肿瘤候选抑制基因RASSF1A

新克隆的RASSF1A基因位于3p21.3,是新的肿瘤候选抑制基因,能明显抑制肿瘤细胞生长.RASSF1A失表达见于多种实性肿瘤组织,与RASSF1A启动子甲基化密切相关.RASSF1A启动子甲基化检测可能是很有用的临床指标.     

鼻咽鳞癌组织RASSF1A基因表达失活及其临床意义的探讨

目的:研究鼻咽鳞癌组织中的抑癌基因RASSF1A的表达及其基因启动子区异常甲基化的情况.并分析DNA异常甲基化与鼻咽鳞癌临床病理因素之间的关系.方法:利用RT-PCR和MS-PCR的方法,分析38例鼻咽鳞癌组织标本、10例鼻咽炎性组织标本、4例正常鼻咽黏膜组织标本、两种鼻咽癌细胞株中RASSF1A基因的表达和其基因启动子区异常甲基化的情况.采用甲基化抑制剂5-Aza-CdR处理鼻咽癌细胞株,观察RASSF1A重新表达的情况.结果:38例鼻咽癌组织标本和两种细胞株的RASSF1A基因表达显著低于对照组(P<0.05);71.05 %的鼻咽癌标本及两种鼻咽癌细胞株发生异常甲基化;甲基化与年龄、性别、临床分期和颈部淋巴结转移无相关性(P>0.05),与RASSF1A基因表达和肿瘤分化程度有关(P<0.05);用5-Aza-CdR处理的低表达RASSF1A基因的鼻咽癌细胞株,RASSF1A基因表达上调.结论:鼻咽癌患者肿瘤组织中存在RASSFIA基因的表达下调现象,基因转录启动区的异常甲基化是导致鼻咽癌组织中RASSF1A基因表达下调的主要原因.     

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.     

Involvement of the RASSF1A tumor suppressor gene in controlling cell migration

We have previously shown that RASSF1A associates with the microtubules. This association alters the microtubule dynamics and seems essential for RASSF1A tumor suppressive function. Mutant variants of RASSF1A that do not associate fully with the microtubules have reduced ability to stabilize them and cause cell cycle arrest. Here we show that overexpression of RASSF1A diminished the ability of A549 non-small cell lung cancer cells to migrate either through a transwell filter or to close a wound. In addition, we employed gene knockdown as well as mouse embryonic fibroblasts (MEFs) from Rassf1a knockout mice to analyze RASSF1A function in controlling cell motility. A549 cells stably transfected with RASSF1A exhibited increased cell-cell adhesion and less refractive morphology compared with controls. Conversely, RASSF1A knockdown in HeLa caused loss of cell-cell adhesion and a more refractive morphology. RASSF1A-depleted HeLa cells as well as Rassf1a-/- MEFs displayed increased cell migration that could be partly phosphatidylinositol 3-kinase dependent. Time-lapse microscopy showed the RASSF1A-depleted cells are highly motile with fibroblast-like morphology and diminished cell-cell adhesion. Staining of the cytoskeleton in RASSF1A-depleted HeLa cells and MEFs show marked differences in terms of microtubules outgrowth and actin stress fibers formation. This observation was associated with increased activation of Rac1 in RASSF1A-knockdown cells and the Rassf1a-/- MEFs. In addition, expression of a dominant-negative variant of Rac1 in the RASSF1A-depleted HeLa cells reduced their ability to form lamellipodia and other protrusions. These findings represent a novel function for RASSF1A, which may help explain its tumor suppression ability independently of its effects on cell cycle and apoptosis.     

Epigenetic inactivation of the RASSF1A 3p21.3 tumor suppressor gene in both clear cell and papillary renal cell carcinoma

