Microenvironment-regulated gene expression,morphology, and in vivo performance of mouse pancreatic β-cells

Cell behavior is determined by intrinsic characteristics and complex interactions with microenvironments. This study demonstrated the performance of a murine pancreatic β-cell line, MIN-6, cultured on tissue-culture polystyrene (TCPS), gelatin, type I collagen, and type IV collagen dishes. MIN-6 cells aggregated as clusters on gelatin, type I collagen, and type IV collagen, which was different from the epithelial morphology of cells grown on TCPS. The diameter and survival rate of aggregated cells did not differ significantly regardless of whether the cells were grown on gelatin or type I collagen, while smaller clusters were observed on type IV collagen. Compared with the monolayers on TCPS, the clusters had a higher insulin stimulation index. The mRNA expression levels of Ins1, Pdx-1, NeuroD1 and connexin 36 were upregulated in clusters relative to monolayers. Conversely, E-cadherin and MafA were downregulated when cells were grown on type IV collagen. Monolayers or cell aggregates grown on type IV collagen were subsequently transplanted into diabetic C57BL/6 mice. Animals that received both monolayers and clusters had decreased blood glucose levels and regained body weight. However, the area under curve for the intraperitoneal glucose tolerance test showed that clusters exhibited superior in vivo performance. This study reveals that a type IV collagen substrate promotes β-cell clustering, regulates gene expression and enhances in vivo performance.     

Imaging glucose-regulated insulin secretion and gene expression in single islet β-cells

The mechanisms by which changes in glucose concentration regulate gene expression and insulin secretion in pancreatic islet β-cells are only partly understood. Here we describe the development of new technologies for examining these processes at the level of single living β-cells. We also present recent findings, made using these and other techniques, which implicate a role for adenosine 5′-monophosphate-activated protein kinase in glucose signaling in these cells.     

Blockage of ceramide metabolism exacerbates palmitate inhibition of pro-insulin gene expression in pancreatic β-cells

Nasopharyngeal carcinoma-associated gene 6 (NGX6) was shown to be a novel putative tumor suppressor gene in colon cancer. The purpose of this study is to investigate its role in regulation of miRNA expression for in the hopes of translating this data into a novel strategy in control of colon cancer. In this study colon cancer HT-29 cells were stably transfected with NGX6 or vector-only plasmid and then subjected to miRNA array analysis, and Q-RT-PCR was then used to verify miRNA array data. Then bioinformatic analyses using Sanger, Target Scan, and MicroRNA software were performed to obtain data on the target genes of each miRNA and define their function. Our results showed that 14 miRNAs were found to be differentially expressed in NGX6-transfected cells compared to the control cells. In particular, miR-126, miR-142-3p, miR-155, miR-552, and miR-630 were all upregulated, whereas miR-146a, miR-152, miR-205, miR-365, miR-449, miR-518c, miR-584, miR-615, and miR-622 were downregulated after NGX6 transfection. Q-RT-PCR confirmed all of these miRNAs, and invalidated miR-552 and miR-630. Furthermore, bioinformatic analyses of these 12 miRNAs, among these miRNAs, target genes of miR-615 are unclear, another 11 miRNAs produced a total of 254 potential target genes and further study showed that these genes together formed a regulatory network that contributes to apoptosis, mobility/migration, hydrolysis activity, and molecular signaling through targeting JNK and Notch pathways. Taken together, these results have suggested that NGX6 plays an important role in regulation of apoptosis, mobility/migration, and hydrolase as well as activity of JNK and Notch pathways through NGX6-mediated miRNA expression. Further investigation will reveal the function of these differentially expressed miRNAs and verify expression of the miRNA-targeted genes for development of novel strategies for better control of colon cancer.     

