MAGE A1-A6 RT-PCR and MAGE A3 and p16 methylation analysis in induced sputum from patients with lung cancer and non-malignant lung diseases

The melanoma antigen gene (MAGE) A1-A6 RT-PCR system was developed for the detection of lung cancer cells in the sputum. However, we identified MAGE expression in some patients with non-malignant lung diseases. To understand these patterns of MAGE expression, we performed MAGE A3 methylation-specific PCR (MSP) and p16 MSP. We collected 24 biopsy specimens of lung cancer tissue and performed MAGE A1-A6 RT-PCR, MAGE A3 MSP and p16 MSP. RNA and DNA were simultaneously extracted from induced sputum specimens of 133 patients with lung diseases and 30 random sputum specimens of healthy individuals and the 3 molecular analyses were performed. The patients were diagnosed as 65 cases of lung cancer and 68 of benign lung diseases. Positive rates of MAGE A1-A6 RT-PCR, MAGE A3 MSP and p16 MSP were as follows: in lung cancer tissue, 87.5, 58.3 and 70.8%; in the sputum of lung cancer patients, 50.8, 46.2 and 63.1%; benign lung diseases, 10.3, 30.9 and 39.7%; and healthy individuals, 3.3, 6.7 and 3.3%. Of the 40 MAGE-positive cases, 33 were diagnosed with lung cancer and 7 as having benign lung diseases. From the 7 cases of MAGE-positive benign lung diseases, 6 cases showed methylation abnormalities. The MAGE-positive group revealed significantly higher rates of methylation abnormalities. Of the 40 MAGE-positive cases, 39 cases were found to be lung cancer or benign lung diseases with abnormal methylation. Thus, MAGE expression in the sputum suggests the presence of lung cancer cells or pre-cancerous cells.     

Aberrant p16 promoter methylation among Greek lung cancer patients and smokers: correlation with smoking.

Genetic and environmental factors (dietary and smoking) influence lung cancer epidemiology and induce epigenetic modifications that should be assessed in individual populations. We analyzed p16 methylation among Greek non-small cell lung carcinoma patients and smokers using two-stage methylation-specific polymerase chain reaction. One hundred and fifty specimens from cancerous and adjacent non-cancerous tissue, bronchial washings and sputum from patients and 48 specimens, mostly sputum, from disease-free smokers were included. p16 methylation was very frequent in biopsies (82.85%) and bronchial washings (non-small cell lung carcinoma, 80.35%; small cell lung carcinoma, 16.66%) from patients, but also in adjacent non-cancerous tissue (45.71%). Concordance of p16 methylation and positivity by cytological examination was 51.78%. Methylation was also observed in sputum from asymptomatic cytology-negative smokers (22.5%) and chronic obstructive pulmonary disease patients (three of eight). Among disease-free individuals, methylation correlated only with heavy smoking (>50 pack-years, P<0.001) and differed among male and female disease-free smokers. In summary, p16 methylation is very frequent among non-small cell lung carcinoma patients, and correlates with heavy cigarette consumption only in disease-free smokers.     

Gene promoter methylation in plasma and sputum increases with lung cancer risk.

PURPOSE: Lung cancer is the leading cause of cancer mortality in the United States, due in part to the lack of a validated and effective screening approach for early detection. The prevalence for methylation of seven and three genes was examined in DNA from sputum and plasma, respectively, from women at different risk for lung cancer. EXPERIMENTAL DESIGN: Lung cancer survivors (n = 56), clinically cancer-free smokers (n = 121), and never smokers (n = 74) comprised the study population. Plasma was collected from all three groups, whereas sputum was collected from lung cancer survivors and smokers. RESULTS: Methylation was detected in plasma DNA from 10 of 74 women who never smoked. Prevalence for methylation of the p16 gene in plasma was highest in lung cancer survivors. Lung cancer survivors showed a significant increase in the odds of having at least one or more genes methylated in plasma (odds ratio, 3.6; 95% confidence interval, 1.9-9.1) than never smokers. The prevalence for methylation of the O(6)-methylguanine-DNA methyltransferase, ras effector homologue 1, death associated protein kinase, and PAX5alpha genes in sputum was significantly higher in lung cancer survivors compared with smokers. Lung cancer survivors had 6.2-fold greater odds (95% confidence interval, 2.1-18.5) for methylation of three or more genes in sputum compared with smokers. Methylation was more commonly detected in sputum than plasma for O(6)-methylguanine-DNA methyltransferase and ras effector homologue 1, but not p16, in lung cancer survivors. CONCLUSION: Concomitant methylation of multiple gene promoters in sputum is strongly associated with lung cancer risk.     

