痰液脱落细胞中p16 基因和RASSF1A 基因甲基化与周边型非小细胞 肺癌关系的研究

目的:探讨p16基因和RASSF1A基因甲基化与肺癌发生发展的关系和应用于诊断的意义。方法:采用甲基化特异性PCR(Methylation Specific PCR,MSP)检测120例周边型非小细胞肺癌患者癌组织、痰液脱落细胞和120例非肺癌人群的痰液脱落细胞中p16基因和RASSF1A基因甲基化,分析它们与临床特征的关系以及非肺癌人群与肿瘤患者之间的差异。结果:(1)120例周边型非小细胞肺癌组织中,p16基因甲基化率46.7%(56例),RASSF1A基因甲基化率53.3%(64例)。P16和RASSF1A基因甲基化与吸烟程度、肿瘤大小和临床分期正相关(P<0.05)。(2)肺癌痰液脱落细胞中有28例p16基因出现甲基化(23.3%),20例RASSF1A基因出现甲基化(16.7%),其中32例至少存在一个基因的甲基化(26.7%);66例重度吸烟者中只有4例痰液脱落细胞出现p16基因甲基化(6%),4例出现RASSF1A基因甲基化(6%);54例非重度吸烟正常人中仅有2例出现p16基因甲基化(3.7%),RASSF1A基因无甲基化。(3)液基痰细胞病理学检查与痰脱落细胞p16和RASSF1a基因甲基化检测结合起来可有效提高诊断的灵敏度(P<0.05)。结论:烟草可能具有潜在的诱导抑癌基因p16和RASSF1A发生甲基化的作用;p16和RASSF1A基因甲基化可能参与肺癌的生长过程。痰脱落细胞p16和RASSF1a基因甲基化检测结合液基痰细胞病理学诊断,可提高非小细胞肺癌诊断的灵敏度。     

RG108对肺腺癌A549细胞增殖、凋亡及RASSF1A基因表达的影响

目的探讨DNA甲基转移酶抑制剂RG108对人肺腺癌细胞株A549增殖、凋亡以及对RASSF1A（Ras as-sociation domain proteinfamily1）基因启动子区域甲基化状态、表达的影响。方法用20μmol/L的RG108对A549细胞进行化学干预72h,用MTT法检测细胞生长抑制率;流式细胞术检测细胞周期以及凋亡情况;RT-PCR观察RASSF1A基因mRNA水平变化;Western blot检测RASSF1A蛋白的表达;甲基化特异性PCR（MS-PCR）检测RASSF1A基因启动子区域甲基化状态的改变。结果经RG108干预72h后,A549细胞的抑制率为17.2±0.43%,细胞周期阻滞于G0/G1期,并引起细胞凋亡。RT-PCR和Western blot结果显示在干预组细胞中分别出现RASSF1A基因的DNA条带（329bp）和蛋白质条带（39kD）,而对照组中无相应条带出现。RASSF1A基因启动子区域由甲基化状态转变为非甲基化状态。结论RG108可使RASSF1A基因启动子区域去甲基化,并通过该机制诱导RASSF1A基因在人肺腺癌细胞株A549中表达。     

骨肉瘤中RASSF1A基因的甲基化状态研究

目的：分析骨肉瘤组织中RASSF1A基因甲基化状况。方法：运用甲基化特异性PCR（MSP）分别检测44例骨肉瘤组织及相应的癌旁组织中RASSF1A基因启动子甲基化状态并分析其临床病理意义。结果：骨肉瘤组织中RASSF1A基因异常甲基化率（61.4%）显著高于癌旁正常骨组织中RASSF1A基因的异常甲基化率（20.5%）,二者之间差异具有统计学意义（P〈0.05）。RASSF1A基因异常甲基化导致组织中RASSF1A基因mRNA和蛋白表达水平均显著降低。另外,RASSF1A基因异常甲基化和肿瘤组织分化程度及全身有无转移情况有相关性（P值分别为0.022和0.016）,而与患者年龄、性别、肿瘤位置及大小等临床特征无关（P值分别为0.6944,0.977,0.786和0.831）。结论：RASSF1A基因启动子高甲基化可能是导致其在骨肉瘤中表达水平降低的分子机制之一,有望成为骨肉瘤早期辅助诊断的一个重要分子标志物。     

