Understanding the promoting effect of non-catalytic protein on enzymatic hydrolysis efficiency of lignocelluloses

Zhenggang Gong , Guangxu Yang , Junlong Song , Peitao Zheng , Jing Liu , Wenyuan Zhu , Liulian Huang , Lihui Chen , Xiaolin Luo , Li Shuai

Bioresources and Bioprocessing ›› 2021, Vol. 8 ›› Issue (1) : 9

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Bioresources and Bioprocessing ›› 2021, Vol. 8 ›› Issue (1) : 9 DOI: 10.1186/s40643-021-00363-9
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Understanding the promoting effect of non-catalytic protein on enzymatic hydrolysis efficiency of lignocelluloses

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Abstract

Abstract

Lignin deposits formed on the surface of pretreated lignocellulosic substrates during acidic pretreatments can non-productively adsorb costly enzymes and thereby influence the enzymatic hydrolysis efficiency of cellulose. In this article, peanut protein (PP), a biocompatible non-catalytic protein, was separated from defatted peanut flour (DPF) as a lignin blocking additive to overcome this adverse effect. With the addition of 2.5 g/L PP in enzymatic hydrolysis medium, the glucose yield of the bamboo substrate pretreated by phenylsulfonic acid (PSA) significantly increased from 38 to 94% at a low cellulase loading of 5 FPU/g glucan while achieving a similar glucose yield required a cellulase loading of 17.5 FPU/g glucan without PP addition. Similar promotion effects were also observed on the n-pentanol-pretreated bamboo and PSA-pretreated eucalyptus substrates. The promoting effect of PP on enzymatic hydrolysis was ascribed to blocking lignin deposits via hydrophobic and/or hydrogen-bonding interactions, which significantly reduced the non-productive adsorption of cellulase onto PSA lignin. Meanwhile, PP extraction also facilitated the utilization of residual DPF as the adhesive for producing plywood as compared to that without protein pre-extraction. This scheme provides a sustainable and viable way to improve the value of woody and agriculture biomass.

Peanut protein, a biocompatible non-catalytic protein, can block lignin, improve enzymatic hydrolysis efficiency and thereby facilitate the economics of biorefinery.

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Keywords

Enzymatic hydrolysis / Peanut protein / Lignin deposits / Adsorption / Blocking / Pretreatment

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Zhenggang Gong, Guangxu Yang, Junlong Song, Peitao Zheng, Jing Liu, Wenyuan Zhu, Liulian Huang, Lihui Chen, Xiaolin Luo, Li Shuai. Understanding the promoting effect of non-catalytic protein on enzymatic hydrolysis efficiency of lignocelluloses. Bioresources and Bioprocessing, 2021, 8(1): 9 DOI:10.1186/s40643-021-00363-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Akimkulova A, Zhou Y, Zhao X, Liu D. Improving the enzymatic hydrolysis of dilute acid pretreated wheat straw by metal ion blocking of non-productive cellulase adsorption on lignin. Bioresour Technol, 2016, 208: 110-116.

[2]

Argyropoulos D, Sun YJ, Paluš E. Isolation of residual kraft lignin in high yield and purity. J Pulp Paper Sci, 2002, 28: 50-54.
[3]

Bian H, Chen L, Gleisner R, Dai H, Zhu JY. Producing wood-based nanomaterials by rapid fractionation of wood at 80 °C using a recyclable acid hydrotrope. Green Chem, 2017, 19: 3370-3379.

[4]

Börjesson J, Engqvist M, Sipos B, Tjerneld F. Effect of poly(ethylene glycol) on enzymatic hydrolysis and adsorption of cellulase enzymes to pretreated lignocellulose. Enzyme Microb Tech, 2007, 41: 186-195.

[5]

Cai C, Qiu X, Zeng M, Lin M, Lin X, Lou H, Zhan X, Pang Y, Huang J, Xie L. Using polyvinylpyrrolidone to enhance the enzymatic hydrolysis of lignocelluloses by reducing the cellulase non-productive adsorption on lignin. Bioresour Technol, 2017, 227: 74-81.

[6]

Cai C, Zhan X, Zeng M, Lou H, Pang Y, Yang J, Yang D, Qiu X. Using recyclable pH-responsive lignin amphoteric surfactant to enhance the enzymatic hydrolysis of lignocelluloses. Green Chem, 2017, 19: 5479-5487.

