Roberta L. Beauchamp

Analysis of both TSC1 and TSC2 for germline mutations in 126 unrelated patients with tuberous sclerosis

Tuberous sclerosis complex (TSC) is an autosomal dominant disorder characterized by the development of multiple hamartomas involving many organs. About two‐thirds of the cases are sporadic and appear to represent new mutations. With the cloning of two causative genes, TSC1 and TSC2 it is now possible to analyze both genes in TSC patients and identify germline mutations. Here we report the mutational analysis of the entire coding region of both TSC1 and TSC2 genes in 126 unrelated TSC patients, including 40 familial and 86 sporadic cases, by single‐stranded conformational polymorphism (SSCP) analysis followed by direct sequencing. Mutations were identified in a total of 74 (59%) cases, including 16 TSC1 mutations (5 sporadic and 11 familial cases) and 58 TSC2 mutations (42 sporadic and 16 familial cases). Overall, significantly more TSC2 mutations were found in our population, with a relatively equal distribution of mutations between TSC1 and TSC2 among the familial cases, but a marked underrepresentation of TSC1 mutations among the sporadic cases (P = 0.0035, Fishers exact test). All TSC1 mutations were predicted to be protein truncating. However, in TSC2 13 missense mutations were found, five clustering in the GAP‐related domain and three others occurring in exon 16. Upon comparison of clinical manifestations, including the incidence of intellectual disability, we could not find any observable differences between TSC1 and TSC2 patients. Our data help define the distribution and spectrum of mutations associated with the TSC loci and will be useful for both understanding the function of these genes as well as genetic counseling in patients with the disease. Hum Mutat 14:412–422, 1999.

A NHERF binding site links the betaPDGFR to the cytoskeleton and regulates cell spreading and migration

The Na+/H+ exchanger regulatory factor, NHERF, is a multifunctional adapter protein involved in a wide range of physiological activities. NHERF associates with merlin and the ezrin/radixin/moesin (MERM) family of membrane-actin cytoskeletal linker proteins through its C-terminus and is capable of interacting via its PDZ1 domain to the βPDGF receptor (βPDGFR). Thus, NHERF, potentially links the βPDGFR to the actin cytoskeleton through its interaction with MERM proteins. In the present study, we have examined whether abolishing the interaction of βPDGFR with NHERF results in actin cytoskeletal rearrangements. We have stably expressed a wild-type βPDGFR, a mutant βPDGFR (L1106A) that is incapable of interacting with NHERF, as well as a kinase defective mutant receptor (K634R), in PDGFR-deficient mouse embryonic fibroblasts. Our observations indicate that cells expressing βPDGFR (L1106A) were impaired in their ability to spread and migrate on fibronectin compared with wild-type and K634R cells. L1106A mutant cells also revealed an increased number of focal adhesions, a condensed F-actin ring at the cell periphery and a decrease in total focal adhesion kinase (FAK) tyrosine phosphorylation. Further, we show that NHERF and MERM proteins could act as intermediary bridging proteins between βPDGFR and FAK. Thus, the interaction of βPDGFR with NHERF may provide an essential link between the cell membrane and the cortical actin cytoskeleton independent of receptor activity.

p53 gene analysis of ovarian borderline tumors and stage I carcinomas

Mutations of the p53 gene are common in human ovarian carcinomas; however, their role in the early development of ovarian cancer is unclear. Twelve ovarian borderline tumors (BTs; eight of them p53 immunopositive) and 10 stage I carcinomas (four of them p53 immunopositive) were studied for genetic alterations in the p53 gene. The study was based on single-strand conformation polymorphism (SSCP) analysis and DNA sequencing of exons 2 through 11 of the p53 gene using DNA preparations from microdissected tumors. Mutations were found in 40% of the carcinomas (including a borderline component adjacent to carcinoma in one lesion) but in none of the pure BTs. These findings suggest that p53 mutations may not be commonly associated with the borderline phenotype of ovarian epithelial tumors but may occur during malignant transformation.

Regulation of mTOR Complex 2 Signaling in Neurofibromatosis 2-Deficient Target Cell Types

Inactivating mutations in the neurofibromatosis 2 (NF2) tumor suppressor gene results in the development of schwannomas and meningiomas. Using NF2-deficient meningioma cells and tumors, together with the normal cellular counterparts that meningiomas derive, arachnoid cells, we identified merlin as a novel negative regulator of mTOR complex 1 (mTORC1). We now show that merlin positively regulates the kinase activity of mTORC2, a second functionally distinct mTOR complex, and that downstream phosphorylation of mTORC2 substrates, including Akt, is reduced upon acute merlin deficiency in cells. In response to general growth factor stimulation, Akt signaling is attenuated in merlin RNA interference-suppressed human arachnoid and Schwann cells by mechanisms mediated by hyperactive mTORC1 and impaired mTORC2. Moreover, Akt signaling is impaired differentially in a cell type–dependent manner in response to distinct growth factor stimuli. However, contrary to activation of mTORC1, the attenuated mTORC2 signaling profiles exhibited by normal arachnoid and Schwann cells in response to acute merlin loss were not consistently reflected in NF2-deficient meningiomas and schwannomas, suggesting additional genetic events may have been acquired in tumors after initial merlin loss. This finding contrasts with another benign tumor disorder, tuberous sclerosis complex, which exhibits attenuated mTORC2 signaling profiles in both cells and tumors. Finally, we examined rapamycin, as well as the mTOR kinase inhibitor, Torin1, targeting both mTOR complexes to identify the most efficacious class of compounds for blocking mTOR-mediated signaling and proliferation in merlin-deficient meningioma cells. These studies may ultimately aid in the development of suitable therapeutics for NF2-associated tumors. Mol Cancer Res; 10(5); 649–59. ©2012 AACR.

