Evidence of a four-hit mechanism involving SMARCB1 and NF2 in schwannomatosis-associated schwannomas

Schwannomatosis is characterized by the onset of multiple intracranial, spinal, or peripheral schwannomas, without involvement of the vestibular nerve, which is instead pathognomonic of neurofibromatosis type 2 (NF2). Recently, a schwannomatosis family with a germline mutation of the SMARCB1 gene on chromosome 22 has been described. We report on the molecular analysis of the SMARCB1 and NF2 genes in a series of 21 patients with schwannomatosis and in eight schwannomatosis-associated tumors from four different patients. A novel germline SMARCB1 mutation was found in one patient; inactivating somatic mutations of NF2, associated with loss of heterozygosity (LOH) of 22q, were found in two schwannomas of this patient. This is the second report of a germline SMARCB1 mutation in patients affected by schwannomatosis and the first report of SMARCB1 mutations associated with somatic NF2 mutations in schwannomatosis-associated tumors. The latter observation suggests that a four-hit mechanism involving the SMARCB1 and NF2 genes may be implicated in schwannomatosis-related tumorigenesis.     

Constitutional LZTR1 mutation presenting with a unilateral vestibular schwannoma in a teenager

Schwannomatosis is a rare neurofibromatosis clinically diagnosed by age‐dependent criteria, with bilateral vestibular schwannoma and/or a constitutional NF2 mutation representing exclusion criteria. Following SMARCB1 germline mutations, constitutional mutations in LZTR1 were discovered. We report on the molecular investigation in a patient presenting at 14 years with a unilateral vestibular schwannoma, ultimately causing blindness and unilateral hearing loss, in the absence of other schwannomas or a positive family history. In DNA derived from frozen tumor tissue, a comprehensive NF2, SMARCB1 and LZTR1 analysis showed an NF2 truncating mutation c.1006_1021delins16; an LZTR1 mutation c.791+1G>A; and a partial 22q deletion including NF2, SMARCB1 and LZTR1. Sequence analysis on peripheral blood derived DNA showed the LZTR1 mutation to be constitutional, but the NF2 mutation and partial 22q deletion were not found, indicating them to be somatic events. RNA‐based targeted analysis confirmed missplicing of LZTR1 intron 8, predicted to result in a premature stop codon. This LZTR1 mutation was paternally inherited. While isolated vestibular schwannoma or NF2 may be considered in a young individual with a unilateral vestibular schwannoma, this report suggests that LZTR1 ‐related schwannomatosis be added to this differential diagnosis.     

Update from the 2011 International Schwannomatosis Workshop: From genetics to diagnostic criteria

Schwannomatosis is the third major form of neurofibromatosis and is characterized by the development of multiple schwannomas in the absence of bilateral vestibular schwannomas. The 2011 Schwannomatosis Update was organized by the Children's Tumor Foundation ( www.ctf.org ) and held in Los Angeles, CA, from June 5–8, 2011. This article summarizes the highlights presented at the Conference and represents the “state‐of‐the‐field” in 2011. Genetic studies indicate that constitutional mutations in the SMARCB1 tumor suppressor gene occur in 40–50% of familial cases and in 8–10% of sporadic cases of schwannomatosis. Tumorigenesis is thought to occur through a four‐hit, three‐step model, beginning with a germline mutation in SMARCB1 (hit 1), followed by loss of a portion of chromosome 22 that contains the second SMARCB1 allele and one NF2 allele (hits 2 and 3), followed by mutation of the remaining wild‐type NF2 allele (hit 4). Insights from research on HIV and pediatric rhabdoid tumors have shed light on potential molecular pathways that are dysregulated in schwannomatosis‐related schwannomas. Mouse models of schwannomatosis have been developed and promise to further expand our understanding of tumorigenesis and the tumor microenvironment. Clinical reports have described the occurrence of intracranial meningiomas in schwannomatosis patients and in families with germline SMARCB1 mutations. The authors propose updated diagnostic criteria to incorporate new clinical and genetic findings since 2005. In the next 5 years, the authors expect that advances in basic research in the pathogenesis of schwannomatosis will lead toward clinical investigations of potential drug therapies. © 2013 Wiley Periodicals, Inc.     