[7]

Chen L, Dou J, Ma Q, Li N, Wu R, Bian H, Yelle DJ, Vuorinen T, Fu S, Pan X, Zhu J. Rapid and near-complete dissolution of wood lignin at ≤80°C by a recyclable acid hydrotrope. Sci Adv, 2017, 3: e1701735.

[8]

Chen N, Zeng Q, Lin Q, Rao J. Development of defatted soy flour based bio-adhesives using Viscozyme L. Ind Crop Prod, 2015, 76: 198-203.

[9]

Donohoe BS, Decker SR, Tucker MP, Himmel ME, Vinzant TB. Visualizing lignin coalescence and migration through maize cell walls following thermochemical pretreatment. Biotechnol Bioeng, 2008, 101: 913-925.

[10]

dos Santos AC, Ximenes E, Kim Y, Ladisch MR. Lignin–enzyme interactions in the hydrolysis of lignocellulosic biomass. Trends Biotechnol, 2019, 37: 518-531.

[11]

Eckard AD, Muthukumarappan K, Gibbons W. Analysis of casein biopolymers adsorption to lignocellulosic biomass as a potential cellulase stabilizer. J Biomed Biotechnol, 2012, 2012: 745181.

[12]

Eriksson T, Börjesson J, Tjerneld F. Mechanism of surfactant effect in enzymatic hydrolysis of lignocellulose. Enzyme Microb Tech, 2002, 31: 353-364.

[13]

Florencio C, Badino AC, Farinas CS. Soybean protein as a cost-effective lignin-blocking additive for the saccharification of sugarcane bagasse. Bioresour Technol, 2016, 221: 172-180.

[14]

Gomide FTF, da Silva ASA, da Silva Bon EP, Alves TLM. Modification of microcrystalline cellulose structural properties by ball-milling and ionic liquid treatments and their correlation to enzymatic hydrolysis rate and yield. Cellulose, 2019, 26: 7323-7335.

[15]

Himmel ME, Ding S-Y, Johnson DK, Adney WS, Nimlos MR, Brady JW, Foust TD. Biomass recalcitrance: engineering plants and enzymes for biofuels production. Science, 2007, 315: 804-807.

[16]

Klein-Marcuschamer D, Oleskowicz-Popiel P, Simmons BA, Blanch HW. The challenge of enzyme cost in the production of lignocellulosic biofuels. Biotechnol Bioeng, 2012, 109: 1083-1087.

[17]

Ko JK, Kim Y, Ximenes E, Ladisch MR. Effect of liquid hot water pretreatment severity on properties of hardwood lignin and enzymatic hydrolysis of cellulose. Biotechnol Bioeng, 2015, 112: 252-262.

[18]

Kristensen JB, Börjesson J, Bruun MH, Tjerneld F, Jørgensen H. Use of surface active additives in enzymatic hydrolysis of wheat straw lignocellulose. Enzyme Microb Tech, 2007, 40: 888-895.

[19]

Lai C, Yang B, Lin Z, Jia Y, Huang C, Li X, Song X, Yong Q. New strategy to elucidate the positive effects of extractable lignin on enzymatic hydrolysis by quartz crystal microbalance with dissipation. Biotechnol Biofuels, 2019, 12: 57.

[20]

Lan TQ, Lou H, Zhu JY. Enzymatic saccharification of lignocelluloses should be conducted at elevated pH 5.2–6.2. BioEnerg Res, 2013, 6: 476-485.

[21]

Lan TQ, Wang SR, Li H, Qin YY, Yue GJ. Effect of lignin isolated from p-toluenesulfonic acid pretreatment liquid of sugarcane bagasse on enzymatic hydrolysis of cellulose and cellulase adsorption. Ind Crop Prod, 2020, 155: 112768.

[22]

Li X, Zheng Y. Lignin-enzyme interaction: mechanism, mitigation approach, modeling, and research prospects. Biotechnol Adv, 2017, 35: 466-489.

[23]

Ling Z, Chen S, Zhang X, Takabe K, Xu F. Unraveling variations of crystalline cellulose induced by ionic liquid and their effects on enzymatic hydrolysis. Sci Rep, 2017, 7: 10230.

