Two missense mutations of EGR2 R359W and GJB1 V136A in a Charcot–Marie–Tooth disease family

During mutational analysis of Charcot–Marie–Tooth (CMT) causative genes, we identified a CMT family with two missense mutations in different genes. A R359W mutation in EGR2 was shared by the affected daughter (proband) and her father. In addition, she had a V136A mutation in GJB1, which was determined to be a de novo mutation. The daughter with two different gene mutations showed more severe clinical, electrophysiological and histopathological phenotypes than her father who had only the EGR2 mutation. We suggest that these phenotypic differences between the proband and her father may have been caused by an altered effect of the genetic modifier in EGR2, or by the additive effect of the EGR2 and GJB1 mutations.     

Vincristine exacerbates asymptomatic Charcot–Marie–Tooth disease with a novel EGR2 mutation

Neurotoxicity is a common side effect of vincristine (VCR) treatment. Severe exacerbations of neuropathy have been reported in patients with Charcot–Marie–Tooth disease (CMT) 1A with duplication of the peripheral myelin protein 22 (PMP22) gene. However, whether or not VCR exacerbates neuropathies through mutations in other CMT-associated genes besides PMP22 duplication has not been well studied. The purpose of this study was to identify mutations in any CMT-associated genes in a patient with hypersensitivity to VCR. We performed clinical, electrophysiological, and genetic examinations of a 23-year-old woman, who was hypersensitive to low-dose VCR, and her healthy mother. DNA analysis was performed using our specially designed resequencing array that simultaneously screens for 28 CMT-associated genes. Electrophysiological studies revealed that the patient and her healthy mother had demyelinating polyneuropathy. Furthermore, they showed the same novel mutation in the early growth response 2 (EGR2) gene. Recognizing pre-existing asymptomatic CMT by electrophysiological studies and genetic analysis before VCR treatment allowed us to prevent severe VCR-induced neuropathy.     

Mutation screening of <Emphasis Type="Italic">mitofusin 2</Emphasis> in Charcot-Marie-Tooth disease type 2

Charcot-Marie-Tooth (CMT) disease is among the most common inherited neurological disorders. Mutations in the gene mitofusin 2 (MFN2) cause the axonal subtype CMT2A, which has also been shown to be associated with optic atrophy, clinical signs of first motor neuron involvement, and early onset stroke. Mutations in MFN2 account for up to 20–30% of all axonal CMT type 2 cases. To further investigate the prevalence of MFN2 mutations and to add to the genotypic spectrum, we sequenced all exons of MFN2 in a cohort of 39 CMT2 patients. We identified seven variants, four of which are novel. One previously described change was co-inherited with a PMP22 duplication, which itself causes the demyelinating form CMT1A. Another mutation was a novel in frame deletion, which is a rare occurrence in the genotypic spectrum of MFN2 characterized mainly by missense mutations. Our results confirm a MFN2 mutation rate of ~15–20% in CMT2.     

Novel GDAP1 Mutation in a Turkish Family with CMT2K (CMT2K with Novel GDAP1 Mutation)

Mutations in the ganglioside-induced differentiation-associated protein 1 gene (GDAP1) cause Charcot–Marie–Tooth type 2 (CMT2), a severe autosomal recessive form of neuropathy associated with axonal phenotypes. It has been screened in this study for the presence of mutations in the coding region of GDAP1, which maps to chromosome 8q21, in a family with CMT2. To date, 29 mutations in the GDAP1 have been reported in patients of different ethnic origins. Here, we report a novel missense mutation (c.836A>G), and two polymorphisms: a silent variant (c.102G>C), and a 5′-splice site mutation (IVS5+24C>T) in GDPA1 gene identified in a five generation Turkish family with autosomal recessive CMT2.     

In cis autosomal dominant mutation of <Emphasis Type="Italic">Senataxin</Emphasis> associated with tremor/ataxia syndrome

Senataxin mutations are the molecular basis of two distinct syndromes: (1) ataxia oculomotor apraxia type 2 (AOA2) and (2) juvenile amyotrophic lateral sclerosis 4 (ALS4). The authors describe clinical and molecular genetic studies of mother and daughter who display symptoms of cerebellar ataxia/atrophy, oculomotor defects, and tremor. Both patients share Senataxin mutations N603D and Q653K in cis (N603D–Q653K), adjacent to an N-terminal domain thought to function in protein–protein interaction. The N-terminal and helicase domains appear to harbor missense mutation clusters associated with AOA2 and ALS4. Working synergistically, the N603D–Q653K mutations may confer a partial dominant negative effect, acting on the senataxin N-terminal, further expanding the phenotypic spectrum associated with Senataxin mutations.     

