细菌锌离子调控体系与感染北大核心CSCD

锌(Zn)是生命体不可或缺的微量元素,对细菌和宿主同等重要。细菌体内锌离子稳态的维持依赖锌离子转运和调控体系。宿主通过限制锌离子或高锌离子中毒来控制细菌感染。为了在宿主体内生存,细菌必须表达高亲和力的锌离子转运系统,如ZnuABC,以获取足够的锌离子。由于锌与细菌大量的代谢和毒性通路密切相关,在细菌建立感染的过程中尤为重要,因此通过抑制锌离子转运系统来影响锌离子的稳态,将成为一个非常有发展前途的新型抗菌策略。     

铜绿假单胞菌锌离子摄取系统的研究进展

锌作为一种结构、催化和信号的成分,在许多生理过程中起着关键的作用。它也是病原微生物生长所必需的,不但参与病原微生物代谢和各种毒力因子的调控,而且是病原微生物在宿主中感染和定殖所必需的。铜绿假单胞菌侵染宿主发挥毒力时,宿主会采取营养免疫的策略来限制体内环境中游离的锌离子浓度而抑制该病原菌的感染和定殖。反过来,铜绿假单胞菌则通过自身的锌离子摄取系统克服宿主的营养免疫防御。本综述重点介绍了铜绿假单胞菌中已知的3种锌离子摄取系统(ZnuABC摄取系统、HmtA摄取系统和CntRLMN摄取系统)和锌摄取调控蛋白Zur,同时分析了其他潜在的锌离子摄取途径,并进一步阐述了铜绿假单胞菌锌离子摄取系统在其侵染宿主发挥毒力时和抵御宿主营养免疫时发挥的重要作用。系统总结铜绿假单胞菌对锌离子的摄取过程,旨在为靶向锌离子摄取系统的新型抗铜绿假单胞菌药物的开发提供指导。     

革兰氏阴性菌亚铁离子转运系统的组成及作用机制

几乎所有细菌的生长都离不开铁元素。在有氧的环境中,三价铁离子几乎无法被细菌直接利用。但是在宿主胃肠道中,铁元素主要以可溶性的亚铁离子形式存在,它们可通过革兰氏阴性菌外膜直接进入胞周质,在周质通过亚铁离子转运系统,将铁离子转运至胞浆供细菌利用。绝大多数阴性菌主要是通过Feo转运系统利用亚铁离子,大肠杆菌的Feo转运系统由feoA、feoB和feoC3个基因组成。除Feo转运系统外,还发现Yfe转运系统、Efe转运系统、Sit转运系统等。本文重点介绍革兰氏阴性菌Feo转运系统的组成及作用机制,以期为进一步研究细菌亚铁离子的转运机制提供参考。     

革兰氏阴性菌血红素载体蛋白Hemophore的结构及作用机制

血红素作为宿主体内最丰富的铁离子来源,是致病菌营养竞争的主要目标,尤其对于血红素自身合成途径部分丧失的细菌。革兰氏阴性菌血红素转运系统由血红素载体蛋白(Hemophore)、外膜血红素受体、TonB-ExbB-ExbD复合物、ABC转运体等组成。Hemophore是存在于细菌细胞膜上或分泌到胞外环境中的一种蛋白。它能从宿主血红素结合蛋白中捕获血红素并将其传递给外膜受体。目前,在不同革兰氏阴性菌中已发现3种类型的Hemophore,分别是HasA、HxuA和HmuY型。本文将详细描述这3种Hemophore捕获血红素及与外膜受体相互作用的机制,以期为进一步研究其他细菌血红素载体蛋白的功能及作用机制奠定基础。     

