OBJECTIVE

The purpose of this study was to evaluate the role of the S6K arm of mammalian target of rapamycin complex 1 (mTORC1) signaling in regulation of β-cell mass and function. Additionally, we aimed to delineate the importance of in vivo S6K activation in the regulation of insulin signaling and the extent to which alteration of insulin receptor substrate (IRS) signaling modulates β-cell mass and function.

RESEARCH DESIGN AND METHODS

The current experiments describe the phenotype of transgenic mice overexpressing a constitutively active form of S6K under the control of the rat insulin promoter.

RESULTS

Activation of S6K signaling in these mice improved insulin secretion in the absence of changes in β-cell mass. The lack of β-cell mass expansion resulted from decreased G1-S progression and increased apoptosis. This phenotype was associated with increased p16 and p27 and decreased Cdk2 levels. The changes in cell cycle were accompanied by diminished survival signals because of impaired IRS/Akt signaling.

CONCLUSIONS

This work defines the importance of S6K in regulation of β-cell cycle, cell size, function, and survival. These experiments also demonstrate that in vivo downregulation of IRS signaling by TORC1/S6K induces β-cell insulin resistance, and that this mechanism could explain some of the abnormalities that ultimately result in β-cell failure and diabetes in conditions of nutrient overload.

Pancreatic β-cells expand their function and mass in both physiologic and pathologic states of nutrient excess and increased insulin demand. Failure of β-cells to expand adequately in settings of increased insulin demand results in hyperglycemia and diabetes. The mechanisms involved in β-cell failure in diabetes are not well understood, but determining how glucose and fat overload lead to impaired β-cell mass and function is a key component for understanding the natural history of diabetes and generating pharmacologic agents to treat and prevent this disease.

The mammalian target of rapamycin (mTOR) signaling pathway integrates growth factors and nutrient signals and is essential for cell growth and proliferation (1,2). This pathway is negatively regulated by the activation of tuberous sclerosis complex TSC1/2 and AMP-activated protein kinase (AMPK) signaling pathways (3,,,7). The mTOR is part of two distinct complexes: mTORC1 and mTORC2. The mammalian TORC1 is sensitive to rapamycin and regulates protein translation modulation of ribosomal S6 kinase (S6K), eukaryote initiation factor 4E binding protein 1 (4E-BP1), and eukaryote initiation factor 4E (eIF4E) (8). The mTORC1 is composed of regulatory associated protein of mTOR (Raptor), mLst/GβL, deptor and proline-rich PKB/Akt substrate 40 kDa (PRAS40). The mTORC2 complex includes Lst8/GβL, deptor, rapamycin-insensitive companion of mTOR (Rictor), proline-rich protein 5 (PRR5), and stress-activated protein kinase-interacting protein-1 (mSIN) (9,10). The effects of mTORC1 signaling on cell growth, cell size, and cell cycle progression are mediated, at least in part, by phosphorylation of the downstream effectors S6K and 4E-BP1 (11). Activation of S6K by mTOR phosphorylates the ribosomal protein S6 (rpS6). The importance of S6K signaling in β-cells has been assessed in genetically modified models. Global S6K1 knockouts or mice with knockin at all five phosphorylatable serine residues of rpS6 exhibit decreased β-cell mass, impaired insulin secretion, and hyperglycemia (12,13). Moreover, S6K is important for insulinoma formation induced by activation of Akt signaling (14). A major limitation for understanding the role of S6K signaling in β-cells using S6K-deficient mice is the concomitant alteration in insulin sensitivity by negative feedback on insulin receptor substrate (IRS) proteins (15,17). In contrast, activation of mTORC1 signaling by conditional deletion of TSC2 in β-cells enhances β-cell mass as a result of increased proliferation and cell size (18,19). These experiments suggest that mTORC1/S6K signaling is an important regulator of β-cell mass, although the molecular mechanisms and downstream signaling pathways are not well characterized.

