Integrated genomic and functional analyses reveal glyoxalase I as a novel metabolic oncogene in human gastric cancer.

Chromosomal abnormalities are good guideposts when hunting for cancer-related genes. We analyzed copy number alterations of 163 primary gastric cancers using array-based comparative genomic hybridization and simultaneously performed a genome-wide integrated analysis of copy number and gene expression using microarray data for 58 tumors. We showed that chromosome 6p21 amplification frequently occurred secondary to ERBB2 amplification, was associated with poorer prognosis and caused overexpression of half of the genes mapped. A comprehensive small interfering RNA knockdown of 58 genes overexpressed in tumors identified 32 genes that reduced gastric cancer cell growth. Enforced expression of 16 of these genes promoted cell growth in vitro, and six genes showing more than two-fold activity conferred tumor-forming ability in vivo. Among these six candidates, GLO1, encoding a detoxifying enzyme glyoxalase I (GLO1), exhibited the strongest tumor-forming activity. Coexpression of other genes with GLO1 enhanced growth-stimulating activity. A GLO1 inhibitor, S-p-bromobenzyl glutathione cyclopentyl diester, inhibited the growth of two-thirds of 24 gastric cancer cell lines examined. The efficacy was found to be associated with the mRNA expression ratio of GLO1 to GLO2, encoding glyoxalase II (GLO2), another constituent of the glyoxalase system. GLO1 downregulation affected cell growth through inactivating central carbon metabolism and reduced the transcriptional activities of nuclear factor kappa B and activator protein-1. Our study demonstrates that GLO1 is a novel metabolic oncogene of the 6p21 amplicon, which promotes tumor growth and aberrant transcriptional signals via regulating cellular metabolic activities for energy production and could be a potential therapeutic target in gastric cancer.

DEK oncoprotein regulates transcriptional modifiers and sustains tumor initiation activity in high-grade neuroendocrine carcinoma of the lung.

Lung cancer shows diverse histological subtypes. Large-cell neuroendocrine cell carcinoma and small-cell lung carcinoma show similar histological features and clinical behaviors, and can be classified as high-grade neuroendocrine carcinoma (HGNEC) of the lung. Here we elucidated the molecular classification of pulmonary endocrine tumors by copy-number profiling. We compared alterations of copy number with the clinical outcome of HGNEC and identified a chromosomal gain of the DEK oncogene locus (6p22.3) that was significantly associated with poor prognosis. We further confirmed that DEK overexpression was associated with poor prognosis in a larger set of HGNEC. Downregulation of DEK by small hairpin RNA led to a marked reduction of in vitro colony formation, in vivo tumorigenicity and chemo-resistance, and was associated with loss of lung cancer stem cell markers. Gene expression profiling revealed that DEK downregulation was associated with altered expression of transcriptional regulators, which specifically include known targets of interchromosomal translocations in hematopoietic tumors, and knockdown of these epigenetic modifiers affected colony formation activity. Our study showed that DEK overexpression, partly through an increase in its gene dose, mediates the activity of global transcriptional regulators and is associated with tumor initiation activity and poor prognosis in HGNEC.

A BAC-based STS-content map spanning a 35-Mb region of human chromosome 1p35-p36.

We have devised a mapping method for rapid assembly and ordering of bacterial artificial chromosome (BAC) clones on a radiation hybrid (RH) panel, using sequence-tagged sites (STSs) and PCR. The protocol consists of two rounds of two-dimensional screening from a limited number of BACs to correspond each to an STS. In the first round, STSs are assembled in the RH bins and ordered according to PCR signals derived from 384-well microtiter plates (MTPs) in which BAC clones have been arrayed. In the second round, individual BAC clones are isolated from the MTPs to build a contig. We applied this method to a 35-Mb region spanning human chromosome 1p35-p36 and assembled 1366 BACs in 11 contigs, the longest being about 20 Mb. The working draft sequences of the human genome have been integrated into the contigs to validate the accuracy.

Fusion of MOZ and p300 histone acetyltransferases in acute monocytic leukemia with a t(8;22)(p11;q13) chromosome translocation.

