A kinetic study on the stereospecific inhibition of KCNQ1 and I(Ks) by the chromanol 293B

1. Recently we and others have demonstrated a stereoselective inhibition of slowly activating human I(Ks) (KCNQ1/MinK) and homomeric KCNQ1 potassium channels by the enantiomers of the chromanol 293B. Here, we further characterized the mechanism of the 293B block and studied the influence of the 293B enantiomers on the gating kinetics of both channels after their heterologous expression in Xenopus oocytes. 2. Kinetic analysis of currents partially blocked with 10 microM of each 293B enantiomer revealed that only 3R,4S-293B but not 3S,4R-293B exhibited a time-dependent block of I(Ks) and KCNQ1 currents, indicating preferential open channel block activity. 3. Inhibition of both KCNQ1 and I(Ks) channels by 3R,4S-293B but not by 3S,4R-293B increased during a 2 Hz train of stimuli. 4. At high extracellular potassium concentrations the inhibition of KCNQ1 by 3R,4S-293B and 3S,4R-293B was unaffected. Drug inhibition of KCNQ1 and I(Ks) by both enantiomers also did not display a significant voltage-dependence, indicating that 293B does not strongly interact with permeant ions in the pore. 5. The inhibitory properties of 3R,4S-293B on I(Ks)-channels but not those of 3S,4R-293B fulfill the theoretical requirements for a novel class III antiarrhythmic drug, i.e. positive use-dependency. This enantiomer therefore represents a valuable pharmacological tool to evaluate the therapeutic efficiency of I(Ks)blockade.

DCPIB is a novel selective blocker of I(Cl,swell) and prevents swelling-induced shortening of guinea-pig atrial action potential duration

1. We identified the ethacrynic-acid derivative DCPIB as a potent inhibitor of I(Cl,swell), which blocks native I(Cl,swell) of calf bovine pulmonary artery endothelial (CPAE) cells with an IC(50) of 4.1 microM. Similarly, 10 microM DCPIB almost completely inhibited the swelling-induced chloride conductance in Xenopus oocytes and in guinea-pig atrial cardiomyocytes. Block of I(Cl,swell) by DCPIB was fully reversible and voltage independent. 2. DCPIB (10 microM) showed selectivity for I(Cl,swell) and had no significant inhibitory effects on I(Cl,Ca) in CPAE cells, on chloride currents elicited by several members of the CLC-chloride channel family or on the human cystic fibrosis transmembrane conductance regulator (hCFTR) after heterologous expression in Xenopus oocytes. DCPIB (10 microM) also showed no significant inhibition of several native anion and cation currents of guinea pig heart like I(Cl,PKA), I(Kr), I(Ks), I(K1), I(Na) and I(Ca). 3. In all atrial cardiomyocytes (n=7), osmotic swelling produced an increase in chloride current and a strong shortening of the action potential duration (APD). Both swelling-induced chloride conductance and AP shortening were inhibited by treatment of swollen cells with DCPIB (10 microM). In agreement with the selectivity for I(Cl,swell), DCPIB did not affect atrial APD under isoosmotic conditions. 4. Preincubation of atrial cardiomyocytes with DCPIB (10 microM) completely prevented both the swelling-induced chloride currents and the AP shortening but not the hypotonic cell swelling. 5. We conclude that swelling-induced AP shortening in isolated atrial cells is mainly caused by activation of I(Cl,swell). DCPIB therefore is a valuable pharmacological tool to study the role of I(Cl,swell) in cardiac excitability under pathophysiological conditions leading to cell swelling.

hKChIP2 is a functional modifier of hKv4.3 potassium channels: cloning and expression of a short hKChIP2 splice variant

OBJECTIVE

The Ca(2+) independent transient outward K(+) current (I(to1)) in the heart is responsible for the initial phase of repolarization. The hKv4.3 K(+) channel alpha-subunit contributes to the I(to1) current in many regions of the human heart. Consistently, downregulation of hKv4.3 transcripts in heart failure and atrial fibrillation is linked to reduction in I(to1) conductance. The recently cloned KChIP family of calcium sensors has been shown to modulate A-type potassium channels of the Kv4 K(+) channel subfamily.