Somatic NF2 gene mutations in familial and non-familial vestibular schwannoma

Vestibular schwannoma occurs both as a sporadic tumour and Inthe dominantly inherited familial cancer syndrome neuroflbromatosistype 2 (NF2). The gene for NF2 has recently been Isolated onchromosome 22, and the demonstration of inactivating germllnemutations In NF2 patients and NF2 associated tumours suggeststhat it act as a tumour suppressor. We have investigated 85sporadic and 2 NF2 associated vestibular schwannomas, and onevagal schwannoma for chromosome 22 allele loss and NF2 genemutations. A further 7 vestibular schwannomas were Investigatedfor NF2 mutations only. Chromosome 22 allele loss was detectedin 34 of 87 vestibular schwannomas and In the vagal nerve schwannoma.Six exons of the NF2 gene were Investigated by SSCP analysisin all 95 tumours. Somatic NF2 gene mutations were detectedIn 13 non-familial vestibular schwannomas. and in one of theNF2 vestibular schwannomas. Seven non-famlllal tumours withan NF2 gene mutation also displayed a chromosome 22 allele loss.Thirteen of the mutations were predicted to produce truncationof the NF2 protein. These results suggest that somatic mutationsof the NF2 tumour suppressor gene are a critical step In thepathogenesis of both famlllal and non-famlllal vestibular schwannomaand that the mechanism of tumourigenesis complles with a ‘two-hit’mutation model.     

Predominant occurrence of somatic mutations of the NF2 gene in meningiomas and schwannomas

The NF2 gene is a putative tumor-suppressor gene that, when it is altered in the germline, causes neurofibromatosis type 2, a tumor-susceptibility disease that mainly predisposes to schwannomas and meningiomas. The recent isolation of the NF2 gene on chromosome 22 allows the identification of somatic mutations in human tumors. We have searched for mutations of the NF2 gene in 331 primary human tumors using a screening method based on denaturing gradient gel electrophoresis, which allows the detection of mutations in 95% of the coding sequence. Mutations were observed in 17 of 57 meningiomas and in 30 of 89 schwannomas. No mutations were observed for 17 ependymomas, 70 gliomas, 23 primary melanomas, 24 pheochromocytomas, 15 neuroblastomas, 6 medulloblastomas, 15 colon cancers, and 15 breast cancers. All meningiomas and one-half of the schwannomas with identified NF2 mutations demonstrated chromosome 22 allelic losses. We conclude that the involvement of the NF2 gene in human tumorigenesis may be restricted to schwannomas and meningiomas, where it is frequently inactivated by a two-hit process. © 1995 Wiley-Liss, Inc.     

Immotile cilia syndrome: A recombinant family at HLA-linked gene locus

To determine the spectrum of manifestations in neurofibromatosis 2 (NF2) and to assess possible heterogeneity, we evaluated 63 affected individuals from 32 families. Work-up included skin and neurologic examinations, audiometry, a complete ophthalmology examination with slit-lamp biomicroscopy of the lens and fundus, and gadolinium-enhanced MRI of the brain and, in some, of the spine. Mean age-at-onset in 58 individuals was 20.3 years; initial symptoms resulted from vestibular schwannomas (44.4%), other CNS tumors (22.2%), skin tumors (12.7%), and ocular manifestations including cataracts and retinal hamartomas (12.7%). Five asymptomatic individuals were diagnosed through screening. Vestibular schwannomas were documented in 62 individuals (98.4%); other findings included cataracts (81.0%), skin tumors (67.7%), spinal tumors (67.4%), and meningiomas (49.2%). Usually, clinical manifestations and course were similar within families but differed among families. To assess possible heterogeneity, we assigned affected individuals to three proposed subtypes (representing mild, intermediate, and severe NF2) based on age-at-onset, presence or absence of CNS tumors other than vestibular schwannomas, and presence or absence of retinal hamartomas. Comparisons among the three subtypes for many clinical parameters demonstrated that patients in the mild subtype differed from those in the other two subtypes for most parameters, but that none of the parameters distinguished patients in the intermediate subtype from those in the severe subtype. Thus, there are likely two rather than three subtypes of NF2. Classification of patients to subtype may aid in counseling about long-term prognosis and in formulating individualized guidelines for medical surveillance. © 1994 Wiley-Liss, Inc.

