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。     

一株可增强莱茵衣藻耐盐能力细菌MEZX29的分离与鉴定

【背景】水体中的藻类、细菌及这些微生物之间的相互作用对水体生态系统的功能有着重要作用。近年来,一些河流、湖泊等淡水资源的盐渍化不断加重,对水体生态系统造成严重影响。然而,高盐胁迫条件如何影响藻类与其他细菌的相互作用,以及是否存在能够促进藻类耐盐能力的有益细菌等问题尚未得到深入研究。【目的】分离和鉴定可以促进淡水藻类莱茵衣藻抗盐能力的细菌,并开展相关机制分析。【方法】通过富集培养、筛选和共接种实验,获得可以促进衣藻耐盐的细菌;基于活细胞浓度、叶绿素含量等参数评价衣藻在不同条件下的生长能力;对菌株进行16S rRNA基因序列分析和基因组分析,预测其可能的菌藻相互作用机制。【结果】获得一株在250-290 mmol/L NaCl条件下可以显著增强衣藻耐盐能力的菌株MEZX29,16S rRNA基因序列分析表明,该菌可能属于Rhodococcus qingshengii;基因组分析结果表明,该细菌含有参与糖代谢、乙烯合成、生物膜形成等途径的基因,这些基因可能在促进衣藻抗盐过程中起到重要作用。【结论】Rhodococcus qingshengiiMEZX29可以增强莱茵衣藻21gr抵抗高盐胁迫的能力,为研究藻类与其他微生物之间的有益相互作用提供了新的材料。     

维生素B12的生物合成、发酵生产与应用

维生素B12(VB12)是一种重要的动物和人类营养因子, 广泛应用于饲料、食品和医药卫生领域。中国已成为全球VB12的主要产地, 2007年产量为27 t, 占全球总产量的77%。VB12是目前已发现的最大、最复杂的维生素分子, 化学合成极其困难, 所有VB12产品均采用生物发酵制备其主体结构。VB12主要由古生菌和一些真细菌通过有氧或厌氧两种途径合成, 工业上主要采用费式丙酸菌(Propionibacterium freudenrechii）和脱氮假单胞菌(Pseudomonas denitrificans)进行发酵生产。综述了VB12的基本性质, 生物合成途径, 以及发酵生产工艺, 并对VB12的应用与市场前景作了分析。     

水生生物的紫外光防护剂--类菌胞素氨基酸

类菌胞素氨基酸（mycosporine—like amino acids,MAAs）是一大类以环己烯酮为基本骨架,与不同类型氨基酸通过缩合作用形成的水溶性物质。它能在真菌、海洋细菌、蓝藻和真核藻类细胞中合成,并在海生无脊椎动物和鱼类等生物体内积累,广泛存在于多种水生生物中。它具有紫外光防护、渗透、繁殖调节及发育保护等功能。本文主要介绍有关类菌胞素氨基酸的分布、结构、生物合成和积累以及生理功能的研究进展。     

维生素B12的生物合成、发酵生产与应用

维生素B12(VB12)是一种重要的动物和人类营养因子, 广泛应用于饲料、食品和医药卫生领域。中国已成为全球VB12的主要产地, 2007年产量为27 t, 占全球总产量的77%。VB12是目前已发现的最大、最复杂的维生素分子, 化学合成极其困难, 所有VB12产品均采用生物发酵制备其主体结构。VB12主要由古生菌和一些真细菌通过有氧或厌氧两种途径合成, 工业上主要采用费式丙酸菌(Propionibacterium freudenrechii）和脱氮假单胞菌(Pseudomonas denitrificans)进行发酵生产。综述了VB12的基本性质, 生物合成途径, 以及发酵生产工艺, 并对VB12的应用与市场前景作了分析。     

水生生物的紫外防护剂——类菌胞素氨基酸

类菌胞素氨基酸(mycosporine-like amino acids, MAAs)是一大类以环己烯酮为基本骨架, 与不同类型氨基酸通过缩合作用形成的水溶性物质。它能在真菌、海洋细菌、蓝藻和真核藻类细胞中合成, 并在海生无脊椎动物和鱼类等生物体内积累, 广泛存在于多种水生生物中。它具有紫外光防护、渗透、繁殖调节及发育保护等功能。本文主要介绍有关类菌胞素氨基酸的分布、结构、生物合成和积累以及生理功能的研究进展。     

