Different consequences of cataract-associated mutations at adjacent positions in the first extracellular boundary of connexin50

Gap junction channels, which are made of connexins, are critical for intercellular communication, a function that may be disrupted in a variety of diseases. We studied the consequences of two cataract-associated mutations at adjacent positions at the first extracellular boundary in human connexin50 (Cx50), W45S and G46V. Both of these mutants formed gap junctional plaques when they were expressed in HeLa cells, suggesting that they trafficked to the plasma membrane properly. However, their functional properties differed. Dual two-microelectrode voltage-clamp studies showed that W45S did not form functional intercellular channels in paired Xenopus oocytes or hemichannel currents in single oocytes. When W45S was coexpressed with wild-type Cx50, the mutant acted as a dominant negative inhibitor of wild-type function. In contrast, G46V formed both functional gap junctional channels and hemichannels. G46V exhibited greatly enhanced currents compared with wild-type Cx50 in the presence of physiological calcium concentrations. This increase in hemichannel activity persisted when G46V was coexpressed with wild-type lens connexins, consistent with a dominant gain of hemichannel function for G46V. These data suggest that although these two mutations are in adjacent amino acids, they have very different effects on connexin function and cause disease by different mechanisms: W45S inhibits gap junctional channel function; G46V reduces cell viability by forming open hemichannels.     

Molecular mechanism underlying a Cx50-linked congenital cataract

Mutations in gapjunctional channels have been linked to certain forms of inheritedcongenital cataract (D. Mackay, A. Ionides, V. Berry, A. Moore, S. Bhattacharya, and A. Shiels. Am. J. Hum. Genet. 60: 1474-1478, 1997; A. Shiels, D. Mackay,A. Ionides, V. Berry, A. Moore, and S. Bhattacharya.Am. J. Hum. Genet. 62: 526-532,1998). We used the Xenopus oocyte pairsystem to investigate the functional properties of a missense mutationin the human connexin 50 gene (P88S) associated with zonularpulverulent cataract. The associated phenotype for the mutation istransmitted in an autosomal dominant fashion.Xenopus oocytes injected withwild-type connexin 50 cRNA developed gap junctional conductances of~5 µS 4-7 h after pairing. In contrast, the P88S mutantconnexin failed to form functional gap junctional channels when pairedhomotypically. Moreover, the P88S mutant functioned in a dominantnegative manner as an inhibitor of human connexin 50 gap junctionalchannels when coinjected with wild-type connexin 50 cRNA. Cellsinjected with 1:5 and 1:11 ratios of P88S mutant to wild-type cRNAexhibited gap junctional coupling of ~8% and 39% of wild-typecoupling, respectively. Based on these findings, we conclude that onlyone P88S mutant subunit is necessary per gap junctional channel to abolish channel function.

     

Impermeability of the GIRK2 weaver channel to divalent cations

Asingle amino acid mutation (G156S) in the putative pore-forming regionof the G protein-sensitive, inwardly rectifying K⁺ channelsubunit, GIRK2, renders the conductance constitutively active andnonselective for monovalent cations. The mutant channel subunit(GIRK2wv) causes the pleiotropic weaver disease inmice, which is characterized by the selective vulnerability ofcerebellar granule cells and Purkinje cells, as well as dopaminergicneurons in the mesencephalon, to cell death. It has beenproposed that divalent cation permeability through constitutivelyactive GIRK2wv channels contributes to a rise in internalcalcium in the GIRK2wv-expressing neurons, eventually leadingto cell death. We carried out comparative studies of recombinantGIRK2wv channels expressed in Xenopus oocytes and COS-7cells to determine the magnitude and relative permeability of theGIRK2wv conductance to Ca²⁺. Data from thesestudies demonstrate that the properties of the expressed current differin the two systems and that when recombinant GIRK2wv isexpressed in mammalian cells it is impermeable to Ca²⁺.

