1 Department of Internal Medicine, Laboratory of Molecular Biology 19-135S, University Hospital, CHUV-1011 Lausanne, Switzerland
2 Department of Chemical Sciences, University of Catania, 95125 Catania, Italy
* Author for correspondence (e-mail: jaques-antoine.haeflinger{at}chuv.ch)
Accepted 22 July 2005
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Summary |
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Key words: Gap junctions, Connexin36, Glucose, Transcription, cAMP
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Introduction |
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We and others have demonstrated that connexin36 (Cx36; 36 kDa) is the sole connexin isoform expressed in insulin-producing ß-cells of rat and mouse pancreatic islets (Serre-Beinier et al., 2000; Theis et al., 2004
). In order to evaluate the contribution of Cx36 to the control of insulin secretion, the Cx36 content has been artificially modified in insulin-secreting cells (Caton et al., 2003
; Le Gurun et al., 2003
). These experiments provided evidence that Cx36 has to be expressed at a very precise level in order to maintain a normal insulin secretion. Recently, Leite et al. have suggested that, during the maturation process of neonatal islet, the gain of capacity of the islet to secrete insulin was associated with an increase in Cx36 expression levels. Therefore, variations of the endogenous Cx36 expression levels could have major repercussions on ß-cell function. Considering the fundamental implication of glucose on gene regulation in ß-cells, we investigated the effect of glucose on the Cx36 levels in insulin-producing cells. Early morphological studies have demonstrated that glucose induces a remodeling of the gap junctions aggregates in pancreatic islets (In't Veld et al., 1986
; Meda et al., 1980
). Here, we have demonstrated for the first time that glucose induces a time- and dose-dependent decrease of Cx36 mRNA and protein content in several insulin-secreting cell lines and adult pancreatic rat islets.
In ß-cells, glucose metabolism generates fluctuations in the ATP/ADP ratio, leading to oscillations of membrane potential and cytoplasmic calcium concentrations, which then trigger insulin release (Deeney et al., 2000). Thus, ß-cell stimulation is associated with regular Ca2+ oscillations (Lenzen et al., 2000
). Surprisingly, glucose-induced Ca2+ oscillations are synchronized among the thousands of ß-cells that form each pancreatic islet (Jonkers and Henquin, 2001
), probably because of a diffusible regulator (Meda, 1996
). These oscillations become more regular and prominent in the presence of ß-cell contacts (Squires et al., 2000
), suggesting that the intercellular communication is involved in the synchronization of ß-cells. Calabrese et al. have shown that a marked decrease in the Cx36 expression levels was associated with an altered synchronization of the glucose-induced Ca2+ oscillations, indicating that Cx36 gap junctions control the ion-current flow from one cell to its coupled neighbors (Calabrese et al., 2003
). This observation prompted us to study the effects of different compounds on Cx36 expression levels, particularly KCl and the inhibitor of Ca2+ entry nifedipine, in order to determine whether ß-cell depolarization and Ca2+ entry are implicated in glucose-induced Cx36 regulation. We found that glucose's effect on Cx36 expression is independent of ß-cell depolarization but required PKA activation. We further demonstrated the involvement of a novel cAMP responsive element (CRE) located in the Cx36 promoter.
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Materials and Methods |
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RNA isolation, northern-blot analysis and PCR
Cells were homogenized in Tripure isolation reagent (Roche Diagnostics, Rotkreuz, Switzerland) and total RNA was extracted using the kit procedure. 12 µg total RNA was size fractionated on 1% agarose gels containing 8% formaldehyde and 1 x MOPS buffer (Fluka Chemie). RNAs were transferred overnight on Gene Screen membranes (PerkinElmer Life Science Europe, Zavemtem, Belgium) by capillary transfer in the presence of 10x saline sodium citrate SSC). Membranes were cross-linked using ultraviolet light and vacuum baked for 2 hours at 80°C. Transcript levels were determined by hybridization with random primed (Roche Diagnostics) cDNA probes labeled with 32P-dCTP (Amersham Bioscience Europe, Otelfingen, Switzerland). Probes were prepared using cDNA clones for rat Cx36 (Serre-Beinier et al., 2000
), rat MIF (Waeber et al., 1997
), and ß-actin (Haefliger et al., 2002
). Hybridizations were performed overnight at 68°C in Miraclehyb (Stratagene Europe, Amsterdam, Netherlands). Blots were washed twice in 1 x SSC/1% SDS and twice in 0.1 x SSC/1% SDS. RNA abundance was determined using the ß-radiation counter Instant-Imager (PerkinElmer Life Science Europe).
