Team:Paris/Modeling/f3

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We have [OmpR^*] = {coef}_OmpRexpr(pTet) = {coef}_OmpR ƒ1([aTc]_i)

and [FliA] = {coef}_FliAexpr(pBad) = {coef}_FliA ƒ2([arab]_i)

So, at steady-states,

param	signification	unit	value	comments
[expr(pFlhDC)]	expression rate of pFlhDC with RBS E0032	nM.min^-1		need for 20 mesures with well choosen values of [aTc]_i and for 20 mesures with well choosen values of [arab]_i and 5x5 measures for the SUM?
γ_GFP	dilution-degradation rate of GFP(mut3b)	min^-1	0.0198
[GFP]	GFP concentration at steady-state	nM		need for 20 + 20 measures and 5x5 measures for the SUM?
(fluorescence)	value of the observed fluorescence	au		need for 20 + 20 measures and 5x5 measures for the SUM?
conversion	conversion ratio between fluorescence and concentration	nM.au^-1	(1/79.429)

param	signification corresponding parameters in the equations	unit	value	comments
β₁₂	production rate of FliA-pFlhDC with RBS E0032 β₁₂	nM.min^-1
(K₁₁/{coef_fliA})	activation constant of FliA-pFlhDC K₁₁	nM
n₁₁	complexation order of FliA-pFlhDC n₁₁	no dimension
β₂	production rate of OmpR-pFlhDC with RBS E0032 β₂	nM.min^-1
(K₁₉/{coef_ompR})	activation constant of OmpR-pFlhDC K₁₉	nM
n₁₉	complexation order of OmpR-pFlhDC n₁₉	no dimension

Then, if we have time, we want to verify the expected relation