     

Mutagenesis of the N-glycosylation site of hNaSi-1 reduces transport activity

The human Na⁺-sulfate cotransporter (hNaSi-1) belongs to the SLC13 gene family, which also includes the high-affinity Na⁺-sulfate cotransporter (hSUT-1) and the Na⁺-dicarboxylate cotransporters (NaDC). In this study, the location and functional role of the N-glycosylation site of hNaSi-1 were studied using antifusion protein antibodies. Polyclonal antibodies against a glutathione S-transferase fusion protein containing a 65-amino acid peptide of hNaSi-1 (GST-Si65) were raised in rabbits, purified, and then used in Western blotting and immunofluorescence experiments. The antibodies recognized native NaSi-1 proteins in pig and rat brush-border membrane vesicles as well as the recombinant proteins expressed in Xenopus oocytes. Wild-type hNaSi-1 and two N-glycosylation site mutant proteins, N591Y and N591A, were functionally expressed and studied in Xenopus oocytes. The apparent mass of N591Y was not affected by treatment with peptide-N-glycosylase F, in contrast to the mass of wild-type hNaSi-1, which was reduced by up to 15 kDa, indicating that Asn⁵⁹¹ is the N-glycosylation site. Although the cell surface abundance of the two glycosylation site mutants, N591Y and N591A, was greater than that of wild-type hNaSi-1, both mutants had greatly reduced V_max, with no change in K_m. These results suggest that Asn⁵⁹¹ and/or N-glycosylation is critical for transport activity in NaSi-1. antifusion protein antibodies; Xenopus oocytes; sulfate; immunofluorescence     

Cataract-associated D3Y mutation of human connexin46 (hCx46) increases the dye coupling of gap junction channels and suppresses the voltage sensitivity of hemichannels

Connexin46 (Cx46), together with Cx50, forms gap junction channels between lens fibers and participates in the lens pump-leak system, which is essential for the homeostasis of this avascular organ. Mutations in Cx50 and Cx46 correlate with cataracts, but the functional relationship between the mutations and cataract formation is not always clear. Recently, it was found that a mutation at the third position of hCx46 that substituted an aspartic acid residue with a tyrosine residue (hCx46D3Y) caused an autosomal dominant zonular pulverulent cataract. We expressed EGFP-labeled hCx46wt and hCx46D3Y in HeLa cells and found that the mutation did not affect the formation of gap junction plaques. Dye transfer experiments using Lucifer Yellow (LY) and ethidium bromide (EthBr) showed an increased degree of dye coupling between the cell pairs expressing hCx46D3Y in comparison to the cell pairs expressing hCx46wt. In Xenopus oocytes, two-electrode voltage-clamp experiments revealed that hCx46wt formed voltage-sensitive hemichannels. This was not observed in the oocytes expressing hCx46D3Y. The replacement of the aspartic acid residue at the third position by another negatively charged residue, glutamic acid, to generate the mutant hCx46D3E, restored the voltage sensitivity of the resultant hemichannels. Moreover, HeLa cell pairs expressing hCx46D3E and hCx46wt showed a similar degree of dye coupling. These results indicate that the negatively charged aspartic acid residue at the third position of the N-terminus of hCx46 could be involved in the determination of the degree of metabolite cell-to-cell coupling and is essential for the voltage sensitivity of the hCx46 hemichannels.     

Expression and regulation of ClC-5 chloride channels: effects of antisense and oxidants

Genetic mutations of theCl channel ClC-5 cause Dent's disease in humans. Werecently cloned an amphibian ortholog of Xenopus ClC-5(xClC-5) from the A6 cell line. We now compare the properties and regulation of ClC-5 currents expressed in mammalian (COS-7) cellsand Xenopus oocytes. Whole cell currents in COS-7 cells transfected with xClC-5 cDNA had strong outward rectification, Cl > I anion sensitivity, and wereinhibited at low pH, similar to previous results in oocytes. Inoocytes, antisense xClC-5 cRNA injection had no effect on endogenousmembrane currents or the heterologous expression of human ClC-5.Activators of cAMP and protein kinase C inhibitors had nosignificant effects on ClC-5 currents expressed in either COS-7 cellsor oocytes, whereas H-89, a cAMP-dependent protein kinase (PKA)inhibitor, and hydrogen peroxide decreased the currents. We concludethat the basic properties of ClC-5 currents were independent of thehost cell type used for expression. In addition, ClC-5 channels may bemodulated by PKA and reactive oxygen species.

