革兰氏阴性菌TonB-ExbB-ExbD复合物的功能、作用机制、分布及进化

革兰氏阴性菌在生长繁殖过程中需要从外界摄取营养物质。一些小分子营养物质可以自由地通过革兰氏阴性菌的细胞膜,而一些大分子营养物质的转运需要特异性的TonB复合物依赖性的外膜受体进行转运。TonB复合物由TonB、ExbB、ExbD构成,是革兰氏阴性菌对外界营养物质主动转运过程的能量提供单位,在革兰氏阴性菌分布广泛。近年来,对TonB-ExbB-ExbD复合物的功能、结构及作用机制取得了重大研究进展,然而此复合物在不同的细菌也存在功能及作用机制上的差异。基于此背景,本文综述了TonB复合物的功能和结构研究进展,并分析了TonB复合物在革兰氏阴性菌中的分布、进化,比较了不同革兰氏阴性菌此复合物的差异,有助于进一步发现和揭示TonB复合物的新功能与作用机制。     

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。     

部分革兰氏阴性菌TonB蛋白的结构特点及作用机制

摘要:在革兰氏阴性菌内,TonB系统对环境中的重要营养物质的摄取至关重要。TonB系统由锚定在内膜的ExbB-ExbD和周质蛋白TonB组成,它为TonB依赖性外膜受体(TBDTs)提供能量,使其转运营养物质。TonB系统普遍参与了铁、血红素、维生素B12、碳水化合物及多种过渡金属元素等多种重要物质的转运过程。TonB蛋白的功能与其特殊的结构密切相关,它的结构包括起固定作用的氨基端结构域、柔韧可变的脯氨酸富集的中间结构域和与TonB依赖性受体相互作用的羧基端结构域。虽然TonB蛋白结构特点较为清晰,但 其精确作用机制尚未被完全揭示。本文综述了革兰氏阴性菌TonB依赖性的营养物质摄取、TonB蛋白的结构特点、作用机制模型及表达调控,以期为进一步研究TonB蛋白功能提供理论基础和参考。     

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．     

鸭疫里默氏杆菌铁离子代谢机制研究进展

铁离子是大多数细菌生存所必需的一种营养物质,但过多的铁离子会通过芬顿反应产生的活性氧对细菌造成损伤。因此,细菌通过摄取、调控、螯合、外排等机制维持体内铁离子的稳态。鸭疫里默氏杆菌(Riemerella anatipestifer)是一种最新被归类于威克斯菌科里氏杆菌属的革兰氏阴性菌。该菌主要感染禽类,参与该菌的铁离子代谢基因具有特别之处。本文对鸭疫里默氏杆菌铁离子代谢机制研究进展进行了系统总结和阐述,包括该菌的TonB系统、TonB依赖性受体、Fur蛋白及Dps蛋白等在铁离子转运、调控、螯合中的功能,以及以上蛋白在鸭疫里默氏杆菌致病中的作用,以期更全面地理解鸭疫里默氏杆菌铁代谢机制,并为进一步深入研究该菌铁离子代谢提供理论依据和参考。     

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。     

细菌内依赖TonB的外膜铁转运体的研究进展

铁是细菌所必需的微量营养元素,但由于易被氧化溶解性低,生物体的利用率大大降低。细菌在进化过程中形成多种策略来吸收环境中低浓度的铁,不同类型铁的吸收通过外膜上依赖TonB的转运体(TonB-dependent transporters,TBDTs)完成,TBDTs结合不同形式的铁复合物,通过内膜上的TonB-ExbB-ExbD复合物提供能量完成转运,对其机制的研究一直是微生物基础生命活动研究中的热点问题。近年来新鉴定了一些TBDTs的结构,并对其功能和转运机制有了更深入的研究,对此进行了综述,不仅有助于进一步揭示细菌的铁转运机制,而且有助于寻找新的靶位点以开发新的治疗药物。     

革兰氏阴性菌脂多糖运输系统的构成及作用机制

革兰氏阴性菌包含有两层组分不同的膜结构——内膜和外膜,对大多数革兰氏阴性菌而言,脂多糖(lipopolysaccharides,LPS)是其外膜上最主要的脂质成分,锚定在外膜小叶(the outer leaflet of the OM)上,是革兰氏阴性菌固有免疫的重要组成部分。脂多糖运输系统(lipopolysaccharide transport system,Lpt)将胞内装配完整的LPS正确装配到外膜,使得与脂多糖相关的阻渗、有机溶剂耐受性、疏水性抗生素耐受性、膜通透性等功能得以实现。该运输系统的正确作用主要依赖7个不同的脂多糖运输蛋白(Lpt ABCDEFG)协同完成,整个系统贯穿细菌内膜至外膜,由内膜上ABC转运体复合物Lpt B2FG、胞质内转运协同蛋白Lpt A/C及被许多学者称作脂多糖运输的"命门"的外膜蛋白复合物Lpt DE共同构成。本文就革兰氏阴性菌脂多糖的具体结构功能进行简介,进而综述脂多糖运输系统的7个蛋白的构成和作用机制,以期为进一步研究该系统中每个蛋白的功能提供理论基础及参考。     

