Abstract
Actinosynnema pretiosum ATCC 31280 is the producer of antitumor agent
ansamitocin P-3 (AP-3). Understanding of the AP-3 biosynthetic pathway
and the whole metabolic network in A. pretiosum is important for the
improvement of AP-3 titer. In this study, we reconstructed the first
complete Genome-Scale Metabolic Model (GSMM) Aspm1282 for A. pretiosum
ATCC 31280 based on the newly sequenced genome, with 87% reactions
having definite functional annotation. The model has been validated by
effectively predicting growth and the key genes for AP-3 biosynthesis.
Then we built condition-specific models for an AP-3 high-yield mutant
NXJ-24 by integrating Aspm1282 model with time-course transcriptome
data. The changes of flux distribution reflect the metabolic shift from
growth-related pathway to secondary metabolism pathway since the second
day of cultivation. The AP-3 and methionine metabolisms were both
enriched in active flux for the last two days, which uncovered the
relationships among cell growth, activation of methionine metabolism,
and the biosynthesis of AP-3. Furthermore, we identified four
combinatorial gene modifications for overproducing AP-3 by in silico
strain design, which improved the theoretical flux of AP-3 biosynthesis
from 0.201 to 0.372 mmol/gDW/h. Upregulation of methionine metabolic
pathway is a potential strategy to improve the production of AP-3.
Keywords: Actinosynnema pretiosum ATCC 31280, genome-scale metabolic
model, ansamitocin P-3, methionine metabolism, metabolic shift
1. Introduction
Actinosynnema pretiosum ATCC 31280 was isolated in 1977 [[32]1] and is
known as the producer of ansamitocins [[33]2]. Ansamitocins are a
series of complex polyketide compounds [[34]3], among which ansamitocin
P-3 (AP-3) was confirmed to be the most potent antitumor agent
[[35]4,[36]5]. Recently, AP-3 has been used as the payload in many
antibody-drug conjugants, such as trastuzumab emtansine, which was
approved by the FDA for breast cancer treatment [[37]6]. Although the
antitumor activity of AP-3 is highly effective, the commercial
application of AP-3 is substantially limited by its low production
titer [[38]7]. Therefore, in the past decades, many efforts have been
made to improve the production of AP-3 [[39]8,[40]9,[41]10]. These
strategies includes mutant screening, medium optimization, and genetic
engineering. However, the titer of AP-3 is still far from ideal. The
reason for limited success in the improvement of AP-3 titer is probably
due to a less understanding of the AP-3 biosynthetic pathway, which
involves multiple metabolic pathways ([42]Figure 1) and the whole
metabolic network in A. pretiosum [[43]11].
Figure 1.
[44]Figure 1
[45]Open in a new tab
Biosynthetic pathway of ansamitocin P-3 in Actinosynnema pretiosum.
AP-3: ansamitocin P-3; EMP pathway: Embden Meyerhof Parnas pathway; PP
pathway: pentose phosphate pathway; G3P: glyceraldehyde 3-phosphate;
PEP: phosphoenolpyruvate; DHAP: dihydroxyacetone phosphate; X5P:
D-xylulose 5-phosphate; UDP: uridine diphosphate; Gal:
alpha-d-Galactose; E4P: erythrose 4-phosphate; S7P: sedoheptulose
7-phosphate; PRPP: 5-phosphoribosyl 1-pyrophosphate; AHBA:
3-amino-5-hydroxybenzoic acid; F6P: fructose-6-phosphate; TCA cycle:
tricarboxylic acid cycle.
Genome-Scale Metabolic Models (GSMMs) play important roles in systems
biology [[46]12,[47]13], which aim at understanding complex
interactions between genes, proteins, and metabolites by integrating
and modeling multiple data sources [[48]14]. GSMMs can predict the
theoretical maximum production of a particular compound and simulate
the effects of genetic modification on growth and target compound
production, which provides links between genotype and phenotype of an
organism [[49]15,[50]16]. GSMMs have been widely used in studies of
overproducing target products. For example, using Esterichia coli GSMM
iJR904 [[51]17], Choi et al. found that microaerobic condition was more
efficient than aerobic condition in achieving higher titer of
4-hybroxybutyric acid in E. coli. The yield of 4-hybroxybutyric acid
was increased from 35.2 g/L to 103.4 g/L [[52]18]. Kuhn Ip et al. used
GSMM iJO1366 [[53]19] to explore the genetic manipulation strategies
for overproducing fatty acids in E. coli, resulting in a 5.4-fold
increase by the knockout of gene fadE [[54]20]. Brochado A.R. et al.
achieved a five-fold increase in vanillin production in baker’s yeast
by the overexpression of O-methyltransferase based on genome-scale
modeling approach [[55]21]. Wu et al. increased acarbose production by
78% in Actinoplanes ssp. SE50/110 based on the predicted genetic
modification strategies [[56]22].
