Metagenomics in animal gastrointestinal ecosystem: a microbiological and biotechnological perspective

Metagenomics- the application of the genomics technologies to nonculturable microbial communities, is coming of age. These approaches can be used for the screening and selection of nonculturable rumen microbiota for assessing their role in gastrointestinal (GI) nutrition, plant material fermentation and the health of the host. The technologies designed to access this wealth of genetic information through environmental nucleic acid extraction have provided a means of overcoming the limitations of culture-dependent microbial genetic exploitation. The molecular procedures and techniques will result in reliable insights into the GI microbial structure and activity of the livestock gut microbes in relation to functional interactions, temporal and spatial relationships among different microbial consortia and dietary ingredients. Future developments and applications of these methods promise to provide the first opportunity to link distribution and identity of rumen microbes in their natural habitats with their genetic potential and in situ activities.     

宏基因组学在纤维素酶研究中的应用进展

纤维素酶能降解纤维素,被广泛应用于生物修复、食品加工、化工合成等领域,开发高活力、广底物、耐高温高碱等极端条件的新型纤维素酶具有重要意义。宏基因组学以特定环境样品中微生物的基因组总和为研究对象,避开传统的微生物分离培养过程,为基因资源的开发、利用提供了新技术。文中结合本课题组的研究工作,综述了利用宏基因组学获取纤维素酶的策略,同时着重介绍利用宏基因组学从动物胃肠道、土壤等环境中获取纤维素酶的研究。     

宏基因组学研究进展

不可培养微生物占据微生物总数的99%以上, 这己成为微生物资源开发利用的一个限制性因素。宏基因组学是通过提取某一环境中的所有微生物基因组DNA、构建基因组文库及对文库进行筛选寻找和发现新的功能基因及活性代谢产物的一种方法。它避开了微生物分离培养的过程, 极大地扩展了微生物资源的利用空间, 是现代基因工程一个新的发展方向和研究热点。本文主要对宏基因组的DNA提取方法、文库的构建、筛选策略的选择及近年来宏基因组学在各领域中的应用研究现状进行了综述。     

Metagenomics and biological ontology

Metagenomics is an emerging microbial systems science that is based on the large-scale analysis of the DNA of microbial communities in their natural environments. Studies of metagenomes are revealing the vast scope of biodiversity in a wide range of environments, as well as new functional capacities of individual cells and communities, and the complex evolutionary relationships between them. Our examination of this science focuses on the ontological implications of these studies of metagenomes and metaorganisms, and what they mean for common sense and philosophical understandings of multicellularity, individuality and organism. We show how metagenomics requires us to think in different ways about what human beings are and what their relation to the microbial world is. Metagenomics could also transform the way in which evolutionary processes are understood, with the most basic relationship between cells from both similar and different organisms being far more cooperative and less antagonistic than is widely assumed. In addition to raising fundamental questions about biological ontology, metagenomics generates possibilities for powerful technologies addressed to issues of climate, health and conservation. We conclude with reflections about process-oriented versus entity-oriented analysis in light of current trends towards systems approaches.     

宏基因组学:土壤微生物研究的新策略

土壤中多数微生物不可培养,这限制了微生物资源的开发利用。宏基因组学方法在开发和利用不可培养微生物资源方面有巨大潜力,可以将其运用到土壤微生物学研究中。对土壤宏基因组DNA的提取、宏基因组文库的构建和筛选等方面的研究现状和进展进行了简要综述。     

Metagenomics: Concept,methodology, ecological inference and recent advances

Microorganisms constitute two third of the Earth's biological diversity. As many as 99% of the microorganisms present in certain environments cannot be cultured by standard techniques. Culture-independent methods are required to understand the genetic diversity, population structure and ecological roles of the majority of organisms. Metagenomics is the genomic analysis of microorganisms by direct extraction and cloning of DNA from their natural environment. Protocols have been developed to capture unexplored microbial diversity to overcome the existing barriers in estimation of diversity. New screening methods have been designed to select specific functional genes within metagenomic libraries to detect novel biocatalysts as well as bioactive molecules applicable to mankind. To study the complete gene or operon clusters, various vectors including cosmid, fosmid or bacterial artificial chromosomes are being developed. Bioinformatics tools and databases have added much to the study of microbial diversity. This review describes the various methodologies and tools developed to understand the biology of uncultured microbes including bacteria, archaea and viruses through metagenomic analysis.     

Metagenomics: Future of microbial gene mining

Modern biotechnology has a steadily increasing demand for novel genes for application in various industrial processes and development of genetically modified organisms. Identification, isolation and cloning for novel genes at a reasonable pace is the main driving force behind the development of unprecedented experimental approaches. Metagenomics is one such novel approach for engendering novel genes. Metagenomics of complex microbial communities (both cultivable and uncultivable) is a rich source of novel genes for biotechnological purposes. The contributions made by metagenomics to the already existing repository of prokaryotic genes is quite impressive but nevertheless, this technique is still in its infancy. In the present review we have drawn comparison between routine cloning techniques and metagenomic approach for harvesting novel microbial genes and described various methods to reach down to the specific genes in the metagenome. Accomplishments made thus far, limitations and future prospects of this resourceful technique are discussed.     