Growing evidence suggests that not only fat consumption, but also protein intake and an increase in plasma amino acid concentration, contribute to the development of glucose intolerance, insulin resistance, and type 2 diabetes (20,21). Recent findings demonstrate that S6K activation in states of nutrient overload modulates insulin sensitivity by negatively regulating IRS1 function under conditions of nutrient overload (15,17,22). In addition, the 4E-BP1/eIF4E signaling pathway regulates glucose metabolism by modulation of sensitivity to diet-induced obesity and insulin resistance (23). Although this evidence underscores the importance for mTOR/S6K activation in peripheral tissues as a central player in insulin resistance in nutrient overload, the consequences of activation of this pathway in pancreatic β-cells and the implication of the negative feedback inhibition on IRS signaling in vivo are unknown.

To study the role of S6K activation in β-cells, we developed transgenic mice overexpressing a constitutively active form of S6K in β-cells (S6KCARIP). S6KCARIP mice exhibited improved glucose tolerance because of an increase in insulin secretion and without changes in β-cell mass. The lack of β-cell expansion was characterized by a failure of β-cells to progress normally through the cell cycle and increased apoptosis. Interestingly, these alterations resulted, at least in part, by feedback inhibition on IRS1/2/Akt signaling and increased levels of p16 and p27. The current work defines the importance of the S6K arm activation of mTORC1 signaling in regulation of β-cell cycle, cell size, function, and survival. These experiments also demonstrate that in vivo downregulation of IRS signaling by TORC1/S6K reduces growth factor signaling, and this mechanism could explain some of the abnormalities that ultimately result in β-cell failure and diabetes in conditions of nutrient overload.

S6KCARIP mice have increased S6 kinase activity in islet β-cells.

To increase S6K signaling in β-cells, we inserted a rapamycin-resistant p70S6K Δ2–46/ΔCT104 (T412E) downstream of the rat insulin I promoter (S6KCARIP) (24). Three viable and fertile lines were obtained, and offspring from two founders with similar transgene expression and disturbances in glucose tolerance were studied. The current studies describe the phenotypic characterization of one of these lines. Transgene expression assessed by immunostaining for hemagglutinin (HA) showed cytoplasmic and nuclear staining in most of the β-cells (∼80–90%) from S6KCARIP mice (Fig. 1,A). Immunoblotting for HA also displayed expression of the transgene exclusively in S6KCARIP (Fig. 1,B). Transgene expression was 4.6-fold higher than that of endogenous S6K (P < 0.05). S6K activity measured by phosphorylation of rpS6 was increased in S6KCARIP mice (Fig. 1 C).

S6KCARIP mice exhibit improved glucose tolerance and enhanced insulin secretion.

Glucose levels in 6-h fasted S6KCARIP mice were lower than those of wild-type mice (Fig. 2,A). S6KCARIP mice exhibited higher insulin values than wild-type mice after 6-h fasting (Fig. 2,A). No difference in glucose was observed after overnight fasting (time 0; Fig. 2,B and C, and data not shown). Glucose tolerance test in 4-month-old S6KCARIP mice showed lower glucose levels at 30 and 60 min (Fig. 2,B). Improved glucose tolerance was observed in 4- and 18-month-old S6KCARIP mice (data not shown and Fig. 2,C), indicating that these mice were protected from the impaired glucose tolerance associated with aging (Fig. 2 C). No changes in insulin sensitivity were observed by insulin tolerance tests (data not shown).

