Kidney proximal tubule cells: epithelial cells without EGTA-extractable annexins?

The expression and the subcellular localizations of annexins I, II, IV, VI, and XIII in renal epithelial cells were investigated, using immunological techniques with specific monoclonal antibodies. Upon performing Western blotting experiments, no annexins VI and XIII were detected in kidney, whereas annexins I, II, and IV were. Immunofluorescence labelling procedure performed on thin frozen renal sections showed the presence of these three annexins along the plasma membrane of the collecting duct cells with a restricted expression of annexin I at principal cells. Annexin I was also found present in some glomerular cells. None of these annexins, however, were detected in the proximal tubular cells upon performing immunofluorescence labelling and electrophoretic analysis on an EGTA (ethylenebis(oxyethylenenitrilo)tetraacetic acid)-extractable annexin fraction prepared from freshly isolated cells. This is the first time a mammalian epithelial cell has been found to express non-typical annexin (at least partly solubilized with EGTA). However, when these cells were grown in primary culture, they were found to express annexins I, II, IV, and V. As well as being located along the basolateral membrane, annexins I and II are also present on vesicles, which suggests that these annexins may be involved in vesicular traffic under cell culture conditions.

Polarized localizations of annexins I, II, VI and XIII in epithelial cells of intestinal, hepatic and pancreatic tissues.

The cellular and subcellular localizations of annexins I, II, VI and XIII in the rabbit intestine, liver and pancreas were studied by performing immunofluorescence labeling on thin frozen tissue sections using specific monoclonal antibodies. The expression of annexins was found to be finely regulated. Annexins XIII and I were expressed exclusively in the small intestine and the colon, respectively, whereas annexin II was present in all the tissues tested and annexin VI specifically in the liver and pancreas. These different annexins were concentrated in the basolateral domain of polarized cells, and some of them had an extra-apical localization: annexin XIII was concentrated in the lower 3/4 of enterocyte brush border microvilli; annexin II was present in the upper part of the terminal web in intestinal absorbent cells as well as in the bile canalicular area in hepatocytes, whereas annexin VI was detected on some apical vesicles concentrated around the bile canaliculi. In pancreatic acinar cells, the presence of annexin II on some zymogen granules provides further evidence that annexin II may be involved in exocytic events. In conclusion, this study shows that the basolateral domain of polarized cells appears to be the main site where annexins are located, and they may therefore be involved in the important cellular events occurring at this level.

Cellular and subcellular localization along the digestive and pulmonary tracts of a rabbit intestinal mucin differing from MUC2 and containing a 150 kDa light chain.

Two immunologically different rabbit intestinal mucins were separated by performing fractionated ammonium sulfate precipitation, dialysis against pH 5.5 buffer and filtration through a Sepharose CL 2B column. They each contain a light chain with apparent molecular masses of 150 and 140 kDa, respectively. These L-chains were purified after reduction and carboxymethylation of the disulfide bridges of the native mucins, and their first 22 amino acid sequence was determined. The sequence of the 140 kDa chain is 100% and 95% identical to the N-terminal sequence of the L-chains from human and rat MUC2, respectively and only 54% identical to the sequence of the 150 kDa chain. It can be concluded that the rabbit counterpart of MUC2 exists and that another rabbit intestinal mucin, named here M-6G2, contains an L-chain. As in the case of MUC2, the M-6G2 L-chain may have resulted from a limited proteolysis. This proteolysis seems to occur in a region which is conserved in both mucins, since the two chains both have approximately the same length and the same five-amino acid N-terminal sequence. The cellular expression of M-6G2 along the digestive and respiratory tracts differs from that of the other mucins known so far to be present in the human small intestine.

Cellular and subcellular localizations of annexins I, IV, and VI in lung epithelia.

