p190-A, a human tumor suppressor gene, maps to the chromosomal region 19q13.3 that is reportedly deleted in some gliomas.

To date, two distinct genes coding for Ras GAP-binding phosphoproteins of 190kDa, p190-A and p190-B, have been cloned from mammalian cells. Rat p190-A of 1513 amino acids shares 50% sequence identity with human p190-B of 1499 amino acids. We have previously demonstrated, using rat p190-A cDNA, that full-length p190-A is a tumor suppressor, reversing v-Ha-Ras-induced malignancy of NIH 3T3 cells through both the N-terminal GTPase (residues 1-251) and the C-terminal Rho GAP (residues 1168-1441) domains. Here we report the cloning of the full-length human p190-A cDNA and its first exon covering more than 80% of this protein, as well as its chromosomal mapping. Human p190-A encodes a protein of 1514 amino acids, and shares overall 97% sequence identity with rat p190-A. Like the p190-B exon, the first exon of p190-A is extremely large (3.7 kb in length), encoding both the GTPase and middle domains (residues 1-1228), but not the remaining GAP domain, suggesting a high conservation of genomic structure between two p190 genes. Using a well characterized monochromosome somatic cell hybrid panel, fluorescent in situ hybridization (FISH) and other complementary approaches, we have mapped the p190-A gene between the markers D19S241E and STD (500 kb region) of human chromosome 19q13.3. Interestingly, this chromosomal region is known to be rearranged in a variety of human solid tumors including pancreatic carcinomas and gliomas. Moreover, at least 40% glioblastoma/astrocytoma cases with breakpoints in this region were previously reported to show loss of the chromosomal region encompassing p190-A, suggesting the possibility that loss or mutations of this gene might be in part responsible for the development of these tumors.

CT10: a new cancer-testis (CT) antigen homologous to CT7 and the MAGE family, identified by representational-difference analysis.

Assays relying on humoral or T-cell-based recognition of tumor antigens to identify potential targets for immunotherapy have led to the discovery of a significant number of immunogenic gene products, including cancer-testis (CT) antigens predominantly expressed in cancer cells and male germ cells. The search for cancer-specific antigens has been extended via the technique of representational-difference analysis and SK-MEL-37, a melanoma cell line expressing a broad range of CT antigens. Using this approach, we have isolated CT antigen genes, genes over-expressed in cancer, e. g., PRAME and KOC, and genes encoding neuro-ectodermal markers. The identified CT antigen genes include the previously defined MAGE-A6, MAGE-A4a, MAGE-A10, CT7/MAGE-C1, as well as a novel gene designated CT10, which shows strong homology to CT7/MAGE-C1 both at cDNA and at genomic levels. Chromosome mapping localized CT10 to Xq27, in close proximity to CT7/MAGE-C1 and MAGE-A genes. CT10 mRNA is expressed in testis and in 20 to 30% of various human cancers. A serological survey identified 2 melanoma patients with anti-CT10 antibody, demonstrating the immunogenicity of CT10 in humans.

Isolation of DICE1: a gene frequently affected by LOH and downregulated in lung carcinomas.

In the development and progression of sporadic tumors multiple tumor suppressor genes are inactivated that may be distinct from predisposing cancer genes. Previously, a tumor suppressor locus on human chromosome 13q14 that is distinct from the retinoblastoma predisposing gene 1 (RB1) has been identified in lung, head and neck, breast, ovarian and prostate tumors. By an approach that combines genomic difference cloning and positional cloning we isolated the cDNA of a novel gene (DICE1) located at 13q14.12-14.2. The DICE1 gene is highly conserved in evolution and its mRNA is expressed in a wide variety of fetal and adult tissues. The DICE1 cDNA encodes a predicted protein of 887 amino acids corresponding to an 100 kD protein that shows 92.9% identity to the carboxy-terminal half of the mouse EGF repeat transmembrane protein DBI-1. The DBI-1 protein interferes with the mitogenic response to insulin-like growth factor 1 (IGF-I) and is presumably involved in anchorage-dependent growth. When compared to normal lung tissue expression of the DICE1 mRNA was reduced or undetectable in the majority of non-small cell lung carcinomas analysed. The location of the DICE1 gene in the region of allelic loss, its high evolutionary conservation and the downregulation of expression in carcinoma cells suggests that DICE1 is a candidate tumor suppressor gene in non-small cell lung carcinomas and possibly in other sporadic carcinomas.

Characterization of the GAGE genes that are expressed in various human cancers and in normal testis.

