Evidence for two tumour suppressor loci on chromosomal bands 1p35-36 involved in neuroblastoma: one probably imprinted, another associated with N-myc amplification

Previous reports on possible genomic imprinting of the neuroblastoma tumour suppressor gene on chromosome 1p36 have been conflicting. Here we report on the parental origin of 1p36 alleles lost in 47 neuroblastomas and on a detailed Southern blot analysis of the extent of the 1p deletions in 38 cases. The results are remarkably different for tumours with and without N-myc amplification. In the N-myc single copy tumours we show that the lost 1p36 alleles are of preferential maternal origin (16 of 17 cases) and that the commonly deleted region maps to 1p36.2-3. In contrast, all N-myc amplified neuroblastomas have larger 1p deletions, extending from the telomere to at least 1p35-36.1. These deletions are of random parental origin (18 of 30 maternal LOH). This strongly suggests that different suppressor genes on 1p are inactivated in these two types of neuroblastoma. Deletion of a more proximal suppressor gene is associated with N-myc amplification, while a distal, probably imprinted, suppressor can be deleted in N-myc single copy cases.     

Paget''s disease of bone

The protein encoded by ras and src protooncogenes are frequently activated in a constitutive state in human colorectal cancer. In this study, we investigated the effect of oncogenic p21ras and Py-MT/pp60c-src on the synthesis of syndecan-1, a membrane anchored proteoglycan playing a role in cell-matrix interaction and neoplastic growth control. To this end, we used Caco-2 cells transfected with an activated (Val-12) human Ha-ras gene or the polyoma middle T (Py-MT) oncogene, a constitutive activator of pp60c-src tyrosine kinase activity. As compared to control vector-transfected Caco-2 cells, both oncogene-transfected cells exhibited: (1) a decrease in syndecan-1 specific activity; (2) a decrease in size and sulfation of syndecan-1 ectodomain glycosaminoglycan side chains; and (3) an active heparanase specifically degrading the heparan sulfate chains. In conclusion, the tumorigenic progression induced by oncogenic p21ras or Py-MT/pp60c-src is associated with marked alterations of syndecan-1 at the post-translational level.     

MYC abrogates p53-mediated cell cycle arrest in N-(phosphonacetyl)-L-aspartate-treated cells, permitting CAD gene amplification

Genomic instability, including the ability to undergo gene amplification, is a hallmark of neoplastic cells. Similar to normal cells, "nonpermissive" REF52 cells do not develop resistance to N-(phosphonacetyl)-L-aspartate (PALA), an inhibitor of the synthesis of pyrimidine nucleotides, through amplification of cad, the target gene, but instead undergo protective, long-term, p53-dependent cell cycle arrest. Expression of exogenous MYC prevents this arrest and allows REF52 cells to proceed to mitosis when pyrimidine nucleotides are limiting. This results in DNA breaks, leading to cell death and, rarely, to cad gene amplification and PALA resistance. Pretreatment of REF52 cells with a low concentration of PALA, which slows DNA replication but does not trigger cell cycle arrest, followed by exposure to a high, selective concentration of PALA, promotes the formation of PALA-resistant cells in which the physically linked cad and endogenous N-myc genes are coamplified. The activated expression of endogenous N-myc in these pretreated PALA-resistant cells allows them to bypass the p53-mediated arrest that is characteristic of untreated REF52 cells. Our data demonstrate that two distinct events are required to form PALA-resistant REF52 cells: amplification of cad, whose product overcomes the action of the drug, and increased expression of N-myc, whose product overcomes the PALA-induced cell cycle block. These paired events occur at a detectable frequency only when the genes are physically linked, as cad and N-myc are. In untreated REF52 cells overexpressing N-MYC, the level of p53 is significantly elevated but there is no induction of p21waf1 expression or growth arrest. However, after DNA is damaged, the activated p53 executes rapid apoptosis in these REF52/N-myc cells instead of the long-term protective arrest seen in REF52 cells. The predominantly cytoplasmic localization of stabilized p53 in REF52/N-myc cells suggests that cytoplasmic retention may help to inactivate the growth-suppressing function of p53.     

