Team:TUDelft/Modeling Parameters

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Latest revision as of 12:57, 18 October 2009

Modeling Parameters

Transcriptional Cascade

Parameter	Values	Description	Ref
c_pLac	5e-10	maximum transcription rate (M/min)	[1]
c_pTet	1.5e-7	maximum transcription rate (M/min)	[2]
c_pλ	1.5e-7	maximum transcription rate (M/min)	estimate
K₅₀^IPTG	1.3e-6	dissociation constant (M)	[3]
K₅₀^LacI	800e-9	dissociation constant (M)	[3]
K₅₀^TetR	179e-12	dissociation constant (M)	[3]
K₅₀^CI	8e-12	dissociation constant (M)	[3]
n_IPTG	2	Hills coefficient	[3]
n_LacI	2	Hills coefficient	[3]
n_TetR	3	Hills coefficient	[3]
n_CI	2	Hills coefficient	[3]
d_LacI	0.1386	degradation rate (M/min)	[3]
d_TetR	0.1386	degradation rate (M/min)	[3]
d_CI	0.042	degradation rate (M/min)	[3]
d_RFP	6.3e-3	degradation rate (M/min)	[3]
d_GFP	6.3e-3	degradation rate (M/min)	[3]
d_mRNA	0.029	degradation rate (M/min)	[4]
α	16 - 57	translation rate (translations/min/mRNA), depends on growth rate (a default value of 30 is used)	[5]
k_IPTG	0.92	rate constant for IPTG diffusion into cell	[6]

Conjugation

Parameter	Values	Description	Ref
A	1735	Surface area available (mm²)	Area of 0.2μm filter used in conjugation tests.
r₀	0.8	initial colony radius (μm)	[7]
g_n	0.99	specific growth rate (1/hr)	Determined experimentally for R751 containing cells.
g_r	30	colony radial specific growth rate (μm/hr)	[8]
N_d	10000	initial number of donors	Estimate
N_r	10000	initial number of donors	Estimate
λ	5.76	intensity (CFU/mm²)	Calculated using N_r/A.

Retrieved from "http://2009.igem.org/Team:TUDelft/Modeling_Parameters"

@@ Line 15: / Line 15: @@
 |5e-10
 |maximum transcription rate (M/min)
-| [1]
+| [[Team:TUDelft/Modeling_References|[1]]]
 |-
 | c<sub>pTet</sub>
 |1.5e-7
 |maximum transcription rate (M/min)
-| [2]
+| [[Team:TUDelft/Modeling_References|[2]]]
 |-
 | c<sub>p&lambda;</sub>
@@ Line 30: / Line 30: @@
 |1.3e-6
 |dissociation constant (M)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | K<sub>50</sub><sup>LacI</sup>
 |800e-9
 |dissociation constant (M)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | K<sub>50</sub><sup>TetR</sup>
 |179e-12
 |dissociation constant (M)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | K<sub>50</sub><sup>CI</sup>
 |8e-12
 |dissociation constant (M)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | n<sub>IPTG</sub>
 |2
 | Hills coefficient
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | n<sub>LacI</sub>
 |2
 | Hills coefficient
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | n<sub>TetR</sub>
 |3
 | Hills coefficient
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | n<sub>CI</sub>
 |2
 | Hills coefficient
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>LacI</sub>
 | 0.1386
 | degradation rate (M/min)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>TetR</sub>
 | 0.1386
 | degradation rate (M/min)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>CI</sub>
 | 0.042
 | degradation rate (M/min)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>RFP</sub>
 | 6.3e-3
 | degradation rate (M/min)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>GFP</sub>
 | 6.3e-3
 | degradation rate (M/min)
-| [3]
+| [[Team:TUDelft/Modeling_References|[3]]]
 |-
 | d<sub>mRNA</sub>
 | 0.029
 | degradation rate (M/min)
-| [4]
+| [[Team:TUDelft/Modeling_References|[4]]]
 |-
 | &alpha;
 | 16 - 57
 | translation rate (translations/min/mRNA), depends on growth rate (a default value of 30 is used)
-| [5]
+| [[Team:TUDelft/Modeling_References|[5]]]
 |-
 | k<sub>IPTG</sub>
 | 0.92
 | rate constant for IPTG diffusion into cell
-| [6]
+| [[Team:TUDelft/Modeling_References|[6]]]
 |-
 |}
@@ Line 126: / Line 126: @@
 | 0.8
 | initial colony radius (&mu;m)
-| [7]
+| [[Team:TUDelft/Modeling_References|[7]]]
 |-
 | g<sub>n</sub>
@@ Line 136: / Line 136: @@
 | 30
 | colony radial specific growth rate (&mu;m/hr)
-| [8]
+| [[Team:TUDelft/Modeling_References|[8]]]
 |-
 | N<sub>d</sub>
@@ Line 156: / Line 156: @@
 <br>
-=References=
-. M. Santillan, M.C. Mackey, E.S. Zeron, Origin of Bistability in the lac Operon, Biophysical Journal, Volume 92, Issue 11, 1 June 2007, Pages 3830-3842, ISSN 0006-3495, DOI: 10.1529/biophysj.106.101717. (http://www.sciencedirect.com/science/article/B94RW-4V9YVV6-8/2/cd4c5ba8d532a314eed932d787f56a35)
-. Thuc T. Le, Calin C. Guet, Philippe Cluzel, Protein expression enhancement in efflux-deleted mutant bacteria, Protein Expression and Purification, Volume 48, Issue 1, July 2006, Pages 28-31, ISSN 1046-5928, DOI: 10.1016/j.pep.2005.11.018.
-(http://www.sciencedirect.com/science/article/B6WPJ-4HV73GJ-1/2/36f5ff80fe56e2533f1ec0699bf12a7e)
-. http://parts.mit.edu/igem07/index.php?title=ETHZ/Parameters
-. Barrio M, Burrage K, Leier A, Tian T. Oscillatory regulation of Hes1: Discrete stochastic delay modelling and simulation. PLoS Comput Biol. 2006 Sep 8; 2(9): e117.
-. Liang, S.-T., Xu, Y.-C., Dennis, P., Bremer, H. mRNA Composition and Control of Bacterial Gene Expression. J. Bacteriol. 2000 182: 3037-3044.
-. Michail Stamatakis, Nikos V. Mantzaris, Comparison of Deterministic and Stochastic Models of the lac Operon Genetic Network, Biophysical Journal, Volume 96, Issue 3, 4 February 2009, Pages 887-906, ISSN 0006-3495, DOI: 10.1016/j.bpj.2008.10.028. (http://www.sciencedirect.com/science/article/B94RW-4VGGB7R-D/2/bd642ea418c1213f10259b778907a1ee)
-. E. coli Statistics http://gchelpdesk.ualberta.ca/CCDB/cgi-bin/STAT_NEW.cgi
-. Julian W. T. Wimpenny. <i>CRC handbook of laboratory model systems for microbial ecosystems, Volume 2</i>. page 127. http://books.google.com/books?id=wy4WFX3_7bMC
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