Your search keyword '"Glucagon-Secreting Cells metabolism"' showing total 68 results

1. The Longitudinal Effect of Diabetes-Associated Variation in TCF7L2 on Islet Function in Humans.

Author

Zeini M, Laurenti MC, Egan AM, Muthusamy K, Ramar A, Vella E, Bailey KR, Cobelli C, Dalla Man C, and Vella A

Subjects

Humans, Male, Female, Adult, Middle Aged, Longitudinal Studies, Glucagon-Secreting Cells metabolism, Islets of Langerhans metabolism, Genotype, Blood Glucose metabolism, Glucose Intolerance genetics, Glucose Intolerance metabolism, Alleles, Transcription Factor 7-Like 2 Protein genetics, Transcription Factor 7-Like 2 Protein metabolism, Diabetes Mellitus, Type 2 genetics, Diabetes Mellitus, Type 2 metabolism, Glucagon metabolism, Glucose Tolerance Test, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells physiology

Abstract

The T allele at rs7903146 in TCF7L2 increases the rate of conversion from prediabetes to type 2 diabetes. This has been associated with impaired β-cell function and with defective suppression of α-cell secretion by glucose. However, the temporal relationship of these abnormalities is uncertain. To study the longitudinal changes in islet function, we recruited 128 subjects, with 67 homozygous for the diabetes-associated allele (TT) at rs7903146 and 61 homozygous for the protective allele. Subjects were studied on two occasions, 3 years apart, using an oral 75-g glucose challenge. The oral minimal model was used to quantitate β-cell function; the glucagon secretion rate was estimated from deconvolution of glucagon concentrations. Glucose tolerance worsened in subjects with the TT genotype. This was accompanied by impaired postchallenge glucagon suppression but appropriate β-cell responsivity to rising glucose concentrations. These data suggest that α-cell abnormalities associated with the TT genotype (rs7903146) occur early and may precede β-cell dysfunction in people as they develop glucose intolerance and type 2 diabetes., (© 2024 by the American Diabetes Association.)

Published

2024

2. Leucine Suppresses α-Cell cAMP and Glucagon Secretion via a Combination of Cell-Intrinsic and Islet Paracrine Signaling.

Author

Knuth ER, Foster HR, Jin E, Ekstrand MH, Knudsen JG, and Merrins MJ

Subjects

Animals, Mice, Humans, Glucose metabolism, Keto Acids pharmacology, Male, Islets of Langerhans metabolism, Islets of Langerhans drug effects, Mice, Inbred C57BL, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Glucagon metabolism, Cyclic AMP metabolism, Glucagon-Secreting Cells metabolism, Glucagon-Secreting Cells drug effects, Leucine pharmacology, Paracrine Communication drug effects

Abstract

Glucagon is critical for the maintenance of blood glucose, however nutrient regulation of pancreatic α-cells remains poorly understood. Here, we identified a role of leucine, a well-known β-cell fuel, in the α-cell-intrinsic regulation of glucagon release. In islet perifusion assays, physiologic concentrations of leucine strongly inhibited alanine- and arginine-stimulated glucagon secretion from human and mouse islets under hypoglycemic conditions. Mechanistically, leucine dose-dependently reduced α-cell cAMP, independently of Ca2+, ATP/ADP, or fatty acid oxidation. Leucine also reduced α-cell cAMP in islets treated with somatostatin receptor 2 antagonists or diazoxide, compounds that limit paracrine signaling from β/δ-cells. Studies in dispersed mouse islets confirmed an α-cell-intrinsic effect. The inhibitory effect of leucine on cAMP was mimicked by glucose, α-ketoisocaproate, succinate, and the glutamate dehydrogenase activator BCH and blocked by cyanide, indicating a mechanism dependent on mitochondrial metabolism. Glucose dose-dependently reduced the impact of leucine on α-cell cAMP, indicating an overlap in function; however, leucine was still effective at suppressing glucagon secretion in the presence of elevated glucose, amino acids, and the incretin GIP. Taken together, these findings show that leucine plays an intrinsic role in limiting the α-cell secretory tone across the physiologic range of glucose levels, complementing the inhibitory paracrine actions of β/δ-cells., (© 2024 by the American Diabetes Association.)

Published

2024

3. DNA Methylation-Based Assessment of Cell Composition in Human Pancreas and Islets.

Author

Drawshy Z, Neiman D, Fridlich O, Peretz A, Magenheim J, Rozo AV, Doliba NM, Stoffers DA, Kaestner KH, Schatz DA, Wasserfall C, Campbell-Thompson M, Shapiro J, Kaplan T, Shemer R, Glaser B, Klochendler A, and Dor Y

Subjects

Humans, DNA Methylation, Pancreas metabolism, Insulin metabolism, Diabetes Mellitus, Type 1 metabolism, Diabetes Mellitus, Type 2 metabolism, Islets of Langerhans metabolism, Insulin-Secreting Cells metabolism, Glucagon-Secreting Cells metabolism

Abstract

Assessment of pancreas cell type composition is crucial to the understanding of the genesis of diabetes. Current approaches use immunodetection of protein markers, for example, insulin as a marker of β-cells. A major limitation of these methods is that protein content varies in physiological and pathological conditions, complicating the extrapolation to actual cell number. Here, we demonstrate the use of cell type-specific DNA methylation markers for determining the fraction of specific cell types in human islet and pancreas specimens. We identified genomic loci that are uniquely demethylated in specific pancreatic cell types and applied targeted PCR to assess the methylation status of these loci in tissue samples, enabling inference of cell type composition. In islet preparations, normalization of insulin secretion to β-cell DNA revealed similar β-cell function in pre-type 1 diabetes (T1D), T1D, and type 2 diabetes (T2D), which was significantly lower than in donors without diabetes. In histological pancreas specimens from recent-onset T1D, this assay showed β-cell fraction within the normal range, suggesting a significant contribution of β-cell dysfunction. In T2D pancreata, we observed increased α-cell fraction and normal β-cell fraction. Methylation-based analysis provides an accurate molecular alternative to immune detection of cell types in the human pancreas, with utility in the interpretation of insulin secretion assays and the assessment of pancreas cell composition in health and disease., (© 2024 by the American Diabetes Association.)

Published

2024

4. An Intraislet Paracrine Signaling Pathway That Enables Glucagon to Stimulate Pancreatic β-Cells.

Author

Caicedo A, Huising MO, and Wess J

Subjects

Glucagon metabolism, Paracrine Communication, Insulin metabolism, Islets of Langerhans metabolism, Insulin-Secreting Cells metabolism, Glucagon-Secreting Cells metabolism

Published

2023

5. Conflicting Views About Interactions Between Pancreatic α-Cells and β-Cells.

Author

Weir GC and Bonner-Weir S

Subjects

Humans, Glucagon metabolism, Insulin metabolism, Insulin Secretion, Glucose metabolism, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Hypoglycemia metabolism, Islets of Langerhans metabolism

Abstract

In type 1 diabetes, the reduced glucagon response to insulin-induced hypoglycemia has been used to argue that β-cell secretion of insulin is required for the full glucagon counterregulatory response. For years, the concept has been that insulin from the β-cell core flows downstream to suppress glucagon secretion from the α-cells in the islet mantle. This core-mantle relationship has been supported by perfused pancreas studies that show marked increases in glucagon secretion when insulin was neutralized with antisera. Additional support comes from a growing number of studies focused on vascular anatomy and blood flow. However, in recent years this core-mantle view has generated less interest than the argument that optimal insulin secretion is due to paracrine release of glucagon from α-cells stimulating adjacent β-cells. This mechanism has been evaluated by knockout of β-cell receptors and impairment of α-cell function by inhibition of Gi designer receptors exclusively activated by designer drugs. Other studies that support this mechanism have been obtained by pharmacological blocking of glucagon-like peptide 1 receptor in humans. While glucagon has potent effects on β-cells, there are concerns with the suggested paracrine mechanism, since some of the supporting data are from isolated islets. The study of islets in static incubation or perifusion systems can be informative, but the normal paracrine relationships are disrupted by the isolation process. While this complicates interpretation of data, arguments supporting paracrine interactions between α-cells and β-cells have growing appeal. We discuss these conflicting views of the relationship between pancreatic α-cells and β-cells and seek to understand how communication depends on blood flow and/or paracrine mechanisms., (© 2023 by the American Diabetes Association.)

Published

2023

6. Glucose Controls Glucagon Secretion by Regulating Fatty Acid Oxidation in Pancreatic α-Cells.

Author

Armour SL, Frueh A, Chibalina MV, Dou H, Argemi-Muntadas L, Hamilton A, Katzilieris-Petras G, Carmeliet P, Davies B, Moritz T, Eliasson L, Rorsman P, and Knudsen JG

Subjects

Adenosine Triphosphate metabolism, Blood Glucose metabolism, Fatty Acids metabolism, Glucagon metabolism, Glucose pharmacology, Glucose metabolism, Insulin metabolism, Humans, Animals, Mice, Glucagon-Secreting Cells metabolism, Islets of Langerhans metabolism

Abstract

Whole-body glucose homeostasis is coordinated through secretion of glucagon and insulin from pancreatic islets. When glucose is low, glucagon is released from α-cells to stimulate hepatic glucose production. However, the mechanisms that regulate glucagon secretion from pancreatic α-cells remain unclear. Here we show that in α-cells, the interaction between fatty acid oxidation and glucose metabolism controls glucagon secretion. The glucose-dependent inhibition of glucagon secretion relies on pyruvate dehydrogenase and carnitine palmitoyl transferase 1a activity and lowering of mitochondrial fatty acid oxidation by increases in glucose. This results in reduced intracellular ATP and leads to membrane repolarization and inhibition of glucagon secretion. These findings provide a new framework for the metabolic regulation of the α-cell, where regulation of fatty acid oxidation by glucose accounts for the stimulation and inhibition of glucagon secretion., Article Highlights: It has become clear that dysregulation of glucagon secretion and α-cell function plays an important role in the development of diabetes, but we do not know how glucagon secretion is regulated. Here we asked whether glucose inhibits fatty acid oxidation in α-cells to regulate glucagon secretion. We found that fatty acid oxidation is required for the inhibitory effects of glucose on glucagon secretion through reductions in ATP. These findings provide a new framework for the regulation of glucagon secretion by glucose., (© 2023 by the American Diabetes Association.)

Published

2023

7. Glucagon Acting at the GLP-1 Receptor Contributes to β-Cell Regeneration Induced by Glucagon Receptor Antagonism in Diabetic Mice.

Author

Wei T, Cui X, Jiang Y, Wang K, Wang D, Li F, Lin X, Gu L, Yang K, Yang J, Hong T, and Wei R

Subjects

Mice, Animals, Glucagon metabolism, Receptors, Glucagon genetics, Glucagon-Like Peptide-1 Receptor genetics, Glucagon-Like Peptide-1 Receptor metabolism, Glucagon-Like Peptide 1 metabolism, Insulin metabolism, Antibodies, Monoclonal pharmacology, Antibodies, Monoclonal metabolism, Regeneration, Diabetes Mellitus, Experimental metabolism, Glucagon-Secreting Cells metabolism

Abstract

Dysfunction of glucagon-secreting α-cells participates in the progression of diabetes, and glucagon receptor (GCGR) antagonism is regarded as a novel strategy for diabetes therapy. GCGR antagonism upregulates glucagon and glucagon-like peptide 1 (GLP-1) secretion and, notably, promotes β-cell regeneration in diabetic mice. Here, we aimed to clarify the role of GLP-1 receptor (GLP-1R) activated by glucagon and/or GLP-1 in the GCGR antagonism-induced β-cell regeneration. We showed that in db/db mice and type 1 diabetic wild-type or Flox/cre mice, GCGR monoclonal antibody (mAb) improved glucose control, upregulated plasma insulin level, and increased β-cell area. Notably, blockage of systemic or pancreatic GLP-1R signaling by exendin 9-39 (Ex9) or Glp1r knockout diminished the above effects of GCGR mAb. Furthermore, glucagon-neutralizing antibody (nAb), which prevents activation of GLP-1R by glucagon, also attenuated the GCGR mAb-induced insulinotropic effect and β-cell regeneration. In cultured primary mouse islets isolated from normal mice and db/db mice, GCGR mAb action to increase insulin release and to upregulate β-cell-specific marker expression was reduced by a glucagon nAb, by the GLP-1R antagonist Ex9, or by a pancreas-specific Glp1r knockout. These findings suggest that activation of GLP-1R by glucagon participates in β-cell regeneration induced by GCGR antagonism in diabetic mice., Article Highlights: Glucagon receptor (GCGR) antagonism promotes β-cell regeneration in type 1 and type 2 diabetic mice and in euglycemic nonhuman primates. Glucagon and glucagon-like peptide 1 (GLP-1) can activate the GLP-1 receptor (GLP-1R), and their levels are upregulated following GCGR antagonism. We investigated whether GLP-1R activated by glucagon and/or GLP-1 contributed to β-cell regeneration induced by GCGR antagonism. We found that blockage of glucagon-GLP-1R signaling attenuated the GCGR monoclonal antibody-induced insulinotropic effect and β-cell regeneration in diabetic mice. Our study reveals a novel mechanism of β-cell regeneration and uncovers the communication between α-cells and β-cells in regulating β-cell mass., (© 2023 by the American Diabetes Association.)