Renal cell carcinoma (RCC), the most common adult kidney neoplasm, is histopathologically heterogeneous, with most sporadic RCCs ( approximately 80%) classified as clear cell (CC) tumors. Chromosome 3p allele loss is the most frequent genetic alteration in RCC but is associated specifically with sporadic and hereditary forms of clear cell RCC (CC-RCC) and is not a feature of non-CC-RCC, such as papillary (chromophilic) RCC. The VHL tumor suppressor gene (TSG) maps to chromosome 3p25, and somatic inactivation of the VHL gene occurs in up to 70% of CC-RCC tumors and cell lines. However, VHL inactivation is not sufficient for CC-RCC tumorigenesis, and inactivation of 3p12-p21 TSG(s) appears to be necessary in CC-RCC irrespective of VHL gene inactivation status. Recently, we demonstrated that the candidate 3p21 TSG, RASSF1A, is hypermethylated in most small cell lung cancers. We have now investigated the role of RASSF1A inactivation in primary RCC tumors. RASSF1A promoter methylation was detected in 23% (32 of 138) of primary CC-RCC tumors. In CC-RCC cell lines, RASSF1A methylation was associated with silencing of RASSF1A expression and restoration of expression after treatment with 5'-azacytidine. The frequency of RASSF1A methylation was similar in CC-RCC with and without VHL gene inactivation (24% versus 21%), and there was no association between epigenetic silencing of the RASSF1A and VHL TSGs, because 0 of 6 tumors with VHL hypermethylation had RASSF1A methylation, and VHL was not methylated in 26 CC-RCCs with RASSF1A methylation. Although 3p allele loss has been reported rarely in papillary RCC, we identified RASSF1A methylation in 44% (12 of 27) of papillary RCCs analyzed. Thus: (a) inactivation of RASSF1A is a frequent event in both CC-RCC and papillary RCC tumors; (b) there is no relationship between epigenetic silencing of RASSF1A and VHL inactivation status in CC-RCC. Fifty-four CC-RCCs analyzed for RASSF1A methylation were informative for 3p21 allele loss, and 20% (7 of 35) with 3p21 allele loss demonstrated RASSF1A methylation. All informative CC-RCCs with 3p21 allele loss and no RASSF1A methylation also demonstrated allele losses at other regions of 3p so that tumorigenesis in these cases may result from: (a) haploinsufficiency of RASSF1A; (b) inactivation of other 3p21 TSGs; or (c) inactivation of 3p TSGs from outside of 3p21. RASSF1A is the first TSG to be inactivated frequently in both papillary and CC-RCCs. The finding of frequent epigenetic inactivation of RASSF1A in papillary RCCs despite previous studies reporting infrequent 3p21 allele loss in this tumor type illustrates how the systematic identification of all major human cancer genes will require detailed analysis of the cancer genome and epigenome.     

Frequent epigenetic inactivation of the RASSF1A tumour suppressor gene in testicular tumours and distinct methylation profiles of seminoma and nonseminoma testicular germ cell tumours

Testicular germ cell tumours (TGCTs) are histologically heterogeneous neoplasms with variable malignant potential. Previously, we demonstrated frequent 3p allele loss in TGCTs, and recently we and others have shown that the 3p21.3 RASSF1A tumour suppressor gene (TSG) is frequently inactivated by promoter hypermethylation in a wide range of cancers including lung, breast, kidney and neuroblastoma. In order to investigate the role of epigenetic events in the pathogenesis of TGCTs, we analysed the promoter methylation status of RASSF1A and nine other genes that may be epigenetically inactivated in cancer (p16(INK4A), APC, MGMT, GSTP1, DAPK, CDH1, CDH13, RARbeta and FHIT) in 24 primary TGCTs (28 histologically distinct components). RASSF1A methylation was detected in four of 10 (40%) seminomas and 15 of 18 (83%) nonseminoma TGCT (NSTGCT) components (P=0.0346). None of the other nine candidate genes were methylated in seminomas, but MGMT (44%), APC (29%) and FHIT (29%) were frequently methylated in NSTGCTs. Furthermore, in two mixed germ cell tumours, the NSTGCT component for one demonstrated RASSF1A, APC and CDH13 promoter methylation, but the seminoma component was unmethylated for all genes analysed. In the second mixed germ cell tumour, the NSTGCT component was methylated for RASSF1A and MGMT, while the seminoma component was methylated only for RASSF1A. In all, 61% NSTGCT components but no seminoma samples demonstrated promoter methylation at two or more genes (P=0.0016). These findings are consistent with a multistep model for TGCT pathogenesis in which RASSF1A methylation occurs early in tumorigenesis and additional epigenetic events characterize progression from seminoma to NSTGCTs.     

Hypermethylation of the RASSF1A tumor suppressor gene in Japanese clear cell renal cell carcinoma

