Team:Paris Saclay/Modeling/FNR

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[[Team:Paris_Saclay/Project|Overview]]
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[[Team:Paris_Saclay/PSPCR|PSPCR]]
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[[Team:Paris_Saclay/PS-PCR|PS-PCR]]
[[Team:Paris_Saclay/Achievements|Achievements]]
[[Team:Paris_Saclay/Achievements|Achievements]]
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<p>As we use Hsim for the modeling, if you want to dig in our model we suggest you to read [https://www.lri.fr/~pa/Hsim/ this page] written by Mr. Patrick Amar the developer of Hsim.</p>
+
<p>As we use Hsim for the modeling, a multi-agents programme developped at our university in order to follow the assembly, movements and dissociation of a large number of molecules in a virtual cell. It replaces the Ordinary Differential Equations and mimics chemical reactions of the real system by rewriting specials rules. If you want to dig in our model we suggest you to read [https://www.lri.fr/~pa/Hsim/ this page], written by Mr. Patrick Amar who is the developer of Hsim. .</p>
-
<p>Roughly speaking, we define a sampling volume, size in nanometer and we declare some molecules with their sizes, their moving speed and their number. Once the simulation starts, those molecules move randomly in the space and trigger some possible reaction between them with some probabilities. There is always somehow deviation from the reality, but we are all excited about this particular simulating modeling.</p>
+
<p>Roughly speaking, in our model we define a sampling volume, size in nanometer and we declare some molecules with their sizes, their moving speed and their number. Once the simulation starts, those molecules move randomly in the space and trigger some possible reaction between them with some probabilities. There is always somehow deviation from the reality, but we are all excited about this particular simulating modeling.</p>
-
<p>We represent our FNR regulator model to you by 3 steps. We have chosen HSIM, a multi-agents programme developped at our university in order to follow the assembly, movements and dissociation of a large number of molecules in a virtual cell. HSIM replaces the Ordinary Differential Equations and mimics chemical reactions of the real system by rewriting rules. Following our modeling process, we provided the list of molecules, the rewriting rules, and the initial values of each molecule quantity in a configuration file to HSIM. We also have developed a web version of Hsim which allows user change and test the system parameters.</p>
+
<p>We construct our FNR regulator model by 3 steps.At first, We extract the biological information, draw some schemes for helping us to understand the biological. Then we translate those biological concept into specials equations or pseudo code of Hsim. Finally, we write the Hsim code and run it in different scenarios for the test. We also have developed a web similator which allows user change and test our model with their own parameter.</p>
=='''Translate biological knowledges into functional scheme'''==
=='''Translate biological knowledges into functional scheme'''==
-
[[File:PSFNRcycle.jpg|800px]]<p>This scheme from the Dean A.Tolla and Michael A.Savageauthe's paper shows clearly the FNR transformation cycle. After the fnr mRNA translation, apoFNR is produced and a dimerization of 2 apoFNR catalyzed by ClpXP forme create the 4Fe-FNR. The 4Fe-FNR can be oxidized by oxygen to 2Fe-FNR then to apoFNR. 2Fe-FNR plus ClpXP can generate 4Fe-FNR. And all 3 FNR derivatives sustain a degradation effect. Those proteins will dissimilate in a while.</p>
+
<div>[[File:PSFNRcycle.jpg|500px|thumb|<center> Tolla and Savageau Regulation of Aerobic to Anaerobic Transitions by the FNR cycle in Escherichia coli</center>]]<br></div>
 +
 
