Your search keyword '"SATIN, LESLIE S."' showing total 19 results

1. Intact pancreatic islets and dispersed beta-cells both generate intracellular calcium oscillations but differ in their responsiveness to glucose.

Author

Scarl RT, Corbin KL, Vann NW, Smith HM, Satin LS, Sherman A, and Nunemaker CS

Subjects

Animals, Biological Variation, Individual, Calcium Signaling, Cells, Cultured, Diabetes Mellitus, Type 2 pathology, Diabetes Mellitus, Type 2 therapy, Disease Models, Animal, Humans, Insulin Secretion, Insulin-Secreting Cells pathology, Islets of Langerhans pathology, Male, Mice, Mice, Inbred Strains, Stem Cell Transplantation, Calcium metabolism, Diabetes Mellitus, Type 2 metabolism, Glucose metabolism, Insulin metabolism, Insulin-Secreting Cells metabolism, Intracellular Space metabolism, Islets of Langerhans metabolism

Abstract

Pancreatic islets produce pulses of insulin and other hormones that maintain normal glucose homeostasis. These micro-organs possess exquisite glucose-sensing capabilities, allowing for precise changes in pulsatile insulin secretion in response to small changes in glucose. When communication among these cells is disrupted, precision glucose sensing falters. We measured intracellular calcium patterns in 6-mM-steps between 0 and 16 mM glucose, and also more finely in 2-mM-steps from 8 to 12 mM glucose, to compare glucose sensing systematically among intact islets and dispersed islet cells derived from the same mouse pancreas in vitro. The calcium activity of intact islets was uniformly low (quiescent) below 4 mM glucose and active above 8 mM glucose, whereas dispersed beta-cells displayed a broader activation range (2-to-10 mM). Intact islets exhibited calcium oscillations with 2-to-5-min periods, yet beta-cells exhibited longer 7-10 min periods. In every case, intact islets showed changes in activity with each 6-mM-glucose step, whereas dispersed islet cells displayed a continuum of calcium responses ranging from islet-like patterns to stable oscillations unaffected by changes in glucose concentration. These differences were also observed for 2-mM-glucose steps. Despite the diversity of dispersed beta-cell responses to glucose, the sum of all activity produced a glucose dose-response curve that was surprisingly similar to the curve for intact islets, arguing against the importance of "hub cells" for function. Beta-cells thus retain many of the features of islets, but some are more islet-like than others. Determining the molecular underpinnings of these variations could be valuable for future studies of stem-cell-derived beta-cell therapies., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

2. Gestational exposure to metformin programs improved glucose tolerance and insulin secretion in adult male mouse offspring.

Author

Gregg BE, Botezatu N, Brill JD, Hafner H, Vadrevu S, Satin LS, Alejandro EU, and Bernal-Mizrachi E

Subjects

Age Factors, Animals, Disease Models, Animal, Female, Glucose Tolerance Test, Insulin Resistance, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Male, Mice, Pregnancy, Sex Factors, Glucose metabolism, Insulin metabolism, Maternal Exposure, Metformin administration & dosage, Prenatal Exposure Delayed Effects

Abstract

Pancreatic β-cells are exquisitely sensitive to developmental nutrient stressors, and alterations in nutrient sensing pathways may underlie changes observed in these models. Here we developed a mouse model of in utero exposure to the anti-diabetic agent metformin. We have previously shown that this exposure increases offspring pancreatic β-cell mass at birth. We hypothesized that adult offspring would have improved metabolic parameters as a long-term outcome of metformin exposure. Virgin dams were given 5 mg/mL metformin in their water from E0.5 to delivery at E18.5. Body weight, glucose tolerance, insulin tolerance and glucose stimulated insulin secretion were analyzed in the offspring. When male offspring of dams given metformin during gestation were tested as adults they had improved glucose tolerance and enhanced insulin secretion in vivo as did their islets in vitro. Enhanced insulin secretion was accompanied by changes in intracellular free calcium responses to glucose and potassium chloride, possibly mediated by increased L channel expression. Female offspring exhibited improved glucose tolerance at advanced ages. In conclusion, in this model in utero metformin exposure leads to improved offspring metabolism in a gender-specific manner. These findings suggest that metformin applied during gestation may be an option for reprogramming metabolism in at risk groups.

Published

2018

3. Chronic Glucose Exposure Systematically Shifts the Oscillatory Threshold of Mouse Islets: Experimental Evidence for an Early Intrinsic Mechanism of Compensation for Hyperglycemia.

