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Team:UFMG Brazil/modeling
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{{Team:UFMG Brazil/barra}} {{carlos_teste}} | {{Team:UFMG Brazil/barra}} {{carlos_teste}} | ||
| + | =Modeling TMAO system= | ||
| - | + | ==Labels and conventions== | |
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Ce: The enzymatic complex formed by TorT+TorS+TMAO, which reacts with TorR | Ce: The enzymatic complex formed by TorT+TorS+TMAO, which reacts with TorR | ||
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C_TM: Complex formed by TorT and TMAO | C_TM: Complex formed by TorT and TMAO | ||
| - | + | ==First Modeling== | |
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This is the simplest modeling process to be considered in our study. The product of the enzymatic process is collapsed in only one reaction that was placed at equilibrium. | This is the simplest modeling process to be considered in our study. The product of the enzymatic process is collapsed in only one reaction that was placed at equilibrium. | ||
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| - | + | ==Second Modeling== | |
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It was used the same pattern of reactions as before, but with a standpoint of "essential activation" (the first reaction is no longer considered to equilibrium). Some enzymes need to be activated to bind the substrate. In our case, the enzyme is activated by TorS and activators are TMAO and TorT. The rate of product P appearance depends on the activators concentration. | It was used the same pattern of reactions as before, but with a standpoint of "essential activation" (the first reaction is no longer considered to equilibrium). Some enzymes need to be activated to bind the substrate. In our case, the enzyme is activated by TorS and activators are TMAO and TorT. The rate of product P appearance depends on the activators concentration. | ||
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[[File:tmao_secondModeling.png]] | [[File:tmao_secondModeling.png]] | ||
| - | + | =Modeling IMA System= | |
| - | + | ==First Reaction - Cobalt ions bind to albumin== | |
The cobalt ion binds to albumin protein, originating the cobalt-albumin complex. If the albumin is derived from a healthy patient, it will bind more cobalt ions than a albumin derived from a patient with heart disease. It happens because patients with heart conditions will have a isquemic modified albumin (IMA), which has less capability of binding to cobalt. Thus, the amount of free cobalt in the system will be determined by the presence of a normal or ischemic albumin in the sample. | The cobalt ion binds to albumin protein, originating the cobalt-albumin complex. If the albumin is derived from a healthy patient, it will bind more cobalt ions than a albumin derived from a patient with heart disease. It happens because patients with heart conditions will have a isquemic modified albumin (IMA), which has less capability of binding to cobalt. Thus, the amount of free cobalt in the system will be determined by the presence of a normal or ischemic albumin in the sample. | ||
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[[File:eq1_cobalt.png]] | [[File:eq1_cobalt.png]] | ||
| - | + | ==Second Reaction - The entry of cobalt in the cell== | |
There are four cobalt transporters in the cell. The rcnA (Uniprot code: P76425) and zntA (Uniprot code: P37617) transport the cobalt to outside the cell. The corA (Uniprot code: P0ABI4) and zupT (Uniprot code: P0A8H3) transport the cobalt to inside the cell. | There are four cobalt transporters in the cell. The rcnA (Uniprot code: P76425) and zntA (Uniprot code: P37617) transport the cobalt to outside the cell. The corA (Uniprot code: P0ABI4) and zupT (Uniprot code: P0A8H3) transport the cobalt to inside the cell. | ||
Revision as of 03:55, 27 September 2013
