Preparing Mixed Cellulose Ester or Polycarbonate Membrane Filter Replicas for Transmission Electron Microscopy

Simple methods for preparing large numbers of grids exhibiting excellent coverage of intact replicas on mixed cellulose ester or polycarbonate membrane filters are described. The techniques ensure that grids and carbon replicas receive identical treatment and are not rearranged or lost during processing. The techniques permit grids and filter sections to be handled en masse rather than individually. Also, replica section squares remain centered on the grids. A temporary grid storage method (“grid- pad”) is also described, which facilitates grid identification and handling.     

A Simple Holder for Efficient Mass Staining of Thin Sections for Electron Microscopy

An inexpensive simply-constructed gridholder for reproducible staining of sections and storage of grids is made of a platelet of dental wax (Ladd No. 2460, or Belladi, rosa, normal) mounted on a glass slide. The grids are simply inserted perpendicularly into the wax and are held securely at their edges by the slightly sticky wax. Staining solutions may be applied directly to the standing grids or the gridholder may be inverted in a trough containing the staining solution, thus avoiding excessive contact with the air. Washing is carried out by dipping the gridholder in a series of beakers with distilled water or by flushing gently. The grids may be labeled directly on the slide and are therefore identified easily. The wax-gridholder eliminates excessive handling of the grids with tweezers not only during the staining procedure but as well as during storage and thus helps to prevent mechanical damage of the delicate sections mounted on the grids. Waxes other than those specified should not be used because of a tendency for particles to adhere to the grids, with the attendant possibility of column contamination.     

Accurate Placement of Ultrathin Sections on Grids; Control by Sol-Gel Phases of a Gelatin Flotation Fluid

A 3% solution of gelatin in a petri dish at 25-30 C. provides a liquid, viscous surface upon which ultrathin sections can be floated. On cooling, the gelled substratum immobilizes the sections, allowing grids to be placed on them with any desired grid-to-section orientation. When the gelatin is remelted, the sections remain attached to the grids. After draining, traces of gelatin adhering to the grids are removed by flotation (section side down) for 30 min on 2% acetic acid at 60 C. This is followed by flotation for 3-5 min on Tris buffer, pH 7.1, and then on distilled water for 30 min—both treatments at 60 C. The technique is particularly useful for mounting serial sections.     

Nickel Grids Cause Astigmatism in the Transmission Electron Microscope

Nickel grids are used in various methods (e.g., in immunocytochemistry) where chemically inert grids are required. Recently (Neiss 1983) we have used formvar-coated nickel grids when removing osmium from mounted ultrathin sections with 10% periodic acid (Lewis and Knight 1977). This is possible because nickel, unlike copper, adequately withstands the oxidation necessary for osmium removal. Handling sections on nickel grids avoids the disadvantages of free-floating sections, whose use for osmium removal has been recommended by Lewis and Knight (1977, chapter 2.2.3).     

A Scanning Electron Microscopic Evaluation of Section and Film Mounting for Transmission Electron Microscopy

Mounting of support films and sections for transmission electron microscopy has been examined with the scanning electron microscope. Experiments have been designed to test the adherence of support films to polished and matte surfaces of specimen grids. It is the conclusion of the authors that sections and films should be mounted on the dull or matte surface of Athene-type specimen grids.     

A Simple Method for Handling Grids

A simple method for handling electron microscope grids is described here. While assuring their identification and safety, this method provides improved handling, temporary storage, and identification of grids bearing ultra-thin sections, and in addition, provides a novel method for preparing bulk samples. Grids are attached at their edges to the weakly adhesive surface of a “Post-it” note pad which sits in a petri dish. The grids are safely immobilized on the pad, classified based on their location, and identified by convenient pad notation. Grid manipulation and identification are simplified using this device, which is easily assembled from readily available and inexpensive materials.     

Ultrastructural localization of neurophysin-like immunoreactivity in the rat posterior pituitary. An alternative method using frozen-dried tissue fixed with OsO4 vapor.

Electron microscopic identification of elements containing neurophysin-like immunoreactivity can be accomplished in rat posterior pituitary that has been frozen-dried and fixed with OsO4 vapor. Alternating serial ultrathin sections are placed on grids and glass slides. The sections on the slides are stained for neurophysin using immunofluorescence histochemistry, and the resultant images are superimposed on electron micrographs from the adjacent sections. The method provides several advantages for the localization of neuropeptide immunoreactivity in nervous tissue.     