Author

Glynn E, Thompson B, Vadrevu S, Lu S, Kennedy RT, Ha J, Sherman A, and Satin LS

Subjects

Animals, Cells, Cultured, Glucose administration & dosage, Glucose Intolerance metabolism, Hyperinsulinism metabolism, Insulin metabolism, Insulin Resistance, Insulin Secretion, Male, Mice, Models, Theoretical, Time Factors, Calcium Signaling drug effects, Glucose pharmacology, Hyperglycemia metabolism, Islets of Langerhans drug effects, Islets of Langerhans metabolism

Abstract

Mouse islets exhibit glucose-dependent oscillations in electrical activity, intracellular Ca(2+) and insulin secretion. We developed a mathematical model in which a left shift in glucose threshold helps compensate for insulin resistance. To test this experimentally, we exposed isolated mouse islets to varying glucose concentrations overnight and monitored their glucose sensitivity the next day by measuring intracellular Ca(2+), electrical activity, and insulin secretion. Glucose sensitivity of all oscillation modes was increased when overnight glucose was greater than 2.8mM. To determine whether threshold shifts were a direct effect of glucose or involved secreted insulin, the KATP opener diazoxide (Dz) was coapplied with glucose to inhibit insulin secretion. The addition of Dz or the insulin receptor antagonist s961 increased islet glucose sensitivity, whereas the KATP blocker tolbutamide tended to reduce it. This suggests insulin and glucose have opposing actions on the islet glucose threshold. To test the hypothesis that the threshold shifts were due to changes in plasma membrane KATP channels, we measured cell KATP conductance, which was confirmed to be reduced by high glucose pretreatment and further reduced by Dz. Finally, treatment of INS-1 cells with glucose and Dz overnight reduced high affinity sulfonylurea receptor (SUR1) trafficking to the plasma membrane vs glucose alone, consistent with insulin increasing KATP conductance by altering channel number. The results support a role for metabolically regulated KATP channels in the maintenance of glucose homeostasis.

Published

2016

4. Phosphofructo-2-kinase/fructose-2,6-bisphosphatase modulates oscillations of pancreatic islet metabolism.

Author

Merrins MJ, Bertram R, Sherman A, and Satin LS

Subjects

Animals, Carbohydrate Metabolism, Glucokinase metabolism, Insulin-Secreting Cells metabolism, Mice, Models, Biological, Phosphofructokinase-2 genetics, Phosphorylation, Calcium metabolism, Glucose metabolism, Insulin metabolism, Islets of Langerhans metabolism, Phosphofructokinase-2 metabolism

Abstract

Pulses of insulin from pancreatic beta-cells help maintain blood glucose in a narrow range, although the source of these pulses is unclear. It has been proposed that a positive feedback circuit exists within the glycolytic pathway, the autocatalytic activation of phosphofructokinase-1 (PFK1), which endows pancreatic beta-cells with the ability to generate oscillations in metabolism. Flux through PFK1 is controlled by the bifunctional enzyme PFK2/FBPase2 (6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase) in two ways: via (1) production/degradation of fructose-2,6-bisphosphate (Fru2,6-BP), a potent allosteric activator of PFK1, as well as (2) direct activation of glucokinase due to a protein-protein interaction. In this study, we used a combination of live-cell imaging and mathematical modeling to examine the effects of inducibly-expressed PFK2/FBPase2 mutants on glucose-induced Ca(2+) pulsatility in mouse islets. Irrespective of the ability to bind glucokinase, mutants of PFK2/FBPase2 that increased the kinase:phosphatase ratio reduced the period and amplitude of Ca(2+) oscillations. Mutants which reduced the kinase:phosphatase ratio had the opposite effect. These results indicate that the main effect of the bifunctional enzyme on islet pulsatility is due to Fru2,6-BP alteration of the threshold for autocatalytic activation of PFK1 by Fru1,6-BP. Using computational models based on PFK1-generated islet oscillations, we then illustrated how moderate elevation of Fru-2,6-BP can increase the frequency of glycolytic oscillations while reducing their amplitude, with sufficiently high activation resulting in termination of slow oscillations. The concordance we observed between PFK2/FBPase2-induced modulation of islet oscillations and the models of PFK1-driven oscillations furthermore suggests that metabolic oscillations, like those found in yeast and skeletal muscle, are shaped early in glycolysis.

