RhoA GTPase switch controls Cx43-hemichannel activity through the contractile system

ATP-dependent paracrine signaling, mediated via the release of ATP through plasma membrane-embedded hemichannels of the connexin family, coordinates a synchronized response between neighboring cells. Connexin 43 (Cx43) hemichannels that are present in the plasma membrane need to be tightly regulated to ensure cell viability. In monolayers of bovine corneal endothelial cells (BCEC),Cx43-mediated ATP release is strongly inhibited when the cells are treated with inflammatory mediators, in particular thrombin and histamine. In this study we investigated the involvement of RhoA activation in the inhibition of hemichannel-mediated ATP release in BCEC. We found that RhoA activation occurs rapidly and transiently upon thrombin treatment of BCEC. The RhoA activity correlated with the onset of actomyosin contractility that is involved in the inhibition of Cx43 hemichannels. RhoA activation and inhibition of Cx43-hemichannel activity were both prevented by pre-treatment of the cells with C3-toxin as well as knock down of RhoA by siRNA. These findings provide evidence that RhoA activation is a key player in thrombin-induced inhibition of Cx43-hemichannel activity. This study demonstrates that RhoA GTPase activity is involved in the acute inhibition of ATP-dependent paracrine signaling, mediated by Cx43 hemichannels, in response to the inflammatory mediator thrombin. Therefore, RhoA appears to be an important molecular switch that controls Cx43 hemichannel openings and hemichannel-mediated ATP-dependent paracrine intercellular communication under (patho)physiological conditions of stress.

Induction of a novel cation current in cardiac ventricular myocytes by flufenamic acid and related drugs

BACKGROUND AND PURPOSE

Interest in non-selective cation channels has increased recently following the discovery of transient receptor potential (TRP) proteins, which constitute many of these channels.

EXPERIMENTAL APPROACH

We used the whole-cell patch-clamp technique on isolated ventricular myocytes to investigate the effect of flufenamic acid (FFA) and related drugs on membrane ion currents.

KEY RESULTS

With voltage-dependent and other ion channels inhibited, cells that were exposed to FFA, N-(p-amylcinnamoyl)anthranilic acid (ACA), ONO-RS-082 or niflumic acid (NFA) responded with an increase in currents. The induced current reversed at +38 mV, was unaffected by lowering extracellular Cl(-) concentration or by the removal of extracellular Ca(2+) and Mg(2+), and its inward but not outward component was suppressed in Na(+)-free extracellular conditions. The current was suppressed by Gd(3+) but was resistant to 2-aminoethoxydiphenyl borate (2-APB) and to amiloride. It could not be induced by the structurally related non-fenamate anti-inflammatory drug diclofenac, nor by the phospholipase-A(2) inhibitors bromoenol lactone and bromophenacyl bromide. Muscarinic or alpha-adrenoceptor activation or application of diacylglycerol failed to induce or modulate the current.

CONCLUSIONS AND IMPLICATIONS

Flufenamic acid and related drugs activate a novel channel conductance, where Na(+) is likely to be the major charge carrier. The identity of the channel remains unclear, but it is unlikely to be due to Ca(2+)-activated (e.g. TRPM4/5), Mg(2+)-sensitive (e.g. TRPM7) or divalent cation-selective TRPs.

Inhibition of the calcium-activated chloride current in cardiac ventricular myocytes by N-(p-amylcinnamoyl)anthranilic acid (ACA)

N-(p-amylcinnamoyl)anthranilic acid (ACA), a phospholipase A(2) (PLA(2)) inhibitor, is structurally-related to non-steroidal anti-inflammatory drugs (NSAIDs) of the fenamate group and may also modulate various ion channels. We used the whole-cell, patch-clamp technique at room temperature to investigate the effects of ACA on the Ca(2+)-activated chloride current (I(Cl(Ca))) and other chloride currents in isolated pig cardiac ventricular myocytes. ACA reversibly inhibited I(Cl(Ca)) in a concentration-dependent manner (IC(50)=4.2 μM, n(Hill)=1.1), without affecting the L-type Ca(2+) current. Unlike ACA, the non-selective PLA(2) inhibitor bromophenacyl bromide (BPB; 50 μM) had no effect on I(Cl(Ca)). In addition, the analgesic NSAID structurally-related to ACA, diclofenac (50 μM) also had no effect on I(Cl(Ca)), whereas the current in the same cells could be suppressed by chloride channel blockers flufenamic acid (FFA; 100 μM) or 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS;100 μM). Besides I(Cl(Ca)), ACA (50 μM) also suppressed the cAMP-activated chloride current, but to a lesser extent. It is proposed that the inhibitory effects of ACA on I(Cl(Ca)) are PLA(2)-independent and that the drug may serve as a useful tool in understanding the nature and function of cardiac anion channels.

Intramolecular loop/tail interactions are essential for connexin 43-hemichannel activity

Connexin-assembled gap junctions (GJs) and hemichannels coordinate intercellular signaling processes. Although the regulation of connexins in GJs has been well characterized, the molecular determinants controlling connexin-hemichannel activity are unresolved. Here we investigated the regulation of Cx43-hemichannel activity by actomyosin contractility and intracellular [Ca(2+)] ([Ca(2+)](i)) using plasma membrane-permeable TAT peptides (100 μM) designed to interfere with interactions between the cytoplasmic loop (CL) and carboxy-terminal (CT) in primary bovine corneal endothelial cells and HeLa, C6 glioma, and Xenopus oocytes ectopically expressing Cx43. Peptides corresponding to the last 10 CT aa (TAT-Cx43CT) prevented the inhibition of Cx43-hemichannel activity by contractility/high [Ca(2+)](i), whereas a reverse peptide (TAT-Cx43CTrev) did not. These effects were independent of zonula occludens-1, a cytoskeletal-associated Cx43-binding protein. In contrast, peptides corresponding to CL (TAT-L2) inhibited Cx43-hemichannel responses, whereas a mutant peptide (TAT-L2(H126K/I130N)) did not inhibit. In these assays, TAT-Cx43CT acted as a scaffold for TAT-L2 and vice versa, a finding supported by surface plasmon resonance measurements. Loop/tail interactions appeared essential for Cx43-hemichannel activity, because TAT-Cx43CT restored the activity of nonfunctional hemichannels, consisting of either Cx43 lacking the C-terminal tail (Cx43(M239)) or intact Cx43 ectopically expressed in Xenopus oocytes. We conclude that intramolecular loop/tail interactions control Cx43-hemichannel activity, laying the basis for developing hemichannel-specific blockers.

Reduced intercellular communication and altered morphology of bovine corneal endothelial cells with prolonged time in cell culture

PURPOSE

Mechanical stimulation induces intercellular Ca(2 +) waves in the corneal endothelium. The extent of the wave propagation is dependent on the activity of gap junctions, hemichannels, and ectonucleotidases. To further establish the use of a cell culture model to investigate intercellular communication, in this study, we have characterized the changes in the Ca(2 +) wave propagation in bovine corneal endothelial cells with prolonged time in culture.

MATERIALS AND METHODS

Freshly isolated BCEC were cultured for a short term (8 to 14 days; referred to as "short term") and a long term (21 to 30 days; referred to as "long term"). Cell surface area and size were measured by confocal microscopy and flow cytometry, respectively. Calcium wave propagation was assayed by imaging spread of the Ca(2 +) waves elicited by mechanical stimulation. ATP release was assayed using Luciferin-Luciferase bioluminescence technique.

RESULTS

Cells cultured for a long term showed larger surface area and size compared to those cultured for a short term, but a reduced spread of the Ca(2 +) wave. Exposure to exogenous apyrases, which can rapidly hydrolyze extracellular ATP, reduced the spread of the Ca(2 +) wave in both groups. The fractional decrease, however, was smaller in cells cultured for a long term. Exposure to ARL-67156 to inhibit the ectonucleotidases led to a larger enhancement of the active area in cells cultured for a long term. However, the active areas of the two groups were not significantly different in the presence of the drug. Furthermore, ATP release in response to mechanical stimulation was lower in cells cultured for a long term in the absence of ARL-67156 but not in its presence.

CONCLUSIONS

BCEC cultured for a long term show an increase in cell surface area and cell size similar to the effect of aging in human corneas. Moreover, the cells cultured for a long term showed a reduced ATP-dependent paracrine intercellular communication, largely due to an increase in the activity of the ectonucleotidases.

Inhibition of the magnesium-sensitive TRPM7-like channel in cardiac myocytes by nonhydrolysable GTP analogs: involvement of phosphoinositide metabolism

BACKGROUND/AIMS

A magnesium-inhibited, transient receptor potential melastatin 7 (TRPM7)-like channel is expressed in cardiac cell membranes. The role and regulation of this channel by intracellular nucleotides and membrane components remain unclear.

METHODS

We used the whole-cell voltage-clamp technique in pig isolated ventricular myocytes to investigate the effect of non-hydrolysable guanine nucleotides.

RESULTS

The TRPM7-like current, induced by intracellular dialysis with low [Mg(2+)], remained stable when the intracellular solution contained GTP. Substituting GTP by GTP-gamma-S or Gp-pNp, but not GDP-beta-S, induced a run-down of the current. Under dialysis with GTP-gamma-S, inhibiting phospholipase C by edelfosine or intracellularly adding exogenous phosphatidylinositol-4,5-bisphosphate (PIP(2)) decreased run-down, whereas extracellularly applying carbachol and phenylephrine accelerated it. Pretreatment of cells with pertussis toxin did not prevent the run-down induced by GTP-gamma-S.

CONCLUSION

Guanine nucleotides can modulate cardiac TRPM7-like channels via a mechanism linked to G proteins and to PIP(2) metabolism.