[24]

Liu H, Sun J, Leu S-Y, Chen S. Toward a fundamental understanding of cellulase-lignin interactions in the whole slurry enzymatic saccharification process. Biofuels Bioprod Bior, 2016, 10: 648-663.

[25]

Liu H, Zhu JY, Fu SY. Effects of lignin−metal complexation on enzymatic hydrolysis of cellulose. J Agric Food Chem, 2010, 58: 7233-7238.

[26]

Liu J, Hu H, Gong Z, Yang G, Li R, Chen L, Huang L, Luo X. Near-complete removal of non-cellulosic components from bamboo by 1-pentanol induced organosolv pretreatment under mild conditions for robust cellulose enzymatic hydrolysis. Cellulose, 2019, 26: 3801-3814.

[27]

Lou H, Zhu JY, Lan TQ, Lai H, Qiu X. pH-induced lignin surface modification to reduce nonspecific cellulase binding and enhance enzymatic saccharification of lignocelluloses. Chemsuschem, 2013, 6: 919-927.

[28]

Lu Q, Huang J, Maan O, Liu Y, Zeng H. Probing molecular interaction mechanisms of organic fouling on polyamide membrane using a surface forces apparatus: implication for wastewater treatment. Sci Total Environ, 2018, 622–623: 644-654.

[29]

Lu X, Zheng X, Li X, Zhao J. Adsorption and mechanism of cellulase enzymes onto lignin isolated from corn stover pretreated with liquid hot water. Biotechnol Biofuels, 2016

[30]

Luo X, Gong Z, Shi J, Chen L, Zhu W, Zhou Y, Huang L, Liu J. Integrating benzenesulfonic acid pretreatment and bio-based lignin-shielding agent for robust enzymatic conversion of cellulose in bamboo. Polymers, 2020, 12: 191.

[31]

Luo X, Liu J, Zheng P, Li M, Zhou Y, Huang L, Chen L, Shuai L. Promoting enzymatic hydrolysis of lignocellulosic biomass by inexpensive soy protein. Biotechnol Biofuels, 2019, 12: 51.

[32]

Öhgren K, Bura R, Saddler J, Zacchi G. Effect of hemicellulose and lignin removal on enzymatic hydrolysis of steam pretreated corn stover. Bioresour Technol, 2007, 98: 2503-2510.

[33]

Österberg M. The effect of a cationic polyelectrolyte on the forces between two cellulose surfaces and between one cellulose and one mineral surface. J Colloid Interf Sci, 2000, 229: 620-627.

[34]

Pan X, Arato C, Gilkes N, Gregg D, Mabee W, Pye K, Xiao Z, Zhang X, Saddler J. Biorefining of softwoods using ethanol organosolv pulping: preliminary evaluation of process streams for manufacture of fuel-grade ethanol and co-products. Biotechnol Bioeng, 2005, 90: 473-481.

[35]

Qin C, Clarke K, Li K. Interactive forces between lignin and cellulase as determined by atomic force microscopy. Biotechnol Biofuels, 2014

[36]

Ragauskas AJ, Williams CK, Davison BH, Britovsek G, Cairney J, Eckert CA, Frederick WJ, Hallett JP, Leak DJ, Liotta CL, Mielenz JR, Murphy R, Templer R, Tschaplinski T. The path forward for biofuels and biomaterials. Science, 2006, 311: 484-489.

[37]

Saini JK, Patel AK, Adsul M, Singhania RR. Cellulase adsorption on lignin: a roadblock for economic hydrolysis of biomass. Renew Energ, 2016, 98: 29-42.

[38]

Sannigrahi P, Kim DH, Jung S, Ragauskas A. Pseudo-lignin and pretreatment chemistry. Energ Environ Sci, 2011, 4: 1306-1310.

[39]

Sauerbrey G. Verwendung von schwingquarzen zur wägung dünner schichten und zur mikrowägung. Z Phys, 1959, 155: 206-222.

[40]

Selig MJ, Viamajala S, Decker SR, Tucker MP, Himmel ME, Vinzant TB. Deposition of lignin droplets produced during dilute acid pretreatment of maize stems retards enzymatic hydrolysis of cellulose. Biotechnol Progr, 2007, 23: 1333-1339.

