异养硝化-好氧反硝化菌Acinetobacter johnsonii sp. N26的脱氮性能及代谢途径

【背景】水体中含氮物质的大量累积会造成水体富营养化、水生生物死亡等问题,严重威胁水生态环境,制约我国环境保护的持续发展。【目的】为去除生活污水中的含氮污染物,从羊粪堆肥中筛选出了一株具有异养硝化-好氧反硝化功能的细菌——约氏不动杆菌Acinetobacter johnsonii sp.N26,研究其脱氮性能和代谢途径。【方法】测定菌株N26在氨氮和硝态氮中的生长和脱氮曲线,通过单因素试验对其脱氮性能进行优化,通过氮平衡分析和功能基因鉴定研究其脱氮代谢途径。【结果】生长和脱氮曲线表明,菌株N26对初始浓度均为50 mg/L的氨氮和硝态氮的去除速度快、效率高,其中9 h内对氨氮的去除效率为95.5%,最大去除速率为5.330 mg/(L·h);15 h内对硝态氮的去除效率为93.6%,最大去除速率为3.147 mg/(L·h),且最终仅有少量硝酸盐、亚硝酸盐积累。脱氮性能优化结果表明,该菌株的最适氮源为氯化铵,最适碳源为丁二酸钠,最适温度为30℃,最适接种量为15%,最适p H值为8.0-9.0,最适碳氮比为15,最适转速为120 r/min,最适氮负荷≤300 mg/L (氨氮)。氮平衡...     

Pseudomonas alcaliphila AD-28的脱氮性能及其关键酶活性

【背景】异养硝化-好氧反硝化菌由于能够同时实现硝化反硝化作用而备受关注,但由于菌的种类不同,其脱氮途径不尽相同,研究菌株脱氮关键酶的种类及其活性可以推测菌株的脱氮途径,从而为菌株在生产上的应用提供技术支撑。【目的】研究Pseudomonas alcaliphila AD-28的脱氮性能及其关键酶的活性,为菌株脱氮分子机理研究奠定基础。【方法】以柠檬酸钠为碳源,以硫酸铵、亚硝酸钠、硝酸钾为氮源,研究菌株AD-28的脱氮性能并检测其关键酶氨单加氧酶(AMO)、羟胺氧化还原酶(HAO)、亚硝酸盐还原酶(NIR)、硝酸盐还原酶(NAR)的酶活性。【结果】菌株AD-28培养24h的菌密度(OD600)可达1.971,对初始浓度为18.85mg/L的氨氮、26.13mg/L的硝酸盐氮、19.47mg/L的亚硝酸盐氮、66.11 mg/L的总氮去除率均达到96%以上;关键酶AMO、HAO、NIR和NAR的比活力分别为0.028、0.003、0.011、0.027 U/mg。【结论】Pseudomonas alcaliphila AD-28能同时进行异养硝化-好养反硝化作用,该菌在AMO作用下将NH4+-N氧化为羟胺,然后由HAO氧化为NO2--N,NO2--N和NO3--N在NIR、NAR等酶的催化作用下脱氮。     

一株海水异养硝化-好氧反硝化菌系统发育及脱氮特性

【目的】确定一株分离自海水的异养硝化-好氧反硝化菌的系统发育地位并探索其脱氮特性和机理,以期为解释异养硝化-好氧反硝化机理以及改进海水养殖及废水的生物脱氮工艺提供理论依据。【方法】通过形态观察、生理生化实验和16S rRNA基因序列分析,鉴定该菌株;通过测定菌株在不同无机氮源降解测试液中的生长和脱氮效率,分析其异养硝化和好氧反硝化性能。【结果】经鉴定该菌株属于盐单胞菌属(Halomonas);最适生长条件为盐度3%、pH 8.5、温度28℃、碳氮比10:1,在盐度为15%的培养液中仍能生长;可以同时去除氨氮、亚硝酸氮和硝酸氮,24 h时对NH4+-N、NO2--N、和NO3--N的去除率可分别达到98.29%、99.07%、96.48%,3种形态无机氮同时存在时,会优先利用NH4+-N,且总无机氮去除率较单一存在时更高,说明该菌株可实现同步硝化反硝化。【结论】该分离自海水的异养硝化-好氧反硝化菌属于盐单胞菌属(Halomonas),在高盐环境中仍能生长,同时具有高效的异养硝化和好氧反硝化能力,能够独立完成脱氮的全部过程。     