Published

2012

5. Mice deficient in GEM GTPase show abnormal glucose homeostasis due to defects in beta-cell calcium handling.

Author

Gunton JE, Sisavanh M, Stokes RA, Satin J, Satin LS, Zhang M, Liu SM, Cai W, Cheng K, Cooney GJ, Laybutt DR, So T, Molero JC, Grey ST, Andres DA, Rolph MS, and Mackay CR

Subjects

Animals, Calcium Signaling genetics, Glucose Intolerance genetics, Insulin metabolism, Insulin Resistance genetics, Insulin Secretion, Mice, Mice, Knockout, Monomeric GTP-Binding Proteins genetics, Calcium metabolism, Glucose metabolism, Glucose Intolerance metabolism, Insulin-Secreting Cells metabolism, Monomeric GTP-Binding Proteins metabolism

Abstract

Aims and Hypothesis: Glucose-stimulated insulin secretion from beta-cells is a tightly regulated process that requires calcium flux to trigger exocytosis of insulin-containing vesicles. Regulation of calcium handling in beta-cells remains incompletely understood. Gem, a member of the RGK (Rad/Gem/Kir) family regulates calcium channel handling in other cell types, and Gem over-expression inhibits insulin release in insulin-secreting Min6 cells. The aim of this study was to explore the role of Gem in insulin secretion. We hypothesised that Gem may regulate insulin secretion and thus affect glucose tolerance in vivo., Methods: Gem-deficient mice were generated and their metabolic phenotype characterised by in vivo testing of glucose tolerance, insulin tolerance and insulin secretion. Calcium flux was measured in isolated islets., Results: Gem-deficient mice were glucose intolerant and had impaired glucose stimulated insulin secretion. Furthermore, the islets of Gem-deficient mice exhibited decreased free calcium responses to glucose and the calcium oscillations seen upon glucose stimulation were smaller in amplitude and had a reduced frequency., Conclusions: These results suggest that Gem plays an important role in normal beta-cell function by regulation of calcium signalling.

Published

2012

6. BK channels mediate a novel ionic mechanism that regulates glucose-dependent electrical activity and insulin secretion in mouse pancreatic β-cells.

Author

Houamed KM, Sweet IR, and Satin LS

Subjects

Animals, Calcium metabolism, Cell Membrane, Cells, Cultured, Evoked Potentials drug effects, Glucose metabolism, Insulin Secretion, Large-Conductance Calcium-Activated Potassium Channels antagonists & inhibitors, Male, Mice, Time Factors, Electrophysiological Phenomena physiology, Evoked Potentials physiology, Glucose pharmacology, Insulin metabolism, Insulin-Secreting Cells physiology, Large-Conductance Calcium-Activated Potassium Channels physiology

Abstract

BK channels are large unitary conductance K(+) channels cooperatively activated by intracellular calcium and membrane depolarisation. We show that BK channels regulate electrical activity in β-cells of mouse pancreatic islets exposed to elevated glucose. In 11.1 mM glucose, the non-peptidyl BK channel blocker paxilline increased the height of β-cell action potentials (APs) by 21 mV without affecting burst- or silent-period durations. In isolated β-cells, paxilline increased AP height by 16 mV without affecting resting membrane potential. In voltage clamp, paxilline blocked a transient component of outward current activated by a short depolarisation, which accounted for at least 90% of the initial outward K(+) current. This BK current (I(BK)) was blocked by the Ca(2+) channel blockers Cd(2+) (200 μM) or nimodipine (1 μM), and potentiated by FPL-64176 (1 μM). I(BK) was also 56% blocked by the BK channel blocker iberiotoxin (100 nM). I(BK) activated more than 10-fold faster than the delayed rectifier I(Kv) over the physiological voltage range, and partially inactivated. An AP-like command revealed that I(BK) activated and deactivated faster than I(Kv) and accounted for 86% of peak I(K), explaining why I(BK) block increased AP height. A higher amplitude AP-like command, patterned on an AP recorded in 11.1 mM glucose plus paxilline, activated 4-fold more I(Kv) and significantly increased Ca(2+) entry. Paxilline increased insulin secretion in islets exposed to 11.1 mM glucose by 67%, but did not affect basal secretion in 2.8 mM glucose. These data suggest a modified model of β-cell AP generation where I(BK) and I(Kv) coordinate the AP repolarisation.

Published

2010

7. Glucose metabolism, islet architecture, and genetic homogeneity in imprinting of [Ca2+](i) and insulin rhythms in mouse islets.

Author

Nunemaker CS, Dishinger JF, Dula SB, Wu R, Merrins MJ, Reid KR, Sherman A, Kennedy RT, and Satin LS

Subjects

Aging genetics, Animals, Animals, Outbred Strains, Glucose pharmacology, Insulin Secretion, Insulin-Secreting Cells metabolism, Mice, Mice, Inbred Strains, Microfluidic Analytical Techniques, NADP, Weight Gain genetics, Calcium Signaling genetics, Genomic Imprinting, Glucose metabolism, Insulin metabolism, Islets of Langerhans cytology, Islets of Langerhans metabolism

