Identification of NF2 germ-line mutations and comparison with neurofibromatosis 2 phenotypes

Neurofibromatosis 2 (NF2) is an autosomal inherited disorder that predisposes carriers to nervous system tumors. To examine genotype-phenotype correlations in NF2, we performed mutation analyses and gadolinium-enhanced magnetic resonance imaging of the head and full spine in 59 unrelated NF2 patients. In patients with vestibular schwannomas (VSs) or identified NF2 mutations, the mild phenotype was defined as <2 other intracranial tumors and ≤ 4 spinal tumors, and the severe phenotype as either ≥ 2 other intracranial tumors or > 4 spinal tumors. Nineteen mutations were found in 20 (34%) of the patients and were distributed in 12 of the 17 exons of the NF2 gene, including intron-exon boundaries. Seven mutations were frameshift, six were nonsense, four were splice site, two were missense, and one was a 3-bp in frame deletion. The nonsense mutations included one codon 57 and two codon 262 C→T transitions in CpG dinucleotides. The frameshift and nonsense NF2 mutations occurred primarily in patients with severe phenotypes. The two missense mutations occurred in patients with mild phenotypes, and three of the four splice site mutations occurred in families with both mild and severe phenotypes. Truncating NF2 mutations are usually associated with severe phenotypes, but the association of some mutations with mild and severe phenotypes indicates that NF2 expression is influenced by stochastic, epigenetic, or environmental factors. Received: 4 July 1996     

Two recurrent nonsense mutations and a 4 bp deletion in a quasi-symmetric element in exon 37 of the NF1 gene

We screened a total of 92 unrelated patients with neurofibromatosis type 1 (NF1) for mutations in exon 37 of the NF1 gene, by using temperature gradient gel electrophoresis. Two novel mutations were found: a 4 bp deletion in a so-called quasi-symmetric element (6789delTTAC) and a recurrent nonsense mutation, which was identified in two unrelated patients, at codon 2264 (C6792A). The independent origin of the latter mutation in two families was confirmed by haplotype analysis. The nonsense mutation and the 4 bp deletion are both predicted to lead to a truncated protein product lacking the Cterminal 20% (aproximately) of its sequence. The occurrence of three independent mutations among 92 NF1 patients at codons 2263–2264 (exon 37) suggests that a specific search for mutations in this area should be undertaken in screening programs for NF1 mutations.     

Phenotypic variability in two families with novel splice-site and frameshift NF2 mutations

Neurofibromatosis 2 (NF2) is a clinically variable autosomal dominant disorder, caused by mutations in the NF2 tumor suppressor gene on chromosome 22q12, that predisposes to nervous system tumors and ocular abnormalities. To assess intrafamilial phenotypic variability, we performed mutation analysis and clinical assessment on two multigeneration NF2 families with five patients and seven asymptomatic first-degree relatives of patients. One family had a point mutation of agCC→ggCC at position 1447–2 at the exon 13/14 boundary predicted to lead to an altered splice acceptor sequence and exon deletion. The other family had an insertion of 2 base pairs (TC) at position 761 in exon 8, leading to a frameshift. Both mild and severe phenotypes occurred in each family, indicating that phenotypic variability in NF2 can be caused by factors other than NF2 mutations. Genetic counseling of NF2 families should include the possibility that presymptomatic NF2 mutation carriers can develop a different phenotype than previously diagnosed patients. Received: 4 January 1996 / Revised: 26 March 1996     

The role of NF2 gene mutations and pathogenesis-related proteins in sporadic vestibular schwannomas in young individuals

Vestibular schwannomas (VSs) are benign tumors arising from eighth cranial nerve and most often occur sporadically in individuals of middle age group. Sporadic VSs are rarely reported in the young population. In this study, we evaluated clinical behaviors of 12 young sporadic VSs by the statistical comparison with a matched series of 145 adult cases. We found that young tumors were characterized by an earlier onset of initial symptom, shorter duration from the first symptom to diagnosis, and larger tumor size than adult ones. Standard sequencing demonstrated the presence of NF2 mutations in eight tumors. All NF2 mutations identified were truncating mutations (nonsense, frameshift, and splicing-site mutations). Earlier formation of VSs in young patients was evidenced by the high incidence of NF2 mutations (66.7 %) far beyond our previous study in the adult case series (34.5 %). Furthermore, young tumors exhibited deficient merlin or heightened phosphorylated merlin that was subsequently demonstrated to be well correlated with increased tumor size. Finally, we compared protein levels of four pathogenesis-related molecules between young and adult group but there was no significant difference. These results led us to suggest that high frequency of NF2 mutations may play a critical role in early tumorigenesis of young VSs. Moreover, merlin deficiency or phosphorylation status of merlin was involved in their earlier development. Further study remains to fully understand the mechanism for the rapid growth of young VSs.     

