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458 results on '"SATIN, LESLIE S."'

152. Slow oscillations of KATP conductance in mouse pancreatic islets provide support for electrical bursting driven by metabolic oscillations.

Author

Ren, Jianhua, Sherman, Arthur, Bertram, Richard, Goforth, Paulette B., Nunemaker, Craig S., Waters, Christopher D., and Satin, Leslie S.

Subjects
ADENOSINE triphosphate, ISLANDS of Langerhans, METABOLISM, VOLTAGE-clamp techniques (Electrophysiology), CELL membranes, INTRACELLULAR calcium, LABORATORY mice
Abstract

We used the patch clamp technique in situ to test the hypothesis that slow oscillations in metabolism mediate slow electrical oscillations in mouse pancreatic islets by causing oscillations in KATP channel activity. Total conductance was measured over the course of slow bursting oscillations in surface β-cells of islets exposed to 11.1 mM glucose by either switching from current clamp to voltage clamp at different phases of the bursting cycle or by clamping the cells to -60 mV and running two-second voltage ramps from -120 to -50 mV every 20 s. The membrane conductance, calculated from the slopes of the ramp current-voltage curves, oscillated and was larger during the silent phase than during the active phase of the burst. The ramp conductance was sensitive to diazoxide, and the oscillatory component was reduced by sulfonylureas or by lowering extracellular glucose to 2.8 mM, suggesting that the oscillatory total conductance is due to oscillatory KATP channel conductance. We demonstrate that these results are consistent with the Dual Oscillator model, in which glycolytic oscillations drive slow electrical bursting, but not with other models in which metabolic oscillations are secondary to calcium oscillations. The simulations also confirm that oscillations in membrane conductance can be well estimated from measurements of slope conductance and distinguished from gap junction conductance. Furthermore, the oscillatory conductance was blocked by tolbutamide in isolated β-cells. The data, combined with insights from mathematical models, support a mechanism of slow (~5 min) bursting driven by oscillations in metabolism, rather than by oscillations in the intracellular free calcium concentration. [ABSTRACT FROM AUTHOR]

Published
2013
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154. Glucose Metabolism, Islet Architecture, and Genetic Homogeneity in Imprinting of [Ca2+]i and Insulin Rhythms in Mouse Islets.

Author

Nunemaker, Craig S., Dishinger, John F., Dula, Stacey B., Runpei Wu, Merrins, Matthew J., Reid, Kendra R., Sherman, Arthur, Kennedy, Robert T., and Satin, Leslie S.

Subjects
GLUCOSE synthesis, HOMOGENEITY, PANCREATIC secretions, HYPOGLYCEMIC agents, INTRACELLULAR calcium, BACTERIAL metabolism, PANCREATIC beta cells, INSULIN, LABORATORY mice
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 KATP-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. [ABSTRACT FROM AUTHOR]

Published
2009
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155. 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
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156. Insulin Activates ATP-Sensitive K[sup+] Channels in Pancreatic beta-Cells Through a Phosphatidylinositol 3-Kinase-Dependent Pathway.

Author

Khan, Farrukh A., Goforth, Paulette B., Zhang, Min, and Satin, Leslie S.

Subjects
INSULIN, POTASSIUM channels, PANCREATIC beta cells, PHYSIOLOGY
Abstract

Examines the role of insulin for the activation of adenosine triphosphate-sensitive potassium channels in pancreatic beta-cells. Use of phosphatidylinositol 3-kinase-dependent pathway for the activation; Regulation of pancreatic beta-cell function by the activation of cell surface insulin receptors; Measurement of calcium ion concentration.

Published
2001
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158. Intrinsic Islet Heterogeneity and Gap Junction Coupling Determine Spatiotemporal Ca2+Wave Dynamics

Author

Benninger, Richard K.P., Hutchens, Troy, Head, W. Steven, McCaughey, Michael J., Zhang, Min, Le Marchand, Sylvain J., Satin, Leslie S., and Piston, David W.

Abstract

Insulin is released from the islets of Langerhans in discrete pulses that are linked to synchronized oscillations of intracellular free calcium ([Ca2+]i). Associated with each synchronized oscillation is a propagating calcium wave mediated by Connexin36 (Cx36) gap junctions. A computational islet model predicted that waves emerge due to heterogeneity in β-cell function throughout the islet. To test this, we applied defined patterns of glucose stimulation across the islet using a microfluidic device and measured how these perturbations affect calcium wave propagation. We further investigated how gap junction coupling regulates spatiotemporal [Ca2+]idynamics in the face of heterogeneous glucose stimulation. Calcium waves were found to originate in regions of the islet having elevated excitability, and this heterogeneity is an intrinsic property of islet β-cells. The extent of [Ca2+]ielevation across the islet in the presence of heterogeneity is gap-junction dependent, which reveals a glucose dependence of gap junction coupling. To better describe these observations, we had to modify the computational islet model to consider the electrochemical gradient between neighboring β-cells. These results reveal how the spatiotemporal [Ca2+]idynamics of the islet depend on β-cell heterogeneity and cell-cell coupling, and are important for understanding the regulation of coordinated insulin release across the islet.

Published
2014
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159. Evidence for Residual and Partly Reparable Insulin Secretory Function and Maintained β-Cell Gene Expression in Islets From Patients With Type 1 Diabetes.

Author

Satin, Leslie S. and Schnell, Santiago

Subjects
*PHYSIOLOGICAL effects of glucose, *RNA sequencing, *ISLANDS of Langerhans, *RNA analysis, *NUCLEOTIDE sequence
Abstract

The article discusses a study which compares residual glucose-dependent insulin secretion and whole-genome RNA sequencing of islet tissue from donors with and without diabetes. Topics discussed include the measurements of RNA abundances using islets from control and type 1 diabetes (T1D) donors and its quantification using reads per kilobase per mission (RPKM) measurement and the residual secretion of insulin at low levels in most T1D islet compared with controlled islet.

Published
2015
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162. Metabolic Oscillations in Pancreatic Islets Depend on the Intracellular Ca2+Level but Not Ca2+Oscillations

Author

Merrins, Matthew J., Fendler, Bernard, Zhang, Min, Sherman, Arthur, Bertram, Richard, and Satin, Leslie S.

Abstract

Plasma insulin is pulsatile and reflects oscillatory insulin secretion from pancreatic islets. Although both islet Ca2+and metabolism oscillate, there is disagreement over their interrelationship, and whether they can be dissociated. In some models of islet oscillations, Ca2+must oscillate for metabolic oscillations to occur, whereas in others metabolic oscillations can occur without Ca2+oscillations. We used NAD(P)H fluorescence to assay oscillatory metabolism in mouse islets stimulated by 11.1 mM glucose. After abolishing Ca2+oscillations with 200 μM diazoxide, we observed that oscillations in NAD(P)H persisted in 34% of islets (n= 101). In the remainder of the islets (66%) both Ca2+and NAD(P)H oscillations were eliminated by diazoxide. However, in most of these islets NAD(P)H oscillations could be restored and amplified by raising extracellular KCl, which elevated the intracellular Ca2+level but did not restore Ca2+oscillations. Comparatively, we examined islets from ATP-sensitive K+(KATP) channel-deficient SUR1−/−mice. Again NAD(P)H oscillations were evident even though Ca2+and membrane potential oscillations were abolished. These observations are predicted by the dual oscillator model, in which intrinsic metabolic oscillations and Ca2+feedback both contribute to the oscillatory islet behavior, but argue against other models that depend on Ca2+oscillations for metabolic oscillations to occur.

