Figures
Abstract
Background
The p16INK4a is an important tumor suppressor gene (TSG) and aberrant methylation of promoter is known to be a major inactivation mechanism of the tumor suppressor and tumor-related genes. Aberrant TSG methylation was considered an important epigenetic silencing mechanism in the progression of head and neck squamous cell carcinoma (HNSCC). However, some studies have reported differences in the methylation frequencies of P16INK4a promoter between cancer and the corresponding control group. Therefore, we conducted a meta-analysis to better identify the association.
Methods
PubMed, Ovid, ISI Web of Science, and EMBASE were searched to identify eligible studies to evaluate the association of p16INK4a promoter methylation and HNSCC. Odds ratio (ORs) and 95% confidence intervals (95%CI) were calculated to evaluate the strength of association between p16INK4a promoter methylation and HNSCC.
Results
A total of twenty-one studies with 1155 cases and 1017 controls were included in the meta-analysis. The frequencies of p16INK4a promoter methylation in the cancer group were significantly higher than those in the control group (cancer group: median: 46.67%, range = 7.84%-95.12%; control group: median: 18.37%, range = 0–83.33%; respectively). The pooled odds ratio was 3.37 (95%CI = 2.32–4.90) in the cancer group versus the corresponding control group under the random-effects model.
Citation: Shi H, Chen X, Lu C, Gu C, Jiang H, Meng R, et al. (2015) Association between P16INK4a Promoter Methylation and HNSCC: A Meta-Analysis of 21 Published Studies. PLoS ONE 10(4): e0122302. https://doi.org/10.1371/journal.pone.0122302
Academic Editor: Torbjörn Ramqvist, Karolinska Institutet, SWEDEN
Received: September 23, 2014; Accepted: February 19, 2015; Published: April 2, 2015
Copyright: © 2015 Shi et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by the National Natural Science Foundation of China (81373092).
Competing interests: The authors have declared that no competing interests exist.
Introduction
Head and neck squamous cell carcinoma (HNSCC) occurs in the oral cavity, oropharynx, hypopharynx and larynx. HNSCC is the sixth most common cancer worldwide and the fifth leading cause of cancer death. Over 500,000 HNSCC cases occur each year [1]. However, the five-year survival of patients with HNSCC was only 40–50% [2].
The pathogenesis of HNSCC is a multistep and multifactorial complex mechanism containing a variety of genetic and epigenetic abnormalities, signal transduction, apoptosis, angiogenesis, and cell cycle regulation [3]. Epigenetic inactivation of the gene resulted from the methylation of CpG islands in promoters is one of the most frequent events in human tumors. The p16INK4a gene plays a key role in cell cycle regulation and is located on chromosome 9p21 which consisting of three exons and two introns, spanning approximately 8.5 kb [4, 5]. It is one of the most frequently altered genes observed in various human tumors [6, 7]. P16 prevents the inactivation of retinoblastoma (Rb) protein by inhibiting the cyclin dependent kinases (CDks) and retinoblastoma (Rb) pathway plays an important role in apoptosis and cell cycle regulation [8]. More studies have shown that methylation of p16INK4a promoter may play an important role in the development of HNSCC.
Some studies have reported differences in the methylation frequencies of p16INK4a promoter between cancer and non-cancerous. However, the results are inconsistent. Therefore, the aims of this meta-analysis are to consolidate the available data and to better identify the association between p16INK4a promoter methylation and HNSCC.
Materials and Methods
Search Strategy
Relevant studies were identified from the online electronic databases (PubMed, Ovid, ISI Web of Science, and EMBASE) using the search terms: (squamous cell carcinoma or cancer) and (oropharyngeal or oropharynx or head and neck or tonsil) AND (p16 methylation). The search was limited to English language paper. The search results were updated until August 20, 2014.
