularly those seen for TRPC3 and TRPC4. We have identified transcripts for TRPC4 in individually isolated ICC and have cloned the two alternatively spliced forms of TRPC4, TRPC4 alpha and TRPC4 beta, from GI muscles. TRPC4 beta is missing an 84-amino acid segment from the carboxy terminus. Expression of either form using the whole cell patch-clamp technique led to calcium-inhibited, nonselective cation channels as determined by N-methyl-D-glucamine replacement experiments and BAPTA dialysis. Expression of TRPC4 beta channels recorded at the whole cell level had characteristics similar to the nonselective cation current in ICC. The single-channel conductance of TRPC4 beta was determined to be 17.5 pS. Application of calmidazolium to cells expressing TRPC4 beta led to a significant increase in the inward current of these cells at both the whole cell and single-channel level, and currents were sensitive to block by 10 microM lanthanum, niflumic acid, and DIDS. Comparison of the properties reported for the nonselective cation current in ICC and those identified here for TRPC4 beta led us to conclude that a TRPC4-like current encodes the plasmalemmal pacemaker current in murine small intestine.

ERG K+ channels modulate the electrical and contractile activities of gallbladder smooth muscle.

The current study was undertaken to test the existence and possible role of ether-a-go-go-related gene 1 (ERG1) protein K(+) channels in gallbladder smooth muscle (GBSM). Transcripts encoding ERG1 were detected in human, mouse, and guinea pig GBSM, and ERG1 immunoreactivity was observed in GBSM cells. In intracellular voltage recordings, addition of E-4031 (100 nM-1 microM) or cisapride (100 nM-2 microM) caused concentration-dependent excitation of guinea pig GBSM that was not affected by 500 nM TTX + 5 microM atropine, and E-4031 also depolarized the resting membrane potential. In muscle strip studies, E-4031 either induced phasic contractions or significantly increased the amplitude of phasic contractions in spontaneously active tissues (P = 0.001). E-4031 also potentiated bethanechol-induced contractions. In conclusion, ERG1 channels are expressed in the GBSM, where they play a role in excitation-contraction coupling probably by contributing to repolarization of the plateau phase of the action potential and to the resting membrane potential.

Comparison of the properties of CLCA1 generated currents and I(Cl(Ca)) in murine portal vein smooth muscle cells.

Calcium-activated chloride currents (I(Cl(Ca))) have been recorded in various smooth muscle cells but, to date, there has been no information as to the molecular nature of the channel underlying this conductance. We have characterised native I(Cl(Ca)) in freshly dispersed smooth muscle cells isolated from murine portal vein using whole-cell voltage clamp. I(Cl(Ca)) exhibited time-dependent activation at depolarised potentials and rapid deactivation upon repolarisation. The reversal potential of I(Cl(Ca)) was close to the theoretical equilibrium potential (E(Cl)) and was shifted by replacement of external Cl- by SCN- or isethionate. Dithiothreitol (DTT, 1 mM), a blocker of CLCA1, had no effect on the I(Cl(Ca)) current in myocytes. RT-PCR demonstrated the expression of mCLCA1 transcripts, but not mCLCA3 transcripts, in various murine smooth muscle cells including portal vein, as well as cardiomyocytes, and the levels of mCLCA1 transcriptional expression were quantified by real time quantitative RT-PCR. Stable transfection of HEK293 cells with the cDNA encoding mCLCA1 cloned from murine portal vein smooth muscle yielded a current with notable differences in Ca2+ sensitivity, channel kinetics and modulation by DTT from the native I(Cl(Ca)). However, there was some similarity in the pore properties and these data suggest that mCLCA1 alone does not comprise the Cl- channel in portal vein smooth muscle cells.

Carbon monoxide activates KCa channels in newborn arteriole smooth muscle cells by increasing apparent Ca2+ sensitivity of alpha-subunits.

Carbon monoxide (CO) is a gaseous vasodilator produced by many cell types, including endothelial and smooth muscle cells. The goal of the present study was to investigate signaling mechanisms responsible for CO activation of large-conductance Ca(2+)-activated K(+) (K(Ca)) channels in newborn porcine cerebral arteriole smooth muscle cells. In intact cells at 0 mV, CO (3 microM) or CO released from dimanganese decacarbonyl (10 microM), a novel light-activated CO donor, increased K(Ca) channel activity 4.9- or 3.5-fold, respectively. K(Ca) channel activation by CO was not blocked by 1-H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one (25 microM), a soluble guanylyl cyclase inhibitor. In inside-out patches at 0 mV, CO shifted the Ca(2+) concentration-response curve for K(Ca) channels leftward and decreased the apparent dissociation constant for Ca(2+) from 31 to 24 microM. Western blotting data suggested that the low Ca(2+) sensitivity of newborn K(Ca) channels may be due to a reduced beta-subunit-to-alpha-subunit ratio. CO activation of K(Ca) channels was Ca(2+) dependent. CO increased open probability 3.7-fold with 10 microM free Ca(2+) at the cytosolic membrane surface but only 1.1-fold with 300 nM Ca(2+). CO left shifted the current-voltage relationship of cslo-alpha currents expressed in HEK-293 cells, increasing currents 2.2-fold at +50 mV. In summary, data suggest that in newborn arteriole smooth muscle cells, CO activates low-affinity K(Ca) channels via a direct effect on the alpha-subunit that increases apparent Ca(2+) sensitivity. The optimal tuning by CO of the micromolar Ca(2+) sensitivity of K(Ca) channels will lead to preferential activation by signaling modalities, such as Ca(2+) sparks, which elevate the subsarcolemmal Ca(2+) concentration within this range.

