Kimio Akagawa

Imaging analysis reveals mechanistic differences between first- and second-phase insulin exocytosis

The mechanism of glucose-induced biphasic insulin release is unknown. We used total internal reflection fluorescence (TIRF) imaging analysis to reveal the process of first- and second-phase insulin exocytosis in pancreatic β cells. This analysis showed that previously docked insulin granules fused at the site of syntaxin (Synt)1A clusters during the first phase; however, the newcomers fused during the second phase external to the Synt1A clusters. To reveal the function of Synt1A in phasic insulin exocytosis, we generated Synt1A-knockout (Synt1A−/−) mice. Synt1A−/− β cells showed fewer previously docked granules with no fusion during the first phase; second-phase fusion from newcomers was preserved. Rescue experiments restoring Synt1A expression demonstrated restoration of granule docking status and fusion events. Inhibition of other syntaxins, Synt3 and Synt4, did not affect second-phase insulin exocytosis. We conclude that the first phase is Synt1A dependent but the second phase is not. This indicates that the two phases of insulin exocytosis differ spatially and mechanistically.

Expression and functional role of syntaxin 1/HPC-1 in pancreatic beta cells. Syntaxin 1A, but not 1B, plays a negative role in regulatory insulin release pathway.

Syntaxin 1/HPC-1 is an integral membrane protein, which is thought to be implicated in the regulation of synaptic neurotransmitter release. We investigated syntaxin 1 expression in pancreatic β cells and the functional role of syntaxin 1 in the insulin release mechanism. Expression of syntaxin 1A, but not 1B, was detected in mouse isolated islets by the reverse transcriptase-polymerase chain reaction procedure. An immunoprecipitation study of metabolically labeled islets with an anti-rat syntaxin 1/HPC-1 antibody demonstrated syntaxin 1A protein with an apparent molecular mass of ∼35 kDa. Immunohistochemistry of the mouse pancreas demonstrated that syntaxin 1/HPC-1 was present in the plasma membranes of the islets of Langerhans. In order to determine the functional role of syntaxin 1 in pancreatic β-cells, rat syntaxin 1A or 1B was overexpressed in mouse βTC3 cells using the transient transfection procedure. Transfection of βTC3 cells with either syntaxin 1 resulted in approximately 7-fold increases in their immunodetectable protein levels. Glucose-stimulated insulin release by syntaxin 1A-overexpressing cells was suppressed to about 50% of the level in control cells, whereas insulin release by syntaxin 1B-overexpressing and control cells did not differ. Next, we established stable βTC3 cell lines that overexpressed syntaxin 1A and used them to evaluate the effect of syntaxin 1A on the regulatory insulin release pathway. Two insulin secretogogues, 4-β-phorbol 12-myristate 13-acetate or forskolin, increased insulin release by untransfected βTC3 cells markedly, but their effects were diminished in syntaxin 1A-overexpressing βTC3 cells. Glucose-unstimulated insulin release and the proinsulin biosynthetic rate were not affected by syntaxin 1A overexpression, indicating a specific role of syntaxin 1A in the regulatory insulin release pathway. Finally, in vitro binding assays showed that syntaxin 1A binds to insulin secretory granules, indicating an inhibitory role of syntaxin 1A in insulin exocytosis via its interaction with vesicular proteins. These results demonstrate that syntaxin 1A is expressed in the islets of Langerhans and functions as a negative regulator in the regulatory insulin release pathway.

