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.     

Reconstructionist molecular biology

In the editorial inaugurating this journal, Levine (1989) pointed to a new reductionism in biology, which--unlike the old reductionism that led to specialization and isolation of areas concerned with different aspects of a complex biological problem--is providing a renewed sense of unity. This development is the result of widespread use of common experimental methodology and the emergence of signal transmission and differential gene expression as themes that are central to many areas of modern biology. I describe here a set of complementary developments in molecular biology that focus attention on the problems of complexity and organization. Simple examples are given that illustrate the difficulty of relating systemic behavior to the properties of the underlying molecular determinants, and the outlines of a general approach to this problem are presented. These developments, together with those highlighted by Levine, are leading us to a new, more integrative intellectual paradigm whose fruits will be the elucidation of fundamental issues concerning network function, design, and evolution that cannot be addressed by the current paradigm.     

The August Krogh principle applies to plants

The Krogh principle refers to the use of a large number of animals to study the large number of physiological problems, rather than limiting study to a particular organism for all problems. There may be organisms that are more suited to study of a particular problem than others. This same principle applies to plants. The authors are concerned with the recent trend in plant biology of using Arabidopsis thaliana as the "organism of choice." Arabidopsis is an excellent organism for molecular genetic research, but other plants are superior models for other research areas of plant biology. The authors present examples of the successful use of the Krogh principle in plant cell biology research, emphasizing the particular characteristics of the selected research organisms that make them the appropriate choice.     

Guidelines: From artificial evolution to computational evolution: a research agenda

Computational scientists have developed algorithms inspired by natural evolution for at least 50 years. These algorithms solve optimization and design problems by building solutions that are 'more fit' relative to desired properties. However, the basic assumptions of this approach are outdated. We propose a research programme to develop a new field: computational evolution. This approach will produce algorithms that are based on current understanding of molecular and evolutionary biology and could solve previously unimaginable or intractable computational and biological problems.     

Information literacy in biology education: an example from an advanced cell biology course

Information literacy skills are critically important for the undergraduate biology student. The ability to find, understand, evaluate, and use information, whether from the scientific literature or from Web resources, is essential for a good understanding of a topic and for the conduct of research. A project in which students receive information literacy instruction and then proceed to select, update, and write about a current research topic in an upper-level cell biology course is described. Students research the chosen topic using paper and electronic resources, generate a list of relevant articles, prepare abstracts based on papers read, and, finally, prepare a "state-of-the-art" paper on the topic. This approach, which extends over most of one semester, has resulted in a number of well-researched and well-written papers that incorporate some of the latest research in cell biology. The steps in this project have also led to students who are prepared to address future projects on new and complex topics. The project is part of an undergraduate course in cell biology, but parts of the assignments can be modified to fit a variety of subject areas and levels.     

Human stem cells, chromatin, and tissue engineering: boosting relevancy in developmental toxicity testing

Risk assessment derives its confidence from toxicology research that is based on relevancy to human health. This article focuses on two highly topical areas of current scientific research, stem cells and chromatin biology, which present new avenues for preclinical and clinical applications, and the frontier role of tissue engineering and regeneration. Appreciating the utility and necessity of chromatin and human somatic stem cells as research tools and looking toward tissue engineering may close the uncertainty gaps between animal and human cross-species toxicology evaluations. The focus will be on developmental toxicology applications, but appropriate extrapolation to any other areas of toxicology can be made. We further provide background on basic biology of these three areas and examples of how early life exposure to known and potential environmental toxicants induce malformations, childhood and adult-onset diseases, through aberrant chromatin modification of critical gene expressions (acute lymphocyte leukemia, heavy-metal nickel and cadmium-associated defects, and reproductive tract malformations and carcinomas induced by the synthetic estrogen, diethylstilbestrol).     

Intermediary metabolism in parasitic helminths

This review is a survey of progress in the field of helminth intermediary metabolism since ICOPA V. Data on the catabolism and synthesis of carbohydrates, lipids, amino acids, proteins, nucleotides and nucleic acids are presented and discussed in relation to previous work. The large number of references cited reflects a continued interest of parasite biochemists in this field, although many fundamental problems of helminth metabolism remain unsolved. Important areas for future research are identified and the potential application of new biochemical techniques, especially those in molecular biology, are emphasised.     

