中国精神分裂症的全基因组关联分析及其转化医学进展

我国在精神分裂症的遗传学和生命组学研究方面取得了很大进展,如在全基因组关联分析(genome-wide association study,GWAS)方面工作获得了一系列成果.随着我国对重大疾病转化医学的逐步关注和重视,利用在精神分裂症上已经获得的广泛和深入的研究结果,寻找精神分裂症各种临床应用的生物标记物研究,系统性地建立适合于类似精神分裂症这类复杂疾病的早期诊断、干预和预防的临床咨询和应用体系等将是该疾病转化医学方面可实施的方法和案例.精神分裂症的转化医学方面还涉及精神分裂症患者的个体化用药方案建立.药物疗效和药物不良反应的个体差异具有较复杂的环境和遗传背景,结合精神分裂症的遗传学病因和药物作用的遗传学差异,将有效发挥治疗药物的功效,并降低重大不良反应在敏感个体上的发生.对精神分裂症这类给国家和社会带来极其重大负担的重大疾病,积极推动我国在此类疾病上的基础研究成果转化和转化医学的实施具有重要的社会效应和积极的带动作用.     

Conservation genetics and genomics of threatened vertebrates in China

Conservation genetics and genomics are two independent disciplines that focus on using new techniques in genetics and genomics to solve problems in conservation biology. During the past two decades, conservation genetics and genomics have experienced rapid progress. Here, we summarize the research advances in the conservation genetics and genomics of threatened vertebrates (e.g., carnivorans, primates, ungulates, cetaceans, avians, amphibians and reptiles) in China. First, we introduce the concepts of conservation genetics and genomics and their development. Second, we review the recent advances in conservation genetics research, including noninvasive genetics and landscape genetics. Third, we summarize the progress in conservation genomics research, which mainly focuses on resolving genetic problems relevant to conservation such as genetic diversity, genetic structure, demographic history, and genomic evolution and adaptation. Finally, we discuss the future directions of conservation genetics and genomics.     

An essay on the necessity and feasibility of conservation genomics

The basic premise of conservation genetics is that small populations may be genetically threatened. The two steps leading to this premise are: (1) due to prominent influence of random genetic drift and inbreeding allelic and genotypic diversity in small populations is expected to be low, and (2) low allelic diversity and high homozygosity are expected to lead to immediate fitness decreases (inbreeding depression) and a compromised potential for evolutionary adaptation. Conservation genetic research has been strongly stimulated by the application of neutral molecular markers like microsatellites and AFLPs. In general these marker studies have provided evidence for step 1. It is less evident how these markers may provide evidence for step 2. In this essay we argue that, in order to get detailed insight in step 2, adopting a conservation genomic approach, in which conservation genetics will use approaches from ecological and evolutionary functional genomics (ecogenomics), is both necessary and feasible. Conservation genomics is necessary for studying functional genomic variation as function of drift and inbreeding, for studying the mechanisms that relate low genetic variation to low fitness, for integrating environmental and genetic approaches to conservation biology, and for developing modern, fast monitoring tools. The rapid technical and financial developments in genomics currently make conservation genomics feasible, and will improve feasibility in the very near future even further. We therefore argue that conservation genomics personifies part of the near future of conservation genetics.     

Exploring Complex Ornamental Genomes: The Rose as a Model Plant

Despite its high economic importance, little is known about rose genetics, genome structure, and the function of rose genes. Reasons for this lack of information are polyploidy in most cultivars, simple breeding strategies, high turnover rates for cultivars, and little public funding. Molecular and biotechnological tools developed during the genomics era now provide the means to fill this gap. This will be facilitated by a number of model traits as e.g., a small genome, a large genetic diversity including diploid genotypes, a comparatively short generation time and protocols for genetic engineering. A deeper understanding of genetic processes and the structure of the rose genome will serve several purposes: Applications to the breeding process including marker-assisted selection and direct manipulation of relevant traits via genetic engineering will lead to improved cultivars with new combinations of characters. In basic research, unique characters, e.g., the biosynthesis and emission of particular secondary metabolites will provide new information not available in model species. Furthermore comparative genomics will link information about the rose genome to ongoing projects on other rosaceous crops and will add to our knowledge about genome evolution and speciation. This review is intended as a presentation and is the compilation of the current knowledge on rose genetics and genomics, including functional genomics and genetic engineering. Furthermore, it is intended to show ways how knowledge on rose genetics and genomics can be linked to other species in the Rosaceae in order to utilize this information across genera.     