Homozygosity for the <Emphasis Type="Italic">MTX1</Emphasis> c.184T>A (p.S63T) alteration modifies the age of onset in <Emphasis Type="Italic">GBA</Emphasis>-associated Parkinson's disease

A strong association was established between the GBA gene and Parkinson's disease (PD) worldwide. The most frequent GBA mutation among the Ashkenazi population (p.N370S) was previously associated with the c.1051T>C (p.F351L) alteration in the closely located MTX1 gene. We further studied the association between these two genes and its possible effect on PD. The entire coding region and exon–intron boundaries of MTX1 were analyzed in 81 PD patient carriers of GBA mutations, 15 healthy controls that carry GBA mutations, and in 25 non-carrier patients. Among them, the MTX1 c.184T>A (p.S63T) variation was detected in 93% of GBA mutation carriers (both patients and healthy controls) and in 64% of non-carrier patients (p = 0.0008). This alteration was analyzed in 600 consecutively recruited Ashkenazi PD patients and in 353 controls, all genotyped for the LRRK2 p.G2019S and GBA founder mutations. A significantly higher frequency of the MTX1 c.184A allele was found in carriers of GBA mutations compared to non-carriers (0.67 and 0.45, respectively, p < 0.0001). The homozygous MTX1 c.184A/A genotype was associated with a significantly earlier age of motor symptoms onset in patients with GBA mutations compared to other groups of patients tested (5.1–5.9 years younger, p = 0.002–0.01). A significantly higher frequency of early-onset PD (<50 years) was detected among patients carrying both GBA mutation and the homozygous MTX1 c.184A/A genotype (35.9%, compared to 13.6–17.5%, p = 0.028). Our results raise the possibility that alteration on the opposite allele, which is in trans to the GBA mutant allele, may affect the clinical course of GBA-associated PD.     

Episodic ataxia type 2. Three novel truncating mutations and one novel missense mutation in the CACNA1A gene

We analysed the CACNA1A gene, located on chromosome 19p13, in three unrelated families and one sporadic case with episodic ataxia type 2 (EA–2). In two of the families and the sporadic patient, novel truncating mutations, which disrupt the reading frame and result in a premature stop of the CACNA1A protein, were identified in exons 14, 16 and 26. In the remaining family, a novel missense mutation (H253Y) was found. Of the twenty two EA–2 mutations identified thus far, including those of the present study, seventeen are truncating mutations and five are missense mutations, all resulting in an EA–2 clinical phenotype. Received: 20 December 2001, Received in revised form: 15 April 2002, Accepted: 22 April 2002 Correspondence to M. D. Ferrari, MD PhD     

A new POLG1 mutation with peo and severe axonal and demyelinating sensory–motor neuropathy

Background Progressive external ophthalmoplegia (PEO) is a mitochondrial disorder associated with defective enzymatic activities of oxidative phosphorylation (OXPHOS), depletion of mitochondrial DNA (mtDNA) and/or accumulation of mtDNA mutations and deletions. Recent positional cloning studies have linked the disease to four different chromosomal loci. Mutations in POLG1 are a frequent cause of this disorder. Methods We describe two first–cousins: the propositus presented with PEO,mitochondrial myopathy and neuropathy, whereas his cousin showed a Charcot– Marie–Tooth phenotype. Neurophysiological studies, peroneal muscle and sural nerve biopsies, and molecular studies of mtDNA maintenance genes (ANT1, Twinkle, POLG1, TP) and non dominant CMT–related genes (GDAP1, LMNA, GJB1) were performed. Results A severe axonal degeneration was found in both patients whereas hypomyelination was observed only in the patient with PEO whose muscle biopsy specimen also showed defective OXPHOS and multiple mtDNA deletions. While no pathogenetic mutations in GDAP1, LMNA, and GJB1 were found, we identified a novel homozygous POLG1 mutation (G763R) in the PEO patient. The mutation was heterozygous in his healthy relatives and in his affected cousin. Conclusions A homozygous POLG1 mutation might explain PEO with mitochondrial abnormalities in skeletal muscle in our propositus, and it might have aggravated his axonal and hypomyelinating sensory–motor neuropathy. Most likely, his cousin had an axonal polyneuropathy with CMT phenotype of still unknown etiology.     