METHODS AND RESULTS

We describe the cloning and tissue distribution of hKChIP2, as well as its functional interaction with hKv4.3 after expression in Xenopus oocytes. Furthermore, we isolated a short splice variant of the hKChIP2 gene (hKCNIP2), which represents the major hKChIP2 transcript. Northern blot analyses revealed that hKChIP2 is expressed in the human heart and occurs in the adult atria and ventricles but not in the fetal heart. Upon coexpression with hKv4.3 both hKChIP2 isoforms increased the current amplitude, slowed the inactivation and increased the recovery from inactivation of hKv4.3 currents. For the first time we analyzed the influence of a KChIP protein on the voltage of half-maximal inactivation of Kv4 channels. We demonstrate that the hKChIP2 isoforms shifted the half-maximal inactivation to more positive potentials, but to a different extent. By elucidating the genomic structure, we provide important information for future analysis of the hKCNIP2 gene in candidate disorders. In the course of this work we mapped the hKCNIP2 gene to chromosome 10q24.

CONCLUSIONS

Heteromeric hKv4.3/hKChIP2 currents more closely resemble native epicardial I(to1), suggesting that hKChIP2 is a true beta-subunit of human cardiac I(to1). As a result hKChIP2 might play a role in cardiac diseases, where a contribution of I(to1) has been shown.

Characterization of TASK-4, a novel member of the pH-sensitive, two-pore domain potassium channel family

We report the primary sequence of TASK-4, a novel member of the acid-sensitive subfamily of tandem pore K(+) channels. TASK-4 transcripts are widely expressed in humans, with highest levels in liver, lung, pancreas, placenta, aorta and heart. In Xenopus oocytes TASK-4 generated K(+) currents displaying a marked outward rectification which was lost by elevation of extracellular K(+). TASK-4 currents were efficiently blocked by barium (83% inhibition at 2 mM), only weakly inhibited by 1 mM concentrations of quinine, bupivacaine and lidocaine, but not blocked by tetraethylammonium, 4-aminopyridine and Cs(+). TASK-4 was sensitive to extracellular pH, but in contrast to other TASK channels, pH sensitivity was shifted to more alkaline pH. Thus, TASK-4 in concert with other TASK channels might regulate cellular membrane potential over a wide range of extracellular pH.

Molecular cloning and functional expression of KCNQ5, a potassium channel subunit that may contribute to neuronal M-current diversity

We have isolated KCNQ5, a novel human member of the KCNQ potassium channel gene family that is differentially expressed in subregions of the brain and in skeletal muscle. When expressed in Xenopus oocytes, KCNQ5 generated voltage-dependent, slowly activating K(+)-selective currents that displayed a marked inward rectification at positive membrane voltages. KCNQ5 currents were insensitive to the K(+) channel blocker tetraethylammonium but were strongly inhibited by the selective M-current blocker linopirdine. Upon coexpression with the structurally related KCNQ3 channel subunit, current amplitudes increased 4-5-fold. Compared with homomeric KCNQ5 currents, KCNQ3/KCNQ5 currents also displayed slower activation kinetics and less inward rectification, indicating that KCNQ5 combined with KCNQ3 to form functional heteromeric channel proteins. This functional interaction between KCNQ5 and KCNQ3, a component of the M-channel, suggests that KCNQ5 may contribute to a diversity of heteromeric channels underlying native neuronal M-currents.

Molecular physiology of renal chloride channels

Chloride channels are present in all cells of the kidney. Physiological studies have revealed a bewildering variety of kidney chloride channels, but only in the past few years has molecular information on some of these channels emerged. This review will focus on cloned chloride channels expressed in renal cells.

