Backgroud/Aims: Besides its anti-allergic properties as a histamine receptor antagonist, olopatadine stabilizes mast cells by inhibiting the release of chemokines. Since olopatadine bears amphiphilic features and is preferentially partitioned into the lipid bilayers of the plasma membrane, it would induce some morphological changes in mast cells and thus affect the process of exocytosis. Methods: Employing the standard patch-clamp whole-cell recording technique, we examined the effects of olopatadine and other anti-allergic drugs on the membrane capacitance (Cm) in rat peritoneal mast cells during exocytosis. Using confocal imaging of a water-soluble fluorescent dye, lucifer yellow, we also examined their effects on the deformation of the plasma membrane. Results: Low concentrations of olopatadine (1 or 10 µM) did not significantly affect the GTP-γ-S-induced increase in the Cm. However, 100 µM and 1 mM olopatadine almost totally suppressed the increase in the Cm. Additionally, these doses completely washed out the trapping of the dye on the cell surface, indicating that olopatadine counteracted the membrane surface deformation induced by exocytosis. As shown by electron microscopy, olopatadine generated inward membrane bending in mast cells. Conclusion: This study provides electrophysiological evidence for the first time that olopatadine dose-dependently inhibits the process of exocytosis in rat peritoneal mast cells. Such mast cell stabilizing properties of olopatadine may be attributed to its counteracting effects on the plasma membrane deformation in degranulating mast cells.
Leucine-rich repeat-containing G protein-coupled receptor (LGR)-4 is a G protein-coupled receptor (GPCR) with a seven-transmembrane domain structure. LGRs are evolutionally and structurally phylogenetic, classified into three subgroups and are members of the so-called orphan receptors whose ligands have yet to be identified. We generated knockout mice lacking Lgr4(Gpr48) by targeted deletion of part of exon 18, which codes for the transmembrane and signal-transducing domains of the receptor. Lgr4 null mice were born at much less than the 25% expected frequency from crosses of Lgr4 heterozygous mice (Lgr4+/–). Lgr4 null mice that survived in utero died shortly after birth in almost all cases. We observed striking renal hypoplasia in the null mice, accompanied by elevated concentration of plasma creatinine. Histological analysis of the P0 null mouse kidney showed a notable decrease in the total number and density of the glomerulus. Thus, the function of Lgr4 is essential to regulate renal development in the mouse. This study suggests that the Lgr4 gene is a new and important member of LGRs involved in a group of genes responsible for hereditary disease in the kidney.
Background/Aims: Salicylate and chlorpromazine exert differential effects on the chemokine release from mast cells. Since these drugs are amphiphilic and preferentially partitioned into the lipid bilayers of the plasma membranes, they would induce some morphological changes in mast cells and thus affect the process of exocytosis. Methods: Employing the standard patch-clamp whole-cell recording technique, we examined the effects of salicylate and chlorpromazine on the membrane capacitance (Cm) during exocytosis in rat peritoneal mast cells. Using confocal imaging of a water-soluble fluorescent dye, lucifer yellow, we also examined their effects on plasma membrane deformation of the cells. Results: Salicylate dramatically accelerated the GTP-γ-S-induced increase in the Cm immediately after its application, whereas chlorpromazine significantly suppressed the increase. Treatment with salicylate increased the trapping of the dye on the cell surface, while treatment with chlorpromazine completely washed it out, indicating that both drugs induced membrane surface deformation in mast cells. Conclusion: This study demonstrated for the first time that membrane amphipaths, such as salicylate and chlorpromazine, may oppositely modulate the process of exocytosis in mast cells, as detected by the changes in the Cm. The plasma membrane deformation induced by the drugs was thought to be responsible for their differential effects.
Background: Anti-allergic drugs, such as tranilast and ketotifen, inhibit the release of chemokines from mast cells. However, we know little about their direct effects on the exocytotic process of mast cells. Since exocytosis in mast cells can be monitored electrophysiologically by changes in the whole-cell membrane capacitance (Cm), the absence of such changes by these drugs indicates their mast cell-stabilizing properties. Methods: Employing the standard patch-clamp whole-cell recording technique in rat peritoneal mast cells, we examined the effects of tranilast and ketotifen on the Cm during exocytosis. Using confocal imaging of a water-soluble fluorescent dye, lucifer yellow, we also examined their effects on the deformation of the plasma membrane. Results: Relatively lower concentrations of tranilast (100, 250 µM) and ketotifen (1, 10 µM) did not significantly affect the GTP-γ-S-induced increase in the Cm. However, higher concentrations of tranilast (500 µM, 1 mM) and ketotifen (50, 100 µM) almost totally suppressed the increase in the Cm, and washed out the trapping of the dye on the surface of the mast cells. Compared to tranilast, ketotifen required much lower doses to similarly inhibit the degranulation of mast cells or the increase in the Cm. Conclusions: This study provides electrophysiological evidence for the first time that tranilast and ketotifen dose-dependently inhibit the process of exocytosis, and that ketotifen is more potent than tranilast in stabilizing mast cells. The mast cell-stabilizing properties of these drugs may be attributed to their ability to counteract the plasma membrane deformation in degranulating mast cells.
Individuals with congenital renal hypoplasia display a defect in the growth of nephrons during development. Many genes that affect the initial induction of nephrons have been identified, but little is known about the regulation of postinductive stages of kidney development. In the absence of the growth factor bone morphogenic protein 7 (BMP7), kidney development arrests after induction of a small number of nephrons. The role of BMP7 after induction, however, has not been fully investigated. Here, we generated a podocyte-specific conditional knockout of BMP7 (Bmp7 flox/flox ;Nphs2-Cre ϩ [BMP7 CKO]) to study the role of podocyte-derived BMP7 in nephron maturation. By postnatal day 4, 65% of BMP7 CKO mice had hypoplastic kidneys, but glomeruli demonstrated normal patterns of laminin and collagen IV subunit expression. Developing proximal tubules, however, were reduced in number and demonstrated impaired cellular proliferation. We examined signaling pathways downstream of BMP7; the level of cortical phosphorylated Smad1, 5, and 8 was unchanged in BMP CKO kidneys, but phosphorylated p38 mitogen-activated protein kinase was significantly decreased. In addition, -catenin was reduced in BMP7 CKO kidneys, and its localization to intracellular vesicles suggested that it had been targeted for degradation. In summary, these results define a BMP7-mediated regulatory axis between glomeruli and proximal tubules during kidney development.
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