多组学前沿技术专刊序言

后基因组时代,基因组学、转录组学、蛋白质组学及代谢组学等技术应用日趋广泛,功能注释成为生命科学研究的中心任务,多组学整合分析成为全面解析生物学机理的主要手段。本专刊邀请了国内多组学领域的相关专家学者介绍了基因组学、转录组学、蛋白质组学及代谢组学等领域最新进展和应用成果,收录了相关文章28篇,以供从事多组学研究的科研工作者参考。     

生物组学在污染环境微生物修复研究中的应用

随着分子生物学、生物信息学和各种理化检测技术的发展,特别是人类基因组计划成功实施以来,基因组学研究取得了重大突破与进展。而包括转录组学、蛋白组学和代谢组学在内的后基因组学也相继出现,并被广泛应用在环境微生物学的各个研究领域。本文主要概述了当前基因组学、转录组学、蛋白质组学和代谢组学在污染环境生物修复研究中的最新研究进展,分析比较了各组学的优势与不足,同时结合本课题组的主要研究方向探讨了各生物组学在赤潮生消过程和有机污染物降解机理等研究中的应用。     

Meta-analysis在多种组学领域的应用

Meta-analysis作为一种整合多特征、多数据的统计方法,上世纪90年代被引入生命科学领域。随着高通量测序技术的快速发展,以基因组学、转录组学和蛋白质组学为核心的生命组学逐渐成为生命科学研究的新热点。海量数据的快速产出推动了组学研究的发展,也引发了数据规模过大、难以系统整合等问题。针对上述情况,meta-analysis被广泛地应用于分析各组学数据,方法也不断得到改进。本文系统总结了有代表性的meta-analysis方法,考察了目前meta-analysis在多个组学领域的应用现状,最后讨论了meta-analysis尚待解决的问题并展望未来的发展方向。     

基于宏组学方法认识微生物群落及其功能

进入后基因组学时代,测序技术飞速发展,测序成本明显下降,形成了涵盖宏基因组学、宏转录组学和宏蛋白质组学的宏组学技术,推动了对微生物群落的多样性、结构及潜在基因功能方面的深入研究。最近随着整合的宏组学技术的提出及应用,全面系统分析微生物群落动态变化及其代谢功能已成为可能,这将成为微生物生态学研究的新趋势。本文综述了宏组学在研究海洋湖泊、深海热泉、人体肠道、牛瘤胃生境、森林土壤与堆肥生境等环境中微生物群落的结构和功能方面的最新进展与成功应用案例。     

宏组学方法在污水处理系统中的应用进展

污水生物处理由微生物生理过程驱动,宏组学方法能够获得不同水平的分子信息,为认识污水处理系统中的微生物提供了新途径。本文对宏基因组学、宏转录组学、宏蛋白质组学与代谢组学等宏组学方法的发展进行综述,着重介绍各组学及整合宏组学在污水处理系统中的研究现状,并指出其应用前景。     

肠道微生物功能宏基因组学与代谢组学关联分析方法研究进展

近年来基于高通量基因测序的微生物组学研究极大加深了人们对微生物与健康和疾病关系的认识。然而基因测序方法不能直接测定微生物的功能活性,难以鉴定微生物中的关键功能分子,单独使用无法回答肠道微生物何种成员通过何种方式影响宿主等关键科学问题。单一组学研究弊端尽显,多组学联用势在必行。肠道微生物代谢组学以微生物群落所有小分子代谢物为研究对象,可发现肠道微生物随宿主病理生理变化的关键代谢物,为微生物组-宿主互作机制研究提供线索,成为微生物组学研究的重要补充。肠道微生物功能基因组学与代谢组学关联分析在宿主生理、疾病病理、药物药理等方面取得众多进展,展现良好应用前景。然而目前肠道微生物功能基因组学与代谢组学关联分析存在方法滥用、相关性结论与生物学知识相悖等突出问题。为帮助正确应用肠道微生物功能宏基因组学与代谢组学关联分析,本文综述了各种多组学数据整合分析方法的原理、优缺点与适用范围,并给出了应用建议。     

