BACKGROUND/AIMS: This study focused on the oncogenic role of Diphthamide biosynthesis 1 (DPH1) in colorectal cancer (CRC) cells.
METHODS: The expression of DPH1 was determined by quantitative RT-PCR analysis and western blotting in CRC tissues. The role of DPH1 in CRC cells was investigated via cell viability and invasion assays under the condition of DPH1 silencing or overexpression. Bioinformatics analysis and luciferase reporter analysis were used to identify the upstream microRNA which might regulate DPH1.The inverse correlation between the microRNA and DPH1 was also detected in CRC cells.
RESULTS: We identified an unexpected role for DPH1 as an oncogene in CRC cells. The tumour-suppressive miR-218-5p regulates DPH1 directly and negatively. Loss of miR-218-5p drives the oncogenic role of DPH1 in CRC cells.
CONCLUSION: The modulation of DPH1 by miR-218-5p may be an important regulatory axis during CRCtumourigenesis.

The diphthamide on human eukaryotic translation elongation factor 2 (eEF2) is the target of ADP ribosylating diphtheria toxin (DT) and Pseudomonas exotoxin A (PE). This modification is synthesized by seven dipthamide biosynthesis proteins (DPH1-DPH7) and is conserved among eukaryotes and archaea. We generated MCF7 breast cancer cell line-derived DPH gene knockout (ko) cells to assess the impact of complete or partial inactivation on diphthamide synthesis and toxin sensitivity, and to address the biological consequence of diphthamide deficiency. Cells with heterozygous gene inactivation still contained predominantly diphthamide-modified eEF2 and were as sensitive to PE and DT as parent cells. Thus, DPH gene copy number reduction does not affect overall diphthamide synthesis and toxin sensitivity. Complete inactivation of DPH1, DPH2, DPH4, and DPH5 generated viable cells without diphthamide. DPH1ko, DPH2ko, and DPH4ko harbored unmodified eEF2 and DPH5ko ACP- (diphthine-precursor) modified eEF2. Loss of diphthamide prevented ADP ribosylation of eEF2, rendered cells resistant to PE and DT, but does not affect sensitivity toward other protein synthesis inhibitors, such as saporin or cycloheximide. Surprisingly, cells without diphthamide (independent of which the DPH gene compromised) were presensitized toward nuclear factor of kappa light polypeptide gene enhancer in B cells (NF-κB) and death-receptor pathways without crossing lethal thresholds. In consequence, loss of diphthamide rendered cells hypersensitive toward TNF-mediated apoptosis. This finding suggests a role of diphthamide in modulating NF-κB, death receptor, or apoptosis pathways.

During inflammation, high-mobility group box 1 in reduced all-thiol form (at-HMGB1) takes charge of chemoattractant activity, whereas only disulfide-HMGB1 (ds-HMGB1) has cytokine activity. Also as pro-angiogenic inducer, the role of HMGB1 in different redox states has never been defined in tumour angiogenesis. To verify which redox states of HMGB1 induces angiogenesis in colorectal carcinoma. To measure the expression of VEGF-A and angiogenic properties of the endothelial cells (ECs), at-HMGB1 or ds-HMGB1 was added to cell medium, further with their special inhibitors (DPH1.1 mAb and 2G7 mAb) and antibodies of corresponding receptors (RAGE Ab and TLR4 Ab). Also, a co-culture system and conditioned medium from tumour cells were applied to mimic tumour microenvironment. HMGB1 triggered VEGF-A secretion mainly through its disulfide form interacting with TLR4, while co-operation of at-HMGB1 and RAGE mediated migratory capacity of ECs. Functional inhibition of HMGB1 and its receptors abrogated HMGB1-induced angiogenic properties of ECs co-cultured with tumour cells. HMGB1 orchestrates the key events of tumour angiogenesis, migration of ECs and their induction to secrete VEGF-A, by adopting distinct redox states.

Overexpression of SIRT1 is frequently observed in various types of cancers, suggesting its potential role in malignancies. However, the molecular basis of how SIRT1 is elevated in cancer is less understood. Here we show that cancer-related SIRT1 overexpression is due to evasion of Sirt1 mRNA from repression by a group of Sirt1-targeting microRNAs (miRNAs) that might be robustly silenced in cancer. Our comprehensive library-based screening and subsequent miRNA gene profiling revealed a housekeeping gene-like broad expression pattern and strong CpG island-association of the Sirt1-targeting miRNA genes. This suggests aberrant CpG DNA methylation as the mechanistic background for malignant SIRT1 elevation. Our work also provides an example where epigenetic mechanisms cause the group-wide regulation of miRNAs sharing a common key target.