革兰氏阴性菌血红素转运系统结构及功能特点

铁是大多数生物包括细菌生存的必需营养元素．对于感染宿主的致病细菌,血红素(heme/haem)可作为一种主要的铁来源．血红素转运系统在革兰氏阴性菌和革兰氏阳性菌中均有发现和鉴定,其转运机制在革兰氏阴性菌中有较为深入研究．革兰氏阴性菌血红素转运系统主要由分泌于细胞外的血红素载体(hemophore)、血红素受体、TonB ExbB ExbD复合物、ABC转运体、血红素降解蛋白和调控蛋白等结构单元组成．对参与该系统的各个蛋白结构特点以及它们之间的相互作用机制的讨论,有助于对病原菌致病机制的深入研究和抗菌新药的研发．     

细菌铁离子利用系统与宿主抗感染免疫

铁离子对于绝大多数微生物及其宿主都是必需的营养物质,它是许多蛋白和酶的重要辅助因子。致病菌为了成功致病,进化出了多种机制来摄取宿主体内的铁离子,其中主要包括三价铁离子转运系统和亚铁血红素转运系统。而对于宿主而言,铁离子虽然在细胞呼吸和DNA复制等过程中扮演着重要的角色,但过多的铁离子也会产生细胞毒性。因此,宿主体内的铁离子浓度必须受到严格的调控。为限制病原菌感染,宿主先天性免疫系统进化出一系列限制自身铁离子进入微生物的机制,这一过程被称为宿主的"营养免疫"。从病原菌和宿主两个方面详细讨论病原菌是如何从宿主获取铁离子以及宿主如何防止细菌获取铁离子的分子机制,能为更好地提高宿主免疫力来阻止细菌感染和开发有效的非抗生素类药物提供理论依据。     

细菌金属离子外排系统及金属稳态调控

铁、铜、锌、锰等金属离子是各类生物体生存和增殖所必需的微量元素,可影响生物体内蛋白酶活性、免疫反应、生理过程和抗感染机制。细菌感染过程中,宿主可通过限制或提高体内环境中金属离子的浓度来抑制细菌增殖,与此同时,细菌进化出各种转运系统以适应宿主体内金属离子水平的变化。由于不同细菌的金属离子外排系统在结构和生化特性上存在变异,它们呈现出独特的金属离子外排模式。本文根据现有文献报道及本团队研究结果,对铁、铜、锌和锰离子的细菌外排系统进行讨论和总结,旨在综述目前对细菌金属离子稳态调控机制研究进展的认识,为深入理解细菌金属稳态调控相关机制提供参考。     

革兰氏阴性菌TonB依赖性受体的功能与结构研究进展*

为维持生长所需,革兰氏阴性菌需要从外界摄取多种营养物质。分子量小于600 Da的分子可以通过自由扩散的方式通过革兰氏阴性菌的外膜,而大分子物质则需要特殊的转运系统才能将其转运至革兰氏阴性菌的胞内。革兰氏阴性菌对大分子营养物质的识别和转运主要由TonB依赖性受体负责完成。所有革兰氏阴性菌中均有TonB依赖性受体的存在,然而不同种类的革兰氏阴性菌拥有TonB依赖性受体的数量不同且功能各异。最近研究表明,TonB依赖性受体不仅参与了铁、血红素、锰、锌、镍、维生素、碳水化合物等多种营养物质的摄取,而且参与了蛋白酶的分泌。为对TonB依赖性受体提供更为深入和系统的理解,详细介绍了目前已知的TonB依赖性受体的功能及结构,以期为更进一步探知TonB依赖性受体未知功能提供可参考依据。     

