Kuniaki Takata

ERYTHROCYTE/HEPG2-TYPE GLUCOSE TRANSPORTER IS CONCENTRATED IN CELLS OF BLOOD-TISSUE BARRIERS

In search of possible diverse roles of glucose transporters (GTs), we examined whether any GTs are present in blood-tissue barriers where selective flow of glucose from blood to tissue cells is critically important. We found in rat that the erythrocyte/HepG2-type GT is localized in all the limiting plasma membranes known to serve as blood-tissue barriers, whether the barriers are endothelial type (brain, iris, inner retina, peripheral nerve) or epithelial type (choroid plexus, ciliary body, outer retina, peripheral nerve, placenta), except for plasma membranes in testis and thymus where no appreciable amount of the GT was found. The erythrocyte/HepG2-type GT may play a vital role for the entry of glucose into these firmly guarded tissues.

Localization of erythrocyte/HepG2-type glucose transporter (GLUT1) in human placental villi

SummaryThe syncytiotrophoblast covering the surface of the placental villi contains the machinery for the transfer of specific substances between maternal and fetal blood, and also serves as a barrier. Existence of a facilitated-diffusion transporter for glucose in the syncytiotrophoblast has been suggested. Using antibodies to erythrocyte/HepG2-type glucose transporter (GLUT1), one isoform of the facilitated-diffusion glucose transporters, we detected a 50 kD protein in human placenta at term. By use of immunohistochemistry, GLUT1 was found to be abundant in both the syncytiotrophoblast and cytotrophoblast. Endothelial cells of the fetal capillaries also showed positive staining for GLUT1. Electron-microscopic examination revealed that GLUT1 was concentrated at both the microvillous apical plasma membrane and the infolded basal plasma membrane of the syncytiotrophoblast. Plasma membrane of the cytotrophoblast was also positive for GLUT1. GLUT1 at the apical plasma membrane of the syncytiotrophoblast may function for the entry of glucose into its cytoplasm, while GLUT1 at the basal plasma membrane may be essential for the exit of glucose from the cytoplasm into the stroma of the placental villi. Thus, GLUT1 at the plasma membranes of syncytiotrophoblast and endothelial cells may play an important role in the transport of glucose across the placental barrier.

The role of N-glycosylation in the targeting and stability of GLUT1 glucose transporter

The cDNAs encoding the GLUT1 glucose transporter protein were altered by site‐directed mutagenesis at consensus sites for the addition of N‐linked glycosylation. These cDNAs were transfected into CHO cells with an expression vector and the subcellular distribution and stability of the expressed glycosylation‐defective GLUT1 protein were analyzed. Immunohistochemical analysis with a specific antibody demonstrated that a significant portion of glycosylation‐defective GLUT1 protein remained in the intracellular compartment. By contrast, most of the wild‐type GLUT1 proteins expressed with the same procedures resided in the plasma membranes. Metabolic labeling studies revealed that the half‐life of the glycosylation‐defective GLUT1 protein was significantly shorter than that of wild‐type GLUT1 protein. These results indicate that N‐glycosylation of the glucose transporter affects its intracellular targeting and protein stability.

Distribution of glycoconjugates in normal human skin using biotinyl lectins and avidin-horseradish peroxidase

SummaryLectin binding patterns in normal human skin were studied using five different biotinyl lectins and avidin-horseradish peroxidase. The staining pattern was specific for each lectin. In the epidermis, peanut agglutinin (PNA) and soybean agglutinin (SBA) preferentially stained the cell membranes of keratinocytes in the spinous and granular cell layers, indicating changes in the saccharide residues during keratinocyte differentiation. In the secretory segment of an eccrine sweat gland, the superficial cells gave a strong granular staining with Ricinus communis agglutinin (RCA). Dolichos biflorus agglutinin (DBA) and SBA, on the other hand, strongly stained the basal cells. With these lectins, two types of cells in the secretory segment were clearly distinguished. These results show that (1) PNA and SBA binding sites increase during the course of keratinocyte differentiation, and (2) RCA, DBA, and SBA are good markers to distinguish two types of cells in the secretory segment of an eccrine sweat gland.