 +
<p>This scheme from the Dean A.Tolla and Michael A.Savageauthe's paper shows clearly the FNR transformation cycle. After the fnr translation, apoFNR(inactive) is produced. And the dimerization of 2 apoFNR which id catalyzed by ClpXP create the active 4Fe-FNR. The 4Fe-FNR can be oxidized by oxygen to 2Fe-FNR then reduce to apoFNR with another oxygen. 2Fe-FNR plus ClpXP can also generate 4Fe-FNR. So there is a cycle for this 3 FNR derivatives. All proteins sustain a degradation effect. Of cause, if there are too mang active FNR (4Fe-FNR), those active FNR will suppress the translating of fnr.</p>
<br>
<br>
-
<p>If we combine the FNR cycle and color reporter system :</p>
+
<br>
-
[[File:PSFNRmodel.jpg|800px|alt Claire]]<p>The FNR behave differently for aerobic and anaerobic condition. In the case that oxygen is absent, a pair of 4Fe-FNR fix on the reporter DNA sequence and the green reporter gene is expressed so we will see the blue color for those colonies. But a group of 4 4Fe-FNR comes to fix at red reporter’s gene and prevents the expression of red color. If oxygen is sufficient, FNR derivatives keep in inactive form, the red reporter’s gene continue to produce the red color.</p>
+
<br>
 +
<p>Now we combine the FNR cycle and the color reporter system together:</p>
 +
[[File:PSFNRmodel.jpg|800px|alt Claire]]<p>The FNR behave differently in aerobic and anaerobic condition. In the case that oxygen is absent, a pair of 4Fe-FNR fix on the green reporter DNA sequence and the green reporter gene is expressed, so we will observe this color for sample colonies. However a group of 4 4Fe-FNR comes to fix at red reporter gene and prevents the expression of red reporter protein. If oxygen is sufficient, so in aerobic condition, FNR derivatives keep in inactive form, there is no fixing of FNR on mRNA. The red reporter protein always produces the red protein but production of green reporter protein ceases.</p>
=='''Transcribe functional description into equation system'''==
=='''Transcribe functional description into equation system'''==
-
<br>
+
<p>We transcribe biological informations into chemical reaction by simpliying the system which means that we chose to ignore some molecules(especially the enzymes) and focus on the IN and OUT of the system.</p>
==Summary for equations:==
==Summary for equations:==
<p>
<p>
-
*translation of Pfnr gene into FNR protein (FNR without Fe)
+
*Translation of fnr gene into FNR protein (FNR without Fe)
-
*dimerisation of 4Fe-FNR (action of Ise protein)
+
*Dimerisation of apoFNR (action of Ise protein)
-
*oxydation: in aerobic conditions, oxygen inactivates FNR but cell continues to reactivate it (action of Ise protein)
+
*Oxydation: in aerobic conditions, oxygen inactivates FNR but cell continues to reactivate it (action of Ise protein)
-
degradation of each kind of FNR (FNR without Fe, FNR activated, and FRN inactivated), a green protein, and a red protein (action of ClpXP
+
*Degradation of each kind of FNR (FNR without Fe, FNR activated, and FRN inactivated), green and red proteins (action of ClpXP
protein)
protein)
-
*activation/inactivation of a gene under a repressor promotor (green) and production or not of the cognate protein
+
*Activation/inactivation of a gene under a repressor promotor (green) and production or not of the cognate protein
-
*activation/inactivation of a gene under an activator promotor (red) and production or not of the cognate protein
+
*Activation/inactivation of a gene under an activator promotor (red) and production or not of the cognate protein
</p>
</p>
 +
==Details==
==Details==
<br>
<br>
 +
<blockquote>
*Translating fnr to FNR  
*Translating fnr to FNR  
-
: fnr mRNA generates steadily apoFNR(inactived).
+
: fnr mRNA generates steadily apoFNR(inactive)
::''fnr -> fnr + apoFNR ''
::''fnr -> fnr + apoFNR ''
<br>
<br>
*Dimerization of apoFNR
*Dimerization of apoFNR
-
:2 apoFNRs form 4Fe-FNR(activated) with catalyzer Ise.
+
:2 apoFNRs form active 4Fe-FNR(QFeFNRa) with catalyzer Ise.
-
::''{apoFNR}apoFNR + Ise -> QFeFNRa + Ise''
+
::''apoFNR + apoFNR + Ise -> QFeFNRa + Ise''
<br>
<br>
-