代谢物组学及其在微生物研究中的应用

代谢物组学(metabolomics)是继基因组学(genomics)、蛋白质组学(proteomics)后发展起来的一门新学科。对代谢物组学的含义,研究方法及流程,特别是其在微生物中的应用进行了介绍,包括使用代谢物组学中的NMR技术研究微生物在降解环境污染物中的作用;使用代谢物组学技术研究微生物代谢通量,从而在分析代谢通量的基础上通过代谢工程改变代谢通量,提高目的产物的得率;确定所获得基因库中沉默基因的功能;运用代谢物组学分析方法阐明生物体系对于环境变化的响应,从而协助我们确定最佳的取样时间及最佳分析组织,设计实验。随后简要对代谢物组学发展动态进行了展望。     

分子微生物学研究动态与发展趋势

在基因组学、蛋白质组学、转录组学和代谢组学等不同层次展开的分子微生物学研究取得了丰硕成果。分子微生物学正在从分析生物学迈向统一生物学的研究阶段,其研究成果必将对揭开生命活动的奥秘和推动第三生物产业的发展具有重要的意义。     

环境微生物学的组学技术应用和突破（英文稿）

由于研究环境变化和微生物群落的需要,近年来高通量组学技术得到了迅猛开发和应用.其中,基于测序和芯片技术的宏基因组学是一个关键的、最成熟的组学技术,为大多数的其它组学技术提供了支撑.相比较而言,宏转录组学、宏蛋白质组学和宏代谢组学也取得了少数的有限成功,但已经显示出可喜的潜力.所有的组学技术都有赖于生物信息学,使得后者成为组学技术应用的一个主要的技术瓶颈.这些新的组学技术对环境微生物学领域产生了革命性的影响,极大地丰富了我们对于环境微生物基因资源和功能活性的了解.     

激光捕获显微切割在肿瘤多组学研究中的应用进展

当今社会,肿瘤因其高发病率和高死亡率成为威胁人类健康的重要疾病,研究者们对其发病机制及治疗手段的研究和探索也在不断深入。随着单细胞多组学测序技术的发展,肿瘤组织的异质性问题逐渐被研究人员所认识。为了解决这一问题,激光捕获显微切割（laser capture microdissection,LCM）技术应运而生。LCM技术是一种在显微镜直视下从器官或组织中准确获取某种特定的细胞群或单个细胞的样本收集技术。LCM技术结合多种分子生物学手段可以对异质性组织进行多组学研究,丰富了现有的肿瘤蛋白质组学、基因组学以及转录组学图谱,因此,LCM技术成为研究特异性表达及分子机制的有力工具,在肿瘤学领域得到广泛应用。基于此,对LCM的原理、优势及其在肿瘤多组学研究中的应用进行了综述,并对其未来可能的发展方向进行了展望,以期为肿瘤的研究和治疗提供新的思路。     

Marine molecular biology: an emerging field of biological sciences

An appreciation of the potential applications of molecular biology is of growing importance in many areas of life sciences, including marine biology. During the past two decades, the development of sophisticated molecular technologies and instruments for biomedical research has resulted in significant advances in the biological sciences. However, the value of molecular techniques for addressing problems in marine biology has only recently begun to be cherished. It has been proven that the exploitation of molecular biological techniques will allow difficult research questions about marine organisms and ocean processes to be addressed. Marine molecular biology is a discipline, which strives to define and solve the problems regarding the sustainable exploration of marine life for human health and welfare, through the cooperation between scientists working in marine biology, molecular biology, microbiology and chemistry disciplines. Several success stories of the applications of molecular techniques in the field of marine biology are guiding further research in this area. In this review different molecular techniques are discussed, which have application in marine microbiology, marine invertebrate biology, marine ecology, marine natural products, material sciences, fisheries, conservation and bio-invasion etc. In summary, if marine biologists and molecular biologists continue to work towards strong partnership during the next decade and recognize intellectual and technological advantages and benefits of such partnership, an exciting new frontier of marine molecular biology will emerge in the future.     