1 This article is a U.S. Government work and, as such, is in the public domain in the United States of America

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Phenotypic variability in monozygotic twins with neurofibromatosis 2

Mutations in the neurofibromatosis 2 (NF2) tumor suppressor gene on chromosome 22q12 cause a clinically variable autosomal dominant syndrome characterized by bilateral vestibular schwannomas (VSs), other nervous system tumors, and early onset lenticular cataracts. We studied three pairs of monozygotic (MZ) twins with NF2, all with bilateral VSs, to separate genetic from nongenetic causes of clinical variability. The evaluation included gadolinium-enhanced high-resolution magnetic resonance imaging of the head and spine, neuro-ophthalmic examination with slit lamp, physical examination, and zygosity testing with microsatellite markers. Each MZ pair was concordant for general phenotypic subtype (mild or severe) and often for the affected organ systems. However, the MZ pairs were discordant for some features of disease presentation or progression. For example, all three pairs were discordant for presence or type of associated cranial tumors. We hypothesize that phenotypic differences between NF2 MZ twins are at least partly due to stochastic processes, such as the loss of the second NF2 allele or alleles of other genes. © 1996 Wiley-Liss, Inc.     

Molecular characterization of chromosome 22 deletions in schwannomas.

Schwannomas are tumors of the cranial, spinal, and peripheral nerve sheaths that originate from Schwann cells. Acoustic neurinomas are the most frequent cranial schwannomas. They might develop sporadically or in the context of neurofibromatosis type 2 (NF2). Loss of part or all of chromosome 22 is frequently found in acoustic schwannomas, suggesting that the NF2 gene is a tumor suppressor gene involved in the genesis of these tumors. Only a few spinal schwannomas have been molecularly characterized so far, showing that chromosome 22 loss might also occur in these tumors. Here we present the molecular analysis of chromosome 22 in 23 acoustic schwannomas and nine schwannomas of other locations (including other cranial nerves and spinal and peripheral nerves). Most of these tumors were from sporadic cases. Multiple schwannomas of various locations were analyzed in two patients with NF2. We found partial or complete monosomy for chromosome 22 in 22% of the acoustic schwannomas and 55% of the non-acoustic schwannomas. The tumors with partial monosomy included four with terminal deletions and one with a deletion of the centromeric part of the long arm of chromosome 22. The region between the beta B2-1 crystallin locus (CRYB2A) and the myoglobin locus (MB) was commonly deleted in these tumors. Our studies suggest that a schwannoma-related tumor suppressor gene within this region, which might be the NF2 gene, is involved in the development of schwannomas of various locations in the nervous system. Our studies indicate that the second hit in the genesis of different schwannomas within one (predisposed) NF2 patient occurs independently and via different mechanisms.     

Molecular genetic analysis of the NF2 gene in young patients with unilateral vestibular schwannomas

Neurofibromatosis type 2 (NF2) must be suspected in patients presenting with a unilateral vestibular schwannoma at a young age who are therefore at theoretical risk of developing bilateral disease. We identified 45 patients aged 30 years or less at the onset of symptoms of a unilateral vestibular schwannoma. Molecular genetic analysis of the NF2 gene was completed on peripheral blood samples in all 45 and on 28 tumour samples. No pathogenic NF2 mutations were identified in any of the blood samples. NF2 point mutations were identified in 21/28 (75%) tumour samples and loss of heterozygosity (LOH) in 21/28 (75%) tumour samples. Both mutational hits were identified in 18/28 (65%) tumour samples. In one multilobular tumour, one (presumably first hit) mutation was confirmed which was common to different foci of the tumour, while the second mutational event differed between foci. The molecular findings in this patient were consistent with somatic mosaicism for NF2 and the clinical diagnosis was confirmed with the presence of two meningiomas on a follow up MRI scan. A further patient developed a contralateral vestibular schwannoma on a follow up MRI scan in whom neither of the truncating mutations in the vestibular schwannoma were present in blood.