ATF3 represses PDX-1 expression in pancreatic β-cells

The downregulation of PDX-1 expression plays an important role in development of type 2 diabetes. However, the negative regulator of PDX-1 expression is not well known. In this study, we analyzed the mouse PDX-1 promoter to characterize the effects of ATF3 on PDX-1 expression in pancreatic β-cells. Both thapsigargin treatment, an inducer of ER stress, and ATF3 expression decreased PDX-1 expression in pancreatic β-cells, MIN6N8. Furthermore, they also repressed the activity of −4.5 Kb promoter of mouse PDX-1 gene. Transfection studies with 5′ deleted-reporters showed that ATF3 repressed the activity of 0.9 Kb PDX-1 promoter, whereas it did not affect the activity of 0.7 Kb PDX-1 promoter, suggesting that ATF3 responsive element is located between the −903 and −702. An electrophoretic mobility shift assay and chromatin immunoprecipitation assay demonstrated that ATF3 binds directly to the promoter region spanning from −759 to −738. Moreover, mutation of the putative ATF/CRE site between −752 and −745 abrogated ATF3-mediated transrepression of the PDX-1 promoter. PDX-1 was decreased in MIN6N8 cells treated with high glucose or high palmitate, whereas ATF3 was increased, indicating that ATF3 plays a role in hyperglycemia or hyperlipidemia-mediated downregulation of PDX-1 expression. Collectively, these results demonstrate that ATF3 represses PDX-1 expression via binding to an ATF3-responsive element in its promoter, which plays an important role in suppression of pancreatic β-cells function.     

Electrophysiology of pancreatic β-cells in intact mouse islets of Langerhans

When exposed to intermediate glucose concentrations (6–16 mol/l), pancreatic β-cells in intact islets generate bursts of action potentials (superimposed on depolarised plateaux) separated by repolarised electrically silent intervals. First described more than 40 years ago, these oscillations have continued to intrigue β-cell electrophysiologists. To date, most studies of β-cell ion channels have been performed on isolated cells maintained in tissue culture (that do not burst). Here we will review the electrophysiological properties of β-cells in intact, freshly isolated, mouse pancreatic islets. We will consider the role of ATP-regulated K⁺-channels (K_ATP-channels), small-conductance Ca²⁺-activated K⁺-channels and voltage-gated Ca²⁺-channels in the generation of the bursts. Our data indicate that K_ATP-channels not only constitute the glucose-regulated resting conductance in the β-cell but also provide a variable K⁺-conductance that influence the duration of the bursts of action potentials and the silent intervals. We show that inactivation of the voltage-gated Ca²⁺-current is negligible at voltages corresponding to the plateau potential and consequently unlikely to play a major role in the termination of the burst. Finally, we propose a model for glucose-induced β-cell electrical activity based on observations made in intact pancreatic islets.     

Evidence for voltage-dependent Cl− permeability in mouse pancreatic β-cells

Microdissected -cell-rich pancreatic islets fromob/ob-mice were used in studies of transmembrane³⁶Cl^– efflux. The mean rate coefficient for³⁶Cl^– efflux was stable at 0.158 min^–1 during the initial 10 min. Depolarization of the -cell plasma membrane by acute increases in extracellular K⁺ (5–130mM) stimulated the³⁶Cl^– efflux in a concentration-dependent manner. Glucose-induced (20mM) and K⁺-induced increases in³⁶Cl^– efflux were largely overlapping, but even at 135.9 mM K⁺, glucose slightly further enhanced the³⁶Cl^– efflux rate. The data suggest (1) that pancreatic -cells are equipped with a voltage-dependent Cl^– permeability, (2) that glucose-induced increase in Cl^– permeability may, at least partly, be mediated by primary membrane depolarization, and (3) that glucose in addition may activate other mechanisms for -cell Cl^– transport.     

A transgenic mouse line expressing cre recombinase in pancreatic β-cells

Transgenic mouse lines expressing Cre recombinase in a cell-specific and tissue-specific manner are essential tools for studying gene function and for developing suitable models for human diseases. Here, we used an expression cassette containing the full 5' untranslated region of the porcine insulin gene to generate a mouse line expressing Cre recombinase specifically in pancreatic β-cells by pronuclear DNA microinjection. We obtained a founder animal that transmitted the construct to its descendants in a Mendelian fashion and whose descendants showed a clear activation of β-galactosidase expression in pancreatic β-cells after crossing into the ROSA26 lacZ reporter mouse line. Cre expression in other organs was negative except for the kidney, intestine, and the cerebral pons where β-galactosidase activity was detected in a small percentage of the cells. This new mouse line is a valuable tool for recombination of floxed alleles in pancreatic β-cells in vivo.     