合成生物学技术在材料科学中的应用

材料是人类赖以生存与发展的物质基础,科技和社会的进步都离不开材料技术的发展,未来先进材料的合成和制备必然朝着绿色可持续、低耗高产出、精细可调控、高效多功能的方向发展。以"基因调控·工程设计"为核心的合成生物学技术从分子、细胞层面极大地推动了生命科学的发展,也已经并继续为材料科学的发展注入新的思路和活力。本文将围绕合成生物学技术在材料科学中的应用,以基因回路设计为核心,概念应用为线索,重点介绍合成生物学技术在高分子生物材料和无机纳米材料领域的开发和生产,细胞展示和蛋白定向进化战略对分子材料的筛选和优化,"活体"功能材料、工程菌调节的人工光合系统功能材料体系以及基因回路在材料科学中的应用。     

Do human ‘life history strategies’ exist?

Interest in incorporating life history research from evolutionary biology into the human sciences has grown rapidly in recent years. Two core features of this research have the potential to prove valuable in strengthening theoretical frameworks in the health and social sciences: the idea that there is a fundamental trade-off between reproduction and health; and that environmental influences are important in determining how life histories develop. However, the literature on human life histories has increasingly travelled away from its origins in biology, and become conceptually diverse. For example, there are differences of opinion between evolutionary researchers about the extent to which behavioural traits associate with life history traits to form ‘life history strategies’. Here, I review the different approaches to human life histories from evolutionary anthropologists, developmental psychologists and personality psychologists, in order to assess the evidence for human ‘life history strategies’. While there is precedent in biology for the argument that some behavioural traits, notably risk-taking behaviour, may be linked in predictable ways with life history traits, there is little theoretical or empirical justification for including a very wide range of behavioural traits in a ‘life history strategy’. Given the potential of life history approaches to provide a powerful theoretical framework for understanding human health and behaviour, I then recommend productive ways forward for the field: 1) greater focus on the life history trade-offs which underlie proposed strategies; 2) greater precision when using the language of life history theory and life history strategies; 3) collecting more empirical data, from a diverse range of populations, on linkages between life history traits, behavioural traits and the environment, including the underlying mechanisms which generate these linkages; and 4) greater integration with the social and health sciences.     

Bottom-up genome assembly using the Bacillus subtilis genome vector

We established a protocol to construct complete recombinant genomes from their small contiguous DNA pieces and obtained the genomes of mouse mitochondrion and rice chloroplast using a B. subtilis genome (BGM) vector. This method allows the design of any recombinant genomes, valuable not only for fundamental research in systems biology and synthetic biology but also for various applications in the life sciences.     

Systems biology in animal sciences

Systems biology is a rapidly expanding field of research and is applied in a number of biological disciplines. In animal sciences, omics approaches are increasingly used, yielding vast amounts of data, but systems biology approaches to extract understanding from these data of biological processes and animal traits are not yet frequently used. This paper aims to explain what systems biology is and which areas of animal sciences could benefit from systems biology approaches. Systems biology aims to understand whole biological systems working as a unit, rather than investigating their individual components. Therefore, systems biology can be considered a holistic approach, as opposed to reductionism. The recently developed 'omics' technologies enable biological sciences to characterize the molecular components of life with ever increasing speed, yielding vast amounts of data. However, biological functions do not follow from the simple addition of the properties of system components, but rather arise from the dynamic interactions of these components. Systems biology combines statistics, bioinformatics and mathematical modeling to integrate and analyze large amounts of data in order to extract a better understanding of the biology from these huge data sets and to predict the behavior of biological systems. A 'system' approach and mathematical modeling in biological sciences are not new in itself, as they were used in biochemistry, physiology and genetics long before the name systems biology was coined. However, the present combination of mass biological data and of computational and modeling tools is unprecedented and truly represents a major paradigm shift in biology. Significant advances have been made using systems biology approaches, especially in the field of bacterial and eukaryotic cells and in human medicine. Similarly, progress is being made with 'system approaches' in animal sciences, providing exciting opportunities to predict and modulate animal traits.     

