Intestinal tissue transglutaminase in coeliac disease of children and adults: ultrastructural localization and variation in expression.

BACKGROUND: Tissue transglutaminase is the main antigen for the anti-endomysial antibodies used for diagnosis of coeliac disease and can with some specificity in vitro deamidate gliadins generating potent epitopes. The intestinal levels and the ultrastructural localization of tissue transglutaminase in normal and affected persons were investigated to provide further information on its role in this disease. Intestinal biopsies were taken from normal and coeliac children and adults. METHODS: The level of transglutaminase was analysed by means of a quantitative enzymatic assay and its ultrastructural localization by immunogold electronmicroscopy using a monoclonal antibody against tissue transglutaminase. RESULTS: In relation to normal individuals, the enzymatic activity of tissue transglutaminase in adult coeliac patients was increased. The enzyme was found in the enterocytes and in increased amount just beneath the enterocytes, where cytosolic and nuclear labelling of distinct elongated cells was seen in addition to extracellular labelling close to collagen fibrils. In children, the enzymatic activity and the immunogold labelling could not be shown to be related to disease. In all cases the enzyme activity was EDTA-sensitive. CONCLUSIONS: The increased amount of tissue transglutaminase activity in coeliac adults was shown to be due to the appearance of the enzyme in enterocytes and increased expression in the lamina propria. No evidence was found to support the idea of a changed localization or changed amounts as primary elements in coeliac disease pathogenesis, nor for the involvement of non-calcium dependent microbial transglutaminases.

Scavenger receptor class B type I (SR-BI) in pig enterocytes: trafficking from the brush border to lipid droplets during fat absorption.

BACKGROUND: Scavenger receptor class B type I (SR-BI) is known to mediate cellular uptake of cholesterol from high density lipoprotein particles and is particularly abundant in liver and steroidogenic tissues. In addition, SR-BI expression in the enterocyte brush border has also been reported but its role in the small intestine remains unclear. AIM AND METHODS: To gain insight into the possible function of pig SR-BI during uptake of dietary fat, its localisation in enterocytes was studied in the fasting state and during fat absorption by immunogold electron microscopy and subcellular fractionation. RESULTS: In the fasting state, SR-BI was mainly localised in the microvillar membrane and in apical invaginations/pits between adjacent microvilli. In addition, a subapical compartment and small cytoplasmic lipid droplets were distinctly labelled. During lipid absorption, the receptor was found in clathrin positive apical coated pits and vesicles. In addition, cytoplasmic lipid droplets that greatly increased in size and number were strongly labelled by the SR-BI antibody whereas apolipoprotein A-1 positive chylomicrons were largely devoid of the receptor. CONCLUSION: During absorption of dietary fat, SR-BI is endocytosed from the enterocyte brush border and accumulates in cytoplasmic lipid droplets. Internalisation of the receptor occurs mainly by clathrin coated pits rather than by a caveolae/lipid raft based mechanism.

Lipid rafts exist as stable cholesterol-independent microdomains in the brush border membrane of enterocytes.

Glycosphingolipid/cholesterol-rich membranes ("rafts")can be isolated from many types of cells, but their existence as stable microdomains in the cell membrane has been elusive. Addressing this problem, we studied the distribution of galectin-4, a raft marker, and lactase, a protein excluded from rafts, on microvillar vesicles from the enterocyte brush border membrane. Magnetic beads coated with either anti-galectin-4 or anti-lactase antibodies were used for immunoisolation of vesicles followed by double immunogold labeling of the two proteins. A morphometric analysis revealed subpopulations of raft-rich and raft-poor vesicles by the following criteria: 1) the lactase/galectin-4 labeling ratio/vesicle captured by the anti-lactase beads was significantly higher (p < or = 0.01) than that of vesicles captured by anti-galectin-4 beads, 2) subpopulations of vesicles labeled by only one of the two antibodies were preferentially captured by beads coated with the respective antibody (p < or = 0.01), 3) the average diameter of "galectin-4 positive only" vesicles was smaller than that of vesicles labeled for lactase. Surprisingly, pretreatment with methyl-beta-cyclodextrin, which removed >70% of microvillar cholesterol, did not affect the microdomain localization of galectin-4. We conclude that stable, cholesterol-independent raft microdomains exist in the enterocyte brush border.

Cholesterol depletion of enterocytes. Effect on the Golgi complex and apical membrane trafficking.

