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Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens and its use in membrane reactor
Accepted Manuscript Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens and its use in membrane reactor Zhen Qin, Sa Luo, Yun Li, Qiming Chen, Yongjun Qiu, Liming Zhao, Lihua Jiang, Jiachun Zhou PII:
S0023-6438(18)30538-3
DOI:
10.1016/j.lwt.2018.06.027
Reference:
YFSTL 7211
To appear in:
LWT - Food Science and Technology
Received Date: 8 February 2018 Revised Date:
12 June 2018
Accepted Date: 13 June 2018
Please cite this article as: Qin, Z., Luo, S., Li, Y., Chen, Q., Qiu, Y., Zhao, L., Jiang, L., Zhou, J., Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens and its use in membrane reactor, LWT - Food Science and Technology (2018), doi: 10.1016/j.lwt.2018.06.027. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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ACCEPTED MANUSCRIPT Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens
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and its use in membrane reactor
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Zhen Qinab, Sa Luoa, Yun Lia, Qiming Chenab, Yongjun Qiuab, Liming Zhaoab*, Lihua
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Jiangab, Jiachun Zhouab
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5 6
a
School of Biotechnology, State Key Laboratory of Bioreactor Engineering, R&D
Center of Separation and Extraction Technology in Fermentation Industry, East China
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University of Science and Technology, Shanghai 200237, China
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b
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Shanghai Collaborative Innovation Center for Biomanufacturing Technology
(SCICBT), Shanghai 200237, China
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* Corresponding author.
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E-mail address: [email protected] (L.M. Zhao)
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Fax: +86 021-64250829
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No. 130 Meilong Road, Shanghai 200237, China
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Abstract Chitooligosaccharides are widely used in functional food, medicaments and
25
agriculture. Controllable conversion of chitosan to chitooligosaccharides with desired
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degree of polymerization (DP) is of great value. Herein, a novel glycoside hydrolase
27
family 46 chitosanase (BaCsn46A) was cloned and expressed from Bacillus
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amyloliquefaciens. BaCsn46A exhibited good enzymatic properties with high specific
29
activity (1031.2 U/mg) under optimal hydrolysis conditions of pH 6.0 and 50°C.
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BaCsn46A is an endo-type chitosanase, which could be utilized to yield abundant
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chitooligosaccharides. Furthermore, the preparation of high degree of polymerization
32
chitooligosaccharides (DP 5–10) was investigated by BaCsn46A in an enzymatic
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reactor with a subsequent series of membranes. The maximum concentration of total
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chitooligosaccharides (DP 2–10) was 28.11 g/L (93.70% yield). The proportion of high
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degree of polymerization chitooligosaccharides (DP 5–10) occupied 56.17% (w/w) of
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total chitooligosaccharides. This study provided a cleaner production process for the
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controllable
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polymerization.
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preparation of chitooligosaccharides
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with
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KEYWORDS: Chitosanase; Chitooligosaccharides; Glycoside hydrolase family 46;
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Enzyme membrane reactor; Product selectivity
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1. Introduction Chitooligosaccharides are the degradation products of chitosan, which showed
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various functional properties, including antimicrobial, antitumor, antioxidant,
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immunostimulatory and elicitors of plant defence (Aam et al., 2010). As beneficial
49
biological activities, chitooligosaccharides are widely used in functional food,
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medicaments and agriculture (Das et al., 2015; Zou et al., 2016). Commercial
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chitooligosaccharides are often obtained by enzymatic hydrolysis of chitosan. The
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specific chitosan hydrolytic enzyme is chitosanase (E C 3.2.1.132). However, as the
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endo-type catalytic mode, chitosanases often randomly cleave β-1,4-glycosidic bond
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inside of chitosan, and release a mixture of uncontrollable chitooligosaccharides. Most
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of the reported chitosanases tend to hydrolyze chitosan to produce chitobiose,
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chitotriose and chitotetraose as final hydrolytic products rather than higher degree of
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polymerization (DP) chitooligosaccharides (Nidheesh, Pal & Suresh, 2015; Zhang, et
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al., 2015). The high DP chitooligosaccharides are intermediate products, which are
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continuously degraded in the reaction progress (Kuroiwa et al., 2009; Lin, Hsiao &
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Chiang, 2009). However, the biological activities of chitooligosaccharides depend on
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their DP (Sanchez et al., 2017; Sinha, Chand & Tripathi, 2016). Some previous studies
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confirmed that high DP chitooligosaccharides exhibited more significant physiological
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activity to be utilized in functional foods and pharmaceutical than the low DP
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chitooligosaccharides (Kuroiwa, et al., 2009; Li, Xing, Liu & Li, 2016; Lin et al.,
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2009). Therefore, obtaining novel specific chitosanase and investigating controllable
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bioconversion process are highly beneficial for the production of high value
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chitooligosaccharides in industrial scale. The
development
of
membrane
separation
technology
introduces
enzyme-membrane coupling process (also named enzyme membrane reactor) in which
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continuous reaction occurs simultaneously with separation of the target product from
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the reaction mixture (Pinelo, Jonsson & Meyer, 2009). Thus the enzyme-membrane
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coupling process has the potential to separate high DP chitooligosaccharides from the
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hydrolytic
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chitooligosaccharides being further hydrolyzed. Moreover, a membrane process after
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the enzymatic treatment allows the continuous separation the products from reaction
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mixture, which decrease product inhibition in the enzymatic reaction and promote the
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cyclic utilization of enzyme (Andric, Meyer, Jensen & Dam-Johansen, 2010). To date,
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most of the chitooligosaccharides enzyme-membrane coupling studies focus on the
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continuous production of chitooligosaccharides (Jeon & Kim, 2000; Kuroiwa, et al.,
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2009; Santos-Moriano, Woodley & Plou, 2016). Some previous studies indeed
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demonstrated that high DP chitooligosaccharides could be enriched through enzyme
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membrane bioreactor, the final yields of high DP chitooligosaccharides reached 46–69 %
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in total (Kuroiwa et al., 2009; Lin et al., 2009). However, the high investment of
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pressurized membrane reactor and the lack of suited low-cost specific chitosanases
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limits the further process engineering investigation of enzyme-membrane coupling
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technology.
and
prevent
the
intermediate
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mixture,
high
DP
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In this study, the gene cloning, expression and biochemical properties of a novel
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chitosanase from Bacillus amyloliquefaciens were investigated. Furthermore, the 4
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matching technique for producing high DP chitooligosaccharides was investigated by
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hydrolysis
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ultrafiltration-nanofiltration membrane system. This study provided potential
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enzyme-membrane coupling technology and relevant enzyme for the preparation of
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high DP chitooligosaccharides.
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2. Materials and methods
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2.1. Cloning, expression and enzyme purification
in
an
enzymatic
reactor
in
series
with
an
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chitosan
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of
B. amyloliquefaciens YX-01 used in this study was isolated from fermented fruits
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beverages samples. From the genome information of B. amyloliquefaciens (He et al.,
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2012), a putative GH family 46 chitosanase gene (GenBank: AFJ63438) was identified.
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To express this gene (BaCsn46A) in E. coli, the gene fragment was amplified from the
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genomic DNA of B. amyloliquefaciens YX01. NheI and XhoI sites (underlined) were
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added
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ATTCTAGCTAGCGCCGGGCTGAATAAGGATC;
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CCGCTCGAGTTATTGAATAGTGAAATTACCGTATTCGC), respectively. The
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PCR products were gel-purified, digested, and cloned into pET-28a vector, and the
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recombinant plasmids were transformed into E. coli BL21 (DE3) competent cells for
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gene expression.
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The recombinant protein was concentrated and purified as described before (Qin,
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Yan, Yang & Jiang, 2016). Briefly, the cells were harvested and suspended in buffer A
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(50 mmol/L Tris–HCl pH 8.0, 500 mmol/L NaCl, 20 mmol/L imidazole), then
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disrupted by sonication. The debris was removed by centrifugation at 10,000×g for 5 5
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Sciences, USA) pre-equilibrated with buffer A. The column was washed with 15
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column volumes (CV) of buffer A followed by 5 CV of buffer B (Buffer A containing
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50 mmol/L imidazole), and the recombinant protein was eluted by 5 CV of buffer C
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(Buffer A containing 200 mmol/L imidazole). The purified protein fractions were
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combined, concentrated and buffer exchanged in buffer (20 mmol/L Tris-HCl, 100
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mmol/L NaCl, pH 7.5) for subsequent experiments. Protein concentration was
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measured by the Bradford method Kit (Sangon, Shanghai, China), using BSA as the
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standard. Briefly, serial dilutions of the protein samples (100 µL, final concentrations
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of 0 to 200 µg/mL) were prepared. Then added 1.0 mL of coomassie blue reagent to
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each tube and mixed by vortex. After 5 minutes, the protein concentration was
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determined by measuring absorbance at 595 nm and calculated through the calibration
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curve (R2=0.9995). The association form and the molecular weight of BaCsn46A were
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estimated by Matrix-Assisted Laser Desorption/Ionization Time of Flight Mass
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Spectrometry (MALDI-TOF MS; AB SCIEX TOF/TOFTM 4800 System, AB SCIEX,
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USA).
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2.2. Sequencing and phylogenetic analysis
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N-terminal
signal
peptide
was
analyzed
using
SignalP
4.1
Server
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(http://www.cbs.dtu.dk/services/SignalP/). Database homology searches of sequences
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were carried out using BLAST in GenBank at the NCBI. Sequence analysis and
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multiple alignments were performed by Clustal W program and ESPript.
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2.3. Enzyme assay, substrate specificity and kinetic parameters 6
ACCEPTED MANUSCRIPT Chitosanase activity was assayed using 3,5-dinitrosalicylic acid (DNS) method as
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previous study (Qin et al., 2018). Namely, 50 µL properly diluted enzyme solution was
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added into 350 µL of 0.5 % (w/v) chitosan (degree of deacetylation ≥ 95%; molecular
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weight 150–300 kDa; Aladdin, Shanghai, China) substrate mixture (prepared in 50
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mmol/L sodium acetate buffer pH 6.0, which was preincubated at 50 °C for 5 min). The
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reaction mixture was incubated at 50 °C in a water bath for 10 min. The reaction was
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terminated by adding 600 µL DNS reagent and boiled for 10 min. The reducing sugar in
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the supernatant was determined by measuring absorbance at 540 nm, using
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D-glucosamine as standards. The dilution ratio of enzyme solution was based on the
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absorbance of final mixture at 540 nm, namely the absorbance values should be ensured
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within 0.2-0.8. The reactions were done in triplicate and their mean and standard
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deviation values were used for analysis. One unit (U) of chitosanase activity was
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defined as the amount of enzyme liberating 1 µmol D-glucosamine-equivalent reducing
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sugars per minute under the above conditions.
