Keiko Fujikura

DNA Staining for Fluorescence and Laser Confocal Microscopy

We examined five nucleic acid binding fluorescent dyes, propidium iodide, SYBR Green I, YO-PRO-1, TOTO-3, and TO-PRO-3, for nuclear DNA staining, visualized by fluorescence and laser confocal microscopy. The optimal concentration, co-staining of RNA, and bleaching speeds were examined. SYBR Green I and TO-PRO-3 almost preferentially stained the nuclear DNA, and the other dyes co-stained the cytoplasmic RNA. RNAse treatment completely prevented the cytoplasmic RNA staining. In conventional fluorescence microscopy, these dyes can be used in combination with fluorescence-labeled antibodies. Among the dyes tested, TOTO-3 and TO-PRO-3 stained the DNAs with far-red fluorescence under red excitation. Under Kr/Ar-laser illumination, TOTO-3 and TO-PRO-3 were best suited as the nuclear staining dyes in the specimens immunolabeled with fluorescein and rhodamine (or Texas red).

Direct gene transfer into rat liver cells by in vivo electroporation

In vivo electro‐transfection efficiency and manner of transferred gene expression were investigated by fluorescence microscopic image analysis. Green fluorescent protein (GFP) gene was used as the genetic marker. Electroporation was carried out on the liver of live rats by use of disk electrodes mounted in the tips of tweezers, which were directly pressed onto the surface of a liver lobe in situ. Electroporation with eight electric pulses of 50 ms in duration at 50 V gave a good efficiency of transfection as judged by the induced GFP expression. Bright fluorescence of GFP appeared as dots, which were scattered around the area damaged by electroporation. The transfection efficiency increased as the amount of injected DNA was increased. The results indicate that the amount of induced gene expression can be controlled. Estimation of the efficiency of electro‐gene transfer using the fluorescence of GFP and digital analysis of microscopic images was useful to determine the optimum conditions for local gene therapy in tissues and organs.

Localization of the ATP-Sensitive K+ Channel Subunit Kir6.2 in Mouse Pancreas

Kir6.2, a member of the inward rectifier K+ channel family, is a component of the ATP-sensitive K+ (KATP) channel considered to play a key role in glucose-induced insulin secretion. We studied the distribution of Kir6.2 in mouse pancreas at the cellular level. The sites of Kir6.2 mRNA expression were determined by in situ hybridization histochemistry with a digoxigenin (DIG)-labeled antisense cRNA probe. The hybridization signal was unevenly present throughout the islets of Langerhans, while no distinct signal was detected in exocrine acinar cells. This distribution was confirmed by another cRNA probe complementary to a different region of Kir6.2 mRNA. In situ hybridization and immunofluorescence staining of serial sections with the anti-insulin, the anti-glucagon, and the anti-somato-statin antibodies showed Kir6.2 mRNA to be present in α-, β-, and δ-cells. Furthermore, immunofluorescence staining with antibody raised against Kir6.2 revealed that Kir6.2 protein is localized within the pancreatic islets and is not found in exocrine pancreas. Kir6.2 was further shown to be located together with insulin, glucagon, or somatostatin. The positive staining of Kir6.2 appeared concentrated along the contour of each islet cell, suggesting that Kir6.2 is at the plasma membrane of islet cells. These results suggest that Kir6.2, as a component of KATP channels, is an important molecule in the regulation of all the release of insulin, glucagon, and somatostatin.

Differential localization of organic cation transporters rOCT1 and rOCT2 in the basolateral membrane of rat kidney proximal tubules

Abstract. Organic cation transporters play an important role in the secretion of cationic drugs as well as endogenous cationic metabolites in the renal tubules. Immunoblotting showed the presence of organic cation transporter proteins, rOCT1 and rOCT2, in the rat kidney. By immunofluorescence microscopy, rOCT1 was shown to be concentrated in the proximal tubules in the renal cortex. rOCT2, on the other hand, was rich in the proximal tubules in the outer stripe of the outer medulla. Confocal microscopy revealed that both rOCT1 and rOCT2 were localized to the basolateral membranes of these tubule cells. These findings directly show that rOCT1 and rOCT2 are basolateral membrane proteins and are differentially distributed along the proximal tubules.

Immuno-localization of sulphonylurea receptor 1 in rat pancreas

Aims/hypothesis. A sulphonylurea receptor, SUR1, and an inward rectifier potassium channel, Kir6.2, reconstitute the ATP-sensitive K+ channel that mediates glucose-induced insulin secretion in pancreatic beta cells. We reported previously that Kir6.2 were localized at insulin-, glucagon-, and somatostatin-producing cells. In this new study we aimed to determine the distribution of SUR1 in rat pancreatic islets and to suggest the location of the ATP-sensitive K+ channels in the islet. Methods. Western blot analysis was carried out using two anti-SUR1 antibodies, which had been raised against different portions of rat SUR1. SUR1, Kir 6.2, and islet hormones were then localized by indirect immunofluorescence staining of the cryosections of rat pancreas. Results. In Western blot analysis, each of the anti-SUR1 antibodies detected a band at 140 kDa, which is close to the predicted molecular weight of SUR1, in the homogenate of isolated pancreatic islets. Double immunofluorescence staining of cryosections showed that SUR1 occurred all over the islets, and that SUR1 colocalized with insulin, glucagon, somatostatin, and pancreatic polypeptide. Kir6.2 was also shown to be present in pancreatic polypeptide cells. Conclusion/interpretation. Together with our previously reported data, the above findings indicate that KATP channels comprising SUR1 and Kir6.2 occur not only in beta cells but also in the alpha, delta, and pancreatic polypeptide cells of the pancreatic islets, suggesting that therapeutic sulphonylureas could act on these cells directly. [Diabetologia (1999) 42: 1204–1211]