Hypermethylation associated inactivation of RASSF1A tumor suppressor gene at chromosome 3p21.3 has been observed in several human malignancies. Relatively high (91%) or low (23%) frequencies were reported in the methylation status of promoter region of the RASSF1A gene in clear cell renal carcinoma (RCC) depending on the country the report was from. To clarify exact contribution of the hypermethylation of RASSF1A gene in the development of RCC in Japan, we analyzed the methylation status of the RASSF1A promoter region in 50 Japanese clear cell RCC and RCC cell lines. Although relatively high frequency of hypermethylation in RASSF1A promoter (39 of 50 tumors, 78%) was observed, most of matched proximal normal tissue DNA also showed weak methylation. By comparison with methylation level of adapted normal kidney tissue DNA, tumor preferential hypermethylation in RASSF1A promoter was recognized as 40% (20/50 matched sets) of primary clear cell RCCs. Hypermethylation in RASSF1A promoter was observed in 36% (15/42) and 64% (5/8) of stage I-II or III-IV tumors, and also observed in 42% (11/26) and 38% (9/24) of our tumor samples with pathological grade I or II, respectively. In addition, 16 of 19 RCC cell lines (84%) showed complete or partial methylation of RASSF1A promoter region. There was no association between the frequency of RASSF1A methylation and inactivation of VHL tumor suppressor gene in either primary RCCs or RCC cell lines. Our results showed tumor specific RASSF1A promoter hypermethylation in up to 40% of low grade or low stage clear cell RCCs. It is essential to compare the methylation status of RASSF1A promoter in tumor with normal tissue to understand tumor specific hypermethylation. Since considerable cases of normal kidney are hypermethylated, contribution of the RASSF1A for the development and progression of kidney cancer may be more complex than expected.     

Role of the tumor suppressor RASSF1A in Mst1-mediated apoptosis

Mammalian sterile 20-like kinase 1 (Mst1) is activated by both caspase-mediated cleavage and phosphorylation in response to apoptotic stimuli, including Fas ligation. Here, we examined the possible role of the tumor suppressor RASSF1A in Mst1 activation and Mst1-mediated apoptosis induced by death receptor signaling. Immunoprecipitation and immunofluorescence analyses revealed that Mst1 was associated with RASSF1A in cultured mammalian cells, with both proteins colocalizing to microtubules throughout the cell cycle. Whereas purified recombinant RASSF1A inhibited the kinase activity of purified recombinant Mst1 in vitro, overexpression of RASSF1A increased the kinase activity of Mst1 in intact cells, suggesting that regulation of Mst1 by RASSF1A in vivo involves more than the simple association of the two proteins. Both the activation of Mst1 and the incidence of apoptosis induced by Fas ligation were markedly reduced in cells depleted of RASSF1A by RNA interference and were increased by restoration of RASSF1A expression in RASSF1A-deficient cells. Moreover, the stimulatory effect of RASSF1A overexpression on Fas-induced apoptosis was inhibited by depletion of Mst1. These findings indicate that RASSF1A facilitates Mst1 activation and thereby promotes apoptosis induced by death receptor signaling.     

Control of microtubule stability by the RASSF1A tumor suppressor

The RAS association domain family 1A (RASSF1A) gene is silenced by DNA methylation in over 50% of all solid tumors of different histological types. However, the biochemical function of the RASSF1A protein is unknown. We show that RASSF1A colocalizes with microtubules in interphase and decorates spindles and centrosomes during mitosis. RASSF1A has a strong cytoprotective activity against the microtubule-destabilizing drug nocodazole, and against cold-treatment in vivo. Conversely, loss of RASSF1 in RASSF1-/- mouse embryonic fibroblasts renders the cells more sensitive to nocodazole-induced depolymerization of microtubules. The domain required for both microtubule association and stabilization was mapped to a 169 amino-acid fragment that contains the RAS association domain. Overexpression of RASSF1A induces mitotic arrest at metaphase with aberrant mitotic cells reminiscent of such produced by the microtubule-stabilizing drug paclitaxel (taxol), including monopolar spindles, or complete lack of a mitotic spindle. Altered microtubule stability in cells lacking RASSF1A is likely to affect spindle assembly and chromosome attachment, processes that need to be carefully controlled to protect cells from genomic instability and transformation. In addition, knowledge of the microtubule-targeting function of RASSF1 may aid in the development of new anticancer drugs.     

抑癌基因的失活机制

肿瘤的发生发展与抑癌基因的失活和原癌基因的激活密切相关.对抑癌基因失活机制的深入研究,不但可揭示肿瘤发生发展的机制,同时也有助于肿瘤的诊断及基因治疗.     

The RASSF1A tumor suppressor gene is commonly inactivated in adenocarcinoma of the uterine cervix.