Adenosine opposes thrombin-induced inhibition of intercellular calcium wave in corneal endothelial cells

PURPOSE

In corneal endothelial cells, intercellular Ca(2+) waves elicited by a mechanical stimulus involve paracrine intercellular communication, mediated by ATP release via connexin hemichannels, as well as gap junctional intercellular communication. Both mechanisms are inhibited by thrombin, which activates RhoA and hence results in myosin light chain phosphorylation. This study was conducted to examine the effects of adenosine, which is known to oppose thrombin-induced RhoA activation, thereby leading to myosin light chain dephosphorylation, on gap junctional intercellular communication and paracrine intercellular communication in cultured bovine corneal endothelial cells.

METHODS

An intercellular Ca(2+) wave was elicited by applying a mechanical stimulus to a single cell in a confluent monolayer. The area of Ca(2+) wave propagation was measured by [Ca(2+)](i) imaging using the fluorescent dye Fluo-4. Gap junctional intercellular communication was assessed by fluorescence recovery after photobleaching. Activity of hemichannels was determined by uptake of the hydrophilic dye Lucifer yellow in a Ca(2+)-free medium containing 2 mM EGTA. Adenosine triphosphate (ATP) release in response to mechanical stimulation was measured using the luciferin-luciferase technique. Gap26, a connexin mimetic peptide, was used to block hemichannels.

RESULTS

Exposure to thrombin or TRAP-6 (a selective PAR-1 agonist) inhibited the Ca(2+) wave propagation by 70%. Pretreatment with adenosine prevented this inhibitory effect of thrombin. NECA (a potent A2B agonist) and forskolin, agents known to elevate cAMP in bovine corneal endothelial cells, also suppressed the effect of thrombin. The A1 receptor agonist CPA failed to inhibit the effect of thrombin. Similar to the effects on Ca(2+) wave propagation, adenosine prevented the thrombin-induced reduction in the fluorescence recovery during photobleaching experiments. Furthermore, pretreatment with adenosine prevented both thrombin and TRAP-6 from blocking the uptake of Lucifer yellow in a Ca(2+)-free medium. However, adenosine was ineffective in overcoming the Gap26-mediated block of Lucifer yellow uptake. In consistence with Lucifer yellow uptake through hemichannels, the thrombin-induced inhibition of ATP release was overcome by pretreatment with adenosine.

CONCLUSIONS

Adenosine prevents thrombin-induced inhibition of hemichannel-mediated paracrine intercellular communication and of gap junctional intercellular communication. The mechanism involves an increase in cAMP, which results in inhibition of RhoA and a subsequent decrease in myosin light chain phosphorylation. Since myosin light chain dephosphorylation causes a decrease in contractility of the actin cytoskeleton, the results suggest possible effects of the actin cytoskeleton on gap junctions and connexin hemichannels.

Thrombin inhibits intercellular calcium wave propagation in corneal endothelial cells by modulation of hemichannels and gap junctions

PURPOSE

Thrombin, a serine protease, breaks down the barrier integrity of corneal endothelial cells by phosphorylation of the regulatory light chain of myosin II (myosin light chain; MLC), which induces contractility of the actin cytoskeleton. This study was undertaken to investigate the effect of thrombin on gap junctional (GJIC) and paracrine (PIC) intercellular communication in cultured bovine corneal endothelial cells (BCECs).

METHODS

An intercellular Ca(2+) wave, a form of cell-cell communication, was elicited by applying a mechanical stimulus to a single cell in a confluent monolayer. Changes in [Ca(2+)](i) were imaged by fluorescence microscopy with a fluorescent calcium indicator, and the images were used to calculate the area reached by the Ca(2+) wave (active area). GJIC was assessed by fluorescence recovery after photobleaching (FRAP). Activity of hemichannels was assayed by lucifer yellow (LY) uptake and also by adenosine triphosphate (ATP) release by using the luciferin-luciferase technique.

RESULTS

RT-PCR showed transcripts for PAR-1 and -2 receptors, but not for PAR-4 receptors. Immunocytochemistry showed thrombin-sensitive PAR receptors as well as trypsin-sensitive PAR-2 receptors. Both thrombin and the selective PAR-1 agonist TRAP-6 reduced the active area of the Ca(2+) wave. These agents also reduced the fluorescence recovery in FRAP experiments. The effect of thrombin on the Ca(2+) wave was inhibited by a peptide antagonist of PAR-1, but not by a PAR-4 antagonist. Pretreatment with ML-7 (an MLCK inhibitor), Y-27632 (a Rho kinase inhibitor) or chelerythrine (a PKC inhibitor) prevented the effect of thrombin on the Ca(2+) wave. Activation of PAR-1 did not affect the Ca(2+) wave propagation in cells pretreated with Gap26, which blocks hemichannels. However, PAR-1 activation decreased the active area in cells pretreated with Gap27, which inhibits gap junctions. Thrombin abolished enhancement of the Ca(2+) wave propagation by ARL-67156 (inhibitor of ecto-ATPases). The effect of the PAR-1 agonists on the Ca(2+) wave was not detectable in cells pretreated with exogenous apyrases.

CONCLUSIONS

Thrombin inhibits intercellular Ca(2+) wave propagation in BCECs. This effect is due to activation of PAR-1 receptors and involves MLC phosphorylation by MLCK-, PKC- and Rho kinase-sensitive pathways. Thrombin mainly inhibits the ATP-mediated PIC pathway, and also reduces GJIC to a lesser extent.

Gap junctional intercellular communication in bovine corneal endothelial cells

Gap junctions and/or paracrine mediators, such as ATP, mediate intercellular communication (IC) in non-excitable cells. This study investigates the contribution of gap junctions toward IC during propagation of Ca(2+) waves in cultured bovine corneal endothelial cells (BCEC) elicited by applying a point mechanical stimulus to a single cell in a confluent monolayer. Changes in [Ca(2+)](i) were visualized using the fluorescent dye Fluo-4. The area reached by the Ca(2+) wave, called the active area (AA), was determined as a measure of efficacy of IC. RT-PCR and Western blotting showed expression of Cx43, a major form of connexin, in BCEC. In scrape-loading (using lucifer yellow) and fluorescence recovery after photobleaching (FRAP; using carboxyfluorescein) protocols, significant dye transfer of the hydrophilic dyes was evident indicating functional gap junctional IC (GJIC) in BCEC. Gap27 (300 microM), a connexin mimetic peptide that blocks gap junctions formed by Cx43, reduced the fluorescence recovery in FRAP experiments by 19%. Gap27 also reduced the active area of the Ca(2+) wave induced by point mechanical stimulation from 73,689 microm(2) to 26,936 microm(2), implying that GJIC contribution to the spread of the wave is at least approximately 63%. Inhibitors of ATP-mediated paracrine IC (PIC), such as a combination of apyrase VI and apyrase VII (5U/ml each; exogenous ATPases), suramin (200 microM; P2Y antagonist), or Gap26 (300 microM; blocker of Cx43 hemichannels) reduced the active area by 91%, 67%, and 55%, respectively. Therefore, estimating the contribution of GJIC from the residual active area after PIC inhibition appears to suggest that GJIC contributes no more than approximately 9% towards the active area of the Ca(2+) wave. Gap27 did not affect the enhancement in active area induced by ARL-67156 (200 microM, ectonucleotidase inhibitor), ATP release induced by point mechanical stimulation, and zero [Ca(2+)](o)-induced lucifer yellow uptake, indicating that the peptide has no influence on PIC. Exposure to Gap27 in the presence of PIC inhibitors led to a significant further inhibition of the Ca(2+) wave. The finding that the residual active area after inhibition of PIC by apyrases was much smaller than the reduction of the active area by Gap27, provides evidence for interaction between GJIC and PIC. These findings together suggest that functional gap junctions are present in BCEC, that both GJIC and PIC contribute significantly to IC, and that the two pathways interact.

ATP and PIP2 dependence of the magnesium-inhibited, TRPM7-like cation channel in cardiac myocytes

The Mg(2+)-inhibited cation (MIC) current (I(MIC)) in cardiac myocytes biophysically resembles currents of heterologously expressed transient receptor potential (TRP) channels, particularly TRPM6 and TRPM7, known to be important in Mg(2+) homeostasis. To understand the regulation of MIC channels in cardiac cells, we used the whole cell voltage-clamp technique to investigate the role of intracellular ATP in pig, rat, and guinea pig isolated ventricular myocytes. I(MIC), studied in the presence or absence of extracellular divalent cations, was sustained for >or=50 min after patch rupture in ATP-dialyzed cells, whereas in ATP-depleted cells I(MIC) exhibited complete rundown. Equimolar substitution of internal ATP by its nonhydrolyzable analog adenosine 5'-(beta,gamma-imido)triphosphate failed to prevent rundown. In ATP-depleted cells, inhibition of lipid phosphatases by fluoride + vanadate + pyrophosphate prevented I(MIC) rundown. In contrast, under similar conditions neither the inhibition of protein phosphatases 1, 2A, 2B or of protein tyrosine phosphatase nor the activation of protein kinase A (forskolin, 20 microM) or protein kinase C (phorbol myristate acetate, 100 nM) could prevent rundown. In ATP-loaded cells, depletion of phosphatidylinositol 4,5-bisphosphate (PIP(2)) by prevention of its resynthesis (10 microM wortmannin or 15 microM phenylarsine oxide) induced rundown of I(MIC). Finally, loading ATP-depleted cells with exogenous PIP(2) (10 microM) prevented rundown. These results suggest that PIP(2), likely generated by ATP-utilizing lipid kinases, is necessary for maintaining cardiac MIC channel activity.

ATP release through connexin hemichannels in corneal endothelial cells

PURPOSE

Intercellular Ca(2+) wave propagation is a distinct form of cell-cell communication. In corneal endothelial cells, intercellular Ca(2+) wave propagation evoked by a point mechanical stimulus (PMS) is partially mediated by adenosine triphosphate (ATP) release and subsequent activation of P2Y receptors. This study was conducted to investigate the possibility that extrajunctional connexons (hemichannels) play a role in ATP release during PMS-induced Ca(2+) wave propagation in bovine corneal endothelial cells (BCECs).

