Molecular Illustration in Research and Education: Past,Present, and Future

Two-dimensional illustration is used extensively to study and disseminate the results of structural molecular biology. Molecular graphics methods have been and continue to be developed to address the growing needs of the structural biology community, and there are currently many effective, turn-key methods for displaying and exploring molecular structure. Building on decades of experience in design, best-practice resources are available to guide creation of illustrations that are effective for research and education communities.     

KING (Kinemage,Next Generation): A versatile interactive molecular and scientific visualization program

Proper visualization of scientific data is important for understanding spatial relationships. Particularly in the field of structural biology, where researchers seek to gain an understanding of the structure and function of biological macromolecules, it is important to have access to visualization programs which are fast, flexible, and customizable. We present KiNG, a Java program for visualizing scientific data, with a focus on macromolecular visualization. KiNG uses the kinemage graphics format, which is tuned for macromolecular structures, but is also ideal for many other kinds of spatially embedded information. KiNG is written in cross‐platform, open‐source Java code, and can be extended by end users through simple or elaborate “plug‐in” modules. Here, we present three such applications of KiNG to problems in structural biology (protein backbone rebuilding), bioinformatics of high‐dimensional data (e.g., protein sidechain chi angles), and classroom education (molecular illustration). KiNG is a mature platform for rapidly creating and capitalizing on scientific visualizations. As a research tool, it is invaluable as a test bed for new methods of visualizing scientific data and information. It is also a powerful presentation tool, whether for structure browsing, teaching, direct 3D display on the web, or as a method for creating pictures and videos for publications. KiNG is freely available for download at http://kinemage.biochem.duke.edu .     

From Atoms to Cells: Using Mesoscale Landscapes to Construct Visual Narratives

Modeling and visualization of the cellular mesoscale, bridging the nanometer scale of molecules to the micrometer scale of cells, is being studied by an integrative approach. Data from structural biology, proteomics, and microscopy are combined to simulate the molecular structure of living cells. These cellular landscapes are used as research tools for hypothesis generation and testing, and to present visual narratives of the cellular context of molecular biology for dissemination, education, and outreach.     

分子酶工程学研究进展

酶工程的研究已经发展到分子水平,通过基因操作,已实现了许多酶的克隆和表达。定点突变成为研究酶结构与功能的常规手段,并被广泛用于改善酶的性能。体外分子进化方法则大幅提高了酶分子的进化效率,并有可能发展新功能酶。融合蛋白技术的发展使构建新型多功能融合酶成为可能。这里对分子酶工程学的研究与发展情况进行了综述。      

分子人类学与现代人的起源*

1953年Watson & Crick 对于DNA双螺旋结构模型的提出及对其遗传机理的解释,标志着现代分子生物学的诞生。其后短短50年的时间里,分子生物学在各个学科之间广泛渗透,相互促进,不断深入和发展。在以研究人类的起源和进化为首要任务的人类学领域,由于现代分子生物学理论和方法的应用,诞生了分子人类学这一全新的结合型分支学科,为人类学的发展提供了科学可信的研究方法和具发展前景的研究方向。系统地介绍了分子人类学的发展历史、研究方法及原理;另外,结合分子人类学在古人类学研究中的应用,讨论了关于现代人起源的“非洲起源说”和“多地区连续演化说”。Abstract: Since Watson & Crick put forward the double-helix model of DNA structure and hereditary mechanism in 1953, it is generally accepted that this event marks the birth of modern molecular biology. This new field of biology has experienced a flourishing development in the past 50 years. On one hand, the development of molecular biology has been deeply influencing many relative fields; on the other hand, its own proceeding pace has been accelerated by the reaction from the other fields. Anthropology is one of the fields most deeply impacted by the theory and method of molecular biology. Most importantly, molecular anthropology was born as a result of combination of molecular biology, anthropology as well as paleoanthropology. This new branch provides reliable method and vital direction for paleoanthropology. This paper systematically reviews the history, principle and method of molecular anthropology. Two hypotheses on the origin of modern human, which include “out-of-African theory” and “theory of multiregional evolution” are also discussed for the purpose of showing how molecular anthropology is applied in paleoanthropology.     

本科生“分子生物学实验”课程设计的改革与探索

"分子生物学实验"是分子生物学理论课配套的实验课。掌握分子生物学基本实验技术是生命科学对新时代人才发展的基本需求。上海科技大学通过整合教学资源与实验室资源,对传统本科生"分子生物学实验"的教学内容和体系进行调整,建立了一套基础实验与前沿实验相结合、验证性实验和自主设计性实验相结合的教学体系,为提高本科生"分子生物学实验"课程教学质量和培养综合型人才奠定了基础。     

