Microwaves and tea: new tools to process plant tissue for transmission electron microscopy

Optimizing sample processing, reducing the duration of the preparation of specimen, and adjusting procedures to adhere to new health and safety regulations, are the current challenges of plant electron microscopists. To address these issues, plant processing protocols for TEM, combining the use of polyphenolic compounds as substitute for uranyl acetate with microwave technology are being developed. In the present work, we optimized microwave-assisted processing of different types of plant tissue for ultrastuctural and immunocytochemical studies. We also explored Oolong tea extract as alternative for uranyl acetate for the staining of plant samples. We obtained excellent preservation of cell ultrastructure when samples were embedded in epoxy resin, and of cell antigenicity, when embedded in LR-White resin. Furthermore, Oolong tea extract successfully replaced uranyl acetate as a counterstain on ultrathin sections, and for in block staining. These novel protocols reduce the time spent at the bench, and improve safety conditions for the investigator. The preservation of the cell components when following these approaches is of high quality. Altogether, they offer significant simplification of the procedures required for electron microscopy of plant ultrastructure.     

Chloroplast ultrastructure in leaves of Urtica dioica L. analyzed after high-pressure freezing and freeze-substitution and compared with conventional fixation followed by room temperature dehydration

In this article, we report on the adaptation of high-pressure freezing and freeze-substitution (HPF-FS) for ultrastructural analysis of leaf tissue with special emphasis on chloroplasts. To replace the gas in the intercellular spaces, a mixture of water and methanol (MeOH) was employed. We compared three different supplements for FS--osmiumtetroxide, uranyl acetate, and safranin--with regard to the preservation of the ultrastructure of chloroplasts and other cellular compartments. The results show that (i) replacement of air within intercellular spaces by 8% (v/v) MeOH has no influence on the ultrastructure of the chloroplasts, (ii) undulation of membranes frequently observed after conventional preparation of specimens does not occur during chemical fixation but during room temperature dehydration, and (iii) uranyl acetate or osmium tetroxide employed during FS are not superior over safranin.     

Processing and characterization of canine mixed mammary tumor using transmission electron microscopy

Canine mammary gland tumors represent the second most frequent type of neoplasm in dogs, being an important problem within veterinary medical field. Canine mixed mammary tumors are the most common; the use of a transmission electron microscope (TEM) can contribute as a tool in its diagnosis by determining the characteristics of cellular components from numerous neoplasms. The aim of this study was to characterize cytologically canine mammary mixed tumor by the use of the TEM. A biopsy collected from an 11 years old bitch Shih‐Tzu and analyzed by histopathology was used for ultrastructural analysis. Specimens obtained were double stained using uranyl acetate and lead citrate prior to observation in the TEM. The protocol established to transmission electron microscopy observation allowed the identification of main cellular characteristics of canine mixed mammary tumors; however, it was not possible a detailed visualization of the organelles due to the preservation of the biopsy in formaldehyde.     

Factors which influence light microscopic visualization of biological material in sections prepared for electron microscopy

Epoxy-embedded biological material, sectioned for conventional or high-voltage electron microscopy, can be visualized within the section with good contrast and detail by phase-contrast or dark-field light microscopy. The (phase) contrast of such material is not substantially influenced by the type of embedding resin or section support substrate. It is, however, influenced by the type of fixation, by heavy metal (uranyl and lead) staining and by the section thickness. After screening ultrathin and semithin sections for content with the light microscope, one need stain and examine only those grids containing sections of interest. This approach eliminates the need to screen sections with the electron microscope and, in some cases, the need to stain non-useful sections. This time-saving procedure is particularly useful for studies requiring ultrastructural examination of a selected area or structure which is large enough to be visualized with the light microscope but which comprises only a small volume of the embedded material.     

A double lead stain method for enhancing contrast of ultrathin sections in electron microscopy: a modified multiple staining technique

A modification of the conventional method for the staining of ultrathin sections resulted in an increase in contrast of ultrastructural detail in tissues. Tissues embedded in Spurr's low viscosity embedding medium were stained with freshly centrifuged Reynolds' lead citrate for 1–5 min, rinsed in double distilled water and dried prior to staining with a saturated solution of uranyl acetate for 40 min, and freshly centrifuged Reynolds' lead citrate for 20 min. Sections treated by this procedure showed enhanced staining of cellular organelles and cytoplasmic matrix. This procedure is recommended for tissues with poor staining qualities resulting from either prolonged fixation or from inadequacies in the buffer or embedding medium used.     

