Kyproula Christodoulou

Glycyl tRNA synthetase mutations in Charcot-Marie-Tooth disease type 2D and distal spinal muscular atrophy type V

Charcot-Marie-Tooth disease type 2D (CMT2D) and distal spinal muscular atrophy type V (dSMA-V) are axonal peripheral neuropathies inherited in an autosomal dominant fashion. Our previous genetic and physical mapping efforts localized the responsible gene(s) to a well-defined region on human chromosome 7p. Here, we report the identification of four disease-associated missense mutations in the glycyl tRNA synthetase gene in families with CMT2D and dSMA-V. This is the first example of an aminoacyl tRNA synthetase being implicated in a human genetic disease, which makes genes that encode these enzymes relevant candidates for other inherited neuropathies and motor neuron diseases.

Charcot-Marie-Tooth type 4B is caused by mutations in the gene encoding myotubularin-related protein-2.

A gene mutated in Charcot-Marie-Tooth disease type 4B (CMT4B), an autosomal recessive demyelinating neuropathy with myelin outfoldings, has been mapped on chromosome 11q22. Using a positional-cloning strategy, we identified in unrelated CMT4B patients mutations occurring in the gene MTMR2, encoding myotubularin-related protein-2, a dual specificity phosphatase (DSP).

A novel NF-L mutation Pro22Ser is associated with CMT2 in a large Slovenian family

Abstract. Charcot-Marie-Tooth (CMT) disease is the most-common form of inherited motor and sensory neuropathy. The autosomal dominant axonal form of the disease (CMT2) is currently subdivided into seven types based on genetic localization. These are CMT2A (1p35-p36), CMT2B (3q13-q22), CMT2C (unknown), CMT2D (7p14), CMT2E (8p21), HMNSP (3q13.1), and CMT2F (7q11-q21). Two loci have thus far been identified for autosomal recessive CMT2; ARCMT2A (1q21.1-q21.3) and ARCMT2B (19q13.3). Mutations in four genes (connexin 32, myelin protein zero, neurofilament-light, and kinesin) have been associated with the CMT2 phenotype. We identified a novel neurofilament-light missense mutation (C64T) that causes the disease in a large Slovenian CMT2 family. This novel mutation shows complete co-segregation with the dominantly inherited CMT2 phenotype in our family.

Linkage of otosclerosis to a third locus (OTSC3) on human chromosome 6p21.3-22.3

Clinical otosclerosis (OMIM 166800/605727) has a prevalence of 0.2-1% among white adults, making it the single most common cause of hearing impairment in this group. It is caused by abnormal bone homeostasis of the otic capsule with the consequent development of sclerotic foci that invade the stapedio-vestibular joint (oval window) interfering with free motion of the stapes. Impaired ossicular chain mobility results in a conductive hearing loss. We identified the first locus for otosclerosis (OTSC1) on chromosome 15 in 1998 and reported a second locus (OTSC2) on chromosome 7 last year. Here we present results of a genome wide linkage study on a large Cypriot family segregating otosclerosis. Results of this study exclude linkage to OTSC1 and OTSC2 and identify a third locus, OTSC3, on chromosome 6p. The defined OTSC3 interval covers the HLA region, consistent with reported associations between HLA-A/HLA-B antigens and otosclerosis.

Phenotypic and cellular expression of two novel connexin32 mutations causing CMT1X

Objective: To determine the phenotypic and cellular expression of two novel connexin32 (Cx32) mutations causing X-linked Charcot–Marie–Tooth disease (CMT1X). Methods: The authors evaluated several members of two families with CMT1X clinically, electrophysiologically, pathologically, and by genetic testing. The Cx32 mutations were expressed in vitro and studied by immunocytochemistry. Results: In both families, men were more severely affected than women with onset in the second decade of life. In the first family, the phenotype was that of demyelinating polyneuropathy with variable involvement of peripheral nerves. There was clinical evidence of CNS involvement in at least three of the patients, with extensor plantar responses and brisk reflexes. In the second family, the affected man presented with symmetric polyneuropathy and intermediate slowing of conduction velocities, whereas affected women had prominent asymmetric atrophy of the leg muscles. The authors identified two novel missense mutations resulting in L143P amino acid substitution in the first family and in V140E substitution in the second family, both located in the third transmembrane domain of Cx32. Expression of these Cx32 mutations in communication-incompetent HeLa cells and immunocytochemical analysis revealed that both mutants were retained intracellularly and were localized in the Golgi apparatus. In contrast to wild-type protein, they did not form gap junctions. Conclusion: These novel connexin32 (Cx32) mutations cause a spectrum of clinical manifestations characteristic of Charcot–Marie–Tooth disease (CMT1X), including demyelinating or intermediate polyneuropathy, which is often asymmetric, and CNS involvement in one family. The position and cellular expression of Cx32 mutations alone cannot fully predict these phenotypic variations in CMT1X.

