基于代谢组的厌氧氨氧化菌群对温度的响应机制

【背景】在环境工程领域中,大多数耐冷菌从活性污泥中分离得到。了解活性污泥菌群对低温的响应有助于耐冷菌的驯化培养。【目的】以厌氧氨氧化污泥菌群作为研究对象,研究温度对厌氧氨氧化菌群代谢通路与代谢产物的影响,以期初步阐释厌氧氨氧化菌群低温响应机理。【方法】在25°C与35°C条件下驯化培养厌氧氨氧化污泥,研究温度对反应器脱氮效能、菌群活性与生长以及群落结构的影响,通过代谢组学比较两个温度下厌氧氨氧化菌群代谢物丰度以及代谢通路活性。【结果】虽然低温导致厌氧氨氧化菌群CO_2固定、TCA循环与丙酮酸代谢的下调,进而导致氮去除活性以及增长速率显著下降,但菌群RNA合成水平、腐胺与信号分子合成上调,从而通过转录调控、调控膜脂组成与改变膜结构的方式,调控菌群代谢以适应低温环境。【结论】从分子机理的角度探究了厌氧氨氧化污泥菌群适应低温环境的生理机制,首次阐释了腐胺与信号分子在污泥菌群适应低温过程中的重要作用。     

厌氧发酵液中溶解性有机物对活性污泥合成聚羟基脂肪酸酯影响的研究进展

利用活性污泥微生物将剩余污泥发酵液中的挥发性脂肪酸(Volatile fatty acids,VFAs)转化为聚羟基脂肪酸酯(Polyhydroxyalkanoates,PHA)是目前环境生物技术领域的研究热点.但针对发酵液中非VFAs物质(主要是溶解性有机物,Dissolved organic matter,DOM)...     

聚羟基脂肪酸酯合成酶的改造和代谢途径构建的研究进展

聚羟基脂肪酸酯(Polyhydroxyalkanoates,PHA)是许多细菌在非平衡生长条件下在胞内积累的以颗粒状态存在的碳源和能源储藏物质。PHA因其具有生物可降解性、生物相容性等许多良好的材料性质、可以作为化学合成塑料未来的替代品而引起广泛关注。但由短链脂肪酸或单一脂肪酸单体合成的PHA的材料性质具有局限性,需要利用多种单体合成满足实际需求的PHA材料。PHA合成酶的底物特异性和PHA合成代谢途径决定着PHA的单体组成情况,进而影响着PHA的理化特性和材料性能。因此需要对PHA合成酶进行改造,扩展其对底物的特异性。另一方面需要构建新的PHA合成代谢途径,能合成出一些不常见的且性能优良的PHA材料。综述了近些年对PHA合成酶改造的研究及PHA代谢途径构建的研究进展。     

碱-组合工艺预处理剩余污泥研究进展

城市污泥在进行厌氧发酵处理时,所需时间长、SS降解率低、产气量也低,难以有效达到污泥减量化的目的(VS去除率30％左右).污泥的厌氧发酵包括水解、酸化、产乙酸、产甲烷的过程.研究发现在污泥进行厌氧发酵过程中固态有机物的水解、酸化是限速步骤,因此为了促进污泥的水解、酸化,使更多的固体有机物转化为水溶性的有机物,进而提高厌氧发酵的效率实现污泥的减量化、无害化和资源化利用,对污泥预处理是必须的.该文着重介绍了NaOH及其组合工艺对污泥预处理的影响.     

不同底物对海洋混合菌群产氢的影响

将采自天津潮间带的污泥进行热休克处理,厌氧条件下富集混合菌群进行产氢试验。混合菌群分别接种于含葡萄糖、蔗糖、乳糖、淀粉和蛋白胨的培养液中,测定不同底物培养条件下混合菌群产氢量及菌群组成。结果表明,以蔗糖为底物时,混合菌群产氢量最高,为（787±24）mL／L;混合菌群以葡糖糖、乳糖和淀粉为底物时,产氢量依次为（530±20）、（46±5）和（455±35）mL／L;混合菌群不能利用蛋白胨为底物产氢。变性梯度凝胶电泳（DGGE）分析不同底物培养条件下的产氢混合菌群组成。混合菌群16S rRNA基因的DGGE分离结果表明,在蛋白胨培养条件下,混合菌群没有能够形成优势菌,其他底物培养时,混合菌群的优势菌是Clostridium sp．。     

