共基质下白腐菌降解含氮杂环类物质的研究

选用不同的营养基质（秸秆、土豆、合成）,通过液体发酵确定白腐菌对典型含氮类杂环化合物喹啉,吲哚分别进行降解。结果表明：秸秆滤液培养基中,喹啉15d内能被降解88．79％,吲哚在6d内降解率能达到99％。采用此培养基,进一步研究喹啉、吲哚及其它物质共基质条件下,白腐菌对喹啉和吲哚的降解性能,发现在共基质条件下喹啉的降解被抑制,而吲哚则能在共基质条件下3d被完全降解,说明共基质促进了白腐菌对吲哚的降解。     

不同共代谢基质对白腐菌降解吲哚的作用研究

选用氨氮、苯酚和喹啉作为吲哚的共代谢基质,通过白腐菌BP对共基质体系的降解研究了白腐菌在秸秆滤出液培养基中对不同共基质体系的代谢过程,并进行了动力学分析,考察了不同共代谢基质物质对白腐菌漆酶分泌和吲哚降解的影响.结果显示,不同降解体系中的白腐菌都可去除99%以上的吲哚.充分的氮源可提高白腐菌的活性和漆酶酶活的峰值;共基质苯酚和喹啉可以增加白腐菌漆酶产量,为吲哚的降解提供较多的电子,同时苯酚和喹啉也能得到较高的去除.在秸秆滤出液中,白腐菌在pH为6～8之间对吲哚都具有较强的降解能力.吲哚在白腐菌的代谢过程中,可能首先在吡啶环的2和3位发生一步羰基化.     

零价铁预厌氧协同MFC强化降解吲哚性能与功能菌群分析

通过零价铁（ZVI）预厌氧与微生物燃料电池（MFC）的协同作用,研究其对单一基质碳源吲哚的降解特性、MFC产电性能及群落分析.结果表明：ZVI（4 g·L^-1）的预厌氧可明显促进吲哚（250 mg·L^-1）在MFC体系中的降解;其中吲哚与TOC在96 h内的降解率分别为97.17%和89.50%,且吲哚的降解符合一级反应动力学模型;体系中MFC最大输出电压和功率密度可达600 mV和439.55 mW·m^-2;通过LC-MS分析,吲哚在协同体系中的主要中间代谢产物为靛红和水杨酸.高通量测序结果表明,ZVI预厌氧体系的引入有利于MFC体系中梭菌（Clostridium sensu stricto）、链霉菌（Streptomyces sp.）、热单胞菌（Thermomonas）的富集与吲哚的厌氧降解;同时促进假单胞菌（Pseudomonas）和梭菌等在代谢过程中的电子转移,提高了MFC的产电性能.     

焦化废水中几种难降解有机物的厌氧生物降解特性

在试验室条件下,采用厌氧间歇试验,分别研究了焦化废水中几种有代表性的难降解有机物——喹啉、吲哚、吡啶、联苯的厌氧生物降解特性.文中突出了以厌氧预处理改善焦化废水中难降解有机物生物降解性的工程实用背景,对这四种有机物的厌氧处理的动力学特性、共基质作用、厌氧处理下去除效果的改善等,进行了较为深入的研究.     

共代谢对难降解有机物生物降解性能的影响

利用瓦呼仪测试法测试了呋喃等6种难降解有机物在单一基质和与苯酚共基质的条件下生物降解性能,研究共代谢对难降解有机物生物降解性能的影响。研究表明,共代谢对呋喃、喹啉、吲哚生物降解性能有明显提高,吡啶、联苯、三联苯在低浓度时,生物降解性能有所改善。     

含氮杂环化合物在厌氧和缺氧条件下的降解研究

选取5种含氮杂环化合物吡啶，吲哚、喹啉、异喹啉，2－甲基喹啉，研究了它们在厌氧和缺氧条件下的降解情况，结果表明，上述5种化合物在厌氧条件下的降解从易到难依次为：吲哚＞异喹啉≈喹啉＞吡啶＞2－甲基喹啉，在缺氧条件下的降解从易到难依次排列为：吡啶＞吲哚＞喹啉＞2－甲基喹啉＞异喹啉。实验比较，说明5种化合物在缺氧条件下都比在厌氧条件下容易降解，特别是吡啶，其降解速率有很大提高。     