Uranyl sulphate: A new negative stain for electron microscopy

Uranyl sulphate is a negative stain of high quality for electron microscopy of macromolecules below their isoelectric point. The stain results in good contrast and high resolution as demonstrated by optical diffraction of periodic structure. Analysis of scanning transmission electron microscopic data reveals that uranyl sulphate is lower in background noise level than uranyl acetate and is dramatically more resistant toward granularization upon continued exposure to electron irradiation. Electron microscopic images of most macromolecules contrasted with uranyl sulphate were indistinguishable from those obtained with uranyl acetate. However, electron microscopic images of Reo virus contrasted with uranyl sulphate are always readily distinguished from those obtained with uranyl acetate.     

Oolong tea extract as a substitute for uranyl acetate in staining of ultrathin sections

In conventional transmission electron microscopy, uranyl acetate staining is used to enhance the cellular components. However, uranyl acetate is considered a radioactive material that is very toxic if ingested or inhaled and subject to restrictions in many countries. In an attempt to introduce a substitute for uranyl acetate, we evaluated oolong tea extract (OTE) for staining of ultrathin sections. Tissue sections from normal rat liver representing an ideal model organ were processed according to a routine electron microscopic fixation and embedding procedure. Serial ultrathin sections were cut and processed with either routine double electron staining or 0.2% OTE staining for 30–40 min at room temperature followed by lead citrate staining (OTE staining method). Transmission electron microscopy observations revealed that all sub‐cellular structures in hepatocytes were clearly visible with OTE staining and the quality of staining was highly compatible with those of routine double staining methods. It is suggested that OTE could be used as a non‐radioactive and hazard‐free substitute for uranyl acetate in transmission electron microscopy staining.     

Dimensional stability in tissues dehydrated with 2,2-dimethoxypropane for electron microscopy

Dimensions of tissues fixed in glutaraldehyde-osmium tetroxide mixture, osmium tetroxide and uranyl acetate and then dehydrated in 2,2-dimethoxypropane (DMP) were measured using transmission and scanning electron microscopy. Rat cardiac muscle, kidney and other tissues were examined in this study. The mean dimensions of characteristic ultrastructural features of material prepared by this method are similar or larger than those reported in the literature for conventionally processed samples. Critical point drying of specimens dehydrated with DMP does not produce abnormal shrinkage. Simultaneous primary fixation of lipids and proteins in a glutaraldehyde osmium tetroxide mixture and omission of the water wash after uranyl acetate appear to be important in stabilizing the tissue for rapid dehydration. The rapid reaction of DMP and water yielding the products acetone and methanol does not appear to denature tissue components to a greater extent than conventional solvent exchange dehydration.     

Electron microscopy of cellulose in entire tissue

Microfibrillar structures can be seen in ultrathin sections of cell walls which have been post-stained with uranyl acetate and lead citrate. This stain is removable by washing, suggesting that a physical mechanism is involved. It is suggested that these structures are the cellulose microfibrils of the wall; they appear to be 3.5 nm in diameter and not fasciated into larger units. Freeze-etching of untreated tissue supports this conclusion. These two techniques seem to have many advantages over methods previously used for the study of microfibril arrangement and structure.     

Comparison of bromine and permanganate as ultrastructural stains for lignin in plants infected by the fungus Colletotrichum lagenarium.

Transmission electron microscopy (TEM) and energy dispersive X-ray microanalysis (EDS) were used to localize manganese from KMnO4, and bromine, as ultrastructural stains for lignin in an herbaceous plant. The Spookie cultivar of pumpkin is susceptible to infection by the fungus Colletotrichum lagenarium and served as a model system to compare the Br and KMnO4 techniques. Bromine was used in a fixation/staining procedure, and in separate experiments, KMnO4 was used as either a fixative or as a postsection stain. The technique for using bromine was modified from the woody plant procedure by adding a paraformaldehyde prefixation step. With the bromine procedure, cell walls were well-preserved, but the cytoplasm was heavily extracted. The KMnO4 procedures produced well-fixed cytoplasm, but with some staining artifacts. With all procedures, EDS dot mapping demonstrated lignin deposition in the cell walls specifically associated with sites of fungal infection. Lignin was also localized in secondary walls of tracheary elements, sites known to be highly lignified. The bromine procedure provided the most specific localization of lignin with a minimum of artifact. The specific applications of these stains provided data on the ultrastructural localization of lignin which contributed to the elucidation of its role in the interactions between pathogenic fungi in both their resistant and susceptible plant hosts.     

