Given the role of microtubules in directing the transport of many intracellular organelies, we investigated whether intact microtubules were also required for transcytosis across epithelia. Using polarized MMCK cells expressing receptors for the Fc domain of IgG (FcRH-B2) or polymeric immunoglobulin (plg-R), we examined the involvement of microtubules in apical to basolateral and basolateral to apical transcytosis, respectively. While depolymerization of microtubules with nocodozole had no effect on apical to basolateral transcytosis via FcR, basolateral to apical transcytosis of dimeric IgA via plg-R was alnost completely blocked. Inhibition due to nocodozole was selective for basolateral to apical transcytosis, since neither endocytosis nor receptor recycling was significantly affected at either plasma membrane domain. As shown by confocal microscopy, the block in transcytosis was due to the inability of MDCK cells to translocate IgA-containing vesicles from the basolateral to the apical cytoplasm in the absence of an intact microtubule network. The nocodazole sensitive step could be partially by-passed, however, by allowing cells to internalize IgA at 17°C prior to nocodazole treatment. Although incubation at 17°C blocked release of IgA into the apical medium, it did not prevent translocation of IgA-containing vesicles to the apical cytoplasm. Thus, receptor-mediated transcytosis in opposite directions exhibits distinct requirements for microtubules, a feature which reflects the spatial organization of MMCK cells.
Abstract. Endosomes are prelysosomal organdies that serve as an intracellular site for the sorting, distribution, and processing of receptors, ligands, fluid phase components, and membrane proteins internalized by endocytosis. Whereas the overall functions of endosomes are increasingly understood, little is known about endosome structure, composition, or biogenesis. In this paper, we describe a rapid procedure that permits analytical and preparative isolation of endosomes from a variety of tissue culture cells. The procedure relies on a combination of density gradient centrifugation and free flow electrophoresis. It yields a fraction of highly purified, functionally intact organdies. As markers for endosomes in Chinese hamster ovary cells, we used endocytosed horseradish peroxidase, FITC-conjugated dextran, and [35S]methionine-labeled Semliki Forest virus. Total postuuclear superuatants, crude microsomal pellets, or partially purified Golgi fractions were subjected to free flow electrophoresis. Endosomes and lysosomes migrated together as a single anodally deflected peak separated from most other organelles (plasma membrane, mitochondria, endoplasmic reticulum, and Golgi). The endosomes and lysosomes were then resolved by centrifugation in Percoll density gradients. Endosomes prepared in this way were enriched up to 70-fold relative to the initial homogenate and were still capable of ATP-dependent acidification. By electron microscopy, the isolated organelles were found to consist of electron lucent vacuoles and tubules, many of which could be shown to contain an endocytic tracer (e.g., horseradish peroxidase). SDS PAGE analysis of integral and peripheral membrane proteins (separated from each other by condensation in Triton X-114) revealed a unique and restricted subset of proteins when compared with lysosomes, the unshifted free flow electrophoresis peak, and total cell protein. Altogether, the purification procedure takes 5-6 h and yields amounts of endosomes (150-200 lxg protein) sufficient for biochemical, immunological, and functional analysis.
The ras‐like GTP binding protein rab4 is the only known rab protein on endosomes that is phosphorylated during mitosis. Since a large fraction of rab4 accumulates in the cytosol in mitotic cells, we investigated the molecular mechanism controlling membrane association of rab4. We first show that human rab4 is phosphorylated by recombinant mammalian p34cdc2 kinase in vitro. Next, the actual site of phosphorylation and its functional significance were determined using stably transfected CHO cell lines producing high levels of wild type rab4 or rab4 mutants bearing alterations at Ser196, which occurs within a consensus site for p34cdc2 kinase phosphorylation (S196PRR). Mutation of Ser196 to glutamine or aspartic acid completely prevented rab4 phosphorylation in mitotic cells and also blocked its appearance in the cytosol. Neither C‐terminal isoprenylation nor carboxymethylation of rab4 was affected by the mutations or by phosphorylation. Finally, dephosphorylation and reassociation of soluble rab4 with membranes occurred upon exit of cells from mitosis. Thus, phosphorylation of Ser196 is directly responsible for the reversible translocation of rab4 into the cytosol of mitotic cells.
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