Difference between revisions of "Team:Toulouse/Modeling"

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<img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
 
<img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
<p class="legend">Butyric acid produced (mmol/L) depending on growth rate</p>
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<p class="legend">Figure 1: Butyric acid produced (mmol/L) depending on growth rate</p></center>
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The only enzyme present in <i>E.coli</i> involved in butyrate production is the Butyryl-coA transferase (Acetate-coA transferase <a href="http://www.brenda-enzymes.org/enzyme.php?ecno=2.8.3.8">[&#8599;]</a>)
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Given the absence of Butanoyl-Coa the reaction can't happen spontaneously in <i>E.coli</i>.
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Thus under the described conditions, our first object was to try to optimize butyrate production flux. As was said before, the support file of the stoichiometric model was modified in such a way as to add the lacking butyrate biosynthesis enzymes. This was done to have a model as close to our in vivo system as possible.
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If we set a minimal value for growth rate, butyrate production drops (Fig. 2), as it can be seen on the graph below obtained for different FBA simulations. We have tried different minimal growth rates up to 0.025 which is the maximal value obtained when the objective function under FBA simulation is biomass production.
 
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<img src="https://static.igem.org/mediawiki/2015/3/34/TLSE_Attract_fig9.png" style="width:100%;"/>  
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<center><img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
<p class="legend">Figure 4: Reaction catalyzed by Butyryl-coA transferase</p></center>  
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<p class="legend">Figure 2: Butyrate flux depending on minimal growth rate</p></center>
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Finally, to understand the effect of the initial glucose
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concentration on the maximum butyrate quantity we can expect,
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we tested different glucose concentrations between 0.4 and 15
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mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP> using FVA method (Flux Variability Analysis). Indeed, 0.4 mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP> corresponds to the glucose flux obtained with the Biosilta Kit for a culture time of 14 days, while 15 mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP> is the flux needed to reach maximum growth rate (same rates are applicable to formate).
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As expected, the higher the initial glucose concentration is, the higher the level of produced metabolites will be.
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<center><img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
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<p class="legend">Figure 3: Butyrate flux depending on growth rate</p></center>
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<div class="subtitle">
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<h3>B. FORMATE</h3>
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<p class="legend">Data not shown. FBA, objective function = biomass production, Result = 0.0268</p>
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<p align="justify" style="font-size:15px;"> After having worked on optimizing butyrate production,
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we proceeded to do the same with formate production.
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As before, maximal production implies no growth and predicts
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a flux value of 2,917 mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP(~ 0.006 mmol.L<SUP>-1</SUP>, Fig. 4).</p>
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<center><img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
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<p class="legend">Figure 4: Formic acid produced for different growth rate</p></center>
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As with butyrate, formate biosynthesis
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is unfavorably altered when a high level
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  of constraint is applied to the minimal
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  growth rate (Fig. 5). And formate production
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    will be more important when glucose availability is higher (Fig. 6).
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</p>
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<center><img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
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<p class="legend">Figure 5: Formate flux (mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP> depending on growth level</p></center>
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<center><img src="https://static.igem.org/mediawiki/2015/f/fb/TLSE_butyrate_graph.png" />
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<p class="legend">Figure 6: Formate flux (mmol.gDW<SUP>-1</SUP>.h<SUP>-1</SUP> depending on growth rate</p></center>
  
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Revision as of 11:45, 9 September 2015

iGEM Toulouse 2015

Modeling


Content


Metabolic networks

As said before, the aim of our project is to create a biological system able to produce two molecules: butyric acid and formic acid.
To achieve this, we need to modify the existing balance between the metabolic pathways present in E. Coli. Indeed, we want to optimize butyrate and formate productions in our bacterium by adjusting environmental conditions in order to obtain the desired concentrations of the associated acids.
The following metabolic network represents all of the known metabolites and metabolic pathways for Escherichia coli K12 MG1655 (best known model) as of today. It was obtained from the KEGG database. Our first step was to identify the pathways in which our molecules take part, in order to have a clear understanding of their role and effect.