一株高效异养硝化菌的选育、鉴定及其硝化条件

【目的】针对现阶段异养硝化菌硝化速率较低的问题,选育更高效的异养硝化菌,进而鉴定该菌株的种属,了解其硝化特性和硝化条件。【方法】分别从污水处理厂活性污泥、化肥厂土壤以及农田土壤中取样,以柠檬酸钠为碳源,NH4Cl为氮源,采用污泥驯化、驯化过程中驯化液连续梯度稀释、平板划线分离及颜色指示剂快速硝化效果检测等步骤,筛得一株高效的异养硝化菌。经生理生化和16SrDNA序列的系统发育分析鉴定其种属;将该菌接入人工氨氮废水,定时检测水中含氮化合物的变化,了解其硝化特性;通过改变培养基碳源、溶氧量、C/N比、温度和pH考察其硝化条件。【结果】获得的高效异养硝化菌为革兰氏阴性杆菌,不利用葡萄糖发酵,氧化酶、接触酶阳性,不产吲哚,能由有机酸盐产碱;其与产碱菌属菌株Alcaligenessp.ES-SDK-3的16SrDNA同源性高达99.7%。用该菌株处理初始氨氮浓度为182.30mg/L的废水,30h后氨氮去除率为99.8%,指数期平均氨氮去除速率为9.61mg-N/L/h,其在硝化过程中几乎没有亚硝酸盐氮和硝酸盐氮产生;最佳碳源为柠檬酸钠;高的溶氧量和高的C/N比有利于其降解氨氮,当C/N比为12时即可达到较好的效果;该菌株在温度为30℃-35℃,pH为5.0-9.0范围内均能较彻底地降解氨氮。【结论】该菌株为产碱菌属,命名为Alcaligenessp.HN-S;其在硝化速率与处理的氨氮浓度方面均高于目前国内外筛出的大多数异养硝化菌;通过考察其硝化条件,为其走向实际污水脱氮工艺提供了依据。     

耐高浓度氨氮的异养硝化好氧反硝化菌株U1的鉴定及其脱氮特性

【背景】城市垃圾渗滤液是一种成分复杂的有机废水,含氮量高,如果未经处理直接排放到环境中会造成严重的环境污染。【目的】筛选可以耐受垃圾渗滤液中高浓度氨氮并高效去除污水中氮素的异养硝化好氧反硝化菌株,为解决垃圾渗滤液的氮素污染提供功能菌株。【方法】从垃圾渗滤液中筛选分离能耐受高氨氮浓度的菌株,通过测定各菌株的脱氮能力,筛选到一株脱氮能力最强的菌株,命名为U1,通过测定16S rRNA基因序列和生理生化特性确定该菌株为铜绿假单胞菌。进一步研究了菌株U1在不同初始氨氮浓度、碳源、转速、初始pH、碳氮比等单因素变量下的脱氮能力,并结合L₉（3⁴）正交试验研究了菌株U1的最佳脱氮条件。【结果】分离出一株铜绿假单胞菌并命名为U1。该菌株的最优脱氮条件为:初始氨氮浓度为1 000 mg/L,红糖和柠檬酸三钠的混合碳源,pH 6.0,C/N为10,转速为130 r/min,菌株U1的最大总氮去除率为64.37%,最大氨氮去除率为76.73%。对于总氮和氨氮含量分别是2 345 mg/L和1 473.8 mg/L的垃圾渗滤液,菌株U1最大总氮去除率为27.86%...     