Analysis of Knock-Out Mice to Determine the Role of HPC-1/Syntaxin 1A in Expressing Synaptic Plasticity

The protein HPC-1/syntaxin 1A is abundantly expressed in neurons and localized in the neuronal plasma membrane. It forms a complex with SNAP-25 (25 kDa synaptosomal-associated protein) and VAMP-2 (vesicle-associated membrane protein)/synaptobrevin called SNARE (a soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptor) complex, which is considered essential for synaptic vesicle exocytosis; thus, HPC-1/syntaxin 1A is considered crucial for synaptic transmission. To examine the physiological function of HPC-1/syntaxin 1A in vivo, we produced knock-out (KO) mice by targeted gene disruption. Although HPC-1/syntaxin 1A expression was completely depleted without any effect on the expression of other SNARE proteins, the KO mice were viable. They grew normally, were fertile, and displayed no difference in appearance compared with control littermate. In cultured hippocampal neurons derived from the KO mice, the basic synaptic transmission in vitro was normal. However, the mutant mice had impaired long-term potentiation in the hippocampal slice. Also, although KO mice exhibited normal spatial memory in the hidden platform test, consolidation of conditioned fear memory was impaired. Interestingly, the KO mice had impaired conditioned fear memory extinction. These observations suggest that HPC-1/syntaxin 1A may be closely related to synaptic plasticity.

Mitochondrial hyperpolarization after transient oxygen-glucose deprivation and subsequent apoptosis in cultured rat hippocampal neurons

Mitochondrial membrane potential (MMP) regulates the production of high-energy phosphate and apoptotic cascade, both occurring after ischemic impact. The timed profile of MMP differing from grading ischemic impact has to be determined. Primary rat hippocampal cultures were exposed to oxygen-glucose deprivation (OGD) for 30, 60, and 90 min and then were reoxygenated. MMP was expressed as a voltage-dependent dye, JC-1 fluorescence, under confocal microscopy. Cell viability was assessed by calcein AM and ethidium homodimer, each at 3 hours and 24 hours after 30, 60, and 90 min of OGD. The appearance of apoptosis was also evaluated by the TUNEL method at 24 hours. Hyperpolarization of MMP (2.31+/-0.94 normalized JC-1 fluorescence ratio between red and green) was observed during reoxygenation after 30 min OGD, while 60 min OGD induced depolarization (0.66+/-0.22, Valinomycin (potassium ionophore)-induced depolarization: 0.53+/-0.19). The fluorescence of mitochondria became weak after 90 min OGD. Most of the neurons were shrunken after 90 min and neurons were TUNEL-positive 24 hours after 30 min OGD, although most neurons were viable at 3 hours. A longer period of OGD induced necrosis, and most neurons remained viable after only 3 hours. Our data present that the short (30 min) OGD induced hyperpolarization of MMP during reoxygenation, while a longer OGD (60 or 90 min) induced depolarization and acute necrosis. Neurons were still viable even during hyperpolarization of mitochondria, but this hyperpolarization appears to be linked to subsequent apoptotic change.

Syntaxin 1A is expressed in airway epithelial cells, where it modulates CFTR Cl– currents

The CFTR Cl(-) channel controls salt and water transport across epithelial tissues. Previously, we showed that CFTR-mediated Cl(-) currents in the Xenopus oocyte expression system are inhibited by syntaxin 1A, a component of the membrane trafficking machinery. This negative modulation of CFTR function can be reversed by soluble syntaxin 1A peptides and by the syntaxin 1A binding protein, Munc-18. In the present study, we determined whether syntaxin 1A is expressed in native epithelial tissues that normally express CFTR and whether it modulates CFTR currents in these tissues. Using immunoblotting and immunofluorescence, we observed syntaxin 1A in native gut and airway epithelial tissues and showed that epithelial cells from these tissues express syntaxin 1A at >10-fold molar excess over CFTR. Syntaxin 1A is seen near the apical cell surfaces of human bronchial airway epithelium. Reagents that disrupt the CFTR-syntaxin 1A interaction, including soluble syntaxin 1A cytosolic domain and recombinant Munc-18, augmented cAMP-dependent CFTR Cl(-) currents by more than 2- to 4-fold in mouse tracheal epithelial cells and cells derived from human nasal polyps, but these reagents did not affect CaMK II-activated Cl(-) currents in these cells.