Moxetumomab pasudotox (HA22) is an immunotoxin with an anti-CD22 Fv fused to a portion of Pseudomonas exotoxin A that kills CD22 expressing ALL cells. HA22 produced significant responses in some cases of ALL. To understand how to increase response rate, we isolated HA22-resistant KOPN-8 cells and found that HA22 cannot inactivate elongation factor-2 (EF2) due to low levels of DPH1 RNA and protein. Resistance was associated with methylation of the CpG island in the DPH1 promoter. 5-Azacytidine prevented resistance and methylation of the CpG residues and merits evaluation to determine if it can increase the efficacy of HA22 in ALL.

OVCA1, a tumor suppressor gene, is deleted or lower expressed in about 80% of ovarian cancer. Over expression of OVCA1 in human ovarian cancer A2780 cells inhibits cell proliferation and arrests cells in G1 stage. However, the fact that the molecular mechanism of OVCA1 inhibits cell growth is presently elusive. Here we investigated the potential signaling pathway induced by over-expression of OVCA1. Our results show that over-expression of human OVCA1 in ovarian cancer cells A2780 leads to down-regulation of cyclin D1, and up-regulation of p16, but no effect on the expression of NF-κB. It indicates that OVCA1 could inhibit the proliferation of ovarian cancer cell A2780 by p16/cyclin D1 pathway, but not by NF-κB.

BACKGROUND: Apart from inactivation of the MEN1 gene, the molecular mechanisms involved in tumorigenesis of the endocrine organs and MEN1-associated non-endocrine lesions remain unknown.
MATERIALS AND METHODS: In order to learn more about down-stream effects upon MEN1 gene inactivation BON1 cells were transfected with a MEN1 gene construct (BON/M1C), and both RT-differential display and oligonucleotide microarrays were performed.
RESULTS: Three genes (SMARCC1, OVCA2 and SRp55) found to be differentially regulated on differential display were corroborated by northern blots on cell line RNA when comparing MEN1 transfected cells with control (empty vector transfection). When comparing two different passages of BON/M1C with two passages of vector control using oligonucleotide microarrays, 25 up-regulated genes and 64 down-regulated genes could be found using a cut-off of >or=1.6 times.
CONCLUSION: These findings might contribute to the understanding of the molecular pathways involved in MEN1 tumorigenesis, and may also provide knowledge of genes involved in sporadic endocrine tumorigenesis.

The BRCA1 gene is responsible for a high number of hereditary breast and ovarian cancers that cluster in families with a strong genetic predisposition. Despite intense investigation, the accumulating findings on BRCA1 biological functions have not yet been translated into specific therapeutic approaches, also due to the lack of suitable experimental models. The purpose of this study was to establish and characterize cell cultures and xenografts from patients with BRCA1 -/- ovarian cancers. We derived two ovarian cancer cell lines, termed PD-OVCA1 and PD-OVCA2, both from patients previously treated with chemotherapy, that propagate in SCID mice as well as in vitro for a limited number of passages. Both cell lines expressed cytokeratins and the CA125 tumour marker. A detailed molecular characterization highlighted both constitutive and somatic genetic events that abrogate BRCA1 gene function. Both cell lines were shown to lose the wild type BRCA1 allele; intriguingly, these deletions were apparently accompanied by gain of one or more copies of the mutant alleles. Finally, a genomic profile of major chromosomal aberrations was obtained by the Multiplex Ligation-dependent Probe Amplification (MLPA) technique, which disclosed chromosomal imbalances targeting specific genes in each cell line. The PD-OVCA1 and PD-OVCA2 ovarian cancer cell lines will provide a valuable tool for new experimental models for the study of BRCA1-associated tumour biology.

OVCA1, also known as DPH2L1, is a tumor suppressor gene associated with ovarian carcinoma and other tumors. Ovca1 homozygous mutant mice die at birth with developmental delay and cell-autonomous proliferation defects. Ovca1 heterozygous mutant mice are tumor-prone but rarely develop ovarian tumors. OVCA1 appears to be the homolog of yeast DPH2, which participates in the first biosynthetic step of diphthamide, by modification of histidine on translation elongation factor 2 (EF-2). Yeast dph2 mutants are resistant to diphtheria toxin, which catalyses ADP ribosylation of EF-2 at diphthamide. Thus, there appears to be growing evidence implicating alterations in protein translation with tumorigenesis.

