中国林蛙蝌蚪肠道及皮肤微生物多样性分析

肠道及皮肤微生物群落对宿主的健康有着至关重要的影响.本研究使用16S rRNA基因测序技术研究中国林蛙(Rana chensinensis)Gosner38期蝌蚪肠道和皮肤共生微生物群落组成之间的差异.在门水平上,林蛙蝌蚪肠道中的优势门为变形菌门(Proteobacteria)、厚壁菌门(Firmicutes)和拟杆菌...     

人体皮肤微生物群落研究进展

皮肤作为人体最大的器官,上面定居着各种各样的微生物,它们大部分是无害的,甚至对人体有益。皮肤表面的生态环境因不同的表面特征和外部因素而呈现不同的格局,使得分布于皮肤上的微生物群落出现差异。分子生物学技术的发展使研究皮肤表面微生物群落的高度多样性和多变性成为可能,而且可从生态系统角度去理解和认识皮肤微生物。本文就皮肤微生物群落的主要特点、微生物群落与疾病的联系及其具体应用等方面作一综述。     

表皮葡萄球菌对皮肤健康的作用研究进展

人体皮肤表面定居着多种微生物,这些微生物与皮肤健康密切相关。表皮葡萄球菌(Staphylococcusepidermidis)是正常人群皮肤表面微生物的主要成员之一,对维持皮肤的健康状态发挥着重要作用。在正常生理环境下,表皮葡萄球菌通过抗菌肽参与皮肤固有免疫,其细胞壁成分脂磷壁酸有助于适应性免疫系统的发育和启动,从而调节皮肤免疫过程。通过分泌鞘磷脂酶,表皮葡萄球菌可以对皮肤上的神经酰胺进行补充,同时可以增强角质形成细胞间的紧密连接,进而维护皮肤屏障稳态。表皮葡萄球菌可以和多种细菌进行交流,在皮肤抗菌防御中发挥着良性的作用,并且可以促进皮肤的再上皮化,加速伤口修复。本文归纳总结了表皮葡萄球菌在维持健康皮肤方面的最新研究结果及认识,有助于深入了解其作为潜在益生菌充分发挥对皮肤的有益影响,为皮肤病的治疗及化妆品的研发提供借鉴。     

婴儿与母亲皮肤细菌群落结构的比较分析

为探索母婴皮肤细菌群落特征,本研究对8对母婴7个不同皮肤部位的细菌群落进行焦磷酸测序分析。结果显示,皮肤细菌主要属于放线菌门(Actinobacteria)、厚壁菌门(Firmicutes)、变形菌门(Proteobacteria)和拟杆菌门(Bacteroidetes)。总体而言,母婴皮肤细菌群落的组成相似,但丰度存在差异。母亲皮肤表面的丙酸杆菌属(Propionibacterium)丰度显著高于婴儿(P<0.05)。在婴儿皮肤表面,链球菌属(Streptococcus)和葡萄球菌属(Staphylococcus)最丰富;剖宫产出生的婴儿额头表面葡萄球菌属的丰度显著高于自然分娩出生的婴儿(P<0.05)。婴儿皮肤表面特有的常驻菌属包括孪生球菌属(Gemella)、普雷沃菌属(Prevotella)、罗思菌属(Rothia)和韦荣球菌属(Veillonella)与成人常见的口腔细菌一致,表明母亲的口腔细菌对婴儿早期皮肤微生态有一定的塑造作用。婴儿皮肤表面的细菌种类与自己母亲相近,各细菌的含量则与其他婴儿相近。母亲皮脂溢出部位(额头和背部)的细菌多样性较其他部位低,且皮肤潮湿、干燥、脂溢部位之间细菌群落差异较大;而婴儿背部细菌群落与肘窝相似,额头与手背相似。     

肠道共生微生物与健康和疾病

人体是个庞大的动态的微生物群落的天然寄居场所,人体的皮肤、口腔、消化道、呼吸道和生殖道等部位都寄生着大量的微生物.这些微生物与人体互惠互利,形成共生复合体.其中,肠道共生微生物与宿主的相关性及对宿主生理和病理状态的影响已经得到了很好的阐释.肠道共生微生物的主要功能是帮助宿主代谢,使得能量和可吸收的营养物质更好的被利用,为肠道上皮细胞提供营养,增强免疫功能,帮助寄主抵抗外来微生物的入侵.肠道菌群紊乱也是一些疾病的症状或诱发原因,比如肥胖、糖尿病和肠道炎症等.深入研究人类共生微生物与健康和疾病的关系,将为一些疾病的预防和治疗提供新的手段.     

