Immunoelectron localization of mitochondrial F1 factor in cryosections of heart muscle cells

Immunocytochemistry was used to investigate the localization of F1 ATPase in mitochondria of cryosections of adult mouse heart muscle cells. The initial aldehyde fixation was the only denaturation step for antigens. The fine structure was preserved with contrast enhancement as the sections were maintained hydrated, with the advantage that the entire procedure is completed in one working day. The reaction was highly specific, and entire mitochondria were labeled with the Protein A-gold complex. A new analytical technique, electron spectroscopic imaging (ESI), contributed to a better visualization of the localization of the F1 factor.     

Junctional complexes and cell polarity in the urinary tubule

In this review, we demonstrate how differentiated membrane domains can be detected in epithelial cells using conventional light and electron microscopy, freeze-fracture electron microscopy and the immunoand cytochemical detection of membrane components. Using specific examples from the kidney, we show how the polarized insertion of these components into either apical or basolateral plasma membrane regions on either side of the tight junction barrier is related to specific functions of principal and intercalated cells in the collecting duct. In addition, distinct basal and lateral membrane domains have been revealed in some cells that are maintained in the absence of a tight junctional barrier in the plane of the membrane. This suggests that other factors, possibly related to cytoskeletal elements, may be involved in the functional segregation of these membrane areas. We propose that epithelial cell plasma membranes should be subdivided into apical, lateral and basal regions, and that the term “basolateral” may be an oversimplification.     

Postembedding ultrastructural immunocytochemistry of neural antigens on tissues previously processed for routine light and electron microscopy: Preservation of antigenicity up to 22 years after initial fixation

A postembedding immunocytochemical technique is described that allows ultrastructural localization of glial fibrillary acidic protein and neuron-specific enolase on tissues originally processed only for routine light and electron microscopy. Use of the oxidizing agent sodium metaperiodate prior to incubation with the primary antiserum sufficiently removes osmium tetroxide (OsO₄) from potential antigen—antibody combining sites to allow specific localization of these neural antigens by colloidal gold immunolabelling. Both human and monkey neural tissues, prepared for routine ultrastructural examination with aldehyde fixatives and OsO₄ postfixation, show excellent ultrastructural morphology and antigen localization. In addition, formalin-fixed, paraffin-embedded pathological human brain tissues, obtained at autopsy up to 22 years previously, show good ultrastructural immunolocalization of glial fibrillary acidic protein when re-embedded for electron microscopy. Thus, ultrastructural immunolocalization of certain neural antigens is easily achieved in tissues originally processed for routine light and electron microscopy. This allows re-examination of archival tissues using current immunocy-tochemical advances, including that of selected pathological tissues previously prepared solely for light microscopy.     

Organization of microtubules in cochlear hair cells

The organization of microtubules in hair cells of the guinea-pig cochlea has been investigated using transmission electron microscopy and correlated with the location of tubulin-associated immunofluorescence in surface preparations of the organ of Corti. Results from both techniques reveal consistent distributions of microtubules in inner and outer hair cells. In the inner hair cells, microtubules are most concentrated in the apex. Reconstruction from serial sections shows three main groups: firstly, in channels through the cuticular plate and in a discontinuous belt around its upper perimeter; secondly, forming a ring inside a rim extending down from the lower perimeter of the plate; and thirdly, in a meshwork underlying the main body of the plate. In the cell body, microtubules line the inner face of the subsurface cistern and extend longitudinally through a tubulo-vesicular track between the apex and base. In outer hair cells, the pattern of microtubules associated with the cuticular plate is similar, although there are fewer present than in inner hair cells. In outer hair cells from the apex of the cochlea, microtubules occur around an infracuticular protrusion of cuticular plate material. In the cell body, many more microtubules occur in the region below the nucleus compared with inner hair cells. The possible functions of microtubules in hair cells are discussed by comparison with those found in other systems. These include morphogenesis and maintenance of cell shape; intracellular transport, e.g., of neurotransmitter vesicles; providing a possible substrate for motility; mechanical support of structures associated with sensory transduction.     

Freezing and drying of biological tissues with a toggle-link helium freezer and an improved freeze-drying apparatus: Application to neuropeptide immunocytochemistry

A freezing apparatus has been developed for bringing blocks of tissue into contact with a block of sapphire chilled to 17°K. A toggle linkage minimizes rebound by slowing the rate of approach of the tissue to the cold surface to a velocity of zero. A glove box limits condensation on the surface of the sapphire, and a miniature moist chamber protects the specimen from drying and premature freezing. About 50 blocks of tissue can be frozen in an hour and a half by using 5 liters of liquid helium. The tissue is then frozendried at controlled temperature, fixed with OsO₄ vapor, and infiltrated with epoxy resin in a simple bench-top freeze-drier without breaking vacuum. About two-thirds of the blocks are useful for electron microscopy. Brain tissue frozen and dried by using these methods retains enough immunoreactivity for enkephalin in plastic sections to permit its detection with immunohistochemistry by using both the light microscope (with immunofluorescence) and the electron microscope (with colloidal gold).     

