Beta-cell Replication Research Articles

Reduced volume of diabetic pancreatic islets in rodents detected by synchrotron X-ray phase-contrast microtomography and deep learning network

The pancreatic islet is a highly structured micro-organ that produces insulin in response to rising blood glucose. Here we develop a label-free and automatic imaging approach to visualize the islets in situ in diabetic rodents by the synchrotron radiation X-ray phase-contrast microtomography (SRμCT) at the ID17 station of the European Synchrotron Radiation Facility. The large-size images (3.2mm×15.97mm) were acquired in the pancreas in STZ-treated mice and diabetic GK rats. Each pancreas was dissected by 3000 reconstructed images. The image datasets were further analysed by a self-developed deep learning method, AA-Net. All islets in the pancreas were segmented and visualized by the three-dimension (3D) reconstruction. After quantifying the volumes of the islets, we found that the number of larger islets (=>1500 μm3) was reduced by 2-fold (wt 1004±94 vs GK 419±122, P<0.001) in chronically developed diabetic GK rat, while in STZ-treated diabetic mouse the large islets were decreased by half (189±33 vs 90±29, P<0.001) compared to the untreated mice. Our study provides a label-free tool for detecting and quantifying pancreatic islets in situ. It implies the possibility of monitoring the state of pancreatic islets in vivo diabetes without labelling.

Targeted delivery of harmine to xenografted human pancreatic islets promotes robust cell proliferation

Type 1 diabetes (T1D) occurs as a consequence of the autoimmune destruction of insulin-producing pancreatic beta (β) cells and commonly presents with insulin deficiency and unregulated glycemic control. Despite improvements in the medical management of T1D, life-threatening complications are still common. Beta-cell replication to replace lost cells may be achieved by using small-molecule mitogenic drugs, like harmine. However, the safe and effective delivery of such drugs to beta cells remains a challenge. This work aims to deploy an antibody conjugated nanocarrier platform to achieve cell-specific delivery of candidate therapeutic and imaging agents to pancreatic endocrine cells. We approached this goal by generating core–shell type micellar nanocarriers composed of the tri-block copolymer, Pluronic®F127 (PEO100–PPO65–PEO100). We decorated these nanocarriers with a pancreatic endocrine cell-selective monoclonal antibody (HPi1), with preference for beta cells, to achieve active targeting. The PPO-based hydrophobic core allows encapsulation of various hydrophobic cargoes, whereas the PEO-based hydrophilic shell curbs the protein adhesion, hence prolonging the nanocarriers' systemic circulation time. The nancarriers were loaded with quantum dots (QDots) that allowed nanocarrier detection both in-vitro and in-vivo. In-vitro studies revealed that HPi1 conjugated nanocarriers could target endocrine cells in dispersed islet cell preparations with a high degree of specificity, with beta cells exhibiting a fluorescent quantum dot signal that was approximately five orders of magnitude greater than the signal associated with alpha cells. In vivo endocrine cell targeting studies demonstrated that the HPi1 conjugated nanocarriers could significantly accumulate at the islet xenograft site. For drug delivery studies, the nanocarriers were loaded with harmine. We demonstrated that HPi1 conjugated nanocarriers successfully targeted and delivered harmine to human endocrine cells in a human islet xenograft model. In this model, targeted harmine delivery yielded an ~ 41-fold increase in the number of BrdU positive cells in the human islet xenograft than that observed in untreated control mice. By contrast, non-targeted harmine yielded an ~ 9-fold increase in BrdU positive cells. We conclude that the nanocarrier platform enabled cell-selective targeting of xenografted human pancreatic endocrine cells and the selective delivery of the hydrophobic drug harmine to those cells. Further, the dramatic increase in proliferation with targeted harmine, a likely consequence of achieving higher local drug concentrations, supports the concept that targeted drug delivery may promote more potent biological responses when using harmine and/or other drugs than non-targeting approaches. These results suggest that this targeted drug delivery platform may apply in drug screening, beta cell regenerative therapies, and/or diagnostic imaging in patients with type 1 diabetes.