高通量测序分析小头裸裂尻鱼皮肤和肠道的微生物多样性

【目的】解析小头裸裂尻鱼不同部位的微生物群落结构、物种组成、多样性特征以及菌群功能差异。【方法】通过Illumina MiSeq扩增子高通量测序,分析小头裸裂尻鱼皮肤黏膜、肠道黏膜和肠道内容物3个部位微生物菌群组成差异,并通过Tax4Fun预测菌群潜在功能。【结果】皮肤黏膜微生物α多样性最高,其Shannon指数显著高于肠道黏膜(P<0.05)和肠道内容物(P<0.001)。主坐标分析表明,皮肤黏膜微生物显著区别于其他2个部位。在门水平小头裸裂尻鱼3个部位相对丰度前五的微生物类群均为放线菌门(Actinobacteria)、变形菌门(Proteobacteria)、厚壁菌门(Firmicutes)、绿弯菌门(Chloroflexi)和蓝藻门(Cyanobacteria),其中肠道内容物中放线菌门相对丰度(46.53%)显著高于肠道黏膜(29.23%,P<0.05)和皮肤黏膜(25.83%,P<0.01);肠道黏膜中变形菌门的相对丰度(40.33%)显著高于肠道内容物(26.10%,P<0.05)。对各部位相对丰度前10的菌群进行分析发现,小头裸裂尻鱼皮肤黏...     

PCR相关分子技术在皮肤黏膜微生态研究中的应用

皮肤黏膜微生态是指寄居在人体体表和与外界相通腔道的微生物群落与人体相互依存相互影响,形成在皮肤黏膜结构功能中发挥重要作用的微生态环境。微生态可对人体的疾病、健康产生不可忽视的影响,因此围绕该领域的研究不容忽视。以往的微生态研究通常基于传统的培养方法,存在诸多无法克服的缺陷和不足。随着PCR技术在生命科学研究中的广泛应用,PCR相关的各种分子技术以其各自的特点在不同的研究领域发挥着重要作用。     

肠道微生物菌群分型的研究进展

人体肠道内存在着处于动态平衡中的复杂微生物群体,包含1000多种细菌和古生菌等共生微生物。它们广泛参与人体的营养、代谢和免疫等生理过程,是影响健康最重要的因素之一。同一个体不同胃肠道部位的微生物群落组成显著不同,而在不同个体的肠道微生物群落组成也存在很大差异。肠道微生物群落结构受到饮食习惯、药物干预以及生活环境等因素影响,形成了不同个体间菌群组成的差异。通过菌群测序分析和群体分型,可以将不同个体的肠道微生物群落组成分为拟杆菌、普氏菌和瘤胃球菌三种肠型。确定肠道微生物群落结构的分型,将复杂的肠道微生物系统模式化,有利于对大样本肠道微生物菌群进行分析,更好地指导相关疾病的诊断和治疗。本文综述了肠道微生物的分型和相关影响因素的进展。     

人体肠道微生物多样性和功能研究进展

人体肠道中庞大而复杂的微生物群落对人体自身代谢表型有深远的影响.肠道微生物群落在亚种或菌株水平上表现出极大的多样性.利用微生物分子生态学、元基因组学和代谢组学研究方法,发现肠道微生物与宿主表现出共进化的特点,肠道微生物群落及其基因组为宿主提供了互补的遗传和代谢功能,表现出互惠共生关系.但是,肠道微生物群落中影响宿主代谢表型的关键功能菌鉴定及其作用模式问题仍然悬而未决,综合运用多种高通量研究方法和多维数据分析方法可能成为解决这个问题的突破口.     

