Mutation of a putative protein degradation gene LITAF/SIMPLE in Charcot-Marie-Tooth disease 1C.

BACKGROUND: Charcot-Marie-Tooth (CMT) neuropathy is a heterogeneous group of inherited disorders of the peripheral nervous system. The authors recently mapped an autosomal dominant demyelinating form of CMT type 1 (CMT1C) to chromosome 16p13.1-p12.3. OBJECTIVE: To find the gene mutations underlying CMT1C. METHODS: The authors used a combination of standard positional cloning and candidate gene approaches to identify the causal gene for CMT1C. Western blot analysis was used to determine relative protein levels in patient and control lymphocyte extracts. Northern blotting was used to characterize gene expression in 1) multiple tissues; 2) developing sciatic nerve; and 3) nerve-crush and nerve-transection experiments. RESULTS: The authors identified missense mutations (G112S, T115N, W116G) in the LITAFgene (lipopolysaccharide-induced tumor necrosis factor-alpha factor) in three CMT1C pedigrees. LITAF, which is also referred to as SIMPLE, is a widely expressed gene encoding a 161-amino acid protein that may play a role in protein degradation pathways. The mutations associated with CMT1C were found to cluster, defining a domain of the LITAF protein having a critical role in peripheral nerve function. Western blot analysis suggested that the T115N and W116G mutations do not alter the level of LITAF protein in peripheral blood lymphocytes. The LITAF transcript is expressed in sciatic nerve, but its level of expression is not altered during development or in response to nerve injury. This finding is in stark contrast to that seen for other known genes that cause CMT1. CONCLUSIONS: Mutations in LITAF may account for a significant proportion of CMT1 patients with previously unknown molecular diagnosis and may define a new mechanism of peripheral nerve perturbation leading to demyelinating neuropathy.

Charcot-Marie-Tooth neuropathy: clinical phenotypes of four novel mutations in the MPZ and Cx 32 genes.

Charcot-Marie-Tooth Hereditary Neuropathy is a heterogeneous syndrome associated with mutations in several different genes including peripheral myelin protein 22, myelin P0, connexin 32, and early growth response 2. There is considerable variability in the phenotypic expression of this syndrome and the relationship of this variability to mutation genotypes requires extensive analysis. Here we describe the phenotypes and genotypes of four new mutations underlying the Charcot-Marie-Tooth syndrome and document segregation with disease. Four families with Charcot-Marie-Tooth were ascertained, examined, and evaluated electrophysiologically. Each family had peripheral blood DNA screened for mutations in myelin protein 22, myelin P0, and connexin 32. Two families were found with new mutations in the myelin P0 gene: S140T in the extracellular domain and K236del in the cytoplasmic domain. All families showed segregation of the mutations with the Charcot-Marie-Tooth phenotype as did a new family with the rare G163R mutation in the membrane domain. A 49-year-old man with the S140T mutation demonstrated conduction block on electrophysiological testing. A family with a novel S49P mutation in the connexin 32 gene had a neuropathy with very slow nerve conduction. These new mutations in the myelin P0 and connexin 32 genes help to clarify the pathophysiology of the clinical Charcot-Marie-Tooth syndrome. The S140T mutation in myelin P0 can be associated with conduction block and Charcot-Marie-Tooth should be part of the differential diagnosis of that phenomenon. Mutations in the cytoplasmic domain of myelin P0 can cause clinical neuropathy. The S49P mutation in the connexin 32 gene can produce aspects of a demyelinating type of X-linked hereditary neuropathy.

Mutations in a plasma membrane Ca2+-ATPase gene cause deafness in deafwaddler mice.

Hearing loss is the most common sensory deficit in humans. Because the auditory systems of mice and humans are conserved, studies on mouse models have predicted several human deafness genes and identified new genes involved in hearing. The deafwaddler (dfw) mouse mutant is deaf and displays vestibular/motor imbalance. Here we report that the gene encoding a plasma membrane Ca2+-ATPase type 2 pump (Atp2b2, also known as Pmca2) is mutated in dfw. An A-->G nucleotide transition in dfw DNA causes a glycine-to-serine substitution at a highly conserved amino-acid position, whereas in a second allele, dfw2J, a 2-base-pair deletion causes a frameshift that predicts a truncated protein. In the cochlea, the protein Atp2b2 is localized to stereocilia and the basolateral wall of hair cells in wild-type mice, but is not detected in dfw2J mice. This indicates that mutation of Atp2b2 may cause deafness and imbalance by affecting sensory transduction in stereocilia as well as neurotransmitter release from the basolateral membrane. These mutations affecting Atp2b2 in dfw and dfw2J are the first to be found in a mammalian plasma membrane calcium pump and define a new class of deafness genes that directly affect hair-cell physiology.

