We compared diagnostic performance of INSM1 and previously reported composite marker CD56 + p16 + thyroid transcription factor-1 (TTF1) in the diagnosis of SCLC in small biopsy specimens and cytoblocks.
Using PDX, we show proof-of-concept that a high ratio of p16 to cyclin D1 gene expression reflects underlying Rb functional loss and distinguishes morphologically identified small-cell carcinoma from prostatic adenocarcinoma in patient specimens (n = 13 and 9, respectively).
A total of 61 tumours (benign and malignant) were deemed suitable for the study. p16INK4 staining yielded three (4.9 per cent) positive samples: one small cell carcinoma, one squamous cell carcinoma and one poorly differentiated carcinoma.
In our study, we investigated polyomavirus infection (SV40 and MCPyV) and promoter hypermethylation of the tumour suppressors RASSF1A and p16 in 18 SCLCs (14 primaries and 4 regional lymph node metastases) and 18 blood control samples.
Mutation at p16 occurred more frequently in non-small cell lung cancer (19.3%) than in small cell lung cancer (5.4%); while the mutation rate of Rb was 32.4% in small cell lung cancer versus 2.3% in non-small cell lung cancer.
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%).
The frequencies of the expressions of CD56, mASH1, TTF-1, and p16 were higher and that of NeuroD was lower in small cell carcinoma than in large cell neuroendocrine carcinoma.
We have examined the expression of the human p19ARF (hp19ARF) protein in a large series of lung cancers using immunohistochemistry and showed that the protein was more frequently lost in high-grade neuroendocrine (NE) lung tumors (large cell NE carcinoma and small cell lung carcinoma; 51 of 78, 65%) than it was in non-small cell lung cancer (25 of 101, 25%).
A homozygous deletion including Hel-N1 and CDKN2a was found in a SCLC cell line, and a single-base polymorphism in exon 2 of Hel-N1 was observed in eight tumors.
Alterations of the p16INK4 and p15INK4B genes were detected in 71% of the NSCLC cell lines (n = 14) and 50% of the NSCLC cell lines (n = 14), respectively, but there were none in the 7 SCLC cell lines studied.
The CDKN2 gene is inactivated more commonly in non-small cell lung cancer than small cell lung cancer while the retinoblastoma gene is inactivated more commonly in small cell lung cancer than non-small cell lung cancer.
Our data confirm the predicted reciprocity between Rb inactivation and p16 expression in a common human malignancy and define differential p16 expression as a fundamental distinction between NSCLC and SCLC.
The inverse correlation of RB and p16INK4 expression and the absence of p16INK4 inactivation in RB (-/-) SCLC lines (0/48) confirms a common p16INK4/RB growth suppressor pathway in human cancers and provides evidence that p16INK4, and not an adjacent gene on chromosome 9p, is a specific target for mutational events.
Numerous investigations suggest that one or more genes residing in the p14 to p21 region of human chromosome 3 are critical to the development of neoplastic diseases such as renal cell carcinoma and small-cell lung cancer (SCLC).