Light and electron microscopic immunohistochemical detection of bromodeoxyuridine-labeled cells in the brain: different fixation and processing protocols.

Bromodeoxyuridine (BrdU) immunohistochemistry is the method of choice for labeling newly generated cells in the brain. Most BrdU studies utilize paraformaldehyde-fixed brain tissue because of its compatibility with both BrdU and other immunohistochemical methods. However, stronger fixation is required for electron microscopic studies, and unfixed tissue is needed for biochemical and molecular studies. Because there are no systematic studies comparing the effects of different fixatives on BrdU immunohistochemistry in brain tissue, we compared BrdU immunohistochemical methods in brain tissue fixed with 4% paraformaldehyde, a mixed glutaraldehyde-paraformaldehyde fixative for electron microscopy, and unfixed tissue from brains perfused only with buffer and flash frozen. After optimizing immunostaining protocols, qualitative assessments of light microscopic diaminobenzidine labeling and of double-label immunofluorescence with confocal microscopy demonstrated excellent BrdU labeling in each of the three groups. Quantitative stereological assessment of the number of BrdU-labeled cells in rat dentate gyrus showed no significant difference in the number of labeled cells detected with each perfusion protocol. Additionally, we developed a protocol to visualize BrdU-labeled cells in the electron microscope with adequate preservation of fine structure in both rat and monkey brain.     

Structure of plasma membrane in radicles from cotton seeds

Summary Cortical cells in the apical region of excised radicles from cotton (Gossypium hirsutum L. var. M-8) seeds of differing moisture content (6, 12, or 16%) were examined in thin sections of vapor-fixed tissue and in freeze-etched replicas of unfixed tissue with transmission electron microscopy (TEM). The structure of the plasma membrane, as revealed in chemically-fixed tissue, had the tripartite feature characteristic of unit membranes. Regions of the plasma membrane appearing as discontinuities or breaks were shown by stereo tilting to represent an optical artifact caused by image superposition of curved regions of the plasma membrane contained within the thickness of a thin section. In freeze-etched preparations two complementary-type images of the plasma membrane were consistently observed. The asymmetric distribution of membrane-associated particles (MAPS) in the P and E fracture faces suggests that the structure of plasma membranes in cells of dry seeds resembles that of plasma membranes in germinating seeds. The physiological significance of these findings is that leaching of ions and small molecules during seed imbibition does not appear to involve passage through disorganized membranes in the radicle.     

Spreading of vascular endothelial cells in culture: Spatial reorganization of cytoplasmic fibers and organelles

The three-dimensional organization and fine structure of cytoplasmic components within whole non-embedded bovine aortic endothelial cells were examined during their attachment and spreading in tissue culture. Cells were cultured directly on Formvar-coated gold grids, fixed in glutaraldehyde and osmium tetroxide, critical point dried and examined by transmission electron microscopy (TEM) using stereoscopic methods, and by scanning electron microscopy (SEM). Reorganization of cytoplasmic structures during cell spreading occurred in four sequential stages: (1) spreading of the plasma membrane and unstructured cytoplasmic matrix; (2) spreading of cytoplasmic fiber systems (microtubules, microfilament bundles and microtrabecular system); (3) alignment of microfilament bundles and formation of radial tracts of microtubules; and (4) centripetal movement of organelles along radial tracts. These stages observed by TEM correlated with progressive degrees of cell flattening as visualized by SEM. These studies demonstrate that a characteristic reorganization of intracellular fiber systems and organelles accompanies the spreading of endothelial cells in culture.     

Processing tissue and cells for transmission electron microscopy in diagnostic pathology and research

In transmission electron microscopy (TEM), electrons are transmitted through a plastic-embedded specimen, and an image is formed. TEM enables the resolution and visualization of detail not apparent via light microscopy, even when combined with immunohistochemical analysis. Ultrastructural examination of tissues, cells and microorganisms plays a vital role in diagnostic pathology and biologic research. TEM is used to study the morphology of cells and their organelles, and in the identification and characterization of viruses, bacteria, protozoa and fungi. In this protocol, we present a TEM method for preparing specimens obtained in clinical or research settings, discussing the particular requirements for tissue and cell preparation and analysis, the need for rapid fixation and the possibility of analysis of tissue already fixed in formalin or processed into paraffin blocks. Details of fixation, embedding and how to prepare thin and semi-thin sections, which can be used for analysis complementary to that performed ultimately using TEM, are also described.     