     

Abnormal regulatory interactions of I148T-CFTR and the epithelial Na+ channel in Xenopus oocytes

The mechanisms underlying regulatory interactions of the cystic fibrosis transmembrane conductance regulator (CFTR) and the epithelial Na⁺ channel (ENaC) in Xenopus oocytes are controversial. CFTR's first nucleotide binding domain (NBD-1) may be important in these interactions, because mutations within NBD-1 impair these functional interactions. We hypothesized that an abnormal CFTR containing a non-NBD-1 mutation and able to transport chloride would retain regulatory interactions with murine ENaC (mENaC). We tested this hypothesis for I148T-CFTR, where the mutation is located in CFTR's first intracellular loop. I148T-CFTR has been associated with a severe CF phenotype, perhaps because of defects in its regulation of bicarbonate transport, but it transports chloride similarly to wild-type CFTR in model systems (Choi JY, Muallem D, Kiselyov K, Lee MG, Thomas PJ, Muallem S. Nature 410: 94–97, 2001). cRNAs encoding -mENaC and I148T-CFTR were injected separately or together into Xenopus oocytes. mENaC and CFTR functional expression were assessed by two-electrode voltage clamp. mENaC whole oocyte expression was determined by immunoblotting, and surface expression was quantitated by surface biotinylation. Injection of I148T-CFTR cRNA alone yielded high levels of CFTR functional expression. In coinjected oocytes, mENaC functional and surface expression was not altered by activation of I148T-CFTR with forskolin/ IBMX. Furthermore, the CFTR potentiator genistein both enhanced functional expression of I148T-CFTR and restored regulation of mENaC surface expression by activated I148T-CFTR. These data suggest that the ability to transport chloride is not a critical determinant of regulation of mENaC by activated CFTR in Xenopus oocytes and provide further evidence that I148T-CFTR is dysfunctional despite maintaining the ability to transport chloride. cystic fibrosis transmembrane conductance regulator; genistein     

Transmembrane domain histidines contribute to regulation of AE2-mediated anion exchange by pH

Activity of the AE2/SLC4A2 anion exchanger is modulated acutely by pH, influencing the transporter's role in regulation of intracellular pH (pH_i) and epithelial solute transport. In Xenopus oocytes, heterologous AE2-mediated Cl^–/Cl^– and Cl^–/HCO₃^– exchange are inhibited by acid pH_i or extracellular pH (pH_o). We have investigated the importance to pH sensitivity of the eight histidine (His) residues within the AE2 COOH-terminal transmembrane domain (TMD). Wild-type mouse AE2-mediated Cl^–/Cl^– exchange, measured as DIDS-sensitive ³⁶Cl^– efflux from Xenopus oocytes, was experimentally altered by varying pH_i at constant pH_o or varying pH_o. Pretreatment of oocytes with the His modifier diethylpyrocarbonate (DEPC) reduced basal ³⁶Cl^– efflux at pH_o 7.4 and acid shifted the pH_o vs. activity profile of wild-type AE2, suggesting that His residues might be involved in pH sensing. Single His mutants of AE2 were generated and expressed in oocytes. Although mutation of H1029 to Ala severely reduced transport and surface expression, other individual His mutants exhibited wild-type or near-wild-type levels of Cl^– transport activity with retention of pH_o sensitivity. In contrast to the effects of DEPC on wild-type AE2, pH_o sensitivity was significantly alkaline shifted for mutants H1144Y and H1145A and the triple mutants H846/H849/H1145A and H846/H849/H1160A. Although all functional mutants retained sensitivity to pH_i, pH_i sensitivity was enhanced for AE2 H1145A. The simultaneous mutation of five or more His residues, however, greatly decreased basal AE2 activity, consistent with the inhibitory effects of DEPC modification. The results show that multiple TMD His residues contribute to basal AE2 activity and its sensitivity to pH_i and pH_o. pH regulation; histidine residues; Cl^–/HCO₃^– exchange     