Study Selection
A study included in the meta-analysis had to meet the following criteria: (1) studies with evaluating the association between p16INK4a promoter methylation frequency and HNSCC, (2) case-control study or providing the case and the control cases, (3) providing the p16INK4a promoter methylation frequency in case and control groups, (4) specimens of HNSCC were surgically respected primary tumor sample. Firstly, the titles and abstracts of initial searching articles were evaluated for whether it met the inclusion criteria. Then all potentially relevant articles were evaluated on full-text paper. If the results of a study were published more than once, only the most complete and up-to-date information were included in the meta-analysis. The study selection process was shown in Fig 1. Finally, a total of 21 studies (PubMed 13, Web of Science 7, Ovid 1) which contain 1155 cases and 1017 controls were included in our meta-analysis.
Data Extraction and Quality Assessment
Three reviewers (Hao Shi, Changmei Gu, and Ruiwei Meng) independently reviewed the included articles. The following information was extracted from the included studies: first author’s name, year of publication, study population, sample size, sample type in case and control group, the state of the individual of the control group, the number of people with p16INK4a methylation in the case and control groups, the number of the case and control groups. All the detailed information of the included studies was checked by three reviewers (Meixia Lu, Xiong Chen, and Cheng Lu) as described in the Cochrane Handbook for systematic reviews.
Statistical Methods
The pooled odds ratios (ORs) and their 95% confidence intervals (CIs) were used to assess the strength of the association between p16INK4a promoter methylation and HNSCC. The x2-based Cochran Q statistic test and I2 statistics were used to test the between-study heterogeneity [9]. When P<0.05 for the Q statistic or I2 ≥50%, the heterogeneity was considered significant and a random-effects model was used to calculate the pooled ORs. Otherwise, a fixed-effects model was applied. The meta-regression (method = restricted maximum-likelihood estimator) was employed to explore the source of heterogeneity. And the subgroup analysis was performed for further evaluation of the source of heterogeneity. The contribution of each study to the final results of the meta-analysis was evaluated according to the sensitivity analysis. Begg’s funnel plot [10] and Egger’s test [11] were used to assess the publication bias. The fail-safe number [12] was also employed to assess the publication bias. In the study, all the P values are two sides with a significant level at 0.05. When the individual studies have cells with zero counts, the default is to add 0.5 to all zero counts in the Meta package. All statistical analyses were performed with the Meta package (version 3.0–1; http://CRAN.R-project.org/package=meta) in R (version 3.10; http://www.r-project.org/).
Results
Study Characteristics
The comprehensive search and selection procedures of literature were displayed in Fig 1 for evaluating the association between p16INK4a promoter methylation frequency and HNSCC. A total of 21 studies with 1155 cases and 1017 controls were included in the meta-analysis. 397 studies were initially identified by searching the electronic databases. 63 potentially relevant studies were retrieved for further evaluation after removing 82 duplicated articles, 59 reviews or meeting reviews, 9 cell lines and animal studies, 175 irrelevant articles, and 9 papers that did not have full text versions. 32 studies without a control group, 8 studies without p16INK4a promoter methylation data, and 2 studies without tissue in the case group were excluded from full-text review. Finally, 21 studies were included in our meta-analysis. Ten studies were of Asian subjects and eleven studies were of Caucasian subjects. The control group included HNSCC patients, benign disease patients, and healthy people. And the sample type of control group included tissue, serum, blood, and saliva. The methylation detection method of p16INK4a in HNSCC and control included 16 studies used methylation-specific polymerase chain reaction (MSP), three studies used real-time quantitative MSP (QMSP), one study used PCR-based methylation-sensitive restriction analysis (MSRA), and one study used pyrosequencing (Pyro). Six studies [13–18] were the methylated CpG islands of promoter and fifteen studies [19–33] were the methylation of promoter. Study characteristics were summarized in Table 1.
Combining Results of Included Studies
The combining result showed the association of p16INK4a promoter methylation with HNSCC risk in Fig 2. A random-effects model was employed because of the significant heterogeneity was observed among the included studies (I2 = 60.1%, Q = 50.07, P<0.001). In the overall meta-analysis, p16INK4a promoter methylation frequency was significantly associated with HNSCC (Summary OR was 3.37, 95%CI = 2.32–4.90) (Fig 2).
