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.     

Sutural mineralization of rat calvaria characterized by atomic-force microscopy and transmission electron microscopy

The application of transmission electron microscopy (TEM) and atomic-force microscopy (AFM) aid the acquisition of detailed structural information on the process of hard tissue formation. The sutural mineralization of rat calvaria is taken as a model for a collagen-related mineralization system. After cryofixation or chemical fixation an anhydrous tissue preparation technique with no staining procedures is used. The atomic-force microscope and the transmission electron microscope are used for structural analysis of the mineralizing region of the sutural tissue. With the application of AFM the collagen macroperiod is shown to be well represented in the unmineralized sutural tissue. At the mineralization front the collagen fibrils are found to be thickened and to change to a characteristic stacked platelet structure. Using TEM the macroperiod is faintly visible before mineral crystallites have formed and is more prominent after the apatite crystallization has started in the fibrils. In this step a needle-like structure of the newly formed apatitic crystals is visible.     

Optimization of immunogold labeling TEM. An ELISA-based method for rapid and convenient simulation of processing conditions for quantitative detection of antigen.

We developed an ELISA-based method for rapid optimization of various tissue processing parameters in immunogold labeling for electron microscopy. The effects of aldehyde fixation, tannic acid, postfixation, dehydration, temperature, and antigen retrieval on antibody binding activity of Vitreoscilla hemoglobin (VHb) expressed in E. coli cells were assayed by ELISA and the results confirmed by quantitative immunogold labeling transmission electron microscopy (TEM). Our results demonstrated that low concentrations (0.2%) of glutaraldehyde fixation caused minimal loss in total binding compared to higher concentrations. Dehydration in up to 70% ethanol resulted in some distortion of cellular ultrastructure but better antibody binding activity compared to dehydration up to 100%. Postfixation or incorporation of tannic acid in the primary fixative caused almost total loss of activity, whereas antigen retrieval of osmium-postfixed material resulted in approximately 90-100% recovery. The sensitivity of detection of proteins by immunogold labeling electron microscopy depends on the retention of antibody binding activity during tissue processing steps, e.g., fixation and dehydration. Our study indicated that an ELISA-based screening method of various tissue processing procedures could help in rapid selection and optimization of a suitable protocol for immunogold localization and quantification of antigen by TEM.     

Acute ischemia causes 'dark cell' change of strial marginal cells in gerbil cochlea

The cochlear stria vascularis produces the endolymph and generates the endocochlear DC potential, two indispensable ingredients of an auditory transduction process. The marginal cell, one of the several cell types constituting the stria vascularis, is called 'the dark cell' on the basis of its appearance by transmission electron microscopy (TEM). To clarify whether this commonly observed 'dark appearance' is a normal characteristic of marginal cells, as conjectured in the literature, or an experimental artifact, we developed an in vivo fixation method for minimizing ischemic tissue damages. While under sustained systemic circulation with oxygenated blood, the stria vascularis of gerbils was chemically fixed by perilymphatic perfusion with a fixative, and the stria vascularis was observed by TEM. In contrast to a number of previous reports, the cytoplasm of marginal cells was not dark, and quantitative analysis showed that the difference between the cytoplasmic electron density of marginal cells and that of intermediate cells (another type of strial cells) was not statistically significant. For comparison, the gerbils were allowed to undergo 3 min of ischemia following decapitation. Under these conditions, marginal cells showed typical 'dark appearance', as reported previously, and their cytoplasmic electron density was 1.7 times higher than that of the intermediate cells. In addition, the volume of mitochondria in marginal cells undergoing 3 min of ischemia was higher than that fixed in vivo. We therefore conclude that the widely recognized 'dark cell' appearance of marginal cells following conventional fixation procedures reflects cell injury due to ischemia, which is inherent in the standard fixation procedures, but can be avoided by our fixation protocol here introduced.     

