海洋中藻菌相互关系及其生态功能

海洋中藻类与细菌密不可分,具有错综复杂的互作关系(如互利共生、敌对拮抗或竞争抑制等),共同构成了海洋生态系统结构与功能的重要调控者。在藻类细胞周围往往存在着特殊的藻际微环境,其中生存着独特的微生物群落,因此藻际环境成为藻菌相互作用的主战场。藻际环境中细菌群落的构建具有一定的规律。在自然生态系统中,藻菌互作影响赤潮生消动态过程,并在水质修复中具有重要作用潜力。同时,藻类和细菌作为驱动海洋固碳与储碳的主要生物因子,在海洋碳循环中具有尤为重要的作用。本文对海洋中藻菌互作关系的研究现状进行了综述,并在此基础上,对未来研究提出了几点展望。例如,目前对海洋中藻菌关系受病毒的调控作用了解甚少,值得未来深入研究。     

微藻-细菌共生体系在废水处理中的应用

在微藻-细菌协同共生的过程中,藻类光合作用释放的氧气被异养微生物利用来矿化水体中的污染物,细菌呼吸为藻类提供二氧化碳作为碳源。近年来,藻类-细菌协同共生体系在污水处理中的应用得到了广泛的研究。本文重点综述了菌藻协同共生体系中微藻与细菌之间的三种相互作用,以及菌藻协同共生体系在废水处理中的应用。菌藻协同共生体系中的微藻与细菌通过营养交换、信号转导及基因转移等相互作用实现共赢。该体系广泛用于处理富营养化、重金属、药物、多环芳烃(polycyclicaromatic hydrocarbons,PAHs)、石油烃化合物等难降解的有机污染的水体。对于氮、磷等营养物质的去除,其主要机理涉及同化作用、厌氧氨氧化作用、硝化与反硝化作用、磷酸化作用等。对重金属、药物、石油烃化合物及其他有机化合物的去除机制主要是生物吸附、生物富集及细胞内外的生物降解。     

藻际环境中胞外聚合物的研究进展

微藻向细胞周围释放营养物质而形成了独特的藻际微环境,吸引了大量细菌的定殖。藻际环境中藻菌关系错综复杂,其间充斥着多样的物质交换与信息交流。以胞外聚合物(extracellularpolymeric substances,EPS)为代表的有机质在其中起着纽带作用。微藻和细菌都可以产生EPS,其过程受多种因素的调节。EPS在藻际环境中具有重要的生态功能,包括参与生物被膜(biofilm)的形成,影响藻菌共生关系的建立以及调节藻际微生物群落组成等。此外,EPS中的一大类别透明胞外聚合物颗粒(transparent exopolymer particles,TEP)还介导了海洋溶解有机碳向颗粒有机碳的转化,参与了海洋碳循环过程。本文以EPS的产生、组成以及对碳转化的影响为重点,综述了其在藻际生态位(Niche)中的生态功能,以期为深入理解藻际环境中的有机质特征和藻菌共生关系提供理论依据。     

杜氏盐藻促生菌株的分离与鉴定

拟通过探究藻际微生物对微藻生长及代谢产物积累的影响,筛选出促进微藻生长的促生菌株。以杜氏盐藻(Dunaliella salina)Ds-SXYC-2为试材,分离鉴定盐藻藻际环境中的共生菌株,进一步构建藻菌(1∶1)共培养体系、测试盐藻生长及代谢产物积累等表型。结果显示,从杜氏盐藻藻际环境分离获得5株共生菌株,经16S rDNA分子鉴定,属于3个菌属。菌株B1与B2为涅斯捷连科氏菌(Nesterenkonia),菌株B3与B4为盐单胞菌(Halomonas),菌株B5为海杆菌(Marinobacter)。5株共生菌株对杜氏盐藻的生长均有促进作用,菌株B3能显著促进杜氏盐藻生长及代谢产物的积累。共培养15 d后,杜氏盐藻生物量达到2.3 g/L,比对照组增加了28.9%,叶绿素a的含量达到4.61 mg/L,比对照组增加了36.3%,β-胡萝卜素比对照组提高了56.4%。盐藻多糖、蛋白质、总脂含量分别比对照组增加了34.8%、71.2%和37.6%。菌株B3盐单胞菌可以作为促进杜氏盐藻生长及代谢产物累积的优势菌株,进一步构建共培养体系可应用于杜氏盐藻的商业生产。     

