Apical cytoplasm

About: Apical cytoplasm is a research topic. Over the lifetime, 1080 publications have been published within this topic receiving 36131 citations.

The fine structure of the pigment epithelium in the albino rat

Abstract: In this report, particular attention is paid to the inclusion bodies found in the apical cytoplasm of the pigment epithelial cell. These bodies are of variable size and form. The smallest (0.4 µ diameter) consist of a granular matrix enclosed by a single membrane, and are similar to the lysosomes of hepatic cells. Larger inclusion bodies contain areas of lamellated material in addition to granular matrix. The largest particles seen (2 µ diameter) are almost entirely lamellar. These different forms seem closely related, for it is possible to find all transitional stages between the smallest and largest particles. The relationship between the lamellar inclusion bodies and the rod outer segments is discussed.

Isolation and characterization of the Fc receptor from the fetal yolk sac of the rat.

Abstract: The yolk sac of the fetal rat and the proximal small intestine of the neonatal rat selectively transport maternal IgG. IgG-Fc receptors are thought to mediate transport across the epithelium of both tissues. We used a mouse mAb (MC-39) against the 45-54-kD component of the Fc receptor of the neonatal intestine to find an antigenically related protein that might function as an Fc receptor in fetal yolk sac. In immunoblots of yolk sac, MC-39 recognized a protein band with apparent molecular mass of 54-58 kD. MC-39 bound to the endoderm of yolk sac in immunofluorescence studies. In immunogold-labeling experiments MC-39 was associated mainly with small vesicles in the apical cytoplasm and in the region near the basolateral membrane of endodermal cells. The MC-39 cross-reactive protein and beta 2-microglobulin, a component of the intestinal Fc receptor, were copurified from detergent-solubilized yolk sac by an affinity purification that selected for proteins which, like the intestinal receptor, bound to IgG at pH 6.0 and eluted at pH 8.0. In summary, the data suggest that we have isolated the Fc receptor of the yolk sac and that this receptor is structurally and functionally related to the Fc receptor of the neonatal intestine. An unexpected finding is that, unlike the intestinal receptor which binds maternal IgG on the apical cell surface, the yolk sac receptor appears to bind IgG only within apical compartments which we suggest represent the endosomal complex.

Time Course and Cellular Source of Pancreatic Regeneration Following Acute Pancreatitis in the Rat

Abstract: The regenerative capacity of the different cell types in the rat exocrine pancreas has been studied in a model of hormone-induced acute pancreatitis in which pancreatic edema, inflammation, and acinar cell destruction were induced within 12 h of infusion of supramaximal concentrations of cerulein (5 micrograms/kg/h). A sequential biochemical and structural analysis of the pancreas in daily intervals was combined with the autoradiographic quantitation of labeling indices of five cell populations following /sup 3/H-thymidine injection at days 1-7 after induction of pancreatitis. Desquamation of acinar cell apical cytoplasm and release of cytoplasmic segments into the acinar lumen on the first day following induction of pancreatitis led to formation of duct-like tubular complexes. Enzyme content in the pancreas decreased progressively following the formation of the edema to levels 15-20% of controls and remained reduced during the initial 5 days. Thymidine incorporation into total DNA showed a biphasic pattern with a distinct peak at day 1 and a second broader peak between days 4 and 7. Autoradiographic quantitation of labeling indices demonstrated the exclusive incorporation into intercalated duct cells and interstitial cells during the initial 24 h, while the second peak was predominantly due to labeling of acinar cells. Larger interlobular ductsmore » and islets did not show changes in labeling index. In vivo labeling with /sup 3/H-thymidine during the first day and analysis of labeling indices 14 days later showed the persistence of label in intercalated duct cells and interstitial cells and argued against the stem cell hypothesis and against transformation of duct cells into acinar cells.« less

Differential microtubule requirements for transcytosis in MDCK cells.

Abstract: Given the role of microtubules in directing the transport of many intracellular organelles, we investigated whether intact microtubules were also required for transcytosis across epithelia. Using polarized MDCK cells expressing receptors for the Fc domain of IgG (FcRII-B2) or polymeric immunoglobulin (pIg-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 pIg-R was almost 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 degrees C prior to nocodazole treatment. Although incubation at 17 degrees 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 MDCK cells.

A concise review: iron absorption--the mucin-mobilferrin-integrin pathway. A competitive pathway for metal absorption.

Abstract: Newly identified iron binding proteins isolated from rat duodenal homogenates permit better understanding of iron absorption. Mucins bind iron at acid pH to keep iron soluble and available for absorption at the more alkaline pH of the duodenum; this explains iron deficiency following prolonged achlorhydria. Integrin (90/150 kD) was identified on the absorptive surface of enterocytes in association with radioiron and is believed to facilitate transit of iron through the microvillous membrane. Mobilferrin, a 56 kD iron binding protein, was isolated from enterocyte cytosol. It coprecipitates with integrin and appears in close association with integrins in the apical cytoplasm. We postulate it accepts dietary iron from integrin and acts as the shuttle protein for iron in the cytoplasm. Since iron in enterocytes remains in equilibrium with body stores, we postulate mucosal iron uptake is regulated by the number of iron binding sites either occupied or unoccupied by iron on mobilferrin. Iron repletion of enterocytes from body stores is accomplished via transferrin receptors on the posterolateral membranes of enterocytes. Increased transfer of iron from blood into absorptive enterocytes occurs in iron replete animals to inhibit mucosal uptake of dietary iron. Little transfer of iron from plasma to enterocytes occurs in iron deficiency. Enhanced mucosal transfer of iron into the body occurs with increased body need for iron. The exact mechanism for mucosal transfer of iron into the plasma has not been defined but may also be mediated by an integrin.