For reverse-transcription PCR (RT-PCR), cytoplasmic RNA was extracted using the Rneasy kit (Qiagen, Garstligweg, Switzerland). Transcripts (1 µg) were reverse transcribed using the ImProm-II Reverse Transcription System (Catalys, Wallisellen, Switzerland). Quantitative PCR was performed, as already published, using the QuantiTect SYBR Green PCR Kit (Qiagen) in a Lightcycler (Roche Diagnostics), according to the manufacturer's instructions (Deglise et al., 2005; Tawadros et al., 2005
). cDNAs were amplified using the following primers: rat Cx36 (192 bp), 5'-ATACAGGTGTGAATGAGGGAGGATG-3' (sense) and 5'-TGGAGGGTGTTACAGATGAAAGAGG-3' (antisense); rat ribosomal protein L-27 (120 bp), 5'-GATCCAAGATCAAGTCCTTTGTG-3' (sense) and 5'-CTGGGTCTCTGAACACATCCT-3' (antisense).
Measurement of intracellular cAMP levels
INS-1 cells were incubated for 24 hours with 2 mM or 20 mM glucose in the presence of nifedipine (10 µM) or forskolin (20 µM). The medium was removed and the cells were lysed with ice-cold lysis reagent as indicated in the cAMP RIA system kit (Amersham Bioscience Europe). The cAMP assay was carried out according to manufacturer's instructions.
Immunofluorescence
For immunofluorescence, cells were grown on glass coverslips, fixed for 5 minutes in 20°C acetone, air-dried, rinsed in PBS, permeabilized for 1 hour in PBS containing 1.5% bovine serum albumin (BSA), 0.1% Triton X-100. Coverslips were incubated overnight at 4°C in the presence of a polyclonal rabbit antiserum against residues 289303 of rat Cx36 (Le Gurun et al., 2003), diluted 1:20. After a 1 hour exposure to fluorescein-conjugated antibodies against rabbit immunoglobulins (Igs) diluted 1:250, cells were counterstained with Evans blue, coverslipped and photographed using a fluorescence microscope (Leica Leitz DMRB, Nidau, Switzerland). Immunolabeling of Cx36 resulted in a punctate membrane labeling in INS-1 cells. Quantification of the fluorescent dots were performed under the microscope on many images by counting the immunofluorescent dots in a square containing approximately 100 cells.
Western blotting
INS-1 cells were solubilized by sonication in SDS buffer (62.5 mM Tris-EDTA, pH 6.8, 5% SDS). Protein content was measured using a detergent-compatible DC protein assay kit (Bio-Rad Laboratories, Reinach BL, Switzerland). Samples were equally loaded (100 µg) on a 12.5% polyacrylamide gel followed by electrophoresis and transferred onto PVDF membrane (Immobilon-P; Millipore, Volketswil, Switzerland). Membranes were incubated for 1 hour in PBS containing 5% milk and 0.1% Tween20 (blocking buffer). Saturated membranes were incubated overnight at 4°C with: rabbit polyclonal antibodies against Cx36 (Le Gurun et al., 2003; Martin et al., 2003
), diluted 1:200; monoclonal anti-
-tubulin antibodies (Fluka Chemie, diluted 1:2000); monoclonal anti-ß-actin antibodies (Fluka Chemie, diluted 1:2000); rabbit polyclonal anti-P-ERK antibodies (Cell Signaling, diluted 1:1000); or rabbit polyclonal anti-ERK1 antibodies (Santa Cruz Biotechnology, diluted 1:500). After incubation at room temperature for 1 hour with a convenient secondary antibody conjugated to horseradish peroxidase (Fluka Chemie, diluted 1:20,000), membranes were revealed by enhanced chemiluminescence (ECL) according to the manufacturer's instructions (Amersham Bioscience Europe). Densitometric analyses of immunolabeled proteins (western blots) were performed using the ImageQuant Software (Molecular Dynamics, Amersham Bioscience Europe).