纤毛虫与藻类共生关系的研究现状与展望

纤毛虫与藻类的共生关系在水体环境中广泛存在并有着重要的生态功能。文章回顾了国内外纤毛虫与藻类共生研究的发展历程,主要介绍了纤毛虫与藻类共生的生态功能,以及显微观察与分子生物学技术在纤毛虫与藻类共生研究中的应用;阐述了包括草履虫与小球藻共生关系建立的4个过程及其互作机制、红色中缢虫与隐藻的共生关系、宿主与共生体之间的互作等内容;提出了纤毛虫与藻类共生研究中亟待解决的科学问题,包括草履虫食物泡膜(digestive vacuole, DV)与围藻膜(perialgal vacuole, PV)发挥作用的分子机制、红色中缢虫与隐藻共生关系的建立过程、红色中缢虫在共生过程中的功能作用等,并展望未来的研究方向。     

东海原甲藻和海洋异养细菌对磷酸盐的竞争吸收

在水生生态系统的研究中, 微型藻类与海洋细菌的相互关系越来越引起人们的重视。微型藻类是引起赤潮的主要生物, 其与海洋细菌的关系主要表现在藻、菌既可相互促进生长, 又可相互抑制以至于杀灭对方。这种复杂的生态关系因藻种及菌种的不同而异, 并受到环境等因素的影响。       

塔玛亚历山大藻藻际细菌溶藻过程

海洋微藻在生长过程中向周围环境分泌多种胞外产物,形成细菌自由生长的藻际环境,藻际细菌对微藻的生长有一定的调控作用。在指数生长期的塔玛亚历山大藻培养液中加入φ为1%的2216E培养基,在加入2216E后16h内藻细胞全部裂解。用数码显微镜记录了藻细胞形态变化,分别用DAPI法和荧光模拟底物法测定了细菌数量、胞外酶活性变化,结果表明:在溶藻过程中细菌数量、胞外酶活性在第6小时到第10小时增加了50～100倍。塔玛亚历山大藻藻际细菌主要分布在藻细胞表面,其群落结构改变和数量剧增是溶藻的主要原因,细菌分泌的β-葡萄糖苷酶和几丁质酶可能在溶藻过程中起重要作用。     

藻菌共生处理污水的机制与应用研究进展

在污水处理领域,藻菌共生有同步脱氮、除磷效率高、排放温室气体量低、生物质可资源化回收等优势,近年来受到学者的重视。目前鲜有综述污水处理中藻类与细菌、真菌及混合藻菌间互作机制的文章。本文从藻类-细菌、藻类-真菌、混合藻-混合菌3个方面介绍藻菌共生处理污水的研究进展,重点阐述藻菌间营养物质交换、信号传导及生物絮凝3种不同互作机制,总结污水处理中常见的藻菌共生生物反应器及其应用效果,并从互作机理研究、规模化应用及生物质回收利用的角度展望了今后的研究方向。     

锥状斯氏藻藻华期间群体感应信号菌株的动态变化

群体感应信号(quorum sensing, QS)是细菌的一种特殊交流方式, 它具有调节种群密度、生物膜形成、毒素产生以及色素的形成等多种功能。藻菌关系是藻华过程中重要的一环, 为了探求藻华过程中信号微生物的动态变化, 我们以深圳大鹏湾的锥状斯氏藻(Scrippsiella trochoidea)藻华中的QS 菌株为研究对象, 应用报告菌株和环境微生物宏基因组方法, 监测了藻华爆发期间信号微生物的动态变化过程, 并构建了藻类、QS 微生物与其它微生物的相关性关系。结果表明:在筛选的QS 菌株中经去冗余和重复后成功鉴定了7 种不同的细菌, 分别是冷杆菌Psychrobacter cryohalolentis、普罗维登斯菌Providencia sneebia、假单胞菌Pseudomonas stutzeri、微小杆菌Exiguobacterium sp. AT1b、产酸克雷伯菌Klebsiellaoxytoca、球形赖氨酸芽孢杆菌Lysinibacillus sphaericus 和鲍氏不动杆菌Acinetobacter baumannii。相关性分析发现P.sneebia 的丰度与藻类数量变化呈正相关, 而L. sphaericus 和P. stutzeri 的丰度与藻类数量变化呈负相关, 其它QS 微生物中未见显著相关性。综合实验的结果来看, QS 微生物在藻际微生物的群体结构中扮演着一定的生态作用, 它帮助我们从一个新的视角了解藻华过程中QS 微生物的丰度变化和网络关系, 为认识藻菌关系提供了新的思路。     