Molecular Visualization on the Holodeck

Can virtual reality be useful for visualizing and analyzing molecular structures and three-dimensional (3D) microscopy? Uses we are exploring include studies of drug binding to proteins and the effects of mutations, building accurate atomic models in electron microscopy and x-ray density maps, understanding how immune system cells move using 3D light microscopy, and teaching schoolchildren about biomolecules that are the machinery of life. Virtual reality (VR) offers immersive display with a wide field of view and head tracking for better perception of molecular architectures and uses 6-degree-of-freedom hand controllers for simple manipulation of 3D data. Conventional computer displays with trackpad, mouse and keyboard excel at two-dimensional tasks such as writing and studying research literature, uses for which VR technology is at present far inferior. Adding VR to the conventional computing environment could improve 3D capabilities if new user-interface problems can be solved. We have developed three VR applications: ChimeraX for analyzing molecular structures and electron and light microscopy data, AltPDB for collaborative discussions around atomic models, and Molecular Zoo for teaching young students characteristics of biomolecules. Investigations over three decades have produced an extensive literature evaluating the potential of VR in research and education. Consumer VR headsets are now affordable to researchers and educators, allowing direct tests of whether the technology is valuable in these areas. We survey here advantages and disadvantages of VR for molecular biology in the context of affordable and dramatically more powerful VR and graphics hardware than has been available in the past.     

Molecules are more than markers: new directions in molecular microbial ecology

Macromolecules such as DNA, RNA, and proteins are widely used to quantify diversity in natural communities, to monitor the dispersal of organisms and their genes, and to trace phylogenetic relationships among organisms. With such widespread use of molecules as markers, it is easy to forget that they perform functions that are integral to the survival of organisms. The structural and functional properties of macromolecules have been intensively studied in genetics, biochemistry, and physiology. These fields, however, have not generally focused on the ecological significance of molecular variation, but instead have used defective variants as tools for identifying structure and function. Understanding the significance of molecular variation for organismal success or failure is a central problem in ecology, one whose solution will require the integration of diverse approaches and perspectives from ecology, molecular biology, genetics, physiology, and evolutionary biology. I review several studies of bacterial populations evolving in simple environments that have begun to integrate these approaches and perspectives in order to examine the consequences of molecular variation for ecological performance.     

红豆杉分子生物学研究进展

红豆杉作为抗癌药物紫杉醇的药源植物得到了国际上的广泛关注。本文综述了近年来国内外关于红豆杉分子生物学方面的研究进展,主要包括编码紫杉醇生物合成的紫杉二烯合成酶、羟基化酶、酰基转移酶等功能基因以及相关转录因子编码基因的分离克隆、表达转化的研究,红豆杉遗传多样性、紫杉醇含量相关的分子标记研究,红豆杉谱系地理学的研究以及解析紫杉醇合成分子机理的红豆杉转录组和代谢组研究等;最后对当前研究的不足和对今后利用分子手段研究红豆杉的发展前景进行了展望。     

植物激素研究中的化学生物学思路与应用

植物激素是植物生长发育过程中必不可少的重要调节物质, 它们直接或间接参与调控从种子萌发到成熟的各个发育阶段以及对生物/非生物胁迫的响应。随着利用小分子化合物探究生物体生理代谢分子机制的不断发展, 植物生物学与化学之间一个新的前沿交叉学科——化学生物学随之诞生, 并在短时间内取得了重要进展。化学生物学的思路与方法在植物激素研究领域中起到了不可替代的作用, 尤其是在激素合成及信号转导研究领域。该文概述了主要植物激素的小分子类似物及其在植物生长发育和生物/非生物胁迫响应等方面的作用机制, 并讨论了激素类似物在实际生产中的应用潜力及未来的研究方向。     

介导硫化氢生理/病理学效应的靶分子及其分子开关调节的原子生物学机制

硫化氢(H_2S)作为继一氧化氮和一氧化碳后的第三种气体信号分子,日渐受到人们的关注,检测技术的发展为研究提供了帮助。H_2S在人体各系统中发挥着重要的作用,如心血管系统、神经系统、呼吸系统等,其与高血压、动脉粥样硬化、神经退行性疾病、哮喘等疾病的发生发展有着密切的联系,具有作为疾病治疗药物的潜能。对于H_2S作用于靶分子机制的阐述深化了小分子物质调控大分子功能的研究,提供了对多种疾病进行干预的新手段。     

Phaeodactylum tricornutum: An established model species for diatom molecular research and an emerging chassis for algal synthetic biology

Diatoms are prominent and highly diverse microalgae in aquatic environments. Compared with other diatom species, Phaeodactylum tricornutum is an “atypical diatom” displaying three different morphotypes and lacking the usual silica shell. Despite being of limited ecological relevance, its ease of growth in the laboratory and well-known physiology, alongside the steady increase in genome-enabled information coupled with effective tools for manipulating gene expression, have meant it has gained increased recognition as a powerful experimental model for molecular research on diatoms. We here present a brief overview of how over the last 25 years P. tricornutum has contributed to the unveiling of fundamental aspects of diatom biology, while also emerging as a new tool for algal process engineering and synthetic biology.     