Viral detection by electron microscopy: past, present and future

Viruses are very small and most of them can be seen only by TEM (transmission electron microscopy). TEM has therefore made a major contribution to virology, including the discovery of many viruses, the diagnosis of various viral infections and fundamental investigations of virus-host cell interactions. However, TEM has gradually been replaced by more sensitive methods, such as the PCR. In research, new imaging techniques for fluorescence light microscopy have supplanted TEM, making it possible to study live cells and dynamic interactions between viruses and the cellular machinery. Nevertheless, TEM remains essential for certain aspects of virology. It is very useful for the initial identification of unknown viral agents in particular outbreaks, and is recommended by regulatory agencies for investigation of the viral safety of biological products and/or the cells used to produce them. In research, only TEM has a resolution sufficiently high for discrimination between aggregated viral proteins and structured viral particles. Recent examples of different viral assembly models illustrate the value of TEM for improving our understanding of virus-cell interactions.     

Fibronectin in the microvasculature: localization in the pericyte-endothelial interstitium

The pericytes of capillaries are interesting cells which resemble the smooth muscle cells of larger vessels in some aspects of their morphology and behavior. In this report, their relationship to the underlying endothelium has been investigated in some detail. Using indirect, fluorescent immunocytochemical techniques on fresh and fixed tissues, it was found that fibronectin (an adhesive protein in many tissue culture systems) is concentrated in spots along vessels and is only faintly visible in the basement membranes of exhaustively perfused preparations. By electron microscopy, using a peroxidase immunocytochemical marker, these concentrations of fibronectin were seen to be localized to the pericyte-endothelial interstitia. Examination by TEM using a new fixation procedure demonstrated the organization of microfilaments and dense plaques along the pericyte membrane with fibrous and basement membrane-like material within this interstitial space. The arrangements of these elements suggest a mechanical linkage between the two cells. Such a linkage would allow contractions or relaxation of the pericyte to affect vessel diameter.     

Transmission Electron Microscopy of Tissue Culture Preparations on Polystyrene Coverslips

Polystyrene coverslips have been utilized in preparing tissue cultures for transmission electron microscopy. A method is described for processing the coverslips, including the marking of selected groups of cells with epoxy-carbon mixture. The epoxy-carbon markings aid in locating the cells during sectioning and the method can be used for small or large numbers of cells. In addition, the methodology allows high power phase contrast photography before and after fixation.     

Cellular changes associated with rest and quiescence in winter-dormant vascular cambium of<Emphasis Type="Italic"> Pinus contorta</Emphasis>

In winter, dormant cambial cells contain many small vacuoles interspersed throughout the cytoplasm. This differs dramatically from actively growing cambial cells whose structure is dominated by large central vacuoles. Structure reported in studies using conventional chemical fixation and transmission electron microscopy (TEM) conflicts with that described earlier for live cambial cells using light microscopy. In this study, cryofixation (high-pressure freezing/freeze substitution) was used to preserve dormant Pinus contorta fusiform cambial cells, revealing structure more consistent with that in early micrographs of live cambial cells. At the ultrastructural level, the plasmalemma was consistently smooth and tightly associated with the cell wall, contrary to the highly in-folded plasmalemma seen in chemically fixed cambial cells. In addition, both TEM and live-cell confocal microscopy demonstrated that, in some places, dormant cells were partitioned into more numerous, smaller vacuoles than were observed after chemical fixation. Populations of different vacuoles were apparent based on size, shape and membrane staining. Larger vacuoles had prominent tonoplasts and were often present as axially elongated, interconnecting networks with associated microfilament bundles. Endoplasmic reticulum fragmented during rest into numerous vesicular structures similar to small vacuoles, then with the transition to quiescence reformed into the smooth cisternal form.     

