“电子显微学与结构生物学”系列讲座（一）

生物电子显微学是结构生物学的重要分支,主要包括电子晶体学（electron crystallography）、单颗粒技术（single particle technique）,电子断层成像技术（electron tomography）,以及冷冻电镜技术（cryo-EM）,适于从分子到细胞各个结构层次的三维结构研究,与X-射线晶体学和核磁共振谱学一道,是结构生物学的重要研究手段。本次研讨会旨在分析该领域国际发展趋势,促进国内合作研究,整合国内资源,加强人才培养。     

单颗粒电子显微学的研究进展

单颗粒电子显微学是一种新型的结构生物学技术和方法,一方面,其解析生物大分子复合体结构的分辨率日益提高,可以达到近原子分辨率,提供大蛋白分子或复合体的精细结构;另一方面,还可以解析生物大分子在不同功能状态下的结构及变化,对于揭示生物大分子复合体结构的作用机理具有重要作用。本文就单颗粒电子显微学的研究进展作一综述。     

三维电子显微学自动化数据采集的进展

生物三维电子显微学在过去几年取得了巨大的突破,一些具有高对称性的病毒颗粒获得了准原子分辨率的结构,非对称性的生物大分子及其复合体的结构分辨率也有快速的提高。而要获得高分辨率的结构,获取足够多的高质量电子显微照片是其中的一个关键因素。近年来,自动化数据采集技术在电子断层成像术和单颗粒方法中都取得了很大的进展。其广泛应用将使结构测定更加快速并使结构分辨率提高到更高的层次。     

封面故事

<正>电子显微镜三维重构技术近年来有了飞速的发展,已逐渐成为研究生物大分子复合体三维结构的重要手段。电子晶体学、单颗粒三维重构技术和电子断层技术是电子显微     

生物高分辨电子显微学进展

生物高分辨电子显微学是近年来发展起来的一种可与X射线晶体学相媲美的测定生物大分子高分辨结构的方法．它克服了一些限制X射线晶体学应用的困难,可以直接对非晶体状态的生物大分子或仅能形成二维晶体的蛋白进行结构测定．这一技术主要包括高分辨电子显微象的获得与电子显微象解析．文章就这一技术应用中的一些问题：自然结构的保持、辐射损伤、低衬度、低信噪比等进行了讨论．     

冷冻电镜单颗粒三维重构密度掩模的自动生成方法研究

冷冻电镜单颗粒三维重构技术是用来解析生物大分子三维结构的常用方法.然而目前在单颗粒三维重构过程中,溶剂平滑操作还存在一定缺陷:没有一款主流的单颗粒三维重构程序能够自动寻找掩模(mask)三维密度图,使得三维重构过程难免受到噪音统计学模型计算偏差的干扰.为解决这一问题,本研究借鉴X射线晶体学中解析优化相位所广泛采用的溶剂平滑方法,采用高斯滤波、坎尼边缘检测、最小误差阈值处理等方法处理重构所得三维密度图,优化溶剂平滑操作,发展在单颗粒三维重构过程中自动寻找mask三维密度图的方法.运用三维密度图傅里叶壳层相关系数(fourier shell correlation,FSC)曲线图、模拟颗粒数据重构角度误差散点图等指标评估此方法的效果.结果表明,自动寻找mask密度图的方法能够较好地找到涵盖分子结构信号区域的mask密度图,较为明显提高三维重构所得密度图分辨率.     

科学出版社新书

病毒的电子显微学技术张景强著主要介绍研究病毒的各种电子显微学方法以及最新进展和取得的成果,内容包括:病毒样品的超薄切片技术,病毒的分离、纯化和病毒样颗粒的组装,病毒免疫电镜技术,生物材料的高分辨率电子显微技术,冷冻电镜单颗粒技术和冷冻电镜电子断层成像技术等。理论介绍尽量做到浅显易懂,书中示例也取自经典的或者最近几年的科研成果。此外,在绪论中简     

冷冻电子断层成像技术及其在生物研究领域的应用

冷冻电子断层成像可以在纳米级尺度上研究那些结构不具有均一性的分子、病毒、细胞器以及它们之间组成的复合体的三维结构。在过去的十年中,电子显微镜硬件、冷冻制样设备和技术,以及自动化断层数据收集方法的进步使得本研究领域得到快速发展。本文对冷冻电子断层成像的方法,包括基本原理、样品制备、断层数据采集和图像处理、三维重构以及重建信息的理解和展示、近年来在生物样品领域的一些典型应用以及前景作一简单介绍。     

低温电子显微技术在膜蛋白结构研究中的应用和展望

介绍了蛋白质电子晶体学和单颗粒分析技术这两种低温电子显微技术在膜蛋白和膜蛋白复合体结构研究中的具体方法和近10~20年来的实际应用,并分别分析了这两种方法的优势和瓶颈。此外,还介绍了Amphipol替代、Streptavidin二维晶体锚定脂质体和纳米球包被脂质体等近两年来出现的新的用于低温电镜成像的膜蛋白样品制备方法。最后对膜蛋白的低温电子显微研究的未来发展做了展望。     

