Susan A. Cook

Editing-defective tRNA synthetase causes protein misfolding and neurodegeneration

Misfolded proteins are associated with several pathological conditions including neurodegeneration. Although some of these abnormally folded proteins result from mutations in genes encoding disease-associated proteins (for example, repeat-expansion diseases), more general mechanisms that lead to misfolded proteins in neurons remain largely unknown. Here we demonstrate that low levels of mischarged transfer RNAs (tRNAs) can lead to an intracellular accumulation of misfolded proteins in neurons. These accumulations are accompanied by upregulation of cytoplasmic protein chaperones and by induction of the unfolded protein response. We report that the mouse sticky mutation, which causes cerebellar Purkinje cell loss and ataxia, is a missense mutation in the editing domain of the alanyl-tRNA synthetase gene that compromises the proofreading activity of this enzyme during aminoacylation of tRNAs. These findings demonstrate that disruption of translational fidelity in terminally differentiated neurons leads to the accumulation of misfolded proteins and cell death, and provide a novel mechanism underlying neurodegeneration.

A major gene affecting age-related hearing loss in C57BL/6J mice

A major gene responsible for age-related hearing loss (AHL) in C57BL/6J mice was mapped by analyses of a (C57BL/6J x CAST/Ei) x C57BL/6J backcross. AHL, as measured by elevated auditory-evoked brainstem response (ABR) thresholds, segregated among backcross mice as expected for a recessive, primarily single-gene trait. Both qualitative and quantitative linkage analyses gave the same genetic map position for the AHL gene (Ahl on chromosome 10, near D10Mit5. Marker assisted selection was then used to produce congenic lines of C57BL/6J that contain different CAST-derived segments of chromosome 10. ABR test results and cochlear histopathology of aged progenitors of these congenic lines are presented. Ahl is the first gene causing late-onset, non-syndromic hearing loss that has been reported in the mouse.

Scrambler, a new neurological mutation of the mouse with abnormalities of neuronal migration.

A novel spontaneous neurological mutation, scrambler (scm), appeared in the inbred mouse strain DC/Le (dancer) in 1991. Mice homozygous for this recessive mutation are recognized by an unstable gait and whole-body tremor. The cerebella of 30-day-old scrambler homozygotes are hypoplastic and devoid of folia; however, neither seizures nor abnormal brain wave patterns have been observed. Homozygous scrambler mutants have an ataxic gait which in the male may be a contributory factor in the failure to mate. Female homozygotes mate and breed. Life span is not reduced in either sex. Scrambler is similar to the reeler mutation in phenotype and pathology and, like reeler, probably results from defective neuronal migration. We mapped the scrambler mutation to Chromosome (Chr) 4, proving that it is distinct from the recently cloned reeler gene on Chr 5. We also determined the map position of the agrin gene, Agrn, on Chr 4, and on this basis eliminated it as a candidate for scm. Currently there is no known homology of scrambler with human lissencephalies or other human disorders caused by abnormal neuronal migration.

A missense mutation in the previously undescribed gene Tmhs underlies deafness in hurry-scurry (hscy) mice

Mouse deafness mutations provide valuable models of human hearing disorders and entry points into molecular pathways important to the hearing process. A newly discovered mouse mutation named hurry-scurry (hscy) causes deafness and vestibular dysfunction. Scanning electron microscopy of cochleae from 8-day-old mutants revealed disorganized hair bundles, and by 50 days of age, many hair cells are missing. To positionally clone hscy, 1,160 F2 mice were produced from an intercross of (C57BL/6-hscy × CAST/EiJ) F1 hybrids, and the mutation was localized to a 182-kb region of chromosome 17. A missense mutation causing a critical cysteine to phenylalanine codon change was discovered in a previously undescribed gene within this candidate interval. The gene is predicted to encode an integral membrane protein with four transmembrane helices. A synthetic peptide designed from the predicted protein was used to produce specific polyclonal antibodies, and strong immunoreactivity was observed on hair bundles of both inner and outer hair cells in cochleae of newborn +/+ controls and +/hscy heterozygotes but was absent in hscy/hscy mutants. Accordingly, the gene was given the name “tetraspan membrane protein of hair cell stereocilia,” symbol Tmhs. Two related proteins (>60% amino acid identity) are encoded by genes on mouse chromosomes 5 and 6 and, together with the Tmhs-encoded protein (TMHS), comprise a distinct tetraspan subfamily. Our localization of TMHS to the apical membrane of inner ear hair cells during the period of stereocilia formation suggests a function in hair bundle morphogenesis.

Chromosomal localization of the murine gene and two related sequences encoding high-mobility-group I and Y proteins

HMG-I and its isoform HMG-Y are members of the abundant high-mobility-group of nonhistone chromatin proteins; they bind to A + T-rich regions of chromosomal DNA and are expressed at high levels in rapidly dividing, undifferentiated mammalian cells. HMG-I and HMG-Y are alternatively spliced products of a single functional gene, designated Hmgi in the mouse. Here, we report the occurrence of at least three distinct Hmgi-related loci in the mouse. Only one of these loci was present in all of the 10 mouse strains examined; therefore, this locus most likely represents the transcriptionally active, functional gene, Hmgi. Genetic linkage analysis of interspecific and intersubspecific backcrosses showed that Hmgi is located in the t-complex region of mouse Chromosome 17. Two additional Hmgi-related sequences, Hmgi-rs1 and Hmgi-rs2, were found only in certain mouse strains and probably represent pseudogenes. Hmgi-rs1 is located on Chromosome 11; it was present in all of the standard laboratory inbred mouse strains examined but was absent in wild-derived inbred strains of Mus spretus, M. musculus castaneus, and M. m. molossinus. Hmgi-rs2 was found only in M. m. castaneus and is located on Chromosome 6. Hmgi genes have not been previously mapped in any species, but the location of the probable functional gene on murine Chromosome 17 suggests that the homologous gene in humans is located on Chromosome 6.

