一株油脂降解菌的筛选鉴定及降解效果分析

为了筛选分离得到一株具有油脂降解能力的菌株,同时探究菌株的特性和降解能力。以屠宰场污染土作为菌源,通过梯度驯化法最终筛选分离得到能够将橄榄油作为单一碳源生长的降解菌。随后通过形态特征观察、Biolog生理生化测试以及16S rRNA基因序列比对分析鉴定,实验菌株为革兰氏阴性菌,属于无色杆菌属（Achromobacter sp.）,在构建的系统发育树上与Achromobacter pulmonis聚为一支。综合运用紫外分光光度法和高效液相色谱法检测,测得实验菌株培养4~5 d时对橄榄油的降解率可以达到90%,同时测得菌株降解油脂的最适pH和最适温度分别为7.5和35 ℃,该菌株在盐浓度低于40 g·L-1环境中降解率较高。此外实验结果表明,实验菌株对各类型油脂均具有较高的降解效率,具有广泛的应用前景。     

高效氯氰菊酯降解菌JCN13的分离鉴定及降解特性研究

从生产高效氯氰菊酯的农药厂污水曝气池中,分离到一株能降解高效氯氰菊酯并以之为唯一碳源进行生长的细菌JCN13.经生理生化试验和16S rDNA分析,鉴定菌株JCN13为沙雷菌属(Serratia sp.).气相色谱检测,菌株JCN13在4 d内对100 mg/L高效氯氰菊酯的降解率为89%,8 d内基本降解完全.经气质联用检测,发现高效氯氰菊酯在被菌株JCN13降解的过程中存在异构体的转化.     

台湾泥鳅源维氏气单胞菌Zy01株的分离鉴定及药敏特性研究

【目的】从患病台湾泥鳅体内分离到一株优势菌Zy01,通过鉴定并筛选敏感药物,为台湾泥鳅维氏气单胞菌病的防控提供参考。【方法】从患病台湾泥鳅肌肉溃烂处分离细菌,经理化特性及16S rRNA基因序列分析对其进行鉴定,通过人工感染试验确定病原,并利用K-B法进行药敏分析。【结果】菌株Zy01为2015年11月引发台湾泥鳅疾病的病原菌,其对台湾泥鳅的LC50为2.0×10~6 CFU/m L。菌株Zy01理化特性与维氏气单胞菌(Aeromonas veronii)基本一致,16S rRNA基因序列与维氏气单胞菌相似性为99%,综合判断该病原菌为维氏气单胞菌。菌株Zy01对环丙沙星、头孢拉定、诺氟沙星、阿奇霉素及庆大霉素等10种抗生素高度敏感;对苯唑西林、青霉素、阿莫西林等9种抗生素不敏感。【结论】分离菌株Zy01对台湾泥鳅有致病性,养殖时可选用庆大霉素及新霉素等药物进行防控。     

降解2,6-二叔丁基苯酚菌种的驯化与鉴定

从腈纶废水处理构筑物中分离筛选到1株高效降解2,6-二叔丁基苯酚的菌株M-Z-8,对其进行了驯化试验以及生理生化、分子生物学鉴定。结果表明,经过驯化后的M-Z-8在100．0mg／L的初始浓度下其降解率在12d可达到51．6％,比未经驯化菌种对底物的降解率要高出12％。扫描电镜观察到菌株形态为杆状,极生鞭毛。将M-Z-8的16SrDNA序列进行核苷酸同源性比较,与气单胞菌种属的16SrDNA核苷酸序列同源性均在97％以上。经生理生化以及分子生物学鉴定M-Z-8为气单胞菌。     

原绿球藻固定化培养去除NH_4~+-N的效果

为了探究固定化微藻去除污水中NH4+-N的效果,以原绿球藻(Prochlorococcus)为藻种,采用褐藻胶包埋技术,进行了不同藻球密度(0、100×104、300×104、500×104、700×104、900×104cells·ball-1)、不同藻球用量(固定化藻球与人工污水的体积比V水/V藻球为4∶1、3∶1、2∶1、1∶1)及藻球加固工艺(Ca Cl2加固)等对比试验。结果表明:固定化藻比悬浮藻生长缓慢,去除NH4+-N的速率小于悬浮藻;固定化藻球藻细胞密度越高,去除NH4+-N的效果越好,但考虑单位藻细胞去除率,包埋密度以700×104cells·ball-1为宜;经N饥饿处理的藻细胞去除NH4+-N效果显著优于未饥饿组;固定化藻球用量大,去除NH4+-N越快,V水/V藻球为1∶1培养3 d后去除率可达100%;固定化藻球定期加固,有利于延长其使用寿命,增加对NH4+-N的吸收量。     

