Homo- and heterotetrameric architecture of the epithelial Ca2+ channels TRPV5 and TRPV6.

The molecular assembly of the epithelial Ca(2+) channels (TRPV5 and TRPV6) was investigated to determine the subunit stoichiometry and composition. Immunoblot analysis of Xenopus laevis oocytes expressing TRPV5 and TRPV6 revealed two specific bands of 75 and 85-100 kDa, corresponding to the core and glycosylated proteins, respectively, for each channel. Subsequently, membranes of these oocytes were sedimented on sucrose gradients. Immuno blotting revealed that TRPV5 and TRPV6 complexes migrate with a mol. wt of 400 kDa, in line with a tetrameric structure. The tetrameric stoichiometry was confirmed in an electrophysiological analysis of HEK293 cells co-expressing concatemeric channels together with a TRPV5 pore mutant that reduced Cd(2+) sensitivity and voltage-dependent gating. Immuno precipitations using membrane fractions from oocytes co-expressing TRPV5 and TRPV6 demonstrated that both channels can form heteromeric complexes. Expression of all possible heterotetrameric TRPV5/6 complexes in HEK293 cells resulted in Ca(2+) channels that varied with respect to Ca(2+)-dependent inactivation, Ba(2+) selectivity and pharmacological block. Thus, Ca(2+)-transporting epithelia co-expressing TRPV5 and TRPV6 can generate a pleiotropic set of functional heterotetrameric channels with different Ca(2+) transport kinetics.

Function and expression of the epithelial Ca(2+) channel family: comparison of mammalian ECaC1 and 2.

1. The epithelial Ca(2+) channel (ECaC) family represents a unique group of Ca(2+)-selective channels that share limited homology to the ligand-gated capsaicin receptors, the osmolarity-sensitive channel OTRPC4, as well as the transient receptor potential family. Southern blot analysis demonstrated that this family is restricted to two members, ECaC1 and ECaC2 (also named CaT1). 2. RT-PCR analysis demonstrated that the two channels are co-expressed in calbindin-D-containing epithelia, including small intestine, pancreas and placenta, whereas kidney and brain only express ECaC1 and stomach solely ECaC2. 3. From an electrophysiological point of view, ECaC1 and ECaC2 are highly similar channels. Differences concern divalent cation permeability, the kinetics of Ca(2+)-dependent inactivation and recovery from inactivation. 4. Ruthenium red is a potent blocker of ECaC activity. Interestingly, ECaC2 has a 100-fold lower affinity for ruthenium red (IC(50) 9 +/- 1 microM) than ECaC1 (IC(50) 121 +/- 13 nM). 5. ECaCs are modulated by intracellular Mg(2+) and ATP. ECaC1 and ECaC2 activity rapidly decay in the absence of intracellular ATP. This effect is further accelerated at higher intracellular Mg(2+) concentrations. 6. In conclusion, ECaC1 and ECaC2 are homologous channels, with an almost identical pore region. They can be discriminated by their sensitivity for ruthenium red and show differences in Ca(2+)-dependent regulation.

Differential activation of the volume-sensitive cation channel TRP12 (OTRPC4) and volume-regulated anion currents in HEK-293 cells.

The detection of changes in volume and osmolality is an essential function in vertebrate cells. A novel member of the transient receptor potential (trp) family of ion channels, which is sensitive to changes in cell volume, has been described recently. Heterologous expression of TRP12 in HEK cells resulted in the appearance of a swelling-activated cation current. The permeability sequence of this cation current for various monovalent cations, as determined from shifts in reversal potential upon extracellular cation substitution, was PK>PCs>PNa>PLi, corresponding to an Eisenman-IV sequence characteristic for a weak-field-strength site. Surprisingly, over-expression of this channel in HEK cells was accompanied by a dramatic down-regulation of the volume-regulated anion channel (VRAC), which is activated by cell swelling in non-transfected cells. In contrast to VRAC, TRP12 could not be activated at constant volume by a reduction of intracellular ionic strength or by intracellular perfusion with guanosine 5'-O-(3-thiotriphosphate (GTPgammaS). The kinetic and pharmacological profile of VRAC and TRP12 currents were also different.

CaT1 and the calcium release-activated calcium channel manifest distinct pore properties.