In this study, we reconstructed and validated the first GSMM of A.
pretiosum ATCC 31280 based on the newly sequenced genome (Genebank
accession number: [57]CP029607). Then we integrated the model with
time-course transcriptome data of a high-yield mutant strain NXJ-24
[[58]23] to investigate the change of metabolic flux distribution
during the fermentation process. Furthermore, potential strategies for
improving AP-3 production were predicted by in silico strain design
based on the established model.
2. Materials and Methods
2.1. Reconstruction of the Genome-Scale Model of Actinosynnema pretiosum ATCC
31280
The genome-scale metabolic model of A. pretiosum ATCC 31280 was
reconstructed based on the newly sequenced genome, by a complicated
process of annotation, transformation, gap filling, and refinement.
Genome annotation was performed through RAST server [[59]24], and then
the draft model was reconstructed by ModelSEED [[60]25] with the
annotation. Public databases, such as KEGG, were used to manually
refine the draft model, including addition of specific reactions, such
as biosynthetic reactions for the biomass and AP-3, modification of the
reversibility of core metabolic reactions, deletion of incorrect
reactions, and filling of metabolic gaps. Some reactions obtained from
published literatures were also incorporated into the model. The final
reconstructed GSMM of A. pretiosum ATCC 31280 has 1282 genes, we called
the model Aspm1282.
2.2. Biomass Composition in Aspm1282 Model
Knowledge of the cellular biomass composition is an important
prerequisite for the in silico flux analysis, especially during the
exponential growth phase, where the primary cellular objective is to
maximize growth [[61]26]. There is no detailed information about the
biomass composition for A. pretiosum, we obtained each component and
corresponding proportion through measurement and literature mining. The
cellular compositions of A. pretiosum, consisting of lipids, proteins,
carbohydrates and so on, were mostly obtained from text books [[62]27].
The dry cell weight (DCW), consumption rate of sugar, and the yield of
AP-3 were determined by our experiment. The DNA composition was
calculated by using the G+C content. The RNA composition was calculated
based on the presumptive percentage of messenger RNA (mRNA), ribosomal
RNA (rRNA), and transfer RNA (tRNA) was 5%, 75%, and 20%, respectively.
The compositions of biomass for A. pretiosum ATCC 31280 are listed in
[63]Table S2 (Supplementary files).
2.3. Flux Balance Analysis
To perform in silico simulations and predict the metabolic
characteristics of A. pretiosum, constraint-based flux analysis was
carried out under the assumption of a pseudo-steady state [[64]28]. For
growth simulation, we set the biomass equation as the objective
function to predict the growth rate and flux distribution, the
optimization problem is formulated as following:
[MATH:
maximum: vbiomass subject to: S·v=0 aj Δ<
mo>≤v≤bj :MATH]
(1)
v is a flux vector representing a particular flux configuration, S is
the stoichiometric matrix, a[j] and b[j] are the minimum and maximum
fluxes through reaction j. We also investigated the metabolic capacity
of A. pretiosum in AP-3 production by setting AP-3 flux as the
objective function. The flux balance analysis (FBA) simulation was
performed using COBRA Toolbox [[65]29] with Gurobi [[66]30] as the
linear programming solver.
2.4. Actinosynnema pretiosum NXJ-24 Mutant and the RNA-Seq Data across
Fermentation Process
In our previous study, the NXJ-24 mutant was generated by knockout
ansa30 gene, and overexpressing asm10 gene [[67]10]. In the disruption
of ansa30 gene, two 1.5-kb homologous arms for ansa30 disruption were
respectively amplified with primers Del30-L-F/R and Del30-R-F/R,
sequenced, and together cloned to SpeI/EcoRI-digested plasmid pJTU1278
to give the ansa30-inactivation plasmid pLQ578. In the overexpression
of asm10, the kasOp promoter was cloned into BamHI/SpeI-digested
plasmid pDR3 [[68]31] to generate plasmid pDR3-K. Genes of asm10 were
amplified with primers asm10-F/R. Subsequently, the sequenced genes
were individually inserted into SpeI/EcoRI-digested plasmid pDR3-K
under the control of kasOp promoter, generating plasmids pLQ586 and
pLQ589. The recombinant plasmids were introduced into NXJ-24 from E.
coli ET12567 (pUZ8002) through intergeneric conjugation. The
transcriptome data of NXJ-24 during fermentation process of day 1, day
2, day 3, and day 5 were sequenced by Shanghai Biotechnology
Corporation, Shanghai, China. We also sequenced the transcriptome of
the wild-type strain in day 5, which was used to construct
decline-phase specific model of the wild-type for strain optimization.
