Resolving the formidable barrier of oxygen transferring rate (OTR) in ultrahigh-titer bioconversion/biocatalysis by a sealed-oxygen supply biotechnology (SOS)

Hua, Xia; Zhou, Xin; Du, GenLai; Xu, Yong

doi:10.1186/s13068-019-1642-1

Cited by 156 publications

(179 citation statements)

References 42 publications

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“…More recently, genera like Acetomicrobium spp., Sedimentibacter spp., Tepidanaerobacter spp., or Sporanaerobacter spp. were shown to be important biomarkers for high phenyl acid concentrations in batch reactors fed with aromatic amino acids [ 21 ]. Whether these genera are directly or indirectly associated with phenyl acid formation remains to be elucidated.…”

Section: Introductionmentioning

confidence: 99%

Lignin intermediates lead to phenyl acid formation and microbial community shifts in meso- and thermophilic batch reactors

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Mutschlechner

Stres

et al. 2021

Biotechnol Biofuels

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Background Lignin intermediates resulting from lignocellulose degradation have been suspected to hinder anaerobic mineralisation of organic materials to biogas. Phenyl acids like phenylacetate (PAA) are early detectable intermediates during anaerobic digestion (AD) of aromatic compounds. Studying the phenyl acid formation dynamics and concomitant microbial community shifts can help to understand the microbial interdependencies during AD of aromatic compounds and may be beneficial to counteract disturbances. Results The length of the aliphatic side chain and chemical structure of the benzene side group(s) had an influence on the methanogenic system. PAA, phenylpropionate (PPA), and phenylbutyrate (PBA) accumulations showed that the respective lignin intermediate was degraded but that there were metabolic restrictions as the phenyl acids were not effectively processed. Metagenomic analyses confirmed that mesophilic genera like Fastidiosipila or Syntrophomonas and thermophilic genera like Lactobacillus, Bacillus, Geobacillus, and Tissierella are associated with phenyl acid formation. Acetoclastic methanogenesis was prevalent in mesophilic samples at low and medium overload conditions, whereas Methanoculleus spp. dominated at high overload conditions when methane production was restricted. In medium carbon load reactors under thermophilic conditions, syntrophic acetate oxidation (SAO)-induced hydrogenotrophic methanogenesis was the most important process despite the fact that acetoclastic methanogenesis would thermodynamically be more favourable. As acetoclastic methanogens were restricted at medium and high overload conditions, syntrophic acetate oxidising bacteria and their hydrogenotrophic partners could step in for acetate consumption. Conclusions PAA, PPA, and PBA were early indicators for upcoming process failures. Acetoclastic methanogens were one of the first microorganisms to be impaired by aromatic compounds, and shifts to syntrophic acetate oxidation coupled to hydrogenotrophic methanogenesis occurred in thermophilic reactors. Previously assumed associations of specific meso- and thermophilic genera with anaerobic phenyl acid formation could be confirmed.

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Section: Introductionmentioning

confidence: 99%

Lignin intermediates lead to phenyl acid formation and microbial community shifts in meso- and thermophilic batch reactors

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Mutschlechner

Stres

et al. 2021

Biotechnol Biofuels

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“…The prospects of keratinases as suitable enzymes for industrial and biotechnological processes include their robustness in withstanding extreme conditions on like the classical proteases (Verma et al 2017 ). Microbial keratinases possess unique properties that bestows a potential suitable for use in a green economy including applications in the formulation of functional feed, detergent formulation, bio-decontamination, bating and tanning processes, personal care product formulation, and nanotechnology (Mitsuiki et al 2006 ; Paul et al 2014b ; Gupta et al 2015 ; Sanghvi et al 2016 ; Kalaikumari et al 2019 ; Peng et al 2020 ). A continuum in the discovery of keratinases with novel properties and function would, significantly, revolutionize the bio-economy landscape, and the prospects presented by proteolytic enzymes.…”

Section: Introductionmentioning

confidence: 99%

Microbial keratinase and the bio-economy: a three-decade meta-analysis of research exploit

Nnolim

Nwodo

2021

AMB Expr

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Microbial keratinase research has been on an upward trajectory due to the robustness and efficiency of the enzyme toward various green technological processes that promote economic development and environmental sustainability. A compendium of research progression and advancement within the domain was achieved through a bibliometric study to understand the trend of research productivity, scientific impacts, authors' involvement, collaboration networks, and the advancement of knowledge gaps for future research endeavours. A three-decade (1990 to 2019) scholarly published articles were retrieved from the web of science database using a combination of terms "keratinas* or keratinolytic proteas* or keratinolytic enzym*", and subsequently analyzed for bibliometric indicators. A collection of 330 peer-reviewed, research, articles were retrieved for the survey period and authored by 1063 researchers with collaboration index of 3.27. Research productivity was most in 2013 with total research output of 28 articles. The top three authors' keywords were keratinase, keratin and protease with a respective frequency of 188, 26 and 22. India, China and Brazil ranked top in terms of keratinase research outputs and total citation with respective article productivity (total citations) of 85 (1533), 57 (826), and 36 (764). This study evaluated the trend of keratinase research outputs, scientific impact, collaboration networks and biotechnology innovations. It has the potentials to influence positively decision making on future research direction, collaborations and development of products for the bio-economy.

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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 – 20 and the reconfiguration of bioreactors 21 .…”

Section: Introductionmentioning

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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Resolving the formidable barrier of oxygen transferring rate (OTR) in ultrahigh-titer bioconversion/biocatalysis by a sealed-oxygen supply biotechnology (SOS)

Cited by 156 publications

References 42 publications

Lignin intermediates lead to phenyl acid formation and microbial community shifts in meso- and thermophilic batch reactors

Lignin intermediates lead to phenyl acid formation and microbial community shifts in meso- and thermophilic batch reactors

Microbial keratinase and the bio-economy: a three-decade meta-analysis of research exploit

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

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