Astrid C. Hauge-Evans

Somatostatin Secreted by Islet δ-Cells Fulfills Multiple Roles as a Paracrine Regulator of Islet Function

OBJECTIVE— Somatostatin (SST) is secreted by islet δ-cells and by extraislet neuroendocrine cells. SST receptors have been identified on α- and β-cells, and exogenous SST inhibits insulin and glucagon secretion, consistent with a role for SST in regulating α- and β-cell function. However, the specific intraislet function of δ-cell SST remains uncertain. We have used Sst−/− mice to investigate the role of δ-cell SST in the regulation of insulin and glucagon secretion in vitro and in vivo. RESEARCH DESIGN AND METHODS— Islet morphology was assessed by histological analysis. Hormone levels were measured by radioimmunoassay in control and Sst−/− mice in vivo and from isolated islets in vitro. RESULTS— Islet size and organization did not differ between Sst−/− and control islets, nor did islet glucagon or insulin content. Sst−/− mice showed enhanced insulin and glucagon secretory responses in vivo. In vitro stimulus-induced insulin and glucagon secretion was enhanced from perifused Sst−/− islets compared with control islets and was inhibited by exogenous SST in Sst−/− but not control islets. No difference in the switch-off rate of glucose-stimulated insulin secretion was observed between genotypes, but the cholinergic agonist carbamylcholine enhanced glucose-induced insulin secretion to a lesser extent in Sst−/− islets compared with controls. Glucose suppressed glucagon secretion from control but not Sst−/− islets. CONCLUSIONS— We suggest that δ-cell SST exerts a tonic inhibitory influence on insulin and glucagon secretion, which may facilitate the islet response to cholinergic activation. In addition, δ-cell SST is implicated in the nutrient-induced suppression of glucagon secretion.

Metabolic phenotyping guidelines: Assessing glucose homeostasis in rodent models

The pathophysiology of diabetes as a disease is characterised by an inability to maintain normal glucose homeostasis. In type 1 diabetes, this is due to autoimmune destruction of the pancreatic β-cells and subsequent lack of insulin production, and in type 2 diabetes it is due to a combination of both insulin resistance and an inability of the β-cells to compensate adequately with increased insulin release. Animal models, in particular genetically modified mice, are increasingly being used to elucidate the mechanisms underlying both type 1 and type 2 diabetes, and as such the ability to study glucose homeostasis in vivo has become an essential tool. Several techniques exist for measuring different aspects of glucose tolerance and each of these methods has distinct advantages and disadvantages. Thus the appropriate methodology may vary from study to study depending on the desired end-points, the animal model, and other practical considerations. This review outlines the most commonly used techniques for assessing glucose tolerance in rodents and details the factors that should be taken into account in their use. Representative scenarios illustrating some of the practical considerations of designing in vivo experiments for the measurement of glucose homeostasis are also discussed.

Role of adenine nucleotides in insulin secretion from MIN6 pseudoislets.

Insulin secretion from MIN6 cells configured as cell aggregates by culture on a gelatin substrate (pseudoislets) is enhanced compared to that of MIN6 cells grown as monolayers on tissue culture plastic, indicating the importance of beta-cell-to-beta-cell proximity for insulin release. In this study we have shown that glucose induced a biphasic release of insulin from pseudoislets, whereas the amplitude and duration of the responses of equivalent monolayer cells were much reduced. Purinergic aqonists have been implicated in intercellular communication between beta-cells, so we investigated whether adenine nucleotides co-released with insulin are responsible for the enhanced secretory responses of pseudoislets. We have demonstrated that MIN6 cells express purinergic A(1) and P2Y receptors, and that adenine nucleotides increased [Ca(2+)](i) with an efficacy of agonists being ATP > ADP > AMP. However, neither suramin nor the more selective A(1) antagonist 1,3-dipropyl-8-cyclopentylxanthine reduced glucose-induced insulin secretion from pseudoislets, and stimulation of monolayer cells with a range of adenine nucleotides did not enhance glucose-induced secretion. These results suggest that enhanced secretion from MIN6 pseudoislets is not due to increased paracrine/autocrine action of adenine nucleotides.

Differential expression of insulin genes 1 and 2 in MIN6 cells and pseudoislets

There is some evidence that the two rodent insulin genes are differentially regulated in mice, although there is no satisfactory consensus on the relative levels and patterns of expression for the two genes. Using the mouse insulinoma cell line MIN6, we have demonstrated by quantitative RT-PCR, differential patterns of expression for the two genes. In mouse islets and early passage MIN6 cells, expression of ins 1 and ins 2 were found to be approximately equal, but levels of ins 1 mRNA diminished rapidly with continued passage. Furthermore, the ins 1 gene was found to be up-regulated in response to glucose stimulation and as a result of increased cell-cell contact, but no effect on the ins 2 gene was observed. Since the MIN6 cell line is frequently used as a beta-cell model for gene expression studies, consideration should be given to both insulin genes.

