Proteome Reference Map and Comparative Proteomic Analysis between a Wild Type<i>Clostridium acetobutylicum</i>DSM 1731 and its Mutant with Enhanced Butanol Tolerance and Butanol Yield

Mao, Shaoming; Luo, Yuanming; Zhang, Tianrui; Li, Jinshan; Bao, Guanhui; Zhu, Yan; Chen, Zugen; Zhang, Yanping; Li, Yin; Ma, Yanhe

doi:10.1021/pr9012078

Cited by 116 publications

(104 citation statements)

References 70 publications

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“…In addition, it facilitates the first step in the formation of acetone (Andersch et al 1983;. This view is supported by several experimental studies which had observed an increased transcription of the encoding genes, ctfA and ctfB, which are part of the sol operon (Grimmler et al 2011;Jones et al 2008), and an increased intracellular concentration of the protein during the pH-induced shift and during solventogenesis (Janssen et al 2010;Mao et al 2010). However, recent experimental evidence indicates that an alternative re-assimilation mechanism for butyrate could exist which is independent of the CoA-transferase (Desai et al 1999;Lehmann et al 2012a) and may rely on a pH-dependent reverse activity of the butyrate forming enzymes (Desai et al 1999;Lehmann et al 2012b).…”

Section: Introductionmentioning

confidence: 70%

“…During exponential growth acetate and butyrate are produced (acidogenic phase). This type of anaerobic metabolism enables the organism to gain the maximal amount of energy (ATP) per mole glucose using substrate-level phosphorylation (Madigan et al 2009). During the transition to the stationary phase the metabolism switches to the formation primarily of acetone and butanol (solventogenic phase).…”

Section: Introductionmentioning

confidence: 99%

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Coenzyme A-transferase-independent butyrate re-assimilation in Clostridium acetobutylicum—evidence from a mathematical model

Millat

Voigt

Janssen

et al. 2014

Appl Microbiol Biotechnol

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(2014) Coenzyme A-transferaseindependent butyrate re-assimilation in Clostridium acetobutylicum -evidence from a mathematical model. Applied Microbiology and Biotechnology, 98 (21 A note on versions:The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher's version. Please see the repository url above for details on accessing the published version and note that access may require a subscription.For more information, please contact eprints@nottingham.ac.uk Coenzyme A-transferase-independent butyrate re-assimilation in Clostridium acetobutylicum -Evidence from a mathematical model Abstract: The hetero-dimeric CoA-transferase CtfA/B is believed to be crucial for the metabolic transition from acidogenesis to solventogenesis in Clostridium acetobutylicum as part of the industrial-relevant acetone-butanol-ethanol (ABE) fermentation. Here, the enzyme is assumed to mediate re-assimilation of acetate and butyrate during a pH-induced metabolic shift and to faciliate the first step of acetone formation from acetoacetyl-CoA. However, recent investigations using phosphate-limited continuous cultures have questioned this common dogma.To adress the emerging experimental discrepancies, we investigated the mutant strain Cac-ctfA398s::CT using chemostat cultures. As a consequence of this mutation, the cells are unable to express functional ctfA and are thus lacking CoA-transferase activity. A mathematical model of the pH-induced metabolic shift, which was recently developed for the wild type, is used to analyse the observed behaviour of the mutant strain with a focus on re-assimilation activities for the two produced acids.Our theoretical analysis reveals that the ctfA mutant still re-assimilates butyrate, but not acetate. Based upon this finding, we conclude that C. acetobutylicum possesses a CoA-tranferase-independent butyrate uptake mechanism that is activated by decreasing pH levels. Furthermore, we observe that butanol formation is not inhibited under our experimental conditions, as suggested by previous batch culture experiments. In concordance with recent batch experiments, acetone formation is abolished in chemostat cultures using the ctfa mutant.