Golgi localization and functionally important domains in the NH2 and COOH terminus of the yeast CLC putative chloride channel Gef1p

GEF1 encodes the single CLC putative chloride channel in yeast. Its disruption leads to a defect in iron metabolism (Greene, J. R., Brown, N. H., DiDomenico, B. J., Kaplan, J., and Eide, D. (1993) Mol. Gen. Genet. 241, 542-553). Since disruption of GEF2, a subunit of the vacuolar H+-ATPase, leads to a similar phenotype, it was previously suggested that the chloride conductance provided by Gef1p is necessary for vacuolar acidification. We now show that gef1 cells indeed grow less well at less acidic pH. However, no defect in vacuolar acidification is apparent from quinacrine staining, and Gef1p co-localizes with Mnt1p in the medial Golgi. Thus, Gef1p may be important in determining Golgi pH. Systematic alanine scanning of the amino and the carboxyl terminus revealed several regions essential for Gef1p localization and function. One sequence (FVTID) in the amino terminus conforms to a class of sorting signals containing aromatic amino acids. This was further supported by point mutations. Alanine scanning of the carboxyl terminus identified a stretch of roughly 25 amino acids which coincides with the second CBS domain, a conserved protein motif recently identified. Mutations in the first CBS domain also destroyed proper function and localization. The second CBS domain can be transplanted to the amino terminus without loss of function, but could not be replaced by the corresponding domain of the homologous mammalian channel ClC-2.

Identification of functionally important regions of the muscular chloride channel CIC-1 by analysis of recessive and dominant myotonic mutations

Mutations in the muscular voltage-dependent Cl-channel, CIC-1, lead to recessive and dominant myotonia. Here we analyse the effects of one dominant (G200R) and three recessive (Y150C, Y261C, and M485V) mutations after functional expression in Xenopus oocytes. Glycine 200 is a highly conserved amino acid located in a conserved stretch in the putatively cytoplasmic loop between domains D2 and D3. Similar to several other dominant mutations the amino acid exchange G200R leads to a drastic shift by approximately 65 mV of the open probability curve to more positive voltages. As explored by co-expression studies, the shift is intermediate in heteromeric mutant/WT channels. Open channel properties such as single channel conductance, rectification or ion selectivity are not changed. Thus we identified a new region of the CIC-1 protein in which mutations can lead to drastic shifts of the voltage dependence. The recessive mutation M485V, which is located in a conserved region at the beginning of domain D10, leads to a drastic reduction of the single channel conductance from 1.5 pS for WT to approximately 0.3 pS. In addition, the mutant is strongly inwardly rectifying and deactivates incompletely at negative voltages. Ion-selectivity, however, is unchanged. These electrophysiological properties fully explain the recessive phenotype of the mutation and identify a new region of the protein that is involved in ion permeation and gating of the CIC-1 channel. The other two recessive mutations (Y150C and Y261C) had been found in a compound heterozygous patient. Surprisingly, expression of these mutants in oocytes yielded currents indistinguishable from WT CIC-1 when explored by two-electrode voltage clamp recording and patch clamping (either singly or both mutations co-expressed). Other mechanisms that are not faithfully represented by the Xenopus expression system must therefore be responsible for the myotonic symptoms associated with these mutations.

Localization and induction by dehydration of ClC-K chloride channels in the rat kidney

We investigate the intrarenal expression of two recently cloned chloride channels, rClC-K1 and rClC-K2, by reverse transcriptase-polymerase chain reaction on single microdissected tubules from the rat kidney and by immunohistochemistry using a polyclonal antibody that recognizes both highly homologous channels. Both rClC-K1 and rClC-K2 mRNAs were detected in outer medullary late proximal tubules (S3), papillary ascending thin limbs (ATL), and outer medullary (MTAL) and cortical (CTAL) thick ascending limbs, distal tubules (DCT), and cortical, outer medullary, and inner medullary collecting ducts. Indirect immunofluorescence studies demonstrated that the rClC-K proteins were restricted to the basolateral membranes from ATL, DCT, and collecting ducts cells, whereas CTAL and MTAL exhibited a more diffuse basal staining. When rats were dehydrated, a condition which increased the expression of rClC-K1 in cortex and medulla, a weak cytoplasmic staining was found in late proximal tubule cells. Thus these results demonstrate that rat kidney ClC-K channels are predominantly located in the basolateral membranes from cells of the late segments of the renal tubule where most of chloride reabsorption takes place.