Published
2010
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163. Oscillations in K(ATP) conductance drive slow calcium oscillations in pancreatic β-cells

Author

Marinelli, Isabella, Thompson, Benjamin M., Parekh, Vishal S., Fletcher, Patrick A., Gerardo-Giorda, Luca, Sherman, Arthur S., Satin, Leslie S., and Bertram, Richard

Abstract

ATP-sensitive K+(K(ATP)) channels were first reported in the β-cells of pancreatic islets in 1984, and it was soon established that they are the primary means by which the blood glucose level is transduced to cellular electrical activity and consequently insulin secretion. However, the role that the K(ATP) channels play in driving the bursting electrical activity of islet β-cells, which drives pulsatile insulin secretion, remains unclear. One difficulty is that bursting is abolished when several different ion channel types are blocked pharmacologically or genetically, making it challenging to distinguish causation from correlation. Here, we demonstrate a means for determining whether activity-dependent oscillations in K(ATP) conductance play the primary role in driving electrical bursting in β-cells. We use mathematical models to predict that if K(ATP) is the driver, then contrary to intuition, the mean, peak, and nadir levels of ATP/ADP should be invariant to changes in glucose within the concentration range that supports bursting. We test this in islets using Perceval-HR to image oscillations in ATP/ADP. We find that mean, peak, and nadir levels are indeed approximately invariant, supporting the hypothesis that oscillations in K(ATP) conductance are the main drivers of the slow bursting oscillations typically seen at stimulatory glucose levels in mouse islets. In conclusion, we provide, for the first time to our knowledge, causal evidence for the role of K(ATP) channels not only as the primary target for glucose regulation but also for their role in driving bursting electrical activity and pulsatile insulin secretion.

Published
2022
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164. Slow oscillations persist in pancreatic beta cells lacking phosphofructokinase M

Author

Marinelli, Isabella, Parekh, Vishal S., Fletcher, Patrick A., Thompson, Benjamin, Ren, Jinhua, Tang, Xiaoqing, Saunders, Thomas L., Ha, Joon, Sherman, Arthur, Bertram, Richard, and Satin, Leslie S.

Abstract

Pulsatile insulin secretion by pancreatic beta cells is necessary for tight glucose control in the body. Glycolytic oscillations have been proposed as the mechanism for generating the electrical oscillations underlying pulsatile insulin secretion. The glycolytic enzyme 6-phosphofructokinase-1 (PFK) synthesizes fructose-1,6-bisphosphate (FBP) from fructose-6-phosphate. It has been proposed that the slow electrical and Ca2+oscillations (periods of 3–5 min) observed in islets result from allosteric feedback activation of PFKM by FBP. Pancreatic beta cells express three PFK isozymes: PFKL, PFKM, and PFKP. A prior study of mice that were engineered to lack PFKM using a gene-trap strategy to delete Pfkmproduced a mosaic reduction in global Pfkmexpression, but the islets isolated from the mice still exhibited slow Ca2+oscillations. However, these islets still expressed residual PFKM protein. Thus, to more fully test the hypothesis that beta cell PFKM is responsible for slow islet oscillations, we made a beta-cell-specific knockout mouse that completely lacked PFKM. While PFKM deletion resulted in subtle metabolic changes in vivo, islets that were isolated from these mice continued to exhibit slow oscillations in electrical activity, beta cell Ca2+concentrations, and glycolysis, as measured using PKAR, an FBP reporter/biosensor. Furthermore, simulations obtained with a mathematical model of beta cell activity shows that slow oscillations can persist despite PFKM loss provided that one of the other PFK isoforms, such as PFKP, is present, even if its level of expression is unchanged. Thus, while we believe that PFKM may be the main regulator of slow oscillations in wild-type islets, PFKP can provide functional redundancy. Our model also suggests that PFKM likely dominates, in vivo, because it outcompetes PFKP with its higher FBP affinity and lower ATP affinity. We thus propose that isoform redundancy may rescue key physiological processes of the beta cell in the absence of certain critical genes.

Published
2022
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165. Gap Junction Coupling and Calcium Waves in the Pancreatic Islet

Author

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

Abstract

The pancreatic islet is a highly coupled, multicellular system that exhibits complex spatiotemporal electrical activity in response to elevated glucose levels. The emergent properties of islets, which differ from those arising in isolated islet cells, are believed to arise in part by gap junctional coupling, but the mechanisms through which this coupling occurs are poorly understood. To uncover these mechanisms, we have used both high-speed imaging and theoretical modeling of the electrical activity in pancreatic islets under a reduction in the gap junction mediated electrical coupling. Utilizing islets from a gap junction protein connexin 36 knockout mouse model together with chemical inhibitors, we can modulate the electrical coupling in the islet in a precise manner and quantify this modulation by electrophysiology measurements. We find that after a reduction in electrical coupling, calcium waves are slowed as well as disrupted, and the number of cells showing synchronous calcium oscillations is reduced. This behavior can be reproduced by computational modeling of a heterogeneous population of β-cells with heterogeneous levels of electrical coupling. The resulting quantitative agreement between the data and analytical models of islet connectivity, using only a single free parameter, reveals the mechanistic underpinnings of the multicellular behavior of the islet.

Published
2008
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166. 230-LB: Differential Roles of Beta-Cell IP3R and RyR ER Ca2+ Channels in Tunicamycin-Induced Disruption of Beta-Cell Ca2+ Homeostasis.

Author

ZHANG, IRINA, PAREKH, VISHAL S., LEON, JUAN J., and SATIN, LESLIE S.

Abstract

Pancreatic beta cells maintain glucose homeostasis by secreting insulin following a rise in plasma glucose. Insulin secretion is pulsatile, which is brought about because of oscillations in the concentrations of beta-cell cytosolic Ca2+. The endoplasmic reticulum (ER) helps to regulate the cytosolic Ca2+ level, thereby playing a role in Ca2+-induced insulin release. ER stress, triggered by the accumulation of unfolded proteins in the ER, can lead to the ER Ca2+ depletion, which in turn can contribute to beta-cell deterioration and an increased risk of type-2 diabetes. We sought to determine the effects of tunicamycin (TM)-induced ER stress on ER Ca2+ channels, inositol 1,4,5-triphosphate (IP3) receptors (IP3Rs) and ryanodine receptors (RyRs), and subsequent alterations in beta-cell Ca2+ homeostasis that result from these alterations. To determine the roles of these receptors in TM-induced beta-cell dysfunction, we treated mouse pancreatic islets with the RyR1 inhibitor dantrolene (Dan) or the IP3R inhibitor xestospongin C (XeC) along with TM. Beta cells treated with TM exhibited altered cytosolic and mitochondrial Ca2+ when in sub-threshold glucose compared to vehicle controls. As TM treatment also reduced ER Ca2+, this raised the possibility that the mitochondrial and cytosolic Ca2+ oscillations seen in stressed cells resulted from increased ER Ca2+ efflux mediated by RyRs and/or IP3Rs. We found that TM-induced ER Ca2+ depletion, as well as cytosolic and mitochondrial Ca2+ oscillations were inhibited by co-treatment with Dan, whereas the inclusion of XeC had little or no effect. Taken together, these results suggest that RyRs, and more specifically RyR1 plays a critical role in mediating the disturbed cellular Ca2+ homeostasis seen in response to the induction of ER stress. Disclosure: I. Zhang: None. V. S. Parekh: None. J. J. Leon: None. L. S. Satin: None. Funding: National Institutes of Health (R01DK46409); University of Michigan; JDRF (2-SRA-2018-539-A-B) [ABSTRACT FROM AUTHOR]

Published
2021
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168. Leptinotarsin: A presynaptic neurotoxin that stimulates release of acetylcholine

Author

McClure, William O., Abbott, Bernard C., Baxter, Daniel E., Hsiao, Ting H., Satin, Leslie S., Siger, Alvin, and Yoshino, Jun E.