Immunohistochemical localization of Na+-dependent glucose transporter in rat jejunum

SummaryGlucose is actively absorbed via a Na+-dependent active glucose transporter (Na-GT) in the small intestine. We raised a polyclonal antibody against the peptide corresponding to amino acids 564–575 of rabbit intestinal Na-GT, and localized it immunohistochemically in the rat jejunum. By means of immunofluorescence staining, Na-GT was located at the brush border of the absorptive epithelial cells of the intestinal villi. Electron-microscopic examination showed that Na-GT was localized at the plasma membrane of the apical microvilli of these cells. Little Na-GT was found at the basolateral plasma membrane. Along the crypt-villus axis, all of the absorptive epithelial cells in the villus were positive for Na-GT. In addition to the brush border staining, the supranuclear positive staining, which was shown to be the Golgi apparatus by use of electron microscopy, was seen in cells located between the base to the middle of the villus. Cells in crypts exhibited little or no staining for Na-GT. Goblet cells scattered in the intestinal epithelium were negative for Na-GT staining. These observations show that Na-GT is specific to the apical plasma membrane of the absorptive epithelial cells, and that the onset of Na-GT synthesis may occur near the crypt-villus junction.

Lectin-binding pattern in normal human gastric mucosa. A light and electron microscopic study.

SummaryNormal human gastric mucosal cells were examined by light and electron microscopy using lectins as a probe. The ABC method was used with biotinylated lectins for light microscopy and HRP-labeled lectins for electron microscopy. The human gastric mucosal cells revealed specific binding patterns for each lectin by light microscopy. Among the lectins tested, in particular, DBA gave a characteristic pattern. It specifically stained the supranuclear region of surface epithelial cells and the perinuclear region of parietal cells. By electron microscopy, the stacked cisternae and the vesicles of the Golgi apparatus of the surface epithelial cells were positive for the DBA staining. These results show that the DBA-positive supranuclear region observed by light microscopy corresponds to the Golgi apparatus. In the parietal cells, DBA, RCA and ConA bound to the intracellular secretory canaliculi which are invaginations of the cell membrane running around the nucleus in the cytoplasm. Therefore, the tubular perinuclear positive region observed by light microscopy corresponds to the membranes of the intracellular secretory canaliculi. In addition, the ConA reagent stained the endoplasmic reticulum, Golgi apparatus, nuclear envelope, and cell membrane of the parietal cell, which explains the diffuse cytoplasmic staining observed at the light microscopic level with this lectin. Lectins have proved to be very useful for the evaluation of in situ cytochemical aspects of the glycoconjugates characteristic to human gastric mucosal cells.

Changes in Soybean Agglutinin (SBA) and Peanut Agglutinin (PNA) Binding Pattern in the Epidermis of the Developing Chick Embryo

Lectin binding pattern in the developing chick embryonic epidermis was studied using peroxidase labeling method. The epidermis of the 13‐day‐old embryo is in an undifferentiated state. Little binding of soybean agglutinin (SBA), specific for N‐acetyl‐D‐galactosamine, and peanut agglutinin (PNA), specific for β‐D‐galactose, was seen in such epidermal cells. As the epidermis developed toward keratinization, the cell membrane of the differentiating flattened cells was positively stained with SBA and PNA. The positive staining was also seen in the supranuclear region of the cells located between the flattened cells and the basal cells. The basal cells remained unstained in all the stages of development. Similar staining pattern with SBA and PNA was seen in the cultured skin explants during the epidermal differentiation in vitro. These observations show that the SBA‐ and PNA‐reactive glycoconjugates accumulate during the epidermal cell differentiation, suggesting their important roles in the maintenance of the ordered structure of the epidermis.

