Spine deformities in Charcot-Marie-Tooth 4C caused by SH3TC2 gene mutations.

BACKGROUND: Charcot-Marie-Tooth (CMT) disease is a heterogeneous group of inherited peripheral motor and sensory neuropathies with several modes of inheritance: autosomal dominant, X-linked, and autosomal recessive (AR) CMT. A locus responsible for the demyelinating form of ARCMT was assigned to the 5q23-q33 region (CMT4C) by homozygosity mapping. Recently, 11 mutations were identified in the SH3TC2 (KIAA1985) gene in 12 families with demyelinating ARCMT from Turkish, Iranian, Greek, Italian, or German origin. OBJECTIVE: To identify mutations in the SH3TC2 gene. METHODS: The authors searched for SH3TC2 gene mutations in 10 consanguineous CMT families putatively linked to the CMT4C locus on the basis of haplotype segregation and linkage analysis. RESULTS: Ten families had mutations, eight of which were new and one, R954X, recurrent. Six of the 10 mutations were in exon 11. Onset occurred between ages 2 and 10. Scoliosis or kyphoscoliosis and foot deformities were found in almost all patients and were often inaugural. The median motor nerve conduction velocity values (

Coincidence of two genetic forms of Charcot-Marie-Tooth disease in a single family.

The authors report a family in which two affected first cousins had a severe demyelinating Charcot-Marie-Tooth disease (CMT) phenotype. One had related parents, and there were no other affected relatives, suggesting an autosomal recessive mode of inheritance. Molecular studies showed that a de novo duplication in 17p11.2 and a second mutation in MTMR2 were present.

Ataxin-7 interacts with a Cbl-associated protein that it recruits into neuronal intranuclear inclusions.

Spinocerebellar ataxia 7 (SCA7) is a neurodegenerative disease caused by expansion of a CAG repeat in the coding region of the SCA7 gene. The disease primarily affects the cerebellum and the retina, but also many other central nervous system (CNS) structures as the disease progresses. Ataxin-7, encoded by the SCA7 gene, is a protein of unknown function expressed in many tissues including the CNS. In normal brain, ataxin-7 is found in the cytoplasm and/or nucleus of neurons, but in SCA7 brain ataxin-7 accumulates in intranuclear inclusions. Ataxin-7 is expressed ubiquitously, but mutation leads to neuronal death in only certain areas of the brain. This selective pattern of degeneration might be explained by interaction with a partner that is specifically expressed in vulnerable cells. We used a two-hybrid approach to screen a human retina cDNA library for ataxin-7-binding proteins, and isolated R85, a splice variant of Cbl-associated protein (CAP). R85 and CAP are generated by alternative splicing of the gene SH3P12 which we localized on chromosome 10q23-q24. The interaction between ataxin-7 and the SH3P12 gene products (SH3P12GPs) was confirmed by pull-down and co-immunoprecipitation. SH3P12GPs are expressed in Purkinje cells in the cerebellum. Ataxin-7 colocalizes with full-length R85 (R85FL) in co-transfected Cos-7 cells and with one of the SH3P12GPs in neuronal intranuclear inclusions in brain from a SCA7 patient. We propose that this interaction is part of a physiological pathway related to the function or turnover of ataxin-7. Its role in the pathophysiological process of SCA7 disease is discussed.

A mutation in periaxin is responsible for CMT4F, an autosomal recessive form of Charcot-Marie-Tooth disease.

Charcot-Marie-Tooth (CMT) disease is a heterogeneous group of inherited peripheral motor and sensory neuropathies characterized by chronic distal weakness with progressive muscular atrophy and sensory loss in the distal extremities. Inheritance can be autosomal dominant, X-linked or autosomal recessive (ARCMT). Recently, a locus responsible for a demyelinating form of ARCMT disease, named CMT4F, has been mapped on 19q13 in a large consanguineous Lebanese family. L- and S-periaxin are proteins of myelinating Schwann cells and homozygous periaxin-null mice display extensive demyelination of myelinated fibers in the peripheral nervous system, which suggests that the periaxin gene is a good candidate gene for an ARCMT disease. The human gene encoding the periaxins (PRX) was mapped to 19q13, in the CMT4F candidate interval. After characterizing the human PRX gene, we identified a nonsense R196X mutation in the Lebanese family which cosegregated with CMT. Histopathological and immunohistochemical analysis of a sural nerve biopsy of one patient revealed common features with the mouse mutant and the absence of L-periaxin from the myelin sheath. These data confirm the importance of the periaxin proteins to normal Schwann cell function and substantiate the utility of the periaxin-null mouse as a model of ARCMT disease.

Genetic, cytogenetic and physical refinement of the autosomal recessive CMT linked to 5q31-q33: exclusion of candidate genes including EGR1.