Fetal Programming of the Endocrine Pancreas: Impact of a Maternal Low-Protein Diet on Gene Expression in the Perinatal Rat Pancreas.

In rats, the time of birth is characterized by a transient rise in beta cell replication, as well as beta cell neogenesis and the functional maturation of the endocrine pancreas. However, the knowledge of the gene expression during this period of beta cell expansion is incomplete. The aim was to characterize the perinatal rat pancreas transcriptome and to identify regulatory pathways differentially regulated at the whole organ level in the offspring of mothers fed a regular control diet (CO) and of mothers fed a low-protein diet (LP). We performed mRNA expression profiling via the microarray analysis of total rat pancreas samples at embryonic day (E) 20 and postnatal days (P) 0 and 2. In the CO group, pancreas metabolic pathways related to sterol and lipid metabolism were highly enriched, whereas the LP diet induced changes in transcripts involved in RNA transcription and gene regulation, as well as cell migration and apoptosis. Moreover, a number of individual transcripts were markedly upregulated at P0 in the CO pancreas: growth arrest specific 6 (Gas6), legumain (Lgmn), Ets variant gene 5 (Etv5), alpha-fetoprotein (Afp), dual-specificity phosphatase 6 (Dusp6), and angiopoietin-like 4 (Angptl4). The LP diet induced the downregulation of a large number of transcripts, including neurogenin 3 (Neurog3), Etv5, Gas6, Dusp6, signaling transducer and activator of transcription 3 (Stat3), growth hormone receptor (Ghr), prolactin receptor (Prlr), and Gas6 receptor (AXL receptor tyrosine kinase; Axl), whereas upregulated transcripts were related to inflammatory responses and cell motility. We identified differentially regulated genes and transcriptional networks in the perinatal pancreas. These data revealed marked adaptations of exocrine and endocrine in the pancreas to the low-protein diet, and the data can contribute to identifying novel regulators of beta cell mass expansion and functional maturation and may provide a valuable tool in the generation of fully functional beta cells from stem cells to be used in replacement therapy.

Exogenous Lactogenic Signaling Stimulates Beta Cell Replication In Vivo and In Vitro.

As patients recently diagnosed with T1D and patients with T2D have residual beta cell mass, there is considerable effort in beta cell biology to understand the mechanisms that drive beta cell regeneration as a potential cellular therapy for expanding patients’ residual beta cell population. Both mouse and human studies have established that beta cell mass expansion occurs rapidly during pregnancy. To investigate the mechanisms of beta cell mass expansion during pregnancy, we developed a novel in vivo and in vitro models of pseudopregnancy. Our models demonstrate that pseudopregnancy promotes beta cell mass expansion in parous mice, and this expansion is driven by beta cell proliferation rather than hypertrophy. Importantly, estrogen, progesterone, and placental lactogen induce STAT5A signaling in the pseudopregnancy model, demonstrating that this model successfully recapitulates pregnancy-induced beta cell replication. We then created an in vitro model of pseudopregnancy and found that the combination of estrogen and placental lactogen induced beta cell replication in human islets and rat insulinoma cells. Therefore, beta cells both in vitro and in vivo increase proliferation when subjected to the pseudopregnancy cocktail compared to groups treated with estradiol or placental lactogen alone. The pseudopregnancy models described here may help inform novel methods of inducing beta cell replication in patients with diabetes.

