Team:TU-Eindhoven/LEC/Modelling

From 2012.igem.org

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Biological cells use highly regulated homeostasis systems to keep a very low cytosolic Ca<sup>2+</sup> level. In normal-growing yeast the cytosolic Ca<sup>2+</sup> concentration is maintained in the range of 50-200nM in the presence of environmental Ca<sup>2+</sup> concentrations ranging from &micro;M to 100mM <html><a href="#ref_miseta" name="text_miseta"><sup>[1]</sup></a></html>. The homeostatis system in yeast cells has two basic characteristics. The
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Biological cells use highly regulated homeostasis systems to keep a very low cytosolic Ca<sup>2+</sup> level. In normal-growing yeast the cytosolic Ca<sup>2+</sup> concentration is maintained in the range of 50-200nM in the presence of environmental Ca<sup>2+</sup> concentrations ranging from &micro;M to 100mM <html><a href="#ref_miseta" name="text_miseta"><sup>[1]</sup></a></html>.
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cytosolic Ca2+ concentration is tightly controlled by zero steady-state error to extracellular stimuli and the system is relatively insensitive to speci�c kinetic parameters, due to robustness of such adaptation <html><a href="#ref_kitano" name="text_kitano"><sup>[3]</sup></a></html>.  
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The homeostatis system in yeast cells has two basic characteristics. The cytosolic Ca<sup>2+</sup> concentration is tightly controlled by zero steady-state error to extracellular stimuli and the system is relatively insensitive to specific kinetic parameters, due to robustness of such adaptation <html><a href="#ref_kitano" name="text_kitano"><sup>[2]</sup></a></html>.  
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To achieve an accurate model, the influences of voltage-dependent calcium channels are added to a basic model for yeast calcium homeostasis. In this model, first described by J. Cui <i>et al</i>, the main contributions of calcium transport are defined <html><a href="#ref_cui" name="text_cui"><sup>[2]</sup></a></html>.  
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To achieve an accurate model, the influences of voltage-dependent calcium channels are added to a basic model for yeast calcium homeostasis. In this model, first described by J. Cui <i>et al</i>, the main contributions of calcium transport are defined <html><a href="#ref_cui" name="text_cui"><sup>[3]</sup></a></html>.  
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Under normal conditions, extracellular Ca<sup>2+</sup> enters the cytosol through an unknown Transporter X, whose encoded gene has not been identified yet. Cytosolic Ca<sup>2+</sup> can be pumped into the endoplasmic reticulum (ER) and Golgi system through Pmr1 and can be sequestered into the vacuole through Pmc1 and Vcx1. Both the expression and function of Pmc1, Pmr1 and Vcx1 are regulated by calcineurin, a highly conserved protein phosphatase that is activated
Under normal conditions, extracellular Ca<sup>2+</sup> enters the cytosol through an unknown Transporter X, whose encoded gene has not been identified yet. Cytosolic Ca<sup>2+</sup> can be pumped into the endoplasmic reticulum (ER) and Golgi system through Pmr1 and can be sequestered into the vacuole through Pmc1 and Vcx1. Both the expression and function of Pmc1, Pmr1 and Vcx1 are regulated by calcineurin, a highly conserved protein phosphatase that is activated
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by Ca<sup>2+</sup>-bound calmodulin<html><a href="#ref_cui" name="text_cui"><sup>[2]</sup></a></html>. Therefore, the transcription factor Crz1 can be dephosporylated by activated calcineurin. A conformational switch model is used to simulate Crz1 translocation, as described by Okamura <i>et al</i><html> <a href="#ref_switch" name="text_switch"><sup>[4]</sup></a></html>.
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by Ca<sup>2+</sup>-bound calmodulin<html><a href="#ref_cui" name="text_cui"><sup>[3]</sup></a></html>. Therefore, the transcription factor Crz1 can be dephosporylated by activated calcineurin. A conformational switch model is used to simulate Crz1 translocation, as described by Okamura <i>et al</i><html> <a href="#ref_switch" name="text_switch"><sup>[4]</sup></a></html>.
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<li><a href="#text_miseta" name="ref_miseta">[1]</a> A. Miseta, L. Fu, R. Kellermayer, J. Buckley, D.M. Bedwell, “The Golgi Apparatus plays a significant role in the maintainance of Ca2+ homeostasis in the vps33 vacuolar biogenesis mutant of Saccharomyces cerevisiae”, J. Biol. Chem. 274: 5939-5947, (1999)</li>
<li><a href="#text_miseta" name="ref_miseta">[1]</a> A. Miseta, L. Fu, R. Kellermayer, J. Buckley, D.M. Bedwell, “The Golgi Apparatus plays a significant role in the maintainance of Ca2+ homeostasis in the vps33 vacuolar biogenesis mutant of Saccharomyces cerevisiae”, J. Biol. Chem. 274: 5939-5947, (1999)</li>
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<li><a href="#text_cui" name="ref_cui">[2]</a> J. Cui, Mathematical modeling of metal ion homeostasis and signaling systems, (2009)</li>
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<li><a href="#text_kitano" name="ref_kitano">[2]</a> H. Kitano, Systems biology : a brief overview, Nature 295: 1662-1664, (2002).</li>
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<li><a href="#text_kitano" name="ref_kitano">[3]</a> H. Kitano, Systems biology : a brief overview, Nature 295: 1662-1664, (2002).</li>
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<li><a href="#text_cui" name="ref_cui">[3]</a> J. Cui, Mathematical modeling of metal ion homeostasis and signaling systems, (2009)</li>
<li><a href="#text_switch" name="ref_switch">[4]</a> H. Okamura, J. Aramburu, C. Garca-Rodrguez, et al. Concerted dephosphorylation of the tran-
<li><a href="#text_switch" name="ref_switch">[4]</a> H. Okamura, J. Aramburu, C. Garca-Rodrguez, et al. Concerted dephosphorylation of the tran-
scription factor NFAT1 induces a conformational switch that regulates transcriptional activity,
scription factor NFAT1 induces a conformational switch that regulates transcriptional activity,

Revision as of 11:37, 25 September 2012