The mouse Clc1/myotonia gene: ETn insertion, a variable AATC repeat, and PCR diagnosis of alleles.

Myotonias are muscle diseases in which the function of the muscular chloride channel ClC-1 is impaired. Null alleles of the corresponding Clc1 gene on mouse chromosome (Chr) 6 provide animal models for human myotonias. It was shown that the allele adr (Clc1adr) is due to an insertion of an ETn type transposon that is transcribed and leads to multiple splicing events; the allele mto (Clc1adr-mto) involves a stop codon near the N-terminus. We have determined the genomic organization of the mouse Clc1 gene and the sequence requirements for the transposon insertion in the Clc1adr allele. The mouse Clc1 gene is composed of 23 exons, ranging from 39 to 372 bp, and spans approximately 23 kb of genomic DNA. The exon/intron organization is highly homologous to that of the human CLCN1 gene; the homology of the coding sequence is 97% to rat and 89% to human. In the adr allele the ETn transposon is inserted into intron 12, the largest intron. Whereas the 5' and 3' LTR sequences of the ETn transposon are homologous to those reported for other insertional mutations of the mouse, no consensus motif for an insertion target site could be defined. On the basis of flanking sequences, we provide duplex PCR diagnoses for the adr, adr-mto, and wild-type alleles of Clc1. Close to the 3' end of intron 12, a tetranucleotide repeat (AATC)n was found that is polymorphic between mouse species Mus musculus, M. molossinus, M. castaneus, and M. spretus, and can thus be used for chromosomal mapping studies.

Chloride channel 2 gene (Clc2) maps to chromosome 16 of the mouse, extending a region of conserved synteny with human chromosome 3q.

The Clc2 gene of the mouse codes for the ubiquitously expressed chloride channel ClC-2, a member of a family of at least seven voltage gated chloride channels, some of which are implicated in hereditary diseases. Using a mouse interspecies back-cross panel, we have mapped Clc2 to Chr 16, proximal to the somatostatin gene Smst, extending a region of documented conserved synteny to human Chr 3q.

Exploring the mammalian neuromuscular system by analysis of mutations: spinal muscular atrophy and myotonia.

Any biological structure can be studied using mutations that interfere either with its emergence or its function. We investigate spontaneous and induced mutations in the mouse that affect neuromuscular development and function. The wobbler mouse (phenotype WR, genotype wr/wr) suffers from muscular atrophy because of the degeneration of 20-40% of the motoneurones; it is also unable to produce functional spermatozoa. As a step towards positional cloning of the wr gene, we have mapped the locus to proximal chromosome 11, thus excluding CNTF and its receptor as candidates, and suggesting the closely-linked Rab 1 gene encoding a GTP-binding protein as a possibility. In the case of the adr (arrested development of righting response) mouse, which shows hyperexcitability of mature muscle fibres due to a reduction of the 'dampening' function of chloride conductance at resting potential, we have shown that the defect is in the chloride channel gene adr/Clc-1 on chromosome 6. This allowed us to predict via synteny the chromosomal location of human Thomsen's and Becker's myotonias as close to the TCRB gene on human chromosome 7q. The combination of these approaches with gene-targeting approaches will allow genetic analysis of the establishment and structure of the neuromuscular system.

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.

Chromosomal mapping in the mouse of eight K(+)-channel genes representing the four Shaker-like subfamilies Shaker, Shab, Shaw, and Shal.

The four Shaker-like subfamilies of Shaker-, Shab-, Shaw-, and Shal-related K+ channels in mammals have been defined on the basis of their sequence homologies to the corresponding Drosophila genes. Using interspecific backcrosses between Mus musculus and Mus spretus, we have chromosomally mapped in the mouse the Shaker-related K(+)-channel genes Kcna1, Kcna2, Kcna4, Kcna5, and Kcna6; the Shab-related gene Kcnb1; the Shaw-related gene Kcnc4; and the Shal-related gene Kcnd2. The following localizations were determined: Chr 2, cen-Acra-Kcna4-Pax-6-a-Pck-1-Kras-3-Kcn b1 (corresponding human Chrs 11p and 20q, respectively); Chr 3, cen-Hao-2-(Kcna2, Kcnc4)-Amy-1 (human Chr 1); and Chr 6, cen-Cola-2-Met-Kcnd2-Cpa-Tcrb-adr/Clc-1-Hox-1.1-Myk - 103-Raf-1-(Tpi-1, Kcna1, Kcna5, Kcna6) (human Chrs 7q and 12p, respectively). Thus, there is a cluster of at least three Shaker-related K(+)-channel genes on distal mouse Chr 6 and a cluster on Chr 2 that at least consists of one Shaker-related and one Shaw-related gene. The three other K(+)-channel genes are not linked to each other. The map positions of the different types of K(+)-channel genes in the mouse are discussed in relation to those of their homologs in man and to hereditary diseases of mouse and man that might involve K+ channels.

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.