METHODS

A Ca(2+) wave was evoked by a PMS applied to a single cell in a monolayer of cultured BCECs. Changes in [Ca(2+)](i) in the mechanically stimulated cell (MS cell) and in the neighboring (NB) cells were visualized by fluorescence imaging using the Ca(2+)-sensitive dye Fluo-4. From these images, the maximum normalized fluorescence (NF), the percentage of responsive cells (%RC), and the total area of cells reached by the Ca(2+) wave (active area [AA], in square micrometers) were calculated. Intercellular dye transfer, generally attributed to gap junctional coupling, was assessed by fluorescence recovery after photobleaching (FRAP) using 6-carboxyfluorescein diacetate. Opening of hemichannels was investigated by measuring cellular uptake of the fluorescent dye Lucifer yellow, which is known to permeate hemichannels. ATP release was measured by luciferin-luciferase bioluminescence.

RESULTS

Flufenamic acid (FFA; 50 microM) and the connexin mimetic peptide Gap26 (300 microM), known blockers of hemichannels, significantly reduced AA in confluent monolayers as well as in contact-free cells. Neither FFA nor Gap26 affected the FRAP, indicating that reduction in AA of the PMS-induced wave by these agents is not due to a block of gap junction channels. FFA as well as Gap26 inhibited the increase in AA of the wave that was observed when cells were pretreated with the ectonucleotidase inhibitor ARL-67156 (100 microM). These findings suggest that the hemichannel blockers reduce the Ca(2+) wave propagation by inhibiting ATP release. Consistent with this finding, PMS or exposure to Ca(2+)-free solution (a maneuver known to induce the opening of hemichannels) led to ATP release; moreover, the release was inhibited by the hemichannel blockers. The extracellular ATP levels in response to both PMS and extracellular Ca(2+) removal were strongly enhanced by ARL-67156, and this effect was inhibited by FFA as well as by Gap26. Moreover, pretreatment of subconfluent BCEC monolayers with FFA or Gap26 inhibited the uptake of Lucifer yellow induced by removal of extracellular Ca(2+).

CONCLUSIONS

Hemichannels contribute to ATP release on mechanical stimulation in BCECs. The released ATP contributes to propagation of the Ca(2+) wave.

Novel Mutation in the Per-Arnt-Sim Domain of KCNH2 Causes a Malignant Form of Long-QT Syndrome

Background— It has been proposed that the highest risk for cardiac events in patients with long-QT syndrome subtype 2 (LQT2) is related to mutations in the pore region of the KCNH2 channel. It has also been suggested that a subpopulation of LQT2 patients may benefit from pharmacological therapy with modified KCNH2 channel–blocking drugs.

Methods and Results— In a large LQT2 family (n=33), we have identified a novel nonpore missense mutation (K28E) in the Per-Arnt-Sim (PAS) domain of the KCNH2 channel associated with a malignant phenotype: One third of the suspected gene carriers experienced a major cardiac event. Wild-type and K28E-KCNH2 channels were transiently transfected in HEK293 cells. For the mutant channel, whole-cell patch-clamp analysis showed a reduced current density, a negative shift of voltage-dependent channel availability, and an increased rate of deactivation. Western blot analysis and confocal imaging revealed a trafficking deficiency for the mutant channel that could be rescued by the K + channel blocker E-4031. In cells containing both wild-type and mutant channels, deactivation kinetics were normal. In these cells, reduced current density was restored with E-4031.

Conclusions— Our data suggest that besides pore mutations, mutations in the PAS domain may also exhibit a malignant outcome. Pharmacological restoration of current density is promising as a mutation-specific therapy for patients carrying this trafficking-defective mutant.

ATP-dependent paracrine intercellular communication in cultured bovine corneal endothelial cells

PURPOSE

Intercellular communication (IC) in nonexcitable cells is mediated through gap junctions and/or through the release of paracrine mediators. This study was conducted to investigate adenosine-5' triphosphate (ATP)-dependent paracrine IC in the propagation of Ca2+ waves in confluent monolayers of cultured bovine corneal endothelial cells (BCECs).

METHODS

A Ca2+ wave was induced by point mechanical stimulation (PMS) of a single cell by indentation with a glass micropipette (approximately 1 microm tip) for <1 second. Dynamic changes in [Ca2+]i in the mechanically stimulated (MS) cell and in the neighboring (NB) cells were visualized with a confocal microscope, using a fluorescent dye. Normalized fluorescence (NF), calculated as the ratio of the average fluorescence of a cell to the average under resting conditions, was used as a measure of [Ca2+]i. Expression of P2Y receptors and ecto-adenosine triphosphatases (ATPases) was investigated by RT-PCR. ATP release in response to PMS was measured by luciferin-luciferase (LL) bioluminescence.

RESULTS

BCECs subjected to PMS showed a transient [Ca2+]i increase. Under control conditions, the maximum NF in the MS cell occurred within 600 ms, and the fluorescence returned to baseline within 170 seconds. NB cells also presented a [Ca2+]i increase with a transient characterized by decreasing maximum NF and increasing latency as a function of the distance from the MS cell. These transients propagated as an intercellular Ca2+ wave to a distance of five or six NB cells away from the MS cell, covering areas (called active areas, AAs) up to 77,000 +/- 3,200 microm2 (N=21). The percentage of responsive cells (defined as cells showing maximum NF >1.1) decreased with increasing distance from the MS cell. The Ca2+ wave crossed cell-free lanes. Pretreatment of cells with the nonselective purinergic receptor antagonist suramin (200 microM), exogenous apyrases, which break down nucleotides (10 U/mL), or the PLC inhibitor U-73122 (10 microM) reduced the wave propagation, whereas the ecto-ATPase inhibitor ARL-67156 (100 microM) significantly enhanced it. ATP-dependent LL bioluminescence increased after PMS. RT-PCR showed mRNAs for P2Y1 and P2Y2 receptors and ecto-ATPases in BCECs.

CONCLUSIONS

PMS of BCECs induces release of ATP and a concomitant intercellular Ca2+ wave, even in the absence of direct cell-cell contacts. The AA of the wave is modulated by agents that affect P2Y receptor activity. Thus, PMS-induced intercellular Ca2+ wave propagation in BCECs involves ATP-dependent paracrine IC.

Magnesium-inhibited, TRPM6/7-like channel in cardiac myocytes: permeation of divalent cations and pH-mediated regulation

Cardiac tissue expresses several TRP proteins as well as a Mg2+ -inhibited, non-selective cation current (IMIC) that bears many characteristics of TRP channel currents. We used the whole-cell voltage clamp technique in pig and rat ventricular myocytes to characterize the permeation, blockage properties and regulation of the cardiac IMIC channels in order to compare them with TRP channels, in particular with Mg2+ -sensitive TRPM6 and TRPM7. We show that removing extracellular divalent cations unmasks large inward and outward monovalent currents, which can be inhibited by intracellular Mg2+. Inward currents are suppressed upon replacing extracellular Na+ by NMDG+. Divalent cations block monovalent IMIC and, at 10-20 mm, carry measurable currents. Their efficacy sequence in decreasing outward IMIC (Ni2+ = Mg2+ > Ca2+ > Ba2+) and in inducing inward IMIC (Ni2+ >> Mg2+ = Ca2+ approximately Ba2+), and their permeabilities calculated from reversal potentials are similar to those of TRPM6 and TRPM7 channels. The trivalent cations Gd3+ and Dy3+ also block IMIC in a voltage-dependent manner (delta = 0.4-0.5). In addition they inhibit the inward current carried by divalent cations. IMIC is regulated by pH. Decreasing or increasing extracellular pH decreased and increased IMIC, respectively (pH0.5 = 6.9, nH = 0.98). Qualitatively similar results were obtained on IMIC in rat basophilic leukaemia cells. These effects in cardiac myocytes were absent in the presence of high intracellular buffering by 40 mm Hepes. Our results suggest that IMIC in cardiac cells is due to TRPM channels, most probably to TRPM6 or TRPM7 channels or to their heteromultimeres.

Intercellular Ca(2+)-transient propagation in normal and high glucose solutions in rat retinal epithelial (RPE-J) cells during mechanical stimulation

We investigated the effect of high glucose and modulation of protein kinase C (PKC) on the intercellular propagation of Ca(2+)-waves in a rat retinal pigment epithelial cell line (RPE-J cells) in order to compare its properties with the properties previously investigated in primary LE-RPE cells. The intercellular propagation of the Ca(2+)-waves in RPE-J cells was analyzed by fluorescence imaging confocal microscopy and fluorescence recovery after photobleaching (FRAP). In control conditions the maximal normalized fluorescence in the mechanically stimulated (MS) cell and the propagation towards the neighboring RPE-J cells were similar to LE-RPE cells. As in LE-RPE cells, the propagation was reduced by the gap junction (GJ) blocker halothane, and FRAP experiments demonstrated the presence of functional GJ coupling. Similar to the effect in LE-RPE cells, the propagation of the Ca(2+)-transient was reduced by 25 mM glucose. However, unlike LE-RPE cells, the neighboring RPE-J cells presented a Ca(2+)-rise of amplitude similar to that in normal glucose levels. PKC activation with 1 microM PMA for 30 min resulted in inhibition of the Ca(2+)-wave propagation, which could be overcome by PKC downregulation as in LE-RPE cells. Cells grown for 72 h in a high glucose solution in which PKC activity was downregulated, did not develop the inhibitory effect on Ca(2+)-wave propagation that was induced by elevated glucose levels. However, the effects were not as pronounced as in LE-RPE cells. We concluded that despite marked similarities, the transduction and the modulation of intercellular propagation of the Ca(2+)-transients in RPE-J cells are not identical to the mechanisms in primary LE-RPE cells.