Abstract

Leptinotarsin, a toxin found in the hemolymph of the beetle Leptinotarsa haldemani, can stimulate release of acetylcholine from synaptic termini. Leptinotarsin causes an increase in the frequency of miniature end plate potentials (mepps) of the rat phrenic nerve-diaphragm preparation. The increase in the frequency of mepps induced by leptinotarsin is biphasic: about 10% of the total mepps are released in an initial burst that lasts about 90 sec, after which the remaining mepps are released over a period of 10-20 min. Tetrodotoxin has no effect upon the release induced by leptinotarsin, but low-Ca2+conditions abolish the first phase. The two phases of release may represent two presynaptic pools of acetylcholine, both of which can be released in quantized form. In a second study, rat brain synaptosomes were incubated with [3H]choline and were immobilized on Millipore filters. Leptinotarsin induced release of [3H]acetylcholine from this preparation, confirming the release seen by using neurophysiological methods. The ability of leptinotarsin to induce release from either intact nerve terminals or synaptosomes was abolished when the toxin was heated. The releasing activity of leptinotarsin from synaptosomes was also partially dependent upon the presence of Ca2+in the perfusing solution. Release from synaptosomes followed first-order kinetics, and was not inhibited by commercial antibodies to black widow spider antigens. The data suggest that leptinotarsin acts as a presynaptic neurotoxin and may be of value as a mechanistic probe in understanding the storage and release of neurotransmitters.

Published
1980
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170. Intact pancreatic islets and dispersed beta-cells both generate intracellular calcium oscillations but differ in their responsiveness to glucose.

Author

Scarl, Rachel T., Corbin, Kathryn L., Vann, Nicholas W., Smith, Hallie M., Satin, Leslie S., Sherman, Arthur, and Nunemaker, Craig S.

Abstract

• When removed from islet structures, insulin-producing beta-cells produce heterogeneous calcium responses to glucose. • The sum of responses from many dispersed beta-cells produces an aggregate response similar to that of the intact islet. • A subset of beta cells possesses the fine-tuned glucose sensitivity found in the intact islet. • Mouse-to-mouse variability is a substantial contributor to islet heterogeneity in calcium patterns in vitro. 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. [ABSTRACT FROM AUTHOR]

Published
2019
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171. IAPP toxicity activates HIF1α/PFKFB3 signaling delaying β-cell loss at the expense of β-cell function.

Author

Montemurro, Chiara, Nomoto, Hiroshi, Pei, Lina, Parekh, Vishal S., Vongbunyong, Kenny E., Vadrevu, Suryakiran, Gurlo, Tatyana, Butler, Alexandra E., Subramaniam, Rohan, Ritou, Eleni, Shirihai, Orian S., Satin, Leslie S., Butler, Peter C., and Tudzarova, Slavica

Abstract

The islet in type 2 diabetes (T2D) is characterized by amyloid deposits derived from islet amyloid polypeptide (IAPP), a protein co-expressed with insulin by β-cells. In common with amyloidogenic proteins implicated in neurodegeneration, human IAPP (hIAPP) forms membrane permeant toxic oligomers implicated in misfolded protein stress. Here, we establish that hIAPP misfolded protein stress activates HIF1α/PFKFB3 signaling, this increases glycolysis disengaged from oxidative phosphorylation with mitochondrial fragmentation and perinuclear clustering, considered a protective posture against increased cytosolic Ca2+ characteristic of toxic oligomer stress. In contrast to tissues with the capacity to regenerate, β-cells in adult humans are minimally replicative, and therefore fail to execute the second pro-regenerative phase of the HIF1α/PFKFB3 injury pathway. Instead, β-cells in T2D remain trapped in the pro-survival first phase of the HIF1α injury repair response with metabolism and the mitochondrial network adapted to slow the rate of cell attrition at the expense of β-cell function. Type 2 diabetes is associated with islet amyloid deposits derived from islet amyloid polypeptide (IAPP) expressed by β-cells. Here the authors show that IAPP misfolded protein stress induces the hypoxia inducible factor 1 alpha injury repair pathway and activates survival metabolic changes mediated by PFKFB3. [ABSTRACT FROM AUTHOR]

Published
2019
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174. KATP channel activity and slow oscillations in pancreatic beta cells are regulated by mitochondrial ATP production.

Author

Corradi, Jeremías, Thompson, Benjamin, Fletcher, Patrick A., Bertram, Richard, Sherman, Arthur S., and Satin, Leslie S.

Subjects
*PANCREATIC beta cells, *PYRUVATE kinase, *OXIDATIVE phosphorylation, *PHASE oscillations, *BLOOD sugar
Abstract

Pancreatic beta cells secrete insulin in response to plasma glucose. The ATP‐sensitive potassium channel (KATP) links glucose metabolism to islet electrical activity in these cells by responding to increased cytosolic [ATP]/[ADP]. It was recently proposed that pyruvate kinase (PK) in close proximity to beta cell KATP locally produces the ATP that inhibits KATP activity. This proposal was largely based on the observation that applying phosphoenolpyruvate (PEP) and ADP to the cytoplasmic side of excised inside‐out patches inhibited KATP. To test the relative contributions of local vs. mitochondrial ATP production, we recorded KATP activity using mouse beta cells and INS‐1 832/13 cells. In contrast to prior reports, we could not replicate inhibition of KATP activity by PEP + ADP. However, when the pH of the PEP solutions was not corrected for the addition of PEP, strong channel inhibition was observed as a result of the well‐known action of protons to inhibit KATP. In cell‐attached recordings, perifusing either a PK activator or an inhibitor had little or no effect on KATP channel closure by glucose, further suggesting that PK is not an important regulator of KATP. In contrast, addition of mitochondrial inhibitors robustly increased KATP activity. Finally, by measuring the [ATP]/[ADP] responses to imposed calcium oscillations in mouse beta cells, we found that oxidative phosphorylation could raise [ATP]/[ADP] even when ADP was at its nadir during the burst silent phase, in agreement with our mathematical model. These results indicate that ATP produced by mitochondrial oxidative phosphorylation is the primary controller of KATP in pancreatic beta cells. Key points: Phosphoenolpyruvate (PEP) plus adenosine diphosphate does not inhibit KATP activity in excised patches. PEP solutions only inhibit KATP activity if the pH is unbalanced.Modulating pyruvate kinase has minimal effects on KATP activity.Mitochondrial inhibition, in contrast, robustly potentiates KATP activity in cell‐attached patches.Although the ADP level falls during the silent phase of calcium oscillations, mitochondria can still produce enough ATP via oxidative phosphorylation to close KATP.Mitochondrial oxidative phosphorylation is therefore the main source of the ATP that inhibits the KATP activity of pancreatic beta cells. [ABSTRACT FROM AUTHOR]

Published
2023
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175. ER stress increases expression of intracellular calcium channel RyR1 to modify Ca2+ homeostasis in pancreatic beta cells.

Author

Zhang, Irina X., Herrmann, Andrea, Leon, Juan, Jeyarajan, Sivakumar, Arunagiri, Anoop, Arvan, Peter, Gilon, Patrick, and Satin, Leslie S.