Sensitivity Analysis
A sensitivity analysis was performed by omitting a single study and calculating the pooled OR for the remaining studies under the random-effect model to assess the effects of each individual study on the pooled OR. The results of sensitivity analysis were summarized in the Table 2. According to sensitivity analysis the odds ratio ranged from 3.10 (95%CI = 2.16–4.46) to 3.65 (95%CI = 2.55–5.23) by omitting a single study under the random-effect model. The sensitivity analysis indicated that the pooled OR between p16INK4a promoter methylation and HNSCC were reliable and stable.
Meta-regression and Subgroup Analysis
As the significant heterogeneity across the studies was found (I2 = 60.1%, Q = 50.07, P<0.001), the meta-regression was employed to explore potential sources of heterogeneity. We conducted a multiple regression model with six variables (i.e. Population subgroup, publication year, case sample size, control type, control sample type, and method). No source of significant heterogeneity was found (Table 3). The subgroup analysis was performed to further evaluate the source of the heterogeneity according to populations, case sample size, control type, control sample type, and method.
The OR for was 4.76 (95%CI = 3.00–7.54) in Asians under the random-effects model, and 2.25 (95%CI = 1.61–3.13) in Caucasians under the fixed-effects model. With the case sample size, the OR for was 3.33 (95%CI = 1.68–6.60) in the >60 case group under the random-effects model, and 3.59 (95%CI = 2.65–4.87) in the ≤60 case group under the fixed-effects model. In the subgroup analysis of the control type, the frequencies of p16INK4a promoter methylation in the autologous group were higher than those in the heterogeneous group including benign disease and healthy individuals under the random-effects model (Autologous: 3.14, 95%CI = 1.76–5.59; Heterogeneous: 4.62, 95%CI = 2.43–8.79; respectively). Subgroup analysis of the control sample type showed that the frequencies of p16INK4a promoter methylation in the Non-tissue group (control sample type: serum or saliva) were higher than those in the tissue group (control sample type: tissue) under the random-effects model (Non-tissue: 5.92, 95%CI = 2.94–15.30; Tissue: 3.43, 95%CI = 2.25–5.24; respectively). For the methylation detection method of p16INK4a promoter, Ghosh [27] used PCR-based methylation-sensitive restriction analysis (MSRA) and we have put the study classified as MSP group. The OR was 7.30 (95%CI = 4.26–12.48) in the QMSP group under the fixed-effects model, 2.83 (95%CI = 1.89–4.23) in the MSP group under the random-effects model, and 9.48 (95%CI = 1.21–74.26) in the Pyro group. All results of subgroup analysis were summarized in Table 4.
Publication bias
Begg’s funnel plot, Egger’s test, and the fail-safe number were performed to assess the publication bias of the literature. The shape of the Begg’s funnel plot in Fig 3 showed a possible asymmetry, but the Egger’s test did not detect publication bias (P = 0.25). The fail-safe number (Z = 54.20, Nfs0.05 = 1071.09, Nfs0.01 = 520.05) also did not display statistical evidence for publication bias.
Discussion
Hypermethylation of the tumor suppressor gene (TSG) promoter can be found in various cancers and induce the silencing of tumor suppressor genes in the process of carcinogenesis. The p16INK4a is an important tumor suppressor and DNA repair genes with a major negative regulator of critical tumor pathway [34] and the pl6/cyclin D/CDK/pRB pathway is also prominent in many epithelial malignancies [35]. Inactivation of p16INK4a induced by aberrant hypermethylation plays a role in the process of carcinogenesis in various cancers (i.e. Lung, hepatocellular, gastric, and breast cancer) [36–39].
The current meta-analysis assessed the association between p16INK4a promoter methylation and HNSCC, which included 21 studies with 1155 cases and 1017 controls. The frequency of p16INK4a promoter methylation in tumor was 43.98% and 21.14% in control. The pooled odds ratio under a random-effect model was 3.37 (95%CI = 2.32–4.90) in the cancer cases versus the controls. The result identified that methylation of p16INK4a promoter had 3.37 fold increased risks of HNSCC compared with the control group.