Metagenomics and the niche concept

The metagenomics approach has revolutionised the fields of bacterial diversity, ecology and evolution, as well as derived applications like bioremediation and obtaining bioproducts. A further associated conceptual change has also occurred since in the metagenomics methodology the species is no longer the unit of study, but rather partial genome arrangements or even isolated genes. In spite of this, concepts coming from ecological and evolutionary fields traditionally centred on the species, like the concept of niche, are still being applied without further revision. A reformulation of the niche concept is necessary to deal with the new operative and epistemological challenges posed by the metagenomics approach. To contribute to this end, I review past and present uses of the niche concept in ecology and in microbiological studies, showing that a new, updated definition need to be used in the context of the metagenomics. Finally, I give some insights into a more adequate conceptual background for the utilisation of the niche concept in metagenomic studies. In particular, I raise the necessity of including the microbial genetic background as another variable into the niche space. Diana Marco is a member of the Consejo Nacional de Investigaciones Científicas y Tecnológicas (CONICET).     

环境微生物不依赖于培养的基因组学研究及应用

微生物在生物圈中分布广泛,并且在地球物质循环中占有重要地位,但是约99﹪的微生物目前还不能通过传统的培养方法得到纯培养物（即未培养微生物）,给这些未培养微生物的研究带来很大的困难。随着分子生物学的快速发展及其在微生物研究中的广泛运用,促进了以环境中未培养微生物为研究对象的新兴学科--环境基因组学的产生和发展。在不进行相关微生物培养分离的情况下,通过从环境样品中直接提取获得所有微小生物的全部遗传物质,并构建环境基因组文库;进一步利用功能基因组学研究策略,从文库中寻找编码产生新的有生物活性产物的基因;通过对系统发育相关锚定位点基因序列分析,从而确定特定生态环境体系中未培养微生物的种类结构组成及进化地位,并最终重建该体系中微生物群体的基本物质循环模式。此外,环境基因组学也可以在对未培养微生物生理生化特性深入了解的基础上,建立发展合适的培养体系,最终获得某些特定微生物的纯培养物。本文对环境基因组的构建及相关分析研究策略的进展进行了综述;同时介绍了其在微生物分类及生态学研究的应用。     

Web Resources for Metagenomics Studies

The development of next-generation sequencing(NGS) platforms spawned an enormous volume of data. This explosion in data has unearthed new scalability challenges for existing bioinformatics tools. The analysis of metagenomic sequences using bioinformatics pipelines is complicated by the substantial complexity of these data. In this article, we review several commonly-used online tools for metagenomics data analysis with respect to their quality and detail of analysis using simulated metagenomics data. There are at least a dozen such software tools presently available in the public domain. Among them, MGRAST, IMG/M, and METAVIR are the most well-known tools according to the number of citations by peer-reviewed scientific media up to mid-2015. Here, we describe 12 online tools with respect to their web link, annotation pipelines, clustering methods, online user support, and availability of data storage. We have also done the rating for each tool to screen more potential and preferential tools and evaluated five best tools using synthetic metagenome. The article comprehensively deals with the contemporary problems and the prospects of metagenomics from a bioinformatics viewpoint.     

Metagenomics as a new technological tool to gain scientific knowledge

Metagenomics (also Environmental Genomics, Ecogenomics or Community Genomics) is an emerging approach to studying microbial communities in the environment. This relatively new technique enables studies of organisms that are not easily cultured in a laboratory, thus differing from traditional microbiology that relies almost entirely on cultured organisms. Metagenomics technology thus holds the premise of new depths of understanding of microbes and, importantly, is a new tool for addressing biotechnological problems, without tedious cultivation efforts. DNA sequencing technology has already made a significant breakthrough, and generation of gigabase-pairs of microbial DNA sequences is not posing a challenge any longer. However, conceptual advances in microbial science will not only rely on the availability of innovative sequencing platforms, but also on sequence-independent tools for getting an insight into the functioning of microbial communities. This is an important issue, as we know that even the best annotations of genomes and metagenomes only create hypotheses of the functionality and substrate spectra of encoded proteins which require experimental testing by classical disciplines such as physiology and biochemistry. In this review, we address the following question, how to take advantage of, and how can we improve the, metagenomic technology for accommodating the needs of microbial biologists and enzymologists?     