Subjects
*INTRACELLULAR calcium, *PANCREATIC beta cells, *CALCIUM channels, *RYANODINE receptors, *HOMEOSTASIS, *BLOOD sugar, *TYPE 2 diabetes, *ENDOPLASMIC reticulum
Abstract

Pancreatic beta cells maintain glucose homeostasis by secreting pulses of insulin in response to a rise in plasma glucose. Pulsatile insulin secretion occurs as a result of glucoseinduced oscillations in beta-cell cytosolic Ca2+. The endoplasmic reticulum (ER) helps regulate beta-cell cytosolic Ca2+, and ER stress can lead to ER Ca2+ reduction, beta-cell dysfunction, and an increased risk of type 2 diabetes. However, the mechanistic effects of ER stress on individual calcium channels are not well understood. To determine the effects of tunicamycin-induced ER stress on ER inositol 1,4,5- triphosphate receptors (IP3Rs) and ryanodine receptors (RyRs) and their involvement in subsequent Ca2+ dysregulation, we treated INS-1 832/13 cells and primary mouse islets with ER stress inducer tunicamycin (TM). We showed TM treatment increased RyR1 mRNA without affecting RyR2 mRNA and decreased both IP3R1 and IP3R3 mRNA. Furthermore, we found stress reduced ER Ca2+levels, triggered oscillations in cytosolic Ca2+under subthreshold glucose conditions, and increased apoptosis and that these changes were prevented by cotreatment with the RyR1 inhibitor dantrolene. In addition, we demonstrated silencing RyR1-suppressed TM-induced subthreshold cytosolic Ca2+ oscillations, but silencing RyR2 did not affect these oscillations. In contrast, inhibiting IP3Rs with xestospongin-C failed to suppress the TM-induced cytosolic Ca2+ oscillations and did not protect beta cells from TM-induced apoptosis although xestosponginC inclusion did prevent ER Ca2+ reduction. Taken together, these results show changes in RyR1 play a critical role in ER stress-induced Ca2+ dysfunction and beta-cell apoptosis. [ABSTRACT FROM AUTHOR]

Published
2023
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176. Ca2+ release or Ca2+ entry, that is the question: what governs Ca2+ oscillations in pancreatic β cells?

Author

Fletcher, Patrick A., Thompson, Ben, Liu, Chanté, Bertram, Richard, Satin, Leslie S., and Sherman, Arthur S.

Subjects
*RYANODINE receptors, *OSCILLATIONS, *MEMBRANE potential, *BLOOD sugar, *ENDOPLASMIC reticulum, *PLASMA potentials
Abstract

The standard model for Ca2+ oscillations in insulin-secreting pancreatic β cells centers on Ca2+ entry through voltage-activated Ca2+ channels. These work in combination with ATP-dependent K+ channels, which are the bridge between the metabolic state of the cells and plasma membrane potential. This partnership underlies the ability of the β cells to secrete insulin appropriately on a minute-to-minute time scale to control whole body plasma glucose. Though this model, developed over more than 40 years through many cycles of experimentation and mathematical modeling, has been very successful, it has been challenged by a hypothesis that calcium-induced calcium release from the endoplasmic reticulum through ryanodine or inositol trisphosphate (IP3) receptors is instead the key driver of islet oscillations. We show here that the alternative model is in fact incompatible with a large body of established experimental data and that the new observations offered in support of it can be better explained by the standard model. [ABSTRACT FROM AUTHOR]

Published
2023
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177. Synchronization of Islet Calcium Oscillations by Cholinergic Agonists.

Author

Min Zhang, Fendler, Bernard, Peercy, Bradley, Bertram, Richard, Sherman, Arthur, and Satin, Leslie S.

Subjects
SYNCHRONIZATION, CALCIUM in the body, OSCILLATIONS, ISLANDS of Langerhans, PARASYMPATHOLYTIC agents
Abstract

While individual pancreatic islets exhibit oscillations in free calcium and insulin secretion in response to glucose in vitro, how these oscillations are coordinated between islets in vivo is poorly understood. This is a significant gap in our knowledge as islet-islet oscillations must be synchronized for the pancreas to produce pulses of insulin. To ascertain how synchronization might be accomplished, we simultaneously monitored free Ca levels in 4-6 islets using the Ca sensing dye fura-2. Mouse islets were isolated using collagenase digestion and maintained in culture overnight. When placed in a chamber held at 37° C and perifused with saline containing 11.1 mM glucose, islets exhibited regular Ca oscillations with a period of 3-6 minutes. Under these conditions, the Ca oscillations of neighboring islets were asynchronous even though the periods of the oscillations were similar. However, a 15 see application of the cholinergic agonist carbachol (25/µM) caused profound islet to islet synchronization in >50 experiments. In contrast, application of the adrenergic agonists clonidine or norepinephrine or the depolarizing agents KCI or tolbutamide failed to synchronize the islets. The action of carbachol was glucose-dependent, as carbachol applied in saline containing 5.5 or 7.5 mM glucose was much less effective in synchronizing neighboring islets. Cholinergic agonists increase both Ca influx and ER Ca release in islet beta cells. Synchronization persisted in islets treated with 1 µM thapsigargin to deplete their ER Ca stores suggesting that Ca influx is sufficient for islet to islet synchronization. Parallel computer simulations of model islets suggest a dynamic mechanism for the synchronization that we observe. These results suggest that acetylcholine release from intrapancreatic neurons may help mediate islet to islet synchronization within the pancreas and the coordination of islet secretory oscillations. Supported by NIH DK RO146409 and NSF DMS 0613179. [ABSTRACT FROM AUTHOR]

Published
2007

180. Metabolic and electrical oscillations: partners in controlling pulsatile insulin secretion.

Author

Bertram, Richard, Sherman, Arthur, and Satin, Leslie S.

Subjects
*OSCILLATIONS, *INSULIN, *PANCREATIC secretions, *PANCREATIC beta cells, *MATHEMATICAL models, *DIABETES, *ISLANDS of Langerhans
Abstract

Impairment of insulin secretion from the β-cells of the pancreatic islets of Langerhans is central to the development of type 2 diabetes mellitus and has therefore been the subject of much investigation. Great advances have been made in this area, but the mechanisms underlying the pulsatility of insulin secretion remain controversial. The period of these pulses is 4–6 min and reflects oscillations in islet membrane potential and intracellular free Ca2+ Pulsatile blood insulin levels appear to play an important physiological role in insulin action and are lost in patients with type 2 diabetes and their near relatives. We present evidence for a recently developed β-cell model, the ‘dual oscillator model,’ in which oscillations in activity are due to both electrical and metabolic mechanisms. This model is capable of explaining much of the available data on islet activity and offers possible resolutions of a number of longstanding issues. The model, however, still lacks direct confirmation and raises new issues. In this article, we highlight both the successes of the model and the challenges that it poses for the field. [ABSTRACT FROM AUTHOR]

Published
2007
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181. ER stress increases store-operated Ca2+ entry (SOCE) and augments basal insulin secretion in pancreatic beta cells.

Author

Zhang, Irina X., Jianhua Ren, Vadrevu, Suryakiran, Raghavan, Malini, and Satin, Leslie S.

Subjects
*ENDOPLASMIC reticulum, *PANCREATIC beta cells, *PANCREATIC secretions, *TYPE 2 diabetes, *INSULIN
Abstract

Type 2 diabetes mellitus (T2DM) is characterized by impaired glucose-stimulated insulin secretion and increased peripheral insulin resistance. Unremitting endoplasmic reticulum (ER) stress can lead to beta-cell apoptosis and has been linked to type 2 diabetes. Although many studies have attempted to link ER stress and T2DM, the specific effects of ER stress on beta-cell function remain incompletely understood. To determine the interrelationship between ER stress and beta-cell function, here we treated insulin-secreting INS-1(832/13) cells or isolated mouse islets with the ER stress-inducer tunicamycin (TM). TM induced ER stress as expected, as evidenced by activation of the unfolded protein response. Beta cells treated with TM also exhibited concomitant alterations in their electrical activity and cytosolic free Ca2+ oscillations. As ER stress is known to reduce ER Ca2+ levels, we tested the hypothesis that the observed increase in Ca2+ oscillations occurred because of reduced ER Ca2+ levels and, in turn, increased store-operated Ca2+ entry. TM-induced cytosolic Ca2+ and membrane electrical oscillations were acutely inhibited by YM58483, which blocks store-operated Ca2+ channels. Significantly, TM-treated cells secreted increased insulin under conditions normally associated with only minimal release, e.g.5mM glucose, and YM58483 blocked this secretion. Taken together, these results support a critical role for ER Ca2+ depletion-activated Ca2+ current in mediating Ca2+-induced insulin secretion in response to ER stress. [ABSTRACT FROM AUTHOR]

Published
2020
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182. Deconstructing the integrated oscillator model for pancreatic [formula omitted]-cells.