A family of putative chloride channels from Arabidopsis and functional complementation of a yeast strain with a CLC gene disruption

We have cloned four novel members of the CLC family of chloride channels from Arabidopsis thaliana. The four plant genes are homologous to a recently isolated chloride channel gene from tobacco (CLC-Nt1; Lurin, C., Geelen, D., Barbier-Brygoo, H., Guern, J., and Maurel, C. (1996) Plant Cell 8, 701-711) and are about 30% identical in sequence to the most closely related CLC-6 and CLC-7 putative chloride channels from mammalia. AtCLC transcripts are broadly expressed in the plant. Similarly, antibodies against the AtCLC-d protein detected the protein in all tissues, but predominantly in the silique. AtCLC-a and AtCLC-b are highly homologous to each other ( approximately 87% identity), while being approximately 50% identical to either AtCLC-c or AtCLC-d. None of the four cDNAs elicited chloride currents when expressed in Xenopus oocytes, either singly or in combination. Among these genes, only AtCLC-d could functionally substitute for the single yeast CLC protein, restoring iron-limited growth of a strain disrupted for this gene. Introduction of disease causing mutations, identified in human CLC genes, abolished this capacity. Consistent with a similar function of both proteins, the green fluorescent protein-tagged AtCLC-d protein showed the identical localization pattern as the yeast ScCLC protein. This suggests that in Arabidopsis AtCLC-d functions as an intracellular chloride channel.

A common molecular basis for three inherited kidney stone diseases

Kidney stones (nephrolithiasis), which affect 12% of males and 5% of females in the western world, are familial in 45% of patients and are most commonly associated with hypercalciuria. Three disorders of hypercalciuric nephrolithiasis (Dent's disease, X-linked recessive nephrolithiasis (XRN), and X-linked recessive hypophosphataemic rickets (XLRH)) have been mapped to Xp11.22 (refs 5-7). A microdeletion in one Dent's disease kindred allowed the identification of a candidate gene, CLCN5 (refs 8,9) which encodes a putative renal chloride channel. Here we report the investigation of 11 kindreds with these renal tubular disorders for CLCN5 abnormalities; this identified three nonsense, four missense and two donor splice site mutations, together with one intragenic deletion and one microdeletion encompassing the entire gene. Heterologous expression of wild-type CLCN5 in Xenopus oocytes yielded outwardly rectifying chloride currents, which were either abolished or markedly reduced by the mutations. The common aetiology for Dent's disease, XRN and XLRH indicates that CLCN5 may be involved in other renal tubular disorders associated with kidney stones.

Cloning and functional expression of rat CLC-5, a chloride channel related to kidney disease

We have cloned a novel member of the CLC chloride channel family from rat brain, rCLC-5. The cDNA predicts a 83-kDa protein belonging to the branch including CLC-3 and CLC-4, with which it shares approximately 80% identity. Expression of rCLC-5 in Xenopus oocytes elicits novel anion currents. They are strongly outwardly rectifying and have a conductivity sequence of NO3- > Cl- > Br- > I- >> glutamate-. Although CLC-5 has consensus sites for phosphorylation by protein kinase A, raising the intracellular cAMP concentration had no effect on these currents. Currents were also unchanged when rCLC-5 was coexpressed with rCLC-3 and rCLC-4, either singly or in combination. rCLC-5 is expressed predominantly in kidney and also in brain, lung, and liver. Along the nephron, rCLC-5 message is detectable in all tubule segments investigated, but expression in the glomerulus and the S2 segment of the proximal tubule is low.

Spectrum of mutations in the major human skeletal muscle chloride channel gene (CLCN1) leading to myotonia

Autosomal dominant myotonia congenita and autosomal recessive generalized myotonia (GM) are genetic disorders characterized by the symptom of myotonia, which is based on an electrical instability of the muscle fiber membrane. Recently, these two phenotypes have been associated with mutations in the major muscle chloride channel gene CLCN1 on human chromosome 7q35. We have systematically screened the open reading frame of the CLCN1 gene for mutations by SSC analysis (SSCA) in a panel of 24 families and 17 single unrelated patients with human myotonia. By direct sequencing of aberrant SSCA conformers were revealed 15 different mutations in a total of 18 unrelated families and 13 single patients. Of these, 10 were novel (7 missense mutations, 2 mutations leading to frameshift, and 1 mutation predicted to affect normal splicing). In our overall sample of 94 GM chromosomes we were able to detect 48 (51%) mutant GM alleles. Three mutations (F413C), R894X, and a 14-bp deletion in exon 13) account for 32% of the GM chromosomes in the German population. Our finding that A437T is probably a polymorphism is in contrast to a recent report that the recessive phenotype GM is associated with this amino acid change. We also demonstrate that the R894X mutation may act as a recessive or a dominant mutation in the CLCN1 gene, probably depending on the genetic background. Functional expression of the R894X mutant in Xenopus oocytes revealed a large reduction, but not complete abolition, of chloride currents. Further, it had a weak dominant negative effect on wild-type currents in coexpression studies. Reduction of currents predicted for heterozygous carriers are close to the borderline value, which is sufficient to elicit myotonia.

