A missense mutation in Fgfr1 causes ear and skull defects in hush puppy mice.

The hush puppy mouse mutant has been shown previously to have skull and outer, middle, and inner ear defects, and an increase in hearing threshold. The fibroblast growth factor receptor 1 (Fgfr1) gene is located in the region of chromosome 8 containing the mutation. Sequencing of the gene in hush puppy heterozygotes revealed a missense mutation in the kinase domain of the protein (W691R). Homozygotes were found to die during development, at approximately embryonic day 8.5, and displayed a phenotype similar to null mutants. Reverse transcription PCR indicated a decrease in Fgfr1 transcript in heterozygotes and homozygotes. Generation of a construct containing the mutation allowed the function of the mutated receptor to be studied. Immunocytochemistry showed that the mutant receptor protein was present at the cell membrane, suggesting normal expression and trafficking. Measurements of changes in intracellular calcium concentration showed that the mutated receptor could not activate the IP(3) pathway, in contrast to the wild-type receptor, nor could it initiate activation of the Ras/MAP kinase pathway. Thus, the hush puppy mutation in fibroblast growth factor receptor 1 appears to cause a loss of receptor function. The mutant protein appears to have a dominant negative effect, which could be due to it dimerising with the wild-type protein and inhibiting its activity, thus further reducing the levels of functional protein. A dominant modifier, Mhspy, which reduces the effect of the hush puppy mutation on pinna and stapes development, has been mapped to the distal end of chromosome 7 and may show imprinting.

A loss of function allele for murine Staufen1 leads to impairment of dendritic Staufen1-RNP delivery and dendritic spine morphogenesis.

The dsRNA-binding protein Staufen was the first RNA-binding protein proven to play a role in RNA localization in Drosophila. A mammalian homolog, Staufen1 (Stau1), has been implicated in dendritic RNA localization in neurons, translational control, and mRNA decay. However, the precise mechanisms by which it fulfills these specific roles are only partially understood. To determine its physiological functions, the murine Stau1 gene was disrupted by homologous recombination. Homozygous stau1(tm1Apa) mutant mice express a truncated Stau1 protein lacking the functional RNA-binding domain 3. The level of the truncated protein is significantly reduced. Cultured hippocampal neurons derived from stau1(tm1Apa) homozygous mice display deficits in dendritic delivery of Stau1-EYFP and beta-actin mRNA-containing ribonucleoprotein particles (RNPs). Furthermore, these neurons have a significantly reduced dendritic tree and develop fewer synapses. Homozygous stau1(tm1Apa) mutant mice are viable and show no obvious deficits in development, fertility, health, overall brain morphology, and a variety of behavioral assays, e.g., hippocampus-dependent learning. However, we did detect deficits in locomotor activity. Our data suggest that Stau1 is crucial for synapse development in vitro but not critical for normal behavioral function.

Characterization of a new mouse mutant, flouncer, with a balance defect and inner ear malformation.

HYPOTHESIS: Balance anomalies are often associated with abnormalities of the vestibular part of the inner ear. We studied a newly generated mouse mutant with balance defects and asked whether its behavioral anomalies were associated with inner ear defects. Furthermore, we asked whether the mutation responsible for the defects was located in the same region of mouse chromosome 4 as several other mouse mutations that we have previously described. BACKGROUND: Phenotypic and genotypic analysis of mouse mutants with hearing or balance problems has helped greatly with the identification of the genes involved in deafness and has contributed to the understanding of mechanisms of normal hearing and balance. This article describes a new mouse mutant, flouncer, that shows a balance defect. The flouncer mutation shows semidominant inheritance, and was generated by mutagenesis using N- ethyl-N- nitrosourea. METHODS: Hearing was assessed by the Preyer reflex (ear-flick) test. Behavioral tests including open field and swimming tests were performed. The morphology of the middle and inner ears was investigated by microdissection, clearing using glycerol, paint-filling of the labyrinth, and scanning electron microscopy. RESULTS: Flouncer mutants showed vestibular dysfunction but do respond to sounds. Phenotypically, mutants had various degrees of truncation of the lateral semicircular canals, small or obliterated round window of the cochlea, and mild morphologic anomalies of the stapes. Flouncer mutants showed circling behavior and hyperactivity. Linkage mapping using a backcross has indicated that the mutation lies in proximal chromosome 4 proximal to D4Mit171. CONCLUSION: The lateral semicircular canal has been described to be the most commonly affected part of the inner ear in humans, and flouncer provides a mouse model for genetic and developmental analysis of such defects.

Disproportionate language impairment in children using cochlear implants.

OBJECTIVES: To examine the nature of previously unexplained, severe language impairments in some children using a cochlear implant (CI). DESIGN: Six prelingually deaf children with unexplained, "disproportionate" language problems (DLI group) were matched to Control children on etiology, age at implantation, and CI experience. All children completed a test battery used to identify specific language impairment in normally hearing children. RESULTS: Despite equivalent performance IQ, significant differences were found between the DLI and Control children on all five language tests. CONCLUSIONS: Language difficulties experienced by some children using a CI seem to be additional to those produced by their deafness and may reflect the same, predominantly inherited basis as specific language impairment.

Two new mouse mutants with vestibular defects that map to the highly mutable locus on chromosome 4.

The purpose of this study was to characterise two new mouse mutants, carousel, and whirligig. Both were derived from a large-scale mutagenesis programme which screened for dominantly inherited mutations that cause hearing impairments and balance defects. Genetic mapping placed both mutations on the proximal region of chromosome 4. Paint-filling and clearing techniques revealed abnormalities of the lateral semicircular canal. Scanning electron microscopy showed increased numbers of outer and inner hair cells in the apical region of the organ of Corti. The behavioural, genetic, and morphological characteristics lead us to the conclusion that both mutants are probably alleles of seven previously identified mutants which all map to proximal chromosome 4 and share similar defects of the lateral semicircular canal. We suggest that this region may be particularly susceptible to ENU mutagenesis independent of genetic background.