Immunolocalization of glucose transporter GLUT1 in the rat placental barrier : possible role of GLUT1 and the gap junction in the transport of glucose across the placental barrier

GLUT1 is an isoform of facilitated-diffusion glucose transporters and has been shown to be abundant in cells of blood-tissue barriers. Using antibodies against GLUT1, we investigated the immunohistochemical localization of GLUT1 in the rat placenta. Rat placenta is of the hemotrichorial type. Three cell layers (from the maternal blood side inward) cytotrophoblast and syncytiotrophoblasts I and II, lie between the maternal and fetal bloodstreams. GLUT1 was abundant along the invaginating plasma membrane facing the cytotrophoblast and the syncytiotrophoblast I. Also, the infolded basal plasma membrane of the syncytiotrophoblast II was rich in GLUT1. Apposing plasma membranes of syncytiotrophoblasts I and II, however, had only a small amount of GLUT1. Numerous gap junctions were seen between syncytiotrophoblasts I and II. Taking into account the localization of GLUT1 and the gap junctions, we suggest a possible major transport route of glucose across the placental barrier, as follows: glucose in the maternal blood passes freely through pores of the cytotrophoblast. Glucose is then transported into the cytoplasm of the syncytiotrophoblast I via GLUT1. Glucose enters the syncytiotrophoblast II throught the gap junctions. Finally glucose leaves the syncytiotrophoblast II via GLUT1 and enters the fetal blood through pores of the endothelial cells.

Induction of the alpha-type keratinization by hydrocortisone in embryonic chick skins grown in a chemically defined medium: An electron microscopic study☆

Abstract Previous biochemical analyses showed the differential accumulation of the epidermal structural protein, which yielded S -carboxymethylated epidermal protein A (SCMEp A ), in the hydrocortisone-induced in vitro keratinization of 13-day embryonic chick tarsometatarsal skin growing in a chemically defined medium (Sugimoto et al. , 1974). Fine structural features of such an in vitro keratinization process were studied by electron microscopy in the present work. After 2 days of culture with hydrocortisone (0.02 or 0.2 μ M ), development of the tonofilament bundles occurred to some extent, but the keratinized layer was not formed. Keratinization was observed after 4 days of culture with hydrocortisone (0.02 or 0.2 μ M ). Desmosomes and tonofilament bundles were prominent in the cytoplasm of the basal and intermediate cell layers of the epidermis. Keratohyalin granules and lipid droplets appeared in the upper layer. Degradation of cellular organelles such as nuclei and mitochondria then proceeded, leaving only filament bundles and electron-dense amorphous masses in the cytoplasm. Thickened cellular envelopes, which are characteristic of keratinized cells, were also observed. These features are characteristic of alpha-type keratinization which is common for other body surfaces. Beta-type keratinization, typical of normal embryonic scales, was not observed even after 6 days of culture with hydrocortisone. Keratinization of embryonic subperiderm of beta-type did not occur either. These ultrastructural observations clearly showed that hydrocortisone induced the alpha-type keratinization. It was also suggested that SCMEp A was closely related to alpha-type keratinization.

Localization of Forssman glycolipid and GM1 ganglioside intracellularly and on the surface of germ cells during fetal testicular and ovarian development of mice.

SummaryChanges in the expression pattern and intracellular localization of Forssman glycolipid (FA) and GM1 ganglioside (GM1) in fetal mouse gonads were examined during germ cell differentiation by immunofluorescence microscopy and immunoelectron microscopy.In male germ cells from the 12th to 14th day p.c., anti-FA binding was localized in granular structures aggregated on one side of the cytoplasm and/or in the plasma membrane. On day 16 p.c., some germ cells still showed patch-like positive reactions in the plasma membrane, but by day 18 p.c., positive reactions for FA had completely disappeared. The female germ cells showed granular bindings of anti-FA scattered throughout their cytoplasm during the 13th to 16th day p.c., although the positive reactions in female germ cells on day 12 p.c. tended to be found in one side of cytoplasm and/or plasma membrane similar to those in male germ cells from 12th to 14th day p.c. On day 18 p.c., positive reactions remained in the plasma membrane of some germ cells, but these positive reactions disappeared before birth. Immunoelectron microscopic observation showed that the sites of anti-FA bindings were equivalent to the “small dense bodies” (SDB) and the Golgi lamellae both in male and female germ cells. On the other hand, GM1 was not detected in male germ cells at any time during fetal testicular development, whereas an anti-GM1 reaction was detected in the plasma membrane of female germ cells from the 16th to 18th day p.c. (oocytes in the first meiotic prophase).Therefore, these results indicate that kinetic translocation of FA between the plasma membrane and the SDB and Golgi lamellae takes place during germ cell differentiation in fetal gonads. Moreover, the ganglioside composition containing GM1 seems to change in association with the first meiotic prophase.