细菌的信息交流

细菌与细菌之间的信息交流是通过相互交换一种自动诱导物(autoinducer)的信号分子来实现的。这种信息交换的过程被称为群体感应(quorumsystem)。细菌根据这种特定信号分子浓度的变化来监测环境中其它细菌数量的变化。细菌的群体感应系统分为种内和种间信息交流两大类。细菌间的信息交流涉及到细菌的多种生理功能,如细菌的致病能力等。因此研究细菌间的信息交流有可能找到一条新的防治细菌感染途径。     

细菌中群体感应调节系统

细菌根据特定信号分子的浓度可以监测周围环境中自身或其它细菌的数量变化,当信号达到一定的浓度阈值时,能启动菌体中相关基因的表达来适应环境中的变化,这一调控系统被称为细菌的群体感应调节系统(QuorumSensing系统)。本文系统介绍了细菌感知种内与种间数量的群体感应调节系统,并阐述了植物针对病原菌这一信号系统的抗病策略。     

环境因素对细菌群体感应的影响

一种海洋费氏弧菌(Vibrio fischeri)的发光现象在20世纪60年代引起了科学家的兴趣,Nealson等在1970年首次报道了该菌的菌体密度与发光呈正相关,该发光现象受细菌本身的群体感应调节系统所控制[1]。尽管细菌是单细胞原核生物,但是越来越多的研究发现细菌在自然环境中常常表现出多细胞的群体行为。细菌利用自诱导物进行相互交流并调控其群体行为的现象被称为群体感应(Quorum sensing,QS)[2],这个概念最早由Fuqua等     

细菌群体感应信号分子N-酰基高丝氨酸内酯的检测

群体感应是细菌生长到一定密度时相互感应,并进行基因表达及调控产生的独特、多样的群体行为现象。N-酰基高丝氨酸内酯(AHL)类化合物是革兰阴性菌群体感应中最重要的一类信号分子,调控许多生理特性基因的表达。快速、简便、有效地检测细菌能否产生AHL或产生何种信号分子,成为深入研究和了解细菌群体感应的重要手段。我们就细菌群体感应信号分子AHL检测的基本原理和方法及国内外研究进展进行了总结。     

细菌群体感应淬灭酶的研究进展

细菌的群体感应系统（Quorum sensing,QS）参与许多生物学功能的调控,其中包括动植物病原细菌致病因子的生成以及人类某些病原细菌生物膜的形成。酰基高丝氨酸内酯（N—acylhomoserine laetone,AHL）是调控群体感应系统的关键信号分子。近年的研究表明,不同生物体包括细菌和真核生物中都存在类别不同的能够降解AHL的群体感应淬灭酶（Quorum—quenching enzyme）。在AHL依赖型致病菌和转基因植物中表达AHL降解酶能有效地抑制QS信号分子的积累,从而阻断了病原细菌的发病机制,提高了植物的抗病性。这些新颖的群体感应淬灭酶的发现,不仅为防治细菌侵染提供了可行的途径,也对研究它们在宿主中的功能和对生态系统的潜在影响提出挑战。     

凡纳滨对虾源不动杆菌群体感应信号分子分离鉴定及其调控

【目的】鉴定凡纳滨对虾源不动杆菌(Acinetobacter spp.M1)分泌的N-酰基高丝氨酸内酯(AHLs)类型,探究细菌生长阶段及环境因素对其分泌信号分子的影响。【方法】报告菌株平板法检测M1的AHLs的活性;采用报告平板与薄层层析(TLC)相结合法对M1分泌的AHLs类型进行鉴定。【结果】菌株M1分泌N-3-氧代-己酰基-高丝氨酸内酯和N-3-氧代-辛酰基-高丝氨酸内酯两种信号分子。在适宜条件下AHLs活性随着培养时间的延长先升高后降低,在对数末期(30 h)达到最大。弱酸和弱碱环境能够降低M1分泌AHLs的能力,p H 7.0是M1分泌AHLs的最适p H。较高浓度的Na Cl促进了个体M1分泌AHLs的能力,但是Na Cl浓度对M1总体分泌AHLs没有显著的影响。菌株M1分泌AHLs的最佳温度为30°C,温度过高或过低都会影响其分泌。【结论】菌株M1主要产生N-3-氧代-己酰基-高丝氨酸内酯和N-3-氧代-辛酰基-高丝氨酸内酯两种类型信号分子。M1的QS系统受菌体密度和环境因素的双重调控。     

