Mathematical modeling of heat shock protein synthesis in response to temperature change

One of the most important questions in cell biology is how cells cope with rapid changes in their environment. The range of common molecular responses includes a dramatic change in the pattern of gene expression and the elevated synthesis of so-called heat shock (or stress) proteins (HSPs). Inductio...

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Bibliographic Details
Published in:Journal of theoretical biology 2009-08, Vol.259 (3), p.562-569
Main Authors: Szymańska, Zuzanna, Zylicz, Maciej
Format: Article
Language:English
Subjects:
Animals
Cell stress
Cells - metabolism
Computer Simulation
Heat shock proteins
Heat-Shock Proteins - biosynthesis
Heat-Shock Proteins - genetics
Heat-Shock Response - physiology
Models, Biological
RNA, Messenger - analysis
Signaling pathways
Stress, Physiological
Temperature
Transcription, Genetic
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Summary:One of the most important questions in cell biology is how cells cope with rapid changes in their environment. The range of common molecular responses includes a dramatic change in the pattern of gene expression and the elevated synthesis of so-called heat shock (or stress) proteins (HSPs). Induction of HSPs increases cell survival under stress conditions [Morimoto, R.I., 1993. Cells in stress: transcriptional activation of heat shock genes. Science 259, 1409–1410]. In this paper we propose a mathematical model of heat shock protein synthesis induced by an external temperature stimulus. Our model consists of a system of nine nonlinear ordinary differential equations describing the temporal evolution of the key variables involved in the regulation of HSP synthesis. Computational simulations of our model are carried out for different external temperature stimuli. We compare our model predictions with experimental data for three different cases—one corresponding to heat shock, the second corresponding to slow heating conditions and the third corresponding to a short heat shock (lasting about 40 min). We also present our model predictions for heat shocks carried out up to different final temperatures and finally we present a new hypothesis concerning the molecular response to stress that explains some phenomena observed in experiments.
ISSN:0022-5193
1095-8541
DOI:10.1016/j.jtbi.2009.03.021