Published

2023

8. RhoA as a Signaling Hub Controlling Glucagon Secretion From Pancreatic α-Cells.

Author

Ng XW, Chung YH, Asadi F, Kong C, Ustione A, and Piston DW

Subjects

Animals, Humans, Mice, Actins metabolism, Calcium metabolism, Diabetes Mellitus, Type 1 metabolism, Diabetes Mellitus, Type 2 metabolism, Ephrins metabolism, Glucose metabolism, Insulin metabolism, Islets of Langerhans metabolism, Ligands, Receptors, Eph Family metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, rhoA GTP-Binding Protein metabolism

Abstract

Glucagon hypersecretion from pancreatic islet α-cells exacerbates hyperglycemia in type 1 diabetes (T1D) and type 2 diabetes. Still, the underlying mechanistic pathways that regulate glucagon secretion remain controversial. Among the three complementary main mechanisms (intrinsic, paracrine, and juxtacrine) proposed to regulate glucagon release from α-cells, juxtacrine interactions are the least studied. It is known that tonic stimulation of α-cell EphA receptors by ephrin-A ligands (EphA forward signaling) inhibits glucagon secretion in mouse and human islets and restores glucose inhibition of glucagon secretion in sorted mouse α-cells, and these effects correlate with increased F-actin density. Here, we elucidate the downstream target of EphA signaling in α-cells. We demonstrate that RhoA, a Rho family GTPase, plays a key role in this pathway. Pharmacological inhibition of RhoA disrupts glucose inhibition of glucagon secretion in islets and decreases cortical F-actin density in dispersed α-cells and α-cells in intact islets. Quantitative FRET biosensor imaging shows that increased RhoA activity follows directly from EphA stimulation. We show that in addition to modulating F-actin density, EphA forward signaling and RhoA activity affect α-cell Ca2+ activity in a novel mechanistic pathway. Finally, we show that stimulating EphA forward signaling restores glucose inhibition of glucagon secretion from human T1D donor islets., (© 2022 by the American Diabetes Association.)

Published

2022

9. The Essential Role of Pancreatic α-Cells in Maternal Metabolic Adaptation to Pregnancy.

Author

Qiao L, Saget S, Lu C, Zang T, Dzyuba B, Hay WW, and Shao J

Subjects

Animals, Female, Glucagon metabolism, Glucagon-Like Peptide 1 metabolism, Glucagon-Like Peptide-1 Receptor genetics, Glucagon-Like Peptide-1 Receptor metabolism, Glucose metabolism, Insulin metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Pregnancy, Receptors, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Islets of Langerhans metabolism

Abstract

Pancreatic α-cells are important in maintaining metabolic homeostasis, but their role in regulating maternal metabolic adaptations to pregnancy has not been studied. The objective of this study was to determine whether pancreatic α-cells respond to pregnancy and their contribution to maternal metabolic adaptation. With use of C57BL/6 mice, the findings of our study showed that pregnancy induced a significant increase of α-cell mass by promoting α-cell proliferation that was associated with a transitory increase of maternal serum glucagon concentration in early pregnancy. Maternal pancreatic GLP-1 content also was significantly increased during pregnancy. Using the inducible Cre/loxp technique, we ablated the α-cells (α-null) before and during pregnancy while maintaining enteroendocrine L-cells and serum GLP-1 in the normal range. In contrast to an improved glucose tolerance test (GTT) before pregnancy, significantly impaired GTT and remarkably higher serum glucose concentrations in the fed state were observed in α-null dams. Glucagon receptor antagonism treatment, however, did not affect measures of maternal glucose metabolism, indicating a dispensable role of glucagon receptor signaling in maternal glucose homeostasis. However, the GLP-1 receptor agonist improved insulin production and glucose metabolism of α-null dams. Furthermore, GLP-1 receptor antagonist Exendin (9-39) attenuated pregnancy-enhanced insulin secretion and GLP-1 restored glucose-induced insulin secretion of cultured islets from α-null dams. Together, these results demonstrate that α-cells play an essential role in controlling maternal metabolic adaptation to pregnancy by enhancing insulin secretion., (© 2022 by the American Diabetes Association.)

Published

2022

10. Targeting the Pancreatic α-Cell to Prevent Hypoglycemia in Type 1 Diabetes.

Author

Panzer JK and Caicedo A

Subjects

Blood Glucose drug effects, Blood Glucose metabolism, Diabetes Mellitus, Type 1 blood, Diabetes Mellitus, Type 1 complications, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Humans, Hypoglycemia blood, Hypoglycemia etiology, Insulin pharmacology, Insulin therapeutic use, Molecular Targeted Therapy trends, Diabetes Mellitus, Type 1 therapy, Glucagon-Secreting Cells drug effects, Hypoglycemia prevention & control, Molecular Targeted Therapy methods

Abstract

Life-threatening hypoglycemia is a limiting factor in the management of type 1 diabetes. People with diabetes are prone to develop hypoglycemia because they lose physiological mechanisms that prevent plasma glucose levels from falling. Among these so-called counterregulatory responses, secretion of glucagon from pancreatic α-cells is preeminent. Glucagon, a hormone secreted in response to a lowering in glucose concentration, counteracts a further drop in glycemia by promoting gluconeogenesis and glycogenolysis in target tissues. In diabetes, however, α-cells do not respond appropriately to changes in glycemia and, thus, cannot mount a counterregulatory response. If the α-cell could be targeted therapeutically to restore its ability to prevent hypoglycemia, type 1 diabetes could be managed more efficiently and safely. Unfortunately, the mechanisms that allow the α-cell to respond to hypoglycemia have not been fully elucidated. We know even less about the pathophysiological mechanisms that cause α-cell dysfunction in diabetes. Based on published findings and unpublished observations, and taking into account its electrophysiological properties, we propose here a model of α-cell function that could explain its impairment in diabetes. Within this frame, we emphasize those elements that could be targeted pharmacologically with repurposed U.S. Food and Drug Administration-approved drugs to rescue α-cell function and restore glucose counterregulation in people with diabetes., (© 2021 by the American Diabetes Association.)

Published

2021

11. Glucagon Resistance and Decreased Susceptibility to Diabetes in a Model of Chronic Hyperglucagonemia.

Author

Bozadjieva Kramer N, Lubaczeuski C, Blandino-Rosano M, Barker G, Gittes GK, Caicedo A, and Bernal-Mizrachi E

Subjects

Animals, Body Weight physiology, Disease Models, Animal, Disease Susceptibility, Eating physiology, Glucagon-Like Peptide 1 metabolism, Glucose Intolerance metabolism, Insulin blood, Insulin Secretion physiology, Mice, Receptors, Glucagon metabolism, Signal Transduction physiology, Tuberous Sclerosis Complex 2 Protein genetics, Tuberous Sclerosis Complex 2 Protein metabolism, Blood Glucose metabolism, Glucagon blood, Glucagon-Secreting Cells metabolism, Mechanistic Target of Rapamycin Complex 1 metabolism

Abstract

Elevation of glucagon levels and increase in α-cell mass are associated with states of hyperglycemia in diabetes. Our previous studies have highlighted the role of nutrient signaling via mTOR complex 1 (mTORC1) regulation that controls glucagon secretion and α-cell mass. In the current studies we investigated the effects of activation of nutrient signaling by conditional deletion of the mTORC1 inhibitor, TSC2, in α-cells (αTSC2 KO ). We showed that activation of mTORC1 signaling is sufficient to induce chronic hyperglucagonemia as a result of α-cell proliferation, cell size, and mass expansion. Hyperglucagonemia in αTSC2 KO was associated with an increase in glucagon content and enhanced glucagon secretion. This model allowed us to identify the effects of chronic hyperglucagonemia on glucose homeostasis by inducing insulin secretion and resistance to glucagon in the liver. Liver glucagon resistance in αTSC2 KO mice was characterized by reduced expression of the glucagon receptor (GCGR), PEPCK, and genes involved in amino acid metabolism and urea production. Glucagon resistance in αTSC2 KO mice was associated with improved glucose levels in streptozotocin-induced β-cell destruction and high-fat diet-induced glucose intolerance. These studies demonstrate that chronic hyperglucagonemia can improve glucose homeostasis by inducing glucagon resistance in the liver., (© 2020 by the American Diabetes Association.)

Published

2021

12. Updating the Role of α-Cell Preproglucagon Products on GLP-1 Receptor-Mediated Insulin Secretion.

Author

Sandoval D

Subjects

Gene Expression Regulation, Glucagon-Like Peptide-1 Receptor genetics, Humans, Glucagon-Like Peptide-1 Receptor metabolism, Glucagon-Secreting Cells metabolism, Insulin metabolism, Proglucagon metabolism

Abstract

While the field of islet biology has historically focused its attention on understanding β-cell function and the mechanisms by which these cells become dysfunctional with diabetes, there has been a scientific shift toward greater understanding of other endocrine cells of the islet and their paracrine role in regulating the β-cell. In recent years, many questions and new data have come forward regarding the paracrine role of the α-cell and specifically preproglucagon peptides in regulating insulin secretion. The role of intestinally secreted glucagon-like peptide 1 (GLP-1) in regulation of insulin secretion has been questioned, and a physiological role of pancreatic GLP-1 in regulation of insulin secretion has been proposed. In addition, in the last 2 years, a series of studies demonstrated a physiological role for glucagon, acting via the GLP-1 receptor, in paracrine regulation of insulin secretion. Altogether, this work challenges the textbook physiology of both GLP-1 and glucagon and presents a critical paradigm shift for the field. This article addresses these new findings surrounding α-cell preproglucagon products, with a particular focus on GLP-1, in the context of their roles in insulin secretion and consequently glucose metabolism., (© 2020 by the American Diabetes Association.)

Published

2020

13. The Local Paracrine Actions of the Pancreatic α-Cell.

Author

Rodriguez-Diaz R, Tamayo A, Hara M, and Caicedo A

Subjects

Animals, Humans, Insulin metabolism, Insulin Secretion physiology, Diabetes Mellitus metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Paracrine Communication physiology

Abstract

Secretion of glucagon from the pancreatic α-cells is conventionally seen as the first and most important defense against hypoglycemia. Recent findings, however, show that α-cell signals stimulate insulin secretion from the neighboring β-cell. This article focuses on these seemingly counterintuitive local actions of α-cells and describes how they impact islet biology and glucose metabolism. It is mostly based on studies published in the last decade on the physiology of α-cells in human islets and incorporates results from rodents where appropriate. As this and the accompanying articles show, the emerging picture of α-cell function is one of increased complexity that needs to be considered when developing new therapies aimed at promoting islet function in the context of diabetes., (© 2019 by the American Diabetes Association.)