The GAGE-1 gene was identified previously as a gene that codes for an antigenic peptide, YRPRPRRY, which was presented on a human melanoma by HLA-Cw6 molecules and recognized by a clone of CTLs derived from the patient bearing the tumor. By screening a cDNA library from this melanoma, we identified five additional, closely related genes named GAGE-2-6. We report here that further screening of this library led to the identification of two more genes, GAGE-7B and -8. GAGE-1, -2, and -8 code for peptide YRPRPRRY. Using another antitumor CTL clone isolated from the same melanoma patient, we identified antigenic peptide, YYWPRPRRY, which is encoded by GAGE-3, -4, -5, -6, and -7B and which is presented by HLA-A29 molecules. Genomic cloning of GAGE-7B showed that it is composed of five exons. Sequence alignment showed that an additional exon, which is present only in the mRNA of GAGE-1, has been disrupted in gene GAGE-7B by the insertion of a long interspersed repeated element retroposon. These GAGE genes are located in the p11.2-p11.4 region of chromosome X. They are not expressed in normal tissues, except in testis, but a large proportion of tumors of various histological origins express at least one of these genes. Treatment of normal and tumor cultured cells with a demethylating agent, azadeoxycytidine, resulted in the transcriptional activation of GAGE genes, suggesting that their expression in tumors results from a demethylation process.

Isoforms of the human PDZ-73 protein exhibit differential tissue expression.

Patients with renal and colon cancer frequently develop IgG autoantibodies toward the NY-CO-38/PDZ-73 antigen, a protein of 652 amino acids (73 kDa) which contains three copies of the PDZ protein-protein interaction domain. The gene encoding PDZ-73 mapped to chromosome 11p15.4-p15.1. Additional tissue-specific isoforms were identified: PDZ-45, which lacks the third PDZ domain and the putative PEST protein degradation motif, is expressed in kidney, colon, small intestine, brain and testis; PDZ-54 and PDZ-59, which also lack the third PDZ domains, have unique carboxyl terminal amino acids and are expressed in brain, kidney, bladder, colon cancer and renal cancer; and a putative PDZ-37 isoform, containing only the third PDZ domain, that is expressed in the central nervous system. Immunohistochemical staining with anti-PDZ 73 monoclonal antibodies showed strong cytoplasmic reactivity in epithelial cells of the small intestine, colon and kidney tubules, with a prominent apical staining pattern in cells of the small intestine. The reactivity pattern of the antibodies with various tissues correlated with the mRNA expression pattern of the PDZ-45 isoform. The existence of multiple PDZ-73 isoforms with variations in tissue distribution, PDZ domains, protein degradation sequences and carboxyl terminal structure indicate that these isoforms have distinct tissue-specific functions.

Localization of serine kinases, SRPK1 (SFRSK1) and SRPK2 (SFRSK2), specific for the SR family of splicing factors in mouse and human chromosomes.

The serine- and arginine-rich (SR) splicing factors play an important role in both constitutive and alternative pre-mRNA splicing, and the functions of these splicing factors are regulated by phosphorylation. We have previously characterized SRPK1 (SFRSK1) and SRPK2 (SFRSK2), which are highly specific protein kinases for the SR family of splicing factors. Here we report the chromosomal localization of the mouse and human genes for both kinases. SRPK1 probes detected two loci that were mapped to mouse Chromosomes 17 and X using The Jackson Laboratory interspecific backcross DNA panel, and SRPK2 probes identified a single locus on mouse Chromosome 5. Using a somatic cell hybrid mapping panel and by fluorescence in situ hybridization, SRPK1 and SRPK2 were respectively mapped to human chromosomes 6p21.2-p21.3 (a region of conserved synteny to mouse Chromosome 17) and 7q22-q31.1 (a region of conserved synteny to mouse Chromosome 5). In addition, we also found multiple SRPK-related sequences on other human chromosomes, one of which appears to correspond to a SRPK2 pseudogene on human chromosome 8.

Identification of a human gene encoding a homologue of Saccharomyces cerevisiae EXO1, an exonuclease implicated in mismatch repair and recombination.

The EXO1 gene was identified in Saccharomyces cerevisiae as a gene encoding an exonuclease that interacts with MSH2 and functions in mismatch repair and genetic recombination. To understand the role of EXO1 in higher eukaryotes, we identified the human EXO1 gene. The hEXO1 predicted amino acid sequence shares 26.6% identity with the S. cerevisiae EXO1 amino acid sequence. The human and S. cerevisiae proteins showed a similar ability to complement the mutator phenotype of S. cerevisiae rad27 mutants indicating that the two proteins are functionally similar. There appear to be two forms of hEXO1 that differ by the COOH-terminal 1 and 44 amino acids, respectively, and these appear to result from alternative RNA splicing. The hEXO1 gene consists of 14 exons and is transcribed to yield a 3-kb mRNA. Radiation hybrid and fluorescence in situ hybridization mapping studies indicate that the human gene is located at 1q42.2-qter. Northern blot analysis demonstrates that hEXO1 is expressed in high levels in testis; elevated expression was also observed in thymus and colon and to a lesser extent in small intestine, placenta, spleen, and ovary.