Surrogacy theory and models of convoluted organic systems

The theory of surrogacy is briefly outlined as one of the conceptual foundations of systems biology that has been developed for the last 30 years in the context of Hertz-Rosen modeling relationship. Conceptual foundations of modeling convoluted (biologically complex) systems are briefly reviewed and discussed in terms of current and future research in systems biology. New as well as older results that pertain to the concepts of modeling relationship, sequence of surrogacies, cascade of representations, complementarity, analogy, metaphor, and epistemic time are presented together with a classification of models in a cascade. Examples of anticipated future applications of surrogacy theory in life sciences are briefly discussed.     

News and views in Histochemistry and Cell Biology

Advances in histochemical methodology and ingenious applications of novel and improved methods continue to confirm the standing of morphological means and approaches in research efforts, and contribute significantly to increasing our knowledge about structures and functions in all areas of the life sciences from cell biology to pathology. Reports published during recent months documenting this progress are summarized in the present review.This revised version was published online in January 2005 with a corrected section title.     

合成生物学生物安全风险评价与管理

合成生物学(synthetic biology)已迅速发展为生命科学最具发展潜力的分支学科之一,但它同时也会给生态环境和人类健康带来潜在的风险。结合国内外合成生物学发展现状,本文综述了基因回路(DNA-based biocircuits)、最小基因组(minimal genome)、原型细胞(protocells)、化学合成生物学(chemical synthetic biology)等涉及的风险评价、合成生物学与生物安全工程(biosafety engineering)、合成生物学对社会伦理道德法律的影响以及当前热点议题,如生物朋(黑)客(biopunk(or biohackery))、家置生物学(garage biology)、DIY生物学(do-it-yourselfbiology)、生物恐怖主义(bioterrorism)等方面的新进展。分析讨论了世界各国合成生物学以自律监管或技术为主的安全管理原则和基于5个不同政策干预点的5P管理策略的合理性与潜在不足。同时结合我国合成生物学当前研究进展以及现有的安全管理规范,提出了建立以安全评价为核心的法规体系、生物学生物安全规范以及加强研发单位内部管理和生物安全科普宣传等我国合成生物学安全管理制度与措施等建议。     

合成生物学及其在生物技术中的应用进展

合成生物学是一门21世纪生物学的新兴学科,它着眼生物科学与工程科学的结合,把生物系统当作工程系统"从下往上"进行处理,由"单元"(unit)到"部件"(device)再到"系统"(system)来设计,修改和组装细胞构件及生物系统.合成生物学是分子和细胞生物学、进化系统学、生物化学、信息学、数学、计算机和工程等多学科交叉的产物.目前研究应用包括两个主要方面:一是通过对现有的、天然存在的生物系统进行重新设计和改造,修改已存在的生物系统,使该系统增添新的功能.二是通过设计和构建新的生物零件、组件和系统,创造自然界中尚不存在的人工生命系统.合成生物学作为一门建立在基因组方法之上的学科,主要强调对创造人工生命形态的计算生物学与实验生物学的协同整合.必须强调的是,用来构建生命系统新结构、产生新功能所使用的组件单元既可以是基因、核酸等生物组件,也可以是化学的、机械的和物理的元件.本文跟踪合成生物学研究及应用,对其在DNA水平编程、分子修饰、代谢途径、调控网络和工业生物技术等方面的进展进行综述.