Effects of hyperglycemia and protein kinase C on connexin43 expression in cultured rat retinal pigment epithelial cells

Previous results demonstrated that the intercellular communication mediated by gap junctions in retinal pigment epithelial (RPE) cells from the healthy Long Evans (LE) rat strain is higher than that from the dystrophic Royal College of Surgeons (RCS) rat strain. We examined connexin (Cx) expression in both cell types. At the mRNA level, a qualitatively similar expression pattern was found whereby Cx26, Cx32, Cx36, Cx43, Cx45 and Cx46 were all expressed. At the protein level, only Cx43 and Cx46 were detected. Expression of both isoforms was higher in LE-RPE as compared to RCS-RPE by a factor of 1.25 and 2 respectively. Phosphorylation of Cx43 was increased upon activation of protein kinase C (PKC) by 1 microM phorbol 12-myristate 13-acetate (PMA). The phosphorylation status was not changed in hyperglycemic conditions, but this treatment strongly decreased total Cx43 levels to about 75 and 40% (in LE-RPE and RCS-RPE cells respectively) of the control level in LE-RPE cells. This decrease could be overcome by PKC downregulation. These results demonstrate that PKC activation and hyperglycemic conditions have different effects on Cx43 and that PKC is involved in the metabolic pathway induced by hyperglycemic conditions.

[Intra- and intercellular Ca(2+)-signal transduction]

Calcium is one of the most universal signal-transduction elements in a large variety of cells ranging from bacteria to specialized neurons. Ca2+ acts as a second messenger controlling such processes as secretion, cell differentiation or signal transmission. In order to be able to execute their specific functions and to react in a coordinated way to stimuli, multicellular organs need a precise orchestration of cellular functions. For this purpose cells have developed different forms of intercellular communication (IC). In this study we investigated a number of mechanisms of intracellular propagation and IC using experiments with fluorescent Ca(2+)-indicators, confocal microscopy and digital imaging techniques. In ROS 17/2.8 osteoblasts, retinal pigment epithelial cells (RPE) and CPAE endothelial cells, a small mechanical deformation of the plasma membrane results in a transient increase of free cytoplasmic Ca2+ concentration ([Ca2+]i). This Ca(2+)-rise starts at the site of stimulation and propagates concentrically to neighboring cell layers. The intracellular Ca(2+)-wave in RPE and ROS cells is caused by Ca(2+)-influx followed by Ca(2+)-release from the intracellular stores and by intercellular propagation of the Ca(2+)-wave. The [Ca2+]i-transient upon mechanical stimulation of LLC-PK1 epithelial cells, C6 glioma cells and MLO-Y4 osteocytes was limited and/or variable. In CPAE cells only the intracellular release is important for evoking the Ca(2+)-transient, and is followed by IC. IC can occur via gap junctions (GJ) consisting of membrane-spanning proteins, connexins (Cx). It was demonstrated that IC and GJ in RPE and ROS cells can be reversibly blocked by gap-junction inhibitors such as heptanol or halothane. We demonstrated important differences in modulation of gap junctional communication between these cell types. While in RPE cells stimulation of PKC activity was able to inhibit IC, this was not the case in ROS cells. We screened LE-RPE cDNA via PCR using specific primers for different connexins and found no effect of high glucose solutions, which cause decreased intercellular communication, on the Cx-isoforms expressed. Cx43 is the only Cx-isoform present at the protein level for which Western blot analysis revealed the presence of different forms corresponding to different phosphorylated states. Increased phosphorylation of Cx43 was only seen after direct PKC activation by PMA, but not by indirect PKC activation by high glucose levels. The decreased communication by high glucose concentrations was however associated by a decreased expression of cellular Cx43 to about 3/4 of the level in control conditions. High glucose concentrations therefore decrease Cx43 at the protein level via a PKC effect that appears to be independent of the direct activation of PKC by phorbolesters. Mechanical stimulation did not evoke intercellular Ca(2+)-waves in LLC-PK1 epithelial cells, C6 glioma cells and MLO-Y4 osteocytes. In CPAE-endothelial cells, the contribution of gap junctions to IC following mechanical stimulation is negligible, and modulation of gap junctions via phosphorylation or high glucose solutions is absent. Perfusion experiments and pharmacological studies demonstrated that IC following mechanical stimulation of these cells occurs via release of an extracellular mediator. Our experiments provide strong evidence in favor of purinergic agonists as mediators, such as ATP but mainly ADP. In conclusion we can say that cells contain a wide spectrum of mechanisms for intra- and intercellular communication, and that widely different mechanisms can evoke the same phenomenon of intra- and intercellular Ca(2+)-waves.

Intercellular communication upon mechanical stimulation of CPAE- endothelial cells is mediated by nucleotides

Intercellular Ca(2+)-signaling, after mechanical stimulation of calf pulmonary artery endothelial cells (CPAE), was investigated with fluorescence video imaging. Mechanical stimulation evoked an intracellular Ca(2+)-response in the mechanically stimulated (MS) cell, proceeding to the neighboring (NB) cells as a Ca(2+)-wave. The intercellular propagation of the Ca(2+)-wave was unaffected by the gap junction blockers halothane or heptanol. Therefore the intercellular communication (IC) pathway of the Ca(2+)-wave in CPAE cells does not depend on gap junctional communication but is most likely mediated by release of an extracellular mediator. Continuous unilateral flow experiments confirmed the presence of a diffusible mediator: the Ca(2+)-rise in upstream NB cells is significantly lower than in control experiments. After desensitization of purinergic receptors by pretreatment of CPAE cells with ATP (100mM), UTP (100 microM), 2MeSATP (100microM) or ADPbS (100 microM), the propagation of the intercellular Ca(2+)-wave upon mechanical stimulation was significantly inhibited. Also suramin (200 and 400 microM), a non-specific purinergic receptor blocker, reduced the IC. Application of the nucleotidase apyrase VI (10U/ml), which has a high ATPase/ADPase ratio, enhanced Ca(2+)-signaling and IC. In contrast, apyrase VII (10U/ml), which has a high ADPase/ATPase ratio, significantly depressed the propagation of the intercellular Ca(2+)-wave upon mechanical stimulation. Our experiments therefore demonstrate that the IC, evoked by a mechanical stimulus of CPAE cells, is mediated via release of nucleotides in the extracellular space. The data indicate that the diffusible messenger, responsible for the propagation of a Ca(2+)-wave, is mainly ADP or a combination of ADP/ATP.

Intra- and intercellular Ca(2+)-transient propagation in normal and high glucose solutions in ROS cells during mechanical stimulation

Experiments using confocal laser microscopy on the rat osteosarcoma cell line (ROS 17/2.8) indicate that mechanical stimulation elicits pronounced [Ca2+](i)transients in the MS (mechanically stimulated) cell, which then propagate to the NB (neighbouring) cells. Experiments with Ca(2+)-free solutions or gadolinium suggest that Ca(2+)-influx through stretch-sensitive channels is required. When intracellular stores are depleted with thapsigargin, mechanical stimulation was able to evoke a Ca(2+)transient of reduced amplitude that disappeared entirely after subsequent blocking of Ca(2+)-influx. Heptanol inhibited intercellular propagation of the Ca(2+)transient, demonstrating the involvement of gap junctions in the propagation of the Ca(2+)transient in ROS cells. PKC activation has only a small inhibitory effect, while inhibition of PKC or tyrosine kinase was ineffective. PKA activation reduced the amplitude of the [Ca2+](i)-rise in NB cells, and decreased the percentage of responsive cells. Cells grown in 50mM glucose for 72h presented only a very limited decrease of the Ca(2+)-rise during mechanical stimulation in the MS and NB cells compared to control conditions. PKC downregulation in high glucose did not modulate this effect. The results of our experiments indicate that PKC or sustained high glucose concentrations do not affect gap junctional communication in ROS cells, while activation of PKA has an inhibitory effect. This might indicate that osteoblastic dysfunction in diabetes could be directly related to the high glucose concentrations and not to inhibition of the intercellular communication.

Mechanism of intracellular Ca(2+)-wave propagation elicited by mechanical stimulation in cultured endothelial CPAE cells

Intra- and intercellular Ca(2+)-signaling during mechanical stimulation in calf pulmonary artery endothelial cells (CPAE) was investigated with digital fluorescence microscopy. Mechanical stimulation of a CPAE cell in a Ca(2+)-containing solution revealed a rise of the free intracellular Ca(2+)-concentration ([Ca(2+)](i)) in the mechanically stimulated cell (MS) proceeding to the neighboring (NB) cells as an intercellular Ca(2+)-wave. Experiments in Ca(2+)-free solution, containing 2mM EGTA, demonstrated that a detectable [Ca(2+)](i)-transient in the MS cell is not always a requisite for intercellular communication (IC). The Ca(2+)-wave propagation was not affected by changes in membrane potential and was not mediated by voltage-dependent Ca(2+)-channels. Ca(2+)-influx through the Ni(2+)-sensitive Ca(2+)-pathway occurred in the MS as could be assessed by Mn(2+)-quenching experiments. The intra- and intercellular Ca(2+)-wave was triggered by the release of thapsigargin-sensitive intracellular Ca(2+)-stores. Phospholipase C (PLC) inhibition by U73122 reduced the Ca(2+)-amplitude of the MS cell and almost completely inhibited the IC, indicating that the Ca(2+)-release in the MS and NB cells is PLC/inositol 1,4,5-trisphosphate (IP(3)) mediated.

