Molecular genetics and biology of inherited peripheral neuropathies: a fast-moving field

The recent progress of molecular genetics has considerably increased our knowledge about the underlying disease mechanism of inherited peripheral neuropathies. Mutations in three genes coding for the myelin proteins peripheral myelin protein 22, myelin protein zero and connexin 32 and in one gene coding for the transcription factor early growth response 2 element are associated with Charcot-Marie-Tooth type 1 and 2, hereditary neuropathy with liability to pressure palsies, Dejerine-Sottas syndrome and congenital hypomyelination. This review focuses on the correlation of the different human phenotypes associated with distinct mutations with those found in cellular and animal models.

Localization of mariner DNA transposons in the human genome by PRINS

Homologous recombination occurring among misaligned repeated sequences is a significant source of the molecular rearrangements resulting in human genetic disease. Studies of the Charcot-Marie-Tooth disease locus on chromosome 17 have implicated the involvement of an ancient DNA transposon of the mariner family (Hsmar2) in the initiation of double-strand break events leading to homologous recombination. In this study, the genomic locations of 109 Hsmar2 elements were determined by primed in situ labeling (PRINS) using primers designed to match the right and left inverted terminal repeats (ITRs) of the transposon. Although the resolution of the PRINS technique is approximately 400 chromosomal Giemsa bands, the data presented here provide the first large-scale mapping study of these elements, which may be involved in initiation of homologous recombination events in the human genome.

A GLC1A gene Gln368Stop mutation in a patient with normal-tension open-angle glaucoma

PURPOSE

To present a case involving a patient with normal-tension glaucoma with a Gln368Stop mutation of the myocilin/trabecular meshwork inducible glucocorticoid response protein (MYOC/TIGR) gene.

METHODS

Slit-lamp biomicroscopic and gonioscopic examination, morphometry of the optic disc, 24-hour intraocular pressure (IOP) profile, and perimetry were performed to determine the phenotype of the patient. Neurologic examination and a computed tomographic (CT) scan of the brain were performed to rule out a neurologic disorder. Single-strand confirmation polymorphism (SSCP) analysis and subsequent sequence analysis of blood was performed for genotyping of the GLC1A gene.

RESULTS

A nonsense codon, namely a Gln368Stop mutation in the third exon of the GLC1A gene, was found in this patient with normal-tension glaucoma.

CONCLUSION

In contrast to previous reports, a Gln368Stop mutation of the GLC1A gene need not be confined to patients with glaucomatous optic atrophy due to high IOP. The pathogenesis of glaucoma associated with GLC1A gene mutations might be more complex than expected, and (unknown) suppressor mechanisms have to be considered.

Charcot-Marie-Tooth disease type 1A and hereditary neuropathy with liability to pressure palsies: a SacI polymorphism in the proximal CMT1A-REP elements may lead to genetic misdiagnosis

A male patient with clinical signs and symptoms of a demyelinating neuropathy was shown to have a duplication of the 1.5-Mb region on chromosome 17p11.2 by means of two-color fluorescence in situ hybridization (FISH). This duplication is typical for the vast majority of Charcot-Marie-Tooth type 1A (CMT1A) cases. Analysis of DNA extracted from peripheral blood used to detect an EcoRI/SacI 3. 2-kb junction fragment with probe pLR7.8 confirmed the CMT1A duplication, but also revealed a 7.8-kb fragment usually observed in patients with a hereditary neuropathy with liability to pressure palsies (HNPP). Both fragments observed in one patient canot result from one unequal crossover. In EcoRI/SacI Southern hybridization experiments with probe pLR7.8 DNA of his healthy parents also revealed a 7.8-kB restriction fragment. A subsequent two-color FISH analysis, however, indicated a normal status for interphase nuclei of the parents. Hence we hypothesize that the 7.8-kb fragment observed in our patient and his parents is not the product of unequal crossover during meiosis but due to a polymorphism of the SacI site in a proximal CMT1A-REP element.

