细菌群体感应系统与噬菌体的相互作用机制研究进展

细菌在与噬菌体的长期共进化过程中形成多种抵抗噬菌体侵染的机制,其中群体感应参与的细菌抵御噬菌体侵染机制成为近年来的研究热点。群体感应与噬菌体之间的相互作用是复杂和多样的,本文将重点综述群体感应在噬菌体侵染中的作用、调控在噬菌体裂解-溶源转变的作用,以及群体感应与噬菌体的其他相互影响等内容,为噬菌体在细菌性疾病的治疗提供理论依据。     

细菌与噬菌体相互抵抗机制研究进展

噬菌体作为一种侵染细菌的病毒,能够特异性识别宿主细菌。近年来,抗生素的过度使用导致耐药细菌的出现,噬菌体有望成为对抗耐药细菌的新武器。在细菌与噬菌体长期共进化过程中,二者都演化出一系列抵御策略。本文从抑制噬菌体吸附、阻止噬菌体DNA进入、切割噬菌体基因组、流产感染以及群体感应对噬菌体的调控等方面,对细菌抵抗噬菌体的机制以及噬菌体应对细菌的策略进行了综述,同时还列举了细菌和噬菌体相互抵抗机制的检测方法,以期为噬菌体在细菌控制中的应用以及探究细菌抵抗噬菌体的机制提供理论依据。     

群体感应QseB/QseC系统对外界环境变化的响应机制

细菌群体感应(quorum sensing, QS)是一种细菌种群之间和与环境之间的相互作用机制，不仅可以评估其自身物种的种群密度，还可以评估给定环境中其他细菌物种的种群密度，是维持细菌感知并响应环境变化的重要协调途径。编码鞭毛表达和组装以及运动性的基因是潜在的毒力相关因子，受细菌种群密度调节，利用群体感应激活。QseB/QseC双组分系统是参与鞭毛和运动基因调节的群体感应调节级联反应的一个重要组成部分。本文综述了细菌群体感应系统的种类及其作用，将近年来有关QseB/QseC双组分系统介导的群体感应系统结构功能、QseB/QseC信号转导调控机制以及QseB/QseC双组分系统在调控细菌致病性、生物膜形成、鞭毛运动性等方面所发挥的作用进行整理、归纳和总结，并对目前研究不足的地方作出了展望，希望能找出下一个研究的方向。对QseB/QseC信号系统介导的群体感应机制的深入研究，不仅为解决细菌耐药及致病机制等问题提供新思路，还可能为开发疫苗和药物提供新靶点。     

乳酸菌群体感应系统研究进展

群体感应及其自我调控是细菌间进行信息交流的重要机制。细菌通过特定的化学信号分子来监测菌群密度和周围环境的变化,进而调节菌体内相关基因表达,使菌体更加适应周围环境。乳酸菌很多生物学现象都与群体感应系统有关。本文中,笔者总结了乳酸菌群体感应系统的组成、信号转导机制及其生物学功能,这些功能包括调控菌体生物膜的形成、菌株自溶、抗菌肽的合成、酸胁迫应答。本综述将为乳品工业提高乳酸菌的发酵密度和扩大其益生菌功能提供新思路。     

群体感应与病原菌致病性研究进展

群体感应是细菌根据细胞密度变化进行基因表达调控的一种生理行为。当细菌密度达到临界阈值时能释放一些特定的自诱导信号分子,从而调节本种群或同环境中其他种群的群体行为。细菌群体感应参与包括人类、动植物、病原菌在内的多种生物的生物学功能调节,如生物膜的形成、毒力因子的产生、病原菌的耐药性等。深入研究病原菌群体感应系统的调控机制,将提高对病原菌发病机制的认识,有利于以群体感应作为防治疾病策略的研究。系统阐述了群体感应系统的组成类型、群体感应与病原菌致病性的关系,及其在抑制病原菌致病方面的应用。     

