We examined the expression of p16 and Rb protein by means of immunohistochemistry in 61 non-small cell lung cancers and have demonstrated an inverse relationship between the expression of p16 and Rb protein: 28/30 specimens that did not stain for p16 stained for Rb and 21/31 p16-positive specimens did not stain for Rb.
These results provide the first link between germ-line functional deficits in pathways that protect the cell from tobacco- and radon-induced DNA damage, and the development of aberrant promoter methylation of the p16 and MGMT genes in the respiratory epithelium of individuals at high risk for lung cancer.
Furthermore, rat lung cancer appears to be an excellent model in which to investigate the mechanisms of de novo gene methylation and the role of p16 dysfunction in the progression of neoplasia.
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.
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.
Furthermore, the p16 gene was affected by promoter methylation at a frequency even higher among the lung cancer group, compared with the noncancer group [70.7% (41/58) versus 51.7% (55/107), p = 0.017].
To determine whether P16 methylation directly increased the sensitivity of cancer cells to palbociclib, we induced P16 methylation in the lung cancer cell lines H661 and HCC827 and the gastric cancer cell line BGC823 via an engineered P16-specific DNA methyltransferase (P16-Dnmt) and found that the sensitivity of these cells to palbociclib was significantly increased.
The present review article summarizes evaluations of P53, P16 and K-RAS in lung cancer with particular focus on biological and clinical implications, as well as on new molecular approaches to the study of these genes: P53 by yeast functional assay, P16 by methylation specific PCR (MSP) and K-RAS by enriched PCR technique.
In contrast, p16 expression was lost in moderate dysplasia (12%) and in CIS (30%) in patients with lung cancer. p16 loss occurred exclusively in patients who displayed loss of p16 expression in their related invasive carcinoma.
Based on smoking status, the promoter methylation ratios of both RASSF1A and p16 was significantly higher in lung cancer patients with smoking history compared to nonsmokers.
In summary, our data suggest that targeted DNA methylation silencing of ECAD and DAPK occurs in the early stages and that of p16 and MGMT in the later stages of lung cancer progression.
Since somatic mutations of the p53, RB and p16 genes occur frequently in lung cancer and the replication error phenotype is seen in a subset of lung cancer, it is possible that germ-line mutations of the p53, RB, p16 and mismatch repair genes influence the susceptibility to lung cancer.