冷冻电子显微学在结构生物学研究中的现状与展望

冷冻电子显微学近年来在电子显微镜的硬件设备及结构解析的软件算法等方面取得了多个重要的技术突破,正在成为结构生物学研究的重要技术手段,为越来越多的生物学研究者所重视.冷冻电子显微学的技术特点决定了它所具备的一些独特优势和发展方向,同时作为一个正在迅速发展的科学技术领域,需要多学科的交叉促进.本文主要介绍冷冻电子显微学的研究现状及面临的技术挑战,并提出未来可能实现结构生物学与细胞生物学不同尺度的研究在冷冻电子显微学技术上融合的新方法.     

Use of cryo-negative staining in tomographic reconstruction of biological objects: application to T4 bacteriophage

Recent advances in electron microscopy and image analysis techniques have resulted in the development of tomography, which makes possible the study of structures neither accessible to X-ray crystallography nor nuclear magnetic resonance. However, the use of tomography to study biological structures, ranging from 100 to 500 nm, requires developments in sample preparation and image analysis. Indeed, cryo-electron tomography present two major drawbacks: the low contrast of recorded images and the sample radiation damage. In the present work we have tested, on T4 bacteriophage samples, the use of a new preparation technique, cryo-negative staining, which reduces the radiation damage while preserving a high signal-to-noise ratio. Our results demonstrate that the combination of cryo-negative staining in tomography with standard cryo-microscopy and single particle analysis results in a methodological approach that could be useful in the study of biological structures ranging in the T4 bacteriophage size.     

Toward visualization of nanomachines in their native cellular environment

The cellular nanocosm is made up of numerous types of macromolecular complexes or biological nanomachines. These form functional modules that are organized into complex subcellular networks. Information on the ultra-structure of these nanomachines has mainly been obtained by analyzing isolated structures, using imaging techniques such as X-ray crystallography, NMR, or single particle electron microscopy (EM). Yet there is a strong need to image biological complexes in a native state and within a cellular environment, in order to gain a better understanding of their functions. Emerging methods in EM are now making this goal reachable. Cryo-electron tomography bypasses the need for conventional fixatives, dehydration and stains, so that a close-to-native environment is retained. As this technique is approaching macromolecular resolution, it is possible to create maps of individual macromolecular complexes. X-ray and NMR data can be ‘docked’ or fitted into the lower resolution particle density maps to create a macromolecular atlas of the cell under normal and pathological conditions. The majority of cells, however, are too thick to be imaged in an intact state and therefore methods such as ‘high pressure freezing’ with ‘freeze-substitution followed by room temperature plastic sectioning’ or ‘cryo-sectioning of unperturbed vitreous fully hydrated samples’ have been introduced for electron tomography. Here, we review methodological considerations for visualizing nanomachines in a close-to-physiological, cellular context. EM is in a renaissance, and further innovations and training in this field should be fully supported. Robert Feulgen Lecture 2009 presented at the 51st symposium of the Society for Histochemistry in Stubai, Austria, October 7–10, 2009.     

Structural physiology based on electron crystallography

There are many questions in brain science, which are extremely interesting but very difficult to answer. For example, how do education and other experiences during human development influence the ability and personality of the adult? The molecular mechanisms underlying such phenomena are still totally unclear. However, technological and instrumental advancements of electron microscopy have facilitated comprehension of the structures of biological components, cells, and organelles. Electron crystallography is especially good for studying the structure and function of membrane proteins, which are key molecules of signal transduction in neural and other cells. Electron crystallography is now an established technique to analyze the structures of membrane proteins in lipid bilayers, which are close to their natural biological environment. By utilizing cryo-electron microscopes with helium cooled specimen stages, which were developed through a personal motivation to understand functions of neural systems from a structural point of view, structures of membrane proteins were analyzed at a resolution higher than 3 Å. This review has four objectives. First, it is intended to introduce the new research field of structural physiology. Second, it introduces some of the personal struggles, which were involved in developing the cryo-electron microscope. Third, it discusses some of the technology for the structural analysis of membrane proteins based on cryo-electron microscopy. Finally, it reviews structural and functional analyses of membrane proteins.     

Watching the components of photosynthetic bacterial membranes and their in situ organisation by atomic force microscopy

The atomic force microscope has developed into a powerful tool in structural biology allowing information to be acquired at submolecular resolution on the protruding structures of membrane proteins. It is now a complementary technique to X-ray crystallography and electron microscopy for structure determination of individual membrane proteins after extraction, purification and reconstitution into lipid bilayers. Moving on from the structures of individual components of biological membranes, atomic force microscopy has recently been demonstrated to be a unique tool to identify in situ the individual components of multi-protein assemblies and to study the supramolecular architecture of these components allowing the efficient performance of a complex biological function.Here, recent atomic force microscopy studies of native membranes of different photosynthetic bacteria with different polypeptide contents are reviewed. Technology, advantages, feasibilities, restrictions and limits of atomic force microscopy for the acquisition of highly resolved images of up to 10 Å lateral resolution under native conditions are discussed. From a biological point of view, the new insights contributed by the images are analysed and discussed in the context of the strongly debated organisation of the interconnected network of membrane-associated chlorophyll-protein complexes composing the photosynthetic apparatus in different species of purple bacteria.     