结肠癌组织RASSF1A基因转录表达和启动子区甲基化研究

目的:研究Ras相关区域家族1A基因(ras association domain family 1A,RASSF1A)启动子区甲基化对结肠癌组织中该基因转录和表达的影响.方法:应用甲基化特异性PCR(Methylation-special PCR,MSP)、RT-PCR和Western blot方法检测30例结肠癌组织和癌旁组织中的RASSF1A基因启动子区甲基化状态、mRNA和蛋白表达水平.结果:①RASSF1A基因启动子区在结肠癌纽织和正常组织中的甲基化频率分别为57%(17/30)和20%(6/30),甲基化频率在两组具有统计学差异(p＜0.01),,结肠癌组织中RASSF1A基因启动子区甲基化频率显著高于癌旁正常组织(x2=8.531,p＜0.01);②结肠癌组织中RASSF1A基因mRNA和蛋白袁达均显著低于癌旁组织(癌组织和癌旁正常组织中mRNA相对表达量分别为0.2836±0.0493和0.5092±0.0433,P＜0.001;以上组织中蛋白相对表达量分别为0.3124±0.0472和0.5320±0.0440,P＜0.01);③在结肠癌组织中,甲基化组RASSF1A基因mRNA和蛋白表达明显低于非甲基化组(甲基化组和非甲基化组mRNA相对表达量分别为0.0686±0.0174和0.5511±0.0486,P＜0.0001;以上组中蛋白相对表达量分别为0.1219±0.0326和0.5614±0.0380,P＜0.0001).结论:结肠癌组织中RASSF1A基因启动子区甲基化明显增高,与该基因蛋白表达减少显著相关,这可能是导致结肠癌中RASSF1A抑癌基因失活的主要因为.     

骨肉瘤中RASSF1A基因的甲基化状态研究

目的:分析骨肉瘤组织中RASSF1A基因甲基化状况。方法:运用甲基化特异性PCR(MSP)分别检测44例骨肉瘤组织及相应的癌旁组织中RASSF1A基因启动子甲基化状态并分析其临床病理意义。结果:骨肉瘤组织中RASSF1A基因异常甲基化率(61.4%)显著高于癌旁正常骨组织中RASSF1A基因的异常甲基化率(20.5%),二者之间差异具有统计学意义(P<0.05)。RASSF1A基因异常甲基化导致组织中RASSF1A基因mRNA和蛋白表达水平均显著降低。另外,RASSF1A基因异常甲基化和肿瘤组织分化程度及全身有无转移情况有相关性(P值分别为0.022和0.016),而与患者年龄、性别、肿瘤位置及大小等临床特征无关(P值分别为0.6944,0.977,0.786和0.831)。结论:RASSF1A基因启动子高甲基化可能是导致其在骨肉瘤中表达水平降低的分子机制之一,有望成为骨肉瘤早期辅助诊断的一个重要分子标志物。     

RASSF1A对黑色素瘤A375细胞基因网络的影响

RASSF1A(Ras association domain family 1 isoform A)是定位于染色体3p21.3区域的抑瘤基因,编码一个由340个氨基酸残基构成的微管相关蛋白.该基因在包括恶性黑色素瘤在内的多种肿瘤中因启动子高甲基化而表达沉默.本研究建立了RASSF1A稳定表达的恶性黑色素瘤A375细胞系,通过全基因组表达谱基因芯片分析RASSF1A过表达对A375细胞基因表达谱的影响,发现RASSF1A引起184个基因表达上调,26个基因表达下调.通过Realtime RT-PCR对部分差异表达基因进行验证,结果表明与芯片筛选结果一致.RASSF1A影响的差异表达基因功能上归属于细胞生长与增殖、细胞周期、细胞凋亡、细胞间黏附、信号传导等生物过程.采用STRING软件构建了RASSF1A影响的差异表达基因调控网络,结果表明RASSF1A调控的差异表达基因构成一个高连接度的基因网络.其中,炎症细胞因子、转录因子位于网络中央.RASSF1A通过影响炎症细胞因子与转录因子之间的表达,影响A375细胞基因网络,调节黑色素瘤恶性生物学行为.     

