Literature DB >> 24464224

DNA hypermethylation in prostate cancer is a consequence of aberrant epithelial differentiation and hyperproliferation.

D Pellacani1, D Kestoras1, A P Droop1, F M Frame1, P A Berry1, M G Lawrence2, M J Stower3, M S Simms4, V M Mann4, A T Collins1, G P Risbridger2, N J Maitland1.   

Abstract

Prostate cancer (CaP) is mostly composed of luminal-like differentiated cells, but contains a small subpopulation of basal cells (including stem-like cells), which can proliferate and differentiate into luminal-like cells. In cancers, CpG island hypermethylation has been associated with gene downregulation, but the causal relationship between the two phenomena is still debated. Here we clarify the origin and function of CpG island hypermethylation in CaP, in the context of a cancer cell hierarchy and epithelial differentiation, by analysis of separated basal and luminal cells from cancers. For a set of genes (including GSTP1) that are hypermethylated in CaP, gene downregulation is the result of cell differentiation and is not cancer specific. Hypermethylation is however seen in more differentiated cancer cells and is promoted by hyperproliferation. These genes are maintained as actively expressed and methylation-free in undifferentiated CaP cells, and their hypermethylation is not essential for either tumour development or expansion. We present evidence for the causes and the dynamics of CpG island hypermethylation in CaP, showing that, for a specific set of genes, promoter methylation is downstream of gene downregulation and is not a driver of gene repression, while gene repression is a result of tissue-specific differentiation.

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Year:  2014        PMID: 24464224      PMCID: PMC3978305          DOI: 10.1038/cdd.2013.202

Source DB:  PubMed          Journal:  Cell Death Differ        ISSN: 1350-9047            Impact factor:   15.828


  60 in total

1.  Development and limitations of lentivirus vectors as tools for tracking differentiation in prostate epithelial cells.

Authors:  Fiona M Frame; Stefanie Hager; Davide Pellacani; Mike J Stower; Hannah F Walker; Julie E Burns; Anne T Collins; Norman J Maitland
Journal:  Exp Cell Res       Date:  2010-08-19       Impact factor: 3.905

Review 2.  Epigenetic modifications and human disease.

Authors:  Anna Portela; Manel Esteller
Journal:  Nat Biotechnol       Date:  2010-10       Impact factor: 54.908

Review 3.  Revisiting the concept of cancer stem cells in prostate cancer.

Authors:  Z A Wang; M M Shen
Journal:  Oncogene       Date:  2010-11-29       Impact factor: 9.867

Review 4.  The cancer stem cell: premises, promises and challenges.

Authors:  Hans Clevers
Journal:  Nat Med       Date:  2011-03       Impact factor: 53.440

5.  DNA methylation profiling reveals novel biomarkers and important roles for DNA methyltransferases in prostate cancer.

Authors:  Yuya Kobayashi; Devin M Absher; Zulfiqar G Gulzar; Sarah R Young; Jesse K McKenney; Donna M Peehl; James D Brooks; Richard M Myers; Gavin Sherlock
Journal:  Genome Res       Date:  2011-04-26       Impact factor: 9.043

6.  Regulation of the stem cell marker CD133 is independent of promoter hypermethylation in human epithelial differentiation and cancer.

Authors:  Davide Pellacani; Richard J Packer; Fiona M Frame; Emma E Oldridge; Paul A Berry; Marie-Christine Labarthe; Michael J Stower; Matthew S Simms; Anne T Collins; Norman J Maitland
Journal:  Mol Cancer       Date:  2011-07-29       Impact factor: 27.401

7.  Prostate cancer stem cells: do they have a basal or luminal phenotype?

Authors:  Norman J Maitland; Fiona M Frame; Euan S Polson; John L Lewis; Anne T Collins
Journal:  Horm Cancer       Date:  2011-02       Impact factor: 3.869

8.  Stromal upregulation of lateral epithelial adhesions: gene expression analysis of signalling pathways in prostate epithelium.