工业微生物的噬菌体感染与防治策略

以细菌为基础的生物技术在蓬勃发展的同时也不断受到噬菌体感染的威胁,噬菌体感染已成为微生物发酵过程中的一个顽疾,其实质是噬菌体与细菌之间复杂的共进化关系。在漫长的进化过程中,噬菌体已经形成了多种针对细菌抗性系统的逃逸机制。合理的工厂设计、菌株的轮换策略和传统的基因工程方法能在一定程度上降低噬菌体感染的风险,但仍然无法避免。基于CRISPR-Cas系统的防治策略仅需噬菌体的序列信息就可以理性设计噬菌体抗性菌株,且可以通过叠加效应不断增强菌种抗性,从而避免噬菌体的逃逸;群体感应信号分子则可以从整体水平上调节细菌的噬菌体抗性。这些新发现为噬菌体感染问题的解决带了新的希望,而噬菌体基因组编辑技术和合成生物学的快速发展则将进一步加深人们对噬菌体感染防治领域的认识。     

铜绿假单胞菌群体感应系统研究进展

群体感应系统是一种细胞密度依赖的基因表达系统,其广泛存在于细菌性病原体中,是细菌细胞通讯方式的一种。群体感应系统可利用细菌释放的信号分子不断监控周围细菌的密度。当细菌密度达到阈值时,群体感应系统网络将启动,参与调控生物被膜、细菌毒力等特定基因的表达,从而使临床抗感染治疗失败。而通过抑制群体感应系统,可一定程度上治疗铜绿假单胞菌引起的感染。本文通过查阅近年国内外相关文献,对铜绿假单胞菌群体感应系统研究进展进行总结,为临床铜绿假单胞菌治疗提供新的方向,即群体感应系统抑制剂有可能成为治疗铜绿假单胞菌感染的新策略。     

细菌耐受噬菌体感染的分子机制研究进展

噬菌体是能感染细菌的病毒。为了抵抗噬菌体的感染,细菌进化出多种抵抗噬菌体感染的机制,这些机制的阐析极大地促进了基因编辑领域的发展,同时也为噬菌体治疗的开展奠定了基础。本文就细菌针对噬菌体感染的各个环节所进行的抵抗及其分子机制进行了简要综述,同时讨论了这些防御系统的存在对细菌自身的影响,分析了当前细菌耐受噬菌体机制研究存在的局限性,并对未来研究进行了展望。     

噬菌体群体感应系统及其分子机理研究进展

群体感应（Quorum Sensing,QS）是微生物群体在生长过程中,随着群体密度的增加,其分泌的“信号分子”的浓度达到一定阈值后与微生物体内特定受体结合,从而影响微生物特定基因表达,导致其生理和生化特性的变化,表现出少量菌体或单个菌体所不具备的特征。1994年Fuqua提出群体感应概念后就成为微生物领域的研究热点。然而,群体感应的研究主要集中在细菌中,但近年来群体感应在噬菌体、真菌中也不断被发现,尤其自2017年Erez在多种枯草芽孢杆菌噬菌体中发现群体感应现象,并且揭示噬菌体群体感应主要调控其溶原-裂解途径的转换。近年来的研究又陆续在其他噬菌体中发现了群体感应。本文综述了噬菌体群体感应系统最新研究进展及其相关的基因功能和分子机理。     

细菌密度阈值感应现象的研究

细菌通过复杂的信号传递系统进行着信息交流.细菌的密度阈值感应现象(quorum sensing,QS)是这一信号系统的重要组成部分.细菌通过释放,发现,接受信号分子而实现这一途径.这些信号分子被称为自体诱导分子(autoinducers,AI).通过自体诱导分子细菌可以分辨细胞密度的大小,并通过控制基因的表达而调节细菌的数量.这一过程被称为细菌的密度阈值感应现象.通过这一机制,细菌可以调控整个细菌菌落的基因表达.细菌的密度阈值感应现象使真核生物与原核生物之间的界限变得模糊,细菌可以像多细胞生物一样拥有许多作为个体细菌不可能拥有的特性.细菌的许多行为都受到密度阈值感应机制的调控,如共生现象,毒力因子的表达,耐药性的产生及生物膜的形成等等.研究表明正是通过这种密度阈值感应现象,无论是高度特异的密度阈值感应现象还是普遍存在的密度阈值感应现象,实现了细菌与细菌之间的交流.原核生物与真核生物都不可避免地受到密度阈值感应现象的影响.竞争细菌及易感的真核生物宿主可以通过分泌破坏自体诱导分子或产生自体诱导分子抗体来破坏细菌的密度阈值感应系统而对抗细菌的入侵.     