Molecular characterization of germline NF2 gene rearrangements

Neurofibromatosis type 2 (NF2) is an autosomal dominant disease that causes a predisposition to nervous system tumors. Deleterious point mutations have been found in about 55% of NF2 patients, and large genomic deletions account for approximately 33% of NF2 gene alterations. The majority of these deletions are larger than 50 kb, with a breakpoint usually lying outside the NF2 gene. We identified two cases of intragenic deletion with loss of 1.5 and 40 kb, respectively. In both cases, one boundary of the deletion was located in or at the proximity of an SVA sequence in NF2 intron 4. No sequence identity longer than 5 bases and no signal of specific recombination have been evidenced on either side of the deletion breakpoints. These observations are compatible with a nonhomologous recombination being responsible for the genomic deletions. In a third case, a paracentric inversion of chromosome 22 was found. This chromosomal rearrangement breaks the NF2 gene in two parts and carries the first NF2 exon in a juxta-centromeric position. The variability in position of the deletions and the observation of a new chromosomal rearrangement in the NF2 gene underscore the importance of FISH analysis in the molecular diagnosis of NF2.     

A missense mutation in the NF2 gene results in moderate and mild clinical phenotypes of neurofibromatosis type 2

Since the identification of the NF2 tumor suppressor gene in 1993, various mutations have been found in NF2-related tumors and in lymphocytes from NF2 patients. Most of the reported mutations result in truncated gene products. Missense mutations affecting the tumor suppressor are rare. These missense mutations would provide valuable information for the understanding of the function of the tumor suppressor, since they should affect critical parts of the protein. In this study we describe a novel point mutation in exon 15 of the NF2 gene, which is found in lymphocyte DNA of two NF2 patients from one family. This mutation is expected to result in a substitution of Pro for Gln at codon 538. Though both of the two patients developed bilateral vestibular schwannomas, the first patient showed onset of the disease at the age of 31 years and presented with various central, peripheral and abdominal tumors, while the second patient showed later onset of clinical symptoms (at age 52 years) and presented with only two additional small spinal tumors.     

Spinal Neurofibromatosis without Café-au-Lait Macules in Two Families with Null Mutations of the NF1 Gene

Spinal neurofibromatosis (SNF) is considered to be an alternative form of neurofibromatosis, showing multiple spinal tumors and café-au-lait macules. Involvement of the neurofibromatosis type 1 (NF1) locus has been demonstrated, by linkage analysis, for three families with SNF. In one of them, a cosegregating frameshift mutation in exon 46 of the NF1 gene was identified. In the present study, we report four individuals from two families who carry NF1 null mutations that would be expected to cause NF1. Three patients have multiple spinal tumors and no café-au-lait macules, and the fourth has no clinical signs of NF1. In the first family, a missense mutation (Leu2067Pro) in NF1 exon 33 was found, and, in the second, a splice-site mutation (IVS31-5A-->G) enlarging exon 32 by 4 bp at the 5' end was found. The latter mutation has also been observed in an unrelated patient with classical NF1. Both NF1 mutations cause a reduction in neurofibromin of approximately 50%, with no truncated protein present in the cells. This demonstrates that typical NF1 null mutations can result in a phenotype that is distinct from classical NF1, showing only a small spectrum of the NF1 symptoms, such as multiple spinal tumors, but not completely fitting the current clinical criteria for SNF. We speculate that this phenotype is caused by an unknown modifying gene that compensates for some, but not all, of the effects caused by neurofibromin deficiency.     

Three different pathological lesions in the <Emphasis Type="Italic">NF1</Emphasis> gene originating de novo in a family with neurofibromatosis type 1

Three members of a Portuguese family, who exhibited clinical evidence of neurofibromatosis type 1 (NF1), were found to possess different heritable and pathological mutations in their NF1 genes: a 1.5-Mb deletion spanning the entire NF1 gene, a truncating CGA-->TGA transition in exon 22 (R1241X), and a frameshift mutation in exon 29 (5406insT). All three lesions occurred de novo and are likely to have been generated by different mutational mechanisms. At least two of the mutations occurred on different chromosomal backgrounds. The probability of finding three non-identical NF1 gene lesions arising de novo in a family with NF1 is very remote, too low to be readily accepted as mere coincidence. A number of possible explanations for this unique finding were therefore explored, but none were found to be wholly convincing. This report nevertheless serves as a reminder that it is unwise, even in the case of an autosomal dominant condition, to extrapolate from the detection of a single mutation in a specific individual to assuming an identical molecular genetic aetiology in other clinically affected members of the same family.     