A new missense <Emphasis Type="Italic">GDAP1</Emphasis> mutation disturbing targeting to the mitochondrial membrane causes a severe form of AR-CMT2C disease

Charcot–Marie–Tooth disease (CMT) caused by mutations in the ganglioside-induced differentiation-associated protein 1 (GDAP1) gene is characterized by a spectrum of phenotypes. Recurrent nonsense mutations (Q163X and S194X) showing regional distribution segregate with an early onset, severe course of recessive CMT disease with early loss of ambulancy. Missense mutations in GDAP1 have been reported in sporadic CMT cases with variable course of disease, among them the recurrent L239F missense GDAP1 mutation occurring in the European population. Finally, some GDAP1 mutations are associated with a mild form of CMT inherited as an autosomal dominant trait. In this study, we characterize the CMT phenotype in one Polish family with recessive trait of inheritance at the clinical, electrophysiological, morphological, cellular, and genetic level associated with a new Gly327Asp mutation in the GDAP1 gene. In spite of the nature of Gly327Asp mutation (missense), the CMT phenotype associated with this variant may be characterized as an early onset, severe axonal neuropathy, with severe skeletal deformities. The mutation lies within the transmembrane domain of GDAP1 and interferes with the mitochondrial targeting of the protein, similar to the loss of the domain in the previously reported Q163X and S194X mutations. We conclude that the loss of mitochondrial targeting is associated with a severe course of disease. Our study shows that clinical outcome of CMT disease caused by mutations in the GDAP1 gene cannot be predicted solely on the basis of genetic results (missense/nonsense mutations).     

Homozygous splice‐site mutation c.78 + 5G>A in PMP22 causes congenital hypomyelinating neuropathy

Congenital hypomyelinating neuropathy (CHN) presents in the neonatal period and results in delayed development of sensory and motor functions due to several gene mutations including in EGR2, MPZ, CNTNAP1, and PMP22. The phenotype of homozygous splice‐site mutation in the PMP22 gene has not been described in humans or animal models. Here we describe a family carrying a pathogenic splice‐site c.78 + 5G>A mutation in the PMP22 gene. We evaluated the clinical, electrophysiological, histological, and genetic features of the family. The proband with homozygous mutation presented with CHN, while his consanguineous parents with heterozygous mutation were asymptomatic. The proband was a 7‐year‐old boy. He had motor retardation after birth and had remained unable to walk independently at the time of the study. The compound muscle action potentials and sensory nerve action potentials were not recordable in the boy. The motor and sensory nerve conduction velocities of the parents were slightly to moderately decreased, although they had no symptoms of peripheral neuropathy. The sural nerve biopsy of the boy revealed hypomyelinating neuropathy with absence of large myelinated fibers, no myelin breakdown products, and numerous basal lamina onion bulb formations. To our knowledge, this is the first report of a homozygous splice‐site mutation in the PMP22 gene in humans. Our study expands the phenotype and genotype of PMP22‐related neuropathy.     

Analysis of spectrum and frequencies of mutations in McArdle disease

Abstract Background McArdle disease, a common metabolic myopathy with autosomal recessive inheritance, is caused by a frequent R50X mutation and many rare mutations in the myophosphorylase gene. Objectives To identify spectrum and frequencies of myophosphorylase gene mutations in a large cohort of patients with McArdle disease, to discuss diagnostic implications, and to analyse genotype–phenotype relationship. Methods Molecular genetic analysis of 56 index patients with muscle biopsy-proven myophosphorylase deficiency from Germany (n = 35), UK (n = 13), and several other countries (n = 8) was performed using direct sequencing. Results Allele frequency of the R50X mutation was 58%, and 71% of the patients carried this mutation at least on one allele. We detected 26 other less common mutations, 13 of which are novel: G157V, R161C, Q337R, E384K, S450L, G486D, R570W, K575E, IVS6-2A>T, IVS10+1G>A, R650X, c.1354insC, c.1155_1156delGG. There was no genotype-phenotype correlation with respect to age of onset and severity. R270X was the most frequent mutation among the less common mutations reaching an allele frequency of 5% followed by R94W and G686R representing a frequency of 4% each. Conclusions The study further extends the genetic heterogeneity of myophosphorylase gene mutations showing no mutational hotspot and no genotype–phenotype correlation. Most novel missense mutations were located in secondary structures or active sites of the enzyme. Some of the less common mutations are recurrent with different frequencies within Europe. Ethnic origin and frequency of less common mutations must be considered to establish efficient strategies in molecular genetic testing. Performing molecular testing can avoid muscle biopsy.     