Serotonin regulates glucose-stimulated insulin secretion from pancreatic β cells during pregnancy

Significance During pregnancy, maternal insulin secretion increases markedly. This increase is not simply a response to increased demand, as it precedes the insulin resistance that develops late in pregnancy, nor is it solely a result of increased β cell mass, as secretion per beta cell increases as well. Here we show that the increased islet serotonin induced by pregnancy signals through the 5-HT3 receptor (Htr3) to increase insulin secretion dramatically. Htr3 signaling increases the excitability of the β cell membrane, thereby decreasing the threshold for insulin secretion. These studies elucidate the mechanism for pregnancy-induced increase in insulin release. In preparation for the metabolic demands of pregnancy, β cells in the maternal pancreatic islets increase both in number and in glucose-stimulated insulin secretion (GSIS) per cell. Mechanisms have been proposed for the increased β cell mass, but not for the increased GSIS. Because serotonin production increases dramatically during pregnancy, we tested whether flux through the ionotropic 5-HT3 receptor (Htr3) affects GSIS during pregnancy. Pregnant Htr3a−/− mice exhibited impaired glucose tolerance despite normally increased β cell mass, and their islets lacked the increase in GSIS seen in islets from pregnant wild-type mice. Electrophysiological studies showed that activation of Htr3 decreased the resting membrane potential in β cells, which increased Ca2+ uptake and insulin exocytosis in response to glucose. Thus, our data indicate that serotonin, acting in a paracrine/autocrine manner through Htr3, lowers the β cell threshold for glucose and plays an essential role in the increased GSIS of pregnancy.

Mitochondrial membrane potential and intracellular ATP content after transient experimental ischemia in the cultured hippocampal neuron.

Ischemia limits the delivery of oxygen and glucose to cells and disturbs the maintenance of mitochondrial membrane potential (MMP). MMP regulates the production of high-energy phosphate and apoptotic cascading. Thus, MMP is an important parameter determining the fate of neurons. Differences in the time course of MMP according to the grading of the ischemic impact have not been clarified. MMP and intracellular ATP contents were monitored before and after short-term oxygen-glucose deprivation. A primary hippocampal culture seeded in a 35 mm fenestrated dish for fluorescence microscopy was mounted in a sealed chamber for an anaerobic incubation. A continuous flow of 100% nitrogen into the chamber and a replacement of glucose-free medium allowed the condition of oxygen-glucose deprivation (OGD), thereby extrapolating ischemia. MMP was evaluated by the fluorescence of a voltage-dependent dye, JC-1, under fluorescence microscopy. The intracellular ATP content was evaluated in a hippocampal culture seeded in a 96-well plate by the luciferin-luciferase reaction after a designated period of OGD. During OGD, MMP decreased to 0.72+/-0.03 (normalized JC-1 fluorescence), then increased to the hyperpolarized level 1.99+/-0.12 during 60 min reoxygenation after 30 min OGD. MMP after 60 min OGD decreased and recovered occasionally during reoxygenation. After 90 min OGD and reoxygenation, MMP was reduced and never recovered. The intracellular ATP content was 8.1+/-6.6 and 3.2+/-1.9% after 30 min OGD and 30 min reoxygenation following 30 min OGD, respectively; 60 min OGD did not significantly change these levels (7.1+/-5.8, 2.6+/-0.5%). Hyperpolarization after OGD did not accompany ATP production. This observation suggests the inhibition of electron reentry into an inner membrane during reoxygenation and the disturbance of FoF1-ATP synthase. This pathological finding of an energy-producing system after OGD may provide a clue to explain post-ischemic energy failure.

Neuron-specific antigen HPC-1 from bovine brain reveals strong homology to epimorphin, an essential factor involved in epithelial morphogenesis: Identification of a novel protein family

We have already cloned the cDNA for the HPC-1 antigen, a neuron-specific protein antigen from the rat brain. Here we report the molecular cloning of the bovine HPC-1 antigen homologue, and much strong sequence conservation between rat and bovine. By searching the recent protein data base, it was found that the HPC-1 antigen revealed unusual similarity to epimorphin which was mesenchymal factor related to the morphogenesis of primitive epidermal tissues in embryonic stages. We also found that the HPC-1 antigen was identical to p35A (syntaxin) which bound both to a synaptic vesicle protein and to N-type calcium channel. Although the relationship of the physiological functions, structures and topologies along cellular membrane between the HPC-1 antigen and epimorphin have not been consistent yet, these two proteins belong to a novel protein family.