两栖动物皮肤结构及皮肤抗菌肽

两栖动物皮肤在自然进化过程中形成了防御病原微生物的三套防御系统,相应地具有特定结构。皮肤抗菌肽是其中先天性防御系统的主要组成部分。本文概述了两栖动物皮肤结构特点以及皮肤抗菌肽在国内外的最新研究进展,重点介绍了两栖动物皮肤腺体和蛙皮抗菌肽的种类、分子结构、抗菌机理、基因表达调控及cDNA编码特点以及基因工程等。以期系统认识和了解这些方面的研究与进展。     

人类肠道微生物组与相关疾病研究进展

人体肠道共生着数以万亿计的微生物,肠道微生物在维持宿主正常生理功能中发挥重要作用,其成分和功能变化可导致严重的肠道和全身性疾病。以新一代测序技术和生物信息学分析为基础的元基因组学研究不仅极大地推动了对人类肠道微生物的整体认识,还加深了对肠道微生物代谢产物促进人类健康机理的理解,为肠道炎症、代谢性疾病和癌症等人类疾病的诊断与治疗提供了新思路。就肠道微生物元基因组学与肠道相关疾病的研究进展作一综述。     

Interactions between commensal bacteria and viral infection: insights for viral disease control in farmed animals

Viral diseases cause serious economic loss in farmed animals industry. However, the efficacy of remedies for viral infection in farmed animals is limited, and treatment strategies are generally lacking for aquatic animals. Interactions of commensal microbiota and viral infection have been studied in recent years, demonstrating a third player in the interaction between hosts and viruses. Here, we discuss recent developments in the research of interactions between commensal bacteria and viral infection,including both promotion and inhibition effect of commensal bacteria on viral pathogenesis, as well as the impact of viral infection on commensal microbiota. The antiviral effect of commensal bacteria is mostly achieved through priming or regulation of the host immune responses, involving differential microbial components and host signaling pathways, and gives rise to various antiviral probiotics. Moreover, we summarize studies related to the interaction between commensal bacteria and viral infection in farmed animals, including pigs, chickens, fish and invertebrate species. Further studies in this area will deepen our understanding of antiviral immunity of farmed animals in the context of commensal microbiota, and promote the development of novel strategies for treatment of viral diseases in farmed animals.     

Defining dysbiosis and its influence on host immunity and disease

Mammalian immune system development depends on instruction from resident commensal microorganisms. Diseases associated with abnormal immune responses towards environmental and self antigens have been rapidly increasing over the last 50 years. These diseases include inflammatory bowel disease (IBD), multiple sclerosis (MS), type I diabetes (T1D), allergies and asthma. The observation that people with immune mediated diseases house a different microbial community when compared to healthy individuals suggests that pathogenesis arises from improper training of the immune system by the microbiota. However, with hundreds of different microorganisms on our bodies it is hard to know which of these contribute to health and more importantly how? Microbiologists studying pathogenic organisms have long adhered to Koch's postulates to directly relate a certain disease to a specific microbe, raising the question of whether this might be true of commensal–host relationships as well. Emerging evidence supports that rather than one or two dominant organisms inducing host health, the composition of the entire community of microbial residents influences a balanced immune response. Thus, perturbations to the structure of complex commensal communities (referred to as dysbiosis) can lead to deficient education of the host immune system and subsequent development of immune mediated diseases. Here we will overview the literature that describes the causes of dysbiosis and the mechanisms evolved by the host to prevent these changes to community structure. Building off these studies, we will categorize the different types of dysbiosis and define how collections of microorganisms can influence the host response. This research has broad implications for future therapies that go beyond the introduction of a single organism to induce health. We propose that identifying mechanisms to re‐establish a healthy complex microbiota after dysbiosis has occurred, a process we will refer to as rebiosis, will be fundamental to treating complex immune diseases.     