Intestinal brush border enzymes, including aminopeptidase N and sucrase-isomaltase, are associated with "rafts" (membrane microdomains rich in cholesterol and sphingoglycolipids). To assess the functional role of rafts in the present work, we studied the effect of cholesterol depletion on apical membrane trafficking in enterocytes. Cultured mucosal explants of pig small intestine were treated for 2 h with the cholesterol sequestering agent methyl-beta-cyclodextrin and lovastatin, an inhibitor of hydroxymethylglutaryl-coenzyme A reductase. The treatment reduced the cholesterol content >50%. Morphologically, the Golgi complex/trans-Golgi network was partially transformed into numerous 100-200 nm vesicles. By immunogold electron microscopy, aminopeptidase N was localized in these Golgi-derived vesicles as well as at the basolateral cell surface, indicating a partial missorting. Biochemically, the rates of the Golgi-associated complex glycosylation and association with rafts of newly synthesized aminopeptidase N were reduced, and less of the enzyme had reached the brush border membrane after 2 h of labeling. In contrast, the basolateral Na(+)/K(+)-ATPase was neither missorted nor raft-associated. Our results implicate the Golgi complex/trans-Golgi network in raft formation and suggest a close relationship between this event and apical membrane trafficking.

Transcytosis of immunoglobulin A in the mouse enterocyte occurs through glycolipid raft- and rab17-containing compartments.

BACKGROUND & AIMS: Glycolipid "rafts" have been shown to play a role in apical membrane trafficking in the enterocyte. The present study characterized the membrane compartments of the enterocyte involved in transepithelial transport of small intestinal immunoglobulin A (IgA). METHODS: Immunogold electron microscopy and radioactive labeling of mouse small intestinal explants were performed. RESULTS: IgA and the polymeric immunoglobulin receptor/secretory component were present in a raft compartment. Raft association occurred posttranslationally within 30 minutes, preceding secretion into the culture medium. IgA labeling was seen primarily in enterocytes along the basolateral plasma membrane and over endosomes and small vesicles in the basolateral and apical regions of the cytoplasm. IgA and a brush border enzyme, aminopeptidase N, were colocalized in apical endosomes and small vesicles and were also frequently seen associated with the same vesicular profiles of glycolipid rafts. Colocalization of IgA and rab17, a small guanosine triphosphatase involved in transcytosis, was seen mainly along the basolateral plasma membrane and over basolateral endosomes and vesicles, but also in the apical region of the cytoplasm. CONCLUSIONS: IgA is transcytosed through a raft-containing compartment, most likely the apical endosomes. Our data also support the notion that rab17 is involved in transcytotic membrane traffic.

Localization and biosynthesis of aminopeptidase N in pig fetal small intestine.

BACKGROUND & AIMS: Little is known about the expression of brush border enzymes in fetal enterocytes. The aim of this study was to describe the localization and biosynthesis of porcine fetal aminopeptidase N. METHODS: This study was performed using histochemistry and immunoelectron microscopy and [35S]methionine labeling of cultured mucosal explants. RESULTS: Enzyme activity was present in the brush border membrane and extended into the apical cytoplasm. The protein was colocalized with cationized ferritin at the surface of endocytic structures including coated pits, vesicles, tubules, and large vacuoles in the apical cytoplasm. The transient high mannose-glycosylated form of fetal aminopeptidase N was processed to the mature complex-glycosylated form at a markedly slower rate than the enzyme in adult intestine. Likewise, dimerization occurred slowly compared with the adult form of aminopeptidase N, and it took place mainly after the Golgi-associated complex glycosylation. The enzyme had a biphasic appearance in the Mg(2+)-precipitated and microvillar fractions, indicating that the bulk of newly made aminopeptidase N is transported to the brush border membrane before appearing in the apical endocytic structures. CONCLUSIONS: In comparison with the adult enzyme, fetal aminopeptidase N has a more widespread subcellular distribution with substantial amounts present in apical endocytic compartments characteristic of the fetal enterocyte.

Distribution of three microvillar enzymes along the small intestinal crypt-villus axis.

Aminopeptidase N (ApN), dipeptidyl peptidase IV (DPP IV) and sucrose-isomaltase (S-I) are differentially expressed along the pig jejunum crypt-villus axis. Quantitative immunoelectron microscopy and enzyme cytochemistry show that DPP IV and S-I are expressed in enterocytes along the entire length of the axis, whereas ApN is found mainly in the villar and upper crypt enterocytes. All three enzymes are detected in the basolateral membrane at all levels along the crypt-villus axis, although ApN and S-I only occurred at low intensities in the villus region. The microvillar/basolateral labelling ratio for the three enzymes increases to a varying degree for the three enzymes along the axis suggesting that the sorting efficiency to the apical membrane improves at least for ApN and S-I as the cells mature. These findings might indicate that the enterocytes change from a transcytotic to a direct apical transport as the enterocytes mature.