High-resolution surface views of human lymphocytes during capping of CD4 and HLA antigens as revealed by immunogold fracture-flip

Freeze-fracture immunogold labeling

Several approaches have been developed to combine immunogold cytochemistry and freeze-fracture techniques. These methods are highly heterogeneous regarding both the sequence of the procedural steps and the aspect of the resulting images. They imply immunolabeling either before or after freeze-fracture or even immunolabeling of platinum/carbon replicas of the freeze-fractured membranes, and have been used alternatively or in parallel to address different questions related to cell membrane structure, composition and dynamics or to intracellular membrane traffic. This review will briefly describe these methods and report most of their immunogold cytochemical applications, with the aim of facilitating selection of the most appropriate approach.

Gap junctions revealed by freeze-fracture electron microscopy

Gap junctions provide the basis for the formation of elaborate networks of communication between cells in animal tissues. Electron microscopic examination of thin sections of plastic embedded gap junctions has provided valuable information on the anatomy and function of these remarkable structures. Freeze-fracture electron microscopy, however, has made available unique vistas of gap junction-bearing intramembrane surface--surface previously inaccessible to the researcher's eyes. Data on population density, distribution, size, geometry of intramembrane particle packing, and structural responses of gap junction components to experimental manipulation are simply and easily obtained with freeze fracture. Recent developments of sophisticated protocols of immunocytochemistry as applied to freeze-fracture replicas further serve to reinforce the notion that freeze-fracture is a powerful tool for study of gap junctions. Molecular techniques of gap junction gene transfection promise to add a truly unique dimension to investigations of the broad spectrum of functional roles of gap junctions.

Surface distribution and partition during freeze-fracture of CD8 antigens on human lymphocytes and on epithelial transfected cells

Freeze-fracture immunocytochemistry was used to analyse the surface distribution, redistribution induced by antibodies, and partition during freeze-fracture, of CD8 molecules on human T lymphocytes and rat epithelial transfected (FRT-U10) cells. Immunogold labelling of CD8 antigens was uniform over the unfractured cell surfaces of both lymphocytes and epithelial transfected cells. After freeze-fracture, the gold particles were associated with the exoplasmic outer leaflets of the plasma membranes in both cell types. In lymphocytes, incubation with antibodies at 37 degrees C up to 20 min induced patching and capping of the antigens on the unfractured cell surface. After fracture, the patched molecules appeared associated with the protoplasmic inner leaflet of the plasma membranes. Parallel antibody-treatment at 37 degrees C of FRT-U10 cells induced clustering of CD8 molecules but failed to cause further aggregation in larger patches or in caps. After freeze-fracture, the immunolabelling was clustered, but associated with the exoplasmic outer leaflet of the plasma membranes as in untreated cells. The different redistribution induced by antibodies and the different behaviour on fracture of the redistributed molecules in the two cell types may be regulated by CD8 interaction with the cytoskeleton.

Patching and capping of LFA-1 molecules on human lymphocytes

The distribution and dynamics of LFA-1 molecules over the surface of human lymphocytes were analysed using immunogold label-fracture and fracture-flip methods. Patching and capping were induced by incubation at 37 degrees C with antibodies directed against the alpha and beta chains respectively of the heterodimeric LFA-1 molecule, and were followed by immunofluorescence. Treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA) to link LFA-1 molecules to the cytoskeleton increased the percentage of capped cells, implying a faster and more efficient process of capping. At all times of clustering or upon phorbol ester treatment, the concentration of LFA-1 in patches and then in caps was not accompanied by a parallel concentration of membrane particles on the freeze-fractured plasma membranes. Our results support the role of the cytoskeleton in regulating the capping phenomenon and in controlling the structural organization of the plasma membranes.

Internalization of CD4 molecules in human T-cells demonstrated by immuno-electron microscopy

Internalization of CD4 molecules on human CD4-enriched T-cells was demonstrated by immunocytochemical electron microscopy. CD4+ T-cell subclones were obtained from normal human peripheral blood, followed by one-way MLC screening and co-culturing with IL-2. Fixed and non-fixed T-cell samples were indirectly immunolabeled with mouse anti-human CD4 monoclonal antibody and goat anti-mouse IgG conjugated with peroxidase. Unfixed T-cells were immunolabeled at 4 degrees C and then re-incubated for 5-45 min at 37 degrees C. The selected CD4+ T-cell subclones showed strong CD4 binding on the cell surface after IL-2 incubation. However, fresh T-cells, monocytes, bone marrow cells and CD8+ T-cells all stained negative for CD4. The distribution of CD4 molecules on the fixed cell surface showed a homogeneous pattern. Capping and internalization of CD4-antibody-peroxidase complexes from the cell surfaces were observed follow a pathway of receptor-mediated endocytosis in unfixed T cells. Endocytotic vesicles, vacuoles of diverse sizes and shapes near the cell membrane or deep in the cell center were found to contain CD4 molecules. Negatively stained Golgi saccules were observed up to 45 min after re-incubation. These results suggest that increased CD4 molecules can be induced on the surface of normal human T-cells in vitro. Internalization and accumulation of CD4 molecules occurred in CD4-enriched T-cells with IL-2 pretreatment.

Freeze-fracture cytochemistry: a simplified guide and update on developments

A wide variety of methods by which cytochemistry and freeze-fracture can be successfully combined have recently become available. All these techniques are designed to provide information on the chemical nature of structural components revealed by freeze-fracture, but differ in how this is achieved, in precisely what type of information is obtained, and in which types of specimen can be studied. Colloidal gold labelling is the most widely used cytochemical technique in freeze-fracture cytochemistry, and for many of the methods it is indispensable. In principle, there are four points in which the cytochemical labelling step may be integrated into the standard freeze-fracture procedure: (i) before the specimen has been frozen, (ii) after it has been fractured and thawed, (iii) after platinum shadowing or (iv) after completion of the full replication sequence. Retention of the gold label so that it can be viewed with replicas can be achieved by depositing platinum and/or carbon upon the labelled surface, thereby partially entrapping the marker particles within the replica, or by retaining, attached to the replica, fragments of fractured membrane (or other cellular components) that would normally have been lost during the replica cleaning step. Another approach to visualizing the label is to use sections, either with portions of a replica included face-on, or for examining the fracture path through the sample (without replica). Recent developments have centered on the use of replicas to stabilize half-membrane leaflets; not only may these and associated attached components be retained for labelling just before mounting, but they provide a means for manipulating the specimen--specifically, turning it over during processing--so that additional structural information can be obtained. This article aims to explain how modern freeze-fracture cytochemistry works, and how the various techniques differ in what they can tell us about membranes and other cellular structures. With the effectiveness of many of the techniques now demonstrated, freeze-fracture cytochemistry is firmly established, alongside a range of related labelling techniques, for increasing application in cell and membrane biology in the 1990s.