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.     

Neuropathology and Molecular Genetics of Neurofibromatosis 2 and Related Tumors

Neurofibromatosis 2 (NF2) is an uncommon, autosomal dominant disorder in which patients are predisposed to neoplastic and dysplastic lesions of Schwann cells (schwannomas and schwannosis), meningeal cells (meningiomas and meningioan-giomatosis) and glial cells (gliomas and glial hamar-tomas). Clinical and genetic criteria that distinguish NF2 from neurofibromatosis 1 have allowed more accurate assignment of specific pathological features to NF2. The NF2 tumor suppressor gene on chromosome 22q12 encodes a widely expressed protein, named merlin, which may link the cytoskeleton and cell membrane. Germline NF2 mutations in NF2 patients and somatic NF2 mutations in sporadic schwannomas and meningiomas have different mutational spectra, but most NF2 alterations result in a truncated, inactivated merlin protein. In NF2 patients, specific mutations do not necessarily correlate with phenotypic severity, although grossly truncating alterations may result in a more severe phenotype. In schwannomas, NF2 mutations are common and may be necessary for tumorigenesis. In meningiomas, NF2 mutations occur more commonly in fibroblastic than meningothelial subtypes, and may cluster in the first half of the gene. In addition, in meningiomas, a second, non- NF2 meningioma locus is probably also involved. Future efforts in NF2 research will be directed toward elucidating the role of merlin in the normal cell and the sequelae of its inactivation in human tumors.     

Exon scanning for mutation of the NF2 gene in schwannomas

Family studies and tumor analyses have combined to indicatethat neurofibromatosls 2 (NF2), a disorder characterized bymultiple benign tumors of the nervous system, and sporadic non-Inheritedforms of the same tumor types are both caused by inactlvationof a tumor suppressor gene located in 22q12. Recently, the geneencoding merlin, a novel member of a family of cytoskeleton-associatedproteins, was Identified as the NF2 tumor suppressor. To facilitatethe search for merlin mutations, we have defined the exon-intronboundaries for all 17 NF2 exons, including one subject to alternativesplicing. We have developed polymerase chain reaction assaysto amplify each exon from genomlc DNA, and used these assaysto perform single-strand conformation polymorphism analysisof DNA from 30 sporadic and eight NF2-derlved schwannomas, thehallmark tumor type In this disorder. Of a maximum of 60 allelesscanned, 32 showed mutations affecting expression of the merlinprotein. Thirty of these mutations are predicted to lead toa truncated protein due to frameshift, creation of a stop codon,or interference with normal splicing, while two are missensemutations. Thus, Inactivation of merlin is a common featureunderlying both Inherited and sporadic forms of schwannoma.     

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.     

Functional analysis of the relationship between the neurofibromatosis 2 tumor suppressor and its binding partner,hepatocyte growth factor-regulated tyrosine kinase substrate

Individuals with the neurofibromatosis 2 (NF2) inherited tumor predisposition syndrome are prone to the development of nervous system tumors, including schwannomas and meningiomas. The NF2 tumor suppressor protein, merlin or schwannomin, inhibits cell growth and motility as well as affects actin cytoskeleton-mediated processes. Merlin interacts with several proteins that might mediate merlin growth suppression, including hepatocyte growth factor-regulated tyrosine kinase substrate (HRS or HGS). Previously, we demonstrated that regulated overexpression of HRS in RT4 rat schwannoma cells had the same functional consequences as regulated overexpression of merlin. To determine the functional significance of this interaction, we generated a series of HRS truncation mutants and defined the regions of HRS required for merlin binding and HRS growth suppression. The HRS domain required for merlin binding was narrowed to a region (residues 470-497) containing the predicted coiled-coil domain whereas the major domain responsible for HRS growth suppression was distinct (residues 498-550). To determine whether merlin growth suppression required HRS, we demonstrated that merlin inhibited growth in HRS (+/+), but not HRS( -/-) mouse embryonic fibroblast cells. In contrast, HRS could suppress cell growth in the absence of Nf2 expression. These results suggest that merlin growth suppression requires HRS expression and that the binding of merlin to HRS may facilitate its ability to function as a tumor suppressor.     

神经纤维瘤病Ⅱ型的分子遗传研究进展

神经纤维瘤病Ⅱ型(neurofibromatosis type 2,NF2)是由于抑癌基因NF2突变而导致的常染色体显性遗传的多发肿瘤综合征。神经纤维瘤病Ⅱ型以神经系统肿瘤、皮肤肿瘤和晶体损害为临床特征。临床表现为双侧听神经瘤、脑膜瘤、脊髓肿瘤、周围神经肿瘤,白内障也很常见。NF2基因定位于染色体22q12.2,编码的蛋白质称为merlin(moesin-ezrin-radixin like protean)或schwannomin。异常的merlin影响体内的促有丝分裂途径导致肿瘤的发生。本文就其病变的分子遗传研究进展进行综述。     

Defects in neurofibromatosis 2 protein function can arise at multiple levels

Neurofibromatosis 2 (NF2) is an inherited cancer syndrome resulting from mutations in the NF2 tumor suppressor gene. Analysis of NF2 mutations has revealed some general genotype-phenotype correlations. Severe disease has been associated with mutations that produce a premature termination while more mild disease has been associated with missense mutations. Here, we provide experimental proof for these genotype-phenotype correlations by demonstrating that nonsense mutations fail to produce stable merlin protein while missense mutations result in the generation of merlin proteins defective in negative growth regulation. This inability to suppress cell growth may result from defects in the function of merlin at several levels, including failure to form an intramolecular complex. Based on these findings, we propose a model for merlin growth suppression that provides a framework for analyzing NF2 patient mutations and merlin function.      

