Tripathi Anupriya, Melnik Alexey V, Xue Jin, Poulsen Orit, Meehan Michael J, Humphrey Gregory, Jiang Lingjing, Ackermann Gail, McDonald Daniel, Zhou Dan, Knight Rob, Dorrestein Pieter C, Haddad Gabriel G
Division of Biological Sciences, University of California, San Diego, San Diego, California, USA.
Department of Pediatrics, University of California, San Diego, San Diego, California, USA.
mSystems. 2018 Jun 5;3(3). doi: 10.1128/mSystems.00020-18. eCollection 2018 May-Jun.
Obstructive sleep apnea (OSA) is a common disorder characterized by episodic obstruction to breathing due to upper airway collapse during sleep. Because of the episodic airway obstruction, intermittently low O (hypoxia) and high CO (hypercapnia) ensue. OSA has been associated with adverse cardiovascular and metabolic outcomes, although data regarding potential causal pathways are still evolving. As changes in inspired O and CO can affect the ecology of the gut microbiota and the microbiota has been shown to contribute to various cardiometabolic disorders, we hypothesized that OSA alters the gut ecosystem, which, in turn, exacerbates the downstream physiological consequences. Here, we model human OSA and its cardiovascular consequence using mice fed a high-fat diet and exposed to intermittent hypoxia and hypercapnia (IHH). The gut microbiome and metabolome were characterized longitudinally (using 16S rRNA amplicon sequencing and untargeted liquid chromatography-tandem mass spectrometry [LC-MS/MS]) and seen to covary during IHH. Joint analysis of microbiome and metabolome data revealed marked compositional changes in both microbial (>10%, most remarkably in ) and molecular (>22%) species in the gut. Moreover, molecules that altered in abundance included microbe-dependent bile acids, enterolignans, and fatty acids, highlighting the impact of IHH on host-commensal organism cometabolism in the gut. Thus, we present the first evidence that IHH perturbs the gut microbiome functionally, setting the stage for understanding its involvement in cardiometabolic disorders. Intestinal dysbiosis mediates various cardiovascular diseases comorbid with OSA. To understand the role of dysbiosis in cardiovascular and metabolic disease caused by OSA, we systematically study the effect of intermittent hypoxic/hypercapnic stress (IHH, mimicking OSA) on gut microbes in an animal model. We take advantage of a longitudinal study design and paired omics to investigate the microbial and molecular dynamics in the gut to ascertain the contribution of microbes on intestinal metabolism in IHH. We observe microbe-dependent changes in the gut metabolome that will guide future research on unrecognized mechanistic links between gut microbes and comorbidities of OSA. Additionally, we highlight novel and noninvasive biomarkers for OSA-linked cardiovascular and metabolic disorders.
阻塞性睡眠呼吸暂停(OSA)是一种常见疾病,其特征是睡眠期间上呼吸道塌陷导致间歇性呼吸阻塞。由于间歇性气道阻塞,继而出现间歇性低氧(缺氧)和高二氧化碳(高碳酸血症)。OSA与不良心血管和代谢后果相关,尽管关于潜在因果途径的数据仍在不断发展。由于吸入氧和二氧化碳的变化会影响肠道微生物群的生态,并且微生物群已被证明会导致各种心脏代谢疾病,我们推测OSA会改变肠道生态系统,进而加剧下游的生理后果。在此,我们使用喂食高脂饮食并暴露于间歇性缺氧和高碳酸血症(IHH)的小鼠对人类OSA及其心血管后果进行建模。对肠道微生物组和代谢组进行纵向表征(使用16S rRNA扩增子测序和非靶向液相色谱 - 串联质谱[LC - MS/MS]),并观察到在IHH期间它们会共同变化。微生物组和代谢组数据的联合分析揭示了肠道中微生物(>10%,最显著的是在……方面)和分子(>22%)种类的显著组成变化。此外,丰度发生改变的分子包括微生物依赖性胆汁酸、肠木脂素和脂肪酸,突出了IHH对肠道中宿主共生生物共代谢的影响。因此,我们提供了首个证据表明IHH在功能上扰乱了肠道微生物组,为理解其在心脏代谢疾病中的作用奠定了基础。肠道微生物失调介导了与OSA共病的各种心血管疾病。为了了解失调在OSA引起的心血管和代谢疾病中的作用,我们在动物模型中系统地研究间歇性低氧/高碳酸血症应激(IHH,模拟OSA)对肠道微生物的影响。我们利用纵向研究设计和配对组学来研究肠道中的微生物和分子动态,以确定微生物对IHH中肠道代谢的贡献。我们观察到肠道代谢组中依赖微生物的变化,这将为未来关于肠道微生物与OSA合并症之间未被认识的机制联系的研究提供指导。此外,我们强调了与OSA相关的心血管和代谢疾病的新型非侵入性生物标志物。