A group of schwannomas with interstitial deletions on 22q located outside the NF2 locus shows no detectable mutations in the NF2 gene

Schwannomas are tumors arising mainly at cranial and spinal nerves. Bilateral vestibular schwannoma is the hallmark of neurofibromatosis type 2 (NF2). The NF2 gene has been cloned and comprehensive analysis of its mutations in schwannomas shows that up to 60% of tumors carry inactivating mutations. Thus, the genetic mechanism behind the development of more than 40% of schwannomas without NF2 mutations is unknown. We have therefore studied tumor tissue from 50 human schwannomas by allelotyping and have found chromosome 22 deletions in over 80% of the cases. We detected 14 cases (27%) that revealed partial deletions of one copy of chromosome 22, i.e., terminal and/or interstitial deletions. We sequenced the NF2 gene in seven of these tumors and detected only one case with mutations. The deletion mapping of chromosome 22 in tumors with partial deletions indicates that several regions, in addition to the NF2 locus, harbor genes involved in schwannoma tumorigenesis. Our findings suggest that heterogeneity in the mechanisms leading to the development of schwannomas probably exists. These findings are in agreement with the recent analysis of schwannomas from familial and sporadic cases of schwannomatosis and point to a possible role of an additional gene, which, in cooperation with the NF2 tumor suppressor, causes schwannomas. Received: 12 November 1998 / Accepted: 1 March 1999     

Screening for mutations in the neurofibromatosis type 2 (NF2) gene in sporadic meningiomas

Meningiomas are benign tumors of the central nervous system. They are usually sporadic but can also occur associated with the neurofibromatosis type 2 (NF2) syndrome. The gene responsible for NF2, recently isolated from chromosome 22, encodes a membrane-organizing protein that shows high sequence homology to a protein family thought to link the cytoskeleton with membrane proteins. Mutations of the NF2 gene have been described in sporadic meningiomas, exclusively in tumors that show loss of heterozygosity (LOH) of 22q. These preliminary results indicate that the NF2 gene is involved in the pathogenesis of at least a subset of meningiomas, where it does indeed behave as a tumor suppressor gene. In order to characterize better the role of the NF2 gene in the genesis of meningiomas we have examined the entire coding sequence of the gene in 125 meningiomas by single-strand conformational polymorphism analysis; furthermore, LOH analysis for markers of 22q has been carried out. Inactivating mutations were identified in 30% of our samples, all of which also showed LOH of 22q. The majority of mutations identified were frameshifts and nonsense mutations, which are predicted to produce a truncated or non-functional protein. We also found two missense and three in-frame deletions that may pinpoint specific regions of the protein critical to its function. Furthermore, the distribution of mutations throughout the gene, suggested that exons 2, 3, 5, 11 and 13 are more frequently involved. Our results reconfirm the importance of the NF2 gene in the pathogenesis of meningiomas and also suggest that there may be a nonrandom clustering of mutations throughout the gene.     

Genetic and epigenetic alterations of the NF2 gene in sporadic vestibular schwannomas

Background

Mutations in the neurofibromatosis type 2 (NF2) tumor-suppressor gene have been identified in not only NF2-related tumors but also sporadic vestibular schwannomas (VS). This study investigated the genetic and epigenetic alterations in tumors and blood from 30 Korean patients with sporadic VS and correlated these alterations with tumor behavior.

Methodology/Principal Findings

NF2 gene mutations were detected using PCR and direct DNA sequencing and three highly polymorphic microsatellite DNA markers were used to assess the loss of heterozygosity (LOH) from chromosome 22. Aberrant hypermethylation of the CpG island of the NF2 gene was also analyzed. The tumor size, the clinical growth index, and the proliferative activity assessed using the Ki-67 labeling index were evaluated. We found 18 mutations in 16 cases of 30 schwannomas (53%). The mutations included eight frameshift mutations, seven nonsense mutations, one in-frame deletion, one splicing donor site, and one missense mutation. Nine patients (30%) showed allelic loss. No patient had aberrant hypermethylation of the NF2 gene and correlation between NF2 genetic alterations and tumor behavior was not observed in this study.