Dominant-negative effects of human P/Q-type Ca2+ channel mutations associated with episodic ataxia type 2

Episodic ataxia type 2 (EA2) is an inherited autosomal dominant disorder related to cerebellar dysfunction and is associated with mutations in the pore-forming _1A-subunits of human P/Q-type Ca²⁺ channels (Cav2.1 channels). The majority of EA2 mutations result in significant loss-of-function phenotypes. Whether EA2 mutants may display dominant-negative effects in human, however, remains controversial. To address this issue, five EA2 mutants in the long isoform of human _1A-subunits were expressed in Xenopus oocytes to explore their potential dominant-negative effects. Upon coexpressing the cRNA of _1A-WT with each _1A-mutant in molar ratios ranging from 1:1 to 1:10, the amplitude of Ba²⁺ currents through wild-type (WT)-Cav2.1 channels decreased significantly as the relative molar ratio of _1A-mutants increased, suggesting the presence of an _1A-mutant-specific suppression effect. When we coexpressed _1A-WT with proteins not known to interact with Cav2.1 channels, we observed no significant suppression effects. Furthermore, increasing the amount of auxiliary subunits resulted in partial reversal of the suppression effects in nonsense but not missense EA2 mutants. On the other hand, when we repeated the same coinjection experiments of _1A-WT and mutant using a splice variant of _1A-subunit that contained a considerably shorter COOH terminus (i.e., the short isoform), no significant dominant-negative effects were noted until we enhanced the relative molar ratio to 1:10. Altogether, these results indicate that for human WT-Cav2.1 channels comprising the long-_1A-subunit isoform, both missense and nonsense EA2 mutants indeed display prominent dominant-negative effects. channelopathy; voltage clamp; Xenopus oocytes; cerebellum; splice variants     

Altered gating properties of functional Cx26 mutants associated with recessive non-syndromic hearing loss

Connexins (Cx) form gap junctions that allow the exchange of small metabolites and ions. In the inner ear, Cx26 is the major gap junction protein and mutations in the Cx26-encoding gene, GJB2, are the most frequent cause of autosomal recessive non-syndromic hearing loss (DFNB1). We have functionally analyzed five Cx26 mutations associated with DFNB1, comprising the following single amino-acid substitutions: T8M, R143W, V153I, N206S and L214P. Coupling of cells expressing wild-type or mutant Cx26 was measured in the paired Xenopus oocyte assay. We found that the R143W, V153I and L214P mutations were unable to form functional channels. In contrast, the T8M and N206S mutants did electrically couple cells, though their voltage gating properties were different from wild-type Cx26 channels. The electrical coupling of oocytes expressing the T8M and N206S mutants suggest that these channels may retain high permeability to potassium ions. Therefore, deafness associated with Cx26 mutations may not only depend on reduced potassium re-circulation in the inner ear. Instead, abnormalities in the exchange of other metabolites through the cochlear gap junction network may also produce deafness.     