宏基因组学应用于耐盐酶类及耐盐基因研究的进展

耐盐酶在高盐浓度下仍具备催化活性和稳定性,在高盐食品和海产品加工、洗涤及其它高盐环境生物技术领域被广泛应用;耐盐基因在高盐条件下可以使微生物维持正常功能,获取并研究不同环境中的耐盐基因对揭示微生物的耐盐机制,以及实现其在高盐环境中的定向应用具有的重要意义。宏基因组学避开纯培养技术探知微生物的多样性及其功能,为我们提供了一种发现新基因、开发新的微生物活性物质和研究微生物群落结构及其功能的新技术。文中结合本课题组的研究工作,综述了利用宏基因组学获取耐盐酶类及耐盐基因的策略,同时着重介绍利用宏基因组学从海洋、土壤、胃肠道等环境中获取耐盐酶类及耐盐基因的研究。     

Metagenomics in animal gastrointestinal ecosystem: Potential biotechnological prospects

Microbial metagenomics---the applications of the genomics suit of technologies to nonculturable microorganisms, is coming of age. These approaches can be used for the screening and identification of nonculturable gastrointestinal (GI) microflora for assessing and exploiting them in nutrition and the health of the host. Advances in technologies designed to access this wealth of genetic information through environmental nucleic acids extraction and analysis have provided the means of overcoming the limitations of conventional culture-dependent microbial genetic exploitation. The molecular techniques and bioinformatics tools will result in reliable insights into the animals' GI microbial structure and activity of the livestock gut microbes in relation to functional interactions, temporal and spatial relationships among different microbial consortia and dietary ingredients. Further developments and applications of these methods promise to provide the opportunity to link distribution and identity of various GI microbes in their natural habitats, and explore their use for promoting livestock health and industrial development.     

Metagenomics: advances in ecology and biotechnology

This review highlights the significant advances which have been made in prokaryotic ecology and biotechnology due to the application of metagenomic techniques. It is now possible to link processes to specific microorganisms in the environment, such as the detection of a new phototrophic process in marine bacteria, and to characterise the metabolic cooperation which takes place in mixed species biofilms. The range of prokaryote derived products available for biotechnology applications is increasing rapidly. The knowledge gained from analysis of biosynthetic pathways provides valuable information about enzymology and allows engineering of biocatalysts for specific processes. The expansion of metagenomic techniques to include alternative heterologous hosts for gene expression and the development of sophisticated assays which enable screening of thousands of clones offers the possibility to find out even more valuable information about the prokaryotic world.     

宏基因组测序在传染性疾病中的研究进展

微生物和人类已经共同进化几百万年了,微生物在维持宿主健康方面起到了非常重要的作用。随着下一代测序技术的进步,可以获得人体在不同环境下微生物群落的特征。本文综述了当前感染各种不同病原菌时复杂微生物群落的变化,病原菌包括HIV、乙肝病毒、流感病毒和结核分支杆菌,以及不同的身体部位。我们相信,增加对传染性疾病和微生物群落变化之间关系的认识,能够更好地管理疾病进展。然而,将来的研究可能需要更加整体化,通过分析人体宿主微生物与传染性疾病的发生机制之间的关系,以建立疾病的确切因果关系。     

Iron metabolism: microbes,mouse, and man

Recent advances in research on iron metabolism have revealed the identity of a number of genes, signal transduction pathways, and proteins involved in iron regulation in mammals. The emerging paradigm is a coordination of homeostasis within a network of classical iron metabolic pathways and other cellular processes such as cell differentiation, growth, inflammation, immunity, and a host of physiologic and pathologic conditions. Iron, immunity, and infection are intricately linked and their regulation is fundamental to the survival of mammals. The mutual dependence on iron by the host and invading pathogenic organisms elicits competition for the element during infection. While the host maintains mechanisms to utilize iron for its own metabolism exclusively, pathogenic organisms are armed with a myriad of strategies to circumvent these measures. This review explores iron metabolism in mammalian host, defense mechanisms against pathogenic microbes and the competitive devices of microbes for access to iron.     

Industrial biotechnology: Tools and applications

Industrial biotechnology involves the use of enzymes and microorganisms to produce value-added chemicals from renewable sources. Because of its association with reduced energy consumption, greenhouse gas emissions, and waste generation, industrial biotechnology is a rapidly growing field. Here we highlight a variety of important tools for industrial biotechnology, including protein engineering, metabolic engineering, synthetic biology, systems biology, and downstream processing. In addition, we show how these tools have been successfully applied in several case studies, including the production of 1, 3-propanediol, lactic acid, and biofuels. It is expected that industrial biotechnology will be increasingly adopted by chemical, pharmaceutical, food, and agricultural industries.     

烟草根际微生物研究

利用选择性培养基,对土壤肥力肥沃、中等、贫瘠的烟区根际细菌、真菌和放线菌进行了分离和测数。根据菌体形态及培养特征、生理生化指标及16S rDNA部分序列分析等,对根际自生固氮菌、磷细菌、钾细菌进行了鉴定和分类。主要结果为：土壤肥沃的烟区根际细菌的数量最多,土壤贫瘠的烟区数量最少;土壤贫瘠烟区根际真菌的数量较多,中等和肥沃烟区的较少;根际故线菌的数量随土壤肥力的降低而依次减小。从不同肥力烟区分离的根际自生固氮菌、磷细菌、钾细菌以革兰氏阴性杆菌为主,分别属于10个属。土壤的肥沃程度对根际3类细菌的种类和数量都有影响,总体上看,土壤肥沃和中等的条件下,细菌类群的多样性和丰富度较大,而贫瘠土壤细菌类群的优势度较大。