PURPOSE: Development of adenocarcinoma (AC) of the uterine cervix, as well as squamous cell carcinoma (SCC), is strongly linked to infection by high-risk human papillomavirus (HPV) types. Human HPV E6 and E7 proteins inactivate the tumor suppressor genes p53 and retinoblastoma, respectively. However, additional genetic alterations may be required to maintain a malignant phenotype. Allelic loss at the short arm of chromosome 3 is one of the most frequent genetic changes found in cervical cancer and various other types of human cancer, including lung, breast, and ovarian cancer. This implies that a resident tumor-suppressor gene in this region is involved in the genesis of these tumors. RASSF1A, which is located at 3p21.3, is rarely inactivated by mutations but has been suggested as a target tumor suppressor gene on the basis of its frequent inactivation through promoter hypermethylation and loss of heterozygosity in a variety of primary human cancers. In the present study, we sought to determine whether epigenetic silencing of RASSF1A caused by hypermethylation of the promoter region plays a role in the development of uterine cervical cancer. Experimental Design: We studied 51 uterine cervical carcinoma samples. These 51 cases were comprised of 31 SCCs and 20 ACs. Real-time methylation-specific PCR system was used for the detection and quantitation of the bisulfite-converted methylated version of the RASSF1A promoter region. The 20 cases of cervical AC were also analyzed for the presence of oncogenic HPV 16 DNA using a PCR-based method. RESULTS: We found complete methylation of the RASSF1A promoter in 45% (9 of 20 samples) of AC cases. There was no promoter methylation observed in any of the 31 cases of SCC. We also correlated RASSF1A promoter hypermethylation to oncogenic HPV 16 infection. HPV 16 DNA was found in 3 of 9 (33%) AC tumors with RASSF1A promoter hypermethylation and 5 of 11 (45%) AC tumors without RASSF1A promoter hypermethylation. We could not demonstrate an inverse correlation between RASSF1A methylation and HPV 16 infection in AC of the uterine cervix. CONCLUSIONS: Hypermethylation of the RASSF1A promoter region is common in AC of the uterine cervix and rare in squamous carcinoma of uterine cervix. HPV infection does not correlate with RASSF1A methylation status in AC of the uterine cervix, but the absence of RASSF1A methylation in SCC of the uterine cervix coupled with the high incidence of HPV 16 infection in this subtype is in accord with previous reports. Our results suggest that epigenetic silencing of RASSF1A may play a role in the development of AC of the uterine cervix.     

Association of epigenetic inactivation of RASSF1A with poor outcome in human neuroblastoma.

PURPOSE: To investigate the prevalence and potential clinical significance of epigenetic aberrations in neuroblastoma (NB). EXPERIMENTAL DESIGN: The methylation status of 11 genes that are frequently epigenetically inactivated in adult cancers was assayed in 13 NB cell lines. The prevalence of RASSF1A and TSP-1 methylation was also analyzed in 56 NBs and 5 ganglioneuromas by methylation-specific PCR. Associations between the methylation status of RASSF1A and TSP-1 and patient age, tumor stage, tumor MYCN status, and patient survival were evaluated. RESULTS: Epigenetic changes were detected in all 13 NB cell lines, although the pattern of gene methylation varied. The putative tumor suppressor gene RASSF1A was methylated in all 13 cell lines, and TSP-1 and CASP8 were methylated in 11 of 13 cell lines. Epigenetic changes of DAPK and FAS were detected in only small numbers of cell lines, whereas none of the cell lines had methylation of p16, p21, p73, RAR-beta2, SPARC, or TIMP-3. RASSF1A was also methylated in 70% of the primary NB tumors tested, and TSP-1 methylation was detected in 55% of the tumors. RASSF1A methylation was significantly associated with age >1 year (P < 0.01), high-risk disease (P < 0.016), and poor survival (P < 0.001). In contrast, no association between TSP-1 methylation and prognostic factors or survival was observed. CONCLUSIONS: Our results suggest that epigenetic inactivation of RASSF1A may contribute to the clinically aggressive phenotype of high-risk NB.     

Frequent 3p allele loss and epigenetic inactivation of the RASSF1A tumour suppressor gene from region 3p21.3 in head and neck squamous cell carcinoma

