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。     

嗜麦芽窄食单胞菌外排泵的研究进展

嗜麦芽窄食单胞菌为机会致病菌,是医院内感染的一个重要致病菌,据报道,该菌对临床使用的多数抗生素都有耐药性,耐β－内酰胺类,氨基糖苷类和大环内酯类药物,多重外排泵是嗜麦芽窄食单胞菌固有和获得性多重耐药的最重要原因,该菌参与抗生素和多种毒性物质外排的泵系统为SmeDEF和SmeABC。     

单增李斯特菌耐药外排泵研究进展

单增李斯特菌是一种重要的人兽共患食源性胞内致病菌,广泛存在于自然环境中且易污染动物性食品,人及动物感染后可引起严重的李斯特菌病,死亡率高达30%。单增李斯特菌通常对多种药物敏感,然而,因不合理使用抗菌药或消毒剂形成的选择压力导致李斯特菌多重耐药情况的报道日渐增多。外排泵蛋白是细菌中一类重要的蛋白,可参与机体多种生物学过程,包括影响细菌对抗生素敏感性、促进有毒化合物泵出、影响细菌毒力等。本文综述了近年来关于单增李斯特菌耐药外排泵的功能及调控机制的研究进展,为深入理解李斯特菌耐药等环境适应机制及有效控制该病原污染传播和筛选抗感染药物新靶点提供理论基础。     

细菌耐多药外排泵的研究进展

近年来,由于抗生素的不合理及广泛使用,全球多重耐药菌和广泛耐药菌不断出现。关于细菌耐药机制中外排泵及生物膜形成的研究越来越受关注。研究发现,外排泵与生物膜形成有密切联系,不同细菌的不同外排泵对生物膜形成的影响各异,而生物膜形成又影响外排泵基因表达。本文就细菌耐多药外排泵的研究进展进行综述。     

药物外排泵与生物被膜在微生物耐药机制中的相关性研究进展

生物被膜是介导微生物耐药与多重耐药的一大热点机制,涉及微生物的生长代谢、耐药基因等基因表型改变、群体感应系统的调控及药物外排泵等多重因素。耐药基因、药物外排泵与生物被膜在微生物耐药机制中,具有复杂而密切的相互影响。分别从生物被膜对药物外排泵、耐药基因的影响,药物外排泵对生物被膜的影响,以及药物外排泵和微生物生物被膜共同的调节因素,对近年来的相关研究进展作一综述。     

结核分枝杆菌外排泵研究进展

结核病是由结核分枝杆菌(Mycobacterium tuberculosis,Mtb)引起的一种传染病。随着多药耐药和广泛耐药结核分枝杆菌的出现,结核病的治疗变得更为艰难。近年来研究发现,结核分枝杆菌存在外排泵是其耐药的原因之一,现已发现结核分枝杆菌的主要易化子超家族(major facilitator superfamily,MFS)、三磷酸腺苷(adenosine-triphosphate,ATP)结合盒超家族(ATP-Binding Cassette,ABC)、耐受小节分裂区家族(resistance-nodulation-division,RND)和小耐多药性家族(small multidrug resistance,SMR)外排泵。但是人们对结核分枝杆菌外排泵介导的耐药现象认识不足,仍缺乏从新药发现角度研发外排泵抑制剂的研究。本文拟对结核分枝杆菌的ABC、MFS、RND和SMR外排泵的结构和功能,以及结核分枝杆菌外排泵抑制剂的研究进展进行综述。     

鲍曼不动杆菌耐药程度与其主动外排泵蛋白的相关性研究

目的:探讨鲍曼不动杆菌耐药程度与其主动外排泵蛋白的相关性。方法:首先用纸片扩散法检测64株临床鲍曼不动杆菌对8种抗菌药物的敏感性;将其分为A组(0～2种抗生素耐药)、B组(对3～5种抗生素耐药)和C组(对6～8种抗生素耐药);检测64株临床鲍曼不动杆菌对罗丹明6G的外排情况,筛选出罗丹明6G外排明显增加的菌株;并用逆转录-聚合酶链反应(RT-PCR)方法检测主动外排泵基因AdeABC的表达水平。结果:64株鲍曼不动杆菌中有4株对0～2种抗生素耐药(A组),对3～5种抗生素耐药的有33株(B组),对6～8种抗生素耐药的有27株(C组);多重耐药组鲍曼不动杆菌罗丹6G外排明显增高,外排程度A组相似文献   