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Substrate specificity of BaCsn46A was determined by measuring the enzyme’s
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activity in the presence of different substrates such as chitosan, colloidal chitin and
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microcrystalline cellulose. The enzyme activity was determined under standard
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conditions. The kinetic parameters were analyzed using various concentrations of
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chitosan, ranging from 0.5 to 10.0 mg/mL. The reactions were performed at 50 °C for 5
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min in 50 mmol/L sodium acetate buffer pH 6.0. Experiments were carried out in
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triplicate. By plotting reaction rate against concentration, Km and Vmax values were
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calculated using the nonlinear regression analysis of the Michaelis–Menten equation by
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program Grafit.
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2.4. Characterization of BaCsn46A Chitosan was used as substrate to determine the enzymatic characterization of
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BaCsn46A.The optimal pH for purified BaCsn46A was determined by measuring the
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activity from pH 4.5 to 8.0 using 50 mmol/L various buffers. To determine pH
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stability, residual activity was measured after incubation of the enzyme at 20 °C for
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30 min in the 50 mmol/L various buffers. The optimal temperature was determined at
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30–70 °C in 50 mmol/L sodium acetate buffer pH 6.0. Enzymatic activity was
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determined under standard conditions. Thermostability of the enzyme was determined
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by measuring residual activity after incubation of the enzyme at different
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temperatures (30–70 °C) for 30 min in 50 mmol/L sodium acetate buffer pH 6.0.
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Thermostability means the quality of enzyme to resist irreversible inactivation at a
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high relative temperature. The enzyme activity was determined by standard enzyme
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assay conditions mentioned above. The concentration of chitosan substrate was 0.5 %
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(w/v) and the concentration of enzyme solution (about 0.05-0.5 µg/mL) was diluted
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based on the absorbance values mentioned above.
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2.5. Hydrolytic pattern of BaCsn46A
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The hydrolytic properties of BaCsn46A were investigated by analyzing the
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hydrolysis products from the substrates including chitosan and chitooligosaccharides
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(chitobiose: (GlcN)2; chitotriose: (GlcN)3; chitotetraose: (GlcN)4; chitopentaose:
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(GlcN)5 and chitohexaose: (GlcN)6) (purity ≥ 95%, Long Dragon Bio., Huizhou,
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China). BaCsn46A (1.5 U/mL) was added to 1% (w/v) chitosan and then incubated at 8
ACCEPTED MANUSCRIPT 177
50 °C for 2 h in 50 mmol/L acetate buffer pH 6.0 (reaction volume: 500 µL). For the
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chitooligosaccharides,
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chitooligosaccharides, and then incubated at 50 °C for a certain reaction time in 50
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mmol/L acetate buffer pH 6.0 (reaction volume: 100 µL). Samples withdrawn at
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different times were immediately boiled for 5 min, and then analyzed by Thin-Layer
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Chromatography (TLC) method. Samples were spotted on a TLC plate (Silica gel 60
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F254, Merck, Darmstadt, Germany), developed in isopropanol: water: ammonium
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hydroxide (15:1:7.5, v/v) as solvent, and sprayed with alcohol: p-anisaldehyde:
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sulfuric acid: acetic acid (89:5:5:1, v/v). The hydrolysis products were visualized by
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heating the plate at 130 °C in an oven for a few minutes.
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2.6. Enzyme-membrane coupling reactor system
U/mL)
was
added
to
1%
(w/v)
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(1.5
A spiral-wound membrane system (Ruina membrane engineering, Hangzhou, China)
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BaCsn46A
was coupled with a 5 L stainless steel jacket reaction tank to build the
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enzyme-membrane coupling reactor system (Fig. 1). The membrane was a
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polyethersulfone UF membrane with molecular weight cut-off 5000 Da (Risingsun,
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Beijing, China). The effective membrane area was 0.37 m2. The impeller pump
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installed in the spiral-wound membrane system was used to provide transmembrane
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pressure and link the membrane module and the reaction tank to circulate reaction
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solution through the system. Warm water from a circulating water bath flowed
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continuously through the jacket of reaction tank to maintain a constant reaction
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temperature.
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For the substrate preparation, chitosan powder was dissolved in 0.05 mol/L 9
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chitosan solution (3 L) was further moved to the reaction tank, and the catalytic
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reaction was started by adding 100 U/g crude enzyme of BaCsn46A. The reaction
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mixture was maintained at 40 °C for 150 min. In order to reduce the viscosity of the
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chitosan solution, the enzymatic reaction was first proceeding for 20 min in the
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reaction tank. Then the pump was turned on to pump the mixture in the reaction tank
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through the membrane module with 5 bar pressure. The permeate was diverted to the
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product tank of tandem nanofiltration system, and the retentate was returned circularly
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to the reaction tank for further reaction. The proper amount of 0.05 mol/L acetate
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buffer at pH 5.5 was continuously fed to the reaction tank from another feed tank to
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maintain a minimum volume of the mixture in the reaction tank. At various time
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intervals, samples of permeate and retentate were withdrawn at different times and
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immediately boiled for 5 min. The concentrations of different chitooligosaccharides
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were analyzed by TLC and High Performance Liquid Chromatography (HPLC). The
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content of total chitooligosaccharides was calculated by the total concentration of
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different chitooligosaccharides in permeate from the product tank multiply by permeate
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volume. The yield was calculated by following formula:
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Yield =
C×V M
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C: the total concentration of chitooligosaccharides;
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V: the volume of permeate from the product tank;
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M: the content of initial chitosan.
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2.7. Nanofiltration concentration of chitooligosaccharides products 10
ACCEPTED MANUSCRIPT In order to concentrate the chitooligosaccharides products, desalinate reaction
221
mixture and recycle the acetate buffer from aforementioned enzyme-membrane
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coupling reactor system, a nanofiltration system was used in series (Fig. 1). A
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spiral-wound NF membrane system (Ruina membrane engineering, Hangzhou, China)
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was coupled with aforementioned enzyme-membrane coupling reactor system. The
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memberane was a three-layer thin-film composite NF membrane with molecular
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weight cut-off 300 Da (Risingsun, Beijing, China). The effective membrane area was
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0.37 m2. After the volume of feed liquid in the product tank was more than the dead
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volume of nanofiltration system, the pump was turned on to pump the feed liquid
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through the nanofiltration membrane module with 10 bar pressure. The permeate was
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diverted to the reaction tank of aforementioned enzyme-membrane coupling reactor
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system, and the retentate was returned to the product tank of nanofiltration system
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(Fig. 1). After 150 min, the previous step of ultrafiltration system was turned off and 6
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L deionized water was gradually added into the product tank. The nanofiltration
234
system continued working until the feed liquid was concentrated about 3 L. The
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concentrations of different chitooligosaccharides in the final products were analyzed by
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MALDI-TOF MS and HPLC. The yield of total chitooligosaccharides was calculated
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by above formula.
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2.8. Hydrolysis of chitosan by free BaCsn46A
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In order to compare the differences between the enzyme-membrane coupling process
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and uncontrolled enzymatic hydrolysis process during the chitooligosaccharides
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preparation. Enzymatic reaction in bulk system with same conditions was further 11
ACCEPTED MANUSCRIPT investigated. The hydrolytic process was carried out under the following conditions:
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pH 5.5, 40 °C, substrate concentration 3%, enzyme concentration 100 U/g, reaction
244
time 150 min, stirring rate 80 rpm/min, reaction volume 3 L. Samples were withdrawn
245
at different times (the same as enzyme-membrane coupling process) and immediately
246
boiled for 5 min, followed by TLC and HPLC analysis.
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2.9. Chitooligosaccharides analysis methods
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The chitooligosaccharides mixtures were analyzed by HPLC system (Shimadzu
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20A, Shimadzu, Kyoto, Japan) equipped with evaporative light-scattering detector
250
(ELSD). The chitooligosaccharides were separated on high-performance sugar
251
column (Shodex Asahipak NH2 P-50 4E, Shodex, Kyoto, Japan), eluted by acetonitrile
252
and distilled water (70/30) mixture with a flow rate of 1.0 mL/min at 30 °C. The
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concentrations of different chitooligosaccharides were quantified by integrating peak
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areas based on the respective standard curve. The pure standards of high DP
255
chitooligosaccharides (DP>6) were unable purchased or obtained, therefore, the high
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DP chitooligosaccharides were identified by the sequence of peaks appeared in the
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HPLC chromatogram, and the concentrations of these chitooligosaccharides were
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estimated based on the standard curve of chitohexaose (Lin et al., 2009). In order to
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determine the DP of chitooligosaccharides, mixtures were analyzed by MALDI-TOF
260
MS.
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3. Results
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3.1. Sequence analysis, expression and purification of BaCsn46A
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The full-length BaCsn46A gene had an open reading frame (ORF) of 843 bp 12
ACCEPTED MANUSCRIPT encoding 280 amino acids with a theoretical molecular mass of 31.62 kDa and pI of
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8.83. A signal peptide of 38 amino acids was predicted by SignalP analysis. The active
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sites were highly conversed in all reported GH family 46 enzymes (Supplementary Fig.
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1). Two strictly reserved residues, Glu57 and Asp73, were hypothesized to be the
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general acid/base and the nucleophilic catalytic residues in BaCsn46A, respectively.
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To study the enzymatic properties of this GH family 46 enzyme without potential
270
interference from the signal peptide, only the nucleotide sequence corresponding to the
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GH family 46 catalytic module was cloned into the vector pET28A. BaCsn46A was
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purified by one step of affinity chromatography with a purification factor of 5.86 and a
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recovery yield of 53.5% (Supplementary Table S1). The recombinant BaCsn46A
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migrated as a single band with molecular mass of 31 kDa on SDS-PAGE (Fig. 2A), in
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good accordance with the predicted molecular weight. MALDI-TOF MS analysis
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showed that BaCsn46A are mainly present as monomers in the solution and the
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monomeric molecular weight of BaCsn46A was about 29.68 kDa (Fig. 2B).