High pressure freezing and freeze substitution reveal new aspects of fine structure and maintain protein antigenicity in barley aleurone cells

High pressure freezing and freeze substitution (HPF-FS) were used to prepare barley ( Hordeum vulgare L. cv Himalaya) aleurone protoplasts for transmission electron microscopy (TEM). We show that HPF-FS is superior to conventional chemical fixation and dehydration techniques for the preservation of cellular fine structure and antigenicity of proteins in barley aleurone protoplasts. HPF-FS extracted fewer proteins from the cytosol and organelles of aleurone protoplasts and maintained the details of cellular structure. The cortical cytoskeleton, made up of microtubules, was observed for the first time by TEM in barley aleurone protoplasts prepared by HPF-FS. Organelles such as protein storage vacuoles retained their proteinaceous contents, and other cellular organelles (including the Golgi apparatus, the nucleus and mitochondria) were also well preserved in protoplasts fixed by HPF-FS. Antibodies to the vacuolar enzyme nuclease I, the tonoplast aquaporin α-TIP and the glyoxysomal enzyme malate synthase showed that the antigenicity of organellar enzymes and membrane proteins was preserved in cells prepared by HPF-FS. We conclude that HPF-FS is superior to chemical fixation for the preparation of plant protoplasts for TEM and is the method of choice for the preservation of aleurone protoplasts for structural and immunochemical studies.     

Whole-cell-mount cytochemistry by the colloidal gold labeling method. Combined transmission and scanning electron microscopic study of ConA binding sites in mouse macrophages

Binding, redistribution, and endocytosis of colloidal gold (CG)-labeled concanavalin A (ConA) were studied by transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Mouse peritoneal macrophages were cultured on Formvar-coated platinum grids. Either fixed or unfixed cells were labeled by the indirect ConA-CG labeling method. Specimens were critical-point-dried and observed by TEM and SEM in the same region. Surface-bound ConA-CG was easily seen by SEM. Stereomicroscopic observation by TEM clearly showed the three-dimensional distribution of ConA on the cell surface as well as in the cytoplasmic vesicles and vacuoles. In the prefixed cells, CG was distributed randomly on the cell surface. When unfixed cells were labeled at 0 degree C, a similar binding pattern was observed, although the density of bound CG was decreased. When cells labeled with ConA-CG at 0 degree C were further incubated at 37 degrees C, redistribution and endocytosis of the label were seen. Endocytosed CG in the cytoplasmic vesicles and vacuoles was clearly seen by TEM. In addition, three-dimensional location and relationship with other organelles were easily observed. Combined TEM and SEM observation of CG-labeled whole-cell-mount specimens is a useful method to study the dynamics of cell-bound ligands.     

Whole-cell-mount cytochemistry by the colloidal gold labeling method

Summary Binding, redistribution, and endocytosis of colloidal gold (CG)-labeled concanavalin A (ConA) were studied by transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Mouse peritoneal macrophages were cultured on Formvar-coated platinum grids. Either fixed or unfixed cells were labeled by the indirect ConA-CG labeling method. Specimens were critical-pointdried and observed by TEM and SEM in the same region. Surface-bound ConA-CG was easily seen by SEM. Stereomicroscopic observation by TEM clearly showed the threedimensional distribution of ConA on the cell surface as well as in the cytoplasmic vesicles and vacuoles. In the prefixed cells, CG was distributed randomly on the cell surface. When unfixed cells were labeled at 0° C, a similar binding pattern was observed, although the density of bound CG was decreased. When cells labeled with ConA-CG at 0° C were further incubated at 37° C, redistribution and endocytosis of the label were seen. Endocytosed CG in the cytoplasmic vesicles and vacuoles was clearly seen by TEM. In addition, three-dimensional location and relationship with other organelles were easily observed. Combined TEM and SEM observation of CG-labeled whole-cell-mount specimens is a useful method to study the dynamics of cellbound ligands.This work was supported in part by grants-in-aid for scientific research from the Ministry of Education, Science, and Culture of Japan, and the Japan Private School Promotion Foundation     

Visualization of the nuclear lamina in mouse anterior pituitary cells and immunocytochemical detection of lamin A/C by quick-freeze freeze-substitution electron microscopy.