In subgroup analysis, the OR for was 4.76 (95%CI = 3.00–7.54) in Asians under the random-effects model, and 2.25 (95%CI = 1.61–3.13) in Caucasians under the fixed-effects model. The association between p16INK4a promoter methylation and HNSCC in Asians was stronger than that in Caucasians. Similarly, Kaur’s study observed that the frequency of p16INK4a promoter methylation (47.8%) in Indian cohort was higher than that in North-American cohort (37.5%) [25]. In method subgroup, The OR was 7.30 (95%CI = 4.26–12.48) in the QMSP group under the fixed-effects model, 2.83 (95%CI = 1.89–4.23) in the MSP group under the random-effects model, and 9.48 (95%CI = 1.21–74.26) in the Pyro group. In the past few years, several methods were developed to detect aberrant gene methylation (e.g. MSP, QMSP, Pyro, etc.). MSP is a simple, sensitive, and specific method for detecting the methylation status of CpG rich region [40]. However, MSP and QMSP require particular gene sequence information for the design of PCR primers [41]. The different primers may have an impact on the results. MSP (a nonquantitative nonfluorometric PCR method) could not detect low levels of promoter methylation, unlike QMSP which can detect up to 1/1000 methylated alleles [42]. Pyro is a much more accurate and quantitative method in detecting gene methylation level and is based on DNA sequence analysis. The detection method of gene methylation and primers selected from regions of the same CpG island and gene promoter was different in each study. These factors may have different sensitivities and specificities in detection of gene methylation [43]. In addition, the degrees of heterogeneity of tumors are different, either as infiltrating normal cells or different clones of tumor cells. This will influence the results of methylation analyses. These reasons may lead to different results and be a source of heterogeneity. In the subgroup analysis of sample size, control type, and control sample type, significant associations were observed for all subgroups.
Some studies found that reduced p16 expression in 55–89% of oral and oropharyngeal SCC [44–46]. The unusual p16 protein expression is probably due to different demographical and clinicopathological characteristics, HPV-driven HNSCC cases, or gene hypermethylation, etc [47–49]. Demokan’s study noted that promoter hypermethylation levels were associated with decreased p16 expression in the tumor samples [22]. Interestingly, Annette’s study found that 95% (110/116) of OSCC did not overexpress p16, while p16INK4a promoter methylation was 18% (20/113) [50]. Human papillomaviruses (HPV) is also an important factor in carcinogenesis of HNSCC. It is well documented that HPV infection induced overexpression p16 in OSCCs [51–54], however, Weiss’s study did not show any significantly difference frequencies of p16INK4a promoter methylation between HPV16 positive cancer and HPV16 negative cancer [24]. Then, future studies are needed to evaluate the interaction of HPV16 infection and p16INK4a promoter methylation on expression p16 in HNSCC.
There were some limitations in the meta-analysis. Firstly, a significant heterogeneity across the studies was found (I2 = 60.1%, Q = 50.07, P<0.001) in the meta-analysis. According to meta-regression and subgroup analysis, no sources of heterogeneity were founded. Therefore, some source of heterogeneity may exist among studies. Secondly, we do not study the association between p16INK4a promoter methylation and disease characteristics (stage, metastasis, relapse and so on) of HNSCC. According to study the association between p16INK4a promoter methylation and disease characteristics, the special role of p16INK4a promoter methylation in the carcinogenic process of HNSCC may be found.
In conclusion, the results of the meta-analysis showed aberrant methylation of p16INK4a promoter was found to be associated with HNSCC, which suggested that promoter methylation of p16INK4a may be a potential biomarker in the carcinogenic process of HNSCC.
Supporting Information
S2 Checklist. Meta-analysis on Genetic Association Studies Checklist.
https://doi.org/10.1371/journal.pone.0122302.s002
(DOCX)
Author Contributions
Conceived and designed the experiments: MXL XC YXH. Performed the experiments: HS CL XN. Analyzed the data: HS CMG RWM. Contributed reagents/materials/analysis tools: MXL HWJ. Wrote the paper: HS XC.
References
- 1. Jemal A, Bray F, Center MM, Ferlay J, Ward E, Forman D. Global cancer statistics. CA: a cancer journal for clinicians. 2011;61(2):69–90. Epub 2011/02/08. pmid:21296855.
- 2. Leemans CR, Braakhuis BJ, Brakenhoff RH. The molecular biology of head and neck cancer. Nature reviews Cancer. 2011;11(1):9–22. Epub 2010/12/17. pmid:21160525.