巢式甲基化特异性PCR检测肝细胞癌患者血清中RASSF1A和CDH13基因启动子区甲基化

为了检测肝细胞癌患者血清中RASSF1A和CDH13基因启动子的甲基化状态,收集肝细胞癌患者及健康对照者的血清标本,采用巢式甲基化特异性PCR(nMSP)法检测RASSF1A和CDH13基因启动子区甲基化状态.结果肝细胞癌患者血清样品中RASSF1A和CDH13基因启动子区甲基化率为53.12%和31.25%,68.75%的患者血清可以检测到异常甲基化,正常对照血清中未检测到RASSF1A和CDH13基因启动子区甲基化,RASSF1A和CDH13基因甲基化与患者的临床病理资料无明显相关性(P>0.05);表明nMSP法检测血清中RASSF1A和CDH13基因启动子区甲基化具有较高的敏感性,可为肝细胞癌的筛查、早期诊断和预后判断提供有价值的信息.     

Fibulin3基因在非小细胞肺癌中的蛋白表达及甲基化检测

目的:检测Fibulin3基因在非小细胞肺癌患者(non-small cell hung cancer,NSCLC)组织中的表达和甲基化状态,并分析其临床病理意义.方法:收集59例NSCLC患者术后病理蜡块,进行免疫组化染色;提取癌组织及相应癌旁组织DNA,甲基化特异性聚合酶链反应(MSP)检测Fibulin3基因启动子区甲基化情况.结果:59例NSCLC标本中,25例(42.4%)Fibulin3表达水平比相应癌旁组织下调(P＜0.05);癌组织和相应癌旁组织甲基化22例和5例检出Fibulin3基因启动子区高甲基化,其阳性率分别为37.3%和8.5%,差异具有统计学意义(P＜0.001);Fibulin3启动子甲基化导致蛋白表达下调或缺失(P＜0.001),并与临床分期(P=0.035)及淋巴结转移(P=0.011)相关.结论:启动子甲基化引起的Fibulin3基因失活在NSCLC发生发展中起重要作用,Fibulin3启动子甲基化可能成为NSCLC早期诊断和预后评估的潜在标记物.     

白血病患者骨髓中RASSF1A基因启动子甲基化状态及其临床意义

目的:通过检测各类型白血病骨髓中RASSF1A基因启动子区甲基化水平,探讨其对白血病分型的临床检测意义。方法:抽选93例不同类型白血病患者(观察组)予以甲基化特异性PCP(MSP)方法进行骨髓RASSF1A基因甲基化状态检测,研究不同类型白血病甲基化状态差异,同期抽选93例非白血病者为对照研究(对照组)。结果:观察组中有13例(13.98%)检测到RASSF1A基因甲基化,而对照组中RASSF1A基因甲基化率为0%,比较差异显著(P0.05)。不同类型白血病RASSF1A甲基化率比较:淋巴系显著高于髓系(P0.05),急性与慢性白血病比较差异无显著性(P0.05)。结论:白血病骨髓中MSP法检测存在RASSF1A甲基化;而RASSF1A基因在淋巴系白血病中的甲基化概率明显增高,因此,对RASSF1A进行甲基化检测有可能作为白血病临床诊断分型的生物学指标之一。     

