A novel thermostable β-glucosidase (Te-BglA) from Thermoanaerobacter ethanolicus JW200 was cloned, characterized and compared for its activity against isoflavone glycosides with two β-glucosidases (Tm-BglA, Tm-BglB) from Thermotoga maritima. Te-BglA exhibited maximum hydrolytic activity toward pNP-β-d-glucopyranoside (pNPG) at 80 °C and pH 7.0, was stable for a pH range of 4.6-7.8 and at 65 °C for 3 h, and had the lowest K(m) for the natural glycoside salicin and the highest relative substrate specificity (k(cat)/K(m))((salicin))/(k(cat)/K(m))((pNPG)) among the three enzymes. It converted isoflavone glycosides, including malonyl glycosides, in soybean flour to their aglycons more efficiently than Tm-BglA and Tm-BglB. After 3 h of incubation at 65 °C, Te-BglA produced complete hydrolysis of four isoflavone glycosides (namely, daidzin, genistin and their malonylated forms), exhibiting higher productivity of genistein and daidzein than the other two β-glucosidases. Our results suggest that Te-BglA is preferable to Tm-BglA and Tm-BglB, but all three enzymes have great potential applications in converting isoflavone glycosides into their aglycons.
A recombinant Thermotoga maritima beta-glucosidase A (BglA) was purified to homogeneity for performing enzymatic hydrolysis of isoflavone glycosides from soy flour. The kinetic properties K(m), k(cat), and k(cat)/K(m) of BglA towards isoflavone glycosides, determined using high-performance liquid chromatography, confirmed the higher efficiency of BglA in hydrolyzing malonylglycosides than non-conjugated glycosides (daidzin and genistin). During hydrolysis of soy flour by BglA at 80 degrees C, the isoflavone glycosides (soluble form) were extracted from soy flour (solid state) into the solution (liquid state) in thermal condition and converted to their aglycones (insoluble form), which mostly existed in the pellet to be separated from BglA in the reaction solution. The enzymatic hydrolysis in one-step and two-step approaches yielded 0.38 and 0.35 mg genistein and daidzein per gram of soy flour, respectively. The optimum conditions for conversion of isoflavone aglycones were 100 U per gram of soy flour, substrate concentration 25% (w/v), and incubation time 3 h for 80 degrees C.
To produce aglycone isoflavones from soy flour, the b-glucosidase A gene (bglA) of Thermotoga maritima was overexpressed in Escherichia coli BL21-CodonPlus (DE3)-RIL. The K m and V max values of the purified BglA for pNPG were 0.43 mM and 323.6 U mg -1 , respectively, and those for salicin were 9.0 mM and 183.2 U mg -1 , respectively. The biochemical and kinetic characteristics of his-tagged BglA were found to be similar to those of BglA, except for the temperature stability and specific activity. Production of aglycone isoflavones from soy flour by BglA was examined by HPLC. For 3 h at 80°C, all the isoflavone glycosides approximated to the complete conversion into aglycone isoflavones, over seven times higher than that obtained from soy flour without BglA.
Enzyme immobilization is a powerful tool not only as a protective agent against harsh reaction conditions but also for the enhancement of enzyme activity, stability, reusability, and for the improvement of enzyme properties as well. Herein, immobilization of β-glucosidase from Thermotoga maritima (tm-β-Glu) on magnetic nanoparticles (Mnps) functionalized with chitin (ch) was investigated. This technology showed a novel thermostable chitin-binding domain (Tt-ChBD), which is more desirable in a wide range of large-scale applications. This exclusive approach was fabricated to improve the Galacto-oligosaccharide (GOS) production from a cheap and abundant by-product such as lactose through a novel green synthesis route. Additionally, SDS-PAGE, enzyme activity kinetics, transmission electron microscopy (TEM) and Fourier transform infrared spectroscopy (FT-IR) revealed that among the immobilization strategies for Thermotoga maritime-β-Glucosidase thermostable chitinbinding domain (tm-β-Glu-Tt-ChBD) on the attractive substrate; Ch-MNPs had the highest enzyme binding capacity and GOS production ratio when compared to the native enzyme. More interestingly, a magnetic separation technique was successfully employed in recycling the immobilized Tm-β-Glu for repetitive batch-wise GOS without significant loss or reduction of enzyme activity. This immobilization system displayed an operative stability status under various parameters, for instance, temperature, pH, thermal conditions, storage stabilities, and enzyme kinetics when compared with the native enzyme. Conclusively, the GOS yield and residual activity of the immobilized enzyme after the 10 th cycles were 31.23% and 66%, respectively. Whereas the GOS yield from native enzyme synthesis was just 25% after 12 h in the first batch. This study recommends applying Tt-ChBD in the immobilization process of tm-β-Glu on Ch-MNPs to produce a low-cost GOS as a new eco-friendly process besides increasing the biostability and efficiency of the immobilized enzyme.
The β glucosidase Tm bglA gene from hyperthermophile Thermotoga maritima was cloned into expression vectors pET 28a, producing two proteins of 55 kDa and 52 kDa in cell, which could be referred to Tm BglA with and without 23 amino acids. The results showed that fusion of 23 amino acids to Tm BglA improved its soluble expression and product tolerance, resulting over 60% yield of recombinant Tm BglA secreted into the growth medium in Escherichia coli JM109 (DE3). Tm BglA with 23 amino acids had higher k cat and K M values for p nitrophenyl β D glycopyranoside and much stronger product inhibition than Tm BglA without 23 amino acids. Subsequently, the Tm BglA was immobilized on chitin efficiently by genetically fusing the chitin binding domain of chitinase A1 from Thermoanaerobacterium thermosaccharolyticum DSM571. The immobilized Tm BglA had higher optimal temperature (95°C) and was more thermostable at the range from 75 to 100°C than its free form. This immobilized protein exhibited high stability and the con version yield exceeding 90%. The high level soluble expression, combined simultaneous purification and immobilization of the enzyme on chitin offers a novel approach for the low cost production of β glucosidase to produce lactose free fresh dairy products.
A thermostable beta-xylosidase from a hyperthermophilic bacterium, Thermotoga maritima, was over-expressed in Escherichia coli using the T7 polymerase expression system. The expressed beta-xylosidase was purified in two steps, heat treatment and immobilized metal affinity chromatography, and gave a single band on SDS-PAGE. The maximum activity on p-nitrophenyl beta-D-xylopyranoside was at 90 degrees C and pH 6.1. The purified enzyme had a half-life of over 22-min at 95 degrees C, and retained over 57% of its activity after holding a pH ranging from 5.4 to 8.5 for 1 h at 80 degrees C. Among all tested substrates, the purified enzyme had specific activities of 275, 50 and 29 U mg(-1) on pNPX, pNPAF, and pNPG, respectively. The apparent Michaelis constant of the beta-xylosidase was 0.13 mM for p NPX with a V (max) of 280 U mg(-1). When the purified beta-xylosidase was added to xylanase, corncob xylan was hydrolized completely to xylose.
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