焦化废水中几种含氮杂环有机物在A1-A2-O系统中的降解特性研究

在对焦化废水中有机物在A1－A2－O生物膜系统中降解转化规律进行分析的基础上，选取焦化废水中6种主要的含氮杂环化合物，吡啶，吲哚，喹啉，异喹啉，8－羟基喹啉，与苯酚共同配制成溶液，在A1－A2－O生物膜系统中运行，结果表明上述几种含氮杂环有机物在A1－A2－O 都可得到较完全的去除，它们在厌氧段的降解速率从大到小依次为，吲哚＞2－甲基喹啉＞8－羟基喹啉＞异喹啉＞喹啉＞吡啶。在厌氧条件下，吲哚和喹啉存在拮抗作用，而吡啶对喹啉有协同作用，啉啶的加入有利于改善由喹啉和吲哚之间产生的拮抗作用。     

链霉菌(Streptomyces sp.)对吲哚废水的降解特性

链霉菌(Streptomycessp.)HJ02能以吲哚为唯一碳源生长,考察了初始吲哚质量浓度、外加碳源、温度、pH等对其降解效果的影响,探讨了该菌降解吲哚的动力学与机理.结果表明,链霉菌对吲哚有很强的耐受力,在pH=7、温度为30℃的条件下培养6d,初始浓度为300mg·L-1吲哚的降解率达到97.4%.菌株对吲哚的降解过程动力学符合Andrews方程.外加葡萄糖会抑制链霉菌降解吲哚的速率,葡萄糖与吲哚之间存在底物竞争抑制.紫外光谱与GC分析表明,吲哚的特征杂环被链霉菌破坏.     

新型无极准分子光源深度处理水相中含N-杂环化合物

采用微波激发Kr/I2混合气体产生的206 nm准分子紫外光降解水相含N-杂环化合物,考察了206 nm准分子光直接光解模拟喹啉和吲哚废水的效果.结果表明,初始浓度为20 mg.L-1的吲哚溶液,光照80 min时去除率达62.0%,150 min时TOC去除达50.7%.光照时间、初始浓度和溶液的pH值对喹啉的降解有一定的影响.相同条件下,喹啉的去除率和TOC损失率都明显低于吲哚.光解后的溶液经旋转蒸发提取,顶空注射进入气相色谱/质谱联用仪(GC/MS)定性分析,结果表明,光照下喹啉发生开环降解,生成了甲苯、二甲苯、酸、醛和酯类化合物,而吲哚降解过程中发生了聚合反应.最后,根据中间产物,推断了206 nm准分子光源光解喹啉和吲哚的机制.     

四环素降解对厌氧反硝化产甲烷性能的影响

为有效去除污水中的四环素(TC),以乙酸钠为共代谢基质,研究厌氧反硝化同时产甲烷(SDM)体系中TC的降解特性及体系性能变化.结果表明,5d内SDM体系中TC(1mg/L)的降解率可达82.6%,同时TC降解过程中TOC的降解率可达95%以上;但一定浓度的TC压力对TC的降解、NO₃^--N去除以及CH₄的产生有抑制作用,影响SDM处理废水的性能.此外,根据中间产物推测出该反应体系中微生物对TC的降解途径主要包括羟基化、碳键的断裂和脱氨基等;通过高通量测序对微生物群落进行分析,发现厌氧功能菌群得到富集,细菌菌门以Proteobacteria为主,菌属以Candidatus＿Promineofilum和Candidatus＿Microthrix为主;古菌菌门主要以Euryarchaeota和Halobacterota为主,菌属以Methanosaeta和Methanothrix为主.出水生物毒性检测结果显示,周期末出水生物毒性降低且接近空白组.     