5-Aza-dC对Molt-4细胞RASSF10基因启动子的去甲基化作用

探讨甲基化抑制剂5-氮杂-2’-脱氧胞苷(5-Aza-2’deoxycytidine,5-Aza-dC)对人急性淋巴细胞白血病Molt-4细胞的增殖抑制作用及对RASSF10基因启动子甲基化状态的影响。体外培养Molt-4细胞,采用不同浓度5-Aza-dC对Molt-4细胞进行处理。采用MTT法检测细胞增殖抑制率,RT-PCR法检测RASSF10 mRNA表达的变化,Westernblot检测RASSF10蛋白表达的变化,COBRA实验检测RASSF10甲基化水平。一定浓度的5-Aza-dC作用Molt-4细胞后,细胞增殖抑制率显著升高,且具有时间和剂量依赖性。对照组Molt-4细胞未检出RASSF10 mRNA及蛋白表达,而5-Aza-dC处理组检出RASSF10基因重新表达。COBRA实验结果提示对照组Molt-4细胞中存在启动子高甲基化的现象,而5-Aza-dC处理组Molt-4细胞的RASSF10基因被部分去甲基化。甲基化抑制剂5-Aza-dC可通过对RASSF10基因的去甲基化作用,重新恢复RASSF10的表达,从而抑制Molt-4细胞的增殖。     

Prognostic value of RASSF1A methylation status in non-small cell lung cancer (NSCLC) patients: A meta-analysis of prospective studies

Objective: Ras association domain family 1?A (RASSF1A) has been regarded as a biomarker predicting the prognosis of non-small cell lung cancer (NSCLC), but previous findings are inconsistent. This meta-analysis of prospective studies aimed to assess the value of RASSF1A methylation in predicting the prognosis of NSCLC patients.

Methods: Studies were searched in PubMed and Web of Science. The estimates of the effects and the corresponding 95% confidence intervals (95% CIs) were used for the analyses. The overall effects of RASSF1A methylation on overall survival (OS) were estimated, after which subgroup analysis based on regions was conducted. Sensitivity analyses were conducted to restrict the studies with certain features.

Results: A total of 16 studies with 2210 participants were included in this meta-analysis. The overall analysis result indicated that RASSF1A methylation had no statistically significant effects on OS of NSCLC patients (HR?=?1.28; 95% CI 0.86–1.70), which were confirmed by the subgroup analysis. However, the sensitivity analysis indicated that RASSF1A methylation from lung cancer tissues was significantly associated with lower OS (HR?=?1.24; 95% CI 1.04–1.45).

Conclusion: RASSF1A methylation in lung cancer tissue can serve as a prognostic factor of NSCLC. More studies are needed to uncover the underlying mechanisms.     

Quantitative analysis of mRNA expression levels and DNA methylation profiles of three neighboring genes: FUS1, NPRL2/G21 and RASSF1A in non-small cell lung cancer patients

Background

Tumor suppressor gene (TSG) inactivation plays a crucial role in carcinogenesis. FUS1, NPRL2/G21 and RASSF1A are TSGs from LUCA region at 3p21.3, a critical chromosomal region in lung cancer development. The aim of the study was to analyze and compare the expression levels of these 3 TSGs in NSCLC, as well as in macroscopically unchanged lung tissue surrounding the primary lesion, and to look for the possible epigenetic mechanism of TSG inactivation via gene promoter methylation.

Methods

Expression levels of 3 TSGs and 2 DNA methyltransferases, DNMT1 and DNMT3B, were assessed using real-time PCR method (qPCR) in 59 primary non-small cell lung tumors and the matched macroscopically unchanged lung tissue samples. Promoter methylation status of TSGs was analyzed using methylation-specific PCRs (MSP method) and Methylation Index (MI) value was calculated for each gene.

Results

The expression of all three TSGs were significantly different between NSCLC subtypes: RASSF1A and FUS1 expression levels were significantly lower in squamous cell carcinoma (SCC), and NPRL2/G21 in adenocarcinoma (AC). RASSF1A showed significantly lower expression in tumors vs macroscopically unchanged lung tissues. Methylation frequency was 38–76 %, depending on the gene. The highest MI value was found for RASSF1A (52 %) and the lowest for NPRL2/G21 (5 %). The simultaneous decreased expression and methylation of at least one RASSF1A allele was observed in 71 % tumor samples. Inverse correlation between gene expression and promoter methylation was found for FUS1 (rs = −0.41) in SCC subtype. Expression levels of DNMTs were significantly increased in 75–92 % NSCLCs and were significantly higher in tumors than in normal lung tissue. However, no correlation between mRNA expression levels of DNMTs and DNA methylation status of the studied TSGs was found.

