Abstract
Type 2 diabetes (T2D) is characterized by β cell dysfunction and loss. Single nucleotide polymorphisms in the T-cell factor 7-like 2 (TCF7L2) gene, associated with T2D by genome-wide association studies, lead to impaired β cell function. While deletion of the homologous murine Tcf7l2 gene throughout the developing pancreas leads to impaired glucose tolerance, deletion in the β cell in adult mice reportedly has more modest effects. To inactivate Tcf7l2 highly selectively in β cells from the earliest expression of the Ins1 gene (∼E11.5) we have therefore used a Cre recombinase introduced at the Ins1 locus. Tcfl2fl/fl::Ins1Cre mice display impaired oral and intraperitoneal glucose tolerance by 8 and 16 weeks, respectively, and defective responses to the GLP-1 analogue liraglutide at 8 weeks. Tcfl2fl/fl::Ins1Cre islets displayed defective glucose- and GLP-1-stimulated insulin secretion and the expression of both the Ins2 (∼20%) and Glp1r (∼40%) genes were significantly reduced. Glucose- and GLP-1-induced intracellular free Ca2+ increases, and connectivity between individual β cells, were both lowered by Tcf7l2 deletion in islets from mice maintained on a high (60%) fat diet. Finally, analysis by optical projection tomography revealed ∼30% decrease in β cell mass in pancreata from Tcfl2fl/fl::Ins1Cre mice. These data demonstrate that Tcf7l2 plays a cell autonomous role in the control of β cell function and mass, serving as an important regulator of gene expression and islet cell coordination. The possible relevance of these findings for the action of TCF7L2 polymorphisms associated with Type 2 diabetes in man is discussed.
Introduction
A considerable body of evidence suggests there is a strong hereditary component to type 2 diabetes (T2D) (1–3). Indeed, genome-wide association studies (GWAS) have now identified over 90 loci that are associated with T2D risk (reviewed in 4). Most of the identified single nucleotide polymorphisms (SNP) associated with T2D appear to affect β cell mass or function (5). However, most of these are in intronic or intergenic regions, making it difficult to identify the causal gene(s) and thus the impact of the identified SNP(s) at the molecular and cellular level (6).
Recently, much effort has been devoted to elucidating how the T2D-associated SNP rs7903146, which lies in intron 3 of the T-cell factor 7 like-2 (TCF7L2) gene, may lead to increased risk of diabetes. First described in Icelandic, Danish and US cohorts (7) SNP rs7903146 is presently the most strongly associated of the GWAS-identified variants with T2D (7–10) and is also associated with latent autoimmune diabetes in adults (11). Available clinical evidence points to an action of the risk alleles to impair insulin secretion in man with little, or a slightly protective effect, on insulin action (7–19).
TCF7L2 is a member of the TCF family of transcription factors involved in the control of cell growth and signalling downstream of wingless-type MMTV integration site family (Wnt) receptors (20) and was previously best known for its association with prostate and colon cancer development (21,22). Activation of the Wnt pathway leads to release of catenin from an inhibitory complex and its translocation to the nucleus, where it binds TCF7L2 and other related TCF factors (23). The function of this transcriptional complex is context dependent, i.e. it may act as either a transcriptional activator or repressor (5,23). In the pancreas, TCF7L2 and the Wnt signalling pathway are essential for proliferation of the pancreatic epithelium (24) and enhanced Wnt signalling has been shown to lead to islet proliferation (25). While loss of β-catenin signalling leads to pancreatic hypoplasia (26), stabilization of β-catenin results in the formation of large pancreatic tumours (27).