An adhesion test system based on Schneider cells to determine genotype-phenotype correlations for mutated P0 proteins

Myelin protein zero (MPZ, P0) is well known as the adhesion molecule responsible for the compaction of the myelin sheath of peripheral nerves. Mutations are linked to Charcot-Marie-Tooth syndrome type 1B (CMT1B) and the more severe Dejerine-Sottas syndrome (DSS). Three mutations leading to phenotypes of increasing severity (Ser34del/CMT1B, Ser34Cys/DSS, INS663GC/DSS) were expressed in S2 insect cells and resulted in a decreased adhesion capability in correlation with their respective phenotypes.

Mosaicism for Charcot-Marie-Tooth disease type 1A: onset in childhood suggests somatic reversion in early developmental stages

A 1.5 Mb duplication on chromosome 17p11.2 is typical for the great majority of patients suffering from Charcot-Marie-Tooth type 1A (CMT1A) disease. A female child of 4 years with clinical signs and symptoms of a demyelinating neuropathy was examined for the presence of this duplication. Analysis of MspI polymorphisms in DNA extracted from peripheral blood failed due to homozygosity for probes pVAW409R3a and pEW401HE. Also, no EcoRI/SacI 3.2 kb junction fragment or dosage difference with probe pLR7.8, characteristic of the CMT1A duplication, was found. However, fluorescence in situ hybridization (FISH) analysis with the PMP22 specific probe c132G8 revealed in peripheral blood lymphocytes 60% of interphase nuclei with CMT1A duplication indicating the probability of mosaicism. In interphase nuclei extracted from nerve tissue the duplication was detectable in 88%, in muscle tissue in 72% of the analyzed nuclei. This suggests the presence of a somatic CMT1A duplication mosaicism that can only be reliably detected by FISH. The early onset and severity of the phenotype indicates that the hypothesized somatic reversion is probably fixed to early developmental stages.

Autosomal dominant Charcot-Marie-Tooth disease type 1A and hereditary neuropathy with liability to pressure palsies: detection of the recombination in Slovene patients and exclusion of the potentially recessive Thr118Met PMP22 point mutation

Charcot-Marie-Tooth disease type 1 (CMT1) and hereditary neuropathy with liability to pressure palsies (HNPP) are the most frequent autosomal dominantly inherited disorders of the peripheral nervous system. The recessive inheritance is observed only exceptionally. Unequal crossing-over of misaligned flanking CMT1A-REP elements on chromosome 17p11.2 is the most frequent cause of the CMT1A duplication and of the reciprocal deletion in HNPP patients. Recently a recombination was noted. In our study 71 Slovene CMT1 patients from 36 families, 12 HNPP patients from 6 families and their 31 healthy relatives were analysed for the presence of these recombination mutations. In 29 of 36 unrelated CMT1 (81%) and in all 6 unrelated HNPP patients the duplication or the deletion, on chromosome 17p11.2-12 was detected. In 26 out of 29 duplication patients (CMT1A) (90%) a 3.2 kb EcoRI/SacI duplication junction fragment was observed. The analogous 7.8 kb EcoRI/EcoRI deletion junction fragment was found in 4 out of 6 unrelated HNPP deletion patients (67%). Overall we found a recombination mutation inside the in 86% of unrelated Slovene CMT1A and HNPP patients. One hundred and thirty-six DNA samples of the CMT1 and HNPP patients and of the healthy controls were negative for the potentially recessive Thr118Met PMP22 amino acid substitution. Dominantly inherited CMT1A duplications and HNPP deletions on chromosome 17p11.2 are thus, as in most other European countries, the most common mutations in Slovene CMT1 and HNPP patients. No signs of polymorphism or of potentially recessive mutation were found at the specific Thr118Met PMP22 site.