一株海洋好氧反硝化细菌的鉴定及其好氧反硝化特性

【目的】从处理海洋养殖循环水的生物滤器生物膜中分离到1株具有好氧反硝化活性的细菌(菌株2-8),并进一步研究了该菌的分类地位及反硝化特性。【方法】采用16S rRNA基因序列分析对菌株进行初步鉴定,采用好氧培养技术,探讨了碳源种类、起始pH、NaCl浓度、C/N、温度和摇床转速对菌株2-8好氧反硝化活性的影响。【结果】该菌株的16S rRNA基因序列与Pseudomonas segetis FR1439T(AY770691)的相似性最高,达到99.9%,因此初步鉴定菌株2-8属于假单胞菌属(Pseudomonas sp.2-8)。碳源类型和C/N对其好氧反硝化作用的影响最为显著,以柠檬酸钠为唯一碳源,C/N为15时脱氮效率最高,低C/N导致亚硝酸盐的积累;其好氧反硝化的最适温度和pH分别为30℃和7.5;菌株2-8在摇床转速为160r/min下脱氮效果最好;NaCl浓度对其反硝化活性的影响不明显。【结论】在初始硝酸氮浓度为140mg/L,以柠檬酸钠为唯一碳源、C/N为15、pH为7.5、NaCl浓度为30g/L,30℃以及160r/min摇床培养的条件下,菌株2-8在48h内脱氮率可达92%且无亚硝酸盐积累。     

硝化细菌群的富集及其去除城镇寡营养河道中氨氮污染的应用

[背景]随着工农业的发展,污水排放导致的氨氮超标逐渐成为水体污染的重要因素,脱氮已成为人们研究的重点.目前脱氮方法主要集中于硝化细菌的硝化作用,其将氨氮转化为硝酸盐氮,从而减少水体中氨氮的污染.由于工业废水和农业污水中的有机物含量较高,而且异养硝化细菌具有生长较快等优势,因此对异养菌的研究多于自养菌.然而现有的异养硝化...     

一株异养硝化菌的筛选及生长特性研究

从郑州市纳污河流贾鲁河中筛选出一株能高效去除氨氮的细菌,并对其生长特性进行研究。采用传统的微生物分离纯化的方法对所采集的样品进行筛选,用分子生物学的方法对菌株进行鉴定,并通过单因素实验对所选菌株的培养条件进行初步优化。结果显示,所筛选菌株为假黄单胞菌属(Pseudoxanthomonas sp.),命名为C2。该菌株能在有机物存在的条件下进行异养硝化作用,并快速繁殖,当接种量为10%时,培养4 h后即进入对数生长期。该菌株异养硝化的最佳接种量为3%,最适碳源为丁二酸钠,最适p H为6-9,适宜的温度范围为25-30℃,摇床转速对氨氮的去除效果影响不大。菌株C2对氨氮的去除效果较好,对于河水中氨氮的去除具有一定的应用价值。     

深海沉积物高效脱氮菌筛选分离及其脱氮特性研究

【背景】深海海域具有高压、低温、无光等环境条件,蕴含着丰富而独特的微生物资源。【目的】从深海沉积物中定向分离、筛选脱氮效率高的好氧脱氮菌株资源,并揭示其脱氮特性,为开发水体脱氮微生物技术提供物质基础。【方法】以东太平洋、南大西洋、西南印度洋共10个站位的深海沉积物为研究材料,在28°C下使用无机氮源连续进行两轮富集培养,然后定性筛选可以脱除氨氮、亚硝态氮和硝态氮的菌株,并通过形态学和16S rRNA基因序列分析进行初步分类鉴定;对优选得到的功能菌株,分别采用以氨氮、亚硝态氮、硝态氮为唯一氮源的培养基定量研究其生长和脱氮性能。【结果】从10份大洋深海沉积物样品中共分离得到49株好氧反硝化菌,其中3株在有氧条件下反硝化效率较高,分别命名为Pseudomonassp.G111、Pseudomonassp.G112和Dietziamaris W023a,其中菌株G111和G112与模式菌株博岑假单胞菌Pseudomonas bauzanensis BZ93T的16S rRNA基因序列相似度为99.2%,菌株W023a与模式菌株海洋迪茨氏菌DietziamarisATCC35013T的16SrRNA基因序列相似度为99.9%。菌株G111、G112和W023a培养48h后,对氨氮的脱除率分别为98.0%、85.2%和97.6%;对亚硝态氮的脱除率分别为71.9%、67.5%和34.7%;对硝态氮的脱除率分别为66.0%、52.6%和56.3%。菌株G111、G112和W023a均为异养硝化-好氧反硝化菌,可通过好氧反硝化作用将亚硝态氮和硝态氮还原为含氮气体,也可通过异养硝化-好氧反硝化作用将氨氮转化为含氮气体。【结论】从深海沉积物中分离筛选得到3株高效好氧反硝化菌,所获得的菌株在水体净化、污水处理、生态系统修复等领域具有应用潜力。     

