Scaffoldless engineered enzyme assembly for enhanced methanol utilization

Price, J. M.; Chen, Long; Whitaker, W. Brian; Papoutsakis, Eleftherios T.; Chen, Wilfred

doi:10.1073/pnas.1601797113

Cited by 100 publications

(100 citation statements)

References 42 publications

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“…By selecting Mdh, Hps, and Phi enzymes with high activities and employing the fusing engineering strategy, accelerated F6P formation from methanol was achieved in vitro. When purified enzymes were used at a concentration of 1 μ m , the highest F6P formation rate reached 1.45 μ m min −1 , which was above the previously engineered self‐assembly Mdh‐Hps‐Phi complex (67.7 μ m F6P produced in 14 h) . Although the fusion proteins worked well in vitro, its application in vivo still faced challenges.…”

Section: Resultsmentioning

confidence: 77%

“…Next, the formation efficiency of F6P was used to evaluate the performance of fusion proteins on methanol bioconversion (Figure A). A cascade reaction was set up for F6P formation from methanol and ribose‐5‐phosphate (R5P) and detection according to a procedure described previously . In the formation phase, in addition to Mdh, Hps and Phi, phosphoriboisomerase (Rpi) was required to convert R5P to the formaldehyde accepter Ru5P.…”

Section: Resultsmentioning

confidence: 99%

“…Price et al. used the decameric Mdh3 from Bacillus methanolicus MGA3, the artificial Hps‐Phi fusion from Mycobacterium gastri MB19, and the well‐known interaction pair SH3 and its ligand (sSH3lig), to construct Mdh3‐sSH3lig and SH3‐Hps‐Phi that can self‐assemble into a scaffoldless supramolecular enzyme complex . This resulted in significantly increased F6P formation efficiency from methanol in vitro.…”

Section: Introductionmentioning

confidence: 99%

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Engineering Artificial Fusion Proteins for Enhanced Methanol Bioconversion

et al. 2018

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Methanol is a low‐cost and abundantly available feedstock derived from natural gas and syngas. Although bioconversion holds promise for producing desired chemicals from methanol under economically viable operating conditions, the efficiency is limited by unfavorable kinetics of methanol oxidation and assimilation. Herein, artificial fusion proteins were engineered to enhance methanol bioconversion. Nicotinamide adenine dinucleotide (NAD)‐dependent methanol dehydrogenase (Mdh), 3‐hexulose‐6‐phosphate synthase (Hps) and 6‐phospho‐3‐hexuloisomerase (Phi) from different sources were first screened for catalytic activity. Next, we designed six fusion proteins using the best enzyme candidates and flexible linkers. Fusing Mdh with Hps or Hps‐Phi increased the Vmax of methanol oxidation up to 5.8‐fold, and enhanced methanol conversion to fructose‐6‐phosphate up to 1.3‐fold. Interestingly, fusion engineering changed the polymerization states of proteins and produced larger multimers, which may be responsible for the changed catalytic characteristics. This fusion engineering approach can be coupled with other metabolic engineering strategies for enhanced methanol bioconversion to valuable chemicals.

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Section: Resultsmentioning

confidence: 77%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Engineering Artificial Fusion Proteins for Enhanced Methanol Bioconversion

et al. 2018

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“…On the contrary, the linear formaldehyde assimilation pathway used in this study only requires one enzyme FLS and directly produces C3 intermediate DHA, which could be a great advantage for pathway engineering. Previous and the present studies revealed that constructing synthetic methylotrophs was far more complicated than complementing metabolic pathways where several crucial factors need to be considered, such as how to keep the intracellular formaldehyde concentration below the toxicity threshold (Witthoff et al 2015) and how to balance the reducing equivalent generated by methanol oxidation (Price et al 2016). In this case, combining metabolic engineering and adaptive evolution could be an easy strategy to prepare a desirable mutant that assimilates methanol efficiently.…”

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confidence: 84%

Biological conversion of methanol by evolved Escherichia coli carrying a linear methanol assimilation pathway

Wang

Liu

et al. 2017

Bioresour. Bioprocess.