Studies from our own laboratory and others' have shown that silencing of Tcf7l2 gene expression in clonal cell lines (28) and primary islets (28,29) leads to increased apoptosis and impaired β cell function. Moreover, LoxP-mediated deletion specifically in the pancreas using a PDX1.Cre (30), led to glucose intolerance and impaired β cell mass on a high fat diet. On the other hand, a recent report (31) indicated that whereas deletion in the liver led to lowered hepatic glucose output, consistent with earlier findings of perinatal mortality in global Tcf7l2 null mice (32), deletion in the β cell in adult mice using a tamoxifen-inducible rat insulin promoter 2-driven (RIP2.Cre-ERT2) deleter strain exerted no apparent effect on glucose homeostasis. The authors therefore concluded that changes in Tcf7l2 expression in the β cell in man are unlikely to contribute to diabetes risk. However, the latter studies were limited to the examination of relatively young (<12 weeks old) mice maintained on a normal chow diet. Moreover, deletion in adults precluded examination of the effects on β cell proliferation during early post-natal growth. Finally, it was unclear in these studies whether Tcf7l2 expression was affected in the hypothalamus of the resulting KO mice, as might be expected using the Pdx1.Cre line (33).
Gene expression analysis following Tcf7l2 deletion or silencing revealed changes in the expression of a number of genes in mouse pancreatic islets, including that encoding the GLP-1 receptor (Glp1r; (15,28,30,34). Correspondingly, it has previously been reported that TCF7L2 may mediate GLP-1-induced β cell proliferation (35). Since GLP-1 has also been implicated in β cell survival, the increased incidence of apoptosis in TCF7L2-silenced islets (29,36), and in individuals carrying the risk variants of TCF7L2 (15), are both consistent with lowered GLP-1 signalling (15,36). Supporting this view is the decrease in β cell mass in high fat-fed, pancreas-specific Tcf7l2 null mice (30) and in mice over-expressing a dominant negative form of Tcf7l2 in β cells (37). Thus, the diminished insulinotropic effect of GLP-1 in islets lacking Tcf7l2 activity seems likely to be due, at least in part, to a lack of cognate receptors on the cell surface (28,30,37). Diminished brain GLP-1 signalling in mice over-expressing a dominant negative form of Tcf7l2 was also reported to lead to impaired glucose tolerance and insulin sensitivity when mice were administered a high fat diet (38).
While the above evidence suggests that loss of Tcf7l2 from the β cell is likely to impair insulin production, and hence increase T2D risk, adult Tcf7l2 knockout mice show reduced hepatic glucose production during fasting and improved glucose homeostasis when maintained on a high fat diet (31); loss of Tcf7l2 signalling in the liver is associated with lowered expression of genes involved in glucose metabolism in this tissue (31,39). Such data together indicate that lowering Tcf7l2 activity, at least in the liver, may be beneficial in metabolic diseases. Moreover, it has also been reported that transgenic mice over-expressing TCF7L2 systemically have impaired glucose homeostasis, among other physiological anomalies (40). The latter data are consistent with those from Gaulton et al. (41), indicating that chromatin at the TCF7L2 gene is in an islet-specific ‘open’ conformation, and that in β cell lines the enhancer activity of the at-risk T-allele is elevated compared with the C-allele. Moreover, Savic et al. (42) have identified tissue-specific enhancer activity within the association interval of rs7903146 which may lead to the generation of different splice variants of TCF7L2, potentially leading to different functional effects in different tissues. Thus, the apparent discordance between the metabolic phenotype of the various mouse models could be partly due to the involvement of TCF7L2 in glucose homeostasis in more than one tissue, potentially in opposing directions. Further complicating the potential actions of genomic risk loci, TCF7L2 is subject to tissue-specific alternative splicing (43–46).
Given the existing controversy in the literature over the relative importance of Tcf7l2 in the β cell versus the liver and other tissues (30,31), and the contributions of extrapancreatic tissues to the action of risk variants on diabetes risk (47), the present study was designed to achieve highly selective deletion of Tcf7l2 in the β cell, from the earliest possible stages in the establishment of a definitive β cell status, i.e. expression of the insulin gene. To this end we have used a highly β cell selective Cre recombinase, based on expression of the enzyme from the Ins1 locus. In contrast to the use of Pdx1- (30) or Pdx1ER-based Cres (31) this strategy allows recombination highly selectively and early in the development of individual β cells, without the complications of deletion in other tissues including the brain (33,48).
