一色齿毛菌CB1对活性染料的脱色研究

前期工作中采用组织分离法分离、纯化得到一白腐真菌CB1,本研究进一步观察菌株CB1形态特征和培养特性,克隆菌株CB1的ITS基因序列,对菌株CB1的ITS序列进行同源性比对和系统进化分析,完成菌株CB1综合的鉴定。同时对菌株CB1脱色两种活性染料进行了研究,探讨菌株CB1脱色活性染料的能力。结果表明,菌株CB1形态特征和培养特性与一色齿毛菌Cerrena unicolor特征基本吻合,菌株CB1的系统进化分析表明菌株CB1的ITS序列与一色齿毛菌的ITS序列有较近的进化关系,形态学和分子生物学综合鉴定菌株CB1为C.unicolor CB1。染料脱色结果表明,菌株CB1可以明显脱色活性黑和活性红染料,与脱色活性黑相比,菌株CB1可以更有效地脱色活性红染料,在脱色12d时,菌株CB1对浓度为10、50、100、250、500mg/L的活性黑脱色率分别为96%、93%、65%、55%、40%,菌株CB1对浓度为10、50、100、250、500mg/L的活性红在12d时的脱色率分别为98%、95%、91%、87%、83%。     

不同培养基对富集筛选脱色真菌菌群的效果比较

利用活性黑RB5和活性红M-3BE作为筛选因子，从染料脱色效果、菌群产酶能力以及菌群中的微生物丰富度三方面比较了酵母培养基A、产漆酶真菌培养基B和白腐真菌培养基D在脱色真菌富集筛选方面的效果。富集筛选结果共得到11组具有明显脱色效果的真菌菌群，其中5组来自于D培养基，A和B培养基各获得3组。来自A培养基的3组菌群显示出最好的脱色效果和最大的菌群丰富度，对50mg/L的活性红M-3BE和酸性红A溶液的脱色率最高达到99.53%和97.42%，从中分离到了16株真菌，初步鉴定分属于水霉科、曲霉科（红曲霉属）、节壶菌科和白粉菌科；而B和D培养基中所获得的菌群脱色效果稍差，从中仅得到3株和2株真菌，初步鉴定属于酵母和青霉。A、B两种培养基在各种染料存在下更易产生木质素过氧化物酶，产漆酶能力较弱，而D培养基产漆酶活性较高。     

不同培养基对富集筛选脱色真菌菌群的效果比较

利用活性黑RB5和活性红M-3BE作为筛选因子,从染料脱色效果、菌群产酶能力以及菌群中的微生物丰富度三方面比较了酵母培养基A、产漆酶真菌培养基B和白腐真菌培养基D在脱色真菌富集筛选方面的效果。富集筛选结果共得到11组具有明显脱色效果的真菌菌群,其中5组来自于D培养基,A和B培养基各获得3组。来自A培养基的3组菌群显示出最好的脱色效果和最大的菌群丰富度,对50mg/L的活性红M-3BE和酸性红A溶液的脱色率最高达到99.53%和97.42%,从中分离到了16株真菌,初步鉴定分属于水霉科、曲霉科(红曲霉属)、节壶菌科和白粉菌科;而B和D培养基中所获得的菌群脱色效果稍差,从中仅得到3株和2株真菌,初步鉴定属于酵母和青霉。A、B两种培养基在各种染料存在下更易产生木质素过氧化物酶,产漆酶能力较弱,而D培养基产漆酶活性较高。     

不同培养基对富集筛选脱色真菌菌群的效果比较

利用活性黑RB5和活性红M-3BE作为筛选因子,从染料脱色效果、菌群产酶能力以及菌群中的微生物丰富度三方面比较了酵母培养基A、产漆酶真菌培养基B和白腐真菌培养基D在脱色真菌富集筛选方面的效果。富集筛选结果共得到11组具有明显脱色效果的真菌菌群,其中5组来自于D培养基,A和B培养基各获得3组。来自A培养基的3组菌群显示出最好的脱色效果和最大的菌群丰富度,对50mg/L的活性红M-3BE和酸性红A溶液的脱色率最高达到99.53%和97.42%,从中分离到了16株真菌,初步鉴定分属于水霉科、曲霉科（红曲霉属）、节壶菌科和白粉菌科;而B和D培养基中所获得的菌群脱色效果稍差,从中仅得到3株和2株真菌,初步鉴定属于酵母和青霉。A、B两种培养基在各种染料存在下更易产生木质素过氧化物酶,产漆酶能力较弱,而D培养基产漆酶活性较高。     