Author

Bertram, Richard, Marinelli, Isabella, Fletcher, Patrick A., Satin, Leslie S., and Sherman, Arthur S.

Subjects
*ISLANDS of Langerhans, *MATHEMATICAL models, *ANNIVERSARIES, *OSCILLATIONS, *PANCREATIC beta cells
Abstract

Electrical bursting oscillations in the β -cells of pancreatic islets have been a focus of investigation for more than fifty years. This has been aided by mathematical models, which are descendants of the pioneering Chay–Keizer model. This article describes the key biophysical and mathematical elements of this model, and then describes the path forward from there to the Integrated Oscillator Model (IOM). It is both a history and a deconstruction of the IOM that describes the various elements that have been added to the model over time, and the motivation for adding them. Finally, the article is a celebration of the 40th anniversary of the publication of the Chay–Keizer model. • Description of the first model of bursting activity in pancreatic β -cells. • Progression to the recent Integrated Oscillator Model for β -cells. • Key steps driven by interaction with an experimental lab. • Widely applicable mathematical concepts for multi-modal oscillations are discussed. [ABSTRACT FROM AUTHOR]

Published
2023
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184. Loss of Cyclin-dependent Kinase 2 in the Pancreas Links Primary β-Cell Dysfunction to Progressive Depletion of β-Cell Mass and Diabetes.

Author

So Yoon Kim, Ji-Hyeon Lee, Merrins, Matthew J., Gavrilova, Oksana, Bisteau, Xavier, Kaldis, Philipp, Satin, Leslie S., and Rane, Sushil G.

Subjects
*CYCLIN-dependent kinases, *CELL proliferation, *DIABETES, *CELL metabolism, *MITOCHONDRIA
Abstract

The failure of pancreatic islet β-cells is a major contributor to the etiology of type 2 diabetes. β-Cell dysfunction and declining β-cell mass are two mechanisms that contribute to this failure, although it is unclear whether they are molecularly linked. Here, we show that the cell cycle regulator, cyclin-dependent kinase 2 (CDK2), couples primary β-cell dysfunction to the progressive deterioration of β-cell mass in diabetes. Mice with pancreasspecific deletion of Cdk2 are glucose-intolerant, primarily due to defects in glucose-stimulated insulin secretion. Accompanying this loss of secretion are defects in β-cell metabolism and perturbed mitochondrial structure. Persistent insulin secretion defects culminate in progressive deficits in β-cell proliferation, reduced β-cell mass, and diabetes. These outcomes may be mediated directly by the loss of CDK2, which binds to and phosphorylates the transcription factor FOXO1 in a glucose-dependent manner. Further, we identified a requirement for CDK2 in the compensatory increases in β-cell mass that occur in response to age- and diet-induced stress. Thus, CDK2 serves as an important nexus linking primary β-cell dysfunction to progressive β-cell mass deterioration in diabetes. [ABSTRACT FROM AUTHOR]

Published
2017
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185. RhoC GTPase Is a Potent Regulator of Glutamine Metabolism and N-Acetylaspartate Production in Inflammatory Breast Cancer Cells.

Author

Wynn, Michelle L., Yates, Joel A., Evans, Charles R., Van Wassenhove, Lauren D., Zhi Fen Wu, Bridges, Sydney, Liwei Bao, Fournier, Chelsea, Ashrafzadeh, Sepideh, Merrins, Matthew J., Satin, Leslie S., Schnell, Santiago, Burant, Charles F., and Merajver, Sofia D.

Subjects
*RHO GTPases, *GLUTAMINE metabolism, *ASPARTATES, *INFLAMMATORY breast cancer, *METASTASIS
Abstract

Inflammatory breast cancer (IBC) is an extremely lethal cancer that rapidly metastasizes. Although the molecular attributes of IBC have been described, little is known about the underlying metabolic features of the disease. Using a variety of metabolic assays, including 13C tracer experiments, we found that SUM149 cells, the primary in vitro model of IBC, exhibit metabolic abnormalities that distinguish them from other breast cancer cells, including elevated levels ofN-acetylaspartate, a metabolite primarily associated with neuronal disorders and gliomas. Here we provide the first evidence ofN-acetylaspartate in breast cancer. We also report that the oncogene RhoC, a driver of metastatic potential, modulates glutamine and N-acetylaspartate metabolism in IBC cells in vitro, revealing a novel role for RhoC as a regulator of tumor cell metabolism that extends beyond its well known role in cytoskeletal rearrangement. [ABSTRACT FROM AUTHOR]

Published
2016
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186. Pancreatic and Duodenal Homeobox Protein 1 (Pdx-1) Maintains Endoplasmic Reticulum Calcium Levels through Transcriptional Regulation of Sarco-endoplasmic Reticulum Calcium ATPase 2b (SERCA2b) in the Islet β Cell.

Author

Johnson, Justin S., Tatsuyoshi Kono, Xin Tong, Wataru R. Yamamoto, Zarain-Herzberg, Angel, Merrins, Matthew J., Satin, Leslie S., Gilon, Patrick, and Evans-Molina, Carmella

Subjects
*HOMEOBOX proteins, *INTRACELLULAR calcium, *ADENOSINE triphosphatase, *PANCREATIC beta cells, *BINDING sites, *SMALL interfering RNA, *PROMOTERS (Genetics), *LUCIFERASES
Abstract

Although the pancreatic duodenal homeobox 1 (Pdx-1) transcription factor is known to play an indispensable role in β cell development and secretory function, recent data also implicate Pdx-1 in the maintenance of endoplasmic reticulum (ER) health. The sarco-endoplasmic reticulum Ca2+ ATPase 2b (SERCA2b) pump maintains a steep Ca2+ gradient between the cytosol and ER lumen. In models of diabetes, our data demonstrated loss of β cell Pdx-1 that occurs in parallel with altered SERCA2b expression, whereas in silico analysis of the SERCA2b promoter revealed multiple putative Pdx-1 binding sites. We hypothesized that Pdx-1 loss under inflammatory and diabetic conditions leads to decreased SERCA2b levels and activity with concomitant alterations in ER health. To test this, siRNA-mediated knockdown of Pdx-1 was performed in INS-1 cells. The results revealed reduced SERCA2b expression and decreased ER Ca2+, which was measured using fluorescence lifetime imaging microscopy. Cotransfection of human Pdx-1 with a reporter fused to the human SERCA2 promoter increased luciferase activity 3- to 4-fold relative to an empty vector control, and direct binding of Pdx-1 to the proximal SERCA2 promoter was confirmed by chromatin immunoprecipitation. To determine whether restoration ofSERCA2b could rescue ER stress induced by Pdx-1 loss, Pdx1+/- mice were fed a high-fat diet. Isolated islets demonstrated an increased spliced-to-total Xbp1 ratio, whereas SERCA2b overexpression reduced the Xbp1 ratio to that of wild-type controls. Together, these results identify SERCA2b as a novel transcriptional target of Pdx-1 and define a role for altered ER Ca2+ regulation in Pdx-1-deficient states. [ABSTRACT FROM AUTHOR]

Published
2014
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187. Maternal diet-induced microRNAs and mTOR underlie β cell dysfunction in offspring.

