Automated reconstruction of GEMs based on protein homology.

Previously published GEMs represent a solid basis for metabolic reconstruction of models for new organisms, in particular if the organisms are closely related and therefore share many metabolic capabilities. The main advantage of using existing models compared to reaction databases, such as KEGG or BRENDA [29], is that they contain information that can be difficult to obtain in an automated manner, in particular directionality and compartmentalization. There have been attempts to predict the directionality of reactions based on the estimates of the standard Gibbs energies of formation for the involved metabolites [30]. However, we believe that manually reconstructed networks for related species can be a more reliable source of directionality information. The same is true for compartmentalization. Even though the RAVEN Toolbox contains methods for inferring subcellular localization based on predictors, it is to be viewed as an aid rather than an exact method. GEMs are also typically constructed for modeling purposes, which is not the case for reaction databases. The downside is that only reactions present in the template models can be included. The RAVEN Toolbox therefore contains two approaches for automatic generation of draft models; while the method mentioned above relies on the metabolic functions represented in previously published models, the complementary method uses the KEGG database for automatic identification of new metabolic functions that are not included in the published models.

The first approach lets the user supply a number of existing GEMs and FASTA files with protein sequences for the template models and for the organism of interest. The software then generates a draft model based on protein orthology. The default implementation uses bi-directional BLASTp [31] for evaluation of protein homology, but the software also supports other homology measurements as long as a score can be assigned to each pair wise protein comparison. The resulting model can be exported as a SBML file or be used in MATLAB for simulation and further analysis.

The second approach is also based on protein homology but requires no template models. Instead it relies on the information on protein sequences and on the assigned metabolic reactions that is available in the KEGG database. The method makes use of the KEGG Orthology (KO) IDs, which are manually annotated sets of genes that encode some specified metabolic function. Each KO is associated with a number of metabolic reactions. The aim of the present method is to assign genes to these KOs based on the consensus protein sequence. The tool first downloads all relevant parts of the KEGG database to a local directory and parses these files to generate a GEM representing a metabolic network across all of the species annotated in KEGG, i.e. this would lead to a network comprising 7029 metabolites, 8398 reactions and 843369 genes, when using the most current version of the KEGG database. A GEM for the organism of interest is then constructed by choosing a subset of this larger model and linking the reactions with the corresponding genes. The protein sequences for each KO are retrieved and aligned using MUSCLE [32]. The user has the option to only use genes from organisms of a given phylogenetic distance from the target organism, e.g. only fungal genes or only eukaryotic genes. A hidden Markov model is then generated based on the sequences for each KO using HMMER [33]. The final step is the querying of the set of HMMs with the protein sequences of the organism of interest. If a gene has a significant match to one KO, the reactions associated to that KO are added to the model together with the corresponding gene. This process is fully automated, and the user only needs to supply a FASTA file with protein sequences. Users who do not subscribe to KEGG can download pre-trained HMMs for eukaryotes and prokaryotes through the BioMet Toolbox (http://www.sysbio.se/BioMet). These HMMs are based on the last open version of KEGG. More advanced users can set parameters that affect how genes are mapped to KOs and how general, unbalanced, or otherwise problematic reactions from KEGG should be dealt with.

Model analysis and simulation.

The approach proposed above will facilitate and accelerate the generation of a draft metabolic network reconstruction. The automated reconstruction can lead to some loss of control compared to a stricter manual, bottom-up approach. It is therefore important to identify and fill gaps in the model to ensure that the network is functioning as required. In a high quality model all reactions should be able to have a flux if all uptake and excretion reactions are allowed and net synthesis of most metabolites should be possible (the exception would normally be some co-factors). The second criterion is important, since the large degree of freedom in GEMs allow for internal loops where reactions can carry flux but where no net consumption or synthesis of metabolites occurs. The RAVEN Toolbox contains a number of methods to support the gap filling process. The following section describes the suggested workflow for gap identification and filling when starting from a draft network.

