Epigenetic inactivation of RASSF1A candidate tumor suppressor gene at 3p21.3 in brain tumors

The human Ras association domain family 1A (RASSF1A) gene, recently isolated from the lung and breast tumor suppressor locus 3p21.3, is highly methylated in primary lung, breast, nasopharyngeal and other tumors, and re-expression of RASSF1A suppresses the growth of several types of cancer cells. Epigenetic inactivation of RASSF1A by promoter hypermethylation is also important in the development of several human cancers. The methylation status of the promoter region of RASSF1A was analysed in primary brain tumors and glioma cell lines by methylation-specific polymerase chain reaction. In primary brain tumors, 25 of 46 (54.3%) gliomas and five of five (100%) medulloblastomas showed RASSF1A methylation. In benign tumors, only one of 10 (10%) schwannomas and two of 12 (16.7%) meningiomas showed RASSF1A methylation. The RASSF1A promoter region was methylated in all four glioma cell lines. RASSF1A was re-expressed in all methylated cell lines after treatment with the demethylating agent 5-aza-2'-deoxycytidine. Methylation of the promoter CpG islands of the RASSF1A may play an important role in the pathogenesis of glioma and medulloblastoma.     

RAS相关家族1A基因在胃癌中的表达和启动子甲基化

目的分析散发性胃癌中RAS相关家族1A基因(RASSF1A基因)的表达、突变和启动子甲基化状况,探讨RASSF1A基因在胃癌发生、发展中的意义.方法采用定量PCR、RT-PCR和SSCP的检测90例胃癌组织和30例相应癌旁正常组织中RASSF1A基因表达水平以及基因突变的情况;采用甲基化特异性PCR (MSP)方法检测RASSF1A基因启动子甲基化情况.结果 90例胃癌中有52例(57.8%)RASSF1A无表达或表达低下.RASSF1A无表达或表达低下和肿瘤细胞的分化(P<0.05)以及分期(P<0.001)相关,但是和肿瘤的浸润深度以及淋巴结转移不相关(P>0.05).90例胃癌中52例启动子发生甲基化(57.8%),其中90.3%(47/52)的RASSF1A无表达或表达低下组织中检测到RASSF1A基因启动子的甲基化,然而癌旁正常组织未发现有RASSF1A基因启动子的甲基化,SSCP没有发现任何突变.结论胃癌中存在较多的启动子异常甲基化造成RASSF1A基因失活,这可能是胃癌发生发展的因素之一.     

NORE1A,a homologue of RASSF1A tumour suppressor gene is inactivated in human cancers

We recently demonstrated that RASSF1A, a new tumour-suppressor gene located at 3p21.3 is frequently inactivated by promoter region hypermethylation in a variety of human cancers including lung, breast, kidney and neuroblastoma. We have identified another member of the RASSF1 gene family by in silico sequence analysis using BLAST searches. NORE1 located at 1q32.1 exists in three isoforms (NORE1Aalpha, NORE1Abeta and NORE1B). Both NORE1A and NORE1B isoforms have separate CpG islands spanning their first exons. NORE1Aalpha Produces a 418 aa protein containing a Ras-association (RA) domain and a diacylglycerol (DAG) binding domain. NORE1Abeta produces a C-terminal truncation of the RA domain. NORE1B also contains the RA domain but not the DAG domain. NORE1 is the human homologue of the mouse Ras effector Nore1. No inactivating somatic mutations were found in lung tumour lines; however, NORE1A promoter region CpG island was hypermethylated in primary tumours and tumour cell lines. NORE1A promoter was methylated in 10/25 breast, 4/40 SCLC, 3/17 NSCLC, 1/6 colorectal and 3/9 kidney tumour cell lines, while NORE1B promoter was unmethylated in the same tumour cell lines. While 24% (6/25) of primary NSCLC underwent NORE1A methylation, methylation in SCLC was a rare event (0/22); (P = 0.0234). NORE1A expression in tumour cell lines was reactivated after treatment with a demethylating agent. There was no correlation between NORE1A and RASSF1A methylation status in NSCLC. Our results demonstrate that NORE1A is inactivated in a subset of human cancers by CpG island promoter hypermethylation, and in lung cancer this hypermethylation may be histological type specific.     