Glucose-stimulated insulin secretion demonstrated comparable insulin values after overnight fasting in 4- and 18-month-old S6KCARIP and wild-type mice (Fig. 2,D and E). Insulin levels at 15 min after glucose injection were increased in 4- and 18-month-old S6KCARIP mice (Fig. 2,D and E). No difference between S6KCARIP mice and controls were observed after 30 min of glucose injection (Fig. 2,D and E). Static incubation of isolated islets demonstrated increased insulin levels in islets from S6KCARIP mice when exposed to 2 mmol/l glucose (Fig. 2,F). Insulin secretion was comparable after stimulation with 20 mmol/l glucose (Fig. 2,F). Measurements of ATP/ADP content in isolated islets showed that islets from S6KCARIP mice exhibited higher levels of ATP/ADP in 2 mmol/l glucose (Fig. 2 G). Similar ATP/ADP levels between wild-type and S6KCARIP were obtained with 20 mmol/l glucose.

Islet morphometry and analysis of cell size.

Immunofluorescence staining for insulin and non–β-cells showed that islet architecture was conserved in S6KCARIP mice (Fig. 3,A). Similar β-cell mass between S6KCARIP and wild-type mice β-cells was comparable at 6 and 18 months of age (Fig. 3,B and C). Islet size distribution between S6KCARIP and wild-type mice was unchanged (data not shown). Double staining for HA and insulin in dispersed islets from S6KCARIP and wild-type mice showed that β-cells from transgenic mice appeared to have increased in size (supplementary Fig. 1 in the online appendix available at http://diabetes.diabetesjournals.org/cgi/content/full/db09-0851/DC1). Cell size measurements in pancreatic sections stained for Glut2 and HA demonstrated a 50% increase in the size of β-cells expressing the transgene (Fig. 4,A and B, P < 0.05). The number of β-cells per islet was reduced in S6KCARIP mice, suggesting that islets from these mice exhibited fewer β-cells with increased cell size (Fig. 4 C, P < 0.05).

Assessment of proliferation and apoptosis in S6KCARIP and wild-type mice.

β-Cell proliferation assessed by Ki67 staining showed increased proliferative rate in S6KCARIP mice (Fig. 5,A). The increased proliferative rate with absence of changes in β-cell mass suggests that β-cells failed to complete the cell cycle or underwent programmed cell death. Since Ki67 is a marker for G1, G2, S, and M phases, we used bromodeoxyuridine (BrdU) and phospho-Histone-3 (pH3) to specifically assess cell cycle progression through the S and M phases, respectively. The rate of BrdU in β-cells was similar between S6KCARIP and wild-type mice, indicating that β-cells were not progressing to the S phase (Fig. 5,B). Also, no difference in the rate of pH3 in β-cells was observed between wild-type and S6KCARIP mice (data not shown). Assessment of β-cell apoptosis by cleaved caspase 3 staining showed a fourfold increase in apoptosis in S6KCARIP mice (Fig. 5,C). Similar increases in apoptosis in S6KCARIP mice were observed by using transferase-mediated dUTP nick-end labeling (TUNEL) assay (Fig. 5 D). The results of these experiments suggest that increased S6K activity in β-cells induced entry, but delayed completion of the cell cycle. In addition, these mice also exhibited increased apoptosis.

Alterations in cell cycle progression in S6KCARIP mice are associated with increased p27 and p16 levels.

Assessment of cell cycle components responsible for G1-S progression demonstrated that protein levels for Cyclin D1, D2, D3, E, and Cdk4 were similar in islets from S6KCARIP and wild-type mice (Fig. 6,A). In contrast, Cdk2 was reduced in islets from S6KCARIP mice (Fig. 6,A). Levels for p16, a major regulator of G1-S progression in β-cells, were increased in islets from S6KCARIP mice (Fig. 6,A). Assessment of the Cip/Kip inhibitors p21 and p27 showed that p27 levels were higher in S6KCARIP mice (Fig. 6,A). The number of β-cells with nuclear p27 was increased in S6KCARIP mice (Fig. 6 B).

Decreased IRS signaling in β-cells from S6KCARIP transgenics.