金属蛋白质组学研究锌离子匮乏对肺炎链球菌的影响

【目的】研究锌离子缺乏对肺炎链球菌的影响,找到其适应性生长机制。【方法】以肺炎链球菌为模型,利用加锌和不加锌的培养基对细菌进行培养,收集细胞蛋白,采用双向凝胶电泳,结合金属亲和层析和质谱技术鉴定差异表达蛋白,进而通过生物信息学分析蛋白质相互关系,从中找到细菌适应锌离子匮乏条件的关键代谢通路和蛋白。【结果】测定了在限制培养条件下肺炎链球菌的最适生长浓度,建立了锌离子调控蛋白双向凝胶电泳图谱,鉴定到了96个差异表达蛋白斑点,共67个差异蛋白,其中32个表达下调,35个表达上调,锌离子调控蛋白的作用可能主要体现在糖代谢、核酸代谢、氧化还原作用、辅助蛋白质翻译、合成及折叠等方面。建立了锌结合蛋白的差异表达图谱,鉴定到了10个差异表达蛋白斑点,共7个差异蛋白,其中1个表达下调,6个表达上调。锌离子结合蛋白的作用可能主要体现在应对压力、蛋白质折叠和转运、氨基酸代谢等方面。【结论】肺炎链球菌主要通过调控碳水化合物代谢和核酸代谢等多个代谢通路来应对宿主锌金属离子匮乏的环境,从而使自身能够存活并对宿主形成感染。本研究为揭示细菌在宿主环境,特别是金属离子匮乏条件下的适应性生长机制提供理论基础。     

革兰氏阴性菌脂蛋白Lol系统转运蛋白的功能及表面展示分泌机制

细菌脂蛋白是细胞膜的重要组成成分,在革兰氏阴性菌的生理及致病性中扮演着重要的角色。革兰氏阴性菌中已知负责胞内脂蛋白转运的是Lol(Localization of lipoprotein)系统。该系统识别成熟脂蛋白的分泌信号,将外膜脂蛋白转运并定位于细胞外膜内侧。近年来的研究发现,跨细胞外膜进行表面展示的脂蛋白实际上在革兰氏阴性菌中广泛存在,其分泌机制开始成为研究热点。为了对革兰氏阴性菌中脂蛋白分泌机制的研究现状有一个系统全面的了解,本文概述了脂蛋白转运过程中Lol系统5个转运蛋白的功能与保守性、不同细菌中脂蛋白分泌信号的差异以及表面展示脂蛋白可能的分泌机制。     

Zinc Piracy as a Mechanism of Neisseria meningitidis for Evasion of Nutritional Immunity

The outer membrane of Gram-negative bacteria functions as a permeability barrier that protects these bacteria against harmful compounds in the environment. Most nutrients pass the outer membrane by passive diffusion via pore-forming proteins known as porins. However, diffusion can only satisfy the growth requirements if the extracellular concentration of the nutrients is high. In the vertebrate host, the sequestration of essential nutrient metals is an important defense mechanism that limits the growth of invading pathogens, a process known as “nutritional immunity.” The acquisition of scarce nutrients from the environment is mediated by receptors in the outer membrane in an energy-requiring process. Most characterized receptors are involved in the acquisition of iron. In this study, we characterized a hitherto unknown receptor from Neisseria meningitidis, a causative agent of sepsis and meningitis. Expression of this receptor, designated CbpA, is induced when the bacteria are grown under zinc limitation. We demonstrate that CbpA functions as a receptor for calprotectin, a protein that is massively produced by neutrophils and other cells and that has been shown to limit bacterial growth by chelating Zn²⁺ and Mn²⁺ ions. Expression of CbpA enables N. meningitidis to survive and propagate in the presence of calprotectin and to use calprotectin as a zinc source. Besides CbpA, also the TonB protein, which couples energy of the proton gradient across the inner membrane to receptor-mediated transport across the outer membrane, is required for the process. CbpA was found to be expressed in all N. meningitidis strains examined, consistent with a vital role for the protein when the bacteria reside in the host. Together, our results demonstrate that N. meningitidis is able to subvert an important defense mechanism of the human host and to utilize calprotectin to promote its growth.     

Iron acquisition by Streptococcus species: An updated review

Streptococcus is a genus of spherical Gram-positive bacteria responsible for many cases of meningitis, bacterial pneumonia, endocarditis, erysipelas, and necro-tizing fasciitis. To survive in the host environment with limited free iron available, Streptococcus species have developed various mechanisms to uptake iron as an essential nutrient. They can directly extract the metal ions from host iron-containing proteins such as ferritin, transferrin, lactoferrin, and hemoproteins. Other iron-uptake strategies, which are broadly distributed in the strains, include the employment of specialized secreted hemophores to acquire heme and the usage of small molecules called siderophores as high-affinity ferric chelators. This review intends to discuss the most recent discoveries of these iron acquisition systems and their relevant regulators in Streptococcus species.     