短期填埋龄垃圾堆体内微生物群落结构与种群分布特征

填埋垃圾的稳定化过程一般经历好氧过渡、水解酸化、初期产甲烷及稳定产甲烷阶段,固相垃圾的厌氧水解酸化阶段常被视为垃圾降解的限速步骤,而这一阶段微生物的降解作用是影响垃圾稳定化进程的关键.以青岛市小涧西生活垃圾填埋场短期填埋龄垃圾为研究对象,采用MiSeq高通量测序研究了填埋龄0～1、1.0～1.5、1.5～2 a垃圾堆体内微生物的群落结构多样性及种群分布特征.结果表明,0～1 a填埋龄垃圾微生物多样性高于1.0～1.5 a和1.5～2 a垃圾堆体,且微生物多样性整体上随填埋深度呈降低趋势.参与垃圾降解细菌多样性比真菌更丰富,而真菌多样性随填埋区域、填埋龄的不同呈现更显著的差异.参与短期填埋龄垃圾降解的细菌中,Firmicutes在填埋层上层为优势菌门,最大比例达到65%,Proteobacteria在填埋层中下层为优势菌门,最大比例达到88%.填埋上层细菌菌属以Defluviitoga、Aerococcus、Clostridium III和Proteiniphilum为主,而在中下层以Thiopseudomonas、Sporosarcina和Eionea为主.真菌主要包括3个菌门,Ascomycota在各点位均为最优势菌门,属水平上Kernia及Aspergillus作为常见的腐生菌属,在不同点位均有较高的丰度.冗余分析表明短期填埋龄垃圾堆体内微生物不同时空分布存在显著差异性,且细菌群落结构的变化受pH值影响较大,而真菌群落结构的变化与垃圾有机质密切相关.     

乙酸钠为电子供体时反硝化耦合甲烷化过程的数学模拟

基于化学计量学与生物力能学确定生化反应的理论反应式,结合multiplicative Monod及non-competitive Monod方程,建立了反硝化耦合甲烷化的数学模型。以乙酸钠为电子供体,厌氧颗粒污泥为接种污泥,通过间歇实验获取模型的相关参数。结果表明:该模型能较好地分析反硝化耦合甲烷化过程底物降解、竞争规律及反硝化中间产物对甲烷化的抑制作用;预测气体的累积产气量及各菌群生物量变化。参数灵敏度分析表明:甲烷化、硝酸盐还原和亚硝酸盐过程的灵敏度因子分别为km,a、km,NO3和km,NO2,这证实最大比底物利用速率对底物降解过程影响最显著,其值分别为km,a=0.098 h-1,km,NO3=0.0824 h-1和km,NO2=0.0695 h-1。     

Influence of influent on anaerobic ammonium oxidation in an Expanded Granular Sludge Bed-Biological Aerated Filter integrated system

Shortcut nitrification-denitrification, anaerobic ammonium oxidation (ANAMMOX), and methanogenesis have been successfully coupled in an Expanded Granular Sludge Bed-Biological Aerated Filter (EGSB-BAF) integrated system. As fed different synthetic wastewater with chemical oxygen demand (COD) of 300–1200 mg·L⁻¹ and NH₄⁺-N of 30–120 mg·L⁻¹ at the outer recycle ratio of 200%, the influence of influent on ANAMMOX in the integrated system was investigated in this paper. The experimental results showed that higher COD concentration caused an increase in denitrification and methanogenesis but a decrease in ANAMMOX; however, when an influent with the low concentration of COD was used, the opposite changes could be observed. Higher influent NH₄⁺-N concentration favored ANAMMOX when the COD concentration of influent was fixed. Therefore, low COD =NH₄⁺-N ratio would decrease competition for nitrite between ANAMMOX and denitrification, which was favorable for reducing the negative effect of organic COD on ANAMMOX. The good performance of the integrated system indicated that the bacterial community of denitrification, ANAMMOX, and methanogenesis could be dynamically maintained in the sludge of EGSB reactor for a certain range of influent.     

Microbial community changes in aquifer sediment microcosm for anaerobic anthracene biodegradation under methanogenic condition

The widespread distribution of polycyclic aromatic hydrocarbons (PAHs) in groundwater has become an important environmental issue. Knowledge of microbial community changes could aid in identification of particular microorganisms that are capable of degrading PAHs in contaminated aquifers. Therefore, 16S rRNA gene clone library analysis was used to identify the archaeal and bacterial communities in an aquifer sediment microcosm used for anaerobic anthracene degradation under methanogenic conditions. A remarkable shift of the archaeal community structure occurred after anaerobic anthracene degradation, but the types of the abundant bacterial phyla did not change. However, a decrease of both archaeal and bacterial diversity was observed. Bacterial genera Bacillus, Rhodococcus and Herbaspirillum might have links with anaerobic anthracene degradation, suggesting a role of microbial consortia. This work might add some new information for understanding the mechanism of PAH degradation under methanogenic conditions.     