Author

Alejandro, Emilyn U., Gregg, Brigid, Wallen, Taylor, Kumusoglu, Doga, Meister, Daniel, Chen, Angela, Merrins, Matthew J., Satin, Leslie S., Liu, Ming, Arvan, Peter, and Bernal-Mizrachi, Ernesto

Subjects
*MICRORNA, *TYPE 2 diabetes risk factors, *MATERNAL nutrition, *LOW-protein diet, *MTOR protein
Abstract

A maternal diet that is low in protein increases the susceptibility of offspring to type 2 diabetes by inducing long-term alterations in β cell mass and function. Nutrients and growth factor signaling converge through mTOR, suggesting that this pathway participates in β cell programming during fetal development. Here, we revealed that newborns of dams exposed to low-protein diet (LP0.5) throughout pregnancy exhibited decreased insulin levels, a lower β cell fraction, and reduced mTOR signaling. Adult offspring of LP0.5-exposed mothers exhibited glucose intolerance as a result of an insulin secretory defect and not β cell mass reduction. The β cell insulin secretory defect was distal to glucose-dependent Ca2+ influx and resulted from reduced proinsulin biosynthesis and insulin content. Islets from offspring of LP0.5-fed dams exhibited reduced mTOR and increased expression of a subset of microRNAs, and blockade of microRNA-199a-3p and -342 in these islets restored mTOR and insulin secretion to normal. Finally, transient β cell activation of mTORC1 signaling in offspring during the last week of pregnancy of mothers fed a LP0.5 rescued the defect in the neonatal β cell fraction and metabolic abnormalities in the adult. Together, these findings indicate that a maternal low-protein diet alters microRNA and mTOR expression in the offspring, influencing insulin secretion and glucose homeostasis. [ABSTRACT FROM AUTHOR]

Published
2014
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188. Direct Measurements of Oscillatory Glycolysis in Pancreatic Islet β-Cells Using Novel Fluorescence Resonance Energy Transfer (FRET) Biosensors for Pyruvate Kinase M2 Activity.

Author

Merrins, Matthew J., Van Dyke, Aaron R., Mapp, Anna K., Rizzo, Mark A., and Satin, Leslie S.

Subjects
*GLYCOLYSIS, *BLOOD testing, *ISLANDS of Langerhans, *ENDOCRINE glands, *B cells, *FLUORESCENCE resonance energy transfer
Abstract

Pulses of insulin released from pancreatic β-cells maintain blood glucose in a narrow range, although the source of these pulses is unclear. We and others have proposed that positive feedback mediated by the glycolytic enzyme phosphofructoki-nase-1 (PFK1) enables β-cells to generate metabolic oscillations via autocatalytic activation by its product fructose 1,6-bisphosphate (FBP). Although much indirect evidence has accumulated in favor of this hypothesis, a direct measurement of oscillating glycolytic intermediates has been lacking. To probe glycolysis directly, we engineered a family of inter- and intramolecular FRET biosensors based on the glycolytic enzyme pyruvate kinase M2 (PKAR; pyruvate kinase activity reporter), which multimerizes and is activated upon binding FBP. When introduced into Min6 β-cells, PKAR FRET efficiency increased rapidly in response to glucose. Importantly, however, metabolites entering downstream of PFK1 (glyceraldehyde, pyruvate, and ketoisocaproate) failed to activate PKAR, consistent with sensor activation by FBP; the dependence of PKAR on FBP was further confirmed using purified sensor in vitro. Using a novel imaging modality for monitoring mitochondrial flavin fluorescence in mouse islets, we show that slow oscillations in mitochondrial redox potential stimulated by 10 mM glucose are in phase with glycolytic efflux through PKM2, measured simultaneously from neighboring islet β-cells expressing PKAR. These results indicate that PKM2 activity in β-cells is oscillatory and are consistent with pulsatile PFK1 being the mediator of slow glycolytic oscillations. [ABSTRACT FROM AUTHOR]

Published
2013
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189. 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
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190. Proinsulin folding and trafficking defects trigger a common pathological disturbance of endoplasmic reticulum homeostasis.

Author

Arunagiri A, Alam M, Haataja L, Draz H, Alasad B, Samy P, Sadique N, Tong Y, Cai Y, Shakeri H, Fantuzzi F, Ibrahim H, Jang I, Sidarala V, Soleimanpour SA, Satin LS, Otonkoski T, Cnop M, Itkin-Ansari P, Kaufman RJ, Liu M, and Arvan P

Subjects
Mice, Animals, Proinsulin genetics, Proinsulin chemistry, Protein Folding, Insulin chemistry, Endoplasmic Reticulum, Homeostasis, Disulfides chemistry, Diabetes Mellitus, Insulin-Secreting Cells
Abstract

Primary defects in folding of mutant proinsulin can cause dominant-negative proinsulin accumulation in the endoplasmic reticulum (ER), impaired anterograde proinsulin trafficking, perturbed ER homeostasis, diminished insulin production, and β-cell dysfunction. Conversely, if primary impairment of ER-to-Golgi trafficking (which also perturbs ER homeostasis) drives misfolding of nonmutant proinsulin-this might suggest bi-directional entry into a common pathological phenotype (proinsulin misfolding, perturbed ER homeostasis, and deficient ER export of proinsulin) that can culminate in diminished insulin storage and diabetes. Here, we've challenged β-cells with conditions that impair ER-to-Golgi trafficking, and devised an accurate means to assess the relative abundance of distinct folded/misfolded forms of proinsulin using a novel nonreducing SDS-PAGE/immunoblotting protocol. We confirm abundant proinsulin misfolding upon introduction of a diabetogenic INS mutation, or in the islets of db/db mice. Whereas blockade of proinsulin trafficking in Golgi/post-Golgi compartments results in intracellular accumulation of properly-folded proinsulin (bearing native disulfide bonds), impairment of ER-to-Golgi trafficking (regardless whether such impairment is achieved by genetic or pharmacologic means) results in decreased native proinsulin with more misfolded proinsulin. Remarkably, reversible ER-to-Golgi transport defects (such as treatment with brefeldin A or cellular energy depletion) upon reversal quickly restore the ER folding environment, resulting in the disappearance of pre-existing misfolded proinsulin while preserving proinsulin bearing native disulfide bonds. Thus, proper homeostatic balance of ER-to-Golgi trafficking is linked to a more favorable proinsulin folding (as well as trafficking) outcome., (© 2024 The Authors. Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published
2024
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191. K ATP channel activity and slow oscillations in pancreatic beta cells are regulated by mitochondrial ATP production.

Author

Corradi J, Thompson B, Fletcher PA, Bertram R, Sherman AS, and Satin LS

Subjects
Mice, Animals, Adenosine Triphosphate pharmacology, Adenosine Triphosphate metabolism, Phosphoenolpyruvate metabolism, Phosphoenolpyruvate pharmacology, Pyruvate Kinase metabolism, Pyruvate Kinase pharmacology, Adenosine Diphosphate pharmacology, Adenosine Diphosphate metabolism, Mitochondria metabolism, Insulin-Secreting Cells metabolism, Islets of Langerhans
Abstract

Pancreatic beta cells secrete insulin in response to plasma glucose. The ATP-sensitive potassium channel (K ATP ) links glucose metabolism to islet electrical activity in these cells by responding to increased cytosolic [ATP]/[ADP]. It was recently proposed that pyruvate kinase (PK) in close proximity to beta cell K ATP locally produces the ATP that inhibits K ATP activity. This proposal was largely based on the observation that applying phosphoenolpyruvate (PEP) and ADP to the cytoplasmic side of excised inside-out patches inhibited K ATP . To test the relative contributions of local vs. mitochondrial ATP production, we recorded K ATP activity using mouse beta cells and INS-1 832/13 cells. In contrast to prior reports, we could not replicate inhibition of K ATP activity by PEP + ADP. However, when the pH of the PEP solutions was not corrected for the addition of PEP, strong channel inhibition was observed as a result of the well-known action of protons to inhibit K ATP . In cell-attached recordings, perifusing either a PK activator or an inhibitor had little or no effect on K ATP channel closure by glucose, further suggesting that PK is not an important regulator of K ATP . In contrast, addition of mitochondrial inhibitors robustly increased K ATP activity. Finally, by measuring the [ATP]/[ADP] responses to imposed calcium oscillations in mouse beta cells, we found that oxidative phosphorylation could raise [ATP]/[ADP] even when ADP was at its nadir during the burst silent phase, in agreement with our mathematical model. These results indicate that ATP produced by mitochondrial oxidative phosphorylation is the primary controller of K ATP in pancreatic beta cells. KEY POINTS: Phosphoenolpyruvate (PEP) plus adenosine diphosphate does not inhibit K ATP activity in excised patches. PEP solutions only inhibit K ATP activity if the pH is unbalanced. Modulating pyruvate kinase has minimal effects on K ATP activity. Mitochondrial inhibition, in contrast, robustly potentiates K ATP activity in cell-attached patches. Although the ADP level falls during the silent phase of calcium oscillations, mitochondria can still produce enough ATP via oxidative phosphorylation to close K ATP . Mitochondrial oxidative phosphorylation is therefore the main source of the ATP that inhibits the K ATP activity of pancreatic beta cells., (© 2023 The Authors. The Journal of Physiology published by John Wiley & Sons Ltd on behalf of The Physiological Society.)