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。     

Ca~(2+)结合蛋白Rcn2的生理学功能

Rcn2(Reticulocalbin2)是一种普遍存在于哺乳动物细胞中的分泌蛋白,它不仅是细胞维持正常生理功能所必需的,更参与了肿瘤细胞的生长侵袭,并且与动脉粥样硬化易感基因、乳头瘤病毒结合蛋白E6、丝氨酸/苏氨酸激酶40、维生素D受体等生物分子相互作用,在动脉粥样硬化、宫颈癌、维生素D吸收异常等疾病中发挥着重要的调控作用。该文就Rcn2对人乳头瘤病毒、Taipoxin蛇毒摄入突触机制、SOC钙离子通道、EGFR-ERK信号通路、ERK-MAPK信号通路的影响及分子作用机制等方面的最新研究进行概述,总结了Rcn2及其相互作用分子的重要功能,为结直肠癌、肝癌、动脉粥样硬化等疾病的诊断和治疗提供重要的科学依据。     

小球藻病毒的分离

真核藻类作为一类重要的淡水和海洋水生生物与人类和环境有密切关系。在生态学上,藻类作为普通食物链中的原初生产者,在水环境中显得尤为重要,可作为许多水生生物的食物,也可使水域在一定范围内自净。藻类还极有希望成为人类新的食物来源和能源。但藻类的过量繁殖可引起严重的水污染。因此,搞清真核藻类与其寄生物—真核藻类病毒的关系,对维持藻类的生态平衡,控制利用藻类资源意义重大。对真核藻类病毒的深入研究已揭示出这类病毒在自然界的广泛存在。到目前为止,已报道发现的真核藻类病毒或病毒状颗粒(Virus—like particle)至少有44种,但多数仅限于电镜观察。直到病毒裂解性小球藻的发现,才使得对真核藻类病毒的研究提高到一个新水平,也使该领域的研究越来越受到人们的关注,国际上已开展真核藻类病毒研究的国家有美国、日本,德国等,我国在该领域的研究尚属空白。在国内开展真核藻类病毒的研究,首先要深入地调查我国的真核藻类病毒资源,同时可阐明一类新的病毒——寄主关系的分子生物学基础,了解诸如病毒基因组在寄主细胞中的表达调控,为研究高等植物基因的表达调控提供一个适宜的模型。另外,由于已知的真核藻类病毒具有相当大的基因组,可预见其基因…     

青海地区不同品种青稞中B族维生素含量分布

利用HPLC法对青海不同产地的15个不同品种青稞中6种B族维生素质量分数进行了测定.结果表明:15个不同品种的青稞,除叶酸(未检出)、VB12(含量较少)外,其余4种所测B族维生素含量均较丰富.其中称多产的二道眉黑青稞VB总量最高,可达0.10842 mg·g-1,民和产的长芒黄脉青稞VB总量最低,为0.03892 m...     

Influence of metazooplankton on interactions of bacteria and phytoplankton in an oligotrophic lake

Commensalism based on organic carbon supplied by phytoplanktonand competition for mineral nutrients are important interactionsbetween bacteria and phytoplankton in oligotrophic clear-watersystems. Both interactions are influenced by zooplankton activity.To examine the relation ship between algae and bacteria in LakeLa Caldera, we studied: the correlations among phyto plankton,bacteria and phosphorus (P) dynamics; the ratio of organic carbonsupplied by algae to organic carbon demand by bacteria; andthe importance of P remineralized by metazooplankton for bothcommunities. Phytoplankton and bacteria had a similar seasonaldynamics, and there was a sig nificant and positive relationshipbetween bacterial abundance and algal biomass (P<0.01). However,the release of organic carbon from phytoplankton was usuallyhigher than the bacterioplankton carbon requirement. P availablevia zooplankton remineralization satisfied between 74 and 316%of the minimum P demands of algae and bacteria. To elucidatewhether zooplankton operate similarly on algae and bacterialgrowth or indirectly influence bacterial growth through phytoplanktonmetab olism, we performed zooplankton manipulation experiments.High zooplankton biomass in these experiments stimulated bothprimary and bacterial production, but release of organic carbonfrom phytoplankton declined. These results suggest a directstimulus of bacterial growth, so algae and bac teria can balancegrazing losses by compensatory growth. Further, the algal decreaseof the organic carbon supply for bacteria could, over time,lead to a change in the algae-bacteria interaction from competitionto commensalism. This reduction in organic carbon excretioncould affect the balance of the competitive interaction.     

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。     

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。     

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。     

Interactions between the diatom Thallasiosira pseudonanna and an associated pseudomonad in a mariculture system.

