Phylogenomics of caspase-activated DNA fragmentation factor

The degradation of nuclear DNA by DNA fragmentation factor (DFF) is a key step in apoptosis of mammalian cells. Using comparative genomics, we have here determined the evolutionary history of the genes encoding the two DFF subunits, DFFA (also known as ICAD) and DFFB (CAD). Orthologs of DFFA and DFFB were identified in Nematostella vectensis, a representative of the primitive metazoan clade cnidarians, and in various vertebrates and insects, but not in representatives of urochordates, echinoderms, and nematodes. The domains mediating the interaction of DFFA and DFFB, a caspase cleavage site in DFFA, and the amino acid residues critical for endonuclease activity of DFFB were conserved in Nematostella. These findings suggest that DFF has been a part of the primordial apoptosis system of the eumetazoan common ancestor and that the ancient cell death machinery has degenerated in several evolutionary lineages, including the one leading to the prototypical apoptosis model, Caenorhabditis elegans.     

Refined physical mapping and genomic structure of the EXTL1 gene

Recently, the EXTL1 gene, a member of the EXT tumor suppressor gene family, has been mapped to 1p36, a chromosome region which is frequently implicated in a wide variety of malignancies, including breast carcinoma, colorectal cancer and neuroblastoma. In this study, we show that the EXTL1 gene is located between the genetic markers D1S511 and D1S234 within 200 kb of the LAP18 gene on chromosome 1p36. 1, a region which has been proposed to harbor a tumor suppressor gene implicated in MYCN-amplified neuroblastomas. In addition, we determined the genomic structure of the EXTL1 gene, revealing that the EXTL1 coding sequence spans 11 exons within a 50-kb region.     

Genomic Organization and Mutation Analysis ofp73in Oligodendrogliomas with Chromosome 1 p-Arm Deletions

p73, a protein having substantial structural and functional similarity to p53, has recently been identified and demonstrated to be a potential tumor suppressor. Its location on human chromosome 1p36.33 implicates p73 as a candidate for neuroblastoma. Like neuroblastoma, oligodendrogliomas also show a high frequency of deletions in chromosome 1p36.3. To determine whetherp73is a potential tumor suppressor gene involved in the development of oligodendrogliomas, we performed mutation analysis ofp73in oligodendrogliomas with chromosome 1 p-arm deletions. We first determined the genomic organization and the intron–exon boundary sequences of thep73gene by long PCR, vectorette PCR, and Southern hybridization. This gene spans about 65 kb with a large first intron. Primer pairs for the amplification of each of the 13 p73 encoding exons were designed in corresponding introns. The amplicons were then analyzed using the denaturing high-performance liquid chromatography system for mutations in thep73gene. Twenty oligodendroglioma samples with 1p36.3 deletions were screened, but no mutations were detected except for several polymorphisms. It is thus clear thatp73is not a candidate gene for oligodendroglioma despite its location in the frequently deleted 1p36.3 region.     

A polymorphism but no mutations in the GADD45 gene in breast cancers

The p53 gene product is part of a pathway regulating growth arrest at the G₁ checkpoint of the cell cycle. Mutation of other components of this pathway, including the products of the ataxia telangiectasia (AT), GADD45, mdm2, and p21^WAF1/CIP1 genes may have effects comparable to mutations in the p53 gene. The GADD45 gene is induced by ionizing radiation and several DNA-damaging xenobiotics. Induction requires the binding of wild-type p53 to an evoulutionarily highly conserved putative intronic p53 binding site in intron 3 of GADD45. We recently analyzed the entire coding region of the p53 gene in primary breast cancers of Midwestern white women and found 21 mutations among 53 tumors (39,6%). We now have shown by direct sequencing that there are no mutations in the intronic p53 binding site of the GADD45 gene in any of the 53 primary breast cancers and no mutations in the entire coding region of the GADD45 gene in a subset of 26 consecutive tumors (12 with p53 mutation and 14 without p53 mutation). The only sequence variation detected was a common polymorphism in intron 3. The absence of mutations in the GADD45 gene, including the putative p53-binding intronic site, suggests that this gene is not a frequent target of mutations in breast cancer. Although mutations of the p53 gene have been studied in a wide spectrum of human cancers, GADD45 has not been examined in any tumor or cell line to the best of our knowledge. Our results raise the possibility that mutation of the GADD45 gene alone is not functionally equivalent to loss of wild-type p53 activity. Received: 14 September 1995     