Identification of a new MAGE gene with tumor-specific expression by representational difference analysis.

Human genes expressed exclusively in tumors and male germ line cells, such as those of the MAGE, BAGE, and GAGE families, encode antigens recognized by T lymphocytes, which are potentially useful for antitumor immunotherapy. To identify new genes of this type, we generated cDNA populations enriched in sequences expressed only in testis and melanoma, using the representational difference analysis approach. A testis cDNA library enriched by subtraction with cDNA from four other normal tissues was hybridized with radiolabeled melanoma cDNA enriched by subtraction with normal skin cDNA. A cDNA fragment sharing significant homology with MAGE genes was identified, and a cosmid containing this new gene, named MAGE-C1, was isolated. MAGE-C1 is composed of four exons and encodes a putative protein of 1142 amino acids. It is about 800 residues longer than the other MAGE proteins due to the insertion of a large number of short repetitive sequences in front of the MAGE-homologous sequence. The MAGE-C1 gene appears to be located on band Xq26, whereas the MAGE-A and MAGE-B genes are located on Xq28 and Xp21, respectively. Like other MAGE genes, MAGE-C1 is expressed in a significant proportion of tumors of various histological types, whereas it is silent in normal tissues except testis. It is probable, therefore, that like other MAGE genes, MAGE-C1 encodes antigens that may constitute useful targets for cancer immunotherapy because of their strict tumoral specificity.

Genetic instability leads to loss of both p53 alleles in a human glioblastoma.

Little is known about the relationship between genetic recombination mechanisms and loss of tumour suppressor genes in solid tumours. Here, we demonstrate deletion and truncation of both p53 alleles in a primary human glioblastoma and a derived cell line as the combined result of a t(17;20) reciprocal translocation and a 1.1 Mbp genomic deletion on chromosome 17p, starting in intron 4 of the p53 gene and ending at the telomeric CA-repeat marker D17S960. These results (i) suggest that genetic instability can lead to loss of tumour suppressor gene function in solid cancers, (ii) provide mapping of one such recombination event at the nucleotide level, and (iii) establish the orientation of the p53 gene on chromosome 17 as: centromere 5'-3'-telomere.

Cloning and characterization of three human forkhead genes that comprise an FKHR-like gene subfamily.

Alveolar rhabdomyosarcomas are associated with unique chromosomal translocations t(2;13) and t(1;13), which arise from fusion of the genes for the paired box proteins PAX3 and PAX7, respectively, to the FKHR (forkhead in rhabdomyosarcoma) gene on chromosome 13q14. Here we report the identification and characterization of three novel human forkhead genes with similarity to FKHR. The three genes (HGMW-approved symbols FKHRP1, FKHRL1, and FKHRL1P1) map to chromosomal regions 5q35.2-q35.3, 6q21, and 17p11, respectively. Based on amino acid sequence comparisons of their forkhead domains, FKHRL1, FKHRL1P1, and FKHRP1 share 86, 84, and 68% identity, respectively, with FKHR. While FKHR and FKHRL1 are expressed in every human adult tissue examined, FKHRP1 mRNA expression could not be detected, and FKHRL1P1 expression was present only at low levels. FKHR and FKHRL1 share a similar genomic organization, each having a very large intron 1 (FKHR approximately 130 kb and FKHRL1 > 90 kb), which bisects their respective forkhead domains at identical positions, as well as a second intron just downstream of each stop codon. FKHRP1 and FKHRL1P1 lack introns and contain stop codons that prevent them from yielding full-length proteins. Thus, while FKHR and FKHRL1 represent functional genes, FKHRP1 and FKHRL1P1 probably are processed pseudogenes. These results suggest that these four genes represent an FKHR-like gene subfamily within the larger human forkhead gene family.

Chromosomal mapping and mutational analysis of the coding region of the glycogen synthase kinase-3alpha and beta isoforms in patients with NIDDM.

Activation of glycogen synthesis in skeletal muscle in response to insulin results from the combined inactivation of glycogen synthase kinase-3 (GSK-3) and activation of the protein phosphatase-1, changing the ratio between the inactive phosphorylated state of the glycogen synthase to the active dephosphorylated state. In a search for genetic defects responsible for the decreased insulin stimulated glycogen synthesis seen in patients with non-insulin-dependent diabetes mellitus (NIDDM) and their glucose-tolerant first-degree relatives we have performed mutational analysis of the coding region of the 2 isoforms of GSK-3alpha and GSK-3beta in 72 NIDDM patients and 12 control subjects. No structural changes were detected apart from a few silent mutations. Mapping of the GSK-3alpha to chromosome 19q13.1-13.2 and the GSK-3beta to chromosome 3q13.3-q21 outside known genetic loci linked to NIDDM further makes it unlikely that these genes are involved in the pathogenesis of common forms of NIDDM.

