Context-dependent effects of CCN2 on ß-cell mass expansion and indicators of cell stress in the setting of acute and chronic stress.

Stimulation of functional ß-cell mass expansion can be beneficial for the treatment of type 2 diabetes. Our group has previously demonstrated that the matricellular protein CCN2 can induce ß-cell mass expansion during embryogenesis, and postnatally during pregnancy and after 50% ß-cell injury. The mechanism by which CCN2 stimulates ß-cell mass expansion is unknown. However, CCN2 does not induce ß-cell proliferation in the setting of euglycemic and optimal functional ß-cell mass. We thus hypothesized that ß-cell stress is required for responsiveness to CCN2 treatment. In this study, a doxycycline-inducible ß-cell-specific CCN2 transgenic mouse model was utilized to evaluate the effects of CCN2 on ß-cell stress in the setting of acute (thapsigargin treatment ex vivo) or chronic [high-fat diet or leptin receptor haploinsufficiency (db/+) in vivo] cellular stress. CCN2 induction during 1 wk or 10 wk of high-fat diet or in db/+ mice had no effect on markers of ß-cell stress. However, CCN2 induction did result in a significant increase in ß-cell mass over high-fat diet alone when animals were fed high-fat diet for 10 wk, a duration known to induce insulin resistance. CCN2 induction in isolated islets treated with thapsigargin ex vivo resulted in upregulation of the gene encoding the Nrf2 transcription factor, a master regulator of antioxidant genes, suggesting that CCN2 further activates this pathway in the presence of cell stress. These studies indicate that the potential of CCN2 to induce ß-cell mass expansion is context-dependent and that the presence of ß-cell stress does not ensure ß-cell proliferation in response to CCN2.NEW & NOTEWORTHY CCN2 promotes ß-cell mass expansion in settings of suboptimal ß-cell mass. Here, we demonstrate that the ability of CCN2 to induce ß-cell mass expansion in the setting of ß-cell stress is context-dependent. Our results suggest that ß-cell stress is necessary but insufficient for CCN2 to increase ß-cell proliferation and mass. Furthermore, we found that CCN2 promotes upregulation of a key antioxidant transcription factor, suggesting that modulation of ß-cell oxidative stress contributes to the actions of CCN2.

The Tetracycline-Controlled Transactivator (Tet-On/Off) System in ß-Cells Reduces Insulin Expression and Secretion in Mice.

Controllable genetic manipulation is an indispensable tool in research, greatly advancing our understanding of cell biology and physiology. However in ß-cells, transgene silencing, low inducibility, ectopic expression, and off-targets effects are persistent challenges. In this study, we investigated whether an inducible Tetracycline (Tet)-Off system with ß-cell-specific mouse insulin promoter (MIP)-itTA-driven expression of tetracycline operon (TetO)-CreJaw/J could circumvent previous issues of specificity and efficacy. Following assessment of tissue-specific gene recombination, ß-cell architecture, in vitro and in vivo glucose-stimulated insulin secretion, and whole-body glucose homeostasis, we discovered that expression of any tetracycline-controlled transactivator (e.g., improved itTA, reverse rtTA, or tTA) in ß-cells significantly reduced Insulin gene expression and decreased insulin content. This translated into lower pancreatic insulin levels and reduced insulin secretion in mice carrying any tTA transgene, independent of Cre recombinase expression or doxycycline exposure. Our study echoes ongoing challenges faced by fundamental researchers working with ß-cells and highlights the need for consistent and comprehensive controls when using the tetracycline-controlled transactivator systems (Tet-On or Tet-Off) for genome editing.

Ins1-Cre and Ins1-CreER Gene Replacement Alleles Are Susceptible To Silencing By DNA Hypermethylation.

Targeted gene ablation studies of the endocrine pancreas have long suffered from suboptimal Cre deleter strains. In many cases, Cre lines purportedly specific for beta cells also displayed expression in other islet endocrine cells or in a subset of neurons in the brain. Several pancreas and endocrine Cre lines have experienced silencing or mosaicism over time. In addition, many Cre transgenic constructs were designed to include the hGH mini-gene, which by itself increases beta-cell replication and decreases beta-cell function. More recently, driver lines with Cre or CreER inserted into the Ins1 locus were generated, with the intent of producing ß cell-specific Cre lines with faithful recapitulation of insulin expression. These lines were bred in multiple labs to several different mouse lines harboring various lox alleles. In our hands, the ability of the Ins1-Cre and Ins1-CreER lines to delete target genes varied from that originally reported, with both alleles displaying low levels of expression, increased levels of methylation compared to the wild-type allele, and ultimately inefficient or absent target deletion. Thus, caution is warranted in the interpretation of results obtained with these genetic tools, and Cre expression and activity should be monitored regularly when using these lines.

Extracellular Matrix-Associated Factors Play Critical Roles in Regulating Pancreatic ß-Cell Proliferation and Survival.

This review describes formation of the islet basement membrane and the function of extracellular matrix (ECM) components in ß-cell proliferation and survival. Implications for islet transplantation are discussed. The insulin-producing ß-cell is key for maintaining glucose homeostasis. The islet microenvironment greatly influences ß-cell survival and proliferation. Within the islet, ß-cells contact the ECM, which is deposited primarily by intraislet endothelial cells, and this interaction has been shown to modulate proliferation and survival. ECM-localized growth factors, such as vascular endothelial growth factor and cellular communication network 2, signal through specific receptors and integrins on the ß-cell surface. Further understanding of how the ECM functions to influence ß-cell proliferation and survival will provide targets for enhancing functional ß-cell mass for the treatment of diabetes.