To determine whether islets from S6KCARIP mice exhibited decreased IRS/Akt signaling, we performed immunostaining for phospho-GSK3β. Marked reduction of phospho-GSK3β staining was observed in islets from S6KCARIP mice (Fig. 7,A). Levels for IRS1 and IRS2 were decreased by 50 and 40%, respectively, in islet lysates from S6KCARIP mice (Fig. 7,B, P < 0.05). Phosphorylation of IRS1 on Ser 307, one of the many S6K phosphorylation sites on IRS1, was increased in S6KCARIP mice (Fig. 7,B). The decreased IRS1 and IRS2 levels were associated with decreased levels of phospho-GSK3β and phospho-FoxO1 in islets from S6KCARIP mice (Fig. 7,B). As expected reduced Akt signaling also resulted in increased TSC2 levels in S6KCARIP mice (Fig. 7,B). We next assessed the alterations in IRS/Akt signaling after stimulation with insulin-like growth factor 1 (IGF1) (Fig. 7,C). Phosphorylation of Akt at Ser473 was unchanged in S6KCARIP mice (Fig. 7,C). S6KCARIP mice exhibited reduction of Akt phosphorylation at Thr308. The decreased phosphorylation of Akt at Thr308 resulted in reduced Akt activity, as demonstrated by phosphorylation of GSK3β (Fig. 7 C). Interestingly, phosphorylation of 4E-BP1, a downstream mTORC1 target, was reduced in S6KCARIP mice. The results of the current experiments demonstrate that activation of S6K in β-cells reduces Akt activity by decreasing the levels of IRS proteins.

The results of the current studies serve to elucidate the importance of S6K in regulation of β-cell mass and function and provide insight into the molecular mechanisms involved in the adaptation of β-cells to states of nutrient overload and hyperglycemia. Similar to exposure of β-cells to glucose and amino acids, activation of S6K signaling resulted in improved glucose tolerance, insulin secretion, and hyperinsulinemia. These findings show, for the first time, that activation of S6K induces β-cell insulin resistance by feedback inhibition of IRS signaling. Importantly, these studies also show that S6K regulates IRS2 levels, a major determinant for β-cell proliferation and survival. The β-cell insulin resistance induced by this mechanism had major effects on cell cycle regulation by modulation of Cdk2, p27, and p16 levels. Another major effect of insulin resistance in this model was the increased apoptosis by decreased survival signals from Akt. The current work suggests that one of the major consequences of chronic exposure of β-cells to nutrient overload is the development of impaired IRS signaling. These results serve to elucidate some of the abnormalities observed in adaptive responses of β-cells to nutrient excess and tentatively to explain some of the mechanisms involved in glucose toxicity. Finally, these data also demonstrate that the negative feedback of S6K on IRS signaling can be a major modulator of β-cell mass and function in vivo.

The current study shows that activation of S6K signaling in β-cells causes improved glucose tolerance by increase in insulin secretion. The augmented insulin secretion in the presence of normal β-cell mass suggests that S6K modulates glucose-induced insulin secretion. Based on the insulin secretion experiments, it is possible that S6K activation regulates early events in insulin secretion, and islet perifusion experiments will be required to address this. The mechanism involved in this process is not completely understood, but our experiments suggest that modulation of the ATP/ADP ratio could play an important role. Similar to the potentiation of insulin secretion by amino acids reported in the literature, the maximal increase in ATP/ADP ratio observed in islets from S6K in low glucose could prime β-cells to respond to a glucose challenge (25). These findings together with impaired glucose tolerance and defective insulin secretion in S6K1-deficient mice or mice with knock-in at serine residues of rpS6 suggest that S6K modulates insulin secretion. The mechanism implicated in defective insulin secretion in these models is unclear, but previous evidence suggests that small cell size with a reduction in membrane surface has pronounced effects on insulin secretion (26,27). The relation between cell size and insulin secretion is intriguing, and it is reasonable to speculate that increased cell size and membrane surface size could contribute to the augmented insulin secretion observed in S6KCARIP mice. Further studies are needed to evaluate this hypothesis and to explore a role of S6K in regulation of distal exocytotic events involved in first and second phases of insulin secretion.