The role of microbiota in infectious disease

The intestine harbors an ecosystem composed of the intestinal mucosa and the commensal microbiota. The microbiota fosters development, aids digestion and protects host cells from pathogens - a function referred to as colonization resistance. Little is known about the molecular basis of colonization resistance and how it can be overcome by enteropathogenic bacteria. Recently, studies on inflammatory bowel diseases and on animal models for enteric infection have provided new insights into colonization resistance. Gut inflammation changes microbiota composition, disrupts colonization resistance and enhances pathogen growth. Thus, some pathogens can benefit from inflammatory defenses. This new paradigm will enable the study of host factors enhancing or inhibiting bacterial growth in health and disease.     

Microbiome dynamics of human epidermis following skin barrier disruption

Background

Recent advances in sequencing technologies have enabled metagenomic analyses of many human body sites. Several studies have catalogued the composition of bacterial communities of the surface of human skin, mostly under static conditions in healthy volunteers. Skin injury will disturb the cutaneous homeostasis of the host tissue and its commensal microbiota, but the dynamics of this process have not been studied before. Here we analyzed the microbiota of the surface layer and the deeper layers of the stratum corneum of normal skin, and we investigated the dynamics of recolonization of skin microbiota following skin barrier disruption by tape stripping as a model of superficial injury.

Results

We observed gender differences in microbiota composition and showed that bacteria are not uniformly distributed in the stratum corneum. Phylogenetic distance analysis was employed to follow microbiota development during recolonization of injured skin. Surprisingly, the developing neo-microbiome at day 14 was more similar to that of the deeper stratum corneum layers than to the initial surface microbiome. In addition, we also observed variation in the host response towards superficial injury as assessed by the induction of antimicrobial protein expression in epidermal keratinocytes.

Conclusions

We suggest that the microbiome of the deeper layers, rather than that of the superficial skin layer, may be regarded as the host indigenous microbiome. Characterization of the skin microbiome under dynamic conditions, and the ensuing response of the microbial community and host tissue, will shed further light on the complex interaction between resident bacteria and epidermis.     

Modulation of immune homeostasis by commensal bacteria

Intestinal bacteria form a resident community that has co-evolved with the mammalian host. In addition to playing important roles in digestion and harvesting energy, commensal bacteria are crucial for the proper functioning of mucosal immune defenses. Most of these functions have been attributed to the presence of large numbers of 'innocuous' resident bacteria that dilute or occupy niches for intestinal pathogens or induce innate immune responses that sequester bacteria in the lumen, thus quenching excessive activation of the mucosal immune system. However it has recently become obvious that commensal bacteria are not simply beneficial bystanders, but are important modulators of intestinal immune homeostasis and that the composition of the microbiota is a major factor in pre-determining the type and robustness of mucosal immune responses. Here we review specific examples of individual members of the microbiota that modify innate and adaptive immune responses, and we focus on potential mechanisms by which such species-specific signals are generated and transmitted to the host immune system.     

A role for IL-22 in the relationship between intestinal helminths,gut microbiota and mucosal immunity

The intestinal tract is home to nematodes as well as commensal bacteria (microbiota), which have coevolved with the mammalian host. The mucosal immune system must balance between an appropriate response to dangerous pathogens and an inappropriate response to commensal microbiota that may breach the epithelial barrier, in order to maintain intestinal homeostasis. IL-22 has been shown to play a critical role in maintaining barrier homeostasis against intestinal pathogens and commensal bacteria. Here we review the advances in our understanding of the role of IL-22 in helminth infections, as well as in response to commensal and pathogenic bacteria of the intestinal tract. We then consider the relationship between intestinal helminths and gut microbiota and hypothesize that this relationship may explain how helminths may improve symptoms of inflammatory bowel diseases. We propose that by inducing an immune response that includes IL-22, intestinal helminths may enhance the mucosal barrier function of the intestinal epithelium. This may restore the mucosal microbiota populations from dysbiosis associated with colitis and improve intestinal homeostasis.     

