Optimality in DNA repair

Morgiane Carole Richard; Matthew Fryett; Samantha Miller; Ian Booth; Celso Grebogi; Alessandro Moura

doi:10.1016/j.jtbi.2011.08.024

Optimality in DNA repair

Morgiane Carole Richard, Matthew Fryett, Samantha Miller, Ian Booth, Celso Grebogi, Alessandro Moura

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Abstract

DNA within cells is subject to damage from various sources. Organisms have evolved a number of mechanisms to repair DNA damage. The activity of repair enzymes carries its own risk, however, because the repair of two nearby lesions may lead to the breakup of DNA and result in cell death. We propose a mathematical theory of the damage and repair process in the important scenario where lesions are caused in bursts. We use this model to show that there is an optimum level of repair enzymes within cells which optimises the cell's response to damage. This optimal level is explained as the best trade-off between fast repair and a low probability of causing double-stranded breaks. We derive our results analytically and test them using stochastic simulations, and compare our predictions with current biological knowledge. (C) 2011 Elsevier Ltd. All rights reserved.

Original language	English
Pages (from-to)	39-43
Number of pages	5
Journal	Journal of Theoretical Biology
Volume	292
Early online date	19 Sept 2011
DOIs	https://doi.org/10.1016/j.jtbi.2011.08.024
Publication status	Published - 7 Jan 2012

Keywords

DNA damage
DNA repair
stochastic modelling
nucleotide excision-repair
Escherichia-coli
mathematical-model
SOS response
damage
mechanisms
irradiation
radiation
survival

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title = "Optimality in DNA repair",

abstract = "DNA within cells is subject to damage from various sources. Organisms have evolved a number of mechanisms to repair DNA damage. The activity of repair enzymes carries its own risk, however, because the repair of two nearby lesions may lead to the breakup of DNA and result in cell death. We propose a mathematical theory of the damage and repair process in the important scenario where lesions are caused in bursts. We use this model to show that there is an optimum level of repair enzymes within cells which optimises the cell's response to damage. This optimal level is explained as the best trade-off between fast repair and a low probability of causing double-stranded breaks. We derive our results analytically and test them using stochastic simulations, and compare our predictions with current biological knowledge. (C) 2011 Elsevier Ltd. All rights reserved.",

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author = "Richard, {Morgiane Carole} and Matthew Fryett and Samantha Miller and Ian Booth and Celso Grebogi and Alessandro Moura",

year = "2012",

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doi = "10.1016/j.jtbi.2011.08.024",

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journal = "Journal of Theoretical Biology",

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T1 - Optimality in DNA repair

AU - Richard, Morgiane Carole

AU - Fryett, Matthew

AU - Miller, Samantha

AU - Booth, Ian

AU - Grebogi, Celso

AU - Moura, Alessandro

PY - 2012/1/7

Y1 - 2012/1/7

N2 - DNA within cells is subject to damage from various sources. Organisms have evolved a number of mechanisms to repair DNA damage. The activity of repair enzymes carries its own risk, however, because the repair of two nearby lesions may lead to the breakup of DNA and result in cell death. We propose a mathematical theory of the damage and repair process in the important scenario where lesions are caused in bursts. We use this model to show that there is an optimum level of repair enzymes within cells which optimises the cell's response to damage. This optimal level is explained as the best trade-off between fast repair and a low probability of causing double-stranded breaks. We derive our results analytically and test them using stochastic simulations, and compare our predictions with current biological knowledge. (C) 2011 Elsevier Ltd. All rights reserved.

AB - DNA within cells is subject to damage from various sources. Organisms have evolved a number of mechanisms to repair DNA damage. The activity of repair enzymes carries its own risk, however, because the repair of two nearby lesions may lead to the breakup of DNA and result in cell death. We propose a mathematical theory of the damage and repair process in the important scenario where lesions are caused in bursts. We use this model to show that there is an optimum level of repair enzymes within cells which optimises the cell's response to damage. This optimal level is explained as the best trade-off between fast repair and a low probability of causing double-stranded breaks. We derive our results analytically and test them using stochastic simulations, and compare our predictions with current biological knowledge. (C) 2011 Elsevier Ltd. All rights reserved.

KW - DNA damage

KW - DNA repair

KW - stochastic modelling

KW - nucleotide excision-repair

KW - Escherichia-coli

KW - mathematical-model

KW - SOS response

KW - damage

KW - mechanisms

KW - irradiation

KW - radiation

KW - survival

U2 - 10.1016/j.jtbi.2011.08.024

DO - 10.1016/j.jtbi.2011.08.024

M3 - Article

SN - 0022-5193

VL - 292

SP - 39

EP - 43

JO - Journal of Theoretical Biology

JF - Journal of Theoretical Biology

ER -

Optimality in DNA repair

Abstract

Keywords

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