Charcot-Marie-Tooth disease is an heterogeneous group of inherited peripheral motor and sensory neuropathies with several modes of inheritance: autosomal dominant, X-linked and autosomal recessive. By homozygosity mapping, we have identified, in the 5q23-q33 region, a third locus responsible for an autosomal recessive form of demyelinating CMT. Haplotype reconstruction and determination of the minimal region of homozygosity restricted the candidate region to a 4 cM interval. A physical map of the candidate region was established by screening YACs for microsatellites used for genetic analysis. Combined genetic, cytogenetic and physical mapping restricted the locus to a less than 2 Mb interval on chromosome 5q32. Seventeen consanguineous families with demyelinating ARCMT of various origins were screened for linkage to 5q31-q33. Three of these seventeen families are probably linked to this locus, indicating that the 5q locus accounts for about 20% of demyelinating ARCMT. Several candidate genes in the region were excluded by their position on the contig and/or by sequence analysis. The most obvious candidate gene, EGR1, expressed specifically in Schwann cells, mapped outside of the candidate region and no base changes were detected in two families by sequencing of the entire coding sequence.

Fine mapping of de novo CMT1A and HNPP rearrangements within CMT1A-REPs evidences two distinct sex-dependent mechanisms and candidate sequences involved in recombination.

The molecular mechanism resulting in the duplication or deletion of a 1.5 Mb region of 17p11.2-p12, associated, respectively, with Charcot-Marie-Tooth type 1A (CMT1A) and hereditary neuropathy with liability to pressure palsies (HNPP), has been proposed to be an unequal crossing-over during meiosis between the two chromosome 17 homologues generated by misalignment of the proximal and distal CMT1A-REP repeats, two homologous sequences flanking the 1.5 Mb CMT1A/HNPP monomer unit. In a recent study of a large series of de novo cases of CMT1A and HNPP, two distinct sex-dependent mechanisms were identified. Rearrangements of paternal origin, essentially duplications, were indeed generated by unequal meiotic crossing-over between the two chromosome 17 homologues, but duplications and deletions of maternal origin resulted from an intrachromosomal process, either unequal sister chromatid exchange or, in the case of deletion, excision of an intrachromatidal loop. In order to determine how these recombinations occur, 24 de novo crossover breakpoints were localized within the 1.7 kb rearrangement hot spot by comparing the sequences of the parental CMT1A-REPs with the chimeric copy in affected offspring. Nineteen out of 21 paternal crossovers were found in a 741 bp hot spot. All the breakpoints of maternal origin (n = 3), however, were located outside this interval, but in closely flanking sequences, supporting the hypothesis that two distinct sex-dependent mechanisms are involved. Several putative recombination promoting sequences in the hot spot, which are rare or absent in the surrounding 7.8 kb, were identified.

Homozygosity mapping of an autosomal recessive form of demyelinating Charcot-Marie-Tooth disease to chromosome 5q23-q33.

Charcot-Marie-Tooth (CMT) disease is the most frequent inherited peripheral motor and sensory neuropathy characterised by chronic distal weakness with progressive muscular atrophy and sensory loss of the distal extremities. The dominant form of the disease is genetically heterogeneous but only one locus has been identified on chromosome 8q13-q21.1 for autosomal recessive CMT. By homozygosity mapping in a large Algerian kindred, we have assigned a second locus for autosomal recessive CMT to chromosome 5q23-33. Linkage analysis demonstrated that the same locus is involved in a second Algerian family with a demyelinating CMT. Haplotype reconstruction and determination of the minimal region of homozygosity restricts the candidate region to a 4 cM interval.

A de novo case of hereditary neuropathy with liability to pressure palsies (HNPP) of maternal origin: a new mechanism for deletion in 17p11.2?

Hereditary neuropathy with liability to pressure palsies (HNPP) is an autosomal dominant neuropathy, most often associated with a deletion of the 17p11.2 region, which is duplicated in 70% of patients with Charcot-Marie-Tooth type 1 (CMT1A). Most de novo CMT1A and HNPP cases have been of paternal origin. A rare case of de novo HNPP of maternal origin was analysed to determine the underlying mechanism. Affected individuals in the family carried a deletion corresponding to the CMT1A/HNPP monomer unit associated with a rearrangement of the CMT1A-REP sequences. Segregation analysis of 17p11-p12 markers in the family indicated that the deletion was not generated by unequal crossing over between homologous 17 chromosomes, as in de novo cases from paternal origin, but rather by an intrachromosomal rearrangement. Two distinct mechanisms can therefore lead to the same 17p11.2 deletion. This result suggests that intrachromosomal rearrangement may be specific to maternal transmissions.

Microsatellite mapping of the deletion in patients with hereditary neuropathy with liability to pressure palsies (HNPP): new molecular tools for the study of the region 17p12 --> p11 and for diagnosis.