We examined the nuclear lamina in the quickly frozen anterior pituitary cells by electron microscopic techniques combined with freeze substitution, deep etching, and immunocytochemistry and compared it with that in the chemically fixed cells. By quick-freeze freeze-substitution electron microscopy, an electron-lucent layer, as thick as 20 nm, was revealed just inside the inner nuclear membrane, whereas in the conventionally glutaraldehyde-fixed cells the layer was not seen. By quick-freeze deep-etch electron microscopy, we could not distinguish definitively the layer corresponding to the nuclear lamina in either fresh unfixed or glutaraldehyde-fixed cells. Immunofluorescence microscopy showed that lamin A/C in the nucleus was detected in the acetone-fixed cells and briefly in paraformaldehyde-fixed cells but not in the cells with prolonged paraformaldehyde fixation. Nuclear localization of lamin A/C was revealed by immunogold electron microscopy also in the quickly frozen and freeze-substituted cells, but not in the paraformaldehyde-fixed cells. Lamin A/C was localized mainly in the peripheral nucleoplasm within 60 nm from the inner nuclear membrane, which corresponded to the nuclear lamina. These results suggest that the nuclear lamina can be preserved both ultrastructurally and immunocytochemically by quick-freezing fixation, rather than by conventional chemical fixation.     

Polarized light microscopy reveals physiological and drug-induced changes in surfactant membrane assembly in alveolar type II pneumocytes

In alveolar type II (AT II) cells, pulmonary surfactant (PS) is synthetized, stored and exocytosed from lamellar bodies (LBs), specialized large secretory organelles. By applying polarization microscopy (PM), we confirm a specific optical anisotropy of LBs, which indicates a liquid-crystalline mesophase of the stored surfactant phospholipids (PL) and an unusual case of a radiation-symmetric, spherocrystalline organelle. Evidence is shown that the degree of anisotropy is dependent on the amount of lipid layers and their degree of hydration, but unaffected by acutely modulating vital cell parameters like intravesicular pH or cellular energy supply. In contrast, physiological factors that perturb this structure include osmotic cell volume changes and LB exocytosis. In addition, we found two pharmaceuticals, Amiodarone and Ambroxol, both of which severely affect the liquid-crystalline order. Our study shows that PM is an easy, very sensitive, but foremost non-invasive and label-free method able to collect important structural information of PS assembly in live AT II cells which otherwise would be accessible by destructive or labor intense techniques only. This may open new approaches to dynamically investigate LB biosynthesis - the incorporation, folding and packing of lipid membranes - or the initiation of pathological states that manifest in altered LB structures. Due to the observed drug effects, we further suggest that PM provides an appropriate way to study unspecific drug interactions with alveolar cells and even drug-membrane interactions in general.     

The incubation of unfixed tissues for electron microscopic histochemistry

Summary Small tissue blocks of various organs of the rat were incubated for gradually increasing times in a neutral buffer-sucrose medium modelling the main parameters of the histochemical incubations. Following incubation the blocks were fixed in paraformaldehydeosmium and embedded in Durcupan. The electron microscopic study revealed that even after 40 minutes of incubation prior to fixation, fine structure is preserved satisfactorily from the histochemical point of view. With consideration to further advantages of such a proceeding, the incubation of unfixed tissue blocks for electron-histochemistry is recommended.     

The desmosome: Fine structural studies with freeze-fracture replication and tannic acid staining of sectioned epidermis

Desmosomes of larval and post-metamorphic newt epidermis have been studied by freeze-fracture replication both with and without prior glutaraldehyde fixation. Characteristic particles of a diameter (70-130 A) similar to that of typical membrane associated particles are found clustered on the exposed internal faces of adherent desmosomal membranes. They remain attached to the B-face in unfixed material, but occupy the desmosomal A-face after fixation. Membrane associated particles of nondesmosomal surfaces are found predominantly on the A-face in both fixed and unfixed epidermis. Suitably oriented replicas of unfixed desmosomes reveal profiles of apparent fine filaments extending from the region of tonofilament loops through the desmosomal plaque to traverse the cytoplasmic leaflet of the plasmalemma. They can be traced onto the B-face. Their position correlates to fine linear profiles noted in tannic acid/glutaraldehyde-fixed and sectioned desmosomes. The possibility that these represent a mechanism for anchorage of tonofilaments to the plaque and to the membrane is discussed. These and other fine structural features are compared and contrasted to the properties of hemidesmosomes described in the preceding report.     

Three dimensional fine structure of cultured cells: possible implications for subcellular motility.

To determine the three dimensional fine structure of whole motile cells, rat embryo cells, cultured on Formvar-coated cover-glasses, were glutaraldehyde/osmium-fixed, mounted on grids, dehydrated, critical point dried and examined by transmission electron microscopy using stereoscopic techniques. Three dimensional arrays of organelles occurred in a filament-rich cytoplasmic matrix. Here, besides microtubules and elongate filaments, inter-connected filaments formed a widespread fine-mesh space network which attached to the plasma membrane and closely surrounded all organelles. Negative staining revealed a similar newtork in unfixed cells. It is concluded that this network represents part of the force-generating mechanism for various subcellular movements.     

