Abstract
Aims/hypothesis
Glucose and incretins regulate beta cell function, gene expression and insulin exocytosis via calcium and cAMP. Prolonged exposure to elevated glucose (also termed glucotoxicity) disturbs calcium homeostasis, but little is known about cAMP signalling. We therefore investigated long-term effects of glucose on this pathway with special regard to the incretin glucagon-like peptide 1 (GLP-1).
Methods
We exposed INS-1E cells and rat or human islets to different levels of glucose for 3 days and determined functional responses in terms of second messengers (cAMP, Ca2+), transcription profiles, activation of cAMP-responsive element (CRE) and secretion by measuring membrane capacitance. Moreover, we modulated directly the abundance of a calcium-sensitive adenylyl cyclase (ADCY8) and GLP-1 receptor (GLP1R).
Results
GLP-1- or forskolin-mediated increases in cytosolic calcium, cAMP-levels or insulin secretion were largely reduced in INS-1E cells cultured at elevated glucose (>5.5 mmol/l). Statistical analysis of transcription profiles identified cAMP pathways as major targets regulated by glucose. Quantitative PCR confirmed these findings and unravelled marked downregulation of the calcium-sensitive adenylyl cyclase ADCY8 also in rat and in human islets. Re-expression of ADCY8, but not of the GLP1R, recovered GLP-1 signalling in glucotoxicity in INS-1E cells and in rat islets. Moreover, knockdown of this adenylyl cyclase showed that GLP-1-induced cAMP generation, calcium signalling, activation of the downstream target CRE and direct amplification of exocytosis by cAMP-raising agents (evaluated by capacitance measurement) proceeds via ADCY8.
Conclusions/interpretation
cAMP-mediated pathways are modelled by glucose, and downregulation of the calcium-sensitive ADCY8 plays a central role herein, including signalling via the GLP1R.
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Introduction
Glucose stimulates insulin secretion and modulates gene expression by regulating levels of calcium and cAMP in pancreatic beta cells [1]. Prolonged exposure to elevated levels of glucose, termed glucotoxicity [2], reduces glucose detection, modifies glucose metabolism as well as calcium handling and induces cellular stress [3]. Moreover, increased levels of glucose are directly correlated to decreased efficiency of incretin hormones, such as glucagon-like peptide 1 (GLP-1), on insulin secretion [4, 5].
The stimulatory action of incretins contributes considerably to physiological insulin secretion in beta cells [6]. Recognition of GLP-1 by its cognate receptor activates a classical signalling cascade via Gs and adenylyl cyclases, thus increasing cellular levels of cAMP and activating the effectors protein kinase A (PKA) and exchange protein directly activated by cAMP (EPAC [6]. GLP-1 facilitates membrane depolarisation through ATP-dependent potassium channels (KATP) in a PKA-and EPAC-dependent manner, antagonises voltage-dependent K+ channels via PKA and transactivates the epidermal growth factor receptor [7–9]. The ensuing Ca2+ influx is further enhanced by PKA-dependent phosphorylation of voltage-dependent calcium channels and mobilisation of calcium from stores [10, 11]. Whereas calcium constitutes the sole trigger of insulin exocytosis [1, 12], cAMP amplifies exocytosis and is required for the full physiological response [13]. In addition, GLP-1 also acts as a growth factor as well as a differentiation factor, and activation of the cAMP-response element (CRE) via calcium- and cAMP-dependent pathways is essential for glucose homeostasis and beta cell survival [14].
Prolonged exposure to elevated levels of glucose alters calcium handling in a cAMP-dependent manner [15, 16]. As the incretin GLP-1 exerts most of its effects through these second messengers and its efficacy is partially lost in type 2 diabetes, we used this hormone to investigate the interplay between cAMP and calcium under exposure to normal and chronically elevated glucose levels to identify underlying changes in signal transduction and gene expression.
