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。     

中度嗜盐菌群对酸性大红GR的脱色性能研究

【目的】获得能够在高盐环境下脱色偶氮染料的高效脱色菌群,应用于印染废水的生物处理。【方法】采用在5%盐度培养基富集的方法,从印染废水的活性污泥中富集能够在5%盐度下脱色酸性大红GR的嗜盐混合菌群,利用高通量测序方法研究其群落结构,利用静置培养的方法研究其脱色性能。【结果】该菌群可以在5%盐度、静置培养下15 h内将100 mg/L的酸性大红GR几乎完全脱色,主要由Halomonas、Salinicoccus、Nitratireductor和Aequorivita等4个属组成,Halomonas是主要的脱色菌。高浓度的Na NO_3、Na_2SO_4和Na Cl抑制菌群的脱色,其中Na NO_3抑制作用最强。该菌群的最佳脱色条件是在p H 7.0、盐度5%、30°C脱色效果最好,可脱色直接耐黑G和分散深蓝S-3BG等偶氮染料,并且具有连续脱色的能力。【结论】嗜盐菌群在处理偶氮染料废水中具有良好的应用价值。     

嗜盐菌群对酸性金黄G的脱色特性和机理

【目的】为了获得能够在高盐环境下脱色偶氮染料的嗜盐菌群及其降解机理。【方法】采用富集驯化的方法获得一个嗜盐菌群,采用Illumina HiSeq2500测序平台对其群落结构进行测定;采用分光光度法测定了其降解特性;采用GC-MS和红外图谱分析了其降解机理;采用微核实验的方法比较了偶氮染料降解前后的毒性。【结果】该菌群在10%的盐度下,使100mg/L的酸性金黄G在8h内脱色。菌群主要由Zobellella、Rheinheimera、Exiguobacterium和Marinobacterium组成。最适宜的脱色条件是:pH=6,酵母粉为碳源,蛋白胨或硝酸钾作为氮源,盐度为1%–10%。酸性金黄G降解产物的毒性比降解前降低。酸性金黄G主要的降解产物是对氨基二苯胺和二苯胺。此外,该菌群还能使酸性大红GR和直接湖蓝5B等多种偶氮染料脱色,具有较好的脱色广谱性。【结论】获得了快速降解偶氮染料的嗜盐菌群及降解机理,为该嗜盐菌群应用于高盐印染废水的处理提供菌种资源和理论支持。     

一株广谱高效脱色菌的分离鉴定及其脱色特性

为了获得具有广谱染料降解脱色能力的脱色菌,为印染工业废水生物处理提供菌种资源,本研究采用平板稀释涂布法从绍兴某印染厂排污口采集的土壤中分离得到7株脱色菌,从中筛选出脱色能力最强的菌株CM-T1,经菌落形态、生理生化特性及16S r RNA基因序列分析将其鉴定为气单胞菌(Aeromonas sp.),其16S r RNA在Gen Bank的登录号为KJ958903。对CM-T1脱色特性的初步研究结果表明,该菌株在p H5.0~9.0、30~40℃、0~4%Na Cl浓度范围内对碱性品红、活性大红和茜素红染料(50 mg/L)均具有较好的降解脱色能力,并且在12 h内对碱性品红和活性大红的脱色率达到90%以上,对茜素红达到同样的脱色效果则需要32 h。CM-T1是一株具有广谱的染料脱色降解能力的优良菌株,能够作用于多种不同结构的三苯甲烷、偶氮、蒽醌类染料,脱色能力强,在印染工业废水生物处理中有很好的应用前景。     

脱色希瓦氏菌(Shewanella decolorationis)S12T的脱色特性

从印染废水活性污泥中分离到一株高效染料脱色菌,经鉴定该菌株为希瓦氏菌属的一个新种,命名为脱色希瓦氏菌(Shewanelladecolorationis)S12T。该菌株在偶氮染料浓度为50mg/L的培养基中培养4h后,染料去除率达到96%,对偶氮染料的最高脱色浓度达到2000mg/L。在浓度为500mg/L的偶氮染料平板上生长4d后,可观察到明显的脱色圈。全波长光谱扫描的结果表明希瓦氏菌S12T以生物降解的方式对偶氮染料进行脱色。希瓦氏菌S12T的脱色酶为组成型的胞内酶。     