Advances in Charcot-Marie-Tooth disease research: cellular function of CMT-related proteins, transgenic animal models, and pathomechanisms. The European CMT Consortium

The First Workshop of the European Consortium on Charcot-Marie-Tooth (CMT) disease brought together neuroscientists, molecular and cell biologists, neuropathologists, neurologists, and geneticists with a common interest in the understanding of the fundamental mechanisms that underlie the pathogenesis of CMT. The interdisciplinary group of 25 expert scientists discussed recent advances in (i) molecular genetics and histopathology of CMT, (ii) development of suitable animal models, (iii) understanding of the cellular function of CMT-related proteins, and (iv) studies using nerve biopsies from CMT patients. In this minireview, we summarize the key findings presented and discuss their impact on CMT research.

Molecular diagnosis of PMP22-associated neuropathies using fluorescence in situ hybridization (FISH) on archival peripheral nerve tissue preparations

Charcot-Marie-Tooth (CMT) syndrome type 1 and tomaculous neuropathy, also called hereditary neuropathy with liability to pressure palsies (HNPP), represent two groups of neurological disorders with different subtypes, which can be distinguished at the molecular level. It is known that a 1.5-mb region on chromosome 17p11.2-12, which includes the gene for the peripheral myelin protein 22 kDa (PMP22), is duplicated in more than 95% of patients with CMT type 1A (CMT1A; gene dosage 3) and is deleted in about 90% of subjects suffering from HNPP (gene dosage 1). This duplication/deletion can be detected reliably by interphase-two-color fluorescence in situ hybridization (FISH). We report here a technique for extraction of nuclei from paraffin-embedded and cryofixed sural nerve biopsies for precise molecular diagnosis, employing interphase-two-color FISH in clinically diagnosed CMT1 or HNPP patients. Following this technique we were able to identify six CMT1A duplications in 13 clinically diagnosed CMT1 cases and five HNPP deletions in 6 clinically diagnosed HNPP cases; 8 control persons were included in this study. This is the first report on the use of FISH in the detection of 17p11.2-12 duplication and deletion in archival biopsy material.

The peripheral myelin protein 22 kDa (PMP22) gene is amplified in cell lines derived from glioma and osteogenic sarcoma

Two glioma (SF188, SF763) and two osteogenic sarcoma cell lines (RH30, SA1) were examined for the presence of an amplification of the PMP22 gene by means of fluorescence in situ hybridization (FISH). In one cell line of both cell types, we found about 10 copies of the PMP22 (peripheral myelin protein 22 kDa) gene, located on different marker chromosomes within homogeneously staining regions. Surrounding chromosome 17p material was found to be coamplified, but coamplification of TP53 (17p13) and erbB2/Her2 (17q11.12) were excluded by FISH for both cell lines, SF763 and RH30. This is the first report of a PMP22 amplification in cell lines derived from human tumors.

Detection of the CMT1A/HNPP recombination hotspot in unrelated patients of European descent

Charcot-Marie-Tooth type 1 disease (CMT1) and hereditary neuropathy with liability to pressure palsies (HNPP) are common inherited disorders of the peripheral nervous system. The majority of CMT1 patients have a 1.5Mb tandem duplication (CMT1A) in chromosome 17p11.2 while most HNPP patients have a deletion of the same 1.5 Mb region. The CMT1A duplication and HNPP deletion are the reciprocal products of an unequal crossing over event between misaligned flanking CMT1A-REP elements. We analysed 162 unrelated CMT1A duplication patients and HNPP deletion patients from 11 different countries for the presence of a recombination hotspot in the CMT1A-REP sequences. A hotspot for unequal crossing over between the misaligned flanking CMT1A-REP elements was observed through the detection of novel junction fragments in 76.9% of 130 unrelated CMT1A patients and in 71.9% of 32 unrelated HNPP patients. This recombination hotspot was also detected in eight out of 10 de novo CMT1A duplication and in two de novo HNPP deletion patients. These data indicate that the hotspot of unequal crossing over occurs in several populations independently of ethnic background and is directly involved in the pathogenesis of CMT1A and HNPP. We conclude that the detection of junction fragments from the CMT1A-REP element on Southern blot analysis is a simple and reliable DNA diagnostic tool for the identification of the CMT1A duplication and HNPP deletion in most patients.