*Oxidation, from 4Fe-FNR to apoFNR(inactivated)
+
*Oxidation, from 4Fe-FNR to apoFNR(inactive)
-
: Aerobically, oxygen inactivates FNR, from 4Fe-FNR to 2Fe-FNR(inactivated)
+
: In aerobical condition, oxygen inactivates FNR, 4Fe-FNR generates to 2 inactive Fe-FNR(DFeFNRi)
::''QFeFNRa + o2 -> DFeFNRi +o2 ''
::''QFeFNRa + o2 -> DFeFNRi +o2 ''
-
:Then, oxidize from 2Fe-FNR to apoFNR
+
: Then oxidize FNR from 2Fe-FNR to apoFNR
::''DFeFNRi + o2 -> apoFNR +o2 ''
::''DFeFNRi + o2 -> apoFNR +o2 ''
-
:2Fe-FNR can be reactivate by Ise  
+
: 2Fe-FNR can be reactivate by Ise  
-
::''DFeFNRi + Ise -> QFeFNRa + Ise''
+
::''DFeFNRi + DFeFNRi + Ise -> QFeFNRa + Ise''
<br>
<br>
*Degradation FNR
*Degradation FNR
Line 75: Line 81:
::''QFeFNRa + ClpXP -> ClpXP''
::''QFeFNRa + ClpXP -> ClpXP''
<br>
<br>
-
*Activation/inactivation of green gene
+
*Activation/inactivation of green reporter gene
-
: Association between 4Fe-FNR(activated) and green protein gene
+
: Association between 2 4Fe-FNR(active) and green reporter protein gene
-
::''QFeFNRa + GPV -> QFeFNRa_GPV_binded''
+
::''QFeFNRa + QFeFNRa + green_reporter_protein_gene -> DQFeFNRa_green_binded''
-
: Dissociation between 4Fe-FNR(activated) and green protein gene
+
: Dissociation between 4Fe-FNR(active) and green reporter protein gene
-
::''QFeFNRa_GPV_binded -> QFeFNRa + GPV ''
+
::''DQFeFNRa_green_binded -> QFeFNRa + QFeFNRa + green_reporter_protein_gene ''
-
::''QFeFNRa_GPV_binded -> PV + QFeFNRa_GPV_binded''
+
: Production of green reporter protein
 +
::''DQFeFNRa_green_binded -> green_reporter_protein + DQFeFNRa_green_binded''
<br>
<br>
-
*Green protein degradation :catalyzed by ClpXP
+
*Green protein degradation  
-
::''PV + ClpXP -> ClpXP ''
+
::''green_reporter_protein + proteinase1 -> proteinase1 ''
<br>
<br>
-
*Repression of red protein gene : Association between 4Fe-FNR(activated) and red protein gene
+
*Repression of red protein gene : Association between 4Fe-FNR(active) and red reporter protein gene
-
::''QFeFNRa + GPR -> QFeFNRa_GPR_binded''
+
::''QFeFNRa + QFeFNRa + red_reporter_pretein_gene -> DQFeFNRa_red_binded''
-
: Dissociation between 4Fe-FNR(activated) and red protein gene
+
: Dissociation between 4Fe-FNR(active) and red protein reporter gene
-
::''QFeFNRa_GPR_binded -> QFeFNRa + GPR ''
+
::''DQFeFNRa_red_binded -> QFeFNRa + QFeFNRa + red_reporter_pretein_gene ''
-
:Association of 4 4Fe-FNR(activated)
+
:Association of 4 4Fe-FNR(active) binded, prevent the production of red reporter protein
-
::''{QFeFNRa_GPR_binded}QFeFNRa_GPR_binded -> rep ''
+
::''DQFeFNRa_red_binded + DQFeFNRa_red_binded -> repression_red ''
-
:Dissociation of 4 4Fe-FNR(activated)
+
:Dissociation of 4 4Fe-FNR(active)
-
::''rep -> QFeFNRa_GPR_binded + QFeFNRa_GPR_binded ''
+
::''repression_red -> DQFeFNRa_red_binded + DQFeFNRa_red_binded ''
<br>  
<br>  
*Expression the red gene in aerobic condition
*Expression the red gene in aerobic condition
: Production of red protein without repression
: Production of red protein without repression
-
::''GPR -> GPR + PR [probability]''
+
::''DQFeFNRa_red_binded -> DQFeFNRa_red_binded + red_reporter_protein ''
-
::''QFeFNRa_GPR_binded -> QFeFNRa_GPR_binded + PR ''
+
<br>  
<br>  
*Degradation of red protein
*Degradation of red protein
-
::''PR + ClpXP -> ClpXP ''
+
::''red_reporter_protein + proteinase2 -> proteinase2 ''
<br>
<br>
 +
</blockquote>
 +
=='''Transcribe equations to Hsim code'''==
-
<p>Here you will find our configuration files to launch HSIM: [https://2013.igem.org/Team:Paris_Saclay/simulation#simulation.hsim links].</p>
+
<p>Thanks to the equations that we wrote, we have all the informations needed for Hsim. In the Hsim code, we simplify some equations by deleting some objets, Ise for example. Because Hsim has some limit for maximum element number in one rule, we have to declare some new objets such like FNRa_binded,FNRa_binded_green_protein. In the case that we want change speed of degradation, we give 3 different names for different proteinase.</p>
-
==''Scenarios and results''==
+
<p>You can check our source code [https://2013.igem.org/Team:Paris_Saclay/Modeling/FNR/hsimcode here]</p>
-
