Organophosphate pesticides an emerging environmental contaminant: Pollution, toxicity, bioremediation progress, and remaining challenges.

Organophosphates (OPs) are an integral part of modern agriculture; however, due to overexploitation, OPs pesticides residues are leaching and accumulating in the soil, and groundwater contaminated terrestrial and aquatic food webs. Acute exposure to OPs could produce toxicity in insects, plants, animals, and humans. OPs are known for covalent inhibition of acetylcholinesterase enzyme in pests and terrestrial/aquatic organisms, leading to nervous, respiratory, reproductive, and hepatic abnormalities. OPs pesticides also disrupt the growth-promoting machinery in plants by inhibiting key enzymes, permeability, and trans-cuticular diffusion, which is crucial for plant growth. Excessive use of OPs, directly/indirectly affecting human/environmental health, raise a thoughtful global concern. Developing a safe, reliable, economical, and eco-friendly methods for removing OPs pesticides from the environment is thus necessary. Bioremediation techniques coupled with microbes or microbial-biocatalysts are emerging as promising antidotes for OPs pesticides. Here, we comprehensively review the current scenario of OPs pollution, their toxicity (at a molecular level), and the recent advancements in biotechnology (modified biocatalytic systems) for detection, decontamination, and bioremediation of OP-pesticides in polluted environments. Furthermore, the review focuses on onsite applications of OPs degrading enzymes (immobilizations/biosensors/others), and it also highlights remaining challenges with future approaches.

Improved live-cell PCR method for detection of organophosphates degrading opd genes and applications.

Organophosphates are becoming an emerging pollutant due to their various applications, particularly as pesticides. In this study, an improved Colony (Live-cell) PCR method was developed for the detection of opd genes from bacteria encoding the organophosphate hydrolase enzymes capable of degrading various organophosphates. The improved method does not require pre-heating or pre-lysis of bacterial cells as essential in the conventional colony PCR. The reaction volume was scaled down to 10 µl by optimizing the PCR buffer and amplification conditions. The improved method was used for Gram positive and negative bacteria, glycerol stocks, liquid cultures, recombinant and mutant strains. Also, 16S rRNA gene was amplified from unknown environmental isolates and known E. coli strains. The amplified opd and 16S rRNA genes from the improved colony PCR method and by conventional PCR were sequenced, and similar results were obtained from both techniques. Thus, the improved method can be further explored in molecular biology or during biomarker studies. KEY POINTS: • Improved colony PCR method was developed for screening of opd genes from bacteria. • Method was validated for Gram positive/negative bacteria from solid as well as liquid media. • The improved method was rapid, efficient, and can be applied under various conditions.

Molecular and biochemical characterization of a thermostable keratinase from Bacillus altitudinis RBDV1.

A thermostable keratinase designated as KBALT was purified from Bacillus altitudinis RBDV1 from a poultry farm in Gujarat, India. The molecular weight of the native KBALT (nKBALT) purified using ammonium sulfate and ion exchange and gel permeation chromatography with a 40% yield and 80-fold purification was estimated to be ~ 43 kDa. The gene for KBALT was successfully cloned, sequenced and expressed in Escherichia coli. Recombinant KBALT (rKBALT) when purified using a single step Ni-NTA His affinity chromatography achieved a yield of 38.20% and a 76.4-fold purification. Comparison of the deduced amino acid sequence of rKBALT with known proteases of Bacillus species and inhibitory effect of PMSF suggest that rKBALT was a subtilisin-like serine protease. Both native and rKBALT exhibited higher activity at 85 °C and pH 8.0 in the presence of Mg2+, Mn2+, Zn2+, Ba2+ and Fe3+ metal ions. Interestingly, 70% of their activity was retained at temperatures ranging from 35 to > 95 °C. The keratinolytic activity of both nKBALT and rKBALT was enhanced in the presence of reducing agents. They exhibited broad substrate specificity towards various protein substrates. KBALT was determined for its kinetic properties by calculating its Km (0.61 mg/ml) and Vmax (1673 U/mg/min) values. These results suggest KBALT as a robust and promising contender for enzymatic processing of keratinous wastes in waste processing plants.

Effects of substrate binding site residue substitutions of xynA from Bacillus amyloliquefaciens on substrate specificity.

BACKGROUND: The aromatic residues of xylanase enzyme, W187, Y124, W144, Y128 and W63 of substrate binding pocket from Bacillus amyloliquefaciens were investigated for their role in substrate binding by homology modelling and sequence analysis. These residues are highly conserved and play an important role in substrate binding through steric hindrance. The substitution of these residues with alanine allows the enzyme to accommodate nonspecific substrates. RESULTS: Wild type and mutated genes were cloned and overexpressed in BL21. Optimum pH and temperature of rBAxn exhibited pH 9.0 and 50 °C respectively and it was stable up to 215 h. Along with the physical properties of rBAxn, kinetic parameters (Km 19.34 ± 0.72 mg/ml; kcat 6449.12 ± 155.37 min- 1 and kcat/Km 333.83 ± 6.78 ml min- 1 mg- 1) were also compared with engineered enzymes. Out of five mutations, W63A, Y128A and W144A lost almost 90% activity and Y124A and W187A retained almost 40-45% xylanase activity. CONCLUSIONS: The site-specific single mutation, led to alteration in substrate specificity from xylan to CMC while in case of double mutant the substrate specificity was altered from xylan to CMC, FP and avicel, indicating the role of aromatic residues on substrate binding, catalytic process and overall catalytic efficiency.

Characterization of a recombinant glutaminase-free L-asparaginase (ansA3) enzyme with high catalytic activity from Bacillus licheniformis.

L-Asparaginase (3.5.1.1) is an enzyme widely used to treat the acute lymphoblastic leukemia. Two genes coding for L-asparaginase (ansA1 and ansA3) from Bacillus licheniformis MTCC 429 were cloned and overexpressed in Escherichia coli BL21 (DE3) cells. The recombinant proteins were purified to homogeneity by one-step purification process and further characterized for various biochemical parameters. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis showed that both the enzymes are monomers of ∼37 kDa. Recombinant ansA1 was found to be highly unstable, and recombinant ansA3 was catalytically active and stable, which showed an optimum activity of 407.65 IU/mg at 37 °C and pH 8. Recombinant ansA3 showed higher substrate specificity for L-asparagine with negligible glutaminase activity. Kinetic parameters like K m , V max, k cat, and k cat/K m were calculated for recombinant ansA3.