神经精神疾病微生物组研究现状和展望

人类肠道微生物组是一个数量庞大的微生物群落,它们与宿主互为影响,被认为是维持机体健康和许多疾病致病机制的重要环节。越来越多的研究认为,肠道正常菌群对于中枢神经系统的发育和情感的调控至关重要。随着微生物与大脑相互作用研究的深入,"肠-脑轴"的概念也被进一步扩展为"微生物-肠-脑轴"。目前,主要的研究集中于探究肠道微生物在健康和致病中的具体机制,如应激相关的疾病抑郁症、焦虑症等,神经退行性疾病帕金森病、阿尔兹海默症等。肠道微生物组与中枢神经系统的双向调节主要通过调节单胺类神经递质、下丘脑垂体肾上腺激活、调节神经营养因子分泌、神经免疫激活等途径来实现。微生物-肠-脑轴失衡可影响行为表型,导致神经精神疾病,因此,通过调节肠道微生物组成来治疗神经精神疾病是今后的研究热点。对神经精神疾病肠道微生物组的研究现状进行了总结,为肠道微生物组对神经心理的调控寻找更多的证据,以便能更好地理解微生物-肠-脑轴的潜在机制。     

肠道微生物菌群对脑及行为的影响

肠道微生物菌群组成的变化对正常生理的影响及其在疾病中的作用逐渐成为研究热点。肠道微生物菌群通过脑肠轴影响宿主生理学的各个方面,包括脑-肠交流、脑功能甚至行为。对无菌动物、被致病细菌感染的、使用益生菌或用抗生素药物的动物研究表明,肠道微生物菌群可以调节宿主焦虑样症状及行为。研究表明对肠道微生物菌群的调节可能是治疗复杂中枢神经系统失调症的新策略。     

微生物-肠-脑轴与抑郁症中医药研究进展

肠道微生物-肠-脑轴因其在调节精神疾病中的可能生物学基础作用而受到越来越多的关注。肠道微生物与抑郁症等精神疾病密切相关,肠道微生物可通过与"肠-脑轴"交互作用影响抑郁症的发生和发展,然而,肠道微生物与抑郁症之间的具体相互作用及机制还未十分明晰。深入研究微生物-肠-脑轴和抑郁症之间的相互关系,有助于我们从另一个角度更为深刻地认识和阐明抑郁症这种精神疾病。调节肠道微生物组成来治疗、预防抑郁症等精神疾病是今后的研究方向之一,可为探索中医药治疗、预防抑郁症机理提供新的思路。     

基于脑-肠-微生物轴的肠易激综合征机制与治疗研究进展

肠易激综合征(irritablebowelsyndrome,IBS)是常见的功能性肠病之一,目前尚缺乏可用器质性疾病解释的临床特征,最新研究将其机制描述为脑-肠-微生物轴紊乱,强调了肠道微生物群在调节脑肠互动中的中介作用,而中医药对于脑肠稳态调节有着悠久广泛的治疗经验并取得了良好疗效,但两者关联性缺乏论述。因此,本文以脑肠轴为切入点,以肠道微生物作为介质,基于脑肠轴-中医药的良性互动,结合我们相关工作,综述了目前与脑-肠-微生物轴相关的IBS的中西医研究,为同行提供参考。     

微生物在精神分裂症发病机制的研究现状

脑和肠道微生物群之间的相互作用逐渐被揭示。目前已经提出脑-肠轴失调和异常与各种中枢神经系统疾病有关。精神分裂症是一种病因不明的严重精神障碍。最近研究表明,肠道微生物的组成和数量变化会通过肠道菌群-肠-脑轴影响人类的认知和社会行为,这意味着肠道菌群在精神分裂症患者中可能起着重要的作用,并有望成为精神分裂症新的治疗靶点。本文综述了肠道菌群与精神分裂症相关性的研究进展,为预防和治疗精神分裂症等精神障碍类疾病提供了理论依据。     

动物宿主——肠道微生物代谢轴研究进展

肠道中栖息着数量庞大且复杂多样的微生物菌群,在维持宿主肠道微环境稳态中发挥重要作用。微生物菌群可以利用宿主肠道的营养素,发酵产生代谢产物,与宿主机体形成宿主—微生物代谢轴(host-microbe metabolic axis)。该代谢轴既能影响营养素吸收和能量代谢,又可调控宿主各项生理过程。本文主要阐述宿主-肠道微生物代谢轴的概念、肠-肝轴、肠-脑轴、肠道微生物与宿主肠道代谢轴的互作以及对机体健康的影响。     

肠道菌群与脑-肠轴相互作用关系研究进展

人体肠道内定植了大量的细菌,它们参与机体多种生理功能的维持。大脑与胃肠道之间通过脑-肠轴进行双向关联。近年研究发现肠道菌群与脑-肠轴可相互作用、相互影响。肠道菌群可影响机体神经内分泌系统及免疫系统的功能,脑-肠轴功能变化同样也会改变肠道的菌群结构。本研究就肠道菌群与脑-肠轴功能相互影响的研究进展作一综述,以期为深入了解肠道菌群对脑-肠轴功能的影响提供参考。     