The cellular and subcellular localizations of annexins I, IV, and VI in the rabbit tracheal and alveolar epithelia were studied by performing immunofluorescence labeling on thin frozen sections of these tissues, using specific monoclonal antibodies. Annexin I was highly expressed by ciliated cells, where it was concentrated in the cilia but was also present along the basolateral domain of the plasma membrane and in the nuclei. It was also abundant in the cytoplasm of type II pneumocytes and alveolar macrophages. Either one or both of these alveolar cells might be capable of secreting a very small amount of annexin I, which was found to be associated with the surfactant layer. Annexin IV was synthesized by all the lung epithelial cells. It was associated with the plasma membrane basolateral domain in ciliated cells and with either the apical or basal domain of plasma membrane in type I pneumocytes, whereas it was cytoplasmic in goblet cells and type II pneumocytes. Annexin VI was expressed only by alveolar endothelial cells, where it was probably cytoplasmic. None of these three annexins seem to be expressed in the nondifferentiated tracheal basal epithelial cells.

Changes in expression and subcellular localization of annexin IV in rabbit kidney proximal tubule cells during primary culture.

In the present study, we investigated the polarized expression of annexin IV at various stages in the growth of rabbit kidney proximal tubule cells (PTC) in primary cultures. The results of immunoblotting analysis and indirect immunofluorescence studies using a specific anti-annexin IV monoclonal antibody, indicated that annexin IV is expressed in proximal tubule cultured cells, although it was not detected in the proximal tubules present in frozen sections of kidney cortex and freshly isolated proximal tubule cells. In either non-confluent or confluent cells which remained attached to the collagen-coated support, annexin IV was mainly concentrated around the nucleus, whereas in PTC forming the monolayer of domes, it was restricted to the basolateral membrane domain. This basolateral localization was identical to that observed in other polarized epithelial cell types such as enterocytes. When the domes burst, the cells returned to the collagen-coated support and the annexin IV was again localized around the nuclei. The fact that the change of localization was very rapid suggested the existence of a considerable difference between the differentiation states of dome forming and adherent confluent cells. Moreover, a transient association of annexin IV with the basal body of apically located cilia also seemed to be correlated with a particular polarization state and/or differentiation states of adherent cultured cells, corresponding to the beginning of the polarized expression of aminopeptidase N, a hydrolase located in the apical brush border membrane, and to the falling of cells onto the support, subsequent to the bursting of the domes. In conclusion, these results provide evidence that annexin IV may constitute a new marker of the basolateral membrane domain of polarized epithelial renal cells in primary cultures.

Expression and glycosylation of the filamentous brush border glycocalyx (FBBG) during rabbit enterocyte differentiation along the crypt-villus axis.

The filamentous brush border glycocalyx forming the 'enteric surface coat' of the intestinal epithelium is composed in rabbits of a 400 kDa mucin-type glycoprotein, which was purified using the 3A4 monoclonal antibody. This monoclonal antibody recognizes a filamentous brush border glycocalyx-specific glycosidic structure containing an O-acetylated sialic acid, which is absent from all the other glycoproteins in the epithelium, with the exception of certain goblet cell mucins. Here we establish that only 50% of the rabbits tested synthesized this glycosidic structure. Upon immunolabeling surface epithelia and sections of jejunum from these rabbits, the carbohydrate epitope recognized by the 3A4 mAb was found to be present on the filamentous brush border glycocalyx of a variable number of enterocytes, which were patchily distributed over all the villi. This heterogeneous expression of 3A4 antigenicity, which was also observed in the crypts, suggests the existence of differences between the patterns of differentiation of enterocytes, which results in the expression of different pools of glycosyltransferases and/or acetyl transferases. In mature enterocytes, the 3A4 determinants were present only on the filamentous brush border glycocalyx, which is anchored solely to the membrane microdomain at the tip of brush border microvilli. However, expression of 3A4 antigenicity begins in the median third of crypts, in enterocytes with a short, thin brush border devoid of apical filamentous brush border glycocalyx. Here the 3A4 epitopes were present over the whole brush border membrane.(ABSTRACT TRUNCATED AT 250 WORDS)

The filamentous brush border glycocalyx, a mucin-like marker of enterocyte hyper-polarization.