It is important when counselling patients with unilateral vestibular schwannomas to identify (1) those at risk of bilateral disease, (2) those at risk of developing other tumours, and (3) other family members at risk of developing NF2. Comparing tumour and blood DNA cannot exclude mosaicism in the index case and cannot, therefore, be used to predict those at risk of developing further tumours. However, identification of both mutations or one mutation plus LOH in the tumour and exclusion of those mutations in the blood samples of the sibs or offspring of the affected case may be sufficient to render further screening unnecessary in these relatives.

     

The neurofibromatosis type 2 gene is inactivated in schwannomas

Schwannomas are tumors arising from schwann cells surroundingperipheral nerves. Although most schwannomas are sporadic, theyare seen in approximately 90% of individuals with neuro-fibromatosistype 2 (NF2), an autosomai dominantiy inherited disease withan incidence of 1: 40000 live births. The NF2 gene has recentlybeen isolated on chromosome 22 and encodes a putative membraneorganizing protein named schwannomin. It is believed to actas a tumor suppressor gene based on the high frequency of lossof heterozygosity (LOH) on this autosome in both sporadic andNF2 associated schwannomas and meningiomas and the identificationof inactivating mutation in NF2 patients. In this study we examined61 schwannomas Including 48 sporadic schwannomas (46 of whichare vestlbular schwannomas) and 12 schwannomas obtained fromNF2 patients, for mutations in 10 of the 16 coding exons ofthe NF2 gene. Twelve inactivating mutations were Identified,8 In sporadic tumours and 4 in tumors from people with NF2.These results support the hypothesis that loss of function ofschwannomin is a frequent and fundamental event in the genesisof schwannomas.     

Phenotypic variability associated with 14 splice-site mutations in the NF2 Gene

Neurofibromatosis type 2 (NF2) is an autosomal dominant disorder caused by mutations in the NF2 gene. Patients carrying NF2 mutations are predisposed to cerebral and spinal tumors with bilateral vestibular schwannomas as the hallmark. Using single strand conformation polymorphism and temperature gradient gel electrophoresis analysis, we have screened 87 unrelated NF2 patients for mutations in the NF2 gene. In this study, we report phenotypes associated with 14 splice-site mutations carried by 14 propositi and 11 relatives. The mutations were distributed in exons 2, 3, 5, 7, 8, 14, and 15. These splice-site mutations were associated with various phenotypes, from severe to asymptomatic. Phenotypic variation was also observed within families. Mutations downstream from exon 8 resulted more often in mild phenotypes. No meningiomas were found in any of 13 affected or mutation bearing individuals from three families with splice-site mutations of exons 14 and 15. These data suggest that splice-site alteration is a relatively common cause of NF2, and that unlike other mutations the clinical outcomes of splice-site mutations in the NF2 gene are variable. These results add to the growing body of information on genotype–phenotype correlation in NF2. Am. J. Med. Genet. 77:228–233, 1998. © 1998 Wiley-Liss, Inc.     

Evaluation of NF2 and NF1 tumor suppressor genes in distinctive gastrointestinal nerve sheath tumors traditionally diagnosed as benign schwannomas: s study of 20 cases

A significant percentage of conventional schwannomas, whether sporadic or associated with neurofibromatosis 2 (NF2), show loss of heterozygosity (LOH) at NF2 and/or NF2 inactivating mutations. Similarly, a significant percentage of neurofibromas show LOH at NF1 and/or NF1 inactivating mutations. There are no molecular genetic data on gastrointestinal (GI) nerve sheath tumors traditionally diagnosed as benign schwannomas, rare neoplasms possibly derived from the schwannian elements dispersed between the smooth muscle fibers. In this study, we analyzed 1 esophageal, 16 gastric, 1 small intestinal, and 2 colonic tumors of such type. Histologically, all were spindle cell neoplasms positive for S-100 protein, vimentin, and glial fibrillary acidic protein, and negative for smooth muscle markers, KIT, CD34, neurofilament proteins, and HMB45. Focal or extensive lymphoid cuffs, often containing germinal centers, were present in most cases. None of the patients had NF2 or NF1. Chromosomes 22 and 17, particularly NF2 and NF1 loci, were analyzed for LOH in all GI tumors and for comparative purposes in 10 conventional schwannomas. LOH on 22q was seen in 40% of conventional schwannomas but in only 5% (1 of 20) of GI schwannomas. PCR amplification followed by direct sequencing of PCR products failed to identify mutations in NF2 coding sequences (exons 1-15) in 13 cases, including a case with LOH on 22q. Losses on 17q involving NF1 were seen in both GI and conventional schwannomas in 50% and 33% of analyzed tumors, respectively. LOH at NF1 might be one of the genetic features seen in peripheral nerve sheath tumors from different locations and should be interpreted with caution. However, lack of NF2 alterations strongly supports the hypothesis that GI schwannomas represent a morphologically and genetically distinct group of peripheral nerve sheath tumors that are different from conventional schwannomas.     