Ultrastructural changes in β-cells of pancreatic islets in α-amanitin-poisoned Mice

In mice poisoned by alpha-amanitin nuclear changes typical of this toxin were observed in beta-cells of pancreatic islets. The lesions became progressively more severe and at 48 h after toxin injection some cells were necrotic. The damage to these cells could have implications in the changes in glycogen metabolism which occur after alpha-aminitin poisoning.     

BACE2 plays a role in the insulin receptor trafficking in pancreatic ß-cells

BACE1 (β-site amyloidogenic cleavage of precursor protein-cleaving enzyme 1) is a β-secretase protein that plays a central role in the production of the β-amyloid peptide in the brain and is thought to be involved in the Alzheimer's pathogenesis. In type 2 diabetes, amyloid deposition within the pancreatic islets is a pathophysiological hallmark, making crucial the study in the pancreas of BACE1 and its homologous BACE2 to understand the pathological mechanisms of this disease. The objectives of the present study were to characterize the localization of BACE proteins in human pancreas and determine their function. High levels of BACE enzymatic activity were detected in human pancreas. In normal human pancreas, BACE1 was observed in endocrine as well as in exocrine pancreas, whereas BACE2 expression was restricted to β-cells. Intracellular analysis using immunofluorescence showed colocalization of BACE1 with insulin and BACE2 with clathrin-coated vesicles of the plasma membrane in MIN6 cells. When BACE1 and -2 were pharmacologically inhibited, BACE1 localization was not altered, whereas BACE2 content in clathrin-coated vesicles was increased. Insulin internalization rate was reduced, insulin receptor β-subunit (IRβ) expression was decreased at the plasma membrane and increased in the Golgi apparatus, and a significant reduction in insulin gene expression was detected. Similar results were obtained after specific BACE2 silencing in MIN6 cells. All these data point to a role for BACE2 in the IRβ trafficking and insulin signaling. In conclusion, BACE2 is hereby presented as an important enzyme in β-cell function.     

GABA coordinates with insulin in regulating secretory function in pancreatic INS-1 β-cells

Pancreatic islet β-cells produce large amounts of γ-aminobutyric acid (GABA), which is co-released with insulin. GABA inhibits glucagon secretion by hyperpolarizing α-cells via type-A GABA receptors (GABA(A)Rs). We and others recently reported that islet β-cells also express GABA(A)Rs and that activation of GABA(A)Rs increases insulin release. Here we investigate the effects of insulin on the GABA-GABA(A)R system in the pancreatic INS-1 cells using perforated-patch recording. The results showed that GABA produces a rapid inward current and depolarizes INS-1 cells. However, pre-treatment of the cell with regular insulin (1 μM) suppressed the GABA-induced current (I(GABA)) by 43%. Zinc-free insulin also suppressed I(GABA) to the same extent of inhibition by regular insulin. The inhibition of I(GABA) occurs within 30 seconds after application of insulin. The insulin-induced inhibition of I(GABA) persisted in the presence of PI3-kinase inhibitor, but was abolished upon inhibition of ERK, indicating that insulin suppresses GABA(A)Rs through a mechanism that involves ERK activation. Radioimmunoassay revealed that the secretion of C-peptide was enhanced by GABA, which was blocked by pre-incubating the cells with picrotoxin (50 μM, p<0.01) and insulin (1 μM, p<0.01), respectively. Together, these data suggest that autocrine GABA, via activation of GABA(A)Rs, depolarizes the pancreatic β-cells and enhances insulin secretion. On the other hand, insulin down-regulates GABA-GABA(A)R signaling presenting a feedback mechanism for fine-tuning β-cell secretion.     