细菌DC10的溶藻作用及环境因子对该作用的影响

从云南滇池分离获得溶藻细菌DC₁₀, 该菌属于假单胞菌属(Pseudomonas sp.), 它能强烈地溶解绿色微囊藻(Microcystis viridis, FACHB 102)等6种蓝藻及月芽藻 (Selenastrum capricornutum, FACHB 271) 等2种绿藻. 试验发现, 该菌通过分泌某种物质来溶解藻类, 较低的温度以及黑暗条件有利于细菌溶藻, 不同浓度的氯化钙、硝酸钠对该菌的溶藻作用有一定影响; 不同pH条件下, 溶藻作用的强弱依次为: pH 4 > pH 9 > pH 7 > pH 5.5. 发展利用该菌进行水华控制的技术具有现实意义.     

Microalgae–bacteria symbiosis in microalgal growth and biofuel production: a review

Photosynthetic microalgae can capture solar energy and convert it to bioenergy and biochemical products. In nature or industrial processes, microalgae live together with bacterial communities and may maintain symbiotic relationships. In general interactions, microalgae exude dissolved organic carbon that becomes available to bacteria. In return, the bacteria remineralize sulphur, nitrogen and phosphorous to support the further growth of microalgae. In specific interactions, heterotrophic bacteria supply B vitamins as organic cofactors or produce siderophores to bind iron, which could be utilized by microalgae, while the algae supply fixed carbon to the bacteria in return. In this review, we focus on mutualistic relationship between microalgae and bacteria, summarizing recent studies on the mechanisms involved in microalgae–bacteria symbiosis. Symbiotic bacteria on promoting microalgal growth are described and the relevance of microalgae–bacteria interactions for biofuel production processes is discussed. Symbiotic microalgae–bacteria consortia could be utilized to improve microalgal biomass production and to enrich the biomass with valuable chemical and energy compounds. The suitable control of such biological interactions between microalgae and bacteria will help to improve the microalgae-based biomass and biofuel production in the future.     

赤潮过程中“藻-菌”关系研究进展

微生物对促进海洋物质循环,维持水生环境的生态平衡具有重要作用。在赤潮事件中,基于微生物(尤其是细菌)的多样性和重要性,它们与藻类之间的相互关系成为了研究的热点。过去20年里,人们从不同角度对"藻-菌"间的关系进行了探索,包括物理学过程、生物学过程、环境过程以及化学过程。就化学过程而言,它作为一种较早出现的技术,在以往的研究中带给人们许多认识藻菌关系的方法。随着学科的渗透,化学法有了拓展与延伸,为人们认识藻菌关系带来了新的契机。从化学生态学领域来梳理"藻-菌"关系中涉及的现象和行为,包括菌对藻的有益面、菌对藻的有害面、以及藻类应答细菌行为的化学途径;并从信号语言(群体感应、化感作用)的角度来阐释两者之间的互生或克生关系。通过文献综述的方式来解读藻菌关系的互作过程和机理,为认识赤潮的发生和防控方法提供借鉴。     

Quorum Sensing Is a Language of Chemical Signals and Plays an Ecological Role in Algal-Bacterial Interactions

Algae are ubiquitous in the marine environment, and the ways in which they interact with bacteria are of particular interest in the field of marine ecology. The interactions between primary producers and bacteria impact the physiology of both partners, alter the chemistry of their environment, and shape microbial diversity. Although algal-bacterial interactions are well known and studied, information regarding the chemical-ecological role of this relationship remains limited, particularly with respect to quorum sensing (QS), which is a system of stimuli and response correlated to population density. In the microbial biosphere, QS is pivotal in driving community structure and regulating behavioral ecology, including biofilm formation, virulence, antibiotic resistance, swarming motility, and secondary metabolite production. Many marine habitats, such as the phycosphere, harbor diverse populations of microorganisms and various signal languages (such as QS-based autoinducers). QS-mediated interactions widely influence algal-bacterial symbiotic relationships, which in turn determine community organization, population structure, and ecosystem functioning. Understanding infochemicals-mediated ecological processes may shed light on the symbiotic interactions between algae host and associated microbes. In this review, we summarize current achievements about how QS modulates microbial behavior, affects symbiotic relationships, and regulates phytoplankton chemical-ecological processes. Additionally, we present an overview of QS-modulated co-evolutionary relationships between algae and bacterioplankton, and consider the potential applications and future perspectives of QS.     