Physical and genetic maps of the deafwaddler region on distal mouse Chr 6.

The deafwaddler (dfw) mutation, displaying motor ataxia and profound deafness, arose spontaneously in a C3H/HeJ colony and was mapped previously to distal mouse Chr 6. In this study, a high-resolution genetic map was generated by positioning 10 microsatellite markers and 5 known genes on a 968-meioses intersubspecific backcross segregating for dfw [(CAST/Ei(-)+/+ x C3HeB/ FeJ-dfw/dfw) x C3HeB/FeJ-dfw/dfw], giving the following marker order and sex-averaged distances: D6Mit64-(0.10 + 0.10 cM)-Pang-(1.24 + 0.36 cM)-Itpr1-(0.62 + 0.25 cM)-D6Mit108-(0.52 + 0.23 cM)-D6Mit54-(0.21 + 0.15 cM)-D6Mit23, D6Mit107, D6Mit328-(0.72 + 0.27 cM)-D6Mit11-(0.21 + 0.15 cM)-dfw-(0.93 + 0.31 cM)-Gat4, D6Mit55-(0.10 + 0.10 cM)-D6Mit63-(0.31 + 0.18 cM)-Syn2-(0.62 + 0.25 cM)-D6Mit44 (Rho). Female and male genetic maps are similar immediately surrounding the dfw locus, but show marked differences in other areas. A yeast artificial chromosome-based physical map suggests that the closest markers flanking the dfw locus, D6Mit11 (proximal) and Gat4, D6Mit55 (distal), are contained within 650-950 kb. The human homologues of the flanking loci Itpr1 (proximal) and Syn2 (distal) map to chromosome 3p25-p26, suggesting that the human homologue of the dfw gene is located within this same region.

Physical mapping of potassium channel gene clusters on mouse chromosomes three and six.

Mammalian voltage-gated K channel genes have been divided into four subfamilies (Shaker, Shab, Shal, and Shaw) based on their sequence identity and similarity to related genes in Drosophila. Genetic mapping of the voltage-gated K channel genes has shown that similar multigene clusters exist on mouse Chr 3 and 6 and suggests that the clusters may have arisen through chromosomal duplication. In this report, YAC-based physical maps of the clustered mouse Shaker-like K channel genes have been constructed using restriction endonuclease and yeast chromosome fragmentation approaches. These data define the physical spacing as 5'-Kcna3-(60 kb)-Kcna2-(90 kb)-Kcna8-3' on Chr 3, and as 5'-Kcna6-(80 kb)-Kcna1-(110 kb)-Kcna5-3' on Chr 6, with all genes oriented in a head-to-tail manner within their respective clusters. These detailed physical maps of both K channel gene clusters provide additional support for the idea of an ancient genome tetraploidization event.

The type 1 inositol 1,4,5-trisphosphate receptor gene is altered in the opisthotonos mouse.

The opisthotonos (opt) mutation arose spontaneously in a C57BL/Ks-db2J colony and is the only known, naturally occurring allele of opt. This mutant mouse was first identified based on its ataxic and convulsive phenotype. Genetic and molecular data presented here demonstrate that the type 1 inositol 1,4,5-trisphosphate receptor (IP3R1) protein, which serves as an IP3-gated channel to release calcium from intracellular stores, is altered in the opt mutant. A genomic deletion in the IP3R1 gene removes two exons from the IP3R1 mRNA but does not interrupt the translational reading frame. The altered protein is predicted to have lost several modulatory sites and is present at markedly reduced levels in opt homozygotes. Nonetheless, a strong calcium release from intracellular stores can be elicited in cerebellar Purkinje neurons treated with the metabotropic glutamate receptor (mGluR) agonist quisqualate (QA). QA activates Group 1 mGluRs linked to GTP-binding proteins that stimulate phospholipase C and subsequent production of the intracellular messenger IP3, leading to calcium mobilization via the IP3R1 protein. The calcium response in opt homozygotes shows less attenuation to repeated QA application than in control littermates. These data suggest that the convulsions and ataxia observed in opt mice may be caused by the physiological dysregulation of a functional IP3R1 protein.

