Increased Lipolysis and Energy Expenditure in a Mouse Model with Severely Impaired Glucagon Secretion

10.1371/journal.pone.0026671PLoS ONE610

Neuronal Calcium Sensor Synaptotagmin-9 Is Not Involved in the Regulation of Glucose Homeostasis or Insulin Secretion

BACKGROUND:Insulin secretion is a complex and highly regulated process. It is well established that cytoplasmic calcium is a key regulator of insulin secretion, but how elevated intracellular calcium triggers insulin granule exocytosis remains unclear, and we have only begun to define the identities of proteins that are responsible for sensing calcium changes and for transmitting the calcium signal to release machineries. Synaptotagmins are primarily expressed in brain and endocrine cells and exhibit diverse calcium binding properties. Synaptotagmin-1, -2 and -9 are calcium sensors for fast neurotransmitter release in respective brain regions, while synaptotagmin-7 is a positive regulator of calcium-dependent insulin release. Unlike the three neuronal calcium sensors, whose deletion abolished fast neurotransmitter release, synaptotagmin-7 deletion resulted in only partial loss of calcium-dependent insulin secretion, thus suggesting that other calcium-sensors must participate in the regulation of insulin secretion. Of the other synaptotagmin isoforms that are present in pancreatic islets, the neuronal calcium sensor synaptotagmin-9 is expressed at the highest level after synaptotagmin-7. METHODOLOGY/PRINCIPAL FINDINGS:In this study we tested whether synaptotagmin-9 participates in the regulation of glucose-stimulated insulin release by using pancreas-specific synaptotagmin-9 knockout (p-S9X) mice. Deletion of synaptotagmin-9 in the pancreas resulted in no changes in glucose homeostasis or body weight. Glucose tolerance, and insulin secretion in vivo and from isolated islets were not affected in the p-S9X mice. Single-cell capacitance measurements showed no difference in insulin granule exocytosis between p-S9X and control mice. CONCLUSIONS:Thus, synaptotagmin-9, although a major calcium sensor in the brain, is not involved in the regulation of glucose-stimulated insulin release from pancreatic β-cells

Cell-Specific Ca2+ Response in Pancreatic ß-cells

Pancreatic ß-cells are heterogeneous in their secretory responsiveness, glucose sensitivity and metabolic rate. A diminished and delayed first-phase insulin release is an early sign of failing ß-cells in diabetes. Mechanisms controlling functional characteristics, such as lag time for insulin release or magnitude of the response in each individual cell are unknown. To find out whether the heterogeneity represents a random phenomenon in ß-cell or is a manifestation of reproducible characteristics, we compared parameters of Ca2+ response in Fura-2 labelled ob/ob mouse ß-cells during two consecutive stimulations with glucose. Lag times, as well as peak heights and nadirs of initial lowering showed a strong correlation between the first and second stimulation. Thus, timing and magnitude of the early Ca2+ response were specific for each cell. ß-Cells from lean mice, diabetic db/db mice and rats also showed cell-specific responses characteristics. This indicates that a cell-specific Ca2+ response to glucose is common in rodent ß-cells, both normal and diabetic. Another question was whether aggregated ß-cells show cell-specific responses. Using the same protocol as for dispersed ß-cells, we analysed Ca2+ responses in clusters of different size and in intact islets from ob/ob and lean mice. Correlations were found between the first and second stimulation for timing and magnitude of [Ca2+]i rise, and for the initial lowering. Next, we tested if the ß-cell response is cell-specific, when induced at different steps of the stimulus-secretion coupling. The glycolytic intermediate glyceraldehyde, the mitochondrial substrate KIC, the KATP-channel blocker tolbutamide and arginine were used as tools. [Ca2+]i changes were studied in dispersed ß-cells from lean, ob/ob and db/db mice. NADH responses to glucose and KIC were analyzed as a measure of metabolic flux. The correlation between Ca2+ and insulin response from individual ß-cells was tested using Fluo-3 and Fluozin-3. Both timing and magnitude of calcium responses were cell-specific in lean mouse ß-cells with all tested secretagogues. ß-Cells from ob/ob and db/db mice showed cell-specific timing of Ca2+ responses to glyceraldehyde but not to KIC, tolbutamide or arginine. However, ob/ob mouse ß-cells within intact islets showed cell-specific timing of tolbutamide-induced response. NADH responses to glucose were cell-specific in all three mouse models, but the timing of NADH responses to KIC was cell-specific only in lean mice. Thus, a cell-specific response can be induced in normal ß-cells at several steps of stimulus-secretion coupling for nutrient-stimulated insulin release. Cell-specific properties of ß-cell ion channels and the mitochondrial metabolism are affected in db/db and ob/ob mice. The relation between mitochondrial mass and parameters of Ca2+ responses were investigated in Mitotracker Red and Fluo-3 labelled ß-cells using confocal microscopy. Data show that ß-cell mitochondrial state may play an important role in determining the timing of [Ca2+]i changes. In summary, the early Ca2+ response pattern in ß-cells, including the lag time, the nadir of initial lowering and the height of the first peak response is cell-specific. Isolated and functionally coupled ß-cells show cell-specific timing of Ca2+ responses when stimulated with metabolic and non-metabolic agents. This may be a robust mechanism of importance for the adequate function of ß-cells and a basis for the pacemaker function of some cells. A disturbed cell specificity of the mitochondrial metabolism and ion channel function appears to be a marker of ß-cell dysfunction in hyperglycemia and diabetes and may explain the delayed insulin release in ß-cells from diabetic subjects

Impaired insulin secretion and glucose intolerance in synaptotagmin-7 null mutant mice

Vertebrates express at least 15 different synaptotagmins with the same domain structure but diverse localizations and tissue distributions. Synaptotagmin-1,-2, and -9 act as calcium sensors for the fast phrase of neurotransmitter release, and synaptotagmin-12 acts as a calcium-independent modulator of release. The exact functions of the remaining 11 synaptotagmins, however, have not been established. By analogy to the role of synaptotagmin-1, -2, and -9 in neurotransmission, these other synaptotagmins may serve as Ca2+ transducers regulating other Ca2+-dependent membrane processes, such as insulin secretion in pancreatic β-cells. Of these other synaptotagmins, synaptotagmin-7 is one of the most abundant and is present in pancreatic β-cells. To determine whether synaptotagmin-7 regulates Ca2+-dependent insulin secretion, we analyzed synaptotagmin-7 null mutant mice for glucose tolerance and insulin release. Here, we show that synaptotagmin-7 is required for the maintenance of systemic glucose tolerance and glucose-stimulated insulin secretion. Mutant mice have normal insulin sensitivity, insulin production, islet architecture and ultrastructural organization, and metabolic and calcium responses but exhibit impaired glucose-induced insulin secretion, indicating a calcium-sensing defect during insulin-containing secretory granule exocytosis. Taken together, our findings show that synaptotagmin-7 functions as a positive regulator of insulin secretion and may serve as a calcium sensor controlling insulin secretion in pancreatic β cells