Abstract

We reported previously that islets isolated from individual, outbred Swiss-Webster mice displayed oscillations in intracellular calcium ([Ca2+](i)) that varied little between islets of a single mouse but considerably between mice, a phenomenon we termed "islet imprinting." We have now confirmed and extended these findings in several respects. First, imprinting occurs in both inbred (C57BL/6J) as well as outbred mouse strains (Swiss-Webster; CD1). Second, imprinting was observed in NAD(P)H oscillations, indicating a metabolic component. Further, short-term exposure to a glucose-free solution, which transiently silenced [Ca2+](i) oscillations, reset the oscillatory patterns to a higher frequency. This suggests a key role for glucose metabolism in maintaining imprinting, as transiently suppressing the oscillations with diazoxide, a K(ATP)-channel opener that blocks [Ca2+](i) influx downstream of glucose metabolism, did not change the imprinted patterns. Third, imprinting was not as readily observed at the level of single beta cells, as the [Ca2+](i) oscillations of single cells isolated from imprinted islets exhibited highly variable, and typically slower [Ca2+](i) oscillations. Lastly, to test whether the imprinted [Ca2+](i) patterns were of functional significance, a novel microchip platform was used to monitor insulin release from multiple islets in real time. Insulin release patterns correlated closely with [Ca2+](i) oscillations and showed significant mouse-to-mouse differences, indicating imprinting. These results indicate that islet imprinting is a general feature of islets and is likely to be of physiological significance. While islet imprinting did not depend on the genetic background of the mice, glucose metabolism and intact islet architecture may be important for the imprinting phenomenon.

Published

2009

8. Glucose-induced release of nitric oxide from mouse pancreatic islets as detected with nitric oxide-selective glass microelectrodes.

Author

Nunemaker CS, Buerk DG, Zhang M, and Satin LS

Subjects

Animals, Calcium metabolism, Dose-Response Relationship, Drug, Glass, Islets of Langerhans metabolism, Male, Mice, Microelectrodes, Nitric Oxide metabolism, Organ Culture Techniques, Pulsatile Flow, Clinical Laboratory Techniques instrumentation, Glucose pharmacology, Islets of Langerhans drug effects, Nitric Oxide analysis

Abstract

Nitric oxide (NO) is believed to play an important role in pancreatic islet physiology and pathophysiology. Research in this area has been hampered, however, by the use of indirect methods to measure islet NO. To investigate the role of NO in islet function, we positioned NO-sensitive, recessed-tip microelectrodes in close proximity to individual islets and monitored oxidation current to detect subnanomolar NO in the bath. NO release from islets consisted of a series of rapid bursts lasting several seconds and/or slow oscillations with a period of approximately 100-300 s. Average baseline NO near the islets in 2.8 mM glucose was 524+/-59 nM (n=12). Raising glucose from 2.8 to 11.1 mM augmented NO release by 429+/-133 nM (n=12, P<0.05), an effect blocked by the NO synthase inhibitor L-NAME (n=3). We also observed that glucose-stimulated increases in NO release were contemporaneous with changes in NAD(P)H and O2 but occurred well before increases in calcium associated with glucose-stimulated insulin secretion. In summary, we demonstrate that NO release from islets is oscillatory and rapidly augmented by glucose, suggesting that NO release occurs early following an increase in glucose metabolism and may contribute to the stimulated insulin secretion triggered by suprathreshold glucose.

Published

2007

9. Oscillatory membrane potential response to glucose in islet beta-cells: a comparison of islet-cell electrical activity in mouse and rat.

Author

Manning Fox JE, Gyulkhandanyan AV, Satin LS, and Wheeler MB

Subjects

Animals, Calcium metabolism, Cell Separation, Electrophysiology, Glucagon-Secreting Cells drug effects, Humans, Insulin metabolism, Membrane Potentials drug effects, Mice, Patch-Clamp Techniques, Rats, Rats, Wistar, Species Specificity, Glucose pharmacology, Insulin-Secreting Cells drug effects

Abstract

In contrast to mouse, rat islet beta-cell membrane potential is reported not to oscillate in response to elevated glucose despite demonstrated oscillations in calcium and insulin secretion. We aim to clarify the electrical activity of rat islet beta-cells and characterize and compare the electrical activity of both alpha- and beta-cells in rat and mouse islets. We recorded electrical activity from alpha- and beta-cells within intact islets from both mouse and rat using the perforated whole-cell patch clamp technique. Fifty-six percent of both mouse and rat beta-cells exhibited an oscillatory response to 11.1 mm glucose. Responses to both 11.1 mm and 2.8 mm glucose were identical in the two species. Rat beta-cells exhibited incremental depolarization in a glucose concentration-dependent manner. We also demonstrated electrical activity in human islets recorded under the same conditions. In both mouse and rat alpha-cells 11 mm glucose caused hyperpolarization of the membrane potential, whereas 2.8 mm glucose produced action potential firing. No species differences were observed in the response of alpha-cells to glucose. This paper is the first to demonstrate and characterize oscillatory membrane potential fluctuations in the presence of elevated glucose in rat islet beta-cells in comparison with mouse. The findings promote the use of rat islets in future electrophysiological studies, enabling consistency between electrophysiological and insulin secretion studies. An inverse response of alpha-cell membrane potential to glucose furthers our understanding of the mechanisms underlying glucose sensitive glucagon secretion.

