The tobacco-specific carcinogen NNK induces DNA methyltransferase 1 accumulation and tumor suppressor gene hypermethylation in mice and lung cancer patients
Ruo-Kai Lin, … , Chung-Fan Lee, Yi-Ching Wang
Ruo-Kai Lin, … , Chung-Fan Lee, Yi-Ching Wang
Published January 19, 2010
Citation Information: J Clin Invest. 2010;120(2):521-532. https://doi.org/10.1172/JCI40706.
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Research Article Oncology

The tobacco-specific carcinogen NNK induces DNA methyltransferase 1 accumulation and tumor suppressor gene hypermethylation in mice and lung cancer patients

Abstract

DNA methyltransferase 1 (DNMT1) catalyzes DNA methylation and is overexpressed in many human diseases, including cancer. The tobacco-specific carcinogen NNK also induces DNA methylation. However, the role of DNMT1-mediated methylation in tobacco carcinogenesis remains unclear. Here we used human and mouse lung cancer samples and cell lines to determine a mechanism whereby NNK induced DNMT1 expression and activity. We determined that in a human lung cell line, glycogen synthase kinase 3β (GSK3β) phosphorylated DNMT1 to recruit β-transducin repeat–containing protein (βTrCP), resulting in DNMT1 degradation, and that NNK activated AKT, inhibiting GSK3β function and thereby attenuating DNMT1 degradation. NNK also induced βTrCP translocation to the cytoplasm via the heterogeneous nuclear ribonucleoprotein U (hnRNP-U) shuttling protein, resulting in DNMT1 nuclear accumulation and hypermethylation of the promoters of tumor suppressor genes. Fluorescence immunohistochemistry (IHC) of lung adenomas from NNK-treated mice and tumors from lung cancer patients that were smokers were characterized by disruption of the DNMT1/βTrCP interaction and DNMT1 nuclear accumulation. Importantly, DNMT1 overexpression in lung cancer patients who smoked continuously correlated with poor prognosis. We believe that the NNK-induced DNMT1 accumulation and subsequent hypermethylation of the promoter of tumor suppressor genes may lead to tumorigenesis and poor prognosis and provide an important link between tobacco smoking and lung cancer. Furthermore, this mechanism may also be involved in other smoking-related human diseases.

Authors

Ruo-Kai Lin, Yi-Shuan Hsieh, Pinpin Lin, Han-Shui Hsu, Chih-Yi Chen, Yen-An Tang, Chung-Fan Lee, Yi-Ching Wang

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Figure 5

NNK enhances hnRNP-U/βTrCP translocation to the cytoplasm and induces DNMT1 accumulation in the nucleus, but this effect is attenuated by AKT inhibition.

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NNK enhances hnRNP-U/βTrCP translocation to the cytoplasm and induces DN...
(A) Immunofluorescence confocal microscopy to localize DNMT1 (green), βTrCP (red), and nucleus (blue; DAPI). The merged figures showed colocalization of DNMT1 with βTrCP protein in A549 cells treated with DMSO control. Mutually exclusive localization of DNMT1 and βTrCP was observed in cells treated with NNK. Original magnification, ×630. Scale bar: 20 μm. (B) Cell fractionation assay to analyze distribution of nuclear and cytoplasmic proteins, using anti-DNMT1, anti-βTrCP, anti–hnRNP-U, and anti-GSK3βSer9 antibodies. Anti-GAPDH and anti–lamin A/C antibodies were used as cytoplasmic and nuclear protein markers, respectively. The distribution of βTrCP and hnRNP-U proteins was contrary to that of DNMT1 protein. (C) DNMT1 and βTrCP interaction was interrupted by NNK treatment. In contrast, βTrCP and hnRNP interaction was increased by NNK treatment. (D) Cell fractionation assay was performed in A549 cells with or without AKT siRNA. Inhibition of AKT induced both hnRNP-U and βTrCP proteins predominantly located in the nucleus, where DNMT1 protein level decreased. (E) IP assay using anti-AKT antibody showed that hnRNP formed a complex with AKT, and the interaction was attenuated by LY294002. (F) An increase of hnRNP-U phosphorylation was mediated by exogenous AKT, which increased the interaction between hnRNP-U and βTrCP. In addition, AKT decreased the interaction of DNMT1 with hnRNP-U and βTrCP.