基因组学时代的真菌分类学:机遇与挑战

真菌物种的形态特征有限,加之形态滞后和形态可塑性,仅靠外部形态、内部结构及生理生化指标,很难把握真菌的系统亲缘。应用DNA测序、基因组测序、比较基因组学及生物信息学等技术,研究人员可以快速识别真菌演化中出现的数量众多的单系支系,为建立各分类等级的新分类单元提供有力证据,为真菌分类学研究带来了新的希望和活力。自2000年以来,在真菌界至少发表了1新亚界、4新门、7新亚门、19新纲、9新亚纲、40余新目等高级分类单元。近3年来,我国发表了20余个真菌新属,其中绝大多数属的建立都有分子证据支持。可以预见,大量的新种、新属、新科乃至更高级分类单元将会在今后10年内持续发现和建立。这必将大大促进真菌分类学的发展,完善现有的真菌分类系统。我们应该顺势而上,利用我国丰富的真菌资源,为真菌分类学的发展做出应有贡献。与此同时,真菌分类学也面临着十分严峻的挑战。挑战主要来自3个方面,一是研究变得越来越综合,不但需要有相应的研究经费支持,而且要求从事该领域的研究人员技术更全面、知识更广博及知识更新速度更快捷;二是新物种描述进度偏慢,远远不能满足人们对物种认识和利用的日益增长的需要;三是研究人员亟需创新研究模式,以新技术、新思路、新机制来构建新的真菌分类学,加速新物种的发现和描述进度,最终为社会进步和科学发展服务。     

Structural genomics: opportunities and challenges

Following the complete genome sequencing of an increasing number of organisms, structural biology is engaging in a systematic approach of high-throughput structure determination called structural genomics to create a complete inventory of protein folds/structures that will help predict functions for all proteins. First results show that structural genomics will be highly effective in finding functional annotations for proteins of unknown function.     

Structural genomics: a new era for pharmaceutical research

A report on the 15th Annual Center for Advanced Biotechnology and Medicine Symposium on structural genomics in pharmaceutical design, Princeton, USA, 24-25 October 2001.     

Human obesity: toward functional genomics

Genetic and environmental aspects are recognized in the obesity field and attempts to elucidate multiple genes and gene/environment interactions are necessary. In rare cases of monogenic obesities, genetic tools have proved extremely powerful for identifying the genes responsible and for defining new syndromes. Abnormalities of genes involved in the leptin/melanocortin axis have been described. In common obesity, most studies include the search for genotype/phenotype associations without taking into account the influence of environment (diet, sedentary lifestyle) in the relationship. Many genes and candidate regions have been proposed to be involved in the determinism of human obesity. Among the limitations to this integrated approach, one can cite the difficulty of having large enough samples as well as biocomputing tools that are still in their infancy for accessing the question of multiple interactions with no "a priori hypotheses". This picture will probably change rapidly in the future. The purpose of this paper is to present some examples of the knowledge acquired in the field of obesity genetics and the new ongoing tools and developments that aim at studying the contribution of genes to obesity and their response to environmental changes. The capacity for studying multiple genes at once at the DNA or RNA levels is rapidly growing. Finally, tremendous progress in biocomputing will allow the integration of information from different sources (i.e. environment, phenotype, genotype, gene expression) and thus improve our ability to deal with complexity. Examples of these approaches exist in humans and in animal models.     

生理学与基因组学:走向系统生物学

近十年来,生理学与基因组学达到了空前的融合。尽管生理基因组学还是一个非常年轻的研究领域,系统生物学概念的引入必将推进生理基因组学达到全新的水平。本文概要地叙述了这个令人振奋的生理科学的新时代给生理学家带来的机遇和挑战,并以我们自己近十年来的经验为例,讨论了怎样通过扩展和延伸生理学与基因组学的结合,从而对生物学得到系统的理解。     

Sequence-based cancer genomics: progress,lessons and opportunities

Technologies that provide a genome-wide view offer an unprecedented opportunity to scrutinize the molecular biology of the cancer cell. The information that is derived from these technologies is well suited to the development of public databases of alterations in the cancer genome and its expression. Here, we describe the synergistic efforts of research programmes in Brazil, the United Kingdom and the United States towards building integrated databases that are widely accessible to the research community, to enable basic and applied applications in cancer research.     

Nutritional biology: a neglected basic discipline of nutritional science

On the basis of a scientific-philosophical analysis, this paper tries to show that the approaches in current nutritional science—including its subdisciplines which focus on molecular aspects—are predominantly application-oriented. This becomes particularly evident through a number of conceptual problems characterized by the triad of ‘dearth of theoretical foundation,’ ‘particularist research questions,’ and ‘reductionist understanding of nutrition.’ The thesis presented here is that an interpretive framework based on nutritional biology is able to shed constructive light on the fundamental problems of nutritional science. In this context, the establishment of ‘nutritional biology’ as a basic discipline in research and education would be a first step toward recognizing the phenomenon of ‘nutrition’ as an oecic process as a special case of an organism–environment interaction. Modern nutritional science should be substantively grounded on ecological—and therefore systems biology as well as organismic—principles. The aim of nutritional biology, then, should be to develop near-universal ‘law statements’ in nutritional science—a task which presents a major challenge for the current science system.     

Functional genomics of parasitic worms: the dawn of a new era

The study of gene function in parasitic worms is technically demanding due to difficulties associated with life-cycle propagation and, hence, molecular genetics. Exploitation of the free-living nematode, Caenorhabditis elegans, coupled with recent major advances in molecular studies of parasitic nematodes, have opened up new avenues for understanding the biology of these parasites and present opportunities for novel strategies of therapeutic intervention and control.     

The genomics era is upon us

Alternative gene form discovery and candidate gene selection from gene indexing projectsBurke, J., Wang, H., Hide, W. and Davidson, D.B. (1998)Genome Res. 8, 276–290Phylogenomics: improving functional predictions for uncharacterized genes by evolutionary analysisEisen, J.A. (1998)Genome Res. 8, 163–167     

Functional genomics in the post-genome era

As the biomedical research community enters the post-genome era, studying gene expression patterns and phenotypes in model organisms will be an important part of analyzing the role of genes in human health and disease. New technologies involving DNA chips will improve the ability to evaluate the differential expression of a large number of genes simultaneously. Also, new approaches for generating mutations in mice will significantly decrease the cost and increase the rate of generating mutant lines that model human disease.     

Prokaryotic systematics in the genomics era

As an essential and basic biological discipline, prokaryotic systematics is entering the era of genomics. This paradigmatic shift is significant not only for understanding molecular phylogeny at the whole genome level but also in revealing the genetic or epigenetic basis that accounts for the phenotypic criteria used to classify and identify species. These developments provide an opportunity and a challenge for systematists to reanalyze the molecular mechanisms underlying the taxonomic characteristics of prokaryotes by drawing the knowledge from studies of genomics and/or functional genomics employing platform technologies and related bioinformatics tools. It is expected that taxonomic books, such as Bergey’s Manual of Systematic Bacteriology may evolve into a systematics library indexed by phylogenomic information with an comprehensive understanding of prokaryotic speciation and associated increasing knowledge of biological phenomena.