Methods
Materials
The following antibodies were used: anti-actin (Abcam, Cambridge, UK), anti-CD8 (DAKO, Glostrup, Denmark), anti-adenylyl cyclase (ADCY8), anti-glucagon-like peptide 1 (GLP1R) and anti-synaptotagmin IV (SYT4) (Santa Cruz Biotechnology, Santa Cruz, CA, USA). Antibodies against enhanced green fluorescent protein (eGFP), cAMP-responsive element modulator/inducible cAMP early repressor (CREM/ICER), A kinase (PRKA) anchor protein 12 (AKAP12) and calcium and DAG-regulated guanine nucleotide exchange factor (Caldag-GEFI [also known as RASGRP2]) were generously donated by M. Rout (Rockefeller University, New York, NY, USA), J. Miano (University of Rochester, Rochester, NY, USA), L. Gao and I. Gelman (Roswell Park Cancer Institute, Buffalo, NY, USA) and A. Graybiel (MIT, Cambridge, MA, USA), respectively. Plasmids encoding ADCY8, ADCY8-eGFP and myc-GLP1R were generously donated by D. Cooper (University of Cambridge, UK) and A. Bisello (University of Pittsburgh, PA, USA). Plasmids encoding control short hairpin RNA (shRNA) or shRNA directed against ADCY8 were from SABiosciences (Frederick, MD, USA), the plasmid encoding human growth hormone (hGH) has been described [16, 17]. CD8-eGFP was obtained by replacing the cytosolic domain of CD8 with eGFP.
Preparation of islets, cell culture, secretion assays, immunofluorescence, determination of cAMP and CRE-activation
Rat islets or human donor islets were obtained and cultured as described [18, 19] and approved by the ethics committee. For calcium imaging, rat islet cells were seeded on polylysine-coated glass coverslips (6,000/coverslip, 25 mm diameter) and precultured for 4 days at 11 mmol/l glucose before transfection with lipofectamine. Cells were cultured subsequently for 72 h at indicated glucose concentration as described [19].
INS-1E cells were generously provided by P. Maechler and C. B. Wollheim (Université de Genève, Switzerland). Cell culture, transfections, secretion assays and immunocytochemistry were as published [16, 17]. Glucose pretreatments were conducted in the presence of 10% FCS [16]. For determination of cAMP, cells were exposed for 30 min to indicated agents and cellular cAMP was measured by ELISA (Correlate-EIA; Assay Designs, Ann Harbor, MI, USA). Activation of CRE was determined using pCRE-LUC (Invitrogen, Carlsbad, CA, USA) and peGFP for normalisation, luciferase was measured using the Luciferase Assay System (Promega, Madison, WI, USA).
Sorting of co-transfected INS-1E cells
Cells were co-transfected with a plasmid encoding the extracellular/transmembrane domain of CD8 linked to eGFP and the plasmid of interest. After 72 h of culture, cells were detached in PBS/10 mmol/l EDTA at 37°C, centrifuged, resuspended in ice-cold PBS/2 mmol/l EDTA and incubated at 4°C for 30 min with magnetic beads coated with anti-CD8 antibodies (Invitrogen). CD8-expressing cells were recovered using a magnet and washed three times in cold PBS/EDTA 2 mmol/l before assays.
Protein production and quantitative PCR
Proteins resolved by SDS-PAGE were immunoblotted as described [16]. Quantitative PCR was performed as published [16]. The cycle threshold (Ct) value of each gene was normalised against household genes (EF1a [also known as EF1A] and β-actin, INS-1E cells; TBP, rat islets; GUSB, human islets) and the relative expression levels calculated using the comparative (\( {2^{{ - \Delta \Delta {{\rm{C}}_{\rm{t}}}}}} \)) method. Threshold cycles ranged from 14 to 30 and primers used are detailed in Electronic supplementary material (ESM) Table 1. Statistics were performed on Ct values normalised for household genes.