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3.2. Biochemical properties of BaCsn46A
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Effects of pH and temperature on the chitosanase activity of BaCsn46A were
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examined. BaCsn46A was most active at pH 6.0 in acetate buffer (Fig. 3A) and
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exhibited better activity within pH 4.0–9.5 as more than 80% of its activity was
282
retained after incubation in various buffers for 30 min (Fig. 3B). It is noteworthy that
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BaCsn46A was unstable in McIlvaine buffer, which showed about half activity
284
towards optimal buffer (acetate buffer) and partly inactivated after incubation in
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McIlvaine buffers (pH 3.0–5.0) for 30 min. The optimal temperature for BaCsn46A
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287
60 °C (Fig. 3C). The suitable catalytic temperature of BaCsn46A for application was
288
below 45 °C. It retained more than 80% of its initial activity after incubation at 45 °C
289
for 30 min (Fig. 3D).
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BaCsn46A showed relative high specific activity towards chitosan (1031.2 U/mg),
291
but exhibited no activity towards other β-1,4 linked polysaccharide such as colloidal
292
chitin and microcrystalline cellulose. The kinetic parameters, Vmax and Km of
293
BaCsn46A towards chitosan were determined to be 7142.9 µmol/min.mg and 2.8
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mg/mL.
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3.3. Hydrolysis pattern of BaCsn46A
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The hydrolysis of chitosan by the purified BaCsn46A was performed. The DP of
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oligosaccharides products from BaCsn46A was related to the reaction time. The
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degradation of chitosan produced a mixture of chitooligosaccharides (mainly DP 2–6)
299
during the initial hydrolysis, with chitobiose and chitotriose as the end products (Fig. 4).
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To understand the details of the hydrolysis mechanism, hydrolysis patterns of various
301
linear chitooligosaccharides were further investigated by TLC (Fig. 5). The enzyme
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hardly hydrolyzed chitobiose and chitotriose. However, it could effectively hydrolyze
303
chitotetraose, chitopentaose and chitohexaose. Chitotetraose was gradually hydrolyzed
304
to produce mainly chitobiose in 30 min (Fig. 5), whereas chitopentaose and
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chitohexaose was completely hydrolyzed to yield mainly chitobiose and chitotriose in 2
306
h (Fig. 5).
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3.4. Hydrolysis of chitosan in the membrane reactor
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309
membrane material, the membrane reactor system worked at an operating temperature
310
of 40 °C. The results show that the series of chitooligosaccharides produced was mainly
311
DP2 to DP10 (Fig. 6A). Chitopentaose was the most abundant component in the
312
reaction mixture. In the enzyme-membrane coupling reaction process, the entire
313
chitooligosaccharides component gradually accumulated with reaction time (Fig. 6B).
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The concentration of high DP chitooligosaccharides (DP5–10, intermediate products)
315
was not decreased during enzyme-membrane coupling reaction. The proportions of
316
different chitooligosaccharides components were almost unchanged during the whole
317
reaction process (Fig. 6C). After 150 min reaction, there was nearly no
318
chitooligosaccharides and reducing sugar in the real-time permeate (Supplementary
319
Fig. S2). The yield of total chitooligosaccharides (DP2–10) was 100.06 % by HPLC
320
analysis. The part of high DP chitooligosaccharides (DP5–10) was 50.50 g, which
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occupied 56.08% (w/w) of total detected chitooligosaccharides.
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3.5. Nanofiltration of chitooligosaccharides products
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and
MALDI-TOF
MS
analysis
indicated
that
the
final
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chitooligosaccharides products after nanofiltration concentration mainly contained
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(GlcN)2 to (GlcN)10, no glucosamine was deteted in the final products (Fig. 7). After
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nanofiltration, the maximum concentration of total chitooligosaccharides (DP2–10)
327
was 28.11 g/L, corresponding to 93.70% of the initial chitosan concentration. The ratio
328
(w/w) of (GlcN)2, (GlcN)3, (GlcN)4, (GlcN)5, (GlcN)6, (GlcN)7–10 were 6.55%,
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16.51%, 20.77%, 28.51%, 11.56% and 16.10% respectively. The proportion of high 15
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DP
chitooligosaccharides
(DP5–10)
occupied
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chitooligosaccharides.
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3.6. Hydrolysis of chitosan by free BaCsn46A
56.17%
(w/w)
of
total
In order to evaluate the hydrolytic result of chitosan by enzyme-membrane coupling
334
system, the time course of different chitooligosaccharides concentrations during the
335
batch hydrolysis of chitosan in the same condition using free BaCsn46A was
336
investigated. Free BaCsn46A could efficiently degrade chitosan, releasing a series of
337
chitooligosaccharides (DP2–10) (Fig. 6D). The concentrations of the target high DP
338
chitooligosaccharides (DP5–10) increased in the initial reaction time (0–30 min) and
339
then decreased in the remaining reaction process (Fig. 6E). The hydrolysis of chitosan
340
yielded predominantly (GlcN)2–5 as the main end products (Fig. 6F). The final yield of
341
total chitooligosaccharides (DP2–10) was 86.85% during 150 min hydrolytic reaction.
342
The concentration of high DP chitooligosaccharides (DP5–10) was 9.90 g/L, which
343
occupied 38.01% (w/w) of total chitooligosaccharides.
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4. Discussion
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Most chitosanases have been reported to display strict substrate specificity (Weikert,
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Niehues, Cord-Landwehr, Hellmann & Moerschbacher, 2017). In this study,
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BaCsn46A exhibited relatively high specific activity towards chitosan. No activity
348
towards chitin and cellulose had been observed for BaCsn46A. A comparison of the
349
hydrolysis behavior of BaCsn46A to other GH family 46 chitosanases indicated that
350
BaCsn46A produce (GlcN)2 and (GlcN)3 as the major end products, no glucosamine
351
was detected during hydrolytic process. Moreover, BaCsn46A hardly hydrolyzed
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353
action pattern with a demand of at least four glucosamine residues for effective
354
cleavage. The -2, -1, +1 and +2 subsites were necessary for the catalytic reaction of
355
BaCsn46A in the total six subsites of catalytic groove (Supplementary Fig. S3). Thus,
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the minimum substrate of BaCsn46A was (GlcN)4, and no GlcN yield in the
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hydrolytic reaction.
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Biochemical properties analysis suggested that BaCsn46A was a typical endo-type
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GH family 46 chitosanase. The high specific activity and appropriate catalytic property
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of BaCsn46A suggested its potential use in conversion of chitosan into
361
chitooligosaccharides with commercial value. There are many previous studies
362
identified various valuable chitosanases (Thadathil & Velappan, 2014), however only
363
a few subsequent studies investigated how to well use these valuable chitosanases and
364
develop suitable chitooligosaccharides production process. Controllable enzymatic
365
preparing chitooligosaccharides with desired DP are still complicated in industrial
366
scale. As the endo-type catalytic mode of BaCsn46A, chitooligosaccharides with high
367
DP (DP 5–10) were suitable substrates of BaCsn46A, which were hydrolyzed to small
368
chitooligosaccharides during the subsequent hydrolytic process. If the target
369
intermediate chitooligosaccharides products could be separated from the hydrolytic
370
mixture containing the chitosanase, further hydrolyzing could be avoided and the
371
high-value chitooligosaccharides with high DP could be obtained in higher yield.
372
Therefore, the membrane separation technique was coupled with the hydrolytic process
373
of BaCsn46A to produce the target intermediate chitooligosaccharides in the further
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studies. The molecular weight of BaCsn46A was about 30,000 Da and the initial average
376
molecular weight of undegraded chitosan was about 150–300 kDa. In contrast, the
377
target intermediate chitooligosaccharides (DP 5–10) was between about 823 Da and
378
1628 Da. Thus the ultrafiltration membranes with the average pore sizes of 5000 Da
379
were choose in the in the following experiments. The target intermediate high DP
380
chitooligosaccharides products could be separated from reaction mixture, and
381
BaCsn46A could be retained and recycled to reactor tank. Through a series membrane
382
separation system, the enzymatic hydrolysis of chitosan was performed with batch
383
operation of enzyme-membrane reactor coupled with nanofiltration membrane. After
384
nanofiltration, the maximum total concentration of chitooligosaccharides (DP2–10)
385
was 28.11 g/L, corresponding to 93.70% of the initial chitosan concentration. There
386
were nearly no acetate detected form HPLC analysis in the chitooligosaccharides
387
product (Fig. 7A), which indicated that chitooligosaccharide syrup was effectively
388
concentrated and desalinated by single step nanofiltration. Furthermore, the
389
spiral-wound membrane reactor could avoid membrane fouling in the hydrolytic
390
process comparing with previous flat sheet enzyme-membrane reactor (Kuroiwa, et al.,
391
2009). More importantly, the proportion of high DP chitooligosaccharides (DP5–10)
392
occupied 56.17% (w/w) of total chitooligosaccharides. The yield of target high DP
393
chitooligosaccharides (DP5–10) was higher than previous immobilized enzyme
394
bioreactor, membrane bioreactor and free chitosanase hydrolysis studies (Kuroiwa, et
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al., 2009; Ming, Kuroiwa, Ichikawa, Sato & Mukataka, 2006; Nidheesh et al., 2015).
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the target high DP chitooligosaccharides initially increased with time and then
398
decreased after peaking under the same reaction condition (Fig. 6E). These
399
oligosaccharides were intermediate products of the hydrolysis reaction and were
400
degraded by further enzymatic reaction. Moreover, chitooligosaccharides products in
401
high
402
chitooligosaccharides products increased slowly after 70 min incubation. The final
403
yield of total chitooligosaccharides by free BaCsn46A (86.85%) was lower than
404
enzyme-membrane coupling system (93.70%) during the same reaction time. Thus it is
405
hardly to obtain abundant high DP chitooligosaccharides by free BaCsn46A in high
406
yield. Without enzyme-membrane coupling operation, low DP chitooligosaccharides
407
(DP2–4) would gradually be primary hydrolytic products by free BaCsn46A. These
408
results illustrated that efficient preparation of the intermediate chitooligosaccharides
409
products required that the enzymatic hydrolytic progress of chitosan should be
410
appropriately controlled.
411
5. Conclusion
chitosanase's
reaction
rate.