Increases in bioactive lipids accompany early metabolic changes associated with ß-cell expansion in response to short-term high-fat diet.

Pancreatic ß-cell expansion is a highly regulated metabolic adaptation to increased somatic demands, including obesity and pregnancy; adult ß cells otherwise rarely proliferate. We previously showed that high-fat diet (HFD) feeding induces mouse ß-cell proliferation in less than 1 wk in the absence of insulin resistance. Here we metabolically profiled tissues from a short-term HFD ß-cell expansion mouse model to identify pathways and metabolite changes associated with ß-cell proliferation. Mice fed HFD vs. chow diet (CD) showed a 14.3% increase in body weight after 7 days; ß-cell proliferation increased 1.75-fold without insulin resistance. Plasma from 1-wk HFD-fed mice induced ß-cell proliferation ex vivo. The plasma, as well as liver, skeletal muscle, and bone, were assessed by LC and GC mass-spectrometry for global metabolite changes. Of the 1,283 metabolites detected, 159 showed significant changes [false discovery rate (FDR) < 0.1]. The majority of changes were in liver and muscle. Pathway enrichment analysis revealed key metabolic changes in steroid synthesis and lipid metabolism, including free fatty acids and other bioactive lipids. Other important enrichments included changes in the citric acid cycle and 1-carbon metabolism pathways implicated in DNA methylation. Although the minority of changes were observed in bone and plasma (<20), increased p-cresol sulfate was increased >4 fold in plasma (the largest increase in all tissues), and pantothenate (vitamin B5) decreased >2-fold. The results suggest that HFD-mediated ß-cell expansion is associated with complex, global metabolite changes. The finding could be a significant insight into Type 2 diabetes pathogenesis and potential novel drug targets.

Opposing effects of prostaglandin E2 receptors EP3 and EP4 on mouse and human ß-cell survival and proliferation.

OBJECTIVE: Hyperglycemia and systemic inflammation, hallmarks of Type 2 Diabetes (T2D), can induce the production of the inflammatory signaling molecule Prostaglandin E2 (PGE2) in islets. The effects of PGE2 are mediated by its four receptors, E-Prostanoid Receptors 1-4 (EP1-4). EP3 and EP4 play opposing roles in many cell types due to signaling through different G proteins, Gi and GS, respectively. We previously found that EP3 and EP4 expression are reciprocally regulated by activation of the FoxM1 transcription factor, which promotes ß-cell proliferation and survival. Our goal was to determine if EP3 and EP4 regulate ß-cell proliferation and survival and, if so, to elucidate the downstream signaling mechanisms. METHODS: ß-cell proliferation was assessed in mouse and human islets ex vivo treated with selective agonists and antagonists for EP3 (sulprostone and DG-041, respectively) and EP4 (CAY10598 and L-161,982, respectively). ß-cell survival was measured in mouse and human islets treated with the EP3- and EP4-selective ligands in conjunction with a cytokine cocktail to induce cell death. Changes in gene expression and protein phosphorylation were analyzed in response to modulation of EP3 and EP4 activity in mouse islets. RESULTS: Blockade of EP3 enhanced ß-cell proliferation in young, but not old, mouse islets in part through phospholipase C (PLC)-γ1 activity. Blocking EP3 also increased human ß-cell proliferation. EP4 modulation had no effect on ex vivo proliferation alone. However, blockade of EP3 in combination with activation of EP4 enhanced human, but not mouse, ß-cell proliferation. In both mouse and human islets, EP3 blockade or EP4 activation enhanced ß-cell survival in the presence of cytokines. EP4 acts in a protein kinase A (PKA)-dependent manner to increase mouse ß-cell survival. In addition, the positive effects of FoxM1 activation on ß-cell survival are inhibited by EP3 and dependent on EP4 signaling. CONCLUSIONS: Our results identify EP3 and EP4 as novel regulators of ß-cell proliferation and survival in mouse and human islets ex vivo.

Chronic caffeine produces sexually dimorphic effects on amphetamine-induced behavior, anxiety and depressive-like behavior in adolescent rats.

Caffeine consumption has been increasing rapidly in adolescents; however, most research on the behavioral effects of caffeine has been conducted in adults. Two experiments were conducted in which adolescent male and female rats were treated with a moderate dose of caffeine (0.25 g/l) in their drinking water beginning on P26-28. In the first experiment, animals were maintained on caffeinated drinking water or normal tap water for 14 days and were then tested for behavioral and striatal c-Fos response to amphetamine (1.5 mg/kg). In the second experiment, rats were maintained on caffeinated drinking water or normal tap water beginning on P28 and were tested for novel object recognition, anxiety in the light/dark test (L/D) and elevated plus maze (EPM), and depressive like behavior in the forced swim test (FST) beginning on the 14th day of caffeine exposure. Caffeine decreased amphetamine-induced rearing in males, but had no effect in females; however, this behavioral effect was not accompanied by changes in striatal c-Fos, which was increased by amphetamine but not altered by caffeine. No effects of caffeine were observed on novel object recognition or elevated plus maze behavior. However, in the L/D test, there was a sex by caffeine interaction on time spent in the light driven by a caffeine-induced increase in light time in the males but not the females. On the pretest day of the FST, sex by caffeine interactions were observed for swimming and struggling; caffeine decreased struggling behavior and increased swimming behavior in males and caffeine-treated females demonstrated significantly more struggling and significantly less swimming than caffeine-treated males. A similar pattern was observed on the test day in which caffeine decreased immobility overall and increased swimming. These data reveal sex dependent effects of caffeine on behavior in adolescent rats.