We show (a) that β-cell deficient Tcf7l2 mice show impaired insulin release and glucose homeostasis, particularly in response to oral glucose challenge; (b) when examined in intact islets, an unsuspected action is observed on both intracellular calcium signalling and cell–cell communication, likely to contribute to the deranged insulin secretion in vivo. These findings provide further evidence for the β-cell autonomous role of Tcf7l2, and imply that this factor maybe particularly important during expansion of these cells in the post-natal period or during adaptation to metabolic stresses including high fat diet
Results
Abnormal glucose tolerance and insulin secretion in β cell selective Tcf7l2 null mice
In the present study, we used Ins1.Cre mice (48) (B. Thorens and J. Ferrer, manuscript in preparation) to effect highly selective and early (∼E11.5) (49,50) deletion of Tcf7l2 in β cells, based on Cre expression driven by the Ins1 gene (33,51). The resultant Tcf7l2 null (Tcf7l2fl/fl::Ins1.Cre+) mice were born at the expected Mendelian ratio and gained weight similarly to wild-type mice (Tcf7l2fl/fl::Ins1.Cre−) when maintained on regular chow (Supplementary Material, Fig. S1).
As shown in Figure 1A–D, Tcf7l2fl/fl::Ins1.Cre+ mice developed impaired intraperitoneal glucose tolerance in an age-dependent manner, displaying significant impairments from 16 weeks (increase in AUC of 13.6 ± 2.8%, n = 6 mice per genotype, P < 0.05). Impaired oral glucose tolerance (increase in AUC of 10.6 ± 1.3%, n = 6, P < 0.05) was apparent in younger animals (from 8 weeks; Fig. 1E). Consistent with a more marked effect via altered incretin responses, the glucose excursion prompted by elevated glucose (1 g/kg) plus the GLP-1 analogue liraglutide (200 µg/kg) (52) was particularly strongly affected by Tcf7l2 deletion (Fig. 1F). These changes were not associated with any alteration in sensitivity to intraperitoneal insulin (Fig. 1G).
Glucose and insulin tolerance in Tcf7l2fl/fl::Ins1.Cre+mice. Intraperitoneal glucose tolerance was assessed at 8 (A), 12 (B), 16 (C) and 20 (D) weeks of age in Tcf7l2fl/fl::Ins1.Cre+(blue) and Tcf7l2fl/fl::Ins1.Cre− (black dotted) mice maintained on a normal chow diet (ND), and Tcf7l2fl/fl::Ins1.Cre+(red) and Tcf7l2fl/fl::Ins1.Cre− (black) maintained on a high fat (HFD; 60%) diet. Glucose tolerance and area under the curve (inset) are shown. Oral glucose tolerance was assessed at 8 weeks in mice maintained on a normal chow diet (E). Intraperitoneal glucose (1 g/kg) tolerance and response to liraglutide (200 µg/kg) treatment (F) and insulin (0.75 units/kg) tolerance (G) was assessed at 20 weeks in mice maintained on a normal chow diet. (H) Fasting plasma glucagon concentration was measured on mice fed on a HFD (see Materials and Methods) n = 7–10 mice; *P ≤ 0.05.
To determine whether the imposition of a metabolic stress may affect the glucose intolerance observed in Tcf7l2fl/fl::Ins1.Cre+mice, animals were maintained for the indicated times on a high fat (∼60% total calories) diet. Null animals under these conditions gained weight similarly to wildtype littermates, albeit with a small increase versus controls apparent from 20 weeks (Supplementary Material, Fig. S1). While glucose intolerance was not apparent at 12 weeks (Fig. 1B), the dysglycemia observed at 16 and 20 weeks was further exaggerated compared with that apparent in animals maintained on regular chow (Fig. 1C and D). Insulin tolerance did not differ between genotypes (Fig. 1G), and fasting glucagon levels were identical (Fig. 1H). Nonetheless, in vivo insulin release prompted by IP injection of 1 g/kg glucose was markedly impaired in the null mice (Fig. 2A).