一株轻度嗜盐反硝化细菌的分离鉴定和反硝化特性初探

从处理高盐度废水的成熟活性污泥中分离筛选得到1株轻度嗜盐反硝化细菌GYL, 通过对该菌株的形态观察、生理生化实验以及16S rDNA序列分析, 确定该菌株为盐单胞菌(Halomonas sp.)。该菌株能在盐度为10%的培养液中生长, 最适盐度为2%~7%, 最适pH为7.5~8.5, 最佳碳源为蔗糖, 在25°C~30°C的温度范围内脱氮效率达到80%以上。对该菌株的异养硝化能力进行了测定, 其对氨氮的去除率可达98.3%, 说明该菌株可实现同步硝化反硝化, 即该菌可以独立完成生物脱氮的全部过程。     

菌藻共生系统对序批式反应器处理养猪废水脱氮除磷效果及微生物群落结构的影响

【背景】养猪废水作为高浓度有机废水,是导致我国农业面源污染的主要因素之一。目前采用菌藻共生系统处理养猪废水越来越受到关注,与传统序批式反应器(Sequencing Batch Reactor,SBR)相比,藻辅助SBR具有提高脱氮除磷效果、增加污泥活性和降低能源消耗的特点。【目的】针对SBR中菌藻共生系统对养猪废水脱氮除磷效能的影响,比较分析菌藻共生系统与常规SBR系统中污泥特性及微生物群落结构特征差异。【方法】在室温条件下分别平行运行SBR+微藻(R1)和作为对照系统不添加微藻的SBR(R2)。监测R1和R2系统废水处理效果,污泥的粒径、沉降性和代谢产物等污泥特性。利用变性梯度凝胶电泳(Denaturing Gradient Gel Electrophoresis,DGGE)技术分析R1和R2系统中的微生物种类和分布。【结果】与对照R2反应器相比,R1的化学需氧量(Chemical Oxygen Demand,COD)去除率提高了5.1%,NH4+-N提高了20.3%,总氮(Total Nitrogen,TN)提高了19.4%,总磷(Total Phosphorus,TP)提高了23.9%。进一步对反应器中的污泥特性进行分析发现,与R2相比,R1的胞外聚合物(ExtracellularPolymericSubstances,EPS)平均含量提高3.7%,可溶性微生物产物(Soluble MicrobialProduct,SMP)平均增加了38.5%。同时R1的污泥粒径较R2提高了14.8%,污泥体积指数(Sludge Volume Index,SVI)值较R2降低了11.7%,污泥的好氧呼吸速率(Specific Oxygen Uptake Rate,SOUR)较R2提高了64.8%,而且稳定的菌藻共生系统的形成进一步减少反应器出水中的悬浮固体浓度,表明藻类的添加对R1污泥特性具有改良作用【结论】R1反应器形成的菌藻共生体系可进一步优化微生物群落结构,其中放线菌纲(Actinobacteria)、α-变形菌纲(Alphaproteobacteria)和γ-变形菌纲(Gammaproteobacteria)为R1反应器的主要菌群,对养猪废水的处理起到重要作用。R1反应器中的藻类主要为链带藻属(Desmodesmus)和尖带藻属(Acutodesmus),对养猪废水的脱氮除磷起到重要作用。     

Identifying an interfering factor on chemical oxygen demand (COD) determination in piggery wastewater and eliminating the factor by an indigenous Pseudomonas stutzeri strain

