Rational Design of a
            <i>Corynebacterium glutamicum</i>
            Pantothenate Production Strain and Its Characterization by Metabolic Flux Analysis and Genome-Wide Transcriptional Profiling

Hüser, Andrea T.; Chassagnole, Christophe; Lindley, Nic D.; Merkamm, Muriel; Guyonvarch, Armel; Elišáková, Veronika; Pátek, Miroslav; Kalinowski, Jörn; Brune, Iris; Pühler, Alfred; Tauch, Andreas

doi:10.1128/aem.71.6.3255-3268.2005

Cited by 98 publications

(50 citation statements)

References 54 publications

(54 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…As shown here for L-lysine, the strain engineered to generate NADPH through 22 glycolysis is likely to be an effective host for other NADPH-requiring compounds, such as other amino acids , commodity chemicals (Kind et al, 2011;Song et al, 2013), vitamins (Hüser et al, 2005;, fatty acids , and carotenoids (Heider et al, 2012). The results of the present study will pave the way for efficient production of these compounds.…”

Section: Discussionmentioning

confidence: 85%

l -Lysine production independent of the oxidative pentose phosphate pathway by Corynebacterium glutamicum with the Streptococcus mutans gapN gene

Takeno

Hori

Ohtani

et al. 2016

Metabolic Engineering

View full text Add to dashboard Cite

We have recently developed a Corynebacterium glutamicum strain that generates NADPH via the glycolytic pathway by replacing endogenous NAD-dependent glyceraldehyde 3-phosphate dehydrogenase (GapA) with a nonphosphorylating NADP-dependent glyceraldehyde 3-phosphate dehydrogenase (GapN) from Streptococcus mutans. Strain RE2, a suppressor mutant spontaneously isolated for its improved growth on glucose from the engineered strain, was proven to be a high-potential host for L-lysine production (Takeno et al., 2010). In this study, the suppressor mutation was identified to be a point mutation in rho encoding the transcription termination factor Rho. Strain RE2 still showed retarded growth despite the mutation rho696. Our strategy for reconciling improved growth with a high level of L-lysine production was to use GapA together with GapN only in the early growth phase, and subsequently shift this combination-type glycolysis to one that depends only on GapN in the rest of the growth phase. To achieve this, we expressed gapA under the 2 myo-inositol-inducible promoter of iolT1 encoding a myo-inositol transporter in strain RE2. The resulting strain RE2A iol was engineered into an L-lysine producer by introduction of a plasmid carrying the desensitized lysC, followed by examination for culture conditions with myo-inositol supplementation. We found that as a higher concentration of myo-inositol was added to the seed culture, the following fermentation period became shorter while maintaining a high level of L-lysine production. This finally reached a fermentation period comparable to that of the control GapA strain, and yielded a 1.5-fold higher production rate compared with strain RE2. The transcript level of gapA, as well as the GapA activity, in the early growth phase increased in proportion to the myo-inositol concentration and then fell to low levels in the subsequent growth phase, indicating that improved growth was a result of increased GapA activity, especially in the early growth phase. Moreover, blockade of the pentose phosphate pathway through a defect in glucose 6-phosphate dehydrogenase did not significantly affect L-lysine production in the engineered GapN strains, while a drastic decrease in L-lysine production was observed for the control GapA strain. Determination of the intracellular NADPH/NADP + ratios revealed that the ratios in the engineered strains were significantly higher than the ratio of the control GapA strain irrespective of the pentose phosphate pathway. These results demonstrate that our strain engineering strategy allows efficient L-lysine production independent of the oxidative pentose phosphate pathway.

show abstract

Section: Discussionmentioning

confidence: 85%

l -Lysine production independent of the oxidative pentose phosphate pathway by Corynebacterium glutamicum with the Streptococcus mutans gapN gene

Takeno

Hori

Ohtani

et al. 2016

Metabolic Engineering

View full text Add to dashboard Cite

show abstract

“…The bacterium often shows a V-shaped cell form under the microscope, and its coryneform rod-shaped cells have one side of their poles slightly wider than the other. Since its unique characteristics enable it to produce such large amounts of amino acids, most C. glutamicum research has remained focused on the creation of highly productive strains on the one hand and analysis of metabolic flow regulation on the other (14,15,32). Consequently, the unusual behavior of the bacterium to produce V-shaped cells has elicited less research attention.…”

mentioning

confidence: 99%

Deletion of cgR_1596 and cgR_2070, Encoding NlpC/P60 Proteins, Causes a Defect in Cell Separation in Corynebacterium glutamicum R

