Team:WashU/FBA

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<h1>Carbon Flux</h1>
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<h1>Flux Balance Analysis</h1>
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In addition to measuring the OD730 of our Synechocystis, we also measured the dry weight in grams of the culture between the third and eighth day. We also measured the dry weight of an equal volume of BG-11 to obtain the dry weight of the Synechocystis alone. Our measurements were made by weighing 10mL of culture in pre-weighed aluminum weigh boats that had been dried for 24 hours in a 900 C oven. In order to calculate the approximate carbon flux from our data, several other plots were created.  
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Rather than constructing our model from the ground up, we built off the work of Knoop et al. and their flux balance analysis model created for <i>Synechocystis</i> sp. PCC 6803.<sup><a href= "http://dl.dropbox.com/u/88390549/knoop%20model.pdf">2</a></sup> In addition, we incorporated the work of Nogales et al. and their more recent model, which highlights the photosynthetic pathways in <i>Synechocystis</i>.<sup><a href="http://dl.dropbox.com/u/88390549/6803%20model.pdf">3</a></sup> Finally, we used the KEGG online reaction database to supplement our model.  
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First, we selected a linear portion of our growth curve, and fitted the curve to a line in order to determine the rate of change of OD730 per day.
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The COBRA Toolbox (Constraints Based Reconstruction and Analysis)<sup><a href="http://dl.dropbox.com/u/88390549/genome-scale%20model%20protocol.pdf">4</a></sup> and MATLAB were used to read and modify the model. The Knoop model lacked the terpenoid backbone biosynthesis, carotenoid biosynthesis, and the saffron biosynthesis pathway. We added a condensed version of these pathways to the existing model using the ‘addReaction’ command in the COBRA Toolbox. An excerpt of the code can be found below.  
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<img src = "http://dl.dropbox.com/u/88390549/carbonflux.png" width=600px>
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Second, a graph of gDW vs OD730 and fitted to a line to determine the rate of change of gDW per OD730.
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modelKnoop=addReaction(modelKnoop,'R381',{'C00022','C00118','C00005','C00002','h2mb4p','C00006','C00008','C00013','C00020','C00011'},[-1,-1,-2,-2,1,2,1,1,1,1],false,0,1000);
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<img src = "http://dl.dropbox.com/u/88390549/gdwVSod.png width = 600px>
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modelKnoop=addReaction(modelKnoop,'R382',{'h2mb4p','C00005','ipdp','C00006'},[-1,-1,1,1],false,0,1000);
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Finally, a graph of the mass of culture vs day was fitted to a line to determine the rate of change of gDW per day.  
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<img src ="http://dl.dropbox.com/u/88390549/culturemassperday.png width=700px>
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modelKnoop=addReaction(modelKnoop,'R383',{'h2mb4p','C00005','dmpp','C00006'},[-1,-1,1,1],false,0,1000);
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With all these data, we were able to calculate the influx of carbon into the cell, assuming that all the increase in mass of the culture was from bicarbonate. The calculations used to obtain the flux are shown below
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modelKnoop=addReaction(modelKnoop,'R384',{'ipdp','dmpp'},[-1,1],true,-1000,1000);
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modelKnoop=addReaction(modelKnoop,'R385',{'ipdp','dmpp','grpp','C00013'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R386',{'ipdp','grpp','fpp','C00013'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R387',{'fpp','C00005','squa','C00006','C00013'},[-2,-1,1,1,2],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R388',{'fpp','ipdp','C00013','dpp'},[-1,-7,7,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R389',{'ggpp','C00005','ppp','C00006'},[-1,-3,1,3],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R390',{'fpp','ipdp','C00013','ggpp'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R391',{'ggpp','C00007','b-caro','C00013'},[-2,-2,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R392',{'b-caro','C00007','ech'},[-1,-1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R393',{'b-caro','C00005','C00007','zeax','C00006'},[-1,-2,-2,1,2],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R394',{'zeax','C00007','crocDia','hydCycCitral'},[-1,-1,1,2],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R395',{'C00029','hydCycCitral','picr','C00015'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R396',{'crocDia','C00006','crocet','C00005'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R397',{'crocet','C00029','glucCrocet','C00015'},[-1,-1,1,1],false,0,1000);
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modelKnoop=addReaction(modelKnoop,'R398',{'glucCrocet','C00029','croc','C00015'},[-1,-3,1,3],false,0,1000);
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The biomass reaction of the model was modified to include the carotenoids. We used the bounds suggested by Knoop as constraints for our model, setting the flux for bicarbonate equal to 0.45 mmol g-1 DW-1 and the flux for photons equal to 7 photons g-1 DW-1 using the ‘changeRxnBounds’ command.  
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modelKnoop=changeRxnBounds(modelKnoop,'R203',7,'b');
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modelKnoop=changeRxnBounds(modelKnoop,'R344',.45,'b');
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Setting the objective to the biomass formula and optimizing the model, we determined that the growth rate of our organism was .0887 hr-1, a near identical result to the growth rate of .09 hr-1 calculated by Knoop.  
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modelKnoop=changeObjective(modelKnoop,'R351');
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optimizeCbModel(modelKnoop);
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In addition, we generated a phenotypic phase plane of the growth rate versus bicarbonate and photon flux:
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<img src = "http://dl.dropbox.com/u/88390549/growth%20rate.png" width = 765>  
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<img src ="http://dl.dropbox.com/u/88390549/eqn1.png">
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<h1>Analysis</h1>
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Since the molar mass of bicarbonate is 61.017 g/mol, the influx of bicarbonate into the cell can be calculated to be:
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When the table of fluxes obtained from the optimization of the model was examined for the fluxes of picrocrocin and crocin, it was noticed that all the fluxes in the saffron biosynthesis pathway were zero. In order to try and fix this, the biomass reaction was again altered to include picrocrocin and crocin. However, optimizing for the growth rate under this modified biomass reaction resulted in zero growth. This data from our model suggests that either further work needs to be done on the model to produce a result for picrocrocin and crocin, or that the metabolic network of <i>Synechocystis</i> as it currently stands is unfit for the production of picrocrocin and crocin.
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<img src = "http://dl.dropbox.com/u/88390549/eqn2.png">
 
