光电关联显微镜技术及其在植物学研究中的应用

光电关联显微镜技术(correlative light and electron microscopy,CLEM)将光学显微镜的高灵敏度和大视场与电子显微镜的高分辨率相结合,弥补了各自成像的局限,可在原位获得更全面、更精细的定位及结构信息,近年来受到广泛关注.目前,该技术广泛应用于亚细胞结构与特定结构的观察、蛋白质的精...     

Low-Cost Cryo-Light Microscopy Stage Fabrication for Correlated Light/Electron Microscopy

The coupling of cryo-light microscopy (cryo-LM) and cryo-electron microscopy (cryo-EM) poses a number of advantages for understanding cellular dynamics and ultrastructure. First, cells can be imaged in a near native environment for both techniques. Second, due to the vitrification process, samples are preserved by rapid physical immobilization rather than slow chemical fixation. Third, imaging the same sample with both cryo-LM and cryo-EM provides correlation of data from a single cell, rather than a comparison of "representative samples". While these benefits are well known from prior studies, the widespread use of correlative cryo-LM and cryo-EM remains limited due to the expense and complexity of buying or building a suitable cryogenic light microscopy stage. Here we demonstrate the assembly, and use of an inexpensive cryogenic stage that can be fabricated in any lab for less than $40 with parts found at local hardware and grocery stores. This cryo-LM stage is designed for use with reflected light microscopes that are fitted with long working distance air objectives. For correlative cryo-LM and cryo-EM studies, we adapt the use of carbon coated standard 3-mm cryo-EM grids as specimen supports. After adsorbing the sample to the grid, previously established protocols for vitrifying the sample and transferring/handling the grid are followed to permit multi-technique imaging. As a result, this setup allows any laboratory with a reflected light microscope to have access to direct correlative imaging of frozen hydrated samples.     

A Variant of A Slam Freezing Device for Electron Microscopy

A home-made slam freezing device is presented that allows reproducible results in freezing various unfixed tissues. The heart of the device is an aluminium socket, which harbors a plunger that is set in motion by a spring. At the end of the plunger there is an electromagnet which holds the sample on a sheet metal planchette. During stop freezing the electrical contacts are interrupted and the plunger can be withdrawn leaving the specimen on the cooled copper block. This guarantees freezing of not only solid tissues, but also cell suspensions, such as blood or bone marrow.     

Multilayer Mounting for Long-term Light Sheet Microscopy of Zebrafish

Light sheet microscopy is the ideal imaging technique to study zebrafish embryonic development. Due to minimal photo-toxicity and bleaching, it is particularly suited for long-term time-lapse imaging over many hours up to several days. However, an appropriate sample mounting strategy is needed that offers both confinement and normal development of the sample. Multilayer mounting, a new embedding technique using low-concentration agarose in optically clear tubes, now overcomes this limitation and unleashes the full potential of light sheet microscopy for real-time developmental biology.     

斑马鱼胚胎显微注射基因分析平台的建立

斑马鱼作为一种新的理想模式动物,已在发育生物学、环境毒理学和人类疾病及相关基因功能等研究中得到广泛应用。本文就建立斑马鱼胚胎的显微注射基因分析平台进行了探究,并通过piwil2基因的抑制和过表达实验验证了平台的可操作性,也对建立平台中所要注意的问题进行了讨论。     

A Method of Fixing Rat Testis for Light and Electron Microscopy

To overcome the difficulty of obtaining compact slices or pieces of tissue from the rat testis, due to the scarcity of interstitial tissue, the fixation of the testis is started in the live anesthetized animal by injecting 3% glutaraldehyde in 0.1 M cacodylate buffer at pH 7.2 under the albuginea; within a few minutes this causes sufficient hardening of the testis tissue to enable one to cut neat slices from it with a razor blade. Fixation is completed with the usual immersion method. The fixed tissue may then be processed for either light or electron microscopy. Preservation of structural detail is comparable to that obtained with perfusion-fixation. The main advantages of the method are speed and simplicity, which may be very important when dealing simultaneously with several animals.     

Polystyrene Embedding: A New Method for Light and Electron Microscopy

Polystyrene embedments of histological specimens can be Obtained with a solution 1 : 4 polystyrene-toluene, 5% benzyl alcohol and 1% dibutyl phthalate, allowing the solvent to evaporate in polyethylene containers for 2-3 days at 58 C. The resulting blocks are easily cut into truncated pyramids, each containing a piece of tissue. which are then glued to a Plexiglas support Drying is completed at 80 C for 20 hr. The pyramids can then be sectioned to produce thick sections, with a steel knife or to produce semi- or ultrathin sections with a glass knife. A 10% paraldehyde solution is used to mount the light microscopy dons on a slide heated on a hot plate to 80 C; those can be treated with the same techniques used with paraffin sections. The results are of high quality. Semithin sections of tissues fired for electron microscopy can be stained directly after mounting, or by a wider range of stains once the polystyrene has been removed by organic solvents. In electron-microscopy, the ultrathin sections obtained with the usual techniques are highly electron beam-resistant and give acceptable results.     