In the present work, overexpression of S6K recapitulated the proliferative and the cell size phenotype described in mice overexpressing a constitutively active form of Akt and mice with conditional deletion of TSC2 in β-cells (18,28,29). These results suggest that this kinase relates some of the proliferative and growth signals induced by Akt/mTOR. The effect of S6K on β-cell proliferation is also in agreement with recent findings implicating this kinase in insulinoma formation by Akt activation (14). The absence of β-cell mass changes, together with the results of Ki67, BrdU, and pH3 measurements, suggests that more β-cells enter the cell cycle, but G1-S progression is delayed by partial inhibition of the cyclin D/Cdk4 and cyclin E/Cdk2 complexes. The alteration in G1-S progression could be explained in part by increased levels of p16 and p27, respectively, and lower Cdk2 expression. The normal β-cell mass in this model could be explained by a balance between increased entry, but slow progression through the cell cycle combined with increased apoptosis and a long half-life of β-cells. The increase in p16 levels is intriguing, as this cell cycle inhibitor is a biomarker of aging and is elevated in aged β-cells (30). It is possible that continuous activation of S6K reproduces some of the abnormalities observed in aged β-cells. The augmented levels and nuclear localization of p27 observed in S6KCARIP mice were most likely caused by a negative feedback inhibition in IRS/Akt signaling. The decreased insulin/IRS/Akt signaling could alter p27 levels by several mechanisms, including FoxO1-mediated p27 transcription (31,32) and/or increases in p27 stability by GSK3β (33). Decreased IRS signaling induces nuclear p27 in β-cells from IRS2-deficient mice (34). The importance of p27 in regulation of the β-cell cycle in our model resembles the findings obtained in islets from models of diet-induced obesity and suggests that S6K signaling may be implicated in the β-cell failure observed in this model (34). Based on the current studies and published evidence, p27 levels are likely to be a marker for impaired IRS signaling in β-cells. This mechanism plays a pivotal role in regulating cell-cycle progression under normal conditions or in states of β-cell expansion (34). A major difference between the β-cell mass phenotype of βTSC2−/− and S6KCARIP mice is that β-cells from βTSC2−/− are probably less susceptible to inhibition in IRS signaling, as the mTOR activation in this model is downstream and not dependent on IRS signaling. In addition, the activation of the mTORC2/Akt pathway could activate survival signals.

The alteration of β-cell survival was the other major component observed by augmented S6K signaling in β-cells. The mechanism involved in apoptosis in these mice could be multifactorial, but our results are consistent with a critical role for a negative feedback of S6K on IRS1/IRS2/Akt signaling. The decreased Akt activity was characterized by decreased phosphorylation of Thr308, but not Ser473, suggesting alterations in PDK1 and not mTORC2 activity. Assessment of downstream Akt targets in islets from S6KCARIP mice implied that the inhibition of IRS2/Akt signaling observed in S6KCARIP induced apoptosis by activation of FoxO1 and GSK3β. Interestingly, Pdx1 levels in S6KCARIP mice were unchanged, suggesting that this is not a major contributor to the increased apoptosis in these mice (data not shown). The inhibition of IRS signaling by S6K-mediated phosphorylation and degradation of IRS1 signaling has been demonstrated in vivo and in vitro (15,17). Less is known about a feedback inhibition on IRS2 signaling, but recent data on INS1 cells suggest that IGF1 signaling downregulates IRS2 protein by activation of mTOR signaling (35). Our results show, for the first time, that S6K regulates IRS2 levels in vivo, and that this mechanism has major implications for regulation of survival and cell cycle progression in β-cells. The increased apoptosis observed in S6KCARIP mice was unexpected, as S6K has been shown to induce pro-survival signals by inhibiting BAD in lymphocytes (36). This discrepancy could be explained by the fact that β-cells are very sensitive to modulation of IRS2 levels, as demonstrated in mice deficient for IRS2 (37). The decreased survival in the S6K mice is in contrast to the absence of apoptosis in βTSC2−/− mice (18). These could be explained, at least in part, by the antiapoptotic effects induced by activation of the eIF4E and mTORC2 activation (21,38,39). Taken together, these studies suggest that β-cell insulin resistance induced by a negative feedback of S6K on IRS signaling not only affects cell cycle progression, but also impairs survival signals. However, activation of S6K signaling alone is not sufficient to induce β-cell failure and diabetes.

