Ultrathin cryosections in the plane of cell monolayers: evaluation of their potential for antibody localization studies of the cytoskeleton.

In spite of the fact that the preembedding method is satisfactory for the ultrastructural localization of cytoskeletal proteins, there is a need for a localization method that retains the cells' ground substance, delicate filament arrangements, and membrane-filament interactions and provides a good delineation of ultrastructural detail. Ultracryomicrotomy, a resinless sectioning method, can combine good morphology with optimal antibody labeling. Until now, however, it has not been possible to section cell monolayers parallel to their plane of growth. This is a prerequisite for the localization of proteins along segments of filaments, contained within the section thickness. We describe such a method and give a first appreciation of its potential for antibody localization studies of cytoskeletal proteins. The method consists of seeding cells on a parallel 0.75-mm-thick gelatin substrate that can later be cut and used as a mounting block. An adapted negative staining has yielded a very useful delineation of the well-preserved structures within the cells, even in combination with immunogold labeling. The latter has been in its indirect version less satisfactory in dense microfilament bundles because of penetration problems, and more satisfactory on microtubules. Clearly, the penetration properties of gold probes will have to be improved before this method will become widely applicable. The availability of a sectioning method like this will provide the basis for further progress. There will be many cases which will justify the use of this relatively more difficult approach.

The molecular organization of myosin in stress fibers of cultured cells.

Antibodies to chicken gizzard myosin, subfragment 1, light chain 20, and light meromyosin were used to visualize myosin in stress fibers of cultured chicken cells. The antibody specificity was tested on purified gizzard proteins and total cell lysates using immunogold silver staining on protein blots. Immunofluorescence on cultured chicken fibroblasts and epithelial cells exhibited a similar staining pattern of antibodies to total myosin, subfragment 1, and light chain 20, whereas the antibodies to light meromyosin showed a substantially different reaction. The electron microscopic distribution of these antibodies was investigated using the indirect and direct immunogold staining method on permeabilized and fixed cells. The indirect approach enabled us to describe the general distribution of myosin in stress fibers. Direct double immunogold labeling, however, provided more detailed information on the orientation of myosin molecules and their localization relative to alpha-actinin: alpha-actinin, identified with antibodies coupled to 10-nm gold, was concentrated in the dense bodies or electron-dense bands of stress fibers, whereas myosin was confined to the intervening electron-lucid regions. Depending on the antibodies used in combination with alpha-actinin, the intervening regions revealed a different staining pattern: antibodies to myosin (reactive with the head portion of nonmuscle myosin) and to light chain 20 (both coupled to 5-nm gold) labeled two opposite bands adjacent to alpha-actinin, and antibodies to light meromyosin (coupled to 5-nm gold) labeled a single central zone. Based on these results, we conclude that myosin in stress fibers is organized into bipolar filaments.

Sensitive visualization of antigen-antibody reactions in dot and blot immune overlay assays with immunogold and immunogold/silver staining.

The use of colloidal gold and colloidal gold followed by silver enhancement as marker for dot or blot immune overlays is described. Colloidal gold probes concentrating at the sites of immune reaction gradually develop a pinkish colour during incubation that can be seen with the naked eye. With a physical developer, very high sensitivity and contrast is obtained by silver precipitation on the gold marker. Comparison of the immunogold and immunogold/silver staining methods with the indirect, PAP and ABC immunoperoxidase methods demonstrates that colloidal gold probes are excellent markers for immune overlay assays.

Ultrastructural localization of alpha-actinin and filamin in cultured cells with the immunogold staining (IGS) method.

Monospecific antibodies to chicken gizzard actin, alpha-actinin, and filamin have been used to localize these proteins at the ultrastructural level: secondary cultures of 14-d-old chicken embryo lung epithelial cells and chicken heart fibroblasts were briefly lysed with either a 0.5% Triton X-100/0.25% glutaraldehyde mixture, or 0.1% Triton X-100, fixed with 0.5% glutaraldehyde, and further permeabilized with 0.5% Triton X-100, to allow penetration of the gold-conjugated antibodies. After immunogold staining (De Mey, J., M. Moeremans, G. Geuens, R. Nuydens, and M. De Brabander, 1981, Cell Biol. Int. Rep. 5:889-899), the cells were postfixed in glutaraldehyde-tannic acid and further processed for embedding and thin sectioning. This approach enabled us to document the distribution of alpha-actinin and filamin either on the delicate cortical networks of the cell periphery or in the densely bundled stress fibers and polygonal nets. By using antiactin immunogold staining as a control, we were able to demonstrate the applicability of the method to the microfilament system: the label was distributed homogeneously over all areas containing recognizable microfilaments, except within very thick stress fibers, where the marker did not penetrate completely. Although alpha-actinin specific staining was homogeneously localized along loosely-organized microfilaments, it was concentrated in the dense bodies of stress fibers. The antifilamin-specific staining showed a typically spotty or patchy pattern associated with the fine cortical networks and stress fibers. This pattern occurred along all actin filaments, including the dense bodies also marked by anti-alpha-actinin antibodies. The results confirm and extend the data from light microscopic investigations and provide more information on the structural basis of the microfilament system.

Epithelial organoids and mononuclear phagocytes from DMBA-induced mammary tumors of the rat secrete collagenase in vitro.

The production of collagenase has been examined in primary cultures of multicellular epithelial organoids and of stromal cells isolated from DMBA-induced mammary tumors of the rat. Plastic culture dishes and dishes coated with collagen fibrils were used to study the effect of such a substrate on collagenase release. Cultures of 51-micron epithelial organoids consisted of cuboidal cells and a myoepithelial-like cell type which formed a continuous layer under the cuboidal cells. A transient low production of collagenase with an apparent molecular weight (MW) of 72 kD was detected on both substrates. Upon separation by trypsin only cuboidal cells released collagenase. Cultures of 27-micron organoids contained only few myoepithelial-like cells. On plastic, they formed dense monolayers of cuboidal cells and released more collagenase than the greater aggregates. On collagen fibrils, these organoids formed cords and ridges and collagenase production was about 4- to 6-fold higher. These results indicate that collagenase release is influenced by the nature of the interaction of cuboidal cells with the substrate on which they grow. Similar organoids prepared from virgin mammary glands failed to secrete collagenase on either substrate. Primary cultures of stromal cells derived from tumor tissues comprised one basic cell type that expressed a series of properties characteristic for monocytes/macrophages. These cultures were capable of producing collagenase with an apparent MW of 56 kD. Collagenase with a similar size was detected in the extracts of 51 from 65 mammary tumors.