The calcium release-activated calcium channel (CRAC) is a highly Ca(2+)-selective ion channel that is activated on depletion of inositol triphosphate (IP(3))-sensitive intracellular Ca(2+) stores. It was recently reported that CaT1, a member of the TRP family of cation channels, exhibits the unique biophysical properties of CRAC, which led to the conclusion that CaT1 comprises all or part of the CRAC pore (Yue, L., Peng, J. B., Hediger, M. A., and Clapham, D. E. (2001) Nature 410, 705-709). Here, we directly compare endogenous CRAC with heterologously expressed CaT1 and show that they manifest several clearly distinct properties. CaT1 can be distinguished from CRAC in the following features: sensitivity to store-depleting agents; inward rectification in the absence of divalent cations; relative permeability to Na(+) and Cs(+); effect of 2-aminoethoxydiphenyl borate (2-APB). Moreover, CaT1 displays a mode of voltage-dependent gating that is fully absent in CRAC and originates from the voltage-dependent binding/unbinding of Mg(2+) inside the channel pore. Our results imply that the pores of CaT1 and CRAC are not identical and indicate that CaT1 is a Mg(2+)-gated channel not directly related to CRAC.

Pharmacological modulation of monovalent cation currents through the epithelial Ca2+ channel ECaC1.

1. The recent identification of the epithelial Ca(2+) channel, ECaC1, represents a major step forward in our knowledge of renal Ca(2+) handling. ECaC1 constitutes the rate-limiting apical Ca(2+) entry mechanism of active, transcellular Ca(2+) reabsorption. This unique highly selective Ca(2+) channel shares a low but significant homology with transient receptor potential (TRP) channels and vanilloid receptors (VR). 2. We have studied the pharmacological modulation of currents through ECaC1 heterologously expressed in HEK 293 cells. Monovalent cation currents were measured by use of the whole cell patch clamp technique in cells dialysed with 10 mM BAPTA or 10 mM EGTA to prevent the fast Ca(2+) dependent inactivation of ECaC1. 3. Several modulators were tested, including inorganic cations, putative store-operated Ca(2+) entry (SOC) blockers, the vanilloid receptor (VR-1) blocker capsazepine, protein tyrosine kinase blockers, calmodulin antagonists and ruthenium red. 4. Ruthenium red and econazole appeared to be the most effective inhibitors of currents through ECaC1, with IC(50) values of 111 nM and 1.3 microM, respectively, whereas the selective SOC inhibitor, SKF96365, was nearly ineffective. 5. The divalent cation current block profile for ECaC1 is Pb(2+)=Cu(2+) >Zn(2+) >Co(2+) >Fe(2+) with IC(50) values between 1 and approximately 10 microM. 6. In conclusion, ECaC activity is effectively inhibited by various compounds including ruthenium red, antimycotic drugs and divalent cations, which might be useful tools for pharmacological manipulation and several disorders related to Ca(2+) homeostasis could benefit from such developments.

Modulation of the epithelial Ca2+ channel ECaC by extracellular pH.

We investigated the effect of extracellular pH on whole-cell currents through the epithelial Ca2+ channel, ECaC, expressed in HEK 293 cells. Both mono- and divalent current densities were significantly smaller at pH 6.0 than at pH 7.4. At pH 8.5 they were slightly larger. Lowering extracellular pH enhanced the slow component of monovalent current activation at negative potentials but had no significant effect on the kinetics of Ca2+ currents. The kinetics of block of monovalent cation current by extracellular Mg2+ was significantly changed at high and low pH. The time constant of the time- and voltage-dependent current component during a voltage step to -140 mV was significantly larger at pH 8.5 than at pH 7.4. At pH 6.0 it was almost absent. The [Mg2+] inhibiting 50% of monovalent current through ECaC at pH 6.0 (IC50) was 323 +/- 23 microM (n = 8), compared with 62 +/- 9 microM (n = 4) at pH 7.4 and 38 +/- 4 microM (n = 8) at pH 8.5. The affinity of ECaC for Ca2+ was also affected by extracellular pH, shifting from 4.8 +/- 0.7 microM (n = 6) at pH 6.0 to 161 +/- 30 nM (n = 5) at pH 7.4 and 425 +/- 117 nM (n = 8) at pH 8.5.