裂褶菌菌株G18对孔雀石绿染料的脱色优化

通过对兔眼蓝莓幼果组织中分离得到的内生真菌G18进行形态特征、ITS序列和系统进化分析鉴定菌株G18为裂褶菌Schizophyllum commune。同时,对菌株G18产生的3种木质素降解酶进行监测,发现G18菌株可以分泌漆酶、木质素过氧化物酶和锰过氧化物酶。为明确裂褶菌G18对染料的脱色能力,利用裂褶菌G18对固体条件下8种染料进行脱色能力的检测,筛选出较易脱色的染料后,对该染料的脱色条件进行优化。结果表明,裂褶菌G18对8种染料均可以脱色,对孔雀石绿染料的脱色效果最好。裂褶菌G18对孔雀石绿的脱色优化结果为pH 7.0、20.0g/L淀粉、1.0g/L尿素、1.0g/L硫酸锌、接菌量9片（d=5.0mm）。     

耐碱的偶氮染料脱色菌筛选及其特性的研究

从浙江某污水处理厂的活性污泥中筛选出若干株在高pH条件下对偶氮染料酸性大红GR有脱色能力的菌株,经脱色验证得到一株具有高效脱色活性的菌株Z1,经鉴定为巴斯德葡萄球菌(Staphylococcus pasteuri),并对此菌株的脱色特性进行了初步研究。结果表明,在厌氧条件下,Z1在pH7~12,40h对50mg/L的酸性大红GR脱色率均可达90%以上。该菌株对染料有较强的耐受力,在酸性大红GR浓度为300mg/L时,48h的脱色率仍可达93%。此外,该菌株能够对多种偶氮染料脱色,具有较好的脱色广谱性,有望应用于处理工业废水中的偶氮染料。     

阿魏菇与胶红酵母共培养产漆酶对活性艳蓝W-RV的脱色

利用阿魏菇与胶红酵母共培养所产漆酶对染料活性艳蓝W-RV进行脱色,同时考察不同p H、温度、染料浓度和漆酶酶活等条件对脱色的影响。结果显示,酸性范围内的p H有利于活性艳蓝W-RV的脱色,较高温度并不适于脱色反应。在研究不同染料浓度的影响时发现,不同浓度染料的脱色率在7 h反应后都达到了稳定,而漆酶酶活在达到200 U/L后脱色率不再变化。因此,最终得到的最适反应条件为p H 4.5、30℃、染料质量浓度100 mg/L、漆酶酶活200 U/L,在此条件下,活性艳蓝W-RV的最高脱色率为89.91%。     

Ganoderma lucidum U-281漆酶催化偶氮染料活性黑5脱色

漆酶在纺织染料脱色及印染废水处理领域有着广阔的应用前景。活性黑5是纺织印染中应用广泛的偶氮类活性染料,结构复杂,生物降解性低。以灵芝菌Ganoderma lucidum U-281所产漆酶对活性黑5进行氧化脱色,采用单因素逐一优化方法得到了U-281漆酶催化活性黑5脱色的工艺参数：染料初始浓度25mg/L、漆酶用量2.0U/mL、铜离子添加量40mmol/L、pH 6.0、40℃。在优化条件下,4h可使RB5脱色62.34%,24h可完成90%以上的脱色效果。     

