The tumor suppressor RASSF10 is upregulated upon contact inhibition and frequently epigenetically silenced in cancer.

The Ras association domain family (RASSF) comprises a group of tumor suppressors that are frequently epigenetically inactivated in various tumor entities and linked to apoptosis, cell cycle control and microtubule stability. In this work, we concentrated on the newly identified putative tumor suppressor RASSF10. Methylation analysis reveals RASSF10 promoter hypermethylation in lung cancer, head and neck (HN) cancer, sarcoma and pancreatic cancer. An increase in RASSF10 methylation from normal tissues, primary tumors to cancer cell lines was observed. Methylation was reversed by 5-aza-2'-deoxycytidine treatment leading to reexpression of RASSF10. We further show that overexpression of RASSF10 suppresses colony formation in cancer cell lines. In addition, RASSF10 is upregulated by cell-cell contact and regulated on promoter level as well as endogenously by forskolin, protein kinase A (PKA) and activator Protein 1 (AP-1), linking RASSF10 to the cAMP signaling pathway. Knockdown of the AP-1 member JunD interfered with contact inhibition induced RASSF10 expression. In summary, we found RASSF10 to be epigenetically inactivated by hypermethylation of its CpG island promoter in lung, HN, sarcoma and pancreatic cancer. Furthermore, our novel findings suggest that tumor suppressor RASSF10 is upregulated by PKA and JunD signaling upon contact inhibition and that RASSF10 suppresses growth of cancer cells.

RASSF1A interacts with and activates the mitotic kinase Aurora-A.

The RAS association domain family 1A (RASSF1A) gene is located at chromosome 3p21.3 within a specific area of common heterozygous and homozygous deletions. RASSF1A frequently undergoes promoter methylation-associated inactivation in human cancers. Rassf1a(-/-) mice are prone to both spontaneous and carcinogen-induced tumorigenesis, supporting the notion that RASSF1A is a tumor suppressor. However, it is not fully understood how RASSF1A is involved in tumor suppression pathways. Here we show that overexpression of RASSF1A inhibits centrosome separation. RASSF1A interacts with Aurora-A, a mitotic kinase. Surprisingly, knockdown of RASSF1A by siRNA led to reduced activation of Aurora-A, whereas overexpression of RASSF1A resulted in increased activation of Aurora-A, suggesting that RASSF1A is involved in Aurora-A activation. Like other Aurora-A activators, RASSF1A was also a substrate of Aurora-A in vitro. The failure of recombinant RASSF1A to activate recombinant Aurora-A indicates that RASSF1A may not activate Aurora-A directly and suggests that RASSF1A may function as a scaffold to bring together Aurora-A and its activator(s). Inhibition of centrosome separation by RASSF1A overexpression is most likely a consequence of hyperstabilization of microtubules by this protein.

Frequent intra-tumoural heterogeneity of promoter hypermethylation in malignant melanoma.

To investigate intra-tumoural coexistence and heterogeneity of aberrant promoter hypermethylation of different tumour suppressor genes in melanoma, we analyzed the intra-tumoural distribution of promoter methylation of RASSF1A, p16, DAPK, MGMT, and Rb in 339 assays of 34 tumours (15 melanoma primaries, 19 metastases) by methylation-specific PCR, correlation to histopathology and RASSF1A expression. We detected promoter hypermethylation of at least one gene in 74% of tumours (30%, 52%, 33%, 20%, and 40% for RASSF1A, p16, DAPK, MGMT and Rb, respectively). 70% of the cases exhibited an inhomogeneous methylation pattern (17%, 45%, 33%, 20%, and 40% for RASSF1A, p16, DAPK, MGMT and Rb, respectively). Samples from the core of the tumours represented the methylation state of the whole tumours more accurately than the periphery. Local intra-tumoural correlation was found between the promoter hypermethylation state of p16 and Rb or p16 and DAPK, or epitheloid tumour cell type and RASSF1A or p16 methylation. Mitosis rate and sex was correlated with methylation of RASSF1A. Histological results confirmed that promoter hypermethylation of RASSF1A led to aberrant expression patterns. We conclude that intra-tumoural inhomogeneity of promoter hypermethylation is frequent in melanoma and this supports the hypothesis of clonal instability during progression of melanomas. In prognosis studies, missing the intra-tumoural sample representativeness may result in a reduction of the sensitivities or specificities.