脱水污泥中脱色偶氮染料功能菌

近年来,随着印染与染料工业的发展,染料的数量和品种不断增多,由染料废水造成的污染呈增加的趋势,开发环境友好、高效、快速、低成本的染料废水处理方法是当前研究的热点。国内外常用的偶氮染料废水处理的方法可以分为物理法、化学法和生物法。传统的物化法虽然效果好,但较高的成本以及严重的二次污染,限制了其在实际中的应用,生物法以廉价、高效与环境友好等优势而广为应用。目前利用微生物处理偶氮染料废水的应用和研究居于首位,许多研究者致力于高效脱色偶氮染料微生物的筛选、分离和驯化[1-2]。本刊2014年第12期刊登了解井坤、花莉等的文章《脱水污泥中脱色偶氮染料功能菌群的驯化分离》[3]。作者以脱水污泥作为脱色偶氮染料功能菌群的新来源,经驯化分离获得降解混合偶氮染料的高效降解菌株若干,菌株所制备干粉也可在无外源碳源的条件下完全脱色金橙I,研究表明脱水污泥是耐胁迫工程菌株的理想种质来源。近年来该研究团队利用研究所得菌株,对脱水污泥处理不同偶氮染料废水的微生物群落结构进行了基于分子生物学的分析,得到了偶氮染料结构和功能群落结构组成的信息,研究结果表明偶氮染料结构同降解菌群落组成有对应关系,不同偶氮染料驯化下的混合微生物更倾向于形成以优势种群为主的特定微生物群落结构,而群落多样性在偶氮染料的脱色作用中不是主要因素[4];基于脱污污泥中分离得到的偶氮染料脱色菌种构建的聚氨酯泡沫固定化微生物体系,能够快速、反复用于偶氮染料废水的脱色[5]。由于实际偶氮染料废水的成分十分复杂,针对不同的偶氮染料废水构建特定的高效脱色微生物群落结构在实际中的应用有待进一步探究;其次本研究在固定化微生物的脱色过程中,采用的是较小的反应器,对于反应器放大后的脱色效果也需要进一步的研究。进行了脱色偶氮染料废水的微生物燃料电池体系的搭建和运行,证明分离株能够有效进行胞外电子传递,在脱色偶氮染料的同时实现产能资源化,同时说明脱水污泥也可作为保外电子呼吸菌的种质来源[6-7];在MFC同步脱色产电性能的研究中,虽然MFC加速了偶氮染料的脱色,但是其产电水平整体偏低,达不到有效利用水平,所以如何进一步提升产电能力从而到达有效利用水平也是亟待解决的问题。     

脱色希瓦氏菌(Shewanella decolorationis)S12T的脱色特性*

从印染废水活性污泥中分离到一株高效染料脱色菌,经鉴定该菌株为希瓦氏菌属的一个新种,命名为脱色希瓦氏菌(Shewanelladecolorationis)S12^T。该菌株在偶氮染料浓度为50mg/L的培养基中培养4h后,染料去除率达到96%,对偶氮染料的最高脱色浓度达到2000mg/L。在浓度为500mg/L的偶氮染料平板上生长4d后,可观察到明显的脱色圈。全波长光谱扫描的结果表明希瓦氏菌S12^T以生物降解的方式对偶氮染料进行脱色。希瓦氏菌S12相似文献   

果糖共代谢强化功能菌群/菌株降解活性黑5效能差异及机制比较

【背景】偶氮染料及其降解产物对生物具有高毒性和“三致”效应,利用共代谢强化纯培养细菌菌株或共培养混合菌群降解偶氮染料去除效能是一种环境友好型方法,但针对共基质调控下菌群/菌株的效能差异机制比较研究有待深入。【目的】考察果糖作为共基质强化功能菌群DDMZ1和功能菌株DDMZ1-1(经鉴定属于Burkholderia sp.)降解脱色活性黑5(reactive black 5, RB5)的效能差异机制。【方法】优化功能菌群/菌株培养条件,对果糖共代谢强化功能菌群/菌株的脱色性能及偶氮还原酶活性进行测定,通过液相色谱-飞行时间串联质谱联用仪(LC-TOF-MS)及植物毒性实验对RB5降解产物进行分析鉴定及毒性评估,并考察比较功能菌群/菌株对不同结构染料的广谱脱色性能。【结果】功能菌群DDMZ1和功能菌株Burkholderia sp. DDMZ1-1在优化条件下(pH 5.5, 37℃)对RB5的去除效率分别为79%和73%,而且功能菌群对高盐环境具有更强的适应优势。果糖的添加能够显著提升功能菌群/菌株对不同初始浓度RB5的脱色性能,特别是针对200 mg/L RB5的去除效率相较于不添加果...     