Microwave assisted rapid diagnosis of plant virus diseases by transmission electron microscopy

Investigations of ultrastructural changes induced by viruses are often necessary to clearly identify viral diseases in plants. With conventional sample preparation for transmission electron microscopy (TEM) such investigations can take several days and are therefore not suited for a rapid diagnosis of plant virus diseases. Microwave fixation can be used to drastically reduce sample preparation time for TEM investigations with similar ultrastructural results as observed after conventionally sample preparation. Many different custom made microwave devices are currently available which can be used for the successful fixation and embedding of biological samples for TEM investigations. In this study we demonstrate on Tobacco Mosaic Virus (TMV) infected Nicotiana tabacum plants that it is possible to diagnose ultrastructural alterations in leaves in about half a day by using microwave assisted sample preparation for TEM. We have chosen to perform this study with a commercially available microwave device as it performs sample preparation almost fully automatically in contrast to the other available devices where many steps still have to be performed manually and are therefore more time and labor consuming. As sample preparation is performed fully automatically negative staining of viral particles in the sap of the remaining TMV-infected leaves and the following examination of ultrastructure and size can be performed during fixation and embedding.     

Phase-partition fixation and staining of Drosophila eggs.

Aqueous solutions of alcohol-acetic acid-formalin or glutaraldehyde-acrolein were shaken with heptane and heptane phase used for fixation. Phase-partition fixation is akin to fixation with vapor. The organic solvent, immiscible with water, penetrates hydrophobic membranes and carries the fixative in contact with water phase of the tissue. Only the fixative enters the tissue, without changing the ionic and water-soluble substance concentrations in the tissue. The quality of this fixation for optical or electron microscopy was as good as that of any conventional fixation method. Staining with basic fuchsin after 2 N HCl hydrolysis gave brilliant staining of nuclei, more intense than that with Feulgen reagent, while cytoplasm remained nearly colorless. Fixing and staining procedures for Drosophila eggs are given.     

Visualization of the nucleus and nuclear envelope in situ by SEM in tissue culture cells

Our previous work characterizing the biogenesis and structural integrity of the nuclear envelope and nuclear pore complexes (NPCs) has been based on amphibian material but has recently progressed into the analysis of tissue-culture cells. This protocol describes methods for the high resolution visualization, by field-emission scanning electron microscopy (FESEM), of the nucleus and associated structures in tissue culture cells. Imaging by fluorescence light microscopy shows general nuclear and NPC information at a resolution of approximately 200 nm, in contrast to the 3-5 nm resolution provided by FESEM or transmission electron microscopy (TEM), which generates detail at the macromolecular level. The protocols described here are applicable to all tissue culture cell lines tested to date (HeLa, A6, DLD, XTC and NIH 3T3). The processed cells can be stored long term under vacuum. The protocol can be completed in 5 d, including 3 d for cell growth, 1 d for processing and 1 d for imaging.     

Cryosectioning and immunolabeling

In this protocol, we describe cryoimmunolabeling methods for the subcellular localization of proteins and certain lipids. The methods start with chemical fixation of cells and tissue in formaldehyde (FA) and/or glutaraldehyde (GA), sometimes supplemented with acrolein. Cell and tissue blocks are then immersed in 2.3 M sucrose before freezing in liquid nitrogen. Thin cryosections, cut in an ultracryotome, can be single- or multiple immunolabeled with differently sized gold particles, contrasted and viewed in an electron microscope. Semi-thin cryosections can be used for immunofluorescence microscopy. We describe the detailed procedures that have been developed and tested in practice in our laboratory during the past decades.     

Extraction of extendable beaded structures and their identification as fibrillin-containing extracellular matrix microfibrils