Ultrastructural autometallography: a method for silver amplification of catalytic metals

The autometallographic technique involves application of a silver bromide-containing emulsion on the surface of ultrathin sections placed on grids that are subsequently exposed to a photographic developer. In tissue sections from animals treated intravitally with gold, silver, or mercury compounds, accumulations of the metals are visualized by autometallography and can be used for quantitative studies. After amplification, sections can be stained with lead citrate and uranyl acetate. Using autometallography, particles of colloidal gold dispersed in a film of gelatin showed a time-dependent growth and were gradually amplified up to 3.5-fold after 15 min of development. Hence the method may prove useful tracing colloidal gold particles in sections with low particle density, and be a powerful tool for revealing metals in biological tissues.     

A new tool based on two micromanipulators facilitates the handling of ultrathin cryosection ribbons

A close to native structure of bulk biological specimens can be imaged by cryo-electron microscopy of vitreous sections (CEMOVIS). In some cases structural information can be combined with X-ray data leading to atomic resolution in situ. However, CEMOVIS is not routinely used. The two critical steps consist of producing a frozen section ribbon of a few millimeters in length and transferring the ribbon onto an electron microscopy grid. During these steps, the first sections of the ribbon are wrapped around an eyelash (unwrapping is frequent). When a ribbon is sufficiently attached to the eyelash, the operator must guide the nascent ribbon. Steady hands are required. Shaking or overstretching may break the ribbon. In turn, the ribbon immediately wraps around itself or flies away and thereby becomes unusable. Micromanipulators for eyelashes and grids as well as ionizers to attach section ribbons to grids were proposed. The rate of successful ribbon collection, however, remained low for most operators. Here we present a setup composed of two micromanipulators. One of the micromanipulators guides an electrically conductive fiber to which the ribbon sticks with unprecedented efficiency in comparison to a not conductive eyelash. The second micromanipulator positions the grid beneath the newly formed section ribbon and with the help of an ionizer the ribbon is attached to the grid. Although manipulations are greatly facilitated, sectioning artifacts remain but the likelihood to investigate high quality sections is significantly increased due to the large number of sections that can be produced with the reported tool.     

The use of slotted grids for electron microscopic radioautography

A method for electron microscopic radioautography on slotted grids is presented which allows examination of the distribution of silver grains over sections of entire structural units without interference by grid bars. Tissue sections of a size such as to fit the opening of the grid slot are placed on slides coated with a Formvar film of sufficient strength to permit transfer of the completed radioautograph onto the grid and to support it over the slot. Sections are block stained prior to radioautography to minimize the risk of loss of the radioautograph during the procedure.     

The Use of Slotted Grids for Electron Microscopic Radioautography

A method for electron microscopic radioautography on slotted grids is presented which allows examination of the distribution of silver grains over sections of entire structural units without interference by grid bars. Tissue sections of a size such as to fit the opening of the grid slot are placed on slides coated with a Formvar film of sufficient strength to permit transfer of the completed radioautograph onto the grid and to support it over the slot. Sections are block stained prior to radioautography to minimize the risk of loss of the radioautography during the procedure.     

The ultramicrotome superstage: a versatile aid for section manipulation

The design and properties of a rigid, box-like device to be placed on the knife stage of a Porter-Blum MT-2 ultramicrotome are described. This "superstage" acts as a hand and tool rest, and a wind screen for the knife boat. The superstage easily permits tight rafts of ultrathin sections to be centrally located on grids. Additionally, it aids in placing 1 micron thick sections at the same relative location on glass slides to facilitate their examination in the light microscope.     

Distribution of cortical microtubules in tobacco protoplasts. An immunofluorescence microscopic and ultrastructural study

Summary The arrangement of cortical microtubules in tobacco protoplasts is described using the following techniques: 1. Transmission electron microscopy (TEM) of thin sections of whole protoplasts, 2. TEM of negatively stained protoplast ghosts, and 3. Indirect immunofluorescence microscopy of protoplast ghosts. Ghosts were prepared by attaching freshly isolated protoplasts to glass coverslips or formvar/carbon-coated grids with poly-L-lysine and then bursting them either osmotically or by detergent treatment in the presence of a microtubule stabilizing buffer. Osmotic bursting of protoplasts yielded large pieces of plasma membrane with attached microtubules. These preparations proved very useful for measuring the density and length of cortical microtubules. Detergent treatment dissolved the plasma membrane and altered the distribution of cortical microtubules.     