Co-amplification of a novel gene, NAG, with the N-myc gene in neuroblastoma

Substantial evidence implicates amplification of the N-myc gene with aggressive tumor growth and poor outcome in neuroblastoma. However some evidence suggests that this gene alone is not the sole determinant of outcome in N-myc amplified tumors. We have searched for genes that co-amplify with N-myc in neuroblastoma by means of two-dimensional analysis of genomic restriction digests. Using this approach, we have identified and cloned a novel genomic fragment which is co-amplified with N-myc in neuroblastomas. This fragment was mapped in close vicinity to N-myc on chromosome arm 2p24. It was amplified in 5/8 N-myc amplified neuroblastoma cell lines and in 9/13 N-myc amplified tumors. Using a PCR-based approach we isolated a 4.5 kb c-DNA sequence that is partly contained in the genomic fragment. The open reading frame of the cDNA encodes a predicted protein of 1353 amino acids (aa). The homology of the predicted protein, which we designated NAG (neuroblastoma amplified gene), to a C. elegans protein of as yet unknown function, and its ubiquitous expression suggest that NAG may serve an essential function. By Northern blot analysis we showed that amplification of the cloned gene correlates with over-expression in neuroblastoma cell lines. Amplification and consequent over-expression of NAG may, therefore, contribute to the phenotype of a subset of neuroblastomas.     

Quantitation of endopeptidase 24.11 and endopeptidase 24.15 in human blood leukocytes

In order to know the involvement of multiple gene alterations in the pathogenesis of human lung cancer, we examined the genes of K-, H-ras (codons 12, 13, 61), p53(exons 5-9) and the retinoblastoma susceptibility gene (RB)(exons 20-22) using the polymerase chain reaction/single-strand conformation polymorphism method in 32 human lung cancer cell lines (5 squamous-cell carcinomas, 10 adenocarcinomas, 3 large-cell carcinomas, 14 small-cell carcinomas). In 18 non-small-cell lung cancer lines, gene alterations were found in 4 for K-ras (22%), none for H-ras (0%), 4 for p53 (22%) and none for the RB (0%) gene. In 14 small-cell lung cancer (SCLC) lines, no gene alterations were found in K-ras (0%), or H-ras (0%), but 6 were found for p53 (43%) and 3 for the RB (21%) gene. Coincident abnormalities of K-ras and p53, or K-ras and RB genes were not found in any cell lines, and those of the p53 and RB genes were found in only 2 SCLC lines. No association was observed between these three gene alterations and N-myc amplification. Although the above three genes may be involved to some extent in the pathogenesis of lung cancer, more factors are required for its development.     

Endogenous thrombopoietin levels and effect of recombinant human thrombopoietin on megakaryocyte precursors in term and preterm babies

We have isolated genomic DNA containing the human tissue inhibitor of metalloproteinases-4 gene (TIMP4) and determined the structure of the exons comprising the gene. Like other members of the TIMP family, the TIMP-4 protein is encoded by five exons. These span 6 kb of genomic DNA, so that TIMP4 is similar in size to Timp1 but considerably smaller than TIMP2 and TIMP3. The exon-intron boundaries of TIMP4 are at locations very similar to those of the other TIMP genes, demonstrating the high degree of conservation of gene structure in this family. The human and mouse TIMP-4 genes map to comparable locations in the respective genomes, localizing to human chromosome 3p25 and mouse chromosome 6.     

Ethylene responses are negatively regulated by a receptor gene family in Arabidopsis thaliana

Disseminated neuroblastoma frequently show a very poor prognosis. N-myc gene amplification, 1p deletion and lack of CD44 gene expression, are all genetic factors associated with the disease's dissemination. Human neuroblastoma xenografts in nude mice has permitted to characterize, in disseminated neuroblasts, oncogenes overexpression, inactivation of tumor suppressor genes as well as detoxifying genes activation which contributes to increase cellular resistance to chemotherapy. These genetic abnormalities permit to propose a nosology of this very aggressive pediatric solid tumor. Hopefully, this genetic classification could be of great value for new therapeutic approaches.     