ZBED6 counteracts high-fat diet-induced glucose intolerance by maintaining beta cell area and reducing excess mitochondrial activation

Aims/hypothesisZBED6 (zinc finger, BED-type containing 6) is known to regulate muscle mass by suppression of Igf2 gene transcription. In insulin-producing cell lines, ZBED6 maintains proliferative capacity at the expense of differentiation and beta cell function. The aim was to study the impact of Zbed6 knockout on beta cell function and glucose tolerance in C57BL/6 mice.MethodsBeta cell area and proliferation were determined in Zbed6 knockout mice using immunohistochemical analysis. Muscle and fat distribution were assessed using micro-computed tomography. Islet gene expression was assessed by RNA sequencing. Effects of a high-fat diet were analysed by glucose tolerance and insulin tolerance tests. ZBED6 was overexpressed in EndoC-βH1 cells and human islet cells using an adenoviral vector. Beta cell cell-cycle analysis, insulin release and mitochondrial function were studied in vitro using propidium iodide staining and flow cytometry, ELISA, the Seahorse technique, and the fluorescent probes JC-1 and MitoSox.ResultsIslets from Zbed6 knockout mice showed lowered expression of the cell cycle gene Pttg1, decreased beta cell proliferation and decreased beta cell area, which occurred independently from ZBED6 effects on Igf2 gene expression. Zbed6 knockout mice, but not wild-type mice, developed glucose intolerance when given a high-fat diet. The high-fat diet Zbed6 knockout islets displayed upregulated expression of oxidative phosphorylation genes and genes associated with beta cell differentiation. In vitro, ZBED6 overexpression resulted in increased EndoC-βH1 cell proliferation and a reduced glucose-stimulated insulin release in human islets. ZBED6 also reduced mitochondrial JC-1 J-aggregate formation, mitochondrial oxygen consumption rates (OCR) and mitochondrial reactive oxygen species (ROS) production, both at basal and palmitate + high glucose-stimulated conditions. ZBED6-induced inhibition of OCR was not rescued by IGF2 addition. ZBED6 reduced levels of the mitochondrial regulator PPAR-γ related coactivator 1 protein (PRC) and bound its promoter/enhancer region. Knockdown of PRC resulted in a lowered OCR.Conclusions/interpretationIt is concluded that ZBED6 is required for normal beta cell replication and also limits excessive beta cell mitochondrial activation in response to an increased functional demand. ZBED6 may act, at least in part, by restricting PRC-mediated mitochondrial activation/ROS production, which may lead to protection against beta cell dysfunction and glucose intolerance in vivo.Graphical abstract

\u03b2-Arrestin-1 is required for adaptive \u03b2-cell mass expansion during obesity

Obesity is the key driver of peripheral insulin resistance, one of the key features of type 2 diabetes (T2D). In insulin-resistant individuals, the expansion of beta-cell mass is able to delay or even prevent the onset of overt T2D. Here, we report that beta-arrestin-1 (barr1), an intracellular protein known to regulate signaling through G protein-coupled receptors, is essential for beta-cell replication and function in insulin-resistant mice maintained on an obesogenic diet. Specifically, insulin-resistant beta-cell-specific barr1 knockout mice display marked reductions in beta-cell mass and the rate of beta-cell proliferation, associated with pronounced impairments in glucose homeostasis. Mechanistic studies suggest that the observed metabolic deficits are due to reduced Pdx1 expression levels caused by beta-cell barr1 deficiency. These findings indicate that strategies aimed at enhancing barr1 activity and/or expression in beta-cells may prove useful to restore proper glucose homeostasis in T2D.

Wisp1 is a circulating factor that stimulates proliferation of adult mouse and human beta cells

Expanding the mass of pancreatic insulin-producing beta cells through re-activation of beta cell replication has been proposed as a therapy to prevent or delay the appearance of diabetes. Pancreatic beta cells exhibit an age-dependent decrease in their proliferative activity, partly related to changes in the systemic environment. Here we report the identification of CCN4/Wisp1 as a circulating factor more abundant in pre-weaning than in adult mice. We show that Wisp1 promotes endogenous and transplanted adult beta cell proliferation in vivo. We validate these findings using isolated mouse and human islets and find that the beta cell trophic effect of Wisp1 is dependent on Akt signaling. In summary, our study reveals the role of Wisp1 as an inducer of beta cell replication, supporting the idea that the use of young blood factors may be a useful strategy to expand adult beta cell mass.