The probably sole constituent of the filamentous brush border glycocalyx, which has been defined on the basis of electron microscopic data as a set of filaments radiating from the tip of rabbit intestinal brush border microvilli, has been purified. It consists of a mucin-type glycoprotein that can be solubilized by either Triton extraction or papain treatment of the brush border membrane vesicles but is insensitive to phosphatidylinositol phospholipase C. The detergent- and papain-solubilized forms both have the same apparent molecular mass of 400 kDa (SDS/PAGE). This suggests that the filamentous brush border glycocalyx may be anchored to the membrane by a small hydrophobic peptidic tail. Ser, Thr, Pro and Ala amount to 65% of the protein core amino acid residues. The glycosidic moiety, which amounts to 73% of the molecular mass, has high O-acetylated sialic acid contents. A monoclonal antibody (3A4) raised against the purified material was produced which specifically recognized the 400-kDa band by immunoprecipitation and immunoblotting, and the filamentous brush border glycocalyx of villus enterocytes when jejunum sections were immunolabelled. The 3A4 determinant was identified with a filamentous brush border glycocalyx-specific carbohydrate structure containing an O-acetylated sialic acid. The fact that the labeled glycocalyx was anchored entirely in a membrane microdomain at the tip of the microvilli shows that mature enterocytes are hyper-polarized epithelial cells.

Expression of sucrase-isomaltase and dipeptidylpeptidase IV in human small intestine and colon.

One monoclonal antibody (8A9) against the human sucrase-isomaltase complex and one (4H3) against the human dipeptidylpeptidase IV were produced in the rat and used to immunolabel thin frozen sections of human small intestine and colon. Both enzymes were found to be expressed in the poorly differentiated crypt cells of the small intestine as well as in the mature villous cells, and very low levels were found to be expressed in the colon. Homogeneous immunolabeling of the whole colonic epithelium with the monoclonal antibody 4H3 was often observed, whereas labeling with the monoclonal antibody 8A9, if any, was either restricted to a few crypts and plateaus. The two antibodies were used to perform specific immunoprecipitation of the corresponding antigen, the N-terminal sequence of which was determined after sodium dodecyl sulfate-polyacrylamide gel electrophoresis purification and electroblotting, and were compared with those of other species. In secretor blood group A humans, both the sucrase-isomaltase and the dipeptidylpeptidase IV have type 3 blood group A determinants.

Lipocortin IV is a basolateral cytoskeleton constituent of rabbit enterocytes.

A monoclonal antibody, BL7B1, which specifically recognized rabbit lipocortin IV, was produced. The BL7B1 epitope is localized between the methionine residues that occupy positions 148 and 259 in human lipocortin IV. Immunofluorescence and subcellular fractionation studies showed that in the rabbit enterocytes, lipocortin IV is specifically associated with the basolateral membranes. When these membranes are solubilized by Triton X-100 in the presence of 1 mM of Ca2+ the lipocortin IV, like the cytoskeleton, remained insoluble suggesting that it might be associated with this structure in vivo. No lipocortin IV was detected in the brush border using immunofluorescence techniques and less than 10% of the amount present in the purified basolateral membranes was detected in the brush border membrane fraction.

Cellular and subcellular localization of annexin IV in rabbit intestinal epithelium, pancreas and liver.

The results of immunoblot analysis performed with a specific monoclonal antibody showed that the intestinal mucosa, pancreas and liver are privileged tissues for the expression of annexin IV. Immunofluorescence labelling of thin frozen sections of these tissues showed a strong concentration of annexin IV along the basolateral domain of the plasma membrane of intestinal absorbing cells, hepatocytes and pancreatic acinar cells, whereas in intestinal mucous secreting cells and centro acinar pancreatic cells, annexin IV was found to be present throughout the cytoplasm.

Conformational change of rabbit aminopeptidase N into enterocyte plasma membrane domains analyzed by flow cytometry fluorescence energy transfer.