2.5. Pathway Enrichment Analysis for Essential Genes and Active Reactions in
Aspm1282 Model
We used enrichment analysis to identify pathways enriched in essential
genes for AP-3 biosynthesis and active reactions during fermentation
process significantly. The hypergeometric test was used to calculate
the p-value of each pathway (Equation (2)).
[MATH:
pj=1
−∑i=0<
/mn>m−1
(Mji)(N−Mjn−i)(Nn) :MATH]
(2)
p[j] is the p-value of subsystem j, N is the total number of
reactions/genes in Aspm1282 model, M[j] is the number of
reactions/genes in subsystem j, n is the number of essential genes or
active reactions in the whole model, m is the number of essential genes
or active reactions in subsystem j.
2.6. E-FLUX Method for Condition-Specific Model Construction by Integrating
Gene Expression Data
E-FLUX is a method for modeling metabolic states under specific
conditions by integrating gene or protein expression data, which
extends the technique of FBA by modeling maximum flux constraint as a
function of measured gene expression [[69]32]. Here we set the upper
bound b[j] of each reaction as the expression value of the genes
encoding enzymes catalyzing reaction j.
[MATH:
expi
=log(FPKMi+1) :MATH]
(3)
[MATH: bj=∑i∈
rxnjex
pi :MATH]
(4)
FPKM[i] is the FPKM (fragments per kilobaseof exon per million
fragments mapped) of gene i measured by experiment, exp[i] represents
the expression level of gene i, b[j] represents the upper bound of
reaction j, rxn[j] represents the reaction j.
By this conversion, we set constraints on both lowly and highly
expressed reactions, then FBA will be run by fulfilling the same
objective function.
2.7. In Silico Strain Design Approach OptRAM
OptRAM (optimization of regulatory and metabolic network) is a
meta-heuristic strain optimization method based on GSMM, which can be
divided into three parts: prediction, random modification, simulation,
and evaluation. Firstly, we use parsimonious enzyme usage FBA (pFBA)
[[70]33] to predict the flux value of each reaction. To identify the
global optimal genetic modification strategy, we used simulated
annealing [[71]34,[72]35], which is able to accept a worse solution in
the early stage (avoiding getting stuck in local maximal). In each
iteration of simulated annealing:
1. Randomly pick up one gene and assign a random mutation code to it.
As shown in [73]Table 1, code represents the manipulation of the
mutation on selected gene, and FC is the corresponding fold change
of the mutated gene expression, which reasonably simulates the
up-regulation, down-regulation, or knockout of particular gene.
2. The expression of genes will be transformed to corresponding
reactions in the metabolic model through changing the upper bound
or lower bound of it. The range of changes is based on the
reference flux values from pFBA.
3. The phenotype of modified strain was simulated using FBA, and the
objective value was used to evaluate the mutant. OptRAM will choose
to go back to last round of iteration or accept this solution
according to the Metropolis criterion [[74]35]:
[MATH: P=eΔfT(K<
mo>)
:MATH]
(5)
T (k + 1) = T (k) × α (6)
where
[MATH: Δf :MATH]
is the difference between objective score of new solution and the
previous one, T is the control parameter, α is the attenuation
factor (α < 1). When
[MATH: Δf :MATH]
> 0 or P > R, new objective score is accepted as the new solution,
otherwise OptRAM will go back to the original solution. When OptRAM
gets a new solution, T (k + 1) = T (k) × α will be carried out.
When a certain number of iterations is reached, the solution at
that moment will be the final strain genetic modification solution.
Table 1.
Perturbation code and the corresponding fold change (FC) of mutated
gene expression.
Code 1 2 3 4 5
FC 2 4 8 16 32
Code 0 −1 −2 −3 −4 −5
FC 0.001 1/2 1/4 1/8 1/16 1/32
[75]Open in a new tab
3. Results
3.1. Reconstructed Genome-Scale Metabolic Model of A. pretiosum
The composition of model Aspm1282 is shown in [76]Table 2, including
1282 genes, 1614 metabolites, and 1669 reactions (1520 intracellular
metabolic reactions, 148 transport and exchange reactions, and 1
biomass reaction. [77]Tables S1 and S2 in Supplementary Materials).
