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Predicted Functions of MdmX in Fine-Tuning the Response of p53 to DNA Damage

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  • Sohyoung Kim
  • Mirit I Aladjem
  • Geoffrey B McFadden
  • Kurt W Kohn

Abstract

Tumor suppressor protein p53 is regulated by two structurally homologous proteins, Mdm2 and MdmX. In contrast to Mdm2, MdmX lacks ubiquitin ligase activity. Although the essential interactions of MdmX are known, it is not clear how they function to regulate p53. The regulation of tumor suppressor p53 by Mdm2 and MdmX in response to DNA damage was investigated by mathematical modeling of a simplified network. The simplified network model was derived from a detailed molecular interaction map (MIM) that exhibited four coherent DNA damage response pathways. The results suggest that MdmX may amplify or stabilize DNA damage-induced p53 responses via non-enzymatic interactions. Transient effects of MdmX are mediated by reservoirs of p53∶MdmX and Mdm2∶MdmX heterodimers, with MdmX buffering the concentrations of p53 and/or Mdm2. A survey of kinetic parameter space disclosed regions of switch-like behavior stemming from such reservoir-based transients. During an early response to DNA damage, MdmX positively or negatively regulated p53 activity, depending on the level of Mdm2; this led to amplification of p53 activity and switch-like response. During a late response to DNA damage, MdmX could dampen oscillations of p53 activity. A possible role of MdmX may be to dampen such oscillations that otherwise could produce erratic cell behavior. Our study suggests how MdmX may participate in the response of p53 to DNA damage either by increasing dependency of p53 on Mdm2 or by dampening oscillations of p53 activity and presents a model for experimental investigation.Author Summary: A Molecular Interaction Map (MIM) akin to a circuit diagram of an electric device can give a comprehensive view of cellular processes and help understand complex protein functions in cells. To this end, we generated a MIM focused on the p53-Mdm2-MdmX network proteins and performed computer simulations to help understand how Mdm2 and MdmX may regulate p53. Proper regulation of p53 is important for cell survival: elevated levels of p53 can lead to cell death, and decreased levels of p53 can lead to cancer. Mdm2 and MdmX are structurally homologous proteins that regulate p53. Mdm2 negatively regulates p53 by degradation, but MdmX regulation of p53 is not well understood. Recently, Mdm2 and MdmX have been recognized as potential cancer therapeutic targets. In an effort to better understand how MdmX can alter the p53 activity under various conditions, we used mathematical models based on the MIM network to generate hypotheses that can be tested by experiments. Our simulations suggest that MdmX may increase the dependency of p53 on Mdm2 or dampen p53 oscillations during DNA damage response.

Suggested Citation

  • Sohyoung Kim & Mirit I Aladjem & Geoffrey B McFadden & Kurt W Kohn, 2010. "Predicted Functions of MdmX in Fine-Tuning the Response of p53 to DNA Damage," PLOS Computational Biology, Public Library of Science, vol. 6(2), pages 1-18, February.
    • Handle: RePEc:plo:pcbi00:1000665
    DOI: 10.1371/journal.pcbi.1000665
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    References listed on IDEAS

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    1. Bert Vogelstein & David Lane & Arnold J. Levine, 2000. "Surfing the p53 network," Nature, Nature, vol. 408(6810), pages 307-310, November.
    2. Gerardo Ferbeyre & Scott W. Lowe, 2002. "The price of tumour suppression?," Nature, Nature, vol. 415(6867), pages 26-27, January.
    3. Christopher J. Bakkenist & Michael B. Kastan, 2003. "DNA damage activates ATM through intermolecular autophosphorylation and dimer dissociation," Nature, Nature, vol. 421(6922), pages 499-506, January.
    4. Éric Fernandez & Renaud Schiappa & Jean-Antoine Girault & Nicolas Le Novère, 2006. "DARPP-32 Is a Robust Integrator of Dopamine and Glutamate Signals," PLOS Computational Biology, Public Library of Science, vol. 2(12), pages 1-15, December.
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