黄瓜种子萌发过程中Ca~(2 )分布的变化

采用细胞化学方法 ,研究了黄瓜种子中贮藏Ca2 的分布特点及其在萌发过程中的变化动态。干种子的子叶细胞中贮藏有大量的蛋白体、油脂体 ,Ca2 沉淀颗粒大量分布于胞质、胞间隙以及细胞质膜上。大多数蛋白体中有 1至数个圆球形或椭圆体形含Ca2 的球状晶体。相比之下 ,胚芽和胚根细胞中Ca2 较少。种子萌发早期 ,子叶中的贮藏钙及晶体溶解释放出的Ca2 部分转运到生长发育中的胚芽和胚根中。随着萌发的继续 ,胚根和胚芽细胞中的Ca2 不会持续增多 ,反而下降     

Studies on the Fine Structure of the Scutellum of the Oat Seed During Germination

Structural changes in the seutellar parenchyma and epithelial cells of oats during the first 3 days of germination were followed by electron microscopy. The seutellar parenchyma cells contain more protein bodies than the epithelial cells, otherwise the general fine structures of the two types of cells arc quite similar: When the seed starts to germinate the protein bodies change into vacuoles and the proteins inside the protein bodies gradually disappear. Spherosomes are in abundance ill the seutcllar cells of the dry seed. Few disappeared during germination. Other cellular organelles, such as the mitochondria, endoplasmie reticulum, plastids, Golgi apparatus and glyoxysomes are scarcely seen in the seutellar cells of the dry seed. They become more obvious and easily recognizable after germination. In the dry seed, the walls of the epithelial cell that abut the endospernl show a two layered structure, consisted of an inner and outer layer. The outer layer becomes hydrolysed during seed germination, but the inner layer remains intact. The scutetlar epithelial cells are known for their ability to secret enzymes ute and absorb nutrients from the endosperm. But in the fine structural studies we have not been able to locate any specific strurcture that could be related to their known functions of enzyme secretion and nutrient absorption.     

Freeze-substitution of dehydrated plant tissues: Artefacts of aqueous fixation revisited

Summary This investigation assessed the extent of rehydration of dehydrated plant tissues during aqueous fixation in comparison with the fine structure revealed by freeze-substitution. Radicles from desiccation-tolerant pea (Pisum sativum L.), desiccation-sensitive jackfruit seeds (Artocarpus heterophyllus Lamk.), and leaves of the resurrection plantEragrostis nindensis Ficalho & Hiern. were selected for their developmentally diverse characteristics. Following freeze-substitution, electron microscopy of dehydrated cells revealed variable wall infolding. Plasmalemmas had a trilaminar appearance and were continuous and closely appressed to cell walls, while the cytoplasm was compacted but ordered. Following aqueous fixation, separation of the plasmalemma and the cell wall, membrane vesiculation and distortion of cellular substructure were evident in all material studied. The sectional area enclosed by the cell wall in cortical cells of dehydrated pea and jackfruit radicles and mesophyll ofE. nindensis increased after aqueous fixation by 55, 20, and 30%, respectively. Separation of the plasmalemma and the cell wall was attributed to the characteristics of aqueous fixatives, which limited the expansion of the plasmalemma and cellular contents but not that of the cell wall. It is proposed that severed plasmodesmatal connections, plasmalemma discontinuities, and membrane vesiculation that frequently accompany separation of walls and protoplasm are artefacts of aqueous fixation and should not be interpreted as evidence of desiccation damage or membrane recycling. Evidence suggests that, unlike aqueous fixation, freeze-substitution facilitates reliable preservation of tissues in the dehydrated state and is therefore essential for ultrastructural studies of desiccation.Abbreviations LM light microscopy - TEM transmission electron microscopy - CF conventional (aqueous) fixation - FS freeze-substitution - ER endoplasmic reticulum     

Sensory organs in a cavernicolous insect after cryofixation without cryoprotectants: a comparative ultrastructural study

Three different sensory organs (one mechanoreceptor, one chemoreceptor and one chemo-mechanoreceptor) of the antennae of the cavernicolous Coleoptera Speonomus hydrophilus and S. zophosinus have been compared by means of electron microscopy after chemical fixation or cryofixation without cryoprotectant; when cryofixation succeeds, cells and organelles have a different appearance from the chemically fixed ones: they have rounded and smooth outlines and are more electron-dense; some very fine details, such as tubulinc sub-units of microtubules, are perceptible after cryofixation only. However, chemical fixation gives much more reproducible results than cryofixation; moreover, when good cryofixation is achieved preservation of cells and organelles is satisfactory only for the peripheral region; large ice-crystals more or less destroying the central zone, except the nerves. In short, chemical fixation and cryofixation appear as complementary techniques: chemical fixation must be used as a routine fixation and cryofixation when specially good cell and molecular preservation must be achieved for peripheral tissues only.     