Oligonucleotide microarray
Total RNA was extracted (RNAeasy; Qiagen, France) and used to synthesise labelled cRNAs for hybridisation of rat expression arrays (230 2.0; Affymetrix, Santa Clara, CA, USA). Data were analysed with Arraystar v3.0 (DNASTAR, Madison, WI, USA) and PLIER (Quantile/Perfect Match-Mismatch) used for normalisation. Of 31,099 transcripts, 22,084 were reliably detected on arrays in at least one glucose concentration at a mean signal intensity >5 (log2 value) and selected for further analysis; 3,614 transcripts showed differences among at least two conditions (ANOVA, p < 0.02), and finally 2,064 transcripts were retained with a fold change >1.5 and a false discovery rate <0.02 in at least one comparison (see ESM Table 2). Pathway analysis was performed using Ingenuity Pathways Analysis (Ingenuity Systems, Redwood City, CA, USA).
Microfluorimetry and electrophysiology
Microfluorimetry was performed as described [16, 17]. Electrophysiological recordings were performed by the whole-cell configuration of the patch clamp technique using an EPC-9 amplifier (HEKA, Lambrecht, Germany). Data were acquired and analysed with Patchmaster/Fitmaster (v2.35, HEKA). Patch pipettes pulled from borosilicate glass capillaries had tip resistances of 2–4 MΩ when filled with intracellular solutions. The zero-current potential was adjusted in the bath. The composition of the intracellular pipette solution was (in mmol/l): KCl 135; NaCl 10; MgCl2 1; CaCl2 9, EGTA 10, Mg-ATP 3; HEPES 5; pH adjusted to 7.1 with KOH. The extracellular medium was (in mmol/l): NaCl 138; KCl 5.6; MgCl2 1.2; CaCl2 2.6, HEPES 5; glucose 5.5, pH 7.4 with NaOH. Holding potential was −70 mV to prevent activation of voltage-dependent depolarising channels. Increases of cell capacitance were determined using a sine + DC protocol of the LockIn extension of the HEKA software (40 mV peak-to-peak, 1,250 Hz). Exocytosis was triggered by either iterative 200 ms depolarising steps from a holding potential at −70 to 0 mV or by intracellular dialysis of the calcium containing solution (1.5 μmol/l) [20] from the micropipette. Changes of cell capacitance were measured during the first minutes following the establishment of the whole-cell configuration. Curve fittings were done in ORIGIN v8 (OriginLab Corporation, Northampton, MA, USA).
Statistics
Experiments were replicated at least three times. Unless otherwise stated, data are given as mean ± SEM and groups were compared using ANOVA with Bonferroni as post hoc test.
Results
Prolonged exposure to elevated glucose blunts cAMP-mediated effects
Dynamics of cAMP and cytosolic calcium are linked [21], contributing both to insulin secretion and gene expression [12, 13]. We first examined whether prolonged exposure to glucose alters the generation of cAMP in INS-1E cells (Fig. 1a). Note that the conditions used induced only a minor increase in apoptosis in line with previous observations [16]. The response to forskolin, a general activator of adenylyl cyclases, or IBMX, a general inhibitor of phosphodiesterases, was reduced by 60% and 30%, respectively, in cells cultured for 3 days at 20 mmol/l glucose (G20). When both agents were added together, cAMP accumulation was again reduced by two-thirds in cells cultured at G20. This suggests that the decrease in stimulation observed at G20 is linked to cAMP generation rather than its metabolism.
As shown in Fig. 1b, GLP-1 raised cytosolic calcium [Ca2+]i when added to cells kept for 72 h at 5.5 mmol/l glucose (G5.5). This effect was reduced in cells cultured at G11 and completely lost in cells cultured at G20. To allow clear observation of the potentiating effects of GLP-1 and separate them from glucose effects, cells were kept at G15 for 30 min before the addition of GLP-1, which ensured a stable baseline. Note that preculture at G20 almost completely abolishes acute stimulation by glucose, as published previously [16]. Similarly to the effect of GLP-1 alone, the response to GLP-1/glucose was pronounced in cells cultured in G5.5 but was largely decreased in cells cultured in G11 and abolished by preculture at G20. Increasing cAMP levels by forskolin raised [Ca2+]i as expected [22]. The effect was reduced in cells cultured in G20, but to a lesser extent than observed for GLP-1. As decreased efficiency of GLP-1 or forskolin might be due to enhanced cAMP metabolism, the latter was blocked with IBMX. In the presence of 100 μmol/l IBMX, the loss in forskolin-induced responses was less prominent (G5.5 vs G20, 687 ± 101 vs 441 ± 61 nmol/l, n = 10 for each, 2p < 0.05, Student’s t test), whereas the response to GLP-1 was lost to the same extent as in the absence of IBMX in cells cultured at G11 or G20 (data not shown).