The effect of external pH on the delayed rectifying K+ current in cardiac ventricular myocytes

The effects of extracellular pH (pHe) on the delayed rectifying K+ current iKr in rabbit ventricular myocytes were studied using the whole-cell-clamp technique. Since a variety of results have been reported on the effect of pH on expressed hERG channels, our aim was to investigate the effects of pH on iKr channels in their native environment. iKr is reduced by extracellular acidification and its deactivation is faster. Extracellular acidification results in a marked shift of the steady-state activation curve to more positive potentials, while alkalinization does not produce a significant shift. E1/2= - 11.3 mV, -20.2 mV, -21.4 mV at pHe 6.5, 7.4, 8.5 respectively; the slope factor is 6.2 mV, and is not affected by pHe. Deactivation of iKr is biexponential, with time constants of the order of 0.5 s and 10 s at -50 mV. Both time constants decrease with external acidification. Also the contribution of the fast component to the total amplitude becomes larger with acidification. Acidification also decreases the fully activated iKr current. Our experiments demonstrate that extracellular acidification reduces iKr by increasing the rate of deactivation, causing a shift of the voltage dependence of activation and producing a voltage-dependent block of the fully activated iKr current.

Intra- and intercellular Ca2+ signaling in retinal pigment epithelial cells during mechanical stimulation

The intercellular communication (IC) was investigated between cultured rat retinal pigment epithelial (RPE) cells isolated from Long-Evans (LE) or dystrophic Royal College of Surgeons (RCS) rats and grown in solutions containing normal and high glucose concentrations, or after modulation of protein kinase C (PKC). This was performed by studying the conduction of the free Ca2+-concentration ([Ca2+]i) wave elicited by mechanical stimulation and by analyzing the fluorescence recovery after photobleaching (FRAP). Mechanical stimulation of LE-RPE cells triggers Ca2+ influx, mediated by stretch-sensitive cation channels followed by intracellular Ca2+ release. A regenerative [Ca2+]i wave was found with a lower propagation rate in RCS-RPE cells. This rate could be increased by PKC down-regulation. Mechanical stimulation caused a [Ca2+]i increase in the mechanically stimulated (MS) cell followed after a delay by a [Ca2+]i rise in the adjacent cell layers. The intercellular [Ca2+]i wave propagation could be blocked by gap junction blockers such as halothane or PKC activation. An inhibition of the [Ca2+]i-wave propagation similar to that induced by halothane could be observed in cells grown in solutions containing 14 mM or higher concentrations of glucose. PKC down-regulated cells grown in glucose-rich medium did not develop this inhibitory effect on gap junction communication (GJC). FRAP experiments confirmed that the observed changes were consistent with a PKC-mediated inhibitory effect of high glucose concentrations on GJC.

Mechanism of L- and T-type Ca2+ channel blockade by flunarizine in ventricular myocytes of the guinea-pig

Flunarizine is a substance known to block voltage-dependent Ca2+ channels in smooth muscle and neuronal cells. Reports on the effect on voltage-dependent cardiac Ca2+ channels are however sparse. Therefore, the mechanism of action of flunarizine on two types of voltage-dependent cardiac Ca2+ channels, the L- and T-type, in single ventricular myocytes of the guinea-pig was investigated using the whole-cell voltage clamp technique. Both channel types can be blocked by flunarizine in a time-, frequency-, voltage-, Ca(2+)-, and proton-dependent way. While the overall mechanism of action on cardiac myocytes is similar to the one reported for other cell types, we found that cardiomyocytes are less susceptible to block (Kd 3.3-11 mM). We also describe a complete analysis of the different components of block, together with evidence for open channel state block and drug-induced changes in channel gating. These findings provide new insights into the mechanism of action of flunarizine on voltage-dependent Ca2+ channels.

[Ca2+]i-dependent membrane currents in guinea-pig ventricular cells in the absence of Na/Ca exchange

Transient inward currents (Iti) during oscillations of intracellular [Ca2+] ([Ca2+]i) in ventricular myocytes have been ascribed to Na/Ca exchange. We have investigated whether other Ca2+-dependent membrane currents contribute to Iti in single guinea-pig ventricular myocytes, by examining membrane currents during [Ca2+]i oscillations and during caffeine-induced Ca2+ release from the sarcoplasmic reticulum in the absence of Na+. Membrane currents were recorded during whole-cell voltage clamp and [Ca2+]i measured simultaneously with fura-2. In the absence of Na/Ca exchange, i.e., with Li+, Cs+ or N-methyl-D-glucamine (NMDG+) substituted for Na+, the cell could be loaded with Ca2+ by repetitive depolarizations to +10 mV, resulting in spontaneous [Ca2+]i oscillations. During these oscillations, no inward currents were seen, but instead spontaneous Ca2+ release was accompanied by a shift of the membrane current in the outward direction at potentials between -40 mV and +60 mV. This [Ca2+]i-dependent outward current shift was not abolished when NMDG+ was substituted for internal monovalent cations, nor was it sensitive to substitution of external Cl-. It was however, sensitive to the blockade of ICa by verapamil. These results suggest that the transient outward current shift observed during spontaneous Ca2+ release represents [Ca2+]i-dependent transient inhibition of ICa. Similarly, during the [Ca2+]i transients induced by brief caffeine (10 mM) applications, we could not detect membrane currents attributable to a Ca2+-activated nonselective cation channel, or to a Ca2+-activated Cl- channel; however, transient Ca2+-dependent inhibition of ICa was again observed. We conclude that neither the Ca2+-activated nonselective cation channel nor the Ca2+-activated Cl- channel contribute significantly to the membrane currents during spontaneous [Ca2+]i oscillations in guinea-pig ventricular myocytes. However, in the voltage range between -40 mV and +60 mV Ca2+-dependent transient inhibition of ICa will contribute to the oscillations of the membrane current.

Reversal of rectification and alteration of selectivity and pharmacology in a mammalian Kv1.1 potassium channel by deletion of domains S1 to S4

1. A possible relation between the family of inwardly rectifying K+ channels and the Shaker superfamily of K+ channels was investigated using a deletion mutant (DelS1-S4) of a delayed rectifier Kv1.1 (RCK1) K+ channel. 2. The mutant DelS1-S4 was made by eliminating the sequence coding for transmembrane domains S1 to S4 of the Kv1.1 K+ channel, and re-ligating the sequence coding for the cytoplasmic amino terminus to transmembrane domain S5. Microelectrode voltage-clamp and patch-clamp experiments were performed on Xenopus laevis oocytes after injection of in vitro transcribed mRNA coding for mutant and wild-type channels. 3. The lack of transmembrane domains S1 to S4 converts a depolarization-activated wild-type Kv1.1 K+ channel with outward rectification into a hyperpolarization-activated channel with inward rectification. Although the pore region of the deletion mutant is identical to the wild-type channel, the mutant channel is a non-selective cation channel and is characterized by an altered pharmacology profile.

Effects of intracellular sodium and hydrogen ion on the sodium activated potassium channel in isolated patches from guinea pig ventricular myocytes

OBJECTIVE

The Na+ activated K+ channel (IK(Na)) may be activated during ischaemia when the intracellular Na+ concentration is raised. As ischaemia is also associated with intracellular acidification, the influence of intracellular pH on this K+ channel was investigated.

METHODS

The effects of intracellular Na+ and H+ on the IK(Na) channel were investigated in isolated patches from guinea pig ventricular myocytes by the patch clamp technique.

RESULTS

Increase of intracellular Na+ increased the open probability of the channel. Intracellular acidification had no effect on the single channel conductance, but significantly decreased the open probability of the channel in the pH range 7.5-6.5. The effect of intracellular pH on open probability was about the same in a wide range of intracellular Na+ concentrations. The lower open probability induced by acidification seemed to be caused by prolonged closed times.

CONCLUSIONS

Because the effects of increased intracellular Na+ and decreased pH on open probability are opposite, it is suggested that the IK(Na) channel might be important under conditions of raised intracellular Na+ with relatively unchanged intracellular pH. Consequently, it is hypothesised that this channel may be involved in adaptation of action potential duration at high heart rate and in action potential shortening in the border zone of regional ischaemic areas.

Mode of regulation by G protein of the ATP-sensitive K+ channel in guinea-pig ventricular cell membrane

1. The effect of G protein activation on the ATP-sensitive K+ (K+ATP) channel was examined in inside-out patches from guinea-pig ventricular myocytes. At low (0.3 mM) intracellular ATP concentration ([ATP]i) in the bathing solution, in the absence of agonists in the pipette, guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) or AlF4- applied to the intracellular side of the patch membrane gradually activated the K+ATP channel. The activation by GTP gamma S was irreversible, although high [ATP]i could completely close the channel. 2. In ATP-free media GTP gamma S did not increase further the activity of the fully active channel, and was unable to reactivate the channel in the non-operative state after rundown. [ATP]i-channel activity curves constructed before and after GTP gamma S application demonstrated that GTP gamma S shifts the half-inhibitory [ATP]i from 19.5 to 110 microM without changing the Hill coefficient. 3. When acetylcholine or adenosine was included in the pipette, intracellular GTP reversibly activated the K+ATP channel which was partially inhibited by [ATP]i. 4. These results indicate that G protein may stimulate myocardial K+ATP channels in the operative state by reducing the potency of ATP inhibition. The possible coupling of the G protein with muscarinic as well as A1 adenosine receptors is suggested.

