Recent Advances in Developing Artificial Autotrophic Microorganism for Reinforcing CO2 Fixation

Liang, Bo; Zhao, Yaohua; Jian-ming, Yang

doi:10.3389/fmicb.2020.592631

Cited by 25 publications

(36 citation statements)

References 103 publications

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“…Fungi and bacteria can be used in these processes (Menon et al, 2019). However, most interestingly, a number of researches are currently focussed on the creation of new synthetic organisms able to capture CO 2 using HCOOH or light, opening new frontiers in this field (Woo, 2017;Franc ßois et al, 2020;Liang et al, 2020;Satanowski and Bar-Even, 2020;Satanowski et al, 2020). Rewiring Escherichia coli for CO 2 fixation to convert it into sugar may enable diverse biotechnological applications (Antonovsky et al, 2017;Flamholz et al, 2020).…”

Section: Co 2 Capturementioning

confidence: 99%

Integrating greenhouse gas capture and C1 biotechnology: a key challenge for circular economy

Garcı́a

2021

Microbial Biotechnology

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Section: Co 2 Capturementioning

confidence: 99%

Integrating greenhouse gas capture and C1 biotechnology: a key challenge for circular economy

Garcı́a

2021

Microbial Biotechnology

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“…While various technologies have been being studied intensively to capture or utilize CO 2 to reduce the emissions [ 4 ], it is also important to understand the carbon cycle on earth, where biological CO 2 fixation by autotrophic microorganisms plays an important role. In nature, autotrophic microorganisms utilize light or inorganic compounds as an energy source to reduce CO 2 into organic compounds via six natural carbon fixation pathways including the Calvin–Benson–Bassham cycle, the reductive citric acid cycle, the 3-hydroxypropionate bicycle, the 3-hydroxypropionate/4-hydroxybutyrate cycle, dicarboxylate/4-hydroxybutyrate cycle, and the reductive acetyl-CoA pathway (Wood–Ljungdahl pathway) [ 5 , 6 , 7 ]. In these CO 2 -fixation pathways, the Wood–Ljungdahl pathway has high energy efficiency due to the consumption of only one mole of ATP to fix one mole of CO 2 [ 7 ], which has garnered more interest for many researchers.…”

Section: Introductionmentioning

confidence: 99%

Effect of Humin and Chemical Factors on CO2-Fixing Acetogenesis and Methanogenesis

Pham

Kasai

et al. 2022

IJERPH

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Acetogenesis and methanogenesis have attracted attention as CO2-fixing reactions. Humin, a humic substance insoluble at any pH, has been found to assist CO2-fixing acetogenesis as the sole electron donor. Here, using two CO2-fixing consortia with acetogenic and methanogenic activities, the effect of various parameters on these activities was examined. One consortium utilized humin and hydrogen (H2) as electron donors for acetogenesis, either separately or simultaneously, but with a preference for the electron use from humin. The acetogenic activity was accelerated 14 times by FeS at 0.2 g/L as the optimal concentration, while being inhibited by MgSO4 at concentration above 0.02 g/L and by NaCl at concentrations higher than 6 g/L. Another consortium did not utilize humin but H2 as electron donor, suggesting that humin was not a universal electron donor for acetogenesis. For methanogenesis, both consortia did not utilize extracellular electrons from humin unless H2 was present. The methanogenesis was promoted by FeS at 0.2 g/L or higher concentrations, especially without humin, and with NaCl at 2 g/L or higher concentrations regardless of the presence of humin, while no significant effect was observed with MgSO4. Comparative sequence analysis of partial 16S rRNA genes suggested that minor groups were the humin-utilizing acetogens in the consortium dominated by Clostridia, while Methanobacterium was the methanogen utilizing humin with H2.

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“…Growing concerns over global fossil-resources and food shortages have motivated the development of sustainable commodity biomanufacturing from alternative resources ( Clomburg et al, 2017 ). Over the past decade, advances in the bioconversion of non-food, low-cost, and abundant one-carbon compounds such as methanol, formate, and CO 2 using native or synthetic methylotrophs highlighted a potentially green and economical alternative to current sugar-based biomanufacturing ( Liang et al, 2020 ; Mao et al, 2020 ; Nguyen and Lee, 2020 ). Notably, electron-enriched methanol (CH 4 O) is expected to support more economical biosynthesis of chemicals with higher theoretical carbon-molar yields than sugars.…”

Section: Introductionmentioning

confidence: 99%

Non-natural Aldol Reactions Enable the Design and Construction of Novel One-Carbon Assimilation Pathways in vitro

et al. 2021

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Methylotrophs utilizes cheap, abundant one-carbon compounds, offering a promising green, sustainable and economical alternative to current sugar-based biomanufacturing. However, natural one-carbon assimilation pathways come with many disadvantages, such as complicated reaction steps, the need for additional energy and/or reducing power, or loss of CO2, resulting in unsatisfactory biomanufacturing performance. Here, we predicted eight simple, novel and carbon-conserving formaldehyde (FALD) assimilation pathways based on the extended metabolic network with non-natural aldol reactions using the comb-flux balance analysis (FBA) algorithm. Three of these pathways were found to be independent of energy/reducing equivalents, and thus chosen for further experimental verification. Then, two novel aldol reactions, condensing D-erythrose 4-phosphate and glycolaldehyde (GALD) into 2R,3R-stereo allose 6-phosphate by DeoC or 2S,3R-stereo altrose 6-phosphate by TalBF178Y/Fsa, were identified for the first time. Finally, a novel FALD assimilation pathway proceeding via allose 6-phosphate, named as the glycolaldehyde-allose 6-phosphate assimilation (GAPA) pathway, was constructed in vitro with a high carbon yield of 94%. This work provides an elegant paradigm for systematic design of one-carbon assimilation pathways based on artificial aldolase (ALS) reactions, which could also be feasibly adapted for the mining of other metabolic pathways.

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Recent Advances in Developing Artificial Autotrophic Microorganism for Reinforcing CO2 Fixation

Cited by 25 publications

References 103 publications

Integrating greenhouse gas capture and C1 biotechnology: a key challenge for circular economy

Integrating greenhouse gas capture and C1 biotechnology: a key challenge for circular economy

Effect of Humin and Chemical Factors on CO2-Fixing Acetogenesis and Methanogenesis

Non-natural Aldol Reactions Enable the Design and Construction of Novel One-Carbon Assimilation Pathways in vitro

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