分子生物学方法提高电活性微生物胞外电子传递效率的研究进展*

微生物细胞与电极之间的胞外电子传递效率是限制微生物电化学技术发展的关键因素,而分子生物学的发展为提高胞外电子传递效率带来了光明前景。从四种具有代表性的纯培养电活性微生物(奥奈达希瓦氏菌、铜绿假单胞菌、硫还原地杆菌和工程大肠杆菌)和混合培养电活性微生物出发,综述了利用分子生物学手段改造几种电活性微生物的研究成果,阐明了针对特异的电活性微生物,如何采取相应的分子生物学手段提高其胞外电子传递的效率,并展望了未来的研究方向。     

电活性微生物胞外聚合物的特征与应用

电活性微生物是一类能够通过直接接触、导电菌毛或氧化还原介质与电极或者其他细胞进行胞外电子传递的微生物。而在这个过程中,胞外聚合物(extracellular polymeric substances, EPS)扮演着重要的角色。EPS是微生物生长过程中通过细胞裂解、水解分泌的高分子聚合物的混合物,主要由蛋白质、多糖和腐殖质等物质组成。来自电活性微生物的EPS的不同组成成分和特性会对EPS的电活性以及电活性微生物胞外电子传递产生一定的影响,同时在环境应用方面发挥重要作用。因此,为了更全面了解电活性微生物EPS的电活性及其对电活性微生物胞外电子传递的作用,本文总体介绍了电活性微生物EPS的电活性的直接表征方法,再从组成成分、化学性质、物理性质和空间分布4个方面综述了其对EPS电活性的影响及其在电子传递中的作用,介绍了当前电活性微生物EPS在染料废水脱色、重金属吸附、有机污染物的生物转化和渗滤液管理等方面的环境应用,并从表征方法、试验规模和互作机理研究等角度展望了未来的研究方向。     

基于电活性微生物的芳香烃类污染物转化机制研究进展

芳香烃类化合物(aromatic hydrocarbon compounds)是一类基于苯环结构的有机物,广泛分布在自然环境中,难以自然降解、易被生物积累,且有很大的环境危害性。生物法是有机化合物转化降解的主流工艺,而电活性微生物(electroactive microorganisms, EAM)因其独特的胞外电子传递(extracellular electron transfer, EET)能力和生理代谢模式在芳香烃类化合物污染修复领域具有巨大的应用潜力。电活性微生物可以通过还原脱卤、脱硝与氧化开环过程相结合的方式,最终实现芳香烃类污染物的降解矿化。本文重点综述了电活性微生物降解芳香烃类污染物过程中主要还原/氧化反应机理,归纳了电活性微生物高效还原脱卤、脱硝的关键酶活、代谢途径及转化机理,分析了不同含氧条件下电活性微生物开环方式及降解代谢途径,并通过调控微生物胞外聚合物与添加导电材料等途径来提升电活性微生物的胞外电子传递过程,总结了电极电位、电极材料、电解液性质及温度等环境因子对芳香烃类化合物降解的影响,探讨了芳香烃类污染物的强化生物降解策略的可行性。最后,展望了电活性微生物降解技...     

群感效应对电活性微生物胞外电子传递的影响

群感效应（quorum sensing,QS）是微生物之间以信号分子受体蛋白感知信号浓度变化,从而调控菌群的行为及功能,使其适应环境变化的信号通讯机制。电活性微生物（electroactive microorganisms,EAMs）能进行胞外电子传递,在可再生能源利用和环境修复方面具有广阔的应用前景。近年来,关于QS在EAMs胞外电子传递中的作用的研究日益增多。本文总结了QS对纯EAMs或混合产电菌群的直接或间接电子传递的影响效应及机制,阐述了基于QS的EAMs逻辑与门的构建及其应用前景,并从机制研究的角度展望其未来发展方向。     