N-myc suppresses major histocompatibility complex class I gene expression through down-regulation of the p50 subunit of NF-kappa B

In neuroblastoma, N-myc suppresses the expression of major histocompatibility complex (MHC) Class I antigens by reducing the binding of a nuclear factor to the enhancer-A element in the MHC Class I gene promoter. We show here that the p50 subunit of NF-kappa B is part of this complex and that expression of p50 mRNA is suppressed by N-myc. Transfection of a p50 expression vector in neuroblastoma cells that express N-myc at a high level leads to restoration of factor binding to the MHC Class I gene enhancer, restores enhancer activity and leads to re-expression of MHC Class I antigens at the cell surface. These data indicate that the p50 subunit of NF-kappa B is involved in the regulation of MHC Class I antigen expression and that N-myc down-regulates MHC Class I gene expression primarily through suppression of p50 expression.     

Localization of putative tumor suppressor loci by genome-wide allelotyping in human pancreatic endocrine tumors

Only two tumor suppressor gene loci, one on 3p25 and the MEN1 gene on 11q13, have thus far been implicated in the pathogenesis of sporadic human pancreatic endocrine tumors (PETs). A genome-wide allelotyping study of 28 human PETs was undertaken to identify other potential tumor suppressor gene loci. In addition to those on chromosomes 3p and 11q, frequent allelic deletions were identified on 3q (32%), 11p (36%), 16p (36%), and 22q (29%). Finer deletion mapping studies localized the smallest regions of common deletion to 3q27, 11p13, and 16p12.3-13.11. Potential candidate genes at these loci include WT1 (11p13), TSC2 (16p13), and NF2 (22q12), but no known tumor suppressor gene localizes to 3q27. The mean fractional allelic loss among these human PETs is 0.126, and no correlation was observed between allelic loss and clinical parameters, including age, sex, hormonal subtype, and disease stage. These findings highlight novel locations of tumor suppressor gene loci that contribute to the pathogenesis of human PETs, and several of these on 3p, 3q, and 22q are syntenic with loci on mouse chromosomes 9 and 16 that are implicated in a murine transgenic model of PETs.     

Refined chromosomal localization of the mismatch repair and hereditary nonpolyposis colorectal cancer genes hMSH2 and hMSH6

The genomic loci for the mismatch repair genes hMSH2 and hMSH6 were mapped by fluorescence in situ hybridization, analysis of radiation hybrid panel markers, and linkage analysis of syntenic chromosome regions between human and mouse. Both genes were localized to chromosome 2p21, adjacent to the luteinizing hormone/choriogonadotropin receptor gene (LHCGR; 2p21), telomeric to the D2S123 polymorphic marker, and centromeric to the calmodulin-2 gene (CALM-2; 2p22-21) and son-of-sevenless gene (SOS; 2p22-21). The genomic locations of hMSH2 and hMSH6 appears to be within 1 Mb of each other because they could not be separated by interphase fluorescence in situ hybridization. These results clarify the position of the chromosome 2 hereditary nonpolyposis colorectal cancer locus, which was originally reported to be associated with an adjacent region (chromosome 2p14-16).     

Gene and locus structure and chromosomal localization of the protease-activated receptor gene family

Protease-activate receptors (PARs) mediate activation of platelets and other cells by thrombin and other proteases. Such protease-triggered signaling events are thought to be critical for hemostasis, thrombosis, and other normal and pathological processes. We report here the structure of the mouse and human PAR3 genes as well as the organization of a PAR gene cluster encompassing the genes encoding PARs 1, 2, and 3. We also report the structure of the mouse and human PAR4 genes, which map to distinct chromosomal locations and encode a new thrombin receptor. PARs 1-4 are all encoded by genes with the same two exon structure. In each case, exon 1 encodes a signal peptide, and exon 2 encodes the mature receptor protein. These are separated by an intron of variable size. The genes encoding PARs 1-3 all map to chromosome 13D2 in mouse and chromosome 5q13 in human. In mouse, all three genes are located within 80 kilobases of each other. The PAR1 gene is located centrally and is flanked upstream by the PAR3 gene and downstream by the PAR2 gene in both species. The proximity of the PAR1 and PAR3 genes suggests the possibility that these genes might share regulatory elements. A comparison of the structures of the PAR amino acid sequences, gene structures, locus organization, and chromosomal locations suggests a working model for PAR gene evolution.     