86-OR: High-Fat Diet Prevents Autoimmune Diabetes in NOD Mice

Type 1 diabetes (T1D) has a strong genetic predisposition and requires an environmental trigger to initiate autoimmune destruction of beta cells. The rate of childhood obesity has risen in parallel to the rate of T1D, suggesting high fat diet (HFD) may be an environmental trigger in the development of autoimmune diabetes. Supporting this hypothesis, HFD can induce insulin resistance, beta cell stress, dysfunctional insulin production, and beta cell death. To explore the role of HFD in the development of T1D, 4 week-old non-obese diabetic (NOD) female mice were placed on HFD or chow diet (CD). At 10 weeks of age NOD mice fed with HFD demonstrated a significant increase in body weight and non-fasting blood glucose along with mild glucose intolerance compared with NOD CD fed mice. Histological analysis at 10 weeks of age revealed significantly less pancreatic immune cell infiltration and increased beta cell mass in HFD fed mice compared to CD fed mice. By 15 weeks of age, HFD fed NOD animals demonstrated impaired glucose tolerance similar to CD fed mice, increased glucose-stimulated insulin secretion and total insulin content, and insulin resistance. Surprisingly, at 25 weeks of age the HFD fed NOD mice were completely protected from the development of diabetes, while as expected 70% of NOD CD fed mice had developed diabetes. In summary, this study demonstrates that in the NOD model of T1D HFD reduced islet immune cell infiltration, increased beta cell mass, insulin content and insulin secretion protecting the mice from development of diabetes. The mechanism underlying this protection seems to be two-fold: expansion of beta cell mass and prevention of autoimmune-mediated beta cell death. Our data correlate with other recent studies indicating that early stimulation of beta cell replication can induce immune tolerance in NOD animals preventing T1D. Identification of the mechanisms by which HFD leads to prevention of diabetes in NOD animals may lead to the development of novel therapeutic interventions to prevent T1D in humans. Disclosure A.L. Clark: None. Z. Yan: None. S.X. Chen: None. M. Fuess: None. G. McGinn: None. M.S. Remedi: None. Funding National Institutes of Health (P30DK020579, K12HD076224-04)

Combined inhibition of menin-MLL interaction and TGF-β signaling induces replication of human pancreatic beta cells

Both type 1 and type 2 diabetes are associated with hyperglycemia and loss of functional beta cell mass. Inducing proliferation of preexisting beta cells is an approach to increase the numbers of beta cells. In this study, we examined a panel of selected small molecules for their proliferation-inducing effects on human pancreatic beta cells. Our results demonstrated that a small molecule inhibitor of the menin-MLL interaction (MI-2) and small molecule inhibitors of TGF-β signaling (SB431542, LY2157299, or LY364947) synergistically increased ex vivo replication of human beta cells. We showed that this increased proliferation did not affect insulin production, as a pivotal indication of beta cell function. We further provided evidence which suggested that menin-MLL and TGF-β inhibition cooperated through downregulation of cell cycle inhibitors CDKN1A, CDKN1B, and CDKN2C. Our findings might provide a new option for extending the pharmacological repertoire for induction of beta cell proliferation as a potential therapeutic approach for diabetes.

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 β 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.