Response of anaerobes to methyl fluoride, 2-bromoethanesulfonate and hydrogen during acetate degradation

To use the selective inhibition method for quantitative analysis of acetate metabolism in methanogenic systems,the responses of microbial communities and metabolic activities,which were involved in anaerobic degradation of acetate,to the addition of methyl fluoride(CH3F),2-bromoethanesulfonate(BES)and hydrogen were investigated in a thermophilic batch experiment.Both the methanogenic inhibitors,i.e.,CH3F and BES,showed their effectiveness on inhibiting CH4 production,whereas acetate metabolism other than acetoclastic methanogenesis was stimulated by BES,as reflected by the fluctuated acetate concentration.Syntrophic acetate oxidation was thermodynamically blocked by hydrogen(H2),while H2-utilizing reactions as hydrogenotrophic methanogenesis and homoacetogenesis were correspondingly promoted.Results of PCR-DGGE fingerprinting showed that,CH3F did not influence the microbial populations significantly.However,the BES and hydrogen notably altered the bacterial community structures and increased the diversity.BES gradually changed the methanogenic community structure by affecting the existence of different populations to different levels,whilst H2 greatly changed the abundance of different methanogenic populations,and induced growth of new species.     

Promotive effect of pyridine on indole degradation by activated sludge under anoxic conditions

Batch experiments were carried out to investigate the promotive effect of pyridine on indole degradation under denitrifying conditions. The seed sludge was obtained from a local coal-coking wastewater treatment facility and was acclimated in the laboratory. Indole and pyridine were supplemented to the synthetic wastewater at different ratios. The optimum ratio of chemical oxygen demand (COD) to nitrate (C/N) was 8.4–8.9 for both denitrification and indole and pyridine degradation. At a temperature of 28°C and pH of 7.0–7.5, the nitrate reductase activity (NRA) was in the best state. The addition of pyridine could promote NRA and the degradation of indole. When the initial concentration of indole was 150 mg/L, the concentration ratio of indole to pyridine was in the range of 1–10. Under optimum C/N conditions, the degradation of indole could be described with pseudo-zero-order kinetics. There was no accumulation of nitrite during the reaction. When the concentration ratio of pyridine to indole was less than 0.25 with an increase in the pyridine proportion, there were more significant augment rates for NRA and the degradation of indole than the situation when the concentration ratio was more than 0.25. __________ Translated from Environmental Science, 2006, 27(2): 300–304 [译自: 环境科学]     

氢气和氮气对厌氧甲烷降解过程及微生物多样性的影响

针对厌氧甲烷氧化过程,考察了填埋场稳定化过程中气态物质(H₂、N₂)的影响,阐明了微生物群落结构的响应。结果表明:在N₂氛围下,存在甲烷氧化、固氮、硝化、反硝化的循环过程;通入H₂对于厌氧甲烷降解过程有一定影响,CH₄含量呈先下降后升高再降低的趋势,CO₂含量则呈先升高后降低趋势,表明H₂可将CO₂还原为CH₄。经过N₂和H₂长期驯化后,土壤微生物群落结构发生了显著变化,放线菌门中具有硝化、反硝化及固氮作用的菌群增加,出现了具有甲烷氧化功能的Methylococcale菌群。好氧菌(如甲烷氧化菌、硝化菌)对O₂的消耗有利于反硝化和厌氧甲烷氧化的进行,为反硝化型厌氧甲烷氧化的发生提供了有利条件。研究揭示了填埋场稳定化过程中气态物质影响厌氧甲烷氧化的过程。     

PCR-DGGE研究处理垃圾渗滤液序批式生物膜反应器(SBBR)中的细菌多样性

为了研究序批式生物膜反应器中的细菌多样性及其脱氮的微生物学机理,为工艺改进提供依据,从同步高效去除垃圾渗滤液中高氨氮和高COD的SBBR生物膜和渗滤液原水中采集微生物样品并提取微生物总DNA,使用细菌通用引物对（GC341F/907R）从总DNA中成功扩增出目标16S rDNA片段,然后对扩增的16S rDNA进行DGGE,对凝胶染色并进行条带统计分析和切胶测序,使用序列数据进行同源性分析并建立了系统发育树.结果表明,该驯化后的SBBR生物膜和渗滤液原水中都有比较丰富的细菌多样性,驯化的生物膜细菌主要来自渗滤液原水,而且生物膜细菌在反应器正常运行时不会出现明显的群落结构变化;在该SBBR中有多种硝化细菌与反硝化细菌、好氧反硝化细菌和厌氧氨氧化细菌共存,说明该反应器中可能同时存在全程硝化反硝化、同步硝化反硝化和厌氧氨氧化3种脱氮方式.研究结果为SBBR脱氮微生物机理研究提供了一些有价值的参考依据.