驯化对生物阴极微生物燃料电池中阴极微生物群落多样性的影响

【背景】生物阴极微生物燃料电池因其构造成本低和阴极可持续性发展的优点而成为一种很有前途的废水处理系统,但阴极微生物的氧化还原性能限制了其在实际应用中的推广。【目的】为了提高生物阴极的性能,需要深入了解影响阴极氧化还原性能的微生物群落。【方法】利用16S rRNA基因高通量测序技术分析对比原始接种污泥样品和驯化后阴极电极上生物膜样品多样性及结构变化。【结果】测序结果表明,原始接种污泥样品与驯化后阴极电极生物膜样品中微生物群落种类和结构存在显著差异,驯化后阴极电极生物膜样品中变形菌门(Proteobacteria)、γ-变形菌纲(Gammaproteobacteria)和特吕珀菌属(Trueperaceae)相对丰度比例高于原始污泥样品,成为优势菌群。【结论】驯化对系统阴极电极生物膜群落影响显著,随着产电量的输出,优势菌群不断富集,最终形成一个适应该实验环境下的新的微生物群落。对优势菌群结构和变化进行探讨,为生物阴极的研究补充更多生物学方面的理论基础。     

厌氧产酸菌群培养技术在窖泥质量快速检测中的应用

【背景】窖泥质量决定了浓香型白酒品质的高低,窖泥中的产酸功能菌群显著影响着窖泥的质量及对应的浓香型白酒品质,但目前对窖泥质量的评价尚缺乏明确和完善的标准。【目的】建立一种快速、准确评价窖泥质量的方法,解析窖泥中参与己酸合成的重要微生物。【方法】通过窖泥产酸菌群培养和产酸代谢特征研究,构建厌氧产酸菌群发酵体系,根据窖泥中厌氧菌的己酸合成能力来评价相应窖泥的质量;利用高通量测序技术分析可培养发酵体系中产己酸功能微生物的群落组成。【结果】葡萄糖碳源相比乳酸碳源可以更有效地富集窖泥中的产己酸菌群;采用毫升级别发酵体系、对窖底泥进行多点取样,产酸菌群发酵代谢产物稳定期的己酸产量、己酸/丁酸值可较准确地评价不同窖泥的质量。16S rRNA基因测序结果表明,利用产酸菌群培养方法可以有效地富集未培养产己酸细菌(Uncultured bacterium Caproiciproducens)。【结论】基于产酸菌群培养的窖泥微生物发酵体系可用于实际生产中快速、准确地评价窖泥质量,并为窖泥微生物己酸合成代谢机制的研究提供参考。     

活性污泥合成聚羟基脂肪酸脂的研究进展

聚羟基脂肪酸( PHAs) 是许多原核微生物在不平衡生长条件下合成的细胞内能量和碳源储藏性物质,同时也是一种可完全生物降解的塑料,由于其良好的环境效应及机械性能而受到广泛关注.使用活性污泥合成PHA既能降低PHA的生产成本,又能充分利用活性污泥资源,减少对环境的污染.综述了活性污泥合成PHA的研究进展, 包括合成PHA的主要微生物、碳源及影响PHA积累的因素.     

剩余活性污泥完全资源化利用微生物集成技术

剩余活性污泥完全资源化利用微生物集成技术包括: 使用土著PHA合成菌回注法驯化并发酵活性污泥, 生产生物降解材料聚羟基脂肪酸酯(PHA); 采用土著嗜酸性氧化亚铁硫杆菌和氧化硫硫杆菌进行生物淋滤, 去除重金属; 以解磷菌和解钾菌为菌种, 进行固态发酵, 生产生物菌肥。结果表明, 500 L中试PHA占挥发性悬浮固体的20%以上; 重金属含量达到国家排放要求; 生物菌肥中活菌数大于1×108 个/g以上。实现了剩余活性污泥的近零排放。     

pH值和产甲烷抑制剂对两相耦合系统污泥发酵定向产乙酸的影响

采用产氢产乙酸/同型产乙酸两相耦合工艺对剩余污泥进行了半连续式厌氧发酵,主要研究了pH值和产甲烷抑制剂2-bromoethanesulphonate(BES)对耦合系统定向产乙酸的影响.结果表明:碱性pH(pH=10.0)和添加BES都能促进A相乙酸的积累,提高乙酸的产率,同时碱性pH比添加BES更有利于污泥的水解.当...     

