Contact microscopy with synchrotron radiation

Soft X-ray contact microscopy with synchrotron radiation offers the biologist, and especially the microscopist, a way to morphologically study specimens that could not be imaged by conventional TEM, STEM, or SEM methods (i.e., hydrated samples, samples easily damaged by an electron beam, electron-dense samples, thick specimens, unstained, low-contrast specimens) at spatial resolutions approaching those of the TEM, with the additional possibility to obtain compositional (elemental) information about the sample as well. Although flash X-ray sources offer faster exposure times, synchrotron radiation provides a highly collimated, intense radiation that can be tuned to select specific discrete ranges of X-ray wavelengths or specific individual wavelengths that optimize imaging or microanalysis of a specific sample. This paper presents an overview of the applications of X-ray contact microscopy to biological research and some current research results using monochromatic synchrotron radiation to image biological samples.     

ULTRASTRUCTURAL LOCALIZATION OF CELL SURFACE IMMUNOSPECIFICITY IN ANABAENA AZOLLAE USING INDIRECT FLUORESCENT ANTIBODY STAINING

Antisera prepared against whole cells were used to differentiate between freshly isolated and cultured cyanobacteria from the nitrogen-fixing fern Azolla filiculoides using both light and transmission electron microscopy (TEM). TEM suggested that the differentiating antigens are evenly distributed on the cell wall outer membrane of the cyanobacteria. The fluorescein isothiocyanate (FITC)-conjugated secondary antibody accumulation was sufficiently electron-dense to be detected without the need for either gold or ferritin labelling. Relative amounts of fluorescence which occurred on specimens viewed with fluorescent light microscopy were comparable to the thickness of electron dense material on the surfaces of these cells. Thus, it is possible to use the same immunological procedure to prepare cells for both light and TEM study.     

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 expression of tumor endothelial marker 7 is associated with metastasis and poor survival of patients with osteogenic sarcoma

Our objective is to identify genes regulating metastasis of osteogenic sarcoma (OGS) since metastasis is the primary cause of mortality among patients with OGS. To identify such genes, we first created a database of differentially expressed genes between six low-grade and six high-grade OGS tumors, and between a normal immortalized osteoblast cell line (FOB) and four commercially available OGS-derived cell lines. We specifically searched for surface proteins over-expressed in high-grade OGS, since we hypothesize that tumor-cell specific surface markers are key to metastasis. A gene encoding Tumor Endothelial Marker7 (TEM7) was selected as a candidate for further study. TEM7 expression pattern was assessed by RT-PCR, Western blotting and immunostaining. TEM7 mRNA was abundantly expressed in SAOS cells (derived from high-grade OGS), but not in FOB or MG63 cells (derived from low-grade OGS). Virtually no expression of TEM7 protein was observed in FOB cells but abundant expression was noted in SAOS and TE85 cells. Employing immunostaining of 92 human OGS specimens (50 high-grade and 42 low-grade) collected before chemotherapy show 97% (37 of 38) of high-grade OGS specimens with metastasis have high TEM7 staining. Further, we found that elevated expression of TEM7 correlated with poor survival (p<0.04) of affected patients. Inhibiting TEM7 function by siRNA inhibited invasion and migration of OGS cells with metastatic potential. Our results suggest TEM7 expression level closely parallels histology-based prognostication of OGS metastasis and, therefore, it is a therapeutic target. This is the first demonstration of a link between TEM7 and cancer metastasis.     

Application of electron tomography to fungal ultrastructure studies

Access to structural information at the nanoscale enables fundamental insights into many complex biological systems. The development of the transmission electron microscope (TEM) has vastly increased our understanding of multiple biological systems. However, when attempting to visualize and understand the organizational and functional complexities that are typical of cells and tissues, the standard 2-D analyses that TEM affords often fall short. In recent years, high-resolution electron tomography methods, coupled with advances in specimen preparation and instrumentation and computational speed, have resulted in a revolution in the biological sciences. Electron tomography is analogous to medical computerized axial tomography (CAT-scan imaging) except at a far finer scale. It utilizes the TEM to assemble multiple projections of an object which are then combined for 3-D analyses. For biological specimens, tomography enables the highest 3-D resolution (5 nm spatial resolution) of internal structures in relatively thick slices of material (0.2-0.4 microm) without requiring the collection and alignment of large numbers of thin serial sections. Thus accurate and revealing 3-D reconstructions of complex cytoplasmic entities and architecture can be obtained. Electron tomography is now being applied to a variety of biological questions with great success. This review gives a brief introduction into cryopreservation and electron tomography relative to aspects of cytoplasmic organization in the hyphal tip of Aspergillus nidulans.     