Methylation profile in tumor and sputum samples of lung cancer patients detected by spiral computed tomography: a nested case-control study

We evaluated the aberrant promoter methylation profile of a panel of 3 genes in DNA from tumor and sputum samples, in view of a complementary approach to spiral computed tomography (CT) for early diagnosis of lung cancer. The aberrant promoter methylation of RARbeta2, p16(INK4A) and RASSF1A genes was evaluated by methylation-specific PCR in tumor samples of 29 CT-detected lung cancer patients, of which 18 had tumor-sputum pairs available for the analysis, and in the sputum samples from 112 cancer-free heavy smokers enrolled in a spiral CT trial. In tumor samples from 29 spiral CT-detected patients, promoter hypermethylation was identified in 19/29 (65.5%) cases for RARbeta2, 12/29 (41.4%) for p16(INK4A) and 15/29 (51.7%) for RASSF1A. Twenty-three of twenty-nine (79.3%) samples of the tumors exhibited methylation in at least 1 gene. In the sputum samples of 18 patients, methylation was detected in 8/18 (44.4%) for RARbeta2 and 1/18 (5%) for both RASSF1A and p16(INK4A). At least 1 gene was methylated in 9/18 (50%) sputum samples. Promoter hypermethylation in sputum from 112 cancer-free smokers was observed in 58/112 (51.7%) for RARbeta2 and 20/112 (17.8%) for p16, whereas methylation of the RASSF1A gene was found in only 1/112 (0.9%) sputum sample. Our study indicates that a high frequency of hypermethylation for RARbeta2, p16(INK4A) and RASSF1A promoters is present in spiral CT-detected tumors, whereas promoter hypermethylation of this panel of genes in uninduced sputum has a limited diagnostic value in early lung cancer detection.     

肺癌患者组织样品中p16基因的异常甲基化

目的 分析肺癌患者组织样品中p16基因启动子区域异常甲基化的改变情况,评价该指标作为辅助临床诊断的分子标记物的价值。方法 运用甲基化特异性PCR技术,检测51例原发性肺癌患者的肿瘤组织、外周血血浆和痰标本中p16基因启动子区域的异常甲基化改变。结果 在43例肿瘤组织、36例血浆和39例痰标本中检测到了p16基因异常甲基化。凡在肿瘤组织检出p16基因甲基化阳性的病例,其血浆和(或)痰标本也为阳性;而肿瘤组织p16基因甲基化阴性的病例,其血浆和痰标本也为阴性。将血浆和痰标本的p16甲基化分析与痰细胞学检查相结合,可以发现92．2％的肺癌病例。结论 利用半巢式甲基化特异性PCR进行的血浆和痰标本p16基因甲基化分析,有可能成为辅助肺癌诊断的分子生物学指标。     

Aberrant methylation of multiple genes in the upper aerodigestive tract epithelium of heavy smokers

An important method for silencing tumor suppressor genes in cancers is by aberrant methylation (referred to as methylation) of CpG islands in gene promoter regions. In lung cancer, methylation of the genes retinoic acid receptor beta-2 (RARbeta-2), CDH13 (H-cadherin), p16(INK4a) (p16), RASSF1A (RAS association domain family I) is frequent. Thus, we investigated methylation of these genes in 4 different types of specimens (oropharyngeal brushes, sputum samples, bronchial brushes and bronchioloalveolar lavage [BAL] samples) of the upper aerodigestive tract epithelium from heavy smokers without evidence of cancer but with morphometric evidence of sputum atypia and compared the frequencies of methylation in the different types of specimens. In addition, we also analyzed sputum samples from 30 never smokers for methylation of these genes. Our major findings are: (i) At least one gene was methylated in one or more specimens from 48% of the smokers. However, methylation was statistically significant less frequently in never smokers compared to smokers. (ii) In general, methylation occurred more frequently in samples from the central airways (sputum, bronchial brushes) compared to the peripheral airways (BAL) and only occasionally in the oropharynx. (iii) RARbeta-2 was the most frequently methylated gene, whereas the frequency of methylation for the other genes was lower. (iv) Data from sputum samples and bronchial brushes were comparable. Our findings suggest that detection of methylation should be investigated as an intermediate marker for lung cancer risk assessment and response to chemopreventive regimens.     

