Javed Muhammad Rizwan, Rashid Muhammad Hamid, Riaz Muhammad, Nadeem Habibullah, Qasim Muhammad, Ashiq Nourin
Department of Bioinformatics and Biotechnology, Government College University Faisalabad (GCUF), Allama Iqbal Road, 38000, Faisalabad, Pakistan.
Industrial Biotechnology Division, National Institute for Biotechnology and Genetic Engineering (NIBGE), P.O. Box 577, Jhang Road, Faisalabad, Pakistan.
Protein Pept Lett. 2018;25(2):208-219. doi: 10.2174/0929866525666180130161504.
Cellulose represents a major source of fermentable sugars in lignocellulosic biomass and a combined action of hydrolytic enzymes (exoglucanases , endoglucanases and β-glucosidases) is required to effectively convert cellulose to glucose that can be fermented to bio-ethanol. However, in-order to make the production of bio-ethanol an economically feasible process, the costs of the enzymes to be used for hydrolysis of the raw material need to be reduced and an increase in specific activity or production efficiency of cellulases is required. Among the cellulases, β-glucosidase not only hydrolyzes cellobiose to glucose but it also reduces the cellobiose inhibition, resulting in efficient functioning of endo- and exo-glucanases. Therefore, in the current study kinetic and thermodynamic characteristics of highly active β-glucosidase from randomly mutated Aspergillus niger NIBGE-06 have been evaluated for its industrial applications.
The main objective of this study was the identification of mutations and determination of their effect on the physiochemical, kinetic and thermodynamic characteristics of β-glucosidase activity and stability.
Pure cultures of Aspergillus niger NIBGE and its 2-Deoxy-D-glucose resistant γ-rays mutant Aspergillus niger NIBGE-06 were grown on Vogel's medium containing wheat bran (3% w/v), at 30±1 °C for 96-108 h. Crude enzymes from both strains were subjected to ammonium sulfate precipitation and column chromatography on Fast Protein Liquid Chromatography (FPLC) system. The purified β-glucosidases from both fungal sources were characterized for their native and subunit molecular mass through FPLC and SDS-PAGE, respectively. The purified enzymes were then comparatively characterized for their optimum temperature, activation energy (Ea), temperature quotient (Q10), Optimum pH, Heat of ionization (ΔHI) of active site residues , Michaelis-Menten constants (Vmax, Km, kcat and kcat/Km) and thermodynamics of irreversible inactivation through various enzyme assays. The genomic DNA from both fungal strains was also extracted by SDS-method and full length β- glucosidase genes (bgl) were amplified through PCR. The PCR products were cloned in TA cloning vector followed by the sequencing of potentially full length clones using the commercial services of Macrogen, Korea. The in silico analyses of the sequences thus obtained were also performed using various online tools such as blastn, blastp, GeneWise, SignalP, Inter- ProScan.
The extracellular β-glucosidases (BGL) from both fungal sources were purified to homogeneity level by ammonium sulfate precipitation and FPLC system. The BGLs from both strains were dimeric in nature, with subunit and native molecular masses of 130 kDa and 252 kDa, respectively. The comparative analysis of nucleotides of bgl genes revealed 8 point mutations. Significant improvement was observed in the kinetic properties of the mutant BGL relative to the wild type enzyme. Arrhenius plot for energy of activation (Ea) showed a biphasic trend and ES-complex formation required Ea of 50 and 42 kJ mol-1 by BGL from parent and mutant, respectively. The pKa1 and pKa2 of the active site residues were 3.4 & 5.5 and 3.2 & 5.6, respectively. The heat of ionization for the acidic limb (ΔHI-AL) and the basic limb (ΔHI-BL) of BGL from both strains were equal to 56 & 41 and 71 & 45 kJ mol-1, respectively. Kinetic constants of cellobiose hydrolysis for BGL from both strains were determined as follows: kcat = 2,589 and 4,135 s-1, Km = 0.24 and 0.26 mM cellobiose, kcat/Km = 10,872 and 15,712 s-1 mM-1 cellobiose, respectively. Thermodynamic parameters for cellobiose hydrolysis also suggested that mutant BGL is more efficient compared to the parent enzyme. Comparative analysis of Ea(d), ΔH* and ΔG* for irreversible thermostability indicated that the thermostabilization of mutant enzyme was due to higher functional energy (free energy), which enabled the enzyme to resist against unfolding of its transition state.
