Transposons, p53 and Genome Security

Bhavana Tiwari; Amanda E. Jones; John M. Abrams

doi:10.1016/j.tig.2018.08.003

Transposons, p53 and Genome Security

Bhavana Tiwari, Amanda E. Jones, John M. Abrams

Research output: Contribution to journal › Review article › peer-review

25 Scopus citations

Abstract

p53, the most commonly mutated tumor suppressor, is a transcription factor known to regulate proliferation, senescence, and apoptosis. Compelling studies have found that p53 may prevent oncogenesis through effectors that are unrelated to these canonical processes and recent findings have uncovered ancient roles for p53 in the containment of mobile elements. Together, these developments raise the possibility that some p53-driven cancers could result from unrestrained transposons. Here, we explore evidence linking conserved features of p53 biology to the control of transposons. We also show how p53-deficient cells can be exploited to probe the behavior of transposons and illustrate how unrestrained transposons incited by p53 loss might contribute to human malignancies.

Original language	English (US)
Pages (from-to)	846-855
Number of pages	10
Journal	Trends in Genetics
Volume	34
Issue number	11
DOIs	https://doi.org/10.1016/j.tig.2018.08.003
State	Published - Nov 2018

Keywords

cancer
mobile elements
p53 biology
retrotransposons
transposons
transrepression

ASJC Scopus subject areas

Genetics

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10.1016/j.tig.2018.08.003

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title = "Transposons, p53 and Genome Security",

abstract = "p53, the most commonly mutated tumor suppressor, is a transcription factor known to regulate proliferation, senescence, and apoptosis. Compelling studies have found that p53 may prevent oncogenesis through effectors that are unrelated to these canonical processes and recent findings have uncovered ancient roles for p53 in the containment of mobile elements. Together, these developments raise the possibility that some p53-driven cancers could result from unrestrained transposons. Here, we explore evidence linking conserved features of p53 biology to the control of transposons. We also show how p53-deficient cells can be exploited to probe the behavior of transposons and illustrate how unrestrained transposons incited by p53 loss might contribute to human malignancies.",

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AU - Tiwari, Bhavana

AU - Jones, Amanda E.

AU - Abrams, John M.

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N2 - p53, the most commonly mutated tumor suppressor, is a transcription factor known to regulate proliferation, senescence, and apoptosis. Compelling studies have found that p53 may prevent oncogenesis through effectors that are unrelated to these canonical processes and recent findings have uncovered ancient roles for p53 in the containment of mobile elements. Together, these developments raise the possibility that some p53-driven cancers could result from unrestrained transposons. Here, we explore evidence linking conserved features of p53 biology to the control of transposons. We also show how p53-deficient cells can be exploited to probe the behavior of transposons and illustrate how unrestrained transposons incited by p53 loss might contribute to human malignancies.

AB - p53, the most commonly mutated tumor suppressor, is a transcription factor known to regulate proliferation, senescence, and apoptosis. Compelling studies have found that p53 may prevent oncogenesis through effectors that are unrelated to these canonical processes and recent findings have uncovered ancient roles for p53 in the containment of mobile elements. Together, these developments raise the possibility that some p53-driven cancers could result from unrestrained transposons. Here, we explore evidence linking conserved features of p53 biology to the control of transposons. We also show how p53-deficient cells can be exploited to probe the behavior of transposons and illustrate how unrestrained transposons incited by p53 loss might contribute to human malignancies.

KW - cancer

KW - mobile elements

KW - p53 biology

KW - retrotransposons

KW - transposons

KW - transrepression

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Transposons, p53 and Genome Security

Abstract

Keywords

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