Isolation of genes from the rhabdoid tumor deletion region in chromosome band 22q11.2

We employed exon trapping and large-scale genomic sequence analysis of two bacterial artificial chromosome clones to isolate genes from the region between the IGLC and BCR in chromosome 22q11.2. At the time these studies were initiated, one previously identified gene, GNAZ, was known to map to this region. Two genes, RTDR1 and RAB36, were cloned from this portion of 22q11, which is heterozygously or homozygously deleted in pediatric rhabdoid tumors of the brain, kidney and soft tissues. RTDR1 is a novel gene with a slight homology to a yeast vacuolar protein. RAB36 is a member of the Rab family of proteins. A series of primary rhabdoid tumors with chromosome 22q11 deletions were screened for mutations in the coding sequences of RTDR1, GNAZ and RAB36, but did not demonstrate any disease-specific alterations. Recently, INI1, which maps to the distal portion of the deletion region in 22q11, was identified as the candidate rhabdoid tumor suppressor gene. Further studies of RTDR1 and RAB36 are required to determine whether their absence contributes to the progression of rhabdoid tumors. Alternatively, these genes may be candidates for other diseases that map to human chromosome 22.     

The gene for leukocyte antigen-related tyrosine phosphatase (LAR) is localized to human chromosome 1p32, a region frequently deleted in tumors of neuroectodermal origin.

In situ hybridization was employed to localize a cDNA probe from the human protein tyrosine phosphatase gene LAR to human metaphase chromosomes. LAR, a putative tumor suppressor gene, has been localized to 1p32, a chromosomal region that is frequently found deleted in human neuroblastoma and pheochromocytoma.     

A cloned ompR-like gene of Streptomyces lividans 66 suppresses defective melC1, a putative copper-transfer gene

Expression of tyrosinase in Streptomyces requires functional MelC1 protein, which is postulated to transfer copper to apotyrosinase. We have previously isolated a mutant of Streptomyces lividans, HT32, that phenotypically suppressed mutations in cloned melC1 (H.-C. Tseng and C. W. Chen, in preparation). Plasmid pLUS132, containing an ATG to ATA transition at the initiation codon of melC1, was used for cloning the suppressor gene from HT32. A 1687 bp suppressor DNA was isolated that contained two characteristic Streptomyces coding sequences: a 217-amino-acid open reading frame (cutR) and a truncated open reading frame (cutS) downstream. Subcloning analysis attributed the phenotypic suppression activity to the putative cutR gene from HT32. The putative CutR exhibited similarity to the response regulator OmpR of the osmoregulatory signal-transduction system in Escherichia coli. The truncated CutS resembled, to a lesser degree, the N-terminus of EnvZ, the histidine protein kinase counterpart of OmpR. DNA hybridizing to the cloned cutR-cutS sequence was detected in 16 other Streptomyces species. We postulate that the putative cutR-cutS operon regulates copper metabolism in Streptomyces.     

Localization of the expressed human p58 protein kinase chromosomal gene to chromosome 1p36 and a highly related sequence to chromosome 15.

The gene for the human p58 protein kinase, a cell division control-related gene, has been mapped by somatic cell hybrid analyses, in situ localization with the chromosomal gene, and nested polymerase chain reaction amplification of microdissected chromosomes. These studies indicate that the expressed p58 chromosomal gene maps to 1p36, while a highly related p58 sequence of unknown nature maps to chromosome 15. Assignment of a p34cdc2-related gene to 1p36 may have implications for numerous tumors that involve deletion of this region, including neuroblastoma, ductal carcinoma of the breast, malignant melanoma, Merkel cell carcinoma, and endocrine neoplasia.     

Lack of cyclin D-Cdk complexes in Rb-negative cells correlates with high levels of p16INK4/MTS1 tumour suppressor gene product.