Human Cx36 promoter isolation and reporter-plasmid construction
A human genomic library in the pBeloBAC11 vector (Genome Systems, St Louis, MO) was screened using a specific CX36 probe amplified by PCR with the following human Cx36 primers [forward, 5'-AACGCCGCTACTCTACAGTCTTCC-3' (intron); reverse, 5'-GATGCCTTCCTGCCTTCTGAGCTT-3' (exon 2)]. The identity of a single positive clone was first confirmed by Southern hybridization with the 269-bp rat Cx36 DNA probe (Belluardo et al., 1999). 3945 bp of the 5' flanking sequence were sequenced (numbering from the translational start site). Five different fragments of the human CX36 promoter were generated by PCR amplification using the same antisense primer for all the constructs: 5'-GCAGATCTCGCTGTGCATCCGGAGGCAGCAGACAA-3'. The sense primers were: 5'-GCGGTACCGGCTTTCTACTGAGGG-3' for the 3945 bp fragment; 5'-GCGGTACCGGATCTGCTGGTTGAGG-3' for the 1384 bp fragment; 5'-GCGGTACCCTCCACACCTGCATTTA-3' for the 1079 bp fragment; 5'-GCGGTACCTGCCACCCCGCCCCGCCC-3' for the 316 bp fragment; and 5'-GCGGTACCCGCGCTTGGATTTCTTTCC-3' for the 200 bp fragment. The fragments were subcloned into the promoterless expression vector pGL3 basic (Catalys) to obtain the plasmids: pGL3-3945, pGL3-1384, pGL3-1079, pGL3-316 and pGL3-200. Another plasmid was constructed, derived from the pGL3-1079 and containing a mutated Cx36 CRE. The mutation was achieved using the QuikChange® Site-Directed Mutagenesis Kit (Stratagene Europe) with the following primer: 5'-GACCTGGCGTAATGCAGGCGGAGACT-3' (underlined amino acids indicate mutated residues. Plasmid constructs were verified by DNA sequencing. The sequence of the human Cx36 promoter fragment (bases 3945/2046; numbering from the translational start site) was submitted to GenBankTM as an update of the previously identified sequence corresponding to a fragment of 2045 bp of the human Cx36 promoter [GenBank accession number AY341000 (Martin et al., 2003
)].
Transient transfection and luciferase assays
INS-1 cells were transiently transfected using the liposome-mediated TRANSFAST reagent (Catalys) at a DNA:lipid ratio of 1:1 in RPMI 1640 according to manufacturer's instructions. After transfection, cells were incubated for 36 hours at 2 mM or 20 mM glucose before harvesting with 100 µl passive lysis buffer (Catalys). Using the Dual-Luciferase reporter assay system (Catalys), a 50 µl sample of the lysates was assayed for luciferase activities in a Turner TD-20/20 Luminometer. Promoter activity was normalized by co-transfection with pRLSV40renilla.
Electrophoretic mobility shift assay
Preparation of nuclear extracts from INS-1 cells and gel-shift analysis were performed as described previously (Martin et al., 2003). For electrophoretic-mobility-shift assay (EMSA), the following double-stranded DNA probes were prepared using oligonucleotides corresponding to the human and rodent Cx36 CRE sequences: sense, 5'-GACCTGGCGTGACGCAGGCGGAGACT-3'; and antisense, 5'-AGTCTCCGCCTGCGTCACGCCAGGTC-3'. For non-specific competition experiments, the following mutant CRE sequences were used: sense, 5'-GACCTGGCGTAATGCAGGCGGAGACT-3'; and antisense, 5'-AGTCTCCGCCTGCATTACGCCAGGTC-3' (underlined amino acids indicate mutated residues. The double-stranded DNA probes were labeled with (
32P)-dCTP using the Klenow fragment of DNA polymerase I (Roche Diagnostic) and purified on microspin S300 HR columns (Amersham Bioscience Europe). 17 fmol 32P-labeled double-stranded DNA probes were incubated with 2 µg poly(dI-dC) (Amersham Bioscience Europe) in binding buffer (20 mM HEPES, pH 7.9, 50 mM KCl, 1 mM EDTA, 1 mM dithiothreitol, 0.25 mg ml-1 BSA, 3% glycerol). Equal amounts of nuclear protein (5 µg) were added and the mixture was incubated for 30 minutes at room temperature. For the supershift analysis, nuclear extract were previously pre-incubated for 10 minutes at room temperature with 1 µg antibody against: CRE-modulator protein 1 (CREM-1) (sc-440, Santa Cruz Biotechnology, LabForce, Nunningen, Switzerland); phosphorylated CRE-binding protein (phospho-CREB) (06-519, Upstate Biotechnology, Lucerne, Switzerland); activating transcription factor 3 (ATF-3) (sc-188, Santa Cruz Biotechnology); CCAAT/enhancer-binding protein ß (C/EBPß) (sc-746, Santa Cruz Biotechnology); or RE-1-silencing transcription factor (REST) (Martin et al., 2003
). In the competition study, unlabeled specific double-stranded DNA competitors (100-fold excess) were added into the reaction mixtures before incubation. Finally, the samples were resolved on a non-denaturing polyacrylamide gel (4% acrylamide 19:1, 0.5 x Tris-borate/EDTA), dried and subjected to autoradiography.
