Deregulation of caspase 8 and 10 expression in pediatric tumors and cell lines.

Methylation of the promoter regions of CpG-rich sites in genes is the major mechanism for the silencing of many genes in tumors. Methylation of the key apoptosis-related gene caspase 8 (CASP8) has been reported in some childhood tumors and in neuroendocrine lung tumors. We examined the methylation status of 181 pediatric tumors and found frequent methylation in rhabdomyosarcomas (83%), medulloblastomas (81%), retinoblastomas (59%), and neuroblastomas (52%). Methylation frequencies were low in Wilms' tumors (19%) and absent in hepatoblastomas, acute leukemias, osteosarcomas, Ewing's sarcomas, and ganglioneuromas and in normal tissues. Methylation of CASP8 and the tumor suppressor gene RASSF1A were highly significantly correlated in all tumor types by both the chi(2) and the Fisher's exact tests (P < 0.0001 for both tests). Because the region of the gene examined by us and others is not located in the promoter region and lacks features of a CpG island, we explored the relationship between methylation and gene silencing in detail using 23 pediatric tumor cell lines. Studies included relating the methylation of the region to gene expression at mRNA and protein levels, enzymatic assays of gene function, clonal analysis of PCR amplicons of the region, and exposure to a demethylating agent. These studies indicated that methylation correlated with the loss of gene function in most cases; however, other mechanisms of gene inactivation were present in some cases. Posttranscriptional inactivation of the closely related gene caspase 10 was present in many cell lines. Our results suggest that deregulation of the death receptor pathway to apoptosis is frequent in many types of pediatric tumors and their cell lines.

Epigenetic down-regulation of death-associated protein kinase in lung cancers.

PURPOSE: Death-associated protein kinase (DAPK) is a pro-apoptotic serine/threonine kinase involved in apoptosis. Aberrant methylation of DAPK was reported in lung cancers by methylation-specific PCR. However, we were unable to relate methylation with gene silencing with the same methodology. Our goals were to develop a methodology that related methylation with gene silencing and use it to study the state of the gene in lung cancers. EXPERIMENTAL DESIGN AND RESULTS: Using a semiquantitative real-time reverse transcription-PCR, DAPK expression was lower in lung cancers than in corresponding nonmalignant bronchial epithelial cells in five of six primary short-term cultures. In continuous cell lines, mRNA expression was down-regulated, as well as compared with nonmalignant bronchial epithelial cells, and its protein was not detected by Western blotting in 17 of 23 (74%) cell lines. We investigated methylation status of 5' flanking region of DAPK by combined bisulfite restriction analysis and bisulfited DNA sequencing. Aberrant methylation was detected in 21 of 48 (44%) cell lines, 2 of 6 primary cultured tumors, and 14 of 38 (37%) primary lung cancers, although varying degrees of methylation were noticed. Furthermore, bisufite sequence data suggested that aberrant methylation might occur selectively at some CpG dinucleotides in cell lines which had absent expression. Treatment with 5-aza-2'-deoxycytidine restored DAPK expression in heavily methylated cell lines tested, and histone deacetylase inhibitor trichostatin A alone restored DAPK expression in some methylated cell lines as well. CONCLUSIONS: Our major findings are: (a) DAPK expression is frequently down-regulated in lung cancers; (b) aberrant methylation of DAPK is frequent in lung cancers, although considerable heterogeneity of methylation is present, and some specific CpG dinucleotides are often methylated in expression negative lung cancers; and (c) besides methylation and histone deacetylation, there may be other mechanisms for down-regulation of DAPK expression.

Differential inactivation of caspase-8 in lung cancers.

Caspase-8 (CASP8) is an apoptosis inducing cysteine protease which is activated through the formation of a death-inducing signaling complex when death receptors are complexed to their specific ligands. Recent reports indicate that CASP8 expression is lost via a combination of promoter methylation and allelic loss in subset of neuroblastomas. We investigated the state of the gene in lung tumors and cell lines. RT-PCR studies indicated that gene expression was lost in most (27 of 34, 79%) of small cell lung carcinoma (SCLC) cell lines, but expression was retained in all 22 non-SCLC (NSCLC) lines tested. Loss of gene expression at the RNA level was associated with absent protein expression by Western blotting and lack of CASP8 enzymatic activity. Methylation of the promoter region of the CASP8 gene was present in 16 of 27 (59%) of the SCLC lines lacking gene expression. All methylated cell lines lacked the presence of an unmethylated allele indicating biallelic methylation or loss of non-methylated allele. Promoter methylation was absent in all SCLC and NSCLC cell lines retaining gene expression, and all of these lines had the unmethylated form of the gene. One non-expressing SCLC cell line, NCI-H82, had a homozygous deletion at 2q33 encompassing the chromosomal location of the CASP8 gene. The mechanism of gene inactivation in the remaining 10 of 27 (37%) non-expressing SCLC cell lines is unknown. Using five polymorphic markers for 2q33 a high frequency of allelic loss was present in SCLC lines. Analyses of fresh tumors showed that 15 of 43 (35%) of the SCLC, seven of 40 (18%) of bronchial carcinoids and none of 44 NSCLC tumors had CASP8 promoter methylation. Because only approximately 60% of SCLC cell lines lacking CASP8 expression were methylated, extrapolating from the cell line data, we estimate that approximately 58% of SCLC and 30% of bronchial carcinoids lack CASP8 expression. Thus, CASP8 expression is absent in a subset of both high grade (SCLC) and low grade (carcinoid) neuroendocrine lung tumors but not in NSCLC, which usually lack neuroendocrine features. CASP8 may function as a tumor suppressor gene in neuroendocrine lung tumors.