Frequent epigenetic inactivation of cystatin M in breast carcinoma.

Cystatin M is a potent endogenous inhibitor of lysosomal cysteine proteases. In breast carcinoma, cystatin M expression is frequently downregulated. It has been shown that cystatin M expression suppressed growth and migration of breast cancer cells. We examined the methylation status of the CpG island promoter of cystatin M in four breast cancer cell lines (MDAMB231, ZR75-1, MCF7 and T47D), in 40 primary breast carcinoma and in corresponding normal tissue probes by combined bisulphite restriction analysis. To investigate the effects of cystatin M expression on the growth of breast carcinoma, cystatin M was transfected in T47D. The cystatin M promoter was highly methylated in all four-breast cancer cell lines. Primary breast tumours were significantly more frequently methylated compared to normal tissue samples (60 vs 25%; P=0.006 Fisher's exact test). Treatment of breast cancer cells with 5-aza-2'-deoxycytidine (5-Aza-CdR), reactivated the transcription of cystatin M. Transfection of breast carcinoma cells with cystatin M caused a 30% decrease in colony formation compared to control transfection (P=0.002). Our results show that cystatin M is frequently epigenetically inactivated during breast carcinogenesis and cystatin M expression suppresses the growth of breast carcinoma. These data suggest that cystatin M may encode a novel epigenetically inactivated candidate tumour suppressor gene.

Identification of RASSF1A modulated genes in nasopharyngeal carcinoma.

RASSF1A is a tumor suppressor gene on 3p21.3 frequently inactivated by promoter hypermethylation in nasopharyngeal carcinoma (NPC). To identify RASSF1A target genes in NPC, we have investigated the expression profile of the stable RASSF1A transfectants and controls by high-density oligonucleotide array. A total of 57 genes showed differential expression in the RASSF1A-expressing cells. These RASSF1A target genes were involved in multiple cellular regulatory processes such as transcription, signal transduction, cell adhesion and RNA processing. The RASSF1A-modulated expression of eight selected genes with the highest fold changes (ATF5, TCRB, RGS1, activin betaE, HNRPH1, HNRPD, Id2 and CKS2) by RASSF1A was confirmed in both stable and transient transfectants. Compared with the RASSF1A transfectants, an inverse expression pattern of activin betaE, Id2 and ATF5 was shown in the immortalized nasopharyngeal epithelial cells treated with siRNA against RASSF1A. The findings imply that the expression of activin betaE, Id2 and ATF5 was tightly regulated by RASSF1A and may associate with its tumor suppressor function. Strikingly, overexpression of Id2 is common in NPC and RASSF1A-induced repression of Id2 was mediated by the overexpression of activin betaE. The results suggest a novel RASSF1A pathway in which both activin betaE and Id2 are involved.

Promoter methylation and loss of coding exons of the fragile histidine triad (FHIT) gene in intrahepatic cholangiocarcinomas.

AIMS: About 10-30% of primary liver cancers represent intrahepatic cholangiocarcinomas (IHCC). Since chromosomal losses of 3p are detectable in about 40% of cholangiocarcinomas our study aimed at the identification of mechanisms leading to functional deletion of tumor suppressor genes in this region. Our efforts focussed on genomic losses and epigenetic inactivation of two tumor suppressor genes, the fragile histidine triad (FHIT) and the ras association domain family 1 (RASSF1A) genes, both located on the short arm of chromosome 3. METHODS: Methylation-specific PCR (MSP) and combined bisulfite-dependent restriction analysis (COBRA) were applied to detect epigenetic silencing of gene promoters. Genomic duplex PCR was used to identify exon losses of the FHIT gene. Nineteen paraffin-embedded samples of intrahepatic cholangiocarcinomas were studied. RESULTS: Here we report for the first time that in addition to frequent losses of the exons 5 and 6, hypermethylation of the FHIT promoter occured in a significant portion of IHCC. Methylation specific PCR (MSP) detected epigenetic inactivation of the FHIT/FRA3B locus in 8 of 19 (42%) cases. Combined bisulfite restriction analysis (COBRA) revealed that high levels of methylated FHIT promoter sequences were present in 6 of the 8 methylation positive samples. In agreement with previous reports MSP identified hypermethylation of the RASSF1A gene in 13 of 19 (68%) IHCC specimens examined. CONCLUSIONS: Epigenetic silencing of the FHIT tumor suppressor gene is a novel inactivation mechanism to be considered in the development of intrahepatic cholangiocarcinomas. However, a statistically significant inverse correlation between K-Ras activation and RASSF1A inactivation was not found.