CpG island promoter hypermethylation of a novel Ras-effector gene RASSF2A is an early event in colon carcinogenesis and correlates inversely with K-ras mutations

We report in silico identification and characterisation of a novel member of the ras association domain family 1 (RASSF1)/NORE1 family, namely, RASSF2, located at chromosomal region 20p13. It has three isoforms, all contain a ras association domain in the C-terminus. The longest isoform RASSF2A contains a 5' CpG island. RASSF2A was cloned from a brain cDNA library and directly sequenced, confirming the genomic gene structure. In previous reports, we and others have demonstrated that RASSF1A is epigenetically inactivated in a variety of cancers, including sporadic colorectal cancer (CRC). In the present report, we analysed the methylation status of RASSF2A promoter region CpG island in sporadic CRC and compared it to K-ras mutation status. RASSF2A promoter region CpG island was hypermethylated in a majority of colorectal tumour cell lines (89%) and in primary colorectal tumours (70%), while DNA from matched normal mucosa was found to be unmethylated (tumour-specific methylation). RASSF2A expression was reactivated in methylated tumour cell lines after treatment with 5-aza 2-deoxycytidine. RASSF2A methylation is an early event, detectable in 7/8 colon adenomas. Furthermore, 75% of colorectal tumours with RASSF2A methylation had no K-ras mutations (codons, 12 and 13) (P=0.048), Fisher's exact test). Our data demonstrate that RASSF2A is frequently inactivated in CRCs by CpG island promoter hypermethylation, and that epigenetic (RASSF2A) and genetic (K-ras) changes are mutually exclusive and provide alternative pathways for affecting Ras signalling.     

Methylation associated inactivation of RASSF1A from region 3p21.3 in lung, breast and ovarian tumours

Previously we analysed overlapping homozygous deletions in lung and breast tumours/tumour lines and defined a small region of 120 kb (part of LCTSGR1) at 3p21.3 that contained putative lung and breast cancer tumour suppressor gene(s) (TSG). Eight genes including RASSF1 were isolated from the minimal region. However, extensive mutation analysis in lung tumours and tumour lines revealed only rare inactivating mutations. Recently, de novo methylation at a CpG island associated with isoform A of RASSF1 (RASSF1A) was reported in lung tumours and tumour lines. To investigate RASSF1A as a candidate TSG for various cancers, we investigated: (a) RASSF1A methylation status in a large series of primary tumour and tumour lines; (b) chromosome 3p allele loss in lung tumours and (c) RASSF1 mutation analysis in breast tumours. RASSF1A promoter region CpG island methylation was detected in 72% of SCLC, 34% of NSCLC, 9% of breast, 10% of ovarian and 0% of primary cervical tumours and in 72% SCLC, 36% NSCLC, 80% of breast and 40% of ovarian tumour lines. In view of the lower frequency of RASSF1 methylation in primary breast cancers we proceeded to RASSF1 mutation analysis in 40 breast cancers. No mutations were detected, but six single nucleotide polymorphisms were identified. Twenty of 26 SCLC tumours with 3p21.3 allelic loss had RASSF1A methylation, while only six out of 22 NSCLC with 3p21.3 allele loss had RASSF1A methylation (P=0.0012), one out of five ovarian and none out of six cervical tumours with 3p21.3 loss had RASSF1A methylation. These results suggest that (a) RASSF1A inactivation by two hits (methylation and loss) is a critical step in SCLC tumourigenesis and (b) RASSF1A inactivation is of lesser importance in NSCLC, breast, ovarian and cervical cancers in which other genes within LCTSGR1 are likely to be implicated.     

Detection of RASSF1A aberrant promoter hypermethylation in sputum from chronic smokers and ductal carcinoma in situ from breast cancer patients

The newly identified 3p21.3 tumour suppressor gene RASSF1A is methylated in the majority of primary lung tumours, lung tumour cell lines and in a variable percentage of breast tumours. To determine the extent of RASSF1A promoter hypermethylation in early lung tumorigenesis, we analysed sputum samples from lung cancer patients and from current and former smokers using a sensitive methylation-specific PCR (MSP) technique. We also analysed RASSF1A promoter region hypermethylation in trios of normal breast/invasive ductal breast carcinoma/ductal carcinoma in situ (DCIS) from breast cancer patients and DCIS without invasive cancer. We found that 50% of small cell lung cancer (SCLC) and 21% of non-small cell lung cancer (NSCLC) patients had RASSF1A methylation, while one of two former smokers and four of 13 current smokers demonstrated RASSF1A methylation in sputum. Furthermore, two of the four current smokers and one former smoker showing RASSF1A methylation in their sputum developed cancer within 12-14 months of bronchoscopy. In our breast cancer trios, RASSF1A promoter hypermethylation was detected in 65% of invasive cancers, in 42% of corresponding DCIS but in none of the normal breast samples. In addition, we found that three out of 10 DCIS without invasive breast cancer also underwent RASSF1A promoter hypermethylation. Our findings suggest that RASSF1A promoter region hypermethylation may be a useful molecular marker for early detection of lung cancer. Furthermore, since RASSF1A promoter hypermethylation was detected in ductal carcinoma in situ, inactivation of RASSF1A may be an early event in breast tumorigenesis.     