The results of the current studies suggest that activation of S6K could play a major role in regulation of β-cell cycle progression and function, and implies that S6K relates proliferative but not survival pathways induced by Akt signaling or activation of mTORC1 signaling. Another important conclusion from these studies is that activating proliferation is not always associated with increases in mass, and that therapeutic strategies should include pharmacologic agents that alter proliferation and apoptosis. These studies collectively show the importance of the S6K arm of mTOR signaling in regulating proliferation, cell size, function, and survival, and increase our knowledge about the mechanism used by β-cells to regulate G1-S transition and mass. Additionally, these studies provide information about the adaptation of the β-cell to states of nutrient overload.

Generation of transgenic mice.

The S6K mutant used in these studies contains deletion of amino acids 2–46, truncation of carboxy-terminal 104 amino acids, and threonine to glutamatic acid mutation at position 412 (p70S6K ΔD2–46/ΔDCT104 T412E). This mutant confers rapamycin resistance and increases in basal S6K activity in transfected cells (24,40). To achieve overexpression of a constitutively active form of S6K in β-cells, this construct was inserted behind the rat insulin promoter I (S6KCARIP). Three transgenic founders were obtained and backcrossed to C57BL6J mice, and the N2 and N3 generation from two lines with similar phenotype were analyzed. Wild-type littermate males with comparable mixed background were used as controls for all of the experiments. All procedures were performed in accordance with Washington University's Animal Studies Committee and the University Committee on Use and Care of Animals at the University of Michigan.

Metabolic studies.

Glucose was measured on whole blood using AccuChek II glucometer (Roche Diagnostics). Plasma insulin levels were determined using a rat insulin ELISA kit (Crystal Chem). Glucose tolerance tests were performed in 12-h fasted animals by injecting glucose (2 g/kg) intraperitoneally as described (28). Insulin secretion in vivo was assessed using 3 g/kg of glucose intraperitoneally in overnight-fasted mice.

Islet studies.

Islet isolation was accomplished by collagenase digestion as described previously (28). Insulin secretion was assessed by static incubation of isolated islets as described (41). After overnight culture in RPMI containing 5 mmol/l glucose, islets were precultured for 1 h in Krebs-Ringer medium containing 2 mmol/l glucose. Groups of 10 islets in triplicate were incubated in Krebs-Ringer medium containing 2 mmol/l glucose or 20 mmol/l glucose for 1 h.

For ATP and ADP measurements, islets were isolated and cultured for 24 h in RPMI containing 5 mmol/l glucose. Thereafter, islets of similar size were handpicked and precultured for 1 h in 0.5 ml Krebs-Ringer medium without glucose in an organ-culture dish. Groups of 20 islets were incubated for 1 h in Krebs-Ringer containing 2 mmol/l and 20 mmol/l glucose, respectively, and rinsed three times in Ringer without glucose. Individual islets were hand picked in 1-μl medium, placed on a slide, and frozen immediately in 2-methylbutane prechilled with liquid nitrogen. They were then freeze-dried at −35°C overnight under vacuum with less than 0.01 mm of Hg and removed for extraction. Each islet was extracted in 0.5 μl of 0.1 N NaOH under oil, heated at 80°C for 20 min, and neutralized with a 0.2-μl mixture of 0.2 mol/l HCl and 0.1 mol/l TrisHCl pH6.8. Samples were stored at −80°C. Aliquot (0.1 μl) was obtained for ATP and ADP microanalysis respectively (42). Data are presented as mean of ATP/ADP ratio per islet from at least 20 islets per mouse. For the experiments using IGF1, islets were serum deprived for an hour followed by stimulation with IGF1 (100 nmol/l) for 15 min.