Neuroblastoma: the result of multistep transformation?

Genetic and molecular abnormalities, in association with malignant phenotypes, have been previously demonstrated in a variety of human tumors. Although the multistep theory fits well for some cancers such as retinoblastoma and colon carcinoma, for many others it still remains to be proven. Neuroblastoma, a tumor found in pediatric patients, seems to fall into the multistep model. Nonrandom chromosome abnormalities have been found with 1p deletion, loss of heterozygosity for short arm of chromosome 1 and for chromosome 11q and 14q. Amplification of N-myc oncogene and an increased level of Ras protein have also been demonstrated. Therefore, even if it is not possible to show that these mutations happen as discrete events in their order of appearance, the multistep model seems involved in neuroblastoma development. Neuroblastoma has a peculiar aspect, however, that makes this tumor a natural model of defect of cell differentiation. In fact, there is a particular subset of metastatic tumors that show spontaneous regression. In vitro, neuroblastoma cell lines can be induced to differentiate along the neural pathway using retinoic acid. Other natural and chemical substances are also able to induce cell differentiation. During retinoic acid treatment, N-myc oncogene expression decreases and other genes are deregulated. p53 and MDR1 gene expression increases. These two different aspects, failure of cell differentiation pathway and genetic mutations, make the neuroblastoma one of the most difficult problems of modern molecular biology.     

Insulin-like growth factor II blocks apoptosis of N-myc2-expressing woodchuck liver epithelial cells

N-myc2 and insulin-like growth factor II (IGF-II) are coordinately overexpressed in the great majority of altered hepatic foci, which are the earliest precancerous lesions observed in the liver of woodchuck hepatitis virus carrier woodchucks, and these genes continue to be overexpressed in hepatocellular carcinomas (HCCs). We have investigated the function of these genes in woodchuck hepatocarcinogenesis by using a woodchuck liver epithelial cell line (WC-3). WC-3 cells react positively with a monoclonal antibody (12.8.5) against woodchuck oval cells, suggesting a lineage relationship with oval cells. Overexpression of N-myc2 in three WC-3 cell lines caused their morphological transformation and increased their growth rate and saturation density in medium containing 10% serum. Removal of serum from the medium increased cell death of the N-myc2-expressing lines, whereas cell death in control lines was minimal. The death of N-myc2-expressing WC-3 cells was accompanied by nucleosomal fragmentation of cellular DNA, and DAPI (4',6-diamidino-2-phenylindole) staining revealed condensation and fragmentation of the nuclei, suggesting that N-myc2-expressing WC-3 cells undergo apoptosis in the absence of serum. In colony regression assays, conducted in the absence of serum, control colonies were stable, while N-myc2-expressing colonies regressed to various degrees. Addition of recombinant human IGF-II to the serum-free medium blocked both cell death and colony regression in all the N-myc2-expressing lines. Therefore, coordinate overexpression of N-myc2 and IGF-II in woodchuck altered hepatic foci may allow cells which otherwise might die to survive and progress to hepatocellular carcinoma.     

The p16 (CDKN2A) gene is involved in the growth of neuroblastoma cells and its expression is associated with prognosis of neuroblastoma patients

We previously reported that loss of heterozygosity (LOH) on chromosome 9p21 correlates with poor prognosis of neuroblastoma and the p16 gene is not expressed in approximately two thirds of neuroblastoma cell lines. Here we demonstrated that p16 expression was induced by 5-aza-2-deoxycytidine treatment in cell lines with 5' CpG island methylation but not in cell lines without methylation. Furthermore, the cell cycle of neuroblastoma cell lines significantly delayed with accumulation of cells in G1 phase by transfection of a wild-type p16 expression vector. These results indicate that p16 is inactivated in part by DNA methylation and its expression is involved in the growth of neuroblastoma cells in vitro. To assess the biological and clinical significance of p16 expression in primary tumors, we undertook immunohistochemical analysis in 74 paraffin sections of neuroblastomas. p16 protein was undetectable in 45 of 74 cases (61%) and lack of p16 expression significantly correlated with poor prognosis of patients and advanced stage of the disease. There was no correlation between loss of p16 expression and N-myc amplification in these tumors. These results indicate that inactivation of the p16 gene is involved in the progression of neuroblastoma independently of N-myc amplification.     