• Gap filling traditionally centers on adding reactions in order to enable production of all precursors needed for biomass production. However, it is equally important to ensure that the model cannot produce anything when there is no uptake of metabolites. The reactions which enable this type of behavior are typically those which involve polymers, metabolite pools, or other abstract metabolites but they can also simply be erroneous reactions. A brute force solution would be to exclude all reactions which are not elementally balanced, but this could result in a large fraction of the network being deleted, as many metabolites typically lack information about elemental composition. The makeSomething and consumeSomething functions identifies such reactions by solving the mixed integer linear programming (MILP) problem of finding the smallest set of reactions which results in the net synthesis or consumption of any metabolite. The solutions can then be cross-referenced to balancing information from getElementalBalance in order to identify reactions which are both active and have wrong/lacking composition. This process can also be done automatically using removeBadRxns.
• After the user has added relevant exchange reactions canProduce/canConsume can be used to generate a list of the metabolites that can have net synthesis or consumption. Early on in the reconstruction process it is likely that not all biomass precursors can be synthesized. The function checkProduction can be very useful in this situation. It calculates the smallest set of metabolites which must have net synthesis in order to enable net synthesis of all other metabolites. This gives the user information such as “in order to synthesize biomass, you must enable synthesis of valine and coenzyme A” or “if synthesis of choline is enabled, the following set of metabolites could also be synthesized”. The function also allows the user to set rules about merging compartments, since it can be easier to first make sure that the model is functional with merged compartments and deal with transport and sub-cellular localization afterwards.
• Ideally all reactions should be able to carry flux if all relevant exchange reactions are available. The function haveFlux can be used to identify reactions which cannot carry flux, and also to distinguish between reactions which cannot carry flux because some substrate cannot be synthesized and those which cannot carry flux because some product cannot be further consumed. However, because of the many internal loops in GEMs it is common that reactions can carry flux and appear well-connected even if they are not connected to the rest of the metabolic network. getAllSubGraphs can be used to identify such subnetworks using Tarjan's algorithm [34].
• The function fillGaps can be used to retrieve reactions from a set of template models or from KEGG in order to generate a functional network. The user can set constraints on their model, such as that it should be able to produce biomass from minimal media, and fillGaps will then solve the MILP problem of including the minimal set of reactions from a set of template models in order to satisfy the constraints. The same function can be used to enable net synthesis of all metabolites or to enable flux through all reactions. This approach is similar to that taken in Model SEED, and enables fully automatic model reconstruction. However, we suggest that GEM reconstruction should be done iteratively and with manual input and that the results from these algorithms are to be viewed as suggestions to point the user in the right direction.
• In eukaryotes the enzymatic reactions are distributed between different organelles. To determine which reactions occur where is a difficult task, and one of the more time-consuming steps in the reconstruction process. The RAVEN Toolbox takes a first step towards speeding up this step by including a method for assigning subcellular localization to enzymatic reactions in an automated fashion. The algorithm aims at assigning localization in a manner that is consistent with signal peptide composition and physiochemical protein properties, while at the same time maintaining a well-connected and functional network. The default predictor is WoLF PSORT, which is distributed with the RAVEN Toolbox [35]. A parser for other predictors, such as CELLO is also included [36]. In short, the algorithm works by generating fully connected solutions, which are then scored based on the agreement to the predicted localization and the number of transport reactions which had to be included in order to have a connected network. The problem is solved using simulated annealing. A more detailed description is available in Figure 2.

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Figure 2. Prediction of subcellular localization of reactions.

Circles correspond to metabolites and lines correspond to reactions. Green lines are reactions which are in their correct compartment according to the predictions. Red are reactions which are in an incorrect compartment and orange are reactions where there is no strong indication for either compartment. A) There is a tradeoff between connectivity and agreement with predicted localization. Network 1 represents the extreme case where connectivity is much more important than predicted localization scores. All reactions are then localized to the cytosol. Network 2 represents the other extreme case where the reactions are localized only based on localization scores and with no regard for connectivity. This would result in an unconnected network. Network 3 represents the case where the network is connected, while still being in good agreement with the localization scores. The underlying assumption in the algorithm is that a good network is characterized by being fully connected, in the sense that all metabolites are synthesized in at least one reaction and consumed in at least one reaction, while still being in good agreement with the localization scores and relying on the smallest possible number of transport reactions to achieve this. B) Summary of the localization algorithm. 1. The algorithm first randomly moves one gene product and its associated reaction(s) to another compartment. The probabilities depend on the scores for the gene products in their respective compartments. 2. This may result in an unconnected network. The algorithm then tries to find a small set of reactions which, when moved, reconnects the network. If moving these reactions would result in a large decrease of fitness, then the network is connected by including transport reactions for some metabolites instead. 3. The connected network is then scored as the sum of scores for all genes in their assigned compartment, minus the cost of all transport reactions that had to be included in order to keep the network connected. The user can set the relative weight given to transport compared to gene localization. The overall problem is solved using simulated annealing.