Three-dimensional analysis of neuronal geometry using HVEM

There is a need for an electron microscopic method for visualization of selectively stained neurons and neuronal processes with higher resolution than can be obtained with the light microscope, but using thick sections that allow visualization of the three-dimensional structure of the neuron. Such a method is required for measurement of the geometry of neurons, and this information is needed to test theoretical predictions on the way in which electrical signals of synaptic origin are processed by the cells. The high voltage electron microscope (HVEM) is well suited to this application, because of its high resolution and ability to form images of thick sections. Use of this instrument requires development of selective stains that can produce diffuse cytoplasmic staining of specific cells or cell populations on the basis of their functional properties. Several such methods currently being employed for light microscopic work can be used directly in the high voltage electron microscope or can be made useful by relatively minor alterations. These include intracellular staining with horseradish peroxidase, axonal tracing with Phaseolus vulgaris leukoagglutinin (PHA-L), and immunocytochemical staining for specific cell markers known to stain the cytoplasm of certain cell populations. Cells stained intracellularly by microinjection of horseradish peroxidase during physiological recording experiments may be stained in thick (ca. 50 μm) sections cut on a vibratome or similar instrument and stained in the standard way, using methods designed for light microscopy. The sections are then postfixed in osmium tetroxide and embedded in epoxy plastic. Sections cut from these blocks at thicknesses of from 1 to 5 μm using a dry glass knife may be examined directly in the HVEM with no further staining. This produces a very clear image of the cell on a relatively unstained background. This method provides more than adequate resolution of the boundary of the neuron, allowing measurement of neuronal processes to better than 10-nm precision. Similar results are obtained when the same method is applied to axonal tracing using PHA-L. In this case, the exogenously applied marker is used to label a small population of nearby neurons and to trace their connections with other cells at a distance. The lectin is detected by immunocytochemistry, but the selective contrast of the image is adjustable because the concentration of antigen in the cell is largely controlled by the experimenter. The lectin is distributed diffusely in the cytoplasm in a pattern identical to that of intracellular staining, so like intracellular staining, it reveals the overall shape of the cell. Immunocytochemical labelling using endogenous antigens known to be distributed in the cytoplasm of specific neurons produced inadequate control of selective contrast when prepared in this manner. Instead, 1–10μm sections cut from blocks of nervous tissue were embedded in polyethylene glycol, stained using a combedded in polyethylene glycol, stained using a combination of immunocytochemistry and histochemical intensification methods, and embedded in plastic on the grid. This method, which is also suited for staining with poorly penetrating markers such as colloidal gold, may also prove useful in a variety of other situations requiring the intensification of selective contrast.     

The cytoplasmic matrix of the adrenal chromaffin cells of rats under normal and stressed conditions

In embedment-free electron microscopy with polyethylene glycol embedding and subsequent deembedding, the conventional cytoplasm of the chromaffin cells was revealed to consist of a three-dimensional lattice of microtrabeculae and gives the impression that the chromaffin granules are held in place by the lattice. After the restraint stress, a substantial number of chromaffin cells were almost free of granules, and the microtrabecular lattice was much more compact than that in cytoplasmic regions occupied with remaining granules or increased mitochondria. In immunocytochemistry, actin immunofluorescence was confined to the subplasmalemmal regions, while tubulin and tropomyosin immunofluorescence appeared throughout the entire cytoplasm of normal chromaffin cells. After the stress, the immunofluorescence for actin and tubulin increased in intensity, while that for tropomyosin decreased. Immunogold labelings for actin and tubulin were found mainly on the thinner subplasmalemmal microtrabeculae and the thicker perikaryal ones, respectively, while some were deposited in the form of small aggregates on portions of microtrabeculae. No specific association between the gold labelings for actin or tubulin and the chromaffin granules was found, even in the subplasmalemmal regions. A hypothetical interpretation was proposed in which a more compact lattice of the microtrabeculae in spatial association with a looser lattice represents a gelated state of the cytoplasm. The significance of the gel—sol transition of the cytoplasmic matrix in relation to the secretory mechanism was discussed.