Mutations in dominant human myotonia congenita drastically alter the voltage dependence of the CIC-1 chloride channel

Autosomal dominant myotonia congenita (Thomsen's disease) is caused by mutations in the muscle chloride channel CIC-1. Several point mutations found in affected families (I29OM, R317Q, P480L, and Q552R) dramatically shift gating to positive voltages in mutant/WT heterooligomeric channels, and when measurable, even more so in mutant homooligomers. These channels can no longer contribute to the repolarization of action potentials, fully explaining why they cause dominant myotonia. Most replacements of the isoleucine at position 290 shift gating toward positive voltages. Mutant/WT heterooligomers can be partially activated by repetitive depolarizations, suggesting a role in shortening myotonic runs. Remarkably, a human mutation affecting an adjacent residue (E291K) is fully recessive. Large shifts in the voltage dependence of gating may be common to many mutations in dominant myotonia congenita.

Role of innervation, excitability, and myogenic factors in the expression of the muscular chloride channel ClC-1. A study on normal and myotonic muscle

The muscular chloride channel (ClC-1) is essential for a normal excitability of mature mammalian muscle fibers; inactivation of the corresponding gene by mutations leads to hyperexcitability of muscle, the hallmark of the disease myotonia. In the mouse, there is very little ClC-1 mRNA in myotubes, and its concentration increases steeply during postnatal development, suggesting a role of the motor nerve in ClC-1 expression. We investigated the response of the expression of the corresponding gene Clc-1 to different patterns of muscle activity as controlled by sarcolemmal excitability and by innervation. In rat and mouse, the level of ClC-1 mRNA was higher in fast (extensor digitorum longus) than in slow (soleus) muscle. Myotonia in the ADR mouse is caused by an insertional mutation leading to the adr allele of the Clc-1 gene and to grossly abnormal ClC-1 mRNAs. Nevertheless, in +/adr heterozygous, phenotypically wild type (WT) animals, the expression levels of both alleles correspond to the gene dosage. However, in the myotonic ADR mouse in which both Clc-1 genes are defective, ClC-1 mRNA levels in slow muscle were nearly as high as in WT fast muscle. In WT muscle, denervation within 2 days caused a drastic reduction of the ClC-1 mRNA level and at the same time an increase of myogenin and MyoD mRNAs. Neither effect of denervation was observed in myotonic mice (homozygous for the alleles adr or adrK), suggesting that spontaneous electrical activity of the hyperexcitable sarcolemma may substitute for nerve activity. Furthermore, potential MyoD/myogenin-binding sequence motifs were identified in the 5' regulatory region of the Clc-1 gene. These findings suggest that the activity-dependent regulation of the muscular chloride channel 1 gene is mediated by myogenic factors.

Genomic organization of the human muscle chloride channel CIC-1 and analysis of novel mutations leading to Becker-type myotonia

The muscle chloride channel CIC-1 regulates the electric excitability of the skeletal muscle membrane. Mutations in the gene encoding this chloride channel (CLCN1) are responsible for both human purely myotonic disorders, autosomal recessive generalized myotonia (Becker's disease, GM) and autosomal dominant myotonia congenita (Thomsen's disease, MC). We now show that the protein-coding sequence of the CLCN1 gene is organized into 23 exons. The CIC-1 upstream region contains a canonical TATA box, several consensus binding sites for myogenic transcription factors and two other putative regulatory elements. SSCA analysis of a German GM family revealed that affected members are compound heterozygotes having two novel mutations. G979A affects a splice consensus site at the end of exon 8, and G1488T in exon 14 leads to a replacement of a positive charge in a highly conserved putative transmembrane domain (R496S). Functional expression of R496S cRNA in Xenopus oocytes did not yield detectable currents. It neither suppressed wild-type currents in a co-expression assay, confirming it as a recessive mutation.