土壤霉菌菌丝球的筛选、鉴定及固定化菌丝球的应用

从土壤中分离纯化真菌并鉴定为烟曲霉L-3。以菌株L-3作为固定化载体,将地衣芽孢杆菌固定在真菌上组成固定化体系。研究了混菌菌丝球,菌丝饼,发酵混合液,粗漆酶液对刚果红染料废水的降解情况并对染料废水进行毒性试验。结果表明,菌丝球对染料废水的降解效果最显著,降解率高达99.96%,菌丝饼仅用20 s降解率为91%,发酵混合液与粗漆酶液的处理效果并不显著。该体系对染料废水的去毒率较明显,尤其是菌丝球的去毒率可达到78%。可见,固定化体系对染料废水不但有较高的降解能力,也有较高的去毒率。     

一株气单胞菌属高酶活角蛋白酶生产菌的分离与鉴定

并非所有气单胞菌属(Aeromonas)细菌都是致病菌, 近年来气单胞菌功能利用方面的研究取得了一些重要进展。用微生物降解法对废弃羽毛加以有效利用, 既可变废为宝又符合低碳环保的要求, 更多分泌高酶活角蛋白酶的新菌种资源的筛选与功能鉴定, 将有助于微生物降解法中降解不彻底和速度慢等难题的解决。以半腐烂羽毛为材料, 先后通过羽毛粉和酪蛋白选择培养基的反复初筛和复筛、羽毛发酵液酶活测定等筛选出相对酶活最高的菌株, 并按常规方法进行分类学鉴定和生长特性分析。经初筛和复筛得到的19 个菌株中, FD41 的羽毛发酵液相对酶活最高, 达3.864 U/OD₆₀₀。根据FD41 菌株的16S rDNA 序列比对、形态特征、革兰氏染色和糖发酵试验等结果, FD41 鉴定为气单胞菌属细菌, 这是首次报道产高酶活角蛋白酶的气单胞菌菌株。研究发现接种量和菌株的不同都是影响培养液中菌体细胞增殖特性的重要因素, 并且发酵液酶活受菌体繁殖量的影响很大, 故提出在相同培养条件下按酶活大小筛选菌种时, 应使用均一化的菌种接种量并以相对酶活为比较指标。     

Burkholderia cepacia X4降解油脂特性研究

从长期受油污染的土壤中分离筛选得到的Burkholderia cepaciaX4菌株能高效降解油脂。该菌株降解油脂的最适温度和pH分别为30℃和7.0,菌株降解油脂时适宜的氮源为硫酸铵,适宜碳氮比为4∶1。共基质碳源的添加有利于生物量的迅速增加和油脂降解率的提高,添加适量的葡萄糖能使油脂降解率提高8%~10%。50mg/L Ca2 对菌株生长和油脂降解更有利。在橄榄油浓度高达20g/L条件下最大油脂降解率仍可达83%。在油脂浓度≤2500mg/L时,该菌对油脂的降解符合抑制动力学Monod方程。     

桦褶孔菌漆酶固定化及其对染料的降解

采用壳聚糖交联法和海藻酸钠-壳聚糖包埋交联法固定化桦褶孔菌产生的漆酶,探讨最佳固定化条件,固定化漆酶的温度,pH稳定性及操作稳定性,并以两种固定化酶分别对4种染料进行了降解.结果表明:(1)壳聚糖交联法固定化漆酶的最佳条件为:壳聚糖2.5%,戊二醛7%,交联时间2h,固定化时间5h,给酶量1g壳聚糖小球:1mL酶液(1U/mL),固定化效率56%;(2)海藻酸钠-壳聚糖包埋交联法固定化漆酶的最佳条件为:海藻酸钠浓度4%,壳聚糖浓度0.7%,氯化钙浓度5%,戊二醛浓度0.6%,给酶量4mL 4%海藻酸钠:1mL酶液(1U/mL),固定化效率高达86%;(3)固定化的漆酶相比游离漆酶有更好的温度和pH稳定性;(4)比较两种固定化漆酶,海藻酸钠-壳聚糖包埋交联法固定化酶的温度及酸度稳定性要优于壳聚糖固定化酶,但可重复操作性要弱于后者,两者重复使用8次后的剩余酶活比率分别为71%及64%;(5)两种固定化酶对所选的4种不同结构的合成染料均有较好的降解效果,其中壳聚糖固定化酶对茜素红的降解效果及重复使用性极佳,重复降解40mg/L的茜素红10次,降解率仍保持在100%.     

