Marga Schepens

Frequent loss of 9p21 (p16(INK4A)) and other genomic imbalances in human malignant fibrous histiocytoma

To search for new recurrent genetic aberrations in malignant fibrous histiocytoma (MFH), a combination of conventional cytogenetic, comparative genomic hybridization (CGH), and Southern blot analyses was applied to a series of 34 tumors. Cytogenetic analysis revealed the presence of multiple structural and numerical aberrations, including marker chromosomes, telomeric associations, double minutes, and ring chromosomes. The most frequent genomic imbalances in this series of neoplasms as detected by CGH were gains of 1q21-q22 (69%), 17q23-qter (41%), and 20q (66%), and losses of 9p21-pter (55%), 10q (48%), 11q23-qter (55%), and 13q10-q31 (55%). Southern blot analyses with p16(INK4A) (CDKN2A; 9p21) and RB1 (13q14) probes provided clear indications for frequent deletions of these tumor suppressor genes, and as such, substantiated the CGH results. Additionally, examination of the TP53 and MDM2 genes showed frequent loss and amplification, respectively. These data indicate that genes involved in the RB1- and TP53-associated cell cycle regulatory pathways may play prominent roles in the development of human MFH.

The cancer-related protein SSX2 interacts with the human homologue of a Ras-like GTPase interactor, RAB3IP, and a novel nuclear protein, SSX2IP

The SSX gene family is composed of at least five functional and highly homologous members, SSX1 to SSX5, that are normally expressed in only the testis and thyroid. SSX1, SSX2, or SSX4 may be fused to the SYT gene as a result of the t(X;18) translocation in synovial sarcoma. In addition, the SSX1, SSX2, SSX4, and SSX5 genes were found to be aberrantly expressed in several other malignancies, including melanoma. The SSX proteins are localized in the nucleus and are diffusely distributed. In addition, they may be included in polycomb‐group nuclear bodies. Other studies have indicated that the SSX proteins may act as transcriptional repressors. As a first step toward the elucidation of the cellular signaling networks in which the SSX proteins may act, we used the yeast two‐hybrid system to identify SSX2‐interacting proteins. By doing so, two novel human proteins were detected: RAB3IP, the human homolog of an interactor of the Ras‐like GTPase Rab3A; and a novel protein, SSX2IP. RAB3IP did not interact with either SSX1, SSX3, or SSX4 in the yeast two‐hybrid system, whereas SSX2IP interacted with SSX3 but not with either SSX1 or SSX4. Further analysis of deletion mutants showed that both RAB3IP and SSX2IP interact with the N‐terminal moiety of the SSX2 protein. Immunofluorescence analyses of transfected cells revealed that the RAB3IP protein is normally localized in the cytoplasm. However, coexpression of both RAB3IP and SSX2 led to colocalization of both proteins in the nucleus. Likewise, the SSX2IP protein was found to be colocalizing with SSX2 in the nucleus. By performing glutathione‐S‐transferase pull‐down assays, we found that both RAB3IP and SSX2IP interact directly with SSX2 in vitro. These newly observed protein/protein interactions may have important implications for the mechanisms underlying normal and malignant cellular growth.

Disruption of a novel gene, DIRC3, and expression of DIRC3-HSPBAP1 fusion transcripts in a case of familial renal cell cancer and t(2;3)(q35;q21)

Previously, we identified a family with renal cell cancer and a t(2;3)(q35;q21). Positional cloning of the chromosome 3 breakpoint led to the identification of a novel gene, DIRC2, that spans this breakpoint. Here we have characterized the chromosome 2 breakpoint in detail and found that another novel gene, designated DIRC3, spans this breakpoint. In addition, we found that the first two exons of DIRC3 can splice to the second exon of HSPBAP1, a JmjC‐Hsp27 domain gene that maps proximal to the breakpoint on chromosome 3. This splice results in the formation of DIRC3‐HSPBAP1 fusion transcripts. We propose that these fusion transcripts may affect normal HSPBAP1 function and concomitant chromatin remodeling and/or stress response signals within t(2;3)(q35;q21)‐positive kidney cells. As a consequence, familial renal cell cancer may develop.

Heterozygous germline mutations in A2ML1 are associated with a disorder clinically related to Noonan syndrome

Noonan syndrome (NS) is a developmental disorder characterized by short stature, facial dysmorphisms and congenital heart defects. To date, all mutations known to cause NS are dominant, activating mutations in signal transducers of the RAS/mitogen-activated protein kinase (MAPK) pathway. In 25% of cases, however, the genetic cause of NS remains elusive, suggesting that factors other than those involved in the canonical RAS/MAPK pathway may also have a role. Here, we used family-based whole exome sequencing of a case–parent trio and identified a de novo mutation, p.(Arg802His), in A2ML1, which encodes the secreted protease inhibitor α-2-macroglobulin (A2M)-like-1. Subsequent resequencing of A2ML1 in 155 cases with a clinical diagnosis of NS led to the identification of additional mutations in two families, p.(Arg802Leu) and p.(Arg592Leu). Functional characterization of these human A2ML1 mutations in zebrafish showed NS-like developmental defects, including a broad head, blunted face and cardiac malformations. Using the crystal structure of A2M, which is highly homologous to A2ML1, we identified the intramolecular interaction partner of p.Arg802. Mutation of this residue, p.Glu906, induced similar developmental defects in zebrafish, strengthening our conclusion that mutations in A2ML1 cause a disorder clinically related to NS. This is the first report of the involvement of an extracellular factor in a disorder clinically related to RASopathies, providing potential new leads for better understanding of the molecular basis of this family of developmental diseases.