High molecular weight aggregates were extracted from human amnion using buffers containing 6 M guanidine hydrochloride. Rotary shadowed preparations and negatively stained samples examined by electron microscopy showed that each aggregate appeared to be a string of globular structures joined by fine filaments, giving the appearance of beads on a string. The periodicity of the beads was variable. A mouse monoclonal antibody directed against a previously characterized pepsin fragment of fibrillin was used with gold-conjugated secondary antibody and immunoelectron microscopy to show that the aggregates contained fibrillin. Similar structures were found in non-denaturing homogenates of skin, tongue, ligament, ciliary zonule, cartilage, and vitreous humor. When immunogold-labeled beaded structures were prepared for electron microscopy in the same manner as tissue, the beaded structures could no longer be seen. Instead, gold-labeled microfibrils were found which appeared to be the same as the fibrillin-containing matrix microfibrils observed in connective tissues and often associated with elastin. Thus, standard TEM protocols including fixation, dehydration, and embedding alter the ultrastructural appearance of microfibrils as compared with negative stain or rotary shadowing techniques. When skin was stretched and prepared for electron microscopy while still under tension, beaded filaments were seen in the tissue sections, but were not visible in non-stretched controls. In addition, when stretched ligament was immunolabeled with antibody directed against fibrillin while still under tension, the periodicity of antibodies along the microfibrils increased compared with non-stretched controls. We propose that microfibrils contain globular structures connected by fine filaments composed at lease in part of highly ordered, periodically distributed fibrillin molecules, whose periodicity is subject to change dependent on the tensional forces applied to the tissue in which they are contained.     

Membrane specializations in flagellar ribbons of elasmobranch fish

Specialized epithelial cells lining the elasmobranch nephron bear numerous flagella which are organized into closely-packed, parallel rows forming ribbons (Lacy et al., 1989a). The compact arrangement of the adjacent flagella comprising each ribbon suggests they are structurally bound together, forming a single unit which functions to force urine along the nephric tubule. In the present study, the structural basis of the interflagellar connections was investigated by scanning electron microscopy (SEM) and by transmission electron microscopy (TEM) of thin sections and freeze fracture replicas. Various fixatives and histochemical stains were used to elucidate the structure and composition of the interflagellar adhesive material. SEM of the luminal cell surface showed the organization of the flagella in ribbons. In TEM, fixation in a solution containing glutaraldehyde and tannic acid, Ruthenium red or Alcian blue, or postfixation in reduced OsO(4) revealed that the plasma membrane of each flagellum of a ribbon was surrounded by a thin layer of surface coat composed of very short filaments more prominent at sites where adjacent flagella were in close apposition. In comparable locations, freeze-fracture replicas disclosed small aggregates or plaques of particles arranged in an irregular, discontinuous line on both faces P and E of the flagellar membrane. In areas where the flagella were not arranged into ribbons (most frequently after immersion fixation), the surface coat was thick and expanded and, in replicas, the intramembranous particles were randomly scattered. All of these plasma membrane specializations appear to function in binding adjacent flagella and thus facilitate a coordinated flagellar ribbon beat.     

Numbers of myosatellite cells in white axial muscle of growing fish: Cyprinus carpio L. (Teleostei).

By means of transmission electron microscopy (TEM), the percentage of myosatellite cells was shown to decrease from about 6% in carp of 5 cm standard length (SL) to less than 1% in carp larger than 18 cm SL. The ratio between muscle nuclei and non muscle nuclei remained constant. These TEM data, combined with data on the amount of DNA per gram of muscle tissue and per nucleus, were used to calculate the numbers of myosatellite cells per gram of tissue (TEM-DNA method). Total numbers of myosatellite cells could be calculated from the TEM-DNA data and the calculated amounts of muscle tissue per fish. After a slight initial increase, the total number of myosatellite cells in the white axial muscle of a carp appears to be rather constant during the growth phase of the fish. But the myosatellite cells become more and more diluted over an increasing number of myonuclei with age. In addition, the reliability of two new light microscopic methods for the determination of numbers of myosatellite cells was examined. The percentages of myosatellite cells were determined by counting the numbers of total nuclei and of heterochromatic nuclei situated inside the muscle fibers' basal laminae which were stained using an antibody against laminin. These percentages were not significantly different from those determined with TEM. The yield of myosatellite cells per gram of muscle tissue, isolated with a previously developed dissociation method, showed a direct relation to the number of myosatellite cells calculated to be present in the tissue (TEM-DNA method), but at a 1% level. Both methods are alternative ways to determine numbers of myosatellite cells when it is impossible or difficult to use TEM (e.g., large sample sizes, combination with immunohistochemical methods).     