AIMS: This study attempted to demonstrate nitrite interference on chemical oxygen demand (COD) determination in piggery wastewater, and the capability of aerobic denitrification of the SU2 strain which is capable of promoting the efficiency of nitrogen and COD removal from piggery wastewater. METHODS AND RESULTS: This study was performed in a 17-litre reactor with a 30% packing ratio, with a ratio of immobilized SU2 cells to sludge of 100:1. The ratio of aeration to nonaeration was 4 : 1.5. Removal efficiency of COD was 86.8%. Removal efficiency of BOD and SS was higher than 90%, and removal efficiency of NH4+-N and TKN was almost 100%. CONCLUSIONS: NO2- -N interference is significant when its concentration in piggery wastewater exceeds 100 mg l-1. COD in piggery wastewater can be indirectly reduced following nitrite reduction by SU2 strain. SIGNIFICANCE AND IMPACT OF THE STUDY: Utilizing immobilized SU2 cells in coordination with an SBR system simultaneously reduces nitrite and COD concentrations.     

反硝化除磷菌筛选及其特性研究

【目的】研究反硝化除磷菌特性。【方法】通过微生物筛选和生物学特性研究方法,从对虾养殖池塘中筛选出多株可在有氧条件下同时具有反硝化除磷功能的菌种。【结果】菌株LY-1可在18 h内将初始量为10 mg/L的亚硝酸盐氮降低至0.04 mg/L,PO43?-P降低至0.05 mg/L。在DO浓度为5.0?5.9 mg/L时,该菌反硝化除磷率近100%。试验选取具有反硝化除磷功能的枯草芽孢杆菌为阳性对照菌,大肠杆菌为阴性对照菌,比较研究了菌株LY-1在不同pH、温度、盐度、PO43?-P浓度、亚硝酸盐浓度时反硝化除磷的强弱,在pH为5?9范围时,该菌亚硝酸盐氮去除率近99%,PO43?-P去除率86%;温度为30°C时,该菌反硝化除磷率近100%;盐度为5‰?15‰、PO43?-P浓度为10 mg/L、亚硝酸盐氮浓度为20 mg/L时,该菌亚硝酸盐氮和PO43?-P去除率均可达99%。【结论】菌株LY-1反硝化除磷性能显著高于对照菌(P<0.05)。通过菌株LY-1形态学观察、生理生化及16S rRNA基因序列分析,初步鉴定为蜡样芽孢杆菌(Bacillus cereus)。     

Nitrification,denitrification and biological phosphorus removal in piggery wastewater using a sequencing batch reactor

Nutrients in piggery wastewater with high organic matter, nitrogen (N) and phosphorus (P) content were biologically removed in a sequencing batch reactor (SBR) with anaerobic, aerobic and anoxic stages. The SBR was operated with 3 cycles/day, temperature 30 degrees C, sludge retention time (SRT) 1 day and hydraulic retention time (HRT) 11 days. With a wastewater containing 1500 mg/l ammonium and 144 mg/l phosphate, a removal efficiency of 99.7% for nitrogen and 97.3% for phosphate was obtained. Experiments set up to evaluate the effect of temperature on the process showed that it should be run at temperatures higher than 16 degrees C to obtain good removals (> 95%). Batch tests (ammonia utilization rate, nitrogen utilization rate and oxygen utilization rate) proved to be good tools to evaluate heterotrophic and autotrophic biomass activity. The SBR proved to be a very flexible tool, and was particularly suitable for the treatment of piggery wastewater, characterized by high nutrient content and by frequent changes in composition and therefore affecting process conditions.     

The effect of pH on the efficiency of an SBR processing piggery wastewater

To treat piggery wastewater efficiently, the hydrolysis of urea (mainly derived from swine urine) in piggery wastewater with the change of sewage pH must be considered. Using activated sludge, piggery wastewater was treated in a sequencing batch reactor (SBR), and the effects of influent pH on SBR processing efficiency, sludge settle ability, and sludge activity were investigated. The results showed that a high influent pH value contributed to the improvement of the removal rate of ammonia nitrogen and reduction of the chemical oxygen demand (COD). When the influent pH was between 9.0 and 9.5, the removal rate of ammonia nitrogen was higher than 90%, and the reduction of COD from its original value was 80%. The influent pH had a greater influence on sludge concentration and sludge activity. When the influent pH increased from 7.0 to 9.5, the sludge concentration increased from 2,350 to 3,947 mg/L in the reactor, and the activities of ammonium oxidizing bacteria (AOB) and nitrite oxidizing bacteria (NOB) first increased and then decreased. When the influent pH was 9.0 and 8.0, the maximum values (0.48 g O₂/(g MLSS/day) and 0.080 g O₂/(g MLSS/day)) were reached, and the sludge settling ratio was nearly steady between 20 and 35% in each reactor.     