Determination of the extraction kinetics for the quantification of polyhydroxyalkanoate monomers in mixed microbial systems

For the first time, a systematic approach was conducted to determine the key factors influencing the kinetics of hydroxyalkanote (HA) extraction in biological systems. Six mixed microbial systems where polyhydroxyalkanoate (PHA) is produced were evaluated. Experiments were carried out for full-scale and lab-scale activated sludge systems using different configurations (containing floccular or granular sludge), as well as specific PHA accumulating cultures that contain high or low intracellular PHA fractions. The overall reaction was limited by the kinetics of the PHA hydrolysis in floccular cultures, whereas in granular cultures, it was limited by the cell lysis step. The monomeric composition of the polymer also had an impact on the HA extraction rate: higher acid concentration and a longer digestion time should be employed when cells accumulate monomers with more substituents, such as hydroxy-2-methylbutyrate (H2MB) and hydroxy-2-methylvalerate (H2MV). This study optimised the method for HA extraction, which impacts the assessment of the quantity and quality of PHA biopolymers.     

Polyhydroxyalkanoate synthesis using different carbon sources by two enhanced biological phosphorus removal microbial communities

Polyhydroxyalkanoate (PHA) is a biodegradable plastic synthesised by bacteria as energy and carbon storage material. PHA production is mostly based on pure cultures operated under sterile conditions, which increase the costs of this biopolymer. The use of inexpensive mixed culture biomass, such as activated sludge, to produce biodegradable plastics from renewable waste streams has been proposed as an alternative.The effect of carbon sources (acetate, propionate, butyrate and glucose) on the type and quantity of PHA synthesis obtained with different enhanced biological phosphorus removal (EBPR) microbial communities enriched with acetate and propionate are reported in this work. Two sequencing batch reactors (SBRs) were seeded with biomass withdrawn from a non-EBPR wastewater treatment plant (WWTP). The same operational conditions were kept, but using acetate or propionate as the sole carbon source of each reactor. These conditions produced two microbial communities with different P-removal capacity. The results presented in this study show the effect of the carbon source on the PHA composition (amount of polyhydroxybutyrate (PHB), polyhydroxyvalerate (PHV) and polyhydroxy-2-methylvalerate (PH2MV)), which differed not just between substrates but also between the two EBPR communities used. In addition, some monomers not always analysed contribute significantly to the total amount of PHA, especially when using butyrate, showing that if they are not considered this can lead to erroneous calculated yields.     

Optimal production of polyhydroxyalkanoates (PHA) in activated sludge fed by volatile fatty acids (VFAs) generated from alkaline excess sludge fermentation

To reduce the production cost of polyhydroxyalkanoates (PHA) and disposal amount of excess sludge simultaneously, the feasibility of using fermentative volatile fatty acids (VFAs) as carbon sources to synthesize PHA by activated sludge was examined. At pH 11.0, 60 degrees C and fermentative time of 7d, the VFAs yield was 258.65 mgTOC/gVSS. To restrain cell growth during PHA production, the released phosphorus and residual ammonium in the fermentative VFAs was recovered by the formation of struvite precipitation. Acetic acid was the predominant composition of the fermentative VFAs. PHA accumulation in excess sludge occurred feeding by fermentative VFAs with aerobic dynamic feeding process. The maximum PHA content accounted for 56.5% of the dry cell. It can be concluded from this study that the VFAs generated from excess sludge fermentation were a suitable carbon source for PHA production by activated sludge.     