K-ras and p16(INK4A)alterations in sputum of NSCLC patients and in heavy asymptomatic chronic smokers

NSCLC rates among the most frequent and lethal neoplasm world-wide and a significant decrease in morbidity and mortality relies only upon effective early diagnostic strategies. We investigated K-ras mutations and p16(INK4A) hypermethylation in tumor tissue and sputum of 50 patients with NSCLC and correlated them with sputum cytology and with tumor staging, grading and location, to ascertain, in sputum, their potential diagnostic impact. The same genetic/epigenetic abnormalities and cytological features were also evaluated in sputum from 100 chronic heavy smokers. Genetic analysis identified molecular abnormalities in 64% tumors (14/50 K-ras mutations and 24/50 p16(INK4A) hypermethylation) and in 48% sputum (11/50 K-ras mutations and 16/50 p16(INK4A) hypermethylation). In tumors K-ras mutations and p16(INK4A) hypermethylation were mostly mutually exclusive, being found in the same patients in 3 cases only. Genetic abnormalities in sputum were detected only in molecular abnormal tumors. Molecular changes in sputum had rates of detection similar to cytology (42%) but the cyto-molecular combination increased the diagnostic yield up to 60%. Interestingly, the rate of detection of genetic changes in sputum of tumors at early stage (T1) was not significantly different from that of tumors at more advanced stage (T2-T4). In fact K-ras point mutations were frequently recognised in tumors at early stage while p16(INK4A) inactivation prevailed in tumors at advanced stage ( P=0.0063). As expected, diagnostic cytological findings were more frequently found in tumors at advanced stage (P=0.004). No correlation was found between tumor grading and location (central versus peripheral) and molecular changes. p16(INK4A) hypermethylation, but not K-ras mutations, was documented in sporadic cases of asymptomatic heavy smokers (4%) where it was uncoupled from cytological abnormalities. In conclusion the cyto-molecular diagnostic strategy adopted in this study was able to detect the majority of tumors but in order to be proposed as effective and early diagnostic tool, this molecular panel needs to be tested in prospective studies with adequate follow-up.     

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.     

痰标本p16和MGMT基因甲基化对肺癌的诊断价值

目的：分析肺癌患者痰标本中p16和MGMT基因启动子区甲基化的改变情况,评价该指标作为肺癌辅助诊断分子标志物的价值。方法：运用甲基化特异性PCR技术,检测77例原发性肺癌患者痰标本和部分对应肿瘤组织(53例),以及30例正常对照者痰标本中p16和MGMT基因启动子区域的甲基化改变。结果：49例(63．6%)肺癌患者痰标本中检测到了pi6基因异常甲基化,34例(44．2%)检测到了MGMT基因异常甲基化,77例患者痰标本中2个基因中至少有1个基因出现甲基化为64例(83．1%),对肿瘤的检出灵敏度较高。长期吸烟史是影响肺鳞状细胞癌痰标本p16(P=0．001)基因启动子区甲基化的因素。随TNM分期增高,肺鳞状细胞癌患者痰标本中p16基因甲基化比例增高(P=0．021)；随TNM分期增高,肺腺癌患者痰标本MGMT基因甲基化比例增高(P=0．023)。对照组正常人痰液标本未发现p16和MGMT基因启动子区甲基化。结论：痰标本中p16和MGMT基因甲基化是临床肺癌辅助诊断的有效生物标志物之一。     

Hypermethylation of p16INK4a in Chinese lung cancer patients: biological and clinical implications