Comparison of aerobic denitrification under high oxygen atmosphere by Thiosphaera pantotropha ATCC 35512 and Pseudomonas stutzeri SU2 newly isolated from the activated sludge of a piggery wastewater treatment system

AIMS: This study compares the ability of Thiosphaera pantotropha ATCC 35512 and the newly isolated Pseudomonas stutzeri SU2 to perform aerobic denitrification. METHODS AND RESULTS: Nitrate-supplemented basal medium in airtight crimp-sealed serum bottles containing an atmosphere of 92% oxygen was inoculated with Ps. stutzeri SU2 or T. pantotropha and incubated at 30 degrees C. During the 92-h incubation period, aerobic denitrification by Ps. stutzeri SU2 (NO3(-) - N removal 99.24%) was more efficient than that by T. pantotropha (NO3(-) - N removal 27.29%). CONCLUSION: Pseudomonas stutzeri SU2, which was isolated from the activated sludge of a sequencing batch reactor treating piggery wastewater, rapidly reduced the nitrate to nitrogen gas without nitrite accumulation. The nitrate removal rate of SU2 was 0.032 mmol NO3(-) - N g cell-1 h-1 after 44 h incubation. SIGNIFICANCE AND IMPACT OF THE STUDY: Pseudomonas stutzeri SU2 can be used in a full-scale sequencing batch system for efficient in situ aerobic nitrate removal from piggery wastewater.     

高效净水异养硝化细菌的筛选鉴定及固定化应用研究

本研究从海参养殖水体、泥土中筛选出4株具有硝化能力的异养硝化细菌。分别将其游离菌体细胞投入海参养殖水体,测定亚硝态氮、氨氮去除率,筛选出HS．NOB2为高效净化菌株,对HS-NOB2进行16SrDNA扩增及序列测定,初步鉴定为节杆菌（Arthrobactersp．）。利用海藻酸钠包埋法对高效净化菌体细胞进行固定化,将该固定化菌投入养殖水体及人工合成污水,研究其对水体中亚硝态氮、氨氮的处理效果,并与游离菌体细胞进行比较。结果表明,固定化后亚硝态氮去除率达到49．85％,氨氮去除率达到56．58％,均明显高于游离菌体细胞。上述研究为探寻水体净化提供了新思路,为水质改良剂的实际生产提供可选菌株。     

Hydrocarbon production from secondarily treated piggery wastewater by the green alga Botryococcus braunii

A laboratory study was conducted on the removal of nitrogen and phosphorus from piggery wastewater during growth of Botryococcus braunii UTEX 572, together with measurements of hydrocarbon formation by the alga. The influence was tested of the initial nitrogen and phosphorus concentration on the optimum concentration range for a culture in secondarily treated piggery wastewater. A high cell density (> 7 g L^–1 d. wt) was obtained with 510 mg L^–1 NO₃-N. Growth increased with nitrogen concentration at the basal phosphorus concentration (14 mg P L^–1). The growth rate was nearly independent ( = 0.027 0.030 h^–1) of the initial phosphate concentration, except under conditions of phosphate deficiency ( = 0.019 h^–1). B. braunii grew well in piggery wastewater pretreated by a membrane bioreactor (MBR) with acidogenic fermentation. A dry cell weight of 8.5 mgL^–1 and hydrocarbon level of 0.95 gL^–1 were obtained, and nitrate was removed at a rate of 620 mg NL^–1. These results indicate that pretreated piggery wastewater provides a good culture medium for the growth and hydrocarbon production by B. braunii.