Your search keyword '"Berggren, Per"' showing total 10 results

1. Removal of Ca2+ Channel β3 Subunit Enhances Ca2+ Oscillation Frequency and Insulin Exocytosis

Author

Berggren, Per-Olof, Yang, Shao-Nian, Murakami, Manabu, Efanov, Alexander M., Uhles, Sabine, Köhler, Martin, Moede, Tilo, Fernström, Andreas, Appelskog, Ioulia B., Aspinwall, Craig A., Zaitsev, Sergei V., Larsson, Olof, de Vargas, Lina Moitoso, Fecher-Trost, Claudia, Weißgerber, Petra, Ludwig, Andreas, Leibiger, Barbara, Juntti-Berggren, Lisa, Barker, Christopher J., and Gromada, Jesper

Subjects

*DIABETES, *CARBOHYDRATE intolerance, *THERAPEUTICS, *HOMEOSTASIS

Abstract

An oscillatory increase in pancreatic β cell cytoplasmic free Ca2+ concentration, [Ca2+]i, is a key feature in glucose-induced insulin release. The role of the voltage-gated Ca2+ channel β3 subunit in the molecular regulation of these [Ca2+]i oscillations has now been clarified by using β3 subunit-deficient β cells. β3 knockout mice showed a more efficient glucose homeostasis compared to wild-type mice due to increased glucose-stimulated insulin secretion. This resulted from an increased glucose-induced [Ca2+]i oscillation frequency in β cells lacking the β3 subunit, an effect accounted for by enhanced formation of inositol 1,4,5-trisphosphate (InsP3) and increased Ca2+ mobilization from intracellular stores. Hence, the β3 subunit negatively modulated InsP3-induced Ca2+ release, which is not paralleled by any effect on the voltage-gated L type Ca2+ channel. Since the increase in insulin release was manifested only at high glucose concentrations, blocking the β3 subunit in the β cell may constitute the basis for a novel diabetes therapy. [Copyright &y& Elsevier]

Published

2004

2. Regulation of glucose homeostasis using radiogenetics and magnetogenetics in mice.

Author

Leibiger, Ingo B and Berggren, Per-Olof

Subjects

*GENE expression in mammals, *RADIOGENETICS, *NANOPARTICLES, *TRANSGENE expression, *HOMEOSTASIS, *MAMMALS

Abstract

The authors focus on a study published in journal "Nature Medicine" related to noninvasively control of gene expression by the application of radiogenetics and magnetic field in mice. Topics discussed include use of nanoparticle to control transgene expression and glucose homeostasis in a diabetic mouse, activation of tethered TRPV1Ca2+ channel by iron nanoparticles through radio waves or magnetic field and conversion of oscillatory magnetic field in oscillatory pattern.

Published

2015

3. Islet vascularization is regulated by primary endothelial cilia via VEGF-A-dependent signaling.

Author

Yan Xiong, Scerbo, M. Julia, Seelig, Anett, Volta, Francesco, O'Brien, Nils, Dicker, Andrea, Padula, Daniela, Lickert, Heiko, Gerdes, Jantje Mareike, and Berggren, Per-Olof

Subjects

*CILIA & ciliary motion, *ISLANDS, *ENDOTHELIAL cells, *HOMEOSTASIS, *GENE silencing, *ISLANDS of Langerhans, *B cells

Abstract

Islet vascularization is essential for intact islet function and glucose homeostasis. We have previously shown that primary cilia directly regulate insulin secretion. However, it remains unclear whether they are also implicated in islet vascularization. At eight weeks, murine Bbs4-/-islets show significantly lower intra-islet capillary density with enlarged diameters. Transplanted Bbs4-/-islets exhibit delayed re-vascularization and reduced vascular fenestration after engraftment, partially impairing vascular permeability and glucose delivery to b-cells. We identified primary cilia on endothelial cells as the underlying cause of this regulation, via the vascular endothelial growth factor-A (VEGF-A)/VEGF receptor 2 (VEGFR2) pathway. In vitro silencing of ciliary genes in endothelial cells disrupts VEGF-A/VEGFR2 internalization and downstream signaling. Consequently, key features of angiogenesis including proliferation and migration are attenuated in human BBS4 silenced endothelial cells. We conclude that endothelial cell primary cilia regulate islet vascularization and vascular barrier function via the VEGF-A/VEGFR2 signaling pathway. [ABSTRACT FROM AUTHOR]