Directional tag PCR subtractive hybridization was applied to construct a cDNA library generated from three different human osteosarcoma (OS) target cell lines (OHS, SaOS-2 and KPDXM) from which normal osteoblast (NO) sequences were subtracted. After two consecutive subtractive steps more than 98% of the common mRNAs species were depleted, leading to effective enrichment of the remaining target sequences. After differential screening of 960 clones, 81 candidates were further studied by Northern blot analysis and 73 represented separate mRNA species. Fifty-three of these showed enriched mRNA levels, of which 36 represented known and 17 not previously published cDNAs or EST sequences. The mRNAs showed a 1.4- to 504-fold enrichment compared to the mRNA levels in NO cells. The known mRNAs are: Ribosomal protein S11, KSP-37, Tethering factor SEC34, FXYD6, Alpha enolase, G-s-alpha, GPR85, DAF, RPL35A, GIF, TAPA-1, ANAPC11, DCI, hsp27, MRPS7 homolog, eIF p110 subunit, DPH2L, HMG-14, FB1 protein, chondroitin-6-sulphonase, calgizzarin, RNA polymerase II subunit, RPL13A, DHS, gp96, HHP2, acidic ribosomal phosphoprotein P2, ANT-2, ARF1, AFG3L2, SKD3, phosphoglucoisomerase, GST pi, CKI gamma 2, DNA polymerase delta small subunit and TRAP delta. Sections of human osteosarcoma biopsies and a xenograft were studied by in situ analysis. Seven cDNAs highly expressed in Northern blot analysis were tested. Their in situ expression differed between the xenograft and human sections as did that of collagen I. In the xenograft made from one of the target cell lines (OHS), a fair to strong representation of 3 cloned mRNAs was observed while collagen I mRNA was not detectable. We conclude that the molecular heterogeneity of these tumors is considerable. These results ought to have implications for future work to describe phenotypic subtypes with the aim of improving the diagnosis of human osteosarcomas.

Inherited mutations of the BRCA1 gene predispose to breast, ovarian, and other cancers. The role of the BRCA1 gene in the maintenance of chromosomal integrity is linked to a number of biological properties of its protein product, including transcriptional regulation. In the present study, we have used suppression subtractive hybridisation (SSH) to identify genes induced by BRCA1 by comparing control MCF7 breast carcinoma cells (driver) with MCF7 cells ectopically expressing BRCA1 (tester) and generated a forward subtracted cDNA library. We screened 500 putative positive clones from this library. Two hundred and ten of these clones were positive by differential screening with forward and reverse subtracted probes and the 65 cDNA clones which showed more than fivefold increase were selected for sequencing analysis. We clustered 46 different genes that share high homology with sequences in the GenBank/EMBL databases. Among these, 30 were genes whose function had been previously identified while the remaining 16 clones were genes with unknown functions. Of particular interest, BRCA1 gene induces the expression of genes encoding DNA repair proteins RAD21 and MSH2, ERBB2/HER2 interacting protein ERBIN, meningioma-associated protein MAC30, and a candidate ovarian tumour-suppressor OVCA1. Northern and Western blot analyses confirmed that the expression of these five genes are up-regulated following BRCA1 overexpression in MCF7 and UBR60-bcl2 cells. This is the first study reporting a set of BRCA1-induced genes in breast carcinoma cells by the SSH technique. We suggest that some known genes identified in this study may provide new insights into the tumour-suppressor function of BRCA1.

Retinoids, the natural and synthetic derivatives of vitamin A, have been shown to regulate the growth and differentiation of a wide variety of cell types and consequently have enormous potential as chemotherapeutic agents. We have previously identified 2 genes, termed OVCA1 and OVCA2, which are located in a small region showing a high frequency of allelic loss in breast and ovarian tumors and share a common exon. Recent studies have suggested that expression of OVCA1 may be influenced by retinoids. Therefore, we analyzed the expression of OVCA1 and OVCA2 in cells in response to treatment with all-trans retinoic acid (RA) and N-(4-hydroxyphenyl)retinamide (4HPR), or under conditions of low serum and confluence, to determine further the roles of OVCA1 and OVCA2 in cell growth, apoptosis and differentiation. We show that OVCA2 mRNA and protein are ubiquitously expressed and that they are downregulated in the lung cancer cell line Calu-6 after treatment with RA and 4HPR. In addition, we observed that OVCA2 protein is proteolytically degraded in response to RA and 4HPR treatment in a time- and dose-dependent manner in the promyelocytic leukemia cell line HL60. In contrast, expression of the candidate tumor suppressor OVCA1 was not downregulated by these treatments. Furthermore, we demonstrate that OVCA2 is evolutionarily conserved and shows regional homology with dihydrofolate reductases (DHFRs), specifically with hydrolase folds found in alpha-beta hydrolases. Our results are in contrast to a previous report and show that OVCA2, not OVCA1 mRNA and protein, is downregulated in response to RA and 4HPR.