We subsequently evaluated insulin secretion, an event downstream from changes in [Ca2+]i or in cAMP [12, 13]. Similar to calcium handling, the amplifying action of GLP-1 was already lost in cells cultured at G11, whereas the effect of forskolin was reduced but still present after culture in G20 (Fig. 1c). As reported previously [16, 23], prolonged exposure to glucose leads to a reduction in insulin content (Fig. 1d). Although this certainly contributes to the decrease in effects, it was not solely due to a reduction in vesicular hormone content by culture in G20, as similar effects were observed in cells transiently expressing human growth hormone as a secretory product under the control of a cytomegalovirus promoter (data not shown).
Prolonged exposure to elevated glucose remodels gene expression in G protein coupled receptor- and cAMP-linked pathways
To get insight into underlying mechanisms, we examined the effect of glucose on gene expression by microarray analysis of INS-1E beta cells after 72 h culture at G5.5, G11 and G20 (see ESM Table 2). Interestingly, statistical evaluation of alterations in canonical pathways revealed the highest scores for two signalling pathways, via cAMP or more generally via G protein coupled receptors (GPCRs), and two metabolic pathways, pyruvate metabolism and glycolysis/gluconeogenesis (see ESM Table 3).
To visualise changes in GPCR- and cAMP-mediated pathways, a map was constructed (Fig. 2), with colour assignment according to clusters (see ESM Fig. 1). In addition, quantitative PCR for a number of transcripts confirmed alterations measured by microarrays (see ESM Table 4). Several GPCRs are differentially regulated, including those known for their specific function in islets [24] such as the GLP1R, as well as G protein subunits and regulators of G protein signalling. Among the adenylyl cyclases detected, calcium-sensitive Adcy8 was strongly downregulated, whereas the major adenylyl cyclase, Adcy6, remained unchanged, as did the more recently described soluble adenylyl cyclase, Adcy10. Indeed, Adcy8 was the most downregulated transcript within the GPCR- or cAMP-linked pathways and ranked also among the five most downregulated identified transcripts in the total study. Concomitantly several phosphodiesterases were upregulated, including calcium-sensitive phosphodiesterase 1C (Pde1c). Changes in expression of other genes intervening in adenylyl cyclase organisation were noted, such as those coded for by the two A-kinase anchoring proteins, Akap7 and -12, whereas expression remained constant for the immediate targets of cAMP Rapgef3/4 (also known as Epac1/2) or subunits of protein kinase A. Downstream of PKA we observed an increase for Sik2, a kinase inhibiting PKA-induced nuclear translocation of the transcription coactivator Torc, a major upregulation of CREM and a decrease in the transactivator Cited2. In addition to changes in cAMP-mediated signalling, altered expression of transcripts implicated in Ca2+ handling as well as Ca2+ targets was evident, including channels (Trpc4, Trpv1), pumps (Serca3 [also known as Atp2a3]) and links to the MAP-kinase pathway (Rasgrp1 and -2, Dusp).
We performed time-course experiments to determine the sequence of events (Fig. 3a–h). Whereas Glp1r, Adcy8 and Akap12 were modulated by glucose at early time points and peaked at 48 h, differences in PDEs reached their maximum later. Altered levels of GLP1R, ADCY8, AKAP12 and the vesicle protein synaptotagmin 4 (SYT4) were also evident at the protein level (Fig. 3i, j). Whereas Adcy8 was already reduced by 40% at G11, Glp1r was significantly reduced only at G20. In addition, the transcriptional regulator of CRE, Crem, was not altered, whereas its splice variant Icer increased mainly between G5 and G11 with little if any further changes at G20.