一株微囊藻毒素降解辅助菌的分离和鉴定

以从太湖蓝藻中提取的微囊藻毒素作为微囊藻毒素降解菌的筛选物质, 通过稀释平板涂布法从腐烂的蓝藻中富集分离到一菌株, 经形态特征、生理生化特征和16S rDNA 序列分析将该菌株(GenBank 序列登录号为GQ143751)鉴定为藤黄微球菌(Micrococcus luteus); 微囊藻毒素降解实验结果表明该菌株几乎不能降解微囊藻毒素, 但可以明显促进一株微囊藻毒素降解菌微嗜酸寡养单胞菌(Stenotrophomonas acidaminiphila)对微囊藻毒素的降解能力, 将筛选菌株与微嗜酸寡养单胞菌混合培养, 混合菌对微囊藻毒素的降解能力比微嗜酸寡养单胞菌单独培养时提高66.7%。     

Diesel oil removal by immobilized Pseudoxanthomonas sp. RN402

Pseudoxanthomonas sp. RN402 was capable of degrading diesel, crude oil, n-tetradecane and n-hexadecane. The RN402 cells were immobilized on the surface of high-density polyethylene plastic pellets at a maximum cell density of 10⁸ most probable number (MPN) g^?1 of plastic pellets. The immobilized cells not only showed a higher efficacy of diesel oil removal than free cells but could also degrade higher concentrations of diesel oil. The rate of diesel oil removal by immobilized RN402 cells in liquid culture was 1,050 mg l^?1 day^?1. Moreover, the immobilized cells could maintain high efficacy and viability throughout 70 cycles of bioremedial treatment of diesel-contaminated water. The stability of diesel oil degradation in the immobilized cells resulted from the ability of living RN402 cells to attach to material surfaces by biofilm formation, as was shown by CLSM imaging. These characteristics of the immobilized RN402 cells, including high degradative efficacy, stability and flotation, make them suitable for the purpose of continuous wastewater bioremediation.     

Characterization of the nitrobenzene-degrading strain Pseudomonas sp. a3 and use of its immobilized cells in the treatment of mixed aromatics wastewater

A bacterial strain Pseudomonas sp. a3 capable of degrading nitrobenzene, phenol, aniline, and other aromatics was isolated and characterized. When nitrobenzene was degraded, the release of NH(4) (+) was detected, but not of NO(2) (-). This result implied that nitrobenzene might have a partial reductive metabolic pathway in strain a3. However, aniline appeared as one of the metabolites during the aerobic degradation of nitrobenzene. Moreover, the appearance of 2-aminophenol during aniline degradation by strain a3 indicated that novel initial reactions existed during the degradation of nitrobenzene and aniline by strain a3. Strain a3 was immobilized in the mixed carrier of polyvinyl alcohol and sodium alginate to improve its degrading efficiency. The optimal concentrations of polyvinyl alcohol and sodium alginate in the mixed carrier were 9 and 3 %, respectively. The immobilized cells had stable degradation activity and good mechanical properties in the recycling tests. The immobilized cells also exhibited higher tolerances in acidic (pH 4-5) and highly saline (10 % NaCl) environments than those of free cells. The biodegradation of nitrobenzene mixed with aniline and phenol using immobilized cells of Pseudomonas sp. a3 was also greatly improved compared with those of free cells. The immobilized cells could completely degrade 300 mg L(-1) nitrobenzene within 10 h with 150 mg L(-1) aniline and 150 mg L(-1) phenol. This result revealed that the immobilized cells of Pseudomonas sp. a3 could be a potential candidate for treating nitrobenzene wastewater mixed with other aromatics.     

Degradation of predigested distillery effluent by isolated bacterial strains

Batch studies were conducted on degradation of anaerobically digested distillery wastewater by three bacterial strains, viz. Xanthomonas fragariae, Bacillus megaterium and Bacillus cereus in free and immobilized form, isolated from the activated sludge of a distillery wastewater treatment plant. The removal of COD and colour with all the three strains increased with time up to 48 hr and only marginal increase in COD and colour removal efficiency was observed beyond this period up to 72 hr. After this period removal efficiency remained fairly constant up to 120 hr. The maximum COD and colour removal efficiency varied from 66 to 81% and 65 to 75%, respectively for both free and immobilized cells of all the three strains. The strain Bacillus cereus showed the maximum efficiency of COD (81%) and colour (75%) removal out of the three strains. An interrelationship between the percent COD and colour removal was carried out by correlation and regression analysis and was justified by high values of coefficient of correlation (r = 0.99) for all the cases. The first order removal rate kinetics was also applied and rate constants were evaluated for COD and colour removal efficiencies.     