D-type cyclins, in association with the cyclin-dependent kinases Cdk4 or Cdk6, regulate events in the G1 phase of the cell cycle and may contribute to the phosphorylation of the retinoblastoma gene product (Rb). However, in cells in which the function of Rb has been compromised, either by naturally arising mutations or through binding to proteins encoded by DNA tumour viruses, Cdk4 and Cdk6 are not associated with D cyclins. Instead, both kinases form binary complexes with a stable 16 kDa protein (p16) encoded by the putative tumour suppressor gene INK4/MTS1 on human chromosome 9p21. Here we show an inverse correlation between Rb status and the expression of p16. Since Rb-negative cells express high levels of p16, we suggest that in these cells p16 competes with D cyclins for binding to Cdk4 and Cdk6 and prevents formation of active complexes. In line with these predictions, DNA tumour virus oncoproteins do not disrupt cyclin D1-Cdk4 complexes in cells lacking p16.     

The EIF3S3 gene encoding the p40 subunit of the translation initiation factor eIF3 has eight exons and maps to the Langer-Giedion syndrome chromosome region on 8q24, but is not the TRPS1 gene

We have mapped the gene encoding the p40 subunit of the eukaryotic translation initiation factor eIF3 (EIF3S3) close to the distal border of the minimal critical region for tricho-rhino-phalangeal syndrome type I (TRPS I) on human chromosome 8q24. Because this location makes EIF3S3 a candidate for the TRPS1 gene, we have determined the genomic structure of the EIF3S3 gene and searched for gene deletions and mutations in patients with TRPS I. The gene has eight exons and is transcribed from telomere to centromere. No deletion could be detected in 32 unrelated patients with an apparently normal karyotype. Sequence analysis of all exons in 15 unrelated patients did not reveal any point mutation either. Our data exclude EIF3S3 as the TRPS1 gene.     

Gadd45 mutations are uncommon in human tumour cell lines

GADD45 is an evolutionarily conserved gene that encodes a small acidic, nuclear protein and is an example of a p53 responsive gene. Gadd45 protein has been shown to interact with PCNA and also p21^waf1. It has been implicated in growth arrest, DNA repair, chromatin structure and signal transduction. The confusing biochemical data has been clarified by the demonstration that Gadd45 null mice have a phenotype strikingly similar to that of p53 null mice, being tumour prone and showing marked genomic instability. We have tested the hypothesis that mutations in the GADD45 coding region might substitute for p53 abnormalities in tumour cell lines where p53 is wild type. After generating cDNA from mRNA in a panel of 24 cell lines we sequenced the GADD45 cDNA and have demonstrated that no mutations can be observed, even in the p53 wild type cell lines. Such data suggest that Gadd45 mutations are uncommon in human cancer. From this we postulate that, despite the phenotype of the GADD45 null mouse, GADD45 is unlikely to be the key mechanistic determinant of the tumour suppressor activity of the p53 pathway.
Note on nomenclature: We have employed GADD45 to designate the gene and Gadd45 to designate the encoded protein. This gene has also be denoted GADD45 α elsewhere in the literature.     

Cloning a calcium channel alpha2delta-3 subunit gene from a putative tumor suppressor gene region at chromosome 3p21.1 in conventional renal cell carcinoma

We have identified loss of heterozygosity (LOH) of approx. 1 cM region around locus D3S1289 at chromosome 3p21.1 in a conventional renal cell carcinoma (RCC). During construction of a YAC/BAC contig for this region and shotgun sequencing of BACs 277p5, 55m24 and 428i24, we detected four new microsatellites. We narrowed down the target region by analysing these new loci to less than 100 kb within the BAC 55m24 and subsequently cloned a human calcium channel alpha2delta-3 subunit gene. This gene is widely expressed in fetal tissues and different types of adult tumors. The exons of the alpha2delta-3 subunit gene are distributed along approx. 500 kb DNA sequences. As the LOH involved exclusively intronic sequences and sequencing the entire coding region did not reveal any mutation, the alpha2delta-3 subunit gene is probably not a tumor suppressor gene.