Methylation of the tumor suppressor gene RASSF1A in human tumors.

Loss of heterozygosity of a segment at 3p21.3 is frequently observed in lung cancer and several other carcinomas. We have identified the Ras-association domain family 1A gene (RASSF1A), which is localized at 3p21.3 in a minimum deletion sequence. De novo methylation of the RASSF1A promoter is one of the most frequent epigenetic inactivation events detected in human cancer and leads to silencing of RASSF1A expression. Hypermethylation of RASSF1A was frequently found in most major types of human tumors including lung, breast, prostate, pancreas, kidney, liver, cervical, thyroid and many other cancers. The detection of RASSF1A methylation in body fluids such as serum, urine, and sputum promises to be a useful marker for early cancer detection. The functional analysis of RASSF1A reveals a potential involvement of this protein in apoptotic signaling, microtubule stabilization, and cell cycle progression.

The tumor suppressor RASSF1A in human carcinogenesis: an update.

Loss of heterozygosity of the small arm of chromosome 3 is one of the most common alterations in human cancer. Most notably, a segment in 3p21.3 is frequently lost in lung cancer and several other carcinomas. We and others have identified a novel Ras effector at this segment, which was termed Ras Association Domain family 1 (RASSF1A) gene. RASSF1 consists of two main variants (RASSF1A and RASSF1C), which are transcribed from distinct CpG island promoters. Aberrant methylation of the RASSF1A promoter region is one of the most frequent epigenetic inactivation events detected in human cancer and leads to silencing of RASSF1A. Hypermethylation of RASSF1A was commonly observed in primary tumors including lung, breast, pancreas, kidney, liver, cervix, nasopharyngeal, prostate, thyroid and other cancers. Moreover, RASSF1A methylation was frequently detected in body fluids including blood, urine, nipple aspirates, sputum and bronchial alveolar lavages. Inactivation of RASSF1A was associated with an advanced tumor stage (e.g. bladder, brain, prostate, gastric tumors) and poor prognosis (e.g. lung, sarcoma and breast cancer). Detection of aberrant RASSF1A methylation may serve as a diagnostic and prognostic marker. The functional analyses of RASSF1A reveal an involvement in apoptotic signaling, microtubule stabilization and mitotic progression. The tumor suppressor RASSF1A may act as a negative Ras effector inhibiting cell growth and inducing cell death. Thus, RASSF1A may represent an epigenetically inactivated bona fide tumor suppressor in human carcinogenesis.

Frequent promoter methylation of tumor-related genes in sporadic and men2-associated pheochromocytomas.

Hypermethylation of CpG island promoters is associated with transcriptional inactivation of tumor suppressor genes in neoplasia. Inactivation of p16 and Pten was related to the development of pheochromocytomas. In this report, we investigated the methylation status of the p16INK4a cell cycle inhibitor gene and other prominent tumor-related genes ( PTEN, RASSF1 A, CDH1, MSH2, MLH1, VHL, and TIMP3) in sporadic and multiple endocrine neoplasia type 2 (MEN2) pheochromocytomas by methylation-specific PCR. Hypermethylation was detected in 48 % of pheochromocytomas for RASSF1 A, 24 % for p16, 36 % for MSH2, 16 % for CDH1, and 8 % for PTEN. No VHL, MLH1, and TIMP3 methylation was observed. Interestingly, the frequency of p16 inactivation in familial tumors was higher (5 out of 12, 42 %) than in sporadic tumors (1 out of 13, 8 %; p = 0.047) and RASSF1 A inactivation was more common in the hereditary tumors (58 %) compared to the sporadic tumors (38 %). Combined methylation of RASSF1 A and p16 was found only in MEN2-related pheochromocytomas. Thus, a subset of hereditary pheochromocytomas displays preferential methylation of p16 and RASSF1 A.