Published

2020

14. A Primary Role for α-Cells as Amino Acid Sensors.

Author

Dean ED

Subjects

Animals, Blood Glucose metabolism, Glucagon metabolism, Humans, Insulin metabolism, Receptors, Glucagon metabolism, Signal Transduction physiology, Amino Acids metabolism, Glucagon-Secreting Cells metabolism, Liver metabolism, Pancreas metabolism

Abstract

Glucagon and its partner insulin are dually linked in both their secretion from islet cells and their action in the liver. Glucagon signaling increases hepatic glucose output, and hyperglucagonemia is partly responsible for the hyperglycemia in diabetes, making glucagon an attractive target for therapeutic intervention. Interrupting glucagon signaling lowers blood glucose but also results in hyperglucagonemia and α-cell hyperplasia. Investigation of the mechanism for α-cell proliferation led to the description of a conserved liver-α-cell axis where glucagon is a critical regulator of amino acid homeostasis. In return, amino acids regulate α-cell function and proliferation. New evidence suggests that dysfunction of the axis in humans may result in the hyperglucagonemia observed in diabetes. This discussion outlines important but often overlooked roles for glucagon that extend beyond glycemia and supports a new role for α-cells as amino acid sensors., (© 2020 by the American Diabetes Association.)

Published

2020

15. β-Cell Fate in Human Insulin Resistance and Type 2 Diabetes: A Perspective on Islet Plasticity.

Author

Mezza T, Cinti F, Cefalo CMA, Pontecorvi A, Kulkarni RN, and Giaccari A

Subjects

Glucagon-Secreting Cells cytology, Humans, Insulin Resistance, Insulin-Secreting Cells cytology, Islets of Langerhans cytology, Islets of Langerhans metabolism, Islets of Langerhans pathology, Organ Size, Cell Dedifferentiation, Cell Plasticity, Cell Transdifferentiation, Diabetes Mellitus, Type 2 metabolism, Glucagon-Secreting Cells metabolism, Insulin Secretion, Insulin-Secreting Cells metabolism

Abstract

Although it is well established that type 2 diabetes (T2D) is generally due to the progressive loss of β-cell insulin secretion against a background of insulin resistance, the actual correlation of reduced β-cell mass to its defective function continues to be debated. There is evidence that a compensatory increase in β-cell mass, and the consequent insulin secretion, can effectively cope with states of insulin resistance, until hyperglycemia supervenes. Recent data strongly indicate that the mechanisms by which islets are able to compensate in response to insulin resistance in peripheral tissues is secondary to hyperplasia, as well as the activation of multiple cellular machineries with diverse functions. Importantly, islet cells exhibit plasticity in altering their endocrine commitment; for example, by switching from secretion of glucagon to secretion of insulin and back (transdifferentiation) or from an active secretory state to a nonsecretory quiescent state (dedifferentiation) and back. Lineage tracing (a method used to track each cell though its differentiation process) has demonstrated these potentials in murine models. A limitation to drawing conclusions from human islet research is that most studies are derived from human autopsy and/or organ donor samples, which lack in vivo functional and metabolic profiling. In this review, we specifically focus on evidence of islet plasticity in humans-from the normal state, progressing to insulin resistance to overt T2D-to explain the seemingly contradictory results from different cross-sectional studies in the literature. We hope the discussion on this intriguing scenario will provide a forum for the scientific community to better understand the disease and in the long term pave the way for personalized therapies., (© 2019 by the American Diabetes Association.)

Published

2019

16. Heterogeneity of the Human Pancreatic Islet.

Author

Dybala MP and Hara M

Subjects

Adolescent, Adult, Aged, Animals, Endocrine Cells cytology, Endocrine Cells metabolism, Female, Glucagon-Secreting Cells metabolism, Humans, Imaging, Three-Dimensional, Immunohistochemistry, Insulin-Secreting Cells metabolism, Islets of Langerhans blood supply, Islets of Langerhans metabolism, Male, Mice, Microscopy, Confocal, Middle Aged, Reproducibility of Results, Somatostatin-Secreting Cells metabolism, Young Adult, Glucagon-Secreting Cells cytology, Insulin-Secreting Cells cytology, Islets of Langerhans cytology, Somatostatin-Secreting Cells cytology

Abstract

Pancreatic β-cells play a pivotal role in maintaining normoglycemia. Recent studies have revealed that the β-cell is not a homogeneous cell population but, rather, is heterogeneous in a number of properties such as electrical activity, gene expression, and cell surface markers. Identification of specific β-cell subpopulations altered in diabetic conditions would open a new avenue to develop targeted therapeutic interventions. As intense studies of β-cell heterogeneity are anticipated in the next decade, it is important that heterogeneity of the islet be recognized. Many studies in the past were undertaken with a small sample of islets, which might overlook important individual variance. In this study, by systematic analyses of the human islet in two and three dimensions, we demonstrate islet heterogeneity in size, number, architecture, cellular composition, and capillary density. There is no stereotypic human islet, and thus, a sufficient number of islets should be examined to ensure study reproducibility., (© 2019 by the American Diabetes Association.)

Published

2019

17. Glucagon Receptor Antagonist-Stimulated α-Cell Proliferation Is Severely Restricted With Advanced Age.

Author

Lam CJ, Rankin MM, King KB, Wang MC, Shook BC, and Kushner JA

Subjects

Animals, Glucagon-Secreting Cells cytology, Hypoglycemic Agents adverse effects, Male, Mice, Thymidine adverse effects, Thymidine analogs & derivatives, Aging physiology, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Receptors, Glucagon antagonists & inhibitors, Receptors, Glucagon metabolism

Abstract

Glucagon-containing α-cells potently regulate glucose homeostasis, but the developmental biology of α-cells in adults remains poorly understood. Although glucagon receptor antagonists (GRAs) have great potential as antidiabetic therapies, murine and human studies have raised concerns that GRAs might cause uncontrolled α-cell growth. Surprisingly, previous rodent GRA studies were only performed in young mice, implying that the potential impact of GRAs to drive α-cell expansion in adult patients is unclear. We assessed adaptive α-cell turnover and adaptive proliferation, administering a novel GRA (JNJ-46207382) to both young and aged mice. Basal α-cell proliferation rapidly declined soon after birth and continued to drop to very low levels in aged mice. GRA drove a 2.4-fold increase in α-cell proliferation in young mice. In contrast, GRA-induced α-cell proliferation was severely reduced in aged mice, although still present at 3.2-fold the very low basal rate of aged controls. To interrogate the lineage of GRA-induced α-cells, we sequentially administered thymidine analogs and quantified their incorporation into α-cells. Similar to previous studies of β-cells, α-cells only divided once in both basal and stimulated conditions. Lack of contribution from highly proliferative "transit-amplifying" cells supports a model whereby α-cells expand by self-renewal and not via specialized progenitors., (© 2019 by the American Diabetes Association.)

Published

2019

18. GLP-1 Receptor in Pancreatic α-Cells Regulates Glucagon Secretion in a Glucose-Dependent Bidirectional Manner.

Author

Zhang Y, Parajuli KR, Fava GE, Gupta R, Xu W, Nguyen LU, Zakaria AF, Fonseca VA, Wang H, Mauvais-Jarvis F, Sloop KW, and Wu H

Subjects

Animals, Female, Flow Cytometry, Glucagon-Like Peptide-1 Receptor genetics, Glucose Tolerance Test, Immunohistochemistry, Mice, Mice, Knockout, Reverse Transcriptase Polymerase Chain Reaction, Glucagon metabolism, Glucagon-Like Peptide-1 Receptor metabolism, Glucagon-Secreting Cells metabolism, Glucose metabolism

Abstract

Glucagon-like peptide 1 (GLP-1) is known to suppress glucagon secretion, but the mechanism by which GLP-1 exerts this effect is unclear. In this study, we demonstrated GLP-1 receptor (GLP-1R) expression in α-cells using both antibody-dependent and antibody-independent strategies. A novel α-cell-specific GLP-1R knockout (αGLP-1R -/- ) mouse model was created and used to investigate its effects on glucagon secretion and glucose metabolism. Male and female αGLP-1R -/- mice both showed higher nonfasting glucagon levels than their wild-type littermates, whereas insulin and GLP-1 levels remained similar. Female αGLP-1R -/- mice exhibited mild glucose intolerance after an intraperitoneal glucose administration and showed increased glucagon secretion in response to a glucose injection compared with the wild-type animals. Furthermore, using isolated islets, we confirmed that αGLP-1R deletion did not interfere with β-cell function but affected glucagon secretion in a glucose-dependent bidirectional manner: the αGLP-1R -/- islets failed to inhibit glucagon secretion at high glucose and failed to stimulate glucagon secretion at very low glucose condition. More interestingly, the same phenomenon was recapitulated in vivo under hypoglycemic and postprandial (fed) conditions. Taken together, this study demonstrates that GLP-1 (via GLP-1R in α-cells) plays a bidirectional role, either stimulatory or inhibitory, in glucagon secretion depending on glucose levels., (© 2018 by the American Diabetes Association.)

Published

2019

19. Glucagon-Like Peptide 1 Increases β-Cell Regeneration by Promoting α- to β-Cell Transdifferentiation.

Author

Lee YS, Lee C, Choung JS, Jung HS, and Jun HS

Subjects

Animals, Cell Proliferation drug effects, Glucagon-Like Peptide 1 genetics, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Islets of Langerhans metabolism, Mice, Regeneration drug effects, Cell Transdifferentiation drug effects, Exenatide pharmacology, Glucagon-Like Peptide 1 metabolism, Glucagon-Secreting Cells cytology, Insulin-Secreting Cells cytology, Islets of Langerhans drug effects

Abstract

Glucagon-like peptide 1 (GLP-1) can increase pancreatic β-cells, and α-cells could be a source for new β-cell generation. We investigated whether GLP-1 increases β-cells through α-cell transdifferentiation. New β-cells originating from non-β-cells were significantly increased in recombinant adenovirus expressing GLP-1 (rAd-GLP-1)-treated RIP-CreER;R26-YFP mice. Proliferating α-cells were increased in islets of rAd-GLP-1-treated mice and αTC1 clone 9 (αTC1-9) cells treated with exendin-4, a GLP-1 receptor agonist. Insulin + glucagon + cells were significantly increased by rAd-GLP-1 or exendin-4 treatment in vivo and in vitro. Lineage tracing to label the glucagon-producing α-cells showed a higher proportion of regenerated β-cells from α-cells in rAd-GLP-1-treated Glucagon-rtTA;Tet- O -Cre;R26-YFP mice than rAd producing β-galactosidase-treated mice. In addition, exendin-4 increased the expression and secretion of fibroblast growth factor 21 (FGF21) in αTC1-9 cells and β-cell-ablated islets. FGF21 treatment of β-cell-ablated islets increased the expression of pancreatic and duodenal homeobox-1 and neurogenin-3 and significantly increased insulin + glucagon + cells. Generation of insulin + glucagon + cells by exendin-4 was significantly reduced in islets transfected with FGF21 small interfering RNA or islets of FGF21 knockout mice. Generation of insulin + cells by rAd-GLP-1 treatment was significantly reduced in FGF21 knockout mice compared with wild-type mice. We suggest that GLP-1 has an important role in α-cell transdifferentiation to generate new β-cells, which might be mediated, in part, by FGF21 induction., (© 2018 by the American Diabetes Association.)

Published

2018

20. Adrenaline Stimulates Glucagon Secretion by Tpc2-Dependent Ca 2+ Mobilization From Acidic Stores in Pancreatic α-Cells.

