Team:Paris/Modeling/Programs

From 2008.igem.org

(Difference between revisions)
(Complexations Caracterisation)
(Equilibrium of a Complex)
Line 20: Line 20:
==Equilibrium of a Complex==
==Equilibrium of a Complex==
 +
 +
Know, if we imagine a given amount of ''A<sub>i</sub>'' and ''B<sub>i</sub>'', that are calculated as their equilibrium without taking acount of their complexation (but, for instance, of other interactions and/or disappearance), and that the produced complex C disappears along time with a ''degradation rate'' &gamma;, we get :
 +
 +
<center> [[Image:GammaC.jpg]] </center>
 +
 +
so that the equilibrium gives :
 +
 +
<center> [[Image:EqGammaC.jpg]] </center>
 +
 +
with
 +
 +
<center> [[Image:Keff.jpg]] </center>
==Hill Functions==
==Hill Functions==

Revision as of 15:05, 21 September 2008

Contents

Complexations Caracterisation

The first hypothesis is that a complexation reaction is fully determined by the following :

Reacthill.jpg

and that the rates k+ et k- stay constant under all conditions. Then, the second hypothesis is that these equations are (kinetically speaking) elementary :

Kinhill.jpg
and at steady-state :
Sshill.jpg

Then, since we guess that the only datas we will have are the quantities of A and B introduced (Ai and Bi), the only equations we will deal with is the following, entirely determining the concentration Ceq at steady-state (at least if we take the smallest real root of the equation, it is useless to demonstrate the unicity, or even the existence, of such a solution) :

Eqnss.jpg

Equilibrium of a Complex

Know, if we imagine a given amount of Ai and Bi, that are calculated as their equilibrium without taking acount of their complexation (but, for instance, of other interactions and/or disappearance), and that the produced complex C disappears along time with a degradation rate γ, we get :

GammaC.jpg

so that the equilibrium gives :

EqGammaC.jpg

with

Keff.jpg

Hill Functions

The previous system of complexation applied in particular to the association of the Promoters (P) and its Transcription Factor (TF).

Because the promoters on a "low copy plasmid" exists in the cell in ten exemplaries, in contrary to a protein, which, as long as it is produced (even weakly) exists in thousands of exemplaries, we assume can the quantities of TF and P are different by several orders of magnitude. Then, with the previous notations, if A, B and C stands respectively for TF, P and the complex TF><P, we will get

Approxhill.jpg

that we can easily solve with :

Reshill.jpg

Depending to the order n (also called cooperativity, because it correponds to the possibilities of the transcription factor to binds in a group on the promoter), this function is a sigmoïd, known as the Hill function. The parameter K , called activation constant, is often replaced in the previous expression by the following notation

ChangeK.jpg

It simplifies the manipulations of the expression ; we can notice that K represents now the amount of TF needed to bind half of the total P in the cell.

Hilldef.jpg

Finding Parameters

Then, by solving the complexation equation for a given set of K et n (and, in term of production of protein, the b (or β) parameter (see hypothesis)), we can have an approximation of the corresponding Ceq. The idea, in order to find the bests parameters which correspond to our measurements, is to run a basical program of quadratic optimisation. The final error would tell us if our modelisation is consistent.



((((the following is not coresponding to the new model, but we will use the same frame to expose the corresponding program)))))


(((((((This program aims at fill this data bank, from experimental data obtained by our wet lab. )))))))

(((((( After some trials, we have obtained interesting results in terms of precision. We are now trying to test the robustness of the estimations in order to quantify the influence of biological variance in the results as well as the influence of the number of points available. ))))))))

(((((
Estimation.jpg
)))))

(((((( The corresponding code can be found there : Estimation of the parameters )))))))


Induction by a small molecule