Conclusions/Significance

The molecular genetic changes in sporadic VS identified here included mutations and allelic loss, but no aberrant hypermethylation of the NF2 gene was detected. In addition, no clear genotype/phenotype correlation was identified. Therefore, it is likely that other factors contribute to tumor formation and growth.     

A second case of somatic triple mosaicism in the CYBB gene causing chronic granulomatous disease

The most common form of chronic granulomatous disease (CGD) is caused by mutations in the CYBB gene that is carried on the X-chromosome and give rise to the X-linked form of the disease. The product of this gene is the large subunit of flavocytochrome b558, gp91phox, the catalytic core of the superoxide-generating enzyme, NADPH oxidase. In the overwhelming majority of cases, mutations are family-specific and occur in the exonic regions of the gene or, less frequently, at the intron/exon borders. In addition, there are large, often multi-gene, deletions. Four mutations have also been found in the promoter regions. In contrast, very few intronic mutations have been reported. Here we describe an unusual intronic mutation that causes CGD. The mutation is the insertion of 12 bp in intron XI, accompanied by the deletion of exon 12. Remarkably, the grandmother of this patient is chimeric, carrying a normal allele, the patient's allele, and an allele with a 4-nucleotide insertion at a site adjacent to the patient's insertion, in combination with a 1.5-kb deletion within intron XI. The patient's mother carries a normal allele and the patient's allele. We propose that an initial mutational event during the grandmother's embryogenesis has undergone unsuccessful DNA repair and has resulted in two aberrant alleles, one of which has been inherited by the patient and his mother. Remarkably, in the only two kindreds that have been examined in detail where deletions originating within introns have led to CGD, both families have contained members with triple somatic mosaicism.     

A Deletion in the Endothelin-B Receptor Gene is Responsible for the Waardenburg Syndrome-Like Phenotypes of WS4 Mice.

The WS4 mouse is an animal model for human Waardenburg syndrome type 4 (WS4), showing pigmentation anomalies, deafness and megacolon, which are caused by defects of neural crest-derived cells. We have previously reported that the gene responsible for the WS4 mouse is an allele of the piebald mutations of the endothelin B receptor gene (Ednrb). In this study, we examined the genomic sequence of the Ednrb gene in WS4 mice and found a 598-bp deletion in the gene. The deleted region contains the entire region of exon 2 and the 5' part of exon 3 and is flanked by inverted repeat sequences which are suggested to trigger the deletion. We concluded that the deletion in the Ednrb gene is the causative mutation for the phenotype of WS4 mice.     

Repeated sequences in CASPASE-5 and FANCD2 but not NF1 are targets for mutation in microsatellite-unstable acute leukemia/myelodysplastic syndrome

Microsatellite instability (MSI) in tumors is diagnostic for inactive DNA mismatch repair. It is widespread among some tumor types, such as colorectal or endometrial carcinoma, but is rarely found in leukemia. Therapy-related acute myeloid leukemia/myelodysplastic syndrome (tAML/MDS) is an exception, and MSI is frequent in tAML/MDS following cancer chemotherapy or organ transplantation. The development of MSI+ tumors is associated with an accumulation of insertion/deletion mutations in repetitive sequences. These events can cause inactivating frameshifts or loss of expression of key growth control proteins. We examined established MSI+ cell lines and tAML/MDS cases for frameshift-like mutations of repetitive sequences in several genes that have known, or suspected, relevance to leukemia. CASPASE-5, an acknowledged frameshift target in MSI+ gastrointestinal tract tumors, was frequently mutated in MSI+ cell lines (67%) and in tAML/MDS (29%). Frameshift-like mutations were also observed in the NF1 and FANCD2 genes that are associated with genetic conditions conferring a predisposition to leukemia. Both genes were frequent targets for mutation in MSI+ cell lines and colorectal carcinomas. FANCD2 mutations were also common in MSI+ tAML/MDS, although NF1 mutations were not observed. A novel FANCD2 polymorphism was also identified.     

Simultaneous detection of multiple mutations in epidermal growth factor receptor based on fluorescence quenching of quantum dots

We have developed a simultaneous detection method for two common mutations in the epidermal growth factor receptor gene based on the fluorescence quenching phenomenon caused by aggregation of CdSe quantum dots. For detection of the in-frame deletion in exon 19 and the L858R point mutation in exon 21, water-soluble CdSe quantum dots with two sizes were functionalized using four different types of probe oligonucleotides. Addition of target oligonucleotides with the deletion mutation in exon 19 into the suspensions caused crosslinking-induced aggregation of green-emitting quantum dots, followed by the fluorescence quenching while that with the L858R point mutation resulted in aggregation of yellow-emitting quantum dots. In addition, targets with both deletion and point mutations caused aggregation of both green- and yellow-emitting quantum dots. This method allows a simultaneous detection of mutations in exon 19 and 21 of EGFR gene in a single experiment. We found that minimum mutant concentration that could be detected by this method was as low as 2% for deletion mutation, and 5% for point mutation. PCR products of EGFR gene were also used to confirm that our method could be used to detect mutation in amplified DNA fragments.     