竹炭固定化施氏假单胞菌Pseudomonas stutzeri ZH-1降解苯酚的研究

通过竹炭固定化以加强施氏假单胞菌Pseudomonas stutzeri ZH-1对苯酚的降解能力。采用正交试验优化竹炭对菌株ZH-1固定化条件,冷场发射扫描电镜（SEM）观察固定化后的菌株在竹炭上的附着情况,对比固定化菌和游离菌的降解性能并对固定化菌做重复利用性能测试。结果显示,竹炭固定化P. stutzeri ZH-1的最适条件为竹炭1 g,接种量5%(体积分数),吸附时间24 h;SEM显示菌附着在竹炭表面和内部空隙中;竹炭固定化后菌株ZH-1对苯酚的降解率显著增加（P<0.05）,处理48 h时降解率增加15%;竹炭固定化菌ZH-1经10轮重复利用后仍有很高的苯酚降解性能,48 h时降解率增加173%（P<0.05）。竹炭固定化菌ZH-1在去除含苯酚类有机废水中具有较好的应用前景。     

Microbiological Activities of Coenzyme Forms of Vitamin B12

A novel quinoline-degrading strain, named K4, was isolated from activated sludge of a coking wastewater treatment plant and identified as Brevundimonas sp. on the basis of its 16s rDNA gene sequence analysis. Its optimum temperature and pH for quinoline degradation were 30 °C and pH 9.0, respectively, and during the biodegradation process, at 100 mg/L initial quinoline concentration, an inoculation amount of 8% (OD600 of 0.23) was the optimal strain concentration. In addition, the kinetics of free K4 strains for quinoline degradation showed that it followed a zero-order equation. Furthermore, compared with free K4 strains, immobilized K4 strains’ potential for quinoline degradation was investigated by adding both of them into SBR reactors for actual coking wastewater treatment on operation over 15 days. The results showed that bioaugmentation by both free and immobilized K4 strains enhanced quinoline removal efficiency, and especially, the latter could reach its stable removal after a shorter accommodation period, with 94.8% of mean quinoline removal efficiency.     

Phenol degradation performance by isolated Bacillus cereus immobilized in alginate

Phenol degradation by Bacillus cereus AKG1 MTCC9817 and AKG2 MTCC 9818 was investigated and degradation kinetics are reported for the free and Ca-alginate gel-immobilized systems. The optimal pH for maximum phenol degradation by immobilized AKG1 and AKG2 was found to be 6.7 and 6.9, respectively, while 3% alginate was optimum for both the strains. The degradation of phenol by free as well as immobilized cells was comparable at lower concentrations of phenol (100–1000 mg l⁻¹). However, the degradation efficiency of the immobilized strains was higher than that of the free strains at higher phenol concentrations (1500–2000 mg l⁻¹), indicating the improved tolerance of the immobilized cells toward phenol toxicity. More than 50% of 2000 mg l⁻¹ phenol was degraded by immobilized AKG1 and AKG2 within 26 and 36 days, respectively. Degradation kinetics of phenol by free and immobilized cells are well represented by the Haldane and Yano model.     

Enhanced biodegradation of phenol by magnetically immobilized <Emphasis Type="Italic">Trichosporon cutaneum</Emphasis>

Aromatic compounds are abundant in aqueous environments due to natural resources or different manufacturer’s wastewaters. In this study, phenol degradation by the yeast, Trichosporon cutaneum ADH8 was compared in three forms namely: free cells, nonmagnetic immobilized cells (non-MICs), and magnetically immobilized cells (MICs). In addition, three different common immobilization supports (alginate, agar, and polyurethane foams) were used for cell stabilization in both non-MICs and MICs and the efficiency of phenol degradation using free yeast cells, non-MICs, and MICs for ten consecutive cycles were studied. In this study, MICs on alginate beads by 12 g/l Fe₂O₃ magnetic nanoparticles had the best efficiency in phenol degradation (82.49%) and this amount in the seventh cycle of degradation increased to 95.65% which was the highest degradation level. Then, the effect of magnetic and nonmagnetic immobilization on increasing the stability of the cells to alkaline, acidic, and saline conditions was investigated. Based on the results, MICs and non-MICs retained their capability of phenol degradation in high salinity (15 g/l) and acidity (pH 5) conditions which indicating the high stability of immobilized cells to those conditions. These results support the effectiveness of magnetic immobilized biocatalysts and propose a promising method for improving the performance of biocatalysts and its reuse ability in the degradation of phenol and other toxic compounds. Moreover, increasing the resistance of biocatalysts to extreme conditions significantly reduces costs of the bioremediation process.     