We further assayed several key transcripts identified in our screen in rat (Fig. 4a, b) or human donor islets (Fig. 4c). Among the GPCRs stimulating adenylyl cyclase, Glp1r was decreased but only after 24 h. Again, Adcy8 but not Adcy6 was strongly downregulated, and the production of Akap12 decreased. The mRNA levels of the phosphodiesterases Pde1c and -10a did not increase above G10, as already observed in INS-1E cells (see Fig. 2). Similarly to clonal beta cells, levels of Crem/Icer were only slightly augmented between G10 and G30. In human donor islets (Fig. 4c) ADCY8 also declined by 60%, whereas ADCY6 and PDEs remained stable. Expression profiles for CREM/ICER were similar to rat islets, although changes did not reach significance.
Re-expression of ADCY8 restores calcium signalling in clonal and primary cells
The functional consequences of prolonged exposure to elevated glucose observed in INS-1E cells in conjunction with transcript profiling in cells and islets pointed towards a major role of ADCY8. To test whether downregulation of this minor isoform in beta cells indeed does play a role, we examined the outcome of its re-expression and of its knockdown on Ca2+ signalling. Transient transfection with a plasmid encoding ADCY8 led to re-expression of this enzyme in cells cultured at G20 and its location at the plasma membrane (Fig. 5a, b). As shown in Fig. 5d, e, culturing cells for 72 h at G20 instead of G5.5 abolished the potentiating effects of forskolin and GLP-1 on cells kept in G15 for 30 min before the addition of the drugs (see also Fig. 1a). Note that transient overabundance of ADCY8 in cells cultured at G5.5 did not increase the response to GLP-1 (Fig. 5e, right-hand side), indicating that ADCY8 is not rate limiting under these conditions. In cells cultured at G20, the effects of forskolin and of GLP-1 were completely restored by re-expression of ADCY8. By contrast, overabundance of the GLP1R in cells cultured at G20 did not restore the effect of GLP-1 (Fig. 5e, right-hand side), although the receptor was clearly expressed and located at the plasma membrane (Fig. 5a, c). Most importantly, these effects were also observed in rat primary cells upon re-expression of ADCY8 (Fig. 6). GLP-1 induced a prominent increase in [Ca2+]i in cells precultured at G11, and preculture at G30 completely abolished hormone effects. Again, re-expression of ADCY8, but not of GLP1R, restored incretin-induced responses.
ADCY8 is required for normal calcium signalling
To further evaluate the role of this minor isoform, we downregulated its expression by shRNA-mediated knockdown. Levels of transiently expressed ADCY8-eGFP or of endogenous ADCY8 were decreased by the expression of shRNAs and plasmid psh-4 was used in subsequent assays (Fig. 7a, b). GLP-1 induced a robust increase in [Ca2+]i in control-transfected cells cultured at G5 and placed at G15 for 30 min before the addition of the hormone. Knockdown of endogenous Adcy8 (shADCY8) reduced the response by 90%. By contrast, knockdown of Adcy8 diminished the effect of forskolin on [Ca2+]i only by one-third (Fig. 7d, e), suggesting that only part of total cellular adenylyl cyclase activity is reduced. The effects of KCl and thapsigargin on [Ca2+]i remained unchanged (Fig. 7e).
ADCY8 is required for GLP-1-induced cAMP generation and CRE activation
Subsequently we asked whether cAMP generation and downstream effects, such as regulation of CRE, may be mediated by ADCY8 and recovered by its re-expression. Knockdown of Adcy8 as well as prolonged exposure to elevated glucose abolished GLP-1-induced cAMP accumulation, and re-expression of Adcy8 recovered two-thirds of the GLP-1 net effect (Fig. 8a). Moreover, culture at G20 for 72 h reduced forskolin- and GLP-1-induced activation of CRE (Fig. 8b). Re-expression of Adcy8 induced full recovery of CRE activation by both agents in cells cultured at G20. The amplification of the effect of glucose by GLP-1 was lost upon knockdown of Adcy8 (Fig. 8c). However, knockdown of Adcy8 did not alter glucose-induced regulation of CRE, which may thus occur independently from ADCY8.