希瓦氏菌铁稳态及调控的研究进展

铁元素通常以蛋白辅因子的形式参与一系列重要的生命过程,是绝大多数生命必需的营养物质。在细菌生命过程中,一方面铁短缺是必须克服的严峻挑战,另一方面铁过量又会危及生命。铁的这种二元性质要求细菌必须严格保持体内的铁稳态。当前革兰氏阴性菌铁稳态的作用模式及理解主要基于肠道细菌大肠杆菌的长期探索成果。近年来,在环境细菌中开展的相关研究揭示了革兰氏阴性菌的铁稳态机制存在出乎意料的多样性:细菌中铁稳态相关的生物途径及组成蛋白、关键调控系统的生理影响以及铁稳态与其他生物过程的相互影响等方面都显示不同菌种的生存和进化特征。本综述以希瓦氏菌中的相关发现为基础,分析总结革兰氏阴性菌铁稳态重要途径及其组成的多样性、不同途径的相互影响以及调控因子的生理影响和调控机理等方面的研究进展和未解决的问题,以期为革兰氏阴性菌铁稳态的研究提供参考。     

革兰氏阴性菌Ⅵ型分泌系统及其参与金属离子转运的研究进展

细菌通过其分泌系统将特定的效应蛋白输送到外界环境或进入靶细胞中,从而在细菌和宿主、细菌和微生物群落的相互作用中占据适应性优势。Ⅵ型分泌系统（The type VI secretion system,T6SS）是革兰氏阴性菌中广泛存在的大分子分泌装置,其结构和功能类似于可收缩的噬菌体尾针样,通过细胞间直接接触将细菌各种酶或毒素效应蛋白转运到原核和真核生物中,从而介导细菌间竞争以及对宿主的致病过程。有些效应蛋白还可通过非接触依赖的方式进入胞外环境来帮助细菌获取稀缺金属离子,并且它们对应激条件下细胞内金属稳态的维持至关重要。这篇综述总结了Ⅵ型分泌系统的结构、组装及其分泌的效应蛋白,并重点阐述了Ⅵ型分泌系统在多种金属离子转运机制中作用的研究进展,有助于理解T6SS在细菌间相互作用和细菌感染过程中发挥的重要作用。     

Characterization of HasB, a Serratia marcescens TonB-like protein specifically involved in the haemophore-dependent haem acquisition system

In Gram-negative bacteria, the TonB-ExbB-ExbD inner membrane multiprotein complex is required for active transport of diverse molecules through the outer membrane. We present evidence that Serratia marcescens, like several other Gram-negative bacteria, has two TonB proteins: the previously characterized TonBSM, and also HasB, a newly identified component of the has operon that encodes a haemophore-dependent haem acquisition system. This system involves a soluble extracellular protein (the HasA haemophore) that acquires free or haemoprotein-bound haem and presents it to a specific outer membrane haemophore receptor (HasR). TonBSM and HasB are significantly similar and can replace each other for haem acquisition. However, TonBSM, but not HasB, mediates iron acquisition from iron sources other than haem and haemoproteins, showing that HasB and TonBSM only display partial redundancy. The reconstitution in Escherichia coli of the S. marcescens Has system demonstrated that haem uptake is dependent on the E. coli ExbB, ExbD and TonB proteins and that HasB is non-functional in E. coli. Nevertheless, a mutation in the HasB transmembrane anchor domain allows it to replace TonBEC for haem acquisition. As the change affects a domain involved in specific TonBEC-ExbBEC interactions, HasB may be unable to interact with ExbBEC, and the HasB mutation may allow this interaction. In E. coli, the HasB mutant protein was functional for haem uptake but could not complement the other TonBEC-dependent functions, such as iron siderophore acquisition, and phage DNA and colicin uptake. Our findings support the emerging hypothesis that TonB homologues are widespread in bacteria, where they may have specific functions in receptor-ligand uptake systems.     