- 3. Scully C, Field JK, Tanzawa H. Genetic aberrations in oral or head and neck squamous cell carcinoma (SCCHN): 1. Carcinogen metabolism, DNA repair and cell cycle control. Oral Oncol. 2000;36(3):256–63. Epub 2000/05/04. pmid:10793327.
- 4. Lukas J, Parry D, Aagaard L, Mann DJ, Bartkova J, Strauss M, et al. Retinoblastoma-protein-dependent cell-cycle inhibition by the tumour suppressor p16. Nature. 1995;375(6531):503–6. Epub 1995/06/08. pmid:7777060.
- 5. Piepkorn M. Melanoma genetics: an update with focus on the CDKN2A(p16)/ARF tumor suppressors. Journal of the American Academy of Dermatology. 2000;42(5 Pt 1):705–22; quiz 23–6. Epub 2000/04/25. pmid:10775844.
- 6. Nobori T, Miura K, Wu DJ, Lois A, Takabayashi K, Carson DA. Deletions of the cyclin-dependent kinase-4 inhibitor gene in multiple human cancers. Nature. 1994;368(6473):753–6. Epub 1994/04/21. pmid:8152487.
- 7. Okamoto A, Demetrick DJ, Spillare EA, Hagiwara K, Hussain SP, Bennett WP, et al. Mutations and altered expression of p16INK4 in human cancer. Proc Natl Acad Sci U S A. 1994;91(23):11045–9. Epub 1994/11/08. pmid:7972006; PubMed Central PMCID: PMC45163.
- 8. de Assis LV, Locatelli J, Isoldi MC. The role of key genes and pathways involved in the tumorigenesis of Malignant Mesothelioma. Biochimica et biophysica acta. 2014;1845(2):232–47. Epub 2014/02/05. pmid:24491449.
- 9. Higgins JP, Thompson SG. Quantifying heterogeneity in a meta-analysis. Statistics in medicine. 2002;21(11):1539–58. Epub 2002/07/12. pmid:12111919.
- 10. Begg CB, Mazumdar M. Operating characteristics of a rank correlation test for publication bias. Biometrics. 1994;50(4):1088–101. Epub 1994/12/01. pmid:7786990.
- 11. Egger M, Davey Smith G, Schneider M, Minder C. Bias in meta-analysis detected by a simple, graphical test. BMJ (Clinical research ed). 1997;315(7109):629–34. Epub 1997/10/06. pmid:9310563; PubMed Central PMCID: PMC2127453.
- 12. R R. The file drawer problem and tolerance for null results. Psychological bulletin. 1979;(86):638–41.
- 13. Laytragoon-Lewin N, Chen F, Castro J, Elmberger G, Rutqvist LE, Lewin F, et al. DNA content and methylation of p16, DAPK and RASSF1A gene in tumour and distant, normal mucosal tissue of head and neck squamous cell carcinoma patients. Anticancer research. 2010;30(11):4643–8. Epub 2010/12/01. pmid:21115918.
- 14. Steinmann K, Sandner A, Schagdarsurengin U, Dammann RH. Frequent promoter hypermethylation of tumor-related genes in head and neck squamous cell carcinoma. Oncology reports. 2009;22(6):1519–26. Epub 2009/11/04. pmid:19885608.
- 15. Shaw RJ, Liloglou T, Rogers SN, Brown JS, Vaughan ED, Lowe D, et al. Promoter methylation of P16, RAR beta, E-cadherin, cyclin A1 and cytoglobin in oral cancer: quantitative evaluation using pyrosequencing. British journal of cancer. 2006;94(4):561–8. PubMed PMID: WOS:000235475300017. pmid:16449996
- 16. Maruya S, Issa JP, Weber RS, Rosenthal DI, Haviland JC, Lotan R, et al. Differential methylation status of tumor-associated genes in head and neck squamous carcinoma: incidence and potential implications. Clinical cancer research: an official journal of the American Association for Cancer Research. 2004;10(11):3825–30. Epub 2004/06/03. pmid:15173091.
