Team:TU Delft/Modeling/MFA/additional pathways

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Pathways added to the E. coli metabolic network

Figure 1 – Reaction taken from Ecocyc

The E. coli network from Cell Net Analyzer contains, glycolysis, TCA cycle, pentose phosphate pathway, gluconeogenesis, anapleorotic routes, oxydative phosphorilization and biosynthesis pathways. CellNetAnalyzer can be found here.


There was one change made in the network provided by CellNetAnalyzer for the NADH dehydrogenase reaction, annotated as NADHdehydro in CellNetAnalyzer. In the network of CellNetAnalyzer this reaction exports two protons, but this was changed to 4 as given by Ecocyc. This reaction is shown in figure 1.


Alkane degradation

To link alkanes to the existing network, the beta-oxidation was chosen as entry point. Several genese from biobricks were used to transform alkanes in to fatty acids which enter the beta oxydation cycle. These genes were:


AlkB2 (EC 1.14.15.3)

Figure 2 – Reaction taken from Metacyc

The reaction for AlkB2 is shown in figure 2.

The reaction was implemented in CNA as;

n-alkane + reduced rubredoxin + O2 -> n-alkanol + oxidized rubredoxin


RubA3/RubA4 (EC 1.18.1.1)

Figure 3 – Reaction taken from Metacyc

The reaction for the regeneration of rubredoxin is shown in figure 3.

The reaction was implemented in CNA as;

oxidized rubredoxin + NADH -> reduced rubredoxin


ADH (EC 1.1.1.1)

Figure 4 – Reaction taken from Metacyc

The reaction for ADH is shown in figure 4.

The reaction was implemented in CNA as;

n-alkanol -> n-aldehyde + NADH


ALDH (EC 1.2.1.3)

Figure 5 – Reaction taken from Metacyc

The reaction for ALDH is shown in figure 5.

The reaction was implemented in CNA as;

n-aldehyde -> n-fatty acid + NADH


fatty acyl-CoA synthetase (EC 6.2.1.3)

Figure 6 – Reaction taken from Ecocyc

From here the genes are already present in the E. coli genome. They were not yet present in the metabolic network for E. coli in CellNetAnalyzer however. So the following reactions and pathways were also implemented in CNA. The reaction for fatty acyl-CoA synthetase is shown in figure 6.

The reaction was implemented in CNA as;

n-fatty acid + ATP -> n-saturated fatty acyl-CoA + AMP


Adenylate kinase (EC 2.7.4.3)

Figure 7 – Reaction taken from Ecocyc

CNA did not have a reaction to regenerate AMP yet, so the reaction for adenylate kinase was added to the network. The reaction for adenylate kinase is shown in figure 7.

The reaction was implemented in CNA as;

ATP + AMP -> 2 ADP


Fatty acid beta-oxidation cycle (EC 1.3.99.3 EC 4.2.1.17 EC 1.1.1.35 EC 2.3.1.16)

Figure 8 – Reaction taken from Ecocyc

The reactions for this pathway are shown in figure 8.

The lumped reaction was implemented in CNA as;

n-saturated fatty acyl-CoA -> (n - 2)-saturated fatty acyl-CoA + acetyl-CoA + FADH2 + NADH


FADH2 regeneration

The cofactor FADH2 is not yet defined in the network of CNA, so a reaction had to be introduced to regenerate it. FADH2 gives its electrons to ubiquinol just like NADH, however in this process no protons are exported.

The reaction was implemented in CNA as;

1 FADH2 -> 1 QH2


Odd numbered alkanes

For all even numbered alkanes the above reactions completely link them to the main network in CNA. All the cofactors have regeneration reactions and all the alkanes are converted into acetyl-CoA. The final reaction in the beta oxidation cycle (n = 4) produces then two acetyl-CoA. For odd numbered alkanes the final reaction however (n = 5), a propionyl-CoA is generated;

n-saturated fatty acyl-CoA -> propionyl-CoA + acetyl-CoA + FADH2 + NADH


2-methylcitrate cycle (EC 2.3.3.5 EC 4.2.1.79 EC 4.2.1.99 EC 4.1.3.30)

Figure 9 – Reaction taken from Ecocyc

This propionyl-CoA still needs to be linked to the main network in CNA. The pathway that was used to process this metabolite, was a part of the 2-methylcitrate cycle. The reactions for this pathway are shown in figure 9.