Published

2020

4. Enhanced expression of β cell CaV3.1 channels impairs insulin release and glucose homeostasis.

Author

Jia Yu, Yue Shi, Kaixuan Zhao, Guang Yang, Lina Yu, Yuxin Li, Andersson, Eva-Marie, Ämmälä, Carina, Shao-Nian Yang, and Berggren, Per-Olof

Subjects

*INSULIN, *GLUCOSE, *FORKHEAD transcription factors, *HOMEOSTASIS

Abstract

Voltage-gated calcium 3.1 (CaV3.1) channels are absent in healthy mouse β cells and mediate minor T-type Ca2+ currents in healthy rat and human β cells but become evident under diabetic conditions. Whether more active CaV3.1 channels affect insulin secretion and glucose homeostasis remains enigmatic. We addressed this question by enhancing de novo expression of β cell CaV3.1 channels and exploring the consequent impacts on dynamic insulin secretion and glucose homeostasis as well as underlying molecular mechanisms with a series of in vitro and in vivo approaches. We now demonstrate that a recombinant adenovirus encoding enhanced green fluorescent protein-CaV3.1 subunit (Ad-EGFPCaV3.1) efficiently transduced rat and human islets as well as dispersed islet cells. The resulting CaV3.1 channels conducted typical T-type Ca2+ currents, leading to an enhanced basal cytosolic-free Ca2+ concentration ([Ca2+]i). Ad-EGFP-CaV3.1-transduced islets released significantly less insulin under both the basal and first phases following glucose stimulation and could no longer normalize hyperglycemia in recipient rats rendered diabetic by streptozotocin treatment. Furthermore, Ad-EGFP-CaV3.1 transduction reduced phosphorylated FoxO1 in the cytoplasm of INS-1E cells, elevated FoxO1 nuclear retention, and decreased syntaxin 1A, SNAP-25, and synaptotagmin III. These effects were prevented by inhibiting CaV3.1 channels or the Ca2+-dependent phosphatase calcineurin. Enhanced expression of β cell CaV3.1 channels therefore impairs insulin release and glucose homeostasis by means of initial excessive Ca2+ influx, subsequent activation of calcineurin, consequent dephosphorylation and nuclear retention of FoxO1, and eventual FoxO1-mediated down-regulation of β cell exocytotic proteins. The present work thus suggests an elevated expression of CaV3.1 channels plays a significant role in diabetes pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2020

5. Phase modulation of insulin pulses enhances glucose regulation and enables inter-islet synchronization.

Author

Lee, Boah, Song, Taegeun, Lee, Kayoung, Kim, Jaeyoon, Han, Seungmin, Berggren, Per-Olof, Ryu, Sung Ho, and Jo, Junghyo

Subjects

*PHASE modulation, *INSULIN, *GLUCOSE, *GENETIC regulation, *HOMEOSTASIS

Abstract

Insulin is secreted in a pulsatile manner from multiple micro-organs called the islets of Langerhans. The amplitude and phase (shape) of insulin secretion are modulated by numerous factors including glucose. The role of phase modulation in glucose homeostasis is not well understood compared to the obvious contribution of amplitude modulation. In the present study, we measured Ca2+ oscillations in islets as a proxy for insulin pulses, and we observed their frequency and shape changes under constant/alternating glucose stimuli. Here we asked how the phase modulation of insulin pulses contributes to glucose regulation. To directly answer this question, we developed a phenomenological oscillator model that drastically simplifies insulin secretion, but precisely incorporates the observed phase modulation of insulin pulses in response to glucose stimuli. Then, we mathematically modeled how insulin pulses regulate the glucose concentration in the body. The model of insulin oscillation and glucose regulation describes the glucose-insulin feedback loop. The data-based model demonstrates that the existence of phase modulation narrows the range within which the glucose concentration is maintained through the suppression/enhancement of insulin secretion in conjunction with the amplitude modulation of this secretion. The phase modulation is the response of islets to glucose perturbations. When multiple islets are exposed to the same glucose stimuli, they can be entrained to generate synchronous insulin pulses. Thus, we conclude that the phase modulation of insulin pulses is essential for glucose regulation and inter-islet synchronization. [ABSTRACT FROM AUTHOR]