The
yield
of
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concentration
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In conclusion, a novel chitosanase (BaCsn46A) from B. amyloliquefaciens was gene
413
cloned, expressed, and biochemically characterized. BaCsn46A is a monomer with a
414
molecular mass of 29.68 kDa. It was most active at pH 6.0 and 50 °C. BaCsn46A
415
showed relative high specific activity towards chitosan (1031.2 U/mg) to yield a series
416
of chitooligosaccharides by an endo-type cleavage pattern. In addition, this study
417
demonstrated that hydrolysis of chitosan by BaCsn46A through an enzyme-membrane 19
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419
preparation of high degree of polymerization chitooligosaccharides. The maximum
420
total yield of chitooligosaccharides (DP 2–10) was 93.70%, and the proportion of high
421
degree of polymerization chitooligosaccharides (DP 5–10) occupied 56.17% (w/w) of
422
total chitooligosaccharides.
423
Acknowledgements
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This work was financially supported by the National Natural Science Foundation of
425
China (31701537), China Postdoctoral Science Foundation (2016M601530),
426
Shanghai Sailing Program (17YF1403500), Fundamental Research Funds for the
427
Central Universities (222201814031) and “Shu Guang” project of Shanghai
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Municipal Education Commission and Shanghai Education Development Foundation
429
(15SG28).
430
References
431
Aam, B. B., Heggset, E. B., Norberg, A. L., Sorlie, M., Varum, K. M., & Eijsink, V.
432
G. H. (2010). Production of chitooligosaccharides and their potential applications
433
in medicine. Marine Drugs, 8, 1482–1517.
AC C
EP
TE D
M AN U
SC
424
434
Andric, P., Meyer, A. S., Jensen, P. A., & Dam-Johansen, K. (2010). Reactor design
435
for minimizing product inhibition during enzymatic lignocellulose hydrolysis: I.
436 437
Significance and mechanism of cellobiose and glucose inhibition on cellulolytic enzymes. Biotechnology Advances, 28, 308–324.
438
Das, S. N., Madhuprakash, J., N., P. V. S. R., Purushotham, P., Suma, K., Manjeet, K.,
439
Rambabu, S., El Gueddari, N. E., Moerschbacher, B. M., & Podile, A. R. (2015). 20
ACCEPTED MANUSCRIPT 440
Biotechnological approaches for field applications of chitooligosaccharides (COS)
441
to induce innate immunity in plants. Critical Reviews in Biotechnology, 35, 29–43.
442
He, P., Hao, K., Blom, J., Ruckert, C., Vater, J., Mao, Z., Wu, Y., Hou, M., He, P., He, Y., & Borriss, R. (2012). Genome sequence of the plant growth promoting strain
444
Bacillus amyloliquefaciens subsp. plantarum B9601-Y2 and expression of
445
mersacidin and other secondary metabolites. Journal of Biotechnology, 164, 281–
446
291.
448
SC
Jeon, Y. J., & Kim, S. K. (2000). Continuous production of chitooligosaccharides
M AN U
447
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443
using a dual reactor system. Process Biochemistry, 35, 623–632. Kuroiwa, T., Izuta, H., Nabetani, H., Nakajima, M., Sato, S., Mukataka, S., &
450
Ichikawa, S. (2009). Selective and stable production of physiologically active
451
chitosan oligosaccharides using an enzymatic membrane bioreactor. Process
452
Biochemistry, 44, 283–287.
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449
Li, K., Xing, R., Liu, S., & Li, P. (2016). Advances in preparation, analysis and
454
biological activities of single chitooligosaccharides. Carbohydrate Polymers, 139,
455
178–190.
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EP
453
456
Lin, Y., Hsiao, Y., & Chiang, B. (2009). Production of high degree polymerized
457
chitooligosaccharides in a membrane reactor using purified chitosanase from
458
Bacillus cereus. Food Research International, 42, 1355–1361.
459
Ming, M., Kuroiwa, T., Ichikawa, S., Sato, S., & Mukataka, S. (2006). Production of
460
chitosan oligosaccharides by chitosanase directly immobilized on an agar
461
gel-coated multidisk impeller. Biochemical Engineering Journal, 28, 289–294. 21
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Nidheesh, T., Pal, G. K., & Suresh, P. V. (2015). Chitooligomers preparation by
463
chitosanase produced under solid state fermentation using shrimp by-products as
464
substrate. Carbohydrate Polymers, 121, 1–9. Pinelo, M., Jonsson, G., & Meyer, A. S. (2009). Membrane technology for
466
purification of enzymatically produced oligosaccharides: Molecular and operational
467
features affecting performance. Separation and Purification Technology, 70, 1–11. Qin, Z., Yan, Q., Yang, S., & Jiang, Z. (2016). Modulating the function of a beta-1,3-glucanosyltransferase
that
of
an
endo-beta-1,3-glucanase
470
structure-based protein engineering. Applied Microbiology and Biotechnology, 100,
471
1765–1776.
M AN U
469
472
to
SC
468
RI PT
465
by
Qin, Z., Chen, Q., Lin, S., Luo, S., Qiu, Y., & Zhao, L. (2018). Expression and characterization
of
a
novel
cold-adapted
chitosanase
suitable
for
474
chitooligosaccharides controllable preparation. Food Chemistry, 253, 139–147.
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473
Sanchez, A., Mengibar, M., Rivera-Rodriguez, G., Moerchbacher, B., Acosta, N., &
476
Heras, A. (2017). The effect of preparation processes on the physicochemical
477
characteristics and antibacterial activity of chitooligosaccharides. Carbohydrate
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478
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475
Polymers, 157, 251–257.
479
Santos-Moriano, P., Woodley, J. M., & Plou, F. J. (2016). Continuous production of
480
chitooligosaccharides by an immobilized enzyme in a dual-reactor system. Journal
481 482 483
of Molecular Catalysis B-Enzymatic, 133, 211–217. Sinha, S., Chand, S., & Tripathi, P. (2016). Recent progress in chitosanase production of
monomer-free
chitooligosaccharides: 22
bioprocess
strategies
and
future
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applications. Applied Biochemistry and Biotechnology, 180, 883–899. Thadathil, N., & Velappan, S. P. (2014). Recent developments in chitosanase research and its biotechnological applications: A review. Food Chemistry, 150, 392–399. Weikert, T., Niehues, A., Cord-Landwehr, S., Hellmann, M. J., & Moerschbacher, B.
488
M. (2017). Reassessment of chitosanase substrate specificities and classification.
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Nature Communications, 8, 1698.
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Zhang, J., Cao, H., Li, S., Zhao, Y., Wang, W., Xu, Q., Du, Y., & Yin, H. (2015).
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Characterization of a new family 75 chitosanase from Aspergillus sp. W-2.
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International Journal of Biological Macromolecules, 81, 362–369.
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Zou, P., Yang, X., Wang, J., Li, Y., Yu, H., Zhang, Y., & Liu, G. (2016). Advances in
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characterisation and biological activities of chitosan and chitosan oligosaccharides.
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Food Chemistry, 190, 1174–1181.
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Figure legends
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Figure 1 Schematic diagram of the enzyme-membrane coupling reactor system.
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Figure 2 Protein analysis of BaCsn46A. (A) SDS-PAGE of proteins during
500
purification of the recombinant BaCsn46A by Ni-IDA. Lane M: standard protein
501
molecular weight markers; Lane 1: supernatant of lysate cells; Lane 2: purified enzyme.
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(B) MALDI-TOF MS showing the association form and molecular weight of
503
BaCsn46A.
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Figure 3 The effects of temperature and pH on activity of the purified BaCsn46A. (A)
505
Optimum pH, acetate buffer (■), McIlvaine buffer (●), phosphate buffer (▲); (B) pH
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(▼), glycine-NaOH buffer (♦); (C) Optimum temperature and (D) Thermostability. For
508
thermostability, residual activity was measured after incubating the enzyme at different
509
temperatures for 30 min in 50 mM acetate buffer (pH 6.0). The experiments were done
510
in triplicate and their mean and standard deviation values were used for analysis.
511
Figure 4 Hydrolytic process of BaCsn46A towards chitosan. M, marker sugars. The
512
reactions were performed at 50 °C in 50 mmol/L citrate buffer (pH 6.0) and analyzed
513
by TLC. (GlcN)–(GlcN)6: glucosamine, chitobiose, chitotriose, chitotetraose,
514
chitopentaose and chitohexaose, respectively.
515
Figure 5 Hydrolytic process of BaCsn46A towards chitooligosaccharides. M, marker
516
sugars. The substrates were (GlcN)2, (GlcN)3, (GlcN)4, (GlcN)5 and (GlcN)6,
517
respectively. The reactions were performed at 50 °C in 50 mmol/L citrate buffer (pH
518
6.0) and analyzed by TLC.
519
Figure 6 Enzymatic reaction pattern in the membrane reactor system (A–C) and free
520
enzyme system (D–F). (A) Total chitooligosaccharides of permeate by TLC analysis;
521
(B) Total chitooligosaccharides of permeate by HPLC analysis, glucosamine (■),
522
(GlcN)2 (●), (GlcN)3 (▲), (GlcN)4 (▼), (GlcN)5 (♦), (GlcN)6 (◄), (GlcN)7–10 (►)
523
and yield (○); (C) Composing proportion of different chitooligosaccharides monomers
524
in the permeate; (D) Total chitooligosaccharides of free enzymatic reaction mixture
525
by TLC analysis; (E) Total chitooligosaccharides of free enzymatic reaction mixture
526
by HPLC analysis; (F) Composing proportion of different chitooligosaccharides
527
monomers in the free enzymatic reaction mixture. The dot lines in each figures means
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Figure 7 HPLC analysis (A) and MALDI-TOF MS analysis (B) of final products by
530
enzyme-membrane coupling reactor system. The peaks in the spectra correspond to the
531
monoisotopic masses of sodium adducts [M+Na]+ of the chitooligosaccharides. The
532
final products contain chitooligosaccharides with DP 2–10.
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A high-activity chitosanase from B.amyloliquefaciens (BaCsn46A) was identified. BaCsn46A could be used for controllable producing chitooligosaccharides in membrane reactor. High degree polymerized chitooligosaccharides was accumulated by enzyme-membrane coupling process. This study provided a cleaner production process for controllable producing chitooligosaccharides.
