Heterologous Expression, Enzymatic Characterization of Laccase BmLac and Degradation of Gossypol by It

doi:10.13560/j.cnki.biotech.bull.1985.2022-1469

Abstract

Abstract:

To develop enzymatic proteins for the efficient degradation of gossypol, a strain of B. amyloliquefaciens XP-13 was screened from soil, the gene BmLac was amplified from its genome, then the recombinant plasmid Ppic9k-BmLac was constructed and introduced into Pichia pastoris GS115 for heterologous expression. The characteristics of the laccase BmLac and the degradation effect of gossypol were studied. The results showed that the enzyme activity was 101.56 U/mL at pH 4 and 55℃ under the optimal reaction conditions with ABTS as the substrate; the relative enzyme activity was retained over 70% after incubation at 90℃ for 1 h; the relative enzyme activity was retained over 96% after incubation at pH 3-7 for 1 h. The enzyme activity increased 1.93 times by adding 1 mmol/L Cu²⁺, but high concentrations（10 mmol/L）of Fe²⁺, Fe³⁺ and Al³⁺ completely inhibited the enzyme activity. After reaction at 55℃ for 2 h, the degradation rate of gossyrol by this enzyme reached 94.57%（without mediator）and 98.73%（with ABTS）. In conclusion, the laccase BmLac has good thermal stability and wide pH adaptability and can effectively degrade gossypol, and this enzyme provides the basic support for the effective degradation of free gossypol in the cottonseed meal.

Key words: free gossypol, Bacillus amyloliquefaciens, laccase, enzymatic characterization, cottonseed meal

WEI Ting-liu, MIAO Hua-biao, WU Qian, HUANG Zun-xi. Heterologous Expression, Enzymatic Characterization of Laccase BmLac and Degradation of Gossypol by It[J]. Biotechnology Bulletin, 2023, 39(12): 320-328.

Figures/Tables 9

Fig. 1 Identification of XP-13 strain A: Gel electrophoresis of 16S rDNA. B: Light micrograph of strain XP-13 bacteriop-hage. C: Phylogenetic tree construction of strain XP-13 based on 16S rDNA

Fig. 2 Analysis of laccase BmLac A : The secondary structure of BmLac. B: The 3D structure of BmLac with 1GSK homology (purple indicates β-sheet. Blue indicates α-helix)

Fig. 3 BmLac and pPic9k gel electrophoresis A: Gel electrophoresis map of BmLac gene. B: Gel electrophoresis map of pPic9k double digestion. 1 : Target band; M: DNA maker

Fig. 4 SDS-PAGE of BmLac M: Protein maker. 1: Inactivated BmLac crude enzyme solution. 2: 0.5 mmol/L ABTS staining BmLac crude enzyme solution for 1 h

Fig. 5 Optimal pH and pH stability of the BmLac A: Optimal pH. B : pH stability

Fig. 6 Optimal temperature and temperature stability of the BmLac A : Optimal temperature. B : Temperature stability

Table 1 Effects of metal ions and chemical reagents on BmLac

试剂 Reagent	相对酶活1 Relative activity 1/%	相对酶活2 Relative activity 2/%
None	100±1.43	100±4.20
CuSO₄	193.09±5.05	98.71±2.44
MnSO₄	102.05±1.99	96.56±3.25
Pb（CH₃CO₂）₂	99.69±2.78	69.35±6.03
MgSO₄	98.36±2.15	97.15±4.36
ZnSO₄	98.26±1.13	86.13±4.69
NiSO₄	94.32±1.63	61.77±0.43
KCl	93.15±3.11	58.60±5.83
NaCl	90.74±0.49	59.52±1.77
CaCl₂	90.33±2.07	45.32±4.09
FeCl₃	90.43±1.83	0.00
LiCl	88.34±1.78	65.11±3.04
CoCl₂	84.30±3.28	19.84±1.26
AlCl₃	71.92±2.70	0.00
Fe SO₄	2.92±0.80	0.00
Guanidine hydrochloride	95.40±3.40	69.68±2.12
Urea	92.53±2.93	103.49±3.87
EDTA	86.75±1.29	42.37±1.25

Fig. 7 Enzyme kinetic curves of BmLac

Fig. 8 HPLC analysis of BmLac degrading gossypol A：Without mediator ABTS. B：With 1.25 mmol/L ABTS. C：Gossypol degradation rate

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