A research agenda for helminth diseases of humans: basic research and enabling technologies to support control and elimination of helminthiases

Successful and sustainable intervention against human helminthiases depends on optimal utilisation of available control measures and development of new tools and strategies, as well as an understanding of the evolutionary implications of prolonged intervention on parasite populations and those of their hosts and vectors. This will depend largely on updated knowledge of relevant and fundamental parasite biology. There is a need, therefore, to exploit and apply new knowledge and techniques in order to make significant and novel gains in combating helminthiases and supporting the sustainability of current and successful mass drug administration (MDA) programmes. Among the fields of basic research that are likely to yield improved control tools, the Disease Reference Group on Helminth Infections (DRG4) has identified four broad areas that stand out as central to the development of the next generation of helminth control measures: 1) parasite genetics, genomics, and functional genomics; 2) parasite immunology; 3) (vertebrate) host-parasite interactions and immunopathology; and 4) (invertebrate) host-parasite interactions and transmission biology. The DRG4 was established in 2009 by the Special Programme for Research and Training in Tropical Diseases (TDR). The Group was given the mandate to undertake a comprehensive review of recent advances in helminthiases research in order to identify notable gaps and highlight priority areas. This paper summarises recent advances and discusses challenges in the investigation of the fundamental biology of those helminth parasites under the DRG4 Group's remit according to the identified priorities, and presents a research and development agenda for basic parasite research and enabling technologies that will help support control and elimination efforts against human helminthiases.     

粪便学在有蹄类动物数量调查研究中的应用与展望

随着与分子生物学的结合,传统的粪便学不仅拓宽了在种群生态学、行为生态学及保护遗传学等研究时取样的范围,而且能提供更多的有效信息,使得传统的粪便计数方法得以在新的领域里发展。本文对传统粪便学在有蹄类动物数量研究中的应用加以总结,并结合国内外研究现状对分子粪便学在这一领域内的可靠性、局限性及应用前景做了概述。     

Synthetic biology: a foundation for multi-scale molecular biology

The field of synthetic biology has made rapid progress in a number of areas including method development, novel applications and community building. In seeking to make biology "engineerable," synthetic biology is increasing the accessibility of biological research to researchers of all experience levels and backgrounds. One of the underlying strengths of synthetic biology is that it may establish the framework for a rigorous bottom-up approach to studying biology starting at the DNA level. Building upon the existing framework established largely by the Registry of Standard Biological Parts, careful consideration of future goals may lead to integrated multi- scale approaches to biology. Here we describe some of the current challenges that need to be addressed or considered in detail to continue the development of synthetic biology. Specifically, discussion on the areas of elucidating biological principles, computational methods and experimental construction methodologies are presented.     

Chemoproteomic approaches to drug target identification and drug profiling

Chemoproteomics represents a new research discipline at the interface of medicinal chemistry, biochemistry, and cell biology focused on studying the molecular mechanisms of action of drugs and other bioactive small molecules. Research strategies frequently combine phenotypic screening with subsequent target identification, and aim at a proteome-wide characterization of drug-induced changes in cellular protein expression and post-translational modifications. In recent years quantitative mass spectrometry has taken center stage in many of these approaches. This review describes experimental strategies in current chemical proteomics research, discusses recent examples of successful applications, and highlights areas in drug discovery where chemical proteomics-based assays using native endogenous proteins are expected to have substantial impact.     

Ecological research in Nicaragua

Shortages of funds and personnel have restricted the development of ecological research in Nicaragua. These problems are exacerbated by the current war between the forces of the government and the contras. In spite of these difficulties, there has been considerable recent progress in research that focuses on urgent environmental problems - especially agricultural ecology and conservation biology.     

金属型植物的研究进展

金属型植物是治理和修复土壤重金属污染的理想材料.综述了金属型植物的耐性机理、生殖生物学及进化生态学方面的研究进展,并对目前研究中存在的问题进行了分析和展望.     

Modern methods of genome sequencing and their application for deciphering genomes of microorganisms

Development of new methods for genome sequencing allows rapid and relatively inexpensive determination of the large volumes of nucleotide sequences and opens new possibilities to conduct fundamental and applied research in biology, medicine, and biotechnology. The traditional and the newest methods of genome sequencing of microorganisms including the Sanger sequencing method, parallel pyrosequencing (454 Life Sciences/Roche), Solexa/Illumina technologies, and ligation-based sequencing (SOLiD System) are discussed in the current review. The main areas and prospects of applying various sequencing methods to achieve diverse scientific goals are presented. The possibilities of applying methods of parallel pyrosequencing for deciphering genomes of microorganisms are reviewed, using as an example the genome projects completed at the Bioengineering Center, Russian Academy of Sciences.     

Exploring frontiers in the DNA landscape: an introduction to the symposium "Genome Analysis and the Molecular Systematics of Retroelements"

The emerging field of phylogenomics is influencing both the amount and type of characters being brought to bear on long-standing problems in systematic biology. Moreover, the proliferation of sequence information from genome projects in concert with the development of new informatics tools is widening access to comparative data on retroelements to a broad cross section of investigators. Motivated by this, the Society of Systematic Biologists sponsored a symposium entitled "Genome Analysis and the Molecular Systematics of Retroelements," and the resulting papers illustrate this theme of new discoveries and cover three basic areas of research: (i) the taxonomic distribution and phylogenetic structure of families of retroelements; (II) the use of SINE and LINE insertions for phylogenetic inference; and (III) the informatics and classification of repetitive elements. Contributions of each article are briefly discussed in this context and particularly fruitful directions for future research illuminated by results of this symposium are reviewed.     