Histone acetyltransferase p300 functions as a transcriptional co-activator which interacts with a number of transcription factors. Monocytic leukemia zinc finger protein (MOZ) has histone acetyltransferase activity. We report the fusion of the MOZ gene to the p300 gene in acute myeloid leukemia with translocation t(8;22)(p11;q13). FISH and Southern blot analyses showed the rearrangement of the MOZ and p300 genes. We determined the genomic structure of the p300 and the MOZ genes and the breakpoints of the translocation. Analysis of fusion transcripts indicated that the zinc finger and acetyltransferase domains of MOZ are fused to a largely intact p300. These results suggest that MOZ-p300, which has two acetyltransferase domains, could be involved in leukemogenesis through aberrant regulation of histone acetylation.

Detection of t(I 1; 18) in MALT-type lymphoma with dual-color fluorescence in situ hybridization and reverse transcriptase-polymerase chain reaction analysis.

t(11:8) is a recurrent chromosomal abnormality observed in mucosa-associated lymphoid tissue (MALT)-type lymphoma. API2 and MLT genes have been implicated. The authors devised a dual-color interphase fluorescence in situ hybridization (FISH) system to detect splitting of 11q22 and its fusion with 18q21. Subjects were 44 cases of extranodal lymphoma and cases of primary macroglobulinemia. Whenever RNA was available, reverse transcriptase-polymerase chain reaction followed by sequence analysis was performed. Positive cases by dual-color FISH analysis were restricted to MALT-type lymphoma and one case of primary macroglobulinemia. Among 24 cases of MALT-type lymphoma, 14 (58%) (4 gastric, 5 pulmonary, 3 orbital, 1 salivary, and 1 thyroid lymphomas) had splitting of the 11q22 region probes and fusion of signals suggesting the translocation of chromosome 11 and 18. Reverse transcriptase-polymerase chain reaction analysis showed the API2/MLT gene fusion in 9 of 10 cases. Sequence analyses showed three different modes of involvement of the MLT gene, whereas the breakpoint at API2 was the same. Monoclonal component of serum immunoglobulin M was observed in 3 of 14 positive cases for the translocation. Direct visualization using dual-color FISH on samples serves as a molecular tool for management of MALT-type lymphoma with API2/MLT gene fusion.

A 2-Mb sequence-ready contig map and a novel immunoglobulin superfamily gene IGSF4 in the LOH region of chromosome 11q23.2.

Human chromosome 11q23.2 has been proposed to contain a tumor suppressor gene(s) whose deletion has been associated with cancer of the lung and breast and with neuroblastoma. To analyze the genomic structure and to isolate a candidate tumor suppressor gene from this region, we constructed a 2-Mb sequence-ready contig map using bacteriophage P1 (P1), bacterial artificial chromosome (BAC), and P1-derived artificial chromosome (PAC). The map comprises a contig of 24 overlapping P1, BAC, and PAC clones. To isolate gene fragments from the region, we performed direct cDNA library screening, exon trapping, EST mapping, and genomic sequencing using the P1, BAC, and PAC clones. Sequence analysis of 5 clones, which spans 23% (458,738 bp) of the region, and extensive gene scanning along the entire region revealed that the region is extraordinarily scarce in genes, but we identified one ubiquitously expressed novel gene and one testis-specific gene fragment. The novel gene, which we call IGSF4 (immunoglobulin superfamily 4), is transcribed into a 1.6- or 4.4-kb RNA encoding a 442-amino-acid protein. It shares strong homology with mouse IGSF-B12 and cell adhesion molecules NCAM1 and NCAM2 within their Ig-like C2-type domains. The IGSF4 gene, a novel gene that is shown to be located in the common loss of heterozygosity region, possesses a number of interesting features and may be good candidate for a tumor suppressor gene.

Consistent detection of CALM-AF10 chimaeric transcripts in haematological malignancies with t(10;11)(p13;q14) and identification of novel transcripts.