Acetylcholine-mediated K+ channel activity in guinea-pig atrial cells is supported by nucleoside diphosphate kinase

We studied the role of nucleoside diphosphate kinase (NDPK) in acetylcholine-mediated muscarinic K+ channel activation in inside-out patches of guinea-pig atrial cells. NDPK-catalysed activation of the muscarinic K+ channels by adenosine triphosphate-Mg2+ (ATP-Mg2+) is not prevented by occupation of the muscarinic receptor [by acetylcholine (ACh) or atropine], nor by uncoupling of the receptor from the G protein by pertussis-toxin-catalysed adenosine diphosphate (ADP)-ribosylation of GK. In the presence of ACh, addition of 0.1 mM guanosine triphosphate (GTP) after activation of the channels by 4 mM ATP alone resulted in a moderate increase of channel activity (in contrast to block in the absence of ACh): NDPK-mediated direct transphosphorylation is uncoupled by the G nucleotide but agonist-induced guanosine diphosphate (GDP)-to-GTP exchange takes over activation of the channels. Moreover, ACh-dependent channel stimulation was possible in inside-out patches while ATP and GDP were present in the bathing solution (in contrast to the complete absence of channel activation in the absence of ACh). This indicates that NDPK synthesizes sufficient GTP to support channel activation by exchange. Hence, it is postulated that the main functional role of NDPK under physiological conditions is to provide a local supply of GTP (using GDP and ATP) in the immediate vicinity of the G protein, thereby maintaining a high local GTP/GDP ratio and ensuring adequate receptor-mediated regulation of muscarinic K+ channel activity.

Intracellular protons inhibit inward rectifier K+ channel of guinea-pig ventricular cell membrane

The effect of intracellular protons (Hi+) on the inward rectifier K+ channel of the guinea-pig ventricular cell membrane was examined, using the patch-clamp technique. The inward single-channel current was recorded in "inside-out" and "outside-out" patch configurations, while the pH of the solution perfusing the intra- and extracellular side, respectively, was varied. Low intracellular pH (pHi), but not low extracellular pH, inhibited the channel. Low pHi reduced the unit amplitude, which was about 20% smaller at pHi 6.0 than that at pHi 7.4 at every voltage tested. The slope conductance decreased from 41.7 pS at pHi 7.4 to 35.1 pS at pHi 6.0. Low pHi also reduced the channel activity without apparent voltage dependence. The concentration/response curve indicated the half-maximum inhibition at pHi 6.11 and a Hill coefficient of 2.52. Lowering the pHi from 7.4 to 6.0 did not affect the distributions of the open times and the closed times below 50 ms, while the time constant of the histogram constructed from closings longer than 50 ms was approximately doubled. These results indicate that the inward rectifier K+ channel in ventricular myocytes is inhibited by H+ from the intracellular side. This might contribute to the depolarization of the resting membrane potential induced by intracellular acidosis during myocardial ischaemia.

Membrane-bound nucleoside diphosphate kinase activity in atrial cells of frog, guinea pig, and human

Muscarinic K+ channels in inside-out patches of atrial cells from guinea pig or rabbit can be activated by Mg(2+)-ATP in the absence of acetylcholine and GTP or GDP. The ATP-dependent activation involves a phosphorylation and is postulated to be due to the association of a membrane-bound nucleoside diphosphate kinase (NDPK) with the G protein GK: direct phosphorylation of the GK-bound GDP into GTP, catalyzed by NDPK, would result in activation of the G protein and, hence, activation of the channels. The aim of this study was to identify the presence of NDPK activity in atrial membranes by investigating the phosphate transfer between tritium-labeled nucleotides. We show that frog, guinea pig, and human atrial membranes contain a substantial NDPK activity since they catalyze the conversion from [3H]GDP+nucleoside triphosphate (NTP or NTP gamma S) to [3H]GTP (or [3H]GTP gamma S), from [3H]ADP+NTP to [3H]ATP, and from [3H]GTP+nucleoside diphosphate (NDP) to [3H]GDP. The phosphate transfer rates for the [3H]GDP+ATP to [3H]GTP conversion are 1.8, 0.5, and 2.4 mumol inorganic phosphate formation/mg per 10 minutes at 37 degrees C in frog, guinea pig, and human, respectively. The order of substrate efficiency for different NTPs was ATP greater than ITP approximately equal to GTP greater than UTP greater than CTP, which parallels the efficiency of these nucleotides in their activation of the muscarinic K+ channels. Addition of other nucleotides blocked the transphosphorylation reaction, indicating that the NTP-NDP conversion mechanism is aspecific, as is expected for an NDPK-catalyzed reaction. In conclusion, the data support the concept of NDPK involvement in the atrial muscarinic signal transduction cascade.

Effects of the enantiomers of disopyramide and its major metabolite on the electrophysiological characteristics of the guinea-pig papillary muscle

Disopyramide, a Class Ia antiarrhythmic drug, is clinically used as a racemic mixture; R(-)disopyramide and S(+)disopyramide. The major metabolite in man is desisopropyldisopyramide: R(-)desisopropyldisopyramide and S(+)desisopropyldisopyramide. The effects of the four compounds were compared on the electrophysiological characteristics of the guinea-pig papillary muscle using the standard microelectrode technique. At an external K+ concentration of 5.4 mmol/l and a stimulation frequency of 1 Hz, S(+)disopyramide (20 mumols/l) increased action potential duration (APD) by more than 18%, while it was diminished by 6% in the presence of R(-)disopyramide. Resting membrane potential amounted to -87.1 +/- 0.5 mV (n = 14) and -85.6 +/- 1.2 mV (n = 10), respectively. Also a small but significant difference in effect on the maximal rate of depolarization was observed, R(-)disopyramide being more potent, related with a slower recovery of the maximal rate of depolarization. The enantiomers of the metabolite appeared to be three times less potent than those of the parent drug in their effect on the maximal rate of depolarization. The characteristics of the enantiomers of the metabolite correlated with those of the parent drug: also the R(-)enantiomer was more potent in decreasing the maximal rate of depolarization and caused more shortening of the action potential than the S(+)enantiomer. Time constants for onset and recovery of/from rate dependent block of the maximal rate of depolarization were dependent upon the external K+ concentration, both for the enantiomers of the parent drug and those of the metabolite. Onset slowed down while recovery accelerated when external K+ was increased. Time constants were lower for the metabolite. When stimulation interval was shortened, the effect on the maximal rate of depolarisation increased. Only for the metabolite statistical significant stereoselective differences were observed at all stimulation intervals. The effects on the action potential duration were dependent upon stimulation interval; for all enantiomers the action potential duration tended to be relatively (% of control) higher at short stimulation intervals than at large stimulation intervals. The effect on the maximal rate of depolarization was also voltage dependent, but no significant differences were observed between the enantiomers, for the parent drug as well as for the metabolite.

Atrial membranes contain nucleoside diphosphate kinase (NDPK) activity: its role in regulation of muscarinic K+ channels

Guinea pig or rabbit atrial muscarinic K+ channels in cell-free inside-out patches can be activated in the absence of extracellular agonist and cytoplasmic G nucleotides by intracellular ATP-Mg2+. This ATP-dependent activation is compatible with the existence of a membrane-bound nucleoside diphosphate kinase (NDPK), which directly phosphorylates GK-bound GDP. We show that this ATP-dependent activation is also possible in frog atrial cells, and that atrial membranes of frog and guinea pig contain NDPK activity. The relative order of different nucleoside triphosphates (NTPs) as phosphate donors parallels the observed efficiency of these nucleotides in activation of the channels. Thus, atrial membranes contain NDPK activity, which can be responsible for the ATP-dependent activation of muscarinic K+ channels, seen in patches of atrial cells. Under physiological conditions, NDPK can act as a GTP supply in the immediate vicinity of the G protein to ensure reliable signal transduction.

Differential electrophysiologic and inotropic effects of phenylephrine in atrial and ventricular heart muscle preparations from rats

Stimulation of alpha 1-adrenoceptors evokes a different pattern of inotropic responses in atrial and ventricular heart muscle preparations from rats. The inotropic effects are accompanied by different changes in membrane potential. In an attempt to clarify the question whether or to which extent these events are causally related, the effects of phenylephrine on force of contraction, transmembrane potential, Ca2+ current (ICa) and K+ currents were comparatively studied in either tissue. In atrial preparations, phenylephrine 10 mumol/l caused an increase in force of contraction, a marked prolongation of the action potential duration and a depolarization of the membrane at rest. In the ventricle, however, the addition of phenylephrine 10 mumol/l produced first a decline in force of contraction associated with a hyperpolarization of the membrane and a reduction in the action potential duration. These changes were followed by an increase in force of contraction and a slight prolongation of the action potential, whereas the resting membrane potential remained increased. The hyperpolarization was eliminated in the presence of ouabain 100 mumol/l. In enzymatically isolated atrial and ventricular myocytes, the whole-cell voltage clamp technique was used to study membrane currents on exposure to phenylephrine. Phenylephrine 30 mumol/l did not affect the magnitude of ICa in either cell type. Transient and steady state K+ outward currents, however, were significantly diminished to a similar extent in atrial and in ventricular myocytes. It is concluded that the positive inotropic effect of alpha 1-adrenoceptor stimulation in the rat atrium is related to an increase in action potential duration and a decrease in resting membrane potential due to a decrease in K+ currents.(ABSTRACT TRUNCATED AT 250 WORDS)

Flunarizine inhibits a high-threshold inactivating calcium channel (N-type) in isolated hippocampal neurons

The action of flunarizine on the high-threshold inactivating calcium channel (N-type) in hippocampal neurons of the rat was investigated using the whole-cell voltage clamp technique. Flunarizine reduced the currents at all test potentials, without shifting the peak of the current-voltage relationship along the voltage-axis. The drug did not affect the activation curve, but drastically decreased the slope conductance in the linear region of the current-voltage relationship. Block of the current by flunarizine occurred in a use-dependent way. Flunarizine was without effect when applied intracellulary, and the onset of action, when applied extracellularly, was slow (range of minutes). The Kd for the block by flunarizine obtained after 6 repetitive depolarizations at 0.2 Hz (pulse duration 150 ms) from -90 mV to 0 mV was 0.8 microM. In conclusion, we present electrophysiological evidence that flunarizine blocks the high-threshold inactivating Ca channel of hippocampal neurons of the rat. We discuss the possibility that flunarizine might inhibit neuronal transmitter release by means of this effect.