Statistical analysis
Data were expressed as means ± s.e.m. Differences between means were assessed using Student's t test. Statistical significance was defined at a value of P<0.05 (*), P<0.01 (**) and P<0.001 (***).
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Results |
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To gain insight into the mode of action of glucose on Cx36 expression, we tested the effects of several glucose analogs, nutrient stimuli and pharmacological agents. L-Glucose, an analog of glucose that cannot enter the cell, had no effect on Cx36 expression; neither had 3-O-methyl-D-glucose, a glucose analog that rapidly enters the ß-cell via the glucose transporter GLUT2 but is not metabolized (Fig. 3). Leucine (which enters the Krebs cycle at the mitochondria level) and glucosamine [a specific substrate for the hexosamine synthesis pathway (Yoshikawa et al., 2002)] were also unable to reduce Cx36 levels. By contrast, 2-deoxy-D-glucose, which is phosphorylated by glucokinase (Km 55 mM vs 10 mM for glucose) but poorly metabolized in the glycolytic or pentose-phosphate pathway (Girard et al., 1997
), induced a 50% decrease in Cx36 protein levels (70% for D-glucose). Taken together, these results provide evidence that glycolytic steps beyond the initial phosphorylation of glucose are not required to repress Cx36 expression.
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Measurement of the cAMP content of INS-1 revealed a 30% increase between cAMP levels in cells cultured for 24 hours at 2 mM or 20 mM glucose (Fig. 6). This effect was not inhibited by nifedipine and was therefore not mediated by Ca2+ influx. This result demonstrates the ability of glucose to stimulate the cAMP-PKA pathway independently of Ca2+ entry. As a positive control, forskolin induced a twofold increase in cAMP content regardless of the glucose concentration.
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Effect of glucose on Cx36 promoter activity
Using specific human Cx36 primers, we PCR amplified and sequenced a 3945 bp fragment of the human Cx36 promoter, and subcloned it in front of a reporter gene encoding luciferase (Fig. 7A). To evaluate the minimal region responsible for glucose responsiveness, five constructs consisting of full-length and 5'-deleted fragments of the isolated human Cx36 promoter were transiently transfected in INS-1 cells incubated with 2 mM or 20 mM glucose (Fig. 7A). These constructs drove high transcriptional activity compared with the pGL3 basic vector (basal activity). Apart from pGL3-316 and the pGL3-200, shifting the glucose concentration from 2 mM to 20 mM caused a 30-40% decrease in luciferase activity. These data suggest that putative glucose-responsive elements are located within the 1079 to 316 fragment of the human Cx36 promoter. We have previously demonstrated (Martin et al., 2003) that this region contains a functional repressive motif called neuron-restrictive silencing element (NRSE) that binds the repressor REST, which is not expressed in unstimulated ß-cells. Northern and western-blot analysis of REST expression revealed that glucose did not induce the expression of REST in INS-1 cells (data not shown), indicating that glucose-induced Cx36 downregulation is not caused by the repressor REST.