Modulation of the epithelial calcium channel, ECaC, by intracellular Ca2+.

We have studied the modulation by intracellular Ca2+ of the epithelial Ca2+ channel, ECaC, heterologously expressed in HEK 293 cells. Whole-cell and inside-out patch clamp current recordings were combined with FuraII-Ca2+ measurements:1. Currents through ECaC were dramatically inhibited if Ca2+ was the charge carrier. This inhibition was dependent on the extracellular Ca2+ concentration and occurred also in cells buffered intracellularly with 10 mM BAPTA.2. Application of 30 mM [Ca(2)]e induced in non-Ca2+] buffered HEK 293 cells at -80 m V an increase in intracellular Ca2+([Ca2]i) with a maximum rate of rise of 241 +/-15nM/s (n= 18 cells) and a peak value of 891 +/- 106 nM. The peak of the concomitant current with a density of 12.3 +/- 2.6 pA/pF was closely correlated with the peak of the first-time derivative of the Ca2+ transient, as expected if the Ca2+ transient is due to influx of Ca2+. Consequently, no Ca2+] signal was observed in cells transfected with the Ca2+ impermeable ECaC mutant, D542A, in which an aspartate in the pore region was neutralized.3. Increasing [Ca2+]i by dialyzing the cell with pipette solutions containing various Ca2+] concentrations, all buffered with 10 mM BAPTA, inhibited currents through ECaC carried by either Na+ or Ca2+] ions. Half maximal inhibition of Ca(2+)currents in the absence of monovalent cations occurred at 67 nM (n between 6 and 8), whereas Na+ currents in the absence of Ca2+] and Mg2+ were inhibited with an IC50 of 89 nM (n between 6 and 10). Currents through ECaC in the presence of 1 mM Ca2+ and Na+, which are mainly carried by Ca2+, are inhibited by [Ca2]i with an IC50of 82 nM (n between 6 and 8). Monovalent cation currents through the Ca2+impermeable D542A ECaC mutant were also inhibited by an elevation of [Ca2]i (IC50 = 123 nM, n between 7 and 18). 4. The sensitivity of ECaC currents in inside-out patches for [Ca2]i was slightly shifted to higher concentrations as compared with whole cell measurements. Half-maximal inhibition occurred at 169 nM if Na+ was the charge carrier (n between 4 and 11) and 228 nM at 1 mM [Ca2]e (n between 4 and 8).5. Recovery from inhibition upon washout of extracellular Ca2+ (whole-cell configuration) or removal of Ca2+ from the inner side of the channel (inside-out patches) was slow in both conditions. Half-maximal recovery was reached after 96 +/- 34 s (n= 15) in whole-cell mode and after 135 +/- 23 s (n = 17) in inside-out patches.6. We conclude that influx of Ca2+ through ECaC and [Ca2]i induce feedback inhibition of ECaC currents, which is controlled by the concentration of Ca2+ in a micro domain near the inner mouth of the channel. Slow recovery seems to depend on dissociation of Ca( 2+ from an internal Ca2+ binding site at ECaC.

Pore properties and ionic block of the rabbit epithelial calcium channel expressed in HEK 293 cells.

We have used the whole-cell patch-clamp technique to analyse the permeation properties and ionic block of the epithelial Ca2+ channel ECaC heterologously expressed in human embryonic kidney (HEK) 293 cells. Cells dialysed with 10 mM BAPTA and exposed to Ca2+-containing, monovalent cation-free solutions displayed large inwardly rectifying currents. Their reversal potential depended on the extracellular Ca2+ concentration, [Ca2+]o. The slope of the relationship between reversal potential and [Ca2+]o on a logarithmic scale was 21 +/- 4 mV, compared with 29 mV as predicted by the Nernst equation (n = 3-5 cells). Currents in mixtures of Ca2+ and Na+ or Ca2+ and Ba2+ showed anomalous mole fraction behaviour. We have described the current-concentration plot for Ca2+ and Na+ by a kinetic permeation model, i.e. the "step" model. Extracellular Mg2+ blocked both divalent and monovalent currents with an IC50 of 62 +/- 9 microM(n = 4) in Ca2+-free conditions and 328 +/- 50 microM (n = 4-9) in 100 microM Ca2+ solutions. Mono- and divalent currents through ECaCs were blocked by gadolinium, lanthanum and cadmium, with a blocking order of Cd2+ >> Gd3+ > La3+. We conclude that the permeation of monovalent and divalent cations through ECaCs shows similarities with L-type voltage-gated Ca2+ channels, the main differences being a higher Ca2+ affinity and a significantly higher current density in micromolar Ca2+ concentrations in the case of ECaCs.