Advanced Correlative Light/Electron Microscopy: Current Methods and New Developments Using Tokuyasu Cryosections

Microscopy is an essential tool for analysis of cellular structures and function. With the advent of new fluorescent probes and super-resolution light microscopy techniques, the study of dynamic processes in living cells has been greatly facilitated. Fluorescence light microscopy provides analytical, quantitative, and three-dimensional (3D) data with emphasis on analysis of live cells using fluorescent markers. Sample preparation is easy and relatively inexpensive, and the use of appropriate tags provides the ability to track specific proteins of interest. Of course, only electron microscopy (EM) achieves the highest definition in terms of ultrastructure and protein labeling. To fill the gap between light microscopy and EM, correlative light and electron microscopy (CLEM) strategies have been developed. In particular, hybrid techniques based upon immuno-EM provide sensitive protein detection combined with high-resolution information on cell structures and protein localization. By adding the third dimension to EM with electron tomography (ET) combined with rapid freezing, CLEM techniques now provide additional tools for quantitative 3D analysis. Here, we overview the major methods applied and highlight the latest advances in the field of CLEM. We then focus on two selected techniques that use cryosections as substrate for combined biomolecular imaging. Finally, we provide a perspective of future developments in the field. (J Histochem Cytochem 57:1103–1112, 2009)     

A Quick Embedding Method for Light and Electron Microscopy of Textile Fibers

A quick embedding method employing UV polymerization reactions has been devised for embedding fibers in acrylic and meth-acrylate media. The resultant thin, flat embed-dings are suitable for both light and electron microscopy.     

A Quick Embedding Method for Light and Electron Microscopy of Textile Fibers

A quick embedding method employing UV polymerization reactions has been devised for embedding fibers in acrylic and meth-acrylate media. The resultant thin, flat embed-dings are suitable for both light and electron microscopy.     

A New Method for Studying Human Oocytes by Light and Electron Microscopy

Since ovarian follicles appear to be randomly oriented with respect to the plane of the section, the method of sectioning and examining follicles at their raimm diameter described here allows direct comparison between oocyte populations of women and small differences can be detected. Re-sectioning for EM allows selected follicles of interest to be examined at a higher resolution.     

Immuno‐ and Correlative Light Microscopy‐Electron Tomography Methods for 3D Protein Localization in Yeast

Compartmentalization of eukaryotic cells is created and maintained through membrane rearrangements that include membrane transport and organelle biogenesis. Three‐dimensional reconstructions with nanoscale resolution in combination with protein localization are essential for an accurate molecular dissection of these processes. The yeast Saccharomyces cerevisiae is a key model system for identifying genes and characterizing pathways essential for the organization of cellular ultrastructures. Electron microscopy studies of yeast, however, have been hampered by the presence of a cell wall that obstructs penetration of resins and cryoprotectants, and by the protein dense cytoplasm, which obscures the membrane details. Here we present an immuno‐electron tomography (IET) method, which allows the determination of protein distribution patterns on reconstructed organelles from yeast. In addition, we extend this IET approach into a correlative light microscopy‐electron tomography procedure where structures positive for a specific protein localized through a fluorescent signal are resolved in 3D. These new investigative tools for yeast will help to advance our understanding of the endomembrane system organization in eukaryotic cells.      

An Embedding Method for Monolayer Cell Cultures for Light and Electron Microscopy

Plastic containers are widely used for monolayer cell culture. In situ embedding, the obvious method of choice for subsequent ultrastructural study, has been achieved by Brinkley et al. (1967) using Epon as a final embedding medium and water soluble acrylates as intermediates. Although the results are satisfactory, the method has two drawbacks: firstly, the water soluble acrylates are difficult to get, and secondly, removal of the plastic container is possible only with blocks already cut off for electron microscopy.     

A Method for the Examination of the Same Cell Using Light, Scanning and Transmission Electron Microscopy

A method is described for preparing the same cell from a cytospin preparation for comparative investigation by light microscopy, scanning electron microscopy and transmission electron microscopy. A permanent numbered grid pattern was etched on a glass microscope slide to facilitate cell location in each microscopic mode. Data from one cell or group of cells was thus obtained from three sources. This method provides a useful adjunct to routine cytological diagnosis.     