In vivo and in vitro development of mouse pancreatic β-cells in organotypic slices

Taking tissue slices of the embryonic and newborn pancreas is a novel approach for the study of the perinatal development of this gland. The aim of this study was to describe the morphology and physiology of in vivo and in vitro developing -cells. In addition, we wanted to lay a foundation for the functional analysis of other pancreatic cells, either alone or as part of an integrative pancreatic physiology approach. We used cytochemistry and light microscopy to detect specific markers and the whole-cell patch-clamp to assess the function of single -cells. The insulin signal in the embryonic -cells was condensed to a subcellular compartment and redistributed throughout the cytosol during the first 2 days after birth. The hormone distribution correlated well with the development of membrane excitability and hormone release competence in -cells. Endocrine cells survived in the organotypic tissue culture and maintained their physiological properties for weeks. We conclude that our preparation fulfills the criteria for a method of choice to characterize the function of developing pancreas in wild-type and genetically modified mice that die at birth. We suggest organotypic culture for in vitro studies of the development and regeneration of -cells.This work was supported by the European Commission (grant QLG1-CT-2001-02233 to TMR, AR and MR), the DFG Research Center for Molecular Physiology of the Brain (CMPB) and the Max-Planck Society (MR)     

Ultra-structural study of insulin granules in pancreatic β-cells of db/db mouse by scanning transmission electron microscopy tomography

Insulin granule trafficking is a key step in the secretion of glucose-stimulated insulin from pancreatic β-cells. The main feature of type 2 diabetes (T2D) is the failure of pancreatic β-cells to secrete sufficient amounts of insulin to maintain normal blood glucose levels. In this work, we developed and applied tomography based on scanning transmission electron microscopy (STEM) to image intact insulin granules in the β-cells of mouse pancreatic islets. Using three-dimensional (3D) reconstruction, we found decreases in both the number and the grey level of insulin granules in db/db mouse pancreatic β-cells. Moreover, insulin granules were closer to the plasma membrane in diabetic β-cells than in control cells. Thus, 3D ultra-structural tomography may provide new insights into the pathology of insulin secretion in T2D.     

N-Acyl taurines trigger insulin secretion by increasing calcium flux in pancreatic β-cells

Pancreatic β-cells secrete insulin in response to various stimuli to control blood glucose levels. This insulin release is the result of a complex interplay between signaling, membrane potential and intracellular calcium levels. Various nutritional and hormonal factors are involved in regulating this process. N-Acyl taurines are a group of fatty acids which are amidated (or conjugated) to taurine and little is known about their physiological functions. In this study, treatment of pancreatic β-cell lines (HIT-T15) and rat islet cell lines (INS-1) with N-acyl taurines (N-arachidonoyl taurine and N-oleoyl taurine), induced a high frequency of calcium oscillations in these cells. Treatment with N-arachidonoyl taurine and N-oleoyl taurine also resulted in a significant increase in insulin secretion from pancreatic β-cell lines as determined by insulin release assay and immunofluorescence (p < 0.05). Our data also show that the transient receptor potential vanilloid 1 (TRPV1) channel is involved in insulin secretion in response to N-arachidonoyl taurine and N-oleoyl taurine treatment. However our data also suggest that receptors other than TRPV1 are involved in the insulin secretion response to treatment with N-oleoyl taurine.     

Stimulation of the insulin secretory mechanism following barium accumulation in pancreatic β-cells

Electrothermal atomic absorption spectroscopy was employed for measuring barium in β-cell-rich pancreatic islets microdissected from ob/ob-mice. Both the uptake and efflux of barium displayed two distinct phases. There was a 4-fold accumulation of barium into intracellular stores when its extracellular concentration was 0.26 mM. Unlike divalent cations with more extensive intracellular accumulation, the washout of Ba²⁺ was not inhibited by d-glucose. Ba²⁺ served as a substitute for Ca²⁺ both in maintaining the glucose metabolism after removal of extracellular Ca²⁺ and making it possible for glucose to stimulate insulin release. Furthermore, Ba²⁺ elicited insulin release in the absence of glucose and other secretagogues. The latter effect was reversible and was markedly potentiated under conditions known to increase the β-cell content of cyclic AMP. It is likely that the observed actions of Ba²⁺ are mediated by Ca²⁺, since Ca²⁺-dependent regulatory proteins, such as calmodulin, apparently cannot bind Ba²⁺ specifically.     