Stereoselective effects of the enantiomers of bupivacaine on the electrophysiological properties of the guinea-pig papillary muscle

1 Direct myocardial effects of the S(-)- and R(+)-enantiomers of bupivacaine were compared in the guinea-pig isolated papillary muscle by recording transmembrane action potentials with the standard microelectrode technique. 2 In 5.4 mM K+, at a stimulation rate of 1 Hz, the maximal rate of depolarization (Vmax) was reduced to 59.9 +/- 1.4% (n = 10) of control (mean +/- s.e.mean) in the presence of 10 microM R(+)-bupivacaine, and to 76.7 +/- 1.2% (n = 14) in the presence of the same concentration of S(-)-bupivacaine. This was mainly due to a difference in time constant at which block dissipated during the diastolic period. Recovery was slower in the presence of R(+)-bupivacaine. The slower recovery in the presence of R(+)-bupivacaine resulted also in a more pronounced frequency-dependent block of Vmax. 3 Time constants for recovery from use-dependent block became significantly faster for both enantiomers on hyperpolarization, while no significant change was observed at depolarization. At all membrane potentials recovery was slower in the presence of R(+)-bupivacaine. 4 The action potential duration (APD) was shortened to a greater extent in the presence of R(+)-bupivacaine over a large range of stimulation frequencies. 5 We conclude that S(-)-bupivacaine affects Vmax and APD in the guinea-pig papillary muscle less than the R(+)-enantiomer at different rates of stimulation and resting membrane potentials.

Dual effect of the local anaesthetic penticainide on the Na+ current of guinea-pig ventricular myocytes

1. The effect of the local anaesthetic penticainide (2-alkyl-(4-dialkylamino)-2-pyridyl-butyramide) on macroscopic and single-channel sodium current (INa) of guinea-pig ventricular myocytes was studied with the patch-clamp technique in the cell-attached and inside-out mode. 2. Penticainide (3-60 microM) affected the INa from the outside as well as from the cytoplasmic side. 3. Peak INa was reduced by penticainide at concentrations of 6, 30 and 60 microM, and this decrease of peak INa was more pronounced when the holding potential was more negative. Despite a reduction of peak INa, the time integral of the Na+ current was not changed (60 microM) or was even enhanced (6 microM), and this enhancement became more pronounced at less negative potentials. 4. At a concentration of 3 microM, penticainide increased both the time integral of the current and peak INa. 5. The shape of the steady-state current-voltage relationship and the steady-state inactivation curve were not influenced by penticainide. 6. In pronase-modified inside-out patches penticainide reduced INa at the beginning of a depolarizing pulse to the same extent as at the end (400 ms), indicating a very fast blockade of the bursting Na+ channel. The most prominent effects on pronase-modified single-channel INa were an increase of sweeps without activity, and a fast, repeatedly occurring block (flickering) of the bursting Na+ channel. 7. The amplitude of the unitary current was not altered. 8. It is concluded that penticainide blocks the open Na+ channel, and in addition shows the macroscopic inactivation.

Ionic currents activated during hyperpolarization of single right atrial myocytes from cat heart

Whole-cell recording techniques were used on single right atrial myocytes to study the ionic currents that may be responsible for the diverse diastolic voltage characteristics of atrial tissue. Ionic currents were activated by hyperpolarizing voltage pulses negative to -30 mV. In general, four different types of cells were identified based primarily on the ionic currents elicited during hyperpolarization. The first cell type exhibited an inward current that decayed with time at more negative voltages, reversed near the potassium equilibrium potential, inwardly rectified at more positive voltages, increased in elevated extracellular potassium, and was blocked by 3 mM barium or 10 mM cesium. This current was identified as the potassium current iK1. A second cell type exhibited a time-dependent inward current that increased at more negative voltages, had an activation range between -50 and -110 mV, had a reversal potential of -26 mV, and was blocked by 3 mM cesium. This current was identified as an if current. A third cell type exhibited an inward current that initially decayed and then became more inward with time. Barium (3 mM) abolished the initial inward current and revealed a time-dependent increasing inward current that was blocked by 3 mM cesium. This current was composed of both the iK1 and if currents. A fourth cell type exhibited only small time-independent leak currents in response to hyperpolarization. These results indicate that individual cells within the right atrium are electrophysiologically heterogeneous with respect to the types of ionic channels present in their sarcolemmal membranes. This specialization in ionic currents partially explains the diverse diastolic voltage characteristics and functional properties of atrial tissue.

Effects of the enantiomers of flecainide on action potential characteristics in the guinea-pig papillary muscle

The enantiomers of flecainide, a Class Ic antiarrhythmic agent, were tested in the guinea-pig papillary muscle using the standard microelectrode technique. In 5.4 mM external K+ and at a stimulation frequency of 1 Hz, significant differences were observed in the effect of the enantiomers on maximal rate of depolarization, action potential amplitude and action potential duration. Maximal rate of depolarization and action potential amplitude were more suppressed in the presence of (+)flecainide. Maximal rate of depolarization was reduced to 54.4 +/- 1.4% (n = 23) (mean +/- S.E.M.) of maximum in the presence of 7.2 microM (+)flecainide and to 60.5 +/- 1.1% (n = 24) in the presence of the same concentration of (-)flecainide. The stimulation interval used had a pronounced influence on maximal rate of depolarization for both enantiomers. At almost all stimulation intervals tested, block was larger for (+)flecainide than for (-)flecainide. When the stimulation interval was shortened from 10 sec to 0.25 sec, the maximal rate of depolarization was reduced from 89.8 +/- 0.8% (n = 13) to 37.4 +/- 2.3% (n = 10) of the control in the presence of 7.2 microM of (+)flecainide and from 91.7 +/- 0.8% (n = 14) to 44.9 +/- 1.6% (n = 12) when the same concentration of (-)flecainide was used. The effect on maximal rate of depolarization was also voltage-dependent. For both enantiomers, inactivation curves, recorded at a frequency of 0.6/min, were shifted to more negative potentials. There was no significant difference in magnitude of shift between the two enantiomers.

Depolarization-induced influx of sodium in response to phenylephrine in rat atrial heart muscle

1. The effects of alpha 1-adrenoceptor stimulation on transmembrane potential, currents and ion fluxes were investigated in multicellular preparations and/or single cells obtained from the left atrium of rat hearts. 2. In multicellular preparations, phenylephrine caused a concentration-dependent positive inotropic effect, an increase in action potential duration, and a decrease in resting potential; the effects were antagonized by phentolamine. 3. In the presence of phenylephrine (100 mumol/1), two levels of resting potential were observed when the preparations were, alternately, electrically stimulated or kept at rest (-74 +/- 1 mV during activity and -62 +/- 4 mV at rest; mean +/- S.E.M.; n = 9). 4. In resting preparations, the depolarization in response to phenylephrine was eliminated in low-Na+ solution (12 mmol/l) and antagonized by tetrodotoxin (10 mumol/l). 5. The phenylephrine-induced depolarization was also seen in nominally Ca(2+)-free solution and in the presence of (-)-devapamil (1 mumol/l). 6. The alkylating agent N-ethyl-maleimide (30 mumol/l) abolished the depolarizing effect of phenylephrine. 7. Phorbol 12,13-dibutyrate (10 mumol/l) also abolished the depolarizing effect of phenylephrine. 8. Phenylephrine caused a significant increase of 22Na+ uptake in resting preparations and of 45Ca2+ uptake in beating preparations. 9. The depolarizing effect of phenylephrine was also observed in single atrial myocytes. Steady-state membrane currents in response to 500 ms depolarizing and hyperpolarizing voltage clamp steps were decreased. The cross-over of I-V curves under control and test conditions was at about -70 mV. The effects of phenylephrine were antagonized in the presence of phentolamine. 10. After suppression of potassium currents by substitution of CsCl for internal and external KCl ([KCl]o), phenylephrine had no effect on membrane currents. 11. In conclusion, we presume the following sequence of events in response to phenylephrine in rat atrial heart muscle. First, the stimulation of alpha 1-adrenoceptors decreases the K+ conductance thereby producing a depolarization in the presence of an inward current. Second, the change of the membrane potential in the depolarizing direction induces a TTX-sensitive Na+ window current which further propels the depolarization. Third, the increase in Na+ influx may increase Ca2+ influx by activating the Na(+)-Ca2+ exchange in mechanism. The greater influx of Ca2+ may contribute to the positive inotropic effect in response to phenylephrine.

Non-selective cation and dysfunctional chloride channels in the apical membrane of nasal epithelial cells cultured from cystic fibrosis patients

Chloride channels and non-selective cation channels in the apical membranes of cultured nasal epithelial cells from three cystic fibrosis patients were investigated with the patch-clamp technique. Outwardly rectifying chloride channels were found in 31% of the inside-out patches, but activity of this channel was never observed in cell-attached patches, even after stimulation with adrenaline. In 30% of the patches with chloride channels, activation occurred immediately after excision. Most of the channels, however, activated only after a membrane depolarization of +40 to +120 mV. Once activated, the chloride channels were indistinguishable from those in nasal epithelial cells of control patients. Amiloride-insensitive, calcium- and voltage-dependent, non-selective cation channels were present in 11% of the cell-attached and 43% of the cell-free patches and could not be distinguished from those in controls. The cystic fibrosis chloride channel defect is conserved in cultured nasal epithelial cells, while a non-selective cation channel is apparently not affected.

