Yayue Zheng scite author profile

Background During the dilute acid pretreatment process, the resulting pseudo-lignin and lignin droplets deposited on the surface of lignocellulose and inhibit the enzymatic digestibility of cellulose in lignocellulose. However, how these lignins interact with cellulase enzymes and then affect enzymatic hydrolysis is still unknown. In this work, different fractions of surface lignin (SL) obtained from dilute acid-pretreated bamboo residues (DAP-BR) were extracted by various organic reagents and the residual lignin in extracted DAP-BR was obtained by the milled wood lignin (MWL) method. All of the lignin fractions obtained from DAP-BR were used to investigate the mechanism for interaction between lignin and cellulase using surface plasmon resonance (SPR) technology to understand how they affect enzymatic hydrolysis Results The results showed that removing surface lignin significantly decreased the yield for enzymatic hydrolysis DAP-BR from 36.5% to 18.6%. The addition of MWL samples to Avicel inhibited its enzymatic hydrolysis, while different SL samples showed slight increases in enzymatic digestibility. Due to the higher molecular weight and hydrophobicity of MWL samples versus SL samples, a stronger affinity for MWL (KD = 6.8–24.7 nM) was found versus that of SL (KD = 39.4–52.6 nM) by SPR analysis. The affinity constants of all tested lignins exhibited good correlations (r > 0.6) with the effects on enzymatic digestibility of extracted DAP-BR and Avicel. Conclusions This work revealed that the surface lignin on DAP-BR is necessary for maintaining enzyme digestibility levels, and its removal has a negative impact on substrate digestibility.

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Enhancing the enzymatic digestibility of bamboo residues by biphasic phenoxyethanol-acid pretreatment

Zheng

Lin

et al. 2021

Bioresource Technology

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Revealing the mechanism of surfactant-promoted enzymatic hydrolysis of dilute acid pretreated bamboo

Huang

Zhao

Zheng

et al. 2022

Bioresource Technology

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Removal of fermentation inhibitors from pre-hydrolysis liquor using polystyrene divinylbenzene resin

Huang

Zheng

Lin

et al. 2020

Biotechnol Biofuels

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Background The presence of soluble lignin, furfural and hydroxymethylfurfural (HMF) in industrial pre-hydrolysis liquor (PHL) from the pulping process can inhibit its bioconversion into bioethanol and other biochemicals. Although various technologies have been developed to remove these inhibitors, certain amounts of sugars are also inevitably removed during the treatment process. Hence, polystyrene divinylbenzene (PS-DVB) resin was used as an adsorptive material to simultaneously remove fermentation inhibitors while retaining sugars with high yields to improve the fermentability of PHL after acid hydrolysis by enriching its xylose concentration. The fermentability of acid-hydrolyzed PHL (A-PHL) was evaluated by the bioconversion into ethanol and xylosic acid (XA) after treatment with PS-DVB resin. Results The results showed that the highest xylose concentration (101.1 g/L) in PHL could be obtained by acid hydrolysis at 100 °C for 80 min with 4% acid, while the concentration of fermentation inhibitors (furfural, HMF and lignin) in PHL could also be significantly improved during the acid-hydrolysis process. After treatment with PS-DVB resin, not only were 97% of lignin, 92% of furfural, and 97% of HMF removed from A-PHL, but also 96% of xylose was retained for subsequent fermentation. With resin treatment, the fermentability of A-PHL could be improved by 162–282% for ethanol production from A-PHL containing 30–50 g/L xylose and by 18–828% for XA production from A-PHL containing 90–150 g/L xylose. Conclusions These results confirmed that PS-DVB resin can remove inhibitors from PHL before producing value-added products by bioconversion. In addition, this work will ideally provide a concept for producing value-added chemicals from pre-hydrolysis liquor, which is regarded as the waste stream in the pulping process.

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Perspectives of biotechnological production of l-ribose and its purification

Zheng

et al. 2011

Appl Microbiol Biotechnol

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L-ribose is a non-natural and expensive sugar that can be used as an important intermediate for the synthesis of L-nucleoside analogues, which are used as antiviral drugs. In contrast to chemical production, biotechnological methods can produce L-ribose from biomass under environmentally friendly conditions. In this mini-review, various strategies for synthesizing L-ribose by applying microorganisms and their enzymes are discussed, including microbial biotransformation and biocatalysis by engineering bacteria. Furthermore, subsequent isolation-and-purification techniques, as an integral step in the whole process, are accordingly described, containing the special introduction of a promising strategy of L-ribose separation. Particularly, further researches and outlook for the improvement of L-ribose preparation was solely stressed. Compared with each method, this mini-review provides a panorama of respective advantages and disadvantages existing in them.

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Yayue Zheng

Understanding the effects of different residual lignin fractions in acid-pretreated bamboo residues on its enzymatic digestibility

Enhancing the enzymatic digestibility of bamboo residues by biphasic phenoxyethanol-acid pretreatment

Revealing the mechanism of surfactant-promoted enzymatic hydrolysis of dilute acid pretreated bamboo

Removal of fermentation inhibitors from pre-hydrolysis liquor using polystyrene divinylbenzene resin

Perspectives of biotechnological production of l-ribose and its purification

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