Genotype-phenotype correlations for nervous system tumors in neurofibromatosis 2: a population-based study

Neurofibromatosis 2 (NF2) is an autosomal dominant disease that is characterized by tumors on the vestibular branch of the VIII cranial nerve, but other types of nervous system tumors usually occur as well. Genotype-phenotype correlations are well documented for overall NF2 disease severity but have not been definitively evaluated for specific types of non-VIII nerve tumors. We evaluated genotype-phenotype correlations for various types of non-VIII nerve tumors in 406 patients from the population-based United Kingdom NF2 registry, using regression models with the additional covariates of current age and type of treatment center (specialty or nonspecialty). The models also permitted consideration of intrafamilial correlation. We found statistically significant genotype-phenotype correlations for intracranial meningiomas, spinal tumors, and peripheral nerve tumors. People with constitutional NF2 missense mutations, splice-site mutations, large deletions, or somatic mosaicism had significantly fewer tumors than did people with constitutional nonsense or frameshift NF2 mutations. In addition, there were significant intrafamilial correlations for intracranial meningiomas and spinal tumors, after adjustment for the type of constitutional NF2 mutation. The type of constitutional NF2 mutation is an important determinant of the number of NF2-associated intracranial meningiomas, spinal tumors, and peripheral nerve tumors.     

Four novel RUNX2 mutations including a splice donor site result in the cleidocranial dysplasia phenotype

Cleidocranial dysplasia (CCD) is an autosomal dominant disorder caused by haploinsufficiency of the RUNX2 gene. In this study, we analyzed by direct sequencing RUNX2 mutations from eleven CCD patients. Four of seven mutations were novel: two nonsense mutations resulted in a translational stop at codon 50 (Q50X) and 112 (E112X); a missense mutation converted arginine to glycine at codon 131 (R131G); and an exon 1 splice donor site mutation (donor splice site GT/AT, IVS1 + 1G > A) at exon 1-intron junction resulted in the deletion of QA stretch contained in exon 1 of RUNX2. We focused on the functional analysis of the IVS1 + 1G > A mutation. A full-length cDNA of this mutation was cloned (RUNX2Deltae1) and expressed in Chinese hamster ovary (CHO) and HeLa cells. Functional analysis of RUNX2Deltae1 was performed with respect to protein stability, nuclear localization, DNA binding, and transactivation activity of a downstream RUNX2 target gene. Protein stability of RUNX2Deltae1 is similar to wild-type RUNX2 as determined by Western blot analysis. Subcellular localization of RUNX2Deltae1, assessed by in situ immunofluorescent staining, was observed with partial retention in both the nucleus and cytoplasm. This finding is in contrast to RUNX2 wild-type, which is detected exclusively in the nucleus. DNA binding activity was also compromised by the RUNX2Deltae1 in gel shift assay. Finally, RUNX2Deltae1 blocked transactivation of the osteocalcin gene determined by transient transfection assay. Our findings demonstrate for the first time that the CCD phenotype can be caused by a splice site mutation, which results in the deletion of N-terminus amino acids containing the QA stretch in RUNX2 that contains a previously unidentified second nuclear localization signal (NLS). We postulate that the QA sequence unique to RUNX2 contributes to a competent structure of RUNX2 that is required for nuclear localization, DNA binding, and transactivation function.     

A de novo nonsense mutation in exon 28 of the neurofibromatosis type l (NF1) gene

We have screened a total of 105 unrelated patients with neurofibromatosis type l (NF1) for mutations in exon 28 of the NF1 gene using heteroduplex analysis and single strand conformation polymorphism analysis. One novel mutation has been identified and characterised. This mutation involves a 13-bp deletion (AAACTGGCTGAGC or AACTGGCTGAGCA) from base position 5077 (or 5078) to 5089 (or 5090) of the cDNA coding sequence. This alteration leads to a reading frame shift with a premature amber termination signal (TAG) at codon 1694. In addition, there is a change from lysine to threonine at codon 1693. The truncated gene product is estimated to be 1125 amino acid residues shorter than the predicted normal protein (2818 amino acids).