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Bioinformatic analysis (http://www.genomatix.de/) of this region failed to identify any glucose-responsive element (GlRE) or carbohydrate-responsive element (ChoRE) (Girard et al., 1997). However, it revealed the presence between bases 566 and 556 of a putative CRE, which is the known target motif for the activated cAMP-PKA pathway. Sequence alignment (Fig. 7B) of functional CREs (Dumonteil and Philippe, 1996
) with human and rodent Cx36 promoter fragments revealed that this motif is highly conserved and corresponds to a partial consensus CRE. To investigate the involvement of this motif in glucose-induced Cx36 downregulation, we generated a pGL3-1079 construct containing a mutated CRE (pGL3-1079m) (Fig. 7B). The promoter of this plasmid did not respond to glucose, indicating that the Cx36 CRE is functional and required for glucose-induced Cx36 downregulation. Using a Cx36 CRE probe and nuclear extracts from INS-1 cells, EMSAs revealed the presence of two specific protein/DNA-binding complexes C1 and C2 (Fig. 8, lanes 2,5) when compared with the free probe (lane 1). EMSAs using the consensus CRE (Fig. 7B) displayed a similar pattern of interactions (data not shown). Competition assays performed using 100 x excess of cold Cx36 CRE (Fig. 8, lanes 3,6) totally extinguished the C1 complex and decreased the C2 complex. Competition using a mutated CRE (Fig. 7B) had no effect on the binding profile (Fig. 8, lanes 4,7). Nuclear extracts prepared from cells incubated in a medium containing a high glucose concentration showed an enhanced formation of the two protein-DNA complexes (Fig. 8, lane 5). Moreover, in the presence of a low glucose concentration, cAMP content elevation by forskolin resulted in increased appearance of these complexes (Fig. 8, lane 8), whereas these were decreased in presence of the PKA inhibitor H89 and a high glucose concentration (Fig. 8, lane 9).
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Discussion |
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Considering the various effects of different glucose analogs that are phosphorylated or not by glucokinase and the lack of effect of other secretagogues, our results indicate that glucose-induced CX36 downregulation shares many characteristics with those previously observed for the glucose modulation of the genes encoding liver-type pyruvate kinase (Marie et al., 1983), ACC (Brun et al., 1993
) and PPAR
(Roduit et al., 2000
). These similarities suggest that an analogous metabolic intermediate, possibly glucose-6-phosphate, mediates the action of glucose on the expression of its target genes (Scott et al., 1998
).
Glucose elicits its better-known molecular actions on insulin-secreting cells via cellular uptake and mitochondrial metabolism, increased ATP/ADP ratio, closure of K+/ATP channels and calcium influx via VDCCs (Maechler and Wollheim, 2001). The fact that none of these events were implicated in glucose-induced Cx36 downregulation confirmed the hypothesis that glucose metabolism beyond phosphorylation by glucokinase is not mandatory to inhibit expression of Cx36 and that the classical glucose-induced mechanism of insulin secretion is not involved in this regulation.
We further analysed two different transduction pathways, the PKC and the cAMP-PKA pathways, that have been shown to be implicated in glucose-induced gene regulation in ß-cells (Arnette et al., 2003; Lawrence et al., 2002
). Downregulation of PKC by PMA (Seissler et al., 2000
) or inhibition by PD98059 of the MEK1/2 kinases, which can be activated by PKC (Gutkind, 1998
), both failed to block the effect of glucose. These results demonstrate that the PKC signaling pathway is not involved in glucose-induced Cx36 repression. By contrast, forskolin (a strong activator of adenylate cyclase) induced a decrease in Cx36 levels. Although forskolin (in the presence of low or high glucose concentration) stimulated a larger synthesis of cAMP than glucose (Fig. 6), it was unable to induce a further decrease in Cx36 expression levels (Fig. 5). Several recent studies indicate that elevation of the internal concentration of cAMP ([cAMP]i) occurs in discrete microdomains and that each PKA substrate would have its own anchored pool of PKA and its own local gradient of cAMP (Tasken and Aandahl, 2004
). Thus, the large amount of cAMP produced in response to forskolin treatment might not be fully available to the specific cAMP-PKA pathway involved in Cx36 downregulation. Previous work has indicated that glucose induces [cAMP]i elevation in INS-1 cells through an upstream increase of the cytosolic Ca2+ concentration (Briaud et al., 2003
). Here, we demonstrated that long-term (24 hour) exposure to 20 mM glucose increased the cAMP content of INS-1 cells independently of Ca2+ entry. However, we cannot rule out the possibility that glucose could increase [Ca2+]i independently of Ca2+ entry by mobilizing the intracellular Ca2+ pool. Nevertheless, our results indicate that cAMP could mediate the impact of glucose on Cx36 expression. cAMP exerts most of its effects by activating PKA and the role of the PKA in glucose-dependent signaling pathways is well documented (Vaulont et al., 2000
). In the presence of H89, an inhibitor of PKA, the effects of glucose or forskolin on Cx36 expression levels were abolished. Moreover, forskolin did not synergize with glucose to decrease Cx36 levels. Taken together, these data suggest that, in INS-1 cells, glucose induces the accumulation of cAMP, leading to the release of the active catalytic subunit of PKA which, in turn, phosphorylates a range of substrates.