Author

Hamilton A, Zhang Q, Salehi A, Willems M, Knudsen JG, Ringgaard AK, Chapman CE, Gonzalez-Alvarez A, Surdo NC, Zaccolo M, Basco D, Johnson PRV, Ramracheya R, Rutter GA, Galione A, Rorsman P, and Tarasov AI

Subjects

Adrenergic Neurons cytology, Adrenergic Neurons drug effects, Adrenergic Neurons metabolism, Animals, Animals, Outbred Strains, Calcium Channels chemistry, Calcium Channels genetics, Cyclic AMP-Dependent Protein Kinases antagonists & inhibitors, Cyclic AMP-Dependent Protein Kinases metabolism, Endoplasmic Reticulum drug effects, Endoplasmic Reticulum enzymology, Endoplasmic Reticulum metabolism, Enzyme Inhibitors pharmacology, Glucagon-Secreting Cells cytology, Glucagon-Secreting Cells drug effects, Guanine Nucleotide Exchange Factors antagonists & inhibitors, Guanine Nucleotide Exchange Factors metabolism, Humans, Membrane Transport Modulators pharmacology, Mice, Mice, Inbred C57BL, Mice, Knockout, Pancreas drug effects, Pancreas innervation, Pancreas metabolism, Patch-Clamp Techniques, Sarcoplasmic Reticulum drug effects, Sarcoplasmic Reticulum enzymology, Sarcoplasmic Reticulum metabolism, Tissue Culture Techniques, Calcium Channels metabolism, Calcium Signaling drug effects, Epinephrine metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Up-Regulation drug effects

Abstract

Adrenaline is a powerful stimulus of glucagon secretion. It acts by activation of β-adrenergic receptors, but the downstream mechanisms have only been partially elucidated. Here, we have examined the effects of adrenaline in mouse and human α-cells by a combination of electrophysiology, imaging of Ca 2+ and PKA activity, and hormone release measurements. We found that stimulation of glucagon secretion correlated with a PKA- and EPAC2-dependent (inhibited by PKI and ESI-05, respectively) elevation of [Ca 2+ ] i in α-cells, which occurred without stimulation of electrical activity and persisted in the absence of extracellular Ca 2+ but was sensitive to ryanodine, bafilomycin, and thapsigargin. Adrenaline also increased [Ca 2+ ] i in α-cells in human islets. Genetic or pharmacological inhibition of the Tpc2 channel (that mediates Ca 2+ release from acidic intracellular stores) abolished the stimulatory effect of adrenaline on glucagon secretion and reduced the elevation of [Ca 2+ ] i Furthermore, in Tpc2-deficient islets, ryanodine exerted no additive inhibitory effect. These data suggest that β-adrenergic stimulation of glucagon secretion is controlled by a hierarchy of [Ca 2+ ] i signaling in the α-cell that is initiated by cAMP-induced Tpc2-dependent Ca 2+ release from the acidic stores and further amplified by Ca 2+ -induced Ca 2+ release from the sarco/endoplasmic reticulum., (© 2018 by the American Diabetes Association.)

Published

2018

21. Endogenous Glucose Production and Hormonal Changes in Response to Canagliflozin and Liraglutide Combination Therapy.

Author

Martinez R, Al-Jobori H, Ali AM, Adams J, Abdul-Ghani M, Triplitt C, DeFronzo RA, and Cersosimo E

Subjects

Adult, Canagliflozin adverse effects, Diabetes Mellitus, Type 2 blood, Diabetes Mellitus, Type 2 metabolism, Drug Therapy, Combination adverse effects, Female, Glucagon agonists, Glucagon antagonists & inhibitors, Glucagon blood, Glucagon metabolism, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Humans, Hyperglycemia prevention & control, Hypoglycemia chemically induced, Hypoglycemia prevention & control, Hypoglycemic Agents adverse effects, Incretins adverse effects, Insulin agonists, Insulin blood, Insulin chemistry, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Liraglutide adverse effects, Male, Membrane Transport Modulators adverse effects, Membrane Transport Modulators therapeutic use, Middle Aged, Reproducibility of Results, Sodium-Glucose Transporter 2 metabolism, Sodium-Glucose Transporter 2 Inhibitors, Canagliflozin therapeutic use, Diabetes Mellitus, Type 2 drug therapy, Down-Regulation drug effects, Gluconeogenesis drug effects, Hypoglycemic Agents therapeutic use, Incretins therapeutic use, Liraglutide therapeutic use

Abstract

The decrement in plasma glucose concentration with SGLT2 inhibitors (SGLT2i) is blunted by a rise in endogenous glucose production (EGP). We investigated the ability of incretin treatment to offset the EGP increase. Subjects with type 2 diabetes ( n = 36) were randomized to 1 ) canagliflozin (CANA), 2 ) liraglutide (LIRA), or 3 ) CANA plus LIRA (CANA/LIRA). EGP was measured with [3- 3 H]glucose with or without drugs for 360 min. In the pretreatment studies, EGP was comparable and decreased (2.2 ± 0.1 to 1.7 ± 0.2 mg/kg ⋅ min) during a 300- to 360-min period ( P < 0.01). The decrement in EGP was attenuated with CANA (2.1 ± 0.1 to 1.9 ± 0.1 mg/kg ⋅ min) and CANA/LIRA (2.2 ± 0.1 to 2.0 ± 0.1 mg/kg ⋅ min), whereas with LIRA it was the same (2.4 ± 0.2 to 1.8 ± 0.2 mg/kg ⋅ min) (all P < 0.05 vs. baseline). After CANA, the fasting plasma insulin concentration decreased (18 ± 2 to 12 ± 2 μU/mL, P < 0.05), while it remained unchanged in LIRA (18 ± 2 vs. 16 ± 2 μU/mL) and CANA/LIRA (17 ± 1 vs. 15 ± 2 μU/mL). Mean plasma glucagon did not change during the pretreatment studies from 0 to 360 min, while it increased with CANA (69 ± 3 to 78 ± 2 pg/mL, P < 0.05), decreased with LIRA (93 ± 6 to 80 ± 6 pg/mL, P < 0.05), and did not change in CANA/LIRA. LIRA prevented the insulin decline and blocked the glucagon rise observed with CANA but did not inhibit the increase in EGP. Factors other than insulin and glucagon contribute to the stimulation of EGP after CANA-induced glucosuria., (© 2018 by the American Diabetes Association.)

Published

2018

22. The p300 and CBP Transcriptional Coactivators Are Required for β-Cell and α-Cell Proliferation.

Author

Wong CK, Wade-Vallance AK, Luciani DS, Brindle PK, Lynn FC, and Gibson WT

Subjects

Acetylation, Animals, Animals, Newborn, Blood Glucose analysis, CREB-Binding Protein genetics, Cell Size, Crosses, Genetic, E1A-Associated p300 Protein genetics, Glucagon-Secreting Cells cytology, Glucagon-Secreting Cells pathology, Glucose Intolerance blood, Glucose Intolerance metabolism, Glucose Intolerance pathology, Histones metabolism, Homeobox Protein Nkx-2.2, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells cytology, Insulin-Secreting Cells pathology, Lysine, Mice, Knockout, Mice, Transgenic, Protein Processing, Post-Translational, Stem Cells cytology, Stem Cells pathology, CREB-Binding Protein metabolism, Cell Proliferation, E1A-Associated p300 Protein metabolism, Gene Expression Regulation, Developmental, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Stem Cells metabolism

Abstract

p300 ( EP300 ) and CBP ( CREBBP ) are transcriptional coactivators with histone acetyltransferase activity. Various β-cell transcription factors can recruit p300/CBP, and thus the coactivators could be important for β-cell function and health in vivo. We hypothesized that p300/CBP contribute to the development and proper function of pancreatic islets. To test this, we bred and studied mice lacking p300/CBP in their islets. Mice lacking either p300 or CBP in islets developed glucose intolerance attributable to impaired insulin secretion, together with reduced α- and β-cell area and islet insulin content. These phenotypes were exacerbated in mice with only a single copy of p300 or CBP expressed in islets. Removing p300 in pancreatic endocrine progenitors impaired proliferation of neonatal α- and β-cells. Mice lacking all four copies of p300/CBP in pancreatic endocrine progenitors failed to establish α- and β-cell mass postnatally. Transcriptomic analyses revealed significant overlaps between p300/CBP-downregulated genes and genes downregulated in Hnf1α-null islets and Nkx2.2-null islets, among others. Furthermore, p300/CBP are important for the acetylation of H3K27 at loci downregulated in Hnf1α-null islets. We conclude that p300 and CBP are limiting cofactors for islet development, and hence for postnatal glucose homeostasis, with some functional redundancy., (© 2017 by the American Diabetes Association.)

Published

2018

23. Mitochondrial Protein UCP2 Controls Pancreas Development.

Author

Broche B, Ben Fradj S, Aguilar E, Sancerni T, Bénard M, Makaci F, Berthault C, Scharfmann R, Alves-Guerra MC, and Duvillié B

Subjects

Animals, Blotting, Western, Cells, Cultured, Glucagon-Secreting Cells metabolism, Immunohistochemistry, Insulin-Secreting Cells metabolism, Membrane Potential, Mitochondrial genetics, Membrane Potential, Mitochondrial physiology, Mice, Mice, Knockout, NF-E2-Related Factor 2 genetics, NF-E2-Related Factor 2 metabolism, Phosphorylation genetics, Phosphorylation physiology, Polymerase Chain Reaction, Reactive Oxygen Species metabolism, Uncoupling Protein 2 genetics, Pancreas enzymology, Pancreas metabolism, Uncoupling Protein 2 metabolism

Abstract

The mitochondrial carrier uncoupling protein (UCP) 2 belongs to the family of the UCPs. Despite its name, it is now accepted that UCP2 is rather a metabolite transporter than a UCP. UCP2 can regulate oxidative stress and/or energetic metabolism. In rodents, UCP2 is involved in the control of α- and β-cell mass as well as insulin and glucagon secretion. Our aim was to determine whether the effects of UCP2 observed on β-cell mass have an embryonic origin. Thus, we used Ucp2 knockout mice. We found an increased size of the pancreas in Ucp2 -/- fetuses at embryonic day 16.5, associated with a higher number of α- and β-cells. This phenotype was caused by an increase of PDX1 + progenitor cells. Perinatally, an increase in the proliferation of endocrine cells also participates in their expansion. Next, we analyzed the oxidative stress in the pancreata. We quantified an increased nuclear translocation of nuclear factor erythroid 2-related factor 2 (NRF2) in the mutant, suggesting an increased production of reactive oxygen species (ROS). Phosphorylation of AKT, an ROS target, was also activated in the Ucp2 -/- pancreata. Finally, administration of the antioxidant N -acetyl-l-cysteine to Ucp2 -/- pregnant mice alleviated the effect of knocking out UCP2 on pancreas development. Together, these data demonstrate that UCP2 controls pancreas development through the ROS-AKT signaling pathway., (© 2017 by the American Diabetes Association.)

Published

2018

24. Mafa Enables Pdx1 to Effectively Convert Pancreatic Islet Progenitors and Committed Islet α-Cells Into β-Cells In Vivo.

Author

Matsuoka TA, Kawashima S, Miyatsuka T, Sasaki S, Shimo N, Katakami N, Kawamori D, Takebe S, Herrera PL, Kaneto H, Stein R, and Shimomura I

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors metabolism, Cell Count, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Immunohistochemistry, Insulin-Secreting Cells metabolism, Islets of Langerhans cytology, Islets of Langerhans metabolism, Mice, Mice, Transgenic, Nerve Tissue Proteins metabolism, Stem Cells metabolism, Cell Differentiation genetics, Cell Transdifferentiation genetics, Glucagon-Secreting Cells cytology, Homeodomain Proteins genetics, Insulin-Secreting Cells cytology, Maf Transcription Factors, Large genetics, Stem Cells cytology, Trans-Activators genetics

Abstract

Among the therapeutic avenues being explored for replacement of the functional islet β-cell mass lost in type 1 diabetes (T1D), reprogramming of adult cell types into new β-cells has been actively pursued. Notably, mouse islet α-cells will transdifferentiate into β-cells under conditions of near β-cell loss, a condition similar to T1D. Moreover, human islet α-cells also appear to poised for reprogramming into insulin-positive cells. Here we have generated transgenic mice conditionally expressing the islet β-cell-enriched Mafa and/or Pdx1 transcription factors to examine their potential to transdifferentiate embryonic pan-islet cell Ngn3-positive progenitors and the later glucagon-positive α-cell population into β-cells. Mafa was found to both potentiate the ability of Pdx1 to induce β-cell formation from Ngn3-positive endocrine precursors and enable Pdx1 to produce β-cells from α-cells. These results provide valuable insight into the fundamental mechanisms influencing islet cell plasticity in vivo., (© 2017 by the American Diabetes Association.)