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The RAVEN Toolbox also contains a number of methods for performing simulations using GEMs. In this aspect it is similar to the COBRA Toolbox [21]. Most of the features of COBRA Toolbox are also present in the RAVEN Toolbox, with the exception of dynamic FBA. This includes linear programming such as FBA, quadratic programming such as MoMA, mixed integer linear programming applications, and random sampling. Utility functions such as setting constraints and objectives, adding or removing model elements, presenting simulation outputs, sensitivity analysis, screening for gene deletions, and fitting model parameters such as maintenance ATP consumption are also included. For a full description of all functions of the toolbox, see the supplied manual. The RAVEN Toolbox uses MOSEK (MOSEK ApS, Copenhagen, Denmark) for solving the underlying optimization problems. MOSEK is proprietary software but a full featured license is freely available for academic use.

Validation of the workflow.

The RAVEN Toolbox pipeline was validated by constructing a model for Saccharomyces cerevisiae, a model organism for which several GEMs have been constructed. To compare the quality of the automatically generated model to a manually curated one, some kind of reference was needed. As all models contain errors it would not be very relevant to simply compare the similarity between the RAVEN Toolbox generated model and a previously published model. Saccharomyces Genome Database (SGD) was therefore used as a reference with respect to the enzymes present in S. cerevisiae and their subcellular localization. A model was generated from KEGG in a fully automatic manner and then compared to the iIN800 model, a model which has been shown to have excellent simulation capabilities [37]. It should be noted that this fully automatic reconstruction is not how the RAVEN Toolbox is intended to be used for reconstruction. We suggest that the user view the output of each step as suggestions, and manually fill gaps or fix problematic reactions. However, we wanted to perform an evaluation of the overall reconstruction feature of the RAVEN Toolbox.

The model was generated using getKEGGModelForOrganism with the settings to only use eukaryotic genes when training the HMMs, a cutoff of 1e-30 when matching genes to the HMMs, and to exclude reactions labeled as general or incomplete in KEGG. S. cerevisiae genes were excluded in the training of the HMMs to simulate reconstruction of an organism for which there is little previous gene annotation. Not all unbalanced or erroneous reactions were labeled as such, and this resulted in that the KEGG model could produce some metabolites without any uptakes. removeBadRxns identified 79 reactions which enabled such production (see Table S1). Out of these 72 were unbalanced, general or polymer reactions and as such were correctly removed. 7 reactions were correct, but lacked composition about the metabolites (it is a setting in removeBadRxns whether it is allowed to remove such reactions).

Based on experimental minimal media the model was allowed uptake of glucose, phosphate, sulfate, NH3, oxygen and the essential nutrients 4-aminobenzoate, riboflavin, thiamine, biotin, folate, and nicotinate [38]. Uptake of the carriers carnitine and acyl-carrier protein was allowed for modeling purposes (many compounds are bound to them and therefore net synthesis of these compounds is not possible without them). This was the only manual step in the reconstruction of the yeast model.

The resulting model contained 1126 reactions, 1144 metabolites and 713 genes (before compartmentalization). 521 (73%) of those genes were shared with iIN800. 192 genes were unique to the automatically reconstructed model and 91 genes were unique to the iIN800 model (since there are no transport reactions in KEGG, all transporters were excluded from iIN800 for the purpose of this comparison). Figure 3 shows a classification of the genes that are unique to either the automatically reconstructed model or to iIN800 (see Table S2 for details). As can be seen, the automatically reconstructed model has a significantly larger proportion of enzymes compared to the published model.

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Figure 3. Overview of the genes which are unique to the automatically reconstructed model and iIN800, respectively.