Automated most-probable loss tomography of thick selectively stained biological specimens with quantitative measurement of resolution improvement

We describe the technique and application of energy filtering, automated most-probable loss (MPL) tomography to intermediate voltage electron microscopy (IVEM). We show that for thick, selectively stained biological specimens, this method produces a dramatic increase in resolution of the projections and the computed volumes versus standard unfiltered transmission electron microscopy (TEM) methods. This improvement in resolution is attributed to the reduction of chromatic aberration, which results from the large percentage of inelastic electron-scattering events for thick specimens. These improvements are particularly evident at the large tilt angles required to improve tomographic resolution in the z-direction. This method effectively increases the usable thickness of selectively stained samples that can be imaged at a given accelerating voltage by dramatically improving resolution versus unfiltered TEM and increasing signal-to-noise versus zero-loss imaging, thereby expanding the utility of the IVEM to deliver information from within specimens up to 3 microm thick.     

Unique advantages of using low temperature scanning electron microscopy to observe bacteria

Summary Electron microscopy (EM) has greatly helped to elucidate our understanding of bacterial structure and function. However, several recent studies have cautioned investigators about artifacts that result from the use of conventional EM preparation procedures. To avoid these problems, the use of low temperature scanning electron microscopy (LTSEM) was evaluated for examining frozen, fully hydrated specimens. Spinach leaves (Spinacia oleracea L. cv. New Jersey), which were naturally infected or inoculated with bacteria, were used as the experimental material. 1 cm segments of the infected leaves were plunge frozen in liquid nitrogen, transferred to a cryochamber for sputter coating and then moved onto a cryostage in an SEM. After observation, some of the frozen, hydrated leaf segments were transferred onto agar medium to determine whether preparation for LTSEM was nondestructive to the bacteria. The other tissue segments were chemically fixed by freeze-substitution. The results indicated that after cryopreparation and observation in the LTSEM: (i) viable bacteria, which were recovered from the leaf sample, could be cultured on agar medium for subsequent study, and (ii) the frozen samples could be freeze substituted and embedded so that transmission electron microscopic (TEM) observations could be carried out on the same specimen. In conclusion, frozen, hydrated leaf tissue infected with bacteria can be observed using LTSEM and then can be either processed for TEM observation to obtain further structural details or recovered to culture the pathogenic bacteria for supplementary studies.Abbreviations EPS extracellular polysaccharide - EM electron microscopy - LTSEM low temperature scanning electron microscopy - SEM scanning electron microscopy - TEM transmission electron microscopy - TSA tryptic soy agar - TSB tryptic soy broth Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

emScope: A Tool Kit for Control and Automation of a Remote Electron Microscope

We have developed a portable and extensible set of tools and applications for control of a remote transmission electron microscope (TEM). These tools will be used to develop a system for automatically acquiring large numbers of high quality images from a TEM in a routine, robust, and efficient manner. In particular we plan to develop applications that allow for data collection from specimens preserved in vitreous ice.     

Ultrastructure and evolution of ballistosporic basidiospores

Basidiospores oiCoprinus cinereus were examined before and during spore discharge using light microscopy, and SEM of frozen-hydrated and other preparations. The process of droplet development at the hilar appendix was divided into three stages: pre-droplet, early and late enlargement. The fully expanded droplet was preserved only in frozen-hydrated specimens. Two-step droplet enlargement was also observed with TEM in Boletus rubinellus, and the droplet at the early enlargement stage was enclosed by a trilaminate membrane. The droplet was not observed in Auricularia species, but basidiospore preservation for SEM was optimum in Auricularia auricula with frozen-hydrated preparations. The hilar appendix of Auricularia fuscosuccinea as studied by TEM was simple compared with those of the Homobasidiomycetes. The implications of the data for evolution of the ballistosporic basidiospore and the discharge mechanism are considered.     

A simple and direct pre-embedding technique for ultrastructure of scarce biological specimens

A simple and rapid technique for pre-embedding scarce biological specimens for Transmission electron microscopy (TEM) is reported. It is based on pre-embedding biological samples in bovine serum albumin (BSA) and bis-acrylamide (BA), cross-linked and polymerized with paraformaldehyde, glutaraldehyde, ammonium persulfate and Temed. Pre-embedding in BSA and BA offers several advantages over traditional pre-embedding techniques for TEM including the ability to visualize the sample and a more resistant matrix. This results in more reproducible and consistent analysis. It can be applied to tissues, cells, and subcellular structures handled as pellets or suspensions. In addition, use of the pre-embedding matrix for light microscopy is reported. The ability to pre-embed scarce biological specimens efficiently and reproducibly provides a valuable way to study and characterize cytological tissues such as biopsies or cystic and amniotic fluid cells.     