<p>Here we prepared 3 scenarios in order to testing our model. Each of them represent  one specific condition which can accord with our experiments. In the beginning of each scenario, we let our system run in the distribution mode for few generation, so molecules will spread homogeneously in the virtual bacterium.</p>
+
==''Set of parameters''==
-
:*I. Degradation of red reporter protein
+
<p>In our model Hsim, Kinect of reaction is represented by probability of rules (probability that the reaction takes place). Those probability is the result of a ratio between the Km of 2 side of chemical equilibrium equation, however in our model there are lots of no reversal reaction, we have some trouble to deal with them, for e.g. the dimensions of some units. But somehow we can peep some reality, the article of Dean A.Tolla and Michael A.Savageau show us some relation among their system. For example, we can estimate which reaction is faster than others: the Kinect of oxidation for active FNR is much quick than dimerization of 2 inactive FNR. So what we did for those probability is a large amount of test.</p>
 +
<p>We had some difficults in the beginning, the model did not accord with our estimation. However, we figured out at last some reliable combination of paremeters. And we have chosen one for our testing scenarios.</p>
 +
<p>You can check our paremeters setting [https://2013.igem.org/Team:Paris_Saclay/simulation#simulation.hsim here] in source code of second scenario.</p>
-
<p>In this first scenario, we have a situation that the system has been in a anaerobic condition for a while, there is already some of red protein molecules. What we wish to see is a decline of red protein from initial value to 0, and it is what we observed in our model. There is also a latency due to the time needed for the formation of binding FNR molecules. The synthesize of green protein begins before oxygen running out.</p>
+
=='''Scenarios and results'''==
-
[[]]
+
<p>Here we prepared 3 scenarios in order to testing our model. Each of them represent one specific condition which could happen in our experiments. The first scenario is about the degradation of red reporter protein in aerobic condition. In the second scenario, the model submit to aerobic then anaerobic condition.  The last one is a rare situation, we want to see how our model acts.</p>
 +
<p>In the beginning of each scenario, we let our system run in the distribution mode for few generation, the molecules will spread homogeneously in the virtual bacterium.</p>
-
:*II. Alternation of reporter protein
+
<br>
 +
:* Degradation of red reporter protein
 +
<br>
 +
<p>In this first scenario, we have a situation that the system has been in a anaerobic condition for a while, there is already some of red protein molecules. What we wish to see is a decline of red protein from initial value to 0, and it is what we observed in our model. There is also a latency due to the time needed for the formation of binding FNR molecules. The synthesis of green protein begins before oxygen running out.</p>
 +
<br>
 +
[[File:PSscenario1.gif|center]]
 +
<br>
 +
<p>The red and green sphere represent respectively the red reporter protein and green reporter protein. 4 FNRa combine with 2 red reporter protein gene and form those large pink spheres. In our configuration, those combination is stable, once created, it is relatively hard to dissimilate them. This characteristic help the system represse the production of red reporter protein in anaerobic condition. </p>
-
<p>In this scenario, we changed the nature of oxygen from “metabolite” to “molecule” which means the quantity of oxygen in our system is no more constant, and distribution of oxygen become heterogeneous. We begin with 5000 molecules of oxygen, and 0 reporter protein. The red reporter protein is synthesized immediately. Oxygen is used to oxidant the FNR active to inactive state, however, when all oxygen is consumed, FNR n-mer begin to synthesize green protein and prevent red one. So we observe a exchange of curve position in the scheme. This scenario reveal the result of our experiments.</p>
 