Epigenetic inactivation of the Ras-association domain family 1 (RASSF1A) gene and its function in human carcinogenesis.

The Ras GTPases are a superfamily of molecular switches that regulate cellular proliferation and apoptosis in response to extra-cellular signals. The regulation of these pathways depends on the interaction of the GTPases with specific effectors. Recently, we have cloned and characterized a novel gene encoding a putative Ras effector: the Ras-association domain family 1 (RASSF1) gene. The RASSF1 gene is located in the chromosomal segment of 3p21.3. The high allelic loss in a variety of cancers suggested a crucial role of this region in tumorigenesis. At least two forms of RASSF1 are present in normal human cells. The RASSF1A isoform is highly epigenetically inactivated in lung, breast, ovarian, kidney, prostate, thyroid and several other carcinomas. Re-expression of RASSF1A reduced the growth of human cancer cells supporting a role for RASSF1 as a tumor suppressor gene. RASSF1A inactivation and K-ras activation are mutually exclusive events in the development of certain carcinomas. This observation could further pinpoint the function of RASSF1A as a negative effector of Ras in a pro-apoptotic signaling pathway. In malignant mesothelioma and gastric cancer RASSF1A methylation is associated with virus infection of SV40 and EBV, respectively, and suggests a causal relationship between viral infection and progressive RASSF1A methylation in carcinogenesis. Furthermore, a significant correlation between RASSF1A methylation and impaired lung cancer patient survival was reported, and RASSF1A silencing was correlated with several parameters of poor prognosis and advanced tumor stage (e.g. poor differentiation, aggressiveness, and invasion). Thus, RASSF1A methylation could serve as a useful marker for the prognosis of cancer patients and could become important in early detection of cancer.

Hypermethylation of the CpG island of the RASSF1A gene in ovarian and renal cell carcinomas.

Homozygous deletion and loss of heterozygosity (LOH) at chromosome 3p21 have been observed in several types of human cancer including lung cancer and breast cancer. In previous work, we cloned and identified the human RAS association domain family 1A gene (RASSF1A) from the lung tumor suppressor locus 3p21.3. The CpG island and promoter region of RASSF1A is highly methylated in primary lung and breast tumors. In this study, we analyzed the methylation status of the promoter region of RASSF1A in 3 different tumor types: colon, ovarian and renal cell carcinoma. In colon cancers, 3 out of 26 tumor tissues (12%) were methylated at the CpG island of the RASSF1A gene. Renal and ovarian cancers showed a much higher frequency of methylation. For ovarian tumors, 8 out of 20 tumors (40%) were methylated. In renal cell carcinomas, 18 out of 32 cases (56%) were methylated. For all tumor types, none of the available normal tissues was methylated. This data suggests that methylation of the CpG island and promoter of the RASSF1A gene is common not only in lung and breast tumors but also in renal cell carcinoma and ovarian cancer.

The CpG island of the novel tumor suppressor gene RASSF1A is intensely methylated in primary small cell lung carcinomas.

Loss of heterozygosity at 3p21.3 occurs in more than 90% of small cell lung carcinomas (SCLCs). The Ras association domain family 1 (RASSF1) gene cloned from the lung tumor suppressor locus 3p21.3 consists of two major alternative transcripts, RASSF1A and RASSF1C. Epigenetic inactivation of isoform A (RASSF1A) was observed in 40% of primary non-small cell lung carcinomas and in several tumor cell lines. Transfection of RASSF1A suppressed the growth of lung cancer cells in vitro and in nude mice. Here we have analysed the methylation status of the CpG island promoters of RASSF1A and RASSF1C in primary SCLCs. In 22 of 28 SCLCs (=79%) the promoter of RASSF1A was highly methylated at all CpG sites analysed. None of the SCLCs showed evidence for methylation of the CpG island of RASSF1C. The results suggest that hypermethylation of the CpG island promoter of the RASSF1A gene is associated with SCLC pathogenesis.