Functional analysis of neurofibromatosis 2 (NF2) missense mutations.

Neurofibromatosis 2 (NF2) is a tumor predisposition syndrome in which affected individuals develop nervous system tumors at an increased frequency. The most common tumor in individuals with NF2 is the schwannoma, which is composed of neoplastic Schwann cells lacking NF2 gene expression. Moreover, inactivation of the NF2 gene is observed in nearly all sporadic schwannomas, suggesting that the NF2 gene is a critical growth regulator for Schwann cells. In an effort to gain insights into the function of the NF2 gene product, merlin or schwannomin, we performed a detailed functional analysis of eight naturally occurring non-conservative missense mutations in the NF2 gene. Using a regulatable expression system in rat schwannoma cells, we analyzed proliferation, actin cytoskeleton-mediated events and merlin folding. In this report, we demonstrate that mutations clustered in the predicted alpha-helical region did not impair the function of merlin whereas those in either the N- or C-terminus of the protein rendered merlin inactive as a negative growth regulator. These results suggest that the key functional domains of merlin lie within the highly conserved FERM domain and the unique C-terminus of the protein.     

NF2: the wizardry of merlin

Neurofibromatosis type II (NF2) is an autosomal dominant cancer syndrome characterized by the formation of tumors of the nervous system, particularly schwannomas and meningiomas. The NF2 gene is also implicated in the development of sporadic schwannomas and meningiomas, as well as tumor types seemingly unrelated to the NF2 disorder, such as malignant mesotheliomas. Inactivation of NF2 occurs by a "two-hit" mechanism, as proposed by Al Knudson, and the NF2 gene behaves as a classical tumor suppressor gene. The NF2 gene product, merlin, exhibits homology with the ezrin-radixin-moesin family of membrane-cytoskeleton-linking proteins. During the past several years, there has been intensive investigation aimed at elucidating the mechanisms underlying merlin's functions. In this review, we summarize the involvement of NF2 inactivation in tumorigenesis. We also discuss observations implicating merlin in cell motility and cell proliferation, with a focus on recent findings linking merlin to Rac signaling.     

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.     

Reduced apoptosis rates in human schwannomas

Schwannomas, tumors originating from Schwann cells, represent a frequent neurological tumor and can occur both in a genetic disorder called neurofibromatosis type 2 (NF2) and sporadically. In both cases the genetic background is identical as all schwannomas are caused by biallelic mutations in the tumor suppressor gene NF2 coding for merlin. Mutations in this gene have also been found to be responsible for 50% to 60% of spontaneous and 100% of the NF2 associated meningiomas. The NF2 gene product, merlin, links transmembrane proteins to the cytoskeleton and is involved in intracellular signaling processes. It has previously been shown that reexpression of wild-type merlin in primary human schwannoma cells leads to an increase in the number of apoptotic cells. Here, we report in vivo and in vitro evidence that the basal apoptosis rate of primary human schwannoma cells is reduced in comparison to that of normal Schwann cells, supporting the idea that in this benign tumor type, apoptosis has a role in tumorigenesis.     

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.     

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.     

Mutations of the neurofibromatosis type 2 gene and lack of the gene product in vestibular schwannomas

Schwannomas are common tumors of the nervous system and arefrequently found in patients with neurofibromatosis (NF) 2.Although loss of heterozygosity in NF2 tumors suggests thatthe NF2 gene functions as a tumor suppressor gene, the NF2 geneshows amino acid sequence homology to structural proteins inone of which dominantly acting mutations have been described.We performed a mutational analysis in 30 vestibular schwannomasand examined the effect of mutations on the NF2 protein. Wedetected 18 mutations in 30 vestibular schwannomas of whichseven contained loss or mutation of both NF2 alleles. Most mutationswere predicted to result in a truncated protein. Mutationalhot spots were not identified. Immunocytochemical studies usingantibodies to the NF2 protein showed complete absence of stainingin tumor Schwann cells, whereas staining was observed in normalvestibular nerve. These data indicate that loss of NF2 proteinfunction is a necessary step in schwannoma pathogenesis andthat the NF2 gene functions as a recessive tumor suppressorgene.     

Identification of recurrent regions of chromosome loss and gain in vestibular schwannomas using comparative genomic hybridisation

Background: Schwannomas are benign tumours of the nervous system that are usually sporadic but also occur in the inherited disorder neurofibromatosis type 2 (NF2). The NF2 gene is a tumour suppressor on chromosome 22. Loss of expression of the NF2 protein product, merlin, is universal in both sporadic and NF2 related schwannomas. The GTPase signalling molecules RhoA and Rac1 regulate merlin function, but to date only mutation in the NF2 gene has been identified as a causal event in schwannoma formation.

