Abstract
As our understanding of cellular behaviour grows, and we identify more and more genes involved in the control of such basic processes as cell division and programmed cell death, it becomes increasingly difficult to integrate such detailed knowledge into a meaningful whole. This is an area where mathematical modelling can complement experimental approaches, and even simple mathematical models can yield useful biological insights. This review presents examples of this in the context of understanding the combined effects of different levels of cell death and cell division in a number of biological systems including tumour growth, the homeostasis of immune memory and pre-implantation embryo development. The models we describe, although simplistic, yield insight into several phenomena that are difficult to understand using a purely experimental approach. This includes the different roles played by the apoptosis of stem cells and differentiated cells in determining whether or not a tumour can grow; the way in which a density dependent rate of apoptosis (for instance mediated by cell-cell contact or cytokine signalling) can lead to homeostasis; and the effect of stochastic fluctuations when the number of cells involved is small. We also highlight how models can maximize the amount of information that can be extracted from limited experimental data. The review concludes by summarizing the various mathematical frameworks that can be used to develop new models and the type of biological information that is required to do this.
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References
Heemels M-T Nature insight: Apoptosis. Nature 2000; 407: 769.
Los M, Stroh C, Janicke RU, Engels IH, Schulze-Osthoff K Caspases: More than just killers? Trends Immunol 2001; 22: 31-34.
Hengartner MO The biochemistry of apoptosis. Nature 2000; 407: 770-775.
Callard R, George AJT, Stark J Cytokines, chaos and complexity. Immunity 1999; 11: 507-513.
Strogatz SH Exploring complex networks. Nature 2001; 410: 268-276.
Tomlinson IPM, Bodmer WF Failure of programmed cell death and differentiation as causes of tumors: Some simple mathematical models. Proc Natl Acad Sci USA 1995; 92: 11130-11134.
Hardy K, Spanos S, Becker D, Iannelli P, Winston RML, Stark J From cell death to embryo arrest: Mathematical models of human preimplantation embryo development. Proc Natl Acad Sci USA 2001; 98: 1655-1660.
Krammer P CD95's deadly mission in the immune system. Nature 2000; 407: 785-759.
Yates A, Callard R Cell death and the maintenance of immunological memory. Discrete and Continuous Dyn Sys B 2001; 1: 43-60.
Yates A, Bergmann C, van Hemmen JL, Stark J, Callard R Cytokine-modulated regulation of helper T-cell populations. J Theor Biol 2000; 206: 539-560.
Hardy K Cell death in the mammalian blastocyst. Mol Hum Reprod 1997; 3: 919-925.
Jagers P. Branching Processes with Biological Applications. London: Wiley, 1975.
Byrne HM, Chaplain MAJ Growth of nonnecrotic tumours in the presence and absence of inhibitors. Math Biosci 1995; 130: 151-181.
Hearn T, Haurie C, Mackey M Cyclical neutropenia and the peripheral control of white blood cell production. J Theor Biol 1998; 192: 167-181.
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Hardy, K., Stark, J. Mathematical models of the balance between apoptosis and proliferation. Apoptosis 7, 373–381 (2002). https://doi.org/10.1023/A:1016183731694
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DOI: https://doi.org/10.1023/A:1016183731694