锰过氧化物酶的固态发酵及其对染料的脱色作用

采用稻壳作为基质,利用裂褶菌F17固态发酵产锰过氧化物酶(MnP),通过正交实验对发酵条件进行优化,并对5种不同结构类型的染料进行脱色.结果显示,含水率、温度、Mn2 、Cu2 对裂褶菌F17产MnP有显著影响;MnP发酵的最优化条件为稻壳27g、黄豆粉3g、MnSO40.4mg·g-1、含水率150%、接种量50%、培养温度22℃,pH不调节,优化后酶活达到16.39 U·g-1,比优化前的酶活9.20 U·g-1提高了78.2%.优化后的发酵体系对染料刚果红、茜素红、Poly R-478、中性红和结晶紫的24h脱色率分别达到92.6%、90.3%、93.1%、87.3%和95.6%.     

硝基芳香烃降解菌株的分离、鉴定和应用

从被二硝基甲苯(DNT)和三硝基甲苯(TNT)污染的土壤中分离到5个高效降解硝基芳香烃类化合物的菌株TD1、TD2、TD3、TD4和TD5。16S rDNA序列分析表明,TD1、TD2、TD3和TD4属于节杆菌属(Arthrobacter),TD5属于不动杆菌属(Acinetobacter)。菌株复配试验表明,TD1、TD2、TD3、TD4和TD5的体积比例为2:2:2:1:1时对含有DNT和TNT的炸药废水的CODC r去除率最好。最佳复配的菌液投加到装有合适填料载体的生物反应器中用于处理炸药废水,运行47d后出水CODC r不超过200 mg/L,硝基苯类化合物的浓度在2 mg/L以下。     

利用流式细胞术研究鞘氨醇单胞菌GY2B降解菲过程中细菌表面特性的变化

微生物与污染物接触是生物降解的第一步,为进一步了解降解过程中有机污染物对降解菌的影响,通过对不同条件下鞘氨醇单胞菌GY2B(Sphingomonas sp.GY2B)降解菲的研究,并结合Propidium Iodide(PI)染料和流式细胞仪分析不同底物及污染物浓度对GY2B菌体细胞表面性质的影响.结果表明,随着菲的降解,PI染色的GY2B菌株细胞增多,说明细菌膜结构受到一定的破坏,通透性不断增强.污染物浓度越高,降解菌的膜完整性的破坏越为严重.60 h时,300 mg·L-1浓度条件下,染色细胞/未被染色细胞的比值可达12.44,而在100 mg·L-1和1.2 mg·L-1浓度条件下,比值分别为1.95和1.11.同时降解过程中细菌细胞的傅里叶红外光谱检测,死亡、受损和完整细胞的区分以及Zeta电位分析也进一步验证了细菌细胞表面性质的改变.利用流式细胞术与染料结合分析降解过程中细菌细胞膜完整性的变化,从单细胞水平上了解细菌降解污染物过程中其细胞表面性质的改变,有助于更好地研究GY2B对菲的降解机制.     

假单胞菌P12对菲的降解

从武汉石油化工厂的活性污泥中,分离到一株可以以菲为唯一碳源和能源的假单胞菌P_(12)该菌经靛蓝产生法测定有双加氧酶,在菲无机盐培养基中生长时,有3-菲酚物质积累,经检测有一条质粒带。用丝裂霉素C消除质粒后的菌落,失去了降解菲的能力,说明P_(12)对菲的降解功能是由质粒控制的。     

假单胞菌磷代谢特性的研究

本文考察了处理效果良好的循序间歇式废水生物脱氮除磷试验装置内活性污泥优势菌——假单胞菌(Pseudomonas sp.)的磷代谢特性。试验结果表明,在好氧条件下,以乙酸盐为基质培养时,向培养基内滴加H_2SO_4可导致假单胞菌产生磷释放现象,滴加NaOH或NaHCO_3时,则发生过量摄磷现象,且加NaOH较加NaHCO_3所引起的磷摄取量大。另外,当以乙酸盐为基质时,假单胞菌于好氧培养过程中能明显除磷,其效果与厌氧-好氧培养过程相近。     

己烯雌酚降解菌株沙雷氏菌的分离鉴定及其降解特性

利用具有降解己烯雌酚(diethylstilbestrol,DES)特性的功能微生物来降解DES、有望实现环境中DES的有效去除,然而迄今关于降解DES的功能菌株及其降解特性的报道很少.本研究通过选择性富集培养,从某污水处理站活性污泥中分离获得1株具有DES降解特性的细菌(菌株S).经形态观察、生理生化试验及16S rDNA序列同源性分析将菌株S鉴定为沙雷氏菌属(Serratia sp.)细菌.菌株S好氧生长,30℃、150 r·min-1摇床培养7 d后,对无机盐培养基中DES(50 mg·L-1)的降解率达68.3%.通过摇瓶实验,优化了菌株S生长和降解DES的最适环境条件:温度30℃,底物浓度40～60 mg·L-1,pH 7.0,接种量5%,盐添加量0 g·L-1,装液量10 mL(100 mL三角瓶).     

