Darshan H. Patel

Immobilization on graphene oxide improves the thermal stability and bioconversion efficiency of D-psicose 3-epimerase for rare sugar production

D-Psicose (D-ribo-2-hexulose or D-allulose), an epimer of D-fructose is considered as a rare low-calorie sugar displaying important physiological functions. Enzymatic production using ketose 3-epimerases is the feasible process for the production of D-Psicose. However, major drawbacks in application of ketose 3-epimerases are bioconversion efficiency and reusability of the enzyme. We have attempted immobilization of ketose 3-epimerases from Agrobacterium tumefaciens (agtu) D-psicose 3-epimerase (DPEase) on graphene oxide. Scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR) and Thermo gravimetric analysis (TGA) showed that the enzyme was successfully immobilized on the graphene oxide. Graphene oxide immobilized agtu-DPEase (GO-agtu-DPEase) shows pH optima at 7.5 and 60°C as higher working temperature. Significant improvement in thermal stability was observed which showed half-life of 720min at 60°C whereas Agrobacterium tumefaciens (agtu) DPEase displayed 3.99min. At equilibrium, 40:60 (D-psicose: D-fructose) the bioconversion efficiency was accounted for Graphene oxide immobilized DPEase which is higher than the agtu-DPEase. Graphene oxide immobilized DPEase showed bioconversion efficiency up to 10 cycles of reusability.

A single and two step isomerization process for d-tagatose and l-ribose bioproduction using l-arabinose isomerase and d-lyxose isomerase

l-ribose and d-tagatose are biochemically synthesized using sugar isomerases. The l-arabinose isomerase gene from Shigella flexneri (Sf-AI) was cloned and expressed in Escherichia coli BL-21. Sf-AI was applied for the bioproduction of d-tagatose from d-galactose. l-ribose synthesis was performed by two step isomerization using Sf-AI and d-lyxose/ribose isomerase from Cohnella laevoribosii. The overall 22.3% and 25% conversion rate were observed for d-tagatose and l-ribose production from d-galactose and l-arabinose respectively. In the present manuscript, synthesis of rare sugars from naturally available sugars is discussed along with the biochemical characterization of Sf-AI and its efficiency.

Engineering of the catalytic site of xylose isomerase to enhance bioconversion of a non-preferential substrate

Mutation in active site would either completely eliminate enzyme activity or may result in an active site with altered substrate-binding properties. The enzyme xylose isomerase (XI) is sterospecific for the α-pyranose and α-fructofuranose anomers and metal ions (M1 and M2) play a pivotal role in the catalytic action of this enzyme. Mutations were created at the M2 site of XI of Thermus thermophilus by replacing D254 and D256 with arginine. Mutants D254R and a double mutant (D254R/D256R) showed complete loss of activity while D256R showed an increase in the specificity on D-lyxose, L-arabinose and D-mannose which are non-preferential substrates for XI. Both wild type (WT) and D256R showed higher activity at pH 7.0 and 85°C with an increase in metal requirement. The catalytic efficiency Kcat/Km (S(-1) mM(-1)) of D256R for D-lyxose, L-arabinose and D-mannose were 0.17, 0.09 and 0.15 which are higher than WT XI of T.thermophilus. The altered catalytic activity for D256R could be explained by the possible role of arginine in catalytic reaction or the changes in a substrate orientation site. However, both the theories are only assumptions and have to be addressed with crystal study of D256R.

Enhanced catalysis of l-asparaginase from Bacillus licheniformis by a rational redesign

L-Asparaginase (3.5.1.1) being antineoplastic in nature are used in the treatment of acute lymphoblastic leukemia (ALL). However glutaminase activity is the cause of various side effects when used as a drug against acute lymphoblastic leukemia (ALL). Therefore, there is a need of a novel L-asparaginase (L-ASNase) with low or no glutaminase activity. Such a property has been observed with L-ASNase from B. licheniformis (BliA). The enzyme being glutaminase free in nature paved the way for its improvement to achieve properties similar to or near to the commercially available L-ASNases. Rational enzyme engineering approach resulted in four mutants: G238N, E232A, D103V and Q112H. Among these the mutant enzyme, D103V, had a specific activity of 597.7IU/mg, which is higher than native (rBliA) (407.65IU/mg). Moreover, when the optimum temperature and in vitro half life were studied and compared with native BliA, D103V mutant BliA was better, showing tolerance to higher temperatures and a 3 fold higher half life. Kinetic studies revealed that the mutant D103V L-ASNase has increased substrate affinity, with Km value of 0.42mM and Vmax of 2778.9μmolmin(-1).

Application of an industrial waste magnetic iron dust as a solid phase support for immobilizing enzyme of industrial applications

Magnetic iron dust, a byproduct by many chemical industries that performs the reduction of nitro compounds to amine, was used for laccase immobilization. The characterization of magnetic iron dust was done by X-ray diffraction, Fourier-transform infrared, and dynamic light scattering. Biodegradable polymer, chitosan, was coated on to the magnetic iron dust by reverse phase suspension method, which was confirmed by Fourier-transform infrared analysis. Immobilization of the laccase enzyme was done onto the chitosan-coated and non-coated magnetic iron dust. The immobilization was monitored by Fourier-transform infrared analysis. Binding efficiency, optimum pH, and optimum temperature for these immobilized laccases were investigated. X-ray diffraction pattern of magnetic iron dust confirmed presence of magnetite (Fe3O4) and maghemite (γ-Fe2O3) with a particle size of 529.6 nm measured by dynamic light scattering. Laccase was immobilized on chitosan-coated and non-coated magnetic iron dust, monitored by Fourier-transform infrared spectra. Binding efficiency of the laccases was found to be 100% onto the coated and non-coated magnetic iron dust and their activity remained to be 63% and 82%, respectively, even after the 10th cycle of their use. The present results demonstrated the applicability of these immobilized laccase system in the industry in terms of their reusability and waste recycling.