植物伴生细菌数量应答系统的研究进展*

N-酰基高丝氨酸内酯(AHLs)作为信号分子介导的细菌数量应答系统参与许多生物学功能的调节,当侵染动植物寄主组织的病原菌繁殖到一定量时,细菌本身产生的AHLs积累到临界浓度,AHLs与胞内特异受体结合,启动致病因子的表达。利用AIRs降解酶和AHLs类似物的特性,干扰和破坏病原菌的AHLs数量应答系统,将为利用现代生物技术防治细菌病害开辟了一条全新的途径。     

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 lactone,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     

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     

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。     

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。     

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。     

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。     

一株沙雷氏菌的分离及其群体感应现象

从腐败的凡纳滨对虾中分离得到一株具有群体感应的菌株,利用16S rRNA和生理生化试验鉴定其为黏质沙雷氏菌,但不产灵红素,命名为Serratia marcescens AK1。通过生物检测方法对菌株AK1进行群体感应检测,薄层层析法鉴定该菌株的信号分子类型。结合菌株生长规律,测定不同时间段信号分子的含量。结果显示,菌株AK1能诱导紫色杆菌CV026产生紫色杆菌素,诱导根癌农杆菌A136分解X-gal产生蓝色;薄层层析检测结果显示该菌能产生两种群体感应信号分子C6-HSL和3-oxo-C6-HSL,并具有密度依赖性,信号分子含量在生长对数后期达到最大值。     

多酚干扰细菌群体感应研究进展*

多酚化合物是人类日常饮食中一类典型的天然产物,具有干扰分子信号通路、影响肠道菌群组成和保护人体肠道健康的功能。针对不同微生物群体感应(quorum sensing,QS)系统,多酚能够干扰细菌生物膜的形成和微生物致病性。介绍多酚的类型、来源和含量,总结多酚对多种QS相关表型,如菌体运动性、黏附性、生物膜形成和毒力因子的释放等具有的干扰作用,以及一些常见多酚对典型病原体的干扰作用,提出基于多酚的QS干扰在未来疾病治疗中面临的主要挑战。     

根瘤菌与群体感应

细菌在高细胞密度下可以产生群体感应信号分子,调控细菌相关基因的表达,这种信号分子被称为自体诱导物。酰基高丝氨酸内酯类化合物(acyl-HSLs)是在根瘤菌中广泛存在的一类自体诱导物,该群体感应系统与根瘤菌和植物的共生作用密切相关。本文概述了AHLs介导的群体感应系统的组成及调控机制和不同根瘤菌中群体感应调节对根瘤菌生理行为及共生固氮的影响。     

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。     

假单胞菌Quorum sensing调控体系

群体感应(Quorum sensing,QS)是近来受到广泛关注的一种细菌群体行为调控机制,通过感应一些信号分子如酰基高丝氨酸环内酯(acyl-homoserine lactone,AHL)来判断菌群密度和周围环境变化,假单胞菌中同样也有AHL信号分子,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,从而调节菌体的群体行为(如致病性及群体生长调节)。众多报道说明了假单胞菌的群体感应调节系统是由一些全面的调节子所调控的。本文系统介绍了假单胞菌群体感应调控系统,并分析假单胞菌在该系统中复杂的应答反应。     

N-hexanoyl-L-homoserine lactone, a mediator of bacterial quorum-sensing regulation, exhibits plant-dependent stability and may be inactivated by germinating Lotus corniculatus seedlings

The half-life of N-hexanoyl-l-homoserine lactone (C6-HSL) was determined under various pH and temperature conditions, and in several plant environments. C6-HSL was sensitive to alkaline pH, a process that was also temperature-dependent. In addition, C6-HSL disappeared from plant environments, i.e. axenic monocot and dicot plants cultivated under gnotobiotic, hydroponic conditions, albeit with variable kinetics. The disappearance was rapid at the root system of legume plants such as clover or Lotus, and slow or non-existent at the root system of monocots such as wheat or corn. These variable kinetics were not dependent upon pH changes that may have affected the growth media of the plants. Furthermore, C6-HSL did not accumulate in the plant, and the plant did not produce inhibitors of the C6-HSL signal. HPLC analyses revealed that C6-HSL disappeared from the media, and hence, Lotus exhibited a natural C6-HSL inactivating ability. This ability was not specific for C6-HSL and allowed the degradation of other N-acyl-homoserine lactones such as 3-oxo-C6-HSL, 3-oxo-octanoyl-HSL and 3-oxo-decanoyl-HSL. Preliminary investigation revealed that the inactivating ability is temperature-dependant and possibly of enzymatic origin.     