Authors:  Karen F Chambers; Joanna F Pearson; Davide Pellacani; Naveed Aziz; Miodrag Gužvić; Christoph A Klein; Shona H Lang
Journal:  J Biomed Sci       Date:  2011-06-22       Impact factor: 8.410

9.  Stroma regulates increased epithelial lateral cell adhesion in 3D culture: a role for actin/cadherin dynamics.

Authors:  Karen F Chambers; Joanna F Pearson; Naveed Aziz; Peter O'Toole; David Garrod; Shona H Lang
Journal:  PLoS One       Date:  2011-04-18       Impact factor: 3.240

10.  ENCODE whole-genome data in the UCSC genome browser (2011 update).

Authors:  Brian J Raney; Melissa S Cline; Kate R Rosenbloom; Timothy R Dreszer; Katrina Learned; Galt P Barber; Laurence R Meyer; Cricket A Sloan; Venkat S Malladi; Krishna M Roskin; Bernard B Suh; Angie S Hinrichs; Hiram Clawson; Ann S Zweig; Vanessa Kirkup; Pauline A Fujita; Brooke Rhead; Kayla E Smith; Andy Pohl; Robert M Kuhn; Donna Karolchik; David Haussler; W James Kent
Journal:  Nucleic Acids Res       Date:  2010-10-30       Impact factor: 16.971
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  11 in total

1.  Investigation of methylation and protein expression of the Runx3 gene in colon carcinogenesis.

Authors:  Shao-Ya He; Ren-Fa Jiang; Jie Jiang; Yang-Sheng Xiang; Ling Wang
Journal:  Biomed Rep       Date:  2015-06-17

2.  DNA-Methyltransferase 1 Induces Dedifferentiation of Pancreatic Cancer Cells through Silencing of Krüppel-Like Factor 4 Expression.

Authors:  Victoria K Xie; Zhiwei Li; Yongmin Yan; Zhiliang Jia; Xiangsheng Zuo; Zhenlin Ju; Jing Wang; Jiawei Du; Dacheng Xie; Keping Xie; Daoyan Wei
Journal:  Clin Cancer Res       Date:  2017-06-28       Impact factor: 12.531

3.  Methylation of PITX2, HOXD3, RASSF1 and TDRD1 predicts biochemical recurrence in high-risk prostate cancer.

Authors:  Kirill Litovkin; Steven Joniau; Evelyne Lerut; Annouschka Laenen; Olivier Gevaert; Martin Spahn; Burkhard Kneitz; Sofie Isebaert; Karin Haustermans; Monique Beullens; Aleyde Van Eynde; Mathieu Bollen
Journal:  J Cancer Res Clin Oncol       Date:  2014-06-18       Impact factor: 4.553

Review 4.  Molecular pathways and targets in prostate cancer.

Authors:  Emma Shtivelman; Tomasz M Beer; Christopher P Evans
Journal:  Oncotarget       Date:  2014-09-15

5.  Exendin-4 promotes extracellular-superoxide dismutase expression in A549 cells through DNA demethylation.

Authors:  Hiroyuki Yasuda; Koji Mizukami; Mutsuna Hayashi; Tetsuro Kamiya; Hirokazu Hara; Tetsuo Adachi
Journal:  J Clin Biochem Nutr       Date:  2015-11-20       Impact factor: 3.114

6.  Tumor necrosis factor-α decreases EC-SOD expression through DNA methylation.

Authors:  Shunpei Morisawa; Hiroyuki Yasuda; Tetsuro Kamiya; Hirokazu Hara; Tetsuo Adachi
Journal:  J Clin Biochem Nutr       Date:  2017-04-07       Impact factor: 3.114

7.  DNA methylation profile is associated with the osteogenic potential of three distinct human odontogenic stem cells.

Authors:  Tingting Ai; Jieni Zhang; Xuedong Wang; Xiaowen Zheng; Xueyan Qin; Qian Zhang; Weiran Li; Wei Hu; Jiuxiang Lin; Feng Chen
Journal:  Signal Transduct Target Ther       Date:  2018-01-12

8.  Phenotype-independent DNA methylation changes in prostate cancer.

Authors:  Davide Pellacani; Alastair P Droop; Fiona M Frame; Matthew S Simms; Vincent M Mann; Anne T Collins; Connie J Eaves; Norman J Maitland
Journal:  Br J Cancer       Date:  2018-10-15       Impact factor: 7.640

Review 9.  Prostate Cancer Stem-like Cells Contribute to the Development of Castration-Resistant Prostate Cancer.

Authors:  Diane Ojo; Xiaozeng Lin; Nicholas Wong; Yan Gu; Damu Tang
Journal:  Cancers (Basel)       Date:  2015-11-18       Impact factor: 6.639

10.  MiR-455-3p inhibits the degenerate process of chondrogenic differentiation through modification of DNA methylation.

Authors:  Hao Sun; Xiaoyi Zhao; Chengyun Zhang; Ziji Zhang; Jiayong Lun; Weiming Liao; Zhiqi Zhang
Journal:  Cell Death Dis       Date:  2018-05-01       Impact factor: 8.469
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