Neuron specific expression of a membrane protein, HPC-1: tissue distribution, and cellular and subcellular localization of immunoreactivity and mRNA

The monoclonal antibody HPC-1 recognizes a protein antigen in the hippocampus, and its specific reactivity to the plasma membrane of the amacrine cell somas and the inner plexiform layer in rat retina has been reported. Sequencing the cDNA indicated in our previous study that the HPC-1 antigen was a membrane protein. By means of immunoblotting, an antiserum against the fusion protein of Escherichia coli beta-galactosidase and the HPC-1 antigen detected several proteins of about 35 kDa in the nervous tissues including retina, cerebral cortex, hippocampus, cerebellum and spinal cord, but no signal was obtained in the non-neuronal tissues. Immunofluorescent histochemistry of the various rat tissues revealed that the HPC-1 antigen was confined to the nervous system, including the matrices of the cerebral cortex and hippocampus, the molecular layer, membranes of granular cell somas and glomeruli in the cerebellum and gray matter of spinal cord. However, little staining was seen in the white matter of the central nervous tissues. Thus, the HPC-1 antigen was accumulated in the synapse-rich regions of neuronal cells. In situ hybridization revealed that the HPC-1 mRNA was present in most, if not all, neurons in the central and peripheral nervous systems except for the retina. In the retina, mRNA signals were detected in amacrine and ganglion cells in which HPC-1 immunoreactivity was absent in their soma, suggesting polarized localization of the HPC-1 mRNA on the ganglion cell axon terminal.

Neuroprotective effect of propofol on necrosis and apoptosis following oxygen–glucose deprivation—Relationship between mitochondrial membrane potential and mode of death

Mitochondrial membrane potential (MMP) appears to play an important role in apoptotic cascade and has been proposed as an index for apoptosis or necrosis. We examined the neuroprotective effect of propofol on mode of death, focusing on MMP. Hippocampal cell culture was divided into three groups: control, oxygen-glucose deprivation for 30 min (30OGD), 90 min (90OGD). Propofol was added to each culture group at a concentration of 0 microM (Vehicle), 0.1 microM (Pro0.1) or 1.0 microM (Pro1.0). MMP was expressed as normalized JC-1 fluorescence. ATP content was assayed using the luciferin-luciferase reaction. Neuronal viability and appearance of apoptosis were also assessed. ATP content was decreased after OGD (0.276 +/- 0.115 microM/microg (control), 0.172 +/- 0.125 microM/microg (30OGD) and 0.096 +/- 0.092 microM/microg (90OGD)). Propofol did not alter ATP content. MMP was hyperpolarized after 30OGD (1.26 +/- 0.23 (vehicle), 1.29 +/- 0.13 (Pro0.1) and 1.18 +/- 0.06 (Pro1.0)) but was depolarized after 90OGD (0.77 +/- 0.04 (vehicle), 0.89 +/- 0.04 (Pro0.1), but Pro1.0 prevented depolarization (1.03 +/- 0.15 (P < 0.05)). Viability of cells significantly decreased to 50.3 +/- 5.7% (vehicle), 46.1 +/- 7.5% (Pro0.1), but Pro1.0 significantly salvaged neurons 65.1 +/- 6.2% (higher than vehicle and Pro0.1 value, P < 0.05) after 90OGD. At 24 h after OGD, TUNEL-positive cells were increased to 34.5 +/- 6.2% (vehicle), 26.7 +/- 7.9% (Pro0.1) and 30.4 +/- 7.1% (Pro1.0) in the 30OGD group. No pharmacological effect of propofol on the incidence of apoptosis was found. Propofol inhibited acute neuronal death accompanied with the maintenance of MMP but did not prevent subsequent apoptosis. Propofol induces a moratorium on neuronal death, during which pharmacological intervention might be able to prevent cell death.