Nonsense and missense mutations in the muscular chloride channel gene Clc-1 of myotonic mice

In mature vertebrate muscle, the chloride channel Clc-1 is necessary for the stabilization of the resting potential. Its functional defect leads to the disease myotonia. The ADR mouse (phenotype ADR, genotype adr/adr) is an animal model for human myotonias. The adr gene is a member of a family of non-complementing recessive autosomal mutations ("alleles" of adr) that cause myotonia in the mouse. The standard allele adr has arisen by the insertion of a retroposon into the chloride channel gene Clc-1 (Steinmeyer, K., Klocke, R., Ortland, C., Gronemeier, M., Jockusch, H., Gründer, S., and Jentsch, T. J. (1991) Nature 354, 304-308). In order to study the nature of two other alleles, adrmto and adrK, we have analyzed overlapping Clc-1 cDNA amplification products by the hydroxylamine and osmium tetroxide modification technique and direct sequencing. A comparison between ADR*MTO and C57BL/6 wild type showed six base pair substitutions, one of which resulted in a stop codon in position 47, whereas the five others are either silent or lead to amino acid substitutions in non-conserved regions of the Clc-1 sequence and were already present in the wild type inbred SWR/J strain from which adrmto was derived. The detection of the stop codon in the adrmto allele is further indication of the identity of the Clc-1 chloride channel with the adr myotonia gene in the mouse, because a chain termination close to the N terminus would necessarily destroy gene function. For the ethylnitrosourea-induced mutation adrK, an Ile-->Thr exchange in codon 553 was identified. As this affects a conserved residue within a highly conserved region of the Clc-1 gene, a functional significance of this residue is suggested.

Multimeric structure of ClC-1 chloride channel revealed by mutations in dominant myotonia congenita (Thomsen)

Voltage-gated ClC chloride channels play important roles in cell volume regulation, control of muscle excitability, and probably transepithelial transport. ClC channels can be functionally expressed without other subunits, but it is unknown whether they function as monomers. We now exploit the properties of human mutations in the muscle chloride channel, ClC-1, to explore its multimeric structure. This is based on analysis of the dominant negative effects of ClC-1 mutations causing myotonia congenita (MC, Thomsen's disease), including a newly identified mutation (P480L) in Thomsen's own family. In a co-expression assay, Thomsen's mutation dramatically inhibits normal ClC-1 function. A mutation found in Canadian MC families (G230E) has a less pronounced dominant negative effect, which can be explained by functional WT/G230E heterooligomeric channels with altered kinetics and selectivity. Analysis of both mutants shows independently that ClC-1 functions as a homooligomer with most likely four subunits.

Low single channel conductance of the major skeletal muscle chloride channel, ClC-1

We expressed the skeletal muscle chloride channel, ClC-1, in HEK293 cells and investigated it with the patch-clamp technique. Macroscopic properties are similar to those obtained after expression in Xenopus oocytes, except that faster gating kinetics are observed in mammalian cells. Nonstationary noise analysis revealed that both rat and human ClC-1 have a low single channel conductance of about 1 pS. This finding may explain the lack of single-channel data for chloride channels from skeletal muscle despite its high macroscopic chloride conductance.

Evidence for genetic homogeneity in autosomal recessive generalised myotonia (Becker)

Generalised myotonia Becker (GM) is an autosomal recessively inherited muscle disorder. Affected subjects exhibit myotonic muscle stiffness in all skeletal muscles with marked hypertrophy in the legs. A transient muscle weakness is particularly pronounced in the arms and hands and is a typical symptom of the disorder. Recently, we showed complete linkage of the disorder GM to the gene (CLCN1) coding for the skeletal muscle chloride channel CLC-1 and the TCRB gene on chromosome 7 in German families. In the study presented here we performed linkage analysis on 14 new GM families. The GM locus was again completely linked to both the CLCN1 and the TCRB gene in all families with a combined lod score of Z = 9.26 at a recombination fraction of theta = 0.00. This confirms our previous data and supports the hypothesis that GM is a genetically homogeneous disorder. The previously detected T to G missense mutation is found on 15% of the 66 GM chromosomes counted so far.