Tcf7l2 deletion impairs glucose and GLP1-stimulated insulin secretion from isolated islets. (A) Plasma insulin following intraperitoneal injection of glucose from 20-week-old mice that had been maintained on a high fat diet was measured as described in Materials and Methods. (B) Real-time quantitative PCR analysis was performed on islets from 20-weeks-old mice that had been maintained on a normal chow diet. n = 7–10 mice; *P ≤ 0.05. (C and D) Insulin secretion as assessed in isolated islets from 20-week old Tcf7l2fl/fl::Ins1.Cre+(red) and littermate Tcf7l2fl/fl::Ins1.Cre− (black) mice on normal chow (C) or high fat diet (D). n = 5 mice per genotype; *P ≤ 0.05; **P ≤ 0.01.
Confirming recombination in the β cell compartment, qRT-PCR revealed ∼75% decrease in the expression of Tcf7l2 in the islet (Fig. 2B). This was associated with decreased expression of both Ins2 and Glp1r (Fig. 2B).
Consistent with the impaired glucose tolerance observed in vivo, islets of Langerhans isolated from Tcf7l2fl/fl::Ins1.Cre+ mice at 20 weeks displayed impaired glucose (P < 0.05) and GLP-1-(P < 0.05) stimulated insulin secretion versus islets from control Cre- mice (Fig. 2C). These effects were even more marked in islets extracted from high fat-diet treated animals (Fig. 2D), where the effects of GLP-1 to potentiate those of 17 mm glucose were completely abolished.
Effects of Tcf7l2 elimination on glucose and GLP-1-induced intracellular free Ca2+ dynamics and β cell connectivity
In healthy β cells, high glucose induces elevations in intracellular ATP/ADP ratio, the closure of ATP-sensitive K+ channels and the opening of voltage-gated Ca2+ channels to increase intracellular (cytosolic) free calcium ([Ca2+]cyt) (53,54). To further explore the mechanisms underlying the altered secretory responses in Tcf7l2 null β cells we therefore determined whether glucose-induced [Ca2+]cyt dynamics may be affected. Examined in whole islets from normal diet-fed mice by functional multicellular imaging (55–57), we observed largely unaltered responses to glucose of individual β cells after Tcf7l2 elimination (Fig. 3A and C). In contrast, those in response to GLP-1 were significantly impaired, with the proportion of GLP-1-responsive cells markedly reduced (Fig. 3C). On the other hand, after maintenance on a high fat diet, both the amplitude of the [Ca2+]cyt response to high glucose (Fig. 3B), and the proportion of cells responding to GLP-1 (Fig. 3D), were reduced in Tcf7l2fl/fl::Ins1.Cre+ mice versus controls.
Impact of Tcf7l2 deletion on intra- and inter-cellular Ca2+ dynamics. (A and C) Responses to glucose (17 mm; G17) or GLP-1 (100 nm) of β cells within intact islets of Tcf7l2fl/fl::Ins1.Cre+(red) and Tcf7l2fl/fl::Ins1.Cre− (black) mice maintained on a normal chow diet. (B and D) as for (A and C) but for islets from animals maintained for 12 weeks on a 60% fat diet. Correlation analysis (55,56) for islets from mice maintained on (E) normal diet and (F) high fat diet, and (G) quantitation of changes in typical islets from Tcf7l2fl/fl::Ins1.Cre+ and Tcf7l2fl/fl::Ins1.Cre− mouse islets as indicated.
Changes in β cell ‘connectivity’, i.e. the degree to which β cells across the islet syncytium mount a coordinated (synchronized) response to stimulation (56), are associated with impaired insulin secretion (55). We have also recently demonstrated that human β cells depleted for another GWAS gene for T2D, adenylate cyclase V (ADCY5) (57), show impaired cellular connectivity. Whereas Tcf7l2 elimination exerted no effect on the number of connected cell pairs in islets from normal chow-fed mice (Fig. 3E), inter-cellular connectivity was significant reduced by loss of this transcription factor from islets maintained on a high fat diet (Fig. 3F and G).