Published

2017

6. Defects in β-Cell Ca2+ Dynamics in Age-Induced Diabetes.

Author

Luosheng Li, Trifunovic, Aleksandra, Köhler, Martin, Yixin Wang, Berglund, Jelena Petrovic, Illies, Christopher, Juntti-Berggren, Lisa, Larsson, Nils-Göran, and Berggren, Per-Olof

Subjects

*CELL physiology, *INSULIN, *HOMEOSTASIS, *LABORATORY mice, *CELL membranes, *MITOCHONDRIAL DNA

Abstract

Little is known about the molecular mechanisms underlying age-dependent deterioration in β-cell function. We now demonstrate that age-dependent impairment in insulin release, and thereby glucose homeostasis, is associated with subtle changes in Ca2+ dynamics in mouse β-cells. We show that these changes are likely to be accounted for by impaired mitochondrial function and to involve phospholipase C/inositol 1,4,5-trisphosphate-mediated Ca2+ mobilization from intracellular stores as well as decreased β-cell Ca2+ influx over the plasma membrane. We use three mouse models, namely, a premature aging phenotype, a mature aging phenotype, and an aging-resistant phenotype. Premature aging is studied in a genetically modified mouse model with an age-dependent accumulation of mitochondrial DNA mutations. Mature aging is studied in the C57BL/6 mouse, whereas the 129 mouse represents a model that is more resistant to age-induced deterioration. Our data suggest that aging is associated with a progressive decline in β-cell mitochondrial function that negatively impacts on the fine tuning of Ca2+ dynamics. This is conceptually important since it emphasizes that even relatively modest changes in β-cell signal transduction over time lead to compromised insulin release and a diabetic phenotype. [ABSTRACT FROM AUTHOR]

Published

2014

7. Control of Insulin Secretion by Cholinergic Signaling in the Human Pancreatic Islet.

Author

Molina, Judith, Rodriguez-Diaz, Rayner, Fachado, Alberto, Jacques-Silva, M. Caroline, Berggren, Per-Olof, and Caicedo, Alejandro

Subjects

*ACETYLCHOLINE, *HORMONE research, *ISLANDS of Langerhans, *GLUCOSE, *HOMEOSTASIS

Abstract

Acetylcholine regulates hormone secretion from the pancreatic islet and is thus crucial for glucose homeostasis. Little is known, however, about acetylcholine (cholinergic) signaling in the human islet. We recently reported that in the human islet, acetylcholine is primarily a paracrine signal released from α-cells rather than primarily a neural signal as in rodent islets. In this study, we demonstrate that the effects acetylcholine produces in the human islet are different and more complex than expected from studies conducted on cell lines and rodent islets. We found that endogenous acetylcholine not only stimulates the insulin-secreting β-cell via the muscarinic acetylcholine receptors M3 and M5, but also the somatostatin-secreting δ-cell via M1 receptors. Because somatostatin is a strong inhibitor of insulin secretion, we hypothesized that cholinergic input to the δ-cell indirectly regulates β-cell function. Indeed, when all muscarinic signaling was blocked, somatostatin secretion decreased and insulin secretion unexpectedly increased, suggesting a reduced inhibitory input to β-cells. Endogenous cholinergic signaling therefore provides direct stimulatory and indirect inhibitory input to b-cells to regulate insulin secretion from the human islet. [ABSTRACT FROM AUTHOR]

Published

2014

8. Reporter islets in the eye reveal the plasticity of the endocrine pancreas.

Author

Ilegems, Erwin, Dicker, Andrea, Speier, Stephan, Sharma, Aarti, Bahow, Alan, Karlsson Edlund, Patrick, Leibiger, Ingo B., and Berggren, Per-Olof