野生型糙皮侧耳Pleurotus ostreatus JY2746对合成染料脱色性能的评价（英文）

随着我国印染工业的不断发展,人工合成染料给环境造成严重污染,现急需开发一种成本低廉、脱色效果显著的方法治理水污染问题。本研究发现糙皮侧耳的胞外粗酶液对5种合成染料均具有良好的脱色作用,其中对结晶紫、酸性品红和考马斯亮蓝G-250(浓度为40mg/L)的最高脱色率可分别达到100%、98.67%和92.5%。糙皮侧耳在液体发酵过程中主要产生3种酶类,即漆酶、锰过氧化物酶和木质素过氧化物酶,他们分别在第12天,第7天和第8天酶活达到最高,并且第12天产生的粗酶液对染料的脱色效果最好,根据酶活高峰形成时间与脱色率之间的关系,推测糙皮侧耳分泌的漆酶对染料起主要降解作用,而锰过氧化物酶和木质素过氧化物酶起辅助作用。本研究发现发酵粗酶液较纯化的酶类工艺简单,成本低廉,因此糙皮侧耳发酵液中提取的粗酶液在染料废水脱色处理方面具有潜在的应用价值。     

白腐真菌染料脱色菌株的筛选及一色齿毛菌脱色条件的研究

以平皿培养方式对采集自中国和芬兰的白腐真菌菌株降解6种不同结构的人工染料的能力进行了筛选研究。在40株菌株中,黑管孔菌Bjerkandera adusta Y5012,一色齿毛菌Cerrena unicolor Y5002,硬毛粗盖孔菌Funalia trogii Y4997,香栓孔菌Trametes suaveolens D8325和云芝栓孔菌Trametes versicolor Y4946对刚果红、橙黄G、茜素红、结晶紫、中性红和亚甲基蓝均显示出较强的脱色能力。对一色齿毛菌Cerrena unicolor Y5002的液体培养脱色条件进行了研究,其最适碳源和氮源分别为蔗糖和麦芽浸粉;在不同橙黄G浓度下均获得较高的脱色率,因此浓度为500mg/L的橙黄G未对该菌的脱色能力产生抑制作用,而浓度为400mg/L茜素红则对其脱色作用产生明显抑制。对菌丝生物量和染料脱色率的研究表明,在不同碳源和氮源条件下,两者之间具有明显的正相关性。     

白囊耙齿菌对茜素红脱色条件优化及其毒性变化检测

白囊耙齿菌Irpex lacteus是分离自倒木上的一株可以分泌漆酶和锰过氧化物酶的白腐真菌。利用I. lacteus对固体条件下的活性黑、活性红、结晶紫、茜素红和孔雀石绿进行脱色能力的检测,通过单因素和正交试验优化I. lacteus对茜素红的脱色条件,并以3种作物发芽率为指标测定茜素红被I. lacteus脱色前后的毒性变化。结果显示,I. lacteus对5种染料均可脱色,其中对茜素红染料的脱色更为彻底;单因素和正交试验优化I. lacteus对茜素红的脱色条件为：pH 7.0、葡萄糖10.0g/L、硫酸铵0.66g/L、接种量2片（Φ=8.0mm）、100.0mL三角瓶装液20.0mL,优化条件下I. lacteus对茜素红脱色10d时的脱色率为88.26%,与未优化前的脱色率相比提高了60.50%;茜素红染料被I. lacteus脱色前后毒性大小排序为：染料原液>染料脱色后>PDB培养基处理,表明茜素红染料存在一定的毒性,I. lacteus脱色茜素红后可以使其毒性减弱。通过本研究,为I. lacteus在茜素红等染料废水脱色以及降低染料废水毒性方面的应用奠定基础。     