17.61% of the total open reading frames (ORFs), corresponding to 1282
genes of 7279 ORFs, were incorporated into the model. The SBML
representation of the model can be downloaded from the supplemental
files ([78]File S1 in Supplementary Materials).
Table 2.
Composition of Genome-Scale Metabolic Models (GSMM) Aspm1282 for
Actinosynnema pretiosum ATCC 31280.
Categories Numbers
Genes 1282
Reactions 1669
Metabolites 1614
Open reading frames (ORFs) 7279
Exchange reactions 118
Transport reactions 30
Compartments 2
Subsystems 12
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According to KEGG [[80]36] and RAST [[81]37] database, the 1399
reactions with functional annotation in Aspm1282 are classified into
eight subsystems, including carbohydrate metabolism, amino acid
metabolism, energy metabolism, lipid metabolism, metabolism of
terpenoids and polyketides, metabolism of cofactors and vitamins,
biosynthesis of ansamycins, and other metabolism ([82]Figure 2). 87%
reactions have definite functional annotations, indicating a highly
completed model among actinobacteria. The lipid metabolism is the
largest subsystem with 18% reactions, followed by carbohydrate
metabolism (17%), and amino acid metabolism (15%), totally accounting
for half of the entire biological processes.
Figure 2.
[83]Figure 2
[84]Open in a new tab
Percentage of reactions in each subsystem in Aspm1282 model.
3.2. Aspm1282 Model Validation by the Prediction of Growth and Key Genes for
Ansamitocin P-3 Biosynthesis
Aspm1282 is so far the first reconstructed genome-scale model for A.
pretiosum, there are no enough standard information can be used to
validate the accuracy of the model, such as essential genes for E. coli
and yeast model evaluation [[85]38,[86]39]. We compared simulated
growth phenotypes of Aspm1282 by FBA with the experimental data. The
glucose uptake rate was set as 0.0912 mmol/gDW/h, which was the maximum
measured uptake rate. We predicted the maximal biomass flux was
0.2019/h, similar with the experimental data, 0.1792/h, which showed
that the model can simulate the growth of ATCC 31280 to some extent.
To validate the effectiveness of Aspm1282 in predicting AP-3
biosynthesis, essential gene analysis was performed by single-gene
deletion, with the flux of AP-3 production as the objective function.
There were 37 genes in the model predicted as influential genes, and 21
of them were found to be essential, whose deletions causing a decrease
of AP-3 production more than 90% ([87]Table S3 in Supplementary
Materials). The enriched pathways [[88]40] for influential genes is
shown in [89]Figure 3, and the genes in AP-3 biosynthesis pathway has
the most significant effect on AP-3 production, which is consistent
with previous finding [[90]23]. In addition, central carbohydrate
metabolism, histidine metabolism, and branched-chain amino acid pathway
are also enriched with the influential genes, providing precursors for
AP-3 biosynthesis, such as malonyl-CoA (coenzyme A), methylmalonyl-CoA,
methoxymalonyl-ACP (acyl carrier protein), glutamate, and valine.
Phosphorus metabolism involves the biosynthesis of ATP, which provides
the necessary energy for the AP-3 product. The Aspm1282 model
efficiently reflects the metabolic characteristics of AP-3
biosynthesis.
Figure 3.
[91]Figure 3
[92]Open in a new tab
Enriched pathways of the genes essential for ansamitocin P-3 (AP-3)
biosynthesis. The vertical axis represents enriched pathways, and the
horizontal axis represents the p-value of each pathway.
To further validate the accuracy of the model, we compared the
experimental data collected from published literatures ([93]Table 3)
with the phenotype predicted by Aspm1282. Previous experiments
confirmed that the expression level of specific regulatory genes
including Asm8 and Asm18, and the concentrations of metabolites
including Mg^2+, glycerol, and ammonium have a dominant impact on the
production of AP-3 [[94]8,[95]41,[96]42,[97]43,[98]44,[99]45,[100]46].
The affected genes or enzymes by these regulatory genes and metabolites
are summarized as in [101]Table 2. Then, we carried out the robustness
analysis for each key gene/enzyme and found that all genes/enzymes are
positively correlated with the production of AP-3 ([102]Text S1 in
Supplementary Materials), which proved that the Aspm1282 model can
accurately reflect the effects of the key regulatory genes and
metabolites on AP-3 biosynthesis.