A Standardized Method for the Analysis of Liver Sinusoidal Endothelial Cells and Their Fenestrations by Scanning Electron Microscopy

Liver sinusoidal endothelial cells are the gateway to the liver, their transcellular fenestrations allow the unimpeded transfer of small and dissolved substances from the blood into the liver parenchyma for metabolism and processing. Fenestrations are dynamic structures - both their size and/or number can be altered in response to various physiological states, drugs, and disease, making them an important target for modulation. An understanding of how LSEC morphology is influenced by various disease, toxic, and physiological states and how these changes impact on liver function requires accurate measurement of the size and number of fenestrations. In this paper, we describe scanning electron microscopy fixation and processing techniques used in our laboratory to ensure reproducible specimen preparation and accurate interpretation. The methods include perfusion fixation, secondary fixation and dehydration, preparation for the scanning electron microscope and analysis. Finally, we provide a step by step method for standardized image analysis which will benefit all researchers in the field.     

VIS2FIX: a high-speed fixation method for immuno-electron microscopy

Immuno-transmission electron microscopy (TEM) is the technique of choice for high-resolution localization of proteins in fixed specimen. Here we introduce 2 novel methods for the fixation of sections from cryo-immobilized samples that result in excellent ultrastructural preservation. These high-speed fixation techniques, both called VIS2FIX, allow for a reduction in sample preparation time from at least 1 week to only 8 h. The methods were validated in immuno-TEM experiments on THP-1 monocytes, human umbilical vein endothelial cells (HUVECs) and Madin-Darby canine kidney (MDCK-II) cells. The fixation and retention of neutral lipids is demonstrated, offering unique prospects for the application of immuno-TEM in the lipidomics field. Furthermore, the VIS2FIX methods were successfully employed in correlative fluorescence and electron microscopy.     

A histological comparison of phase-partition fixation with fixation in aqueous solutions

In phase-partition fixation, tissue is immersed in a non-aqueous solvent at equilibrium with an aqueous solution of a fixing agent to minimize osmotic effects. Preservation of morphology afforded by phase-partition fixation using formalin and glutaraldehyde and several organic solvents was compared to aqueous 10% neutral buffered formalin fixation for five tissues. It was shown that phase-partition fixation can provide excellent fixation for light microscopy if the proper combinations of fixatives and solvents are used.     

Methods for the determination of adipose cell size in man and animals

Four methods for the sizing of adipose cells in small samples of human or animal adipose tissue are compared. These methods depend on the preparation of cell suspensions by incubation of the tissue with collagenase or by prolonged fixation with osmium tetroxide and separation of the fixed cells. A Coulter electronic counter was used to count and size the suspended cells and a Zeiss particle size analyzer for the sizing of cells in photomicrographs. The use of the Coulter counter to count cells in a suspension derived from a known amount of tissue and subjected to osmium tetroxide fixation is recommended for accuracy and general applicability to adipose cells of all sizes in man and animals.     

Sample preparation of animal tissues and cell cultures for secondary ion mass spectrometry (SIMS) microscopy.

Sample preparation is a critical step in the elemental analysis of animal tissues and cell cultures with ion microscopy. Since live cells cannot be analyzed with ion microscopy, a careful sample fixation is necessary which preserves the native structural and chemical integrity of a specimen. The evaluation of morphological and chemical integrity of a fixed specimen is necessary before any physiological explanation of ion fluxes is interpreted based on ion microscopy. For diffusible ion localization studies, strict cryogenic procedures are recommended. Examples are shown for diffusible ion microanalysis in frozen-freeze-dried tissues and cell cultures. Ion microscopy studies of tightly bound elements/molecules may be conducted in chemically fixed and/or plastic embedded specimens. Since it is not generally known which elements/molecules are tightly bound to the tissue matrix, a confirmation of elemental distribution with cryogenic procedures is desirable. A recent approach of combining laser scanning confocal fluorescence microscopy and ion microscopy on the same frozen freeze-dried cell is also discussed for recognizing smaller cytoplasmic structures in ion microscopy images.