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Latest revision as of 03:42, 4 October 2012




Flux Balance Analysis

Rather than constructing our model from the ground up, we built off the work of Knoop et al. and their flux balance analysis model created for Synechocystis sp. PCC 6803.2 In addition, we incorporated the work of Nogales et al. and their more recent model, which highlights the photosynthetic pathways in Synechocystis.3 Finally, we used the KEGG online reaction database to supplement our model.

The COBRA Toolbox (Constraints Based Reconstruction and Analysis)4 and MATLAB were used to read and modify the model. The Knoop model lacked the terpenoid backbone biosynthesis, carotenoid biosynthesis, and the saffron biosynthesis pathway. We added a condensed version of these pathways to the existing model using the ‘addReaction’ command in the COBRA Toolbox. An excerpt of the code can be found below.

modelKnoop=addReaction(modelKnoop,'R381',{'C00022','C00118','C00005','C00002','h2mb4p','C00006','C00008','C00013','C00020','C00011'},[-1,-1,-2,-2,1,2,1,1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R382',{'h2mb4p','C00005','ipdp','C00006'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R383',{'h2mb4p','C00005','dmpp','C00006'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R384',{'ipdp','dmpp'},[-1,1],true,-1000,1000);

modelKnoop=addReaction(modelKnoop,'R385',{'ipdp','dmpp','grpp','C00013'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R386',{'ipdp','grpp','fpp','C00013'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R387',{'fpp','C00005','squa','C00006','C00013'},[-2,-1,1,1,2],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R388',{'fpp','ipdp','C00013','dpp'},[-1,-7,7,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R389',{'ggpp','C00005','ppp','C00006'},[-1,-3,1,3],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R390',{'fpp','ipdp','C00013','ggpp'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R391',{'ggpp','C00007','b-caro','C00013'},[-2,-2,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R392',{'b-caro','C00007','ech'},[-1,-1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R393',{'b-caro','C00005','C00007','zeax','C00006'},[-1,-2,-2,1,2],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R394',{'zeax','C00007','crocDia','hydCycCitral'},[-1,-1,1,2],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R395',{'C00029','hydCycCitral','picr','C00015'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R396',{'crocDia','C00006','crocet','C00005'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R397',{'crocet','C00029','glucCrocet','C00015'},[-1,-1,1,1],false,0,1000);

modelKnoop=addReaction(modelKnoop,'R398',{'glucCrocet','C00029','croc','C00015'},[-1,-3,1,3],false,0,1000);

The biomass reaction of the model was modified to include the carotenoids. We used the bounds suggested by Knoop as constraints for our model, setting the flux for bicarbonate equal to 0.45 mmol g-1 DW-1 and the flux for photons equal to 7 photons g-1 DW-1 using the ‘changeRxnBounds’ command.

modelKnoop=changeRxnBounds(modelKnoop,'R203',7,'b');

modelKnoop=changeRxnBounds(modelKnoop,'R344',.45,'b');

Setting the objective to the biomass formula and optimizing the model, we determined that the growth rate of our organism was .0887 hr-1, a near identical result to the growth rate of .09 hr-1 calculated by Knoop.

modelKnoop=changeObjective(modelKnoop,'R351');

optimizeCbModel(modelKnoop);

In addition, we generated a phenotypic phase plane of the growth rate versus bicarbonate and photon flux:

Analysis

When the table of fluxes obtained from the optimization of the model was examined for the fluxes of picrocrocin and crocin, it was noticed that all the fluxes in the saffron biosynthesis pathway were zero. In order to try and fix this, the biomass reaction was again altered to include picrocrocin and crocin. However, optimizing for the growth rate under this modified biomass reaction resulted in zero growth. This data from our model suggests that either further work needs to be done on the model to produce a result for picrocrocin and crocin, or that the metabolic network of Synechocystis as it currently stands is unfit for the production of picrocrocin and crocin.