The amino side of the C-terminus determines fast inactivation of the T-type calcium channel alpha1G.

We analysed the kinetic properties of the fast inactivating T-type calcium channel alpha1G in HEK 293 cells transfected with different alpha1G chimeras, containing the N-terminus, III-IV linker or various C-terminal regions of the slowly inactivating L-type alpha1C. A highly negatively charged region of 23 amino acids at the amino side of the intracellular carboxy terminus of alpha1G was found to be critical for fast inactivation. The N-terminus of alpha1G does not seem to be necessary for inactivation of the T-type calcium channel because replacement of the a1G N-terminus with the alpha1C N-terminus did not influence channel kinetics at all. Replacing the III-IV linker of alpha1G with that of a1C decreased the rate of inactivation at -20 mV from 15.8 +/- 1.8 to 8.5 +/- 1.1 ms, and shifted the potential for half-maximal inactivation from -69.6 +/- 0.8 to -54.0 +/- 1.7 mV. However, these parameters were not significantly different at other potentials. We suggest a putative 'ball-and-chain'-like mechanism for inactivation in which the negative charges function as an acceptor domain for a ball, hypothetically located at a different intracellular part of the channel. In addition, transferring the IQ motif and EF hand of alpha1C to alpha1G does not confer Ca2+-dependent inactivation on alpha1G, suggesting that other sequences besides the C-terminus are needed for Ca2+-dependent inactivation of alpha1C.

The single pore residue Asp542 determines Ca2+ permeation and Mg2+ block of the epithelial Ca2+ channel.

The epithelial Ca(2+) channel (ECaC), which was recently cloned from rabbit kidney, exhibits distinctive properties that support a facilitating role in transcellular Ca(2+) (re)absorption. ECaC is structurally related to the family of six transmembrane-spanning ion channels with a pore-forming region between S5 and S6. Using point mutants of the conserved negatively charged amino acids present in the putative pore, we have identified a single aspartate residue that determines Ca(2+) permeation of ECaC and modulation by extracellular Mg(2+). Mutation of the aspartate residue, D542A, abolishes Ca(2+) permeation and Ca(2+)-dependent current decay as well as block by extracellular Mg(2+), whereas monovalent cations still permeate the mutant channel. Variation of the side chain length in mutations D542N, D542E, and D542M attenuated Ca(2+) permeability and Ca(2+)-dependent current decay. Block of monovalent currents through ECaC by Mg(2+) was decreased. Exchanging the aspartate residue for a positively charged amino acid, D542K, resulted in a nonfunctional channel. Mutations of two neighboring negatively charged residues, i.e. Glu(535) and Asp(550), had only minor effects on Ca(2+) permeation properties.

Whole-cell and single channel monovalent cation currents through the novel rabbit epithelial Ca2+ channel ECaC.

This study describes properties of monovalent cation currents through ECaC, a recently cloned epithelial Ca2+-permeable channel from rabbit. The kinetics of currents through ECaC was strongly modulated by divalent cations. Currents were inhibited in the presence of extracellular Ca2+. They showed an initial voltage-dependent decay in the presence of mM Mg2+ at hyperpolarizing steps in Ca2+-free solutions, which represents a voltage-dependent Mg2+ block through binding of Mg2+ to a site localized in the electrical field of the membrane (delta = 0.31) and a voltage-dependent binding constant (at 0 mV 3.1 mM Ca2+, obtained from a Woodhull type analysis). Currents were only stable in the absence of divalent cations and showed under these conditions a small time- and voltage-dependent component of activation. Single channel currents in cell-attached and inside-out patches had a conductance of 77.5 +/- 4.9 pS (n = 11) and reversed at +14.8 +/- 1. 6 11imV81i (n = 9) in the absence of divalent cations. The permeation sequence for monovalent cations through ECaC was Na+ > Li+ > K+ > Cs+ > NMDG+ which is identical to the Eisenmann sequence X for a strong field-strength binding site. It is concluded that the permeation profile of ECaC for monovalent cations suggests a strong field-strength binding site that may be involved in Ca2+ permeation and Mg2+ block.