Quantitative analysis by flow cytometry of interstitial cells of Cajal, pacemakers, and mediators of neurotransmission in the gastrointestinal tract.

BACKGROUND: Interstitial cells of Cajal (ICCs) are mesenchymal cells that play critical roles in gastrointestinal motility as electrical pacemakers and mediators of neuromuscular neurotransmission. Although depletions of ICCs have been implicated in several gastrointestinal motor disorders, quantification of these cells has been difficult due to their varied morphology, regionally changing network density, and overall scarcity. Our goal was to evaluate flow cytometry (FCM) for the enumeration of ICCs. METHODS: We identified murine ICCs in live gastrointestinal muscles or primary cell cultures grown in the presence or absence of stem cell factor (SCF)-expressing STO fibroblasts with fluorescent Kit (CD117) antibodies. Because this technique also labels resident macrophages nonspecifically, we identified the latter with additional fluorescent antibodies. Dispersed cells were analyzed by FCM. RESULTS: ICCs represented 1.63 +/- 0.17% of the total cell count in the distal stomach (n = 18 mice) and 5.85 +/- 0.84% in the proximal colon and 6.28 +/- 0.61% in the distal colon (n = 3 mice). In fundic muscles of W/WV mice (n = 5) that virtually lack ICCs, very few Kit+ cells were detected. FCM identified approximately 2.6- to 7.3-fold more Kit+ ICCs in small intestinal cell cultures grown on STO fibroblasts expressing membrane-bound SCF (n = 6) than in cultures stimulated with soluble SCF (n = 6). CONCLUSIONS: FCM is a sensitive and specific method for the unbiased quantification of ICCs.

Hypotonic activation of volume-sensitive outwardly rectifying chloride channels in cultured PASMCs is modulated by SGK.

The serum- and glucocorticoid-inducible kinase (SGK) is a serine/threonine protein kinase (PK) transcriptionally regulated by corticoids, serum, and cell volume. SGK regulates cell volume of various cells by effects on Na(+) and K(+) transport through membrane channels. We hypothesized a role for SGK in the activation of volume-sensitive osmolyte and anion channels (VSOACs) in cultured canine pulmonary artery smooth muscle cells (PASMCs). Intracellular dialysis through the patch electrode of recombinant active SGK, but not kinase-dead Delta60-SGK-K127M, heat-inactivated SGK, or active Akt1, partially activated VSOACs under isotonic conditions. Dialysis of active SGK before cell exposure to hypotonic medium significantly accelerated the activation kinetics and increased the maximal density of VSOAC current. Exposure of PASMCs to hypotonic medium (230 mosM) activated phosphatidylinositol 3-kinases (PI3Ks) and their downstream targets Akt/PKB and SGK but not PKC-epsilon. Inhibition of PI3Ks with wortmannin reduced the activation rate and maximal amplitude of VSOACs. Immunoprecipitated ClC-3 channels were phosphorylated by PKC-epsilon but not by SGK in vitro, suggesting that SGK may activate VSOACs indirectly. These data indicate that the PI3K-SGK cascade is activated on hypotonic swelling of PASMCs and, in turn, affects downstream signaling molecules linked to activation of VSOACs.

Mechanism of active repolarization of inhibitory junction potential in murine colon.

Enteric inhibitory responses in gastrointestinal (GI) smooth muscles involve membrane hyperpolarization that transiently reduce the excitability of GI muscles. We examined the possibility that an active repolarization mechanism participates in the restoration of resting membrane potential after fast inhibitory junction potentials (IJPs) in the murine colon. Previously, we showed these cells express a voltage-dependent nonselective cation conductance (NSCC) that might participate in active repolarization of IJPs. Colonic smooth muscle cells were impaled with micro-electrodes and voltage responses to nerve-evoked IJPs, and locally applied ATP were recorded. Ba2+ (500 muM), a blocker of the NSCC, slowed the rate of repolarization of IJPs. We also tested the effects of Ba2+, Ni2+, and mibefradil, all blockers of the NSCC, on responses to locally applied ATP. Spritzes of ATP caused transient hyperpolarization, and the durations of these responses were significantly increased by the blockers of the NSCC. We considered whether NSCC blockers might affect ATP metabolism and found that Ni2+ decreased ATP breakdown in colonic muscles. Mibefradil had no effect on ATP metabolism. Because both Ni2+ and mibefradil had similar effects on prolonging responses to ATP, it appears that restoration of resting membrane potential after ATP spritzes is not primarily due to ATP metabolism. Neurally released enteric inhibitory transmitter and locally applied ATP resulted in transient hyperpolarizations of murine colonic muscles. Recovery of membrane potential after these responses appears to involve an active repolarization mechanism due to activation of the voltage-dependent NSCC expressed by these cells.