The t(10;11)(p13-14;q14-21) is a rare but recurring translocation associated with acute lymphoblastic leukaemia (ALL) and acute myeloid leukaemia (AML). Recently the CALM gene was cloned from the t(10;11) breakpoint of U937 and fused to AF10, a putative transcription factor, which had been identified as one of the fusion partners of the MLL gene. In order to define the involvement of these genes in primary leukaemias and cell lines with t(10;11), we analysed the expression of fusion transcripts by reverse transcriptase-polymerase chain reaction (RT-PCR) in five patient samples including ALL, AML and lymphoblastic lymphoma, and three monocytic cell lines (P31/Fujioka, KP-Mo-TS and U937). The CALM-AF10 fusion transcript was detected in all samples; however, the AF10-CALM fusion was not detected in two patient samples and one cell line. In RT-PCR analysis there were six isoforms of the CALM-AF10 fusion transcripts and five of AF10-CALM fusion transcripts. We also detected novel transcripts in U937. Sequence analysis revealed that all these isoforms had in-frame junctions and that some of them resulted from alternative splicing at different exons of CALM and others from different breakpoints at CALM and/or AF10. There were at least two different breakpoints of CALM and three of AF10 gene. Our results suggest that the CALM-AF10 fusion gene is a constant feature and is involved in the pathogenesis of haematological malignancies with t(10;11)(p13-14;q14-21), showing various and often multilineage phenotypes. Thus, t(10;11) needs to be investigated by RT-PCR for identification of the genes involved.

The isolation of CpG islands from human chromosomal regions 11q13 and Xp22 by segregation of partlymelted molecules.

We isolated fragments containing parts of CpG islands from human chromosomal regions chosen for expected differences in gene density by segregation of partly melted molecules. Restriction fragments of P1 bacteriophage clones covering a region of 11q13 and those of cosmid clones derived from Xp22 were recovered from bands in denaturing gradient gels that were retained following prolonged exposure to electric field. Forty-five independent fragments derived from 11q13 and five from Xp22 were isolated. Nucleotide sequence analysis revealed that 11 of the 45 fragments from 11q13 contained CpG islands including four derived from known genes in 11q13. None of the five fragments derived from Xp22 resembled CpG islands. The number of CpG island fragments obtained was consistent with the expectation based on the number of Not I restriction endonuclease sites present at these regions. Adjustment of parameters in our quasi-theoretical approach to the rate of fragment dissociation improves the discrimination between retention and non-retention. The results support probable identification of CpG island fragments by their reduced rate of strand dissociation when retarded in a denaturing gradient gel.

Pseudoachondroplasia with de novo deletion [del(11)(q21q22.2)].

Pseudoachondroplasia (PSACH) is a relatively common osteochondrodysplasia characterized clinically by short-limbed short stature with normal face, and radiographically by platyspondyly and dysplasias of epiphyses and metaphyses of the tubular bones. Recently, mutation of cartilage oligomeric matrix protein has been identified in PSACH. However, clinical variability and genetic heterogeneity have been reported in PSACH, indicating a possible existence of a second PSACH gene. Here, we report on a patient with a typical severe form of PSACH who had a de novo interstitial deletion in the long arm of chromosome 11 [del(11)(q21q22.2)]. The size of the deletion was estimated at 0.8-7.3 Mb using fluorescent in situ hybridization (FISH). This deletion may contain or disrupt a second PSACH locus.

The partner gene of AML1 in t(16;21) myeloid malignancies is a novel member of the MTG8(ETO) family.

The t(16;21)(q24;q22) translocation is a rare but recurrent chromosomal abnormality associated with therapy-related myeloid malignancies and a variant of the t(8;21) translocation in which the AML1 gene on chromosome 21 is rearranged. Here we report the molecular definition of this chromosomal aberration in four patients. We cloned cDNAs from the leukemic cells of a patient carrying t(16;21) by the reverse transcription polymerase chain reaction using an AML1-specific primer. The structural analysis of the cDNAs showed that AML1 was fused to a novel gene named MTG16 (Myeloid Translocation Gene on chromosome 16) which shows high homology to MTG8 (ETO/CDR) and MTGR1. Northern blot analysis using MTG16 probes mainly detected 4.5 kb and 4.2 kb RNAs, along with several other minor RNAs in various human tissues. As in t(8;21), the t(16;21) breakpoints occurred between the exons 5 and 6 of AML1, and between the exons 1 and 2 or the exons 3 and 4 of MTG16. The two genes are fused in-frame, resulting in the characteristic chimeric transcripts of this translocation. Although the reciprocal chimeric product, MTG16-AML1, was also detected in one of the t(16;21) patients, its protein product was predicted to be truncated. Thus, the AML1-MTG16 gene fusion in t(16;21) leukemia results in the production of a protein that is very similar to the AML1-MTG8 chimeric protein.