Cataracts and Microphthalmia Caused by a Gja8 Mutation in Extracellular Loop 2

The mouse semi-dominant Nm2249 mutation displays variable cataracts in heterozygous mice and smaller lenses with severe cataracts in homozygous mice. This mutation is caused by a Gja8^R205G point mutation in the second extracellular loop of the Cx50 (or α8 connexin) protein. Immunohistological data reveal that Cx50-R205G mutant proteins and endogenous wild-type Cx46 (or α3 connexin) proteins form diffuse tiny spots rather than typical punctate signals of normal gap junctions in the lens. The level of phosphorylated Cx46 proteins is decreased in Gja8^R205G/R205G mutant lenses. Genetic analysis reveals that the Cx50-R205G mutation needs the presence of wild-type Cx46 to disrupt lens peripheral fibers and epithelial cells. Electrophysiological data in Xenopus oocytes reveal that Cx50-R205G mutant proteins block channel function of gap junctions composed of wild-type Cx50, but only affect the gating of wild-type Cx46 channels. Both genetic and electrophysiological results suggest that Cx50-R205G mutant proteins alone are unable to form functional channels. These findings imply that the Gja8^R205G mutation differentially impairs the functions of Cx50 and Cx46 to cause cataracts, small lenses and microphthalmia. The Gja8^R205G mutation occurs at the same conserved residue as the human GJA8^R198W mutation. This work provides molecular insights to understand the cataract and microphthalmia/microcornea phenotype caused by Gja8 mutations in mice and humans.     

Opposite effects of Ni2+ on Xenopus and rat ENaCs expressed in Xenopus oocytes

Opposite effects of Ni²⁺ on Xenopus and rat ENaCs expressed in Xenopus oocytes. Am J Physiol Cell Physiol 289: C946–C958, 2005. First published June 8, 2005; .—The epithelial Na⁺ channel (ENaC) is modulated by various extracellular factors, including Na⁺, organic or inorganic cations, and serine proteases. To identify the effect of the divalent Ni²⁺ cation on ENaCs, we compared the Na⁺ permeability and amiloride kinetics of Xenopus ENaCs (xENaCs) and rat ENaCs (rENaCs) heterologously expressed in Xenopus oocytes. We found that the channel cloned from the kidney of the clawed toad Xenopus laevis [wild-type (WT) xENaC] was stimulated by external Ni²⁺, whereas the divalent cation inhibited the channel cloned from the rat colon (WT rENaC). The kinetics of amiloride binding were determined using noise analysis of blocker-induced fluctuation in current adapted for the transoocyte voltage-clamp method, and Na⁺ conductance was assessed using the dual electrode voltage-clamp (TEVC) technique. The inhibitory effect of Ni²⁺ on amiloride binding is not species dependent, because Ni²⁺ decreased the affinity (mainly reducing the association rate constant) of the blocker in both species in competition with Na⁺. Importantly, using the TEVC method, we found a prominent difference in channel conductance at hyperpolarizing voltage pulses. In WT xENaCs, the initial ohmic current response was stimulated by Ni²⁺, whereas the secondary voltage-activated current component remained unaffected. In WT rENaCs, only a voltage-dependent block by Ni²⁺ was obtained. To further study the origin of the xENaC stimulation by Ni²⁺, and based on the rationale of the well-known high affinity of Ni²⁺ for histidine residues, we designed -subunit mutants of xENaCs by substituting histidines that were expressed in oocytes, together with WT - and -subunits. Changing His²¹⁵ to Asp in one putative amiloride-binding domain (WYRFHY) in the extracellular loop between Na⁺ channel membrane segments M1 and M2 had no influence on the stimulatory effect of Ni²⁺, and neither did complete deletion of this segment. Next, we mutated His⁴¹⁶ flanked by His⁴¹¹ and Cys⁴¹⁷, a unique site for possible heavy metal ion chelation, and, with this quality, most proximal (100 amino acids upstream of the second putative amiloride binding site at the pore entrance), was found localized at M2. Replacing His⁴¹⁶ with arginine, aspartate, tyrosine, and alanine clearly affected amiloride binding in all cases, as well as Na⁺ conductance, as expressed in the xENaC current-voltage relationship, especially with regard to aspartate and tyrosine. However, similarly to those obtained with the WYRFHY stretch, none of these mutations could either abolish the stimulating effect of Ni²⁺ or reverse it to an inhibitory type. epithelia; divalent cations; amiloride; Na⁺; voltage clamp     

Aberrant hemichannel properties of Cx26 mutations causing skin disease and deafness