Recent evidence indicates that inherited and acquired genetic mutations are the driving force behind carcinogenesis and cellular transformation. This review examines a number of proto-oncogenes and tumor suppressor genes that are associated with ovarian carcinomas, including p53, BRCA1, and BRCA2; mismatch repair genes such as hMSH2 and hMLH1; and PTEN, HER-2/neu, K-ras, fms, and AKT2. Novel genes recently implicated in ovarian tumorigenesis are discussed, including NOEY2, OVCA1, and PIK3CA. Although no singular gene alteration has been shown to initiate transformation in the ovarian epithelium, elucidation of the complex molecular and cellular mechanisms involving these known gene mutations may result in new clinical management strategies.

Allelic loss on chromosome 17p has been reported frequently in esophageal squamous cell carcinoma (ESCC) and generally encompasses the p53 locus at 17p13.1. However, a good correlation between allelic loss on 17p and mutation of p53 has not been found. This suggests the possibility that unknown tumor suppressor genes near p53 may be involved in the development of ESCC. To evaluate this possibility, we analyzed 30 microsatellite markers covering the entire short arm of chromosome 17 in 56 ESCC patients from a high risk population in northern China, including 34 with a family history of upper gastrointestinal (UGI) cancer and 22 without a family history of any cancer. Cancer lifestyle risk factors and clinical/pathological characteristics were also collected. We found frequent allelic loss (>/=65%) at 28 of the 30 markers evaluated in these ESCC patients. The highest frequencies of allelic loss (> or =80%) were found in three smaller regions: deletion region I located at 17p13.3-p13.2 (between D17S849 and D17S1828); deletion region II located at 17p13.2-p13.1 (between D13S938 and TP53); deletion region III located at 17p13.1-p12 (between D17S804 and D17S799). A number of genes have already been identified in these deleted regions, including: OVCA1, OVCA2 and HIC-1 in deletion region I; p53 in deletion region II; ZNF18, ZNF29, ALDH3 and ALDH10 in deletion region III. These results will help us direct future testing of candidate genes and narrow the search region for major new tumor suppressor genes that may play a role in the pathogenesis of ESCC.

Loss of all or part of one copy of chromosome 17p is very common in ovarian and breast tumors. OVCA1 is a candidate tumor suppressor gene mapping to a highly conserved region on chromosome 17p13.3 that shows frequent loss of heterozygosity in breast and ovarian carcinomas. Western blot analysis of extracts prepared from breast and ovarian carcinomas revealed reduced expression of OVCA1 compared with extracts from normal epithelial cells from these tissues. Subcellular localization studies indicate that OVCA1 is localized to punctate bodies scattered throughout the cell but is primarily clustered around the nucleus. Attempts to create cell lines that stably expressed OVCA1 from the cytomegalovirus promoter were generally unsuccessful in a variety of different cell lines. This reduction of colony formation was quantified in the ovarian cancer cell line A2780, where it was demonstrated that cells transfected with plasmids expressing OVCA1 had a 50-60% reduction in colony number as compared with appropriate controls, and only a few of these clones expressed OVCA1, albeit at low levels. The clones that expressed exogenous OVCA1 were found to have dramatically reduced rates of proliferation. Reduced growth rates correlated with an increased proportion of the cells in the G1 fraction of the cell cycle compared with the parental cell line and decreased levels of cyclin D1. The low levels of cyclin D1 appeared to be caused by an accelerated rate of cyclin D1 degradation. Overexpression of cyclin D1 was able to override OVCA1's suppression of clonal outgrowth. These results suggest that slight alterations in the level of OVCA1, such as would occur after reduction of chromosome 17p13.13 to hemizygosity, may result in cell cycle deregulation and promote tumorigenesis.

OBJECTIVES: To determine whether there is evidence for allelic imbalance (AI) on chromosome 17p13 in early-stage epithelial ovarian tumors.
METHODS: Studies of allelic imbalance were performed on 29 stage I or stage II epithelial ovarian cancers using 5 short tandem repeat polymorphic markers (STRPs) on chromosome 17p13 by polymerase chain reaction (PCR) amplification.
RESULTS: Sixteen of 29 (55%) tumors showed AI at one or more loci, including 7 of 29 (24%) tumors that showed distinct regions of AI. AI at p53 was present in only 9 of 25 (36%) informative tumors. A region of AI, defined by marker D17S654, close to candidate genes OVCA1 and OVCA2, was identified distal to p53 and occurred in 11 of 23 (48%) informative tumors. This region of AI also extended more distal to this locus, and included marker D17S695 where AI occurred in 11 of 26 (42%) informative tumors. Microsatellite instability was observed in 2 of 29 tumors.
CONCLUSIONS: This study supports the presence of at least one tumor suppressor gene on chromosome 17p13 distal to p53 that is involved in the early development of epithelial ovarian cancer. This study also suggests that the molecular analysis of early-stage epithelial ovarian cancers can provide important information on the genetic etiology of ovarian cancers.