Hematologic malignancies with the t(10;11) (p13;q21) have the same molecular event and a variety of morphologic or immunologic phenotypes.

Previous studies described the t(10;11)(p13-14;q14-21) as a recurring translocation associated with T-cell acute lymphoblastic leukemia (ALL). This translocation has also been reported in monocytic leukemia or ALL with a very early pre-B phenotype. However, whether these cytogenetically similar translocations involve the same molecular breakpoint is unknown. Using fluorescence in situ hybridization (FISH) with a series of probes on 11q, we mapped the 11q breakpoint of the U937 cell line, which was derived from a patient with diffuse histiocytic lymphoma and was shown by FISH to have the t(10;11)(p13-14;q14-21). Subsequently, we identified a yeast artificial chromosome (YAC) clone, y960g8, that included the breakpoint on 11q. From this YAC, we isolated a PI clone, P91B1, that was split by the 10;11 translocation. We studied four patients with a t(10;11), one of whom had acute monocytic leukemia (AMoL), one had acute lymphoblastic leukemia (ALL), one had lymphoblastic lymphoma (LBL), and one had granulocytic sarcoma, by using FISH with y960g8 and P91B1. Y960g8 and P91B1 were split by the translocation in each patient. We showed that P91B1 included a recently identified gene, CALM (Clathrin Assembly Lymphoid Myeloid leukemia gene), and that AF10 was also rearranged in each patient by FISH when we used y807b3, which contains the AF10 gene. These findings indicate that hematologic malignant diseases with fusion of AF10 and CALM show various morphologic and immunologic phenotypes, suggesting that this fusion occurs in multipotential or very early precursor cells.

A 3-Mb sequence-ready contig map encompassing the multiple disease gene cluster on chromosome 11q13.1-q13.3.

Despite the presence of several human disease genes on chromosome 11q13, few of them have been molecularly cloned. Here, we report the construction of a contig map encompassing 11q13.1-q13.3 using bacteriophage P1 (P1), bacterial artificial chromosome (BAC), and P1-derived artificial chromosome (PAC). The contig map comprises 32 P1 clones, 27 BAC clones, 6 PAC clones, and 1 YAC clone and spans a 3-Mb region from D11S480 to D11S913. The map encompasses all the candidate loci of Bardet-Biedle syndrome type I (BBS1) and spinocerebellar ataxia type 5 (SCA5), one-third of the distal region for hereditary paraganglioma 2 (PGL2), and one-third of the central region for insulin-dependent diabetes mellitus 4 (IDDM4). In the process of map construction, 61 new sequence-tagged site (STS) markers were developed from the Not I linking clones and the termini of clone inserts. We have also mapped 30 ESTs on this map. This contig map will facilitate the isolation of polymorphic markers for a more refined analysis of the disease gene region and identification of candidate genes by direct cDNA selection, as well as prediction of gene function from sequence information of these bacterial clones.

Inversion of chromosome 11 inv(11)(p15q22), as a recurring chromosomal aberration associated with de novo and secondary myeloid malignancies: identification of a P1 clone spanning the 11q22 breakpoint.

We studied four patients with inv(11)(p15q22) associated with malignant myeloid diseases by using fluorescence in situ hybridization (FISH) with phage and cosmid probes mapped and ordered on 11q22-24. Two of the four patients had non-Hodgkin's lymphoma or acute lymphoblastic leukemia as the primary malignancy and had received cytotoxic chemotherapy, including topoisomerase II inhibitors. The other two had de novo acute myeloid leukemia or myelodysplastic syndrome. FISH analysis showed that all 11q breakpoints were located centromeric to the MLL gene and between cosmids CN2900 and CN1323. We identified a yeast artificial chromosome (YAC) clone that spanned the inv(11) breakpoints on 11q. From this YAC, we identified a P1 clone, which included the breakpoints in at least three of the four patients. It is highly likely that the same gene on the P1 clone is rearranged in leukemic cells of each patient. This gene may be one of the targets for topoisomerase II inhibitors.