Allelopathic agents from aquatic ecosystems: potential biopesticides models

Allelopathy is usually regarded as a terrestrial science and little attention has been paid to the allelochemicals involved in the interactions between aquatic autotrophs. Also, chemicals involved in the interaction between algae (macro or microscopic) and their environment are not often acknowledged as allelopathic. Allelopathy is a key factor for explaining microalgae assemblages, community structure and the dynamics of the populations within the ecosystem. Herein we present an overview of what is known in this field, describing the chemicals yet identified and which kind of interactions are they involved in.     

珊瑚共生体中“细菌-虫黄藻-宿主”三角关系的通讯交流

“细菌-虫黄藻-珊瑚”是生态系统中一对经典的三角关系,其中包含着复杂的物质流、信息流和能量流,三者的平衡与稳定是维护珊瑚礁生态系统健康的重要保障。过去20年里针对共生体交互关系进行了大量研究,并取得了一些重要成果,明确了“细菌-虫黄藻-宿主”三者之间的物质代谢、营养交换以及与环境的交互关系。然而,基于共生系统的复杂性,一些现象背后的机制仍然未被充分揭示,尤其是共生体之间的通讯交流。信号分子介导的相互作用是珊瑚共生体稳态维持和高效运转的内在驱动力。本文以珊瑚共生体系中化学信号为重点,尝试梳理最新的研究进展,包括细菌与细菌、细菌与珊瑚、细菌与虫黄藻以及虫黄藻与珊瑚之间的通讯方式,重点关注了群体感应信号(QS)、二甲基巯基丙酸盐(DMSP)、糖类信号、脂类信号以及非编码RNA。选择性例举了QS信号介导的微生物协作和竞争、DMSP调节下的细菌和宿主的相互作用,以及环境胁迫下珊瑚和虫黄藻对非编码RNA的响应过程,强调了它们在共生体中的作用模式和生态意义。并对今后的研究重点和可能方向进行了提炼,包括研究维度的扩充、新技术-新方法的应用以及生态模型的构建等,旨在提升对三角关系互作方式的认识,增进对珊瑚共生体的理解,探索基于通讯语言的操纵方式为珊瑚礁生态系统的恢复和保护提供新思路。     

镉离子污染条件下微生物群落中细菌与藻类的相互作用

【背景】水体微生物有着丰富的多样性,不同种类的微生物之间的相互作用对水体生态系统的组成结构与功能具有重要影响。水体内的藻类与某些微生物可以发生多种相互作用,然而人们对逆境条件下的菌藻有益相互作用尚缺乏深入研究。【目的】为了研究镉对水体微生物群落的影响以及镉胁迫下菌藻之间可能的相互作用。【方法】本研究运用了基于16S rRNA基因的高通量测序技术,分析在不同Cd~(2+)条件下微生物群落结构的变化,利用微生物相互作用网络分析菌藻之间可能发生的相互作用。【结果】通过分离培养筛选出了与集胞藻PCC6803互作抗Cd~(2+)的关键细菌Y9菌株。【结论】研究结果表明Y9菌株属于Phyllobacteriaceae科,与微生物群落组成和微生物互作网络的分析结果相符。本研究为探索水体环境中微生物种间相互作用、菌藻互作抗Cd~(2+)的生态效应提供参考依据。     

The Hydra viridis/Chlorella symbiosis. Growth and sexual differentiation in polyps without symbionts

To investigate interactions between the basal metazoan Hydra viridis and its symbiotic Chlorella algae, we generated aposymbiotic hydra lacking algae and compared them to symbiotic ones with regard to growth and sexual differentiation. Under standard feeding conditions aposymbiotic polyps proliferated similarly to symbiotic polyps. Under moderate and low feeding conditions asexual growth was reduced in polyps lacking algae, indicating that the symbionts supply nutrients to their hosts. In addition, the Chlorella symbionts had a strong influence on the sexual reproduction of Hydra viridis: in most cases female gonads were produced only when symbiotic algae were present. Spermatogenesis proceeded similarly in symbiotic and aposymbiotic polyps. Since during oogenesis symbionts are actively transferred from endodermal epithelial cells to the ectodermal oocytes, this oogenesis promoting role could indicate that the symbionts are critically involved in the control of sexual differentiation in green hydra.     