Studies of allelic imbalance and suppression of tumourigenicity have consistently suggested that the short arm of chromosome three (3p) harbours tumour suppressor genes (TSGs) whose inactivation leads to the development of various types of neoplasia including head and neck squamous cell carcinoma (HNSCC). Previously, we defined a critical minimal region of 120kb at 3p21.3 that contains overlapping homozygous deletions in lung and breast tumour lines and isolated eight genes from the minimal region. Mutation analysis in a large panel of lung and breast cancers revealed only rare mutations, but the majority of lung tumour lines showed loss of expression for one of the eight genes (RASSF1A) due to hypermethylation of a CpG island in the promoter region of RASSF1A. We found RASSF1A to be methylated in the majority of lung tumours, but to a lesser extent in breast and ovarian tumours. In order to define the role of 3p TSGs, in particular RASSF1A in HNSCC, we (a) analysed 43 primary HNSCC for allelic loss in regions proposed to contain 3p TSGs (3p25-26, 3p24, 3p21-22, 3p14 and 3p12), (b) analysed 24 HNSCC for evidence of RASSF1A methylation and (c) undertook mutation analysis of RASSF1A in HNSCC. We found that 81% of HNSCC showed allele loss at one or more 3p markers, 66% demonstrated loss for 3p21.3 markers and 56% showed allelic losses at 3p12 loci. Thus, 3p loss is common in HNSCC and extensive 3p loss occurs even in early stage tumours. RASSF1A promoter region hypermethylation was found in 17% (4/24) of the sporadic HNSCC, but RASSF1A mutations were not identified. Furthermore, we found RASSF1A methylation to be significantly higher in poorly differentiated then in moderate to well differentiated HNSCC (P=0.0048). Three of the four tumours showing RASSF1A methylation also underwent 3p21.3 allelic loss, hence RASSF1A behaves as a classical TSG (two hits, methylation and loss). One tumour with RASSF1A methylation had retention of markers at 3p providing further evidence of specific inactivation of RASSF1A as a critical step in some HNSCC. Although the frequency of 3p21.3 allele loss was substantially higher than that of RASSF1A methylation this does not necessarily suggest that other genes from 3p21.3 are also implicated in HNSCC, as 3p21.3 LOH was invariably found with LOH at other 3p loci. Thus, the presence of 3p21.3 allele loss without RASSF1A methylation might reflect a propensity for 3p21.3 loss to occur as a secondary consequence of large 3p deletions targeted at other 3p TSG regions. Furthermore, in the presence of homozygous inactivation of other 3p TSGs, RASSF1A haploinsufficiency might be sufficient to promote tumourigenesis in many HNSCC.     

Epigenetic inactivation of the RASSF10 candidate tumor suppressor gene is a frequent and an early event in gliomagenesis

We have recently described the N-terminal RAS association domain family of genes, RASSF7-10. Previously, we cloned the N-terminal RASSF10 gene and demonstrated frequent methylation of the associated 5'-CpG island in acute lymphoblastic leukemia. To characterize RASSF10 gene expression, we demonstrate that in developing Xenopus embryos, RASSF10 shows a very striking pattern in the rhombencephalon (hind brain). It is also expressed in other parts of the brain and other organs. Due to the well-defined expression pattern in the brain of Xenopus embryos, we analyzed the methylation status of the RASSF10-associated 5'-CpG island in astrocytic gliomas. RASSF10 was frequently methylated in WHO grade II-III astrocytomas and WHO grade IV primary glioblastomas (67.5%), but was unmethylated in grade I astrocytomas and in DNA from age matched control brain samples. RASSF10 gene expression both at the mRNA and protein levels could be switched back on in methylated glioma cell lines after treatment with 5-aza-2'-deoxycytidine. In secondary glioblastomas (sGBM), RASSF10 methylation was an independent prognostic factor associated with worst progression-free survival and overall survival and occurred at an early stage in their development. In cell culture experiments, overexpression of RASSF10 mediated a reduction in the colony forming ability of two RASSF10-methylated glioma cell lines. Conversely, RNAi-mediated knockdown of RASSF10-stimulated anchorage-independent growth of U87 glioma cells, increased their viability and caused an increase in the cells' proliferative ability. We generated and characterized a RASSF10-specific antibody and demonstrated for the first time that RASSF10 subcellular localization is cell-cycle dependent with RASSF10 colocalizing to centrosomes and associated microtubules during mitosis. This is the first report demonstrating that RASSF10 can act as a tumor suppressor gene and is frequently methylated in gliomas and can potentially be developed into a prognostic marker for sGBM.     

Biallelic inactivation of the RIZ1 gene in human gastric cancer

The distal short arm of chromosome 1 is commonly deleted in a variety of human neoplasms including gastrointestinal cancer. Genetic alterations of the retinoblastoma protein-interacting zing-finger gene (RIZ)1 including loss of heterozygosity (LOH) at 1p36, frameshift mutations, and promoter hypermethylation were reported previously in several cancers. In this study, we evaluated RIZ1 in 30 primary gastric cancers and found frameshift mutations in two cases (6.7%). Moreover, using real-time quantitative methylation-specific PCR, methylation of the RIZ1 promoter was detected in 11 (37%) cases. In all 11 cases with methylation, inactivation of the second allele occurred through frameshift mutation, LOH or promoter methylation. Our results suggest that RIZ1 is a specific target of inactivation in human gastric cancer.