Promoter hypermethylation of the p16INK4a gene was investigated in 111 cases of tumor tissue, as well as in 136 circulating plasma and 95 sputum samples from Chinese patients with primary lung cancer, using a modified protocol of semi-nested methylation-specific-PCR (MSP). The results showed hypermethylated p16 sequence in 80.2% of tumor tissues and frequencies of 75.7 and 74.7% in plasma and sputum specimens, respectively. Among the patients, 50 cases of matched plasma, sputum and tumor tissue from the same individual were analyzed. Of these, hypermethylation of the p16 promoter was detected in 84.0% of the tumor tissues, with frequencies of 72.0 and 76.0% in the corresponding plasma and sputum, respectively. Notably, only patients whose tumor tissue showed hypermethylation of p16 exhibited the same aberrant methylation in their sputum and/or plasma. Hypermethylation of p16 in sputum and plasma samples may provide a more sensitive approach to molecular diagnosis of lung cancer than relying on conventional cytological analysis. Our data show that a combination of cytological analysis of sputum and examination of p16 hypermethylation in sputum and plasma identified 92.0% (46/50) of the lung cancer patients studied, offering an effective means of early detection of lung cancer.     

Aberrant promoter methylation in Chinese patients with non-small cell lung cancer: patterns in primary tumors and potential diagnostic application in bronchoalevolar lavage.

This study was aimed at defining patterns of aberrant gene methylation in non-small cell lung cancer (NSCLC) in Chinese patients and its use in detecting cancer cells in bronchoalveolar lavage (BAL). The methylation-specific PCR (MSP) was used to study methylation of the p16, retinoic acid receptor-beta (RARbeta), death-associated protein (DAP) kinase, and O(6)-methylguanine-DNA-methyltransferase (MGMT) genes in 75 NSCLCs [44 adenocarcinomas and 31 squamous cell carcinomas (SCCs)] and 68 BALs from suspected lung cancers. More females had adenocarcinoma than SCC (11 of 44 versus 2 of 31, P = 0.04). Aberrant methylation in at least one gene was found in 63 of 75 (84%) NSCLCs. p16, RARbeta, DAP kinase, and MGMT methylation was similar in adenocarcinoma and SCC. However, females with NSCLC showed more frequent p16 methylation than males (12 of 13 versus 36 of 62, P = 0.02), because of more frequent p16 methylation in female adenocarcinomas (10 of 11 versus 17 of 33, P = 0.02). This sexual difference was not observed in RARbeta, DAP kinase, and MGMT. At 92%, the frequency of p16 methylation in Chinese female NSCLC is one of the highest known. For BAL, MSP and cytological analysis showed concordant and discordant results in 25 of 68 and 43 of 68 samples. Of 41 MSP+/cytology- cases, 35 were eventually shown to have malignant lung lesions, 4 were at high risk but had no evidence of lung cancer, and 2 were lost to follow-up. There were two MSP-/cytology+ cases. Frequent gene methylations were seen in Chinese NSCLC patients. More frequent p16 methylation was seen in female patients. MSP is a useful molecular adjunct for cancer cell detection in BAL samples.     

Aberrant p16 promoter methylation in smokers and former smokers with nonsmall cell lung cancer

Hypermethylation of cytosines in CpG-rich islands of the promoter regions of regulatory genes has been discovered as a common mechanism of gene silencing during carcinogenesis. We analysed 64 primary lung carcinomas for promoter methylation of the tumour suppressor genes (TSGs) p16 (p16(INK4a)/CDKN2A) and p14 (p14(ARF)) by methylation-specific PCR, in order to evaluate aberrant methylation as a potential biomarker for epigenetic alterations in tobacco-related lung cancer. Methylation of p16 was observed in 34% (22/64) of the lung tumours examined. In particular, p16 methylation occurred in nonsmall cell lung cancer (NSCLC) only, with 41 % (22/54) of the tumours being positive. The highest frequency was found in large cell carcinoma (5/7, 71%), followed by adenocarcinoma (9/25, 36%) and squamous cell carcinoma (7/21, 33%). Methylation of the p14 gene was less frequent in lung cancer (4/52, 8%). When association with tobacco smoking was analysed, 42% (21/50) of NSCLC from ever smokers exhibited p16 methylation. Interestingly, the analysis revealed a significantly higher risk of p16 methylation in former smokers as compared to current smokers [odds ratio (OR) 5.1; 95% confidence interval (CI) 1.3-22]. The difference was retained after adjustment for age (OR 3.7; 95% CI 0.9-17). The promoter methylation results were then combined with data on genetic alterations determined previously in the same set of tumours. This data similarly showed that p16 methylation in parallel with p53 gene mutation or p14 methylation occurred more frequently in former smokers than in current smokers (44% vs. 14%; P = 0.035). Taken together, our data suggest that analysis of promoter methylation in TSGs may provide a valuable biomarker for identification of groups with an elevated risk of cancer, such as smokers and ex-smokers.     