Membrane vesicle preparations are very appropriate material for studying the topology of glycoproteins integrated into specialized plasma membrane domains of polarized cells. Here we show that the flow cytometric measurement of fluorescence energy transfer used previously to study the relationship between surface components of isolated cells can be applied to membrane vesicles. The fluorescein and rhodamine derivatives of a monoclonal antibody (4H7.1) that recognized one common epitope of the rabbit and pig aminopeptidase N were used for probing the oligomerization and conformational states of the enzyme integrated into the brush border and basolateral membrane vesicles prepared from rabbit and pig enterocytes. The high fluorescent energy transfer observed in the case of pig enzyme integrated into both types of vesicles and in the case of the rabbit enzyme integrated into basolateral membrane vesicles agreed very well with the existence of a dimeric organization, which was directly demonstrated by cross-linking experiments. Although with the latter technique we observed that the rabbit aminopeptidase was also dimerized in the brush border membrane, no energy transfer was detected with the corresponding vesicles. This indicates that the relative positions of two associated monomers differ depending on whether the rabbit aminopeptidase is transiently integrated into the basolateral membrane or permanently integrated into the brush border membrane. Cross-linking of aminopeptidases solubilized by detergent and of their ectodomains liberated by trypsin showed that only interactions between anchor domains maintained the dimeric structure of rabbit enzyme whereas interactions between ectodomains also exist in the pig enzyme. This might explain why the noticeable change in the organization of the two ectodomains observed in the case of rabbit aminopeptidase N does not occur in the case of pig enzyme.

Renewal of goblet cell mucus granules during the cell migration along the crypt-villus axis in rabbit jejunum: an immunolabeling study.

A monoclonal antibody against intestinal mucins (5H7) was obtained and used immunolabel thin frozen sections and Epon-embedded sections of rabbit jejunum. It recognized a mucin oligosaccharide, the synthesis of which increased during goblet cell migration along the crypt-villus axis. During the earliest steps in their differentiation, the goblet cells located at the bottom of crypts synthesized mucins devoid of the 5H7 epitope, thus generating unlabeled granules. These unlabeled granules were gradually replaced by more and more labeled granules during the cell maturation. During goblet cell migration along the middle half of the villi, the mucus granules were found to be totally renewed twice. However, some newly formed labeled granules were observed to reach the apical pole of the cells before older unlabeled ones and might have had a faster turnover. At least one glycoconjugate of the goblet cell microvillar membrane also bore the 5H7 epitope. It was rapidly carried from the Golgi apparatus to the apical plasma membrane domain by a transport process that was independent of baseline mucin secretion.

Molecular organization of the intestinal brush border.

The brush border of enterocytes represents one of the more specialized apical poles of epithelial cells. It is formed by particularly well-developed apical plasma membrane microvilli, whose shape is ensured by a highly organized cytoskeleton. The molecular organization of the cytoskeleton is described. Whereas several cytoskeleton proteins are ubiquitous, villin is highly specific for intestinal cells and can be used as a differentiation marker of these cells. The major glycoproteins, in particular hydrolases, of the brush border membrane have been characterized. They have many common structural features, in particular their mode of integration into the membrane by their N-terminal hydrophobic sequences that also plays the role of the 'signal peptide' responsible for their co-translational insertions into the endoplasmic reticulum. Studies on the biosynthesis and intracellular pathway of aminopeptidase N strongly suggest that sorting of apical and basolateral glycoproteins could occur after their integration into the basolateral domain.

Immunocytochemical localization of aminopeptidase N on the cell surface of isolated porcine thyroid follicles.

The ultrastructural location of aminopeptidase N on the cell surface of isolated porcine thyroid follicle cells was studied with immunocytochemistry using antibodies against intestinal aminopeptidase N and protein A-colloidal gold. Gold particles, indicating immunoreactivity, were selectively attached to the apical cell surface. Occasionally, there was a sparse labelling of the basal cell surface. In follicles kept at 4 degrees C most gold particles at the apical cell surface appeared as clusters, with each gold particle situated at a constant distance of about 20 nm from the membrane surface. The gold particles were concentrated on the membranes of microvilli, in comparison to the smooth (intermicrovillar) portions of the apical plasma membrane. In follicles incubated at 37 degrees C for 5-180 min gold particles were slowly internalized by predominantly smooth-surfaced micropinocytic vesicles and subsequently appeared in colloid droplets and lysosomes. Gold particles were not observed in Golgi cisternae. TSH did not appear to influence the rate of internalization. TSH-induced pseudopods were unlabeled. Our electron-microscopic observations confirm previous immunofluorescence-microscopic evidence that aminopeptidase N is selectively expressed in the apical plasma membrane domain in the thyroid follicle cell. Furthermore, aminopeptidase N appears to be distributed in microdomains within the apical plasma membrane. Earlier indications of molecular differences between the pseudopod membrane and the apical plasma membrane proper are further emphasized.

