Interference Microscopy in Cell Biophysics. 2. Visualization of Individual Cells and Energy-Transducing Organelles

The coherent phase microscopy (CPM) provides a convenient and non-invasive tool for imaging cells and intracellular organelles. In this article, we consider the applications of the CPM method to imaging different cells and energy-transducing intracellular organelles (mitochondria and chloroplasts). Experimental data presented below demonstrate that the optical path length difference of the object, which is the basic optical parameter measured by the CPM method, can serve as an indicator of metabolic states of different biological objects at cellular and subcellular levels of structural organization.     

Interference Microscopy in Cell Biophysics. 1. Principles and Methodological Aspects of Coherent Phase Microscopy

The coherent phase microscopy (CPM) provides a convenient and non-invasive tool for imaging cells and intracellular organelles. In this article, we consider the applications of the CPM method to imaging different cells and energy-transducing intracellular organelles (mitochondria and chloroplasts). Experimental data presented below demonstrate that the optical path length difference of the object, which is the basic optical parameter measured by the CPM method, can serve as an indicator of metabolic states of different biological objects at cellular and subcellular levels of structural organization.     

Quantitative 3-D imaging of eukaryotic cells using soft X-ray tomography

Imaging has long been one of the principal techniques used in biological and biomedical research. Indeed, the field of cell biology grew out of the first electron microscopy images of organelles in a cell. Since this landmark event, much work has been carried out to image and classify the organelles in eukaryotic cells using electron microscopy. Fluorescently labeled organelles can now be tracked in live cells, and recently, powerful light microscope techniques have pushed the limit of optical resolution to image single molecules. In this paper, we describe the use of soft X-ray tomography, a new tool for quantitative imaging of organelle structure and distribution in whole, fully hydrated eukaryotic Schizosaccharomyces pombe cells. In addition to imaging intact cells, soft X-ray tomography has the advantage of not requiring the use of any staining or fixation protocols—cells are simply transferred from their growth environment to a sample holder and immediately cryofixed. In this way the cells can be imaged in a near native state. Soft X-ray tomography is also capable of imaging relatively large numbers of cells in a short period of time, and is therefore a technique that has the potential to produce information on organelle morphology from statistically significant numbers of cells.     

Characterizing Organelles in Live Stem Cells Using Label-Free Optical Diffraction Tomography

Label-free optical diffraction tomography (ODT), an imaging technology that does not require fluorescent labeling or other pre-processing, can overcome the limitations of conventional cell imaging technologies, such as fluorescence and electron microscopy. In this study, we used ODT to characterize the cellular organelles of three different stem cells—namely, human liver derived stem cell, human umbilical cord matrix derived mesenchymal stem cell, and human induced pluripotent stem cell—based on their refractive index and volume of organelles. The physical property of each stem cell was compared with that of fibroblast. Based on our findings, the characteristic physical properties of specific stem cells can be quantitatively distinguished based on their refractive index and volume of cellular organelles. Altogether, the method employed herein could aid in the distinction of living stem cells from normal cells without the use of fluorescence or specific biomarkers.     

TISSUE PREPARATION AND FINE STRUCTURE OF THE RADICLE APEX FROM COTTON SEEDS

A comparative methodological study was made of the fine structure of apical cortical cells in excised radicles from cotton (Gossypium hirsutum L. var M-8) seeds. Radicles from dry seed had 12% moisture content and were prepared for electron microscopy using several different techniques. These included different methods of chemical fixation or freeze-fracture and etching of unfixed tissue for transmission electron microscopy (TEM) and cryofracturing of fixed and dehydrated radicles for scanning electron microscopy (SEM). Cortical cells had a similar appearance regardless of the method used in tissue preparation. Cell walls had a pronounced waviness which was particularly evident in SEM images of cells lining the elongated intercellular air spaces. The plasma membrane (PM) delimited the cytoplasm of each cell as an intact unit membrane. Single layers of tightly-packed lipid bodies (LB) were apposed to the PM and protein bodies (PB). Distension of cells, membranous organelles and LB was observed in radicles fixed by immersion in aqueous solutions, suggesting that a certain amount of hydration occurred during fixation. This interpretation was supported by the compact appearance of cells and organelles in tissue prepared by freeze-etch or vapor fixation. We conclude that freeze-fracture and etching of unfixed tissue provided the best information for cell morphology and structure of membranes and organelles in dry tissue. Complementary data on the fine details of nuclei and cytoplasmic organelles were best observed with TEM of fixed tissue. These data when viewed collectively indicate the advantage of using several techniques to obtain analogous and complementary information essential for establishing a baseline level of information on the fine structure of cells in dry tissue.     