Published

2006

10. Glucose modulates [Ca2+]i oscillations in pancreatic islets via ionic and glycolytic mechanisms.

Author

Nunemaker CS, Bertram R, Sherman A, Tsaneva-Atanasova K, Daniel CR, and Satin LS

Subjects

Adenine Nucleotides metabolism, Animals, Calcium Signaling drug effects, Cations, Divalent, Cell Membrane physiology, Cytosol physiology, Feedback, Physiological, Glucose pharmacology, Glycolysis, In Vitro Techniques, Islets of Langerhans drug effects, Male, Mice, NADP metabolism, Periodicity, Calcium physiology, Calcium Channels physiology, Calcium Signaling physiology, Glucose physiology, Islets of Langerhans physiology, Models, Biological

Abstract

Pancreatic islets of Langerhans display complex intracellular calcium changes in response to glucose that include fast (seconds), slow ( approximately 5 min), and mixed fast/slow oscillations; the slow and mixed oscillations are likely responsible for the pulses of plasma insulin observed in vivo. To better understand the mechanisms underlying these diverse patterns, we systematically analyzed the effects of glucose on period, amplitude, and plateau fraction (the fraction of time spent in the active phase) of the various regimes of calcium oscillations. We found that in both fast and slow islets, increasing glucose had limited effects on amplitude and period, but increased plateau fraction. In some islets, however, glucose caused a major shift in the amplitude and period of oscillations, which we attribute to a conversion between ionic and glycolytic modes (i.e., regime change). Raising glucose increased the plateau fraction equally in fast, slow, and regime-changing islets. A mathematical model of the pancreatic islet consisting of an ionic subsystem interacting with a slower metabolic oscillatory subsystem can account for these complex islet calcium oscillations by modifying the relative contributions of oscillatory metabolism and oscillatory ionic mechanisms to electrical activity, with coupling occurring via K(ATP) channels.

Published

2006

11. Pulsatile insulin secretion, impaired glucose tolerance and type 2 diabetes

Author

Satin, Leslie S, Butler, Peter C, Ha, Joon, and Sherman, Arthur S

Subjects

Clinical Research, Diabetes, Nutrition, 2.1 Biological and endogenous factors, Aetiology, Metabolic and endocrine, Animals, Diabetes Mellitus, Type 2, Fasting, Glucose, Humans, Insulin, Insulin Resistance, Insulin Secretion, Insulin-Secreting Cells, Islets, Oscillations, Insulin pulsatility, Insulin resistance, Biological Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology

Abstract

Type 2 diabetes (T2DM) results when increases in beta cell function and/or mass cannot compensate for rising insulin resistance. Numerous studies have documented the longitudinal changes in metabolism that occur during the development of glucose intolerance and lead to T2DM. However, the role of changes in insulin secretion, both amount and temporal pattern, has been understudied. Most of the insulin secreted from pancreatic beta cells of the pancreas is released in a pulsatile pattern, which is disrupted in T2DM. Here we review the evidence that changes in beta cell pulsatility occur during the progression from glucose intolerance to T2DM in humans, and contribute significantly to the etiology of the disease. We review the evidence that insulin pulsatility improves the efficacy of secreted insulin on its targets, particularly hepatic glucose production, but also examine evidence that pulsatility alters or is altered by changes in peripheral glucose uptake. Finally, we summarize our current understanding of the biophysical mechanisms responsible for oscillatory insulin secretion. Understanding how insulin pulsatility contributes to normal glucose homeostasis and is altered in metabolic disease states may help improve the treatment of T2DM.

Published

2015

12. Gap junctions and other mechanisms of cell–cell communication regulate basal insulin secretion in the pancreatic islet

Author

Benninger, R K P, Head, W Steven, Zhang, Min, Satin, Leslie S, and Piston, David W

Subjects

Mice, Knockout, Gap Junctions, Cell Communication, In Vitro Techniques, Cyclic AMP-Dependent Protein Kinases, Connexins, Membrane Potentials, Renal and Endocrine, Islets of Langerhans, Mice, Glucose, Insulin-Secreting Cells, Insulin Secretion, Cyclic AMP, Animals, Insulin, Calcium, Cells, Cultured