ADCY8 is required for cAMP-induced potentiation of exocytosis
Re-expression of Adcy8 did not recover stimulation of hormone secretion by glucose or by glucose and forskolin in cells cultured in G20 for 72 h, regardless of whether early (0–10 min) or late phases (10–45 min) of release were measured (data not shown). The lack of reconstitution of exocytosis by re-expression of Adcy8 is in line with previous reports that central components of the secretory machinery are downregulated under these conditions [16, 25–27]. To address specifically the role of ADCY8 in the regulation of exocytosis, the final step in secretion, we resorted to capacitance measurements by patch clamp (Fig. 9). Stimulating exocytosis via intracellular dialysis with 1.5 μmol/l free calcium allowed circumvention of early effects of glucose such as metabolism, membrane depolarisation and calcium influx. The ensuing increase in membrane capacitance was not changed by knockdown of Adcy8. Direct stimulation of exocytosis by dialysis with calcium was further enhanced by the addition of forskolin/IBMX (Fig. 5a) reflecting amplification [28]. Upon knockdown of Adcy8 a complete loss of the effect induced by forskolin/IBMX was observed, demonstrating a prominent role of this isoform in the amplification of exocytosis by cAMP. Inspection of the kinetics of exocytosis revealed that the early phase (up to 15 s) remains unaltered, whereas subsequent exocytosis is largely reduced by the knockdown of Adcy8, indicating its involvement mainly in the second phase.
Discussion
Chronically elevated glucose alters glucose detection, its metabolism and subsequent calcium handling [3] as well as cellular insulin content [16, 23]. By contrast, it has only a minor effect on apoptosis under the conditions used [16, 19]. Our data now demonstrate a profound remodelling of signalling pathways linked to GPCRs such as the GLP-1 receptor, to cAMP and calcium. Moreover, a specific isoform of adenylyl cyclase, ADCY8, ranked among the most downregulated transcripts in this study as well as in a previous one in rat islets [19]. ADCY8 has previously been proposed as glucose/GLP-1 coincidence detector according to its biochemical characteristics and cell-specific production [29]. Our functional assays revealed that this isoform is crucial for incretin signalling in beta cells, and its reduced production constitutes an important element in glucotoxicity.
Changes in intracellular levels of cAMP rely on intricate dynamics between adenylyl cyclases and phosphodiesterases [30]. Several arguments indicate that effects of prolonged exposure to elevated levels of glucose are linked rather to changes in ADCY8 than in phosphodiesterases (PDEs). Decreased cAMP levels as well as a loss in calcium responses were still observed in the presence of the PDE inhibitor IBMX and changes in production occurred at a later time point in PDEs as compared with ADCY8. Furthermore, only a subset of PDEs interferes with secretion: mainly PDE3B, but also PDE1C, PDE4C, PDE5A and PDE8B [31]. Among these, prolonged exposure to glucose upregulated only Pde1c, mainly at low and intermediate glucose levels, whereas Pde3b was downregulated. As the latter event enhances GLP-1 induced insulin secretion [32], it does not account for loss of incretin effects.
