Rebecca Ionasescu scite author profile

Clinical, electrophysiological and genetic linkage studies were performed on a large autosomal dominant family with Charcot-Marie-Tooth axonal neuropathy type 2 (CMT2) with 38 members of which 14 were affected. Onset of the disease was between 16 and 30 years of age with weakness and atrophy of the hands more severe than of the feet with slow progressive course in 12 patients. Deep tendon reflexes were absent in the upper extremities and decreased in the lower extremities. There was distal hypesthesia for touch, proprioception and vibration sense for the hands more than for the feet. Motor nerve conduction velocities showed normal values (48-53 M/s) with normal latencies (2-3 msec) and electromyography revealed signs of denervation. Genetic linkage analysis used 167 short tandem repeat markers (STRPs) spaced throughout the 22 autosomes. Linkage to the short arm of chromosome 7 at 7p14 was found using the marker D7S435 (Z = 4.83 at theta = 0). Flanking markers were D7S1808 and D7S1806 and the genetic distance between them was 6.8 cM. The multipoint linkage analysis gave a peek multipoint lod score of 6.89 between the markers D7S1808 and D7S435. Linkage analysis showed significantly negative lod scores (with values less than -2) with markers of chromosomes 1 and 3 where CMT axonal forms have been previously mapped. PFGE analysis indicated the absence of the CMT1A duplication. Our findings are consistent with a new genetic type of axonal CMT neuropathy designated by us as CMT2D. Potential candidate genes are multiple T-cell gamma receptor genes which map to the same cytogenetic interval as CMT2D neuropathy.

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Point mutations of the connexin32 (GJB1) gene in X-linked dominant Charcot — Marie — Tooth neuropathy

Ionâşescu

1994

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Ten families with X-linked dominant CMT neuropathy (CMTX1) were screened for point mutations of the connexin32 (Cx32, GJB1) gene. Two families showed missense mutations, respectively an A-->G transition at amino acid 102 (glutamate to glycine) and a C-->T transition at amino acid 142 (arginine to tryptophan). Three families showed nonsense mutations, respectively a C-->T transition at amino acid 22 (arginine to stop) a G-->T transversion at amino acid 186 (glutamate to stop), and a T-->A transversion at amino acid 217 (cysteine to stop). Five CMTX1 neuropathy families showed no evidence of point mutations of the connexin32 coding sequence. These findings suggest that the CMTX1 neuropathy genotype is heterogeneous or the result of promoter mutations, 3'-untranslated region mutations or exon/intron splice site mutations. Four of the reported mutations created or destroyed restriction enzyme sites: a HaeIII restriction enzyme site was destroyed by the mutation at amino acid position 22, a HpaII site was eliminated at amino acid position 142, a Bfal restriction site was created by the mutation at amino acid 186 and a Ddel restriction site was created by the mutation at amino acid 217. These changes allowed us to test family members for the mutations and observe the segregation of the disease with the mutations.

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Mutations of the noncoding region of the connexin32 gene in X-linked dominant Charcot-Marie-Tooth neuropathy

Ionâşescu¹,

Searby²,

Ionasescu³

et al. 1996

Neurology

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We studied two families with X-linked dominant Charcot-Marie-Tooth neuropathy. The clinical findings included onset around age 14 years, with moderate weakness of feet extensors and palmar and dorsal interossei, areflexia, distal hypesthesia, and slow progressivity. Motor nerve conduction velocities showed slowing (20 to 30 m/sec) and EMGs were normal. Genetic linkage analysis revealed positive lod scores with the markers of the Xq13.1 region in family 2, but was noninformative in family 1. There were no point mutations in the connexin32 gene coding region. Instead, family 1 revealed a T-to-G transversion at position -528 relative to the ATG start codon, whereas family 2 showed a C-to-T transition at position -458. The first mutation is located in the nerve-specific connexin32 promoter just upstream of the transcription start site, the second is located in the 5' untranslated region of the mRNA.

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Correlation between connexin 32 gene mutations and clinical phenotype in X-linked dominant Charcot-Marie-tooth neuropathy

1996

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We studied the relationship between the genotype and clinical phenotype in 27 families with dominant X‐linked Charcot‐Marie‐Tooth (CMTX1) neuropathy. Twenty‐two families showed mutations in the coding region of the connexin32 (cx32) gene. The mutations include four nonsense mutations, eight missense mutations, two medium size deletions, and one insertion. Most missense mutations showed a mild clinical phenotype (five out of eight), whereas all nonsense mutations, the larger of the two deletions, and the insertion that produced frameshifts showed severe phenotypes. Five CMTX1 families with mild clinical phenotype showed no point mutations of the cx32 gene coding region. Three of these families showed positive genetic linkage with the markers of the Xq13.1 region. The genetic linkage of the remaining two families could not be evaluated because of their small size. © 1996 Wiley‐Liss, Inc.

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Dejerine-Sottas neuropathy in mother and son with same point mutation of PMP22 gene

et al. 1997

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