Isolation, identification and characterization of an algicidal bacterium from Lake Taihu and preliminary studies on its algicidal compounds

In an effort to identify a bio-agent capable of controlling cyanobacterial blooms, we isolated a bacterial strain, A27, which exhibited strong algicidal activity against the dominant bloom-forming species of Microcystis aeruginosa in Lake Taihu. Based on 16S rRNA gene sequence analysis, this strain belongs to the genus Exiguobacterium. This is the first report of an algicidal bacterial strain belonging to the genus Exiguobacterium. Strain A27 exhibited algicidal activity against a broad range of cyanobacteria, but elicited little or no algicidal activity against the two green algal strains tested. The algicidal activity of strain A27 was shown to be dependent on the density of the bacteria and to have a threshold density of 1.5× 10⁶ CFU/mL. Our data also showed that the algicidal activity of strain A27 depended on different growth stages of Microcystis aeruginosa (exponential ≈ lag phase > early stationary) rather than that of the bacterium itself. Our results also suggested the algicidal activity of strain A27 occurred via the production of extracellular algicidal compounds. Investigation of the algicidal compounds revealed that there were at least two different algicidal compounds produced by strain A27. These results indicated that strain A27 has great potential for use in the control of outbreaks of cyanobacterial blooms in Lake Taihu.     

海洋菌株y3的分离鉴定及其异养硝化-好氧反硝化特性

从胶州湾海底沉积物中筛选出1株高效的海洋异养硝化-好氧反硝化细菌y3,经形态学观察、生理生化实验和16S rRNA基因序列分析,确定该菌株为假单胞菌属(Pseudomonas sp.).对其在实际含氮海水中的脱氮实验结果表明,菌株y3的最佳碳源为柠檬酸三钠,最适p H为7.0,最适C/N为13;菌株均能以NH4Cl、Na NO_2和KNO_3为唯一氮源进行反应,20 h后其去除率分别为98.69%、78.38%和72.95%,在硝化过程中几乎没有亚硝酸盐和硝酸盐的积累.以不同比例混合两种氮源反应20 h,当NO~-_3-N∶NO~-_2-N分别为2∶1、1∶1和1∶2时,脱氮率分别为99.56%、99.75%和99.41%;当NH~+_4-N∶NO~-_3-N分别为2∶1、1∶1、1∶2时,脱氮率均为100%;当NH~+_4-N∶NO~-_2-N分别为2∶1、1∶1、1∶2时,脱氮率分别为90.43%、92.79%和99.96%,多高于单一氮源的情况.该菌株具有较好的高盐废水脱氮处理效能.     

Cu2+、Cd2+、Zn2+对两种单胞藻的毒害作用

分别用不同浓度 (c =0 .0 1～ 2 .34mmol/L)的Cu2 + 、Cd2 + 、Zn2 + 处理亚心型大扁藻 (Plztymonassp.)和小球藻(Chlorelavulagris) ,观察了重金属离子对其生长、呼吸及其被富集的情况 .结果表明 :① 3种离子的毒性强度的顺序为Cu2 + >Cd2 + >Zn2 + ;亚心型大扁藻的耐受力大于小球藻 ;②Cu2 + 对生长的抑制最强 ,两种藻的c(EC50 ,72h)分别为 0 .2 11mmol/L和 0 .2 89mmol/L ;Cd2 + 对生长的抑制稍弱 ,两种藻的c(EC50 ,72h)分别为 0 .4 38mmol/L和 0 .2 4 1mmol/L ;Zn2 + 对生长的抑制最弱 ,其c(EC50 ,72h)分别为 0 .75 4mmol/L和 0 .30 8mmol/L ;③在c(EC50 )毒害浓度下 ,两种单胞藻均提前进入生长静止期 ,缩短了种群生长周期 ;呼吸作用先增强后降低 ;④在c(EC50 )毒害浓度下 ,两种藻对Cu2 + 、Zn2 + 的富集量为 4 5 82～ 4 12 83.7mgkg-1,对Cd2 + 的富集量 5 0 0～ 2 72 3.6mgkg-1.图 2表 3参 8     

Role of Acinetobacter sp. in arsenite As(III) oxidation and reducing its mobility in soil

Microbial arsenite oxidation was observed by Acinetobacter sp. XS21, this strain oxidised arsenite As(III) up to 80?mM within 48–72?h of incubation. The present strain XS21 oxidised As(III) at a very high concentration in a shorter interval of time than any of the previous reported microbes. Further, XS21 was applied to the soil to observe its ability in reducing the mobility of As(III), and we found that Acinetobacter sp. XS21 efficiently removed arsenite from soluble-exchangeable fraction and removed 70% of the arsenite as compared to control. This feature makes it a potential candidate for bioremediation. Arsenic-resistant bacteria with strong As(III)-oxidising ability may have potential to improve bioremediation of As(III)-contaminated sites. To understand their basis of resistance and transformation we found the As(III) oxidase gene using degenerate primer and amplified ～550?bp of aioA gene. Amplified aioA gene sequence exhibiting 52% identity in terms of gene and deduced protein sequence to Uncultured bacterium, and Achromobacter sp. arsenite oxidase of larger subunit. Arsenite oxidase, an enzyme, was also observed in this isolate, which may provide a resistance and transforming ability. This bacterium was identified as Acinetobacter sp., by sequencing 16s rRNA gene sequence analysis.