Saccharomyces Genome Database was used to classify the genes. Green corresponds to genes where the function is well-defined and suited for GEMs, basically enzymes involved in metabolism. Red corresponds to genes where the function is unknown, where the corresponding protein is not an enzyme or where the function is in signaling rather than metabolism. These genes should normally not be present in a GEM. Blue corresponds to genes that are putative enzymes or where the ORF is a functional enzyme in some strains but not in others. As can be seen, the automatically reconstructed model has both a larger number of unique genes and a larger proportion of enzymes compared to the published model. For iIN800 some enzymatic genes are further classified as “polymer”, “lipid” or “membrane”. These are parts of metabolism where an automatically generated model from KEGG would have particular drawbacks compared to a manually reconstructed model. “Polymer” corresponds mainly to genes involved in sugar polymer metabolism, which is an area that contains many unbalanced reactions in KEGG. Such reactions were excluded when the validation model was generated, so the corresponding genes could not be included. The same holds for “lipid”, where the reactions contain many general metabolites. This also results in excluded reactions. “Membrane” corresponds to reactions which depend on one metabolite but in two different compartments. This compartmentalization information is absent in KEGG so the equation becomes incorrect and it is therefore excluded.

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Given the inputs the model could have net-synthesis of 476 (42%) of the 1144 metabolites (see Table S3 for details). As a comparison, 456 (66%) out of 683 unique metabolites in iIN800 could be synthesized given the same inputs. Among the 476 metabolites were 19 out of the 22 standard amino acids (leucine, methionine, and taurine could not be synthesized), the nucleotides needed for RNA and DNA synthesis (ATP, GTP, CTP, UTP, dATP, dGTP, dCTP, and dTTP), fatty acids, sterols such as lanosterol and ergosterol, important co-factors such as NADH, NADPH, FADH2 and CoA, and the building blocks needed for cell wall assembly (UDP-glucose, UDP-N-acetyl-D-glucosamine and mannose). The only major biomass constituents that could not be synthesized were complex lipid compounds such as phospholipids and sphingolipids. This is because of the combinatorial nature of fatty acid metabolism (given ∼20 fatty acids there are 20!/2!(20-2) = 190 possible versions of phosphatidylcholine) and how it is represented in KEGG.

As the next step of the fully automatic reconstruction, fillGaps was used to automatically fill gaps in the yeast network using the full KEGG database as a template. This resulted in 45 reactions being added, which in turn enabled the synthesis of 91 metabolites that could previously not be synthesized (see Table S4). Among them were the three amino acids that were previously missing. A closer investigation of the reactions which were added (see Table S5) showed that out of the 45 added reactions, 17 had evidence to support that they should be included in the model, 9 had inconclusive or missing evidence, and 19 reactions should not have been included in the model. 5 of the 91 genes that were previously unique to iIN800 were also added in this process.

The RAVEN Toolbox also contains a method for partitioning enzymatic reactions to compartments in a manner that keeps the network connected, but at the same time in agreement with the results from predictors of protein localization (see Figure 2 for details). The default predictor, WoLF PSORT, was used to predict the protein localization of all ORFs in the FASTA file. predictLocalization was then used to partition the network between mitochondria and cytosol. The transport cost was set to 0.1. Table S6 lists the genes for which the corresponding reactions were assigned to the mitochondria. 119 gene products were assigned to the mitochondria and the remaining 594 gene products were assigned to the cytosol. Out of the 119 predicted mitochondrial gene products, 72% were listed as mitochondrial in the SGD based on experimental evidence. The same calculations for iIN800 give that 91 gene products are mitochondrial and that 83% were listed as mitochondrial in SGD. Localization predictions based only on primary protein sequences are not very exact, and the resulting model from predictLocalization will not be totally biologically correct. The main issue is that all transport reactions are formulated as passive diffusion, while in reality other types of transport are also taking place. However, the method is able to quickly generate a connected model where the enzyme localizations are in almost as good agreement to SGD as a published model. This could be useful for many applications, such as when using metabolic networks for integrating omics data, and it constitutes a first step towards fully automated reconstruction of eukaryote GEMs.