The skeletal muscle chloride channel in dominant and recessive human myotonia

Autosomal recessive generalized myotonia (Becker's disease) (GM) and autosomal dominant myotonia congenita (Thomsen's disease) (MC) are characterized by skeletal muscle stiffness that is a result of muscle membrane hyperexcitability. For both diseases, alterations in muscle chloride or sodium currents or both have been observed. A complementary DNA for a human skeletal muscle chloride channel (CLC-1) was cloned, physically localized on chromosome 7, and linked to the T cell receptor beta (TCRB) locus. Tight linkage of these two loci to GM and MC was found in German families. An unusual restriction site in the CLC-1 locus in two GM families identified a mutation associated with that disease, a phenylalanine-to-cysteine substitution in putative transmembrane domain D8. This suggests that different mutations in CLC-1 may cause dominant or recessive myotonia.

Completely functional double-barreled chloride channel expressed from a single Torpedo cDNA

We have performed an electrophysiological analysis of the recently cloned Torpedo marmorata Cl- channel. Functional expression of Cl- channels in oocytes of Xenopus laevis previously injected with cRNA yielded an outward-rectifying current activated by hyperpolarization. Replacement of Cl- with other anions significantly reduced or inhibited the current. Single-channel recordings from cell-attached patches exhibited burst-like Cl- channel activity with rapid fluctuations between three equally spaced substates (0 pS, 9 pS, and 18 pS). The properties of the cloned Cl- channel were almost identical to those of the reconstituted native T. californica Cl- channel and were in full agreement with the predictions of the double-barreled channel model [Hanke, W. & Miller, C. (1983) J. Gen. Physiol. 82, 25-45]. Our results imply that the cloned cDNA codes for the completely functional Torpedo electroplax Cl- channel.

Inactivation of muscle chloride channel by transposon insertion in myotonic mice

MYOTONIA (stiffness and impaired relaxation of skeletal muscle) is a symptom of several diseases caused by repetitive firing of action potentials in muscle membranes. Purely myotonic human diseases are dominant myotonia congenita (Thomsen) and recessive generalized myotonia (Becker), whereas myotonic dystrophy is a systemic disease. Muscle hyperexcitability was attributed to defects in sodium channels and/or to a decrease in chloride conductance (in Becker's myotonia and in genetic animal models). Experimental blockage of Cl- conductance (normally 70-85% of resting conductance in muscle) in fact elicits myotonia. ADR mice are a realistic animal model for recessive autosomal myotonia. In addition to Cl- conductance, many other parameters are changed in muscles of homozygous animals. We have now cloned the major mammalian skeletal muscle chloride channel (ClC-1). Here we report that in ADR mice a transposon of the ETn family has inserted into the corresponding gene, destroying its coding potential for several membrane-spanning domains. Together with the lack of recombination between the Clc-1 gene and the adr locus, this strongly suggests a lack of functional chloride channels as the primary cause of mouse myotonia.

Primary structure and functional expression of a developmentally regulated skeletal muscle chloride channel

Skeletal muscle is unusual in that 70-85% of resting membrane conductance is carried by chloride ions. This conductance is essential for membrane-potential stability, as its block by 9-anthracene-carboxylic acid and other drugs causes myotonia. Fish electric organs are developmentally derived from skeletal muscle, suggesting that mammalian muscle may express a homologue of the Torpedo mamorata electroplax chloride channel. We have now cloned the complementary DNA encoding a rat skeletal muscle chloride channel by homology screening to the Cl- channel from Torpedo. It encodes a 994-amino-acid protein which is about 54% identical to the Torpedo channel and is predominantly expressed in skeletal muscle. Messenger RNA amounts in that tissue increase steeply in the first 3-4 weeks after birth, in parallel with the increase in muscle Cl- conductance. Expression from cRNA in Xenopus oocytes leads to 9-anthracene-carboxylic acid-sensitive currents with time and voltage dependence typical for macroscopic muscle Cl- conductance. This and the functional destruction of this channel in mouse myotonia suggests that we have cloned the major skeletal muscle chloride channel.