Model for glucagon secretion by pancreatic α-cells

Glucagon hormone is synthesized and released by pancreatic α-cells, one of the islet-cell types. This hormone, along with insulin, maintains blood glucose levels within the physiological range. Glucose stimulates glucagon release at low concentrations (hypoglycemia). However, the mechanisms involved in this secretion are still not completely clear. Here, using experimental calcium time series obtained in mouse pancreatic islets at low and high glucose conditions, we propose a glucagon secretion model for α-cells. Our model takes into account that the resupply of releasable granules is not only controlled by cytoplasmic Ca2+, as in other neuroendocrine and endocrine cells, but also by the level of extracellular glucose. We found that, although calcium oscillations are highly variable, the average secretion rates predicted by the model fall into the range of values reported in the literature, for both stimulated and non-stimulated conditions. For low glucose levels, the model predicts that there would be a well-controlled number of releasable granules refilled slowly from a large reserve pool, probably to ensure a secretion rate that could last for several minutes. Studying the α-cell response to the addition of insulin at low glucose, we observe that the presence of insulin reduces glucagon release by decreasing the islet Ca2+ level. This observation is in line with previous work reporting that Ca2+ dynamics, mainly frequency, is altered by insulin. Thus, the present results emphasize the main role played by Ca2+ and glucose in the control of glucagon secretion by α-cells. Our modeling approach also shows that calcium oscillations potentiate glucagon secretion as compared to constant levels of this cellular messenger. Altogether, the model sheds new light on the subcellular mechanisms involved in α-cell exocytosis, and provides a quantitative predictive tool for studying glucagon secretion modulators in physiological and pathological conditions.     

PCSK9 is expressed in pancreatic δ-cells and does not alter insulin secretion

PCSK9 (Proprotein Convertase Subtilisin Kexin type 9) is a proprotein convertase that plays a key role in cholesterol homeostasis by decreasing hepatic low-density lipoprotein receptor (LDLR) protein expression. Here, we investigated the expression and the function of PCSK9 in pancreatic islets. Immunohistochemistry analysis showed that PCSK9 co-localized specifically with somatostatin in human pancreatic δ-cells, with no expression in α- and β-cells. PCSK9 seems not to be secreted by mouse isolated islets maintained in culture. Pcsk9-deficiency led to a 200% increase in LDLR protein content in mouse isolated islets, mainly in β-cells. Conversely, incubation of islets with recombinant PCSK9 almost abolished LDLR expression. However, Pcsk9-deficiency did not alter cholesterol content nor glucose-stimulated insulin secretion in mouse islets. Finally, invivo glucose tolerance was similar in Pcsk9^+/+ and Pcsk9^−/− mice under basal conditions and following streptozotocin treatment. These results suggest, at least in mice, that PCSK9 does not alter insulin secretion.     

Regulation of calcium in pancreatic α- and β-cells in health and disease

The glucoregulatory hormones insulin and glucagon are released from the β- and α-cells of the pancreatic islets. In both cell types, secretion is secondary to firing of action potentials, Ca(2+)-influx via voltage-gated Ca(2+)-channels, elevation of [Ca(2+)](i) and initiation of Ca(2+)-dependent exocytosis. Here we discuss the mechanisms that underlie the reciprocal regulation of insulin and glucagon secretion by changes in plasma glucose, the roles played by different types of voltage-gated Ca(2+)-channel present in α- and β-cells and the modulation of hormone secretion by Ca(2+)-dependent and -independent processes. We also consider how subtle changes in Ca(2+)-signalling may have profound impact on β-cell performance and increase risk of developing type-2 diabetes.