细菌群体感应及其干扰策略的研究进展

群体感应（QS）广泛存在于细菌中,是细菌根据细胞密度变化调控基因表达的一种机制。许多植物病原菌依赖QS调控致病基因和毒性因子的表达,导致植物发病,因此通过抑制QS效应就为控制细菌病害提供了一种有效的方法。目前发现许多途径可以干扰细菌的QS,如：产生可使信号分子降解的酶,产生病原菌信号分子的类似物与信号分子受体蛋白竞争结合来阻断病原菌的群体感应,利用QS中信号分子来诱发寄主抗性。系统阐述了细菌QS及其干扰策略。     

Quorum sensing of genes expression--perspective drug target against bacterial pathogenicity

Bacteria are capable to sense an increase of cell density population and to reply quickly and coordinately by the induction of special sets of genes. This type of the regulation was named Quorum Sensing (QS); it is based on the effect of low-molecular-weight signaling molecules of different nature (autoinducers) which accumulate in the culture at high density of bacterial population and interact with receptor regulatory proteins. QS systems are the global regulators of bacterial genes expression and play a key role in the control of many metabolic processes in cell including the regulation of virulence of bacteria. Here we review the molecular mechanisms of QS systems functioning in bacteria belonging to different taxonomic groups and discuss the potential of QS regulation as a new drug target for the treatment of bacterial infections. At present this approach is accounted as a new alternative strategy of antimicrobial therapy directed on the development of drugs inhibiting QS regulation and active just against pathogenicity of bacteria (antipathogenic drugs). Such a strategy allows to avoid a wide dissemination of resistant forms of pathogenic bacteria and the formation of biofilms increasing in many times the resistance of bacteria to drug preparations.     

产Ⅱ类细菌素乳酸菌群体感应及其应用

群体感应(quorum sensing,QS)是微生物通过感知与细胞密度相关的信号分子的浓度来调控基因表达的一种行为。许多产Ⅱ类细菌素乳酸菌通过自诱导肽介导的QS系统调控其细菌素的合成。本文综述了乳酸菌Ⅱ类细菌素合成的QS调控现象、调控机制、QS系统组分以及QS的应用。产Ⅱ类细菌素乳酸菌QS的研究,必将为揭示发酵调控机理、调控发酵过程提供新的研究平台,为食品级基因表达系统的开发提供新的选择。     

细菌群体感应信号分子的光电检测技术

群体感应（quorum sensing，QS）是一种依赖菌群密度的细菌交流系统。在探究细菌群体感应系统的调控机制中，对QS信号分子的鉴别和检测是不可或缺的环节，其对生命科学、药学等领域涉及细菌等微生物的相互作用、高效检测和作用机制解析等具有重要的参考意义。本文在总结不同类型细菌QS信号分子来源和结构的基础上，对QS信号分子的光电检测方法和技术进行了综述，重点对光电传感检测的敏感介质、传感界面、传感机制及测试效果进行探讨，同时关注了将微流控芯片分析技术应用于细菌QS信号分子原位监测的相关研究进展。     

Quorum Sensing System Used as a Tool in Metabolic Engineering

Quorum sensing (QS) is a ubiquitous cell–cell communication mechanism in microbes that coordinates population‐level cell behaviors, such as biofilm production, virulence, swarming motility, and bacterial persistence. Efforts to engineer QS systems to take part in metabolic network regulation represent a promising strategy for synthetic biology and pathway engineering. Recently, design, construction, and implementation of QS circuits for programmed control of bacterial phenotypes and metabolic pathways have gained much attention, but have not been reviewed recently. In this article, the architectural organizations and genetic contributions of the naturally occurring QS components to understand the mechanisms are summarized. Then, the most recent progress in application of QS toolkits to develop synthetic networks for novel cell behaviors creation and metabolic pathway engineering is highlighted. The current challenges in large‐scale application of these QS circuits in synthetic biology and metabolic engineering fields are discussed and future perspectives for further engineering efforts are provided.     