Mutations in the human GJB2 gene, which encodes connexin26 (Cx26), underlie various forms of hereditary deafness and skin disease. While it has proven difficult to discern the exact pathological mechanisms that cause these disorders, studies have shown that the loss or abnormal function of Cx26 protein has a profound effect on tissue homeostasis. Here, we used the Xenopus oocyte expression system to examine the functional characteristics of a Cx26 mutation (G45E) that results in keratitis-ichthyosis-deafness syndrome (KIDS) with a fatal outcome. Our data showed that oocytes were able to express both wild-type Cx26 and its G45E variant, each of which formed hemichannels and gap junction channels. However, Cx26-G45E hemichannels displayed significantly greater whole cell currents than wild-type Cx26, leading to cell lysis and death. This severe phenotype could be rescued in the presence of elevated Ca²⁺ levels in the extracellular milieu. Cx26-G45E could also form intercellular channels with a similar efficiency as wild-type Cx26, however, with increased voltage sensitive gating. We also compared Cx26-G45E with a previously described Cx26 mutant, A40V, which has an overlapping human phenotype. We found that both dominant Cx26 mutants elicited similar functional consequences and that cells coexpressing mutant and wild-type connexins predominantly displayed mutant-like behavior. These data suggest that mutant hemichannels may act on cellular homeostasis in a manner that can be detrimental to the tissues in which they are expressed. connexin     

Hyperkalemic periodic paralysis M1592V mutation modifies activation in human skeletal muscle Na+ channel

Mutations in thehuman skeletal muscle Na⁺ channelunderlie the autosomal dominant disease hyperkalemic periodic paralysis (HPP). Muscle fibers from affected individuals exhibit sustained Na⁺ currents thought to depolarizethe sarcolemma and thus inactivate normalNa⁺ channels. We expressed humanwild-type or M₁₅₉₂V mutant-subunits with the ₁-subunitin Xenopus laevis oocytes and recordedNa⁺ currents using two-electrodeand cut-open oocyte voltage-clamp techniques. The most prominentfunctional difference betweenM₁₅₉₂V mutant and wild-typechannels is a 5- to 10-mV shift in the hyperpolarized direction of thesteady-state activation curve. The shift in the activation curve forthe mutant results in a larger overlap with the inactivation curve thanthat observed for wild-type channels. Accordingly, the current throughM₁₅₉₂V channels displays a larger noninactivating component than does that through wild-type channels atmembrane potentials near 40 mV. The functional properties of theM₁₅₉₂V mutant resemble those ofthe previously characterized HPPT₇₀₄M mutant. Both clinicallysimilar phenotypes arise from mutations located at a distance from theputative voltage sensor of the channel.

     

Functional consequences of progressive cone dystrophy-associated mutations in the human cone photoreceptor cyclic nucleotide-gated channel CNGA3 subunit

Progressive cone dystrophies are a genetically heterogeneous group of disorders characterized by early deterioration of visual acuity and color vision, together with psychophysical and electrophysiological evidence of abnormal cone function and cone degeneration. Recently, three mutations in the gene encoding the CNGA3 subunit of cone photoreceptor cyclic nucleotide-gated (CNG) channels have been linked to progressive cone dystrophy in humans. To investigate the functional consequences of these mutations, we expressed mutant human CNGA3 subunits in Xenopus oocytes, alone or together with human CNGB3, and studied these channels using patch-clamp recording. Compared with wild-type channels, homomeric and heteromeric channels containing CNGA3-N471S or CNGA3-R563H subunits exhibited an increase in apparent affinity for cGMP and an increase in the relative agonist efficacy of cAMP compared with cGMP. In contrast, R277C subunits did not form functional homomeric or heteromeric channels. Cell surface expression levels, determined using confocal microscopy of green fluorescent protein-tagged subunits and patch-clamp recording, were significantly reduced for both R563H and R277C but unchanged for N471S. Overall, these results suggest that the plasma membrane localization and gating properties of cone CNG channels are altered by progressive cone dystrophy-associated mutations, providing evidence that supports the pathogenicity of these mutations. phosphodiesterase     

