Tumorigenesis: the adaptation of mammalian cells to sustained stress environment by epigenetic alterations and succeeding matched mutations

doi:10.1093/carcin/bgi079

Carcinogenesis Advance Access published online on March 31, 2005
Carcinogenesis, doi:10.1093/carcin/bgi079

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© The Author 2005. Published by Oxford University Press. All rights reserved. For permissions, please email: journals.permissions@oupjournals.org
Received January 3, 2005
Revised March 21, 2005
Accepted March 22, 2005

COMMENTARY

Tumorigenesis: the adaptation of mammalian cells to sustained stress environment by epigenetic alterations and succeeding matched mutations

Tatiana V. Karpinets ¹^* and Brent D. Foy ²

¹ Department of Plant Sciences, University of Tennessee, 2431 Center Drive Knoxville, TN 37996-4500
² Department of Physics, Wright State University, 3640 Colonel Glenn Hwy, Dayton, OH, 45435, USA

^* To whom correspondence should be addressed.
Tatiana V. Karpinets, E-mail: tkarpine{at}utk.edu

Abstract

Recent studies indicate that during tumorigenic transformationscells may generate mutations by themselves as a result of error-pronecell division with participation of error-prone polymerasesand aberrant mitosis. These mechanisms may be activated in cellsby continuing proliferative and survival signaling in a sustainedstress environment (SSE). The paper hypothesizes that long-termexposure to this signaling epigenetically reprograms the genomeof some cells and, in addition, leads to their senescence. Theepigenetic reprogramming results in (i) hypermethylation oftumor-suppressor genes involved in the onset of cell cycle arrest,apoptosis and DNA repair; (ii) hypomethylation of proto-oncogenesassociated with persistent proliferative activity and in (iii)the global demethylation of the genome and activation of DNArepeats. These epigenetic changes in the proliferating cellsassociate with their replicative senescence and allow the reprogrammedsenescent cells to overcome the cell cycle arrest and to activateerror-prone replications. It is hypothesized that the generationof mutations in the error-prone replications of the epigeneticallyreprogrammed cells is not random. The mutations match epigeneticalterations in the cellular genome, namely gain of functionmutations in the case of hypomethylation and loss of functionsin the case of hypermethylation. In addition, continuing proliferationof the cells imposed by signaling in SSE speeds up the naturalselection of the mutant cells favoring the survival of the cellswith mutations that are beneficial in the environment. In thisway a stress-induced replication of the cells epigeneticallyreprograms their genome for quick adaptation to stressful environmentsproviding an increased rate of mutations, epigenetic tags tobeneficial mutations and quick selection process. In combinationthese processes drive the origin of the transformed mammaliancells, cancer development and progression. Support from genomic,biochemical, and medical studies for the proposed hypothesisand its implementations are discussed.

Keywords: cancer; epigenetics; carcinogenesis; methylation; mutations; senescence; reprogramming.

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