- 17. Nakahara Y, Shintani S, Mihara M, Ueyama Y, Matsumura T. High frequency of homozygous deletion and methylation of p16(INK4A) gene in oral squamous cell carcinomas. Cancer Letters. 2001;163(2):221–8. PubMed PMID: WOS:000168440600011. pmid:11165758
- 18. Sanchez-Cespedes M, Esteller M, Wu L, Nawroz-Danish H, Yoo GH, Koch WM, et al. Gene promoter hypermethylation in tumors and serum of head and neck cancer patients. Cancer research. 2000;60(4):892–5. Epub 2000/03/08. pmid:10706101.
- 19.
Kis A, Tatar TZ, Gall T, Boda R, Tar I, Major T, et al. Frequency of Genetic and Epigenetic Alterations of p14ARF and p16INK4A in Head and Neck Cancer in a Hungarian Population. Pathology oncology research: POR. 2014. Epub 2014/04/09. https://doi.org/10.1007/s12253-014-9775-9 pmid:24710824.
- 20.
Bhatia V, Goel MM, Makker A, Tewari S, Yadu A, Shilpi P, et al. Promoter Region Hypermethylation and mRNA Expression of MGMT and p16 Genes in Tissue and Blood Samples of Human Premalignant Oral Lesions and Oral Squamous Cell Carcinoma. Biomed Research International. 2014. https://doi.org/10.1155/2014/248419 PubMed PMID: WOS:000337398400001.
- 21. Dang J, Bian Y-Q, Sun JY, Chen F, Dong G-Y, Liu Q, et al. MicroRNA-137 promoter methylation in oral lichen planus and oral squamous cell carcinoma. Journal of Oral Pathology & Medicine. 2013;42(4):315–21.
- 22. Demokan S, Chuang A, Suoglu Y, Ulusan M, Yalniz Z, Califano JA, et al. Promoter methylation and loss of p16(INK4a) gene expression in head and neck cancer. Head & neck. 2012;34(10):1470–5. Epub 2011/11/23. pmid:22106032.
- 23. Wong YK, Lee LT, Liu CJ. Hypermethylation of MGMT and DAPK gene promoters is associated with tumorigenesis and metastasis in oral squamous cell carcinoma. Journal of Dental Sciences. 2011;6(3):158–64. PubMed PMID: WOS:000295905700006.
- 24. Weiss D, Basel T, Sachse F, Braeuninger A, Rudack C. Promoter Methylation of Cyclin A1 Is Associated With Human Papillomavirus 16 Induced Head and Neck Squamous Cell Carcinoma Independently of p53 Mutation. Molecular Carcinogenesis. 2011;50(9):680–8. PubMed PMID: WOS:000293952200003. pmid:21563216
- 25. Kaur J, Demokan S, Tripathi SC, Macha MA, Begum S, Califano JA, et al. Promoter hypermethylation in Indian primary oral squamous cell carcinoma. International journal of cancer Journal international du cancer. 2010;127(10):2367–73. Epub 2010/05/18. pmid:20473870; PubMed Central PMCID: PMC2946507.
- 26. Su PF, Huang WL, Wu HT, Wu CH, Liu TY, Kao SY. p16(INK4A) promoter hypermethylation is associated with invasiveness and prognosis of oral squamous cell carcinoma in an age-dependent manner. Oral Oncology. 2010;46(10):734–9. PubMed PMID: WOS:000282281600005. pmid:20729138
- 27. Ghosh A, Ghosh S, Maiti GP, Sabbir MG, Alam N, Sikdar N, et al. SH3GL2 and CDKN2A/2B loci are independently altered in early dysplastic lesions of head and neck: correlation with HPV infection and tobacco habit. The Journal of pathology. 2009;217(3):408–19. Epub 2008/11/22. pmid:19023882.
- 28. Martone T, Gillio-Tos A, De Marco L, Fiano V, Maule M, Cavalot A, et al. Association between hypermethylated tumor and paired surgical margins in head and neck squamous cell carcinomas. Clinical cancer research: an official journal of the American Association for Cancer Research. 2007;13(17):5089–94. Epub 2007/09/06. pmid:17785562.