一株假单胞菌(Pseudomonas sp．)产生的胞外脂酶

假单胞菌(Psendomonas sp．)生长在一定的培养条件中能产生胞外脂酶。 最适碳源为1．0％淀粉,氮源为1．0％蛋白胨。一些植物油,如橄榄油、糠油、菜油等能诱导脂酶的大量产生,诱导脂酶产生的橄榄油最适浓度为0．5％。无机离子在菌培养过程中对脂酶产率影响很大,K+、Na+、Mg2+、Ca2+等对脂酶产生有促进作用,而Mn2+、Ba2+、Zn2+、Fe3+、Co2+、Cu2+件等则抑制脂酶产生。非离子表面活性剂(tween、span及糖脂)能刺激胞外脂酶的产生。     

促进电活性微生物产电呼吸能力的方法研究进展

产电呼吸是指电活性微生物(electroactive microorganisms,EAMs)以胞外固体电极作为电子受体的一种呼吸形式,在可再生能源利用和环境修复方面具有广阔的应用前景。能否进一步提高EAMs的产电呼吸能力是相关技术能否从实验室走向实际应用的核心,而提高产电呼吸能力的关键是加强EAMs与胞外固体电极间的电子传递能力。目前总结如何促进EAMs产电呼吸能力的综述文献极少。因此,本文从投加化学试剂、施加物理作用及改造生物基因3个方面总结了现有的促进EAMs产电呼吸能力的方法,介绍了每种方法的优势与缺陷,重点阐述了每种手段的作用机理及促进效果,并从实际应用和机理研究的角度展望了今后的研究方向。     

4株高效产电菌的电化学活性及其生物学特征

采用循环伏安法对从湖南省吉首大田湾污水处理厂曝气池活性污泥中富集和筛选的37株产电菌的电化学活性进行考察。结果发现,4株菌株（F012、F015、F021、F026）的电化学活性较为显著,其中F026的电化学活性最好。对4株产电菌的系统发育分析表明,菌株F012属于Dyella属,与Dyella marensis CS5-B2^T系统发育关系最为密切（相似性为97.22%）;菌株F015属于Paludibacterium属,与该属的Paludibacterium yongneupense 5YN8-15^T系统发育关系最为密切（相似性为97.70%）;菌株F021和F026都属于Pseudomonas属,分别与该属的Pseudomonas simiae OLi^T和Pseudomonas otitidis MCC10330^T系统发育关系最为密切（相似性分别为99.60%和98.62%）。生物学特性研究表明,电化学活性最好的产电菌F026的生长温度范围为20~40 ℃,最适宜生长温度为30~35 ℃;生长pH范围为5~9,最适pH生长范围为8~9,适合作为微生物燃料电池的高效产电菌。     

靶向铜绿假单胞菌(Pseudomonas aeruginosa)粘肽合成酶PBP3的抗菌先导化合物的虚拟筛选及活性研究

【目的】开发出与铜绿假单胞菌粘肽合成酶PBP3有高亲和力,具有全新结构的先导化合物。【方法】以铜绿假单胞菌粘肽合成酶PBP3为靶点,通过分子对接软件DOCK6.5,对含有104万个小分子化合物的数据库进行了大规模虚拟筛选,选取结构相对简单的中选化合物进行合成,得到先导化合物,并验证其抑菌活性。【结果】通过grid score进行第一轮初筛,筛选出grid score分值小于–30 kcal/mol的6万个化合物,接着以amber score进行第二轮筛选,筛出amber score分值小于–20 kcal/mol的化合物约200个。最终,经过观察分析,从中挑选出4种打分高并且结构新颖的小分子化合物作为先导化合物。合成出的先导化合物及其衍生物对铜绿假单胞菌等常见微生物的最小抑菌浓度(MIC)在175–275μg/m L之间,对革兰氏阴性菌和阳性菌均有效,MIC值比作为阳性对照的磺胺嘧啶更低,说明先导化合物具有较好的抗菌活性。【结论】这些先导化合物可以进一步开发为新型抗菌药物,用于解决铜绿假单胞菌的耐药性问题。     

