Coordination of consolidated bioprocessing technology and carbon dioxide fixation to produce malic acid directly from plant biomass in Myceliophthora thermophila

• Published in: Biotechnology for biofuels Vol. 14; no. 1; p. 186
• Main Authors: Li, Jingen, Chen, Bingchen, Gu, Shuying, Zhao, Zhen, Liu, Qian, Sun, Tao, Zhang, Yongli, Wu, Taju, Liu, Defei, Sun, Wenliang, Tian, Chaoguang
• Format: Journal Article
• Language: English
• Published: London BioMed Central Ltd 23.09.2021; BioMed Central; BMC
• Subjects: Acids; Alternative energy sources; Analysis; Ascomycota; Biodiesel fuels; Biofuels; Biomass; Biomass energy; Bioprocessing; Biorefineries; biorefining; Biosynthesis; biotechnology; carbon; Carbon dioxide; Carbon dioxide fixation; carbon metabolism; CBB cycle; Cellulase; Cellulose; Channeling; CO2-fixation; Control; cost effectiveness; CRISPR; E coli; Enzymes; feedstocks; Fixation; Fixing; Fungi; Genes; Genetic engineering; Genomes; Glucose; hydrolysis; Identification and classification; Lignocellulose; Malic acid; Metabolic engineering; Metabolism; Metabolites; Microorganisms; Modules; Myceliophthora; Myceliophthora thermophila; Organic acids; Organisms; Pentose; pentoses; phytomass; Plant biomass; Production processes; Raw materials; Refining; Testing; Thermophilic fungi; value added; xylose; China
• ISSN: 1754-6834; 1754-6834; 2731-3654
• DOI: 10.1186/s13068-021-02042-5

Consolidated bioprocessing (CBP) technique is a promising strategy for biorefinery construction, producing bulk chemicals directly from plant biomass without extra hydrolysis steps. Fixing and channeling CO.sub.2 into carbon metabolism for increased carbon efficiency in producing value-added compounds is another strategy for cost-effective bio-manufacturing. It has not been reported whether these two strategies can be combined in one microbial platform. In this study, using the cellulolytic thermophilic fungus Myceliophthora thermophila, we designed and constructed a novel biorefinery system DMCC (Direct microbial conversion of biomass with CO.sub.2 fixation) through incorporating two CO.sub.2 fixation modules, PYC module and Calvin-Benson-Bassham (CBB) pathway. Harboring the both modules, the average rate of fixing and channeling .sup.13CO.sub.2 into malic acid in strain CP51 achieved 44.4, 90.7, and 80.7 mg/L/h, on xylose, glucose, and cellulose, respectively. The corresponding titers of malic acid were up to 42.1, 70.4, and 70.1 g/L, respectively, representing the increases of 40%, 10%, and 7%, respectively, compared to the parental strain possessing only PYC module. The DMCC system was further improved by enhancing the pentose uptake ability. Using raw plant biomass as the feedstock, yield of malic acid produced by the DMCC system was up to 0.53 g/g, with .sup.13C content of 0.44 mol/mol malic acid, suggesting DMCC system can produce 1 t of malic acid from 1.89 t of biomass and fix 0.14 t CO.sub.2 accordingly. This study designed and constructed a novel biorefinery system named DMCC, which can convert raw plant biomass and CO.sub.2 into organic acid efficiently, presenting a promising strategy for cost-effective production of value-added compounds in biorefinery. The DMCC system is one of great options for realization of carbon neutral economy.