[41]

Shi H, Zhou M, Li C, Sheng X, Yang Q, Li N, Niu M. Surface sediments formation during auto-hydrolysis and its effects on the benzene-alcohol extractive, absorbability and chemical pulping properties of hydrolyzed acacia wood chips. Bioresour Technol, 2019, 289: 121604.

[42]

Shuai L, Amiri MT, Questell-Santiago YM, Héroguel F, Li Y, Kim H, Meilan R, Chapple C, Ralph J, Luterbacher JS. Formaldehyde stabilization facilitates lignin monomer production during biomass depolymerization. Science, 2016, 354: 329-333.

[43]

Shuai L, Questell-Santiago YM, Luterbacher JS. A mild biomass pretreatment using γ-valerolactone for concentrated sugar production. Green Chem, 2016, 18: 937-943.

[44]

Sluiter A, Hames B, Ruiz R, Scarlata C, Sluiter J, Templeton D, Crocker D (2012) Determination of structural carbohydrates and lignin in biomass. Laboratory Analytical Procedure (LAP), Technical Report: NREL/TP-510–42618. National Renewable Energy Laboratory, Golden, Colorado
[45]

Smith PK, Krohn RI, Hermanson GT, Mallia AK, Gartner FH, Provenzano MD, Fujimoto EK, Goeke NM, Olson BJ, Klenk DC. Measurement of protein using bicinchoninic acid. Anal Biochem, 1985, 150: 76-85.

[46]

Song J, Yang F, Zhang Y, Hu F, Wu S, Jin Y, Guo J, Rojas OJ. Interactions between fungal cellulases and films of nanofibrillar cellulose determined by a quartz crystal microbalance with dissipation monitoring (QCM-D). Cellulose, 2017, 24: 1947-1956.

[47]

Sun Y, Cheng JJ. Dilute acid pretreatment of rye straw and Bermudagrass for ethanol production. Bioresour Technol, 2005, 96: 1599-1606.

[48]

Ueno Y, Taneda D, Okino S, Shirai Y. Inhibitory effect of additives on cellulase adsorption mediated by hydrophobic interaction. J Jpn Petrol Inst, 2018, 61: 357-360.

[49]

Wang Z, Zhu JY, Fu Y, Qin M, Shao Z, Jiang J, Yang F. Lignosulfonate-mediated cellulase adsorption: enhanced enzymatic saccharification of lignocellulose through weakening nonproductive binding to lignin. Biotechnol Biofuels, 2013, 6: 156.

[50]

Yang B, Wyman CE. Effect of xylan and lignin removal by batch and flowthrough pretreatment on the enzymatic digestibility of corn stover cellulose. Biotechnol Bioeng, 2004, 86: 88-98.

[51]

Yang B, Wyman CE. BSA treatment to enhance enzymatic hydrolysis of cellulose in lignin containing substrates. Biotechnol Bioeng, 2006, 94: 611-617.

[52]

Yu H, Xu Y, Hou J, Nie S, Liu S, Wu Q, Liu Y, Liu Y, Yu S. Fractionation of corn stover for efficient enzymatic hydrolysis and producing platform chemical using p-toluenesulfonic acid/water pretreatment. Ind Crop Prod, 2020, 145: 111961.

[53]

Zheng L, Zhao Y, Xiao C, Sun-Waterhouse D, Zhao M, Su G. Mechanism of the discrepancy in the enzymatic hydrolysis efficiency between defatted peanut flour and peanut protein isolate by Flavorzyme. Food Chem, 2015, 168: 100-106.

[54]

Zheng P, Chen N, Mahfuzul Islam SM, Ju L-K, Liu J, Zhou J, Chen L, Zeng H, Lin Q. Development of self-cross-linked soy adhesive by enzyme complex from Aspergillus niger for production of all-biomass composite materials. ACS Sustain Chem Eng, 2019, 7: 3909-3916.

[55]

Zheng P, Zeng Q, Lin Q, Fan M, Zhou J, Rao J, Chen N. Investigation of an ambient temperature-curable soy-based adhesive for wood composites. Int J Adhes Adhes, 2019, 95: 102429.

Funding

National Natural Science Foundation of China(31870559)

National Natural Science Foundation of China(31901262)

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