一株红假单胞菌的分离及生理特性研究

光合细菌在水处理和水生态修复领域应用前景广阔,对其生理特性研究具有重要价值。从武汉东湖分离得到一株不产氧光合细菌PUF1,通过对菌落形态、细胞超微结构、特征吸收光谱以及系统发育等分析,初步确定为红假单胞菌属(Rhodopseudomonas sp.)紫色非硫光合细菌。PUF1细胞呈直的或稍弯曲的杆状,长3.05—10.06μm,直径0.32—0.68μm,具有片层膜结构。PUF1培养物呈深紫红色,主要色素为细菌叶绿素a(Bchl. a)和类胡萝卜素。初始pH 6.0—8.0,光照强度500—3000 lx,稳定期细菌生物量无显著差异,但培养液pH>8.0会显著抑制PUF1最大光量子产量(Fv/Fm)。试验进一步研究了细菌不同生长阶段粗蛋白含量、ATP酶(ATPase)活性及Fv/Fm的变化规律。结果表明, PUF1不同生长阶段其蛋白含量有所差异,以稳定期为最高(>60%),而ATPase活性随培养时间的延长而逐渐降低。此外, PUF1光合作用与其生长状态也有一定的关系,具体表现为细菌生长周期内Fv/Fm变化规律适用单峰高斯模型,且以对数期Fv/Fm为最高。研究结果可为光合细...     

Isolation and Characterization of Group II Introns from Pseudomonas alcaligenes and Pseudomonas putida

Group II introns isolated from Pseudomonas alcaligenes NCIB 9867, Pseudomonas putida NCIB 9869, and P. putida KT2440 were closely related with nucleotide sequence identities of between 87 and 96%. The genome of P. alcaligenes also harbored a truncated group II intron of 682 bp that lacks the gene for the intron-encoded protein (IEP). Unlike most bacterial group II introns, the Pseudomonas introns were found to lack the Zn domains in their IEPs, did not appear to interrupt any genes, and were located downstream of open reading frames which were adjacent to hairpin loop structures that resemble rho-independent terminators. These structures also contain the intron binding sites 1 and 2 (IBS1 and IBS2 sequences) that were required for intron target site recognition in transposition. One of the group II introns found in P. alcaligenes, Xln3, was shown to have transposed from the chromosome to the endogenous pRA2 plasmid at a site adjacent to IBS1- and IBS2-like sequences.     

合成生物学方法构建电活性大肠杆菌

电活性微生物具有独特的在细胞内外环境之间传递电子的能力。在对天然电活性微生物电子传递机制充分研究的基础上,通过合成生物学方法异源构建天然电活性微生物电子传递结构基础也可以将遗传背景清晰的非电活性大肠杆菌改造为电活性微生物。构建获得的工程化电活性大肠杆菌可以直接应用于微生物燃料电池和生物传感器等领域,同时也可以作为底盘细胞整合相应的目标产物合成通路实现电能驱动的生物合成。本文以合成生物学方法构建电活性大肠杆菌为主题,详细阐述天然电活性微生物电子传递的机理及结构基础,总结了工程化电活性大肠杆菌的构建策略、成功案例以及应用领域,并对合成生物学方法构建电活性大肠杆菌未来的研究方向进行了展望。     

人工电活性微生物菌群的设计与应用

包括产电菌群和噬电菌群的人工电活性微生物菌群(synthetic electroactive microbial consortia)通过菌种间的物质能量级联反应介导化学能与(光)电能间的相互转化，其可利用底物来源广泛、双向电子传递速率快、环境稳定性强，在清洁电能开发、废水处理、环境修复、生物固碳固氮以及生物燃料、无机纳米材料、高聚物等高值化学品合成等多个领域具有广泛的应用前景。针对人工电活性微生物菌群设计、构建与应用，本文总结电活性微生物菌群界面电子传递和种间电子传递机制，概括基于“劳力分工”原理设计构建人工电活性微生物菌群物质能量级联反应基本架构，总结菌群关系与菌群生态位优化等人工电活性微生物菌群工程化策略，分类列举人工电活性微生物菌群在利用廉价生物质产电、生物光伏固碳产电，光驱噬电生物菌群固氮等相关应用。最后对人工电活性微生物菌群未来研究方向进行了展望。     