Table 3.
The reported key regulators and metabolites for AP-3 production and the
robustness simulation of corresponding enzymes in the model.
Regulator/Metabolite Corresponding Enzymes in Model Simulation
Positively Correlated with AP-3
Asm8 Asm23, Asm24, Asm43, Asm44, Asm45 √
Asm18 Asm21, AsmA, Asm43 √
Mg^2+ Methylmalonyl-CoA mutase, methylmalonyl-CoA carboxyltransferase √
Glycerol Phosphoglucomutase, Asm14, Asm24 √
Ammonium Asm14, Asm24, Asm43, Asm19 √
[103]Open in a new tab
3.3. Metabolic Shift of Ansamitocin P-3 High-Yield Mutant NXJ-24 During
Fermentation Process by Condition-Specific Models
Since environment conditions have impact on the metabolic capability of
strain [[104]32], condition-specific models are required to reflect the
particular metabolic phenotype by integration with omics data. NXJ-24
is a mutant of A. pretiosum ATCC 31280 with high production of AP-3
[[105]23], and the transcriptome data of NXJ-24 mutant were obtained
with samples collected at the first, second, third, and fifth days
during fermentation process; to better understand the character of
NXJ-24 in decline phase, we chose to sequence the transcriptome at the
fifth day, instead of the fourth day. Here, we constructed
condition-specific metabolic models during the fermentation process by
integrating the transcriptome data using E-FLUX method to make
comparisons of the specific metabolic capabilities and explore the
potential factors that affect the production of AP-3. We generated the
model for NXJ-24 mutant by knocking out of asm30 in Aspm1282 model, and
the overexpression of asm10 gene was automatically converted to higher
flux bound by the mapping to transcriptome data with E-FLUX.
The growth rate, glucose uptake rate, and titer of AP-3 in each day of
cultivation were experimentally measured ([106]Figure 4). Glucose is
considered to be the main carbon source for A. pretiosum [[107]47], and
the uptake rate of glucose has great impact on the energy and
carbohydrate metabolism. The flux of glucose uptake in each day was set
as a particular value, which was calculated from the measured residue
glucose concentrations and DCW (dry cell weight) by experiment.
R[glucose] = consumption[glucose]/(DCW·molecular weight[glucose]·time)
(7)
Figure 4.
[108]Figure 4
[109]Open in a new tab
The dry cell weight (DCW) and titer of AP-3 in NXJ-24 mutant during
fermentation process.
Because simple FBA simulation with the biomass equation in the generic
Aspm1282 model as an objective function will result in no flux through
AP-3 biosynthesis pathway, we added AP-3 in the biomass function to
make a new objective in NXJ-24 specific models (Equation (8)). Then we
can observe the transformation of flux distribution over time in
ansamycin biosynthetic pathway in the high-yield mutant. The
coefficients c of AP-3 component in the objective function were
determined by the relative ratio between AP-3 titer and biomass
measured by experiment in [110]Figure 4.
Objective = Biomass + c × AP-3 (8)
In the conditional specific models of day 1, day 2, day 3, and day 5, c
is equal to 0, 0.0013, 0.0068, 0.0084 respectively.
We used FBA to calculate the flux distribution of each specific model
during cultivation process, as shown in [111]Figure 5. We selected
specific active reactions in each day, whose normalized flux was
greater than 0.5 and lower than 0 in other days. Then we found the
pathways enriched with active reactions, as shown in [112]Figure 6. The
number of active reactions and pathways on the first day is
significantly more than other days, and most of them belong to the
central carbon metabolism, nucleotide metabolism and energy metabolism,
such as citrate cycle pathway, glycolysis/gluconeogenesis pathway,
purine metabolism pathway, and carbon fixation pathways in prokaryotes.
Since the central carbon metabolism, nucleotide metabolism, and energy
metabolism are mainly related with growth and replication of cells, we
call them growth related pathways thereafter. During the fermentation
process, the percentage of growth related pathways in the enriched
active pathways is decreased. For the first two days with higher growth
rate, most of the active reactions belong to the growth related
pathways. While for the last two days, very few growth related pathways
were active, but the AP-3 biosynthesis pathway and cysteine and
methionine metabolism were significantly active. This result showed
that the replication, energy generation, and uptake of carbon source
are the main objective in the first two days, and the capacity of
growth is seriously declined in the last two days, while the AP-3
biosynthesis starts to increase.