Associations of birthweight and history of childhood obesity with beta cell mass in Japanese adults

Aims/hypothesisLow birthweight is associated with a high risk of diabetes, but there are no reports discussing birthweight and pancreatic tissues in humans. The purpose of this study was to examine the correlation between birthweight and beta and alpha cell mass in humans.MethodsSixty-four Japanese adults with and without diabetes who underwent pancreatectomy and were able to recall their weight history including birthweight were included. Pancreatic tissues were stained for insulin and glucagon, and fractional beta cell area (BCA) and alpha cell area (ACA) were quantified. Islet size and density and beta cell replication were also quantified and their associations with birthweight were evaluated.ResultsIn participants without diabetes, there was a weak positive correlation between birthweight and BCA (R = 0.34, p = 0.03). The group with a history of childhood obesity, but not the group with a history of obesity in adulthood only, showed higher BCA compared with those without a history of obesity (1.78 ± 0.74% vs 0.99 ± 0.53%, p = 0.01), and the correlation coefficient between birthweight and BCA increased after excluding those with a history of childhood obesity (R = 0.51, p < 0.01). In those with diabetes, there was no correlation between birthweight and BCA. No correlation was found between birthweight and ACA in either those with or without diabetes.Conclusions/interpretationBirthweight and beta, but not alpha, cell mass are positively correlated in non-diabetic adults, and a history of childhood obesity may affect beta cell mass.Graphical abstract

The Map3k12 (Dlk)/JNK3 signaling pathway is required for pancreatic beta-cell proliferation during postnatal development.

Unveiling the key pathways underlying postnatal beta-cell proliferation can be instrumental to decipher the mechanisms of beta-cell mass plasticity to increased physiological demand of insulin during weight gain and pregnancy. Using transcriptome and global Serine Threonine Kinase activity (STK) analyses of islets from newborn (10days old) and adult rats, we found that highly proliferative neonatal rat islet cells display a substantially elevated activity of the mitogen activated protein 3 kinase 12, also called dual leucine zipper-bearing kinase (Dlk). As a key upstream component of the c-Jun amino terminal kinase (Jnk) pathway, Dlk overexpression was associated with increased Jnk3 activity and was mainly localized in the beta-cell cytoplasm. We provide the evidence that Dlk associates with and activates Jnk3, and that this cascade stimulates the expression of Ccnd1 and Ccnd2, two essential cyclins controlling postnatal beta-cell replication. Silencing of Dlk or of Jnk3 in neonatal islet cells dramatically hampered primary beta-cell replication and the expression of the two cyclins. Moreover, the expression of Dlk, Jnk3, Ccnd1 and Ccnd2 was induced in high replicative islet beta cells from ob/ob mice during weight gain, and from pregnant female rats. In human islets from non-diabetic obese individuals, DLK expression was also cytoplasmic and the rise of the mRNA level was associated with an increase of JNK3, CCND1 and CCND2 mRNA levels, when compared to islets from lean and obese patients with diabetes. In conclusion, we find that activation of Jnk3 signalling by Dlk could be a key mechanism for adapting islet beta-cell mass during postnatal development and weight gain.

The glucose-lowering effects of \u03b1-glucosidase inhibitor require a bile acid signal in mice

Aims/hypothesisBile-acid (BA) signalling is crucial in metabolism homeostasis and has recently been found to mediate the therapeutic effects of glucose-lowering treatments, including α-glucosidase inhibitor (AGI). However, the underlying mechanisms are yet to be clarified. We hypothesised that BA signalling may be required for the glucose-lowering effects and metabolic benefits of AGI.MethodsLeptin receptor (Lepr)-knockout (KO) db/db mice and high-fat high-sucrose (HFHS)-fed Fxr (also known as Nr1h4)-KO mice were treated with AGI. Metabolic phenotypes and BA signalling in different compartments, including the liver, gut and endocrine pancreas, were evaluated. BA pool profiles were analysed by mass spectrometry. The islet transcription profile was assayed by RNA sequencing. The gut microbiome were assayed by 16S ribosomal RNA gene sequencing.ResultsAGI lowered microbial BA levels in BA pools of different compartments in the body, and increased gut BA reabsorption in both db/db and HFHS-fed mouse models via altering the gut microbiome. The AGI-induced changes in BA signalling (including increased activation of farnesoid X receptor [FXR] in the liver and inhibition of FXR in the ileum) echoed the alterations in BA pool size and composition in different organs. In Fxr-KO mice, the glucose- and lipid-lowering effects of AGI were partially abrogated, possibly due to the Fxr-dependent effects of AGI on decelerating beta cell replication, alleviating insulin hypersecretion and improving hepatic lipid and glucose metabolism.Conclusions/interpretationBy regulating microbial BA metabolism, AGI elicited diverse changes in BA pool composition in different host compartments to orchestrate BA signalling in the whole body. The AGI-induced changes in BA signalling may be partly required for its glucose-lowering effects. Our study, hence, sheds light on the promising potential of regulating microbial BA and host FXR signalling for the treatment of type 2 diabetes.Data availabilitySequencing data are available from the BioProject Database (accession no. PRJNA600345; www.ncbi.nlm.nih.gov/bioproject/600345).