Transmission and scanning electron microscopic study of the same cytologic material

The same cytologic material was successively examined by light microscopy (LM), scanning electron microscopy (SEM) and transmission electron microscopy (TEM). After the SEM examination, the specimens were rehydrated for a long period of time to allow the penetration of Epon 812 into the cells. The TEM examination showed the cell organelles to be comparatively well preserved. These consecutively performed LM-SEM-TEM examinations provided useful information on cytologic subjects, especially concerning the origin of the cells.     

Sputter shadowing

A device has been constructed which allows specimens to be shadowed in a conventional sputter water. This process of sputter shadowing lends to specimens a contrast suitable for imaging in the transmission electron microscope (TEM). The process has the practical advantages over metal evaporation shadowing of lower instrumentation costs, less user training, and less time expenditure per shadowing operation. It provides on a single grid a spectrum of shadowing contrasts from which optimal imaging for a particular specimen can be chosen. The process minimizes radiant and metal deposition heating of the specimen and, thereby, may better preserve its structure during the contrasting procedure. The grain resulting from sputter shadowing differs significantly from that obtained by metal evaporation shadowing and the possibility for using this difference to improve resolution in shadowed preparations is discussed.     

Utilization of hydrogen,acetate, and “noncompetitive”; substrates by methanogenic bacteria in marine sediments

We have used a relatively new microscopical technique, environmental scanning electron microscopy (ESEM), along with transmission electron microscopy (TEM) and light microscopy, to investigate a unique microbial community from a temperate-climate, cold sulfide spring near Ancaster, Ontario, Canada. ESEM allows the viewing of fully hydrated specimens that have not undergone the structural or chemical alterations imposed by the extensive procedures necessary for viewing biological specimens in a vacuum. Besides allowing visualization of microorganisms in their natural form and as intact assemblages, ESEM also detects elements, especially those lighter than Si, which tend to be lost or masked by the processes used to prepare samples for conventional SEM and for TEM thin sections. In this study we report new information about the structure of bacteriogenic sulfur deposits and their relationship to the structural aspects of a natural microbial community from a cold sulfide spring.     

Tuning of the Zernike phase-plate for visualization of detailed ultrastructure in complex biological specimens

In order to acquire phase-contrast images with adequate contrast, conventional TEM requires large amount of defocus. Increasing the defocus improves the low-frequency components but attenuates the high-frequency ones. On the other hand, Zernike phase-contrast TEM (ZPC-TEM) can recover low-frequency components without losing the high-frequency ones under in-focus conditions. ZPC-TEM however, has another problem, especially in imaging of complex biological specimens such as cells and tissues; strong halos appear around specimen structures, and these halos hinder the interpretation of images. Due to this problem, the application of ZPC-TEM has been restricted to imaging of smaller particles. In order to improve the halo appearance, we fabricated a new quarter-wave thin film phase-plate with a smaller central hole and tested it on vitreous biological specimens. ZPC-TEM with the new plate could successfully visualize, in in-focus images, the intracellular fine features of cultured cells and brain tissues. This result indicates that reduction of the central hole diameter makes ZPC-TEM applicable on size scales ranging from protein particles to tissue sections. The application of ZPC-TEM to vitreous biological specimens will be a powerful method to advance the new field of imaging science for ultrastructures in close-to-physiological state.     

Cryo-electron Microscopy Specimen Preparation By Means Of a Focused Ion Beam

Here we present a protocol used to prepare cryo-TEM samples of Aspergillus niger spores, but which can easily be adapted for any number of microorganisms or solutions. We make use of a custom built cryo-transfer station and a modified cryo-SEM preparation chamber². The spores are taken from a culture, plunge-frozen in a liquid nitrogen slush and observed in the cryo-SEM to select a region of interest. A thin lamella is then extracted using the FIB, attached to a TEM grid and subsequently thinned to electron transparency. The grid is transferred to a cryo-TEM holder and into a TEM for high resolution studies. Thanks to the introduction of a cooled nanomanipulator tip and a cryo-transfer station, this protocol is a straightforward adaptation to cryogenic temperature of the routinely used FIB preparation of TEM samples. As such it has the advantages of requiring a small amount of modifications to existing instruments, setups and procedures; it is easy to implement; it has a broad range of applications, in principle the same as for cryo-TEM sample preparation. One limitation is that it requires skillful handling of the specimens at critical steps to avoid or minimize contaminations.     

