Quorum sensing and communication in bacteria

Bacteria are able “to sense” an increase in the cell population density and to respond to it by the induction of special sets of genes. This type of regulation, called Quorum Sensing (QS), includes the production and excretion of low-molecular-weight signaling molecules (autoinducers, AI), which diffuse readily through the cell wall, from cells into the medium. As the bacterial population reaches the critical level of density, the concentration of these signaling molecules in the medium increases as a function of population density. On reaching the critical threshold concentration, AIs bind to specific receptor regulatory proteins, which induce the expression of target genes. By means of AIs, bacteria accomplish the communication that is the transmission of information between bacteria belonging to the same or different species, genera, and even families: the signaling molecules of some bacteria affect the receptors of others causing a coordinated reply of cells of the bacterial population. Bacteria of different taxonomic groups use the QS systems in regulation of a broad range of physiological activities. These processes include virulence, symbiosis, conjugation, biofilm formation, bioluminescence, synthesis of enzymes, antibiotic substances, etc. Here we review different QS systems of bacteria, the role of QS in bacterial communication, and some applied aspects of QS regulation application.     

厌氧氨氧化菌群体感应系统研究

厌氧氨氧化(Anammox)是以铵为电子供体将亚硝酸盐转化为氮气的生物过程。厌氧氨氧化菌(AAOB)生理代谢和细胞结构均十分特殊,且在氮素循环中起着十分重要的作用。厌氧氨氧化已成为环境学、微生物学、海洋学等领域的研究热点。但是,至今人们未能对厌氧氨氧化菌进行纯培养,这严重限制了对厌氧氨氧化菌的深入研究。群体感应是一种普遍存在于微生物细胞之间的通讯机制,它具有根据菌群密度和周围环境变化调节基因表达,以控制细菌群体行为的功能。厌氧氨氧化菌活性的细胞密度效应和生物团聚行为与细菌中普遍存在的群体感应现象相符。探讨了厌氧氨氧化菌群体感应系统存在的可能性、工作机制及其生态学意义,以期为厌氧氨氧化菌的分离培养、团聚体培育等提供理论指导。     

Quorum sensing and swarming migration in bacteria

Bacterial cells can produce and sense signal molecules, allowing the whole population to initiate a concerted action once a critical concentration (corresponding to a particular population density) of the signal has been reached, a phenomenon known as quorum sensing. One of the possible quorum sensing-regulated phenotypes is swarming, a flagella-driven movement of differentiated swarmer cells (hyperflagellated, elongated, multinucleated) by which bacteria can spread as a biofilm over a surface. The glycolipid or lipopeptide biosurfactants thereby produced function as wetting agent by reducing the surface tension. Quorum sensing systems are almost always integrated into other regulatory circuits. This effectively expands the range of environmental signals that influence target gene expression beyond population density. In this review, we first discuss the regulation of AHL-mediated surface migration and the involvement of other low-molecular-mass signal molecules (such as the furanosyl borate diester AI-2) in biosurfactant production of different bacteria. In addition, population density-dependent regulation of swarmer cell differentiation is reviewed. Also, several examples of interspecies signalling are reported. Different signal molecules either produced by bacteria (such as other AHLs and diketopiperazines) or excreted by plants (such as furanones, plant signal mimics) might influence the quorum sensing-regulated swarming behaviour in bacteria different from the producer. On the other hand, specific bacteria can reduce the local available concentration of signal molecules produced by others. In the last part, the role and regulation of a surface-associated movement in biofilm formation is discussed. Here we also describe how quorum sensing may disperse existing biofilms and control the interaction between bacteria and higher organisms (such as the Rhizobium-bean symbiosis).     

Quorum sensing: the many languages of bacteria

In the conventional view of prokaryotic existence, bacteria live unicellularly, with responses to external stimuli limited to the detection of chemical and physical signals of environmental origin. This view of bacteriology is now recognized to be overly simplistic, because bacteria communicate with each other through small 'hormone-like' organic compounds referred to as autoinducers. These bacterial cell-to-cell signaling systems were initially described as mechanisms through which bacteria regulate gene expression via cell density and, therefore, they have been collectively termed quorum sensing. The functions controlled by quorum sensing are varied and reflect the needs of a particular species of bacteria to inhabit a given niche. Three major quorum-sensing circuits have been described: one used primarily by Gram-negative bacteria, one used primarily by Gram-positive bacteria, and one that has been proposed to be universal.     

Isolation of bacteria of the family enterobacteriaceae from plant tissues

Bacteria of the family Enterobacteriaceae were isolated from the tissues of a number of wild and cultivated plants. All the cultures isolated had a broad spectrum of resistance to antibiotics and were highly adhesive to human erythrocytes. The studies conducted indicate the possibility of concentration of microorganisms pathogenic for humans in plant tissues.     