Gating kinetics of Shaker K+ channels are differentially modified by general anesthetics

TheShakerBK⁺ channel was used as a modelvoltage-gated channel to probe the interaction of volatile generalanesthetics with gating mechanisms. The effects of three anesthetics,chloroform (CHCl₃), isoflurane,and halothane, were studied using recombinant native and mutantShaker channels expressed inXenopus oocytes. Gating currents andmacroscopic ionic currents were recorded with the cut-open oocytevoltage-clamp technique. The effects ofCHCl₃ and isoflurane on gatingkinetics of noninactivating mutants were opposite, whereas halothanehad no effect. The effects on ionic currents were also agent dependent:CHCl₃ and halothane produced areduction of the macroscopic conductance, whereas isoflurane increasedit. The results indicate that the gating machinery of the channel ismostly insensitive to the anesthetics during activation until near theopen state. The effects on the conductance are mainly due to changes inthe transitions in and out of the open state. The data give support todirect protein-anesthetic interactions. The magnitude and nature of theeffects invite reconsideration ofShaker-likeK⁺ channels as important sites ofaction of general anesthetics.

     

Inversion of both gating polarity and CO2 sensitivity of voltage gating with D3N mutation of Cx50

The effect of CO₂-induced acidification on transjunctional voltage (V_j) gating was studied by dual voltage-clamp in oocytes expressing mouse connexin 50 (Cx50) or a Cx50 mutant (Cx50-D3N), in which the third residue, aspartate (D), was mutated to asparagine (N). This mutation inverted the gating polarity of Cx50 from positive to negative. CO₂ application greatly decreased the V_j sensitivity of Cx50 channels, and increased that of Cx50-D3N channels. CO₂ also affected the kinetics of V_j dependent inactivation of junctional current (I_j), decreasing the gating speed of Cx50 channels and increasing that of Cx50-D3N channels. In addition, the D3N mutation increased the CO₂ sensitivity of chemical gating such that even CO₂ concentrations as low as 2.5% significantly lowered junctional conductance (G_j). With Cx50 channels G_j dropped by 78% with a drop in intracellular pH (pH_i) to 6.83, whereas with Cx50-D3N channels G_j dropped by 95% with a drop in pH_i to just 7.19. We have previously hypothesized that the way in which V_j gating reacts to CO₂ might be related to connexin’s gating polarity. This hypothesis is confirmed here by evidence that the D3N mutation inverts the gating polarity as well as the effect of CO₂ on V_j gating sensitivity and speed. cell communication; lens; gap junctions; chemical gating; channel gating; Xenopus oocytes     

The human NBCe1-A mutant R881C, associated with proximal renal tubular acidosis, retains function but is mistargeted in polarized renal epithelia

The human electrogenic renal Na-HCO₃ cotransporter (NBCe1-A; SLC4A4) is localized to the basolateral membrane of proximal tubule cells. Mutations in the SLC4A4 gene cause an autosomal recessive proximal renal tubular acidosis (pRTA), a disease characterized by impaired ability of the proximal tubule to reabsorb HCO₃^– from the glomerular filtrate. Other symptoms can include mental retardation and ocular abnormalities. Recently, a novel homozygous missense mutant (R881C) of NBCe1-A was reported from a patient with a severe pRTA phenotype. The mutant protein was described as having a lower than normal activity when expressed in Xenopus oocytes, despite having normal Na⁺ affinity. However, without trafficking data, it is impossible to determine the molecular basis for the phenotype. In the present study, we expressed wild-type NBCe1-A (WT) and mutant NBCe1-A (R881C), tagged at the COOH terminus with enhanced green fluorescent protein (EGFP). This approach permitted semiquantification of surface expression in individual Xenopus oocytes before assay by two-electrode voltage clamp or measurements of intracellular pH. These data show that the mutation reduces the surface expression rather than the activity of the individual protein molecules. Confocal microscopy on polarized mammalian epithelial kidney cells [Madin-Darby canine kidney (MDCK)I] expressing nontagged WT or R881C demonstrates that WT is expressed at the basolateral membrane of these cells, whereas R881C is retained in the endoplasmic reticulum. In summary, the pathophysiology of pRTA caused by the R881C mutation is likely due to a deficit of NBCe1-A at the proximal tubule basolateral membrane, rather than a defect in the transport activity of individual molecules. bicarbonate; intracellular pH; acidbase; SLC4A4; Na⁺-HCO₃ cotransporter 1     