-
[[]]
 
-
:*III. Weird situation test
+
:* Alternation of reporter protein
 +
<br>
 +
<p>In this scenario, we changed the nature of oxygen from “metabolite” to “molecule” which means the quantity of oxygen in our system is no more constant, and distribution of oxygen become heterogeneous. We begin with 5000 molecules of oxygen, and 0 reporter protein. The red reporter protein is synthesized immediately. Oxygen is used to oxidant the FNR active to inactive state, however, when all oxygen is consumed, FNR n-mer begin to synthesize green protein and prevent red one. So we observe a change of dominance in the scheme. This scenario reveals a part of result in our experiments.</p>
 +
 
 +
[[File:PSscenario2.gif]]
 +
 
 +
 
 +
<p>Here you can find our configuration files for HSIM: [https://2013.igem.org/Team:Paris_Saclay/simulation#simulation.hsim link].</p>
-
<p>This scenario is a little bizarre, we set the presence of oxygen and a lot of green reporter at the same time. Our purpose is to test our model in some weird conditions, try to find some bug when the model reach its limit. And as we can see, after a period of latency, the system has found its way back to the normal situation.</p>
 
 +
:* Green reporter protein in aerobic condition
-
[[]]
+
<p>This scenario is a little bizarre, we set at the presence of oxygen, there is still a lot of green reporter in the system. What will happen? It is not quite explicit. So how about a simulation, we amused ourtheves by testing some weird values. We try to find its limit.</p>
 +
[[File:PSscenario3.gif]]
 +
<p>And as we can see, after a period of latency, the system has at first systhesized red reporter protein, the number of green reporter protein goes down. But after the system consume all its oxygen, the red reporter protein begin to re dominate the cell.</p>
==''Online simulation''==
==''Online simulation''==
 +
 +
We used our homegrown wiki-integrated [https://2013.igem.org/Team:Paris_Saclay/Modeling/Simulator#Wiki-integrated_simulator simulator] to provide an interactive way of seeing our model in action.
=== Simple simulation ===
=== Simple simulation ===
 +
 +
The first simulation presented here uses the following simplified model :
 +
<blockquote>
 +
*Effective inactivation of FNR by oxydation
 +
:''FNR + O2 -> FNR_ox ''
 +
*Effective reactivation of FNR by reduction
 +
:''FNR_ox -> FNR + O2 ''
 +
<br>
 +
*Active FNR binds to the Pfnr activator
 +
::''FNR + Pfnr_activator -> Pfnr_activator_bond''
 +
*FNR detaches from the Pfnr activator
 +
::''Pfnr_activator_bond -> FNR + Pfnr_activator''
 +
*A green reporter protein (PV) is expressed when active FNR is bound to Pfnr_activator, so when the oxygen level is low.
 +
::''Pfnr_activator_bond -> Pfnr_activator_bond + PV''
 +
<br>
 +
*Active FNR binds to the Pfnr repressor
 +
::''FNR + Pfnr_repressor -> Pfnr_repressor_bond''
 +
*FNR detaches from the Pfnr repressor
 +
::''Pfnr_repressor_bond -> FNR + Pfnr_repressor''
 +
*A red reporter protein (PV) is expressed when '''no''' active FNR is bound to Pfnr_repressor, so when the oxygen level is high.
 +
::''Pfnr_repressor -> Pfnr_repressor + PR''
 +
</blockquote>
 +
 +
Now you just have to choose an oxygen level and push START in the simulator below.
{{Team:Paris_Saclay/simbox|load=modeling/fnr0.xml}}
{{Team:Paris_Saclay/simbox|load=modeling/fnr0.xml}}
 +
Get the [https://2013.igem.org/Team:Paris_Saclay/modeling/fnr0.xml?action=raw&ctype=text/css configuration file]
=== Complex simulation ===
=== Complex simulation ===
 +
 +
A more complete simulation is presented here, which takes into account the detail of the FNR oxydation and dimerization processes.
 +
 +
FNR is the quantity of FNR monomers.
 +
DFNRa represents the quantity of non-oxydated FNR dimers.
{{Team:Paris_Saclay/simbox|load=modeling/fnr1.xml}}
{{Team:Paris_Saclay/simbox|load=modeling/fnr1.xml}}
 +
 +
Get the [https://2013.igem.org/Team:Paris_Saclay/modeling/fnr1.xml?action=raw&ctype=text/css configuration file]
=='''Conclusion'''==
=='''Conclusion'''==
-
<p>Our model reveal successfully the different states of FNR regulation. As you can see, in a anaerobic condition, the number of FNR active is significantly raised, so do the number of green reporter protein. In aerobic condition, because of the presence of oxygen, FNR inactive dominates in the model, the production of green ceases so the number of green protein drops, at the same time the repression for the red reporter disappear so production of red protein restart.</p>
+
<p>Our model successfully revealed the different states of FNR regulation. As you can see, in a anaerobic condition, the number of FNR active is significantly raised, so do the number of green reporter protein. In aerobic condition, because of the presence of oxygen, FNR inactive dominates in the model, the production of green protein ceases so the number of green protein drops, at the same time the repression for the red reporter disappear leading to the restart of the red protein production.</p>
 +
<p>Back to our wet experiments, we used LacZ (blue color BBa_K11550007) and AmilCP (pink color BBa_K11550003) as 2 independent expression reporters which correspond to green reporter protein in our model. The results of modeling for green reporter protein conform to our experiments (PS: green reporter protein in our model correspond to LacZ and AmilCP, there is a deviation). And we had not perform the red reporters protein in the wet experiments.</p>
 +
==''Reference''==
 +
*Wenmao Meng, Jeffrey Green and John R.Guest FNR-dependent repression of ndh gene expression requires two upstream FNR-binding sites Microbiology (1997), 143, 1521-1532
 +
*Parick Amar, Gilles Bernot, Victor Norris HSIM: a simulation programme to study large assemblies of proteins
 +
Article written by Zhou and Damir
{{Team:Paris_Saclay/incl_fin}}
{{Team:Paris_Saclay/incl_fin}}