Determining Beta Cell Mass, Apoptosis, Proliferation, and Individual Beta Cell Size in Pancreatic Sections.

Pancreatic beta cells have a significant remodeling capacity which plays an essential role in the maintenance of glucose homeostasis. Beta cell apoptosis, replication, size, dedifferentiation, and (neo)generation contribute to the beta cell mass regulation. However, the extent of their respective contribution varies significantly depending on the specific condition, and it is the balance among them that determines the eventual change in beta cell mass. Thus, the study of the pancreatic beta cell mass regulation requires the determination of all these factors. In this chapter, we describe the quantification of beta cell replication based on the incorporation of thymidine analogs into replicated DNA strands and on the expression of Ki67 antigen and phosphorylation of histone H3. Beta cell apoptosis is analyzed by the TUNEL technique, and beta cell mass and cross-sectional area of individual beta cells are determined by computerized image processing methods.

The inhibitory heterotrimeric G protein, Gz, regulates alpha‐cell active glucagon‐like peptide 1 (GLP‐1) levels

Biologically‐active glucagon‐like peptide 1 (GLP‐1) is a product of the proglucagon gene and amplifies glucose stimulated insulin secretion and promotes beta‐cell survival via stimulation of cAMP production. Neighboring alpha cells produce and secrete active GLP‐1 to influence beta‐cell function. Although alpha‐cell GLP‐1 production and secretion is poorly understood, cyclic AMP (cAMP) signaling promotes GLP‐1 released from gut L‐cells. Furthermore, cAMP signaling, through activation of cyclic AMP‐responsive transcription factors, may influence expression of the prohormone convertase enzymes specific for GLP‐1. Therefore, it is possible cAMP positively regulates both GLP‐1 production and secretion. Cyclic AMP levels are augmented by stimulatory heterotrimeric G proteins (Gs) and blocked by inhibitory heterotrimeric G proteins (Gi). A unique Gi family member, Gz, is expressed in both alpha and beta cells. Mice lacking the catalytic alpha subunit of Gz (Gαz), are protected from hyperglycemia in several diabetes model systems due to increased beta‐cell function and beta‐cell replication. At least part of this phenotype is beta‐cell autonomous. We hypothesized part of the protective phenotype may be due to loss of Gαz in the alpha‐cell and increased GLP‐1 production and/or secretion. To determine alpha‐cell levels of active GLP‐1, we used immunofluorescence to co‐localize active GLP‐1 to glucagon positive alpha cells in pancreas sections from wild‐type and Gαz‐null mice in different models of diabetes mellitus. Pancreas sections lacking Gαz displayed a dramatic increase in the percentage of cells that are both active GLP‐1 positive and glucagon positive compared to wild‐type counterparts. To determine if beta‐cell Gαz regulates alpha‐cell active GLP‐1 levels, we imaged pancreas sections from beta‐cell specific Gz‐null mice. Because published evidence has shown that alpha‐cell active GLP‐1 levels are elevated in pre‐diabetic and diabetic conditions, we determined if beta cell Gαz expression altered this compensatory increase in active GLP‐1 production. Whether increased active GLP‐1 levels correlated with increased active GLP‐1 secretion over time was determined by high‐sensitivity ELISA of islet incubation medium. Future experiments will focus whether the Gaz‐null mutation affects the production and/or secretion of active GLP‐1 in response to the glucolipotoxic conditions of severe insulin resistance and type 2 diabetes. Our results identify Gαz as a potential new therapeutic target to promote beta‐cell function and replication and underscore the role of intra‐islet cell‐cell communication in beta‐cell biology.Support or Funding InformationVA Merit Review Award: I01 BX003700‐01A1, VA BLR&amp;DR01: R01 DK102598, NIH/NIDDK Type 2 Diabetes/Fatty Acid Diet projects (started by 2016) American Diabetes Association Innovative Basic Science Award: 1‐14‐BS‐115 Type 1 Diabetes projects or projects using Gaz‐floxed miceJDRF J&amp;J Industry Partnership Award: 17‐2011‐608This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Decreased Expression of Cilia Genes in Pancreatic Islets as a Risk Factor for Type 2 Diabetes in Mice and Humans