Abstract

Cell-cell communication in the islet of Langerhans is important for the regulation of insulin secretion. Gap-junctions coordinate oscillations in intracellular free-calcium ([Ca(2+)](i)) and insulin secretion in the islet following elevated glucose. Gap-junctions can also ensure that oscillatory [Ca(2+)](i) ceases when glucose is at a basal levels. We determine the roles of gap-junctions and other cell-cell communication pathways in the suppression of insulin secretion under basal conditions. Metabolic, electrical and insulin secretion levels were measured from islets lacking gap-junction coupling following deletion of connexion36 (Cx36(-/-)), and these results were compared to those obtained using fully isolated β-cells. K(ATP) loss-of-function islets provide a further experimental model to specifically study gap-junction mediated suppression of electrical activity. In isolated β-cells or Cx36(-/-) islets, elevations in [Ca(2+)](i) persisted in a subset of cells even at basal glucose. Isolated β-cells showed elevated insulin secretion at basal glucose; however, insulin secretion from Cx36(-/-) islets was minimally altered. [Ca(2+)](i) was further elevated under basal conditions, but insulin release still suppressed in K(ATP) loss-of-function islets. Forced elevation of cAMP led to PKA-mediated increases in insulin secretion from islets lacking gap-junctions, but not from islets expressing Cx36 gap junctions. We conclude there is a redundancy in how cell-cell communication in the islet suppresses insulin release. Gap junctions suppress cellular heterogeneity and spontaneous [Ca(2+)](i) signals, while other juxtacrine mechanisms, regulated by PKA and glucose, suppress more distal steps in exocytosis. Each mechanism is sufficiently robust to compensate for a loss of the other and still suppress basal insulin secretion.

Published

2011

13. BK channels mediate a novel ionic mechanism that regulates glucose-dependent electrical activity and insulin secretion in mouse pancreatic β-cells

Author

Houamed, Khaled M, Sweet, Ian R, and Satin, Leslie S

Subjects

Male, Time Factors, Cell Membrane, Electrophysiological Phenomena, Renal and Endocrine, Mice, Glucose, Insulin-Secreting Cells, Insulin Secretion, Animals, Insulin, Calcium, Large-Conductance Calcium-Activated Potassium Channels, Evoked Potentials, Cells, Cultured

Abstract

BK channels are large unitary conductance K(+) channels cooperatively activated by intracellular calcium and membrane depolarisation. We show that BK channels regulate electrical activity in β-cells of mouse pancreatic islets exposed to elevated glucose. In 11.1 mM glucose, the non-peptidyl BK channel blocker paxilline increased the height of β-cell action potentials (APs) by 21 mV without affecting burst- or silent-period durations. In isolated β-cells, paxilline increased AP height by 16 mV without affecting resting membrane potential. In voltage clamp, paxilline blocked a transient component of outward current activated by a short depolarisation, which accounted for at least 90% of the initial outward K(+) current. This BK current (I(BK)) was blocked by the Ca(2+) channel blockers Cd(2+) (200 μM) or nimodipine (1 μM), and potentiated by FPL-64176 (1 μM). I(BK) was also 56% blocked by the BK channel blocker iberiotoxin (100 nM). I(BK) activated more than 10-fold faster than the delayed rectifier I(Kv) over the physiological voltage range, and partially inactivated. An AP-like command revealed that I(BK) activated and deactivated faster than I(Kv) and accounted for 86% of peak I(K), explaining why I(BK) block increased AP height. A higher amplitude AP-like command, patterned on an AP recorded in 11.1 mM glucose plus paxilline, activated 4-fold more I(Kv) and significantly increased Ca(2+) entry. Paxilline increased insulin secretion in islets exposed to 11.1 mM glucose by 67%, but did not affect basal secretion in 2.8 mM glucose. These data suggest a modified model of β-cell AP generation where I(BK) and I(Kv) coordinate the AP repolarisation.

Published

2010

14. Upregulation of an inward rectifying K+ channel can rescue slow Ca2+ oscillations in K(ATP) channel deficient pancreatic islets.

Author

Yildirim, Vehpi, Vadrevu, Suryakiran, Thompson, Benjamin, Satin, Leslie S., and Bertram, Richard

Subjects

INSULIN, OSCILLATING chemical reactions, POTASSIUM channels, ISLANDS of Langerhans, ADENOSINE triphosphate, BLOOD sugar