革兰氏阴性菌多药外排泵MacAB-TolC的功能与结构

病原菌日益增长的多药耐药性已成为人类健康和生命的主要威胁之一。多药外排泵介导的药物主动外排是细菌产生耐药性的主要原因之一，给感染性疾病的防治带来了极大挑战。深入研究多药外排泵，了解其作用机制，揭示药物结合位点，可以为临床抗感染治疗提供新思路。在革兰氏阴性菌中，一些多药外排泵形成跨越细菌胞外被膜的三联复合物。MacAB-TolC是普遍存在于革兰氏阴性菌中的ABC家族三联外排泵，在近些年逐渐被关注。本文综述了关于MacAB-TolC外排泵的功能与结构研究以及相应抑制剂研发方面的进展。MacAB-TolC外排泵的底物种类多样，包含抗生素、毒力因子以及代谢产物。本文据此将MacAB-TolC外排泵的功能归纳为3类：耐药功能、病理功能和生理功能，并对相应功能分别进行了阐述。在结构研究方面，本文总结了MacAB-TolC外排泵单个组分的晶体结构和组装完全的MacAB-TolC三联外排泵的冷冻电镜单颗粒结构，并对结构数据所揭示的MacAB-TolC外排泵发挥功能的机制进行了论述。最后，本文介绍了MacAB-TolC外排泵抑制剂的最新研究进展，指出解析MacAB-TolC的原位结构，以及MacB结合底...     

结核杆菌的药物外排泵

外排泵基因过度表达促使细胞内的药物转移到细胞外,胞内药物浓度下降,致使药物临床疗效降低或无效。外排泵上有多个与识别底物结构无关的阴离子凹穴(底物结合位点),通过静电引力非特异性结合各种含阳离子的药物,在能量协助下将药物排到细胞外,进而导致细菌抗药性的产生。研究表明,结核杆菌基因组中存在外排泵基因,但仅分离到几个有功效的外排泵。本文就相关研究进展进行综述。     

近三年鲍曼不动杆菌耐药性变迁及外排泵基因研究

目的研究鲍曼不动杆菌的耐药性变迁及外排泵基因携带情况,为控制医院感染提供依据。方法运用纸片扩散法检测我院2015-2017年临床分离的鲍曼不动杆菌对18种抗菌药物的耐药性,并对耐药性变化趋势进行分析。PCR技术检测多重耐药菌adeB、adeJ、adeE、abeM四种外排泵基因的携带情况。结果三年时间共分离出鲍曼不动杆菌385株,检出数量逐年升高,以呼吸科和重症医学科为主,分别占32.7%和28.3%。药敏结果显示鲍曼不动杆菌对多黏菌素B (0.0%)、替加环素(0.0%～1.6%)耐药率最低,其次为头孢哌酮舒巴坦(22.9%～32.0%)。三年来鲍曼不动杆菌对左氧氟沙星、亚胺培南、美罗培南耐药率有显著升高,超过20%,对庆大霉素、阿米卡星耐药率下降超过10%。172株多重耐药菌(44.7%)中,PCR扩增结果显示adeB和adeJ阳性率分别为76.7%和51.2%,并有5株(2.91%)检出adeE基因。结论近三年鲍曼不动杆菌耐药性呈上升趋势,外排泵是导致其耐药的机制之一。     

Efflux pump inhibition by 11H-pyrido[2,1-b]quinazolin-11-one analogues in mycobacteria