Extra- and intracellular proton-binding sites of volume-regulated anion channels.

We have investigated the effects of extracellular and intracellular pH on single channel and macroscopic (macropatches) currents through volume-regulated anion channels (VRAC) in endothelial cells. Protonation of extracellular binding sites with an apparent pK of 4.6 increased voltage independent of the single-channel amplitude. Cytosolic acidification had a dual effect on VRAC currents: on the one hand, it increased single channel conductance by approximately 20% due to protonation of a group with an apparent pK of 6.5 and a Hill coefficient of 2. On the other hand, it reduced channel activity due to protonation of a group with an apparent pK of 6.3 and a Hill coefficient of 2.1. This dual effect enhances the macroscopic current at a slightly acidic pH but inhibits it at more acidic pH. Cytosolic alkalization also reduced channel activity with a pK of 8.4 and a Hill coefficient of 1.9, but apparently did not affect single-channel conductance. These data show that VRAC channels are maintained in an active state in a narrow pH range around the normal physiological pH and shut down outside this range. They also show that HEPES-buffered pipette solutions do not effectively buffer pH in the vicinity of the VRAC channels.

Endothelial K(+) channel lacks the Ca(2+) sensitivity-regulating beta subunit.

Hyperpolarizing large-conductance, Ca(2+)-activated K(+) channels (BK) are important modulators of vascular smooth muscle and endothelial cell function. In vascular smooth muscle cells, BK are composed of pore-forming alpha subunits and modulatory beta subunits. However, expression, composition, and function of BK subunits in endothelium have not been studied so far. In patch-clamp experiments we identified BK (283 pS) in intact endothelium of porcine aortic tissue slices. The BK opener DHS-I (0.05-0.3 micromol/l), stimulating BK activity only in the presence of beta subunits, had no effect on BK in endothelium whereas the alpha subunit selective BK opener NS1619 (20 micromol/l) markedly increased channel activity. Correspondingly, mRNA expression of the beta subunit was undetectable in endothelium, whereas alpha subunit expression was demonstrated. To investigate the functional role of beta subunits, we transfected the beta subunit into a human endothelial cell line (EA.hy 926). beta subunit expression resulted in an increased Ca(2+) sensitivity of BK activity: the potential of half-maximal activation (V(1/2)) shifted from 73.4 mV to 49.6 mV at 1 micromol/l [Ca(2+)](i) and an decrease of the EC(50) value for [Ca(2+)](i) by 1 microM at +60 mV was observed. This study demonstrates that BK channels in endothelium are composed of alpha subunits without association to beta subunits. The lack of the beta subunit indicates a substantially different channel regulation in endothelial cells compared to vascular smooth muscle cells.

Myosin light chain phosphorylation-dependent modulation of volume-regulated anion channels in macrovascular endothelium.

The Rho/Rho-associated kinase (ROK) pathway has been shown to modulate volume-regulated anion channels (VRAC) in cultured calf pulmonary artery endothelial (CPAE) cells. Since Rho/ROK can increase myosin light chain phosphorylation, we have now studied the effects of inhibitors of myosin light chain kinase (MLCK) or myosin light chain phosphatase (MLCP) on VRAC in CPAE. Application of ML-9, an MLCK inhibitor, inhibited VRAC, both when applied extracellularly or when dialyzed into the cell. A similar inhibitory effect was obtained by dialyzing the cells with AV25, a specific MLCK inhibitory peptide. Conversely, NIPP1(191-210), an MLCP inhibitory peptide, potentiated the activation of VRAC by a 25% hypotonic stimulus. These data indicate that activation of VRAC is modulated by MLC phosphorylation.

Permeation and gating properties of the novel epithelial Ca(2+) channel.