Our data confirm the absolute requirement of ADCY8 for GLP-1 effects on cAMP and [Ca2+]i although it constitutes only a quantitatively minor isoform as compared with ADCY6 in INS-1E cells and rat or human islets [29, 33]. Its functional preponderance over ADCY6 is not too surprising as the latter is inhibited by calcium, similar to ADCY5 [34]. A second calcium-stimulated adenylyl cyclase is produced in beta cells, ADCY1. In contrast to ADCY1, ADCY8 responds more rapidly to changes in calcium and gives rise to oscillations in cAMP in response to Ca2+-transients [35] and may be better suited to the physiology of beta cells. Expression of the direct downstream effectors of cAMP, PKA as well as EPAC, remained stable further pointing towards ADCY8 as an important player. Most importantly, our re-expression experiments demonstrate that calcium, cAMP and CRE responses to GLP-1 can be recovered by restoring levels of ADCY8. Within the same line of arguments, knockdown of Adcy8 imitated the loss or decrease in forskolin or GLP-1 response in [Ca2+]i and cAMP observed in glucotoxicity. This provides the molecular identity for previous observations on calcium-dependency of GLP-1 effects [29] and places this isoform in a central position. Additional, though indirect, arguments for a role of ADCY8 in glucose homeostasis are provided by genetic data. A quantitative trait locus was identified containing the ADCY8 gene with significant linkage to fasting hyperglycaemia and impaired glucose tolerance in the Akita mouse, a non-obese model for type 2 diabetes [36]. A linkage between ADCY8 and type 2 diabetes has recently been mentioned in a genetic study in humans [37].
Prolonged exposure to elevated glucose remodels the production of numerous GPCRs required to adapt beta cells to physiological demands [24]. The GLP-1 receptor was downregulated in INS-1E cells, whereas significant changes were apparent in rat islets after 24, but not after 72 h. These results differ from observations in pancreatectomised rats, db/db mice or islets cultured at elevated glucose [38]. We have no ready explanation for this difference except that islets used in our study were precultured for up to a week to recover from the stress of the isolation procedure. Note that data similar to ours on 24 h effects of glucose have been published by others [39]. As re-expression of ADCY8, but not of the glucagon-like peptide 1 receptor (GLP1R), restored calcium signalling in clonal and primary cells, post-receptor events may represent the most vulnerable part of the pathway.
Regulation of gene expression via the calcium- and cAMP-responsive element CRE is important for beta cell function and survival. Glucose and GLP-1 can activate CRE via PKA either directly or through mitogen-activated kinases (ERK) [40, 41]. Both pathways are probably compromised at G11 by increased expression of the phosphatase DUSP14 acting on ERK [42] and the kinase SIK2 impeding nuclear translocation of CRTC2 (also known as TORC2), a CREB coactivator [43]. Our data also confirm that glucose leads to a large increase in the inducible repressor isoform of CREM, ICER, which inhibits CRE activation [25, 44]. Changes were present between G5.5 and G11 with little further alteration at G20 in clonal cells and islets. Interestingly, loss of forskolin- or GLP-1-induced CRE activation was reverted upon re-expression of ADCY8. Thus, CREM/ICER as well as DUSP and SIK are important physiological regulators, but their alterations seem to be less disruptive than those of ADCY8.
Compartmentalisation and isoform specificity confer selectivity in cAMP signalling [34]. Specific scaffold proteins, the AKAPs, ensure defined localisation of enzymes implicated in cAMP generation [45] and their differential expression by glucose could further disturb signalling. Isoform specificity for effectors was evident as only GLP-1 induced increases in [Ca2+]i and potentiation of CRE activation, but not glucose-induced activation of CRE relied on ADCY8. Recently ADCY10, a forskolin-insensitive isoform, has been identified as mediator of glucose-induced phosphorylation of ERK [46]. Its presence may explain the persistence of glucose-induced CRE activation after ADCY8 knockdown. ADCY10 is probably not involved in glucotoxicity as glucose did not affect its expression in INS-1E cells or rat islets.
The specificity of adenylyl cyclase isoforms was further underlined by measuring exocytosis, the final step in insulin secretion. Insulin exocytosis is triggered by calcium and amplified by cAMP-raising agents, thus providing an adequate response to physiological demands [13]. Although ADCY8 constitutes only a minor adenylyl cyclases [29, 33], its expression was required for cAMP-induced amplification of exocytosis. The observed defect may reside in vesicle priming, reminiscent of the specific role of ADCY8 in hippocampal synapses despite the presence of calcium-sensitive ADCY1 [47].
Collectively our data highlight the role of signalling pathways in glucose desensitisation/glucotoxicity and specifically identify the role of the calcium-sensitive adenylyl cyclase 8 in this setting and in normal signalling. The potential importance of altered signalling pathways, including those linked to GPCRs or to adenylate cyclases, in the pathogenesis of type 2 diabetes has also been underscored by recent genetic studies [48–50].