These results show both strengths and weaknesses of using a fully automatic approach to reconstruction. A model capable of producing all the needed building blocks for synthesis of protein, RNA, DNA, and the cell wall was generated solely from a FASTA file and with almost no manual input. The automated gap filling identified 17 new reactions, out of which 8 were not present in the published S. cerevisiae model. As was shown in Figure 3, the quality in terms of included genes was as good or better compared to the published model. On the other hand, the gap filling included 19 reactions which did not belong in the model, and complex lipids could not be synthesized. The sub-cellular localization of enzymes was up to par with the published model, but with the drawback that all transport reactions were formulated as passive diffusion. In a real situation a reconstruction should therefore be done in an iterative manner, with manual input after each iteration (the user would, for example, remove the 19 bad reactions from the template model and then run fillGaps again).

Visualization of GEMs.

Stoichiometric metabolic models have been proven to generate remarkably good predictions when it comes to the central carbon metabolism in microorganisms. However, the lack of kinetic and regulatory information is a rather large simplification and it is possible to get simulation results that have little biological meaning (such as thermodynamically disallowed loops). It is therefore imperative to understand the underlying reasons for a change in predicted phenotype after a perturbation such as a gene deletion. Due to the large dimensionality of GEMs interpretation of flux distributions is a rather daunting task. Visualization of fluxes can aid with interpretation, as well as provide an instant overview of how the system functions. Software that aims at network visualization based purely on connectivity, such as Cytoscape [39] or CellDesigner [40], cannot provide a comprehensible or well organized image of GEMs due to their size. The RAVEN Toolbox allows for visualization of simulation results based on manually drawn maps. The maps are drawn in CellDesigner and each reaction is labeled with the corresponding reaction identifier in the model. The map can then be imported to MATLAB and the reactions are colored according to the change in the corresponding flux between simulation conditions. Gene expression data can be incorporated in the map to illustrate the correlation between flux and gene expression. This will extraordinarily facilitate the comparison and interpretation of flux distributions found for different environmental conditions. The resulting map is exported as a pdf-file. Figure 4 show a close up on penicillin metabolism in the peroxisome overlaid on the full P. chrysogenum map (see following section for details).

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Figure 4. Example of the visualization capabilities of the RAVEN Toolbox.

The figure shows a small section of the Penicillium metabolic map, depicting peroxisomal penicillin metabolism, superimposed on the full map. Rectangles correspond to reactions and ellipses correspond to metabolites. The broad yellow line represents the peroxisomal membrane. Reactions are colored based on the log-fold change in flux between a reference and a test case, where green represents a higher flux in the test case and red a lower flux. The positive direction of reversible reactions (defined as from left to right in the model equations) is indicated by a red arrow head. For reactions carrying flux in any of the simulated cases, the flux values are printed in the reaction box. The small squares to the right of some of the reactions correspond to the log-fold change of transcript levels of the genes associated to that reaction. The gene-reaction relation is retrieved from the model structure and not implicitly specified in the CellDesigner map.

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Penicillin yields.

Penicillin production is associated with an increased requirement of energy in the form of ATP; in the condensation of the three precursor amino acids to form the tripeptide ACV; in the reduction of sulfate; and when a side chain (the precursor molecule which is supplied to the media and which differs depending on the type of penicillin produced) is activated by ligation to coenzyme A. Penicillin production is also associated with a large requirement of NADPH; primarily needed for the reduction of sulfate but also in the biosynthesis of valine and homoserine from α-ketobutyrate. Elucidating the impact increased ATP requirements have compared to the NADPH requirements is useful when choosing among possible metabolic engineering strategies.