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Section: Introductionmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Coenzyme A-transferase-independent butyrate re-assimilation in Clostridium acetobutylicum—evidence from a mathematical model

Millat

Voigt

Janssen

et al. 2014

Appl Microbiol Biotechnol

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“…The gel was stained with Coomassie Blue after electrophoresis. The putative recombinant protein in the SDS-PAGE gel was cut out, and then matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analysis was performed as described by Mao et al 31) For protein purification, the selected transformant and the transformant with an empty vector were fermented under the same culture conditions. The proteins in the supernatant fluid, the volume of which was normalized according to the OD600 value, were precipitated with 50% ammonium sulphate overnight.…”

Section: Methodsmentioning

confidence: 99%

The Function of Snodprot in the Cerato-Platanin Family fromDactylellina cionopagain Nematophagous Fungi

Duan²,

Wang

et al. 2012

Bioscience, Biotechnology, and Biochemistry

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“…We applied a similar procedure to engineering n-butanol tolerance -E. coli cells carrying pQ-lib were serially transferred in media containing gradually increased n-butanol concentrations. Considering that improvement of complex traits such as n-butanol tolerance might require accumulation of much more adaptive mutations [31,32], the pQ-lib carrying cells were transferred in each n-butanol concentrations for three times, upon full growth, before transferring to the next higher butanol concentration. Figure 4A showed that pQ-lib carrying cells exhibited a better adaptability to the increased n-butanol concentrations.…”

Section: Greace Can Be Successfully Applied To Engineer N-butanol Andmentioning

confidence: 99%

Genome Replication Engineering Assisted Continuous Evolution (GREACE) to Improve Microbial Tolerance for Biofuels Production

Luan¹,

Zhang²,

Li³

et al. 2015

New Microbial Technologies for Advanced Biofuels

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Background: Microbial production of biofuels requires robust cell growth and metabolism under tough conditions. Conventionally, such tolerance phenotypes were engineered through evolutionary engineering using the principle of "Mutagenesis followed-by Selection". The iterative rounds of mutagenesis-selection and frequent manual interventions resulted in discontinuous and inefficient strain improvement processes. This work aimed to develop a more continuous and efficient evolutionary engineering method termed as "Genome Replication Engineering Assisted Continuous Evolution" (GREACE) using "Mutagenesis coupled-with Selection" as its core principle. Results: The core design of GREACE is to introduce an in vivo continuous mutagenesis mechanism into microbial cells by introducing a group of genetically modified proofreading elements of the DNA polymerase complex to accelerate the evolution process under stressful conditions. The genotype stability and phenotype heritability can be stably maintained once the genetically modified proofreading element is removed, thus scarless mutants with desired phenotypes can be obtained. Kanamycin resistance of E. coli was rapidly improved to confirm the concept and feasibility of GREACE. Intrinsic mechanism analysis revealed that during the continuous evolution process, the accumulation of genetically modified proofreading elements with mutator activities endowed the host cells with enhanced adaptation advantages. We further showed that GREACE can also be applied to engineer n-butanol and acetate tolerances. In less than a month, an E. coli strain capable of growing under an n-butanol concentration of 1.25% was isolated. As for acetate tolerance, cell growth of the evolved E. coli strain increased by 8-fold under 0.1% of acetate. In addition, we discovered that adaptation to specific stresses prefers accumulation of genetically modified elements with specific mutator strengths. Conclusions: We developed a novel GREACE method using "Mutagenesis coupled-with Selection" as core principle. Successful isolation of E. coli strains with improved n-butanol and acetate tolerances demonstrated the potential of GREACE as a promising method for strain improvement in biofuels production.

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Proteome Reference Map and Comparative Proteomic Analysis between a Wild TypeClostridium acetobutylicumDSM 1731 and its Mutant with Enhanced Butanol Tolerance and Butanol Yield

Cited by 116 publications

References 70 publications

Coenzyme A-transferase-independent butyrate re-assimilation in Clostridium acetobutylicum—evidence from a mathematical model

Coenzyme A-transferase-independent butyrate re-assimilation in Clostridium acetobutylicum—evidence from a mathematical model

The Function of Snodprot in the Cerato-Platanin Family fromDactylellina cionopagain Nematophagous Fungi

Genome Replication Engineering Assisted Continuous Evolution (GREACE) to Improve Microbial Tolerance for Biofuels Production

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