Published
2023
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192. ER stress increases expression of intracellular calcium channel RyR1 to modify Ca 2+ homeostasis in pancreatic beta cells.

Author

Zhang IX, Herrmann A, Leon J, Jeyarajan S, Arunagiri A, Arvan P, Gilon P, and Satin LS

Subjects
Animals, Mice, Apoptosis, Diabetes Mellitus, Type 2 metabolism, Glucose metabolism, Homeostasis, Tunicamycin, Rats, Cell Line, Calcium Signaling, Endoplasmic Reticulum Stress, Insulin-Secreting Cells metabolism, Ryanodine Receptor Calcium Release Channel genetics, Ryanodine Receptor Calcium Release Channel metabolism
Abstract

Pancreatic beta cells maintain glucose homeostasis by secreting pulses of insulin in response to a rise in plasma glucose. Pulsatile insulin secretion occurs as a result of glucose-induced oscillations in beta-cell cytosolic Ca 2+ . The endoplasmic reticulum (ER) helps regulate beta-cell cytosolic Ca 2+ , and ER stress can lead to ER Ca 2+ reduction, beta-cell dysfunction, and an increased risk of type 2 diabetes. However, the mechanistic effects of ER stress on individual calcium channels are not well understood. To determine the effects of tunicamycin-induced ER stress on ER inositol 1,4,5-triphosphate receptors (IP3Rs) and ryanodine receptors (RyRs) and their involvement in subsequent Ca 2+ dysregulation, we treated INS-1 832/13 cells and primary mouse islets with ER stress inducer tunicamycin (TM). We showed TM treatment increased RyR1 mRNA without affecting RyR2 mRNA and decreased both IP3R1 and IP3R3 mRNA. Furthermore, we found stress reduced ER Ca 2+ levels, triggered oscillations in cytosolic Ca 2+ under subthreshold glucose conditions, and increased apoptosis and that these changes were prevented by cotreatment with the RyR1 inhibitor dantrolene. In addition, we demonstrated silencing RyR1-suppressed TM-induced subthreshold cytosolic Ca 2+ oscillations, but silencing RyR2 did not affect these oscillations. In contrast, inhibiting IP3Rs with xestospongin-C failed to suppress the TM-induced cytosolic Ca 2+ oscillations and did not protect beta cells from TM-induced apoptosis although xestospongin-C inclusion did prevent ER Ca 2+ reduction. Taken together, these results show changes in RyR1 play a critical role in ER stress-induced Ca 2+ dysfunction and beta-cell apoptosis., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2023
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193. Sex Differences in Pancreatic β-Cell Physiology and Glucose Homeostasis in C57BL/6J Mice.

Author

Jo S, Beetch M, Gustafson E, Wong A, Oribamise E, Chung G, Vadrevu S, Satin LS, Bernal-Mizrachi E, and Alejandro EU

Abstract

The importance of sexual dimorphism has been highlighted in recent years since the National Institutes of Health's mandate on considering sex as a biological variable. Although recent studies have taken strides to study both sexes side by side, investigations into the normal physiological differences between males and females are limited. In this study, we aimed to characterized sex-dependent differences in glucose metabolism and pancreatic β-cell physiology in normal conditions using C57BL/6J mice, the most common mouse strain used in metabolic studies. Here, we report that female mice have improved glucose and insulin tolerance associated with lower nonfasted blood glucose and insulin levels compared with male mice at 3 and 6 months of age. Both male and female animals show β-cell mass expansion from embryonic day 17.5 to adulthood, and no sex differences were observed at embryonic day 17.5, newborn, 1 month, or 3 months of age. However, 6-month-old males displayed increased β-cell mass in response to insulin resistance compared with littermate females. Molecularly, we uncovered sexual dimorphic alterations in the protein levels of nutrient sensing proteins O-GlcNAc transferase and mTOR, as well as differences in glucose-stimulus coupling mechanisms that may underlie the differences in sexually dimorphic β-cell physiology observed in C57BL/6J mice., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Endocrine Society.)

Published
2023
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194. Ca 2+ release or Ca 2+ entry, that is the question: what governs Ca 2+ oscillations in pancreatic β cells?

Author

Fletcher PA, Thompson B, Liu C, Bertram R, Satin LS, and Sherman AS

Subjects
Calcium metabolism, Insulin metabolism, Calcium Signaling, Insulin Secretion, Insulin-Secreting Cells metabolism
Abstract

The standard model for Ca 2+ oscillations in insulin-secreting pancreatic β cells centers on Ca 2+ entry through voltage-activated Ca 2+ channels. These work in combination with ATP-dependent K + channels, which are the bridge between the metabolic state of the cells and plasma membrane potential. This partnership underlies the ability of the β cells to secrete insulin appropriately on a minute-to-minute time scale to control whole body plasma glucose. Though this model, developed over more than 40 years through many cycles of experimentation and mathematical modeling, has been very successful, it has been challenged by a hypothesis that calcium-induced calcium release from the endoplasmic reticulum through ryanodine or inositol trisphosphate (IP3) receptors is instead the key driver of islet oscillations. We show here that the alternative model is in fact incompatible with a large body of established experimental data and that the new observations offered in support of it can be better explained by the standard model.

Published
2023
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195. Simultaneous Measurement of Changes in Mitochondrial and Endoplasmic Reticulum Free Calcium in Pancreatic Beta Cells.

Author

Jeyarajan S, Zhang IX, Arvan P, Lentz SI, and Satin LS

Subjects
Calcium metabolism, Calcium pharmacology, Mitochondria metabolism, Endoplasmic Reticulum, Insulin Secretion, Insulin-Secreting Cells metabolism
Abstract

The free calcium (Ca 2+ ) levels in pancreatic beta cell organelles have been the subject of many recent investigations. Under pathophysiological conditions, disturbances in these pools have been linked to altered intracellular communication and cellular dysfunction. To facilitate studies of subcellular Ca 2+ signaling in beta cells and, particularly, signaling between the endoplasmic reticulum (ER) and mitochondria, we designed a novel dual Ca 2+ sensor which we termed DS-1. DS-1 encodes two stoichiometrically fluorescent proteins within a single plasmid, G-CEPIA-er, targeted to the ER and R-CEPIA3-mt, targeted to mitochondria. Our goal was to simultaneously measure the ER and mitochondrial Ca 2+ in cells in real time. The K ds of G-CEPIA-er and R-CEPIA3-mt for Ca 2+ are 672 and 3.7 μM, respectively. Confocal imaging of insulin-secreting INS-1 832/13 expressing DS-1 confirmed that the green and red fluorophores correctly colocalized with organelle-specific fluorescent markers as predicted. Further, we tested whether DS-1 exhibited the functional properties expected by challenging an INS-1 cell to glucose concentrations or drugs having well-documented effects on the ER and mitochondrial Ca 2+ handling. The data obtained were consistent with those seen using other single organelle targeted probes. These results taken together suggest that DS-1 is a promising new approach for investigating Ca 2+ signaling within multiple organelles of the cell.

Published
2023
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196. Symbiosis of Electrical and Metabolic Oscillations in Pancreatic β-Cells.