The lumped reaction was implemented in CNA as;

propionyl-CoA + oxaloacetic acid -> succinate + pyruvate


Biomass formation

The biomass is formed by many anabolic reactions that make monomers. All the anabolic reactions start at the so called key metabolites. There are 12 key metabolites and they are all in the glycolytic pathway and the TCA cycle. In the tool they are the red metabolites. For this analysis the anabolic reactions already present in CNA were used.


NO3 as electron acceptor (EC 1.7.99.4)

Figure 10 – Reaction taken from Ecocyc

In oily environments oxygen diffuses more difficult into the water phase. The oxygen is used for the oxydative phosphorylation, regenerating NADH, and for the first step in the hydrocarbon degradation. To be more efficient with oxygen an additional electron acceptor was introduced.

The standard oxydative phosphorylation (EC 1.6.5.3 EC 1.10.2.-) is shown in figure 10.

Figure 11 – Reaction taken from Ecocyc

The second step will be disabled in the network and be replaced with a nitrate reductase. This reaction is shown in figure 11.

The reaction was implemented in CNA as;

NO3- + QH2 -> NO2-

This reaction uses NO3 as an electron acceptor to regenerate NADH and export protons to generate ATP. Less protons are exported per mol of NADH in comparison with oxygen as electron acceptor, so the ATP/NADH ratio will drop. The goal of implementing this pathway however, is to see how much the oxygen requirement of E. coli can maximally be reduced.


PHB production (EC 2.3.19 EC 1.1.1.36 EC 2.3.1.-)

Figure 12 – Reaction taken from Metacyc

In previous situations the hydrocarbons were degraded only to form biomass and CO2. It is interesting to see how much product theoretically could be made from hydrocarbons. PHB is a polymer of polyhydroxybutyrate. The production pathway of PHB is well known. PHB is a solid product which is easy to recover in the down stream process.

The pathway is displayed in figure 12.

The lumped reaction was implemented in CNA as;

2 acetyl-CoA + NADPH -> (R)-3-hydroxybutanoyl-CoA

the polymerization reaction just consumes (R)-3-hydroxybutanoyl-CoA, because a solid has no concentration in the liquid and therefore does not need to fulfill the steady-state condition. There are limiting factors to this reaction, but those are not considered in this analysis.

Hydrogen production

Figure 13 – Reaction taken from Ecocyc

As with PHB, this pathway was added to the metabolic pathway to see how much product could be made from the alkane degraation in stead of just biomass and CO2 formation. Hydrogen is considered a green fuel. Hydrogen is a volatile product and is also easily separated from fermentation broth. It does however contain no carbon atoms, so hydrogen will still result in production of CO2 and biomass.

The pathway is shown in figure 13

The reaction was implemented in CNA as;

Formate -> H2 + CO2

Isoprene production

Figure 14 – Reaction taken from Metacyc

As with the previous product pathways, isoprene is a product that can easily be seperated from liquid. Isoprene is a volatile substance found in plants. E. coli will not be able to produce is in the near future, but it is an interesting product. It is a very reduced product, with a similar amount of electron per carbon atom as alkanes. Alkanes have 6 - 6.3 electrons per carbon atom depending on the length and isoprene has 5.6 electron per carbon electron.

The pathway is displayed in figure 14

The lumped reaction was implemented in CNA as;

1 pyruvate + 1 D-glyceraldehyde-3-phosphate + 1 NADPH + 3 NADH + 3 ATP -> isoprene + CO2


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