Studies of organelle movement in axoplasm extruded from the squid giant axon have led to the basic discoveries of microtubule-dependent organelle motility and the characterization of the microtubule-based motor proteins kinesin and cytoplasmic dynein. Rapid organelle movement in higher animal cells, especially in neurons, is considered to be microtubule-based. The role of actin filaments, which are also abundant in axonal cytoplasm, has remained unclear. The inhibition of organelle movement in axoplasm by actin-binding proteins such as DNase I, gelsolin and synapsin I has been attributed to their ability to disorganize the microtubule domains where most of the actin-filaments are located. Here we provide evidence of a new type of organelle movement in squid axoplasm which is independent of both microtubules and microtubule-based motors. This movement is ATP-dependent, unidirectional, actin-dependent, and probably generated by a myosin-like motor. These results demonstrate that an actomyosin-like mechanism can be directly involved in the generation of rapid organelle transport in nerve cells.
The most common mutation in the cystic fibrosis transmembrane conductance regulator (CFTR) gene in individuals with cystic fibrosis, ⌬F508, causes retention of ⌬F508-CFTR in the endoplasmic reticulum and leads to the absence of CFTR Cl ؊ channels in the apical plasma membrane. Rescue of ⌬F508-CFTR by reduced temperature or chemical means reveals that the ⌬F508 mutation reduces the half-life of ⌬F508-CFTR in the apical plasma membrane. Because ⌬F508-CFTR retains some Cl ؊ channel activity, increased expression of ⌬F508-CFTR in the apical membrane could serve as a potential therapeutic approach for cystic fibrosis. However, little is known about the mechanisms responsible for the short apical membrane half-life of ⌬F508-CFTR in polarized human airway epithelial cells. Accordingly, the goal of this study was to determine the cellular defects in the trafficking of rescued ⌬F508-CFTR that lead to the decreased apical membrane half-life of ⌬F508-CFTR in polarized human airway epithelial cells. We report that in polarized human airway epithelial cells (CFBE41o؊) the ⌬F508 mutation increased endocytosis of CFTR from the apical membrane without causing a global endocytic defect or affecting the endocytic recycling of CFTR in the Rab11a-specific apical recycling compartment.The cystic fibrosis transmembrane conductance regulator (CFTR) 2 is an ATP binding cassette (ABC) transporter and a cAMP-regulated Cl Ϫ channel that mediates transepithelial Cl Ϫ transport in the airways, intestine, pancreas, testis, and other tissues (1-3). Cystic fibrosis (CF), a lethal genetic disease, is caused by mutations in the CFTR gene (1, 2). The most common mutation in CFTR is ⌬F508 (4, 5). ⌬F508-CFTR does not fold properly, and most of the protein is retained within the endoplasmic reticulum (ER) where it is subsequently degraded (5, 6). Several studies suggest that the ER retention of ⌬F508-CFTR is not complete, and some ⌬F508-CFTR is constitutively expressed in the plasma membrane of primary epithelial cells from individuals homozygous for the ⌬F508 mutation (7-10). Because ⌬F508-CFTR retains some Cl Ϫ channel activity when expressed in the plasma membrane (5,6,(11)(12)(13)(14), it would be desirable to increase the expression of ⌬F508-CFTR in the plasma membrane to alleviate the symptoms in CF patients. The trafficking of ⌬F508-CFTR to the plasma membrane can be increased by chemical means or reduced temperature (15-21). Yet, functional and biochemical studies in heterologous cell lines demonstrate that rescued ⌬F508-CFTR has a greatly reduced stability or halflife in the post-ER compartments, including the plasma membrane (13,(22)(23)(24). Very little is known about the apical membrane half-life of rescued ⌬F508-CFTR in polarized human airway epithelial cells. A recent study demonstrates that the functional stability of ⌬F508-CFTR in the apical membrane of differentiated respiratory epithelial cells derived from nasal polyps from individuals homozygous for the ⌬F508 mutation is decreased compared with WT-CFTR (25). Furthermore, the bioc...
The C terminus of CFTR contains a PDZ interacting domain that is required for the polarized expression of cystic fibrosis transmembrane conductance regulator (CFTR) in the apical plasma membrane of polarized epithelial cells. To elucidate the mechanism whereby the PDZ interacting domain mediates the polarized expression of CFTR, Madin-Darby canine kidney cells were stably transfected with wild type (wt-CFTR) or C-terminally truncated human CFTR (CFTR-⌬TRL). We tested the hypothesis that the PDZ interacting domain regulates sorting of CFTR from the Golgi to the apical plasma membrane. Pulse-chase studies in combination with domain-selective cell surface biotinylation revealed that newly synthesized wt-CFTR and CFTR-⌬TRL were targeted equally to the apical and basolateral membranes in a nonpolarized fashion. Thus, the PDZ interacting domain is not an apical sorting motif. Deletion of the PDZ interacting domain reduced the half-life of CFTR in the apical membrane from ϳ24 to ϳ13 h but had no effect on the half-life of CFTR in the basolateral membrane. Thus, the PDZ interacting domain is an apical membrane retention motif. Next, we examined the hypothesis that the PDZ interacting domain affects the apical membrane half-life of CFTR by altering its endocytosis and/or endocytic recycling. Endocytosis of wt-CFTR and CFTR-⌬TRL did not differ. However, endocytic recycling of CFTR-⌬TRL was decreased when compared with wt-CFTR. Thus, deletion of the PDZ interacting domain reduced the half-life of CFTR in the apical membrane by decreasing CFTR endocytic recycling. Our results identify a new role for PDZ proteins in regulating the endocytic recycling of CFTR in polarized epithelial cells.
The mechanism by which cAMP stimulates cystic fibrosis transmembrane conductance regulator (CFTR)-mediated chloride (Cl ؊ ) secretion is cell type-specific. By using Madin-Darby canine kidney (MDCK) type I epithelial cells as a model, we tested the hypothesis that cAMP stimulates Cl ؊ secretion by stimulating CFTR Cl ؊ channel trafficking from an intracellular pool to the apical plasma membrane. To this end, we generated a green fluorescent protein (GFP)-CFTR expression vector in which GFP was linked to the N terminus of CFTR. GFP did not alter CFTR function in whole cell patchclamp or planar lipid bilayer experiments. In stably transfected MDCK type I cells, GFP-CFTR localization was substratum-dependent. In cells grown on glass coverslips, GFP-CFTR was polarized to the basolateral membrane, whereas in cells grown on permeable supports, GFP-CFTR was polarized to the apical membrane. Quantitative confocal fluorescence microscopy and surface biotinylation experiments demonstrated that cAMP did not stimulate detectable GFP-CFTR translocation from an intracellular pool to the apical membrane or regulate GFP-CFTR endocytosis. Disruption of the microtubular cytoskeleton with colchicine did not affect cAMP-stimulated Cl ؊ secretion or GFP-CFTR expression in the apical membrane. We conclude that cAMP stimulates CFTR-mediated Cl ؊ secretion in MDCK type I cells by activating channels resident in the apical plasma membrane.
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