NSCLC患者血清中p16、DAP基因甲基化的研究

目的：探讨p16、死亡相关蛋白激酶（death-associated protein kinase,DAP）基因的异常甲基化作为非小细胞肺癌（NSCLC）患者诊断的基因标志物的可行性。方法：采用甲基化特异性PCR（MSP）法检测30例NSCLC患者肿瘤组织及对应血清中p16、DAP基因的异常甲基化，结果：NCSLC肿瘤中60．0％（18／30）检测出至少一个基因启动子呈甲基化改变，在18例肿瘤组织检测到异常甲基化的患者中，50．0％的患者（9／18）在血清中检测到相应的改变。所有的癌旁组织、健康对照组的血清中及正常肺组织均未检测到p16、DAP的甲基化，结论：检测NSCLC患者血清中p16、DAP基因异常甲基化有可能成为肺癌诊断的分了标志物。     

Alterations of the p16(ink4a) gene in resected nonsmall cell lung tumors and exfoliated cells within sputum

Recently, we reported that p16 protein expression was nondetectable in 49.5% of 107 resected nonsmall cell lung cancers (NSCLCs), suggesting that the p16(INK4a) gene is frequently inactivated in primary NSCLC. To identify the molecular basis for this p16 immunohistochemical negativity further, we performed a genetic and epigenetic study of p16(INK4a) status in a series of 115 NSCLC samples parallel to the clinicopathologic and prognostic analyses. Microdissected tumor DNA samples were screened for homozygous deletion using comparative multiplex-polymerase chain reaction (PCR), for intragenic mutation using direct sequencing and for loss of heterozygosity (LOH) using an intragenic microsatellite marker, D9S942. Of these samples, 67 were further analyzed by SmaI-based PCR methylation assay to evaluate aberrant methylation at the gene. To examine the correlation of aberrant methylation in tumor and sputum samples, sputum samples from 12 matched patients were assessed for this change. We found that methylation of the p16(INK4a) gene was present in 38 of the 67 (56.7%) tumors and was significantly associated with negative p16 protein expression (p = 0.029). A 92% (11/12) concordance of sputum samples with matched resected tumors was found. The survival rates among adenocarcinoma patients with p16(INK4a) methylation were lower, but at a level of borderline significance compared with those patients without methylation (p = 0.071). In addition, 29.4% of the informative cases were found to harbor LOH at D9S942. None of the 115 microdissected tumors exhibited homozygous deletion in the p16(INK4a) gene. Only 1 patient exhibited a complex mutation at the fourth ankyrin repeat consensus sequence and concordantly demonstrated p16 immunohistochemical negativity. Overall, 69% (79/115) of NSCLC tumors had at least 1 type of p16(INK4a) alteration. Our data provide compelling evidence that p16(INK4a) alterations are involved in NSCLC tumorigenesis and that promoter methylation is the predominant mechanism in p16(INK4a) deregulation.     

甲基化特异性PCR检测肺癌p16基因甲基化及其临床意义

目的:探讨甲基化特异性聚合酶链反应(methylation-specific PCR,MSPCR)在肺癌临床诊断中的应用价值.方法:选取56例肺部疾病住院患者手术切除的病变肺组织和相应的支气管肺泡灌洗液(BALF)及痰标本,其中32例为肺癌,24例为良性肺部疾病.标本经一般处理,PCR扩增后,产物经电泳EB染色,紫外灯下观察.结果:32例肺癌组织标本中,14例(43.8%)在p16基因启动子区域呈现异常甲基化,其中9例(64.3%)在相应的BALF中检测出甲基化存在,5例(35.8%)在相应的痰标本中也检测出甲基化存在.24例良性肺部疾病,其中肺囊肿10例,肺结核14例,手术切除标本和BALF及痰标本中均未检测出p16基因甲基化存在.结论:MSPCR技术对肺癌患者BALF及痰标本中的异常甲基化检测具有高度特异性,是一项有潜力的肺癌早期诊断新技术.     