Co-ordinated Ca2+-signalling within pancreatic islets: does β-cell entrainment require a secreted messenger

Isolated beta-cells are heterogeneous in sensory, biosynthetic and secretory capabilities, however, to enable efficient and appropriate secretion, cellular activity within the intact islet is synchronised. Historically, the entrainment of activity to a common pattern has been attributed to gap-junction mediated cell-to-cell communication. Although clearly influential, the possibility remains for other local synchronising mechanisms. In this study, we have used small clusters of insulin-secreting MIN6 cells to assess how contact-dependent, homotypic interactions between cells influences nutrient- and non-nutrient- evoked Ca(2+)-handling and insulin secretion, and to determine whether a secreted product plays a role in the synchronisation of oscillatory activity. Tolbutamide evoked a concentration-dependent recruitment of active cells within cell clusters, both in terms of numbers of cells and amplitude of the evoked Ca(2+)-response. The change in [Ca(2+)](i) was characteristically oscillatory above a mean elevated plateau, and was in phase between member cells of an individual cluster. Even at maximal concentrations (100 microM) some cells within a cluster responded before their immediate neighbours. Subsequent oscillatory behaviour then became entrained between member cells within that cluster. Inhibiting exocytosis using the microtubule inhibitors vincristine and nocodazole, or the adrenergic agent noradrenaline, did not prevent tolbutamide-evoked oscillatory changes in [Ca(2+)](i) but did reduce the probability of obtaining synchronous activity within an individual cluster. Above a threshold glucose concentration, the number of cells secreting insulin increased, without a commensurate change in secretory efficiency. This recruitment of cells secreting insulin mirrored Ca(2+) data that showed a glucose-dependent increase in cell number, without a change in the mean basal-to-peak change in [Ca(2+)](i). Together these data suggest that synchronised behaviour in MIN6 cells is dependent, in part, on a secreted factor that acts in a local paracrine fashion to recruit heterogeneous individual cellular activity into an organised group response.

Delta cell secretory responses to insulin secretagogues are not mediated indirectly by insulin

Aims/hypothesisSomatostatin from islet delta cells inhibits insulin and glucagon secretion, but knowledge of the regulation of pancreatic somatostatin release is limited. Some insulin secretagogues stimulate somatostatin secretion, and here we investigated whether delta cell secretory responses are indirectly regulated in a paracrine manner by insulin released from beta cells.MethodsHormone release from static incubations of primary mouse islets or somatostatin-secreting TGP52 cells was measured by RIA. mRNA expression was assessed by RT-PCR.ResultsGlucose and a range of other physiological and pharmacological agents stimulated insulin and somatostatin release, and insulin receptor mRNA was expressed in islets, MIN6 beta cells and TGP52 cells. However, exogenous insulin did not modulate basal or glucose-induced somatostatin secretion from islets, nor did pre-incubation with an antibody against the insulin receptor or with the insulin receptor tyrosine kinase inhibitor, HNMPA(AM)3. Glucose and tolbutamide stimulated somatostatin release from TGP52 cells, whereas a range of receptor-operating agents had no effect, the latter being consistent with a lack of corresponding receptor mRNA expression in these cells. Parasympathetic activation stimulated insulin, but inhibited somatostatin release from mouse islets in accordance with differences in muscarinic receptor mRNA expression in islets, MIN6 and TGP52 cells. The inhibitory effect on somatostatin secretion was reversed by pertussis toxin or the muscarinic receptor 2 antagonist, methoctramine.Conclusions/interpretationsA number of insulin secretagogues have analogous effects on insulin and somatostatin release, but this similarity of response is not mediated by an indirect, paracrine action of insulin on delta cells.

Pseudoislets as primary islet replacements for research : report on a symposium at King's College London, London UK

Laboratory-based research aimed at understanding processes regulating insulin secretion and mechanisms underlying β-cell dysfunction and loss in diabetes often makes use of rodents, as these processes are in many respects similar between rats/mice and humans. Indeed, a rough calculation suggests that islets have been isolated from as many as 150,000 rodents to generate the data contained within papers published in 2009 and the first four months of 2010. Rodent use for islet isolation has been mitigated, to a certain extent, by the availability of a variety of insulin-secreting cell lines that are used by researchers world-wide. However, when maintained as monolayers the cell lines do not replicate the robust, sustained secretory responses of primary islets which limits their usefulness as islet surrogates. On the other hand, there have been several reports that configuration of MIN6 β-cells, derived from a mouse insulinoma, as three-dimensional cell clusters termed ‘pseudoislets’ largely recapitulates the function of primary islet β-cells. The Diabetes Research Group at King’s College London has been using the MIN6 pseudoislet model for over a decade and they hosted a symposium on “Pseudoislets as primary islet replacements for research”, which was funded by the UK National Centre for the Replacement, Refinement and Reduction of Animals in Research (NC3Rs), in London on 15th and 16th April 2010. This small, focused meeting was conceived as an opportunity to consolidate information on experiences of working with pseudoislets between different UK labs, and to introduce the theory and practice of pseudoislet culture to laboratories working with islets and/or β-cell lines but who do not currently use pseudoislets. This short review summarizes the background to the development of the cell line-derived pseudoislet model, the key messages arising from the symposium and emerging themes for future pseudoislet research.