Abstract

Plasma insulin oscillations are known to have physiological importance in the regulation of blood glucose. In insulin-secreting β-cells of pancreatic islets, K(ATP) channels play a key role in regulating glucose-dependent insulin secretion. In addition, they convey oscillations in cellular metabolism to the membrane by sensing adenine nucleotides, and are thus instrumental in mediating pulsatile insulin secretion. Blocking K(ATP) channels pharmacologically depolarizes the β-cell plasma membrane and terminates islet oscillations. Surprisingly, when K(ATP) channels are genetically knocked out, oscillations in islet activity persist, and relatively normal blood glucose levels are maintained. Compensation must therefore occur to overcome the loss of K(ATP) channels in K(ATP) knockout mice. In a companion study, we demonstrated a substantial increase in Kir2.1 protein occurs in β-cells lacking K(ATP) because of SUR1 deletion. In this report, we demonstrate that β-cells of SUR1 null islets have an upregulated inward rectifying K+ current that helps to compensate for the loss of K(ATP) channels. This current is likely due to the increased expression of Kir2.1 channels. We used mathematical modeling to determine whether an ionic current having the biophysical characteristics of Kir2.1 is capable of rescuing oscillations that are similar in period to those of wild-type islets. By experimentally testing a key model prediction we suggest that Kir2.1 current upregulation is a likely mechanism for rescuing the oscillations seen in islets from mice deficient in K(ATP) channels. [ABSTRACT FROM AUTHOR]

Published

2017

15. Gap junctions and other mechanisms of cell-cell communication regulate basal insulin secretion in the pancreatic islet.

Author

Benninger, R. K. P., Head, W. Steven, Zhang, Min, Satin, Leslie S., and Piston, David W.

Subjects

ISLANDS of Langerhans, INSULIN, PANCREATIC secretions, GLUCOSE, EXOCYTOSIS, TREATMENT of diabetes

Abstract

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Published

2011

16. Differential modulation of L-type calcium channel subunits by oleate.

Author

Yingrao Tian, Corkey, Richard F., Yaney, Gordon C., Goforth, Paula B., Satin, Leslie S., and De Vargas, Lina Moitoso

Subjects

OLEATES, FATTY acids, INSULIN, GLUCOSE, PANCREATIC secretions

Abstract

Nonesterified fatty acids such as oleate and palmitate acutely potentiate insulin secretion from pancreatic islets in a glucose-dependent manner. In addition, recent studies show that fatty acids elevate intracellular free Ca2+ and increase voltage-gated Ca2+ current in mouse β-cells, although the mechanisms involved are poorly understood. Here we utilized a heterologous system to express subunit-defined voltage-dependent L-type Ca2+ channels (LTCC) and demonstrate that β-cell calcium may increase in part from an interaction between fatty acid and specific calcium channel subunits. Distinct functional LTCC were assembled in both COS-7 and HEK-293 cells by expressing either one of the EYFP-tagged L-type α1-subunits (β-cell Cav1.3 or lung Cav1.2) and ERFP-tagged islet β-subunits (iβ2a or iβ3). In COS-7 cells, elevations in intracellular Ca2+ mediated by LTCC were enhanced by an oleate-BSA complex. To extend these findings, Ca2+ current was measured in LTCC-expressing HEK-293 cells that revealed an increase in peak Ca2+ current within 2 mm after addition of the oleate complex, with maximal potentiation occurring at voltages <0 mV. Both Cav1.3 and Cav1.2 were modulated by oleate, and the presence of different auxiliary β-subunits resulted in differential augmentation. The potentiating effect of oleate on Cav1.2 was abolished by the pretreatment of cells with triacsin C, suggesting that long-chain CoA synthesis is necessary for Ca2+ channel modulation. These results show for the first time that two L-type Ca2+ channels expressed in β-cells (Cav1.3 and Cav1.2) appear to be targeted by nonesterified fatty acids. This effect may account in part for the acute potentiation of glucose-dependent insulin secretion by fatty acids. [ABSTRACT FROM AUTHOR]

Published

2008

17. Insulin secretion in the conscious mouse is biphasic and pulsatile.

Author

Nunemaker, Craig S., Wasserman, David H., McGuinness, Owen P., Sweet, Ian R., Teague, Jeanette C., and Satin, Leslie S.

Subjects

PANCREATIC secretions, ISLANDS of Langerhans, LABORATORY mice, CAROTID artery, BLOOD volume, BLOOD circulation, GLUCOSE

Abstract

Islets in most species respond to increased glucose with biphasic insulin secretion, marked by a sharp first-phase peak and a slowly rising second phase. Mouse islets in vitro, however, lack a robust second phase. To date, this observation has not been extended in vivo. We thus compared insulin secretion from conscious mice with isolated mouse islets in vitro. The arterial plasma insulin response to a hyperglycemic clamp was measured in conscious mice 1 wk after surgical implantation of carotid artery and jugular vein catheters. Mice were transfused using clamps with blood from a donor mouse to maintain blood volume, allowing frequent arterial sampling. When plasma glucose in vivo was raised from ∼5 to ∼13 mM, insulin rose to a first-phase peak of 403 ± 73% above basal secretion (n = 5), followed by a rising second phase of mean 289 ± 41%. In contrast, perifused mouse islets (∼75 islets/trial) responded with a similar first phase of 508 ± 94% (n = 4) but a smaller and virtually flat second phase of 169 ± 9% (n = 4, P < 0.05). Furthermore, the slope of the second-phase response differed significantly from zero in mice (2.63 ± 0.39%/min, P < 0.01), in contrast to perifused islets (0.18 ± 0.14%/min, P ± 0.30). Mice also displayed pulsatile patterns in insulin concentration (period: 4.2 ± 0.4 min, n = 8). Conscious mice thus responded to increased glucose with biphasic and pulsatile insulin secretion, as in other species. The robust second phase observed in vivo suggests that the processes needed to generate second-phase insulin secretion may be abrogated by islet isolation. [ABSTRACT FROM AUTHOR]