一株降解N-酰基高丝氨酸内酯酵母菌菌株的分离鉴定及其降解特性

利用N酰基高丝氨酸内酯(N-acyl-homoserine lactone,简称AHL)为唯一碳源和能源,筛选得到一株能够降解AHL的菌株R1。常规鉴定和18S rDNA序列分析表明,菌株R1属于红冬孢酵母菌(Rhodosporidium toruloides),定名为R.toruloidesR1。结果显示R.toruloidesR1能利用所测试的3种AHL作为唯一碳源和能源生长,具有降解AHL的能力,其对AHL依赖型胡萝卜欧文氏软腐病菌(Erwinia carotovora subsp.carotovora)的致病有一定的抑制作用。     

群体感应信号分子及其抑制剂快速检测方法的建立

细菌能自发产生、释放一些特定的信号分子,并能感知其浓度变化,调节微生物的群体行为,这一调控系统称为群体感应。细菌群体感应参与包括人类、动植物病原菌致病力在内的多种生物学功能的调节,群体感应抑制剂成为抗感染药物开发的靶点。利用紫色色杆菌(Chromobacterium violaceum)和根癌农杆菌(Agrobacterium tumefaciens)作为指示菌,建立检测高丝氨酸内酯(AHLs)及其抑制剂的简便方法。结果表明,通过平板交叉划线接种,使用指示菌能够有效地检测AHLs,并且通过薄层层析(TLC)与细菌生物感应器相结合的方法可以快速、方便地鉴定AHLs的种类;通过双层平板法观察指示菌色素产生情况,能够有效地检测群体感应信号分子AHLs抑制剂,且该方法简单易行。     

土壤中群体感应淬灭细菌的原位分离与筛选

【背景】许多革兰氏阴性细菌通常以N-酰基高丝氨酸内酯(N-acylhomoserine lactones,AHLs)作为群体感应主要的信号分子。【目的】从土壤中筛选和鉴定新型群体感应淬灭细菌。【方法】通过"垫圈法"从土壤中原位培养分离细菌,采用琼脂条法、报告菌平板法及β-半乳糖苷酶活性测定筛选群体感应淬灭细菌,根据16S rRNA基因序列同源性分析确定菌株系统发育地位。【结果】从不同地区土样中原位培养共分离获得细菌502株。以根癌土壤杆菌Agrobacterium tumefaciens NTL4 (pZLR4)作为报告菌,最终得到11株具有较强降解AHLs能力的细菌,包括假单胞菌5株、不动杆菌4株、变形杆菌和莱茵海默氏菌各1株。大部分细菌可完全降解N-3-羰基十二酰基高丝氨酸内酯(3OC12-HSL),部分细菌对N-(3-氧代己酰)高丝氨酸内酯(3OC6-HSL)和N-3-氧代辛酰高丝氨酸内酯(3OC8-HSL)具有一定降解活性。【结论】Proteus和Rheinheimera可降解AHLs,为今后防治依赖群体感应的植物细菌病害提供新型生防资源。     

食源假单胞菌群体感应信号分子的研究

从市售鲜鱼中分离的3株革兰氏阴性菌,经16S rDNA鉴定为假单胞菌属,该菌是一种导致食品腐败的重要腐败细菌。N-酰基-高丝氨酸内酯(AHLs)是革兰氏阴性菌群体感应(QS)系统中一类重要的信号分子,以密度依赖的方式调控某些生理性状的表达。利用AHLs检测菌株对3株假单胞菌进行检测发现,均产生AHLs类信号分子,且FML05-1和FML05-2至少产生两种AHLs,主要的信号分子是N-3-氧代-辛酰基-高丝氨酸内酯(N- 3-oxo-C_8-HSL)。同时对菌株FML05-2在生长过程中所产生的AHLs的活性变化进行研究,发现AHLs活性在菌体生长至12h时达到最大。首次对食源假单胞菌所产生的AHLs进行了研究,为以干扰腐败细菌群体感应为靶点的食品防腐保鲜策略提供研究基础。     