The role of the commensal microbiota in adaptive and maladaptive stressor-induced immunomodulation

Over the past decade, it has become increasingly evident that there are extensive bidirectional interactions between the body and its microbiota. These interactions are evident during stressful periods, where it is recognized that commensal microbiota community structure is significantly changed. Many different stressors, ranging from early life stressors to stressors administered during adulthood, lead to significant, community-wide differences in the microbiota. The mechanisms through which this occurs are not yet known, but it is known that commensal microbes can recognize, and respond to, mammalian hormones and neurotransmitters, including those that are involved with the physiological response to stressful stimuli. In addition, the physiological stress response also changes many aspects of gastrointestinal physiology that can impact microbial community composition. Thus, there are many routes through which microbial community composition might be disrupted during stressful periods. The implications of these disruptions in commensal microbial communities for host health are still not well understood, but the commensal microbiota have been linked to stressor-induced immunopotentiation. The role of the microbiota in stressor-induced immunopotentiation can be adaptive, such as when these microbes stimulate innate defenses against bacterial infection. However, the commensal microbiota can also lead to maladaptive immune responses during stressor-exposure. This is evident in animal models of colonic inflammation where stressor exposure increases the inflammation through mechanisms involving the microbiota. It is likely that during stressor exposure, immune cell functioning is regulated by combined effects of both neurotransmitters/hormones and commensal microbes. Defining this regulation should be a focus of future studies.     

The diversity and host interactions of Propionibacterium acnes bacteriophages on human skin

The viral population, including bacteriophages, is an important component of the human microbiota, yet is poorly understood. We aim to determine whether bacteriophages modulate the composition of the bacterial populations, thus potentially playing a role in health or disease. We investigated the diversity and host interactions of the bacteriophages of Propionibacterium acnes, a major human skin commensal implicated in acne pathogenesis. By sequencing 48 P. acnes phages isolated from acne patients and healthy individuals and by analyzing the P. acnes phage populations in healthy skin metagenomes, we revealed that P. acnes phage populations in the skin microbial community are often dominated by one strain. We also found phage strains shared among both related and unrelated individuals, suggesting that a pool of common phages exists in the human population and that transmission of phages may occur between individuals. To better understand the bacterium–phage interactions in the skin microbiota, we determined the outcomes of 74 genetically defined Propionibacterium strains challenged by 15 sequenced phages. Depending on the Propionibacterium lineage, phage infection can result in lysis, pseudolysogeny, or resistance. In type II P. acnes strains, we found that encoding matching clustered regularly interspaced short palindromic repeat spacers is insufficient to confer phage resistance. Overall, our findings suggest that the prey–predator relationship between bacteria and phages may have a role in modulating the composition of the microbiota. Our study also suggests that the microbiome structure of an individual may be an important factor in the design of phage-based therapy.     

Context-dependent symbioses and their potential roles in wildlife diseases

It is well known in ecology, evolution and medicine that both the nature (commensal, parasitic and mutualistic) and outcome (symbiont fitness, survival) of symbiotic interactions are often context-dependent. Less is known about the importance of context-dependence in symbioses involved in wildlife disease. We review variable symbioses, and use the amphibian disease chytridiomycosis to demonstrate how understanding context-dependence can improve the understanding and management of wildlife diseases. In chytridiomycosis, the host-pathogen interaction is context-dependent; it is strongly affected by environmental temperature. Skin bacteria can also modify the interaction; some bacteria reduce amphibians' susceptibility to chytridiomycosis. Augmentation of protective microbes is being considered as a possible management tool, but informed application of bioaugmentation requires understanding of how the interactions between host, beneficial bacteria and pathogen depend upon environmental context. The community-level response of the amphibian skin microbiota to environmental conditions may explain the relatively narrow range of environmental conditions in which past declines have occurred. Environmental context affects virulence and the protection provided by mutualists in other host-pathogen systems, including threatened bats and corals. Increased focus on context-dependence in interactions between wildlife and their symbionts is likely to be crucial to the future investigation and management of emerging diseases of wildlife.