结核分枝杆菌诊断技术研究进展

近年来,结核病的诊断方法逐渐得到完善,将传统细菌学检验方法、免疫学方法和分子生物学的方法相结合,加速了对结核病的诊断研究。特别是分子生物学技术的发展,对于阐明分枝杆菌和结核分枝杆菌的遗传变异规律及分子进化等都有重要的意义。我们结合近年来结核分枝杆菌诊断在免疫学检测、PCR技术、基因技术等方面的进步,从细菌学检测、免疫学检测、分子生物学检测等3个方面做简要综述。     

基于能力培养的分子生物学实验教学改革与探索

分子生物学技术已成为生命科学领域普遍运用的方法和手段,分子生物学实验课是一门让学生理解、掌握分子生物学技术的课程。系统总结了近年来我们以学生的能力培养为宗旨,在分子生物学实验教学中进行的建立“3＋1”的新课程体系、更新教学内容、尝试新的教学方法和手段、改革考核方式等探索,并就下一步改革进行了展望。     

Development of molecular biology at the University of Wisconsin, Madison

Dramatic changes in the foundation of academic departments in our universities are uncommon. With the demonstration that DNA was the cellular source of genetic information, and that this information could be regulated, the field of molecular biology was born. Later, when scientists found that they could tinker with this information, the field matured. In an unusually rapid manner, molecular biology was integrated into the University of Wisconsin, Madison, in the late 1950s and early 1960s. This present article is a chronology of how it happened. What are the factors that made this transition possible in the University of Wisconsin? What lessons have we learned from this experience?     

白蚁的分子生物学研究进展

白蚁是危险性社会昆虫,建立安全有效的白蚁防治方法有赖多学科的参与,分子生物学已经成为白蚁研究的重要工具。目前,DNA序列分析方法已应用于白蚁鉴定和分类,其中线粒体基因是最通用的分子标记;基因工程技术成功构建了可用于白蚁防治的白蚁肠道工程菌;Hexamerin、COX Ⅲ、纤维素酶等白蚁功能基因以及白蚁品级分化相关的若干蛋白相继得到了分离和鉴定。文章从白蚁分类、防治、功能基因、品级分化4个方面综述白蚁分子生物学的研究进展,为白蚁的防治提供新的方法和思路。     

蛋白质结构与功能研究中的分子模拟技术

分子模拟技术为蛋白质的研究提供了一种崭新的手段,在理论上解决了结构预测和功能分析以及蛋白质工程实施方面所面临的难题。它在蛋白质的结构预测和模建工作中占有举足轻重的地位,实现了生物技术与计算机技术的完美结合。本文简要阐述了该技术的基本步骤和工作原理,并以目前应用最广的生物大分子领域的商品化分子模拟软件Accelrys公司基于Linux系统开发的InsightII为例,介绍了相关程序模块的功能和作用,同时结合该技术在蛋白质的结构预测和模建、结构与功能关系分析、分子设计等过程中的开发与应用,加以具体说明和展望。     

Understanding the physical basis of memory: Molecular mechanisms of the engram

Memory, defined as the storage and use of learned information in the brain, is necessary to modulate behavior and critical for animals to adapt to their environments and survive. Despite being a cornerstone of brain function, questions surrounding the molecular and cellular mechanisms of how information is encoded, stored, and recalled remain largely unanswered. One widely held theory is that an engram is formed by a group of neurons that are active during learning, which undergoes biochemical and physical changes to store information in a stable state, and that are later reactivated during recall of the memory. In the past decade, the development of engram labeling methodologies has proven useful to investigate the biology of memory at the molecular and cellular levels. Engram technology allows the study of individual memories associated with particular experiences and their evolution over time, with enough experimental resolution to discriminate between different memory processes: learning (encoding), consolidation (the passage from short-term to long-term memories), and storage (the maintenance of memory in the brain). Here, we review the current understanding of memory formation at a molecular and cellular level by focusing on insights provided using engram technology.     

Synthetic biology of minimal systems

“Synthetic biology” is a concept that has developed together with, or slightly after, “systems biology”. But while systems biology aims at the full understanding of large systems by integrating more and more details into their models, synthetic biology phrases different questions, namely: what particular biological function could be obtained with a certain known subsystem of reduced complexity; can this function be manipulated or engineered in artificial environments or genetically modified organisms; and if so, how? The most prominent representation of synthetic biology has so far been microbial engineering by recombinant DNA technology, employing modular concepts known from information technology. However, there are an increasing number of biophysical groups who follow similar strategies of dissecting cellular processes and networks, trying to identify functional minimal modules that could then be combined in a bottom-up approach towards biology. These modules are so far not as particularly defined by their impact on DNA processing, but rather influenced by core fields of biophysics, such as cell mechanics and membrane dynamics. This review will give an overview of some classical and some quite new biophysical strategies for constructing minimal systems of certain cellular modules. We will show that with recent advances in understanding of cytoskeletal and membrane elements, the time might have come to experimentally challenge the concept of a minimal cell.     

应用分子定向进化技术适时检测及预防鳗鱼主要疾病的初步探讨

应用分子定向进化(directedmolecularevolution)技术研究和解决复杂的生物学和化学问题,已成为化学和生物学中最活跃的领域之一。针对目前鳗鱼主要疾病的检测及预防现状和出现的技术难点及不足,初步探讨了分子定向进化技术在这方面的应用及前景。