Localization of motilin-immunopositive cells in the rat intestine by light microscopic immunocytochemistry

Motilin-immunopositive cells (Mo cells) are known to exist in the upper small intestine of many species including man. However, the possible presence of Mo cells in the rat gastrointestine has remained obscure because antiserum against it raised in rabbit was found not to cross-react with motilin in the rat gastrointestine. The present study was designed to investigate the distribution of Mo cells in the rat gastrointestine by the peroxidase-conjugated second antibody method using newly raised chicken anti-motilin serum (CPV3). This antiserum was suggested to recognize the N-terminal region of the motilin molecule by enzyme-linked immunosorbent assays and immunocytochemical absorption test. Mo cells detected in the rat gastrointestine by immunocytochemistry were found to be distributed in the duodenum (1.5 cells/mm2), jejunum (2.2 cells/mm2), and ileum (0.028 cells/mm2), and no positive cells were found in the gastric body, gastric antrum, cecum, colon, or pancreas. The immunopositive cells in the rat intestine were spindle shaped or polygonal, scattered throughout the epithelium of the villi and crypts, and similar to those commonly observed in the upper small intestine of other species. These results indicate for the first time that motilin-immunopositive cells do exist in the rat intestine.

The apical localization of SGLT1 glucose transporter is determined by the short amino acid sequence in its N-terminal domain.

SGLT1, an isoform of Na+-dependent glucose cotransporters, is localized at the apical plasma membrane in the epithelial cells of the small intestine and the kidney, where it plays a pivotal role in the absorption and reabsorption of sugars, respectively. To search the domain responsible for the apical localization of SGLT1, we constructed an N-terminal deletion clone series of rat SGLT1 and analyzed the localization of the respective products in Madin-Darby canine kidney (MDCK) cells. The products of N-terminal deletion clones up to the 19th amino acid were localized at the apical plasma membrane, whereas the products of N-terminal 20- and 23-amino-acid deletion clones were localized along the entire plasma membrane. Since single-amino-acid mutations of either D28N or D28G in the N-terminal domain give rise to glucose/galactose malabsorption disease, we examined the localization of these mutants. The products of D28N and D28G clones were localized in the cytoplasm, showing that the aspartic acid-28 may be essential for the delivery of SGLT1 to the plasma membrane. These results suggest that a short amino acid sequence of the N-terminal domain of SGLT1 plays important roles in plasma membrane targeting and specific apical localization of the protein.

Na^+ -dependent glucose transporter SGLT1 is localized in the apical plasma membrane upon completion of tight junction formation in MDCK cells

SGLT1, an isoform of Na+-dependent glucose transporters, is localized at the apical plasma membrane in the epithelial cells of the small intestine and the kidney. In the present study we examined its location in SGLT1 cDNA-transfected MDCK cells, which form an epithelial sheet connected by tight junctions in culture. Formation of tight junctions was monitored by staining for occludin, an integral tight junction protein. In the cells demarcated by an uninterrupted occludin meshwork, SGLT1 was specifically localized at the apical plasma membrane, showing that SGLT1 has a signal to accomplish this restricted localization. In the cells with little or no occludin accumulation in the tight junction, however, SGLT1 was present along the entire aspect of the plasma membrane. Similar distribution of SGLT1 was observed in the cells as long as the occludin meshwork remained incomplete. These observations sugget that apical localization of SGLT1 occurs upon the completion of the uninterrupted meshwork of tight junctions.

Biotinyl C-terminal-extended motilin as a biologically active receptor probe

The synthesis, purification, and characterization of biotinylated analogues of motilin are reported. The C-terminal of canine motilin was extended by the addition of a cysteine residue, and then biotinylated. Biotinyl motilin was purified by following HPLC and characterized by amino acid analysis. Biotinylation of the ligand was confirmed by ELISA assay with the avidin-biotin system. Biotinyl motilin showed similar affinity for binding to rabbit gastric membrane fraction compared to unlabeled canine motilin, and also retained functional activity in its ability to cause contraction of rabbit duodenal segments. To determine the binding of biotinyl motilin in isolated rabbit antral smooth muscle, cells were incubated with the biotinyl motilin with and without excess of unlabeled motilin. Subsequent addition of avidin-biotinylated peroxidase complex showed the distribution of reaction products over the cell surface. Bioactive biotinyl motilin provides a useful probe for the demonstration of cell surface motilin receptors and will facilitate receptor purification and characterization.

Histochemistry of acetylcholine receptors and acetylcholinesterase during the formation of neuromuscular junctions in the urodele Hynobius nigrescens

The development and structure of neuromuscular junctions (n‐m‐js) in stylopodia of forelimbs of larvae and adults of Hynobius nigrescens were histochemically investigated for acetylcholine receptors (AChRs) and acetylcholinesterase (AChE) activity. In larvae, the tetramethyl rhodamine‐labelled α‐bungarotoxin (TMR‐αBT) positive areas appeared either as small fluorescent spots or fluorescent plates of various sizes. The mature fluorescent plate was found to be formed by the successive addition of spots, and the plates thus established were arranged linearly parallel to the axes of muscle fibers. AChE activity occurred almost exactly at TMR‐αBT‐positive sites. In adults, plate assemblies were often seen as a single dotted line (type A form) for both AChR binding and AChE reaction, in contrast to larval n‐m‐js in which AChE activity appeared as a continuous line. By applying the TMR‐αBT method, two other forms of adult n‐m‐js were observed: type B, a long dotted line several plates wide; and type C, with a cluster of plates randomly dispersed over the whole width of the muscle fiber. It seems that protoforms of the latter two forms of n‐m‐js appear in the muscles just before and after metamorphosis.