Immunofluorescence staining.

Pancreatic tissues were fixed overnight in 3.7% formalin and embedded in paraffin using standard techniques. The following antibodies were used: guinea pig anti-insulin (Dako), mouse anti-HA.11 (Covance), rabbit anti-glucagon (Chemicon), rabbit anti-pancreatic polypeptide (Chemicon), rabbit antisomatostatin (Dako), rabbit anti-Glut2 (a gift from Bernard Thorens), rabbit anti-Ki67 (Vector), rabbit anti-cleaved caspase 3 (Cell Signaling), rabbit anti-phospho-GSK3α/β (Ser21/9) (Cell Signaling), mouse anti-BrdU (Amersham), and mouse anti-p27Kip1 (BD Transduction). TUNEL assays were performed using the ApopTag Plus fluorescein in situ apoptosis detection kit (Chemicon). The fluorescent secondary antibodies were from Jackson Laboratories. DAPI (Vector) was used to counterstain nuclei.

Western blotting.

Protein from islet lysates were run in polyacrylamide gels and transferred to polyvinylidene fluoride membranes. Protein-band densitometry was determined using the same membrane by pixel intensity using NIH Image J software (v1.42 freely available at http://rsb.info.nih.gov/ij/index.html) (43) and normalized against that of actin or tubulin. Antibodies used for immunoblotting are included in supplementary Table 1.

Islet morphometry.

The β-cell mass was calculated by point-counting morphometry from 5 insulin-stained sections (5 μm) separated by 200 μm using the BQ Classic98 MR software package (BIOQUANT) as described (28). Cell size was determined in immunofluorescence-stained sections for Glut2 and HA. Sectioned areas of individual β- cells from wild-type and transgenic mice that were HA positive were measured using NIH Image J software (v1.42) (43). The number of β-cells per islet was calculated by dividing the number of β-cells in at least 80 islets per animal. Proliferation was assessed in sections stained with insulin and Ki67, BrdU, and phospho-Histone-3. At least 3,000 insulin-stained cells were counted for each animal. Apoptotic rates were determined using cleaved caspase 3 and TUNEL assay (ApopTag Red In Situ Apoptosis Detection Kit, Chemicon) in insulin-stained sections. At least 2,000 β-cells were counted in a blinded fashion.

Statistical analysis.

All values are expressed as mean ± SEM. For all other comparisons, paired Student t test was used. Differences were considered statistically significant at P < 0.05.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

This work was supported by National Institutes of Health Grant RO1-DK-073716-01 (to E.B.-M.) and a Career Development Award from the American Diabetes Association (to E.B.-M.). The authors also acknowledge support from the Radioimmunoassay, Morphology Core from the Washington University Diabetes Research and Training Center.

No potential conflicts of interest relevant to this article were reported.

L.E., M.B.-R., and C.C.-M. researched data and wrote, reviewed, and edited the manuscript. N.B., S.F., A.P.G., M.M.C., and K.H.M. researched data. E.B.-M. wrote, reviewed, and edited the manuscript.

The authors thank Joseph Avruch (Massachusetts General Hospital and the Department of Medicine, Harvard Medical School, Boston, MA) for helpful comments and for providing the constitutively active S6K construct. The authors also thank the Morphology Core from Washington University Digestive Diseases Research Core Center for histology sections. The anti-Glut2 antibody was kindly provided by Bernard Thorens (Université de Lausane, Lausane, Switzerland).

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