植物对细菌群体感应系统的反应

细菌的群体感应系统参与包括动植物病原细菌致病因子产生在内的许多生物学功能的调节。植物可以感知细菌群体感应系统及其信号分子,并作出复杂反应。植物可能受细菌群体感应信号分子诱导产生系统性防御反应,能够分泌细菌群体感应信号分子的类似物,可能产生降解细菌N-酰基高丝氨酸内酯信号分子的酶来阻断或干扰细菌群体感应系统。     

The hierarchy quorum sensing network in Pseudomonas aeruginosa

Pseudomonas aeruginosa causes severe and persistent infections in immune compromised individuals and cystic fibrosis sufferers. The infection is hard to eradicate as P. aeruginosa has developed strong resistance to most conventional antibiotics. The problem is further compounded by the ability of the pathogen to form biofilm matrix, which provides bacterial cells a protected environment withstanding various stresses including antibiotics. Quorum sensing (QS), a cell density-based intercellular communication system, which plays a key role in regulation of the bacterial virulence and biofilm formation, could be a promising target for developing new strategies against P. aeruginosa infection. The QS network of P. aeruginosa is organized in a multi-layered hierarchy consisting of at least four interconnected signaling mechanisms. Evidence is accumulating that the QS regulatory network not only responds to bacterial population changes but also could react to environmental stress cues. This plasticity should be taken into consideration during exploration and development of anti-QS therapeutics.     

Quorum-sensing regulation of gene expression: Fundamental and applied aspects and the role in bacterial communication

Quorum sensing (QS) is a specific type of regulation of gene expression in bacteria; it is dependent on the population density. QS systems include two obligate components: a low-molecular-weight regulator (autoinducer), readily diffusible through the cytoplasmic membrane, and a regulatory receptor protein, which interacts with the regulator. As the bacterial population reaches a critical level of density, autoinducers accumulate to a necessary threshold value and abrupt activation (induction) of certain genes and operons occurs. By means of low-molecular-weight regulators, bacteria accomplish communication between cells belonging to the same or different species, genera, and even families. QS systems have been shown to play a key role in the regulation of various metabolic processes in bacteria and to function as global regulators of the expression of bacterial genes. Data are presented on different types of QS systems present in bacteria of various taxonomic groups, on the species specificity of these systems, and on communication of bacteria by means of QS systems. The possibility is considered of using QS regulation systems as targets while combating bacterial infections; other applied aspects of QS investigation are discussed.     

Quorum-sensing regulation of gene expression: fundamental and applied aspects and the role in bacterial communication

Quorum sensing (QS) is a specific type of regulation of gene expression in bacteria; it is dependent on the population density. QS systems include two obligate components: a low-molecular-weight regulator (autoinducer), readily diffusible through the cytoplasmic membrane, and a regulatory receptor protein, which interacts with the regulator. As the bacterial population reaches a critical level of density, autoinducers accumulate to a necessary threshold value and abrupt activation (induction) of certain genes and operons occurs. By means of low-molecular-weight regulators, bacteria accomplish communication between cells belonging to the same or different species, genera, and even families. QS systems have been shown to play a key role in the regulation of various metabolic processes in bacteria and to function as global regulators of the expression of bacterial genes. Data are presented on different types of QS systems present in bacteria of various taxonomic groups, on the species specificity of these systems, and on communication of bacteria by means of QS systems. The possibility is considered of using QS regulation systems as targets while combating bacterial infections; other applied aspects of QS investigation are discussed.