Effects of Tcf7l2 elimination on β cell expansion in response to high fat diet
To determine whether alterations in β (or α) cell mass also might contribute to impaired insulin production in vivo after Tcf7l2 elimination, pancreata from 20-week-old Tcf7l2fl/fl::Ins1.Cre+mice that had been maintained on a HFD for 12 weeks were stained for insulin and glucagon, respectively, and analyzed by optical projection tomography (OPT). Cre+ islets displayed a markedly (31.7%, P < 0.05; n = 4 mice per genotype) decreased β cell mass, but normal α-cell mass, compared with littermate controls (Fig. 4), resulting in an overall decrease in β to α cell ratio. The number of smaller insulin-stained islets was particularly sharply decreased in TCF7L2fl/fl::Ins1.Cre+ mouse islets (Fig. 4B).
Impact of Tcf7l2 deletion on β and α cell mass. (A) Representative 3D images from OPT (see Material and Methods) of Tcf7l2fl/fl::Ins1.Cre+ and Tcf7l2fl/fl::Ins1.Cre− pancreata labelled with anti-insulin and anti-glucagon primary antibodies, and revealed using AlexaFluor 568 and 680, respectively. Right hand-most panels are overlaid with the autofluorescence signal revealing the pancreatic ductal system. Quantification of β (B), α (C) and (D) β/α cell mass from Tcf7l2fl/fl::Ins1.Cre+(red) and Tcf7l2fl/fl::Ins1.Cre− (black) knockout mice pancreata from 20-week-old mice that had been maintained on high fat diet. Quantification was conducted using Volocity software (Invitrogen), N = 4 mice per genotype.
Discussion
The chief goal of the present studies was to reassess the role in the β cell of the Wnt signalling dependent transcription factor TCF7L2. Using a Cre that is highly selective for the mature β cell (48) (B. Thorens and J. Ferrer unpublished), our findings show firstly that this factor is required for (a) the normal function of these cells, and (b) their expansion under a situation of metabolic stress. Moreover, we provide novel insights into the role of Tcf7l2 in the control of intracellular Ca2+ dynamics and β cell–β cell communication. The latter result was unexpected given previous findings that [Ca2+]cyt changes were apparently unaffected by manipulation of Tcf7l2 expression (28). However, the earlier studies were performed using isolated β cells (or small clusters of cells) rather than intact islets as examined here, where complex inter-cellular cross-talk is likely to overlay cell-intrinsic responses to stimulation. Nonetheless, the present results are consistent with very recent findings (58) showing decreased expression of the voltage-gated calcium channel subunits including Cacna1d in rat insulinoma-derived INS1 β cells silenced for Tcf7l2.
How might TCF7L2 control β cell connectivity? While the disruption of connectivity in earlier studies, e.g. after exposure to lipotoxic conditions (55), could be ascribed to impairments in the expression of the gap junction protein connexin 36 (Gjd2), we were unable to detect changes in Gjd2 mRNA in Tcf7l2 null islets in the present study (Fig. 2B), consistent with an earlier study investigating the role of Wnt signalling in the expression of other gap junction proteins (59). Changes in level or post-translational modifications (60) of this protein nonetheless remain a possibility as, of course do changes in the expression of other genes.
There is gathering evidence to suggest that the effect of TCF7L2 is mediated by resistance to incretin treatment at the level of the β cell (15,16,61–63). The present studies provide further support for this view showing both marked alterations in the expression of the Glp1r gene in Tcf7l2 null islets (Fig. 2B), and impaired glucose-stimulated insulin secretion (Fig. 2C and D). Whether reduced numbers of these receptors on β cells also contributes to the apparent impairment in β cell expansion in the face of a high fat diet is unknown, but would seem worthy of future investigation.
A particularly significant finding of the present study was the appearance in Tcf7l2fl/fl::Ins1.Cre+ mice of glucose intolerance from 16 weeks onwards demonstrating that the appearance of a β cell phenotype is dependent on age or other stresses. Importantly, in recent studies (31), the effects of Tcf7l2 inactivation in the adult mouse β cell (using an alternative model in which exon 10, encoding the DNA-binding HMG box, was deleted) were not examined beyond 12 weeks of age, such that any effects later in life would have been missed. Of note, in the model described here, placing mice on a high fat diet increased the extent of the intolerance but did not bring forward its appearance substantially (Fig. 1).