Application of 16s rDNA and cytochrome <Emphasis Type="Italic">b</Emphasis> ribosomal markers in studies of lineage and fish populations structure of aquatic species

The most economically important form of aquaculture is fish farming, which is an industry that accounts for an ever increasing share of world fishery production. Molecular markers can be used to enhance the productivity of the aquaculture and fish industries to meet the increasing demand. Molecular markers can be identified via a DNA test regardless of the developmental stage, age or environmental challenges experienced by the organism. The application of 16s and cytochrome b markers has enabled rapid progress in investigations of genetic variability and inbreeding, parentage assignments, species and strain identification and the construction of high resolution genetic linkage maps for aquaculture fisheries. In this review, the advantages of principles and potential power tools of 16s and cytochrome b markers are discussed. Main findings in term of trend, aspects and debates on the reviewed issue made from the model of aquatic species for the benefit of aquaculture genomics and aquaculture genetics research are discussed. The concepts in this review are illustrated with various research examples and results that relate theory to reality and provide a strong review of the current status of these biotechnology topics.     

水稻功能基因组学研究

水稻是迄今为止第一个被测序的农作物。随着水稻基因组测序计划的完成,以功能基因组学研究为标志的后基因组时代已经到来。综述了水稻功能基因组学的工作进展与方法,主要包括:表达序列标签(EST)c、DNA微阵列和DNA芯片、蛋白质组学、生物信息学和反向遗传学等新方法。     

Adaptive landscape genetics: pitfalls and benefits

Landscape genetics offers a promising framework for assessing the interactions between the environment and adaptive genetic variation in natural populations. A recent workshop held at the University of Neuchatel brought together leading experts in this field to address current insights and future research directions in adaptive landscape genetics. Considerable amounts of genetic and/or environmental data can now be collected, but the forthcoming challenge is to do more with such manna. This requires a markedly better understanding of the genetic variation that is adaptive and prompts for advances in information management together with the development of a balance between theory and data. Moreover, showing the links between landscapes and adaptive genetic variation will ultimately move the field beyond association studies.     

多年生植物模式物种基因组研究的历史及进展

木本植物有许多不同于一年生草本植物的生物学特性,生物学家提出将木本植物 作为研究多年生植物的模式体系。杨属Populus树种由于研究基础较好且基因组较小,目前已 被广泛地接受作为多年生植物基因组研究的模式物种。随着杨属树种全基因组序列的测定, 杨属树种在多年生植物的功能基因组研究及一些基础科学问题的研究中将发挥重要作用。本 文综述了杨属树种基因组研究的历史、进展及将来的研究热点,旨在为我国多年生植物基因 组研究提供参考和借鉴。本文主要论述了以下几个方面的内容:（1）对杨属树种开展的细胞 遗传学研究;（2）在分子水平上对杨属树种进行的基因组研究,内容包括遗传作图、基因组 测序、物理图谱构建、基因芯片及连锁不平衡分析;（3）杨属树种基因组信息在探讨一些基 础科学问题中的潜在应用。     

玉米比较基因组学研究进展

玉米是世界上重要的粮食作物 ,长期以来一直是遗传学、分子生物学和基因组学研究的重点对象。近十多年来 ,涉及到玉米的基因组学研究取得了很大进展。不仅在利用比较遗传作图方法方面发现玉米和其它植物 (尤其是禾谷类作物 )的基因组存在广泛的共线性 ,在较小的DNA区域上也发现存在微共线性。尽管还存在一些共线性的例外情形 ,进一步的比较基因组学研究将深入阐明玉米基因组的结构和进化 ,并把这些研究成果应用于基因发掘中。     

DNA barcoding: how it complements taxonomy, molecular phylogenetics and population genetics

DNA barcoding aims to provide an efficient method for species-level identifications and, as such, will contribute powerfully to taxonomic and biodiversity research. As the number of DNA barcode sequences accumulates, however, these data will also provide a unique 'horizontal' genomics perspective with broad implications. For example, here we compare the goals and methods of DNA barcoding with those of molecular phylogenetics and population genetics, and suggest that DNA barcoding can complement current research in these areas by providing background information that will be helpful in the selection of taxa for further analyses.     

Chicken genome sequence: a centennial gift to poultry genetics

A draft sequence of the chicken genome will be available by early 2004. This event conveniently marks the start of the second century of poultry genetics, coming 100 years after the use of the chicken to demonstrate Mendelian inheritance in animals by William Bateson. How will the second, post-genomic century of poultry genetics differ from the first? A whole genome shotgun (WGS) approach is being used to obtain the chicken sequence, with the goal of generating approximately six-fold coverage of the genome. Bacterial artificial chromosome (BAC) and fosmid clone end sequences, along with a BAC contig map integrated with genetic linkage and radiation hybrid maps, will form the platform for assembly of the WGS data. Rapid progress in global analysis of chicken gene expression patterns is also being made. Comparative genomics will link these new discoveries to the knowledge base for all other animal species. It's hoped that the genome sequence will also provide common ground on which to unite studies of the chicken as a model species with those aimed at agriculturally-relevant applications. The current status of chicken genomics will be assessed with projections for its near and long term future.     

