Investigation of mitochondrial morphology and function has been hampered because photostable, mitochondrion-spZc stains that are retained in fted, permeabilized cells have not been available. We found that in live cell preparations, the CMXRos and H2-CMXRos dyes were more photostable than rhodamine 123. In addition, fluorescence and morphology of mitochondria stained with the CMXRos and ation and acetone permeabilization. Using epifluorescence microscopy, we showed that CMXRos and H2-CMXRos dye fluorescence fully co-localized with antibodies to subunit I of cytochrome c oxidase, indicating that the dyes specifically stain mitochondria. Confocal microscopy of these mitochondria yielded colored banding pattems, suggesting that these dyes and the mitochondrial enzyme localize to different suborganellat regions. Therefore, these stains provide
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Stimulation of gastric acid secretion in parietal cells involves the translocation of the proton pump (H,K‐ATPase) from cytoplasmic tubulovesicles to the apical membrane to form long, F‐actin‐containing, microvilli. Following secretion, the pump is endocytosed back into tubulovesicles. The parietal cell therefore offers a system for the study of regulated membrane recycling, with temporally separated endocytic and exocytic steps. During cAMP‐mediated stimulation, an 80 kDa peripheral membrane protein becomes phosphorylated on serine residues. This protein is a major component, together with actin and the pump, of the isolated apical membrane from stimulated cells, but not the resting tubulovesicular membrane. Here we show that the gastric 80 kDa phosphoprotein is closely related or identical to ezrin, a protein whose phosphorylation on serine and tyrosine residues was recently implicated in the induction by growth factors of cell surface structures on cultured cells [Bretscher, A. (1989) J. Cell Biol., 108, 921–930]. Light and electron microscopy reveal that ezrin is associated with the actin filaments of the microvilli of stimulated cells, but not with the filaments in the terminal web. In addition, a significant amount of ezrin is present in the basolateral membrane infoldings of both resting and stimulated cells. Extraction studies show that ezrin is a cytoskeletal protein in unstimulated and stimulated cells, and its association with the cytoskeleton is more stable in stimulated cells. These studies indicate that ezrin is a membrane cytoskeletal linker that may play a key role in the control of the assembly of secretory apical microvilli in parietal cells and ultimately in the regulation of acid secretion. Taken together with the earlier studies, we suggest that ezrin might be a general substrate for kinases involved in the regulation of actin‐containing cell surface structures.
When isolated rabbit gastric glands were stimulated with histamine plus isobutylmethylxanthine, a redistribution of H+-K+-ATPase, from microsomes to a low-speed pellet, occurred in association with the phosphorylation of an 80-kDa protein (80K) in the apical membrane-rich fraction purified from the low-speed pellet. Histamine alone or dibutyryl adenosine 3',5'-cyclic monophosphate (DBcAMP), but not carbachol, also stimulated both the redistribution of H+-K+-ATPase and phosphorylation of 80K. Under stimulated conditions, 80K copurified in the apical membrane fraction along with H+-K+-ATPase and actin; whereas purified microsomes from resting stomach were highly enriched in H+-K+-ATPase but contained neither 80K nor actin. Treatment of the apical membranes with detergents, salts, sonication, and so on, led us to conclude that 80K is a membrane protein, unlike actin; however, the mode of association of 80K with membrane differed from H+-K+-ATPase, an integral membrane protein. Isoelectric focusing and peptide mapping revealed that 80K consists of six isomers of slightly differing pI, with 32P occurring only in the three most acidic isomers and exclusively on serine residues. Moreover, stimulation elicited a shift in the amount of 80K isomers, from basic to acidic, as well as phosphorylation. We conclude that 80K is an apical membrane protein in the parietal cell and an important substrate for cAMP-dependent, but not calcium-dependent, pathway of acid secretion.
To characterize the mechanis that determine the apical polarity of proteins anchored by glycosylphosphatidyliuiositol (GPI), we studied the targeting of a GPIanchored form of a herpes simplex glycoprotein, gD-1, in transfected MDCK cells. Using a biotin-based targeting assay, we found that GPI-anchored gD-1 was sorted in llulay and delivered directly to the apical surface. Endocytodus of GPIanchored gD-1 occurred slowly and preferentially from the apical domain, while transcytosis of the basolateral fraction did not occur at a signifcant rate (incompatible with being a precursor to the apical poo). Prevention of tight junction formation by in on in medium with micromolar Ca2+ resulted in expression ofGPI-anchored gD-1 on the fee surface, but not on the attached surface of the cell. Our results indicate that the apical polarity of a GPI-anchored protein is generated by vectorial delivery to the apical membrane, where its distribution is maintained by slow endocytosis and by a retention system not necessarily involving the tight junction.
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