Figure 5.
[113]Figure 5
[114]Open in a new tab
The flux distribution of NXJ-24 mutant during different fermentation
process. The rows represent the reactions in the Asmp1282.
Figure 6.
[115]Figure 6
[116]Open in a new tab
Enriched pathways of specifically active reactions in each day. The
vertical axis represents enriched pathways, and the horizontal axis
represents the p-value of enrich analysis of each pathway.
We found the metabolic shift from growth associated pathways to other
metabolism started from the second day of cultivation. Although the
growth rate was highest on the second day, the active pathway started
to transform from growth related pathways to other pathways, such as
cysteine and methionine metabolism and secondary metabolism pathway. It
indicated that the growth rate might reach maximum at the moment
between the two measurements, but the metabolic mode has changed at the
second measurement. We hope to get more precise metabolic shift pattern
with highly frequent time-course measurements during cultivation in the
future.
In addition, it has been reported that the production of AP-3 was
improved in the pentose phosphate pathway weaken mutant [[117]48]. Here
we found pentose phosphate pathway was active in the first two days,
but inactive in the last two days, when the AP-3 biosynthesis
increased.
3.4. Relationship of Methionine Pathway and Ansamitocin P-3 Biosynthesis
The metabolic shift during fermentation process indicated that the
biosynthesis of AP-3 is initiated when the cells sense stressful
conditions, similar with most secondary metabolism. The significant
high activity of cysteine and methionine metabolism in the last two
days showed that this pathway plays an important role in the
biosynthesis of AP-3. Methionine is the precursor of SAM
(S-adenosyl-l-methionine), which is the key methyl donor for three
steps of methylation reactions in AP-3 biosynthesis pathway. More
significantly, one of the methylation reactions, catalyzed by asm10,
was reported as the bottleneck in the production of AP-3, the increase
in asm10 can increase the AP-3 production by 93% [[118]23,[119]49].
To further explore the relationship among cysteine and methionine
metabolism, cell growth, and AP-3 production, we simulated the
biosynthetic velocity of key metabolites in methionine biosynthesis and
tricarboxylic acid cycle (TCA cycle), as shown in [120]Figure 7. The
biosynthetic velocity of citrate in the first day was significantly
higher than that in other days, while the velocity of aspartate,
methionine, and SAM were lower. Most flux flow into the TCA cycle on
the first day to meet the growth demand of the strain. Since the second
day, the flux turned to flow into the biosynthesis of methionine
pathway, which improve the concentration of SAM in the cell and
contribute to the biosynthesis of AP-3 [[121]50].
Figure 7.
[122]Figure 7
[123]Open in a new tab
The flux change of methionine biosynthesis and tricarboxylic acid cycle
(TCA cycle) in the specific models for day 2 (A), day 3 (B), and day 5
(C) compared with day 1. The values represent the flux through each
reaction. The colored arrow represent the ratio of flux in each day to
that of day 1. SAM: S-adenosyl-L-methionine.
3.5. Strain Optimization for Ansamitocin P-3 Overproduction by Aspm1282 Model
Using the Aspm1282 model, we aimed to identify potential engineering
strategy for AP-3 overproduction. A series of computational strain
optimization methods have been published, such as RobustKnock
[[124]51], OptGene [[125]52], OptORF [[126]53], GDLS [[127]54], and
FSEOF [[128]55]. The meta-heuristic methods such as OptGene have been
used widely, which aim to find the solution fulfilling the best
optimized function, usually biomass-product coupled yield (BPCY). But
sometimes BPCY remains 0, and the algorithm reports no feasible
solution. To better characterize the coupling between biomass and
target production, we proposed an improved objective function (Equation
(9)) in our in silico strain design approach OptRAM, which can identify
strategies for up-regulation, down-regulation or knockout of metabolic
genes by simulated annealing algorithm.
[MATH:
Obj=Target×GrowthSubstrate×(1−logRangeTarget
) :MATH]
(9)
[MATH: Target=Vmax+Vmin2
, Range=<
mrow>Vmax−Vmin2
. :MATH]
(10)
Target means the average flux value of target product. Range is set to
half of the interval between min and max target flux value.
