Decontamination of Chlorpyrifos Residue in Soil by Using Mentha piperita (Lamiales: Lamiaceae) for Phytoremediation and Two Bacterial Strains.

This study utilizes Mentha piperita (MI) for the first time to investigate the uptake and translocation of chlorpyrifos (CPF; 10 µg g-1) from soil, introducing a new approach to improve the efficacy of this technique, which includes using biosurfactants (Bacillus subtilis and Pseudomonas aeruginosa) at 107 CFU/mL to degrade CPF under greenhouse conditions. Moreover, antioxidant enzymes, including superoxide dismutase (SOD) and peroxidase (Prx), and oxidative stress due to hydrogen peroxide (H2O2) and malondialdehyde (MDA) in MI roots and leaves were evaluated under CPF stress. Our results demonstrated that amending soil with MI and B. subtilis followed by P. aeruginosa significantly reduced CPF levels in the soil (p > 0.05) and enhanced CPF concentrations in MI roots and leaves after 1, 3, 7, 10, and 14 days of the experiment. Furthermore, CPF showed its longest half-life (t1/2) in soil contaminated solely with CPF, lasting 15.36 days. Conversely, its shortest half-life occurred in soil contaminated with CPF and treated with MI along with B. subtilis, lasting 4.65 days. Soil contaminated with CPF and treated with MI and P. aeruginosa showed a half-life of 7.98 days. The half-life (t1/2) of CPF-contaminated soil with MI alone was 11.41 days. A batch equilibrium technique showed that B. subtilis is better than P. aeruginosa for eliminating CPF from soil in In vitro experiments. Notably, CPF-polluted soil treated with coadministration of MI and the tested bacteria improved the activities of SOD and Prx and reduced H2O2 and MDA compared with CPF-polluted soil treated with MI alone. Our findings demonstrated that using B. subtilis and P. aeruginosa as biosurfactants to augment phytoremediation represents a commendable strategy for enhancing the remediation of CPF contamination in affected sites while reducing the existence of harmful pesticide remnants in crop plants.

Bird fancier's lung: a state-of-the-art review.

Bird fancier's lung (BFL) resulting from avian antigen exposure is a very common form of hypersensitivity pneumonitis. Its pathogenesis is modified by genetic polymorphisms located within the major histocompatibility complex, and also by smoking, which may decrease serum antibody response to inhaled antigen. Acute, subacute, and chronic presentations of BFL are recognized, but often overlap clinically. Continued antigen exposure in the chronic phase portends a worse prognosis. Chronic bronchitis symptoms may be part of the BFL clinical spectrum, and rhinitis may suggest an allergic component. The diagnosis of BFL is enhanced by a high index of suspicion of exposure to avian antigen, recurrent symptomatic episodes occurring 4-8 h after exposure, inspiratory "velcro" crackles on auscultation, weight loss, and positive IgG precipitins to the antigen. Characteristic findings on high-resolution computed tomography of the chest include centrilobular nodules, ground-glass opacification, and mosaicism due to air trapping. Bronchoalveolar lavage will classically show >25% lymphocytosis, a CD4/CD8 ratio of <1.0 and >1% mast cells in the acute phase. Lung biopsies, if obtained in the subacute phase of the disease, typically show loosely formed granulomas, giant cells, a lymphoplasmacytic interstitial infiltrate, and possibly some degree of fibrosis. In some patients, usual interstitial pneumonia or fibrotic non-specific interstitial pneumonia patterns may be seen on surgical biopsy. Skin testing, serological testing, and bronchial provocation tests for BFL frequently suffer from a lack of standardization. Effective treatment for BFL consists mainly of antigen avoidance, as corticosteroids likely do not alter long-term prognosis. Lung transplantation can be considered for progressive chronic disease refractory to medical measures.

A tree-based algorithm for determining the effects of solvation on the structure of salivary gland tripeptide NH3+-D-PHE-D-GLU-GLY-COO-.

A D-enantiomeric analog of the submandibular gland rat-1 tripeptide FEG (Seq: NH(3)(+)-Phe-Glu-Gly-COO(-)) called feG (Seq: NH(3)(+)-D-Phe-D-Glu-Gly-COO(-)) was examined by molecular dynamics simulations in water. Previous in vacuo simulations suggested a conformation consisting predominantly of interactions between the Phe side chain and glutamyl-carboxyl group and a carboxyl/amino termini interaction. The solvated peptide was simulated using two approaches which were compared-a single 400-ns simulation and a "simulation tree." The "tree" approach utilized 45 10-ns simulations with different conformations used as initial structures for given trajectories. We demonstrate that multiple short duration simulations are able to describe the same conformational space as that described by longer simulations. Furthermore, previously described in vacuo interactions were confirmed with amendments: the previously described head-to-tail arrangement of the amino and carboxyl termini, was not observed; the interaction between the glutamyl carboxyl and Phe side chain describes only one of a continuum of conformations present wherein the aromatic residue remains in close proximity to the glutamyl carbonyl group, and also interacts with either of the two available carboxyl groups. Finally, utilizing only two separate 10-ns trajectories, we were able to better describe the conformational space than a single 60-ns trajectory, realizing a threefold decrease in the computational complexity of the problem.