The inv(11)(p15q22) chromosome translocation of de novo and therapy-related myeloid malignancies results in fusion of the nucleoporin gene, NUP98, with the putative RNA helicase gene, DDX10.

The inv(11)(p15q22) is a recurrent chromosomal abnormality associated with de novo and therapy-related myeloid malignancies. Here we report the molecular definition of this chromosomal aberration in four patients. Positional cloning showed the consistent rearrangement of the DDX10 gene on chromosome 11q22, which encodes a putative RNA helicase. The translocation targets the NUP98 gene on 11p15, a member of the FG peptide repeat nucleoporin family. In DDX10 and NUP98, the inv(11) breakpoints occurred within two introns of each gene and the two genes merged in-frame to produce the chimeric transcripts characteristic of this translocation. Although two reciprocal chimeric products, NUP98-DDX10 and DDX10-NUP98, were predicted, only NUP98-DDX10 appears to be implicated in tumorigenesis. DDX10 is predicted to be involved in ribosome assembly. NUP98 has been identified as a nuclear pore complex protein and a target of chromosomal translocation in acute myeloid leukemia through the t(7;11)(p15;p15) translocation. The predicted NUP98-DDX10 fusion protein may promote leukemogenesis through aberrant nucleoplasmic transport of mRNA or alterations in ribosome assembly.

A complete NotI restriction map covering the entire long arm of human chromosome 11.

BACKGROUND: Human chromosome 11 is one of the autosomes on which many disease genes have been mapped. Many different types of map, including a radiation hybrid map, a genetic map, and an STS-content YAC map, have been constructed for the chromosome. However, a physical map providing accurate physical distances has not yet been established. A chromosome-wide NotI restriction map was constructed to understand the overall feature of the genome organization and to facilitate the positional cloning of disease genes. RESULTS: A complete NotI restriction map of the entire long arm of human chromosome 11 was constructed using linking-clone mapping. This physical map covers 77.6Mb, from a pericentromeric NotI site to the terminus, and provides the most accurate ordering and distance estimation to date. We also mapped 138 sequence markers in the q13 region that have been poorly mapped previously. CONCLUSIONS: The restriction map of the entire long arm of human chromosome 11 is the longest restriction map of the human genome. This mapping has disclosed unique features regarding the organization of the chromosome, indicating that restriction sites of NotI, a CpG-recognition enzyme, are primarily distributed in R (or T) bands and that genetic distance is considerably longer in R (or T) bands than in G bands. The mapping, as well as the dense concentration of mapped markers within the q13 region, should help with positional cloning of the genes associated with various diseases.

A yeast artificial chromosome contig and NotI restriction map that spans the tumor suppressor gene(s) locus, 11q22.2-q23.3.

Human chromosome 11q22-q23 is a pathologically important region in which a high level of loss of heterozygosity has been reported for breast, ovary, cervical, colon, and lung carcinomas, malignant melanomas, and hematologic malignancies. This strongly indicates that one or more tumor suppressor genes reside within the deleted region. In this report, we report the development of a contig map that covers most of the deleted regions found in these malignancies. The map comprises a contig of 66 overlapping yeast artificial chromosomes (YACs) and spans a region of 17 Mb from the PGR gene at 11q22.2 to the MLL gene at q23.3. In the process of screening the YACs, 50 new sequence-tagged site markers were developed from the termini of the YAC inserts. These markers were used for chromosome walking, and the data were then integrated into the contig map. NotI restriction mapping of these YACs revealed the presence of at least 26 NotI sites in the region. Using 22 of them, a NotI restriction map of the region from PGR to D11S939 was developed. This YAC contig will provide efficient tools for identification of the putative tumor suppressor gene(s).

A NotI restriction map of the entire long arm of human chromosome 21.

A variety of maps of the human genome have been constructed, including cloned DNA maps. We have isolated 40 of the 42 NotI sites that exist on the long arm of human chromosome 21, as NotI linking clones and constructed a complete NotI restriction map spanning the entire region. This map, which provides the most reliable ordering and distance estimation in the region from a pericentromeric locus to the terminus, demonstrates the usefulness of linking clone mapping for analysing human chromosomes.