Transcriptional regulator CTCF controls human interleukin 1 receptor-associated kinase 2 promoter.

Immune responses to invading pathogens are mediated largely through a family of transmembrane Toll-like receptors and modulated by a number of downstream effectors. In particular, a family of four interleukin 1 receptor-associated kinases (IRAK) regulates responsiveness to bacterial endotoxins. Pharmacological targeting of particular IRAK components may be beneficial for treatment of bacterial infections. Here, we studied transcriptional regulation of the human IRAK2 gene. Analysis of the IRAK2 promoter region reveals putative binding sites for several transcriptional factors, including ZIP (EGR1 and SP1), CTCF and AP-2beta. Deletion of the ZIP or AP-2 sites did not significantly affect IRAK2 promoter activity in naive and endotoxin-treated mononuclear cells, in dormant and activated Jurkat T-cells, in lung and kidney cells. In contrast, we found that CTCF plays a major role in IRAK2 transcription. An electrophoretic mobility shift assay of the DNA fragments containing the IRAK2 CpG island, revealed a single high-affinity binding site for the transcriptional regulator and a chromatin insulator protein, CTCF. This assay revealed a CTCF-binding site within the mouse Irak2 promoter. The presence of the CTCF protein in human IRAK2 promoter was confirmed by chromatin immunoprecipitation assay. Specific residues that interacted with the CTCF protein, were identified by methylation interference assay. In all cell lines analyzed, including cells of lung, renal, monocytic and T-cell origin, the IRAK2 luciferase reporter construct, containing an intact CTCF-binding site, showed strong promoter activity. However, IRAK2 promoter activity was decreased dramatically for the constructs with a mutated CTCF-binding site.

Inactivation of RAS association domain family 1A gene in cervical carcinomas and the role of human papillomavirus infection.

Recently, we have identified a new putative tumor suppressor gene, RASSF1A (Ras association domain family 1A gene), located at human chromosome 3p21.3, the segment that is often lost in many types of human cancers. The RASSF1A promoter was shown to be frequently hypermethylated in various epithelial tumors, including small cell lung, breast, bladder, prostate, gastric, and renal cell carcinomas. In this study, we have analyzed the methylation status of the RASSF1A gene in primary human cervical cancers and in eight cervical cancer cell lines. The RASSF1A promoter is hypermethylated in 4 of 42 (= 10%) of squamous cell carcinomas, in 4 of 19 (= 21%) of adenosquamous carcinomas, and in 8 of 34 (= 24%) of cervical adenocarcinomas. Although in adenocarcinomas, methylation of RASSF1A and presence of human papillomavirus (HPV) type 16 or 18 sometimes coexisted, not a single case of HPV-16/18-positive squamous cell carcinomas had RASSF1A methylation. Similarly, in all eight analyzed cervical cell lines, RASSF1A inactivation and HPV infection were mutually exclusive (Fisher's exact test; P = 0.0357): two HPV-negative cervical cancer cell lines had a methylated and silenced RASSF1A promoter (C-33A and HT-3), whereas the other six HPV-positive lines expressed RASSF1A mRNA (ME 180, MS751, SiHa, C-4I, HeLa, and CaSki). For cervical tumors and cell lines combined, the Pearson's chi(2) test (chi(2) = 3.99; P

Functional characterization of the candidate tumor suppressor gene NPRL2/G21 located in 3p21.3C.

Initial analysis identified the NPRL2/G21 gene located in 3p21.3C, the lung cancer region, as a strong candidate tumor suppressor gene. Here we provide additional evidence of the tumor suppressor function of NPRL2/G21. The gene has highly conserved homologs/orthologs ranging from yeast to humans. The yeast ortholog, NPR2, shows three highly conserved regions with 32 to 36% identity over the whole length. By sequence analysis, the main product of NPRL2/G21 encodes a soluble protein that has a bipartite nuclear localization signal, a protein-binding domain, similarity to the MutS core domain, and a newly identified nitrogen permease regulator 2 domain with unknown function. The gene is highly expressed in many tissues. We report inactivating mutations in a variety of tumors and cancer cell lines, growth suppression of tumor cells with tet-controlled NPRL2/G21 transgenes on plastic Petri dishes, and suppression of tumor formation in SCID mice. Screening of 7 renal, 5 lung, and 7 cervical carcinoma cell lines showed homozygous deletions in the 3' end of NPRL2 in 2 renal, 3 lung, and 1 cervical (HeLa) cell line. Deletions in the 3' part of NPRL2 could result in improper splicing, leading to the loss of the 1.8 kb functional NPRL2 mRNA. We speculate that the NPRL2/G21 nuclear protein may be involved in mismatch repair, cell cycle checkpoint signaling, and activation of apoptotic pathway(s). The yeast NPR2 was shown to be a target of cisplatin, suggesting that the human NPRL2/G21 may play a similar role. At least two homozygous deletions of NPRL2/G21 were detected in 6 tumor biopsies from various locations and with microsatellite instability. This study, together with previously obtained results, indicates that NPRL2 is a multiple tumor suppressor gene.

The RASSF1A tumor suppressor gene is inactivated in prostate tumors and suppresses growth of prostate carcinoma cells.

We analyzed expression status of the recently identified tumor suppressor geneRASSF1A in primary prostate carcinomas and in prostate cell lines. We found complete methylation of the RASSF1A promoter in 63% of primary microdissected prostate carcinomas (7 of 11 samples). The remaining 4 samples (37%) were partially methylated, possibly because of contamination with normal cells. No promoter methylation was observed in matching normal prostate tissues. High levels of RASSF1A transcript and no methylation of RASSF1A promoter were found in explanted primary normal prostate epithelial and stromal cells. Complete silencing and methylation of RASSF1A promoter was observed in five widely used prostate carcinoma cell lines, which acquired the ability to grow in culture spontaneously, including LNCaP, PC-3, ND-1, DU-145, 22Rv1, and one primary prostate carcinoma immortalized by overexpression of the human telomerase catalytic subunit (RC-58T/hTERT). However, no silencing of RASSF1A was found in four other prostate carcinoma cell lines, which were adapted for cell culture after transformation with human papillomaviral DNA. Suppression of cell growth in vitro was demonstrated after the reintroduction of RASSF1A-expressing construct into LNCaP prostate carcinoma cells. Our data implicate the RASSF1A gene in human prostate tumorigenesis.