Relevance of the present findings for understanding of the action of TCF7L2 T2D risk variants in man
We have previously speculated (6) that variants at rs7903146 and neighbouring SNPs may have differential effects on TCF7L2 expression the liver and on β cells as a result of differing splicing patterns in the two tissues. In particular, alternative splicing at the boundaries of exon 13, 13b and 14 leads to the loss of a ‘CRARF’ motif that appears to be selectively expressed in the β cell and susceptible to modulation by the risk T allele (34). Thus, a decrease in TCF7L2 activity at the protein level may be observed in islets from T-allele carriers despite increases in the overall levels of TCF7L2 transcripts. Thus, the expression of multiple Tcf7l2 alleles globally in mice (40), or forced inactivation of Tcf7l2 in the liver (31), with its consequent dramatic effect to impair hepatic glucose output, may be of limited relevance to the action of the human SNP. In contrast, the impact of lowered Tcf7l2 levels in the β cell, at least during the stresses imposed by aging or high fat feeding, may be more pertinent. Thus, as shown by the present studies, these are likely to act at the same time on the secretory activity of single β cells (28), the coordination of these cells within the islet (likely to further impair insulin output) (55), and finally on β cell mass. Nonetheless, further studies exploring in detail the relationship between Tcf7l2 action in different tissues would seem to be warranted.
On a final note, ‘mice are not men’ and that, given recent findings in relation to the consequences of Slc30a8 deletion (64,65), a certain degree of circumspection is required in transposing findings from one to the other. There is currently no compelling evidence, other than immediate genomic proximity, tying TCF7L2 to the T2D-associated variants, and it remains formally possible, though rather unlikely, that the GWAS signal is mediated via another gene. Our new study reinforces the evidence (though does not prove) that TCF7L2 is the causal gene at this locus.
Material and Methods
Materials
All general chemicals and tissue culture reagents were purchased from Sigma (Dorset, UK) or Invitrogen (Paisley, UK), unless otherwise stated in the text.
Animals
All in vivo procedures were approved by the UK Home Office according to the Animals (Scientific Procedures) Act 1986 and were performed at the Central Biomedical Service, Imperial College, London, UK Rodents were culled by cervical dislocation. Mice were housed at two to five animals per cage in a pathogen-free facility with a 12-h light–dark cycle. Animals were fed ad libitum with a standard mouse chow diet (Research Diet, New Brunswick, NJ) unless otherwise stated. For high fat diet treatment, mice were placed on a high fat diet at 8 weeks of age for 8 weeks (60% [wt/wt] fat content; Research Diet, New Brunswick, NJ, USA) prior to analysis. Mice were weighed weekly from eight weeks.
Generation and characterization of β cell-specific Tcf7l2 knockout mouse
Generation of mice carrying conditional knockout alleles of Tcf7l2 (Tcf7l2fl/fl) was as described in (30). All mouse strains were maintained on a C57BL/6 background. Tcf7l2fl/fl mice were crossed with mice expressing Cre recombinase under the control of the Insulin 1 promoter (Ins1.Cre mice; (48), J. Ferrer, B. Thorens, unpublished) to generate Tcf7l2 conditional knockout mice where exon 1 of the Tcf7l2 gene was removed selectively by Cre-mediated excision in pancreatic β cells (Tcf7l2fl/fl::ins1.Cre+). Mice were born at the expected Mendelian ratios with no obvious abnormalities. Genotyping was performed by PCR using DNA from ear biopsies. Ablation of Tcf7l2 gene expression from pancreatic islets was assessed by real-time quantitative PCR (qPCR) on islet RNA, as described below.
Oral and intraperitoneal glucose tolerance test, insulin tolerance test
Glucose tolerance was assessed by oral and intraperitoneal administration of glucose (1 g/kg). Responsiveness to incretin treatment was assessed by co-injection of liraglutide [200 µg/kg (66); Bachem, Bubendorf, Switzerland] with glucose during an intraperitoneal glucose tolerance test. Mice were fasted for 16 h, with water available ad libitum. Glucose tolerance tests were conducted at 09:00 on each experimental day. Intraperitoneal insulin tolerance (075 Units per kg) test was performed as described in (67).