Published

2017

25. Reestablishment of Glucose Inhibition of Glucagon Secretion in Small Pseudoislets.

Author

Reissaus CA and Piston DW

Subjects

Actins metabolism, Animals, Cell Communication, Cells, Cultured, Cyclic AMP metabolism, Ephrins metabolism, Flow Cytometry, Glucagon drug effects, Glucagon-Secreting Cells drug effects, Glucose pharmacology, Insulin Secretion, Insulin-Secreting Cells drug effects, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Mice, Mice, Transgenic, Organ Culture Techniques, Paracrine Communication, Receptor, EphA4 metabolism, Receptor, EphA7 metabolism, Signal Transduction, Somatostatin metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Insulin metabolism, Insulin-Secreting Cells metabolism

Abstract

Misregulated hormone secretion from the islet of Langerhans is central to the pathophysiology of diabetes. Although insulin plays a key role in glucose regulation, the importance of glucagon is increasingly acknowledged. However, the mechanisms that regulate glucagon secretion from α-cells are still unclear. We used pseudoislets reconstituted from dispersed islet cells to study α-cells with and without various indirect effects from other islet cells. Dispersed islet cells secrete aberrant levels of glucagon and insulin at basal and elevated glucose levels. When cultured, murine islet cells reassociate to form pseudoislets, which recover normal glucose-regulated hormone secretion, and human islet cells follow a similar pattern. We created small (∼40-µm) pseudoislets using all of the islet cells or only some of the cell types, which allowed us to characterize novel aspects of regulated hormone secretion. The recovery of regulated glucagon secretion from α-cells in small pseudoislets depends upon the combined action of paracrine factors, such as insulin and somatostatin, and juxtacrine signals between EphA4/7 on α-cells and ephrins on β-cells. Although these signals modulate different pathways, both appear to be required for proper inhibition of glucagon secretion in response to glucose. This improved understanding of the modulation of glucagon secretion can provide novel therapeutic routes for the treatment of some individuals with diabetes., (© 2017 by the American Diabetes Association.)

Published

2017

26. Glucagon and Amino Acids Are Linked in a Mutual Feedback Cycle: The Liver-α-Cell Axis.

Author

Holst JJ, Wewer Albrechtsen NJ, Pedersen J, and Knop FK

Subjects

Animals, Feedback, Glucagonoma metabolism, Humans, Mice, Mutation, Pancreatic Neoplasms metabolism, Receptors, Glucagon genetics, Urea metabolism, Amino Acids metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Glucose metabolism, Liver metabolism

Abstract

Glucagon is usually viewed as an important counterregulatory hormone in glucose metabolism, with actions opposing those of insulin. Evidence exists that shows glucagon is important for minute-to-minute regulation of postprandial hepatic glucose production, although conditions of glucagon excess or deficiency do not cause changes compatible with this view. In patients with glucagon-producing tumors (glucagonomas), the most conspicuous signs are skin lesions (necrolytic migratory erythema), while in subjects with inactivating mutations of the glucagon receptor, pancreatic swelling may be the first sign; neither condition is necessarily associated with disturbed glucose metabolism. In glucagonoma patients, amino acid turnover and ureagenesis are greatly accelerated, and low plasma amino acid levels are probably at least partly responsible for the necrolytic migratory erythema, which resolves after amino acid administration. In patients with receptor mutations (and in knockout mice), pancreatic swelling is due to α-cell hyperplasia with gross hypersecretion of glucagon, which according to recent groundbreaking research may result from elevated amino acid levels. Additionally, solid evidence indicates that ureagenesis, and thereby amino acid levels, is critically controlled by glucagon. Together, this constitutes a complete endocrine system; feedback regulation involving amino acids regulates α-cell function and secretion, while glucagon, in turn, regulates amino acid turnover., (© 2017 by the American Diabetes Association.)

Published

2017

27. Single-Cell Transcriptomics of the Human Endocrine Pancreas.

Author

Wang YJ, Schug J, Won KJ, Liu C, Naji A, Avrahami D, Golson ML, and Kaestner KH

Subjects

Cell Cycle genetics, Cell Cycle physiology, Cell Proliferation genetics, Cell Proliferation physiology, Computational Biology methods, Diabetes Mellitus, Type 1 genetics, Diabetes Mellitus, Type 1 metabolism, Diabetes Mellitus, Type 2 genetics, Diabetes Mellitus, Type 2 metabolism, Glucagon-Secreting Cells cytology, Glucagon-Secreting Cells metabolism, Humans, Insulin-Secreting Cells cytology, Insulin-Secreting Cells metabolism, Microfluidics methods, Signal Transduction genetics, Signal Transduction physiology, Islets of Langerhans cytology, Islets of Langerhans metabolism, Transcriptome genetics

Abstract

Human pancreatic islets consist of multiple endocrine cell types. To facilitate the detection of rare cellular states and uncover population heterogeneity, we performed single-cell RNA sequencing (RNA-seq) on islets from multiple deceased organ donors, including children, healthy adults, and individuals with type 1 or type 2 diabetes. We developed a robust computational biology framework for cell type annotation. Using this framework, we show that α- and β-cells from children exhibit less well-defined gene signatures than those in adults. Remarkably, α- and β-cells from donors with type 2 diabetes have expression profiles with features seen in children, indicating a partial dedifferentiation process. We also examined a naturally proliferating α-cell from a healthy adult, for which pathway analysis indicated activation of the cell cycle and repression of checkpoint control pathways. Importantly, this replicating α-cell exhibited activated Sonic hedgehog signaling, a pathway not previously known to contribute to human α-cell proliferation. Our study highlights the power of single-cell RNA-seq and provides a stepping stone for future explorations of cellular heterogeneity in pancreatic endocrine cells., (© 2016 by the American Diabetes Association.)

Published

2016

28. MitoNEET-Parkin Effects in Pancreatic α- and β-Cells, Cellular Survival, and Intrainsular Cross Talk.

Author

Kusminski CM, Chen S, Ye R, Sun K, Wang QA, Spurgin SB, Sanders PE, Brozinick JT, Geldenhuys WJ, Li WH, Unger RH, and Scherer PE

Subjects

Animals, Apoptosis, Cell Survival, Glucagon biosynthesis, Glucose metabolism, Glucose Intolerance etiology, Hyperglycemia etiology, Insulin metabolism, Insulin Secretion, Mice, Receptor Cross-Talk, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Iron-Binding Proteins metabolism, Membrane Proteins metabolism, Mitochondria metabolism, Ubiquitin-Protein Ligases metabolism

Abstract

Mitochondrial metabolism plays an integral role in glucose-stimulated insulin secretion (GSIS) in β-cells. In addition, the diabetogenic role of glucagon released from α-cells plays a major role in the etiology of both type 1 and type 2 diabetes because unopposed hyperglucagonemia is a pertinent contributor to diabetic hyperglycemia. Titrating expression levels of the mitochondrial protein mitoNEET is a powerful approach to fine-tune mitochondrial capacity of cells. Mechanistically, β-cell-specific mitoNEET induction causes hyperglycemia and glucose intolerance due to activation of a Parkin-dependent mitophagic pathway, leading to the formation of vacuoles and uniquely structured mitophagosomes. Induction of mitoNEET in α-cells leads to fasting-induced hypoglycemia and hypersecretion of insulin during GSIS. MitoNEET-challenged α-cells exert potent antiapoptotic effects on β-cells and prevent cellular dysfunction associated with mitoNEET overexpression in β-cells. These observations identify that reduced mitochondrial function in α-cells exerts potently protective effects on β-cells, preserving β-cell viability and mass., (© 2016 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2016

29. Expression-Based Genome-Wide Association Study Links Vitamin D-Binding Protein With Autoantigenicity in Type 1 Diabetes.

Author

Kodama K, Zhao Z, Toda K, Yip L, Fuhlbrigge R, Miao D, Fathman CG, Yamada S, Butte AJ, and Yu L

Subjects

Adolescent, Animals, Autoantigens genetics, Autoimmune Diseases blood, Autoimmune Diseases immunology, Autoimmune Diseases pathology, Case-Control Studies, Cells, Cultured, Child, Child, Preschool, Colorado, Diabetes Mellitus, Type 1 blood, Diabetes Mellitus, Type 1 immunology, Diabetes Mellitus, Type 1 pathology, Female, Genome-Wide Association Study, Glucagon-Secreting Cells immunology, Glucagon-Secreting Cells pathology, Humans, Male, Mice, Inbred NOD, Organ Specificity, Seasons, Spleen cytology, Spleen immunology, Spleen metabolism, Spleen pathology, T-Lymphocytes cytology, T-Lymphocytes immunology, T-Lymphocytes metabolism, T-Lymphocytes pathology, Vitamin D analogs & derivatives, Vitamin D blood, Vitamin D-Binding Protein genetics, Autoantigens metabolism, Autoimmune Diseases metabolism, Autoimmunity, Diabetes Mellitus, Type 1 metabolism, Gene Expression Regulation, Developmental, Glucagon-Secreting Cells metabolism, Vitamin D-Binding Protein metabolism

Abstract

Type 1 diabetes (T1D) is caused by autoreactive T cells that recognize pancreatic islet antigens and destroy insulin-producing β-cells. This attack results from a breakdown in tolerance for self-antigens, which is controlled by ectopic antigen expression in the thymus and pancreatic lymph nodes (PLNs). The autoantigens known to be involved include a set of islet proteins, such as insulin, GAD65, IA-2, and ZnT8. In an attempt to identify additional antigenic proteins, we performed an expression-based genome-wide association study using microarray data from 118 arrays of the thymus and PLNs of T1D mice. We ranked all 16,089 protein-coding genes by the likelihood of finding repeated differential expression and the degree of tissue specificity for pancreatic islets. The top autoantigen candidate was vitamin D-binding protein (VDBP). T-cell proliferation assays showed stronger T-cell reactivity to VDBP compared with control stimulations. Higher levels and frequencies of serum anti-VDBP autoantibodies (VDBP-Abs) were identified in patients with T1D (n = 331) than in healthy control subjects (n = 77). Serum vitamin D levels were negatively correlated with VDBP-Ab levels in patients in whom T1D developed during the winter. Immunohistochemical localization revealed that VDBP was specifically expressed in α-cells of pancreatic islets. We propose that VDBP could be an autoantigen in T1D., (© 2016 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2016

30. Evidence of Extrapancreatic Glucagon Secretion in Man.

Author

Lund A, Bagger JI, Wewer Albrechtsen NJ, Christensen M, Grøndahl M, Hartmann B, Mathiesen ER, Hansen CP, Storkholm JH, van Hall G, Rehfeld JF, Hornburg D, Meissner F, Mann M, Larsen S, Holst JJ, Vilsbøll T, and Knop FK

Subjects

Aged, Blood Glucose metabolism, Case-Control Studies, Cholecystokinin metabolism, Chromatography, Liquid, Enzyme-Linked Immunosorbent Assay, Female, Gastric Inhibitory Polypeptide metabolism, Gastrins metabolism, Gastrointestinal Tract drug effects, Glucagon-Like Peptide 1 metabolism, Glucagon-Secreting Cells metabolism, Glucose pharmacology, Glucose Tolerance Test, Humans, Male, Middle Aged, Peptide Fragments metabolism, Proteomics, Radioimmunoassay, Tandem Mass Spectrometry, Gastrointestinal Tract metabolism, Glucagon metabolism, Pancreatectomy, Pancreatic Neoplasms surgery, Pancreatitis surgery

Abstract

Glucagon is believed to be a pancreas-specific hormone, and hyperglucagonemia has been shown to contribute significantly to the hyperglycemic state of patients with diabetes. This hyperglucagonemia has been thought to arise from α-cell insensitivity to suppressive effects of glucose and insulin combined with reduced insulin secretion. We hypothesized that postabsorptive hyperglucagonemia represents a gut-dependent phenomenon and subjected 10 totally pancreatectomized patients and 10 healthy control subjects to a 75-g oral glucose tolerance test and a corresponding isoglycemic intravenous glucose infusion. We applied novel analytical methods of plasma glucagon (sandwich ELISA and mass spectrometry-based proteomics) and show that 29-amino acid glucagon circulates in patients without a pancreas and that glucose stimulation of the gastrointestinal tract elicits significant hyperglucagonemia in these patients. These findings emphasize the existence of extrapancreatic glucagon (perhaps originating from the gut) in man and suggest that it may play a role in diabetes secondary to total pancreatectomy., (© 2016 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2016

31. EphA4 Receptor Forward Signaling Inhibits Glucagon Secretion From α-Cells.

Author

Hutchens T and Piston DW

Subjects

Animals, Humans, Insulin metabolism, Islets of Langerhans metabolism, Mice, Mice, Transgenic, Receptor, EphA4 genetics, Signal Transduction physiology, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Receptor, EphA4 metabolism