Subcellular localization of class I (A,B,C) and class II (DR and DQ) MHC antigens in jejunal epithelium of children with coeliac disease.

Thin frozen sections of 11 jejunal biopsies from 10 children at different stages of coeliac disease were stained by immunofluorescence technique using a panel of anti-HLA class I (A, B, C) and anti-HLA class II (DR and DQ) monoclonal antibodies. On the epithelium of flattened mucosa, in contrast with control sections, the intensity of the labeling on the basolateral membranes with both anti-class I and class II DR antibodies decreased strongly from the bottom to the upper part of the crypts, and no bright patchy staining was observed on the apical part of enterocytes with anti-HLA DR antibodies. Numerous cells with large granules expressing class I and class II DR antigens were found in the epithelium of the small intestine. Children with a fully recovered mucosa expressed MHC antigens identical to those previously observed in normal epithelium. On the other hand, children with intermediate mucosal lesions showed the presence of MHC antigens in varying degrees. The results of this report indicate that immunological mechanisms may play a prominent role in coeliac disease.

Expression of a subclass of human blood group A antigenicity in A+ rabbit jejunum: specific glycosylation of the glycocalyx and a 140 K brush border glycoprotein.

A monoclonal antibody (14 A4) raised against human A erythrocytes has been produced. It specifically reacts with a subclass of human blood group A determinants. Whereas all the major secreted and membrane-bound glycoproteins of A+ rabbit jejunum epithelium bear human blood group A-like determinants recognized by anti-A polyclonal serum or a monoclonal antibody with broad specificity (Cl 3.3), expression of the A-subclass recognized by 14 A4 is very restricted. The contents of secretory granules of Paneth cells but not the mucins of goblet cells were labeled by 14 A4. In the enterocytes, glycans recognized by 14 A4 were present in the glycocalyx, on an early expressed 140 K glycoprotein of brush border membranes and also on a glycoconjugate of the basolateral membrane of immature crypt cells. In the jejunal brush border membrane of blood group A secretor humans, only one glycoprotein of molecular weight 140 K bears the A-subclass recognized by 14 A4.

Evidence for the transit of aminopeptidase N through the basolateral membrane before it reaches the brush border of enterocytes.

In vivo pulse-chase labeling of rabbit jejunum loops was used in conjunction with subcellular fractionation and quantitative immunoprecipitation to determine whether or not the newly synthesized aminopeptidase N transits through the basolateral membrane before it reaches the apical brush border, its final localization. The kinetics of the arrival of the newly synthesized enzyme in the Golgi complex, basolateral and brush border membrane fractions strongly suggest that on leaving the Golgi aminopeptidase N is transiently integrated into the basolateral domain before reaching the brush border.

Further characterization of an early expressed glycoprotein of the rabbit small intestinal brush border. Its interaction with some hydrolases.

Mouse 23 B 921 monoclonal antibody recognized a rabbit brush-border antigen with an apparent molecular mass 140 kDa (140-kDa Ag) which, unlike most hydrolases, is expressed in the poorly differentiated crypt cells of the small intestine. Immunoelectron microscopy of brush-border vesicles showed that the 23 B 921 bound to an epitope localized on the outside of the membrane. As is the case with hydrolases the external domain of the 140-kDa Ag constitutes the main part of the molecule, which can be released by papain treatment of brush-border vesicles. The presence of a small hydrophobic domain, anchoring the molecule into the membrane and responsible for its amphipatic character, was shown by its affinity for Triton-X114 micelles. The topological organization in the membrane of 140-kDa Ag seemed to be identical to that of hydrolases. Unlike hydrolases, however, the native structure of the antigen was found from its sensitivity to proteolysis to be very dependent on its integration into the lipid bilayer. Nevertheless, detergent-extracted 140-kDa Ag can be purified by immunoaffinity chromatography although it cannot be stocked for more than 48 h even in the presence of protease inhibitors. The carbohydrate moiety of 140-kDa Ag, bearing the human blood group A determinant, amounts to 20% of the total molecular mass. The existence of some privileged relationship was established between 140-kDa Ag and hydrolases: in the membrane, hydrolases protect the 140-kDa Ag from papain action; after detergent extraction, 140-kDa Ag is strongly associated with several hydrolases particularly disaccharidases.