Exon scanning of the entire TSC2 gene for germline mutations in 40 unrelated patients with tuberous sclerosis.

Tuberous sclerosis complex (TSC) is a dominantly inherited multisystem disorder resulting in the development of hamartomatous growths in many organs. Genetic heterogeneity has been demonstrated linking the familial cases to either TSC1 at 9q34.3, or TSC2 at 16p13.3. About two‐thirds of the TSC cases are sporadic and appear to represent new mutations. While both genes are thought to account for all familial cases, with each representing approximately 50% of the mutations, the proportion of sporadic cases with mutations in TSC1 and TSC2 is yet to be determined. We have examined the entire coding sequence of the TSC2 gene in 20 familial and 20 sporadic cases and identified a total of twenty‐one mutations representing 50% and 55% of familial and sporadic cases respectively. Our rate of mutation detection is significantly higher than other published reports. Twenty out of 21 mutations are novel and include 6 missense, 6 nonsense, 5 frameshifts, 2 splice alterations, a 34 bp deletion resulting in abnormal splicing, and an 18 bp deletion which maintains the reading frame. The mutations are distributed throughout the coding sequence with no specific hot spots. There is no apparent correlation between mutation type and clinical severity of the disease. Our results document that at least 50% of sporadic cases arise from mutations in the TSC2 gene. The location of the mutations described here, particularly the missense events, should be valuable for further functional analysis of this tumor suppressor protein. Hum Mutat 12:408–416, 1998.

Expression of NF2-encoded Merlin and Related ERM Family Proteins in the Human Central Nervous System

Germline mutations of the neurofibromatosis 2 (NF2) gene are associated with an increased incidence of gliomas and glial harmartomas, suggesting a role for the NF2-encoded protein, merlin, in glial growth control. Using monoclonal and polyclonal anti-merlin antibodies for Western blotting and immunohistochemistry, we evaluated the cellular pattern of merlin expression in the normal human central nervous system (CNS), reactive gliosis; and NF2-associated glial hamartomas. In the normal CNS, merlin is widely expressed in coarse cytoplasmic granules in both glia and neurons, with less pronounced expression in other cells. Merlin is also expressed in reactive astrocytes and in the astrocytes of NF2-associated glial hamartomas. In reactive astrocytes, however, merlin is also present at the cell membrane and in cellular processes, suggesting redistribution of the protein in activated cells. Merlin is structurally related to ezrin, radixin and moesin, which are also expressed in the CNS, as demonstrated by Western blotting. The pattern of merlin expression, however, is distinct from that of ezrin, which has been previously described, and that of moesin, in which immunohistochemistry with an anti-moesin antibody showed expression in endothelial cells, glia and neurons in a membranous or diffuse cytoplasmic pattern. These findings imply that merlin has widespread and specific functions in the human central nervous system.

Ki-ras and p53 Mutations in Pancreatic Ductal Adenocarcinoma

Pancreatic adenocarcinoma involves activation of the Ki-ras oncogene, inactivation of the p53 tumor suppressor gene, and dysregulation of growth factors and perhaps metastasis genes. Ki-ras oncogene point mutations are known to be involved in pancreatic oncogenesis. The p53 tumor suppressor gene product plays a critical role in cell cycle regulation and also functions as a nuclear transcription factor. Point mutations in the p53 gene have been observed in a variety of malignancies. We determined the frequency of p53 protein overexpression and p53 point mutations in the conserved and nonconserved domains in pancreatic cancers as well as the coincidence of Ki-ras mutation in pancreatic ductal adenocarcinoma. Genomic DNA was isolated from 20 frozen pancreatic adenocarcinomas (14 primary, six metastases) along with six specimens of control pancreatic tissue and screened by single-strand conformation polymorphism (SSCP) analysis followed by direct genomic sequencing of SSCP variants. SSCP analysis was accomplished by incorporating 32P-dCTP in 12 separate polymerase chain (PCR) amplifications covering the p53 coding exons 2–11. All mobility shifts on SSCP were subjected to direct genomic sequencing by the modified dideoxy method. Immuno-peroxidase (IP) staining was also done with a p53 monoclonal antibody. Ki-ras codon 12 mutational analysis was accomplished by incorporating 32P-dCTP by polymerase chain reaction amplification utilizing mismatched primers, which create a BstN1 restriction endonuclease site spanning codon 12; the products were digested by BstN1 Polyacrylamide gel electrophoresis allowed distinction between wild-type and mutant Ki-ras. p53 mutations were found in 5 of 20 pancreatic cancers (three of 14 primary tumors, two of six metastatic tumors). Point mutations were observed in three of 14 primary tumors, and one of six metastases, while a 2-base pair duplication resulting in a premature stop codon in exon 5 was found in one metastatic tumor. Point mutations were noted in conserved domains (exons 4, 5, 8) and in the nonconserved domain (exon 10). IP staining revealed that eight of 14 of the primary tumors and two of six metastases exhibited moderate to strong nuclear staining (>30%), while no nuclear staining was evident in the controls. Ki-ras codon 12 mutations were found in 14 of 20 (70%) pancreatic cancers (nine of 14 primary tumors, five of six metastatic tumors) and none of the six controls. Fifty percent of the primary pancreatic tumors demonstrated moderate to strong nuclear staining. Extensive genetic analysis demonstrated mutations in 30% of the pancreatic cancers. One cancer had a nonsense mutation not detected by IP. Seven of 19 (37%) pancreatic cancers exhibited both Ki-ras point mutation and p53 protein overexpression or mutation. Both genetic analysis and IP are required to characterize all p53 mutations in pancreatic cancer. Ki-ras codon 12 mutations and p53 protein overexpression are important steps in pancreatic oncogenesis.