多孔菌Trichaptum abietinum 1302BG自然条件下对合成染料刚果红和酸性品红的高效降解

选用杭州竹林土壤分离并筛选能够降解多种类型染料的真菌。经大量筛选发现一株编号为1302BG的真菌能够在固体培养基上分解所测试的全部9种染料(苯胺蓝、刚果红、橙黄G、甲基红、甲基橙、结晶紫、酸性品红、番红花红、碱性品红、甲基紫)。经形态学和分子生物学方法鉴定, 该菌1302BG为冷杉附毛孔菌(Trichaptum abietinum)。在液体培养基中研究了pH、温度、碳源、氮源、碳氮源组合、碳氮源浓度等参数对该菌脱色效果的影响, 以寻找最适最经济的脱色条件。在液体培养基中研究表明, 冷杉附毛孔菌1302BG既能在酸性又能在碱性条件下有效分解2种测试染料(酸性品红和刚果红)。该真菌能以仅含有0.5 g/L淀粉和0.05 g/L硫酸铵的经济、环境友好的培养基为底物, 能在灭菌和非灭菌(自然)的条件下高效脱色, 在24 h内对2种染料的脱色率均在90%以上。紫外/可见光谱及微核试验分析显示, 该菌脱色主要是以生物降解为主, 2种染料经该菌分解后的毒性也同时大大降低。这些优异特点显示了该菌具有非常广阔的工业染料废水处理应用潜力。     

Decolorization of synthetic dyes by solid state cultures of Lentinula (Lentinus) edodes producing manganese peroxidase as the main ligninolytic enzyme

The ability of the white-rot fungus Lentinula (Lentinus) edodes to decolorize several synthetic dyes was investigated using solid state cultures with corn cob as substrate. Cultures, containing amido black, congo red, trypan blue, methyl green, remazol brilliant blue R, methyl violet, ethyl violet and Poly R478 at 200 ppm, were completely decolorized after 18 days of incubation. Partial decolorization was observed in the cultures containing 200 ppm of brilliant cresyl blue and methylene blue. High manganese peroxidase activity (2600 U/g substrate), but very low lignin peroxidase (<10 U/g substrate) and laccase (<16 U/g substrate) activities were detected in the cultures. In vitro, the dye decolorization was markedly decreased by the absence of manganic ions and H2O2. These data suggest that manganese peroxidase appear to be the main responsible for the capability of L. edodes to decolorize synthetic dyes.     

Synthetic dye decolorization capacity of white rot fungus Dichomitus squalens

The ability to decolorize eight chemically different synthetic dyes (Orange G, Amaranth, Orange I, Remazol Brilliant Blue R (RBBR), Cu-phthalocyanin, Poly R-478, Malachite Green and Crystal Violet) by the white rot fungus Dichomitus squalens was evaluated on agar plates. The fungus showed high decolorization capacity and was able to decolorize all dyes tested, but not to the same extent. Some of the dyes did not limit the decolorization capacity of the strain tested even at a concentration of 2g/l. The presence of the dyes in solid media reduced the mycelial growth rate of D. squalens; a positive correlation was found between the growth rate and the decolorization ability. Decolorization of Orange G and RBBR was studied also in liquid culture, where both dyes caused an enhancement of ligninolytic enzyme and overall hydrogen peroxide production and a decrease of biomass production. RBBR was removed to a higher extent than Orange G.     

Decolorization of Victoria blue by the white rot fungus, <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis>

Synthetic textile dyes are among the most dangerous chemical pollutants released in industrial wastewater streams. Recognizing the importance of reducing the environmental impact of these dyes, the ability of the white rot fungus Phanerochaete chrysosporium to decolorize various textile dyes was investigated. This fungus decolorized 6 of the 14 structurally diverse dyes with varying efficiency (between 14% and 52%). There was no discernable pattern of decolorization even among dyes of the same chemical class, suggesting that attack on the dyes is relatively non-specific. Among the three dyes which showed >40% decolorization, Victoria Blue B (VB) was chosen for further analysis because the ability of the fungus to decolorize VB was nearly independent over a relatively broad concentration range. Blocking lignin peroxidase (LiP) and manganese peroxidase (MnP) production by the fungus did not substantially affect VB decolorization. Inhibition of laccase production by adding various inhibitors to shaken cultures reduced VB decolorization significantly suggesting a role for laccase in VB decolorization. When sodium azide and aminotriazole were used to inhibit endogenous catalase and cytochrome P-450 oxygenase activities, there was 100% and 70% reduction in VB decolorization, respectively. Adding benzoate to trap hydrogen peroxide-derived hydroxyl radicals resulted in 50% decolorization of VB. Boiling the extracellular fluid (ECF) for 30 min resulted in approximately 50% reduction in VB decolorization. Collectively, these data suggest that laccase, and/or oxygenase/oxidase and a heat-stable non-enzymatic factor, but not Lip and MnP, play a role in VB decolorization by P. chrysosporium.     