The Ultramicrotome Superstage: A Versatile Aid for Section Manipulation

The design and properties of a rigid, box-like device to be placed on the knife stage of a Porter-Blum MT-2 ultramicrotome are described. This “superstage” acts as a hand and tool rest, and a wind screen for the knife boat. The superstage easily permits tight rafts of ultrathin sections to be centrally located on grids. Additionally, it aids in placing 1 μm thick sections at the same relative location on glass slides to facilitate their examination in the light microscope.     

Ultrastructural immunocytochemistry of glia cells. Double labeling studies using LR White embedding and colloidal gold

The introduction of acrylate resins (Lowicryl K4M, LR White) into electronmicroscopic immunocytochemistry applied to embedded tissue (post-embedding method) has improved the localization of antigens because of a satisfactory preservation of both ultrastructure and antigenicity of tissues. Here we describe a method that allows double staining of intracellular and membranous determinants in ultrathin sections of nervous tissue and cultures of peripheral nervous system cells. Ultrathin sections of the rat central nervous system fixed on uncoated grids were stained first for MBP selectively on the one face, then the opposite face was stained for GFAP using monoclonal antibodies and indirect immunogold staining method (IGS). Cultured Schwann cells induced to express major histocompatibility complex (MHC) class II antigens were stained for class II antigens by pre-embedding method then followed by post-embedding IGS for the other intracytoplasmic antigens.     

Method for Staining and Washing Thin Sections on Support Films

A procedure is described for staining large numbers of thin sections on support films for use with one-hole grids. The film is picked up, carried and protected using easily made plastic blocks. Loop-tipped forceps are then used to transfer tissue ribbons from the knife boat to the support film. A large number of tissue sections can then be stained and washed simultaneously in a modified Pyrex dish without damaging the film. After staining, the slot in the one-hole grid is centered over the tissue ribbon, and the grid is attached to the film. The method is suitable for serial reconstruction and the unobstructed viewing of large thin sections in the TEM.     

Noncytopathic hepatitis A virus induces surface alterations in LLC-MK2 cells revealed by thin sections,negative staining,and scanning electron microscopy

Previous electron microscope studies of ultrastructural events during hepatitis A virus replication in experimentally infected cells have used only ultrathin section techniques. Nevertheless, no important differences were observed between infected and uninfected cells. This study was carried out using scanning electron microscopy and negative staining of whole LLC-MK2 cells grown directly on grids covered with support membranes, and then infected with an hepatitis A virus strain. Thin sections of infected and uninfected controls were also analyzed. An intricate web of projections forming a net between cell interfaces was observed only in infected cells. Some of these projections were more than 700 nm long and had ballooning tips. Nevertheless, HAV particles were not visualized in the infected cells.     

Modification of a scanning transmission electron microscope specimen holder for large section viewing.

A modification of a scanning transmission electron microscope specimen holder which permits full viewing of large plastic embedded tissue sections is discussed. The method for producing one-centimeter diameter "giant" grids is explained and the procedure for sample preparation is outlined. The modification aids the microscopist in his evaluation of tissue structural relationships by providing large areas of tissue for examination and reduces significantly the time required to prepare and examine standard 1-2 mm2 electron microscopy tissue sections. Light and electron microscopic evaluations can be made on the same tissue sections.     

Ultra-Thin Sectioning for Electron Microscopy

A technic is described for obtaining thin sections of animal tissue suitable for electron microscopy. Fixation is accomplished by perfusion of the whole animal with neutral formalin or alcohol formalin followed by immersion of pieces to be examined in neutralized osmium tetroxide. The embedding medium is a mixture of equal parts of n-butyl and ethyl methacrylate polymerized by ultra-violet light. Sectioning is done by means of a glass knife on an International ultra-thin sectioning microtome set at 0.1 μ. The sections are floated on warm water to spread, then placed on Formvar-coated grids, dried, and put into toluene to dissolve the plastic. The technic produces routinely usable, thin sections that show a minimum of damage owing to fixation, embedding, and sectioning.