TorsinB--perinuclear location and association with torsinA.

The torsins comprise a four‐member family of AAA+ chaperone proteins, including torsinA, torsinB, torp2A and torp3A in humans. Mutations in torsinA underlie early onset torsion dystonia, an autosomal dominant, neurologically based movement disorder. TorsinB is highly homologous to torsinA with its gene adjacent to that for torsinA on human chromosome 9q34. Antibodies have been generated which can distinguish torsinA and torsinB from each other, and from the torps in human and rodent cells. TorsinB (∼ MW 38 kDa), like torsinA (∼ MW 37 kDa), is an N‐glycosylated protein and both reside primarily in the endoplasmic reticulum (ER) and nuclear envelope in cultured cells. Immunoprecipitation studies in cultured cells and human brain tissue indicate that torsinA and torsinB are associated with each other in cells. Overexpression of both wild‐type torsinB and mutant torsinA lead to enrichment of the protein in the nuclear envelope and formation of large cytoplasmic inclusions. We conclude that torsinB and torsinA are localized in overlapping cell compartments within the same protein complex, and thus may carry out related functions in vivo.

Neurofibromatosis 2 gene in human colorectal cancer

Colon cancers commonly have allelic losses of chromosome 22q, which suggests the presence of a tumor suppressor gene on 22q. The candidate tumor suppressor gene on 22q is the neurofibromatosis 2 (NF2) gene. Using single strand conformation polymorphism (SSCP) analysis, we screened 24 pairs of colorectal cancer and adjacent normal mucosa, as well as 10 colon cancer cell lines from non-NF2 patients, for mutations in the coding sequence of the NF2 gene. Two SSCP variants, one in exon 14 and another one in exon 16, were detected in two of the sporadic colorectal cancers, but not in adjacent normal mucosa samples. Sequencing of these variants in one tumor detected an A-to-G transition in bp 1459 of the NF2 cDNA, resulting in the change of Ile to Val at codon 487 of merlin, the NF2 protein product. The other tumor showed a 2-bp (CT) deletion in the intronic sequence of the alternatively spliced exon 16. These results suggest that the NF2 gene is probably involved in some colorectal tumors, but is not the critical chromosome 22q tumor suppressor gene involved in colon tumorigenesis.

Mediator Subunit MED28 (Magicin) Is a Repressor of Smooth Muscle Cell Differentiation

Magicin, a protein that we isolated earlier as an interactor of the neurofibromatosis 2 protein merlin, was independently identified as MED28, a subunit of the mammalian Mediator complex. Mediator complex is an evolutionarily conserved transcriptional cofactor, which plays an essential role in positive and negative gene regulation. Distinct Mediator subunit composition is thought to contribute to gene regulation specificity based on the interaction of specific subunits with subsets of transcription factors. Here we report that down-regulation of Med28 expression in NIH3T3 cells results in a significant induction of several genes associated with smooth muscle cell (SMC) differentiation. Conversely, overexpression of MED28 represses expression of SMC genes, in concordance with our knockdown data. More importantly, multipotent mesenchymal-derived murine precursors can transdifferentiate into SMCs when Med28 is down-regulated. Our data also show that Med28 functions as a negative regulator of SMC differentiation in concert with other Mediator subunits including Med6, Med8, and Med18 within the Mediator head module. Our results provide strong evidence that MED28 may function as a scaffolding protein by maintaining the stability of a submodule within the head module and that components of this submodule act together in a gene regulatory program to suppress SMC differentiation. The results presented here demonstrate for the first time that the mammalian Mediator subunit MED28 functions as a repressor of SMC differentiation, which could have implications for disorders associated with abnormalities in SMC growth and differentiation, including atherosclerosis, asthma, hypertension, and smooth muscle tumors.