权益分类	功能权益	普通用户	{{item.name}}会员
{{category.name}}	{{benefitItem.name}}

Assembly line biosynthesis of bacterial siderophores

细菌铁载体的装配线生物合成

基本信息

批准号：
8274805
负责人：
FRED L HEFFRON
金额：
$ 34.15万
依托单位：
OREGON HEALTH & SCIENCE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2002
资助国家：
美国
起止时间：
2002-02-01 至 2013-05-31
项目状态：
已结题

项目摘要

DESCRIPTION (provided by applicant): The goal of this research is to understand the mechanism of biosynthesis of peptide siderophores in bacteria. Our paradigms are two peptide siderophores produced by the pathogen Vibrio anguillarum. One is anguibactin, an important component of a plasmid-mediated iron uptake system that is essential for virulence of this bacterium. The other is vanchrobactin, a chromosomally-encoded siderophore that in the absence of the pJM1-encoded anguibactin system becomes an important component of the virulence repertoire of V. anguillarum. The specific mechanisms that govern the biosynthesis of these siderophores in this biologically significant pathogen will be further elucidated. In order to dissect these mechanisms we will use a combination of genetic and biochemical approaches. The specific aims are: 1. Dissection of the mechanisms of assembly line enzymology in anguibactin biosynthesis. We plan to ascertain by using in vitro approaches the role of the different domains in each of anguibactin production steps. Specifically, we will assess: the role of the ArCP domain from AngB, the condensation (C) and (PPC) with AngM, the cysteine adenylation domain of AngR in activating cysteine; each Cy domain of AngN in cysteine condensation with 2,3-dihydroxybenzoic acid (DHBA) and cyclization to generate dihydroxyphenylthiazolyn (DHPT); the transfer of DHPT to N-hydroxy- histamine by the C domain of AngM. 2. Do NRPSs communicate with each other through specific domains? Our evidence indicates that several anguibactin biosynthetic genes are encoded redundantly on both the pJM1 plasmid and the chromosome of V. anguillarum and that one, angA is only chromosomally mediated. Our recent work demonstrated that the redundant genes and angA are shared by the biosynthetic apparatus for a chromosomal gene cluster that intervenes in the production of vanchrobactin (N-[N'-(2,3- dihydroxybenzoyl)-arginyl]-serine) and uptake of its ferric complexes and that consists of VabE, VabB, VabD and VabF, as well as other tailoring enzymes. The plasmid-mediated AngB and the chromosomal VabB are NRPSs with two domains each: an isochorysmate lyase and an ArCP that work as the first acceptors of an activated molecule of DHBA in the biosynthesis of anguibactin (AngB) and vanchrobactin (VabB). VabB is slightly larger than AngB due to extensions at the amino and carboxy terminus. Although VabB operates in vanchrobactin biosynthesis it cannot replace AngB in anguibactin biosynthesis synthesis. We believe that these results are due to the presence of specific communication-mediating domains in VabB and AngB that allow them to only interact with their specific NRPSs, VabF for VabB and AngM for AngB. We propose experiments to understand the basis of protein-protein communication between these NRPSs that facilitates the selective interaction in the multienzyme complexes. Our results could lead to the exploration of new avenues in the fascinating field of NRPSs communication during siderophore biosynthesis. These novel approaches will likely lead to a better understanding of siderophore biosynthesis and virulence in bacteria. PUBLIC HEALTH RELEVANCE: We intend to dissect the nonribosomal peptide synthetase systems of pathogenic bacteria into sets of well characterized, interchangeable modular domains that can be used as catalytic reagents for the designed biosynthesis of novel pharmacological and chemotherapeutic products that can be used to combat diseases caused by pathogenic bacteria. These approaches will likely lead to the exploration of new avenues in the process of siderophore biosynthesis and virulence in bacteria.

描述（由申请人提供）：本研究的目的是了解细菌中肽铁载体的生物合成机制。我们的范例是由鳗弧菌病原体产生的两个肽铁载体。一种是anguibactin，它是质粒介导的铁摄取系统的重要组成部分，对这种细菌的毒力至关重要。另一种是vanchrobactin，这是一种染色体编码的铁载体，在缺乏pjm1编码的anguibactin系统的情况下，它成为anguillarum毒力库的重要组成部分。在这种具有生物学意义的病原体中，控制这些铁载体生物合成的具体机制将进一步阐明。为了剖析这些机制，我们将使用遗传和生化方法的结合。具体目标是：1。桂皮素生物合成流水线酶学机制剖析。我们计划通过使用体外方法来确定不同结构域在每个anguibactin生产步骤中的作用。具体来说，我们将评估：来自AngB的ArCP结构域，与AngM的缩合(C)和（PPC）， AngR的半胱氨酸腺苷化结构域在激活半胱氨酸中的作用；半胱氨酸AngN的每个Cy结构域与2,3-二羟基苯甲酸（DHBA）缩合并环化生成二羟基苯基噻唑啉（DHPT）；通过AngM的C结构域将DHPT转移到n -羟基组胺。2. NRPSs是否通过特定的域相互通信？我们的证据表明，几个anguillarum的生物合成基因在pJM1质粒和染色体上都有冗余编码，其中angA仅是染色体介导的。我们最近的工作表明，染色体基因簇的生物合成装置共享冗余基因和angA，该基因簇干预vanchrobactin (N-[N'-（2,3-二羟基苯甲酰）-精氨酸]-丝氨酸的产生和其铁络合物的摄取，包括VabE， VabB， VabD和VabF，以及其他剪裁酶。质粒介导的AngB和染色体VabB都是NRPSs，各自具有两个结构域：一个同染色质裂解酶和一个ArCP，在anguibactin （AngB）和vanchrobactin （VabB）的生物合成中作为DHBA激活分子的第一个受体。由于在氨基端和羧基端有延伸，VabB比AngB稍大。VabB虽然参与万古螺生物合成，但不能代替AngB参与万古螺生物合成。我们认为，这些结果是由于VabB和AngB中存在特定的通信介导结构域，这些结构域允许它们仅与特定的NRPSs， VabB的VabF和AngM的AngB相互作用。我们建议通过实验来了解这些NRPSs之间蛋白质-蛋白质通讯的基础，从而促进多酶复合物中的选择性相互作用。我们的研究结果可能会导致在铁载体生物合成过程中NRPSs通讯的新途径的探索。这些新方法可能会导致更好地了解铁载体的生物合成和细菌的毒力。公共卫生相关性：我们打算将致病菌的非核糖体肽合成酶系统分解为一系列具有良好特征的、可互换的模块结构域，这些结构域可以用作设计生物合成的新型药物和化疗产品的催化试剂，这些产品可用于对抗致病菌引起的疾病。这些方法将有可能为铁载体生物合成过程和细菌毒力研究开辟新的途径。