Hot spots for molecular genetic alterations in lung cancer

Lung cancers are a heterogeneous group of tumors broadly classified as small cell or non-small cell lung cancers. In each case, numerous DNA mutations precede tumor formation, resulting in the activation of growth stimulatory genes and the loss of tumor suppressor genes. The known cellular functions of the tumor suppressor genes most commonly affected in lung cancer are reviewed herein, including the retinoblastoma (Rb) gene on chromosome 13q14, the p53 gene on 17p13, and the cyclin-dependent kinase inhibitor (CDKN2) gene on 9p21. The chromosomal locations for other potential tumor suppressor genes are on chromosomes 3p, 9p, and 11p. Candidate genes in these regions include the von Hippel-Lindau (VHL) gene at 3p25, the ubiquitin-activating enzyme homologue (UBE1L at 3p21, the genes for the dinucleoside polyphosphate hydrolase FHIT and receptor protein-tyrosine phosphatase gamma PTPRG at 3p14.2, the genes for tropomyosin beta (TM1) and a talin homologue (talin) at 9p21, and the H-ras gene at 11p15.     

The human obesity gene map: the 1997 update

An update of the human obesity gene map incorporating published results up to October 1997 is presented. Evidence from Mendelian disorders exhibiting obesity as a clinical feature; single-gene mutation rodent models; quantitative trait loci uncovered in human genome-wide scans and in crossbreeding experiments with mouse, rat, and pig models; association and case-control studies with candidate genes; and linkage studies with genes and other markers is reviewed. All chromosomal locations of the animal loci are converted into human genome locations based on syntenic relationships between the genomes. A complete listing of all of these loci reveals that all but chromosome Y of the 24 human chromosomes are represented. Some chromosomes show at least three putative loci related to obesity on both arms (1, 2, 6, 8, 11, and 20) and several on one chromosome arm only (3p, 4q, 5q, 7q, 12q, 13q, 15q, 15p, 22q, and Xq). Studies reporting negative association and linkage results are also listed, with the exception of the unlinked markers from genome-wide scans.     

Construction of a retroviral vector expressing antisense N-myc gene

In their previous studies the authors demonstrated that nerve growth factor-induced differentiation of neuroblastoma cell lines was closely related with nerve growth factor receptors and amplification of N-myc oncogenes. The authors have also successfully restored the nerve growth factor receptor expression in the cell lines which lacked expression of nerve growth factor receptors. In order to clearify the role of N-myc oncogenes during nerve growth factor-induced differentiation of neuroblastoma cell lines, a new retroviral vector was constructed to express antisense N-myc genes. This new vector contained a puromycin resistant gene, which allowed the authors to express another gene in the cell lines which had already been neomycin resistant.     

Reduction of syndecan-1 mRNA in cervical-carcinoma cells is involved with the 3' untranslated region

Syndecan-1 is a transmembrane proteoglycan expressed predominantly in epithelial cells. Studies with immunohistochemistry have shown that syndecan-1 expression is reduced in carcinoma derived from human epidermis. Here we show that syndecan-1 mRNA, which is abundant in human primary keratinocyte (HK) and HaCaT spontaneous immortalized keratinocyte, is decreased in cervical-carcinoma cell lines. Further, in relation to a long and well-conserved 3' untranslated region (3' UTR) of syndecan-1 cDNA, we examined whether 3' UTR is involved with syndecan-1-mRNA reduction in cervical-carcinoma cells. A stable transfection experiment showed that addition of the 3' UTR does not affect expression in HaCaT, but that syndecan-1 cDNA containing the 3' UTR is not expressed efficiently selectively in cervical-carcinoma cell lines. The transient assay with CAT reporter plasmids linking the 3' UTR confirmed this, and indicated that the 3' end of the 3' UTR (nt 2285-2410) is required to influence expression in cervical-carcinoma cells. Further excessive expression of syndecan-1 suppressed growth in cervical-carcinoma cells. These results demonstrate that the reduction of syndecan-1 mRNA involved with the 3' untranslated region gives growth advantage to cervical-carcinoma cells.