Transduction of wild-type merlin into human schwannoma cells decreases schwannoma cell growth and induces apoptosis.

Mutations in both alleles of the tumour suppressor gene coding for merlin/schwannomin, an ERM family protein, cause the hereditary disease neurofibromatosis type 2 (NF2). NF2 is characterized by the development of multiple nervous system tumours especially vestibular schwannomas. Efficient oncoretrovirus-mediated gene transfer of different merlin constructs was used to stably re-express wild-type merlin in primary cells derived from human schwannomas. Using two-parameter FACS analysis we show that expression of wild-type merlin in NF2 cells led to significant reduction of proliferation and G0/G1 arrest in transduced schwannoma cells. In addition, we show increased apoptosis of schwannoma cells transduced with wild-type merlin. Our findings in primary schwannoma cells from NF2 patients strongly support the hypothesis of merlin acting as a tumour suppressor and may help in understanding development of human schwannomas in NF2.     

Regional fine mapping of the β crystallin genes on chromosome 22 excludes these genes as physically linked markers for neurofibromatosis type 2

Neurofibromatosis type 2 (NF2) is a rare autosomal dominant disease, characterized by the development of bilateral vestibular schwannomas. The NF2 gene has been assigned to chromosome 22. Cataract and other eye abnormalities are frequently seen in NF2 patients. The specific association of eye abnormalities and NF2 might be caused by a genetic change on chromosome 22 that affects both the NF2 gene and a physically linked crystallin gene. In order to test this hypothesis, we regionally localized the known crystallin genes (i.e. CRYBB2, CRYBB2P1, CRYBB3, and CRYBA4) on chromosome 22. Crystallin gene-specific probes were hybridized to an extended panel of human x rodent somatic cell hybrids containing various portions of chromosome 22. It was found that all crystallin genes map to a very small region on chromosome 22 that is physically separate from the NF2 gene region by at least 160 kb of DNA. In addition, we found that the βB crystallin genes (CRYBB2, CRYBB2P1, and CRYBB3) are clustered on a 300 kb Sacll fragment and that the βA4 crystallin gene (CRYBA4) is not part of this cluster. We conclude that the ocular manifestations in many NF2 patients are probably not the primary consequence of rearrangements on chromosome 22 that involve both the NF2 gene and a nearby β crystallin gene.\\wiley5\wiley$\Wiley-JWPH\final\jwph471     

Universal absence of merlin, but not other ERM family members, in schwannomas.

NF2 (neurofibromatosis 2, encoding the merlin protein) gene mutations and chromosome 22q loss have been demonstrated in the majority of sporadic and NF2-associated schwannomas, but many schwannomas fail to demonstrate genetic evidence of biallelic NF2 gene inactivation. In addition, the role of the merlin-related ERM family members (ezrin, radixin, and moesin) remains unclear in these tumors. We therefore studied expression of NF2-encoded merlin as well as ezrin, radixin, and moesin in 22 vestibular and peripheral schwannomas that had been evaluated for NF2 mutations and chromosome 22q loss. Western blotting and immunohistochemistry with antibodies directed against the amino and carboxy termini of merlin demonstrated loss of merlin expression in all studied schwannomas, including 12 tumors lacking genetic evidence of biallelic NF2 gene inactivation. Western blotting with antibodies directed against ezrin, radixin, and moesin, however, showed expression of these proteins in all schwannomas. In addition, immunohistochemistry with an antibody to moesin revealed widespread expression in tumor and endothelial cells. These data indicate that the specific loss of merlin is universal to schwannomas and is not linked to loss of ezrin, radixin, or moesin expression.     