Physiochemical and thermodynamic characterization of extracellular β-glucosidases (BGL) from 2-Deoxy-Dglucose resistant mutant derivative of A. niger showed that mutagenesis did not greatly affect the physiochemical properties of the BGL enzyme, like temperature optima, pH optima and molecular mass, while the catalytic efficiency for cellobiose hydrolysis was significantly improved (High kcat and kcat/Km). Furthermore, the mutant BGL was more thermostable than the parent enzyme. This shows that random mutagenesis has changed the BGL structural gene, resulting in improvement within its stability- function characteristics. Hence, directed evolution or random mutagenesis with careful selection can result in the engineering of highly efficient enzymes for intended industrial applications.
纤维素是木质纤维素生物质中可发酵糖的主要来源,需要水解酶(外切葡聚糖酶、内切葡聚糖酶和β-葡萄糖苷酶)共同作用才能有效地将纤维素转化为可发酵生成生物乙醇的葡萄糖。然而,为使生物乙醇生产成为经济可行的过程,需降低用于水解原料的酶的成本,并提高纤维素酶的比活性或生产效率。在纤维素酶中,β-葡萄糖苷酶不仅能将纤维二糖水解为葡萄糖,还能减轻纤维二糖的抑制作用,从而使内切和外切葡聚糖酶高效发挥作用。因此,在本研究中,对随机诱变的黑曲霉NIBGE-06中高活性β-葡萄糖苷酶的动力学和热力学特性进行了评估,以用于工业应用。
本研究的主要目的是鉴定突变并确定其对β-葡萄糖苷酶活性和稳定性的物理化学、动力学及热力学特性的影响。
将黑曲霉NIBGE及其抗2-脱氧-D-葡萄糖的γ射线突变体黑曲霉NIBGE-06的纯培养物在含有麦麸(3% w/v)的Vogel培养基上,于30±1 °C培养96 - 108小时。对两株菌株的粗酶进行硫酸铵沉淀,并在快速蛋白质液相色谱(FPLC)系统上进行柱色谱分离。分别通过FPLC和SDS-PAGE对两种真菌来源的纯化β-葡萄糖苷酶的天然和亚基分子量进行表征。然后通过各种酶测定法对纯化后的酶进行比较表征,测定其最适温度、活化能(Ea)、温度系数(Q10)、最适pH、活性位点残基的电离热(ΔHI)、米氏常数(Vmax、Km、kcat和kcat/Km)以及不可逆失活的热力学。还通过SDS法从两种真菌菌株中提取基因组DNA,并通过PCR扩增全长β-葡萄糖苷酶基因(bgl)。将PCR产物克隆到TA克隆载体中,随后利用韩国Macrogen公司的商业服务对潜在的全长克隆进行测序。还使用各种在线工具如blastn、blastp、GeneWise、SignalP、Inter - ProScan对所得序列进行了电子分析。
通过硫酸铵沉淀和FPLC系统将两种真菌来源的细胞外β-葡萄糖苷酶(BGL)纯化至均一水平。两株菌株的BGL本质上均为二聚体,亚基分子量和天然分子量分别为130 kDa和252 kDa。对bgl基因核苷酸的比较分析揭示了8个点突变。相对于野生型酶,突变型BGL的动力学特性有显著改善。活化能(Ea)的阿伦尼乌斯图显示出双相趋势,亲本和突变体的BGL形成ES复合物所需的Ea分别为50和42 kJ mol-1。活性位点残基的pKa1和pKa2分别为3.4 & 5.5和3.2 & 5.6。两株菌株BGL酸性分支(ΔHI-AL)和碱性分支(ΔHI-BL)的电离热分别等于56 & 41和71 & 45 kJ mol-1。两株菌株BGL纤维二糖水解的动力学常数测定如下:kcat = 2,589和4,135 s-1,Km = 0.24和0.26 mM纤维二糖,kcat/Km = 10,872和15,712 s-1 mM-1纤维二糖。纤维二糖水解的热力学参数也表明突变型BGL比亲本酶更高效。不可逆热稳定性的Ea(d)、ΔH和ΔG的比较分析表明,突变酶的热稳定性归因于更高的功能能量(自由能),这使酶能够抵抗其过渡态的解折叠。
对黑曲霉抗2-脱氧-D-葡萄糖突变体衍生物的细胞外β-葡萄糖苷酶(BGL)的物理化学和热力学表征表明,诱变并未对BGL酶的物理化学性质如最适温度、最适pH和分子量产生太大影响,而纤维二糖水解的催化效率显著提高(高kcat和kcat/Km)。此外,突变型BGL比亲本酶更耐热。这表明随机诱变改变了BGL结构基因,导致其稳定性 - 功能特性得到改善。因此,定向进化或经过仔细筛选的随机诱变可产生用于预期工业应用的高效酶。