Abstract

The loss of inhibition of glucagon secretion exacerbates hyperglycemia in type 1 and 2 diabetes. However, the molecular mechanisms that regulate glucagon secretion in unaffected and diabetic states remain relatively unexplained. We present evidence supporting a new model of juxtacrine-mediated regulation of glucagon secretion where neighboring islet cells negatively regulate glucagon secretion through tonic stimulation of α-cell EphA receptors. Primarily through EphA4 receptors, this stimulation correlates with maintenance of a dense F-actin network. In islets, additional stimulation and inhibition of endogenous EphA forward signaling result in inhibition and enhancement, respectively, of glucagon secretion, accompanied by an increase and decrease, respectively, in α-cell F-actin density. Sorted α-cells lack endogenous stimulation of EphA forward signaling from neighboring cells, resulting in enhanced basal glucagon secretion as compared with islets and the elimination of glucose inhibition of glucagon secretion. Restoration of EphA forward signaling in sorted α-cells recapitulates both normal basal glucagon secretion and glucose inhibition of glucagon secretion. Additionally, α-cell-specific EphA4(-/-) mice exhibit abnormal glucagon dynamics, and EphA4(-/-) α-cells contain less dense F-actin networks than EphA4(+/+) α-cells. This juxtacrine-mediated model provides insight into the functional and dysfunctional regulation of glucagon secretion and opens up new therapeutic strategies for the clinical management of diabetes., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

32. Novel Observations From Next-Generation RNA Sequencing of Highly Purified Human Adult and Fetal Islet Cell Subsets.

Author

Blodgett DM, Nowosielska A, Afik S, Pechhold S, Cura AJ, Kennedy NJ, Kim S, Kucukural A, Davis RJ, Kent SC, Greiner DL, Garber MG, Harlan DM, and diIorio P

Subjects

Adolescent, Adult, Child, Preschool, Female, Gene Expression Profiling, Humans, Islets of Langerhans cytology, Male, Middle Aged, Pregnancy, Pregnancy Trimester, Second, Sequence Analysis, RNA, Young Adult, Fetus cytology, Gene Expression Regulation, Developmental, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Islets of Langerhans metabolism, RNA genetics, Somatostatin-Secreting Cells metabolism

Abstract

Understanding distinct gene expression patterns of normal adult and developing fetal human pancreatic α- and β-cells is crucial for developing stem cell therapies, islet regeneration strategies, and therapies designed to increase β-cell function in patients with diabetes (type 1 or 2). Toward that end, we have developed methods to highly purify α-, β-, and δ-cells from human fetal and adult pancreata by intracellular staining for the cell-specific hormone content, sorting the subpopulations by flow cytometry, and, using next-generation RNA sequencing, we report the detailed transcriptomes of fetal and adult α- and β-cells. We observed that human islet composition was not influenced by age, sex, or BMI, and transcripts for inflammatory gene products were noted in fetal β-cells. In addition, within highly purified adult glucagon-expressing α-cells, we observed surprisingly high insulin mRNA expression, but not insulin protein expression. This transcriptome analysis from highly purified islet α- and β-cell subsets from fetal and adult pancreata offers clear implications for strategies that seek to increase insulin expression in type 1 and type 2 diabetes., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

33. Altered Phenotype of β-Cells and Other Pancreatic Cell Lineages in Patients With Diffuse Congenital Hyperinsulinism in Infancy Caused by Mutations in the ATP-Sensitive K-Channel.

Author

Salisbury RJ, Han B, Jennings RE, Berry AA, Stevens A, Mohamed Z, Sugden SA, De Krijger R, Cross SE, Johnson PP, Newbould M, Cosgrove KE, Hanley KP, Banerjee I, Dunne MJ, and Hanley NA

Subjects

Case-Control Studies, Cell Lineage, Cell Proliferation, Child, Child, Preschool, Congenital Hyperinsulinism metabolism, Cyclin-Dependent Kinase 6 metabolism, Cyclin-Dependent Kinase Inhibitor p27 metabolism, Fetus cytology, Glucagon-Secreting Cells cytology, Homeobox Protein Nkx-2.2, Homeodomain Proteins metabolism, Humans, Infant, Infant, Newborn, Insulin metabolism, Insulin-Secreting Cells cytology, Mutation, Nuclear Proteins, Paired Box Transcription Factors metabolism, Potassium Channels, Inwardly Rectifying genetics, Somatostatin-Secreting Cells cytology, Sulfonylurea Receptors genetics, Transcription Factors metabolism, Zebrafish Proteins, Congenital Hyperinsulinism genetics, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Somatostatin-Secreting Cells metabolism

Abstract

Diffuse congenital hyperinsulinism in infancy (CHI-D) arises from mutations inactivating the KATP channel; however, the phenotype is difficult to explain from electrophysiology alone. Here we studied wider abnormalities in the β-cell and other pancreatic lineages. Islets were disorganized in CHI-D compared with controls. PAX4 and ARX expression was decreased. A tendency toward increased NKX2.2 expression was consistent with its detection in two-thirds of CHI-D δ-cell nuclei, similar to the fetal pancreas, and implied immature δ-cell function. CHI-D δ-cells also comprised 10% of cells displaying nucleomegaly. In CHI-D, increased proliferation was most elevated in duct (5- to 11-fold) and acinar (7- to 47-fold) lineages. Increased β-cell proliferation observed in some cases was offset by an increase in apoptosis; this is in keeping with no difference in INSULIN expression or surface area stained for insulin between CHI-D and control pancreas. However, nuclear localization of CDK6 and P27 was markedly enhanced in CHI-D β-cells compared with cytoplasmic localization in control cells. These combined data support normal β-cell mass in CHI-D, but with G1/S molecules positioned in favor of cell cycle progression. New molecular abnormalities in δ-cells and marked proliferative increases in other pancreatic lineages indicate CHI-D is not solely a β-cell disorder., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

34. Loss of β-Cell Identity Occurs in Type 2 Diabetes and Is Associated With Islet Amyloid Deposits.

Author

Spijker HS, Song H, Ellenbroek JH, Roefs MM, Engelse MA, Bos E, Koster AJ, Rabelink TJ, Hansen BC, Clark A, Carlotti F, and de Koning EJ

Subjects

Animals, Diabetes Mellitus, Type 2 metabolism, Diabetes Mellitus, Type 2 physiopathology, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Humans, Insulin metabolism, Insulin-Secreting Cells metabolism, Islets of Langerhans metabolism, Islets of Langerhans physiopathology, Macaca fascicularis, Macaca mulatta, Male, Plaque, Amyloid metabolism, Plaque, Amyloid physiopathology, Diabetes Mellitus, Type 2 pathology, Glucagon-Secreting Cells pathology, Insulin-Secreting Cells pathology, Islets of Langerhans pathology, Plaque, Amyloid pathology

Abstract

Loss of pancreatic islet β-cell mass and β-cell dysfunction are central in the development of type 2 diabetes (T2DM). We recently showed that mature human insulin-containing β-cells can convert into glucagon-containing α-cells ex vivo. This loss of β-cell identity was characterized by the presence of β-cell transcription factors (Nkx6.1, Pdx1) in glucagon(+) cells. Here, we investigated whether the loss of β-cell identity also occurs in vivo, and whether it is related to the presence of (pre)diabetes in humans and nonhuman primates. We observed an eight times increased frequency of insulin(+) cells coexpressing glucagon in donors with diabetes. Up to 5% of the cells that were Nkx6.1(+) but insulin(-) coexpressed glucagon, which represents a five times increased frequency compared with the control group. This increase in bihormonal and Nkx6.1(+)glucagon(+)insulin(-) cells was also found in islets of diabetic macaques. The higher proportion of bihormonal cells and Nkx6.1(+)glucagon(+)insulin(-) cells in macaques and humans with diabetes was correlated with the presence and extent of islet amyloidosis. These data indicate that the loss of β-cell identity occurs in T2DM and could contribute to the decrease of functional β-cell mass. Maintenance of β-cell identity is a potential novel strategy to preserve β-cell function in diabetes., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

35. (111)In-exendin uptake in the pancreas correlates with the β-cell mass and not with the α-cell mass.

Author

Brom M, Joosten L, Frielink C, Boerman O, and Gotthardt M

Subjects

Animals, Female, Glucagon-Secreting Cells drug effects, Insulin-Secreting Cells drug effects, Pancreas drug effects, Rats, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism, Pancreas metabolism, Peptides pharmacokinetics, Radiopharmaceuticals pharmacokinetics

Abstract

Targeting of the GLP-1 receptor with (111)In-labeled exendin is an attractive approach to determine the β-cell mass (BCM). Preclinical studies as well as a proof-of-concept study in type 1 diabetic patients and healthy subjects showed a direct correlation between BCM and radiotracer uptake. Despite these promising initial results, the influence of α-cells on the uptake of the radiotracer remains a matter of debate. In this study, we determined the correlation between pancreatic tracer uptake and β- and α-cell mass in a rat model for β-cell loss. The uptake of (111)In-exendin (% ID/g) showed a strong positive linear correlation with the BCM (Pearson r = 0.82). The fraction of glucagon-positive cells in the total endocrine mass was increased after alloxan treatment (26% ± 4%, 43% ± 8%, and 69% ± 21% for 0, 45, and 60 mg/kg alloxan, respectively). The uptake of (111)In-exendin showed a negative linear correlation with the α-cell fraction (Pearson r = -0.76). These data clearly indicate toward specificity of (111)In-exendin for β-cells and that the influence of the α-cells on (111)In-exendin uptake is negligible., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

36. Cadherin engagement improves insulin secretion of single human β-cells.

Author

Parnaud G, Lavallard V, Bedat B, Matthey-Doret D, Morel P, Berney T, and Bosco D

Subjects

Cell Adhesion drug effects, Cells, Cultured, Glucagon-Secreting Cells cytology, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Glucose pharmacology, Humans, Insulin Secretion, Insulin-Secreting Cells cytology, Insulin-Secreting Cells drug effects, Cadherins metabolism, Insulin metabolism, Insulin-Secreting Cells metabolism

Abstract

The aim of this study was to assess whether cadherin-mediated adhesion of human islet cells was affected by insulin secretagogues and explore the role of cadherins in the secretory activity of β-cells. Experiments were carried out with single islet cells adherent to chimeric proteins made of functional E-, N-, or P-cadherin ectodomains fused to the Fc fragment of immunoglobulin (E-cad/Fc, N-cad/Fc, and P-cad/Fc) and immobilized on an inert substrate. We observed that cadherin expression in islet cells was not affected by insulin secretagogues. Adhesion tests showed that islet cells attached to N-cad/Fc and E-cad/Fc acquired, in a time- and secretagogue-dependent manner, a spreading form that was inhibited by blocking cadherin antibodies. By reverse hemolytic plaque assay, we showed that glucose-stimulated insulin secretion of single β-cells was increased by N-cad/Fc and E-cad/Fc adhesion compared with control. In the presence of E-cad/Fc and after glucose stimulation, we showed that total insulin secretion was six times higher in spreading β-cells compared with round β-cells. Furthermore, cadherin-mediated adhesion induced an asymmetric distribution of cortical actin in β-cells. Our results demonstrate that adhesion of β-cells to E- and N-cadherins is regulated by insulin secretagogues and that E- and N-cadherin engagement promotes stimulated insulin secretion., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

37. PTEN deletion in pancreatic α-cells protects against high-fat diet-induced hyperglucagonemia and insulin resistance.

Author

Wang L, Luk CT, Cai EP, Schroer SA, Allister EM, Shi SY, Wheeler MB, Gaisano HY, and Woo M

Subjects

Animals, Arginine metabolism, Diabetes Mellitus, Type 2 genetics, Diet, High-Fat, Female, Glucagon metabolism, Glucagon-Secreting Cells cytology, Glucagon-Secreting Cells metabolism, Hyperglycemia genetics, Hyperglycemia metabolism, Insulin-Secreting Cells cytology, Insulin-Secreting Cells physiology, Male, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Transgenic, PTEN Phosphohydrolase metabolism, Phosphatidylinositol 3-Kinases metabolism, RNA, Small Interfering genetics, Signal Transduction physiology, Diabetes Mellitus, Type 2 metabolism, Glucagon blood, Glucagon-Secreting Cells physiology, Insulin Resistance physiology, PTEN Phosphohydrolase genetics

Abstract

An aberrant increase in circulating catabolic hormone glucagon contributes to type 2 diabetes pathogenesis. However, mechanisms regulating glucagon secretion and α-cell mass are not well understood. In this study, we aimed to demonstrate that phosphatidylinositol 3-kinase (PI3K) signaling is an important regulator of α-cell function. Mice with deletion of PTEN, a negative regulator of this pathway, in α-cells show reduced circulating glucagon levels and attenuated l-arginine-stimulated glucagon secretion both in vivo and in vitro. This hypoglucagonemic state is maintained after high-fat-diet feeding, leading to reduced expression of hepatic glycogenolytic and gluconeogenic genes. These beneficial effects protected high-fat diet-fed mice against hyperglycemia and insulin resistance. The data demonstrate an inhibitory role of PI3K signaling on α-cell function and provide experimental evidence for enhancing α-cell PI3K signaling for diabetes treatment., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

38. Mitochondrial GTP insensitivity contributes to hypoglycemia in hyperinsulinemia hyperammonemia by inhibiting glucagon release.