Analysis of polyhydroxyalkanoate (PHA) synthase gene in activated sludge that produces PHA containing 3-hydroxy-2-methylvalerate

The identification of phaC which encodes PHA synthase, that is involved in the formation of polyhydroxyalkanoate (PHA) containing 3-hydroxy-2-methylvalerate (3H2MV), was attempted. As of now, PHA containing 3H2MV has been reported to be produced only by mixed microbial cultures in activated sludge, but no pure bacterial cultures. A laboratory-scale activated sludge process was operated for 67 days. During the operation of the activated sludge process, its capacity to produce PHA containing 3H2MV, and the diversity of the partial phaC genes in the activated sludge microorganisms were monitored periodically. Analysis of the partial phaC genes was conducted by PCR followed by cloning and DNA sequencing, or by PCR followed by terminal-restriction fragment length polymorphism (T-RFLP). The cloning-sequencing of the 263 clones gave 11 distinct genetic groups (GGs). All of the genetic groups had similarities to known phaC higher than 48%, and one of them had similarity as high as 96% to that of Alcaligenes sp. The behavior of each of the genetic groups during the operation of the activated sludge process was monitored by the T-RFLP method. The restriction enzyme AccII, with the help of MboI, enabled the monitoring of each of the genetic groups. One of the genetic groups was found to have a strong correlation with the capability of the activated sludge to produce PHA containing 3H2MV, and its DNA sequence together with its amino acid sequence are reported.     

含有甲烷氧化菌的混合菌群特性研究

为获得高效甲烷氧化微生物体系,从农业土壤中采样,以甲烷作为唯一碳源进行好氧选择性传代培养,得到生长性能稳定、生长优于Methylosinus trichosporium OB3b纯培养的具有甲烷单加氧酶(Methane Monooxygenase,MMO)活性甲烷氧化混合菌。利用MMO的共代谢特性,分别以苯酚和环氧丙烷作为目标对象,考察该混合菌对有机污染物的降解及用于生产有用化学物质的催化特性。结果表明,所得混合菌具有高效降解苯酚能力,对初始浓度为600mg/L的苯酚,经过11h培养,苯酚降解率可达99%。另外,以该混合菌为催化剂可以实现丙烯氧化生产环氧丙烷。通过降低磷酸盐浓度可以有效提高环氧丙烷的积累浓度,最大可至5mmol/L。此外,采用纯种分离方法结合PCR扩增、16SrRNA和MMO功能基因分析技术对混合菌群结构进行解析。结果表明,该混合菌群由Ⅱ型甲烷氧化菌及其它至少4种非甲烷氧化菌组成,它们分别属于Methylosinus trichosporium和Acinetobacter junii、Cupriavidusme tallidurans、Comamonas testosteroni和Stenotrophomonas maltophilia。采用PCR方法从混合菌及纯化菌株M.trichosporiums Y9总DNA中都能扩增得到mmoB、mmoX和pmoA基因片段,表明该甲烷氧化菌同时具有sMMO和pMMO两种形式的MMO。通过对从甲烷氧化混合菌中分离纯化得到的甲烷氧化菌进行PCR产物测序,结果发现其与Methylosinus trichosporium的同源性为99.9%。     

Aerobic granular sludge: characterization, mechanism of granulation and application to wastewater treatment

Aerobic granular sludge can be classified as a type of self-immobilized microbial consortium, consisting mainly of aerobic and facultative bacteria and is distinct from anaerobic granular methanogenic sludge. Aerobic granular technology has been proposed as a promising technology for wastewater treatment, but is not yet established as a large-scale application. Aerobic granules have been cultured mainly in sequenced batch reactors (SBR) under hydraulic selection pressure. The factors influencing aerobic granulation, granulation mechanisms, microbial communities and the potential applications for the treatment of various wastewaters have been studied comprehensively on the laboratory-scale. Aerobic granular sludge has shown a potential for nitrogen removal, but is less competitive for the high strength organic wastewater treatments. This technology has been developed from the laboratory-scale to pilot scale applications, but with limited and unpublished full-scale applications for municipal wastewater treatment. The future needs and limitations for aerobic granular technology are discussed.     