Methods: Comparative genomic hybridisation (CGH) was used to screen 76 vestibular schwannomas from 76 patients (66 sporadic and 10 NF2 related) to identify other chromosome regions that may harbour genes involved in the tumorigenesis.

Results: The most common change was loss on chromosome 22, which was more frequent in sporadic than in NF2 related tumours. Importantly, eight tumours (10%) showed gain of copy number on chromosome 9q34. Each of the two NF2 patients who had received stereotactic radiotherapy had non-chromosome 22 changes, whereas only one of eight non-irradiated NF2 patients had any chromosome changes. Three tumours had gain on 17q, which has also been reported in malignant peripheral nerve sheath tumours that are associated with neurofibromatosis type 1. Other sites that were identified in three or fewer tumours were regions on chromosomes 10, 11, 13, 16, 19, 20, X, and Y.

Conclusions: These findings should be verified using techniques that can detect smaller genetic changes, such as microarray-CGH.

     

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Background: The tumor suppressor protein merlin is thought to regulate cell proliferation and cell adhesion through interaction with protein partners. Loss of merlin is associated with Neurofibromatosis Type 2 (NF2) tumors. NHERF1 or EBP50 is a scaffolding protein that functions in apical organization of polarized cells. Merlin and NHERF1 have been shown to interact in vitro in vertebrates. We investigate how the Drosophila NHERF1 orthologue, Sip1, and Merlin function to regulate cell proliferation and adhesion. Results: We identify two conserved arginine residues (R325 and R335) in Merlin which, in addition to the FERM domain, are required for interaction with Sip1. Mutation of the arginine residues result in reduced Sip1 binding to Merlin and loss of Merlin growth suppressor function. Over‐expression of Merlin^R325A and/or Merlin^R335L in Drosophila wings result in increased proliferation in the adult wing (increase in size), which is rescued by co‐over‐expression of constitutively active Merlin protein. Reduced Sip1 binding to Merlin also produces defects in adhesion in follicle epithelial cells. Conclusions: Sip1 facilitates the activation of Merlin as a tumor suppressor protein. Thus, our work provides insight into how Merlin functions as a tumor suppressor and in adhesion and this provides insight into the mechanism of NF2 pathogenesis. Developmental Dynamics 243:1554–1570, 2014. © 2014 Wiley Periodicals, Inc.     

Regulation of cell proliferation and adhesion by means of a novel region of drosophila merlin interacting with Sip1

Background: The tumor suppressor protein merlin is thought to regulate cell proliferation and cell adhesion through interaction with protein partners. Loss of merlin is associated with Neurofibromatosis Type 2 (NF2) tumors. NHERF1 or EBP50 is a scaffolding protein that functions in apical organization of polarized cells. Merlin and NHERF1 have been shown to interact in vitro in vertebrates. We investigate how the Drosophila NHERF1 orthologue, Sip1, and Merlin function to regulate cell proliferation and adhesion. Results: We identify two conserved arginine residues (R325 and R335) in Merlin which, in addition to the FERM domain, are required for interaction with Sip1. Mutation of the arginine residues result in reduced Sip1 binding to Merlin and loss of Merlin growth suppressor function. Over‐expression of Merlin^R325A and/or Merlin^R335L in Drosophila wings result in increased proliferation in the adult wing (increase in size), which is rescued by co‐over‐expression of constitutively active Merlin protein. Reduced Sip1 binding to Merlin also produces defects in adhesion in follicle epithelial cells. Conclusions: Sip1 facilitates the activation of Merlin as a tumor suppressor protein. Thus, our work provides insight into how Merlin functions as a tumor suppressor and in adhesion and this provides insight into the mechanism of NF2 pathogenesis. Developmental Dynamics 243:1554–1570, 2014. © 2014 Wiley Periodicals, Inc.     

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.     

Analysis of the neurofibromatosis 2 gene reveals molecular variants of meningioma.

There is evidence from cytogenetic and loss of heterozygosity studies for the involvement of a tumor suppressor gene on chromosome 22 in the formation of meningiomas. Recently, the NF2 gene, which causes neurofibromatosis type 2 and which is located in the affected region on chromosome 22, has been identified. A previous study on 8 of the 17 exons of the NF2 gene described mutations in 16% of meningiomas. We have analyzed the entire coding region of the NF2 gene in 70 sporadic meningiomas and identified 43 mutations in 41 patients. These resulted predominantly in immediate truncation, splicing abnormalities, or an altered reading frame of the predicted protein product. Although there was no evidence for distinct hotspots, all mutations occurred in the first 13 exons, the region of homology with the filopodial proteins moesin, ezrin, and radixin. The association of loss of heterozygosity on chromosome 22 with mutations in the NF2 gene was significant. These data suggest that NF2 represents the meningioma locus on chromosome 22. NF2 mutations occurred significantly more frequently in fibroblastic meningioma (70%) and transitional meningioma (83%) than in meningiothelial meningioma (25%), thus indicating a differential molecular pathogenesis of these meningioma variants.     

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.