Influence of phenol on the biodegradation of pyridine by freely suspended and immobilized Pseudomonas putida MK1

AIMS: To study the effect of co-contaminants (phenol) on the biodegradation of pyridine by freely suspended and calcium alginate immobilized bacteria. METHODS AND RESULTS: Varying concentrations of phenol were added to free and calcium alginate immobilized Pseudomonas putida MK1 (KCTC 12283) to examine the effect of this pollutant on pyridine degradation. When the concentration of phenol reached 0.38 g l(-1), pyridine degradation by freely suspended bacteria was inhibited. The increased inhibition with the higher phenol levels was apparent in increased lag times. Pyridine degradation was essentially completely inhibited at 0.5 g l(-1) phenol. However, immobilized cells showed tolerance against 0.5 g l(-1) phenol and pyridine degradation by immobilized cell could be achieved. CONCLUSIONS: This works shows that calcium alginate immobilization of microbial cells can effectively increase the tolerance of P. putida MK1 to phenol and results in increased degradation of pyridine. SIGNIFICANCE AND IMPACT OF THE STUDY: Treatment of wastewater stream can be negatively affected by the presence of co-pollutants. This work demonstrates the potential of calcium alginate immobilization of microbes to protect cells against compound toxicity resulting in an increase in pollutant degradation.     

Alleviation of metal and BTEX inhibition on BTEX degradation using PVA-immobilized degrader: kinetic model of BTEX degradation

Alleviation of metal inhibition on BTEX degradation using PVA-immobilized degrader (Mycobacterium sp. CHXY119) was investigated. When BTEX of 29 mg L^?1 [B:T:E:X = 1:1:1:1 (mg)] was used, more than 99 % of BTEX was simultaneously degraded by the free cells within 170 h. In contrast, BTEX of 114–172 mg L^?1 seriously inhibited degradation. High concentrations of metals (Mn²⁺: 15, Ni²⁺: 10, and Zn²⁺: 10 mg L^?1) also strongly inhibited BTEX degradation by the free cells at BTEX of 29 mg L^?1. Immobilization of degraders alleviated the inhibition of BTEX and heavy metals at high concentrations. A modified non-competitive inhibition model well described the BTEX degradation by the free and immobilized cells in the absence and presence of metal ions (R ² = 0.92–0.99). The above results provide valuable information on treatment of metal-BTEX co-contaminated wastewater by the immobilized degrader.     

A study of a bacterial immobilization substratum for use in the bioremediation of crude oil in asaltwater system

An immobilization matrix, Drizit, was examined for use in the bioremediation of oil in asaltwater system. The support was examined by scanning electron microscopy, cell-loadingcapacity, absorption of Ekofisk crude oil, the effect on cell recoverability of dryingDrizit-immobilized cells at room temperature, 55°C or freeze drying and storage for up to 3months, and the capability of immobilized Pseudomonas fluorescens to enhance biodegradation ofpetrol (Slovene diesel) in a saltwater system. Results showed that Drizit is an ideal immobilizationsubstratum for use in bioremediation, and the substratum was found to have a good cell-loadingcapacity (3·75 mg protein g⁻¹ substratum) and a high absorbency of oil(7·49 g Ekofisk g⁻¹ substratum). After drying the immobilized cells at roomtemperature, 55°C or freeze drying and subsequent storage, cells were not recoverable after 2weeks, 1 week or 2 months, respectively, and a significant decrease was seen in the number ofcells recovered after drying and 1 week's storage in all cases. Enhanced biodegradation of C₁₃–C₁₈ pristane and phytane, in petrol (Slovene diesel) occurred with theimmobilization of Ps. fluorescens to Drizit. An average degradation of 73·8%occurred in the immobilized system in comparison with the free system which resulted in anaverage degradation of 39·8%. When the two systems were supplemented with nitrates andphosphates, degradation in the free supplemented system increased to an average of 72·4%.However, no significant difference in biodegradation was found between the immobilized systemand the immobilized system supplemented with nitrates and phosphates which achieved anaverage degradation of 74.15%.