基于抗坏血酸过氧化酶的电镜成像和活细胞邻近标记方法的应用进展

Alice Ting实验室开发的抗坏血酸过氧化物酶(engineered ascorbate peroxidase,APEX),相对于经典的辣根过氧化物酶(horse radish peroxidase,HRP),其酶活性不再受细胞内蛋白质定位的影响,可以在几乎所有的亚细胞区域保持活性,这使其在研究亚细胞尺度以及活细胞水平生物学问题时极具优势.目前,基于APEX的二氨基联苯胺(diaminobenzidine,DAB)染色标记技术已经成功地实现对全细胞、亚细胞器和蛋白质水平的电镜成像.同时,与质谱技术结合,基于APEX的活细胞生物素邻近标记方法也极大地推动了亚细胞器蛋白质组学,以及目标蛋白在特定时空条件下邻近蛋白质组学的研究发展.本文将从以上两个方面阐述APEX技术的基本原理及最新应用进展,并讨论和展望其在实际应用中存在的局限性和挑战.     

基于受激发射损耗显微术的活细胞和活体超分辨成像

细胞作为生命体基本的结构和功能单元，在生物、医学等领域有着非常重要的研究意义。随着现代科学和技术的发展，科学家们借助电镜对细胞以及细胞器的空间结构已经有非常清晰的认识，但是对它们的功能以及细胞之间的相互作用却了解得非常少，而这恰恰又是疾病治疗和药物开发亟需了解的信息，因此对离体活细胞（简称活细胞）和活体生物组织细胞（简称活体细胞）中亚细胞器的研究变得非常重要。然而细胞中许多细胞器的结构在纳米量级，传统的光学成像技术由于受到光学衍射极限的限制是无法观察到纳米量级的生物结构，因此光学超分辨成像技术是目前研究亚细胞器结构和功能的有效工具。在所有光学超分辨显微技术中，受激发射损耗显微术（stimulated emission depletionmicroscopy,STED）由于具有实时成像、三维超分辨和断层成像的能力，非常适合用于纳米尺度的活细胞和活体细胞成像研究，而且STED超分辨成像技术经过近几十年的发展，已经广泛用于活细胞甚至活体小鼠细胞的超分辨动态观测。本文总结了近年来活细胞和活体小鼠神经元细胞等领域STED超分辨成像的研究进展，介绍了用于活细胞和活体细胞STED超分辨成像的荧光染料...     

有机荧光团及荧光标记细胞的阴极荧光成像研究

目的 阴极荧光（CL）成像是一种以电子束为激发源的高分辨荧光成像技术,但生物材料对电子束的敏感性限制了CL技术在生命科学中的广泛应用。为了研究和发展CL技术在生物样品中的应用,本文旨在通过探究电子辐照引起碳基材料的结构损伤、有机基团的降解及荧光猝灭等问题,深入理解电子源对有机荧光团的激发特性。方法 本研究应用扫描电镜（SEM）和阴极荧光谱仪系统（SEM-CL）,研究电子源对有机荧光团及荧光探针标记细胞的激发特性,观测了有机物的CL信号的发射特性、强度衰减、成像方式及特点。结果 实验结果显示,在低能量（2.5～5 keV）和低束流（～10 pA）电子辐照下,有机荧光微珠发射出较强的荧光,CL像分辨率达到～30 nm。荧光微珠经过12 min辐照,信号强度衰减了25%,CL像仍保持了可接受的发光强度和足够的信噪比。此外,还获得了从细胞表面到内部一定深度内,荧光标记的亚细胞结构信息。结论 在SEM-CL系统中,可以同时获得由电子束激发产生的电子像和CL像,实现阴极荧光与电子显微镜关联（CCLEM）成像。本实验的研究结果为CCLEM技术应用于生物结构研究提供了数据及技术支持。     

