Incorporation of D-[3H]-glucosamine and L-[3H]-fucose into the developing rat cochlea.

The uptake of two tritiated carbohydrates, D-[3H]-glucosamine and L-[3H]-fucose, to the developing rat cochlea was examined using light and electron microscopic radioautography. Both carbohydrates, administered to in vitro developing rat cochleas, shared a similar ultrastructural labeling pattern on the microvilli and apical cell region and on the tectorial membrane (TM) fibrils. On embryonic day 18, the radiolabeling appeared on the apical surface of the undifferentiated epithelium that will develop into both spiral limbus and Kölliker's organ (KO), while on postnatal day (PD) 1, it was only located on the apical surface of the KO. When D-[3H]-glucosamine was administered in vivo to newborn rats, the radiolabeling was observed in the TM covering the KO at PD 3. Lastly, D-[3H]-glucosamine administered in vivo to PD 7 rats, appeared at PD 9 in the TM region lying just above the organ of Corti. The present findings support the previously suggested leading role of the spiral limbus and KO in the secretion of the TM during cochlear development. The secretion of carbohydrates, and probably of other matrix components, starts on the spiral limbus and KO region and progressively extends to the organ of Corti.

Absence of fodrin (spectrin-like protein) under the pseudopod membrane in stimulated thyroid cells.

A fodrin-like protein purified from porcine thyroid cells and characterized by its properties identical to those of pig brain spectrin (F. Regnouf et al., Eur. J. Biochem. 153, 313-319 (1985)) has been localized by immunofluorescence and electron immunocytochemistry in porcine and rat thyroid. Fodrin-like polypeptides were detected in subplasmalemmal meshworks of microfilaments attached to isolated or in situ plasma membranes. In resting cells, fodrin was found under apical and basolateral membrane domains, whereas it was always absent under the pseudopod membrane domain induced by acute TSH stimulation in vitro, using monolayers of porcine cultured cells attached to collagen permeable substrates, as well as in vivo, using rats intravenously treated with TSH. Thyroid fodrin could be involved in exocytosis and membrane stabilization which occurs during the formation of pseudopods induced by TSH stimulation.

Choroidal ependymocytes in culture: expression of markers of polarity and function.

Long-term primary cultures derived from fetal mouse or rat choroid plexus were obtained in serum-supplemented media. Monoclonal and polyclonal antibodies to basolateral and apical membrane components were used to observe the expression of specific markers of polarity and function. Choroid plexus cultures and thin frozen sections of adult tissues were compared by immunocytochemistry. Two polyclonal antibodies directed against laminin and fibronectin were used on cultured choroid plexus and sectioned tissues, showing that fibronectin and laminin are located on the basolateral membrane domain in ependymocytes in vitro, as well as in vivo. Na(+)-K(+) ATPase was apically detected by light and electron microscopy with a monoclonal antibody (Mab H30) in both cultured cells and sectioned tissues. Double immunofluorescent staining with Mab H30 and affinity-purified polyclonal antibodies to the alpha subunit of G0 protein (G0 alpha) demonstrated the relatively similar distribution of the two antigens on the apical face of the choroidal tissue, both in vivo and in vitro. The distribution of these markers shows a typical differentiation with maintenance of polarized features in choroidal ependymocytes in culture, testifying that this cell culture system constitutes an interesting model for studying the functional characteristics of ependymal cells of the choroid plexus.

Apical localization of the alpha subunit of GTP-binding protein Go in choroidal and ciliated ependymocytes.

The presence of GTP-binding proteins (G proteins) has been studied in murine adult choroid plexuses and cultured fetal choroidal or hypothalamic ependymal cells by ADP-ribosylation catalyzed by Bordetella pertussis toxin (PTX) and by immunodetection using affinity-purified polyclonal antibodies against the alpha subunit of the Go protein (Go alpha), the major brain G protein. ADP-ribosylation with 32P-NAD and PTX of choroid plexus revealed an intense labeling at the 40 kDa level in addition to the known PTX-substrates at 41 kDa (Gi alpha) and 39 kDa (Go alpha). This 40 kDa substrate was also predominant in cultured ependymal cells. However, a positive immunoreactivity with the anti-Go alpha antibodies was detected at the level of the 39 kDa faster component, indicating the presence of Go alpha in both choroid plexuses and cultured ependymal cells. In thin frozen sections as well as in cultured cells, Go alpha was mainly immunolocalized at the apical pole of choroidal ependymocytes and in the kinocilia of ciliated ependymal cells. At the ultrastructural level, using gold immunoprobes, the immunoreactivity of a Go alpha-like protein was detected on the cytoplasmic face of the apical plasma membrane, coated pits and vesicles, and in the apical cytoplasmic matrix. In ciliated ependymal cells, the positive immunostaining displayed a dotted pattern at the surface of demembranated axonema of apical kinocilia. These findings strongly suggest that G proteins, especially Go, are involved in transducing chemical signals that modulate traffic and exchanges between cerebrospinal fluid and ependyma through the apical membrane of ependymocytes.

Ultrastructural localization of the GTP-binding protein Go in neurons.

The ultrastructural localization of Go, a GTP-binding protein (G protein) highly expressed in nervous tissues, was performed in cultured fetal and adult murine neurons, using affinity-purified polyclonal antibodies against the alpha subunit of the Go protein (Go alpha). These antibodies recognized denatured Go alpha and both the native Go alpha-subunit and the Go alpha beta gamma heterotrimer. At the ultrastructural level, the positive immunoreactivity detected in cultured cells as well as in thin frozen sections, showed that Go was largely distributed in cell bodies and neuritic cytoplasm. Labelling was principally noted on the cytoplasmic face of the plasma membrane lining the cell body and the neurites, especially in 'cell-cell' contacts, but also in the cytoplasmic matrix, between endoplasmic reticulum and Golgi cisternae. No immunoreactivity was observed on the inner face of the pre- or postsynaptic membranes in both adult brain and in cultured neurons. This last finding strongly suggests that the Go protein is not involved in transducing chemical signals at the level of synapses, but more probably modulates the synaptic functions by controlling the activity of effectors localized outside of the synaptic densities.