Pushing the envelope: extracytoplasmic stress responses in bacterial pathogens

Despite being nutrient rich, the tissues and fluids of vertebrates are hostile to microorganisms, and most bacteria that attempt to take advantage of this environment are rapidly eliminated by host defences. Pathogens have evolved various means to promote their survival in host tissues, including stress responses that enable bacteria to sense and adapt to adverse conditions. Many different stress responses have been described, some of which are responsive to one or a small number of cues, whereas others are activated by a broad range of insults. The surface layers of pathogenic bacteria directly interface with the host and can bear the brunt of the attack by the host armoury. Several stress systems that respond to perturbations in the microbial cell outside of the cytoplasm have been described and are known collectively as extracytoplasmic or envelope stress responses (ESRs). Here, we review the role of the ESRs in the pathogenesis of Gram-negative bacterial pathogens.     

Outer membrane protein biogenesis in Gram-negative bacteria

Gram-negative bacteria contain a double membrane which serves for both protection and for providing nutrients for viability. The outermost of these membranes is called the outer membrane (OM), and it contains a host of fully integrated membrane proteins which serve essential functions for the cell, including nutrient uptake, cell adhesion, cell signalling and waste export. For pathogenic strains, many of these outer membrane proteins (OMPs) also serve as virulence factors for nutrient scavenging and evasion of host defence mechanisms. OMPs are unique membrane proteins in that they have a β-barrel fold and can range in size from 8 to 26 strands, yet can still serve many different functions for the cell. Despite their essential roles in cell survival and virulence, the exact mechanism for the biogenesis of these OMPs into the OM has remained largely unknown. However, the past decade has witnessed significant progress towards unravelling the pathways and mechanisms necessary for moulding a nascent polypeptide into a functional OMP within the OM. Here, we will review some of these recent discoveries that have advanced our understanding of the biogenesis of OMPs in Gram-negative bacteria, starting with synthesis in the cytoplasm to folding and insertion into the OM.     

Iron acquisition by Streptococcus species: An updated review

Streptococcus is a genus of spherical Gram-positive bacteria responsible for many cases of meningitis, bacterial pneumonia, endocarditis, erysipelas, and necrotizing fasciitis. To survive in the host environment with limited free iron available, Streptococcus species have developed various mechanisms to uptake iron as an essential nutrient. They can directly extract the metal ions from host iron-containing proteins such as ferritin, transferrin, lactoferrin, and hemoproteins. Other iron-uptake strategies, which are broadly distributed in the strains, include the employment of specialized secreted hemophores to acquire heme and the usage of small molecules called siderophores as high-affinity ferric chelators. This review intends to discuss the most recent discoveries of these iron acquisition systems and their relevant regulators in Streptococcus species.     

A novel assay for the distribution of pyrithione biocides in bacterial cells

Sodium pyrithione and zinc pyrithione (NaPT and ZnPT, respectively) are widely used as cosmetic preservatives and metal chelating agents. They are commonly assayed using thin layer chromatography (TLC) and high performance liquid chromatography (HPLC). However, a simple quantitative colorimetric assay has not been previously reported for these compounds. This paper describes the development of a spectrophotometric assay for the quantification of the pyrithiones which is based on the chelation of copper (II) ions by the biocides. This assay was developed in order to facilitate the determination of the distribution of these biocides in the Gram-negative bacteria Escherichia coli NCIMB 10000 and Pseudomonas aeruginosa NCIMB 10548. Sodium pyrithione was exhibited only in the cytosol of E. coli and Ps. aeruginosa . Zinc pyrithione, however, was assayed in the cytosol of both bacteria and was found in the cell envelope of Ps. aeruginosa . These findings suggest that the pyrithione biocides are active within bacterial cells as well as at the cell membrane.