Quorum sensing and virulence regulation in Xanthomonas campestris

It is now clear that cell–cell communication, often referred to as quorum sensing (QS), is the norm in the prokaryotic kingdom and this community-wide genetic regulatory mechanism has been adopted for regulation of many important biological functions. Since the 1980s, several types of QS signals have been identified, which are associated commonly with different types of QS mechanisms. Among them, the diffusible signal factor (DSF)-dependent QS system, originally discovered from bacterial pathogen Xanthomonas campestris pv. campestris , is a relatively new regulatory mechanism. The rapid research progress over the last few years has identified the chemical structure of the QS signal DSF, established the DSF regulon, and unveiled the general signaling pathways and mechanisms. Particular noteworthy are that DSF biosynthesis is modulated by a novel posttranslational autoinduction mechanism involving protein–protein interaction between the DSF synthase RpfF and the sensor RpfC, and that QS signal sensing is coupled to intracellular regulatory networks through a second messenger cyclic-di-GMP and a global regulator Clp. Genomic and genetic analyses show that the DSF QS-signaling pathway regulates diverse biological functions including virulence, biofilm dispersal, and ecological competence. Moreover, evidence is emerging that the DSF QS system is conserved in a range of plant and human bacterial pathogens.     

细菌群体感应信号网络及其应用

群体感应（Quorum sensing,QS）是一种细菌细胞与细胞间的通讯系统,即细菌通过分泌扩散性小分子信号感知细菌群体的密度,从而引起一组特定基因在转录水平协调表达。大量研究已表明,群体感应系统控制细菌多种生理行为和过程,以及与真核宿主（寄主）的互作。参与群体感应调控的信号分子多种多样,QS系统所调控的功能也具有多样性,甚至菌株专化性。通过聚焦同一细菌中由多个QS系统组成的信号网络,综合评述了不同QS系统之间如何相互作用全局调控基因表达,以及QS系统如何通过与其它全局调控系统整合精细调节细菌的社会行为以及环境适应性及其应用前景。     

"Quorum sensing" or social behavior of bacteria

The review deals with the data of literature on the role of the "quorum sensing" (QS) system ensuring the social behavior of bacteria in the regulation of virulence genes. The mechanisms of the action of these systems in Gram-negative and Gram-positive bacteria, as well as the influence of acyl-homoserine lactones, one of the components of the QS system, on the immune response of the infected host are discussed. In addition, in this review the data of literature on the existence of bacteria in the form of biofilms are presented. The methods of the identification of biofilms, the methods of their experimental preparation and the role of the QS system in the process of their formation are considered.     

群感效应与链霉菌次生代谢调控

群感效应是细菌协调群体行为的一种外界信号传递机制,在细菌中普遍存在,参与细胞的多种生理过程。链霉菌中也存在群感效应,在抗生素等次生代谢产物的生物合成中起重要的调控作用;从自诱导信号分子的结构到信号传递机制都存在一定多样性,其中以A-因子为代表的γ-丁酸内酯类信号分子的作用机制研究最为深入。近几年在链霉菌中发现的PI-因子、M-因子以及一些特定的代谢产物则代表几类结构较新颖的信号分子,通过群感效应机制调控次生代谢过程;链霉菌中还发现胆固醇氧化酶、甘油等分子具有信号分子特征,不排除是通过群感效应来参与抗生素生物合成调控。本文主要就参与链霉菌次生代谢调控的几类群感效应系统的研究状况进行综述,重点阐述各类群感信号分子的结构和信号传递机制的不同,并对链霉菌群感效应的研究趋势以及在抗生素高产菌遗传育种中的应用前景进行了展望。     

细菌群体感应及其在食品变质中的作用

食品相关细菌引起的生物被膜形成和食品变质是食品工业中的重大问题。研究表明细菌群体感应(Quorum sensing,QS)与被膜形成、食品腐败变质密切相关。重点对细菌产生的各种QS信号分子及其在被膜形成的作用和被膜在食品工业中的重要性做了介绍。QS信号分子与食品变质密切相关,故对QS抑制剂作为新型食品防腐剂以延长储存期限及加强食品安全的前景进行了概述。     

"Quorum sensing" regulation of lux gene expression and the structure of lux operon in marine bacteria Alivibrio logei

A group of luminescent strains of marine bacteria Alivibrio logei has been isolated (basins of the Okhotsk, White and Bering Seas). Strains A. logei were shown to be psycrophiic bacteria with an optimal growth temperature of approximately 15 degrees C. Biolumiscent characteristics of strains were studied, and the expression of lux genes was shown to be regulated by the "quorum sensing" system. The A. logei lux operon was cloned in Escherichia coli cells and the structure of this operon and its nucleotide sequence were determined. The structure of A. logei lux operon differs markedly from that in the closely related species of luminescent marine bacteria A. fischeri. In the structure of the A. logei lux operon, the the luxI gene is absent in front of luxC, and a fragment containing luxR2-luxI genes is located immediately after luxG gene. Luminescent psycrophiic marine bacteria of A. logei are assumed to be widely distributed in cold waters of northern seas.     