ZFP191 is required by oligodendrocytes for CNS myelination

The controlling factors that prompt mature oligodendrocytes to myelinate axons are largely undetermined. In this study, we used a forward genetics approach to identify a mutant mouse strain characterized by the absence of CNS myelin despite the presence of abundant numbers of late-stage, process-extending oligodendrocytes. Through linkage mapping and complementation testing, we identified the mutation as a single nucleotide insertion in the gene encoding zinc finger protein 191 (Zfp191), which is a widely expressed, nuclear-localized protein that belongs to a family whose members contain both DNA-binding zinc finger domains and protein-protein-interacting SCAN domains. Zfp191 mutants express an array of myelin-related genes at significantly reduced levels, and our in vitro and in vivo data indicate that mutant ZFP191 acts in a cell-autonomous fashion to disrupt oligodendrocyte function. Therefore, this study demonstrates that ZFP191 is required for the myelinating function of differentiated oligodendrocytes.

Neuromuscular degeneration (nmd): a mutation on mouse Chromosome 19 that causes motor neuron degeneration

Neuromuscular degeneration, nmd, is a spontaneous autosomal recessive mutation in the mouse producing progressive hindlimb impairment caused by spinal muscular atrophy. We used an intersubspecific intercross between B6.BKs-nmd2J/+ and Mus musculus castaneus (CAST/Ei) to map the nmd mutation to mouse Chromosome (Chr) 19 with the most likely gene order: nmd-(D19Se12, Pygm)-Cntf-Pomc2-D19Mit16-Cyp2c-Got1. nmd maps near muscle deficient, mdf, and has a very similar clinical phenotype, but allele tests and histological differences suggest that nmd is a distinct mutation at a different locus. Although closely linked, nmd recombined with the candidate genes muscle glycogen phosphorylase, Pygm, and ciliary neurotrophic factor, Cntf.

A Mouse Model for Meckel Syndrome Type 3

Meckel-Gruber syndrome type 3 (MKS3; OMIM 607361) is a severe autosomal recessive disorder characterized by bilateral polycystic kidney disease. Other malformations associated with MKS3 include cystic changes in the liver, polydactyly, and brain abnormalities (occipital encephalocele, hydrocephalus, and Dandy Walker-type cerebellar anomalies). The disorder is hypothesized to be caused by defects in primary cilia. In humans, the underlying mutated gene, TMEM67, encodes transmembrane protein 67, also called meckelin (OMIM 609884), which is an integral protein of the renal epithelial cell and membrane of the primary cilium. Here, we describe a spontaneous deletion of the mouse ortholog, Tmem67, which results in polycystic kidney disease and death by 3 wk after birth. Hydrocephalus also occurs in some mutants. We verified the mutated gene by transgenic rescue and characterized the phenotype with microcomputed tomography, histology, scanning electron microscopy, and immunohistochemistry. This mutant provides a mouse model for MKS3 and adds to the growing set of mammalian models essential for studying the role of the primary cilium in kidney function.

Megencephaly: a new mouse mutation on chromosome 6 that causes hypertrophy of the brain.

Megencephaly, enlarged brain, occurs in several acquired and inherited human diseases including Sotos syndrome, Robinow syndrome, Canavan’s disease, and Alexander disease. This defect can be distinguished from macrocephaly, an enlarged head, which usually occurs as a consequence of congenital hydrocephalus. The pathology of megencephaly in humans has not been well defined, nor has the defect been reported to occur spontaneously in any other species. In this report we describe a recessive mutation in the mouse that results in a 25% increase in brain size in the first 8 months of life. We have determined that the megencephaly is characterized by overall hypertrophy of the brain, and not by hyperplasia of particular cell types or by hypertrophy of a singular tissue compartment. Edema and hydrocephalus are absent. This mutation has been mapped to mid-distal mouse Chromosome (Chr) 6 in a region homologous with human Chr 12.

Identification and genetic mapping of 151 dispersed members of 16 ribosomal protein multigene families in the mouse.

More than 150 individual members of 16 ribosomal protein multigene families were identified as DNA restriction fragments and genetically mapped. The ribosomal protein gene-related sequences are widely dispersed throughout the mouse genome. Map positions were determined by analysis of 144 progeny mice from both an interspecific (C57BL/6J × SPRET/Ei)F1 × SPRET/Ei and an intersubspecific (C57BL/6J × CAST/Ei)F1 × C57BL/6J backcross. In addition, 30 members of the multigene families encoding PGK1 ODC, and TPI, including five new loci for ODC and one new locus for TPI, were characterized and mapped. Interspecific backcross linkage data for 29 nonecotropic murine leukemia retroviruses endogenous to C57BL/6J mice are also reported. Transmission ratio distortions and recombination frequencies are compared between the two backcrosses.