Growth in neurofibromatosis 1 microdeletion patients

Microdeletions of the entire NF1 gene and surrounding genomic region occur in about 5% of patients with neurofibromatosis 1 (NF1). NF1 microdeletion patients usually have more cutaneous and plexiform neurofibromas and a higher risk of developing malignant peripheral nerve sheath tumors than other people with NF1. Somatic overgrowth has also been observed in NF1 microdeletion patients, an observation that is remarkable because most NF1 patients are smaller than average for age and sex. We studied longitudinal measurements of height, weight, and head circumference in 56 patients with NF1 microdeletions and 226 NF1 patients with other kinds of mutations. Although children with NF1 microdeletions were much taller than non‐deletion NF1 patients at all ages after 2 years, the lengths of deletion and nondeletion NF1 patients were similar in early infancy. NF1 microdeletion patients tended to be heavier than other NF1 patients, but height or weight more than 3 standard deviations above the mean for age and sex was infrequent in children with NF1 microdeletions. Head circumference and age of puberty were similar in deletion and non‐deletion NF1 patients. The pattern of growth differs substantially in deletion and non‐deletion NF1 patients, but the pathogenic basis for this difference is unknown.     

Screening for germ-line mutations in the NF2 Gene

Neurofibromatosis type 2 (NF2) is a monogenic dominantly inherited disease that predisposes to the development of tumors of the nervous system, particularly meningiomas and schwannomas. The gene which, when altered, causes NF2, is localized on chromosome 22 and has recently been identified. The NF2 gene is also the site of somatic mutation in tumors, suggesting that it might have a tumor suppressor activity. We here report a screening method for the detection of point mutations in NF2 which takes advantage of denaturing gradient gel electrophoresis (DGGE). This method efficiently screens 95% of the coding sequence and 90% of intron/exon junctions. When applied to 91 unrelated NF2 patients, it enabled the identification of 32 germ-line mutations. Since mutations are found in only one third of the patients, it is expected that mutations or deletions affecting the promoter and/or intronic regions of the NF2 gene occur frequently. The characterized mutations are preferentially located within the 5° half of the gene. Most of them are predicted to lead to the synthesis of a truncated protein. A search for genotype/phenotype correlations showed that, at least in this series of patients, mild manifestations of the disease were associated with mutations which preserve the C-terminal end of the protein.     

Mutations affecting BRAF, EGFR, PIK3CA, and KRAS are not associated with sporadic vestibular schwannomas

Sporadic vestibular schwannomas are benign tumors originating from the Schwann cells of the vestibular portion of the eigth cranial nerve. An important clinical hallmark of these tumors is their variable growth rate. Investigating vestibular schwannoma biology can help to clarify this variable growth rate and may offer targets for therapeutic treatment. A recent mutation analysis on sporadic non-head and neck schwannomas detected BRAF mutations in around 20 % of tumors. BRAF is part of the mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) pathway. MAPK/ERK activation is associated with an uncontrolled cell growth. Mutated BRAF can function as a target to inhibit this pathway. Mutations in BRAF and other members of the MAPK/ERK pathway have not been investigated in sporadic vestibular schwannomas before. The goal of this study was to investigate if these mutations are present in vestibular schwannomas and whether these mutations correlate with tumor growth. Tumor specimens of 48 patients surgically treated for a sporadic vestibular schwannoma were analyzed. An allele-specific quantitative real-time PCR assay was performed to detect the 13 most frequent mutations affecting BRAF, EGFR, PIK3CA, and KRAS. Radiologically measured tumor growth was included in the analysis to identify potential relationships between these mutations and tumor progression. No activating hotspot mutations in BRAF, EGFR, PIK3CA, or KRAS were detected. The 13 most frequent mutations affecting BRAF, EGFR, PIK3CA, and KRAS are not involved in sporadic vestibular schwannoma development. These results are in contrast to the recent detection of these BRAF mutations in non-head and neck schwannomas.