Chromosome 17p-linked myasthenias stem from defects in the acetylcholine receptor ε-subunit gene

Objective: To identify and to characterize functionally the mutational basis of congenital myasthenic syndromes (CMS) linked to chromosome 17p. Background: A total of 37 patients belonging to 13 CMS families, 9 of them consanguineous, were investigated. All patients were linked previously to the telomeric region of chromosome 17p. Two candidate genes in this region encode synaptobrevin 2, a presynaptic protein, and the ε-subunit of the acetylcholine receptor (AChR). Direct sequencing of the synaptobrevin 2 gene revealed no mutations. The authors thus searched for mutations in the ε-subunit gene of AChR. Methods: Direct sequencing of the AChR ε-subunit, restriction analysis, allele-specific PCR, and expression studies in human embryonic kidney cells were performed. Results: The authors identified two previously characterized and five novel ε-subunit gene mutations, all homozygous, in the 13 kinships. Two of the novel mutations are truncating (ε723delC and ε760ins8), one is a missense mutation in the signal peptide region (εV-13D), one is a missense mutation in the N-terminal extracellular domain (εT51P), and one is a splice donor site mutation in intron 10 (εIVS10+2T→G). Unaffected family members have no mutations or are heterozygous. Expression studies indicate that the four novel mutations in the coding region of the gene and the most likely transcript of the splice-site mutation, which skips exon 10, are low-expressor or null mutations. Conclusions: Chromosome 17p-linked congenital myasthenic syndromes are caused by low-expressor/null mutations in the AChR ε-subunit gene. Mutations in this gene are a common cause of CMS in eastern Mediterranean countries.

Mapping of the second Friedreich's ataxia (FRDA2) locus to chromosome 9p23-p11: evidence for further locus heterogeneity

Abstract. Friedreichs ataxia (FRDA), the most-common form of autosomal recessive ataxia, is inherited in most cases by a large expansion of a GAA triplet repeat in the first intron of the frataxin (X25) gene. Genetic heterogeneity in FRDA has been previously reported in typical FRDA families that do not link to the FRDA locus on chromosome 9q13. We report localization of a second FRDA locus (FRDAff2) to chromosome 9p23–9p11, and we provide evidence for further genetic heterogeneity of the disease, in a family with the classic FRDA phenotype.

Huntington's disease in Greece: the experience of 14 years.

Panas M, Karadima G, Vassos E, Kalfakis N, Kladi A, Christodoulou K, Vassilopoulos D. Huntingtons disease in Greece: the experience of 14 years.

Complement C1Q polymorphisms modulate onset in familial amyloidotic polyneuropathy TTR Val30Met.

BACKGROUND Familial amyloidotic polyneuropathy (FAP) TTR Val30Met is a lethal autosomal dominant sensorimotor and autonomic neuropathy due to a substitution of methionine for valine at position 30 of the transthyretin (TTR) gene. Amyloid, composed of mutated TTR, is deposited in the peripheral nervous system, myocardium and kidneys. Considerable variability in the age of onset and penetrance of the disease occurs in different countries. Penetrance in Sweden, Cyprus and Portugal is 2%, 28% and 80% respectively. Environmental and genetic factors are believed to contribute to this variability. So far, no single modifier gene has been unequivocally associated with age of onset or penetrance. METHODS Candidate modifier genes were chosen from among those coding for chaperone proteins co-localized with TTR deposits in peripheral nerves. Seventy one TTRVal30Met carriers, 51 affected and 20 asymptomatic, belonging to 22 unrelated Greek-Cypriot families, and 59 normal controls were recruited for this study. Sequencing of the coding regions of TTR, serum amyloid P (APCS) and complement C1Q (A, B and C) genes was performed and APOE genotypes were determined. We searched for correlations between various polymorphisms of chaperone proteins and age of disease onset. RESULTS Four new and 4 previously described single nucleotide substitutions were identified. One polymorphic site in C1QA (rs172378) and one in C1QC (rs9434) as well as the epsilon2 allele correlated with age of onset (p<0.05). CONCLUSIONS Our study has identified polymorphisms which may influence the FAP-TTR Val30Met phenotype. Identifying modifier genes and their protein products may contribute to therapeutic advances.

A Novel GBA2 Gene Missense Mutation in Spastic Ataxia

Autosomal recessive cerebellar ataxias (ARCA) encompass a heterogeneous group of rare diseases that affect the cerebellum, the spinocerebellar tract and/or the sensory tracts of the spinal cord. We investigated a consanguineous Cypriot family with spastic ataxia, aiming towards identification of the causative mutation. Family members were clinically evaluated and studied at the genetic level. Linkage analysis at marker loci spanning known ARCA genes/loci revealed linkage to the APTX locus. Thorough investigation of the APTX gene excluded any possible mutation. Whole genome linkage screening using microsatellite markers and whole genome SNP homozygosity mapping using the Affymetrix Genome‐Wide Human SNP Array 6.0 enabled mapping of the disease gene/mutation in this family to Chromosome 9p21.1‐p13.2. Due to the large number of candidate genes within this region, whole‐exome sequencing of the proband was performed and further analysis of the obtained data focused on the mapped interval. Further investigation of the candidate variants resulted in the identification of a novel missense mutation in the GBA2 gene. GBA2 mutations have recently been associated with hereditary spastic paraplegia and ARCA with spasticity. We hereby report a novel GBA2 mutation associated with spastic ataxia and suggest that GBA2 mutations may be a relatively frequent cause of ARCA.