Aberrant promoter methylation in bronchial epithelium and sputum from current and former smokers

Recent studies from our laboratory suggest that gene-specific methylation changes in sputum could be good intermediate markers for the early detection of lung cancer and defining the efficacy of chemopreventive interventions. The purpose of our study was to determine the prevalence for aberrant promoter methylation of the p16, O(6)-methylguanine-DNA methyltransferase (MGMT), death-associated protein (DAP) kinase, and Ras effector homologue (RASSFIA) genes in nonmalignant bronchial epithelial cells from current and former smokers in a hospital-based, case control study of lung cancer. The relationship between loss of heterozygosity, at 9p and p16 methylation in bronchial epithelium and the prevalence for methylation of these four genes in sputum from cancer-free, current and former smokers were also determined. Aberrant promoter methylation of p16 was seen in at least one bronchial epithelial site from 44% of cases and controls. Methylation of the DAP kinase gene was seen in only 1 site from 5 cases and 4 controls, whereas methylation of the RASSFIA was not detected in the bronchial epithelium. Promoter methylation for p16 and DAP kinase was seen as frequently in bronchial epithelium from current smokers as from former smokers. No promoter methylation of these genes was detected in bronchial epithelium from never-smokers. Methylation of the p16 gene was detected in sputum from 23 of 66 controls. DAP kinase gene promoter methylation was also seen in sputum from 16 controls, and 8 of these subjects were positive for p16 methylation. Methylation of the MGMT gene was seen in sputum from 9 controls, whereas RASSFIA promoter methylation was only seen in 2 controls. The correlation between p16 status in the bronchial epithelium obtained from lung lobes that did not contain the primary tumor and the tumor itself was examined. Seventeen of 18 tumors (94%) showed an absolute concordance, being either methylated in the tumor and at least 1 bronchial epithelial site, or unmethylated in both tumor and bronchial epithelium. These results indicate that aberrant promoter hypermethylation of the p16 gene, and to a lesser extent, DAP kinase, occurs frequently in the bronchial epithelium of lung cancer cases and cancer-free controls and persists after smoking cessation. The strong association seen between p16 methylation in the bronchial epithelium and corresponding primary tumor substantiates that inactivation of this gene, although not transforming by itself, is likely permissive for the acquisition of additional genetic and epigenetic changes leading to lung cancer.     

Molecular alterations in spontaneous sputum of cancer-free heavy smokers: results from a large screening program.

PURPOSE: The high mortality rate for lung cancer is likely to be reduced by the development of a panel of sensitive biological markers able to identify early-stage lung cancers or subjects at high risk. The aim of this study was to establish the frequency of K-ras and p53 mutations and p16(INK4A), RASSF1A, and NORE1A hypermethylation in sputum of a large cohort of cancer-free heavy smokers and to assess whether these markers are suitable for a routine use in the clinical practice for the early diagnosis of pulmonary cancer. EXPERIMENTAL DESIGN: Sputum samples were collected from 820 heavy smokers. Inclusion criteria consisted of radiologic and cytologic absence of pulmonary lesions, age at least 60 years, male gender, and a smoking history of at least 20 pack-years. RESULTS: The analysis identified 56 individuals (6.9%) with one molecular alteration. p53 mutation and p16(INK4A), RASSF1A, and NORE1A methylation frequencies were 1.9%, 5.1%, 0.8%, and 1.0%, respectively; no K-ras mutations were found. One patient with p53 mutations was diagnosed with an early-stage lung cancer after 3-years of follow-up. The molecular analysis of bronchoscopy samples confirmed in half of the cases alterations present in sputum without revealing additional molecular changes. CONCLUSIONS: Genetic and epigenetic abnormalities can be detected in cancer-free heavy smokers. Although the predictive value of the cancer risk is still to be established as it requires not less than 5 years of follow-up, p53 and p16(INK4A) are more promising candidates than K-ras, RASSF1A, and NORE1A for the pulmonary molecular screening of heavy smokers healthy individuals.     