The recently cloned epithelial Ca(2+) channel (ECaC) constitutes the Ca(2+) influx pathway in 1,25-dihydroxyvitamin D(3)-responsive epithelia. We have combined patch-clamp analysis and fura-2 fluorescence microscopy to functionally characterize ECaC heterologously expressed in HEK293 cells. The intracellular Ca(2+) concentration in ECaC-expressing cells was closely correlated with the applied electrochemical Ca(2+) gradient, demonstrating the distinctive Ca(2+) permeability and constitutive activation of ECaC. Cells dialyzed with 10 mM 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid displayed large inward currents through ECaC in response to voltage ramps. The corresponding current-voltage relationship showed pronounced inward rectification. Currents evoked by voltage steps to potentials below -40 mV partially inactivated with a biexponential time course. This inactivation was less pronounced if Ba(2+) or Sr(2+) replaced Ca(2+) and was absent in Ca(2+)-free solutions. ECaC showed an anomalous mole fraction behavior. The permeability ratio P(Ca):P(Na) calculated from the reversal potential at 30 mM [Ca(2+)](o) was larger than 100. The divalent cation selectivity profile is Ca(2+) > Mn(2+) > Ba(2+) approximately Sr(2+). Repetitive stimulation of ECaC-expressing cells induced a decay of the current response, which was greatly reduced if Ca(2+) was replaced by Ba(2+) and was virtually abolished if [Ca(2+)](o) was lowered to 1 nM. In conclusion, ECaC is a Ca(2+) selective channel, exhibiting Ca(2+)-dependent autoregulatory mechanisms, including fast inactivation and slow down-regulation.

Reduction of ionic strength activates single volume-regulated anion channels (VRAC) in endothelial cells.

We have previously shown that a reduction of intracellular ionic strength is involved in the activation of volume-regulated anion channels (VRAC). Here we show in a single-channel study that VRAC can be activated in a cell-attached patch when the cell interior is dialyzed with a solution of decreased ionic strength. For this purpose, bovine pulmonary endothelial (CPAE) cells) were permeabilized with alpha-staphylotoxin (alphaST) which has a molecular weight cut-off size of 2 kDa. If the ionic strength in the bath solution is reduced from 160 mM to 95 mM, single-channel activity is initiated in cell-attached patches sealed before permeabilization. Conductance is outwardly rectifying with approximately 17 pS at negative and 57 pS at positive potentials. Single-channel currents reverse near the calculated equilibrium potential for Cl-. The averaged current shows inactivation at positive potentials. The current is blocked by 5-nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB). An increase in ionic strength reversibly inhibits current activation. It is concluded that a decrease in ionic strength activates single-channel currents through VRAC rather than shifting the set point of a hypothetical volume sensor.

Characterisation of explanted endothelial cells from mouse aorta: electrophysiology and Ca2+ signalling.

We describe here the isolation and primary culture of endothelial cells from mouse aorta ("primary explant technique"). These cells provide an excellent model for functional studies in transgenic mice. The primary explant method delivers cells that grow out from small pieces of mouse aorta placed on Matrigel enriched with endothelial growth factors. Cells can be studied on the Matrigel after removing the pieces of aorta or after passages by using dispase and reseeding the cells on gelatine-coated cover-slips. Cells on Matrigel or from the first and second passages were characterised using the combined patch-clamp and fura-2 fluorescence methods. Cells had a mean membrane resting potential of -19+/-3 mV (n=21), a membrane capacitance of 49+/-5 pF (n=37) and a resting cytosolic free [Ca2+] ([Ca2+]i) of 103+/-8 nM (n=30). Adenosine 5'-triphosphate (ATP), acetylcholine and bradykinin, but not histamine, induced fast release of intracellular Ca2+ followed by a sustained rise in [Ca2+]i. Oscillations in [Ca2+]i were observed at lower agonist concentrations. In nearly all cells (93%, n=30), these agonists activated charybdotoxin-sensitive, Ca2+-activated K+ channels and induced hyperpolarisation. In 84% of the cells (n=32), an increase in [Ca2+]i also activated strongly outwards-rectifying Cl- channels. These activated slowly at positive potentials and inactivated rapidly at negative potentials. Increasing [Ca2+]i to 1 microM activated a non-selective cation channel in 86% of the cells (n=28). Each tested cell responded to a challenge with hypotonic solution by activating a Cl- current that was modestly outwards rectifying and inactivated at positive potentials. This current is similar to the well-described swelling-activated current through volume-regulated anion channels (VRAC) in endothelial cells. However, its activation is slower, its inactivation faster and the current density lower than in cultured endothelial cells. It is concluded that the primary explant technique provides a reliable cell model for studying mouse vascular endothelial cell function.