Identification and study of the same cell in monolayer culture by different methods of light microscopy,scanning, and transmission electron microscopy. Application for cryodamaged cells examination

Cells were cultivated on transparent conductive substrates, glass slides coated with indium oxide; individual cells were marked with a diamond indentor. Cell cultures were frozen (–15°C), thawed, and then stained with fluorescent dyes to determine cell damage. The marked cells were examined by phase contrast, fluorescence, and Nomarski DIC microscopy. After aldehyde and osmium tetroxide fixation, the cell preparations were sequentially treated with tannic acid, uranyl acetate, and lead citrate. The same marked cell could be sequentially studied by light microscopy (LM; in water immersion conditions), scanning electron microscopy (SEM; after dehydration and critical point drying), and transmission electron microscopy (TEM; after embedding of cell samples in epoxy resin and laser marking of the cell previously marked with a diamond indentor). The method used ensures good preservation of cell morphology, cell surface relief, and intracellular structures. The treatment used renders the cells conductive and permitted SEM of uncoated culture cells on conductive substrates.     

Supramolecular structure of humic acids by TEM with improved sample preparation and staining

Understanding the role of the dissolved organic matter in the environment will benefit from the characterization of its components at the supramolecular scale. With its very high spatial resolution the transmission electron microscope (TEM) allows the determination of colloidal size, structure, and shape on aggregated substances as well as single particles. It also allows the determination of the chemical composition if coupled with an X-ray detector. However, TEM preparation artifacts may hamper the relevance of such observations. This study demonstrates the capacity of TEM for the size and shape analysis of humic substances. Three sample preparation techniques (ultramicrotomy sectioning after embedding into a hydrophilic resin, drop deposition, and absorption) were evaluated with the Fluka humic acid (HA). Additionally, several staining agents (cesium hydroxide, lead citrate, uranyl acetate, and ruthenium tetraoxide) were used to increase the humic acid contrast for TEM observations. An improved simple preparation method with selective staining of the HA is proposed which permits the imaging of the humic acid macromolecules. The results show that the Fluka humic acid is composed mainly of fibrils generated by the interconnection of basic molecules of about 20 nm diameter with some isolated larger macromolecules (30-200 nm).     

Ultrastructural effects of perfomic acid oxidation of epoxy-embedded tissue with and without early uranyl staining.

Epoxy-embedded blocks of glutaradehyde and OSO4 fixed adenohypophyseal tissue were immersed in performic acid, rinsed and sectioned for electron microscopy. Sections exhibited a general image intensity equivalent to control sections but their stainability with both uranyl acetate and lead citrate stains was increased. It was concluded that osmium was not removed by performic acid oxidation. Membranes of endoplasmic reticulum and the Golgi apparatus were not visible, and other components (acidophil granules, in particular) were markedly distored in shape after oxidation. Such changes, however, were not evident in specimens previously exposed to uranyl acetate during ethanol dehydration.     

Alkaline hydrolysis/methylation-acetylation: a new technique for ultrastructural DNA cytochemistry

A new technique for the visualization of DNA-containing structures in electron microscopy is described. Samples of glutaraldehyde-fixed bone marrow from rats were subjected to alkaline hydrolysis to remove RNA and the phosphate of phospho-proteins, followed by a combined blockage of protein carboxyl and amino groups through methylation-acetylation. After uranyl acetate staining of epoxy-embedded ultrathin sections, chromatin from all cell types showed a highly selective and intense electron opacity. Staining methods for DNA were also positive in semithin sections. This simple procedure could be very useful in ultrastructural cytochemistry of DNA and chromatin.     

Increasing membrane contrast by means of imidazole-osmium post-fixation as exemplified by skeletal muscle fiber

Until now, the interpretation of findings derived from investigations on membrane structures (T tubules, sarcoplasmic reticulum, the Golgi apparatus) in thick sections of mammalian muscle tissue has been limited in TEM due to the lack of sharp resolution of the membrane contours. This article shows how the imidazol-osmium post-fixation of tissue blocks can be used to achieve well-contrasted, sharply defined membrane contours. Therefore, unstained sections from imidazol-osmium post-fixed tissue can be examined immediately. But protein structures (e.g., ribosomes) remain uncontrasted with this technique. If needed, it is possible to visualize the protein structures by conventional section staining with uranyl acetate and lead citrate. This method is suitable for both ultrathin and thick sections (>150 nm).     

