Effect of changing the nanoscale environment on activity and stability of nitrate reductase

Kinetic Analysis of Nitrite Reduction Reactions by Nitrite Reductase Derived from Spinach in the Presence of One-Electron Reduced Riboflavin

The development of methods for converting nitrogen oxides in water into valuable resources such as ammonia and hydrazine has been given some attention. By utilizing the nitrite-reducing catalytic activity of nitrite reductase (NiR), nitrite in water can be converted into ammonium. However, there are few reports in the research that synthesized ammonium from nitrite using nitrite reductase. Therefore, we aimed to investigate the effect of temperature on the nitrite-reducing catalytic activity of NiR from spinach in the presence of one-electron reduced riboflavin by kinetic analysis to find the optimum temperature conditions. The results of this study showed that the reaction temperature does not need to be higher than 296.15 K in order to improve the efficiency of ammonium production from nitrite using NiR.

NAP enzyme recruitment in simultaneous bioremediation and nanoparticles synthesis

•

This study employed the immobilized strain MMT and its NAP enzyme in concurrent denitrification and NPs synthesis.

•

The properties of crude NAP enzyme were assessed at different ranges of pH and temperatures and also its stability at 4 °C and 30 °C was studied.

•

The effect of several types of additives were evaluated at concentration rang (1 mM, 2.5 mM, 5 mM and 10 mM).

•

Concurrently, the immobilized MMT cells completely removed NO₃⁻ upon 8th day with AgNPs synthesis ranging from 23.26 to 58.14.

•

Immobilized NAP exhibited lower efficiency with 28.6% of NO₃ elimination and large aggregated AgNPs ranging from 94.44 nm to 172.22 nm.

The periplasmic nitrate reductase enzyme (NAP) has become attractive catalyst, whose exploitation has emerged as one of the indispensable strategies toward environmentally benign applications. To achieve them efficiently and overcome the sensitivity of NAP in harsh environmental circumstances, the immobilization for denitrifying bacteria and NAP enzyme for simultaneous bioremediation and bionanoparticles synthesis was studied. NAP catalyzed NO₃⁻ reduction at V_max of 0.811 μM/min and K_m of 14.02 mM. Concurrently, the immobilized MMT cells completely removed NO₃- upon 192 h with AgNPs synthesis ranging from 23.26 to 58.14 nm as indicated by SEM. Wherase, immobilized NAP exhibited lower efficiency with 28.6% of NO₃⁻ elimination within 288 h and large aggregated AgNPs ranging from 94.44 nm to 172.22 nm. To the best of author knowledge, the immobilization for denitrifying bacteria and NAP enzyme for simultaneous bioremediation and bionanoparticles synthesis was not studied before.

A novel polyurethane/nano ZnO matrix for immobilization of chitinolytic enzymes and optical sensing of chitin

Purified chitinase from Vigna mungo and N-acetyl β glucosaminidase (NAGase) from Canavalia ensiformis were immobilized on to the novel polyurethane (PU)/zinc oxide nanoparticles (nano ZnO) composite matrix with a conjugation yield of 0.785±0.01mg/cm² and 96.19±0.85% retention of specific activity. Scanning Electron Microscopy (SEM) and Fourier Transform Infrared Spectroscopy (FTIR) also confirmed the presence of nano ZnO and enzymes on the PU support. Thus synthesized PU/nano ZnO/chitinase/NAGase conjugates were optimized with respect to pH, temperature and substrate concentration and successfully employed for development of an absorbance based optical biosensor for chitin determination in stored wheat grains. The limit of detection was 0.01mM with linearity from 0.1 to 10.0mM. The% recoveries of added chitin (0.1 and 0.2mM) were >95.0% and >96.5% respectively and within-day and between-day coefficients of variations were 1.03% and 1.78% respectively. The method showed good correlation (R²=0.996) with the popular 3,5-dinitrosalicylic acid method. PU/nano ZnO bound chitinase/NAGase showed good thermal and storage stabilities and could be reused 10 times without any appreciable loss of activity.