微生物-肠-脑轴与神经系统疾病的研究进展

肠道微生物对神经系统疾病 (如帕金森病、抑郁症和阿尔兹海默症等) 的治疗具有辅助治疗的作用。其主要通过神经通路、免疫通路以及微生物代谢物等途径在肠-脑轴的作用下影响大脑功能和宿主行为。因此,文中结合国内外的研究进展,就微生物-肠-脑轴在神经系统疾病中的主要作用进行探讨,以期为神经退行性疾病的治疗提供新思路。     

肠道微生物和肠-脑轴在肥胖发展中的作用

肥胖和相关代谢综合征已成为全球最突出的健康问题之一,肠道微生物已被证明参与肥胖的发展,并可能对肥胖的发展和其干预治疗等提供重要的见解。最近的研究表明,肠道微生物和大脑的相互作用可能是肥胖的后果或解释因素,肠-脑轴是它们相互作用的联络枢纽。此外,肠道微生物可以通过肠道激素（包括ghrelin）以及迷走神经连接（影响能量消耗和CNS中与饮食行为相关的区域）来影响肠-脑轴,从而改变宿主行为。同时,肠道微生物代谢物和其产物还可以充当信号分子并调节肠内分泌细胞的激素分泌,如GLP1和PYY,从而调节食欲、肠道运动、能量吸收和储存以及能量消耗等摄食相关行为,进而影响肥胖的发展。所以,理解这些信号和激素作用并从药理学方法增强它们,可能为治疗肥胖提供一种重要的途径。     

"肠道微生物-肠道-脑轴"机制--肠道微生物干预神经退行性病变研究进展

肠道微生物是人体中最为庞大和复杂的微生物群落,其对机体的健康,尤其是中枢神经退行性病变具有重要调节作用。其中,"肠道微生物-肠道-脑轴"机制是肠道微生物干预中枢神经退行性病变的重要途径。该机制主要通过以下三种方式来调节大脑功能:一是肠道微生物直接产生神经递质通过肠神经细胞上行至中枢神经系统;二是肠道微生物代谢产物刺激肠内分泌细胞产生神经肽类和胃肠激素类物质,影响大脑功能;三是肠道微生物或其代谢产物直接刺激肠道免疫系统,产生干扰素类物质干扰大脑免疫反应。本文对"肠道微生物-肠道-脑轴"机制的概念及研究进展进行了详细的介绍,同时总结了有关肠道微生物与阿尔兹海默症、帕金森症和多发性硬化症等神经退行性疾病相互作用的相关文献。依据"肠道微生物-肠道-脑轴"机制,利用肠道微生物预防和治疗神经退行性病变,或将成为解决中枢神经系统疾病的新措施。     

New challenges in the study of the evolution of wild animals and their gut microbiome

In this viewpoint, by reviewing the recent findings on wild animals and their gut microbiomes, we found some potential new insights and challenges in the study of the evolution of wild animals and their gut microbiome. We suggested that wild animal gut microbiomes may come from microbiomes in the animals'' living habitats along with animals'' special behavior, and that the study of long‐term changes in gut microbiomes should consider both habitat and special behaviors. Also, host behavior would facilitate the gut microbiome transmission between individuals. We suggested that research should integrate the evolutionary history and physiological systems of wild animals to understand the evolution of animals and their gut microbiomes. Finally, we proposed the Noncultured‐Cultured‐Fermentation‐Model Animal pipeline to determine the function (diet digestion, physiology, and behavior) of these target strains in the wild animal gut.     

The Component and Functional Pathways of Gut Microbiota are Altered in Populations with Poor Sleep Quality – A Preliminary Report

With the development of genome sequencing, many researchers have investigated the mechanism by which the intestinal microbiota influences sleep across the brain-gut axis. However, the relationship between gut microbiota and sleep disorder remains unclear. Thus, we studied the difference in gut microbiota composition between poor sleep quality- and normal populations, which helps set the ground for future research. The recruited college students provided baseline information and stool samples and completed the Pittsburgh Sleep Quality Index (PSQI). We compared the two groups’ gut microbiota composition and functional differentiation by using the 16S rRNA gene sequencing analysis. The main bacterial difference and the most critical effect were mainly concentrated within Tenericutes and Elusimicrobia. Compared with the healthy control group, some functions of the gut microbiota were impaired in the poor sleep quality group, such as butanoate metabolism and propanoate metabolism. Bacterial taxa with significant differences raised the possibility for future diagnosis and treatment of sleep problems.     