Medulloblastoma is the most frequent paediatric brain tumour. Because of the uniform histology, a common genetic mechanism has been postulated. Loss of heterozygosity (LOH) studies support evidence that a candidate gene, which functions as a tumour-suppressor gene, is located in 17p13. Eighteen tumours were examined for loss of heterozygosity at 15 different loci at chromosome 17p. Nine of 18 (50%) tumours had allelic loss in 17p 13.3-13.2. The smallest region of overlap, which harbours the disease gene, includes markers from UT222 (D17S675) to UT49 (D17S731) and spans a region of less than 6 cM. Candidate genes within this region are HIC-1, a potential tumour-suppressor gene, and DPH2L, a gene that has been cloned from the ovarian critical region. The putative region excludes the p53 gene and the ABR gene, which have been favoured by others. LOH of chromosome 17p may be used as a new prognostic biological marker. Children with an allelic loss had a poorer prognosis than those patients without loss of heterozygosity (P<0.05).

A second tumor suppressor locus on 17p that is distinct from TP53 has been identified in brain, breast, lung, and ovarian tumors. Using allelic loss mapping and positional cloning methods, we have recently identified two novel genes, which we refer to as OVCA1 and OVCA2, that map to 17p13.3. The two genes are ubiquitously expressed and encode proteins of 443 and 227 amino acids, respectively, with no known functional motifs. Sequence comparison of OVCA1 and OVCA2 revealed extensive sequence identity and similarity to hypothetical proteins from Saccharomyces cerevisiae, Caenorhabditis elegans, and Rattus species. Northern blot analysis reveals that OVCA1 and OVCA2 mRNA were expressed in normal surface epithelial cells of the ovary, but the level of this transcript is significantly reduced or is undetectable in 92% (11/12) of the ovarian tumors and tumor cell lines analyzed. The location, high degree of amino acid conservation, and reduced expression in ovarian tumors and tumor cell lines suggest that decreased expression of these two genes contributes to ovarian tumorigenesis and should be considered candidate tumor suppressor genes.

Chromosome 17p13.3 is frequently deleted in human ovarian carcinoma, and the 15 kb critical region of deletion may contain a tumor suppressor gene. A 2.3 kb cDNA has been identified which spans 17 kb of genomic DNA, including 8.1 kb within the critical region, and thus is a candidate tumor suppressor gene. This highly conserved gene has significant sequence similarity to a yeast gene of unknown function and to one of the yeast enzymes in the diphthamide synthetic pathway, DPH2, that has a role in global protein synthesis regulation. This gene, named DPH2L (diphthamide biosynthesis protein 2-like), is expressed in multiple tissues and stages of development.

Multiple chromosome 17 loci may be involved in ovarian carcinogenesis. Fifty-seven sporadic ovarian epithelial tumors were examined for loss of heterozygosity at 15 loci on chromosomes 17p. Eighty % (39 of 49) of informative tumors had allelic loss in 17p13.3 at D17S30, D17S28, or both loci within this region, including 3 of 7 tumors of low malignant potential and 4 of 5 nonmetastatic carcinomas. The smallest region of overlapping deletions extends from D17S28 to D17S30, a distance of 15 kb. Furthermore, several tumors have breakpoints within the region detected by the D17S30 probe. Chromosome 17p13.3 genes with potential tumor suppressor function include HIC-1, DPH2L (N. J. Phillips et al. Isolation of a human diphthamide biosynthesis gene on chromosome 17p13.3, submitted for publication)/OVCA1, PEDF, and CRK. The HIC-1 coding sequence lies i kb centromeric to the D17S28-S17S30 region of deletion (M. Makos Wales et al., Nat. Med., 1:570-577, 1995) but remains a candidate because 5'-regulatory elements may lie within the critical region. Portions of the DPH2L/OVCA1 coding sequence lie within the D17S28-D17S30 interval. Somatic cell hybrid analysis places PEDF in an interval including D17S28, D17S30, and D17S54, whereas CRK is excluded from this interval. Chromosome 17p13.3 loss precedes TP53 and BRCA1 region deletions because the latter changes are see only in high-stage carcinomas. Microsatellite instability plays only a minor role in sporadic ovarian carcinogenesis because only 1 of 57 tumors showed this finding.