Different types of penicillin can be produced by changing the side chain that is supplied to the medium (e.g. supplementation of phenylacetic acid result in penicillin G and supplementation of phenoxyacetic acid result in penicillin V). However, this has no impact on the yield and it is therefore not necessary to specify the type of penicillin being produced for theoretical evaluations. The maximum theoretical yield of penicillin on glucose with sulfate as the sulfur source was calculated to be 0.42 mol penicillin/mol glucose using the reconstructed genome-scale metabolic model. This is in agreement with what has previously been published [45]. If the sulfur source is sulfite the maximal theoretical yield is found to be 0.45 mol penicillin/mol glucose and if it is hydrogen sulfide it is 0.51 mol penicillin/mol glucose. The difference between using sulfite and hydrogen sulfide is relatively large and can be attributed to the differences in NADPH cost (3 NADPH are consumed in the sulfite reduction to hydrogen sulfide). This points to the importance of NADPH availability for penicillin production. To investigate the effect of ATP an artificial reaction was included that allowed for ATP production from ADP without any energetic costs. This resulted in a yield of 0.52 mol penicillin/mol glucose, using sulfate as the sulfur source. The conclusion is that ATP availability has a relatively small effect on the yield, comparable to that of NADPH consumption in the sulfate reduction. The shadow prices (how much the penicillin production can increase if the availability of a metabolite were to increase by a small amount) were calculated to be 0.015 mol penicillin/mol ATP, 0.040 mol penicillin/mol NADPH, and 0.037 mol penicillin/mol NADH.

NADPH and NADH are similar when it comes to energy content, but have different roles in the metabolism, where NADPH serves primarily anabolic roles and NADH primarily catabolic roles. NADPH is mainly produced in the pentose phosphate pathway, which makes NADPH somewhat more energetically expensive to regenerate compared to NADH. In order to investigate the relative importance of NADH and NADPH an artificial reaction was included that allowed for production of NADPH from NADH to simulate a potential increase of the NADPH availability. Simulations were then carried out maximizing first for growth and then for penicillin production. The resulting flux through the artificial reaction was 8.5 times larger when maximizing for penicillin than when maximizing for growth. This demonstrates that the cells will have a much higher NADPH demand at high penicillin yields compared to normal growth conditions. Redirecting a higher flux through the pentose phosphate pathway and/or introducing NADH-dependent versions of NADPH-consuming enzymes could therefore be potential metabolic engineering strategies for achieving higher penicillin yields.

For the direct identification of possible metabolic engineering targets a gene deletion analysis was performed by searching for sets of gene deletions that result in an increased yield of penicillin, and which would stoichiometrically couple penicillin production to growth. This was performed using FBA, and combinations of up to three gene deletions were evaluated (MoMA was also applied and gave similar results). The only targets which could be identified were the deletion of any of the genes responsible for breakdown of phenylacetic acid (homogentisate 1,2-dioxygenase, maleylacetoacetate isomerase, or fumarylacetoacetase). Deletion of any of these genes resulted in a 21% increase in penicillin production when maximizing for growth.

Identification of transcriptionally regulated metabolic bottlenecks.

The metabolism of cells is redundant in the sense that different sets of metabolic reactions can be used to generate the same net phenotype. A recently developed method aims at finding potential metabolic engineering targets by identifying genes that are differentially expressed between different cultivation conditions and where the corresponding reactions exhibit significantly changed fluxes for the same conditions [4]. Changes in expression level of such genes are then assumed to be likely to result in altered fluxes. The algorithm finds these transcriptionally regulated reactions by random sampling of the solution space, after which it compares the statistics of the sampling with the statistic of the mRNA expression. Here we applied this method to compare the high producing industrial strain DS17690, which has been developed by DSM, and the low producing reference strain Wis 54-1255 (see Methods for details) [46].

A total of 58 fluxes were found to be significantly changed between the high and low production strains (p<0.05) and 612 genes were differentially expressed (p<0.005). Out of those, 36 reactions were identified as having significantly higher flux and up-regulated genes (see Table S10), i.e. they are likely to have transcriptional regulation of their fluxes. Figure 7 shows some of the most important reactions in penicillin biosynthesis together with the responsible enzymes and the corresponding model IDs. Reactions that were identified as probably being transcriptionally controlled and up-regulated are highlighted. In addition, the Reporter Metabolites algorithm was used to identify metabolites around which significant transcriptional changes occurred [47]. These metabolites are highlighted in Figure 7 as well (see Table S11 for a full list of reporter metabolites).

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Figure 7. Integrative analysis of a high and a low producing strain.

