Team:KULeuven/Model/Inverter

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Revision as of 08:28, 12 September 2008

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Pictogram inverter.png

Contents

Invertimer

Position in the system

The invertimer subsystem receives its input from the filter, T7. The invertimer's function is to produce HSL when no input is present, so a low T7 input gives rise to a high HSL output and vice versa. The production of HSL means that the cell will start a timer that eventually will be used in the celldeath-subsystem to produce ccdB. In this way the cell will die off if no desease remains present.

Describing the system

see also: Project:Invertimer

Inverter BioBrick.jpg

ODE's

Parameters

Parameter values (Inverter)
Name Value Comments Reference
Degradation Rates
dLuxI dLVA = 2.814E-4 s-1 LVA-tag reduces lifetime to 40 minutes [2] [7]
dRNA_LuxI 0.0025 s-1 [5]
dLuxI_antimRNA 0.0045303737 s-1 estimate: because this RNA isn't translated, it degrades faster [5]
dLacI dLVA = 2.814E-4 s-1 LVA-tag reduces lifetime to 40 minutes [2] [7]
dclosed mRNA LacI 0.0046209812 s-1 estimate: because this mRNA isn't translated, it degrades faster [5]
dopen mRNA LacI 0.0023104906 s-1 [5]
dopen mRNA LacI complex 0.0023104906 s-1 [5]
dHSL 1.02E-6 s-1 very stable in the medium, lifetime around 185h [11]
LuxI catalysis
kcat 0.0166666667 s-1 Estimated to be about 90% of Vmax in LB medium. [4]
T7 Transcription
KT7 421 dissociation constant, recalculated to remove units [10]
kmax 0.044 s-1 maximal T7 transcription rate [10]
Key-Lock constants
Keq 1 0,015 [M] between closed and open T7 mRNA, modeled for competition, experimental [2]
Keq 2 0.0212 [M] between closed T7 mRNA and key unlocked mRNA complex, modeled for competition, experimental [2]
kdis2 0.00416 s-1 derived from experimental values [2]
kcomplex2 0.00237 s-1 derived from experimental values [2]
kclosed 500 s-1 derived from experimental values [2]
kopen 7.5 s-1 derived from experimental values [2]
LacI repression
KLacI 1.0E-10 M-1 Dissociation constant [3]
nLacI 2.0 Hill coefficient for LacI [3]
k_trans_LacI 0.0025 s-1 Estimated maximal transcription rate from R0011 [9]
Antisense LuxI
k_complex3 0.00237 s-1 rate constant for formation of asRNA - LuxI mRNA duplex [3]
KmRNA_LuxI:antisense_mRNA 4.22E14 Complex of LuxI mRNA with antisense mRNA [1]
Translation Rates
ktransl LuxI 0.167 s-1 translation rate for B0032 RBS (0.3 relative efficiency) [8]
ktransl LacI 0.167 s-1 estimate: lock defined translation rate for LacI [2]

Models

CellDesigner (SBML file)

Inverter

Matlab (SBML file)

Inverter

Simulations

Time span Input (TetR) Results
A 0.0125 s-1 The amount LacI increases from state zero to state one because both mRNA_RIBOKEY and pT7_tag are present. This results in a repression of LuxI which decreases to zero: the input signal (TetR) is inverted.
B 5E-5 s-1 The amount LacI decreases back to state zero. The amount LuxI remains the same (state zero).
C 5E-5 s-1 LuxI changes from state zero to state one. Time span B and C form together the transient behaviour of the inverter when the input signal changes from one to zero.
D 5E-5 s-1 LuxI remains in state one: the input signal is once again inverted.
E 0.0125 s-1 A short pulse of 1000 seconds has a influence a steep decrease of LuxI.
F & G 5E-5 s-1 During time span F and G, LuxI decreases further for a while and increases back to state one.
H 5E-5 s-1 LuxI is back in state one.

The simulation shows a working inverter (left figure). A small disadvantage is the transient behaviour of the inverter: a small pulse of 1000 seconds results in a transient behaviour of +- 30000 seconds. Also for a long pulse (10000 seconds) is a long transient behaviour noticeable (40000 seconds). The effect of the inverter on the timer aspect is visuable in the right figure: a long pulse ( from 10000 till 11000) resets the timer (HSL drecreases till zero). After this pulse and the transient behaviour of the inverter, the timer restarts counting. The short pulse (from 200000 till 201000 seconds) only partially resets the timer.

References

Bibliography

[1]A. E G H Wagner and R W Simons, “Antisense RNA Control in Bacteria, Phages, and Plasmids,” Nov. 2003; http://arjournals.annualreviews.org/doi/abs/10.1146/annurev.mi.48.100194.003433.
 
[2]“Berkeley2006-RiboregulatorsMain - IGEM”; http://parts2.mit.edu/wiki/index.php/Berkeley2006-RiboregulatorsMain.
 
[3]“ETHZ/Parameters - IGEM07”; http://parts.mit.edu/igem07/index.php/ETHZ/Parameters.
 
[4]“Generation of cell-to-cell signals in quorum sensing: acyl homoserine lactone synthase activity of a purified Vibrio fischeri LuxI protein,” Sep. 1996; http://www.pnas.org/content/93/18/9505.
 
[5]J.A. Bernstein et al., “Global analysis of mRNA decay and abundance in Escherichia coli at single-gene resolution using two-color fluorescent DNA microarrays,” Proceedings of the National Academy of Sciences of the United States of America, vol. 99, Jul. 2002, pp. 9697–9702.
 
[6]W. Hsieh et al., “Influence of sequence and distance between two operators on interaction with the lac repressor,” J. Biol. Chem., vol. 262, Oct. 1987, pp. 14583-14591.
 
[7]J.B. Andersen et al., “New Unstable Variants of Green Fluorescent Protein for Studies of Transient Gene Expression in Bacteria,” Applied and Environmental Microbiology, vol. 64, Jun. 1998, pp. 2240–2246.
 
[8]“Part:BBa B0032 - partsregistry.org”; http://partsregistry.org/Part:BBa_B0032.
 
[9]“Part:BBa R0011 - partsregistry.org”; http://partsregistry.org/Part:BBa_R0011.
 
[10]G.M. Skinner et al., “Promoter Binding, Initiation, and Elongation By Bacteriophage T7 RNA Polymerase: A SINGLE-MOLECULE VIEW OF THE TRANSCRIPTION CYCLE,” J. Biol. Chem., vol. 279, Jan. 2004, pp. 3239-3244.
 
[11]Y. Wang and J.R. Leadbetter, “Rapid Acyl-Homoserine Lactone Quorum Signal Biodegradation in Diverse Soils,” Appl. Environ. Microbiol., vol. 71, Mar. 2005, pp. 1291-1299.