Biodegrading of pyrene by a newly isolated Pseudomonas putida PL2

Polycyclic aromatic hydrocarbons (PAHs) are a class of persistent organic compounds derived from natural sources and anthropogenic processes, which have been recommended as priority pollutants. Degradation of PAHs in the environment is becoming more necessary and urgent. In the current study, strain PL2, which is capable of growing aerobically on pyrene (PYR) as the sole carbon source, was isolated from hydrocarbons-contaminated soil and then identified as Pseudomonas putida by morphological and physiological characteristics as well as 16S rDNA sequence. The strain PL2 was able to degrade 50.0% of the pyrene at 28°C within 6 days in the presence of 50 mg/L pyrene, while the strain PL2 degraded 50.0% of the pyrene within 2 days when a solution of 50 mg/L pyrene and 50 mg/L phenanthrene was used. In addition, phenanthrene was shown to increase the biodegradation efficiency of pyrene by the strain PL2. The order of degradation by the strain PL2 was pH 6.0 > pH 7.0 > pH 5.0 > pH 8.0. The degradation rate of PYR in the soil by the strain PL2 reached 70.0% at the 10^th day. The dynamics of PYR degradation in soil by PL2 was fit to the first order model and the strain PL2 was shown to efficiently degrade PYR in soil. The current study showed that P. putida PL2 was a novel bacterium that could degrade pyrene and holds great promise for use in PAHs bioremediation in soil.     

Potential regulates metabolism and extracellular respiration of electroactive Geobacter biofilm

Dissimilatory metal reducer Geobacter sulfurreducens can mediate redox processes through extracellular electron transfer and exhibit potential-dependent electrochemical activity in biofilm. Understanding the microbial acclimation to potential is of critical importance for developing robust electrochemically active biofilms and facilitating their environmental, geochemical, and energy applications. In this study, the metabolism and redox conduction behaviors of G. sulfurreducens biofilms developed at different potentials were explored. We found that electrochemical acclimation occurred at the initial hours of polarizing G. sulfurreducens cells to the potentials. Two mechanisms of acclimation were found, depending on the polarizing potential. In the mature biofilms, a low level of biosynthesis and a high level of catabolism were maintained at +0.2 V versus standard hydrogen electrode (SHE). The opposite results were observed at potentials higher than or equal to +0.4 V versus SHE. The potential also regulated the constitution of the electron transfer network by synthesizing more extracellular cytochrome c such as OmcS at 0.0 and +0.2 V and exhibited a better conductivity. These findings provide reasonable explanations for the mechanism governing the electrochemical respiration and activity in G. sulfurreducens biofilms.     

PHAMCL biosynthesis systems in Pseudomonas aeruginosa and Pseudomonas putida strains show differences on monomer specificities

The production of PHA from plant oils by Pseudomonas species soil isolated from a sugarcane crop was evaluated. Out of 22 bacterial strains three were able to use efficiently plant oils to grow and to accumulate PHA. Pseudomonas putida and Pseudomonas aeruginosa strains produced PHA presenting differences on monomer composition compatible with variability on monomer specificity of their PHA biosynthesis system. The molar fraction of 3-hydroxydodecanoate detected in the PHA was linearly correlated to the oleic acid supplied. A non-linear relationship between the molar fractions of 3-hydroxy-6-dodecenoate (3HDdΔ₆) detected in PHA and the linoleic acid supplied was observed, compatible with saturation in the biosynthesis system capability to channel intermediate of β-oxidation to PHA synthesis. Although P. putida showed a higher 3HDdΔ₆ yield from linoleic acid when compared to P. aeruginosa, in both species it was less than 10% of the maximum theoretical value. These results contribute to the knowledge about the biosynthesis of PHA with a controlled composition from plant oils allowing in the future establishing the production of these polyesters as tailor-made polymers.