Mycobacterium tuberculosis infection causes 1.8 million deaths worldwide, of which half a million has been diagnosed with resistant tuberculosis (TB). Emergence of multi drug resistant and extensive drug resistant strains has made all the existing anti-TB therapy futile. The major involvement of efflux pump in drug resistance has made it a direct approach for therapeutic exploration against resistant M. tuberculosis. This study demarcates the role of 11H-pyrido[2,1-b]quinazolin-11-one (quinazolinone) analogues as efflux pump inhibitor in Mycobacterium smegmatis. Sixteen quinazolinone analogues were synthesized by treating 2-aminopyridine and 2-fluorobenzonitrile with K^tOBu. Analogues were tested, and 3a, 3b, 3c, 3g, 3j, 3l, 3m, and 3p were found to modulate EtBr MIC by >4 whereas 3a, 3g, 3i and 3o showed >4 modulation on norfloxacin MIC. 3l and 3o in addition to their very low toxicity they showed high EtBr and norfloxacin accumulation respectively. Time kill curve showed effective log reduction in colony forming unit in presence of these analogues, thus confirming their role as efflux pump inhibitor. Through docking and alignment studies, we have also shown that the LfrA amino acid residues that the analogues are interacting with are present in Rv2333c and Rv2846c of M. tuberculosis. This study have shown for the first time the possibility of developing the 11H-pyrido[2,1-b]quinazolin-11-one analogues as efflux pump inhibitors for M. smegmatis and hence unbolts the scope to advance this study against resistant M. tuberculosis as well.     

Bacterial efflux systems and efflux pumps inhibitors

It is now well established that bacterial resistance to antibiotics has become a serious problem of public health that concerns almost all antibacterial agents and that manifests in all fields of their application. Among the three main mechanisms involved in bacterial resistance (target modification, antibiotic inactivation or default of its accumulation within the cell), efflux pumps, responsible for the extrusion of the antibiotic outside the cell, have recently received a particular attention. Actually, these systems, classified into five families, can confer resistance to a specific class of antibiotics or to a large number of drugs, thus conferring a multi-drug resistance (MDR) phenotype to bacteria. To face this issue, it is urgent to find new molecules active against resistant bacteria. Among the strategies employed, the search for inhibitors of resistance mechanisms seems to be attractive because such molecules could restore antibiotic activity. In the case of efflux systems, efflux pump inhibitors (EPIs) are expected to block the pumps and such EPIs, if active against MDR pumps, would be of great interest. This review will focus on the families of bacterial efflux systems conferring drug resistance, and on the EPIs that have been identified to restore antibiotic activity.     

Reversed isoniazids: Design,synthesis and evaluation against Mycobacterium tuberculosis

Novel reversed isoniazid (RINH) agents were synthesized by covalently linking isoniazid with various efflux pump inhibitor (EPI) cores and their structural motifs. These RINH agents were then evaluated for anti-mycobacterial activity against sensitive, isoniazid mono-resistant and MDR clinical isolates of M. tuberculosis and a selected number of compounds were also tested ex vivo for intracellular activity as well as in the ethidium bromide (EB) assay for efflux pump inhibition efficacy. The potency of some compounds against various strains of M. tuberculosis (4a–c, 7 and 8; H37Rv-MIC₉₉ ≤1.25?µM, R5401-MIC₉₉ ≤2.5?µM, X_61-MIC₉₉ ≤5?µM) demonstrated the potential of the reversed anti-TB agent strategy towards the development of novel anti-mycobacterial agents to address the rapidly growing issue of resistance. Further, macrophage activity with >90% inhibition by 1a–c and 3b (MIC₉₀ ≤13.42?µM) and inhibition of EB efflux demonstrated by these compounds are encouraging.     

Contribution of the multidrug efflux pump LfrA to innate mycobacterial drug resistance