Cell to cell communication by autoinducing peptides in gram-positive bacteria

While intercellular communication systems in Gram-negative bacteria are often based on homoserine lactones as signalling molecules, it has been shown that autoinducing peptides are involved in intercellular communication in Gram-positive bacteria. Many of these peptides are exported by dedicated systems, posttranslationally modified in various ways, and finally sensed by other cells via membrane-located receptors that are part of two-component regulatory systems. In this way the expression of a variety of functions including virulence, genetic competence and the production of antimicrobial compounds can be modulated in a co-ordinated and cell density- and growth phase-dependent manner. Occasionally the autoinducing peptide has a dual function, such as in the case of nisin that is both a signalling pheromone involved in quorum sensing and an antimicrobial peptide. Moreover, biochemical, genetic and genomic studies have shown that bacteria may contain multiple quorum sensing systems, underlining the importance of intercellular communication. Finally, in some cases different peptides may be recognised by the same receptor, while also hybrid receptors have been constructed that respond to new peptides or show novel responses. This paper provides an overview of the characteristics of autoinducing peptide-based quorum sensing systems, their application in various gram-positive bacteria, and the discovery of new systems in natural and engineered ecosystems. This revised version was published online in August 2006 with corrections to the Cover Date.     

Biofilm formation and cell-to-cell signalling in Gram-negative bacteria isolated from a food processing environment

AIMS: To investigate the biofilm-forming capacity and the production of quorum signals in Gram-negative bacteria isolated from a food production environment, and the possible correlation between both phenotypes. METHODS AND RESULTS: Sixty-eight Gram-negative bacteria were isolated from equipment and working surfaces in a raw vegetable processing line, and tested for biofilm-forming capacity using an in vitro microplate assay. All isolates showed significantly higher biofilm-forming capacity than Escherichia coli laboratory strain DH5alpha, which was included as a negative control, and differed up to 56-fold in relative biofilm-forming capacity. Various assays based on reporter bacteria were used to detect quorum signals produced by the isolates. Twenty-six isolates produced autoinducer-2, five isolates produced N-acyl-homoserine lactones (AHLs), and none produced the Pseudomonas quinolone signal. CONCLUSIONS: No correlation was found between in vitro biofilm-forming capacity and production of quorum signalling molecules among the 68 strains isolated from the raw vegetable processing line. SIGNIFICANCE AND IMPACT OF THE STUDY: Several recent studies have shown a role of AHL-based quorum sensing in biofilm formation of specific Gram-negative bacterial strains. The current work shows that production of AHL and other quorum signals is not widespread in Gram-negative isolates from a raw vegetable processing line, and is not a general requirement for biofilm formation, at least in vitro.     

Diversity and functional analysis of luxS genes in Vibrios from marine sponges Mycale laxissima and Ircinia strobilina

Sponges harbor highly diverse and dense microbial communities, providing an environment in which bacterial signaling may be important. Quorum sensing (QS) is a cell density-dependent signaling process that bacteria employ to coordinate and regulate their gene expression. Previous studies have found that bacteria isolated from sponges are able to produce acyl-homoserine lactones (AHLs), an important class of QS molecules found in proteobacteria. Autoinducer-2 (AI-2) is a second class of QS molecule, and is considered to be an interspecies signal. However, AI-2 signaling has not been reported in sponge bacterial symbionts. In this study, degenerate primers were designed based on known Vibrio luxS sequences to amplify the luxS genes encoding AI-2 synthases of several Vibrio isolates from marine sponges Mycale laxissima and Ircinia strobilina. All the vibrios isolated from these two sponges had luxS genes and were able to produce signals with AI-2 activity as detected using a biological reporter. A novel group of luxS sequences was found, thus extending the known diversity of luxS genes. One isolate was chosen for further analysis of its luxS gene by expression of the gene in Escherichia coli DH5α and by characterization of the profile of AI-2 activity. This work provides the first information about luxS genes and AI-2 activity in sponge-associated bacterial communities.     

