重组细菌多药外排泵AcrAB-TolC的转运功能和动态组装

【背景】多药外排泵多以膜蛋白复合体形式存在,是导致细菌耐药性的重要原因。外排泵的转运功能和组装过程对于细菌耐药性和药物研发具有重要意义。【目的】以多药外排泵耐药结节细胞分化家族(resistance-nodulation-division family, RND)的重要成员AcrAB-TolC复合体为对象,研究其转运活性和体外组装特性。【方法】基于大肠杆菌AcrAB-TolC复合体基因序列,分别构建含有acrA、acrB、tolC基因的重组质粒,表达和纯化复合体各亚基,利用荧光光谱、等温滴定量热法(isothermal titration calorimetry,ITC)等技术分析复合体及亚基的转运功能、亚基与底物的相互作用,以及亚基间的相互作用和动态装配。【结果】实现了AcrAB-TolC复合体各组分的表达和纯化(纯度>98%),证实表达有各组分的活细胞提高了对于溴化乙锭(ethidium bromide,EB)的转运活性,并发现群体感应效应信号分子N-hexanoyl-L-homoserine lactone (C6-HSL)能够抑制AcrB、TolC对于EB的转运活性。ITC结果进一步证实了C6-HSL与AcrB、TolC的相互作用。ITC结果还显示AcrA分别与AcrB、TolC之间存在明显的相互作用,而AcrB与TolC之间无明显的相互作用。在体外装配实验中观测到AcrAB-TolC亚基的单分子荧光强度随时间增加,证实了复合体亚基在膜上的动态组装过程。【结论】实现了AcrAB-TolC外排泵及亚基的表达和纯化,证实了AcrAB-TolC对底物的转运活性及与底物的相互作用,观察到AcrAB-TolC的动态组装过程。以上结果为研究多药外排泵导致的细菌耐药性及抗菌策略具有重要意义。     

综述与专论：细菌的信号转导系统及其在耐药中的作用

耐药菌的日益增多给临床治疗带来巨大的困难,揭示耐药机制成为遏制耐药菌的基本环节。细菌的信号系统是菌体之间信息交流的主要渠道,在调控细菌耐药性方面发挥重要的作用。本文梳理了细菌双组分系统、群体感应系统、第二信使、吲哚等细菌信号系统(分子)与细菌耐药性的关系,总结了各信号系统调控细菌耐药性的机制和途径,包括调控生物膜的形成、调节药物外排泵的活性、激活抗生素灭活酶、提高耐药基因表达水平、促进耐药基因转移、修饰细胞壁结构等,涉及到细菌耐药的多个环节。各信号系统不仅可以独立调控耐药,还可以互相作用,形成调控网络,从多个层面调节细菌耐药性。因此,靶向细菌信号系统,阻断菌体之间的信号联络,有望成为遏制细菌耐药性日益严重的新策略。     

外排泵介导鲍曼不动杆菌耐药性的研究进展

目的鲍曼不动杆菌的多重耐药性问题日趋严重,该菌外膜上外排泵过表达是导致其耐药性的重要机制。详尽地研究多药外排泵的机制以及寻找阻断其功能的外排泵抑制剂,将为多耐药鲍曼不动杆菌的治疗开辟新的路径。本文就近年来鲍曼不动杆菌外排泵的研究现状进行综述,着重描述多药外排泵RND家族的耐药谱特征及其表达调控机制,同时,还阐述了MFS和MATE家族外排泵的研究进展。     

群体感应与微生物耐药性

微生物耐药性已成为全球关注的严重问题,其演化机制和调控机理也已成为研究热点。近年来的研究发现,一些微生物耐药性机制受到群体感应系统的调控。群体感应是一种在微生物界广泛存在并与菌体密度关联的细胞-细胞间的通讯系统。高密度的菌落群体能够产生足够数量的小分子信号,激活下游包括致病毒力和耐药性机制在内的多种细胞进程,耐受抗生素并且危害寄主。本文结合国内外最新的研究进展,对微生物群体感应系统的研究现状进行了概括性介绍,重点阐述了群体感应系统对微生物耐药性机制的调控作用,如微生物生物被膜形成和药物外排泵调控等方面的作用,并探讨了利用群体淬灭控制微生物耐药性的新策略。     

