Vital Marius, Karch André, Pieper Dietmar H
Microbial Interactions and Processes Research Group, Helmholtz Centre for Infection Research, Braunschweig, Germany.
Epidemiological and Statistical Methods Research Group, Helmholtz Centre for Infection Research, Braunschweig, Germany.
mSystems. 2017 Dec 5;2(6). doi: 10.1128/mSystems.00130-17. eCollection 2017 Nov-Dec.
Given the key role of butyrate for host health, understanding the ecology of intestinal butyrate-producing communities is a top priority for gut microbiota research. To this end, we performed a pooled analysis on 2,387 metagenomic/transcriptomic samples from 15 publicly available data sets that originated from three continents and encompassed eight diseases as well as specific interventions. For analyses, a gene catalogue was constructed from gene-targeted assemblies of all genes from butyrate synthesis pathways of all samples and from an updated reference database derived from genome screenings. We demonstrate that butyrate producers establish themselves within the first year of life and display high abundances (>20% of total bacterial community) in adults regardless of origin. Various bacteria form this functional group, exhibiting a biochemical diversity including different pathways and terminal enzymes, where one carbohydrate-fueled pathway was dominant with butyryl coenzyme A (CoA):acetate CoA transferase as the main terminal enzyme. Subjects displayed a high richness of butyrate producers, and 17 taxa, primarily members of the and along with some , were detected in >70% of individuals, encompassing ~85% of the total butyrate-producing potential. Most of these key taxa were also found to express genes for butyrate formation, indicating that butyrate producers occupy various niches in the gut ecosystem, concurrently synthesizing that compound. Furthermore, results from longitudinal analyses propose that diversity supports functional stability during ordinary life disturbances and during interventions such as antibiotic treatment. A reduction of the butyrate-producing potential along with community alterations was detected in various diseases, where patients suffering from cardiometabolic disorders were particularly affected. Studies focusing on taxonomic compositions of the gut microbiota are plentiful, whereas its functional capabilities are still poorly understood. Specific key functions deserve detailed investigations, as they regulate microbiota-host interactions and promote host health and disease. The production of butyrate is among the top targets since depletion of this microbe-derived metabolite is linked to several emerging noncommunicable diseases and was shown to facilitate establishment of enteric pathogens by disrupting colonization resistance. In this study, we established a workflow to investigate in detail the composition of the polyphyletic butyrate-producing community from omics data extracting its biochemical and taxonomic diversity. By combining information from various publicly available data sets, we identified universal ecological key features of this functional group and shed light on its role in health and disease. Our results will assist the development of precision medicine to combat functional dysbiosis.
鉴于丁酸盐对宿主健康的关键作用,了解肠道丁酸盐产生菌群落的生态学是肠道微生物群研究的首要任务。为此,我们对来自15个公开数据集的2387个宏基因组/转录组样本进行了汇总分析,这些数据集来自三大洲,涵盖了八种疾病以及特定干预措施。在分析过程中,我们从所有样本的丁酸盐合成途径的基因靶向组装以及从基因组筛选中获得的更新参考数据库构建了一个基因目录。我们证明,丁酸盐产生菌在生命的第一年内就已定植,并且在成年人中无论其来源如何都表现出高丰度(占细菌群落总数的>20%)。多种细菌构成了这个功能组,表现出包括不同途径和末端酶的生化多样性,其中一种以碳水化合物为燃料的途径占主导地位,丁酰辅酶A(CoA):乙酸CoA转移酶为主要末端酶。受试者的丁酸盐产生菌丰富度很高,在>70%的个体中检测到17个分类群,主要是 和 的成员以及一些 ,它们占丁酸盐产生总潜力的~85%。还发现这些关键分类群中的大多数都表达丁酸盐形成相关基因,这表明丁酸盐产生菌在肠道生态系统中占据了不同的生态位,同时合成这种化合物。此外,纵向分析结果表明,多样性在日常生活干扰以及抗生素治疗等干预期间支持功能稳定性。在各种疾病中检测到丁酸盐产生潜力降低以及群落改变,患有心脏代谢紊乱的患者受到的影响尤为明显。 关于肠道微生物群分类组成的研究很多,但其功能能力仍知之甚少。特定的关键功能值得详细研究,因为它们调节微生物群与宿主的相互作用并促进宿主健康和疾病。丁酸盐的产生是首要研究目标之一,因为这种微生物衍生代谢物的消耗与几种新出现的非传染性疾病有关,并且已证明它会通过破坏定植抗性促进肠道病原体的定植。在本研究中,我们建立了一个工作流程,从组学数据中详细研究多系丁酸盐产生菌群落的组成,提取其生化和分类多样性。通过整合来自各种公开数据集的信息,我们确定了这个功能组的普遍生态关键特征,并阐明了其在健康和疾病中的作用。我们的结果将有助于开发精准医学以对抗功能失调。