藜芦醇和吐温80对白腐菌产木质素降解酶的影响及在偶氮染料脱色中的作用

担子菌PM2在限氮液体培养下,分泌木质素过氧化物酶和锰过氧化物酶;藜芦醇、吐温 80的补充,提高了该菌锰过氧化物酶的产生,获得的最大锰过氧化物酶Mnp酶活为254.2u/L、190.2 u/L,分别是对照的3.4倍和2.5倍。选择三种偶氮染料,在染料体系下,进一步分析藜芦醇、吐温 80对担子菌PM2产过氧化物酶及染料脱色的影响。结果表明,担子菌PM2分泌的锰过氧化物酶Mnp与染料脱色有关,脱色程度受其分子结构特征影响;吐温80的补充,更有利于染料的脱色降解,48h后三种染料均可达到80%以上的脱色率。     

Uptake of reactive textile dyes by Aspergillus foetidus

An isolated fungus, Aspergillus foetidus was found to effectively decolorize media containing azo reactive dyes namely, Drimarene dyes. The extent of color removal was greater than 95% within 48 h of growth of the fungus. The entire color was found to be strongly bioadsorbed to the rapidly settling fungal biomass pellets without undergoing significant biotransformation. Our investigations reveal that the process of decolorization is concomitant with the exponential growth phase of the fungus and has requirement for a biodegradable substrate such as glucose. The fungus was also able to decolorize media containing mixture of dyes to an extent of 85% within 72 h of growth. Kinetic analyses of fungal decolorization indicate that the process is time dependent and follows first order kinetics with respect to initial concentration of dye. The rates of color uptake (k values) decrease to a significant extent with increasing initial concentrations of dye. The fungus was able to grow and decolorize media in the presence of 5 ppm of chromium and 1% sodium chloride. An alternate and cheaper carbon source such as starch supported the growth and decolorization process. These results suggest that dye uptake process mediated by A. foetidus has a potential for large-scale treatment of textile mill discharges.     

Bioremediation of Textile Azo Dyes by Trichophyton rubrum LSK-27

Summary The potential of a recently isolated wood-degrading fungus, Trichophyton rubrum LSK-27, for effective decolorization of textile azo dyes was evaluated. Within two days of dye addition, the fungus was able to decolorize 83% of Remazol Tiefschwarz, 86% of Remazol Blue RR and 80% of Supranol Turquoise GGL in liquid cultures. The reactive dyes, Remazol Tiefschwarz and Remazol Blue, were removed by fungal biodegradation, while decolorization of the acid dye, Supranol Turquoise GGL, was accomplished mainly by bioadsorption. Therefore the fungus proved to be efficiently capable of both biodegradation and biosorption as the major dye removal mechanisms. The extent of biodegradation was associated with the levels of the extracellular ligninolytic enzymes such as manganese peroxidase and laccase.     

Decolorization of dye and molasses by continuous and semi-continuous jar-fermentor cultures ofGeotrichum candidum Dec 1

Two culture modes, continuous and semi-continuous, of the decolorization fungus,Geotrichum candidum Dec 1, were compared to obtain a high treatment efficiency of molasses decolorization and a large productivity of peroxidase (DyP) to simultaneously decolorize dyes and molasses. The continuous culture ofG. candidum Dec 1 using a 5-l jar-fermentor showed high DyP activity at a low dilution ratio of 0.005h⁻¹, and decolorization ratio of molasses of 80% was obtained concomitantly. Therefore, a semi-continuous culture was performed by repeated refill and draw. In this mode, approximately 1.5 liters of the culture broth was replaced per cycle when the decolorization ratio of molasses was near 80%. The molasses medium (1.0 liter per day) was treated and the peroxidase productivity in the drawn culture broth was 26.6 U/day, whereas the peroxidase productivity was 17.9 U/day in the continuous culture with a dilution rate of 0.005 h⁻¹. The semi-continuous treatment system was an efficient decolorization method for the strain,G. candidum Dec 1.