Engineering marine fungi for conversion of d-galacturonic acid to mucic acid

Vidgren, Virve; Halinen, Satu; Tamminen, Anu; Olenius, Susanna; Wiebe, Marilyn G.

doi:10.1186/s12934-020-01411-3

Cited by 10 publications

(14 citation statements)

References 34 publications

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“…Strain D-221704 (VTT culture collection, formerly referred to as T2) was engineered from Trichoderma sp LF328 (courtesy of Prof. Dr. Johannes Imhoff, GEOMAR Helmholtz Centre for Ocean Research Kiel, Germany) by inserting a gene encoding uronate dehydrogenase under a strong synthetic promoter in the D-galacturonate reductase gene ( gar2 ), as described by Vidgren et al ( 2020b ). Spore suspensions were prepared by cultivating the fungus on potato-dextrose agar (BD, Sparks, Maryland, USA) for 7 days, after which the spores were collected from the surface of the culture in a solution containing 0.8% (w/v) NaCl, 0.025% (v/v) Tween20 and 20% (v/v) glycerol and stored at −80 °C.…”

Section: Methodsmentioning

confidence: 99%

“…It is available in relatively large quantities in the pectin found in citrus peel and sugar beet pulp, only part of which is needed or can be used in food products. Several publications have reported the use of genetically engineered fungi to convert D-galacturonic acid to mucic (galactaric) acid (Mojzita et al 2010 ; Kuivanen et al 2016 , 2019 ; Barth and Wiebe 2017 ; Vidgren et al 2020b ). Mucic acid is a symmetrical hexaric acid i.e.…”

Section: Introductionmentioning

confidence: 99%

“…Production in small scale batch cultures may be limited because of sequential use of the co-substrate and the D-galacturonic acid (Mojzita et al 2010 ) or by oxygen limitation. In fed-batch cultures, concentrations of 20 (Barth and Wiebe 2017 ; Paasikallio et al 2017 ) to 25 (Vidgren et al 2020b ) g L −1 have been obtained with the filamentous fungi Trichoderma reesei D-161646 and a marine Trichoderma sp. LF328 T2 (VTTCC D-221704).…”

Section: Introductionmentioning

confidence: 99%

“…The bioconversion process with D-161646 was successfully scaled up to 250 L, but the authors acknowledged that 20 g L −1 was still a low concentration for an efficient process, even though mucic acid can readily be precipitated from the solution at low pH (Paasikallio et al 2017 ). The recently developed T2 strain may have higher production potential than D-161646 (Vidgren et al 2020b ), but conditions for good production were not explored.…”

Section: Introductionmentioning

confidence: 99%

“…We describe here an assessment of pH, yeast extract and co-substrate concentrations in fed-batch cultivation to produce mucic acid from D-galacturonic acid using the marine Trichoderma sp. LF328 T2 (D-221704) that was genetically engineered to produce mucic acid by incorporating a uronate dehydrogenase gene under a strong synthetic promoter that would not be subject to glucose repression (Vidgren et al 2020b ). The cultivations were carried out in 110–150 mL cultures using an ambr ® 250 system, demonstrating its suitability for use with a filamentous fungus.…”

Section: Introductionmentioning

confidence: 99%

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Use of ambr®250 to assess mucic acid production in fed-batch cultures of a marine Trichoderma sp. D-221704

et al. 2022

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Mucic acid, a diacid with potential use in the food, cosmetic, chemical and pharmaceutical industries, can be produced by microbial conversion of D-galacturonic acid, which is abundant in pectin. Using the ambr®250 bioreactor system, we found that a recently generated transformant (D-221704, formerly referred to as T2) of a marine Trichoderma species produced up to 53 g L−1 mucic acid in glucose-limited fed-batch culture with D-galacturonic acid in the feed at pH 4, with a yield of 0.99 g mucic acid per g D-galacturonic acid consumed. Yeast extract was not essential for high production, but increased the initial production rate. Reducing the amount of glucose as the co-substrate reduced the amount of mucic acid produced to 31 g L−1. Mucic acid could also be produced at pH values less than 4.0 (3.5 and 3.0), but the amount produced was less than at pH 4.0. Furthermore, the yield of mucic acid on D-galacturonic acid at the end of the cultivations (0.5 to 0.7 g g−1) at these low pH levels suggested that recovery may be more difficult at lower pH on account of the high level of crystal formation. Another strain engineered to produce mucic acid, Trichoderma reesei D-161646, produced only 31 g L−1 mucic acid under the conditions used with D-221704.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Use of ambr®250 to assess mucic acid production in fed-batch cultures of a marine Trichoderma sp. D-221704

et al. 2022

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The oxidation of d‐galactose into mucic acid (galactaric acid): experimental and computational insights towards a bio‐based platform chemical

Pasquale,

Chiacchio,

Acciaretti

et al. 2024

Asian J Org Chem

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Aldaric acids are becoming valuable platform chemicals in bioeconomy and circular economy approaches. Among them, mucic acid (meso‐galactaric acid) is gaining industrial attention as a bio‐based precursor of adipic acid found in polyamides, and of 2,5‐furan dicarboxylic acid, a valuable substitute for terephthalic acid in polyesters. A combination of detailed experimental protocols and conditions with DFT computational calculations for the synthesis of mucic acid from galactose are herein described. The product is obtained by reaction with diluted aqueous nitric acid as the oxidizing agent and the reaction medium. Optimized reaction conditions require 5 M nitric acid, 95 °C, galactose/HNO3 molar ratio 1:9, 100 g/L galactose concentration in the reaction medium. Computational calculations suggest that the oxidation mechanism may involve a contextual oxygen protonation and nitrate nucleophilic attack, leading to the oxidized product. The proposed mechanism requires a stoichiometry of 6 moles of nitric acid per galactose mole, albeit both experimental and computational data evidence that proton excess may be necessary to start the reaction. The reported study gives useful insights for the production of galactaric acid.

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