Conclusions

The results indicate the potential role of the studied TSGs in the differentiation of NSCLC histopathological subtypes. The significant differences in RASSF1A expression levels between NSCLC and macroscopically unchanged lung tissue highlight its possible diagnostic role in lung cancer in situ recognition. High percentage of lung tumor samples with simultaneous RASSF1A decreased expression and gene promoter methylation indicates its epigenetic silencing. However, DNMT overexpression doesn’t seem to be a critical determinate of its promoter hypermethylation.     

RASSF1C modulates the expression of a stem cell renewal gene, PIWIL1

ABSTRACT: BACKGROUND: RASSF1A and RASSF1C are two major isoforms encoded by the Ras association domain family 1 (RASSF1) gene through alternative promoter selection and mRNA splicing. RASSF1A is a well established tumor suppressor gene. Unlike RASSF1A, RASSF1C appears to have growth promoting actions in lung cancer. In this article, we report on the identification of novel RASSF1C target genes in non small cell lung cancer (NSCLC). METHODS: Over-expression and siRNA techniques were used to alter RASSF1C expression in human lung cancer cells, and Affymetrix-microarray study was conducted using NCI-H1299 cells over-expressing RASSF1C to identify RASSF1C target genes. RESULTS: The microarray study intriguingly shows that RASSF1C modulates the expression of a number of genes that are involved in cancer development, cell growth and proliferation, cell death, and cell cycle. We have validated the expression of some target genes using qRT-PCR. We demonstrate that RASSF1C over-expression increases, and silencing of RASSF1C decreases, the expression of PIWIL1 gene in NSCLC cells using qRT-PCR, immunostaining, and Western blot analysis. We also show that RASSF1C over-expression induces phosphorylation of ERK1/2 in lung cancer cells, and inhibition of the MEK-ERK1/2 pathway suppresses the expression of PIWIL1 gene expression, suggesting that RASSF1C may exert its activities on some target genes such as PIWIL1 through the activation of the MEK-ERK1/2 pathway. Also, PIWIL1 expression is elevated in lung cancer cell lines compared to normal lung epithelial cells. CONCLUSIONS: Taken together, our findings provide significant data to propose a model for investigating the role of RASSF1C/PIWIL1 proteins in initiation and progression of lung cancer.     

Development of a multiplex methylation specific PCR suitable for (early) detection of non-small cell lung cancer

Lung cancer is a worldwide health problem and a leading cause of cancer-related deaths. Silencing of potential tumor suppressor genes (TSGs) by aberrant promoter methylation is an early event in the initiation and development of cancer. Thus, methylated cancer type-specific TSGs in DNA can serve as useful biomarkers for early cancer detection. We have now developed a “Multiplex Methylation Specific PCR” (MMSP) assay for analysis of the methylation status of multiple potential TSGs by a single PCR reaction. This method will be useful for early diagnosis and treatment outcome studies of non-small cell lung cancer (NSCLC). Genome-wide CpG methylation and expression microarrays were performed on lung cancer tissues and matched distant non-cancerous tissues from three NSCLC patients from China. Thirty-eight potential TSGs were selected and analyzed by methylation PCR on bisulfite treated DNA. On the basis of sensitivity and specificity, six marker genes, HOXA9, TBX5, PITX2, CALCA, RASSF1A, and DLEC1, were selected to establish the MMSP assay. This assay was then used to analyze lung cancer tissues and matched distant non-cancerous tissues from 70 patients with NSCLC, as well as 24 patients with benign pulmonary lesion as controls. The sensitivity of the assay was 99% (69/70). HOXA9 and TBX5 were the 2 most sensitive marker genes: 87% (61/70) and 84% (59/70), respectively. RASSF1A and DLEC1 showed the highest specificity at 99% (69/70). Using the criterion of identifying at least any two methylated marker genes, 61/70 cancer samples were positive, corresponding to a sensitivity of 87% and a specificity of 94%. Early stage I or II NSCLC could even be detected with a 100% specificity and 86% sensitivity. In conclusion, MMSP has the potential to be developed into a population-based screening tool and can be useful for early diagnosis of NSCLC. It might also be suitable for monitoring treatment outcome and recurrence.     