The other advantage of OptRAM is that we incorporated an evaluation
mechanism to determine the best and feasible genetic modification
solution, by considering growth rate, product of desired compound, and
implementation cost. We ran OptRAM 25 times for the generic Aspm1282
model and the decline-phase-specific model, respectively, integrating
expression data of the wild-type strain on day 5 ([129]Table S4 in
Supplementary Materials). The average of objective score and AP-3
production flux of the two models were illustrated in [130]Figure 8,
which demonstrated that the decline-phase-specific model outperformed
generic model with both higher AP-3 production and better coupling with
growth. Therefore, the model integrated with gene expression data in
decline phase could be more suitable to simulate the metabolic pattern
of secondary-metabolite-biosynthesis strain.
Figure 8.
[131]Figure 8
[132]Open in a new tab
The mean objective score and mean AP-3 production predicted by generic
Aspm1282 model and decline-phase-specific model.
We selected the solution with the highest objective score among 25
simulations by decline-phase-specific model, which included four
genetic modification sites. The detailed annotation and expression
adjustment were shown in [133]Table 4. The mechanism of the optimized
modification strategy to improve AP-3 was illustrated in [134]Figure 9.
In this strategy, 42197.4.peg.5418 (guanylate kinase) and
42197.4.peg.5889 (uracil permease) are involved in nucleotide
synthesis. The upregulation of 42197.4.peg.5418 can improve the
biosynthesis of GTP (guanosine triphosphate) and thus promote the DNA
replication. The down regulation of uracil permease can reduce the
leakage of uracil to increase the flux rate of RNA synthesis to some
extent. 42197.4.peg.3610 (phosphoglycerate mutase) catalyzes a critical
step in glycolysis/gluconeogenesis pathway, whose upregulation can
improve the growth rate of strain. These three genetic modification
sites are all relevant to growth rate improvement. The other
modification site, upregulation of 42197.4.peg.5886 (dihydroorotate
dehydrogenase), can accelerate the biosynthesis of UDP (uridine
diphosphate), which can not only enhance growth rate, but also improve
the synthesis of UDP-glucose, a key precursor of AP-3. The
combinatorial modification of the above four genes identified by
computational simulation improved the theoretical flux of AP-3
synthesis from 0.201 to 0.372 mmol/gDW/h, and kept better growth
meanwhile. It validated that the Aspm1282 model is relatively accurate
and useful for guiding strain design.
Table 4.
The predicted modification of A. pretiosum ATCC 31280 for AP-3
overproduction.
Genes Enzymes Modifications
42197.4.peg.3610 Phosphoglycerate mutase Overexpression
42197.4.peg.5418 Guanylate kinase Overexpression
42197.4.peg.5886 Dihydroorotate dehydrogenase Overexpression
42197.4.peg.5889 Uracil permease Underexpression
[135]Open in a new tab
Objective Score = 0.388; Product = 0.372.
Figure 9.
[136]Figure 9
[137]Open in a new tab
The mechanism of the optimized modification strategy to improve AP-3
and growth. The arrows represent flux rate of particular biological
processes related with the biomass and AP-3 biosynthesis. The
modification sites identified by OptRAM are labeled with triangle, and
the red and blue ones mean overexpression or underexpression,
respectively. Red and blue colored arrows represent up- or
downregulation of the reactions in modified strain compared to the
wild-type. AP-3: ansamitocin P-3; EMP: Embden Meyerhof Parnas pathway;
UTP: uridine triphosphate; UDP: uridine diphosphate.
4. Discussion
4.1. The First Genome-Scale Metabolic Model of A. pretiosum
In this study, we reconstructed the first GSMM Aspm1282 for A.
pretiosum ATCC 31280, which provides a fundamental and useful system to
study the metabolic mechanism and guide for AP-3 overproduction. The
model Aspm1282 covers 90.7% reactions with annotated genes, and 87%
reactions with clear pathway information. Usually there are 50% genes
with accurate functional annotation for actinobacteria, while our model
accounts 87% metabolic genes with specific pathway function, which
complements the interpretation of A. pretiosum genome and also provides
a reference for other actinobacteria, such as Streptomyces coelicolor
and Sacchropolysora erythrae. The effectiveness of this model has been
confirmed by the positive effects of reported key factors and
metabolites on AP-3 production. The lack of experimental information is
still a limit for the validation of the model reconstructed here.
Further experiments on A. pretiosum time-course growth and gene
deletion should help us better refine and complete the model.