An insufficient adaptive beta-cell compensation is a hallmark of type 2 diabetes (T2D). Primary cilia function as versatile sensory antennae regulating various cellular processes, but their role on compensatory beta-cell replication has not been examined. Here, we identify a significant enrichment of downregulated, cilia-annotated genes in pancreatic islets of diabetes-prone NZO mice as compared with diabetes-resistant B6-ob/ob mice. Among 327 differentially expressed mouse cilia genes, 81 human orthologs are also affected in islets of diabetic donors. Islets of nondiabetic mice and humans show a substantial overlap of upregulated cilia genes that are linked to cell-cycle progression. The shRNA-mediated suppression of KIF3A, essential for ciliogenesis, impairs division of MIN6 beta cells as well as in dispersed primary mouse and human islet cells, as shown by decreased BrdU incorporation. These findings demonstrate the substantial role of cilia-gene regulation on islet function and T2D risk.

Evidence of unrestrained beta-cell proliferation and neogenesis in a patient with hyperinsulinemic hypoglycemia after gastric bypass surgery

ABSTRACTHyperinsulinemic hypoglycemia syndrome (HIHG) is a rare complication of roux-en-Y gastric bypass surgery. The pathology is associated with an excessive function of pancreatic beta-cells, and requires pancreas resection in patients that are recalcitrant to nutritional and pharmacological interventions. The exact prevalence is not clearly understood and the underlying mechanisms not yet fully characterized. We herein sought to perform histological and molecular examination of pancreatic sections obtained from a patient who developed HIHG as a complication of gastric bypass compared to 3 weight-matched controls. We studied markers of cellular replication and beta-cell differentiation by immunohistochemistry and immunofluorescence. HIHG after gastric bypass was characterized by a profound increase in beta-cell mass. Cellular proliferation was increased in islets and ducts compared to controls, suggesting unrestrained proliferation in HIHG. We also detected beta-cell differentiation markers in duct cells and occasional duct cells displaying both insulin and glucagon immunoreactivity. These histological observations suggest that beta-cell differentiation from ductal progenitor cells could also underly beta-cell mass expansion in HIHG. Altogether, our results can be construed to demonstrate that HIHG after gastric bypass is characterized by abnormal beta-cell mass expansion, resulting from both unrestrained beta-cell replication and neogenesis.

(Re)generating Human Beta Cells: Status, Pitfalls, and Perspectives.