微生物-肠-脑轴的研究进展

肠道微生物群能够调节宿主肠道稳态,同时参与调节宿主神经系统功能和行为。肠道菌群失调可能导致宿主神经系统功能障碍,从而引发神经退行性疾病。因此,研究微生物在肠?脑轴中发挥的作用及其机制,靶向调控肠道微生物菌群结构和功能,将为神经系统疾病的诊断与治疗提供新的手段。近年来,有关肠道微生物与机体神经系统间的互作研究受到了广泛关注,然而其具体的调控机制还未明晰。因此,本文综述了肠道微生物对宿主神经健康的调节作用,以及肠道微生物与宿主间的互作在调节神经功能、行为的潜力等研究进展,为更好地了解肠道微生物在调控宿主神经系统功能和行为的作用机制提供参考。     

肠道微生态失调与强直性脊柱炎发生发展的相关性分析

强直性脊柱炎（ankylosing spondylitis,AS）发病较为隐蔽,机制复杂。目前临床诊断方法具有明显的滞后性,因此寻求更为快速、准确的早期诊断指标对缓解甚至治愈AS显得极为重要。现有的大量研究显示肠道微生物与AS关系密切,且可能通过肠道微生物与遗传因子HLA-B27相互作用、肠道通透性改变介导的肠黏膜IgA免疫应答和炎性因子的过度表达、肠—脑轴、肠道微生物之间的相互作用等机制导致AS的发生发展。本文就AS患者肠道微生物变化及肠道微生态失调与AS的相关性作一综述。     

微生物对昆虫行为的影响研究进展

在漫长的进化过程中,微生物与昆虫形成了多种形式的互作关系.微生物的广泛分布为与昆虫接触并影响昆虫的行为提供了背景条件.为了深入探究微生物影响昆虫行为的现象和机制,本文综述了微生物影响昆虫行为方面的研究进展.微生物通过产生可被昆虫识别的化学信号物质、参与昆虫或寄主植物信息化合物的合成等方式可影响昆虫对其寄主的定位和选择....     

肠道微生物群与脱发的相关性研究进展

随着年轻人群脱发比例的逐年增加,头发健康问题日益受到关注。脱发会影响人们的生活质量,并对心理和社交生活产生巨大影响。近年来,对肠道微生物群的生理功能性研究已不再仅仅局限于胃肠道。研究表明肠道和肠道微生物群与皮肤有密切关系,提示“肠-皮肤轴”的存在。本文在已有的“肠-皮肤轴”研究现状基础上,总结近年来文献资料,探讨肠道微生物群与脱发之间可能的联系和潜在机制,为脱发的发病机制和治疗靶点提供新的认识和观点。     

Beneficial psychological effects of novel psychobiotics in diabetic rats: the interaction among the gut,blood and amygdala

Type 2 diabetes mellitus (T2DM) can lead to major complications such as psychiatric disorders which include depressive and anxiety-like behaviors. The association of the gut–brain axis in the development of such disorders, especially in T2DM, has been elucidated; however, gut dysbiosis is also reported in patients with T2DM. Hence, the regulation of the gut–brain axis, in particular, the gut–amygdala, as a vital region for the regulation of behavior is essential. Thirty-five male Wistar rats were divided into six groups. To induce T2DM, treatment groups received high-fat diet and 35 mg/kg streptozotocin. Then, supplements of Lactobacillus plantarum, inulin or their combination were administered to each group for 8 weeks. Finally, the rats were sacrificed for measurement of blood and tissue parameters after behavioral testing. The findings demonstrated the favorable effects of the psychobiotics (L. plantarum, inulin or their combination) on oxidative markers of the blood and amygdala (superoxide dismutase, glutathione peroxidase, malondialdehyde and total antioxidant capacity), as well as on concentrations of amygdala serotonin and brain-derived neurotrophic factor, in the diabetic rats. In addition, beneficial effects were observed on the elevated plus maze and forced swimming tests with no change in locomotor activity of the rats. There was a strong correlation between the blood and amygdala oxidative markers, insulin and fasting blood sugar with depressive and anxiety-like behaviors. Our results identified L. plantarum ATCC 8014 and inulin or their combination as novel psychobiotics that could improve the systemic and nervous antioxidant status and improve amygdala performance and beneficial psychotropic effects.     

Abdominal microbial communities in ants depend on colony membership rather than caste and are linked to colony productivity

Gut bacteria aid their host in digestion and pathogen defense, and bacterial communities that differ in diversity or composition may vary in their ability to do so. Typically, the gut microbiomes of animals living in social groups converge as members share a nest environment and frequently interact. Social insect colonies, however, consist of individuals that differ in age, physiology, and behavior, traits that could affect gut communities or that expose the host to different bacteria, potentially leading to variation in the gut microbiome within colonies. Here we asked whether bacterial communities in the abdomen of Temnothorax nylanderi ants, composed largely of the gut microbiome, differ between different reproductive and behavioral castes. We compared microbiomes of queens, newly eclosed workers, brood carers, and foragers by high‐throughput 16S rRNA sequencing. Additionally, we sampled individuals from the same colonies twice, in the field and after 2 months of laboratory housing. To disentangle the effects of laboratory environment and season on microbial communities, additional colonies were collected at the same location after 2 months. There were no large differences between ant castes, although queens harbored more diverse microbial communities than workers. Instead, we found effects of colony, environment, and season on the abdominal microbiome. Interestingly, colonies with more diverse communities had produced more brood. Moreover, the queens' microbiome composition was linked to egg production. Although long‐term coevolution between social insects and gut bacteria has been repeatedly evidenced, our study is the first to find associations between abdominal microbiome characteristics and colony productivity in social insects.