The quorum sensing molecule N-acyl homoserine lactone produced by Acinetobacter baumannii displays antibacterial and anticancer properties

Secretory N-acyl homoserine lactones (AHLs) mediate quorum sensing (QS) in bacteria. AHLs are shown to be inhibitory for an unrelated group of bacteria and might mimic host signalling elements, thereby subverting the regulatory events in host cells. This study investigated the AHL produced by Acinetobacter baumannii and analysed its effect on other bacterial species and mammalian cells. Chemically characterized AHL had an m/z value of 325 with a molecular formula C₁₈H₃₁NO₄ and showed its inhibitory potential against Staphylococcus aureus. Molecular docking studies identified D-alanine-D-alanine synthetase A, a cell wall synthesizing enzyme of S. aureus having a strong binding affinity towards AHL. Electron microscopy showed the disruption and sloughing off of the S. aureus cell wall when treated with AHL. In vitro experiments revealed that this bacteriostatic AHL showed time-dependent activity and induced apoptosis in cancer cell lines. This compound could be a potential structural backbone for constructing new AHL analogues against S. aureus. The findings emphasize the need to re-evaluate all previously characterized AHLs for any additional new biological functions other than QS.     

真菌中的群体感应系统

以胞间通讯信号分子介导的细菌群体感应参与细菌多种生理功能的调控是非常普遍的。近年的研究表明,真菌中也存在类似于细菌群体感应信号分子的调节分子,并且介导着真菌某些生理行为的调节。这一过程也称为真菌的群体感应系统。文中简要介绍真菌群体感应系统的研究进展,并讨论了真菌群体感应系统作为抗真菌感染靶点的可能性。     

Quorum sensing inhibitors: An overview

Excessive and indiscriminate use of antibiotics to treat bacterial infections has lead to the emergence of multiple drug resistant strains. Most infectious diseases are caused by bacteria which proliferate within quorum sensing (QS) mediated biofilms. Efforts to disrupt biofilms have enabled the identification of bioactive molecules produced by prokaryotes and eukaryotes. These molecules act primarily by quenching the QS system. The phenomenon is also termed as quorum quenching (QQ). In addition, synthetic compounds have also been found to be effective in QQ. This review focuses primarily on natural and synthetic quorum sensing inhibitors (QSIs) with the potential for treating bacterial infections. It has been opined that the most versatile prokaryotes to produce QSI are likely to be those, which are generally regarded as safe. Among the eukaryotes, certain legumes and traditional medicinal plants are likely to act as QSIs. Such findings are likely to lead to efficient treatments with much lower doses of drugs especially antibiotics than required at present.     

Inhibition of Quorum Sensing Mediated Virulence Factors Production in Urinary Pathogen Serratia marcescens PS1 by Marine Sponges

The focal intent of this study was to find out an alternative strategy for the antibiotic usage against bacterial infections. The quorum sensing inhibitory (QSI) activity of marine sponges collected from Palk Bay, India was evaluated against acyl homoserine lactone (AHL) mediated violacein production in Chromobacterium violaceum (ATCC 12472), CV026 and virulence gene expressions in clinical isolate Serratia marcescens PS1. Out of 29 marine sponges tested, the methanol extracts of Aphrocallistes bocagei (TS 8), Haliclona (Gellius) megastoma (TS 25) and Clathria atrasanguinea (TS 27) inhibited the AHL mediated violacein production in C. violaceum (ATCC 12472) and CV026. Further, these sponge extracts inhibited the AHL dependent prodigiosin pigment, virulence enzymes such as protease, hemolysin production and biofilm formation in S. marcescens PS1. However, these sponge extracts were not inhibitory to bacterial growth, which reveals the fact that the QSI activity of these extracts was not related to static or killing effects on bacteria. Based on the obtained results, it is envisaged that the marine sponges could pave the way to prevent quorum sensing (QS) mediated bacterial infections.