华癸根瘤菌7653R中一个RND型药物外排泵的功能表型及调控鉴定

【目的】研究华癸根瘤菌7653R中MCHK_0866和MCHK_0867编码的RND家族外排泵的功能表型。【方法】对外排泵编码基因及候选调控基因在基因组上的结构进行分析。采用测定OD_(600)观察菌株生长曲线的变化。通过测定最低抑菌浓度检测菌株的药物敏感性,RT-PCR检测目的基因经特定物质处理后表达量的变化。通过细菌单杂交系统初步检测外排泵的转录调控。【结果】MCHK_0866和MCHK_0867所编码蛋白共同组成一个RND家族射流泵。缺失该外排泵后,细菌生长曲线在稳定期OD_(600)数值降低,对萘啶酸、四环素和SDS的敏感性发生变化,萘啶酸处理细菌后2个基因的表达量增加。同时,下游属于Tet R转录因子家族的基因MCHK_0869表达产物作用于MCHK_0867的启动子区域。【结论】该外排泵与萘啶酸的运输有关,缺失后自身生长受到影响,表达受到下游转录因子的调控。     

革兰氏阴性菌AcrAB-TolC多药外排泵结构数据对抑制剂研发的启示

革兰氏阴性菌的多重耐药性已成为全球广泛聚焦的问题。近年研究发现,耐药结节细胞分化(resistance-nodulation-cell division,RND)家族外排泵的过表达,与革兰氏阴性菌的多重耐药性密切相关。在RND家族中,广泛存在于革兰氏阴性菌中的AcrAB-TolC外排泵被认为是导致多重耐药性的主要原因之一。为了开发有效的抑制剂,需要对AcrAB-TolC外排泵的结构有一个清晰的认识。以往对该外排泵结构的研究主要局限于体外采用X射线晶体学技术或冷冻电镜单颗粒分析技术来解析其单个组分或全泵的结构。细胞冷冻电子断层扫描技术为揭示AcrAB-TolC外排泵在天然细胞膜环境中的组装和运行机制提供了新的见解,本文综述了AcrAB-TolC不同层级的结构数据在研发外排泵抑制剂方面的贡献。     

鲍曼不动杆菌中外排泵介导耐药机制的研究进展

外排泵的过表达是目前导致鲍曼不动杆菌多重耐药的最重要机制之一,详细了解这一复杂机制有助于尽快找到有效的防治策略。目前,鲍曼不动杆菌中已被报道的外排泵家族包括耐药结节细胞分化(resistance-nodulation-cell division,RND)家族、主要协同转运蛋白超家族(major facilitator superfamily,MFS)、多药及毒性化合物外排(multidrug and toxic compound extrusion,MATE)家族、小多重耐药(small multidrug resistance,SMR)家族。它们之中既有通过染色体介导的外排泵,也有通过质粒等遗传元件介导的外排泵。外排底物可呈现多样性,也可呈现专一性。本文就上述外排泵的种类、功能和调控机制进行综述。     

细菌的信号转导系统及其在耐药中的作用

耐药菌的日益增多给临床治疗带来巨大的困难,揭示耐药机制成为遏制耐药菌的基本环节.细菌的信号系统是菌体之间信息交流的主要渠道,在调控细菌耐药性方面发挥重要的作用.本文梳理了细菌双组分系统、群体感应系统、第二信使、吲哚等细菌信号系统(分子)与细菌耐药性的关系,总结了各信号系统调控细菌耐药性的机制和途径,包括调控生物膜的形成...     

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。     

群体感应系统介导细菌生物膜形成的研究进展

群体感应(QS)是微生物之间的通讯机制,通过信号分子调控基因表达,这种交流可使细菌表达不同的生理行为,包括病原微生物的毒性、对抗生素的形成、生物膜的形成与生长等。生物膜的形成对微生物的代谢、毒力因子的表达等密切相关。群体感应现象与生物膜的形成相互依赖,生物膜提供菌体聚集场所,避免群体感应信号分子的扩散,聚集菌体的群体感应现象为生物膜的形成提供基础。群体感应系统不仅可直接介导细菌生物膜的形成,还可调节胞内第二信使分子水平,间接调控生物膜的生成。本文中,笔者从直接和协同其他信号分子两方面对细菌生物膜形成机制研究进展进行综述,为在工业应用中降低细菌耐药性、指导食品生产安全、提高功能性生物膜产量等方面提供理论依据。     