Frequent RASSF1A promoter hypermethylation and K-ras mutations in pancreatic carcinoma

Recently, we have characterized the Ras association domain family 1A gene (RASSF1A) at the segment 3p21.3, which is frequently lost in variety of human cancers and epigenetically inactivated in many types of primary tumors, such as lung, breast, kidney, prostate and thyroid carcinomas. Here, we investigated the methylation status of the RASSF1A CpG island promoter in the pathogenesis of pancreatic cancer. RASSF1A hypermethylation was detected in 29 out of 45 (64%) primary adenocarcinomas, in 10 out of 12 (83%) endocrine tumors and in eight out of 18 (44%) pancreatitis samples. In seven out of eight pancreas cancer cell lines, RASSF1A was silenced and was retranscribed after treatment with 5-aza-2'-deoxycytidine. Additionally, we analysed the aberrant methylation frequency of cell cycle inhibitor p16(INK4a) and K-ras gene mutations in the pancreatic samples. p16 inactivation was detected in 43% of adenocarcinomas, in 17% of neuroendocrine tumors, in 18% of pancreatitis and in 63% of pancreas cancer cell lines. K-ras mutations were detected in 16 out of 45 (36%) primary adenocarcinomas. Pancreatic adenocarcinomas with K-ras mutation have significantly less RASSF1A methylation and vice versa (P=0.001, chi(2) test). In conclusion, our data indicate that inactivation of the RASSF1A gene is a frequent event in pancreatic cancer and suggest an inverse correlation between RASSF1A silencing and K-ras activation.     

Frequent hypermethylation of MST1 and MST2 in soft tissue sarcoma

The RASSF1A tumor suppressor is involved in regulation of apoptosis and cell cycle progression. RASSF1A is localized to microtubules and binds the apoptotic kinases MST1 and MST2. It has been shown that this interaction is mediated by the Sav-RASSF-Hpo domain, which is an interaction domain characterized for the Drosophila proteins Sav (human WW45), Hpo (human MST1 and MST2) and Warts/LATS (large tumor suppressor). Previously, we have reported that RASSF1A hypermethylation occurs frequently in soft tissue sarcoma and is associated with an unfavorable prognosis for cancer patients. In our study, we performed methylation analysis of the CpG island promoter of MST1, MST2, WW45, LATS1 and LATS2 in soft tissue sarcomas by methylation-specific PCR. No or a very low methylation frequency was detected for WW45, LATS1 and LATS2 (<7%). In 19 out of 52 (37%) sarcomas, a methylated promoter of MST1 was detected and 12 out of 60 (20%) samples showed methylation of the MST2 promoter. Methylation status of MST1 was confirmed by bisulfite sequencing. In tumors harboring a methylated promoter of MST1, a reduction of MST1 expression was observed by RT-PCR. In leiomyosarcomas, MST1 and MST2 or RASSF1A methylation were mutually exclusive (P = 0.007 and P = 0.025, respectively). Surprisingly, a significantly increased risk for tumor-related death was found for patients with an unmethylated MST1 promoter (P = 0.036). In summary, our results suggest that alteration of the Sav-RASSF1-Hpo tumor suppressor pathway may occur through hypermethylation of the CpG island promoter of MST1, MST2 and/or RASSF1A in human sarcomas.     

A methylated oligonucleotide induced methylation of GSTP1 promoter and suppressed its expression in A549 lung adenocarcinoma cells

Glutathione S-transferase P1 (GSTP1) belongs to xenobiotic enzymes, and is supposed to contribute to chemoresistance. Though it was reported that GSTP1 gene is suppressed by cytosine-guanine (CpG) island methylation of its promoter, this promoter is not strongly methylated and GSTP1 protein is highly expressed in lung cancer. We intended to induce methylation of GSTP1 CpG island by using a methylated sense oligonucleotide complementary to this region. When we transduced the methylated oligonucleotides to A549 lung adenocarcinoma cells, methylation of the GSTP1 promoter and reduction of GSTP1 expression was induced, cell viability was reduced; however, chemoresistance against cisplatin has not clearly changed.