Hypermethylation of the death-associated protein kinase promoter attenuates the sensitivity to TRAIL-induced apoptosis in human non-small cell lung cancer cells

Death-associated protein (DAP) kinase plays an important role in IFN-gamma, tumor necrosis factor (TNF)-alpha, or Fas-ligand induced apoptosis. TNF-related apoptosis-inducing ligand (TRAIL) is a member of the TNF ligand family and can induce caspase-dependent apoptosis in cancer cells while sparing most of the normal cells. However, some of the cancer cell lines are insensitive to TRAIL, and such resistance cannot be explained by the dysfunction of TRAIL receptors or their known downstream targets. We reported previously that DAP kinase promoter is frequently methylated in non-small cell lung cancer (NSCLC), and such methylation is associated with a poor clinical outcome. To determine whether DAP kinase promoter methylation contributes to TRAIL resistance in NSCLC cells, we measured DAP kinase promoter methylation and its gene expression status in 11 NSCLC cell lines and correlated the methylation/expression status with the sensitivity of cells to TRAIL. Of the 11 cell lines, 1 had a completely methylated DAP kinase promoter and no detectable DAP kinase expression, 4 exhibited partial promoter methylation and substantially decreased gene expression, and the other 6 cell lines showed no methylation in the promoter and normal DAP kinase expression. Therefore, the amount of DAP kinase expression amount was negatively correlated to its promoter methylation (r = -0.77; P = 0.003). Interestingly, the cell lines without the DAP kinase promoter methylation underwent substantial apoptosis even in the low doses of TRAIL, whereas those with DAP kinase promoter methylation were resistant to the treatment. The resistance to TRAIL was reciprocally correlated to DAP kinase expression in 10 of the 11 cell lines at 10 ng/mL concentration (r = 0.91; P = 0.001). We treated cells resistant to TRAIL with 5-aza-2'-deoxycytidine, a demethylating reagent, and found that these cells expressed DAP kinase and became sensitive to TRAIL. These results suggest that DAP kinase is involved in TRAIL-mediated cell apoptosis and that a demethylating agent may have a role in enhancing TRAIL-mediated apoptosis in some NSCLC cells by reactivation of DAP kinase.     

Development of a multiplex methylation specific PCR suitable for (early) detection of non-small cell lung cancer

Lung cancer is a worldwide health problem and a leading cause of cancer-related deaths. Silencing of potential tumor suppressor genes (TSGs) by aberrant promoter methylation is an early event in the initiation and development of cancer. Thus, methylated cancer type-specific TSGs in DNA can serve as useful biomarkers for early cancer detection. We have now developed a “Multiplex Methylation Specific PCR” (MMSP) assay for analysis of the methylation status of multiple potential TSGs by a single PCR reaction. This method will be useful for early diagnosis and treatment outcome studies of non-small cell lung cancer (NSCLC). Genome-wide CpG methylation and expression microarrays were performed on lung cancer tissues and matched distant non-cancerous tissues from three NSCLC patients from China. Thirty-eight potential TSGs were selected and analyzed by methylation PCR on bisulfite treated DNA. On the basis of sensitivity and specificity, six marker genes, HOXA9, TBX5, PITX2, CALCA, RASSF1A, and DLEC1, were selected to establish the MMSP assay. This assay was then used to analyze lung cancer tissues and matched distant non-cancerous tissues from 70 patients with NSCLC, as well as 24 patients with benign pulmonary lesion as controls. The sensitivity of the assay was 99% (69/70). HOXA9 and TBX5 were the 2 most sensitive marker genes: 87% (61/70) and 84% (59/70), respectively. RASSF1A and DLEC1 showed the highest specificity at 99% (69/70). Using the criterion of identifying at least any two methylated marker genes, 61/70 cancer samples were positive, corresponding to a sensitivity of 87% and a specificity of 94%. Early stage I or II NSCLC could even be detected with a 100% specificity and 86% sensitivity. In conclusion, MMSP has the potential to be developed into a population-based screening tool and can be useful for early diagnosis of NSCLC. It might also be suitable for monitoring treatment outcome and recurrence.