脱水污泥中脱色偶氮染料功能菌群的驯化分离

【目的】获得降解混合偶氮染料的高效降解菌,应用于印染行业偶氮染料废水的生物处理和资源化。【方法】以某污水处理厂的脱水污泥作为分离源,经偶氮染料废水驯化后,分离筛选出9株偶氮染料脱色株(命名为T-1-T-9),通过形态观察、生理特征及基于16S rRNA基因序列的分子生物学鉴定,初步认定分离株分属于芽孢杆菌属(Bacillus)、微小杆菌属(Exiguobacterium)、寡单胞菌属(Stenotrophomonas)和副球菌属(Paracoccus)。【结果】所得分离株纯培养均可不同程度地脱色单一偶氮染料和混合偶氮染料,其中T-8对甲基橙和金橙I的脱色速率最大,40 h的脱色率分别为85.9%和86.2%,T-8菌株干粉也可在无外源碳源的条件下完全脱色金橙I。分离株混合培养脱色混合偶氮染料的效率明显高于纯培养,可达90.1%。【结论】脱水污泥作为脱色偶氮染料功能菌群的新来源具有良好的应用价值。     

酱醪嗜盐四联球菌的分类及特性研究

【目的】对酱油酱醪来源的嗜盐四联球菌进行分类,并比较菌株的生理特性。【方法】采用多位点序列分型和糖类代谢聚类分析相结合的方法对菌株进行分类,通过菌株对环境耐受性分析研究菌株的生理特性。【结果】酱醪来源的12株嗜盐四联球菌被分为两个类群,菌株所属类别与其分离的原生环境存在一定的关联性。嗜盐四联球菌C25、C33、C3、R55耐高盐及高糖能力均较强,菌株C1、R44和R23耐高盐能力较强。虽然嗜盐四联球菌普遍不耐酸,但是菌株C33和R44在酸性培养体系(pH 5.0)中仍能正常生长。较低的培养温度(15℃和25℃)对嗜盐四联球菌的生长有显著抑制。【结论】采用基因型与表型结合的方式成功将酱醪来源的嗜盐四联球菌归为2个类群,不同类群的菌株在耐高渗等生理特性上具有差异性。     

A novel moderately halophilic bacterium for decolorizing azo dye under high salt condition

Halomonas sp strain GTW was newly isolated from coastal sediments contaminated by chemical wastewater and was identified to be a member of the genus Halomonas by 16S rDNA sequence analysis and physical and biochemical tests. The optimal decolorization conditions were as follows: temperature 30°C, pH 6.5.0–8.5, NaCl 10–20% (w/v) and the optimal carbon source was yeast exact. The results of experiments demonstrated that the bacteria could decolorize different azo dyes under high salt concentration conditions, and the decolorization rate of five tested azo dyes could be above 90% in 24 h. The exploitation of the salt-tolerant bacteria in the bio-treatment system would be a great improvement of conventional biological treatment systems and the bio-treatment concept.     

Biodegradation of textile azo dye by <Emphasis Type="Italic">Shewanella decolorationis</Emphasis> S12 under microaerophilic conditions

The complete biodegradation of azo dye, Fast Acid Red GR, was observed under microaerophilic conditions by Shewanella decolorationis S12. Although the highest decolorizing rate was measured under anaerobic condition and the highest biomass was obtained under aerobic condition, a further biodegradation of decolorizing products can only be achieved under microaerophilic conditions. Under microaerophilic conditions, S. decolorationis S12 could use a range of carbon sources for azo dye decolorization, including lactate, formate, glucose and sucrose, with lactate being the optimal carbon source. Sulfonated aromatic amines were not detected during the biotransformation of Fast Acid Red GR, while H₂S formed. The decolorizing products, aniline, 1,4-diaminobenzene and 1-amino-2-naphthol, were followed by complete biodegradation through catechol and 4-aminobenzoic acid based on the analysis results of GC-MS and HPLC.     

Enhanced decolorization of sulfonated azo dye methyl orange by single and mixed bacterial strains AK1, AK2 and VKY1

Abstract

Methyl orange, a sulfonated azo dye having various industrial applications was decolorized by three bacteria Bacillus sp. strain AK1, Lysinibacillus sp. strain AK2 and Kerstersia sp. strain VKY1. The effect of various factors such as dye concentration, pH, temperature and NaCl concentration on decolorization was investigated. At 200?mg/L methyl orange concentration, the strains AK1, AK2 and VKY1 exhibited maximum decolorizing potential of 93, 95 and 96%, respectively, at temperature 35?°C and pH 7.0 within 18?h of incubation. These strains decolorized the dye over a wide range of pH (5–10), temperature (15–55?°C), and NaCl concentration (5–20?g/L). Further, these strains decolorize up to 800?mg/L concentrations of methyl orange within 24?h. The dye decolorization efficiency was further increased by using different consortia of these three strains which could decolorize the dye completely within 12?h of incubation. The cell-free extracts of the strains AK1, AK2 and VKY1 grown on methyl orange exhibited the azoreductase activity of 0.4794, 1.56 and 1.01?µM/min/mg protein, respectively. HPLC and FTIR analysis of the dye decolorized sample indicated the formation of 4-aminobenzenesulfonic acid and N,N-dimethyl-p-phenylenediamine as breakdown products of azo bond. The high decolorization potential of these bacterial strains individually and in consortia has potential application in remediation of dye effluent.     