Author

Marinelli I, Fletcher PA, Sherman AS, Satin LS, and Bertram R

Abstract

Insulin is secreted in a pulsatile pattern, with important physiological ramifications. In pancreatic β-cells, which are the cells that synthesize insulin, insulin exocytosis is elicited by pulses of elevated intracellular Ca 2+ initiated by bursts of electrical activity. In parallel with these electrical and Ca 2+ oscillations are oscillations in metabolism, and the periods of all of these oscillatory processes are similar. A key question that remains unresolved is whether the electrical oscillations are responsible for the metabolic oscillations via the effects of Ca 2+ , or whether the metabolic oscillations are responsible for the electrical oscillations due to the effects of ATP on ATP-sensitive ion channels? Mathematical modeling is a useful tool for addressing this and related questions as modeling can aid in the design of well-focused experiments that can test the predictions of particular models and subsequently be used to improve the models in an iterative fashion. In this article, we discuss a recent mathematical model, the Integrated Oscillator Model (IOM), that was the product of many years of development. We use the model to demonstrate that the relationship between calcium and metabolism in beta cells is symbiotic: in some contexts, the electrical oscillations drive the metabolic oscillations, while in other contexts it is the opposite. We provide new insights regarding these results and illustrate that what might at first appear to be contradictory data are actually compatible when viewed holistically with the IOM., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Marinelli, Fletcher, Sherman, Satin and Bertram.)

Published
2021
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197. Beta-Cell Ion Channels and Their Role in Regulating Insulin Secretion.

Author

Thompson B and Satin LS

Subjects
Glucose metabolism, Humans, Insulin metabolism, Insulin Secretion, Ion Channels metabolism, Diabetes Mellitus, Type 2 metabolism, Insulin-Secreting Cells metabolism
Abstract

Beta cells of the pancreatic islet express many different types of ion channels. These channels reside in the β-cell plasma membrane as well as subcellular organelles and their coordinated activity and sensitivity to metabolism regulate glucose-dependent insulin secretion. Here, we review the molecular nature, expression patterns, and functional roles of many β-cell channels, with an eye toward explaining the ionic basis of glucose-induced insulin secretion. Our primary focus is on K ATP and voltage-gated Ca 2+ channels as these primarily regulate insulin secretion; other channels in our view primarily help to sculpt the electrical patterns generated by activated β-cells or indirectly regulate metabolism. Lastly, we discuss why understanding the physiological roles played by ion channels is important for understanding the secretory defects that occur in type 2 diabetes. © 2021 American Physiological Society. Compr Physiol 11:1-21, 2021., (Copyright © 2021 American Physiological Society. All rights reserved.)

Published
2021
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198. Chop / Ddit3 depletion in β cells alleviates ER stress and corrects hepatic steatosis in mice.

Author

Yong J, Parekh VS, Reilly SM, Nayak J, Chen Z, Lebeaupin C, Jang I, Zhang J, Prakash TP, Sun H, Murray S, Guo S, Ayala JE, Satin LS, Saltiel AR, and Kaufman RJ

Subjects
Animals, Diet, High-Fat adverse effects, Endoplasmic Reticulum Stress, Insulin metabolism, Insulin Secretion, Mice, Mice, Inbred C57BL, Diabetes Mellitus, Type 2 metabolism, Fatty Liver, Insulin-Secreting Cells metabolism
Abstract

Type 2 diabetes (T2D) is a metabolic disorder characterized by hyperglycemia, hyperinsulinemia, and insulin resistance (IR). During the early phase of T2D, insulin synthesis and secretion by pancreatic β cells is enhanced, which can lead to proinsulin misfolding that aggravates endoplasmic reticulum (ER) protein homeostasis in β cells. Moreover, increased circulating insulin may contribute to fatty liver disease. Medical interventions aimed at alleviating ER stress in β cells while maintaining optimal insulin secretion are therefore an attractive therapeutic strategy for T2D. Previously, we demonstrated that germline Chop gene deletion preserved β cells in high-fat diet (HFD)-fed mice and in leptin receptor-deficient db/db mice. In the current study, we further investigated whether targeting Chop/Ddit3 specifically in murine β cells conferred therapeutic benefits. First, we showed that Chop deletion in β cells alleviated β cell ER stress and delayed glucose-stimulated insulin secretion (GSIS) in HFD-fed mice. Second, β cell-specific Chop deletion prevented liver steatosis and hepatomegaly in aged HFD-fed mice without affecting basal glucose homeostasis. Third, we provide mechanistic evidence that Chop depletion reduces ER Ca 2+ buffering capacity and modulates glucose-induced islet Ca 2+ oscillations, leading to transcriptional changes of ER chaperone profile ("ER remodeling"). Last, we demonstrated that a GLP1-conjugated Chop antisense oligonucleotide strategy recapitulated the reduction in liver triglycerides and pancreatic insulin content. In summary, our results demonstrate that Chop depletion in β cells provides a therapeutic strategy to alleviate dysregulated insulin secretion and consequent fatty liver disease in T2D., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2021
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199. New Aspects of Diabetes Research and Therapeutic Development.

Author

Satin LS, Soleimanpour SA, and Walker EM

Subjects
Humans, Hypoglycemic Agents therapeutic use, Insulin, Diabetes Mellitus, Type 1, Diabetes Mellitus, Type 2 drug therapy
Abstract

Both type 1 and type 2 diabetes mellitus are advancing at exponential rates, placing significant burdens on health care networks worldwide. Although traditional pharmacologic therapies such as insulin and oral antidiabetic stalwarts like metformin and the sulfonylureas continue to be used, newer drugs are now on the market targeting novel blood glucose-lowering pathways. Furthermore, exciting new developments in the understanding of beta cell and islet biology are driving the potential for treatments targeting incretin action, islet transplantation with new methods for immunologic protection, and the generation of functional beta cells from stem cells. Here we discuss the mechanistic details underlying past, present, and future diabetes therapies and evaluate their potential to treat and possibly reverse type 1 and 2 diabetes in humans. SIGNIFICANCE STATEMENT: Diabetes mellitus has reached epidemic proportions in the developed and developing world alike. As the last several years have seen many new developments in the field, a new and up to date review of these advances and their careful evaluation will help both clinical and research diabetologists to better understand where the field is currently heading., (U.S. Government work not protected by U.S. copyright.)

Published
2021
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200. Roles of Calreticulin in Protein Folding, Immunity, Calcium Signaling and Cell Transformation.

Author

Venkatesan A, Satin LS, and Raghavan M

Subjects
Calnexin genetics, Calnexin metabolism, Calreticulin genetics, Calreticulin metabolism, Endoplasmic Reticulum genetics, Endoplasmic Reticulum metabolism, Immune System, Protein Folding, Calcium Signaling genetics
Abstract

The endoplasmic reticulum (ER) is an organelle that mediates the proper folding and assembly of proteins destined for the cell surface, the extracellular space and subcellular compartments such as the lysosomes. The ER contains a wide range of molecular chaperones to handle the folding requirements of a diverse set of proteins that traffic through this compartment. The lectin-like chaperones calreticulin and calnexin are an important class of structurally-related chaperones relevant for the folding and assembly of many N-linked glycoproteins. Despite the conserved mechanism of action of these two chaperones in nascent protein recognition and folding, calreticulin has unique functions in cellular calcium signaling and in the immune response. The ER-related functions of calreticulin in the assembly of major histocompatibility complex (MHC) class I molecules are well-studied and provide many insights into the modes of substrate and co-chaperone recognition by calreticulin. Calreticulin is also detectable on the cell surface under some conditions, where it induces the phagocytosis of apoptotic cells. Furthermore, mutations of calreticulin induce cell transformation in myeloproliferative neoplasms (MPN). Studies of the functions of the mutant calreticulin in cell transformation and immunity have provided many insights into the normal biology of calreticulin, which are discussed.

Published
2021
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