The location of DCX mutations predicts malformation severity in X-linked lissencephaly

Lissencephaly spectrum (LIS) is one of the most severe neuronal migration disorders that ranges from agyria/pachygyria to subcortical band heterotopia. Approximately 80% of patients with the LIS spectrum carry mutations in either the LIS1 or DCX (doublecortin) genes which have an opposite gradient of severity. The aim of the study was to evaluate in detail the phenotype of DCX-associated lissencephaly and to look for genotype–phenotype correlations. Of the 180 male patients with DCX-related lissencephaly, 33 males (24 familial cases and nine cases with de novo mutations) were found with hemizygous DCX mutations and were clinically and genetically assessed here. DCX mutation analysis revealed that the majority of mutations were missense (79.2%), clustered in the two evolutionary conserved domains, N-DC and C-DC, of DCX. The most prominent radiological phenotype was an anteriorly predominant pachygyria or agyria (54.5%) although DCX-associated lissencephaly encompasses a complete range of LIS grades. The severity of neurological impairment was in accordance with the degree of agyria with severe cognitive impairment in all patients, inability to walk independently in over half and refractory epilepsy in more than a third. For genotype–phenotype correlations, patients were divided in two groups according to the location of DCX missense mutations. Patients with mutations in the C-DC domain tended to have a less severe lissencephaly (grade 4–5 in 58.3%) compared with those in the N-DC domain (grade 4–5 in 36.3%) although, in this dataset, this was not statistically significant (p = 0.12). Our evaluation suggests a putative correlation between phenotype and genotype. These data provide further clues to deepen our understanding of the function of the DCX protein and may give new insights into the molecular mechanisms that could influence the consequence of the mutation in the N-DC versus the C-DC domain of DCX.     

Analysis of p53 mutation and expression in pleomorphic xanthoastrocytoma

Pleomorphic xanthoastrocytoma (PXA) is a rare, superficially situated tumor that most frequently occurs in the temporal lobe of young adults and is often associated with seizures. It generally has a relatively favorable prognosis. Prior studies have shown that TP53 mutations may occur in up to 25% of PXAs, suggesting that PXA may have an etiology similar to diffuse astrocytoma rather than pilocytic astrocytoma. In the present study, we performed immunostaining for p53 protein and examined the mutation status of exons 5–8 of the p53 gene in 55 PXAs, 8 of which had undergone one or multiple recurrences. Of 55 primary PXAs, 35 (64%) showed staining in <1% of tumor cells, 15 (27%) in 1–10%, 4 (7%) in 11–50%, and only 1 (2%) in >50%. No significant increase in p53 protein expression was noted in recurrences, even when associated with increased histological anaplasia. We found a TP53 heterozygous mutation in exon 7 in 1 of 47 primary tumors that yielded useable DNA, and in its recurrence 3 years later. This tumor, a grade II PXA, did not show signs of anaplastic transformation at recurrence. Eleven additional recurrences from 7 patients, 5 of which showed signs of histological anaplasia, did not show TP53 mutations in exons 5–8. Based on our data, the p53 mutation appears to be an uncommon (2%) genetic event in PXA formation and does not appear to be involved in tumor progression. Consequently, our findings suggest that the genetic events that underlie PXA formation differ from those involved in diffuse astrocytoma. Electronic Publication     

Maternal uniparental heterodisomy with partial isodisomy of a chromosome 2 carrying a splice acceptor site mutation (IVS9–2A>T) in ALS2 causes infantile-onset ascending spastic paralysis (IAHSP)

Infantile-onset ascending spastic paralysis (OMIM #607225) is a rare autosomal recessive early onset motor neuron disease caused by mutations in the gene ALS2. We report on a splice acceptor site mutation in intron 9 of ALS2 (IVS9–2A>T) in a German patient from nonconsanguineous parents. The mutation results in skipping of exon 10. This causes a frame-shift in exon 11 and a premature stop codon. Analysis of the parental ALS2 gene revealed heterozygosity for the mutation in the mother but not in the father. Therefore, we studied polymorphic markers scattered along chromosome 2 in both parents and the patient and found maternal uniparental disomy in the patient. While homozygosity was observed at several loci of chromosome 2 including ALS2, other loci were heterozygous, i.e., both maternal alleles were present. The findings can be explained by at least four recombination events during maternal meiosis followed by a meiosis I error and postzygotic trisomy rescue or gamete complementation. Thilo Herzfeld and Nicole Wolf contributed equally to this paper.     