Structure of the nucleoid in cells of Streptococcus faecalis

The structure of the nucleoid of Streptococcus faecalis (ATCC 9790) was examined and compared in the unfixed and fixed states by immersive refractometry and electron microscopy. It appears from these studies that the nucleoid structure is much more centralized in unfixed chloramphenicol-treated (stationary-phase) cells than it is in cells in the exponential phase of growth. The more dispersed configuration of the exponential-phase nucleoid could be preserved by fixation in glutaraldehyde, but not in Formalin or in osmium tetroxide. One important factor in explaining these differences in preservation is that glutaraldehyde (but not Formalin or osmium tetroxide) can rapidly cross-link the amino groups of macromolecules in cells. It was also observed that osmium tetroxide resulted in a preferential breakdown of nascent ribonucleic acid. These results are interpreted as indicating that glutaraldehyde is able to stabilize the exponential-phase nucleoid before it assumes the more central appearance seen in osmium tetroxide- and Formalin-fixed cells. These results are discussed in terms of the proposed organization of the exponential-phase nucleoid in unfixed cells.     

A fine structural study of microwave fixation of tissues

Microwave fixed liver and kidney tissues were examined by electron microscopy. It was found that the preservation of fine structure of these tissues by this method is equal to that processed by routine methods. No difficulty was encountered in sectioning microwave fixed tissue blocks. It is obvious that microwave fixation is a faster and more efficient method.     

The Fine Structure of some Dry Seed Tissues Observed after Completely Anhydrous Chemical Fixation

Completely anhydrous fixation with acrolein vapour or osmiumtetroxide vapour was applied to tissues of air-dry seeds: thecoleoptile of wheat (Trilicum aestivum), and plumule and radicleof mung bean (Vigna radiata). Great shrinkage of cells and organelleswas noted, but all the usual organelles could be identified,except for Golgi bodies and (in most cases) ribosomes. The endoplasmicreticulum was very abundant and endoplasmic reticulum tubuleswere closely associated with the storage organelles, namelylipid bodies in the wheat coleoptile, and protein bodies inthe mung bean embryo axis. Aqueous fixation resulted in considerabledistortion of cellular structure. Triticum aestivum L., wheat, Vigna radiata L., mung bean, seed, fine structure, anhydrous fixation     

Macrophages Sequester Clofazimine in an Intracellular Liquid Crystal-Like Supramolecular Organization

Clofazimine is a poorly-soluble but orally-bioavailable small molecule drug that massively accumulates in macrophages when administered over prolonged periods of time. To determine whether crystal-like drug inclusions (CLDIs) that form in subcellular spaces correspond to pure clofazimine crystals, macrophages of clofazimine-fed mice were elicited with an intraperitoneal thioglycollate injection. Inside these cells, CLDIs appeared uniform in size and shape, but were sensitive to illumination. Once removed from cells, CLDIs were unstable. Unlike pure clofazimine crystals, isolated CLDIs placed in distilled water burst into small birefringent globules, which aggregated into larger clusters. Also unlike pure clofazimine crystals, CLDIs fragmented when heated, and disintegrated in alkaline media. In contrast to all other organelles, CLDIs were relatively resistant to sonication and trypsin digestion, which facilitated their biochemical isolation. The powder x-ray diffraction pattern obtained from isolated CLDIs was consistent with the diffraction pattern of liquid crystals and inconsistent with the expected molecular diffraction pattern of solid, three dimensional crystals. Observed with the transmission electron microscope (TEM), CLDIs were bounded by an atypical double-layered membrane, approximately 20 nanometers thick. CLDIs were polymorphic, but generally exhibited an internal multilayered organization, comprised of stacks of membranes 5 to 15 nanometers thick. Deep-etch, freeze-fracture electron microscopy of unfixed snap-frozen tissue samples confirmed this supramolecular organization. These results suggest that clofazimine accumulates in macrophages by forming a membrane-bound, multilayered, liquid crystal-like, semi-synthetic cytoplasmic structure.