基因组研究与生命科学工业的崛起

人类基因组的全序列测定预计可提前两年于２００３年完成，特别是基因组内的蛋白质编码序列将更早测定。私人财团斥巨资进入这个领域，并望抢得先手，这意味着基因组研究可创造巨大财富。在过去几年里，国际上一批知名的大型制药集团和化学工业公司已在基因组研究领域内投入大量资金，并形成了一个新的产业部门，即生命科学工业。制药工业是生命科学工业的主要支柱之一，与基因组研究的关系特别密切。药物基因组学研究表明，药物的疗效与患者的基因型相关，因此，今后的药物生产要考虑到药物投放地区人群中有关的等位基因的频率，医疗处方也将因人而异而趋向个人化。比较基因组学研究则有助于从模式生物的资料指出与疾病可能相关的基因，可以此作为靶标来设计药物。     

《动物生物学》教学对生命科学发展和人才培养的作用

动物生物学是揭示动物生命活动规律的科学。作为生命科学专业本科学生最早接触到的主干课程之一,动物生物学的教学对于学生了解生物学的基本概念和基础知识、构建生命科学的知识体系和思维方式、培养和巩固专业兴趣十分重要。系统回顾和总结了动物生物学研究对生命学科发展的贡献,阐明了动物生物学教学对生命科学人才培养与学科建设的作用,引起广大的生物学教学工作者和管理者对动物生物学教学的重视,促进传统重要基础课程的建设与发展。     

Opportunities and challenges for the life sciences community

Twenty-first century life sciences have transformed into data-enabled (also called data-intensive, data-driven, or big data) sciences. They principally depend on data-, computation-, and instrumentation-intensive approaches to seek comprehensive understanding of complex biological processes and systems (e.g., ecosystems, complex diseases, environmental, and health challenges). Federal agencies including the National Science Foundation (NSF) have played and continue to play an exceptional leadership role by innovatively addressing the challenges of data-enabled life sciences. Yet even more is required not only to keep up with the current developments, but also to pro-actively enable future research needs. Straightforward access to data, computing, and analysis resources will enable true democratization of research competitions; thus investigators will compete based on the merits and broader impact of their ideas and approaches rather than on the scale of their institutional resources. This is the Final Report for Data-Intensive Science Workshops DISW1 and DISW2. The first NSF-funded Data Intensive Science Workshop (DISW1, Seattle, WA, September 19-20, 2010) overviewed the status of the data-enabled life sciences and identified their challenges and opportunities. This served as a baseline for the second NSF-funded DIS workshop (DISW2, Washington, DC, May 16-17, 2011). Based on the findings of DISW2 the following overarching recommendation to the NSF was proposed: establish a community alliance to be the voice and framework of the data-enabled life sciences. After this Final Report was finished, Data-Enabled Life Sciences Alliance (DELSA, www.delsall.org ) was formed to become a Digital Commons for the life sciences community.     

Laser tweezers and multiphoton microscopes in life sciences

Near infrared (NIR) laser microscopy enables optical micromanipulation, piconewton force determination, and sensitive fluorescence studies by laser tweezers. Otherwise, fluorescence images with high spatial and temporal resolution of living cells and tissues can be obtained via non-resonant fluorophore excitation with multiphoton NIR laser scanning microscopes. Furthermore, NIR femtosecond laser pulses at TW/cm2 intensities can be used to realize non-invasive contact-free surgery of nanometer-sized structures within living cells and tissues. Applications of these novel versatile NIR laser-based tools for the determination of motility forces, coenzyme and chlorophyll imaging, three-dimensional multigene detection, non-invasive optical sectioning of tissues ("optical biopsy"), functional protein imaging, and nanosurgery of chromosomes are described.     