Episodic ataxia type 1 mutation F184C alters Zn2+-induced modulation of the human K+ channel Kv1.4-Kv1.1/Kvbeta1.1

Episodic ataxia type 1 (EA1) is a Shaker-like channelopathy characterized by continuous myokymia and attacks of imbalance with jerking movements of the head, arms, and legs. Although altered expression and gating properties of Kv1.1 channels underlie EA1, several disease-causing mechanisms remain poorly understood. It is likely that Kv1.1, Kv1.4, and Kv1.1 subunits form heteromeric channels at hippocampal mossy fiber boutons from which Zn²⁺ ions are released into the synaptic cleft in a Ca²⁺-dependent fashion. The sensitivity of this macromolecular channel complex to Zn²⁺ is unknown. Here, we show that this heteromeric channel possesses a high-affinity (<10 µM) and a low-affinity (<0.5 mM) site for Zn²⁺, which are likely to regulate channel availability at distinct presynaptic membranes. Furthermore, the EA1 mutation F184C, located within the S1 segment of the Kv1.1 subunit, markedly decreased the equilibrium dissociation constants for Zn²⁺ binding to the high- and low-affinity sites. The functional characterization of the Zn²⁺ effects on heteromeric channels harboring the F184C mutation also showed that this ion significantly 1) slowed the activation rate of the channel, 2) increased the time to reach peak current amplitude, 3) decreased the rate and amount of current undergoing N-type inactivation, and 4) slowed the repriming of the channel compared with wild-type channels. These results demonstrate that the EA1 mutation F184C will not only sensitize the homomeric Kv1.1 channel to extracellular Zn²⁺, but it will also endow heteromeric channels with a higher sensitivity to this metal ion. During the vesicular release of Zn²⁺, its effects will be in addition to the intrinsic gating defects caused by the mutation, which is likely to exacerbate the symptoms by impairing the integration and transmission of signals within specific brain areas. shaker channel gating; episodic ataxia type 1; Xenopus laevis cocytes     

Channel-forming peptide modulates transepithelial electrical conductance and solute permeability

NC-1059, a synthetic channel-forming peptide, transiently increases transepithelial electrical conductance (g_TE) and ion transport (as indicated by short-circuit current) across Madin-Darby canine kidney (MDCK) cell monolayers in a time- and concentration-dependent manner when apically exposed. g_TE increases from <2 to >40 mS/cm² over the low to middle micromolar range. Dextran polymer (9.5 but not 77 kDa) permeates the monolayer following apical NC-1059 exposure, suggesting that modulation of the paracellular pathway accounts for changes in g_TE. However, concomitant alterations in junctional protein localization (zonula occludens-1, occludin) and cellular morphology are not observed. Effects of NC-1059 on MDCK g_TE occur in nominally Cl^–- and Na⁺-free apical media, indicating that permeation by these ions is not required for effects on g_TE, although two-electrode voltage-clamp assays with Xenopus oocytes suggest that both Cl^– and Na⁺ permeate NC-1059 channels with a modest Cl^– permselectivity (P_Cl:P_Na = 1.3). MDCK monolayers can be exposed to multiple NC-1059 treatments over days to weeks without diminution of response, alteration in the time course, or loss of responsiveness to physiological and pharmacological secretagogues. Together, these results suggest that NC-1059 represents a valuable tool to investigate tight junction regulation and may be a lead compound for therapeutic interventions. transepithelial resistance; cystic fibrosis; tight junction; epithelial barrier; amphipathic -helix