The marine diatom Thallasiosira pseudonanna (3H) and several bacteria associated with it were isolated from batch cultures at the University of Delaware mariculture facility. The interaction between the algae and each of the bacteria was investigated. One of the isolates, T827/2B (Pseudomonas sp.), was incapable of surviving in f/2 culture medium unless the algae were present. When the algae and T827/2B were grown together in the f/2 medium, the bacterial growth was stimulated and the algal growth was inhibited. Bacterial filtrate had a similar effect on the algae, indicating that the bacterial effect is an indirect one most likely resulting from the excretion of a harmful compound into the medium. Preliminary characterization of the material excreted by the bacteria indicates that it s proteinaceous in nature. The interactions observed does not fit into any single category of interactions but can be explained as a combination of competition and indirect parasitism.     

Interactions between the diatom Thallasiosira pseudonanna and an associated pseudomonad in a mariculture system

The marine diatom Thallasiosira pseudonanna (3H) and several bacteria associated with it were isolated from batch cultures at the University of Delaware mariculture facility. The interaction between the algae and each of the bacteria was investigated. One of the isolates, T827/2B (Pseudomonas sp.), was incapable of surviving in f/2 culture medium unless the algae were present. When the algae and T827/2B were grown together in the f/2 medium, the bacterial growth was stimulated and the algal growth was inhibited. Bacterial filtrate had a similar effect on the algae, indicating that the bacterial effect is an indirect one most likely resulting from the excretion of a harmful compound into the medium. Preliminary characterization of the material excreted by the bacteria indicates that it s proteinaceous in nature. The interactions observed does not fit into any single category of interactions but can be explained as a combination of competition and indirect parasitism.     

Chlamydomonas reinhardtii thermal tolerance enhancement mediated by a mutualistic interaction with vitamin B12-producing bacteria

Temperature is one of the most important environmental factors affecting the growth and survival of microorganisms and in light of current global patterns is of particular interest. Here, we highlight studies revealing how vitamin B₁₂ (cobalamin)-producing bacteria increase the fitness of the unicellular alga Chlamydomonas reinhardtii following an increase in environmental temperature. Heat stress represses C. reinhardtii cobalamin-independent methionine synthase (METE) gene expression coinciding with a reduction in METE-mediated methionine synthase activity, chlorosis and cell death during heat stress. However, in the presence of cobalamin-producing bacteria or exogenous cobalamin amendments C. reinhardtii cobalamin-dependent methionine synthase METH-mediated methionine biosynthesis is functional at temperatures that result in C. reinhardtii death in the absence of cobalamin. Artificial microRNA silencing of C. reinhardtii METH expression leads to nearly complete loss of cobalamin-mediated enhancement of thermal tolerance. This suggests that methionine biosynthesis is an essential cellular mechanism for adaptation by C. reinhardtii to thermal stress. Increased fitness advantage of METH under environmentally stressful conditions could explain the selective pressure for retaining the METH gene in algae and the apparent independent loss of the METE gene in various algal species. Our results show that how an organism acclimates to a change in its abiotic environment depends critically on co-occurring species, the nature of that interaction, and how those species interactions evolve.     

Mutualistic interactions between vitamin B(12) -dependent algae and heterotrophic bacteria exhibit regulation

Many algae are auxotrophs for vitamin B₁₂ (cobalamin), which they need as a cofactor for B₁₂‐dependent methionine synthase (METH). Because only prokaryotes can synthesize the cobalamin, they must be the ultimate source of the vitamin. In the laboratory, a direct interaction between algae and heterotrophic bacteria has been shown, with bacteria supplying cobalamin in exchange for fixed carbon. Here we establish a system to study this interaction at the molecular level. In a culture of a B₁₂‐dependent green alga Chlamydomonas nivalis, we found a contaminating bacterium, identified by 16S rRNA analysis as Mesorhizobium sp. Using the sequenced strain of M. loti (MAFF303099), we found that it was able to support the growth of B₁₂‐dependent Lobomonas rostrata, another green alga, in return for fixed carbon. The two organisms form a stable equilibrium in terms of population numbers, which is maintained over many generations in semi‐continuous culture, indicating a degree of regulation. However, addition of either vitamin B₁₂ or a carbon source for the bacteria perturbs the equilibrium, demonstrating that the symbiosis is mutualistic and facultative. Chlamydomonas reinhardtii does not require B₁₂ for growth because it encodes a B₁₂‐independent methionine synthase, METE, the gene for which is suppressed by addition of exogenous B₁₂. Co‐culturing C. reinhardtii with M. loti also results in reduction of METE expression, demonstrating that the bacterium can deliver the vitamin to this B₁₂‐independent alga. We discuss the implications of this for the widespread distribution of cobalamin auxotrophy in the algal kingdom.     

Interactions between metazoans,autotrophs, mixotrophs and bacterioplankton in nutrient‐depleted high DOC environments: a long‐term experiment

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微藻与细菌作用关系的研究进展

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