Author

Kibbey RG, Choi CS, Lee HY, Cabrera O, Pongratz RL, Zhao X, Birkenfeld AL, Li C, Berggren PO, Stanley C, and Shulman GI

Subjects

Animals, Glucose Clamp Technique, Humans, Insulin Secretion, Mice, Mice, Transgenic, Mutation, Syndrome, Amino Acids metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Glutamate Dehydrogenase genetics, Guanosine Triphosphate metabolism, Hyperammonemia genetics, Hyperinsulinism genetics, Hypoglycemia genetics, Insulin metabolism, Insulin-Secreting Cells metabolism, Mitochondria metabolism

Abstract

Mitochondrial GTP (mtGTP)-insensitive mutations in glutamate dehydrogenase (GDH(H454Y)) result in fasting and amino acid-induced hypoglycemia in hyperinsulinemia hyperammonemia (HI/HA). Surprisingly, hypoglycemia may occur in this disorder despite appropriately suppressed insulin. To better understand the islet-specific contribution, transgenic mice expressing the human activating mutation in β-cells (H454Y mice) were characterized in vivo. As in the humans with HI/HA, H454Y mice had fasting hypoglycemia, but plasma insulin concentrations were similar to the controls. Paradoxically, both glucose- and glutamine-stimulated insulin secretion were severely impaired in H454Y mice. Instead, lack of a glucagon response during hypoglycemic clamps identified impaired counterregulation. Moreover, both insulin and glucagon secretion were impaired in perifused islets. Acute pharmacologic inhibition of GDH restored both insulin and glucagon secretion and normalized glucose tolerance in vivo. These studies support the presence of an mtGTP-dependent signal generated via β-cell GDH that inhibits α-cells. As such, in children with activating GDH mutations of HI/HA, this insulin-independent glucagon suppression may contribute importantly to symptomatic hypoglycemia. The identification of a human mutation causing congenital hypoglucagonemic hypoglycemia highlights a central role of the mtGTP-GDH-glucagon axis in glucose homeostasis., (© 2014 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2014

39. Interaction of islet α-cell and β-cell in the regulation of glucose homeostasis in HI/HA syndrome patients with the GDH(H454Y) mutation.

Author

Jia G and Sowers JR

Subjects

Animals, Humans, Insulin Secretion, Amino Acids metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Glutamate Dehydrogenase genetics, Guanosine Triphosphate metabolism, Hyperammonemia genetics, Hyperinsulinism genetics, Hypoglycemia genetics, Insulin metabolism, Insulin-Secreting Cells metabolism, Mitochondria metabolism

Published

2014

40. Blockade of Na+ channels in pancreatic α-cells has antidiabetic effects.

Author

Dhalla AK, Yang M, Ning Y, Kahlig KM, Krause M, Rajamani S, and Belardinelli L

Subjects

Acetanilides pharmacology, Animals, Diabetes Mellitus, Experimental metabolism, Exocytosis drug effects, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Humans, Hypoglycemic Agents pharmacology, Islets of Langerhans metabolism, Male, Piperazines pharmacology, Ranolazine, Rats, Rats, Sprague-Dawley, Acetanilides therapeutic use, Diabetes Mellitus, Experimental drug therapy, Glucagon-Secreting Cells drug effects, Hypoglycemic Agents therapeutic use, Islets of Langerhans drug effects, NAV1.3 Voltage-Gated Sodium Channel metabolism, Piperazines therapeutic use, Sodium Channel Blockers pharmacology

Abstract

Pancreatic α-cells express voltage-gated Na(+) channels (NaChs), which support the generation of electrical activity leading to an increase in intracellular calcium, and cause exocytosis of glucagon. Ranolazine, a NaCh blocker, is approved for treatment of angina. In addition to its antianginal effects, ranolazine has been shown to reduce HbA1c levels in patients with type 2 diabetes mellitus and coronary artery disease; however, the mechanism behind its antidiabetic effect has been unclear. We tested the hypothesis that ranolazine exerts its antidiabetic effects by inhibiting glucagon release via blockade of NaChs in the pancreatic α-cells. Our data show that ranolazine, via blockade of NaChs in pancreatic α-cells, inhibits their electrical activity and reduces glucagon release. We found that glucagon release in human pancreatic islets is mediated by the Nav1.3 isoform. In animal models of diabetes, ranolazine and a more selective NaCh blocker (GS-458967) lowered postprandial and basal glucagon levels, which were associated with a reduction in hyperglycemia, confirming that glucose-lowering effects of ranolazine are due to the blockade of NaChs. This mechanism of action is unique in that no other approved antidiabetic drugs act via this mechanism, and raises the prospect that selective Nav1.3 blockers may constitute a novel approach for the treatment of diabetes., (© 2014 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2014

41. Glycoprotein 130 receptor signaling mediates α-cell dysfunction in a rodent model of type 2 diabetes.

Author

Chow SZ, Speck M, Yoganathan P, Nackiewicz D, Hansen AM, Ladefoged M, Rabe B, Rose-John S, Voshol PJ, Lynn FC, Herrera PL, Müller W, Ellingsgaard H, and Ehses JA

Subjects

Animals, Cytokine Receptor gp130 antagonists & inhibitors, Diet, High-Fat, Glucagon metabolism, Interleukin-6 metabolism, Interleukin-6 pharmacology, Male, Mice, Mice, Knockout, Phosphorylation, Rats, STAT3 Transcription Factor metabolism, Cytokine Receptor gp130 metabolism, Diabetes Mellitus, Experimental physiopathology, Diabetes Mellitus, Type 2 physiopathology, Glucagon-Secreting Cells metabolism

Abstract

Dysregulated glucagon secretion accompanies islet inflammation in type 2 diabetes. We recently discovered that interleukin (IL)-6 stimulates glucagon secretion from human and rodent islets. IL-6 family cytokines require the glycoprotein 130 (gp130) receptor to signal. In this study, we elucidated the effects of α-cell gp130 receptor signaling on glycemic control in type 2 diabetes. IL-6 family cytokines were elevated in islets in rodent models of this disease. gp130 receptor activation increased STAT3 phosphorylation in primary α-cells and stimulated glucagon secretion. Pancreatic α-cell gp130 knockout (αgp130KO) mice showed no differences in glycemic control, α-cell function, or α-cell mass. However, when subjected to streptozotocin plus high-fat diet to induce islet inflammation and pathophysiology modeling type 2 diabetes, αgp130KO mice had reduced fasting glycemia, improved glucose tolerance, reduced fasting insulin, and improved α-cell function. Hyperinsulinemic-euglycemic clamps revealed no differences in insulin sensitivity. We conclude that in a setting of islet inflammation and pathophysiology modeling type 2 diabetes, activation of α-cell gp130 receptor signaling has deleterious effects on α-cell function, promoting hyperglycemia. Antagonism of α-cell gp130 receptor signaling may be useful for the treatment of type 2 diabetes., (© 2014 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2014

42. Grg3/TLE3 and Grg1/TLE1 induce monohormonal pancreatic β-cells while repressing α-cell functions.

Author

Metzger DE, Liu C, Ziaie AS, Naji A, and Zaret KS

Subjects

Animals, Cell Differentiation, Co-Repressor Proteins genetics, Glucagon metabolism, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Humans, Mice, Transcription Factors genetics, Transcription Factors metabolism, Co-Repressor Proteins metabolism, Gene Expression Regulation, Developmental, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism

Abstract

In the pancreas, α- and β-cells possess a degree of plasticity. In vitro differentiation of pluripotent cells yields mostly α- and polyhormonal β-like cells, indicating a gap in understanding of how functional monohormonal β-cells are formed and of the endogenous repressive mechanisms used to maintain β-cell identity. We show that the corepressor Grg3 is expressed in almost all β-cells throughout embryogenesis to adulthood. However, Grg3 is expressed in fewer nascent α-cells and is progressively lost from α-cells as endocrine cells mature into adulthood. We show that mouse Grg3(+/-) β-cells have increased α-specific gene expression, and Grg3(+/-) pancreata have more α-cells and more polyhormonal cells, indicating that Grg3 is required for the physiologic maintenance of monohormonal β-cell identity. Ectopic expression of Grg3 in α-cells represses glucagon and Arx, and the addition of Pdx1 induces Glut2 expression and glucose-responsive insulin secretion. Furthermore, we found that Grg1 is the predominant Groucho expressed in human β-cells but acts functionally similarly to Grg3. Overall, we find that Grg3 and Grg1 establish a monohormonal β-cell identity, and Groucho family members may be useful tools or markers for making functional β-cells.

Published

2014

43. Fibroblast growth factor 21 (FGF21) and glucagon-like peptide 1 contribute to diabetes resistance in glucagon receptor-deficient mice.

Author

Omar BA, Andersen B, Hald J, Raun K, Nishimura E, and Ahrén B

Subjects

Animals, Blood Glucose metabolism, Diabetes Mellitus, Experimental genetics, Glucagon-Like Peptide-1 Receptor, Glucagon-Secreting Cells metabolism, Glucose Tolerance Test, Hyperglycemia genetics, Insulin-Secreting Cells metabolism, Liver metabolism, Mice, Mice, Knockout, Pancreas metabolism, Peptide Fragments pharmacology, Receptors, Glucagon antagonists & inhibitors, Receptors, Glucagon genetics, Diabetes Mellitus, Experimental metabolism, Fibroblast Growth Factors metabolism, Glucagon-Like Peptide 1 metabolism, Hyperglycemia metabolism, Receptors, Glucagon metabolism

Abstract

Mice genetically deficient in the glucagon receptor (Gcgr(-/-)) show improved glucose tolerance, insulin sensitivity, and α-cell hyperplasia. In addition, Gcgr(-/-) mice do not develop diabetes after chemical destruction of β-cells. Since fibroblast growth factor 21 (FGF21) has insulin-independent glucose-lowering properties, we investigated whether FGF21 was contributing to diabetes resistance in insulin-deficient Gcgr(-/-) mice. Plasma FGF21 was 25-fold higher in Gcgr(-/-) mice than in wild-type mice. FGF21 was found to be expressed in pancreatic β- and α-cells, with high expression in the hyperplastic α-cells of Gcgr(-/-) mice. FGF21 expression was also significantly increased in liver and adipose tissue of Gcgr(-/-) mice. To investigate the potential antidiabetic actions of FGF21 in insulin-deficient Gcgr(-/-) mice, an FGF21-neutralizing antibody was administered prior to oral glucose tolerance tests (OGTTs). FGF21 neutralization caused a decline in glucose tolerance in insulin-deficient Gcgr(-/-) mice during the OGTT. Despite this decline, insulin-deficient Gcgr(-/-) mice did not develop hyperglycemia. Glucagon-like peptide 1 (GLP-1) also has insulin-independent glucose-lowering properties, and an elevated circulating level of GLP-1 is a known characteristic of Gcgr(-/-) mice. Neutralization of FGF21, while concurrently blocking the GLP-1 receptor with the antagonist Exendin 9-39 (Ex9-39), resulted in significant hyperglycemia in insulin-deficient Gcgr(-/-) mice, while blocking with Ex9-39 alone did not. In conclusion, FGF21 acts additively with GLP-1 to prevent insulinopenic diabetes in mice lacking glucagon action.