微生物聚集中的群体感应与交流合作

微生物的聚集过程受群体感应机制的调控,而聚集态的形成有利于抵抗环境胁迫压力,同时也增强菌体间的交流合作并影响菌体的行为与代谢。研究微生物间交流合作的机制以及群感效应和群感淬灭机理对于调控有益微生物聚集和病原微生物解聚,实现微生物资源的高效利用和病原微生物的有效防控具有重要意义。同时也为应用于食品、医药、养殖行业的微生态制剂的研发提供新的研究思路。     

The detection of environmental autoinducing peptide quorum-sensing genes from an uncultured Clostridium sp. in landfill leachate reactor biomass

AIMS: To elucidate whether a dominant uncultured clostridial (Clostridium thermocellum-like) species in an environmental sample (landfill leachate), possesses an autoinducing peptide (AIP) quorum-sensing (QS) gene, although it may not be functional. METHODS AND RESULTS: A modified AIP accessory gene regulator (agr)C PCR protocol was performed on extracted DNA from a landfill leachate sample (also characterized by 16S rRNA gene cloning) and the PCR products were cloned, sequenced and phylogenetically analysed. It appeared that two agrC gene phylotypes existed, most closely related to the C. thermocellum agrC gene, differing by only 1 bp. CONCLUSIONS: It is possible to specifically identify and characterize the agrC AIP QS gene from uncultured Firmicutes (C. thermocellum-like) bacteria derived from environmental (landfill leachate) sample. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first successful attempt at identifying AIP QS genes from a cellulolytic environment (landfill). The agrC gene was identified as being most closely related to the C. thermocellum agrC gene, the same bacterium identified as being dominant, according to 16S rRNA gene cloning and subsequently fluorescence in situ hybridization analyses, in the same biomass.     

Differential recognition of Staphylococcus aureus quorum-sensing signals depends on both extracellular loops 1 and 2 of the transmembrane sensor AgrC

Virulence in Staphylococcus aureus is regulated via agr-dependent quorum sensing in which an autoinducing peptide (AIP) activates AgrC, a histidine protein kinase. AIPs are usually thiolactones containing seven to nine amino acid residues in which the thiol of the central cysteine is linked to the α-carboxyl of the C-terminal amino acid residue. The staphylococcal agr locus has diverged such that the AIPs of the four different S. aureus agr groups self-activate but cross-inhibit. Consequently, although the agr system is conserved among the staphylococci, it has undergone significant evolutionary divergence whereby to retain functionality, any changes in the AIP-encoding gene (agrD) that modifies AIP structure must be accompanied by corresponding changes in the AgrC receptor. Since AIP-1 and AIP-4 only differ by a single amino acid, we compared the transmembrane topology of AgrC1 and AgrC4 to identify amino acid residues involved in AIP recognition. As only two of the three predicted extracellular loops exhibited amino acid differences, site-specific mutagenesis was used to exchange the key AgrC1 and AgrC4 amino acid residues in each loop either singly or in combination. A novel lux-based agrP3 reporter gene fusion was constructed to evaluate the response of the mutated AgrC receptors. The data obtained revealed that while differential recognition of AIP-1 and AIP-4 depends primarily on three amino acid residues in loop 2, loop 1 is essential for receptor activation by the cognate AIP. Furthermore, a single mutation in the AgrC1 loop 2 resulted in conversion of (Ala5)AIP-1 from a potent antagonist to an activator, essentially resulting in the forced evolution of a new AIP group. Taken together, our data indicate that loop 2 constitutes the predicted hydrophobic pocket that binds the AIP thiolactone ring while the exocyclic amino acid tail interacts with loop 1 to facilitate receptor activation.