Hypermethylation of the cpG island of Ras association domain family 1A (RASSF1A), a putative tumor suppressor gene from the 3p21.3 locus, occurs in a large percentage of human breast cancers.

The human Ras association domain family 1A gene (RASSF1A), recently cloned from the lung tumor suppressor locus 3p21.3, was shown to be hypermethylated in primary lung tumors, and reexpression of RASSF1A suppressed the growth of lung cancer cells (R. Dammann et al., Nat. Genet., 25: 315-319, 2000). In this study, we analyzed the expression and possible alterations of RASSF1A in breast cancer. In five breast cancer cell lines (MCF7, MDAMB157, MDAMB231, T47D, and ZR75-1), the CpG island and promoter of RASSF1A was completely methylated, and transcription was silenced. Treatment with the DNA methylation inhibitor 5-aza-2'-deoxycytidine reactivated the expression of RASSF1A. In 28 of 45 (62%) primary mammary carcinomas, the promoter of RASSF1A was highly methylated at its CpG sites. Coincident with methylation, the expression level of RASSF1A was lower in tumors compared with matching normal tissues. No somatic mutations were found in the samples that were unmethylated. The data suggest that hypermethylation of the CpG island promoter of RASSF1A may play an important role in breast cancer pathogenesis.

Epigenetic inactivation of a RAS association domain family protein from the lung tumour suppressor locus 3p21.3.

Allelic loss at the short arm of chromosome 3 is one of the most common and earliest events in the pathogenesis of lung cancer, and is observed in more than 90% of small-cell lung cancers (SCLCs) and in 50-80% of non-small-cell lung cancers (NSCLCs). Frequent and early loss of heterozygosity and the presence of homozygous deletions suggested a critical role of the region 3p21.3 in tumorigenesis and a region of common homozygous deletion in 3p21.3 was narrowed to 120 kb (ref. 5). Several putative tumour-suppressor genes located at 3p21 have been characterized, but none of these genes appear to be altered in lung cancer. Here we describe the cloning and characterization of a human RAS effector homologue (RASSF1) located in the 120-kb region of minimal homozygous deletion. We identified three transcripts, A, B and C, derived from alternative splicing and promoter usage. The major transcripts A and C were expressed in all normal tissues. Transcript A was missing in all SCLC cell lines analysed and in several other cancer cell lines. Loss of expression was correlated with methylation of the CpG-island promoter sequence of RASSF1A. The promoter was highly methylated in 24 of 60 (40%) primary lung tumours, and 4 of 41 tumours analysed carried missense mutations. Re-expression of transcript A in lung carcinoma cells reduced colony formation, suppressed anchorage-independent growth and inhibited tumour formation in nude mice. These characteristics indicate a potential role for RASSF1A as a lung tumour suppressor gene.

3-Methyladenine-DNA glycosylase (MPG protein) interacts with human RAD23 proteins.

Human 3-methyladenine-DNA glycosylase (MPG protein) initiates base excision repair by severing the glycosylic bond of numerous damaged bases. In comparison, homologues of the Rad23 proteins (hHR23) and the hXPC protein are involved in the recognition of damaged bases in global genome repair, a subset of nucleotide excision repair. In this report, we show that the hHR23A and -B also interact with the MPG protein and can serve as accessory proteins for DNA damage recognition in base excision repair. Furthermore, the MPG.hHR23 protein complex elevates the rate of MPG protein-catalyzed excision from hypoxanthine-containing substrates. This increased excision rate is correlated with a greater binding affinity of the MPG protein-hHR23 protein complex for damaged DNA. These data suggest that the hHR23 proteins function as universal DNA damage recognition accessory proteins in both of these major excision repair pathways.

Sequence and time-dependent deamination of cytosine bases in UVB-induced cyclobutane pyrimidine dimers in vivo.