S0023-6438(18)30538-3
DOI:
10.1016/j.lwt.2018.06.027
Reference:
YFSTL 7211
To appear in:
LWT - Food Science and Technology
Received Date: 8 February 2018 Revised Date:
12 June 2018
Accepted Date: 13 June 2018
Please cite this article as: Qin, Z., Luo, S., Li, Y., Chen, Q., Qiu, Y., Zhao, L., Jiang, L., Zhou, J., Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens and its use in membrane reactor, LWT - Food Science and Technology (2018), doi: 10.1016/j.lwt.2018.06.027. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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ACCEPTED MANUSCRIPT Biochemical properties of a novel chitosanase from Bacillus amyloliquefaciens
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and its use in membrane reactor
3
Zhen Qinab, Sa Luoa, Yun Lia, Qiming Chenab, Yongjun Qiuab, Liming Zhaoab*, Lihua
4
Jiangab, Jiachun Zhouab
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a
School of Biotechnology, State Key Laboratory of Bioreactor Engineering, R&D
Center of Separation and Extraction Technology in Fermentation Industry, East China
8
University of Science and Technology, Shanghai 200237, China
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b
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Shanghai Collaborative Innovation Center for Biomanufacturing Technology
(SCICBT), Shanghai 200237, China
11
* Corresponding author.
13
E-mail address: [email protected] (L.M. Zhao)
14
Fax: +86 021-64250829
15
No. 130 Meilong Road, Shanghai 200237, China
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Abstract Chitooligosaccharides are widely used in functional food, medicaments and
25
agriculture. Controllable conversion of chitosan to chitooligosaccharides with desired
26
degree of polymerization (DP) is of great value. Herein, a novel glycoside hydrolase
27
family 46 chitosanase (BaCsn46A) was cloned and expressed from Bacillus
28
amyloliquefaciens. BaCsn46A exhibited good enzymatic properties with high specific
29
activity (1031.2 U/mg) under optimal hydrolysis conditions of pH 6.0 and 50°C.
30
BaCsn46A is an endo-type chitosanase, which could be utilized to yield abundant
31
chitooligosaccharides. Furthermore, the preparation of high degree of polymerization
32
chitooligosaccharides (DP 5–10) was investigated by BaCsn46A in an enzymatic
33
reactor with a subsequent series of membranes. The maximum concentration of total
34
chitooligosaccharides (DP 2–10) was 28.11 g/L (93.70% yield). The proportion of high
35
degree of polymerization chitooligosaccharides (DP 5–10) occupied 56.17% (w/w) of
36
total chitooligosaccharides. This study provided a cleaner production process for the
37
controllable
38
polymerization.
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preparation of chitooligosaccharides
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with
specific
degree
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KEYWORDS: Chitosanase; Chitooligosaccharides; Glycoside hydrolase family 46;
41
Enzyme membrane reactor; Product selectivity
42 43 44 2
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1. Introduction Chitooligosaccharides are the degradation products of chitosan, which showed
47
various functional properties, including antimicrobial, antitumor, antioxidant,
48
immunostimulatory and elicitors of plant defence (Aam et al., 2010). As beneficial
49
biological activities, chitooligosaccharides are widely used in functional food,
50
medicaments and agriculture (Das et al., 2015; Zou et al., 2016). Commercial
51
chitooligosaccharides are often obtained by enzymatic hydrolysis of chitosan. The
52
specific chitosan hydrolytic enzyme is chitosanase (E C 3.2.1.132). However, as the
53
endo-type catalytic mode, chitosanases often randomly cleave β-1,4-glycosidic bond
54
inside of chitosan, and release a mixture of uncontrollable chitooligosaccharides. Most
55
of the reported chitosanases tend to hydrolyze chitosan to produce chitobiose,
56
chitotriose and chitotetraose as final hydrolytic products rather than higher degree of
57
polymerization (DP) chitooligosaccharides (Nidheesh, Pal & Suresh, 2015; Zhang, et
58
al., 2015). The high DP chitooligosaccharides are intermediate products, which are
59
continuously degraded in the reaction progress (Kuroiwa et al., 2009; Lin, Hsiao &
60
Chiang, 2009). However, the biological activities of chitooligosaccharides depend on
61
their DP (Sanchez et al., 2017; Sinha, Chand & Tripathi, 2016). Some previous studies
62
confirmed that high DP chitooligosaccharides exhibited more significant physiological
63
activity to be utilized in functional foods and pharmaceutical than the low DP
64
chitooligosaccharides (Kuroiwa, et al., 2009; Li, Xing, Liu & Li, 2016; Lin et al.,
65
2009). Therefore, obtaining novel specific chitosanase and investigating controllable
66
bioconversion process are highly beneficial for the production of high value
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chitooligosaccharides in industrial scale. The
development
of
membrane
separation
technology
introduces
enzyme-membrane coupling process (also named enzyme membrane reactor) in which
70
continuous reaction occurs simultaneously with separation of the target product from
71
the reaction mixture (Pinelo, Jonsson & Meyer, 2009). Thus the enzyme-membrane
72
coupling process has the potential to separate high DP chitooligosaccharides from the
73
hydrolytic
74
chitooligosaccharides being further hydrolyzed. Moreover, a membrane process after
75
the enzymatic treatment allows the continuous separation the products from reaction
76
mixture, which decrease product inhibition in the enzymatic reaction and promote the
77
cyclic utilization of enzyme (Andric, Meyer, Jensen & Dam-Johansen, 2010). To date,
78
most of the chitooligosaccharides enzyme-membrane coupling studies focus on the
79
continuous production of chitooligosaccharides (Jeon & Kim, 2000; Kuroiwa, et al.,
80
2009; Santos-Moriano, Woodley & Plou, 2016). Some previous studies indeed
81
demonstrated that high DP chitooligosaccharides could be enriched through enzyme
82
membrane bioreactor, the final yields of high DP chitooligosaccharides reached 46–69 %
83
in total (Kuroiwa et al., 2009; Lin et al., 2009). However, the high investment of
84
pressurized membrane reactor and the lack of suited low-cost specific chitosanases
85
limits the further process engineering investigation of enzyme-membrane coupling
86
technology.
and
prevent
the
intermediate
SC
mixture,
high
DP
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In this study, the gene cloning, expression and biochemical properties of a novel
88
chitosanase from Bacillus amyloliquefaciens were investigated. Furthermore, the 4
ACCEPTED MANUSCRIPT 89
matching technique for producing high DP chitooligosaccharides was investigated by
90
hydrolysis
91
ultrafiltration-nanofiltration membrane system. This study provided potential
92
enzyme-membrane coupling technology and relevant enzyme for the preparation of
93
high DP chitooligosaccharides.
94
2. Materials and methods
95
2.1. Cloning, expression and enzyme purification
in
an
enzymatic
reactor
in
series
with
an
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chitosan
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of
B. amyloliquefaciens YX-01 used in this study was isolated from fermented fruits
97
beverages samples. From the genome information of B. amyloliquefaciens (He et al.,
98
2012), a putative GH family 46 chitosanase gene (GenBank: AFJ63438) was identified.
99
To express this gene (BaCsn46A) in E. coli, the gene fragment was amplified from the
100
genomic DNA of B. amyloliquefaciens YX01. NheI and XhoI sites (underlined) were
101
added
102
ATTCTAGCTAGCGCCGGGCTGAATAAGGATC;
103
CCGCTCGAGTTATTGAATAGTGAAATTACCGTATTCGC), respectively. The
104
PCR products were gel-purified, digested, and cloned into pET-28a vector, and the
105
recombinant plasmids were transformed into E. coli BL21 (DE3) competent cells for
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gene expression.
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The recombinant protein was concentrated and purified as described before (Qin,
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Yan, Yang & Jiang, 2016). Briefly, the cells were harvested and suspended in buffer A
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(50 mmol/L Tris–HCl pH 8.0, 500 mmol/L NaCl, 20 mmol/L imidazole), then
110
disrupted by sonication. The debris was removed by centrifugation at 10,000×g for 5 5
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112
Sciences, USA) pre-equilibrated with buffer A. The column was washed with 15
113
column volumes (CV) of buffer A followed by 5 CV of buffer B (Buffer A containing
114
50 mmol/L imidazole), and the recombinant protein was eluted by 5 CV of buffer C
115
(Buffer A containing 200 mmol/L imidazole). The purified protein fractions were
116
combined, concentrated and buffer exchanged in buffer (20 mmol/L Tris-HCl, 100
117
mmol/L NaCl, pH 7.5) for subsequent experiments. Protein concentration was
118
measured by the Bradford method Kit (Sangon, Shanghai, China), using BSA as the
119
standard. Briefly, serial dilutions of the protein samples (100 µL, final concentrations
120
of 0 to 200 µg/mL) were prepared. Then added 1.0 mL of coomassie blue reagent to
121
each tube and mixed by vortex. After 5 minutes, the protein concentration was
122
determined by measuring absorbance at 595 nm and calculated through the calibration
123
curve (R2=0.9995). The association form and the molecular weight of BaCsn46A were
124
estimated by Matrix-Assisted Laser Desorption/Ionization Time of Flight Mass
125
Spectrometry (MALDI-TOF MS; AB SCIEX TOF/TOFTM 4800 System, AB SCIEX,
126
USA).
127
2.2. Sequencing and phylogenetic analysis
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N-terminal
signal
peptide
was
analyzed
using
SignalP
4.1
Server
129
(http://www.cbs.dtu.dk/services/SignalP/). Database homology searches of sequences
130
were carried out using BLAST in GenBank at the NCBI. Sequence analysis and
131
multiple alignments were performed by Clustal W program and ESPript.
132
2.3. Enzyme assay, substrate specificity and kinetic parameters 6
ACCEPTED MANUSCRIPT Chitosanase activity was assayed using 3,5-dinitrosalicylic acid (DNS) method as
134
previous study (Qin et al., 2018). Namely, 50 µL properly diluted enzyme solution was
135
added into 350 µL of 0.5 % (w/v) chitosan (degree of deacetylation ≥ 95%; molecular
136
weight 150–300 kDa; Aladdin, Shanghai, China) substrate mixture (prepared in 50
137
mmol/L sodium acetate buffer pH 6.0, which was preincubated at 50 °C for 5 min). The
138
reaction mixture was incubated at 50 °C in a water bath for 10 min. The reaction was
139
terminated by adding 600 µL DNS reagent and boiled for 10 min. The reducing sugar in
140
the supernatant was determined by measuring absorbance at 540 nm, using
141
D-glucosamine as standards. The dilution ratio of enzyme solution was based on the
142
absorbance of final mixture at 540 nm, namely the absorbance values should be ensured
143
within 0.2-0.8. The reactions were done in triplicate and their mean and standard
144
deviation values were used for analysis. One unit (U) of chitosanase activity was
145
defined as the amount of enzyme liberating 1 µmol D-glucosamine-equivalent reducing
146
sugars per minute under the above conditions.