The Structure of HasB Reveals a New Class of TonB Protein Fold

TonB is a key protein in active transport of essential nutrients like vitamin B12 and metal sources through the outer membrane transporters of Gram-negative bacteria. This inner membrane protein spans the periplasm, contacts the outer membrane receptor by its periplasmic domain and transduces energy from the cytoplasmic membrane pmf to the receptor allowing nutrient internalization. Whereas generally a single TonB protein allows the acquisition of several nutrients through their cognate receptor, in some species one particular TonB is dedicated to a specific system. Despite a considerable amount of data available, the molecular mechanism of TonB-dependent active transport is still poorly understood. In this work, we present a structural study of a TonB-like protein, HasB dedicated to the HasR receptor. HasR acquires heme either free or via an extracellular heme transporter, the hemophore HasA. Heme is used as an iron source by bacteria. We have solved the structure of the HasB periplasmic domain of Serratia marcescens and describe its interaction with a critical region of HasR. Some important differences are observed between HasB and TonB structures. The HasB fold reveals a new structural class of TonB-like proteins. Furthermore, we have identified the structural features that explain the functional specificity of HasB. These results give a new insight into the molecular mechanism of nutrient active transport through the bacterial outer membrane and present the first detailed structural study of a specific TonB-like protein and its interaction with the receptor.     

Free and hemophore-bound heme acquisitions through the outer membrane receptor HasR have different requirements for the TonB-ExbB-ExbD complex

Many gram-negative bacteria have specific outer membrane receptors for free heme, hemoproteins, and hemophores. Heme is a major iron source and is taken up intact, whereas hemoproteins and hemophores are not transported: the iron-containing molecule has to be stripped off at the cell surface, with only the heme moiety being taken up. The Serratia marcescens hemophore-specific outer membrane receptor HasR can transport either heme itself or heme bound to the hemophore HasA. This second mechanism is much more efficient and requires a higher TonB-ExbB-ExbD (TonB complex) concentration than does free or hemoglobin-bound heme uptake. This requirement for more of the TonB complex is associated with a higher energy requirement. Indeed, the sensitivity of heme-hemophore uptake to the protonophore carbonyl cyanide m-chlorophenyl hydrazone is higher than that of heme uptake from hemoglobin. We show that a higher TonB complex concentration is required for hemophore dissociation from the receptor. This dissociation is concomitant with heme uptake. We propose that increasing the TonB complex concentration drives more energy to the outer membrane receptor and speeds up the release of empty hemophores, which, if they remained on receptors, would inhibit heme transport.     

Mechanisms and regulation of iron and heme utilization in Gram-negative bacteria

Iron and heme are essential nutrients for most pathogenic microorganisms and play a pivotal role in microbial pathogenesis. To survive within the iron-limited environment of the host, bacteria utilize iron-siderophore complexes, iron-binding proteins (transferrin, lactoferrin), free heme and heme bound to hemoproteins (hemoglobin, haptoglobin, hemopexin). A mechanism of iron and heme transport depends on the structures of Gram-negative bacterial membranes. Siderophores, hemophores and outer membrane receptors take part in iron or heme binding. The transport of these ligands across the outer membrane involves outer membrane receptors. The energy for this transport is delivered from the inner membrane by a TonB-ExbB-ExbD complex. The transport across the cytoplasmic membrane involves periplasmic and inner membrane proteins comprising the ABC systems, which utilize the energy derived from ATP hydrolysis. The major regulatory role in iron homeostasis plays a Fur-Fe2+ repressor.     

Mechanics of force propagation in TonB-dependent outer membrane transport

For the uptake of scarce yet essential organometallic compounds, outer membrane transporters of Gram-negative bacteria work in concert with an energy-generating inner membrane complex, thus spanning the periplasmic space to drive active transport. Here, we examine the interaction of TonB, an inner membrane protein, with an outer membrane transporter based upon a recent crystal structure of a TonB-transporter complex to characterize two largely unknown steps of the transport cycle: how energy is transmitted from TonB to the transporter and how energy transduction initiates transport. Simulations of TonB in complex with BtuB reveal that force applied to TonB is transmitted to BtuB without disruption of the very small connection between the two, supporting a mechanical mode of coupling. Based on the results of different pulling simulations, we propose that the force transduction instigates a partial unfolding of the pore-occluding luminal domain of the transporter, a potential step in the transport cycle. Furthermore, analysis of the electrostatic potentials and salt bridge interactions between the two proteins during the simulations hints at involvement of electrostatic forces in long-range interaction and binding of TonB and BtuB.     