et al. 2008

View full text Add to dashboard Cite

In previous work, random genome deletion mutants of Corynebacterium glutamicum R were generated using the insertion sequence (IS) element IS31831 and the Cre/loxP excision system. One of these mutants, C. glutamicum strain RD41, resulting from the deletion of a 10.1-kb genomic region (⌬cgR_1595 through cgR_ 1604) from the WT strain, showed cell elongation, and several lines appeared on the cell surface (bamboo shape). The morphological changes were suppressed by overexpression of cgR_1596. Single disruption of cgR_ 1596 in WT C. glutamicum R resulted in morphological changes similar to those observed in the RD41 strain. CgR_1596 has a predicted secretion signal peptide in the amino-terminal region and a predicted NlpC/P60 domain, which is conserved in cell wall hydrolases, in the carboxyl-terminal region. In C. glutamicum R, CgR_ 0802, CgR_1596, CgR_2069, and CgR_2070 have the NlpC/P60 domain; however, only simultaneous disruption of cgR_1596 and cgR_2070, and not cgR_2070 single disruption, resulted in cell growth delay and more severe morphological changes than disruption of cgR_1596. Transmission electron microscopy revealed multiple septa within individual cells of cgR_1596 single and cgR_1596-cgR_2070 double disruptants. Taken together, these results suggest that cgR_1596 and cgR_2070 are involved in cell separation and cell growth in C. glutamicum.The gram-positive, high-GC-content bacterium Corynebacterium glutamicum has been one of the most important bacteria in industry for several decades due to its high production of amino acids such as glutamate (16). The bacterium often shows a V-shaped cell form under the microscope, and its coryneform rod-shaped cells have one side of their poles slightly wider than the other. Since its unique characteristics enable it to produce such large amounts of amino acids, most C. glutamicum research has remained focused on the creation of highly productive strains on the one hand and analysis of metabolic flow regulation on the other (14,15,32). Consequently, the unusual behavior of the bacterium to produce V-shaped cells has elicited less research attention. The cell division system resulting in V-shaped cells is known as snapping division (37). Besides C. glutamicum, other Actinomycetales such as Arthorobacter, Nocardia, and Mycobacteria are known to produce V-shaped cells (9,18,28,38). Although several genes involved in cell division (13,17,20,30,34,47) and cell morphology (21,35,44,45) in C. glutamicum have been characterized, the molecular mechanism of the snapping division is still largely unknown.Cell division is achieved by the consecutive actions of cell extension, chromosome replication and segregation, and cell separation. In most prokaryotic and eukaryotic species, cell separation starts by constriction and the subsequent formation of two equivalent daughter cells. After completion of chromosome replication and segregation of the daughter chromosomes to the two halves of the cell, constriction occurs at a predetermined site and two progeny cells are produced. ...

show abstract

“…Rational metabolic engineering by specific targeted modifications can overcome this disadvantage. The recent development of omics technology, combined with computational analysis, now provides a new avenue for strain improvement (1)(2)(3)(4) by providing new information extracted from a large number of data, which is termed ''systems biotechnology'' (5).…”

mentioning

confidence: 99%

Metabolic engineering of Escherichia coli for the production of l -valine based on transcriptome analysis and in silico gene knockout simulation

Park¹,

Lee²,

Kim³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

501

306

View full text Add to dashboard Cite

The L-valine production strain of Escherichia coli was constructed by rational metabolic engineering and stepwise improvement based on transcriptome analysis and gene knockout simulation of the in silico genome-scale metabolic network. Feedback inhibition of acetohydroxy acid synthase isoenzyme III by L-valine was removed by site-directed mutagenesis, and the native promoter containing the transcriptional attenuator leader regions of the ilvGMEDA and ilvBN operon was replaced with the tac promoter. The ilvA, leuA, and panB genes were deleted to make more precursors available for L-valine biosynthesis. This engineered Val strain harboring a plasmid overexpressing the ilvBN genes produced 1.31 g/liter L-valine. Comparative transcriptome profiling was performed during batch fermentation of the engineered and control strains. Among the down-regulated genes, the lrp and ygaZH genes, which encode a global regulator Lrp and L-valine exporter, respectively, were overexpressed. Amplification of the lrp, ygaZH, and lrp-ygaZH genes led to the enhanced production of L-valine by 21.6%, 47.1%, and 113%, respectively. Further improvement was achieved by using in silico gene knockout simulation, which identified the aceF, mdh, and pfkA genes as knockout targets. The VAMF strain (Val ⌬aceF ⌬mdh ⌬pfkA) overexpressing the ilvBN, ilvCED, ygaZH, and lrp genes was able to produce 7.55 g/liter L-valine from 20 g/liter glucose in batch culture, resulting in a high yield of 0.378 g of L-valine per gram of glucose. These results suggest that an industrially competitive strain can be efficiently developed by metabolic engineering based on combined rational modification, transcriptome profiling, and systems-level in silico analysis.systems biology ͉ global regulator ͉ exporter ͉ in silico prediction M ost amino acid-producing bacterial strains have been constructed by random mutagenesis. A significant disadvantage of this approach is the possibility that the random distribution of mutations in regions not directly related to amino acid biosynthesis can cause unwanted changes in physiology and growth retardation. Rational metabolic engineering by specific targeted modifications can overcome this disadvantage. The recent development of omics technology, combined with computational analysis, now provides a new avenue for strain improvement (1-4) by providing new information extracted from a large number of data, which is termed ''systems biotechnology'' (5).L-valine, an essential hydrophobic and branched-chain amino acid, is used as a component of cosmetics and pharmaceuticals as well as animal feed additives. L-valine has been produced by employing bacteria belonging to the genera Brevibacterium, Corynebacterium, and Serratia, which have been improved by random mutation and selection (6, 7). A recent report describes the production of L-valine by rationally constructed Corynebacterium glutamicum, in which a feedback inhibition-resistant small subunit of acetohydroxy acid synthase (AHAS; encoded by ilvN) was generated by site-directed mutagen...

show abstract

Rational Design of a Corynebacterium glutamicum Pantothenate Production Strain and Its Characterization by Metabolic Flux Analysis and Genome-Wide Transcriptional Profiling

Cited by 98 publications

References 54 publications

l -Lysine production independent of the oxidative pentose phosphate pathway by Corynebacterium glutamicum with the Streptococcus mutans gapN gene

l -Lysine production independent of the oxidative pentose phosphate pathway by Corynebacterium glutamicum with the Streptococcus mutans gapN gene

Deletion of cgR_1596 and cgR_2070, Encoding NlpC/P60 Proteins, Causes a Defect in Cell Separation in Corynebacterium glutamicum R

Metabolic engineering of Escherichia coli for the production of l -valine based on transcriptome analysis and in silico gene knockout simulation

Contact Info

Product

Resources

About