Aerobic granular sludge: characterization,mechanism of granulation and application to wastewater treatment

Aerobic granular sludge can be classified as a type of self-immobilized microbial consortium, consisting mainly of aerobic and facultative bacteria and is distinct from anaerobic granular methanogenic sludge. Aerobic granular technology has been proposed as a promising technology for wastewater treatment, but is not yet established as a large-scale application. Aerobic granules have been cultured mainly in sequenced batch reactors (SBR) under hydraulic selection pressure. The factors influencing aerobic granulation, granulation mechanisms, microbial communities and the potential applications for the treatment of various wastewaters have been studied comprehensively on the laboratory-scale. Aerobic granular sludge has shown a potential for nitrogen removal, but is less competitive for the high strength organic wastewater treatments. This technology has been developed from the laboratory-scale to pilot scale applications, but with limited and unpublished full-scale applications for municipal wastewater treatment. The future needs and limitations for aerobic granular technology are discussed.     

筛选生物转化H_2/CO_2气体产乙酸的同型产乙酸菌混培物

同型产乙酸菌是一类具有巨大工业应用潜力的微生物类群,可利用合成气生成乙醇和乙酸等燃料和化学品。本研究采集城市污泥样品利用Hungate滚管法进行同型产乙酸菌的筛选,并利用其进行H2/CO2气体的生物转化,研究了p H对其乙酸和乙醇生成情况的影响。结果表明,所获得的同型产乙酸菌混培物组成为永达尔梭菌,纺缍形赖氨酸芽胞杆菌和蜡样芽胞杆菌等。该混培物最适p H为5-7。p H为7时混培物利用H2/CO2气体得到乙酸浓度可达到31.69 mmol/L。本研究获得了一种可利用H2/CO2合成乙酸的同型产乙酸菌混培物,为合成气生物转化的工业应用提供了有效的微生物资源。     

High tolerance to glycerol and high production of 1,3‐propanediol in batch fermentations by microbial consortium from marine sludge

1,3‐Propanediol (1,3‐PD) is a versatile bulk chemical and widely used as a monomer to synthesis polymers, such as polyesters, polyethers and polyurethanes. 1,3‐PD can be produced by microbial fermentation with the advantages of the environmental protection and sustainable development. Low substrate tolerance and wide by‐product profile limit microbial production of 1,3‐PD by Klebsiella pneumonia on industrial scale. In this study, microbial consortia were investigated to overcome some disadvantages of pure fermentation by single strain. Microbial consortium named DL38 from marine sludge gave the best performance. Its bacterial community composition was analyzed by 16S rRNA gene amplicon high‐throughput sequencing and showed that Enterobacteriaceae was the most abundant family. Compared with three K. pneumonia strains isolated from DL38, the microbial consortium could grow well at an initial glycerol concentration of 200 g/L to produce 81.40 g/L of 1,3‐PD with a yield of 0.63 mol/mol. This initial glycerol concentration is twice the highest concentration by single isolated strain and more than the critical value (188 g/L) extrapolated from the fermentation kinetics for K. pneumonia. On the other hand, a small amount of by‐products were produced in batch fermentation of microbial consortium DL38,  especially no 2,3‐butanediol detected. The mixed culture of strain W3, Y5 and Y1 improved the tolerance to glycerol and changed the metabolite profile of single strain W3. The batch fermentation with the natural proportion (W3: Y5: Y1 = 208: 82: 17) was superior to that with other proportions and single strain. This study showed that microbial consortium DL38 possessed excellent substrate tolerance, narrow by‐product profile and attractive potential for industrial production of 1,3‐PD.     

Polyhydroxyalkanoates as a source of chemicals, polymers, and biofuels

Microbial polyhydroxyalkanoates (PHA) are a family of structurally diverse polyesters produced by many bacteria. Deleting key steps from the beta-oxidation cycle in Pseudomonas putida makes it possible to achieve precise substrate based design of PHA homopolymers, copolymers, and block polymers, allowing the study of structure-property relationship in a clear way. The PHA homopolymer synthesis also allows the microbial or chemical production of pure monomers of PHA in a convenient way without separating the mixed monomers. After used as bioplastics, PHA can be methyl esterified to become biofuels, which further extends the PHA application value. The microbial production of PHA with diverse structures is entering a new developing phase.