Intracellular Localized Surface Plasmonic Sensing for Subcellular Diagnosis

This paper proposes a method for diagnosing intracellular conditions and organelles of cells with localized surface plasmonic resonance (LSPR) by directly internalizing the gold nanoparticles (AuNPs) into the cells and measuring their plasmonic properties through hyperspectral imaging. This technique will be useful for direct diagnosis of cellular organelles, which have potential for cellular biology, proteomics, pharmaceuticals, drug discovery etc. Furthermore, localization and characterization of citrate-capped gold nanoparticles in HeLa cells were studied, by hyperspectral microscopy and other imaging techniques. Here, we present the method of internalizing the gold nanoparticles into the cells and subcellular organelles to facilitate subcellular plasmonic measurements. An advanced label-free visualization technique, namely hyperspectral microscopy providing images and spectral data simultaneously, was used to confirm the internalization of gold nanoparticles and to reveal their optical properties for possible intracellular plasmonic detection. Hyperspectral technology has proved to be effective in the analysis of the spectral profile of gold nanoparticles, internalized under different conditions. Using this relatively novel technique, it is possible to study the plasmonic properties of particles, localized in different parts of the cell. The position of the plasmon bands reflects the interactions of gold nanoparticles with different subcellular systems, including particle-nucleus interactions. Our results revealed the effect of the different intracellular interactions on the aggregation pattern of gold nanoparticles, inside the cells. This novel technique opens the door to intracellular plasmonics, an entirely new field, with important potential applications in life sciences. Similarly, the characterization of AuNP inside the cell was validated using traditional methods such as light microscopy and scanning electron microscopy. Under the conditions studied in this work, gold nanoparticles were found to be non-toxic to HeLa (cervical cancer) cells.     

Advantages of intermediate X-ray energies in Zernike phase contrast X-ray microscopy

Understanding the hierarchical organizations of molecules and organelles within the interior of large eukaryotic cells is a challenge of fundamental interest in cell biology. Light microscopy is a powerful tool for observations of the dynamics of live cells, its resolution attainable is limited and insufficient. While electron microscopy can produce images with astonishing resolution and clarity of ultra-thin (< 1 μm thick) sections of biological specimens, many questions involve the three-dimensional organization of a cell or the interconnectivity of cells. X-ray microscopy offers superior imaging resolution compared to light microscopy, and unique capability of nondestructive three-dimensional imaging of hydrated unstained biological cells, complementary to existing light and electron microscopy.     

电子断层成像技术及其在细胞生物学中的应用

电子断层成像技术（electrontomography）是近年来发展起来一项三维成像技术,可以在纳米分辨率（2-10nm）水平上获得生物大分子及其复合物或聚集体、细胞器、细胞以及组织的三维结构,而且可以用于研究生物大分子在细胞中的定位、排列、分布以及相互作用,已逐渐成为细胞生物学领域中的一项重要技术手段。该文针对这项技术及其在细胞生物学中的应用作一简要介绍。     

Leukocyte lipid bodies: inflammation-related organelles are rapidly detected by wet scanning electron microscopy

Leukocyte lipid bodies are dynamic, functionally active organelles with central roles in inflammation. Here, we report that leukocyte lipid bodies are facilely detected by a versatile, potent technique, termed wet scanning electron microscopy (SEM), which combines the rapid preparation of light microscopy with the resolution of SEM. Using as leukocyte models resting and agonist-stimulated human eosinophils, cells that generate prominent numbers of lipid bodies in inflammatory conditions, we demonstrated that lipid bodies can be rapidly imaged as bright, highly contrasted structures under wet SEM and scored by computerized image processing. Critical advantages of this approach are that it permits cell observation in a fully hydrated system and facilitates lipid preservation. These attributes are especially important because lipid bodies are degraded during routine dehydration processes. Moreover, this technology is advantageous over lipophilic fluorescent probes because it allows sustained detection of lipid bodies in contrast to short-lived fluorescent labeling of these organelles. The value of wet SEM in enabling rapid and large-scale lipid body imaging and scoring within leukocytes is particularly important because lipid bodies are organelles underlying the heightened functions of inflammatory cells. Wet SEM technology provides new approaches and opportunities for delineations of lipid bodies in inflammatory diseases, including allergic inflammation.     