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Substrate specificity of BaCsn46A was determined by measuring the enzyme’s
148
activity in the presence of different substrates such as chitosan, colloidal chitin and
149
microcrystalline cellulose. The enzyme activity was determined under standard
150
conditions. The kinetic parameters were analyzed using various concentrations of
151
chitosan, ranging from 0.5 to 10.0 mg/mL. The reactions were performed at 50 °C for 5
152
min in 50 mmol/L sodium acetate buffer pH 6.0. Experiments were carried out in
153
triplicate. By plotting reaction rate against concentration, Km and Vmax values were
154
calculated using the nonlinear regression analysis of the Michaelis–Menten equation by
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program Grafit.
156
2.4. Characterization of BaCsn46A Chitosan was used as substrate to determine the enzymatic characterization of
158
BaCsn46A.The optimal pH for purified BaCsn46A was determined by measuring the
159
activity from pH 4.5 to 8.0 using 50 mmol/L various buffers. To determine pH
160
stability, residual activity was measured after incubation of the enzyme at 20 °C for
161
30 min in the 50 mmol/L various buffers. The optimal temperature was determined at
162
30–70 °C in 50 mmol/L sodium acetate buffer pH 6.0. Enzymatic activity was
163
determined under standard conditions. Thermostability of the enzyme was determined
164
by measuring residual activity after incubation of the enzyme at different
165
temperatures (30–70 °C) for 30 min in 50 mmol/L sodium acetate buffer pH 6.0.
166
Thermostability means the quality of enzyme to resist irreversible inactivation at a
167
high relative temperature. The enzyme activity was determined by standard enzyme
168
assay conditions mentioned above. The concentration of chitosan substrate was 0.5 %
169
(w/v) and the concentration of enzyme solution (about 0.05-0.5 µg/mL) was diluted
170
based on the absorbance values mentioned above.
171
2.5. Hydrolytic pattern of BaCsn46A
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The hydrolytic properties of BaCsn46A were investigated by analyzing the
173
hydrolysis products from the substrates including chitosan and chitooligosaccharides
174
(chitobiose: (GlcN)2; chitotriose: (GlcN)3; chitotetraose: (GlcN)4; chitopentaose:
175
(GlcN)5 and chitohexaose: (GlcN)6) (purity ≥ 95%, Long Dragon Bio., Huizhou,
176
China). BaCsn46A (1.5 U/mL) was added to 1% (w/v) chitosan and then incubated at 8
ACCEPTED MANUSCRIPT 177
50 °C for 2 h in 50 mmol/L acetate buffer pH 6.0 (reaction volume: 500 µL). For the
178
chitooligosaccharides,
179
chitooligosaccharides, and then incubated at 50 °C for a certain reaction time in 50
180
mmol/L acetate buffer pH 6.0 (reaction volume: 100 µL). Samples withdrawn at
181
different times were immediately boiled for 5 min, and then analyzed by Thin-Layer
182
Chromatography (TLC) method. Samples were spotted on a TLC plate (Silica gel 60
183
F254, Merck, Darmstadt, Germany), developed in isopropanol: water: ammonium
184
hydroxide (15:1:7.5, v/v) as solvent, and sprayed with alcohol: p-anisaldehyde:
185
sulfuric acid: acetic acid (89:5:5:1, v/v). The hydrolysis products were visualized by
186
heating the plate at 130 °C in an oven for a few minutes.
187
2.6. Enzyme-membrane coupling reactor system
U/mL)
was
added
to
1%
(w/v)
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A spiral-wound membrane system (Ruina membrane engineering, Hangzhou, China)
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BaCsn46A
was coupled with a 5 L stainless steel jacket reaction tank to build the
190
enzyme-membrane coupling reactor system (Fig. 1). The membrane was a
191
polyethersulfone UF membrane with molecular weight cut-off 5000 Da (Risingsun,
192
Beijing, China). The effective membrane area was 0.37 m2. The impeller pump
193
installed in the spiral-wound membrane system was used to provide transmembrane
194
pressure and link the membrane module and the reaction tank to circulate reaction
195
solution through the system. Warm water from a circulating water bath flowed
196
continuously through the jacket of reaction tank to maintain a constant reaction
197
temperature.
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ACCEPTED MANUSCRIPT acetate buffer at pH 5.5 to obtain a 30 g/L of chitosan solution. The homogeneous
200
chitosan solution (3 L) was further moved to the reaction tank, and the catalytic
201
reaction was started by adding 100 U/g crude enzyme of BaCsn46A. The reaction
202
mixture was maintained at 40 °C for 150 min. In order to reduce the viscosity of the
203
chitosan solution, the enzymatic reaction was first proceeding for 20 min in the
204
reaction tank. Then the pump was turned on to pump the mixture in the reaction tank
205
through the membrane module with 5 bar pressure. The permeate was diverted to the
206
product tank of tandem nanofiltration system, and the retentate was returned circularly
207
to the reaction tank for further reaction. The proper amount of 0.05 mol/L acetate
208
buffer at pH 5.5 was continuously fed to the reaction tank from another feed tank to
209
maintain a minimum volume of the mixture in the reaction tank. At various time
210
intervals, samples of permeate and retentate were withdrawn at different times and
211
immediately boiled for 5 min. The concentrations of different chitooligosaccharides
212
were analyzed by TLC and High Performance Liquid Chromatography (HPLC). The
213
content of total chitooligosaccharides was calculated by the total concentration of
214
different chitooligosaccharides in permeate from the product tank multiply by permeate
215
volume. The yield was calculated by following formula:
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Yield =
C×V M
216
C: the total concentration of chitooligosaccharides;
217
V: the volume of permeate from the product tank;
218
M: the content of initial chitosan.
219
2.7. Nanofiltration concentration of chitooligosaccharides products 10
ACCEPTED MANUSCRIPT In order to concentrate the chitooligosaccharides products, desalinate reaction
221
mixture and recycle the acetate buffer from aforementioned enzyme-membrane
222
coupling reactor system, a nanofiltration system was used in series (Fig. 1). A
223
spiral-wound NF membrane system (Ruina membrane engineering, Hangzhou, China)
224
was coupled with aforementioned enzyme-membrane coupling reactor system. The
225
memberane was a three-layer thin-film composite NF membrane with molecular
226
weight cut-off 300 Da (Risingsun, Beijing, China). The effective membrane area was
227
0.37 m2. After the volume of feed liquid in the product tank was more than the dead
228
volume of nanofiltration system, the pump was turned on to pump the feed liquid
229
through the nanofiltration membrane module with 10 bar pressure. The permeate was
230
diverted to the reaction tank of aforementioned enzyme-membrane coupling reactor
231
system, and the retentate was returned to the product tank of nanofiltration system
232
(Fig. 1). After 150 min, the previous step of ultrafiltration system was turned off and 6
233
L deionized water was gradually added into the product tank. The nanofiltration
234
system continued working until the feed liquid was concentrated about 3 L. The
235
concentrations of different chitooligosaccharides in the final products were analyzed by
236
MALDI-TOF MS and HPLC. The yield of total chitooligosaccharides was calculated
237
by above formula.
238
2.8. Hydrolysis of chitosan by free BaCsn46A
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239
In order to compare the differences between the enzyme-membrane coupling process
240
and uncontrolled enzymatic hydrolysis process during the chitooligosaccharides
241
preparation. Enzymatic reaction in bulk system with same conditions was further 11
ACCEPTED MANUSCRIPT investigated. The hydrolytic process was carried out under the following conditions:
243
pH 5.5, 40 °C, substrate concentration 3%, enzyme concentration 100 U/g, reaction
244
time 150 min, stirring rate 80 rpm/min, reaction volume 3 L. Samples were withdrawn
245
at different times (the same as enzyme-membrane coupling process) and immediately
246
boiled for 5 min, followed by TLC and HPLC analysis.
247
2.9. Chitooligosaccharides analysis methods
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The chitooligosaccharides mixtures were analyzed by HPLC system (Shimadzu
249
20A, Shimadzu, Kyoto, Japan) equipped with evaporative light-scattering detector
250
(ELSD). The chitooligosaccharides were separated on high-performance sugar
251
column (Shodex Asahipak NH2 P-50 4E, Shodex, Kyoto, Japan), eluted by acetonitrile
252
and distilled water (70/30) mixture with a flow rate of 1.0 mL/min at 30 °C. The
253
concentrations of different chitooligosaccharides were quantified by integrating peak
254
areas based on the respective standard curve. The pure standards of high DP
255
chitooligosaccharides (DP>6) were unable purchased or obtained, therefore, the high
256
DP chitooligosaccharides were identified by the sequence of peaks appeared in the
257
HPLC chromatogram, and the concentrations of these chitooligosaccharides were
258
estimated based on the standard curve of chitohexaose (Lin et al., 2009). In order to
259
determine the DP of chitooligosaccharides, mixtures were analyzed by MALDI-TOF
260
MS.
261
3. Results
262
3.1. Sequence analysis, expression and purification of BaCsn46A
263
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The full-length BaCsn46A gene had an open reading frame (ORF) of 843 bp 12
ACCEPTED MANUSCRIPT encoding 280 amino acids with a theoretical molecular mass of 31.62 kDa and pI of
265
8.83. A signal peptide of 38 amino acids was predicted by SignalP analysis. The active
266
sites were highly conversed in all reported GH family 46 enzymes (Supplementary Fig.
267
1). Two strictly reserved residues, Glu57 and Asp73, were hypothesized to be the
268
general acid/base and the nucleophilic catalytic residues in BaCsn46A, respectively.
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To study the enzymatic properties of this GH family 46 enzyme without potential
270
interference from the signal peptide, only the nucleotide sequence corresponding to the
271
GH family 46 catalytic module was cloned into the vector pET28A. BaCsn46A was
272
purified by one step of affinity chromatography with a purification factor of 5.86 and a
273
recovery yield of 53.5% (Supplementary Table S1). The recombinant BaCsn46A
274
migrated as a single band with molecular mass of 31 kDa on SDS-PAGE (Fig. 2A), in
275
good accordance with the predicted molecular weight. MALDI-TOF MS analysis
276
showed that BaCsn46A are mainly present as monomers in the solution and the
277
monomeric molecular weight of BaCsn46A was about 29.68 kDa (Fig. 2B).