Quorum sensing in Serratia

Many bacteria use cell-cell communication to monitor their population density, synchronize their behaviour and socially interact. This communication results in a coordinated gene regulation and is generally called quorum sensing. In gram-negative bacteria, the most common quorum signal molecules are acylated homoserine lactones (AHLs), although other low-molecular-mass signalling molecules have been described such as Autoinducer-2 (AI-2). The phenotypes that are regulated in Serratia species by means of AHLs are remarkably diverse and of profound biological and ecological significance, and often interconnected with other global regulators. Furthermore, AHL- and AI-2-mediated systems (less profoundly studied) are continuously being discovered and explored in Serratia spp., many having interesting twists on the basic theme. Therefore, this review will highlight the current known quorum sensing systems in Serratia spp., including the important nosocomial pathogen Serratia marcescens.     

Quorum sensing disruption regulates hydrolytic enzyme and biofilm production in estuarine bacteria

Biofilms of heterotrophic bacteria cover organic matter aggregates and constitute hotspots of mineralization, primarily acting through extracellular hydrolytic enzyme production. Nevertheless, regulation of both biofilm and hydrolytic enzyme synthesis remains poorly investigated, especially in estuarine ecosystems. In this study, various bioassays, mass spectrometry and genomics approaches were combined to test the possible involvement of quorum sensing (QS) in these mechanisms. QS is a bacterial cell–cell communication system that relies notably on the emission of N-acylhomoserine lactones (AHLs). In our estuarine bacterial collection, we found that 28 strains (9%), mainly Vibrio, Pseudomonas and Acinetobacter isolates, produced at least 14 different types of AHLs encoded by various luxI genes. We then inhibited the AHL QS circuits of those 28 strains using a broad-spectrum lactonase preparation and tested whether biofilm production as well as β-glucosidase and leucine-aminopeptidase activities were impacted. Interestingly, we recorded contrasted responses, as biofilm production, dissolved and cell-bound β-glucosidase and leucine-aminopeptidase activities significantly increased in 4%–68% of strains but decreased in 0%–21% of strains. These findings highlight the key role of AHL-based QS in estuarine bacterial physiology and ultimately on biogeochemical cycles. They also point out the complexity of QS regulations within natural microbial assemblages.     

Quorum sensing, virulence and secondary metabolite production in plant soft-rotting bacteria

Quorum sensing describes the ability of bacteria to sense their population density and respond by modulating gene expression. In the plant soft-rotting bacteria, such as Erwinia, an arsenal of plant cell wall-degrading enzymes is produced in a cell density-dependent manner, which causes maceration of plant tissue. However, quorum sensing is central not only to controlling the production of such destructive enzymes, but also to the control of a number of other virulence determinants and secondary metabolites. Erwinia synthesizes both N-acylhomoserine lactone (AHL) and autoinducer-2 types of quorum sensing signal, which both play a role in regulating gene expression in the phytopathogen. We review the models for AHL-based regulation of carbapenem antibiotic production in Erwinia. We also discuss the importance of quorum sensing in the production and secretion of virulence determinants by Erwinia, and its interplay with other regulatory systems.     

Quorum sensing by peptide pheromones and two-component signal-transduction systems in Gram-positive bacteria

Cell-density-dependent gene expression appears to be widely spread in bacteria. This quorum-sensing phenomenon has been well established in Gram-negative bacteria, where N -acyl homoserine lactones are the diffusible communication molecules that modulate cell-density-dependent phenotypes. Similarly, a variety of processes are known to be regulated in a cell-density- or growth-phase-dependent manner in Gram-positive bacteria. Examples of such quorum-sensing modes in Gram-positive bacteria are the development of genetic competence in Bacillus subtilis and Streptococcus pneumoniae , the virulence response in Staphylococcus aureus , and the production of antimicrobial peptides by several species of Gram-positive bacteria including lactic acid bacteria. Cell-density-dependent regulatory modes in these systems appear to follow a common theme, in which the signal molecule is a post-translationally processed peptide that is secreted by a dedicated ATP-binding-cassette exporter. This secreted peptide pheromone functions as the input signal for a specific sensor component of a two-component signal-transduction system. Moreover, genetic linkage of the common elements involved results in autoregulation of peptide-pheromone production.