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Background:Methanol is regarded as a biorenewable platform feedstock because nearly all bioresources can be converted into methanol through syngas. Biological conversion of methanol using synthetic methylotrophs has thus gained worldwide attention.Results: Herein, to endow Escherichia coli with the ability to utilize methanol, an artificial linear methanol assimilation pathway was assembled in vivo for the first time. Distinct from native cyclic methanol utilization pathways, such as ribulose monophosphate cycle, the linear pathway requires no formaldehyde acceptor and only consists of two enzymatic reactions: oxidation of methanol into formaldehyde by methanol dehydrogenase and carboligation of formaldehyde into dihydroxyacetone by formolase. After pathway engineering, genome replication engineering assisted continuous evolution was applied to improve methanol utilization. 13C-methanol-labeling experiments showed that the engineered and evolved E. coli assimilated methanol into biomass. Conclusions:This study demonstrates the usability of the linear methanol assimilation pathway in bioconversion of C1 resources such as methanol and methane.

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“…Meanwhile, methanol possesses a higher degree of reduction than traditional sugars do (Whitaker et al 2015). Although efforts have been focused on engineering native or synthetic methylotrophs to convert methanol for the production of biochemical metabolites, the effects are still at the rudimentary level owing to the limited genetic tools for native methylotrophs and the weak methanol consumption abilities of the artificial modified methylotrophs (Whitaker et al 2015;Price et al 2016). Pichia pastoris is a natural methylotrophic yeast that can utilize methanol for growth to high cell densities (Yang and Zhang 2017).…”

Section: Introductionmentioning

confidence: 99%

Improved methanol-derived lovastatin production through enhancement of the biosynthetic pathway and intracellular lovastatin efflux in methylotrophic yeast

Liu

Bai

et al. 2018

Bioresour. Bioprocess.

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Background: Methanol has attracted interest as a substrate for improvement of product titers and yields of bioprocesses, because methanol has a more reduced state than sugars do and can be renewably synthesized from abundant natural gas supplies. Our aim was to engineer methylotrophic Pichia pastoris to convert methanol into value-added lovastatin more productively. Results:A strengthened biosynthetic pathway of lovastatin was constructed through the assembly of three modules with increasing module-specific antibiotic stress in the methylotrophic yeast P. pastoris. The resulting strain (P. p/LV_V#9) produced 287.5 ± 2.0 mg/L lovastatin in a 5-L bioreactor from methanol. The production was further improved by identification and overexpression of a statin pump protein, TapA, a membrane protein capable of lovastatin efflux out of the cell. A TapA-overexpressing strain, P. p/LV_V#9-TapA, produced 419.0 ± 9.5 mg/L lovastatin from methanol: 46% more than P. p/LV_V#9 did, and 520% more relative to the strain (P. p/LV_SC) with single-copy genes. Conclusions:A methylotrophic yeast strain producing 419.0 ± 9.5 mg/L lovastatin was constructed by optimization of biosynthetic gene dosages and coexpression of a statin pump protein; these results proved that P. pastoris is a promising chassis organism for natural-product biosynthesis. A membrane protein, TapA was found to perform the function of exporting intracellular lovastatin and enhanced lovastatin production.

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Scaffoldless engineered enzyme assembly for enhanced methanol utilization

Cited by 100 publications

References 42 publications

Engineering Artificial Fusion Proteins for Enhanced Methanol Bioconversion

Engineering Artificial Fusion Proteins for Enhanced Methanol Bioconversion

Biological conversion of methanol by evolved Escherichia coli carrying a linear methanol assimilation pathway

Improved methanol-derived lovastatin production through enhancement of the biosynthetic pathway and intracellular lovastatin efflux in methylotrophic yeast

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