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。     

染料脱色菌与芳胺降解菌的筛选及降解染料研究

从印染厂废水处理系统的曝气池中分离到17株对多种染料有较高脱色能力的细菌,其脱色率都在80%以上,但偶氮染料脱色后产生的中间产物多数为无色的芳香胺类化合物,大多数细菌不能将其进一步降解。为此,通过富集培养和梯度驯化又筛选到一株以对硝基苯胺为唯一碳、氮源的菌株J18,该菌株虽对染料脱色能力很弱,却能够降解芳香胺类化合物。将芳香胺降解菌J18与染料脱色菌H两菌株混合培养,在最适条件下,结果使染料的脱色率和芳胺降解率均到达90%和85%以上,从而达到了彻底降解染料的目的。     

Fe(III)-enhanced Azo Reduction by <Emphasis Type="Italic">Shewanella decolorationis</Emphasis> S12

Shewanella decolorationis S12 is capable of high rates of azo dye decolorization and dissimilatory Fe(III) reduction. Under anaerobic conditions, when Fe(III) and azo dye were copresent in S12 cultures, dissimilatory Fe(III) reduction and azo dye biodecolorization occurred simultaneously. Furthermore, the dye decolorization was enhanced by the presence of Fe(III). When 1 mM Fe(III) was added, the methyl red decolorizing efficiency was 72.1% after cultivation for 3 h, whereas the decolorizing efficiency was only 60.5% in Fe(III)-free medium. The decolorizing efficiencies increased as the concentration of Fe(III) was increased from 0 to 6 mM. Enzyme activities, which mediate the dye decolorization and Fe(III) reduction, were not affected by preadaption of cells to Fe(III) and azo dye nor by the addition of chloramphenicol. Both the Fe(III) reductase and the azo reductase were membrane associated. The respiratory electron transport chain inhibitors metyrapone, dicumarol, and stigmatellin showed significantly different effects on Fe(III) reduction than on azo dye decolorization.     

Decolorization and biosorption for Congo red by system rice hull- Schizophyllum sp. F17 under solid-state condition in a continuous flow packed-bed bioreactor

Synthetic dyes are important chemical pollutants from various industries. This work developed an efficient and relatively simple continuous decolorization system rice hull-Schizophyllum sp. F17 under solid-state condition in a packed-bed bioreactor, for decolorizing Congo red. In the decolorization system, two decolorization mechanisms exist, one is decolorization by Schizophyllum sp. F17, the other is biosorption by rice hull. The decolorization efficiency was greatly affected by dye concentration and hydraulic retention time (HRT), which were quantificationally analyzed and optimized through response surface methodology (RSM). A 2(2) full factorial central composite design (CCD) was performed, and three second order polynomial models were generated to describe the effects of dye concentration and HRT on total decolorization (R2=0.902), decolorization by Schizophyllum sp. F17 (R2=0.866) and biosorption by rice hull (R2=0.890). Response surface contour plots were constructed to show the individual and cumulative effects of dye concentration and HRT, and the optimum values. A maximum total decolorization 89.71% and maximum decolorization by Schizophyllum sp. F17 60.44% was achieved at dye concentration 142.63mg/L, HRT 41h, and dye concentration 110.7mg/L, HRT 29.4h, respectively. Meanwhile, the role of manganese peroxidase (MnP) in the decolorizaion process was investigated. This study proved the feasibility of continuous mode for decolorizing synthetic dyes by white-rot fungi in solid-state fermentation bioreactors.     

固定化乳白耙齿菌脱色茜素红的研究

利用海藻酸钙法对乳白耙齿菌进行固定化,检测固定化乳白耙齿菌（固定化菌）对几种染料的脱色能力。同时,考察pH值、染料浓度、金属离子、碳源种类、氮源种类、盐浓度对固定化菌脱色茜素红的影响。结果表明,固定化菌的优化条件为海藻酸钠3%、氯化钙5%、固定化时间6h、接菌量10g/100mL;固定化菌对6种染料均可脱色,其中对茜素红染料的脱色效果最为明显;固定化菌对茜素红的脱色率随染料浓度的增加而下降,当染料浓度高于250mg/L时,其脱色效果明显下降;固定化菌对茜素红脱色的适宜pH为7,适宜碳源为可溶性淀粉、适宜氮源为硝酸铵。另外,固定化菌对茜素红的脱色率随盐浓度的升高,呈下降趋势,当盐浓度高于3%时,脱色率下降明显;固定化菌于生理盐水中保存10d后,脱色率维持在较高水平,达94.20%;固定化菌重复利用5次后,脱色率仍高达88.70%。