Transient transfection analysis indicated that glucose-induced Cx36 downregulation requires the presence of a CRE 550 bp upstream of the translational start site of the Cx36 gene. Sequence alignment (Fig. 6B) of the CX36 CRE with functional insulin CREs (Dumonteil and Philippe, 1996) highlighted the fact that, even if the Cx36 CRE is not a perfect consensus CRE sequence (TGACGTCA), it contains the highly conserved core TGACG that is found in many functional CREs (Manna et al., 2002
; Sassone-Corsi, 1995
). In this study, human Cx36 promoter constructs were transiently transfected in rat insulin-secreting cells. However, we have shown in the past that rodent and human Cx36 promoter sequences were highly homologous in the region studied (Martin et al., 2003
). Thus, our results might imply that a similar mechanism of regulation could occur in human and rodents.
CREs are the main DNA targets of a large family of PKA-activated basic leucine-zipper (bZIP) CRE-binding factors including CREB, CREMs and ATFs. These factors are characterized by multiple alternatively spliced forms and some lack transactivation domains and hence function as transcription suppressors (Habener et al., 1995; Hai and Hartman, 2001
). Previous studies have indicated that the transcription of genes encoding insulin and somatostatin is modulated by PKA through CRE-binding proteins (Chepurny et al., 2002
; Montminy et al., 1996
). Interestingly, it has been shown that, in rat islets, glucose induces the overexpression of CREM-17x and ICER, two repressive isoforms of CREM (Chepurny et al., 2002
; Zhou et al., 2003
). Recently, it has also been demonstrated that, in MIN6 cells exposed to 25 mM glucose for 24 hours, total CREB protein levels were decreased by 50% (Costes et al., 2004
), reinforcing the idea that long-term exposure to elevated glucose concentrations leads to the accumulation of repressive isoforms of the CRE-binding protein family.
Using EMSAs, we observed that the level of binding to the Cx36 CRE was increased by glucose or forskolin. Supershift analysis showed that the repressor CREM-1 binds to the Cx36 CRE, whereas ATF3 and C/EBPß, two factors suspected to bind to CREs (Servillo et al., 2002), did not. Moreover, this binding was increased in presence of a high glucose concentration, suggesting that glucose enhances the formation of a repressive complex on the Cx36 CRE. We also demonstrated that glucose increases the binding of the PKA-activated form of CREM (phosphorylated on Ser117) or CREB (phosphorylated on Ser133) (Servillo et al., 2002
). Taken together, our data suggest that glucose activates, through the release of active PKA via cAMP accumulation, the activation of a CRE-binding factor, probably a repressive isoform of CREM, which might be part of a repressive complex binding to the Cx36 CRE. Surprisingly, the C2 complex did not interact with the CRE-binding proteins we tested. It has been demonstrated that active PKA regulates additional proteins (like the CREB-binding protein CBP) that are required for recruitment of the transcriptional apparatus to cAMP-responsive genes (Brindle et al., 1995
). Thus, one could hypothesis that the C2 complex is formed by partners of the CRE binding proteins involved in a repressive complex contributing to glucose-induced CX36 repression. Further studies remain to be carried out to identify the exact isoform(s) involved in this regulation and whether this regulation is merely due to the activation of a repressor or whether it also involves modifications in the expression levels of these factors.
These data provide the first evidences of a regulation of Cx36 by glucose in ß-cells and demonstrate a mechanism whereby pathophysiological conditions of glucose stimulation (20 mM glucose for 24 hours) modulate endogenous Cx36 levels. Glucose-induced transcriptional downregulation of Cx36 was dependent on an upstream release of the active form of PKA through the elevation of [cAMP]i. In view of the complexity of the transcription machinery binding to CREs, it is most likely that PKA phosphorylates and/or activates several effectors, including the repressive isoform CREM-1, that lead to the formation of a complex that binds on the Cx36 CRE, inhibiting Cx36 gene expression.
Considering the fact that adequate levels of Cx36 are crucial for proper ß-cell function (Caton et al., 2003; Le Gurun et al., 2003
), modulation of endogenous Cx36 levels could result in altered insulin secretion. Thus, Cx36 might be a potential candidate for participating in the impaired glucose-induced insulin secretion observed during the glucose desensitization and/or early glucotoxicity phenomena.
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Acknowledgments |
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