We have examined the subcellular localization of the neu protein by immunohistochemistry and immuno-electron microscopy, associated with immunoblotting of normal and neoplastic tissues with 2 monoclonal antibodies (MAbs). Immunoelectron microscopy clearly reveals that neu protein resides only on the lateral plasma membrane of the simple epithelium of the breast and on the plasma membrane of malignant breast cells. It is also found on the membranes of the microvilli and the apical vacuoles of the cells of the proximal convoluted tubule of the kidney. In the cytoplasm, the only immunoreactivity detected with both antibodies was on the membrane of the mitochondrial cristae of normal and malignant cells. Immunoblotting reveals that the molecular weight of the membrane protein is 185 and 155 kDa for the mitochondrial protein. The cell membrane staining pattern can be revealed by light microscopic immunohistochemistry only in malignant cells and is therefore specific for malignancy. The membrane expression in normal cells cannot be visualized in this way. The mitochondrial reactivity appears as a cytoplasmic granular staining when examined under the light microscope. Similar cytoplasmic staining has been described previously in other studies with other antibodies against the neu protein and has lead to speculation about its function in normal and malignant cells. However, it is demonstrated in this study that it is not the known neu-oncogene product.
Ileocolonoscopy and biopsies of patients with spondylarthropathy reveal gut inflammation in 62% of cases. In order to better understand the pathogenetic mechanisms of spondylarthropathy-related gut inflammation, the follicle-associated epithelium was examined. Biopsies from nine controls and 18 patients with spondylarthropathy were studied by electronmicroscopy. Membranous (M) cells were investigated in normal and inflamed ileum. In normal mucosa, M-cells were scarce whereas in inflamed mucosa their number was increased (up to 24% of follicle-associated epithelial cells). They showed a thin rim of cytoplasm covering groups of lymphocytes. In chronic ileitis, necrotic M-cells, rupture of M-cells and lymphocytes entering the gut lumen were observed. The bursting of M-cells at the top of the lymphoid follicles leads to interruption of the gut epithelial lining and gives the luminal content access to the lymphoid tissue. This pathogenetic mechanism may cause aphthoid ulcers.
The diagnosis of infantile sialic acid storage disease (ISSD) was established in two siblings on the basis of typical clinical signs and the biochemical findings of hyperexcretion and intracellular storage of free sialic acid. A severe, steroid resistant nephrosis occurred in both siblings. The activities of lysosomal enzymes, including sialidase, were normal. A combined detection method for sialic acids with Limax flavus agglutinin labelling and phosphotungstic acid staining showed severely alterated sialic acid components in epithelial kidney cells and indicate a causal relationship between the nephrosis and the underlying biochemical defect. Further observations of ISSD patients with renal involvement will prove if a separate nephropathic phenotype exists.
In a previous paper, we have shown that the c-erbB-2-encoded protein p185erbB2 is localized on the brush border of the proximal tubule kidney cells. In invasive duct cell carcinomas, the labeling was most obvious on the villous plasma membrane protrusions. From these observations the hypothesis was raised that p185erbB2 could play a role in motility. To test this hypothesis, we quantified its distribution on the microvilli and plasma membrane protrusions and on the straight parts of the cell membrane after immunoelectron microscopy. These findings were compared with the localization on p185erbB2 overexpressing SK-BR-3 human breast cancer cells before and after stimulation of motility by treatment with conditioned medium from COLO-16 cells (CM), which is also able to induce chemotaxis of these cells in a Boyden chamber assay. In the invasive duct cell carcinomas, the number of gold particles was nine times higher at the plasma membrane protrusions than at the straight parts of the cell membrane. In untreated SK-BR-3 cells, p185erbB2 was similarly concentrated on the membrane of small microvilli and plasma membrane protrusions. Treatment of SK-BR-3 cells with CM leads to cell spreading, enlargement of the microvilli, formation of pseudopodia and chemotaxis. Aggregation of p185erbB2 at the plasma membrane protrusions and pseudopodia is observed on immunofluorescence light microscopy. The concentration of p185erbB2 is several times higher on these membrane extensions than on the straight parts after immunogold labeling. It is concluded that p185erbB2 is localized on cell organelles involved in motility, and it is suggested that the molecule plays a role in cell movement, providing the capacity of tumor cells to spread and metastasize.
In sympathetic neurons the axonal reticulum can be considered an extension of the secretory pole of the Golgi apparatus. If this tubular system indeed represents the neurosecretory apparatus, it would likely contain on its membranes the enzymes involved in catecholamine synthesis. To test this hypothesis, we investigated the distribution of dopamine-beta-hydroxylase and cytochrome b561 in bovine splenic nerve and nerve terminals in the vas deferens with an immunogold procedure after glycolmethacrylate embedding. Counterstaining with phosphotungstic acid at low pH selectively revealed the axonal reticulum elements. With antibodies against both enzymes, gold labeling was observed over the large dense-cored vesicles, the Golgi-associated axonal reticulum, the reticulum within axons, and the tubular complex at the nerve terminal. From our results it can be concluded that in sympathetic neurons the axonal reticulum represents a tubular neurosecretory system, extending from the Golgi apparatus in the cell soma to the nerve terminal. This concept emphasizes the local production of neurosecretory vesicles and may be of importance in the interpretation of neuronal transmission in normal and diseased states.
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