Biodegradation of alkali lignin by Bacillus flexus RMWW II: analyzing performance for abatement of rice mill wastewater.

A potential bacterium Bacillus flexus RMWW II has been isolated from rice mill effluent, and examined for its decolorizing potential for lignin-mimicking dyes. The biodegradation of alkali lignin by the rod-shaped, Gram-positive, oxidase and catalase-positive Bacillus flexus RMWW II bacteria is due to its uptake of lignin as the sole carbon source. The lignin degradation was 100% at a lignin concentration of 50 mg L-1 but the degradation reduced to 20% at 400 mg L-1. The bacterial-mediated biodegradation of alkali lignin was suitably explained by the Edward kinetics model with a maximal specific biodegradation rate (qmax) of 0.056 h-1 and true specific biodegradation rate (q*) of 0.042 h-1. The non-toxic nature of the metabolites of alkali lignin after bacterial degradation was illustrated by phytotoxicity studies. This bacterium was utilized to treat complex rice mill wastewater, as lignin is one of the major components of the effluent. A considerable reduction of 84% of chemical oxygen demand (COD) was observed in a batch reactor in 70 h of operation. The bacterial treatment results for the actual rice mill effluent indicate that Bacillus flexus RMWW II could be a promising agent for microbial remediation of lignin-laden raw rice mill wastewater.

Current techniques in rice mill effluent treatment: Emerging opportunities for waste reuse and waste-to-energy conversion.

Rice mills release huge volumes of wastewater and other by-products when processing paddy rice. The wastewater often contains toxic inorganic and organic contaminants which cause environmental damage when released. Accordingly, cost-effective techniques for removing contaminants are needed. This article reviews current processes for curbing pollution and also reusing and recycling waste products. Novel techniques exist for converting waste products into energy and value-added products.

Treatment of leather industry wastewater by aerobic biological and Fenton oxidation process.

Degradation of leather industry wastewater by sole aerobic treatment incorporating Thiobacillus ferrooxidans, Fenton's reagents, and combined treatment was investigated in this study. The sole treatment by Fenton's oxidation involving the introduction of 6g FeSO(4) and 266 g H(2)O(2) in a liter of wastewater at pH of 3.5 and 30 degrees C for 30 min at batch conditions reduced COD, BOD(5), sulfide, total chromium and color up to 69%, 72%, 88%, 5%, 100% and T. ferrooxidans alone showed maximum reduction to an extent of 77, 80, 85, 52, 89, respectively, in 21 d treatment at pH 2.5, FeSO(4) 16 g/L and temperature of 30 degrees C. The combined treatment at batch conditions involving 30 min chemical treatment by Fenton's oxidation followed by 72 h biochemical treatment by T. ferrooxidans at batch conditions gave rise up to 93%, 98%, 72%, 62% and 100% removal efficiencies of COD, BOD, sulfide, chromium and color at pH of 2.5 and 30 degrees C. Decrease in photo absorption of the Fenton's reagent treated samples, as compared to the banks, at 280, 350 and 470 nm wave lengths was observed. This may be the key factor for stimulating the biodegradation by T. ferrooxidans.

The effect of beta-tubulin-specific antisense oligonucleotide encapsulated in different cationic liposomes on the suppression [correction of supression] of intracellular L. donovani parasites in vitro.

An antisense oligonucleotide (20 mer) targeted to the parasite beta-tubulin gene and encapsulated in cationic liposomes, was used to test its antileishmanial activity in vitro. Cationic liposomes containing dioleyl trimethyl ammonium propane (DOTAP) were found to have higher antileishmanial activity (88% at 4 microM oligonucleotide) compared to two other liposomes with stearyl amine (SA) and cetyl trimethyl ammonium bromide (CTAB) as cations. Dot-blot experiments were performed to analyse the expression of beta-tubulin mRNA using beta-tubulin-specific radiolabelled DNA as a probe. When compared with their respective controls, beta-tubulin-specific gene expression was found to be diminished by treatment with a specific antisense oligonucleotide encapsulated in cationic liposomes (CTAB:DOPE) in a concentration-dependent manner. These experiments show that antisense oligonucleotides targeted to the beta-tubulin gene of Leishmania donovani inhibit beta-tubulin synthesis leading to the arrest of multiplication of intracellular parasites.