Published

2006

18. Individual mice can be distinguished by the period of their islet calcium oscillations: is there an intrinsic islet period that is imprinted in vivo?

Author

Nunemaker, Craig S., Zhang, Min, Wasserman, David H., McGuinness, Owen P., Powers, Alvin C., Bertram, Richard, Sherman, Arthur, and Satin, Leslie S.

Subjects

INSULIN, GLUCOSE, CALCIUM, ISLANDS of Langerhans, LABORATORY mice

Abstract

Pulsatile insulin secretion in vivo is believed to be derived, in part, from the intrinsic glucose-dependent intracellular calcium concentration ([Ca2+]i) pulsatility of individual islets. In isolation, islets display fast, slow, or mixtures of fast and slow [Ca2+]i oscillations. We show that the period of islet [Ca2+]i oscillations is unique to each mouse, with the islets from an individual mouse demonstrating similar rhythms to one another. Based on their rhythmic period, mice were broadly classified as being either fast (0.65 +/- 0.1 min; n = 6 mice) or slow (4.7 +/- 0.2 min; n = 15 mice). To ensure this phenomenon was not an artifact of islet-to-islet communication, we confirmed that islets cultured in isolation (period: 2.9 +/- 0.1 min) were not statistically different from islets cultured together from the same mouse (3.1 +/- 0.1 min, P > 0.52, n = 5 mice). We also compared pulsatile insulin patterns measured in vivo with islet [Ca2+]i patterns measured in vitro from six mice. Mice with faster insulin pulse periods corresponded to faster islet [Ca2+]i patterns, whereas slower insulin patterns corresponded to slower [Ca2+]i patterns, suggesting that the insulin rhythm of each mouse is preserved to some degree by its islets in vitro. We propose that individual mice have characteristic oscillatory [Ca2+]i patterns, which are imprinted in vivo through an unknown mechanism. [ABSTRACT FROM AUTHOR]

Published

2005

19. Pharmacological Properties and Functional Role of Kslow Current in Mouse Pancreatic β-Cells: SK Channels Contribute to Kslow Tail Current and Modulate Insulin Secretion.

Author

Min Zhang, Houamed, Khaled, Kupershmidt, Sabina, Roden, Dan, Satin, Leslie S., and Palmer, Lawrence G.

Subjects

*PHARMACOLOGY, *MEDICAL sciences, *INSULIN, *GLUCOSE, *HORMONES, *HYPOGLYCEMIC agents, *PANCREATIC secretions

Abstract

The pharmacological properties of slow Ca2+-activated K+ current (Kslow) were investigated in mouse pancreatic β-cells and islets to understand how Kslow contributes to the control of islet bursting, [Ca2+]i oscillations, and insulin secretion. Kslow was insensitive to apamin or the KATP channel inhibitor tolbutamide, but UCL 1684, a potent and selective nonpeptide SK channel blocker reduced the amplitude of Kslow tail current in voltage-clamped mouse β-cells. Kslow was also selectively and reversibly inhibited by the class III antiarrythmic agent azimilide (AZ). In isolated β-cells or islets, pharmacologic inhibition of Kslow by UCL 1684 or AZ depolarized β-cell silent phase potential, increased action potential firing, raised [Ca2+]i, and enhanced glucose-dependent insulin secretion. AZ inhibition of Kslow also supported mediation by SK, rather than cardiac-like slow delayed rectifier channels since bath application of AZ to HEK 293 cells expressing SK3 cDNA reduced SK current. Further, AZ-sensitive Kslow current was extant in β-cells from KCNQ1 or KCNE1 null mice lacking cardiac slow delayed rectifier currents. These results strongly support a functional role for SK channel-mediated Kslow current in β-cells, and suggest that drugs that target SK channels may represent a new approach for increasing glucose-dependent insulin secretion. The apamin insensitivity of β-cell SK current suggests that β-cells express a unique SK splice variant or a novel heteromultimer consisting of different SK subunits. [ABSTRACT FROM AUTHOR]

Published

2005