Depicts synthesis pathways of penicillin and important precursors. Green boxes correspond to reactions identified as being transcriptionally controlled and up-regulated by the algorithm (see text). Metabolites around which significant transcriptional changes occur compared to a low producing strain are colored red. SC: side chain (e. g. the precursor molecule phenylacetic acid). The biosynthesis of penicillin starts with the condensation of the three amino acids α-aminoadipate (an intermediate in the L-lysine biosynthesis pathway), L-cystein, and L-valine to form the tripeptide ACV. ACV is further converted to isopenicillin N. For the industrially relevant types of penicillin a side-chain is supplied to the media. This side-chain is activated by ligation to coenzyme A. In the last step of penicillin biosynthesis an acyl transferase exchanges the α-aminoadipate moiety of isopenicillin N with the side-chain, thereby generating penicillin and regenerating α-aminoadipate. Since L-cystein is a sulfur-containing amino acid penicillin production is also tightly associated with sulfur metabolism. The corresponding model IDs for the enzymes are indicated within parentheses. [1] homocitrate synthase (r0683); [2] homocitrate dehydrase (r0684); [3] homoaconitate hydrase (r0685); [4] homoisocitrate dehydrogenase (r0688); [5] α-aminoadipate aminotransferase (r0689); [6] homoserine transacetylase (r0600); [7] O-acetylhomoserine sulfhydrylase (r0601); [8] cystathione-β-synthase (r0632); [9] cystathione-γ-lyase (r0606); [10] acetate CoA ligase (r0025); [11] acetolactate synthase (r0465); [12] ketol-acid reductoisomerase (r0653); [13] dihydroxy acid dehydrase (r0656); [14] branched chain amino acid transferase (r0648); [15] ACV synthase (r0814); [16] isopenicillin N synthase (r0812); [17] acyl CoA ligase (side chain dependent, reaction is for phenylacetate CoA ligase) (r0747); [18] isopenicillin N N-acyltransferase (r0813); [19] sulfate permease (r1408); [20] sulfate adenyl transferase (r1151); [21] adenyl sulfate kinase (r1147); [22] phosphoadenyl sulfate reductase (r1148); [23] sulfite reductase (r1149); [24] thioredoxin reductase (r0419); [25] 3′(2′),5′-bisphosphate nucleotidase (r1150).

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As can be seen in Figure 7, a large proportion of the reactions identified as being a transcriptionally controlled are directly involved in penicillin metabolism (15 out of 38). This indicates that the capabilities of the industrial strain to produce penicillin to a large extent depend on the reactions closely related to penicillin metabolism, rather than more peripheral effects. Among these reactions are many of the reactions responsible for the synthesis of the amino acids that are precursors for ACV as well as the two penicillin producing reactions isopenicillin N synthase and ACV synthase, which is consistent with a study on the gene copy-number effect on penicillin production [48]. The phenylacetate:CoA ligase is high ranking but the acyl-CoA:isopenicillin N acyltransferase is absent, which is consistent with measurements of high activities of this enzyme and the low flux control estimated for this enzyme [49], [50]. Several of the reactions involved in sulfate reduction are present as well as the sulfate permease. It is interesting to note that none of the reactions in the pentose phosphate pathway are identified even though there is an increased demand for NADPH.

We also found that the pathway from α-ketobutyrate to succinate is identified to have both increased flux and increased gene expression. α-ketobutyrate is a by-product of cysteine production via the transsulfuration pathway, and it is used for isoleucine biosynthesis. Under normal growth conditions the demand for cysteine is less than that for isoleucine, meaning that all α-ketobutyrate is converted into isoleucine. However, during high-level penicillin production the cysteine production far exceeds the need for isoleucine, requiring an alternative route for α-ketobutyrate consumption. This route involves the decarboxylation of α-ketobutyrate to yield propionyl-CoA, which then goes into the methylcitrate pathway, eventually resulting in succinate [45]. Several of the reactions in this pathway are identified as transcriptionally controlled by the algorithm (2-methylcitrate synthase, 2-methylcitrate dehydratase, 2-methylisocitrate dehydratase, and methylisocitrate lyase). This finding strongly supports that the transsulfuration pathway is the dominating pathway for cysteine biosynthesis, even though the enzymes for the energetically more efficient direct sulfhydrylation pathway have been identified in P. chrysogenum [51].