- 29. Kulkarni V, Saranath D. Concurrent hypermethylation of multiple regulatory genes in chewing tobacco associated oral squamous cell carcinomas and adjacent normal tissues. Oral Oncology. 2004;40(2):145–53. PubMed PMID: WOS:000188399100005. pmid:14693237
- 30. Wong TS, Man MW, Lam AK, Wei WI, Kwong YL, Yuen AP. The study of p16 and p15 gene methylation in head and neck squamous cell carcinoma and their quantitative evaluation in plasma by real-time PCR. European journal of cancer (Oxford, England: 1990). 2003;39(13):1881–7. Epub 2003/08/23. pmid:12932666.
- 31. Weber A, Wittekind C, Tannapfel A. Genetic and epigenetic alterations of 9p21 gene products in benign and malignant tumors of the head and neck. Pathology, research and practice. 2003;199(6):391–7. Epub 2003/08/20. pmid:12924439.
- 32. Rosas SL, Koch W, da Costa Carvalho MG, Wu L, Califano J, Westra W, et al. Promoter hypermethylation patterns of p16, O6-methylguanine-DNA-methyltransferase, and death-associated protein kinase in tumors and saliva of head and neck cancer patients. Cancer research. 2001;61(3):939–42. Epub 2001/02/28. pmid:11221887.
- 33. Righini CA, de Fraipont F, Timsit JF, Faure C, Brambilla E, Reyt E, et al. Tumor-specific methylation in saliva: a promising biomarker for early detection of head and neck cancer recurrence. Clinical cancer research: an official journal of the American Association for Cancer Research. 2007;13(4):1179–85. Epub 2007/02/24. pmid:17317827.
- 34. Song B, Ai J, Kong X, Liu D, Li J. Aberrant DNA Methylation of P16, MGMT, and hMLH1 Genes in Combination with MTHFR C677T Genetic Polymorphism in gastric cancer. Pak J Med Sci. 2013;29(6):1338–43. Epub 2014/02/20. pmid:24550949; PubMed Central PMCID: PMC3905372.
- 35. Liggett WH Jr., Sidransky D. Role of the p16 tumor suppressor gene in cancer. Journal of clinical oncology: official journal of the American Society of Clinical Oncology. 1998;16(3):1197–206. Epub 1998/03/21. pmid:9508208.
- 36. Belinsky SA, Klinge DM, Dekker JD, Smith MW, Bocklage TJ, Gilliland FD, et al. Gene promoter methylation in plasma and sputum increases with lung cancer risk. Clinical cancer research: an official journal of the American Association for Cancer Research. 2005;11(18):6505–11. Epub 2005/09/17. pmid:16166426.
- 37. Hsu LS, Lee HC, Chau GY, Yin PH, Chi CW, Lui WY. Aberrant methylation of EDNRB and p16 genes in hepatocellular carcinoma (HCC) in Taiwan. Oncology reports. 2006;15(2):507–11. Epub 2006/01/05. pmid:16391877.
- 38. Mino A, Onoda N, Yashiro M, Aya M, Fujiwara I, Kubo N, et al. Frequent p16 CpG island hypermethylation in primary remnant gastric cancer suggesting an independent carcinogenic pathway. Oncology reports. 2006;15(3):615–20. Epub 2006/02/09. pmid:16465421.
- 39. Askari M, Sobti RC, Nikbakht M, Sharma SC. Promoter hypermethylation of tumour suppressor genes (p14/ARF and p16/INK4a): case-control study in North Indian population. Molecular biology reports. 2013;40(8):4921–8. Epub 2013/05/29. pmid:23712779.
- 40. Herman JG, Graff JR, Myohanen S, Nelkin BD, Baylin SB. Methylation-specific PCR: a novel PCR assay for methylation status of CpG islands. Proc Natl Acad Sci U S A. 1996;93(18):9821–6. Epub 1996/09/03. pmid:8790415; PubMed Central PMCID: PMC38513.
- 41. Toyota M, Ho C, Ahuja N, Jair KW, Li Q, Ohe-Toyota M, et al. Identification of differentially methylated sequences in colorectal cancer by methylated CpG island amplification. Cancer research. 1999;59(10):2307–12. Epub 1999/05/27. pmid:10344734.
