Immobilization of the Bacillus licheniformis α-Amylase on Azole Functionalized Nanoparticle: More Active, Stable, and Usability

Heterologous expression of calcium-independent mesophilic α-amylase from Priestia megaterium: Immobilization on genipin-modified multi-walled carbon nanotubes and silica supports to enhance thermostability and catalytic activity

α-Amylases, constituting a significant share of the enzyme market, are mainly synthesized by the genus Bacillus. Enzymes tailored for specific industrial applications are needed to meet the growing demand across a range of industries, and thus finding new amylases and optimizing the ones that already exist are extremely important. This study reports the successful expression, characterization and immobilization of P. megaterium α-amylase (PmAmy) in E. coli protein expression systems. The recombinant PmAmy has a molecular weight of 56 kDa and its in silico predicted model structure presents a monomer composed of three domains, like most amylases. Regarding long-term storage, PmAmy remained 60 % active after 6 weeks of storage at -20 and -80 °C indicating its stable storage at low temperatures. PmAmy was found to be Ca2+ ion-independent for both catalytic activity and thermostability while Mn2+ enhanced activity in a concentration-dependent manner. The optimum characteristic working conditions of PmAmy were measured as pH 7.0 and 40 °C. Immobilizing PmAmy significantly improved its thermal stability, increasing its resistance to thermal denaturation by at least 4.1-fold. Kinetic analyses revealed that the KM and Vmax values of free PmAmy were 0.1 mg mL-1 and 556 U mg-1, respectively while immobilization resulted in an increase for both the KM and Vmax values. Kinetic analysis revealed enhanced activity for the Ca2+-independent immobilized enzyme, making it suitable for industrial applications particularly starch processing requiring moderate thermostability without the need for Ca2+ ions.

Covalent immobilization of α-amylase on hollow metal organic framework coated magnetic phase-change microcapsules for the improvement of its thermostability

Exploring efficient immobilized carrier for α-Amylase (α-Amy) to enhance its thermostability has significant influence in starch related industry. Here, hollow ZIF-8 (HZIF-8) with amino groups coated magnetic phase change microcapsules (PCM) was designed for covalent immobilization of α-Amy. Magnetic PCM consisting n-docosane core and SiO2/Fe3O4 hybrid shell were firstly synthesized. Then, HZIF-8 shell with amino groups was coated and α-Amy was subsequently immobilized through covalent cross-linking strategy. The morphology, chemical structure and magnetic property of PCM@HZIF-8@α-Amy (PCMHA) were comprehensively characterized. Moreover, heat control property of PCMHA was studied with encapsulation efficiency and thermal energy-storage efficiency of 50.55 % and 50.59 %, respectively. Catalytic activity of immobilized α-Amy was fully investigated with Km and Vmax of 2.773 mg/mL and 1.853 μmol/mL·min, respectively. From reusability and storage stability study, immobilized α-Amy not only maintained rather high activity after 9 cycles' reuse, but also exhibited good activity under high salt ion condition after 7 days.

A newly synthesized magnetic nanoparticle coated with glycidyl methacrylate monomer and 1,2,4-Triazole: Immobilization of α-Amylase from Bacillus licheniformis for more reuse, stability, and activity in the presence of H2O2

α-Amylase is a secretory enzyme commonly found in nature. The α-Amylase enzyme catalyzes the hydrolysis of α-D-(1,4)-glucosidic bonds in starch, glycogen, and polysaccharides. The chemical characterization of the composite carrier and the immobilized enzyme was performed, and the accuracy of the immobilization was confirmed by FTIR, SEM, and EDS analyses. The X-ray diffraction (XRD) analysis indicates that the magnetic nanoparticle retained its magnetic properties following the modification process. Based on the Thermogravimetric Analysis (TGA) outcomes, it was evident that the structural integrity of the FPT nanocomposite remained unchanged at 200°C. The optimal pH was determined to be 5.5, and no alteration was observed following the immobilization process. Purified α-amylases usually lose their activity rapidly above 50°C. In this study, Bacillus licheniformis α-Amylase enzyme was covalently immobilized on the newly synthesized magnetic composite carrier having more azole functional group. For novelty-designed immobilized enzymes, while there is no change in the pH and optimum operating temperature of the enzyme with immobilization, two essential advantages are provided to reduce enzyme costs: the storage stability and reusability are increased. Furthermore, our immobilization technique enhanced enzyme stability when comparing our immobilized enzyme with the reference enzyme in industrial applications. The activity of the immobilized enzyme was higher in presence of 1-3% H2O2.

Preparation of water-insoluble lignin nanoparticles by deep eutectic solvent and its application as a versatile and biocompatible support for the immobilization of α-amylase

As one of the most abundant biopolymers, lignin is a widely available resource. However, its potential largely remains untapped, with most of it ending up as waste from industries like paper production, pulp processing, and bio-refining. The research undertaken in this study focused on the extraction of lignin from agroforestry waste using a deep eutectic solvent (DES) as a carrier for α-amylase immobilization, resulting in high stability and reusability. Several techniques, including Nuclear Magnetic Resonance (NMR), Scanning Electron Microscopy (SEM), Energy-Dispersive X-ray Spectroscopy (EDS), and the Brunauer-Emmett-Teller (BET) method were employed to examine the structure and morphology of both the extracted lignin and the immobilized enzyme. The temperature used to recover lignin by DES would affect immobilization efficiency and enzyme loading by influencing its specific surface area, pore size, and volume distribution. Investigations using Nuclear Overhauser Effect Spectroscopy (NOESY) uncovered that the hydroxyl groups in G, H, and S units and the β-O-4 structure of lignin primarily serve as binding sites for enzyme molecules. Immobilized α-amylase demonstrated a higher pH and thermal stability level, with an optimal pH of 7.0 and temperature of 100 °C, compared to the free enzyme, which exhibited optimal activity at a pH of 6.5 and temperature of 90 °C. Importantly, immobilized α-amylase retained >80 % of its initial activity even after 28 days at room temperature, and it maintained 70 % of its activity after being reused 12 times. These findings strongly suggest that lignin derived from agroforestry residues holds promising potential as a future versatile immobilization material, a prospect integral to society's sustainable development.