Figure 1:Kegg Metabolic pathways - Escherichia coli K-12 MG1655

Formate network

Formate is naturally produced by E.coli but at a level that is quite low. Our project requires that Apicoli produces more. Hence we had to optimize its biosynthesis by studying the genes coding for the enzymes involved in the pathway. We decided to focus our efforts on the Pyruvate Formate Lyase (PFL), the enzyme that causes degradation of pyruvate, thus yielding formate.

Figure 2: Reaction catalyzed by PFL

The subnetwork presented below was obtained from MetExplore platform[2] and presents all reactions from the KEGG and ByoCyc databases involved in the production or consumption of formate. This map will help us predict the likely consequences of a PFL-induced formate overproduction in Apicoli. In fact, formate is harmful to our bacterium and is normally metabolized to other products. We thus have to find the balance between producing enough formate to kill the varroa without killing Apicoli.

Figure 3: Metabolic network of all reaction involving formate happening in E.coli

Butyrate network

Contrary to formate, butyrate is not naturally produced by E. Coli. E.coli possesses an enzyme called (Butyryl-coA transferase (or Acetate-coA transferase) that yields butyrate, but this reaction cannot happen spontaneously in the organism due to the lack of Butanoyl-coA, its substrate. Indeed, study of the biosynthesis pathway shows that the enzymes responsible for Butanoyl-coA production (EC.2.1.3.19 phosphate butyryltransferase , EC.1.3.1.44 trans-2-enoyl-CoA reductase (NAD+) , etc.) cannot be found in our strain. Hence, in order to obtain butyrate, we chose to introduce a complete production pathway relying on genes coming from different organisms in Apicoli (see Attract).

Flux Balance Analysis (FBA)

Presentation

To go further in the development of our project, we decided to use a method called Flux Balance Analysis (FBA) and Flux Variability Analysis (FVA). It is based on the model EC_iJO1366 [1]. This is the most recent model concerning E.coli K12 MG1655. It is a stoichiometric model defining all metabolic ways known to this day in this particular strain. It has been adapted to better suit our own bacterial system. Here you will find the associated XML file. The modifications we made are such that the described strain is now capable of producing butyrate.
Our modeling aims at determining the maximum butyrate and formate quantities our system would be able to produce, depending on two initial conditions: oxygen and glucose flux. We set them as follows:

  • Maximal oxygen entry flux: 5 mmol.gDW-1.h-1
  • Maximal glucose entry flux: 0.3998 mmol.gDW-1.h-1

It is interesting to note that FBA provides the produced and consumed metabolites in a quantitative way.
The setpoint for oxygen flux is rather low in order to simulate microaerobic conditions. The glucose flux setpoint was chosen according to the results of our tests with the Biosilta kit (see “Preliminary part”).
This kit was used to ensure a stable availability of glucose over time for our bacteria. Indeed the medium contains enzymes capable of catabolizing starch, thus gradually releasing glucose in the culture.
For known initial quantities of starch and enzymes, we are able to deduce the glucose release flux. Thus, we chose the appropriate enzyme concentration and polymer quantity in order to have a glucose rate of 0.3998 mmol.gDW-1.h-1.

The model provides results for the metabolites flux in mmol.gDW-1.h-1 but it is difficult to get an idea of the actual quantity this represents so we will convert it to mmol/L. To do this we chose a length of time of 13 hours for the day and 7 hours for the night, since our solution will primarily be deployed during summer. This means that butyric acid production time is estimated to 13 hours and formic acid production time to 7 hours.
Concerning biomass it is more complicated since the bacterium grows all the time. Thus in order to ensure a minimum production, biomass concentration (X) at the beginning is defined to X = 0.56 gDW.L-1.

$$ \textrm{Real unit} (mmol.L^{-1})= \textrm{Model unit} (mmol.gDW^{-1}\cdot h^{-1})\times X \times time $$

  • X: 0,56 gDW.L-1
  • time (formic acid): 13h
  • time butyric acid: 7h

Acid/Base Balance

Another parameter has to be taken into account, and this is the acid/base balance. Indeed, our bacteria will produce the base but we are actually interested in the acid concentration. The formula below is used:

$$pH = pKa + log\frac{C_b}{C_a}$$

  • pH: the medium used is buffered so for low acid concentrations pH = 7 is considered
  • pKa: 3,7 for formic acid and 4,81 for butyric acid
  • Cb: base concentration
  • Ca: acid concentration

Finally, it should not be forgotten that FBA methods rely on a stoichiometric model. This implies that some biological realities might be overlooked.
For example, it has been demonstrated that PFL (Pyruvate Formate Lyase), one of the enzymes involved in the production of formate, is inhibited in aerobic conditions [3], a fact that is not taken into account by the Flux Balance Analysis. This can result in the model predicting a higher formate production than what will actually be observed.