Diabetes mellitus results from disturbed glucose homeostasis due to an absolute (type 1) or relative (type 2) deficiency of insulin, a peptide hormone almost exclusively produced by the beta cells of the endocrine pancreas in a tightly regulated manner. Current therapy only delays disease progression through insulin injection and/or oral medications that increase insulin secretion or sensitivity, decrease hepatic glucose production, or promote glucosuria. These drugs have turned diabetes into a chronic disease as they do not solve the underlying beta cell defects or entirely prevent the long-term complications of hyperglycemia. Beta cell replacement through islet transplantation is a more physiological therapeutic alternative but is severely hampered by donor shortage and immune rejection. A curative strategy should combine newer approaches to immunomodulation with beta cell replacement. Success of this approach depends on the development of practical methods for generating beta cells, either in vitro or in situ through beta cell replication or beta cell differentiation. This review provides an overview of human beta cell generation.

Glucocorticoid Receptor Is Instrumental for the Mechanism of Beta-Cell Compensation for Insulin Resistance in Dietary Obesity

The glucocorticoid receptor (GR) is known as a receptor of steroids - potent anti-inflammatory ligands that are commonly used for the medication of allergy or asthma in children and adults. However, chronic use of steroids is associated with a significant risk of developing visceral adiposity and insulin resistance, a medical condition that is known as the Cushing syndrome. We hypothesized that excessive GR activation is deleterious to beta-cells such that genetic GR depletion would preserve beta-cell mass and function in response to metabolic stress. To address this hypothesis, we generated beta-cell specific GR knockout (KO) mice, using an inducible Pdx1-CreERT2-loxP system. We then fed beta-cell GR-KO and WT littermates both regular chow and high-fat diet for up to 30 weeks, followed by determination of beta-cell mass and function. We found that GR-deficient mice, as opposed to WT littermates, developed high blood glucose levels and glucose intolerance. This effect was not secondary to alterations in weight gain or insulin sensitivity. Instead, we detected a significant reduction in glucose-stimulated insulin secretion, correlating with abnormal glucose metabolism in GR-KO mice. We reproduced these findings in both male and female GR-KO mice. Anti-insulin immunohistochemistry revealed that GR-KO mice had significantly reduced beta-cell mass, and decreased beta-cell replication, as visualized by in vivo BrdU-labeling assay. GR deficiency appears to impair the ability of beta-cells to compensate for fat-elicited obesity and insulin resistance, resulting in prediabetes in GR-KO mice. These results unveiled an unexpected role of the glucocorticoid-GR signaling in safeguarding beta-cell mass and function in response to metabolic stress. Disclosure J. Yamauchi: None. S. Lee: None. H. Dong: None.

The Expression Differences of Cyclin Dependent Kinase Inhibitors In Aged and Young Pancreatic Beta Cells

The number of people affected by diabetes is continually rising, affecting over 400 million people worldwide. The insulin secreting pancreatic beta cells are essential to control proper glucose absorption and storage in insulin sensitive peripheral tissue. Both Type 1 and Type 2 diabetes are characterized by decreased functional beta cell mass and, consequently, decreased insulin production. One potential intervention is the use of beta cell transplantation from cadaveric donors. A major impediment to greater application of this treatment is the scarcity of transplant ready beta cells. Increasing the amount of functional beta cells will lead to increased insulin production and better management or a possible treatment strategy for the disease. Various genes have been defined that can induce beta cell replication. A major caveat of these findings, however, is that these factors induce replication in young beta cells and not aged beta cells. Given that the majority of beta cells that will be used for transplant will come from aged donors, it is imperative to understand why aged beta cells are refractory to these proliferative mechanisms. We aimed to determine why aged beta cells do not replicate as well as young beta cells. We hypothesized that one reason for why aged beta cells are refractory to genes that induce proliferation is greater expression of cell cycle inhibitors. The cell cycle is tightly regulated by cyclin‐dependent kinases. Cells also produce proteins known as cyclin‐dependent kinase inhibitors(CDKI's), which bind to cyclin dependent kinases, effectively shutting down cell proliferation. Here we demonstrate the expression of the INK4 and Cip/Kip family of CDKI's by mRNA, protein and histological expression in 5 week old and 5 month old primary rat beta cells. These results begin to define the functional changes that result in the inability of aged beta cells to replicate.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.