Multidrug resistance (MDR) in bacteria has been associated with efflux pumps that export structurally unrelated compounds and decrease cytoplasmic drug accumulation. To investigate MDR in mycobacteria, we studied the Mycobacterium smegmatis mutant mc(2)11, which is resistant to doxorubicin, tetracycline, rhodamine, ethidium bromide and the hydrophilic fluoroquinolones. A genomic library constructed from this mutant was used to select clones conferring resistance to doxorubicin. Surprisingly, the clone selected encodes the efflux pump LfrA, which has been reported to confer resistance to hydrophilic fluoroquinolones, ethidium bromide, rhodamine, and acriflavine. To define the contribution of LfrA to the innate mycobacterial drug resistance and to the MDR phenotype in mc(2)11, the lfrA gene was disrupted in both the mc(2)11 mutant and the mc(2)155 wild-type parent. LfrA disruption of the wild-type strain decreased resistance to ethidium bromide and acriflavine, and increased accumulation of ethidium bromide. However, disruption of lfrA gene results only in a 2-fold decrease in minimal inhibitory concentrations (MICs) for ciprofloxacin, doxorubicin, rhodamine, and accumulation of [(14)C]ciprofloxacin was unchanged. LfrA disruption of the MDR strain mc(2)11 produced a similar phenotype. Thus, LfrA contributes significantly to the intrinsic MICs of M. smegmatis for ethidium bromide and acriflavine, but not for ciprofloxacin, doxorubicin or rhodamine.     

Chloramphenicol and expression of multidrug efflux pump in Enterobacter aerogenes

Chloramphenicol has been reported to act as an inducer of the multidrug resistance in Escherichia coli. A resistant variant able to grow on plates containing 64 microg/ml chloramphenicol was obtained from the Enterobacter aerogenes ATCC 13048-type strain. Chloramphenicol resistance was due to an active efflux of this antibiotic and it was associated with resistance to fluoroquinolones and tetracycline, but not to aminoglycoside or beta-lactam antibiotics. MDR in the chloramphenicol-resistant variant is linked to the overexpression of the major AcrAB-TolC efflux system. This overexpression seems unrelated to the global Mar and the local AcrR regulatory pathways.     

Imipenem and expression of multidrug efflux pump in Enterobacter aerogenes

Imipenem is often used to treat intensive care unit patients infected by Enterobacter aerogenes, but it is leading to an increasing number of antibiotic resistant strains. Clinical isolates and imipenem resistant variants presented a high level of resistance to beta-lactam antibiotic group and to chemically unrelated drugs. We report here that imipenem selects strains which contain active efflux pumps ejecting various unrelated antibiotics including quinolones, tetracycline, and chloramphenicol. An increase of AcrA, an efflux pump component, was observed in the imipenem resistant variants. The overexpression of marA, involved in the genetic control of membrane permeability via porin and efflux pump expression, indicated the activation of the resistance genetic cascade in imipenem resistant variants.     

Directed evolution of a bacterial efflux pump: adaptation of the E. coli TolC exit duct to the Pseudomonas MexAB translocase

Bacterial multidrug efflux pumps operate by periplasmic recruitment and opening of TolC family outer membrane exit ducts by cognate inner membrane translocases. Directed evolution of active hybrid pumps was achieved by challenging a library of mutated, shuffled TolC variants to adapt to the non-cognate Pseudomonas MexAB translocase, and confer resistance to the efflux substrate novobiocin. Amino acid substitutions in MexAB-adapted TolC variants that endowed high resistance were recreated independently, and revealed that MexAB-adaptation was conferred only by substitutions located in the lower alpha-helical barrel of TolC, specifically the periplasmic equatorial domain and entrance coiled coils. These changes converge to the native MexAB partner OprM, and indicate an interface key to the function and diversity of efflux pumps.     

Relative contribution of target gene mutation and efflux to varying quinolone resistance in Irish Campylobacter isolates

The contribution of target gene mutations and active efflux to varying levels of quinolone resistance in Irish Campylobacter isolates was studied. The Thr-86-Ile modification of GyrA did not correlate with the level of quinolone resistance. The efflux pump inhibitor Phe-Arg-beta-Naphthylamide (PAbetaN) had no effect on the MICs to ciprofloxacin. In contrast, a PAbetaN sensitive efflux system contributed to the low-level nalixidic acid resistance phenotype. The lack of effect of PAbetaN in high-level resistant nalidixic isolates may be attributable to mutations identified in the CmeB efflux pump of these isolates. PAbetaN may have limited diagnostic value in the assessment of the contribution of efflux pump activity to ciprofloxacin resistance in Campylobacter.