Team:Freiburg/Modeling/Parameter analysis
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<h2>Parameter estimations for the 2 pools TCR dimerization model</h2> | <h2>Parameter estimations for the 2 pools TCR dimerization model</h2> | ||
<br> | <br> | ||
- | Evolving and regarding the equations was the first step to begin to understand how the | + | Evolving and regarding the equations was the first step to begin to understand how the time course of the involved quantities could behave. To get a deeper insight into the characteristics of the model, the behaviour for different parameters and parameter sets is analyzed. Starting with all parameters at value one except one, even though not very realistic, gives a first clue about the course in time of the active TCR density, the interface pool density and the spare pool density. |
<br><br> | <br><br> | ||
<table> | <table> | ||
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l = 1; % ratio | l = 1; % ratio | ||
p = 1; % exchange rate | p = 1; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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<br><br> | <br><br> | ||
<h4>Different parameter set </h4> | <h4>Different parameter set </h4> | ||
- | The turnover rate ('''S''') is set to a value 10 times smaller than the previous value and the amount of the NIP is now 4 times smaller than in the calculation above. The TCR-NIP dissociating rate ('''k'''<sub>off</sub>) is 5 times smaller than the binding rate ('''k'''<sub>on</sub>). The same holds for the dimer | + | The turnover rate ('''S''') is set to a value 10 times smaller than the previous value and the amount of the NIP is now 4 times smaller than in the calculation above. The TCR-NIP dissociating rate ('''k'''<sub>off</sub>) is 5 times smaller than the binding rate ('''k'''<sub>on</sub>). The same holds for the dimer dissociating rate ('''k'''<sub>doff</sub>) in relation to the dimerization rate ('''k'''<sub>don</sub>). |
<table> | <table> | ||
<tr> | <tr> | ||
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l = 1; % ratio | l = 1; % ratio | ||
p = 1; % exchange rate | p = 1; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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<br> | <br> | ||
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<h4>TCR activity for different binding rates and dimerization rates </h4> | <h4>TCR activity for different binding rates and dimerization rates </h4> | ||
In the calculations for the plots below the same parameters as above were chosen except for '''k'''<sub>on</sub> repectively '''k'''<sub>don</sub>. The black lines represents active TCR densities in time for different '''k'''<sub>on</sub> repectively '''k'''<sub>don</sub>. | In the calculations for the plots below the same parameters as above were chosen except for '''k'''<sub>on</sub> repectively '''k'''<sub>don</sub>. The black lines represents active TCR densities in time for different '''k'''<sub>on</sub> repectively '''k'''<sub>don</sub>. | ||
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</table> | </table> | ||
Increasing the binding rate gives a little higher active TCR densities than increasing the dimerization rate in the same way. | Increasing the binding rate gives a little higher active TCR densities than increasing the dimerization rate in the same way. | ||
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<br><br> | <br><br> | ||
+ | <h4>TCR activity dependent on NIP amount </h4> | ||
The next two plots show how the TCR activity in time differs when different amounts of NIP are used: | The next two plots show how the TCR activity in time differs when different amounts of NIP are used: | ||
<table> | <table> | ||
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l = 1; % ratio | l = 1; % ratio | ||
p = 1; % exchange rate | p = 1; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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l = 1; % ratio | l = 1; % ratio | ||
p = 1; % exchange rate | p = 1; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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</tr> | </tr> | ||
</table> | </table> | ||
- | The | + | The more NIP is used, the higher is the activity. |
<br><br> | <br><br> | ||
<h4>TCR activity dependent on exchange between spare and interface pool </h4> | <h4>TCR activity dependent on exchange between spare and interface pool </h4> | ||
- | + | The TCR can switch from a non-binding state to a binding state or in other words, the TCRs in the spare pool can become TCRs in the interface pool. This exchange is regulated by the parameters '''λ''' and '''φ'''. '''λ''' is a ratio between the spare and the interface pool and '''φ''' is the exchange rate constant.<br><br> | |
- | The TCR can switch from a non-binding state to a binding state or in other words, the TCRs in the spare pool can become TCRs in the interface pool. This exchange is regulated by the parameters '''λ''' and '''φ'''. '''λ''' is a ratio between the spare and the interface pool and '''φ''' is the exchange rate constant<br><br> | + | |
<table> | <table> | ||
<tr> | <tr> | ||
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l = 5; % ratio | l = 5; % ratio | ||
p = 0.05; % exchange rate | p = 0.05; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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</tr> | </tr> | ||
</table> | </table> | ||
- | For a very high ratio λ and a low exchange rate φ the ratio of the spare pool (non-binding TCR) to the interface pool (binding TCR) is high and the switching of a TCR between the non-binding and the binding state is low. Thus there is a low TCR activity because not enough TCRs are accessible by NIP. This can be | + | For a very high ratio λ and a low exchange rate φ the ratio of the spare pool (non-binding TCR) to the interface pool (binding TCR) is high and the switching of a TCR between the non-binding and the binding state is low. Thus there is a low TCR activity because not enough TCRs are accessible by NIP. This can be due to TCRs which are surrounded by big sized proteins who avoid a TCR-NIP formation. |
<table> | <table> | ||
<tr> | <tr> | ||
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l = 0.2; % ratio | l = 0.2; % ratio | ||
p = 5; % exchange rate | p = 5; % exchange rate | ||
- | h = 2; % | + | h = 2; % kinetic order |
</font> | </font> | ||
initial integration conditions: | initial integration conditions: | ||
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</tr> | </tr> | ||
</table> | </table> | ||
- | A low ratio λ and a high exchange rate φ | + | A low ratio λ and a high exchange rate φ lead to a high TCR activity as enough TCRs are available in the interface pool for NIP binding. The fast changing from the non-binding to the binding state assures a sufficient amount of TCRs for TCR-NIP and then dimer formation.<br><br> |
TCR activity for different exchanges (parameters as in the plot above except: N=0.2) | TCR activity for different exchanges (parameters as in the plot above except: N=0.2) | ||
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<tr> | <tr> | ||
<td> | <td> | ||
- | [[image:Freiburg_08_TA_ERates.png|thumb|left|500px| | + | [[image:Freiburg_08_TA_ERates.png|thumb|left|500px|'''Figure 9''': Active TCR density in time for different exchanges]] |
</td> | </td> | ||
</tr> | </tr> | ||
</table> | </table> | ||
- | The x-axis represents the | + | The x-axis represents the time course of the activity, the y-axis represents both parameters φ ( = y) and λ ( = 2 - y). So each black line in the plot is a time course of the TCR activity for a different φ and λ. The z-axis is the response intensity. With increasing exchange between the interface and spare pool, more TCRs switch to the binding state, hence more TCRs can bind NIP. As a consequence the active TCR density is higher then for a low exchange. <br> |
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Latest revision as of 22:49, 8 March 2009