Veillonellae:Keystone species in biofilm development

Veillonellae：生物膜发育的关键物种

• 批准号: 8678161
• 负责人: FENGXIA QI
• 金额: $ 22.2万
• 依托单位: UNIVERSITY OF OKLAHOMA HLTH SCIENCES CTR
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-01 至 2016-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8678161
• 关键词: Address; Adhesions; Affect; Alveolar Bone Loss; Anabolism; Applications Grants; Bacteria; Bacterial Adhesins; Binding; Coculture Techniques; Communities; Databases; Dental; Dental Plaque; Development; Disease; Disease model; Ecology; Etiology; Event; Fusobacterium; Fusobacterium nucleatum; Future; Gene Cluster; Gene Expression; Genes; Genetic Transformation; Gingiva; Gingival Crevicular Fluid; Gingivitis; Goals; Growth; Heme; Immune response; Immunity; In Vitro; Inflammation; Inflammatory; Knowledge; Laboratories; Mediating; Metabolic; Microbial Biofilms; Modeling; Mutagenesis; Mutation; Nutrient; Nutritional Requirements; Operon; Oral; Organism; Pathogenesis; Pathway interactions; Periodontal Diseases; Periodontitis; Play; Population; Porphyromonas; Porphyromonas gingivalis; Process; Production; Proteins; Reporting; Role; Saliva; Source; Staging; Streptococcus; Study models; System; Testing; Tissues; Tooth Loss; Tooth structure; Veillonella; Veillonella atypica; Vitamin K; base; disorder prevention; genome sequencing; heme biosynthesis; human old age (65+); in vivo; mutant; oral biofilm; pathogen; periodontopathogen; prevent; public health relevance

DESCRIPTION (provided by applicant): This R21 grant application aims to understand the earliest events required to initiate gingival inflammation, with an ultimate goal of understanding the complete process of periodontitis development. Periodontal diseases especially periodontitis affect the majority of people 65 years and older, and is the major cause of tooth loss in this population. Development of periodontitis involves a serial transition from healthy gum to gingivitis (gum inflammation) to periodontitis (progressive periodontal tissue destruction and alveolar bone loss). It has been well established that periodontitis results from dysbiotic interaction between the subgingival microbiota and the host. F. nucleatum (Fn) has been found to be associated with gingivitis, while P. gingivalis (Pg) is considered a "keystone pathogen" in periodontitis as it has been shown to trigger dysfunctional host response as well as to influence community ecology of the subgingival microbiota. Although we have ample knowledge about the pathogenesis mechanisms of periodontitis, we know nothing about the earliest events happening in the supragingival plaque that set the stage for future development of disease. Based on findings from both in vitro and in vivo studies, we hypothesize that Veillonella (Va) serves as keystone species in early biofilm (supragingival plaque) development by allowing colonization and growth of periodontopathogens, and that by doing so skews biofilm ecology towards disease. A 3-species model is used, with F. nucleatum (Fn) representing gingivitis pathogen, Pg representing periodontal pathogen, and the transformable strain V. atypica OK5 representing Va. In Aim 1 we will test the hypothesis that Va produces vitamin K and heme, two essential nutrients for Fn and Pg, and that expression of the vitamin K and heme biosynthesis genes is induced or upregulated by coaggregation with Fn and Pg. In Aim 2 we will determine the mechanism of coaggregation between Va and Fn and Pg. Completion of these aims is made possible by our recent development of the first and only tractable transformation system in Veillonella.

描述（由申请人提供）：此R21资助申请旨在了解启动牙龈炎症所需的最早事件，最终目标是了解牙周炎发展的完整过程。牙周病特别是牙周炎影响大多数65岁及以上的人，并且是该人群中牙齿脱落的主要原因。牙周炎的发展涉及从健康牙龈到牙龈炎（牙龈炎症）再到牙周炎（进行性牙周组织破坏和牙槽骨丢失）的一系列转变。牙周炎是由龈下微生物群与宿主之间的生态失调相互作用引起的。F.已发现具核卟啉单胞菌（Fn）与牙龈炎相关，而牙龈卟啉单胞菌（Pg）被认为是牙周炎中的“关键病原体”，因为它已显示出引发功能失调的宿主应答以及影响龈下微生物群的群落生态。虽然我们对牙周炎的发病机制有充分的了解，但我们对龈上菌斑中发生的最早事件一无所知，这些事件为疾病的未来发展奠定了基础。基于体外和体内研究的结果，我们假设韦荣氏球菌（Va）通过允许牙周病原体的定植和生长而在早期生物膜（龈上菌斑）发育中充当关键物种，并且通过这样做使生物膜生态向疾病倾斜。采用3种群模型，F.代表牙龈炎病原体的具核弧菌（Fn），代表牙周病原体的Pg，以及代表Va.在目标1中，我们将检验这样的假设：Va产生维生素K和血红素，这是Fn和Pg的两种必需营养素，目的2我们将确定Va与Fn和Pg之间共聚集的机制。这些目的的完成是通过我们最近开发的第一个也是唯一易处理的Veillonella的转化系统。