Dual-axis electron tomography of biological specimens: Extending the limits of specimen thickness with bright-field STEM imaging

The absence of imaging lenses after the specimen in the scanning transmission electron microscope (STEM) enables electron tomography to be performed in the STEM mode on micrometer-thick plastic-embedded specimens without the deleterious effect of chromatic aberration, which limits spatial resolution and signal-to-noise ratio in conventional TEM. Using Monte Carlo calculations to simulate electron scattering from gold nanoparticles situated at the top and bottom surfaces of a plastic section, we assess the optimal acquisition strategy for axial bright-field STEM electron tomography at a beam-energy of 300keV. Dual tilt-axis STEM tomography with optimized axial bight-field detector geometry is demonstrated by application to micrometer-thick sections of beta cells from mouse pancreatic islet. The quality of the resulting three-dimensional reconstructions is comparable to that obtained from much thinner (0.3-micrometer) sections using conventional TEM tomography. The increased range of specimen thickness accessible to axial STEM tomography without the need for serial sectioning enables the 3-D visualization of more complex and larger subcellular structures.     

Trial comparison of mitochondrial cristae craters images obtained by the freeze-fracturing and ultrathin sections method

In two-folded lamina of the mitochondrial cristae occurs in mitochondria of spermatocytes large areas of the inner and outer halves in freeze-fracturing technique morphological observations suggest that in mitochondrial membrane there exist "crater-like' structures with internal diameter of approximately 18 nm. A question has come up why no mention has so far been found in the literature of the appearance of similar structure in mitochondrial cristae in specimens in transmission electron microscope (TEM) observed. Thus comparison of our findings obtained by the freeze-fracturing (FF) method with those achieved by TEM was made.     

Evidence for a fucose-binding protein in boar spermatozoa

A fucose binding protein was detected in boar spermatozoa by means of a specifically developed modified enzyme-linked-lectin-assay using glycosylated peroxidase derivatives. The distribution of the fucose binding protein was assessed by means of fluorescence microscopy with fluoresceinyl-glycosylated peroxidase. Fucose binding was particularly prominent at the apical region of the sperm head. In order to gain more insight into the precise localization of the carbohydrate binding protein electron microscopical studies were performed using fucosyl peroxidase coupled to colloidal gold. In ultrathin sections as well as in specimens prepared in toto for TEM an intensive binding of fucosylperoxidase-colloidal gold was predominantly found at the apical part of the acrosome appearing as a crescent-like area. In some cases this binding pattern was replaced by a triangle-like intensive labelling at the equatorial segment as revealed clearly by specimens prepared in toto. By SDS-PAGE of the SDS-extractable sperm-proteins, followed by transblotting to nitrocellulose and visualization with the fucosylperoxidase by enzymatic amplification with 4-chloro-1-naphthol mainly one protein with the reduced molecular weight of approximately 53 kdal and some small proteins with apparent molecular weights less than 20 kdal was found to be responsible for the fucose-binding ability of porcine spermatozoa.     

Evidence for a fucose-binding protein in boar spermatozoa

Summary A fucose binding, protein was detected in boar spermatozoa by means of a specifically developed modified enzyme-linked-lectin-assay using glycosylated peroxidase derivatives. The distribution of the fucose binding protein was assessed by means of fluorescence microscopy with fluoresceinyl-glycosylated peroxidase. Fucose binding was particularly prominent at the apical region of the sperm head. In order to gain more insight into the precise localization of the carbohydrate binding, protein electron microscopical studies were performed using fucosyl peroxidase coupled to colloidal gold. In ultrathin sections as well as in specimens, prepared in toto for TEM an intensive binding of fucosylperoxidase-colloidal gold was predominantly found at the apical part of the acrosome appearing as a crescent-like area. In some cases this binding pattern was replaced by a triangle-like intensive labelling at the equatorial segment as revealed clearly by specimens prepared in toto. By SDS-PAGE of the SDS-extractable sperm-proteins, followed by transblotting to nitrocellulose and visualization with the fucosylperoxidase by enzymatic amplification with 4-chloro-1-naphthol mainly one protein with the reduced molecular weight of approximately 53 kdal and some small proteins with apparent molecular weights less than 20 kdal was found to be responsible for the fucose-binding ability of porcine spermatozoa.     

Adjusting interphase FISH results in epithelial tissue sections to whole cell complement

OBJECTIVE: To derive an equation to compensate for the discrepancies between whole cell preparations and tissue sections for more accurate enumeration of fluorescence in situ hybridization (FISH) signals per cell. STUDY DESIGN: Mean centromere signal counts in touch preparations and corresponding 4-6-micron sections of paraffin-embedded tissue were calculated. Mean widest nuclear diameters were also determined from the tissue sections. The observed data were analyzed to define the volumetric relationships between tissue sections and whole cell preparations. RESULTS: Analysis of results from six lung specimens yielded an equation that approximates whole versus sectioned nuclear volume and permits accurate quantification of mean FISH signal count in histologic sections, as follows: [formula: see text].