The time delays influence on the dynamical complexity of algal blooms in the presence of bacteria

Bacteria associated with oceanic algal blooms are acknowledged to play important roles in carbon, nitrogen, and sulfur cycling. They influence the climate, mediate primary production, participate in biogeochemical cycles, and maintain ecological balance. A greater insight on the control of the interactions between microalgae and other microorganisms, particularly bacteria, would be helpful in exploring the role of bacteria on algal blooms in lakes. The present study is to investigate the effects of bacteria on the occurrence of algal blooms in lakes. We propose a nonlinear mathematical model by taking into account interactions among nutrients, algae, detritus and bacteria in a lake. We assume that bacteria enhance the growth of algal biomass through remineralization only. Equilibria are analyzed for feasibility and stability, substantiated via numerical simulations. Increase in uptake rate of nutrients by algae and bacteria death rate generates transcritical bifurcations. We perform a global sensitivity analysis to identify the important parameters of the model having a significant impact on the densities of algae and bacteria in the lake. Our findings show that massive algal production might occur in the presence of bacteria, and microalgae-bacteria interactions can be beneficial to the massive production of microalgae. Further, the effect of time delays involved in the bacterial decomposition conversion of detritus into nutrients is studied. Chaotic oscillations may arise via equilibrium destabilization on increasing the values of the time lag. To support chaos occurrence, the Poincaré map is drawn and the Lyapunov exponents are also computed. The findings, critically important for lake restoration, indicate that hypoxia in the lake can be prevented if detritus removal is performed on a regular basis, at time intervals smaller than the critical threshold in the delay with which detritus is decomposed into nutrients.     

Mild disintegration methods of microalgae–bacteria flocs from wastewater treatment

The use of microalgae in biological wastewater treatment has been widely studied. However, there is a dearth of information about estimating the microalgae and bacteria concentrations. In order to maintain a stable algal-bacterial system, it is necessary to quantify both the algal and bacterial biomasses. Typically, microalgae and bacteria from flocs in activated sludge contribute to better biomass settleability. However, flocs cause problems when it comes to estimating the individual biomass concentrations of microalgae and bacteria in a symbiotic algae-bacteria aggregate. This study aimed to find the best disintegration treatment with low influence on the viability of the microalgal cell determined by its photosynthetic activity. In the present work, biological (enzyme solution), chemical (formaldehyde), mechanical (glass bead-beating), and physical (sonication) treatments were performed on microalgae–bacteria flocs (ALBA flocs) to disintegrate the community as a pre-treatment step in order to develop a method for estimating the algal and bacterial concentration and to quantify the degree of disintegration. The effectiveness of the methods to disintegrate ALBA flocs in descending order are the following: sonication, bead-beating, formaldehyde and enzyme application. Sonication treatment (40 W, 6 min) showed the best disintegration performance of the microalgal-bacterial flocs, up to 90 % with 17 % loss of the algal photosynthetic activity. Bead-beating (3 mm diameter, 80 s) achieved 80 % of disintegration with only 6 % loss of its photosynthetic activity. These results demonstrate the possibility of mild disintegration of compact ALBA flocs without having any adverse impact on the microalgae cell. After these treatments, it becomes possible to estimate the individual biomass concentrations of algae and bacteria manually such as with a cell-counting chamber.     

Synergistic relationships in algal-bacterial microcosms for the treatment of aromatic pollutants

The potential of algal-bacterial microcosms was studied for the biodegradation of salicylate, phenol and phenanthrene. The isolation and characterization of aerobic bacterial strains capable of mineralizing each pollutant were first conducted. Ralstonia basilensis was isolated for salicylate degradation, Acinetobacter haemolyticus for phenol and Pseudomonas migulae and Sphingomonas yanoikuyae for phenanthrene. The green alga Chlorella sorokiniana was then cultivated in the presence of the pollutants at different concentrations, showing increasing inhibitory effects in the following order: salicylate < phenol < phenanthrene. The synergistic relationships in the algal-bacterial microcosms were clearly demonstrated, since for the three contaminants tested, a substantial removal (>85%) was recorded only in the systems inoculated with both algae and bacteria and incubated under continuous lighting. This study presents, to our knowledge, the first reported case of photosynthesis-enhanced biodegradation of toxic aromatic pollutants by algal-bacterial microcosms in a one-stage treatment.