4.2. Metabolic Shift of Ansamitocin P-3 High-Yield Mutant NXJ-24 during
Fermentation Process
As shown in [138]Figure 5, it was obvious that the number of specific
active reactions in the first day is significantly greater than the
other days, which indicated that the strain is relative vigorous in the
first day. [139]Figure 6 illustrated that during the fermentation
process, the percentage of the active growth related pathways
decreased, and there is even no enriched growth related pathway in the
last two days. The changes of flux distribution of condition-specific
model can well reflect the metabolic shift from growth related pathway
to other pathways such as amino acid metabolism and secondary
metabolism pathway since the second day of cultivation. The AP-3 and
cysteine and methionine metabolisms were enriched in the last two days,
which indicated there are certain relationships among cell growth,
activation of cysteine and methionine metabolism, and the biosynthesis
of AP-3.
4.3. Up-Regulation of Methionine Biosynthetic Pathway May Be a Potential
Strategy to Improve the Production of Ansamitocin P-3
Both the significantly active methionine pathway in the latter stage of
fermentation and the relationship between methionine pathway and AP-3
biosynthesis indicated that the methionine pathway could be a
potentially important pathway for AP-3 overproduction. It was reported
that the N-methylation reaction, S-adenosyl-l-methionine +
N-demethyl-ansamitocin P-3 → S-adenosyl-l-homocysteine + ansamitocin
P-3 (named [140]R09852 in KEGG database), catalyzed by Asm10, was one
of the bottlenecks in AP-3 biosynthesis [[141]23]. As a substrate of
[142]R09852, the biosynthesis velocity of SAM and its main precursor,
methionine, could have a prominent impact on the production of AP-3. As
shown in [143]Figure 7A, it was obvious that with the change of
metabolic pattern at the second day, the flux was diverted to aspartate
from citrate. Because aspartate is the beginning of methionine pathway,
this metabolic shift could promote the accumulation of methionine and
thus increase the production of AP-3. For the predicted engineering
strategy obtained from OptRAM, we also found gene 42197.4.peg.5105
(5-methyltetrahydrofolate-homocysteine methyltransferase) involved in
methionine biosynthesis. As mentioned above, the up-regulation of it
may improve the biosynthesis of SAM.
4.4. Application of the Reconstructed Model in Strain Design for Ansamitocin
P-3 Overproduction
In actual industrial production, the target production efficiency is
determined by both the biomass and flux of the target compound.
Therefore, we set Obj as the evaluation of strain modification, which
considers biomass and product simultaneously. We used OptRAM method to
simulate Aspm1282 model and identify a modification strategy for AP-3
overproduction, which enhances the EMP pathway (Embden Meyerhof Parnas
pathway), reduces the release of uracil, and improves the biosynthesis
of UTP and GTP. EMP is an important pathway that provides energy and
carbon skeleton for biomass. The improvement of UTP and GTP
biosynthesis can promote the replication of DNA and the transcription
of RNA, both of which are essential for biomass. What is more, the
biosynthesis of UTP directly affects the production of AP-3 through the
biosynthesis of UDP-glucose, one of the precursors for AP-3. All these
modification sites demonstrated that the strain optimization by our
newly reconstructed model is of great potential for real application in
AP-3 overproduction.
Supplementary Materials
The following are available online at
[144]http://www.mdpi.com/2073-4425/9/7/364/s1, File S1: The SBML file
of reconstructed genome-scale model Aspm1282 for A. pretiosum ATCC
31280, Table S1: List of reactions in Aspm1282 model, Table S2:
Compositions of biomass for A. pretiosum ATCC 31280, Table S3: The
effects of single gene deletions on AP-3 biosynthesis flux predicted by
Aspm1282 model, Table S4: The strain optimization solutions of OptRAM
for improving AP-3 by generic model and Decline-phase-specific model,
Text S1: The positive correlation between AP-3 production with
enzyme-catalyzing-reactions affected by literature-reported regulatory
genes and metabolites for AP-3.
[145]Click here for additional data file.^ (358.7KB, zip)
Author Contributions
J.L. reconstructed and validated the model, performed the in silico
strain design, and wrote the manuscript; R.S. refined the model
according to the literature and experimental measurements. X.N. made
samples of A. pretiosum during the fermentation process for
RNA-Sequencing. X.W. collected the set of key factors for AP-3
biosynthesis for model validation. Z.W. designed the project, analyzed
data, and wrote the manuscript.
Funding
This research was funded by Shanghai Natural Science Funding grant
number 16ZR1449700, Scientific Research Foundation for the Returned
Overseas Chinese Scholars of the State Education Ministry grant number
15Z102050028, National Key Research and Development Plan of China grant
number 2017YFC0908105 and the Science Fund for Creative Research Groups
of the National Natural Science Foundation of China grant number
81421061.
Conflicts of Interest
The authors declare no conflicts of interest.
References