Equivocal cytology in lung cancer diagnosis: improvement of diagnostic accuracy using adjuvant multicolor FISH, DNA-image cytometry, and quantitative promoter hypermethylation analysis

BACKGROUND:

Sometimes, cytological lung cancer diagnosis is challenging because equivocal diagnoses are common. To enhance diagnostic accuracy, fluorescent in situ hybridization (FISH), DNA‐image cytometry, and quantitative promoter hypermethylation analysis have been proposed as adjuncts.

METHODS:

Bronchial washings and/or brushings or transbronchial fine‐needle aspiration biopsies were prospectively collected from patients who were clinically suspected of having lung carcinoma. After routine cytological diagnosis, 70 consecutive specimens, each cytologically diagnosed as negative, equivocal, or positive for cancer cells, were investigated with adjuvant methods. Suspicious areas on the smears were restained with the LAVysion multicolor FISH probe set (Abbott Molecular, Des Plaines, Illinois) or according to the Feulgen Staining Method for DNA‐image cytometry analysis. DNA was extracted from residual liquid material, and frequencies of aberrant methylation of APC, p16^INK4A, and RASSF1A gene promoters were determined with quantitative methylation‐specific polymerase chain reaction (QMSP) after bisulfite conversion. Clinical and histological follow‐up according to a reference standard, defined in advance, were available for 198 of 210 patients.

RESULTS:

In the whole cohort, cytology, FISH, DNA‐image cytometry, and QMSP achieved sensitivities of 83.7%, 78%, 79%, and 49.6%, respectively (specificities of 69.8%, 98.2%, 98.2%, and 98.4%, respectively). Subsequent to cytologically equivocal diagnoses, FISH, DNA‐image cytometry, and QMSP definitely identified malignancy in 79%, 83%, and 49%, respectively. With QMSP, 4 of 22 cancer patients with cytologically negative diagnoses were correctly identified.

CONCLUSIONS:

Thus, adjuvant FISH or DNA‐image cytometry in cytologically equivocal diagnoses improves diagnostic accuracy at comparable rates. Adjuvant QMSP in cytologically negative cases with persistent suspicion of lung cancer would enhance sensitivity. Cancer (Cancer Cytopathol) 2011;. © 2011 American Cancer Society.     

Hypermethylation of E-cadherin gene is frequent and independent of p16INK4A methylation in non-small cell lung cancer: potential prognostic implication

E-cadherin gene is often termed a 'metastasis suppressor' gene and inactivation of this gene through promoter methylation occurs in various epithelial cancer. This study assessed the methylation status of p16INK4a and E-cadherin genes, correlated with clinical characteristics in lung cancer patients. Forty-five patients with non-small cell lung cancer (NSCLC) were evaluated for methylation status of p16INK4a and E-cadherin genes by using the methylation-specific PCR. E-cadherin expression in tumor samples was examined by immunohistochemistry. Overall duration of survival in different subsets of NSCLC with or without p16INK4a or E-cad methylation at diagnosis was compared by using the Kaplan-Meier method and log-rank test. We found the hypermethylation of p16INK4a gene in 38% (17/45) of our subjects. While the E-cadherin gene was hypermethylated in 62% (28/45) related with reduced E-cadherin expression, and methylation status of both p16INK4a and E-cadherin genes seemed to be independent. Seventy-six percent (34/45) of NSCLC patients had an abnormal methylation pattern in at least one gene. Although there was no difference in overall survival of patients between methylated p16INK4a and unmethylated p16INK4a, NSCLS patients with hypermethylation of both genes (concordant pattern) had a significantly good prognosis. In contrast, NSCLC patients with hypermethylated p16INK4a but un-methylated E-cadherin gene (discordant pattern) had a significantly poor prognosis. E-cadherin and p16INK4a are commonly methylated in NSCLC and the methylation pattern of p16INK4a and E-cadherin genes may have prognostic value for the outcome of NSCLC patients.