Abbreviations
- ADCY:
-
Adenylyl cyclase
- AKAP:
-
A-kinase anchoring protein
- [Ca2+]i :
-
Cytosolic free calcium
- CRE:
-
cAMP-responsive element
- CREM/ICER:
-
cAMP-responsive element modulator/inducible cAMP early repressor
- eGFP:
-
Enhanced green fluorescent protein
- EPAC:
-
Exchange protein directly activated by cAMP
- GLP-1:
-
Glucagon-like peptide 1
- GLP1R:
-
Glucagon-like peptide 1 receptor
- GPCR:
-
G protein coupled receptor
- PDE:
-
Phosphodiesterase
- PKA:
-
Protein kinase A
- shRNA:
-
Short hairpin RNA
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Acknowledgements
This work was supported by grants from the University of Bordeaux I (B. Roger, J. Lang), the MENRT and ALFEDIAM/Société française de Diabétologie (M. Dubois, M. Raoux and J. Lang). N. Moustaïd-Moussa was a recipient of a Fulbright Aquitaine Scholarship. J.-C. Jonas is a Senior Research Associate of the Fonds de la Recherche Scientifique-FNRS, Belgium. Human islet production was supported by the Juvenile Diabetes Research Foundation (ECIT, to F. Pattou). We thank G. Drutel and T. Leste-Lasserre (INSERM U, Université de Bordeaux 2) for initial help with quantitative PCRs and M. Bennassy, A. Milochau and C. Blatche for perfect technical assistance.
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B. Roger and J. Papin contributed equally to this study.
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ESM Fig. 1
Clustering of glucose-regulated transcripts. Cluster analysis of glucose affected probe-sets. Given are signal log ratio (SLR) and glucose (Glc) concentrations during 72 h culture. After data normalisation (mean = 0, variance = 1), the 2,064 glucose-affected probe-sets (see ESM Table 1) were separated in ten clusters. In the case of several probe-sets for the same transcript, mean values were used. U (upregulation) or D (downregulation), significant regulation between two consecutive glucose concentrations (FCS >1.5; FDR <0.02); S, no significant change between consecutive glucose concentrations (FCS <1.5). d (downregulation) or u (upregulation), statistically significant change between adjacent glucose concentrations (FDR < 0.02) but FCS > 1.5 only between G5 and G20. Combinations of the abbreviations U, u, D, d or S are used to label the changes over the whole range of glucose concentrations, n equals number of affected probes. a dd, n = 231; b DD, n = 143; c DS, n = 409; d DU, n = 23: e SD, n = 222; f uu, n = 146; g UU, n = 152; h US, n = 520; i UD, n = 57; j SU, n = 160. For each cluster, the mean ± SD of normalised probe-set signal intensities is shown as a function of the glucose concentration. The list of all affected probe-sets with the indication of the corresponding cluster is given in ESM Table 1. *p < 0.001 compared with G5; + p < 0.001 compared with G11, + p < 0.001 compared with G20 (non-parametric ANOVA, Kruskal–Wallis) (PDF 802 kb)
ESM Table 1
Primers used for quantitative PCR (PDF 107 kb)
ESM Table 2
Transcript profiling of INS-1E cells exposed to different glucose concentrations for 72 h (XLS 975 kb)
ESM Table 3
Canonical pathway analysis (PDF 110 kb)
ESM Table 4
Comparison of microarray and real-time RT-PCR measurements of glucose-induced changes in gene mRNA levels in INS-1E cells (PDF 280 kb)
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Roger, B., Papin, J., Vacher, P. et al. Adenylyl cyclase 8 is central to glucagon-like peptide 1 signalling and effects of chronically elevated glucose in rat and human pancreatic beta cells. Diabetologia 54, 390–402 (2011). https://doi.org/10.1007/s00125-010-1955-x
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DOI: https://doi.org/10.1007/s00125-010-1955-x