Genomic cloning and localization of CTAG, a gene encoding an autoimmunogenic cancer-testis antigen NY-ESO-1, to human chromosome Xq28.

CTAG was initially cloned from an esophageal squamous cell carcinoma cDNA expression library by immunoscreening with autologous patient's serum. CTAG mRNA is expressed in a proportion of human cancers in a lineage-nonspecific fashion, whereas its expression in normal tissues is restricted to testis and ovary only. This expression pattern suggests that the CTAG product (NY-ESO-1) is an aberrantly activated tumor antigen and can potentially be an antigenic target for tumor vaccination. In the present study, we isolated human genomic clones of CTAG and established its genomic organization. By somatic cell hybrid studies and fluorescence in-situ hybridization, we localized this gene to chromosome Xq28, a region that also contains members of MAGE, a gene family that encodes several immunogenic tumor antigens with the characteristic cancer/testis expression pattern.

Allelic deletion mapping on chromosome 5 in human carcinomas.

We analysed allelic deletions on chromosome 5 in microdissected human non-small cell lung cancers. Thirty-four primary squamous cell carcinomas, 15 primary adenocarcinomas and five regional lymph node metastases were investigated for loss of heterozygosity (LOH) in chromosomal region 5p15-q21. The sites analysed included the APC tumor suppressor gene at 5q21, five polymorphic microsatellite markers and the putative tumor suppressor locus del-27, that was assigned to chromosomal region 5p13-12 by fluorescence in situ hybridization (FISH) analysis. Allelic deletions encompassed larger genomic regions more often in squamous cell carcinomas than in adenocarcinomas. The del-27 amd APC regions were identified as two distinct regions with the highest LOH frequencies within 5p15-q21. In squamous cell carcinomas LOH frequencies were 73% at the del-27 and 70% at the APC locus. In adenocarcinomas LOH at the del-27 and APC loci occurred in 38% of the informative cases. Allelic deletion of the APC gene and at the del-27 locus was also detected in the metastases. The results suggest involvement of at least two tumor suppressor genes on chromosome 5 in lung tumorigenesis.

Chromosomal localization of mouse and human genes encoding the splicing factors ASF/SF2 (SFRS1) and SC-35 (SFRS2).

The mammalian SR-type splicing factors ASF/SF2 and SC-35 play crucial roles in pre-mRNA splicing and have been shown to shift splice site choice in vitro. We have mapped the ASF/SF2 gene in mice and humans and the SC-35 gene in mice. Somatic cell hybrid mapping of the human ASF/SF2 gene (SFRS1 locus) reveals that it resides on chromosome 17, and fluorescence in situ hybridization refines this localization to 17q21.3-q22. Recombinant inbred mapping of the mouse ASF/SF2 gene (Sfrs1 locus) and the mouse SC-35 gene (Sfrs2 locus) demonstrates that both genes are located in a part of mouse chromosome 11 that is homologous to human chromosome 17. Mapping of Sfrs1 using F1 hybrid backcross mice between the strains C57BL/6 and DDK places Sfrs1 very near the marker D11Mit38 and indicates that the ASF/SF2 gene is closely linked to the Ovum mutant locus.

Localization of the human B-type natriuretic peptide precursor (NPPB) gene to chromosome 1p36.

Cardiac myocytes synthesize and secrete a family of peptide hormones with potent natriuretic, diuretic, and vasodilatory properties. These peptides are derived from precursor molecules that are encoded by two different genes, the atrial natriuretic peptide precursor A (NPPA) and the B-type natriuretic peptide or natriuretic peptide precursor B (NPPB). A human genomic clone for the NPPB gene was used to determine the chromosomal location of the NPPB gene. Analysis of Southern blot hybridization to DNAs from various somatic cell hybrids and fluorescence in situ hybridization allowed assignment of the NPPB locus to human chromosome 1p36. This location coincided with that of the NPPA locus; pulsed-field gel electrophoresis placed NPPA and NPPB within 50 kb of each other. This close chromosomal linkage, together with the conserved primary sequences and structural organization of the two natriuretic peptide precursor genes, suggests that the natriuretic peptide loci may have evolved from a common ancestor gene.

Localization of short/branched chain acyl-CoA dehydrogenase (ACADSB) to human chromosome 10.

Short/branched chain acyl-CoA dehydrogenase, SBCAD (gene symbol ACADSB), is a member of the acyl-CoA dehydrogenase family of genes with activity toward the short/branched chain acyl-CoA derivatives as well as short/straight chain acyl-CoAs. Southern blot analysis of DNA from a panel of human/rodent somatic cell hybrids localized ACADSB to human chromosome 10, and fluorescence in situ hybridization experiments confirmed the chromosomal assignment and refined the subchromosomal localization to 10q25-q26.