Measurement of plasma hormones
Plasma glucagon from mice fasted for 16 h were measured using radioimmunoassay (Millipore, Watford, U.K.). Blood (200 µl) was removed by cardiac puncture from mice killed by cervical dislocation. Plasma was collected using high speed (2000 g, 5 min at 4°C) centrifugation in heparin-coated Microvette® tubes containing EDTA (Sarstedt, Leicester, U.K.) with added DPP IV inhibitor (100 µM; Millipore, Watford, UK). For measurement of plasma insulin following intraperitoneal injection of glucose, blood (100 µl) was removed from the tail vein at various times points and plasma collected as described above. Plasma glucagon and insulin was measured by radioimmunoassay (Millipore).
Quantitative real-time PCR analysis
Primers were designed using Primer Express 3.0 (ABI, CA, USA). Specificity for all primers was verified using BLAST (http://www.ncbi.nlm.nih.gov/blast/). RNA was extracted using Trizol (Invitrogen, UK). cDNA conversion was performed using High Capacity cDNA conversion kit (ABI, UK) after DNAse treatment (Ambion, TX, USA). Real-time PCR was performed on an ABI-Prism Fast 7500 device using powerSYBR reagent (ABI, UK). The primer sequences used were: Tcf7l2 (forward) TTCCCCCTTGACCTCCTAGTC, Tcf7l2 (reverse) GCACACGGTCAGTCCATGTT, Ins2 (forward) AGCCCTAAGTGATCCGCTACAA, Ins2 (reverse) CATGTTGAAACAATAACCTGGAAGA, Glp1r (forward) CCACGGTGTCCCTCTCAGA, Glp1r (reverse) ACTGCCGCCGGTATTCTCT, Gjd2 (forward) CCCAGTCTCTGTTTTATCACCTATTCT, Gjd2 (reverse) CGGCGTTCTCGCTGCTT.
Insulin secretion assay
Secreted insulin from groups of six pancreatic islets of Langerhans was measured by radioimmunoassay (Linco, MA, USA) as previously described (68,69).
Calcium imaging and correlation analysis
Calcium imaging and correlation analysis were performed as described in (55).
Optical projection tomography and calculations of relative α and β cell mass
Whole pancreatic OPT, to 19 µm resolution, was performed as previously described (67,70). Dual labelling for insulin and glucagon was performed using anti-insulin antibody (DAKO) and anti-glucagon antibody (Sigma) revealed using Alexa Fluor 568 and 680 (Invitrogen), respectively.
Statistical analysis
Values presented are the mean ± SEM for the number of observations indicated. Statistical significance and differences between means were assessed by a two-tailed Student's t test or one-way ANOVA with Bonferroni correction for multiple analyses. Linear correlations were calculated using regression analyses. Analysis was performed using Excel™, R, GraphPad Prism (GraphPad Software) and IgorPro.
Funding
G.D.S.X. thanks the European Foundation for the Study of Diabetes (EFSD) and Diabetes UK (13/0004672; Alec and Beryl Warren Award) for Project grants. G.A.R. thanks the MRC (UK) for Programme grant MR/J0003042/1, the BBSRC (UK) for a Project grant (BB/J015873/1), the Royal Society for a Wolfson Research Merit Award and the Wellcome Trust for a Senior Investigator Award (WT098424AIA). D.J.H. is a Diabetes UK R.D. Lawrence Fellow. The work leading to this publication has received support from the Innovative Medicines Initiative Joint Undertaking under grant agreement no. 155005 (IMIDIA), resources of which are composed of a financial contribution from the European Union′s Seventh Framework Programme (FP7/2007-2013) and EFPIA companies' in kind contribution (G.A.R.), and the Wellcome Trust (WT ISSF grant awarded to G.A.R. and P.M.F.). Funding to pay the Open Access publication charges for this article was provided by the Wellcome Trust.
Acknowledgements
We thank Mr Daniel Davidsson (Section of Cell Biology, Imperial College) and Dr Steven Rothery (Facility for Imaging by Light Microscopy, Imperial College) for their help with image analysis.
Conflict of Interest statement. None declared.