Transmission electron microscopy staining methods for the cortex of human hair: a modified osmium method and comparison with other stains

For wool, superior staining of a wide range of ultrastructural components is achieved by en bloc treatment of fibres with a chemical reductant followed by osmium tetroxide. For human scalp hair, although staining quality is similar, the penetration of reagents is poor, resulting in large parts of the fibre cortex remaining unstained. Here we describe a modification to the reduction-osmication method in which reagents penetrate through a cut fibre end, allowing visualization of a wide range of features across the cortex. We compare the staining quality, artefacts and range of structure rendered visible using transmission electron microscopy for en bloc reduction-osmication to other staining alternatives including en bloc silver nitrate and section stains based on uranyl acetate and lead citrate, phosphotungstic acid, potassium permanganate, ammoniacal silver nitrate and some combinations of these stains. The effects of hair-care treatments are briefly examined.     

Routine cryofixation of plant tissue by propane jet freezing for freeze substitution

Cryofixation and freeze substitution methods were developed for ultrastructural studies of cells in complex plant tissues. Leaf tissues and root tips of tobacco (Nicotiana tabacum L. var. Maryland Mammoth) were frozen with a RMC MF7200 propane jet freezer and freeze substituted sequentially with tannic acid and osmium tetroxide/uranyl acetate in acetone. High quality preservation was consistently obtained for epidermal and phloem cells of the leaf, and epidermal, cortical, meristematic, and cap cells of the root tip. Leaf mesophyll cells were also often well frozen. Organelles, including nuclei, endoplasmic reticulum, mitochondria, Golgi bodies, and plastids, showed excellent structural integrity and contrast. Most notable is the superior preservation of the cytoskeleton. Our results demonstrate that the propane jet freezer can be used routinely for high quality cryofixation of higher plant cells in certain complex tissues. This could have important implications for the use of cryofixation approach in a wide range of research in plant biology.     

A novel TEM contrasting technique for extracellular polysaccharides in in vitro biofilms

In the past, the visualization of the extracellular matrix of biofilms on an ultrastructural level was hampered by shrinkage artifacts. In addition, the reproducible contrasting of extracellular polysaccharides (EPS) has not satisfactorily been solved. Here we describe a method overcoming these difficulties, which produces artifact-free transmission electron microscopic (TEM) images using multispecies biofilms grown in vitro. Sufficient contrast was achieved by replacing Schiff's reagent with the osmiophilic amino acid methionine. In addition, shrinkage was avoided by replacing the classical dehydration agents with ethylene glycol and 1,2-pentanediol. Applying this method provided images of biofilms with an intact matrix in which differentially contrasted bacteria were embedded. All six members of the biofilm consortium (Streptococcus sobrinus, Streptococcus oralis, Veillonella dispar, Fusobacterium nucleatum, Actinomyces naeslundii, and Candida albicans) could be distinguished. Within the matrix, structural differences of EPS, probably due to different proportions of alpha-1,3 and alpha-1,6 linkages, were apparent. Fibrilar polysaccharides were evident around microcolonies of S. sobrinus, and fluffy polysaccharides were detected in the vicinity of S. oralis microcolonies. The ultrastructure of biofilms prepared for TEM using this method allows the imaging of undistorted EPS as well as the differentiated contrasting of the six microbial species of the in vitro biofilm model. This is a major step forward in determining the spatial arrangement of microorganisms in biofilms on an ultrastructural level.     

Pure optical contrast in scattering-type scanning near‐field microscopy

A simple contrast enhancement method is presented for Lowicryl K4M ultrathin sections prepared by high pressure freezing/freeze substitution. The sections were treated with an acidified potassium permanganate oxidizing solution followed by uranyl acetate and lead citrate staining. The method, designated KMnO₄–UA/Pb staining, provided a much greater contrast in electron microscopy than conventional UA/Pb staining. In detail, the visibility of plasma membrane was especially improved and the nuclear heterochromatin, mitochondria and cytoplasmic ribosomes showed an adequate increase in electron density. In the mucous cells of rat Brunner's glands, the Golgi cisternae were well defined with the KMnO₄–UA/Pb staining. Interestingly, the membranes of the intermediate compartments were moderately reactive to the KMnO₄–UA/Pb staining, whereas the cis and the trans compartments were only faintly stained. It should be emphasized that the KMnO₄ oxidation following colloidal gold labelling did not cause a remarkable reduction of immunogold labelling and the enhanced contrast helped us to examine the gold particles with high accuracy. This contrast enhancement method is highly promising, with the potential to become a useful tool for histochemical investigation, including immunocytochemistry with the Lowicryl K4M ultrathin sections prepared by high pressure freezing/freeze substitution techniques.