Latest revision as of 02:25, 5 October 2013

Contents

FNR oxygen sensor system

As we use Hsim for the modeling, a multi-agents programme developped at our university in order to follow the assembly, movements and dissociation of a large number of molecules in a virtual cell. It replaces the Ordinary Differential Equations and mimics chemical reactions of the real system by rewriting specials rules. If you want to dig in our model we suggest you to read this page, written by Mr. Patrick Amar who is the developer of Hsim. .

Roughly speaking, in our model we define a sampling volume, size in nanometer and we declare some molecules with their sizes, their moving speed and their number. Once the simulation starts, those molecules move randomly in the space and trigger some possible reaction between them with some probabilities. There is always somehow deviation from the reality, but we are all excited about this particular simulating modeling.

We construct our FNR regulator model by 3 steps.At first, We extract the biological information, draw some schemes for helping us to understand the biological. Then we translate those biological concept into specials equations or pseudo code of Hsim. Finally, we write the Hsim code and run it in different scenarios for the test. We also have developed a web similator which allows user change and test our model with their own parameter.


Translate biological knowledges into functional scheme

Tolla and Savageau Regulation of Aerobic to Anaerobic Transitions by the FNR cycle in Escherichia coli

This scheme from the Dean A.Tolla and Michael A.Savageauthe's paper shows clearly the FNR transformation cycle. After the fnr translation, apoFNR(inactive) is produced. And the dimerization of 2 apoFNR which id catalyzed by ClpXP create the active 4Fe-FNR. The 4Fe-FNR can be oxidized by oxygen to 2Fe-FNR then reduce to apoFNR with another oxygen. 2Fe-FNR plus ClpXP can also generate 4Fe-FNR. So there is a cycle for this 3 FNR derivatives. All proteins sustain a degradation effect. Of cause, if there are too mang active FNR (4Fe-FNR), those active FNR will suppress the translating of fnr.




Now we combine the FNR cycle and the color reporter system together:

alt Claire

The FNR behave differently in aerobic and anaerobic condition. In the case that oxygen is absent, a pair of 4Fe-FNR fix on the green reporter DNA sequence and the green reporter gene is expressed, so we will observe this color for sample colonies. However a group of 4 4Fe-FNR comes to fix at red reporter gene and prevents the expression of red reporter protein. If oxygen is sufficient, so in aerobic condition, FNR derivatives keep in inactive form, there is no fixing of FNR on mRNA. The red reporter protein always produces the red protein but production of green reporter protein ceases.

Transcribe functional description into equation system

We transcribe biological informations into chemical reaction by simpliying the system which means that we chose to ignore some molecules(especially the enzymes) and focus on the IN and OUT of the system.