Prenatal diagnostic testing of the Noonan syndrome genes in fetuses with abnormal ultrasound findings.

In recent studies on prenatal testing for Noonan syndrome (NS) in fetuses with an increased nuchal translucency (NT) and a normal karyotype, mutations have been reported in 9–16% of cases. In this study, DNA of 75 fetuses with a normal karyotype and abnormal ultrasound findings was tested in a diagnostic setting for mutations in (a subset of) the four most commonly mutated NS genes. A de novo mutation in either PTPN11, KRAS or RAF1 was detected in 13 fetuses (17.3%). Ultrasound findings were increased NT, distended jugular lymphatic sacs (JLS), hydrothorax, renal anomalies, polyhydramnios, cystic hygroma, cardiac anomalies, hydrops fetalis and ascites. A second group, consisting of anonymized DNA of 60 other fetuses with sonographic abnormalities, was tested for mutations in 10 NS genes. In this group, five possible pathogenic mutations have been identified (in PTPN11 (n=2), RAF1, BRAF and MAP2K1 (each n=1)). We recommend prenatal testing of PTPN11, KRAS and RAF1 in pregnancies with an increased NT and at least one of the following additional features: polyhydramnios, hydrops fetalis, renal anomalies, distended JLS, hydrothorax, cardiac anomalies, cystic hygroma and ascites. If possible, mutation analysis of BRAF and MAP2K1 should be considered.

A novel chromosomal region of allelic loss, 4q32-q34, in human osteosarcomas revealed by representational difference analysis.

Representational difference analysis (RDA) of a human osteosarcoma xenograft resulted in the isolation of four tumor‐associated homozygously deleted DNA fragments, all originating from chromosome 4, region q32–q34. Southern blot analysis using the RDA fragments and interphase FISH analysis using PACs corresponding to these RDA fragments revealed allelic loss of the 4q32–q34 region in 17 of 27 (63%) osteosarcomas tested. These results suggest the involvement of tumor suppressor gene(s) within this chromosomal region in osteosarcoma development. The RDA fragments and corresponding PAC clones will be instrumental in the isolation of such gene(s). Genes Chromosomes Cancer 26:115–124, 1999.

A novel case of infantile sacral teratoma and a constitutional t(12;15)(q13;q25) pat.

Cytogenetic analysis of peripheral lymphocytes of an infantile patient with a sacral teratoma revealed a constitutional translocation (12;15)(q13;q25) pat. The same translocation was found in four additional relatives. Loss of heterozygosity analysis of the patients tumor material showed retention of both translocation-derived chromosomes. Since allelic loss in the 12q13 region has been observed in germ cell tumors, we hypothesize that disregulation of genes located at or near the 12q13 breakpoint may be related to the development of this sacral teratoma. As a first step towards the identification of these genes, a 12q13 genomic contig that spans the breakpoint has been constructed.

Characterization of a novel transcript of the EHMT1 gene reveals important diagnostic implications for Kleefstra syndrome

The core phenotype of Kleefstra syndrome (KS) is characterized by intellectual disability, childhood hypotonia, and a characteristic facial appearance. This can be caused by either submicroscopic 9q34 deletions or loss of function mutations of the EHMT1 gene. Remarkably, in three patients with a clinical suspicion of KS, molecular cytogenetic analysis revealed an interstitial 9q34 microdeletion proximal to the coding region of the EHMT1 gene based on the NM_ 024757.3 transcript. Because we found a mono‐allelic EHMT1 transcript suggestive for haploinsufficiency of EHMT1 in two of these patients tested, we hypothesized that a deletion of regulatory elements or so far unknown coding sequences in the 5′ region of the EHMT1 gene, might result in a phenotype compatible with KS. We further characterized the molecular content of deletions proximal to the transcript NM_ 024757.3 and confirmed presence of a novel predicted open reading frame comprising 27 coding exons (NM_ 024757.4). Further analysis showed that all three deletions included the presumed novel first exon of the EHMT1 gene. Subsequent testing of 75 individuals without previously detectable EHMT1 aberrations showed one additional case with a deletion comprising only this 5′ part of the gene. These results have important implications for the genetic screening of KS and for studies of the functional significance of EHMT1.Hum Mutat 32:853–859, 2011.

Assignment1 of the PTP-SL/PTPBR7 gene (Ptprr/PTPRR) to mouse chromosome region 8A2 by in situ hybridization

Reversible tyrosine phosphorylation is an important mechanism in the development and function of the central nervous system. Previously we reported the cloning of the brain-specific protein tyrosine phosphatase PTP-SL (Hendriks et al., 1995) which appeared identical to the 535 carboxyl-terminal amino acids of PTPBR7 (Ogata et al., 1995). We could demonstrate that both isoforms originate from the same single-copy gene through the use of alternative promoters (van den Maagdenberg et al., submitted), in line with recent observations on the rat orthologues of PTP-SL and PTPBR7, PCPTP1-Ce and PCPTP1 (Watenabe et al., 1998). Here we report the assignment of the PTP-SL/PTPBR7 gene (Ptprr, protein tyrosine phosphatase, receptor type, R) to its mouse chromosome region and discuss its candidacy for the nr and mnd neurological mutations in mouse. Materials and methods