ClC-3 is a fundamental molecular component of volume-sensitive outwardly rectifying Cl- channels and volume regulation in HeLa cells and Xenopus laevis oocytes.

Volume-sensitive osmolyte and anion channels (VSOACs) are activated upon cell swelling in most vertebrate cells. Native VSOACs are believed to be a major pathway for regulatory volume decrease (RVD) through efflux of chloride and organic osmolytes. ClC-3 has been proposed to encode native VSOACs in Xenopus laevis oocytes and in some mammalian cells, including cardiac and vascular smooth muscle cells. The relationship between the ClC-3 chloride channel, the native volume-sensitive osmolyte and anion channel (VSOAC) currents, and cell volume regulation in HeLa cells and X. laevis oocytes was investigated using ClC-3 antisense. In situ hybridization in HeLa cells, semiquantitative and real-time PCR, and immunoblot studies in HeLa cells and X. laevis oocytes demonstrated the presence of ClC-3 mRNA and protein, respectively. Exposing both cell types to hypotonic solutions induced cell swelling and activated native VSOACs. Transient transfection of HeLa cells with ClC-3 antisense oligonucleotide or X. laevis oocytes injected with antisense cRNA abolished the native ClC-3 mRNA transcript and protein and significantly reduced the density of native VSOACs activated by hypotonically induced cell swelling. In addition, antisense against native ClC-3 significantly impaired the ability of HeLa cells and X. laevis oocytes to regulate their volume. These results suggest that ClC-3 is an important molecular component underlying VSOACs and the RVD process in HeLa cells and X. laevis oocytes.

Contribution of Kv4 channels toward the A-type potassium current in murine colonic myocytes.

A rapidly inactivating K(+) current (A-type current; I(A)) present in murine colonic myocytes is important in maintaining physiological patterns of slow wave electrical activity. The kinetic profile of colonic I(A) resembles that of Kv4-derived currents. We examined the contribution of Kv4 alpha-subunits to I(A) in the murine colon using pharmacological, molecular and immunohistochemical approaches. The divalent cation Cd(2+) decreased peak I(A) and shifted the voltage dependence of activation and inactivation to more depolarized potentials. Similar results were observed with La(3+). Colonic I(A) was sensitive to low micromolar concentrations of flecainide (IC(50) = 11 microM). Quantitative PCR indicated that in colonic and jejunal tissue, Kv4.3 transcripts demonstrate greater relative abundance than transcripts encoding Kv4.1 or Kv4.2. Antibodies revealed greater Kv4.3-like immunoreactivity than Kv4.2-like immunoreactivity in colonic myocytes. Kv4-like immunoreactivity was less evident in jejunal myocytes. To address this finding, we examined the expression of K(+) channel-interacting proteins (KChIPs), which act as positive modulators of Kv4-mediated currents. Qualitative PCR identified transcripts encoding the four known members of the KChIP family in isolated colonic and jejunal myocytes. However, the relative abundance of KChIP transcript was 2.6-fold greater in colon tissue than in jejunum, as assessed by quantitative PCR, with KChIP1 showing predominance. This observation is in accordance with the amplitude of the A-type current present in these two tissues, where colonic myocytes possess densities twice that of jejunal myocytes. From this we conclude that Kv4.3, in association with KChIP1, is the major molecular determinant of I(A) in murine colonic myocytes.

Characterization of the A-type potassium current in murine gastric antrum.

A-type currents are rapidly inactivating potassium currents that operate at subthreshold potentials. A-type currents have not been reported to occur in the phasic muscles of the stomach. We used conventional voltage-clamp techniques to identify and characterize A-type currents in myocytes isolated from the murine antrum. A-type currents were robust in these cells, with peak current densities averaging 30 pA pF(-1) at 0 mV. These currents underwent rapid inactivation with a time constant of 83 ms at 0 mV. Recovery from inactivation at -80 mV was rapid, with a time constant of 252 ms. The A-type current was blocked by 4-aminopyridine (4-AP) and was inhibited by flecainide, with an IC(50) of 35 microM. The voltage for half-activation was -26 mV, while the voltage of half-inactivation was -65 mV. There was significant activation and incomplete inactivation at potentials positive to -60 mV, which is suggestive of sustained current availability in this voltage range. Under current-clamp conditions, exposure to 4-AP or flecainide depolarized the membrane potential by 7-10 mV. In intact antral tissue preparations, flecainide depolarized the membrane potential between slow waves by 5 mV; changes in slow waves were not evident. The effect of flecainide was not abolished by inhibiting enteric neurotransmission or by blocking delayed rectifier and ATP-sensitive K(+) currents. Transcripts encoding Kv4 channels were detected in isolated antral myocytes by RT-PCR. Immunocytochemistry revealed intense Kv4.2- and Kv4.3-like immunoreactivity in antral myocytes. These data suggest that the A-type current in murine antral smooth muscle cells is likely to be due to Kv4 channels. This current contributes to the maintenance of negative resting membrane potentials.