Uncovering the genetic basis of adaptive change: on the intersection of landscape genomics and theoretical population genetics

A workshop recently held at the École Polytechnique Fédérale de Lausanne (EPFL, Switzerland) was dedicated to understanding the genetic basis of adaptive change, taking stock of the different approaches developed in theoretical population genetics and landscape genomics and bringing together knowledge accumulated in both research fields. Indeed, an important challenge in theoretical population genetics is to incorporate effects of demographic history and population structure. But important design problems (e.g. focus on populations as units, focus on hard selective sweeps, no hypothesis‐based framework in the design of the statistical tests) reduce their capability of detecting adaptive genetic variation. In parallel, landscape genomics offers a solution to several of these problems and provides a number of advantages (e.g. fast computation, landscape heterogeneity integration). But the approach makes several implicit assumptions that should be carefully considered (e.g. selection has had enough time to create a functional relationship between the allele distribution and the environmental variable, or this functional relationship is assumed to be constant). To address the respective strengths and weaknesses mentioned above, the workshop brought together a panel of experts from both disciplines to present their work and discuss the relevance of combining these approaches, possibly resulting in a joint software solution in the future.     

The genomic basis of eco‐evolutionary dynamics

Recent recognition that ecological and evolutionary processes can operate on similar timescales has led to a rapid increase in theoretical and empirical studies on eco‐evolutionary dynamics. Progress in the fields of evolutionary biology, genomics and ecology is greatly enhancing our understanding of rapid adaptive processes, the predictability of adaptation and the genetics of ecologically important traits. However, progress in these fields has proceeded largely independently of one another. In an attempt to better integrate these fields, the centre for ‘Adaptation to a Changing Environment’ organized a conference entitled ‘The genomic basis of eco‐evolutionary change’ and brought together experts in ecological genomics and eco‐evolutionary dynamics. In this review, we use the work of the invited speakers to summarize eco‐evolutionary dynamics and discuss how they are relevant for understanding and predicting responses to contemporary environmental change. Then, we show how recent advances in genomics are contributing to our understanding of eco‐evolutionary dynamics. Finally, we highlight the gaps in our understanding of eco‐evolutionary dynamics and recommend future avenues of research in eco‐evolutionary dynamics.     

The influence of genetics on future crop production strategies: from traits to genes, and genes to traits

This paper discusses how a genetical approach to plant physiology can contribute to research underpinning the production of new crop varieties. It highlights the interactions between genetics and plant breeding and how the current advances in genetics and the new science of genomics can contribute to our understanding of the genetical control of key agronomic traits ‐ the process of ‘translating’ traits to identified and mapped genes. Advances in genomics, such as the sequencing of whole genomes and expressed sequence tags, are producing information on genes and gene structures, but without knowing their function. A great deal more biology will be necessary to translate gene structure to function ‐ the process of translating genes to traits. Combining these ‘forward’ and ‘reverse’ genetic approaches will allow us to get comprehensive knowledge of the biology of agronomic traits at the physiological, biochemical and molecular levels, so that the ‘circuitry’ of our crop plants can be elucidated. This will enable plant breeders to manipulate crop phenotype using marker‐assisted breeding or genetic engineering approaches with a precision not previously possible.     

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。     

Saccharomyces sensu stricto as a model system for evolution and ecology

Baker's yeast, Saccharomyces cerevisiae, is not only an extensively used model system in genetics and molecular biology, it is an upcoming model for research in ecology and evolution. The available body of knowledge and molecular techniques make yeast ideal for work in areas such as evolutionary and ecological genomics, population genetics, microbial biogeography, community ecology and speciation. As long as ecological information remains scarce for this species, the vast amount of data that is being generated using S. cerevisiae as a model system will remain difficult to interpret in an evolutionary context. Here we review the current knowledge of the evolution and ecology of S. cerevisiae and closely related species in the Saccharomyces sensu stricto group, and suggest future research directions.     

The biology of aging: 1985-2010 and beyond

In this contribution to the series of reflective essays celebrating the 25th anniversary of The FASEB Journal, our task is to assess the growth of research on the biology of aging during this period and to suggest where we might be heading during the next 25 yr. A review of the literature suggests a healthy acceleration of progress during the past decade, perhaps largely due to progress on the genetics of longevity of model organisms. Progress on the genetics of health span in these model organisms has lagged, however. Research on the genetic basis of the remarkable interspecific variations in life span has only recently begun to be seriously addressed. The spectacular advances in genomics should greatly accelerate progress. Research on environmental effects on life span and health span needs to be accelerated. Stochastic variations in gene expression in aging have only recently been addressed. These can lead to random departures from homeostasis during aging.-Martin, G. M. The biology of aging: 1985-2010 and beyond.