Hereditary neuropathy with liability to pressure palsies (HNPP) is an autosomal dominant peripheral neuropathy characterized by recurrent episodes of nerve palsies. We have analyzed 11 microsatellite markers from chromosome 17p12 --> p11 in nine French families with HNPP. The three microsatellites D17S839 (afm200yb12), D17S955 (afm317ygl), and D17S921 (afm191xh12) were localized in the deleted region. In allele segregation analyses, the microsatellite D17S793 (afm165zd4) detected two chromosome 17-linked loci, one of which was deleted in HNPP patients. Using these STR markers, we found that the deletion coincided with the CMT1A/HNPP monomer unit in eight of the nine families. In the remaining pedigree, the deletion lay between the centromeric microsatellite D17S805 (afm234tal) and the telomeric marker D17S922 (afm197xh6), which flank the CMT1A monomer unit. Comparison of these data with the available genetic and physical maps of 17p12 --> p11 shows that this region, which is frequently subject to rearrangement-inducing diseases, such as Smith-Magenis syndrome, Charcot-Marie-Tooth type 1A, and HNPP, presents recombination hot spots. Finally, this study demonstrates the usefulness of the D17S122 (RM11GT) and D17S921 (afm191xh12) microsatellites as tools for the molecular diagnosis of HNPP.

Linkage analyses between dominant X-linked Charcot-Marie-Tooth disease, and 15 Xq11-Xq21 microsatellites in a new large family: three new markers are closely linked to the gene.

X-linked dominant inheritance was suspected in a large family with Charcot-Marie-Tooth disease since no male to male transmission was observed, and since the sensory and motor neuropathy was more severe in males than in females. To test linkage to the dominant X-linked Charcot-Marie-Tooth disease (DCMTX) locus in Xq13, genotypes of 19 affected and 19 unaffected individuals from this family were determined for 4 microsatellite markers. Close linkage to mfd66 (DXS453) was found by bipoint analysis (Zmax = 4.8 at theta = 0.00). Multipoint analysis mapped the gene between the androgen receptor and DXYS1. In addition, linkage analysis performed with 11 microsatellite markers, derived from a high density map spanning 16 cM on Xq11-Xq21 revealed 3 new tightly linked loci: afm287zg1 (DXS1216), afm261zh5 and afm207zg5 (DXS995). Multipoint analysis localized the DCMTX gene to a 7.5 cM interval between afm123xd4 (DXS988) and afm116xg1 (DXS986). Combined analysis with these new microsatellites provides a powerful tool for carrier detection because of their high informativity and the small genetic distance (< 10 cM) between the markers flanking the gene.

Assignment of 112 microsatellite markers to 23 chromosome 11 subregions delineated by somatic hybrids: comparison with the genetic map.

Using a panel of 25 somatic cell hybrids, we have regionally localized 112 microsatellite markers generated by Généthon and assigned to chromosome 11. A genetic map of 74 of them was produced using linkage analysis of the eight largest CEPH (Centre d'Etude du Polymorphisme Humain) families. They could be ordered on chromosome 11 with an average distance of 2.1 cM. The tight correlation observed between the genetic order and the physical assignment of these microsatellites reinforces the genetic map data. These newly localized markers identified by the PCR method using a standardized protocol represent useful tools for mapping YAC clones and establishing YAC contigs and for studying genetic diseases or cancers associated with specific genes and/or germinal/somatic rearrangements of chromosome 11.

A third locus for autosomal dominant cerebellar ataxia type I maps to chromosome 14q24.3-qter: evidence for the existence of a fourth locus.

The autosomal dominant cerebellar ataxias (ADCA) type I are a group of neurological disorders that are clinically and genetically heterogeneous. Two genes implicated in the disease, SCA1 (spinal cerebellar ataxia 1) and SCA2, are already localized. We have mapped a third locus to chromosome 14q24.3-qter, by linkage analysis in a non-SCA1/non-SCA2 family and have confirmed its existence in a second such family. We suggest designating this new locus "SCA3". Combined analysis of the two families restricted the SCA3 locus to a 15-cM interval between markers D14S67 and D14S81. The gene for Machado-Joseph disease (MJD), a clinically different form of ADCA type I, has been recently assigned to chromosome 14q24.3-q32. Although the SCA3 locus is within the MJD region, linkage analyses cannot yet demonstrate whether they result from mutations of the same gene. Linkage to all three loci (SCA1, SCA2, and SCA3) was excluded in another family, which indicates the existence of a fourth ADCA type I locus.

Detection of deletion within 17p11.2 in 7 French families with hereditary neuropathy with liability to pressure palsies (HNPP).

Hereditary neuropathy with liability to pressure palsies (HNPP) is an autosomal dominant peripheral neuropathy which is characterized by recurrent episodes of truncular palsies. We have analyzed the D17S122 locus in 7 French families, including 18 affected members, with microsatellite RM11GT and the RFLP probe VAW409R3a. Only one allele could be detected in all affected individuals with the highly polymorphic RM11GT marker. Allele segregation at D17S122 showed no contribution from the affected parent to the affected child, demonstrating that an interstitial deletion within the 17p11.2 region is associated with HNPP in the 7 families studied. This same region is duplicated, however, in another inherited neuropathy, Charcot-Marie-Tooth 1A disease. This would be the first example of two dominantly inherited diseases caused by a 'in mirror image' deletion/duplication mechanism where a gene dosage effect would be sufficient to produce two different phenotypes characterized by abnormal myelination of the peripheral nerves. The RM11GT microsatellite is an informative tool for the molecular diagnosis of HNPP.