Published

2014

44. Diminished adenosine A1 receptor expression in pancreatic α-cells may contribute to the pathology of type 1 diabetes.

Author

Yip L, Taylor C, Whiting CC, and Fathman CG

Subjects

Adolescent, Adult, Animals, Child, Diabetes Mellitus, Type 1 genetics, Diabetes Mellitus, Type 1 pathology, Female, Humans, Islets of Langerhans metabolism, Islets of Langerhans pathology, Male, Mice, Mice, Inbred NOD, Middle Aged, Prediabetic State genetics, Prediabetic State pathology, Receptor, Adenosine A1 genetics, Spleen metabolism, Spleen pathology, Diabetes Mellitus, Type 1 metabolism, Glucagon-Secreting Cells metabolism, Prediabetic State metabolism, Receptor, Adenosine A1 metabolism

Abstract

Prediabetic NOD mice exhibit hyperglucagonemia, possibly due to an intrinsic α-cell defect. Here, we show that the expression of a potential glucagon inhibitor, the adenosine A1 receptor (Adora1), is gradually diminished in α-cells of NOD mice, autoantibody-positive (AA(+)) and overtly type 1 diabetic (T1D) patients during the progression of disease. We demonstrated that islet inflammation was associated with loss of Adora1 expression through the alternative splicing of Adora1. Expression of the spliced variant (Adora1-Var) was upregulated in the pancreas of 12-week-old NOD versus age-matched NOD.B10 (non-diabetes-susceptible) control mice and was detected in the pancreas of AA(+) patients but not in control subjects or overtly diabetic patients, suggesting that inflammation drives the splicing of Adora1. We subsequently demonstrated that Adora1-Var expression was upregulated in the islets of NOD.B10 mice after exposure to inflammatory cytokines and in the pancreas of NOD.SCID mice after adoptive transfer of activated autologous splenocytes. Adora1-Var encodes a dominant-negative N-terminal truncated isoform of Adora1. The splicing of Adora1 and loss of Adora1 expression on α-cells may explain the hyperglucagonemia observed in prediabetic NOD mice and may contribute to the pathogenesis of human T1D and NOD disease.

Published

2013

45. Resveratrol prevents β-cell dedifferentiation in nonhuman primates given a high-fat/high-sugar diet.

Author

Fiori JL, Shin YK, Kim W, Krzysik-Walker SM, González-Mariscal I, Carlson OD, Sanghvi M, Moaddel R, Farhang K, Gadkaree SK, Doyle ME, Pearson KJ, Mattison JA, de Cabo R, and Egan JM

Subjects

Animals, Blood Glucose metabolism, Body Weight, Densitometry, Diabetes Mellitus, Experimental drug therapy, Diabetes Mellitus, Experimental genetics, Diabetes Mellitus, Type 2 drug therapy, Diabetes Mellitus, Type 2 genetics, Diet, High-Fat, Dietary Sucrose, Disease Models, Animal, Fluorescent Antibody Technique, Glucagon metabolism, Glucagon-Like Peptide 1 metabolism, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Glucose Tolerance Test, Glycated Hemoglobin metabolism, Homeobox Protein Nkx-2.2, Homeodomain Proteins, Insulin Resistance, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells pathology, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Macaca mulatta, Nuclear Proteins, Protective Agents administration & dosage, Resveratrol, Stilbenes administration & dosage, Transcription Factors, Cell Dedifferentiation, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Type 2 metabolism, Insulin metabolism, Insulin-Secreting Cells drug effects, Protective Agents pharmacology, Sirtuin 1 metabolism, Stilbenes pharmacology

Abstract

Eating a "Westernized" diet high in fat and sugar leads to weight gain and numerous health problems, including the development of type 2 diabetes mellitus (T2DM). Rodent studies have shown that resveratrol supplementation reduces blood glucose levels, preserves β-cells in islets of Langerhans, and improves insulin action. Although rodent models are helpful for understanding β-cell biology and certain aspects of T2DM pathology, they fail to reproduce the complexity of the human disease as well as that of nonhuman primates. Rhesus monkeys were fed a standard diet (SD), or a high-fat/high-sugar diet in combination with either placebo (HFS) or resveratrol (HFS+Resv) for 24 months, and pancreata were examined before overt dysglycemia occurred. Increased glucose-stimulated insulin secretion and insulin resistance occurred in both HFS and HFS+Resv diets compared with SD. Although islet size was unaffected, there was a significant decrease in β-cells and an increase in α-cells containing glucagon and glucagon-like peptide 1 with HFS diets. Islets from HFS+Resv monkeys were morphologically similar to SD. HFS diets also resulted in decreased expression of essential β-cell transcription factors forkhead box O1 (FOXO1), NKX6-1, NKX2-2, and PDX1, which did not occur with resveratrol supplementation. Similar changes were observed in human islets where the effects of resveratrol were mediated through Sirtuin 1. These findings have implications for the management of humans with insulin resistance, prediabetes, and diabetes.

Published

2013

46. Effects of common genetic variants associated with type 2 diabetes and glycemic traits on α- and β-cell function and insulin action in humans.

Author

Jonsson A, Ladenvall C, Ahluwalia TS, Kravic J, Krus U, Taneera J, Isomaa B, Tuomi T, Renström E, Groop L, and Lyssenko V

Subjects

Adult, Blood Glucose metabolism, Diabetes Mellitus, Type 2 metabolism, Finland, Genetic Loci, Genetic Predisposition to Disease, Genome-Wide Association Study, Genotype, Humans, Polymorphism, Single Nucleotide, Blood Glucose genetics, Diabetes Mellitus, Type 2 genetics, Glucagon-Secreting Cells metabolism, Insulin metabolism, Insulin-Secreting Cells metabolism

Abstract

Although meta-analyses of genome-wide association studies have identified >60 single nucleotide polymorphisms (SNPs) associated with type 2 diabetes and/or glycemic traits, there is little information on whether these variants also affect α-cell function. The aim of the current study was to evaluate the effects of glycemia-associated genetic loci on islet function in vivo and in vitro. We studied 43 SNPs in 4,654 normoglycemic participants from the Finnish population-based Prevalence, Prediction, and Prevention of Diabetes-Botnia (PPP-Botnia) Study. Islet function was assessed, in vivo, by measuring insulin and glucagon concentrations during oral glucose tolerance test, and, in vitro, by measuring glucose-stimulated insulin and glucagon secretion from human pancreatic islets. Carriers of risk variants in BCL11A, HHEX, ZBED3, HNF1A, IGF1, and NOTCH2 showed elevated whereas those in CRY2, IGF2BP2, TSPAN8, and KCNJ11 showed decreased fasting and/or 2-h glucagon concentrations in vivo. Variants in BCL11A, TSPAN8, and NOTCH2 affected glucagon secretion both in vivo and in vitro. The MTNR1B variant was a clear outlier in the relationship analysis between insulin secretion and action, as well as between insulin, glucose, and glucagon. Many of the genetic variants shown to be associated with type 2 diabetes or glycemic traits also exert pleiotropic in vivo and in vitro effects on islet function.

Published

2013

47. Comment on: Allister et al. UCP2 regulates the glucagon response to fasting and starvation. Diabetes 2013;62:1623-1633.

Author

Gylfe E

Subjects

Animals, Humans, Male, Caloric Restriction adverse effects, Fasting adverse effects, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Hypoglycemia etiology, Ion Channels metabolism, Mitochondrial Proteins metabolism

Published

2013

48. Somatostatin receptor type 2 antagonism improves glucagon counterregulation in biobreeding diabetic rats.

Author

Karimian N, Qin T, Liang T, Osundiji M, Huang Y, Teich T, Riddell MC, Cattral MS, Coy DH, Vranic M, and Gaisano HY

Subjects

Animals, Catecholamines metabolism, Corticosterone metabolism, Glucagon-Secreting Cells metabolism, Glucose Clamp Technique, Humans, Insulin metabolism, Insulin Secretion, Male, Pancreas metabolism, Peptides, Cyclic pharmacology, Rats, Somatostatin metabolism, Diabetes Mellitus, Type 1 metabolism, Glucagon metabolism, Glucagon-Secreting Cells drug effects, Pancreas drug effects, Prediabetic State metabolism, Receptors, Somatostatin antagonists & inhibitors

Abstract

Impaired counterregulation during hypoglycemia in type 1 diabetes (T1D) is partly attributable to inadequate glucagon secretion. Intra-islet somatostatin (SST) suppression of hypoglycemia-stimulated α-cell glucagon release plays an important role. We hypothesized that hypoglycemia can be prevented in autoimmune T1D by SST receptor type 2 (SSTR2) antagonism of α-cells, which relieve SSTR2 inhibition, thereby increasing glucagon secretion. Diabetic biobreeding diabetes-prone (BBDP) rats mimic insulin-dependent human autoimmune T1D, whereas nondiabetic BBDP rats mimic prediabetes. Diabetic and nondiabetic rats underwent a 3-h infusion of vehicle compared with SSTR2 antagonist (SSTR2a) during insulin-induced hypoglycemia clamped at 3 ± 0.5 mmol/L. Diabetic rats treated with SSTR2a needed little or no glucose infusion compared with untreated rats. We attribute this effect to SSTR2a restoration of the attenuated glucagon response. Direct effects of SSTR2a on α-cells was assessed by resecting the pancreas, which was cut into fine slices and subjected to perifusion to monitor glucagon release. SSTR2a treatment enhanced low-glucose-stimulated glucagon and corticosterone secretion to normal levels in diabetic rats. SSTR2a had similar effects in vivo in nondiabetic rats and promoted glucagon secretion from nondiabetic rat and human pancreas slices. We conclude that SST contributes to impaired glucagon responsiveness to hypoglycemia in autoimmune T1D. SSTR2a treatment can fully restore hypoglycemia-stimulated glucagon release sufficient to attain normoglycemia in both diabetic and prediabetic stages.

Published

2013

49. Response to Comment on: Allister et al. UCP2 regulates the glucagon response to fasting and starvation. Diabetes 2013;62:1623-1633.

Author

Hardy AB, Allister EM, and Wheeler MB

Subjects

Animals, Humans, Male, Caloric Restriction adverse effects, Fasting adverse effects, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Hypoglycemia etiology, Ion Channels metabolism, Mitochondrial Proteins metabolism

Published

2013

50. Conversion of mature human β-cells into glucagon-producing α-cells.

Author

Spijker HS, Ravelli RB, Mommaas-Kienhuis AM, van Apeldoorn AA, Engelse MA, Zaldumbide A, Bonner-Weir S, Rabelink TJ, Hoeben RC, Clevers H, Mummery CL, Carlotti F, and de Koning EJ

Subjects

Adult, Aged, Animals, Cell Lineage genetics, Cell Transdifferentiation drug effects, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells metabolism, Glucose pharmacology, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Humans, Insulin metabolism, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Male, Mice, Middle Aged, Trans-Activators genetics, Trans-Activators metabolism, Cell Transdifferentiation physiology, Glucagon-Secreting Cells cytology, Insulin-Secreting Cells cytology, Islets of Langerhans cytology

Abstract

Conversion of one terminally differentiated cell type into another (or transdifferentiation) usually requires the forced expression of key transcription factors. We examined the plasticity of human insulin-producing β-cells in a model of islet cell aggregate formation. Here, we show that primary human β-cells can undergo a conversion into glucagon-producing α-cells without introduction of any genetic modification. The process occurs within days as revealed by lentivirus-mediated β-cell lineage tracing. Converted cells are indistinguishable from native α-cells based on ultrastructural morphology and maintain their α-cell phenotype after transplantation in vivo. Transition of β-cells into α-cells occurs after β-cell degranulation and is characterized by the presence of β-cell-specific transcription factors Pdx1 and Nkx6.1 in glucagon(+) cells. Finally, we show that lentivirus-mediated knockdown of Arx, a determinant of the α-cell lineage, inhibits the conversion. Our findings reveal an unknown plasticity of human adult endocrine cells that can be modulated. This endocrine cell plasticity could have implications for islet development, (patho)physiology, and regeneration.

Published

2013