278
3.2. Biochemical properties of BaCsn46A
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Effects of pH and temperature on the chitosanase activity of BaCsn46A were
280
examined. BaCsn46A was most active at pH 6.0 in acetate buffer (Fig. 3A) and
281
exhibited better activity within pH 4.0–9.5 as more than 80% of its activity was
282
retained after incubation in various buffers for 30 min (Fig. 3B). It is noteworthy that
283
BaCsn46A was unstable in McIlvaine buffer, which showed about half activity
284
towards optimal buffer (acetate buffer) and partly inactivated after incubation in
285
McIlvaine buffers (pH 3.0–5.0) for 30 min. The optimal temperature for BaCsn46A
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ACCEPTED MANUSCRIPT was determined to be 50 °C, and retained over 90% of its activity between 45 °C and
287
60 °C (Fig. 3C). The suitable catalytic temperature of BaCsn46A for application was
288
below 45 °C. It retained more than 80% of its initial activity after incubation at 45 °C
289
for 30 min (Fig. 3D).
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BaCsn46A showed relative high specific activity towards chitosan (1031.2 U/mg),
291
but exhibited no activity towards other β-1,4 linked polysaccharide such as colloidal
292
chitin and microcrystalline cellulose. The kinetic parameters, Vmax and Km of
293
BaCsn46A towards chitosan were determined to be 7142.9 µmol/min.mg and 2.8
294
mg/mL.
295
3.3. Hydrolysis pattern of BaCsn46A
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The hydrolysis of chitosan by the purified BaCsn46A was performed. The DP of
297
oligosaccharides products from BaCsn46A was related to the reaction time. The
298
degradation of chitosan produced a mixture of chitooligosaccharides (mainly DP 2–6)
299
during the initial hydrolysis, with chitobiose and chitotriose as the end products (Fig. 4).
300
To understand the details of the hydrolysis mechanism, hydrolysis patterns of various
301
linear chitooligosaccharides were further investigated by TLC (Fig. 5). The enzyme
302
hardly hydrolyzed chitobiose and chitotriose. However, it could effectively hydrolyze
303
chitotetraose, chitopentaose and chitohexaose. Chitotetraose was gradually hydrolyzed
304
to produce mainly chitobiose in 30 min (Fig. 5), whereas chitopentaose and
305
chitohexaose was completely hydrolyzed to yield mainly chitobiose and chitotriose in 2
306
h (Fig. 5).
307
3.4. Hydrolysis of chitosan in the membrane reactor
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ACCEPTED MANUSCRIPT In consideration of the stability of BaCsn46A and the temperature tolerance of
309
membrane material, the membrane reactor system worked at an operating temperature
310
of 40 °C. The results show that the series of chitooligosaccharides produced was mainly
311
DP2 to DP10 (Fig. 6A). Chitopentaose was the most abundant component in the
312
reaction mixture. In the enzyme-membrane coupling reaction process, the entire
313
chitooligosaccharides component gradually accumulated with reaction time (Fig. 6B).
314
The concentration of high DP chitooligosaccharides (DP5–10, intermediate products)
315
was not decreased during enzyme-membrane coupling reaction. The proportions of
316
different chitooligosaccharides components were almost unchanged during the whole
317
reaction process (Fig. 6C). After 150 min reaction, there was nearly no
318
chitooligosaccharides and reducing sugar in the real-time permeate (Supplementary
319
Fig. S2). The yield of total chitooligosaccharides (DP2–10) was 100.06 % by HPLC
320
analysis. The part of high DP chitooligosaccharides (DP5–10) was 50.50 g, which
321
occupied 56.08% (w/w) of total detected chitooligosaccharides.
322
3.5. Nanofiltration of chitooligosaccharides products
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and
MALDI-TOF
MS
analysis
indicated
that
the
final
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324
chitooligosaccharides products after nanofiltration concentration mainly contained
325
(GlcN)2 to (GlcN)10, no glucosamine was deteted in the final products (Fig. 7). After
326
nanofiltration, the maximum concentration of total chitooligosaccharides (DP2–10)
327
was 28.11 g/L, corresponding to 93.70% of the initial chitosan concentration. The ratio
328
(w/w) of (GlcN)2, (GlcN)3, (GlcN)4, (GlcN)5, (GlcN)6, (GlcN)7–10 were 6.55%,
329
16.51%, 20.77%, 28.51%, 11.56% and 16.10% respectively. The proportion of high 15
ACCEPTED MANUSCRIPT 330
DP
chitooligosaccharides
(DP5–10)
occupied
331
chitooligosaccharides.
332
3.6. Hydrolysis of chitosan by free BaCsn46A
56.17%
(w/w)
of
total
In order to evaluate the hydrolytic result of chitosan by enzyme-membrane coupling
334
system, the time course of different chitooligosaccharides concentrations during the
335
batch hydrolysis of chitosan in the same condition using free BaCsn46A was
336
investigated. Free BaCsn46A could efficiently degrade chitosan, releasing a series of
337
chitooligosaccharides (DP2–10) (Fig. 6D). The concentrations of the target high DP
338
chitooligosaccharides (DP5–10) increased in the initial reaction time (0–30 min) and
339
then decreased in the remaining reaction process (Fig. 6E). The hydrolysis of chitosan
340
yielded predominantly (GlcN)2–5 as the main end products (Fig. 6F). The final yield of
341
total chitooligosaccharides (DP2–10) was 86.85% during 150 min hydrolytic reaction.
342
The concentration of high DP chitooligosaccharides (DP5–10) was 9.90 g/L, which
343
occupied 38.01% (w/w) of total chitooligosaccharides.
344
4. Discussion
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Most chitosanases have been reported to display strict substrate specificity (Weikert,
346
Niehues, Cord-Landwehr, Hellmann & Moerschbacher, 2017). In this study,
347
BaCsn46A exhibited relatively high specific activity towards chitosan. No activity
348
towards chitin and cellulose had been observed for BaCsn46A. A comparison of the
349
hydrolysis behavior of BaCsn46A to other GH family 46 chitosanases indicated that
350
BaCsn46A produce (GlcN)2 and (GlcN)3 as the major end products, no glucosamine
351
was detected during hydrolytic process. Moreover, BaCsn46A hardly hydrolyzed
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16
ACCEPTED MANUSCRIPT (GlcN)2 and (GlcN)3 (Fig. 4). These results suggested that BaCsn46A exhibits an
353
action pattern with a demand of at least four glucosamine residues for effective
354
cleavage. The -2, -1, +1 and +2 subsites were necessary for the catalytic reaction of
355
BaCsn46A in the total six subsites of catalytic groove (Supplementary Fig. S3). Thus,
356
the minimum substrate of BaCsn46A was (GlcN)4, and no GlcN yield in the
357
hydrolytic reaction.
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Biochemical properties analysis suggested that BaCsn46A was a typical endo-type
359
GH family 46 chitosanase. The high specific activity and appropriate catalytic property
360
of BaCsn46A suggested its potential use in conversion of chitosan into
361
chitooligosaccharides with commercial value. There are many previous studies
362
identified various valuable chitosanases (Thadathil & Velappan, 2014), however only
363
a few subsequent studies investigated how to well use these valuable chitosanases and
364
develop suitable chitooligosaccharides production process. Controllable enzymatic
365
preparing chitooligosaccharides with desired DP are still complicated in industrial
366
scale. As the endo-type catalytic mode of BaCsn46A, chitooligosaccharides with high
367
DP (DP 5–10) were suitable substrates of BaCsn46A, which were hydrolyzed to small
368
chitooligosaccharides during the subsequent hydrolytic process. If the target
369
intermediate chitooligosaccharides products could be separated from the hydrolytic
370
mixture containing the chitosanase, further hydrolyzing could be avoided and the
371
high-value chitooligosaccharides with high DP could be obtained in higher yield.
372
Therefore, the membrane separation technique was coupled with the hydrolytic process
373
of BaCsn46A to produce the target intermediate chitooligosaccharides in the further
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17
ACCEPTED MANUSCRIPT 374
studies. The molecular weight of BaCsn46A was about 30,000 Da and the initial average
376
molecular weight of undegraded chitosan was about 150–300 kDa. In contrast, the
377
target intermediate chitooligosaccharides (DP 5–10) was between about 823 Da and
378
1628 Da. Thus the ultrafiltration membranes with the average pore sizes of 5000 Da
379
were choose in the in the following experiments. The target intermediate high DP
380
chitooligosaccharides products could be separated from reaction mixture, and
381
BaCsn46A could be retained and recycled to reactor tank. Through a series membrane
382
separation system, the enzymatic hydrolysis of chitosan was performed with batch
383
operation of enzyme-membrane reactor coupled with nanofiltration membrane. After
384
nanofiltration, the maximum total concentration of chitooligosaccharides (DP2–10)
385
was 28.11 g/L, corresponding to 93.70% of the initial chitosan concentration. There
386
were nearly no acetate detected form HPLC analysis in the chitooligosaccharides
387
product (Fig. 7A), which indicated that chitooligosaccharide syrup was effectively
388
concentrated and desalinated by single step nanofiltration. Furthermore, the
389
spiral-wound membrane reactor could avoid membrane fouling in the hydrolytic
390
process comparing with previous flat sheet enzyme-membrane reactor (Kuroiwa, et al.,
391
2009). More importantly, the proportion of high DP chitooligosaccharides (DP5–10)
392
occupied 56.17% (w/w) of total chitooligosaccharides. The yield of target high DP
393
chitooligosaccharides (DP5–10) was higher than previous immobilized enzyme
394
bioreactor, membrane bioreactor and free chitosanase hydrolysis studies (Kuroiwa, et
395
al., 2009; Ming, Kuroiwa, Ichikawa, Sato & Mukataka, 2006; Nidheesh et al., 2015).
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18
ACCEPTED MANUSCRIPT In contrast, hydrolysis of chitosan by free BaCsn46A showed that the concentrations of
397
the target high DP chitooligosaccharides initially increased with time and then
398
decreased after peaking under the same reaction condition (Fig. 6E). These
399
oligosaccharides were intermediate products of the hydrolysis reaction and were
400
degraded by further enzymatic reaction. Moreover, chitooligosaccharides products in
401
high
402
chitooligosaccharides products increased slowly after 70 min incubation. The final
403
yield of total chitooligosaccharides by free BaCsn46A (86.85%) was lower than
404
enzyme-membrane coupling system (93.70%) during the same reaction time. Thus it is
405
hardly to obtain abundant high DP chitooligosaccharides by free BaCsn46A in high
406
yield. Without enzyme-membrane coupling operation, low DP chitooligosaccharides
407
(DP2–4) would gradually be primary hydrolytic products by free BaCsn46A. These
408
results illustrated that efficient preparation of the intermediate chitooligosaccharides
409
products required that the enzymatic hydrolytic progress of chitosan should be
410
appropriately controlled.