MexEF-OprN efflux pump exports the Pseudomonas quinolone signal (PQS) precursor HHQ (4-hydroxy-2-heptylquinoline)

Bacterial cells have evolved the capacity to communicate between each other via small diffusible chemical signals termed autoinducers. Pseudomonas aeruginosa is an opportunistic pathogen involved, among others, in cystic fibrosis complications. Virulence of P. aeruginosa relies on its ability to produce a number of autoinducers, including 4-hydroxy-2-alkylquinolines (HAQ). In a cell density-dependent manner, accumulated signals induce the expression of multiple targets, especially virulence factors. This phenomenon, called quorum sensing, promotes bacterial capacity to cause disease. Furthermore, P. aeruginosa possesses many multidrug efflux pumps conferring adaptive resistance to antibiotics. Activity of some of these efflux pumps also influences quorum sensing. The present study demonstrates that the MexEF-OprN efflux pump modulates quorum sensing through secretion of a signalling molecule belonging to the HAQ family. Moreover, activation of MexEF-OprN reduces virulence factor expression and swarming motility. Since MexEF-OprN can be activated in infected hosts even in the absence of antibiotic selective pressure, it could promote establishment of chronic infections in the lungs of people suffering from cystic fibrosis, thus diminishing the immune response to virulence factors. Therapeutic drugs that affect multidrug efflux pumps and HAQ-mediated quorum sensing would be valuable tools to shut down bacterial virulence.     

The impaired quorum sensing response of Pseudomonas aeruginosa MexAB-OprM efflux pump overexpressing mutants is not due to non-physiological efflux of 3-oxo-C12-HSL

Multidrug (MDR) efflux pumps are ancient and conserved molecular machineries with relevant roles in different aspects of the bacterial physiology, besides antibiotic resistance. In the case of the environmental opportunistic pathogen Pseudomonas aeruginosa, it has been shown that overexpression of different efflux pumps is linked to the impairment of the quorum sensing (QS) response. Nevertheless, the causes of such impairment are different for each analysed efflux pump. Herein, we performed an in-depth analysis of the QS-mediated response of a P. aeruginosa antibiotic resistant mutant that overexpresses MexAB-OprM. Although previous work claimed that this efflux pump extrudes the QS signal 3-oxo-C12-HSL, we show otherwise. Our results evidence that the observed attenuation in the QS response when overexpressing this pump is related to an impaired production of alkyl quinolone QS signals, likely prompted by the reduced availability of one of their precursors, the octanoate. Together with previous studies, this indicates that, although the consequences of overexpressing efflux pumps are similar (impaired QS response), the underlying mechanisms are different. This 'apparent redundancy' of MDR efflux systems can be understood as a P. aeruginosa strategy to keep the robustness of the QS regulatory network and modulate its output in response to different signals.     

Multidrug efflux pumps and antimicrobial resistance in Pseudomonas aeruginosa and related organisms

Pseudomonas aeruginosa is an opportunistic human pathogen characterized by an innate resistance to multiple antimicrobial agents. A major contribution to this intrinsic multidrug resistance is provided by a number of broadly-specific multidrug efflux systems, including MexAB-OprM and MexXY-OprM. In addition, these and two additional tripartite efflux systems, MexCD-OprJ and MexEF-OprN, promote acquired multidrug resistance as a result of mutational hyperexpression of the efflux genes. In addition to antibiotics, these pumps promote export of numerous dyes, detergents, inhibitors, disinfectants, organic solvents and homoserine lactones involved in quorum sensing. The efflux pump proteins are highly homologous and consist of a cytoplasmic membrane-associated drug-proton antiporter of the Resistance-Nodulation-Division (RND) family, an outer membrane channel-forming protein [sometimes called outer membrane factor (OMF)] and a periplasmic membrane fusion protein (MFP). Homologues of these systems have been described in Stenotrophomonas maltophilia, Burkholderia cepacia, Burkholderia pseudomallei and the non-pathogen Pseudomonas putida, where they play a role in export of and resistance to multiple antimicrobial agents and/or organic solvents. Although the natural function of these multidrug efflux systems is largely unknown, their contribution to antibiotic resistance and their conservation in a number of important human pathogens makes them logical targets for therapeutic intervention.     