A role for islet somatostatin in mediating sympathetic regulation of glucagon secretion

Aims/hypothesis: Somatostatin (SST) released from islet δ-cells inhibits both insulin and glucagon secretion but the role of this tonic inhibition is unclear. In this study we investigated whether δ-cell SST may facilitate sympathetic regulation of glucagon secretion as part of an ‘accelerator/brake’ mechanism. Methods: The secretory characteristics of islets isolated from SST-deficient (Sst-/-) and control mouse islets were assessed in static incubation studies. Glucagon and SST release was measured by radioimmunoassay (RIA). Results: Arginine stimulated both glucagon and SST release from control mouse islets whereas the sympathetic neurotransmitter noradrenaline (NA) increased glucagon secretion but inhibited SST release in the presence of 2 mmol/l glucose or 20 mmol/l arginine. Experiments were performed using Sst-/- islets to assess whether the reduction of SST secretion by NA offers an indirect mechanism of enhancing glucagon release in response to sympathetic activation. Arginine-induced but not NA-induced glucagon release from Sst-/- islets was significantly increased compared to controls. In combination, NA enhanced arginine-induced release from both groups of mouse islets but to a greater extent in control islets, leading to similar overall levels of glucagon release. The responsiveness of Sst-/- islets to NA was thus blunted under stimulatory but not sub-stimulatory conditions of SST release. Conclusions: Our data suggest that sympathetic activation of glucagon release may be partly mediated by an indirect effect on SST secretion, where the tonic inhibition by δ-cell SST on α-cells is removed, facilitating precise and substantial changes in glucagon release in response to NA.

Down-regulation of proliferation does not affect the secretory function of transformed β-cell lines regardless of their anatomical configuration

Aims and objectives: Proliferation in transformed β-cell lines is high compared to primary islet cells and is accompanied by reduced insulin content and release. Our aim was to determine whether experimental reduction of proliferation restores the cells to a more authentic β-cell phenotype in terms of secretory function and to investigate the potential beneficial effect of their configuration as islet-like structures. Results: Mitosis inhibitor mitomycin c treatment neither altered the rate of proliferation nor improved the secretory responses of MIN6 monolayer cells. The proliferative rate of MIN6 cells was not affected by pseudoislet formation, but in contrast to monolayer cells, pseudoislets responded to 20mM glucose with a 2.6-fold increase in insulin secretion. MMC reduced proliferation in MIN6 pseudoislets, but did not further improve their secretory responsiveness. Withdrawal of doxycycline resulted in complete growth-arrest in R7T1 cells, but monolayer and pseudoislet R7T1 cells were unresponsive to glucose and remained so upon growth-arrest although insulin content was increased in growth-arrested pseudoislets. Methods: MIN6 monolayer and pseudoislet cells were treated with MMC whereas growth-arrest was induced in R7T1 monolayer and pseudoislet cells by withdrawal of doxycycline. Proliferation rates were determined by immunocytochemical measurements of BrdU incorporation and insulin secretion was assessed by radioimmunoassay. Conclusions: Secretory function of transformed β-cells is not influenced by experimental reduction of proliferation, but can be modulated by enhanced cell-cell contact within islet-like structures. These results have implications for future studies of islet cell redifferentiation and for the generation of islet-like material for transplantation therapy in Type 1 diabetes.

Distinct patterns of heparan sulphate in pancreatic islets suggest novel roles in paracrine islet regulation

Heparan sulphate proteoglycans (HSPGs) exist in pancreatic beta cells, and HS seems to modulate important interactions in the islet microenvironment. However, the intra-islet structures of HS in health or altered glucose homeostasis are currently unknown. Here we show that distinct spatial distribution of HS motifs is present in islets in the adult, that intra-islet HS motifs are mostly conserved between rodents and humans, and that HS is abundant in glucagon producing islet alpha cells. In beta cells HS is characterised by 2-O, 6-O and N-sulphated moieties, whereas HS in alpha cells is N-acetylated, N-, and 2-O sulphated and low in 6-O groups. Differential expression of three HS modifying genes in alpha and beta cells was observed and may account for the different HS patterns. Furthermore, we found that FGF1 and FGF2 were present in alpha cells, whereas functional FGFRs exist in beta cells, but not in the alpha cell line aTC1-6, or in primary alpha cells in islets. FGF1 induced signalling was dependent on 2-O, and 6-O HS sulphation in beta cells, and HS desulphation reduced beta cell proliferation and potentiated oxidant induced apoptosis. In leptin resistant animals and in islets from streptozotocin treated rats there was a reduction in alpha cell HS expression. These data demonstrate the distinct HS expression patterns in alpha and beta islet cells and propose a novel role for alpha cells as a source of paracrine FGF ligands to neighbouring beta cells with specific cell-associated HS domains mediating the activation and diffusion of paracrine ligands.