Patent pools and clearinghouses in the life sciences

The biopharmaceutical industry is slowly absorbing the idea of collaborative patent licensing models. Recently, two patent pools for developing countries have been launched: the Pool for Open Innovation against Neglected Tropical Diseases initiated by GlaxoSmithKline (GSK), which is referred to as the BIO Ventures for Global Health (BVGH) pool, and the Medicines Patent Pool (MPP) initiated by UNITAID. Various organizations have recommended using pools or clearinghouses beyond the humanitarian dimension where many patents are owned by many different actors. As a first attempt, MPEG LA, which administers patent pools in various technology fields, is now setting up a clearinghouse for patents related to molecular diagnostics. These examples as well as the results from an empirical study provide useful insights for the design and administration of future pools and clearinghouses in the life sciences.     

Editorial: "crossing boundaries: stem cells, materials, and mesoscopic sciences"

"Crossing Boundaries: Stem Cells, Materials, and Mesoscopic Sciences". This Special Issue, edited by Prof. Anthony Ho and Prof. Norio Nakatsuji, comprises review articles on the interdisciplinary study of stem cells and material science and is a celebration of the friendship and collaboration between Heidelberg University and Kyoto University in Germany and Japan, respectively.     

Synthetic biology for mammalian cell technology and materials sciences

The synthetic reconstruction of natural gene networks and the de novo design of artificial genetic circuits provide new insights into the cell's regulatory mechanisms and will open new opportunities for drug discovery and intelligent therapeutic schemes. We will present how modular synthetic biology tools like repressors, promoters and enzymes can be assembled into complex systems in order to discover small molecules to shut off antibiotic resistance in tubercle bacteria and to design self-sufficient therapeutic networks. The transfer of these synthetic biological modules to the materials science field enables the construction of novel drug-inducible biohybrid materials for biomedical applications.     

The dual-use dilemma for the life sciences: perspectives, conundrums, and global solutions

The term "dual-use" traditionally has been used to describe technologies that could have both civilian and military usage, but this term has at least three different dimensions that pose a dilemma for modern biology and its possible misuse for hostile purposes: (1) ostensibly civilian facilities that are in fact intended for military or terrorist bioweapons development and production; (2) equipment and agents that could be misappropriated and misused for biological weapons development and production; and (3) the generation and dissemination of scientific knowledge that could be misapplied for biological weapons development and production. These three different aspects of the "dual-use dilemma" are frequently confused--each demands a distinct approach within a "web of prevention" in order to reduce the future risk of bioterrorism and biowarfare. This article discusses the nature of the different perspectives and divergent approaches as a contribution to finding a scientifically acceptable global solution to the problem posed by the dual-use dilemma. We propose that: (1) facilities that are intended for bioweapons development and production should be primarily prevented by a strengthened Biological and Toxin Weapons Convention (BTWC) effectively implemented in all nation states, one that includes provisions for adequate transparency to improve confidence and a mechanism for thorough inspections when there is sufficient cause, and enhanced law enforcement activities involving international cooperation and sharing of critical intelligence information; (2) potentially dual-use equipment and agents should be available to legitimate users for peaceful purposes, but strengthened national biosafety and physical and personnel biosecurity controls in all nations together with effective export controls should be implemented to limit the potential for the misappropriation of such equipment and materials; and (3) information should be openly accessible by the global scientific community, but a culture of responsible conduct involving the breadth of the international life sciences communities should be adopted to protect the ongoing revolution in the life sciences from being hijacked for hostile misuse of the knowledge generated and communicated by life scientists.     

Organizing graduate life sciences education around nodes and connections

Biomedical education is currently faced with a number of significant challenges, including the explosion of information and the need to train researchers who can work across traditional disciplinary boundaries. We propose a new integrated model for graduate education in the life sciences that addresses these issues.     

Birth of the life sciences in Spain and Portugal

For many centuries, Spain and Portugal were occupied by various nations. The consequent mixing of cultures formed a unique environment in which to do science.     

Combining competencies and competitiveness for the European life sciences

The Youth Conference on European Life Science Careers News from academia: Women in Science Award for structural biologist