- 42. Yates DR, Rehman I, Meuth M, Cross SS, Hamdy FC, Catto JW. Methylational urinalysis: a prospective study of bladder cancer patients and age stratified benign controls. Oncogene. 2006;25(13):1984–8. Epub 2005/11/17. pmid:16288222.
- 43. Chen Y, Li J, Yu X, Li S, Zhang X, Mo Z, et al. APC gene hypermethylation and prostate cancer: a systematic review and meta-analysis. European journal of human genetics: EJHG. 2013;21(9):929–35. Epub 2013/01/10. pmid:23299921; PubMed Central PMCID: PMC3746257.
- 44. Pande P, Mathur M, Shukla NK, Ralhan R. pRb and p16 protein alterations in human oral tumorigenesis. Oral oncology. 1998;34(5):396–403. pmid:9861348.
- 45. El-Naggar AK, Lai S, Clayman GL, Zhou JH, Tucker SA, Myers J, et al. Expression of p16, Rb, and cyclin D1 gene products in oral and laryngeal squamous carcinoma: biological and clinical implications. Human pathology. 1999;30(9):1013–8. pmid:10492034.
- 46. Wu CL, Roz L, McKown S, Sloan P, Read AP, Holland S, et al. DNA studies underestimate the major role of CDKN2A inactivation in oral and oropharyngeal squamous cell carcinomas. Genes, chromosomes & cancer. 1999;25(1):16–25. pmid:10221335.
- 47. Hasegawa M, Nelson HH, Peters E, Ringstrom E, Posner M, Kelsey KT. Patterns of gene promoter methylation in squamous cell cancer of the head and neck. Oncogene. 2002;21(27):4231–6. pmid:12082610.
- 48. O'Regan EM, Toner ME, Finn SP, Fan CY, Ring M, Hagmar B, et al. p16(INK4A) genetic and epigenetic profiles differ in relation to age and site in head and neck squamous cell carcinomas. Human pathology. 2008;39(3):452–8. pmid:18261630.
- 49. Ai L, Stephenson KK, Ling W, Zuo C, Mukunyadzi P, Suen JY, et al. The p16 (CDKN2a/INK4a) tumor-suppressor gene in head and neck squamous cell carcinoma: a promoter methylation and protein expression study in 100 cases. Modern pathology: an official journal of the United States and Canadian Academy of Pathology, Inc. 2003;16(9):944–50. pmid:13679459.
- 50. Lim AM, Do H, Young RJ, Wong SQ, Angel C, Collins M, et al. Differential mechanisms of CDKN2A (p16) alteration in oral tongue squamous cell carcinomas and correlation with patient outcome. International journal of cancer Journal international du cancer. 2014;135(4):887–95. pmid:24436120.
- 51. Fakhry C, Westra WH, Li S, Cmelak A, Ridge JA, Pinto H, et al. Improved survival of patients with human papillomavirus-positive head and neck squamous cell carcinoma in a prospective clinical trial. J Natl Cancer Inst. 2008;100(4):261–9. Epub 2008/02/14. pmid:18270337.
- 52. Smeets SJ, Hesselink AT, Speel EJ, Haesevoets A, Snijders PJ, Pawlita M, et al. A novel algorithm for reliable detection of human papillomavirus in paraffin embedded head and neck cancer specimen. International journal of cancer Journal international du cancer. 2007;121(11):2465–72. Epub 2007/08/08. pmid:17680565.
- 53. Klussmann JP, Gultekin E, Weissenborn SJ, Wieland U, Dries V, Dienes HP, et al. Expression of p16 protein identifies a distinct entity of tonsillar carcinomas associated with human papillomavirus. The American journal of pathology. 2003;162(3):747–53. Epub 2003/02/25. pmid:12598309; PubMed Central PMCID: PMC1868106.
- 54. Begum S, Cao D, Gillison M, Zahurak M, Westra WH. Tissue distribution of human papillomavirus 16 DNA integration in patients with tonsillar carcinoma. Clinical cancer research: an official journal of the American Association for Cancer Research. 2005;11(16):5694–9. Epub 2005/08/24. pmid:16115905.