A combined study of sodium current and T-type calcium current in isolated cardiac cells

Sodium currents (INa) and T-type calcium currents (ICa,T) of isolated guinea-pig ventricular myocytes were recorded using the whole-cell voltage-clamp technique. Separation of the two currents was obtained by using the difference current method in the presence and absence of 2 mM extracellular Na (Nao). Time to peak and the time constant of inactivation of. INa were about 5 times faster than that of ICa,T (test potential -30 mV), and ICa,T had an activation range positive to -50 mV, were inactivated at -50 mV, and their current/voltage relationships peaked at -22.3 +/- 1.8 mV (n = 18) and -29.3 +/- 0.5 mV (n = 18) respectively, with a reversal potential of +40.3 +/- 4 mV (n = 18) and +30 +/- 10 mV (n = 18), respectively [2 mM Nao; 5.4 mM extracellular Ca (Cao)]. INa was blocked by 30 microM tetrodotoxin (TTX), 500 microM lidocaine, partly inhibited by 1 mM amiloride, but not affected by 100 microM nickel (Ni). ICa,T was neither affected by 30 microM TTX nor 500 microM lidocaine, but blocked by 100 microM Ni, 1 mM amiloride, 10 microM R 56865 and use-dependently reduced by 5 microM flunarizine. Adenosine (500 microM) affected neither INa nor ICa,T, whereas 1 microM isoprenaline did not affect ICa,T, but slightly increased INa. Our results demonstrate that the characteristics of ICa,T are not affected by the concomitant activation of INa, and vice versa. We conclude that ICa,T are not Ca currents through Na channels.

Mechanism of cardiac T-type Ca channel blockade by amiloride

Whole cell clamp experiments were used to study the mechanism of action of amiloride on cardiac T-type Ca channels in guinea pig ventricular myocytes. Two hundred fifty microM amiloride blocked the T-type Ca channel for approximately 50%, whereas this concentration did not suppress the L-type Ca channel. The Kd value for the block of the T-type Ca channel was 233 microM and the Hill coefficient was 1.1. The drug showed a rapid onset of action and a quick wash out with complete reversibility. Amiloride blocked the T-type Ca channel without frequency-dependency, i.e., block was established at the holding potential (-90 mV) without being dependent on activation and inactivation of the channel. Amiloride reduced the amplitude of the T-type Ca current at all potentials without changing steady-state activation and inactivation. Amiloride did not affect the T-type Ca current when the drug was applied intracellularly via the pipette solution. In summary, amiloride blocked the T-type Ca channel in a channel state- and voltage-independent way.

Outward-rectifying chloride channels in cultured adult and fetal human nasal epithelial cells

The patch-clamp technique was used to characterize ion channels in the apical membranes of cultured human nasal epithelial cells, dissociated from fetal nasal mucosa and from adult nasal polyps. Outward-rectifying chloride channels were found in 4.3% of the cell-attached patches from fetal cells (n = 258) and in 3.1% of the patches from adult cells (n = 320). After excision the number of patches containing active chloride channels increased threefold to 13% of the patches from the fetal cells and 10% from adult cells. The single-channel conductance at 0 mV in symmetrical 150 mM NaCl solutions was 24.3 +/- 0.9 pS (n = 28) and 26.0 +/- 1.2 pS (n = 30), respectively, in adult and fetal cells and showed outward rectification in the potential range from -80 to +80 mV. In fetal cells as well as in adult cells the channels were anion selective, and were almost impermeable for larger anions and monovalent cations. In cell-free patches the channels were Ca2+ independent. In most of the channels the open probability was voltage independent and high (+/- 0.86); in 20% of the channels, however, the open probability increased with depolarization. In conclusion, fetal nasal epithelial cells contain chloride channels in their apical membranes with single-channel properties and regulatory mechanisms similar to those found in cells from adults.

Three different potassium channels in human atrium. Contribution to the basal potassium conductance

We applied the cell-attached and inside-out patch-clamp technique under symmetrical isotonic potassium conditions on single human (and guinea pig) atrial cells. The human cells were isolated by a modified method to that described earlier. Our aim was twofold: 1) to study the single-channel characteristics of potassium channels in human atrial single cells, present under basal conditions (iK1 and iK(ATP] or when stimulated with 10(-5) M acetylcholine; and 2) to calculate the contribution of these three channel types to the total basal potassium conductance in human atrial cells, and to compare the results with data on guinea pig atrial cells under the same conditions. We found that in human cells 58% of the patches (n = 42/74) contained acetylcholine-sensitive potassium channels: their conductance was 42 +/- 1.2 pS and mean open time (tau o) was 1.7 +/- 0.5 msec. They showed sporadic openings in the absence of agonist, and activation by acetylcholine was G-protein dependent. In 16% of the patches (n = 7/44), adenosine (10(-4) M) activated the same channels, but the activity was lower than when stimulated by acetylcholine. In 18% of the patches (n = 9/51), an iK1 channel was present (conductance, 27 pS; tau o, 8.7 msec), whereas in the cell-attached mode, ATP-dependent channels were never seen. However, they were present in half of the inside-out patches on washout of ATPi (conductance, 73 pS; tau o, 1.4 msec). The basal potassium conductance (i.e., in the absence of any exogenous hormone or neurotransmitter) was mainly due to iK1 channels in both human and guinea pig cells, a finding that is in contrast with previous reports. However, the potassium current that is induced by acetylcholine is much higher in guinea pig than in human isolated cells; a fraction of it would suffice to fully determine the resting potassium conductance in guinea pig atrial cells, whereas it can play only a modulatory role in human cells. This difference could be important in species-specific autonomic modulation and antiarrhythmic drug action.

ATP-dependent activation of atrial muscarinic K+ channels in the absence of agonist and G-nucleotides

While opening of cardiac muscarinic K+ channels is mediated by a guanine nucleotide-binding protein, GK, and normally requires both ACh and cytosolic GTP, we demonstrate that in the absence of agonist and G-nucleotides guinea-pig atrial muscarinic K+ channels are activated by cytosolic ATP (K50 = 224 microM). This activation involves a phosphorylating reaction and is most probably related to a transphosphorylation by a nucleoside diphosphate kinase (NDPK) from ATP to GK-bound GDP. This ATP-induced response is completely inhibited by nanomolar concentrations of GDP or GTP, suggesting a G-nucleotide specific binding site on NDPK.

Identification of a voltage- and calcium-dependent non-selective cation channel in cultured adult and fetal human nasal epithelial cells

The apical membranes of cultured human nasal epithelial cells from adults and fetuses were investigated with the patch-clamp technique. Amiloride-insensitive, calcium- and voltage-dependent, non-selective cation channels were found in 4% of the cell-attached, and 18% of the inside-out and outside-out patches (n = 412). Multiple functional channels were present in more than 90% of these patches, with a mean of 3.9 channels per patch (n = 55). The current-voltage relationship can be described by the Goldman equations and the single channel conductance was 20.1 +/- 0.3 pS (n = 29) in adult and 20.7 +/- 0.4 pS (n = 44) in fetal cells in symmetrical 150 mM NaCl solutions. The channels were highly selective for cations: P Na/P Cl was 30 in adult and 45 in fetal experiments. They were equally permeable for K+ and Na+, somewhat less for Cs+, and impermeable for choline+ and tetraethylammonium+. The open probability was voltage dependent: it increased approximately 2-fold with 30 mV depolarization in the potential range from -60 mV to +60 mV. The channels were activated by Ca2+ concentrations of about 10(-4) M at the cytoplasmic side, but were insensitive to extracellular Ca2+ and amiloride (10(-4) M). The non-selective cation channels found in apical membranes of cultured fetal nasal epithelial cells were not different from the adult ones.

Single-channel analysis of a large conductance channel in peroxisomes from rat liver

Native membranes and Triton X-100 solubilized integral membrane proteins of peroxisomes from rat liver were reconstituted in liposomes. With the patch clamp technique, a channel was detected with a conductance of 420 +/- 30 pS and a PK/PC1 of about 3. The channel in native membrane fractions was weakly voltage dependent, residing most of the time in an open state with the possibility to shift to different substates. Solubilization changed the kinetic properties. The channel became strongly voltage dependent and closed at voltages negative to -20 mV. The estimated diameter of the channel is about 1.7 nm and might explain, at least partially, the permeability properties of the peroxisomal membrane.

Properties of the block of single Na+ channels in guinea-pig ventricular myocytes by the local anaesthetic penticainide

1. The blocking mechanism of a disopyramide derivative Penticainide (2-alkyl-(4-(dialkylamino)-2-)pyridyl-butyramide) on cardiac Na+ channels has been studied using single-channel analysis in cell-attached and inside-out patches from guinea-pig ventricular cells. Penticainide was applied in concentrations between 3 and 100 microM. The S-enantiomer of DPI 201-106 (5 microM) was used as a tool to slow the inactivation, improve the time resolution by prolonging the mean open time, and to increase the number of openings per depolarization of the channel. 2. When in cell-attached or inside-out patch experiments up to 100 microM-Penticainide was applied to the bathing solution no significant effect was observed on the probability of the channel being open or on the mean open time. 3. In cell-attached patch experiments with 100 microM-Penticainide in the pipette, the open-state probability of the Na+ channel was much lower than in the absence of Penticainide. No significant changes were found in the potential of half-maximum activation or in the slope of the activation curve. The maximum open-state probability was reduced by a factor five in the presence of Penticainide. The single-channel conductance was not affected by the drug. 4. The decrease in the probability of the channel being open was mainly due to an increased probability of observing sweeps with no activity ('nulls'). 5. A dramatic relief from the block was observed when pauses were interposed into the normal activation pattern, or when the pacing rate was reduced. 6. The distribution of the open times of the bursting Na+ channel could be fitted with two exponentials. Penticainide in the patch pipette reduced the mean open time. Also the contribution of the number of long openings to the total number of openings was reduced. 7. Closed-time distribution was also fitted with two exponentials. Penticainide in the patch pipette prolonged the long mean closed time. The contribution of the number of short closings to the total number of closings was decreased. 8. Penticainide in the patch pipette did not significantly change the time constant of the decay of the ensemble-averaged currents measured at -30 mV. Because of the close correlation between the burst duration and the time constant of inactivation (Nilius, Vereecke & Carmeliet, 1988b), we conclude that no striking effect of Penticainide on the burst duration can be expected.(ABSTRACT TRUNCATED AT 400 WORDS)