保护生物学一新分支学科——保护遗传学

研究人类对生物多样性的影响以及防止物种灭绝是保护生物学的两个主要目的。随着环境日益恶化、分子遗传学的迅速发展以及保护生物学和分子遗传学的不为民相互渗透,和产生了一全新的分支学科－－保护遗传学。保护遗传学是保护生物学研究中的一个核心部分,主要研究濒危物种的遗传多样性和保护物种的进化潜力。目前保护遗传学已成为国际上的一个研究热点,但在我国才刚刚起步,为此,本文就保护,遗传学的产生和发展及其研究内容和意义作一简要介绍,以推动我国在该方面的研究。     

对我国分子生态学研究近期发展战略的一些思考

分子生态学是多学科交叉的整合性研究领域, 是运用进化生物学理论解决宏观生物学问题的科学。经过半个多世纪的发展, 本学科已日趋成熟, 它不仅已经广泛渗透到宏观生物学的众多学科领域, 而且已经成为连接和融合很多不同学科的桥梁, 是目前最具活力的研究领域之一。其研究的范畴, 从最基础的理论和方法技术, 到格局和模式的发现和描述, 到对过程和机制的深入探讨, 再到付诸于实践的行动和规划指导等各个层次。分子生态学的兴起给宏观生物学带来了若干飞跃性的变化, 使宏观生物学由传统的以观察、测量和推理为主的描述性研究转变为以从生物和种群的遗传构成的变化和历史演化背景上检验、证明科学假设及揭示机制和规律为主的机制性/解释性研究, 因而使得对具有普遍意义的科学规律、生态和进化过程及机制的探索成为可能。分子生态学已经进入组学研究时代, 这使得阐明复杂生态过程、生物地理过程和适应性演化过程的机制性研究由原来难以企及的梦想变成完全可以实现的探求; 它也带来了全新的挑战, 其中最有深远影响的将是对分子生态学研究至关重要的进化生物学基础理论方面的突破, 例如遗传变异理论、种群分化理论、表观遗传因素的作用, 乃至进化生物学的基本知识构架等等。这些方面的进展必将使宏观生物学迎来一场空前的革命, 并对生态学的所有分支学科产生重大影响, 甚至催生诸如生态表观组学这样的新分支学科。对于中国科学家来说, 分子生态学组学时代的开启, 更是一个千载难逢的机遇, 为提出和建立生命科学的新方法、新假说、新思想和新理论提供了莫大的探索空间——此前我们对宏观生物学方法、理论和思想的发展贡献很小。然而, 限制组学时代重大突破的关键因素是理论、概念、理念、实验方法或分析方法方面的创新和突破, 这正是我国分子生态学研究最薄弱的环节。我国教育部门应尽快调整生命科学本科生培养的理念和方法, 以培养具备突出创新潜力的年轻一代后备人才; 同时, 科研项目资助部门和研究人员不仅应清醒地认识本学科领域的发展态势, 更要及时调整思路, 树立新的项目管理理念和治学 理念。     

Paleobotany: Recent developments and future research directions

The current state of research in the field of paleobotany is reviewed, with emphasis on those areas that deal with more biological approaches to paleobotany. These would include such subjects as the reproductive biology of fossil plants, pollination biology in selected groups, paleobiochemistry, and information on the interaction of plants with other organisms (plant/animal interactions) and their environment (paleoecology). Also discussed are some of the more recent contributions to our understanding of Precambrian paleobiology and early angiosperm reproduction and evolution. Finally, we offer some speculation on the contributions that various areas of paleobotany may provide in the future.     

An evaluation of the role and effectiveness of institutional biosafety committees in providing oversight and security at biocontainment laboratories

Institutional biosafety committees (IBCs) have been charged with the oversight and review of biosafety at thousands of biocontainment labs nationwide, hundreds of which are high-level BSL-3 and BSL-4 labs. In light of the recent rapid proliferation of BSL-3 and BSL-4 facilities and the increases in research in the areas of biodefense, select agents, recombinant DNA, and synthetic biology and dual-use research, questions have been raised about whether IBCs are fulfilling their oversight responsibilities. This article reviews information on the responsibilities and expectations of IBCs as currently constituted and provides an analysis of IBC performance from survey data of hundreds of research institutions over the past several years. The findings highlight serious ongoing problems with IBCs' adherence to NIH Guidelines. This raises questions about the current voluntary governance framework as an effective system to monitor and oversee U.S. research facilities, including high-containment facilities, and their research activities. The findings strongly suggest the need for immediate improvement or replacement of the IBC system.