Combining X-ray crystallography and electron microscopy

The combination of cryo-electron microscopy to study large biological assemblies at low resolution with crystallography to determine near atomic structures of assembly fragments is quickly expanding the horizon of structural biology. This technique can be used to advantage in the study of large structures that cannot be crystallized, to follow dynamic processes, and to "purify" samples by visual selection of particles. Factors affecting the quality of cryo-electron microscopy maps and limits of accuracy in fitting known structural fragments are discussed.     

Molecular architecture of bacteriophage T4

In studying bacteriophage T4—one of the basic models of molecular biology for several decades—there has come a Renaissance, and this virus is now actively used as object of structural biology. The structures of six proteins of the phage particle have recently been determined at atomic resolution by X-ray crystallography. Three-dimensional reconstruction of the infection device—one of the most complex multiprotein components—has been developed on the basis of cryo-electron microscopy images. The further study of bacteriophage T4 structure will allow a better understanding of the regulation of protein folding, assembly of biological structures, and also mechanisms of functioning of the complex biological molecular machines.Translated from Biokhimiya, Vol. 69, No. 11, 2004, pp. 1463–1476.Original Russian Text Copyright © 2004 by Mesyanzhinov, Leiman, Kostyuchenko, Kurochkina, Miroshnikov, Sykilinda, Shneider.     

Imaging of organelles by electron microscopy reveals protein-protein interactions in mitochondria and chloroplasts

Ongoing progress in electron microscopy (EM) offers now an opening to visualize cells at the nanoscale by cryo-electron tomography (ET). Large protein complexes can be resolved at near-atomic resolution by single particle averaging. Some examples from mitochondria and chloroplasts illustrate the possibilities with an emphasis on the membrane organization. Cryo-ET performed on non-chemically fixed, unstained, ice-embedded material can visualize specific large membrane protein complexes. In combination with averaging methods, 3D structures were calculated of mitochondrial ATP synthase at 6 nm resolution and of chloroplast photosystem II at 3.5 nm.     

Difficult macromolecular structures determined using X-ray diffraction techniques

Macromolecular crystallography has been, for the last few decades, the main source of structural information of biological macromolecular systems and it is one of the most powerful techniques for the analysis of enzyme mechanisms and macromolecular interactions at the atomic level. In addition, it is also an extremely powerful tool for drug design. Recent technological and methodological developments in macromolecular X-ray crystallography have allowed solving structures that until recently were considered difficult or even impossible, such as structures at atomic or subatomic resolution or large macromolecular complexes and assemblies at low resolution. These developments have also helped to solve the 3D-structure of macromolecules from twin crystals. Recently, this technique complemented with cryo-electron microscopy and neutron crystallography has provided the structure of large macromolecular machines with great precision allowing understanding of the mechanisms of their function.     

Crystal Structures of Limulus SAP-Like Pentraxin Reveal Two Molecular Aggregations

The serum-amyloid-P-component-like pentraxin from Limulus polyphemus, a recently discovered pentraxin species and important effector protein of the hemolymph immune system, displays two distinct doubly stacked cyclic molecular aggregations, heptameric and octameric. The refined three-dimensional structures determined by X-ray crystallography, both based on the same cDNA sequence, show that each aggregate is constructed from a similar dimer of protomers, which is repeated to make up the ring structure. The native octameric form has been refined at a resolution of 3 Å, the native heptameric form at 2.3 Å, and the phosphoethanolamine (PE)-bound octameric form at 2.7 Å. The existence of the hitherto undescribed heptameric form was confirmed by single-particle analysis using cryo-electron microscopy. In the native structures, the calcium-binding site is similar to that in human pentraxins, with two calcium ions bound in each subunit. Upon binding PE, however, each subunit binds a third calcium ion, with all three calcium ions contributing to the binding and orientation of the bound phosphate group within the ligand-binding pocket. While the phosphate is well-defined in the electron density, the ethanolamine group is poorly defined, suggesting structural and binding variabilities of this group. Although sequence homology with human serum amyloid P component is relatively low, structural homology is high, with very similar overall folds and a common affinity for PE. This is due, in part, to a “topological” equivalence of side-chain position. Identical side chains that are important in both function and fold, from different regions of the sequence in human and Limulus structures, occupy similar space within the overall subunit fold. Sequence and structure alignment, based on the refined three-dimensional structures presented here and the known horseshoe crab pentraxin sequences, suggest that adaptation and refinement of C-reactive-protein-mediated immune responses in these ancient creatures lacking antibody-based immunity are based on adaptation by gene duplication.