Ecofriendly degradation of sulfonated diazo dye C.I. Reactive Green 19A using Micrococcus glutamicus NCIM-2168

Micrococcus glutamicus NCIM-2168 exhibited complete decolorization and degradation of C.I. Reactive Green 19A (an initial concentration of 50 mg l⁻¹) within 42 h at temperature 37 °C and pH 8, under static condition. Extent of mineralization was determined with total organic carbon (TOC) and chemical oxygen demand (COD) measurement, showing a satisfactory reduction of TOC (72%) and COD (66%) within 42 h. Enzyme studies shows involvement of oxidoreductive enzymes in decolorization/degradation process. Analytical studies of the extracted metabolites confirmed the significant degradation of Reactive Green 19A into various metabolites. The microbial toxicity and phytotoxicity assay revealed that the degradation of Reactive Green 19A produced nontoxic metabolites. In addition, the M. glutamicus strain was applied to decolorize a mixture of ten reactive dyes showing a 63% decolorization (in terms of decrease in ADMI value) within 72 h, along with 48% and 42% reduction in TOC and COD under static condition.     

Decolorization of Pulp-Paper Mill Effluents by White-Rot Fungi

ABSTRACT:?

Phenolic effluents are waste products of pulp and paper, coal conversion, dying, textile, and olive oil industries. Such effluents impose coloration and toxicity problems in the receiving waters, causing serious environmental hazards. The pulp and paper mill effluent is highly colored, imparting black/brown color to the water body. The color is mainly due to lignin and its derivatives released during various stages in the paper-making process. The complex nature of such lignin compounds and their phenolic nature make them extremely resistant to microbial degradation. Conventional treatment methods such as aerated lagoons and activated sludge process are ineffective in removing color. However, physical and chemical treatment methods, including ultrafiltration, ion-exchange, and lime precipitation, are expensive and less efficient. Therefore, alternate low-cost biotreatment processes are now being considered, most of which are based on lignin-degrading fungi. Depending on the treatment process, the fungal inoculum for decolorization could be used in the form of mycelium, pellets, or in the immobilized state. The decomposition of lignin is an enzymatic process employing various ligninases being produced by the fungal species. Soluble and immobilized ligninolytic enzymes have also been employed for effluent decolorization. Therefore, the present review is an attempt to compile the scattered information on pulp-paper mill effluent decolorization employing microbes. The structure, distribution, physiology, and enzymology of lignin degradation is also briefly discussed.     

熟地多糖活性炭脱色工艺的研究

本研究旨在探讨活性炭对熟地多糖提取液脱色的工艺条件。在单因素试验基础上,采用正交试验,以多糖脱色率(%)和多糖剩余率(%)为指标,用紫外-可见分光光度法测定,确定了熟地多糖活性炭脱色的最优工艺的参数。结果发现:活性炭添加量对脱色效果的影响最大,其次为温度,再次为时间。最佳脱色条件为脱色温度60℃,活性碳添加量5%,吸附时间30 min,在此条件下,脱色率为98.20%,多糖剩余率为84.89%。从而表明活性炭对熟地多糖脱色工艺可行,简便,有效。     

STATISTICAL OPTIMIZATION OF SYNTHETIC AZO DYE (ORANGE II) DEGRADATION BY AZOREDUCTASE FROM Pseudomonas oleovorans PAMD_1

Pseudomonas oleovorans PAMD_1 produced an intracellular azoreductase as the more prominent enzyme that reduces the azo bridge during the azo dye decolorization process. In order to optimize the expression of azoreductase, statistically based experiments were applied. Eleven significant factors were screened on decolorization activity using Plackett–Burman design. Dye, NADH, glucose, and peptone were identified as having highest positive influence on the decolorization activity. Central composite design of response surface methodology was employed for the concerted effect of these four factors on decolorization activity. This method showed that the optimum medium containing dye (200 mg L^?1), NADH (1.14 mM), glucose (2.07 g L^?1), and peptone (6.44 g L^?1) for the decolorization of Orange II up to 87% in 48 hr. The applied methodology was validated through the adequacy and accuracy of the overall experiments, and the results proved that the applied methods were most effective. Further, the enzyme was purified ninefold with 16% yield by anion-exchange chromatography and a specific activity of 26 U mg^?1. The purified enzyme with a molecular mass of 29,000 Da gave a single band on sodium dodecyl sulfate (SDS) gel, and the degradation products sulfanilic acid and 1-amino-2-napthol of Orange II by azoreductase were analyzed by using an ultraviolet–visible (UV-Vis) spectrophotometer and hish-performance liquid chromatography (HPLC).     