ExbB acts as a chaperone-like protein to stabilize TonB in the cytoplasm

The TonB protein is required to transduce energy from the cytoplasmic membrane to outer membrane transport proteins of Gram-negative bacteria. Two accessory proteins, ExbB and ExbD, are required for TonB function and it has been suggested that TonB and ExbBD form a complex in the membrane. In this paper we demonstrate that there are two spatially distinct, functional interactions between ExbBD and TonB. First, there is an interaction between ExbBD and the N-terminal signal-like peptide of TonB, probabiy the formation of a stable complex in the membrane. Second, ExbB interacts with TonB in the cytoplasm. This interaction involves the domain of TonB that is normally periplasmic. Thus, this is a transient interaction which occurs during the synthesis and/or localization of TonB, implying a chaperone-like role for ExbB. The transmembrane topology of ExbB was shown to be consistent with this role.     

TonB or not TonB: is that the question?

Bacteria are able to survive in low-iron environments by sequestering this metal ion from iron-containing proteins and other biomolecules such as transferrin, lactoferrin, heme, hemoglobin, or other heme-containing proteins. In addition, many bacteria secrete specific low molecular weight iron chelators termed siderophores. These iron sources are transported into the Gram-negative bacterial cell through an outer membrane receptor, a periplasmic binding protein (PBP), and an inner membrane ATP-binding cassette (ABC) transporter. In different strains the outer membrane receptors can bind and transport ferric siderophores, heme, or Fe3+ as well as vitamin B12, nickel complexes, and carbohydrates. The energy that is required for the active transport of these substrates through the outer membrane receptor is provided by the TonB/ExbB/ExbD complex, which is located in the cytoplasmic membrane. In this minireview, we will briefly examine the three-dimensional structure of TonB and the current models for the mechanism of TonB-dependent energy transduction. Additionally, the role of TonB in colicin transport will be discussed.     

Kinetic analyses reveal multiple steps in forming TonB-FhuA complexes from Escherichia coli

FhuA, an outer membrane receptor of Escherichia coli, facilitates transport of hydroxamate siderophores and siderophore-antibiotic conjugates. The cytoplasmic membrane complex TonB-ExbB-ExbD provides energy for transport via the proton motive force. This energy is transduced by protein-protein interactions between TonB and FhuA, but the molecular determinants of these interactions remain uncharacterized. Our analyses of FhuA and two recombinant TonB species by surface plasmon resonance revealed that TonB undergoes a kinetically limiting rearrangement upon initial interaction with FhuA: an intermediate TonB-FhuA complex of 1:1 stoichiometry was detected. The intermediate then recruits a second TonB protein. Addition of ferricrocin, a FhuA-specific ligand, enhanced amounts of the 2:1 complex but was not essential for its formation. To assess the role of the cork domain of FhuA in forming a 2:1 TonB-FhuA complex, we tested a FhuA deletion (residues 21-128) for its ability to interact with TonB. Analytical ultracentrifugation demonstrated that deletion of this region of the cork domain resulted in a 1:1 complex. Furthermore, the high-affinity 2:1 complex requires the N-terminal region of TonB. Together these in vitro experiments establish that TonB-FhuA interactions require sequential steps of kinetically limiting rearrangements. Additionally, domains that contribute to complex formation were identified in TonB and in FhuA.     

Quantification of known components of the Escherichia coli TonB energy transduction system: TonB, ExbB, ExbD and FepA

The TonB-dependent energy transduction system couples cytoplasmic membrane proton motive force to active transport of iron-siderophore complexes across the outer membrane in Gram-negative bacteria. In Escherichia coli, the primary players known in this process to date are: FepA, the TonB-gated transporter for the siderophore enterochelin; TonB, the energy-transducing protein; and two cytoplasmic membrane proteins with less defined roles, ExbB and ExbD. In this study, we report the per cell numbers of TonB, ExbB, ExbD and FepA for cells grown under iron-replete and iron-limited conditions. Under iron-replete conditions, TonB and FepA were present at 335 +/- 78 and 504 +/- 165 copies per cell respectively. ExbB and ExbD, despite being encoded from the same operon, were not equimolar, being present at 2463 +/- 522 and 741 +/- 105 copies respectively. The ratio of these proteins was calculated at one TonB:two ExbD:seven ExbB under all four growth conditions tested. In contrast, the TonB:FepA ratio varied with iron status and according to the method used for iron limitation. Differences in the method of iron limitation also resulted in significant differences in cell size, skewing the per cell copy numbers for all proteins.