Sulphonic acid derivatives as probes of pore properties of volume-regulated anion channels in endothelial cells.

1. We have used the whole-cell patch-clamp technique to study the effects of 4-sulphonic-calixarenes and some other poly-sulphonic acid agents, such as suramin and basilen blue, on volume-regulated anion channel (VRAC) currents in cultured endothelial cells (CPAE cells). 2. The 4-sulphonic-calixarenes induced a fast inhibition at positive potentials but were ineffective at negative potentials. At small positive potentials, 4-sulphonic-calix[4]arene was a more effective inhibitor than 4-sulphonic-calix[6]arene and -calix[8]arene, which became more effective at more positive potentials. 3. Also suramin and basilen blue induced a voltage dependent current inhibition, reaching a maximum around +40 mV and declining at more positive potentials. 4. The voltage dependence of inhibition was modelled by assuming that these negatively charged molecules bind to a site inside VRAC that senses a fraction delta of the applied electrical field, ranging beween 0.16 to 0.32. 4-Sulphonic-calix[4]arene, suramin and basilen blue bind and occlude VRAC at moderate potentials, but permeate the channel at more positive potentials. 4-Sulphonic-calix[6]arene and -calix[8]arene however do not permeate the channel. From the structural information of the calixarenes, we estimate a lower and upper limit of 11*12 and 17*12 A2 respectively for the cross-sectional area of the pore.

Role of Rho and Rho kinase in the activation of volume-regulated anion channels in bovine endothelial cells.

1. We have studied the modulation of volume-regulated anion channels (VRACs) by the small GTPase Rho and by one of its targets, Rho kinase, in calf pulmonary artery endothelial (CPAE) cells. 2. RT-PCR and immunoblot analysis showed that both RhoA and Rho kinase are expressed in CPAE cells. 3. ICl,swell, the chloride current through VRACs, was activated by challenging CPAE cells with a 25 % hypotonic extracellular solution (HTS) or by intracellular perfusion with a pipette solution containing 100 microM GTPgammaS. 4. Pretreatment of CPAE cells with the Clostridium C2IN-C3 fusion toxin, which inactivates Rho by ADP ribosylation, significantly impaired the activation of ICl,swell in response to the HTS. The current density at +100 mV was 49 +/- 13 pA pF-1 (n = 17) in pretreated cells compared with 172 +/- 17 pA pF-1 (n = 21) in control cells. 5. The volume-independent activation of ICl,swell by intracellular perfusion with GTPgammaS was also impaired in C2IN-C3-pretreated cells (31 +/- 7 pA pF-1, n = 11) compared with non-treated cells (132 +/- 21 pA pF-1, n = 15). 6. Activation of ICl,swell was pertussis toxin (PTX) insensitive. 7. Y-27632, a blocker of Rho kinase, inhibited ICl,swell and delayed its activation. 8. Inhibition of Rho and of Rho kinase by the above-described treatments did not affect the extent of cell swelling in response to HTS. 9. These experiments provide strong evidence that the Rho-Rho kinase pathway is involved in the VRAC activation cascade.

Voltage-dependent block of endothelial volume-regulated anion channels by calix[4]arenes.

We have studied the effects of calix[4]arenes on the volume-regulated anion channel (VRAC) currents in cultured calf pulmonary artery endothelial cells. TS- and TS-TM-calix[4]arenes induced a fast inhibition at positive potentials but were ineffective at negative potentials. Maximal block occurred at potentials between 30 and 50 mV. Lowering extracellular pH enhanced the block and shifted the maximum inhibition to more negative potentials. Current inhibition was also accompanied by an increased current noise. From the analysis of the calix[4]arene-induced noise, we obtained a single-channel conductance of 9.3 +/- 2.1 pS (n = 9) at +30 mV. The voltage- and time-dependent block were described using a model in which calix[4]arenes bind to a site at an electrical distance of 0.25 inside the channel with an affinity of 220 microM at 0 mV. Binding occludes VRAC at moderately positive potentials, but calix[4]arenes permeate the channel at more positive potentials. In conclusion, our data suggest an open-channel block of VRAC by calix[4]arenes that also depends on the protonation of the binding site within the pore.