Noninvasive Imaging of Ethanol‐Induced Developmental Defects in Zebrafish Embryos Using Optical Coherence Tomography

In this article, we report the use of optical coherence tomography for noninvasive cross‐sectional real‐time imaging of ethanol‐induced developmental defects in zebrafish embryos larvae. For ethanol concentration of over 300 mM, developmental defects of eye (shrinkage and retinal abnormalities), malformation of the notochord and ataxia arising due to the toxic effects of ethanol were observed in OCT images from 3 days post fertilization onwards. The results suggest that OCT could be a valuable tool for noninvasive assessment of birth defects in small animal systems.     

Use of Atomic Force Microscopy and Transmission Electron Microscopy for Correlative Studies of Bacterial Capsules

Bacteria can possess an outermost assembly of polysaccharide molecules, a capsule, which is attached to their cell wall. We have used two complementary, high-resolution microscopy techniques, atomic force microscopy (AFM) and transmission electron microscopy (TEM), to study bacterial capsules of four different gram-negative bacterial strains: Escherichia coli K30, Pseudomonas aeruginosa FRD1, Shewanella oneidensis MR-4, and Geobacter sulfurreducens PCA. TEM analysis of bacterial cells using different preparative techniques (whole-cell mounts, conventional embeddings, and freeze-substitution) revealed capsules for some but not all of the strains. In contrast, the use of AFM allowed the unambiguous identification of the presence of capsules on all strains used in the present study, including those that were shown by TEM to be not encapsulated. In addition, the use of AFM phase imaging allowed the visualization of the bacterial cell within the capsule, with a depth sensitivity that decreased with increasing tapping frequency.     

Embedding Plant Tissue with Plastic Using High Pressure: A New Method for Light and Electron Microscopy

An embedding technique has been developed to overcome difficulties that confront light and electron microscopists working with so-called “hard-to-embed” plant tissue. The method was originally described for freeze-dried material. It uses a modified Quickfit Rotaflo Valve and low heat to generate high pressure to aid in the infiltration and embedding of tissue with propylene oxide and plastic. The technique is not too cumbersome and requires 6 days from the dehydration step to the end of the polymerization process. Thick sections (1-2 μm) obtained from material prepared by this method stain readily with toluidine blue, and thin sections for the electron microscope stain satisfactorily following standard treatment with uranyl acetate and lead citrate. The thin sections are stable under the beam of the electron microscope. Results indicate that the quality of tissue preservation with this high pressure embedding technique is as good as that observed using standard embedding methods for electron microscopy.     

Resins for Combined Light and Electron Microscopy: A Half Century of Development

The last fifty years have seen enormous improvements in the way biological specimens are prepared for microscopy. The Fifties produced the essential groundwork upon which many of our current methodologies are based. Acrylic resin embedding was introduced in 1949, with subsequent publications seeking improvements to resin formulations, embedding protocols, and modes of polymerisation. Procedures for progressive lowering of temperature processing, cryosubstitution, freeze-drying and polymerisation by ultra-violet light at low temperatures, all had their genesis in this decade of great innovation. The Sixties marked the period when the acrylics were eclipsed by the more stable and reliable epoxy resins, and much of our present-day understanding of ultrastructure was elucidated. The Seventies carried on this work with advances in technical developments concerned mainly with freezing methodologies. The beginning of the Eighties saw a resurrection of the acrylic resins, with new formulations of these resins giving reliable and stable embeddings. The low temperature and freezing methodologies pioneered in the Fifties, backed up by recent improvements to low temperature technologies, were used to further our understanding of ultrastructure and breathe new life into the science of immunocytochemistry. The remainder of the Eighties and Nineties has seen the ever increasing application of these various microscopical techniques to a wide range of biological studies. The flexibility offered by the acrylic resins in choosing between different processing, embedding and polymerisation methods has provided the impetus for detailed studies to bring to the attention of microscopists the underlying trends governing specimen preparation. Therefore, looking forward to the new Millennium, this has allowed for a more reasoned choice in organising a strategy to deal with a variety of microscopical requirements and for planning an appropriate protocol.     

Isolation and Embedding of Single Nerve Cells for Electron Microscopy

Individual neurons have been isolated by freehand dissection under binocular, 40-100 power magnification from the lateral vestibular nucleus of fresh rabbit brain. The cells were fixed with glutaraldehyde and OsO₄ and dehydrated in 33%, 50%, 60% (v/v) and pure Durcupan A prior to embedding in Araldite 502. Blocks were cast in lids of BEEM capsules. The locating of the individually embedded cells and trimming of the blocks were facilitated by means of a holder that permitted visualization in both diffuse transmitted and incident light.