Coherent phase microscopy in cell biology: visualization of metabolic states

Visualization of functional properties of individual cells and intracellular organelles still remains an experimental challenge in cell biology. The coherent phase microscopy (CPM) provides a convenient and non-invasive tool for imaging cells and intracellular organelles. In this work, we report results of statistical analysis of CPM images of cyanobacterial cells (Synechocystis sp. PCC 6803) and spores (Bacillus licheniformis). It has been shown that CPM images of cyanobacterial cells and spores are sensitive to variations of their metabolic states. We found a correlation between one of optical parameters of the CPM image ('phase thicknesses' Deltah) and cell energization. It was demonstrated that the phase thickness Deltah decreased after cell treatment with the uncoupler CCCP or inhibitors of electron transport (KCN or DCMU). Statistical analysis of distributions of parameter Deltah and cell diameter d demonstrated that a decrease in the phase thickness Deltah could not be attributed entirely to a decrease in geometrical sizes of cells. This finding demonstrates that the CPM technique may be a convenient tool for fast and non-invasive diagnosis of metabolic states of individual cells and intracellular organelles.     

A procedure to deposit fiducial markers on vitreous cryo-sections for cellular tomography

We describe a novel approach for the accurate alignment of images in electron tomography of vitreous cryo-sections. Quantum dots, suspended in organic solvents at cryo-temperatures, are applied directly onto the sections and are subsequently used as fiducial markers to align the tilt series. Data collection can be performed from different regions of the vitreous sections, even when the sections touch the grid only at a few places. We present high-resolution tomograms of some organelles in cryo-sections of human skin cells using this method. The average error in image alignment was about 1nm and the resolution was estimated to be 5-7nm. Thus, the use of section-attached quantum dots as fiducial markers in electron tomography of vitreous cryo-sections facilitates high-resolution in situ 3D imaging of organelles and macromolecular complexes in their native hydrated state.     

Extended-resolution imaging of the interaction of lipid droplets and mitochondria

Physical contacts between organelles play a pivotal role in intracellular trafficking of metabolites. Monitoring organelle interactions in living cells using fluorescence microscopy is a powerful approach to functionally assess these cellular processes. However, detailed target acquisition is typically limited due to light diffraction. Furthermore, subcellular compartments such as lipid droplets and mitochondria are highly dynamic and show significant subcellular movement. Thus, high-speed acquisition of these organelles with extended-resolution is appreciated. Here, we present an imaging informatics pipeline enabling spatial and time-resolved analysis of the dynamics and interactions of fluorescently labeled lipid droplets and mitochondria in a fibroblast cell line. The imaging concept is based on multispectral confocal laser scanning microscopy and includes high-speed resonant scanning for fast spatial acquisition of organelles. Extended-resolution is achieved by the recording of images at minimized pinhole size and by post-processing of generated data using a computational image restoration method. Computation of inter-organelle contacts is performed on basis of segmented spatial image data. We show limitations of the image restoration and segmentation part of the imaging informatics pipeline. Since both image processing methods are implemented in other related methodologies, our findings will help to identify artifacts and the false-interpretation of obtained morphometric data. As a proof-of-principle, we studied how lipid load and overexpression of PLIN5, considered to be involved in the tethering of LDs and mitochondria, affects organelle association.     

Correlative microXRF and optical immunofluorescence microscopy of adherent cells labeled with ultrasmall gold particles

Synchrotron-based X-ray fluorescence microscopy (microXRF) is a powerful tool to study the two-dimensional distribution of a wide range of biologically relevant elements in tissues and cells. By growing mouse fibroblast cells directly on formvar-carbon coated electron microscopy grids, microXRF elemental maps with well-defined subcellular resolution were obtained. In order to colocalize the elemental distribution with the location of specific cellular structures and organelles, we explored the application of a commercially available secondary antibody conjugated to FluoroNanogold, a dual-label that combines a regular organic fluorophore with a 1.4 nm Au-cluster as xenobiotic label for microXRF imaging. Adherent mouse fibroblast cells were grown on silicon nitride windows serving as biocompatible XRF support substrate, and labeled with FluoroNanogold in combination with primary antibodies specific for mitochondria or the Golgi apparatus, respectively. Raster scanning of the in-air dried cells with an incident X-ray energy of 11.95 keV, sufficient to ensure excitation of the Au Lalpha line, provided two-dimensional maps with submicron resolution for Au as well as for most biologically relevant elements. MicroXRF proved to be sufficiently sensitive to image the location and structural details of the Au-labeled organelles, which correlated well with the subcellular distribution visualized by means of optical fluorescence microscopy.     