Molecular genetic analysis of distal mouse chromosome 6 defines gene order and positions of the deafwaddler and opisthotonos mutations.

Two neurological mutants deafwaddler (dfw) and opisthotonos (opt) and a cluster of three Shaker-like potassium (K) channel genes Kcna1, Kcna5, and Kcna6 were all independently mapped to distal mouse chromosome six (Chr 6). In this study, genetic and molecular techniques were employed to assess directly the linkage of the two mutants and to investigate the likelihood that a mutation in one of the three K channel genes may underlie dfw and/or opt. Genetic crosses testing for allelism showed that the dfw and opt mutations complement each other. Additional crosses demonstrated that the mutants are separated by a recombination distance of 3.1 +/- 1.8 cM. Microsatellite marker analysis of the crossover chromosomes recovered from the opt, dfw recombination study indicated that opt maps centromeric to dfw. The location of the K channel genes relative to the dfw mutation was determined by mapping these genes and 15 microsatellite markers in an intersubspecific backcross (IB) segregating for dfw [(CAST/Ei-+/+ x C3HeB/FeJ-dfw/dfw) x C3HeB/FeJ-dfw/dfw]. Analysis of the backcross progeny positioned the dfw locus in the interval between the microsatellite markers D6Mit11 and D6Mit55, D6Mit63. The K channel cluster maps telomeric to dfw. This study establishes the gene order cen-opt-dfw-Rho (D6Mit44)-Kcna1, Kcna5, Kcna6 on distal mouse Chr 6 and suggests that the neurological mutants opt and dfw affect two different genes, neither of which is caused by a mutation in any one of the three clustered K channels.

Voltage-gated potassium channel genes are clustered in paralogous regions of the mouse genome.

Cloning of the Drosophila Shaker gene established that a neurological phenotype including locomotor dysfunction can be caused by a mutation in a voltage-gated potassium (K) channel gene. Shaker sequences have been used to isolate a large family of related K channel genes from both flies and mammals. Toward elucidating the evolutionary relationship between loci and the potential causal connection that K channels may have to mammalian genetic disorders, we report here the genetic mapping of 12-16 different murine, voltage-gated K channel genes. We find that multiple genes, in some cases from distantly related K channel subfamilies, occur in clusters in the mouse genome. These mapping results suggest that the K channel gene subfamilies arose through ancient localized gene duplication events, followed by chromosomal duplications and rearrangements as well as further gene duplication. We also note that several neurologic disorders of both mouse and human are associated with the chromosomal regions containing K channel genes.

Selective regulation of Gi alpha 1 expression and function in PC12 cells by cAMP.

Hormone and neutrotransmitter receptor systems regulate both the activity and expression of GTP-binding proteins (G-proteins). However, relatively little is known about the mechanism by which this regulation occurs. One G-protein subtype, Gi alpha 1, is expressed primarily in neuronal cells. Here, we demonstrate the selective regulation of Gi alpha 1 mRNA and protein levels by cAMP. Treatment of PC12 cells with forskolin increases Gi alpha protein levels. Similarly, incubation of PC12 cells with agents that increase intracellular levels of cAMP, including forskolin, dibutyryl-cAMP, and 8-bromo-cAMP, induce a two- to fourfold increase in Gi alpha 1 mRNA levels. Furthermore, the effect of increased intracellular cAMP is specific for Gi alpha 1 mRNA expression; the levels of mRNA encoding other G-protein subtypes remain unaltered. cAMP-stimulated Gi alpha 1 expression occurs within hours of treatment and is sustained for days. Increasing intracellular cAMP by activation of cell surface adenosine receptors also increases Gi alpha 1 mRNA levels. Treatment of PC12 cells with phorbol esters, NGF, or depolarizing concentrations of KCl did not increase Gi alpha 1 mRNA expression, demonstrating that Gi alpha 1 expression is specifically regulated by cAMP. Guanine nucleotide-mediated inhibition of adenylate cyclase activity was measured in order to determine if the change in Gi alpha protein expression was accompanied by a change in G-protein function. Adenylate cyclase activity in PC12 cells treated with an adenosine analog and therefore expressing higher levels of Gi alpha protein is more sensitive to inhibition by guanine nucleotides than in nontreated PC12 cells.(ABSTRACT TRUNCATED AT 250 WORDS)