Adult-onset glycogen storage disease type II: phenotypic and allelic heterogeneity in German patients

Glycogen storage disease type II (GSDII, Pompe's disease) is an autosomal recessive inherited deficiency of lysosomal α-glucosidase (GAA). Clinical as well as biochemical and allelic heterogeneity have been described in GSDII. We identified mutations within the GAA gene in seven unrelated German patients, six with adult- and one with juvenile-onset GSDII. Beside previously described mutations [IVS1 (–13T → G), Δexon 18, C1634T], we characterized four new mutations of GSDII: IVS6 (–22T → G), 271delG, G1912T (Gly638Trp), and 2432insC. The IVS6 (-22T → G) mutation gives rise to aberrant splicing, causing in-frame deletions of 25 or 40 amino acids within the GAA coding sequence and the insertion of a sequence of seven missense amino acids. Two affected siblings and an unrelated patient with adult GSDII are apparently homozygous for the exon 18 deletion. Both siblings are also heteroallelic for IVS1 (–13T → G). In conclusion, we observed pronounced allelic heterogeneity and an unexpectedly high frequency of homozygosity for larger in-frame deletions within the GAA coding sequence in German adult-onset GSDII patients. Received: July 24, 1997 / Accepted: September 22, 1997     

PMP22 Mutations In DÉJÈRine-Sottas Disease: A Mutational "Hot Spot" On Codon 72

Increased dosage of the gene encoding the peripheral myelin protein PMP22 is the most common molecular mechanism underlying the demyelinating form of Charcot-Marie-Tooth disease (CMT1A). It results from the duplication of a 1.5-Mb tract on chr. 17p11.2 which encompasses the PMP22 gene. Mutations in this gene can also cause CMT1A and are often associated with more severe phenotypes such as Déjèrine-Sottas disease (DSD) and congenital hypomyelinating neuropathy (CHN). We have analyzed the PMP22 gene in 20 unrelated patients affected with a severe form of demyelinating motor and sensory neuropathy (severe CMT1 or DSD). All the patients had been found negative for the common CMT1A duplication and for mutations in the myelin protein P₀ gene (MPZ). Direct sequence analysis of PMP22 uncovered the presence of missense mutations in 3 patients diagnosed as having DSD. In each case, the mutation was heterozygous and was not carried by any of the nonaffected parents, thus indicating that it was a de novo dominant mutation. Patient #1, a 3-y-old boy, carried a C-to-T transition in PMP22 exon 4 which would result in the amino acid substitution of Leu-80 with Pro in the 2nd transmembrane domain of the protein. This mutation had been previously observed in another DSD patient (Tyson, 1997). Patient #2, a 3-y-old girl, and patient #3 carried the same mutation, the 215C-to-T transition in exon 4. Interestingly, patient #3 was a 35-y-old man born of consanguineous healthy parents. The disease had started during the first years of life and the patient had become wheelchair-bound at the age of 28 y. The 215C-to-T mutation eliminates a TaqI restriction site and results in the substitution of Ser-72 (TCG) with Leu (TTG) in the 2nd transmembrane domain of PMP22. Approx. 40 different PMP22 mutations are currently listed in the European CMT Consortium Database. In the majority of cases, the mutations have been identified in single or very few patients, with the only exception of the Ser72Leu substitution. Including the two unrelated patients reported here, this mutation has been thus far described in a total of 7 patients. The mutation, which occurs within a CpG dinucleotide, exhibits phenotypic heterogeneity and has been observed in both DSD (6) and CHN (1) cases. In conclusion, PMP22 mutations are rare causes of genetic neuropathies. Given the limited number of such mutations, the recurrence of substitutions at codon 72 would indicate that this may represent a mutational “hot spot”. We therefore suggest that sequence analysis of PMP22 exon 4 should routinely precede analysis of the remaining exons and intron/exon boundaries.