Influence of structure on dye degradation with laccase mediator systems

A new laccase was purified from Trametes hirsuta IMA2002. The laccase had a molecular mass of 62 kDa and an isoelectric point of pH 7. It had an optimum pH of 3.0 and an optimum temperature of 55°C. The laccase was quite stable at 30°C and pH 4.0 with a half-life of more than 100 hours. On ABTS, syringaldazide, and DMP the laccase showed K_M and K_cat values of 75, 12 and 37 μM and 64, 83 and 54 s^-1, respectively. The structurally diverse commercial dyes Indigo Carmine, Lanaset Blue 2R, Diamond Black PV 200 and Diamond Fast Brown were oxidized by the laccase. While the rate and extent of decolorization of the latter dye was significantly enhanced by the presence of different types of mediators, the structurally similar azo-dye Tartrazine was not oxidized. Lanaset Blue 2R, a commercial textile dye containing an anthrachinoid structural fragment acted similarly to anthrachinone sulfonic acid by strongly enhancing the rate of the decolorization reaction. Twenty two model azo-dyes based on the molecular framework of 2,7-dihydroxy-1-phenylazonaphtalene-3,6-disulfonic acid were synthesized and the kinetics of their laccase-catalyzed decolorization was studied. Hydroxy-substituted dyes were the most susceptible to enzyme/mediator action. All reactions were well described by Michaelis-Menten-like kinetics and the Hammett free energy linear relationship could be successfully applied to describe the influence of dye structure (substituents on the aromatic ring) on decolorization. Strongly electron withdrawing substituents such as a nitro-group in the meta-position (+0.7) resulted in positive σ-constants whereas electron donating groups such as para-methyl (-0.3) resulted in negative values for σ-constants.     

Activated charcoal: a versatile decolorization agent for the recovery and purification of alkaline protease

The use of activated charcoal for enzyme recovery and purification was investigated and the optimum activated charcoal concentration and the minimum contact time needed for efficient decolorization of an alkaline protease preparation in terms of surface adsorption and retention of enzyme activity were found to be 7.5 g l^–1 and 30 min, respectively. Elevated temperatures had a greater influence on the rate of decolorization which was faster when the protease was refluxed at 60 °C for 10–15 min. These data suggest that the efficient adsorption characteristics of activated charcoal can be exploited for cost-effective downstream processing of alkaline proteases and possibly other enzymes.     

Degradation of dye-containing textile effluent by the agaric white-rot fungus Clitocybula dusenii

Raw mixed-dye wastewater from a textile dye-producing plant was partly decolorized by the agaric white-rot fungus, Clitocybula dusenii. The fungus had higher Mn peroxidase (MnP) and laccase activities when grown with dye effluent than in control cultures. The activity of MnP increased commensurately with the proportion of the raw dye wastewater in the medium (control: 20 U l^–1; 10% v/v effluent: 67 U l^–1; 25% v/v effluent: 130 U l^–1; and 33% v/v effluent: 180 U l^–1). Maximal decolorization rates were achieved over 20 d at 28 °C using four-fold diluted dye-containing effluent on a 5 d pre-grown mycelium.     

一株刚果红降解菌的筛选、鉴定和性质的初步研究

通过稀释划线的方法,从土壤中分离到一株能降解刚果红的菌株(T1),从菌落和孢子形态来判断该菌为放线菌的链霉菌属。T1菌在含刚果红(100 mg.L-1)高氏液体培养基中培养6 d后,脱色率高达90%。对培养液进行200~800 nm波长扫描的结果表明,培养基中部分刚果红被T1菌降解,其余部分被菌体吸附。活菌体对染料的吸附效率比死菌体高。T1菌对刚果红的脱色主要是通过生物降解和菌体吸附作用来完成。     

Color removal ability of <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis> in relation to lignin peroxidase and manganese peroxidase produced in molasses wastewater

Decolorization of molasses wastewater (MWW) from an ethanolic fermentation plant by Phanerochaete chrysosporium was studied. By diluting MWW properly (10%v/v) and incubating it with an appropriate concentration of the spores (2.5 × 10⁶/ml), extensive decolorization occurred (75%) on day 5 of the incubation. The colour removal ability was found to be correlated to the activity of ligninolytic enzyme system: lignin peroxidase (LiP) activity was 185 U/l while manganese peroxidase (MnP) activity equaled 25 U/l. Effects of some selected operating variables were studied: manganese(II), veratryl alcohol (VA), glucose as a carbon source and urea and ammonium nitrate, each as a source of nitrogen. Results showed that the colour reduction and LiP activity were highest (76% and 186 U/l, respectively) either when no Mn(II) was added or added at the lowest level tested (0.16 mg/l to provide 0.3 mg/l). Activity of MnP was highest (25 U/l) when Mn(II) added to the diluted MWW at the highest level (100 ppm) while activity of LiP was lowest (7.1 U/l) at this level of added Mn(II). The colour reduction in the presence of the added VA was shown to be little less than in its absence (70 vs. 75%). When urea as an organic source of nitrogen for the fungus, was added to the MWW, the decolorizing activity of P. chrysosporium decreased significantly (15 vs. 75%) and no activities were detected for LiP and MnP. Use of ammonium nitrate as an inorganic source of nitrogen did not show such a decelerating effects, although no improvements in the metabolic behavior of the fungus (i.e., LiP and MnP activities) deaccelerating was observed. Effects of addition of glucose was also discussed.     

木质素生物降解与纸浆工业废水脱色

主要工业废水之一的纸浆工业废水中的木质素类有色物质的去除一直倍受关注。本文主要综述了木质素降解微生物、影响木质素降解的因素、木质素降解酶类及其基因工程研究和纸浆工业废水的固定化真菌法和酶法脱色。