BUTYRATE

Thus under the described conditions, our first object was to try to optimize butyrate production flux. As was said before, the support file of the stoichiometric model was modified in such a way as to add the lacking butyrate biosynthesis enzymes. This was done to have a model as close to our in vivo system as possible.
As expected, when we optimize the objective function (butyrate production), it shows an optimum when all the carbon available is used for butyrate production, and none goes into biomass growth. So when there is no growth, butyrate production can be optimized and the corresponding flux level (i.e. maximum flux value) is 0.352 mmol.gDW-1.h-1 (~0.016 mmol.L-1, see Fig.1).

Figure 1: Butyric acid produced (mmol/L) depending on growth rate

Thus under the described conditions, our first object was to try to optimize butyrate production flux. As was said before, the support file of the stoichiometric model was modified in such a way as to add the lacking butyrate biosynthesis enzymes. This was done to have a model as close to our in vivo system as possible.
If we set a minimal value for growth rate, butyrate production drops (Fig. 2), as it can be seen on the graph below obtained for different FBA simulations. We have tried different minimal growth rates up to 0.025 which is the maximal value obtained when the objective function under FBA simulation is biomass production.

Figure 2: Butyrate flux depending on minimal growth rate

Finally, to understand the effect of the initial glucose concentration on the maximum butyrate quantity we can expect, we tested different glucose concentrations between 0.4 and 15 mmol.gDW-1.h-1 using FVA method (Flux Variability Analysis). Indeed, 0.4 mmol.gDW-1.h-1 corresponds to the glucose flux obtained with the Biosilta Kit for a culture time of 14 days, while 15 mmol.gDW-1.h-1 is the flux needed to reach maximum growth rate (same rates are applicable to formate).
As expected, the higher the initial glucose concentration is, the higher the level of produced metabolites will be.

Figure 3: Butyrate flux depending on growth rate

B. FORMATE

Data not shown. FBA, objective function = biomass production, Result = 0.0268

After having worked on optimizing butyrate production, we proceeded to do the same with formate production. As before, maximal production implies no growth and predicts a flux value of 2,917 mmol.gDW-1.h-1 (~ 0.006 mmol.L-1, Fig. 4).

Figure 4: Formic acid produced for different growth rate

As with butyrate, formate biosynthesis is unfavorably altered when a high level of constraint is applied to the minimal growth rate (Fig. 5). And formate production will be more important when glucose availability is higher (Fig. 6).

Figure 5: Formate flux (mmol.gDW-1.h-1 depending on growth level

Figure 6: Formate flux (mmol.gDW-1.h-1 depending on growth rate

Annexes

References


  • [1] KEGG Metabolic pathways - Escherichia coli K-12 MG1655
  • [2] Le Conte Y, Arnold G, Trouiller J, Masson C, Chappe B, Ourisson G. 1989. Attraction of the parasitic mite varroa to the drone larvae of honey bees by simple aliphatic esters. Science 245:638–639.
  • [3] Methods for attracting honey bee parasitic mites. [accessed 2015 Jul 24].
  • [4] Louis P, Flint HJ. 2009. Diversity, metabolism and microbial ecology of butyrate-producing bacteria from the human large intestine. FEMS Microbiol. Lett. 294:1–8.
  • [5] Atsumi S, Cann AF, Connor MR, Shen CR, Smith KM, Brynildsen MP, Chou KJY, Hanai T, Liao JC. 2008. Metabolic engineering of Escherichia coli for 1-butanol production. Metabolic Engineering 10:305–311.
  • [6] Wallace KK, Bao Z-Y, Dai H, Digate R, Schuler G, Speedie MK, Reynolds KA. 1995. Purification of Crotonyl-CoA Reductase from Streptomyces collinus and Cloning, Sequencing and Expression of the Corresponding Gene in Escherichia coli. European Journal of Biochemistry 233:954–962.