411
5. Conclusion
chitosanase's
reaction
rate.
The
yield
of
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concentration
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In conclusion, a novel chitosanase (BaCsn46A) from B. amyloliquefaciens was gene
413
cloned, expressed, and biochemically characterized. BaCsn46A is a monomer with a
414
molecular mass of 29.68 kDa. It was most active at pH 6.0 and 50 °C. BaCsn46A
415
showed relative high specific activity towards chitosan (1031.2 U/mg) to yield a series
416
of chitooligosaccharides by an endo-type cleavage pattern. In addition, this study
417
demonstrated that hydrolysis of chitosan by BaCsn46A through an enzyme-membrane 19
ACCEPTED MANUSCRIPT reactor coupled with nanofiltration system was a viable and efficient method for the
419
preparation of high degree of polymerization chitooligosaccharides. The maximum
420
total yield of chitooligosaccharides (DP 2–10) was 93.70%, and the proportion of high
421
degree of polymerization chitooligosaccharides (DP 5–10) occupied 56.17% (w/w) of
422
total chitooligosaccharides.
423
Acknowledgements
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418
This work was financially supported by the National Natural Science Foundation of
425
China (31701537), China Postdoctoral Science Foundation (2016M601530),
426
Shanghai Sailing Program (17YF1403500), Fundamental Research Funds for the
427
Central Universities (222201814031) and “Shu Guang” project of Shanghai
428
Municipal Education Commission and Shanghai Education Development Foundation
429
(15SG28).
430
References
431
Aam, B. B., Heggset, E. B., Norberg, A. L., Sorlie, M., Varum, K. M., & Eijsink, V.
432
G. H. (2010). Production of chitooligosaccharides and their potential applications
433
in medicine. Marine Drugs, 8, 1482–1517.
AC C
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SC
424
434
Andric, P., Meyer, A. S., Jensen, P. A., & Dam-Johansen, K. (2010). Reactor design
435
for minimizing product inhibition during enzymatic lignocellulose hydrolysis: I.
436 437
Significance and mechanism of cellobiose and glucose inhibition on cellulolytic enzymes. Biotechnology Advances, 28, 308–324.
438
Das, S. N., Madhuprakash, J., N., P. V. S. R., Purushotham, P., Suma, K., Manjeet, K.,
439
Rambabu, S., El Gueddari, N. E., Moerschbacher, B. M., & Podile, A. R. (2015). 20
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Biotechnological approaches for field applications of chitooligosaccharides (COS)
441
to induce innate immunity in plants. Critical Reviews in Biotechnology, 35, 29–43.
442
He, P., Hao, K., Blom, J., Ruckert, C., Vater, J., Mao, Z., Wu, Y., Hou, M., He, P., He, Y., & Borriss, R. (2012). Genome sequence of the plant growth promoting strain
444
Bacillus amyloliquefaciens subsp. plantarum B9601-Y2 and expression of
445
mersacidin and other secondary metabolites. Journal of Biotechnology, 164, 281–
446
291.
448
SC
Jeon, Y. J., & Kim, S. K. (2000). Continuous production of chitooligosaccharides
M AN U
447
RI PT
443
using a dual reactor system. Process Biochemistry, 35, 623–632. Kuroiwa, T., Izuta, H., Nabetani, H., Nakajima, M., Sato, S., Mukataka, S., &
450
Ichikawa, S. (2009). Selective and stable production of physiologically active
451
chitosan oligosaccharides using an enzymatic membrane bioreactor. Process
452
Biochemistry, 44, 283–287.
TE D
449
Li, K., Xing, R., Liu, S., & Li, P. (2016). Advances in preparation, analysis and
454
biological activities of single chitooligosaccharides. Carbohydrate Polymers, 139,
455
178–190.
AC C
EP
453
456
Lin, Y., Hsiao, Y., & Chiang, B. (2009). Production of high degree polymerized
457
chitooligosaccharides in a membrane reactor using purified chitosanase from
458
Bacillus cereus. Food Research International, 42, 1355–1361.
459
Ming, M., Kuroiwa, T., Ichikawa, S., Sato, S., & Mukataka, S. (2006). Production of
460
chitosan oligosaccharides by chitosanase directly immobilized on an agar
461
gel-coated multidisk impeller. Biochemical Engineering Journal, 28, 289–294. 21
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Nidheesh, T., Pal, G. K., & Suresh, P. V. (2015). Chitooligomers preparation by
463
chitosanase produced under solid state fermentation using shrimp by-products as
464
substrate. Carbohydrate Polymers, 121, 1–9. Pinelo, M., Jonsson, G., & Meyer, A. S. (2009). Membrane technology for
466
purification of enzymatically produced oligosaccharides: Molecular and operational
467
features affecting performance. Separation and Purification Technology, 70, 1–11. Qin, Z., Yan, Q., Yang, S., & Jiang, Z. (2016). Modulating the function of a beta-1,3-glucanosyltransferase
that
of
an
endo-beta-1,3-glucanase
470
structure-based protein engineering. Applied Microbiology and Biotechnology, 100,
471
1765–1776.
M AN U
469
472
to
SC
468
RI PT
465
by
Qin, Z., Chen, Q., Lin, S., Luo, S., Qiu, Y., & Zhao, L. (2018). Expression and characterization
of
a
novel
cold-adapted
chitosanase
suitable
for
474
chitooligosaccharides controllable preparation. Food Chemistry, 253, 139–147.
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473
Sanchez, A., Mengibar, M., Rivera-Rodriguez, G., Moerchbacher, B., Acosta, N., &
476
Heras, A. (2017). The effect of preparation processes on the physicochemical
477
characteristics and antibacterial activity of chitooligosaccharides. Carbohydrate
AC C
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EP
475
Polymers, 157, 251–257.
479
Santos-Moriano, P., Woodley, J. M., & Plou, F. J. (2016). Continuous production of
480
chitooligosaccharides by an immobilized enzyme in a dual-reactor system. Journal
481 482 483
of Molecular Catalysis B-Enzymatic, 133, 211–217. Sinha, S., Chand, S., & Tripathi, P. (2016). Recent progress in chitosanase production of
monomer-free
chitooligosaccharides: 22
bioprocess
strategies
and
future
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applications. Applied Biochemistry and Biotechnology, 180, 883–899. Thadathil, N., & Velappan, S. P. (2014). Recent developments in chitosanase research and its biotechnological applications: A review. Food Chemistry, 150, 392–399. Weikert, T., Niehues, A., Cord-Landwehr, S., Hellmann, M. J., & Moerschbacher, B.
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M. (2017). Reassessment of chitosanase substrate specificities and classification.
489
Nature Communications, 8, 1698.
RI PT
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Zhang, J., Cao, H., Li, S., Zhao, Y., Wang, W., Xu, Q., Du, Y., & Yin, H. (2015).
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Characterization of a new family 75 chitosanase from Aspergillus sp. W-2.
492
International Journal of Biological Macromolecules, 81, 362–369.
M AN U
SC
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Zou, P., Yang, X., Wang, J., Li, Y., Yu, H., Zhang, Y., & Liu, G. (2016). Advances in
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characterisation and biological activities of chitosan and chitosan oligosaccharides.
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Food Chemistry, 190, 1174–1181.
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Figure legends
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Figure 1 Schematic diagram of the enzyme-membrane coupling reactor system.
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Figure 2 Protein analysis of BaCsn46A. (A) SDS-PAGE of proteins during
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purification of the recombinant BaCsn46A by Ni-IDA. Lane M: standard protein
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molecular weight markers; Lane 1: supernatant of lysate cells; Lane 2: purified enzyme.
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(B) MALDI-TOF MS showing the association form and molecular weight of
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BaCsn46A.
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Figure 3 The effects of temperature and pH on activity of the purified BaCsn46A. (A)
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Optimum pH, acetate buffer (■), McIlvaine buffer (●), phosphate buffer (▲); (B) pH
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(▼), glycine-NaOH buffer (♦); (C) Optimum temperature and (D) Thermostability. For
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thermostability, residual activity was measured after incubating the enzyme at different
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temperatures for 30 min in 50 mM acetate buffer (pH 6.0). The experiments were done
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in triplicate and their mean and standard deviation values were used for analysis.
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Figure 4 Hydrolytic process of BaCsn46A towards chitosan. M, marker sugars. The
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reactions were performed at 50 °C in 50 mmol/L citrate buffer (pH 6.0) and analyzed
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by TLC. (GlcN)–(GlcN)6: glucosamine, chitobiose, chitotriose, chitotetraose,
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chitopentaose and chitohexaose, respectively.
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Figure 5 Hydrolytic process of BaCsn46A towards chitooligosaccharides. M, marker
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sugars. The substrates were (GlcN)2, (GlcN)3, (GlcN)4, (GlcN)5 and (GlcN)6,
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respectively. The reactions were performed at 50 °C in 50 mmol/L citrate buffer (pH
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6.0) and analyzed by TLC.
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Figure 6 Enzymatic reaction pattern in the membrane reactor system (A–C) and free
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enzyme system (D–F). (A) Total chitooligosaccharides of permeate by TLC analysis;
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(B) Total chitooligosaccharides of permeate by HPLC analysis, glucosamine (■),
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(GlcN)2 (●), (GlcN)3 (▲), (GlcN)4 (▼), (GlcN)5 (♦), (GlcN)6 (◄), (GlcN)7–10 (►)
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and yield (○); (C) Composing proportion of different chitooligosaccharides monomers
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in the permeate; (D) Total chitooligosaccharides of free enzymatic reaction mixture
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by TLC analysis; (E) Total chitooligosaccharides of free enzymatic reaction mixture
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by HPLC analysis; (F) Composing proportion of different chitooligosaccharides
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monomers in the free enzymatic reaction mixture. The dot lines in each figures means
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Figure 7 HPLC analysis (A) and MALDI-TOF MS analysis (B) of final products by
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enzyme-membrane coupling reactor system. The peaks in the spectra correspond to the
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monoisotopic masses of sodium adducts [M+Na]+ of the chitooligosaccharides. The
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final products contain chitooligosaccharides with DP 2–10.
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A high-activity chitosanase from B.amyloliquefaciens (BaCsn46A) was identified. BaCsn46A could be used for controllable producing chitooligosaccharides in membrane reactor. High degree polymerized chitooligosaccharides was accumulated by enzyme-membrane coupling process. This study provided a cleaner production process for controllable producing chitooligosaccharides.