Summary for equations:

  • Translation of fnr gene into FNR protein (FNR without Fe)
  • Dimerisation of apoFNR (action of Ise protein)
  • Oxydation: in aerobic conditions, oxygen inactivates FNR but cell continues to reactivate it (action of Ise protein)
  • Degradation of each kind of FNR (FNR without Fe, FNR activated, and FRN inactivated), green and red proteins (action of ClpXP
protein)
  • Activation/inactivation of a gene under a repressor promotor (green) and production or not of the cognate protein
  • Activation/inactivation of a gene under an activator promotor (red) and production or not of the cognate protein

Details


  • Translating fnr to FNR
fnr mRNA generates steadily apoFNR(inactive)
fnr -> fnr + apoFNR

  • Dimerization of apoFNR
2 apoFNRs form active 4Fe-FNR(QFeFNRa) with catalyzer Ise.
apoFNR + apoFNR + Ise -> QFeFNRa + Ise

  • Oxidation, from 4Fe-FNR to apoFNR(inactive)
In aerobical condition, oxygen inactivates FNR, 4Fe-FNR generates to 2 inactive Fe-FNR(DFeFNRi)
QFeFNRa + o2 -> DFeFNRi +o2
Then oxidize FNR from 2Fe-FNR to apoFNR
DFeFNRi + o2 -> apoFNR +o2
2Fe-FNR can be reactivate by Ise
DFeFNRi + DFeFNRi + Ise -> QFeFNRa + Ise

  • Degradation FNR
Protein FNR and its derivation submit a steady degrading rate
apoFNR + ClpXP -> ClpXP
DFeFNRi + ClpXP -> ClpXP
QFeFNRa + ClpXP -> ClpXP

  • Activation/inactivation of green reporter gene
Association between 2 4Fe-FNR(active) and green reporter protein gene
QFeFNRa + QFeFNRa + green_reporter_protein_gene -> DQFeFNRa_green_binded
Dissociation between 4Fe-FNR(active) and green reporter protein gene
DQFeFNRa_green_binded -> QFeFNRa + QFeFNRa + green_reporter_protein_gene
Production of green reporter protein
DQFeFNRa_green_binded -> green_reporter_protein + DQFeFNRa_green_binded

  • Green protein degradation
green_reporter_protein + proteinase1 -> proteinase1

  • Repression of red protein gene : Association between 4Fe-FNR(active) and red reporter protein gene
QFeFNRa + QFeFNRa + red_reporter_pretein_gene -> DQFeFNRa_red_binded
Dissociation between 4Fe-FNR(active) and red protein reporter gene
DQFeFNRa_red_binded -> QFeFNRa + QFeFNRa + red_reporter_pretein_gene
Association of 4 4Fe-FNR(active) binded, prevent the production of red reporter protein
DQFeFNRa_red_binded + DQFeFNRa_red_binded -> repression_red
Dissociation of 4 4Fe-FNR(active)
repression_red -> DQFeFNRa_red_binded + DQFeFNRa_red_binded

  • Expression the red gene in aerobic condition
Production of red protein without repression
DQFeFNRa_red_binded -> DQFeFNRa_red_binded + red_reporter_protein

  • Degradation of red protein
red_reporter_protein + proteinase2 -> proteinase2

Transcribe equations to Hsim code

Thanks to the equations that we wrote, we have all the informations needed for Hsim. In the Hsim code, we simplify some equations by deleting some objets, Ise for example. Because Hsim has some limit for maximum element number in one rule, we have to declare some new objets such like FNRa_binded,FNRa_binded_green_protein. In the case that we want change speed of degradation, we give 3 different names for different proteinase.

You can check our source code here

Set of parameters

In our model Hsim, Kinect of reaction is represented by probability of rules (probability that the reaction takes place). Those probability is the result of a ratio between the Km of 2 side of chemical equilibrium equation, however in our model there are lots of no reversal reaction, we have some trouble to deal with them, for e.g. the dimensions of some units. But somehow we can peep some reality, the article of Dean A.Tolla and Michael A.Savageau show us some relation among their system. For example, we can estimate which reaction is faster than others: the Kinect of oxidation for active FNR is much quick than dimerization of 2 inactive FNR. So what we did for those probability is a large amount of test.

We had some difficults in the beginning, the model did not accord with our estimation. However, we figured out at last some reliable combination of paremeters. And we have chosen one for our testing scenarios.

You can check our paremeters setting here in source code of second scenario.

Scenarios and results

Here we prepared 3 scenarios in order to testing our model. Each of them represent one specific condition which could happen in our experiments. The first scenario is about the degradation of red reporter protein in aerobic condition. In the second scenario, the model submit to aerobic then anaerobic condition. The last one is a rare situation, we want to see how our model acts.

In the beginning of each scenario, we let our system run in the distribution mode for few generation, the molecules will spread homogeneously in the virtual bacterium.