The mutational specificity of UV-light is characterized by an abundance of C to T transition mutations at dipyrimidines containing cytosine or 5-methylcytosine. A significant percentage of these mutations are CC to TT double transitions. Of the major types of UV-induced DNA lesions, the cis-syn cyclobutane pyrimidine dimers (CPDs) are thought to be the most mutagenic lesions, at least in mammalian cells. It has been proposed that the CPDs become mutagenic perhaps only after cytosine bases within these dimers deaminate to uracil and the resulting U-containing photolesions are correctly bypassed by DNA polymerases. In order to assess the significance of this proposed mutagenic mechanism, we have developed two methods to specifically measure deaminated CPDs in UV-irradiated human cells or DNA. The first method is based on enzymatic photoreversal of CPDs, followed by cleavage of the DNA with uracil DNA glycosylase, an AP lyase activity, and ligation-mediated PCR to map the resulting strand breaks. The second method, which can be used to detect double deamination events (CC to UU), is PCR amplification of photolyase-treated DNA using primers complemetary to the deaminated sequences. We have measured deamination events in the human p53 gene, which contains a large percentage of C to T transitions in skin cancers. The deamination reactions are specific for cytosine within CPDs, are negligible immediately after irradiation, and are time-dependent and DNA sequence context-dependent. Twenty four hours after irradiation of human fibroblasts with UVB light, between 10 and 60% of most CPD signals are converted to the deaminated form, depending on the sequence. Significant deamination occurs at skin cancer mutation sites in the p53 gene. Double deamination also occurs and this reaction can involve dimers containing 5-methylcytosine or cytosine. These double events are expected to occur more frequently in cells with a DNA repair defect because there is more time for deamination in unrepaired lesions. This may explain the relatively high frequency of CC to TT mutations in skin cancers from xeroderma pigmentosum patients. In summary, these novel detection techniques demonstrate that deamination of cytosine in pyrimidine dimers is a significant event that most likely contributes to the mutational specificity of UVB irradiation in human cells.

Cloning and characterization of the human RNA polymerase I subunit hRPA40.

The cloning of the human RNA polymerase I 40 kDa subunit, and the comparison of its amino acid sequence to other related RNA polymerase subunits are described. The amino acid sequence of hRPA40 has high homology to the mouse RNA polymerase I 40 kDa subunit (93%), to two Arabidopsis thaliana subunits (47%), the yeast RPC40 subunit (46%) and the human RNA polymerase II hRPB33 subunit (40%). Southern blot analysis shows that this gene is single copy and Northern blot analysis indicates that the mRNA of 1.3 kb is expressed in different cell types.

Lack of gene- and strand-specific DNA repair in RNA polymerase III-transcribed human tRNA genes.

UV light induces DNA lesions which are removed by nucleotide excision repair. Genes transcribed by RNA polymerase II are repaired faster than the flanking chromatin, and the transcribed strand is repaired faster than the coding strand. Transcription-coupled repair is not seen in RNA polymerase I-transcribed human rRNA genes. Since repair of genes transcribed by RNA polymerase III has not been analyzed before, we investigated DNA repair of tRNA genes after irradiation of human fibroblasts with UVC. We studied the repair of UV-induced cyclobutane pyrimidine dimers at nucleotide resolution by ligation-mediated PCR. A single-copy gene encoding selenocysteine tRNA, a tRNA valine gene, and their flanking sequences were analyzed. Protein-DNA footprinting showed that both genes were occupied by regulatory factors in vivo, and Northern blotting and nuclear run-on analysis of the tRNA indicated that these genes were actively transcribed. We found that both genes were repaired slower than RNA polymerase II-transcribed genes. No major difference between repair of the transcribed and the coding DNA strands was detected. Transcribed sequences of the tRNA genes were not repaired faster than flanking sequences. Indeed, several sequence positions in the 5' flanking region of the tRNA(Val) gene were repaired more efficiently than the gene itself. These results indicate that unlike RNA polymerase II, RNA polymerase III has no stimulatory effect on DNA repair. Since tRNA genes are covered by the regulatory factor TFIIIC and RNA polymerase III, these proteins may actually inhibit the DNA's accessibility to repair enzymes.