Bacterial multidrug efflux pumps: Mechanisms,physiology and pharmacological exploitations

Multidrug resistance (MDR) refers to the capability of bacterial pathogens to withstand lethal doses of structurally diverse drugs which are capable of eradicating non-resistant strains. MDR has been identified as a major threat to the public health of human being by the World Health Organization (WHO). Among the four general mechanisms that cause antibiotic resistance including target alteration, drug inactivation, decreased permeability and increased efflux, drug extrusion by the multidrug efflux pumps serves as an important mechanism of MDR. Efflux pumps not only can expel a broad range of antibiotics owing to their poly-substrate specificity, but also drive the acquisition of additional resistance mechanisms by lowering intracellular antibiotic concentration and promoting mutation accumulation. Over-expression of multidrug efflux pumps have been increasingly found to be associated with clinically relevant drug resistance. On the other hand, accumulating evidence has suggested that efflux pumps also have physiological functions in bacteria and their expression is subject tight regulation in response to various of environmental and physiological signals. A comprehensive understanding of the mechanisms of drug extrusion, and regulation and physiological functions of efflux pumps is essential for the development of anti-resistance interventions. In this review, we summarize the development of these research areas in the recent decades and present the pharmacological exploitation of efflux pump inhibitors as a promising anti-drug resistance intervention.     

In-silico interaction studies suggest RND efflux pump mediates polymyxin resistance in Acinetobacter baumannii

Bacterial efflux pumps have emerged as antibiotic resistance determinants and confers multi-drug resistance to a broad range of antimicrobials as well as non-antibiotic substances. A study about translocation of antibiotic molecules through the efflux transporter, will contribute in determining substrate specificity. In the present study, we have explored RND family efflux pump extensively found in Acinetobacter baumannii i.e. AdeABC. Besides, another well studied RND efflux pump, AcrAB-TolC together with a non-RND efflux pump, NorM was investigated for comparative analysis. We employed a series of computational techniques ranging from molecular docking to binding free energy estimation and molecular dynamics simulations to determine the binding affinity for different classes of drugs, namely aminoglycosides, polymyxins, β-lactams, tetracyclines, glycylcyclines, quinolones and metronidazole with AdeB, AcrB, and NorM efflux proteins. Our results revealed that class polymyxins has the highest binding affinity with the RND efflux pumps i.e. AcrAB-TolC and AdeABC as well as non-RND efflux pump, NorM. The experimental validation study demonstrated bigger zone of inhibition in presence of efflux pump inhibitor than polymyxin alone thus unveiling its specificity toward efflux pump. The reported experimental data comprising of minimum inhibitory concentration of antibiotics toward these efflux pumps also support our finding based on in silico approach. To recapitulate the outcome, polymyxins shows maximum specificity toward RND as well as non-RND efflux pump and may unlatch the way to rationally develop new potential antibacterial agents as well as efflux pump inhibitors in order to combat resistance.     

Mutations in the central cavity and periplasmic domain affect efflux activity of the resistance-nodulation-division pump EmhB from Pseudomonas fluorescens cLP6a

The EmhABC efflux system in Pseudomonas fluorescens cLP6a is homologous to the multidrug and solvent efflux systems belonging to the resistance-nodulation-division (RND) family and is responsible for polycyclic aromatic hydrocarbon transport, antibiotic resistance, and toluene efflux. To gain a better understanding of substrate transport in RND efflux pumps, the EmhB pump was subjected to mutational analysis. Mutagenesis of amino acids within the central cavity of the predicted three-dimensional structure of EmhB showed selective activity towards antibiotic substrates. An A384P/A385Y double mutant showed increased susceptibility toward rhodamine 6G compared to the wild type, and F386A and N99A single mutants showed increased susceptibility to dequalinium compared to the wild type. As well, the carboxylic acid side chain of D101, located in the central cavity region, was found to be essential for polycyclic aromatic hydrocarbon transport and resistance to all antibiotic substrates of EmhB. Phenylalanine residues located within the periplasmic pore domain were also targeted for mutagenesis, and the F325A and F281A mutations significantly impaired efflux activity for all EmhB substrates. One mutation (A206S) in the outer membrane protein docking domain increased antibiotic resistance and toluene tolerance, demonstrating the important role of this domain in transport activity. These data demonstrate the roles of the central cavity and periplasmic domains in the function of the RND efflux pump EmhB.