  • Degradation of red reporter protein


In this first scenario, we have a situation that the system has been in a anaerobic condition for a while, there is already some of red protein molecules. What we wish to see is a decline of red protein from initial value to 0, and it is what we observed in our model. There is also a latency due to the time needed for the formation of binding FNR molecules. The synthesis of green protein begins before oxygen running out.



The red and green sphere represent respectively the red reporter protein and green reporter protein. 4 FNRa combine with 2 red reporter protein gene and form those large pink spheres. In our configuration, those combination is stable, once created, it is relatively hard to dissimilate them. This characteristic help the system represse the production of red reporter protein in anaerobic condition.


  • Alternation of reporter protein


In this scenario, we changed the nature of oxygen from “metabolite” to “molecule” which means the quantity of oxygen in our system is no more constant, and distribution of oxygen become heterogeneous. We begin with 5000 molecules of oxygen, and 0 reporter protein. The red reporter protein is synthesized immediately. Oxygen is used to oxidant the FNR active to inactive state, however, when all oxygen is consumed, FNR n-mer begin to synthesize green protein and prevent red one. So we observe a change of dominance in the scheme. This scenario reveals a part of result in our experiments.

File:PSscenario2.gif


Here you can find our configuration files for HSIM: link.


  • Green reporter protein in aerobic condition

This scenario is a little bizarre, we set at the presence of oxygen, there is still a lot of green reporter in the system. What will happen? It is not quite explicit. So how about a simulation, we amused ourtheves by testing some weird values. We try to find its limit.

File:PSscenario3.gif

And as we can see, after a period of latency, the system has at first systhesized red reporter protein, the number of green reporter protein goes down. But after the system consume all its oxygen, the red reporter protein begin to re dominate the cell.

Online simulation

We used our homegrown wiki-integrated simulator to provide an interactive way of seeing our model in action.

Simple simulation

The first simulation presented here uses the following simplified model :

  • Effective inactivation of FNR by oxydation
FNR + O2 -> FNR_ox
  • Effective reactivation of FNR by reduction
FNR_ox -> FNR + O2

  • Active FNR binds to the Pfnr activator
FNR + Pfnr_activator -> Pfnr_activator_bond
  • FNR detaches from the Pfnr activator
Pfnr_activator_bond -> FNR + Pfnr_activator
  • A green reporter protein (PV) is expressed when active FNR is bound to Pfnr_activator, so when the oxygen level is low.
Pfnr_activator_bond -> Pfnr_activator_bond + PV

  • Active FNR binds to the Pfnr repressor
FNR + Pfnr_repressor -> Pfnr_repressor_bond
  • FNR detaches from the Pfnr repressor
Pfnr_repressor_bond -> FNR + Pfnr_repressor
  • A red reporter protein (PV) is expressed when no active FNR is bound to Pfnr_repressor, so when the oxygen level is high.
Pfnr_repressor -> Pfnr_repressor + PR

Now you just have to choose an oxygen level and push START in the simulator below.

Loading simulation...
Get the configuration file

Complex simulation

A more complete simulation is presented here, which takes into account the detail of the FNR oxydation and dimerization processes.

FNR is the quantity of FNR monomers. DFNRa represents the quantity of non-oxydated FNR dimers.

Loading simulation...

Get the configuration file

Conclusion

Our model successfully revealed the different states of FNR regulation. As you can see, in a anaerobic condition, the number of FNR active is significantly raised, so do the number of green reporter protein. In aerobic condition, because of the presence of oxygen, FNR inactive dominates in the model, the production of green protein ceases so the number of green protein drops, at the same time the repression for the red reporter disappear leading to the restart of the red protein production.

Back to our wet experiments, we used LacZ (blue color BBa_K11550007) and AmilCP (pink color BBa_K11550003) as 2 independent expression reporters which correspond to green reporter protein in our model. The results of modeling for green reporter protein conform to our experiments (PS: green reporter protein in our model correspond to LacZ and AmilCP, there is a deviation). And we had not perform the red reporters protein in the wet experiments.

Reference

  • Wenmao Meng, Jeffrey Green and John R.Guest FNR-dependent repression of ndh gene expression requires two upstream FNR-binding sites Microbiology (1997), 143, 1521-1532
  • Parick Amar, Gilles Bernot, Victor Norris HSIM: a simulation programme to study large assemblies of proteins

Article written by Zhou and Damir