Clinical and morphological phenotype of HMSN 1A mosaicism

Clinical, neurophysiological and morphological studies on a patient with mosaicism of the 17p11.2 duplication were performed in detail for the first time. Since duplication occurs during paternal meiosis, a somatic reversion is suggested, leading to mosaicism. The proportion of nuclei with duplication varied markedly between 49% in blood cells and 74% in tissue from the sural nerve. Clinically, mild symptoms of a motor and sensory neuropathy were present. However, neurophysiological changes and findings in the sural nerve biopsy were consistent with a typical hereditary motor and sensory neuropathy type 1 (HMSN 1). Differing clinical findings in patients with mosaicism of the 17p11.2 duplication may be explained by a varying degree and/or time of reversion.

Mosaicism for the Charcot-Marie-Tooth disease type 1A duplication suggests somatic reversion

A female patient with clinical signs and symptoms of a demyelinating neuropathy was shown to have a duplication of the 1.5-Mb region on chromosome 17p11.2, typical of the great majority of cases of Charcot-Marie-Tooth disease type 1A (CMT1A). However, analysis of DNA extracted from peripheral blood revealed a 2:2.4 instead of the usual 2:3 ratio between the 7.8- and 6.0-kb EcoRI fragments in the proximal and distal repetitive extragenic palindromic (REP) elements of CMT1A. Detection of a 3.2-kb EcoRI/SacI kb junction fragment with probe pLR7.8 confirmed the CMT1A duplication. The dosage of this junction fragment, compared with a 2.8-kb EcoRI/SacI fragment of the proximal REP elements of CMT1A, was 2:0.58 instead of the expected 2:1 dosage for heterozygous CMT1A duplications. We hypothesized that the lower dosages of these restriction fragments specific for the CMT1A duplication were due to mosaicism; this was confirmed by fluorescence in situ hybridization analysis with the D17S122-specific probe pVAW409R1. In peripheral blood lymphocytes the percentage of interphase nuclei with a duplication in 17p11.2 was 49%. In interphase nuclei extracted from buccal mucosa, hair-root cells or paraffin-embedded nervous tissue the duplication was detectable in 51%, 66% and 74%, respectively. This is the first report of mosaicism in a patient with a CMT1A duplication identified by three different and independent techniques.

Widespread expression of the peripheral myelin protein-22 gene (PMP22) in neural and non-neural tissues during murine development

The gene encoding the peripheral myelin protein PMP22 is affected by various mutations in the hereditary peripheral neuropathies Charcot-Marie-Tooth disease type 1A (CMT1A), Déjérine-Sottas syndrome (DSS) and hereditary neuropathy with liability to pressure palsies (HNPP). In contrast to the recent remarkable progress in the genetics of the PMP22 gene, the biological function of PMP22 remains largely unknown. In this report, we have confirmed by using in situ hybridization techniques that high levels of PMP22 mRNA are present in maturing peripheral nerves of the 2-week-old mouse, a finding consistent with the PNS-specific defect observed in hereditary peripheral neuropathies. However, high levels of PMP22 transcripts were also found in the villi of the adult gut, and PMP22 expression was detected in various non-neural tissues during embryonic mouse development. In early embryogenesis (9.5 days postconception, dpc), PMP22 RNA expression appears restricted to the epithelial ectodermal layer. During early organogenesis (11.5 dpc), particularly high levels of expression are present in the capsule surrounding the liver and in the forming gut, while low levels of PMP22 mRNA can be found in precartilagous condensations forming the vertebrae and the ventricular layer of the myelencephalon. During midgestation development (14.5 dpc to 16.5 dpc), the number of PMP22-positive tissues increases, and high expression is detected in several mesoderm-derived tissues, in particular connective tissues of the face region, bones including the vertebrae, the lung mesenchym, and in muscles. In addition, high expression is also found in ectoderm-derived tissues, especially the epithelia of the lens and the skin. These findings strongly suggest that PMP22 serves not only a PNS-specific function but is also of broader biological significance in cell proliferation and/or differentiation.