Apoptosis in tumour cells photosensitized with Rose Bengal acetate is induced by multiple organelle photodamage

Rose Bengal (RB) is a very efficient photosensitizer which undergoes inactivation of its photophysical and photochemical properties upon addition of a quencher group—i.e. acetate—to the xanthene rings. The resulting RB acetate (RB-Ac) derivative behaves as a fluorogenic substrate: it easily enters the cells where the native photoactive molecule is restored by esterase activities. It is known that the viability of RB-Ac-loaded cells is strongly reduced by light irradiation, attesting to the formation of intracellular RB. The aim of this study was to identify the organelles photodamaged by the intracellularly formed RB. RB-Ac preloaded rat C6 glioma cells and human HeLa cells were irradiated at 530 nm. Fluorescence confocal imaging and colocalization with specific dyes showed that the restored RB molecules redistribute dynamically through the cytoplasm, with the achievement of a dynamic equilibrium at 30 min after the administration, in the cell systems used; this accounted for a generalized damage to several organelles and cell structures (i.e. the endoplasmic reticulum, the Golgi apparatus, the mitochondria, and the cytoskeleton). The multiple organelle damage, furthermore, led preferentially to apoptosis as demonstrated by light and electron microscopy and by dual-fluorescence staining with FITC-labelled annexin V and propidium iodide.     

Bridging fluorescence microscopy and electron microscopy

Development of new fluorescent probes and fluorescence microscopes has led to new ways to study cell biology. With the emergence of specialized microscopy units at most universities and research centers, the use of these techniques is well within reach for a broad research community. A major breakthrough in fluorescence microscopy in biology is the ability to follow specific targets on or in living cells, revealing dynamic localization and/or function of target molecules. One of the inherent limitations of fluorescence microscopy is the resolution. Several efforts are undertaken to overcome this limit. The traditional and most well-known way to achieve higher resolution imaging is by electron microscopy. Moreover, electron microscopy reveals organelles, membranes, macromolecules, and thus aids in the understanding of cellular complexity and localization of molecules of interest in relation to other structures. With the new probe development, a solid bridge between fluorescence microscopy and electron microscopy is being built, even leading to correlative imaging. This connection provides several benefits, both scientifically as well as practically. Here, I summarize recent developments in bridging microscopy.     

Microscopy Image Browser: A Platform for Segmentation and Analysis of Multidimensional Datasets

Understanding the structure–function relationship of cells and organelles in their natural context requires multidimensional imaging. As techniques for multimodal 3-D imaging have become more accessible, effective processing, visualization, and analysis of large datasets are posing a bottleneck for the workflow. Here, we present a new software package for high-performance segmentation and image processing of multidimensional datasets that improves and facilitates the full utilization and quantitative analysis of acquired data, which is freely available from a dedicated website. The open-source environment enables modification and insertion of new plug-ins to customize the program for specific needs. We provide practical examples of program features used for processing, segmentation and analysis of light and electron microscopy datasets, and detailed tutorials to enable users to rapidly and thoroughly learn how to use the program.     

Field emission scanning electron microscopy of plant cells

Summary Two basic specimen preparation protocols that allow field emission scanning electron microscope imaging of intracellular structures in a wide range of plants are described. Both protocols depend on freeze fracturing to reveal areas of interest and selective removal of cytosol. Removal of cytosol was achieved either by macerating fixed tissues in a dilute solution of osmium tetroxide after freeze fracturing or by permeabilizing the membranes in saponin before fixation and subsequent freeze fracturing. Images of a variety of intracellular structures including all the main organelles as well as cytoskeletal components are presented. The permeabilization protocol can be combined with immunogold labelling to identify specific components such as microtubules. High-resolution three-dimensional imaging was combined with immunogold labelling of microtubules and actin cables in cell-free systems. This approach should be especially valuable for the study of dynamic cellular processes (such as cytoplasmic streaming) in live cells when used in conjunction with modern fluorescence microscopical techniques.Abbreviations DMSO dimethylsulfoxide - FESEM field emission scanning electron microscope (-scopy) - MTSB microtubule-stabilizing buffer - PBS phosphate-buffered saline - SEM scanning electron microscope (-scopy) - TEM transmission electron microscope (-scopy)