Subjects

*ISLANDS of Langerhans, *BLOOD sugar, *HOMEOSTASIS, *EXOCRINE glands, *TREATMENT of diabetes, *LEPTIN

Abstract

The islets of Langerhans constitute the endocrine part of the pancreas and are responsible for maintenance of blood glucose homeostasis. They are deeply embedded in the exocrine pancreas, limiting their accessibility for functional studies. Understanding regulation of function and survival and assessing the clinical outcomes of individual treatment strategies for diabetes requires a monitoring system that continuously reports on the endocrine pancreas. We describe the application of a natural body window that successfully reports on the properties of in situ pancreatic islets. As proof of principle, we transplanted "reporter islets" into the anterior chamber of the eye of leptin-deficient mice. These islets displayed obesity-induced growth and vascularization patterns that were reversed by leptin treatment. Hence, reporter islets serve as optically accessible indicators of islet function in the pancreas, and also reflect the efficacy of specific treatment regimens aimed at regulating islet plasticity in vivo. [ABSTRACT FROM AUTHOR]

Published

2013

9. Noninvasive in vivo model demonstrating the effects of autonomic innervation on pancreatic islet function.

Author

Rodriguez-Diaz, Rayner, Speier, Stephan, Damaris Molano, Ruth, Formoso, Alexander, Gans, Itai, Abdulreda, Midhat H., Cabrera, Over, Molina, Judith, Fachado, Alberto, Ricordi, Camillo, Leibiger, Ingo, Pileggi, Antonello, Berggren, Per-Olof, and Caicedo, Alejandro

Subjects

*ISLANDS of Langerhans, *INNERVATION, *BLOOD sugar, *HOMEOSTASIS, *CELL physiology, *GLUCOSE, *PARASYMPATHETIC nervous system

Abstract

The autonomic nervous system is thought to modulate blood glucose homeostasis by regulating endocrine cell activity in the pancreatic islets of Langerhans. The role of islet innervation, however, has remained elusive because the direct effects of autonomic nervous input on islet cell physiology cannot be studied in the pancreas. Here, we used an in vivo model to study the role of islet nervous input in glucose homeostasis. We transplanted islets into the anterior chamber of the eye and found that islet grafts became densely innervated by the rich parasympathetic and sympathetic nervous supply of the iris. Parasympathetic innervation was imaged intravitally by using transgenic mice expressing GFP in cholinergic axons. To manipulate selectively the islet nervous input, we increased the ambient illumination to increase the parasympathetic input to the islet grafts via the pupillary light reflex. This reduced fasting glycemia and improved glucose tolerance. These effects could be blocked by topical application of the muscarinic antagonist atropine to the eye, indicating that local cholinergic innervation had a direct effect on islet function in vivo. By using this approach, we found that parasympathetic innervation influences islet function in C57BL/6 mice but not in 129X1 mice, which reflected differences in innervation densities and may explain major strain differences in glucose homeostasis. This study directly demonstrates that autonomic axons innervating the islet modulate glucose homeostasis. [ABSTRACT FROM AUTHOR]

Published

2012

10. Inositol hexakisphosphate promotes dynamin I-mediated endocytosis.

Author

Høy, Mariaane, Efanov, Alexander M., Bertorello, Alejandro M., Zaitsev, Sergel V., Olsen, Hervør L., Bokvist, Krister, Leibiger, Barbara, Leibiger, Ingo B., Zwiller, Jean, Berggren, Per-Olof, and Gromada, Jesper

Subjects

*INOSITOL, *ENDOCYTOSIS, *HOMEOSTASIS, *PROTEIN kinase C

Abstract

Examines the role of inositol (Ins) hexakisphosphate in improving dynamin-medicated endocytosis in the pancreatic cell. Molecular mechanism regulating the membrane homeostasis; Metabolic control of the Ins; Formation of the phosphatidylinositol biphosphate following activation of protein kinase C.

Published

2002