Engineering microbial pathways for production of bio-based chemicals from lignocellulosic sugars: current status and perspectives

François, Jean; Alkım, Ceren; Morin, Nicolas

doi:10.1186/s13068-020-01744-6

Cited by 86 publications

(31 citation statements)

References 159 publications

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“…The diverse target products derived from lignocellulose feedstock can primarily be divided into three categories: monosaccharide and sugar alcohol; biodiesel; bio-oil, bio-char, and syngas, whose downstream products, such as alcohols, diols, carboxylic acids, organic acids, polymers, furfural, bio-gas, liquid alkanes and phenol [ 3 ], show diverse applications in different industries, such as pharmaceuticals, biomedical products, agrochemicals, aerospace, the building sector, filler materials, fragrances, food, cosmetics, etc. [ 98 – 102 ] All the mentioned products derived from plant biomass are listed in Fig. 4 .…”

Section: Products Derived From Plant Biomassmentioning

confidence: 99%

“…In the past decade, the application of genetic and metabolic engineering in butanol-producing Clostridium has been rapidly developed [ 99 , 188 , 189 , 238 – 241 ] with the birth of ClosTron technology, which can be applied for Clostridium gene editing [ 242 , 243 ], and the discovery of the butanol-producing metabolic mechanism of Clostridium acetobutylicum ATCC 824 [ 244 ]. Additionally, genetic and metabolic engineering has also been adopted in Escherichia coli for 2,3-butanediol production [ 245 ], Neurospora crassa for itaconic acid production [ 246 ], Pseudomonas putida KT2440 for substituted styrene bioproduct production [ 247 ], and other strains for biofuel and chemical production [ 98 , 248 – 251 ]. Furthermore, some engineered microorganisms can also increase tolerance to inhibitors or upgrade lignin [ 7 , 252 ].…”

Section: Challenges In the Valorization Of Plant Biomassmentioning

confidence: 99%

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Recent advances in the valorization of plant biomass

Ning

Yang

et al. 2021

Biotechnol Biofuels

178

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Plant biomass is a highly abundant renewable resource that can be converted into several types of high-value-added products, including chemicals, biofuels and advanced materials. In the last few decades, an increasing number of biomass species and processing techniques have been developed to enhance the application of plant biomass followed by the industrial application of some of the products, during which varied technologies have been successfully developed. In this review, we summarize the different sources of plant biomass, the evolving technologies for treating it, and the various products derived from plant biomass. Moreover, the challenges inherent in the valorization of plant biomass used in high-value-added products are also discussed. Overall, with the increased use of plant biomass, the development of treatment technologies, and the solution of the challenges raised during plant biomass valorization, the value-added products derived from plant biomass will become greater in number and more valuable.

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Section: Products Derived From Plant Biomassmentioning

confidence: 99%

Section: Challenges In the Valorization Of Plant Biomassmentioning

confidence: 99%

Recent advances in the valorization of plant biomass

Ning

Yang

et al. 2021

Biotechnol Biofuels

178

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“…Tab. T1) and the break down of large sugar polymers during hydrolosis pretreatment that presumably increased the concentration of fermentable carbohydrates (Sardi et al, 2016), such as galactose and mannose (Francois et al, 2020;see Methods).…”

Section: Yield On Ethanol (G/g Glucose )mentioning

confidence: 99%

CRISPRi screens reveal genes modulating yeast growth in lignocellulose hydrolysate

Gutmann

Jann

Pereira

et al. 2020

Preprint

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BackgroundBaker’s yeast is a widely used eukaryotic cell factory, producing a diverse range of compounds including biofuels and fine chemicals. The use of lignocellulose as feedstock offers the opportunity to run these processes in an environmentally sustainable way. However, the required hydrolysis pretreatment of lignocellulosic material releases toxic compounds that hamper yeast growth and consequently productivity.ResultsHere, we employ CRISPR interference in S. cerevisiae to identify genes modulating fermentative growth in plant hydrolysate and in presence of lignocellulosic toxins. We find that at least one third of hydrolysate-associated gene functions are explained by effects of known toxic compounds, such as the decreased growth of YAP1 or HAA1, or increased growth of DOT6 knock-down strains in hydrolysate.ConclusionOur study confirms previously known genetic elements and uncovers new targets towards designing more robust yeast strains for the utilization of lignocellulose hydrolysate as sustainable feedstock, and, more broadly, paves the way for applying CRISPRi screens to improve industrial fermentation processes.

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“…Surplus precursors are metabolically wasteful and deprive the cell of precious resources that could be re-directed toward growth and maintenance 6 . This excess input can lead to a production of undesired products 16,17 . Current strategies at re-direction of these excess inputs have focused on the generation of biosynthetic pathways [18][19][20] and the reconfiguration of bioreactors 21 .…”

mentioning

confidence: 99%

Co-feeding glucose with either gluconate or galacturonate during clostridial fermentations provides metabolic fine-tuning capabilities

Liu

Gerlach

et al. 2021

Sci Rep

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Clostridiumacetobutylicum ATCC 824 effectively utilizes a wide range of substrates to produce commodity chemicals. When grown on substrates of different oxidation states, the organism exhibits different recycling needs of reduced intracellular electron carrying co-factors. Ratios of substrates with different oxidation states were used to modulate the need to balance electron carriers and demonstrate fine-tuned control of metabolic output. Three different oxidized substrates were first fed singularly, then in different ratios to three different strains of Clostridium sp. Growth was most robust when fed glucose in exclusive fermentations. However, the use of the other two more oxidized substrates was strain-dependent in exclusive feeds. In glucose-galacturonate mixed fermentation, the main products (acetate and butyrate) were dependant on the ratios of the substrates. Exclusive fermentation on galacturonate was nearly homoacetic. Co-utilization of galacturonate and glucose was observed from the onset of fermentation in growth conditions using both substrates combined, with the proportion of galacturonate present dictating the amount of acetate produced. For all three strains, increasing galacturonate content (%) in a mixture of galacturonate and glucose from 0 to 50, and 100, resulted in a corresponding increase in the amount of acetate produced. For example, C.acetobutylicum increased from ~ 10 mM to ~ 17 mM, and then ~ 23 mM. No co-utilization was observed when galacturonate was replaced with gluconate in the two substrate co-feed.

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Engineering microbial pathways for production of bio-based chemicals from lignocellulosic sugars: current status and perspectives

Cited by 86 publications

References 159 publications

Recent advances in the valorization of plant biomass

Recent advances in the valorization of plant biomass

CRISPRi screens reveal genes modulating yeast growth in lignocellulose hydrolysate

Co-feeding glucose with either gluconate or galacturonate during clostridial fermentations provides metabolic fine-tuning capabilities

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