Human Pancreatic Beta Cells Research Articles

Macrophages can transmit coxsackievirus B4 to pancreatic cells and can impair these cells.

Macrophages are suspected to be involved in the pathogenesis of type 1 diabetes. The role of macrophages in the transmission of coxsackievirus B4 (CVB4) to pancreatic cells and in the alteration of these cells was investigated. Human monocytes isolated from peripheral blood were differentiated into macrophages with M-CSF (M-CSF macrophages) or GM-CSF (GM-CSF macrophages). M-CSF macrophages were inoculated with CVB4. M-CSF and GM-CSF macrophages were activated with lipopolysaccharide and interferon (IFN)-γ. Human pancreatic beta cells 1.1B4 were inoculated with CVB4 derived from M-CSF macrophages or were cocultured with CVB4-infected M-CSF macrophages. The antiviral activity of synthetic molecules in macrophage cultures was evaluated. Activated macrophages were cocultured with CVB4-persistently infected 1.1B4 cells, and the specific lysis of these cells was determined. Our study shows that CVB4 can infect M-CSF macrophages, leading to the release of interleukin-6 and tumor necrosis factor-α and later IFN-α. M-CSF macrophage-derived CVB4 can infect 1.1B4 cells, which were then altered; however, when these cells were cultured in medium containing agarose, cell layers were not altered. Fluoxetine and CUR-N373 can inhibit CVB4 replication in macrophage cultures. Supernatants of activated M-CSF and GM-CSF macrophage cultures induced lysis of CVB4-persistently infected 1.1B4 cells. The cytolytic activity of activated GM-CSF macrophages was higher towards CVB4-persistently infected 1.1B4 cells than mock-infected 1.1B4 cells. In conclusion, macrophages may play a role in CVB4 infection of pancreatic cells, and are capable of inducing lysis of infected pancreatic cells.

Effects of novel flame retardants tris(1,3-dichloro-2-propyl) phosphate (TDCIPP) and triphenyl phosphate (TPhP) on function and homeostasis in human and rat pancreatic beta-cell lines

Despite the fact that environmental pollution has been implicated in the global rise of diabetes, the research on the impact of emerging pollutants such as novel flame retardants remains limited. In line with the shift towards the use of non-animal approaches in toxicological testing, this study aimed to investigate the effects of two novel flame retardants tris(1,3-dichloro-2-propyl) phosphate (TDCIPP) and triphenyl phosphate (TPhP) in rat (INS1E) and human (NES2Y) pancreatic beta-cell lines. One-week exposure to 1 μM and 10 μM TDCIPP and TPhP altered intracellular insulin and proinsulin levels, but not the levels of secreted insulin (despite the presence of a statistically insignificant trend). The exposures also altered the protein expression of several factors involved in beta-cell metabolic pathways and signaling, including ATP citrate lyase, isocitrate dehydrogenase 1, perilipins, glucose transporters, ER stress-related factors, and antioxidant enzymes. This study has brought new and valuable insights into the toxicity of TDCIPP and TPhP on beta-cell function and revealed alterations that might impact insulin secretion after more extended exposure. It also adds to the scarce studies using in vitro pancreatic beta-cells models in toxicological testing, thereby promoting the development of non-animal testing strategy for identifying pro-diabetic effects of chemical pollutants.

Senescence of human pancreatic beta cells enhances functional maturation through chromatin reorganization and promotes interferon responsiveness.

Senescent cells can influence the function of tissues in which they reside, and their propensity for disease. A portion of adult human pancreatic beta cells express the senescence marker p16, yet it is unclear whether they are in a senescent state, and how this affects insulin secretion. We analyzed single-cell transcriptome datasets of adult human beta cells, and found that p16-positive cells express senescence gene signatures, as well as elevated levels of beta-cell maturation genes, consistent with enhanced functionality. Senescent human beta-like cells in culture undergo chromatin reorganization that leads to activation of enhancers regulating functional maturation genes and acquisition of glucose-stimulated insulin secretion capacity. Strikingly, Interferon-stimulated genes are elevated in senescent human beta cells, but genes encoding senescence-associated secretory phenotype (SASP) cytokines are not. Senescent beta cells in culture and in human tissue show elevated levels of cytoplasmic DNA, contributing to their increased interferon responsiveness. Human beta-cell senescence thus involves chromatin-driven upregulation of a functional-maturation program, and increased responsiveness of interferon-stimulated genes, changes that could increase both insulin secretion and immune reactivity.

Interferons are key cytokines acting on pancreatic islets in type 1 diabetes.

The proinflammatory cytokines IFN-α, IFN-γ, IL-1β and TNF-α may contribute to innate and adaptive immune responses during insulitis in type 1 diabetes and therefore represent attractive therapeutic targets to protect beta cells. However, the specific role of each of these cytokines individually on pancreatic beta cells remains unknown. We used deep RNA-seq analysis, followed by extensive confirmation experiments based on reverse transcription-quantitative PCR (RT-qPCR), western blot, histology and use of siRNAs, to characterise the response of human pancreatic beta cells to each cytokine individually and compared the signatures obtained with those present in islets of individuals affected by type 1 diabetes. IFN-α and IFN-γ had a greater impact on the beta cell transcriptome when compared with IL-1β and TNF-α. The IFN-induced gene signatures have a strong correlation with those observed in beta cells from individuals with type 1 diabetes, and the level of expression of specific IFN-stimulated genes is positively correlated with proteins present in islets of these individuals, regulating beta cell responses to 'danger signals' such as viral infections. Zinc finger NFX1-type containing 1 (ZNFX1), a double-stranded RNA sensor, was identified as highly induced by IFNs and shown to play a key role in the antiviral response in beta cells. These data suggest that IFN-α and IFN-γ are key cytokines at the islet level in human type 1 diabetes, contributing to the triggering and amplification of autoimmunity.

Light-Mediated Enhancement of Glucose-Stimulated Insulin Release of Optogenetically Engineered Human Pancreatic Beta-Cells.

Enhancement of glucose-stimulated insulin secretion (GSIS) in exogenously delivered pancreatic β-cells is desirable, for example, to overcome the insulin resistance manifested in type 2 diabetes or to reduce the number of β-cells for supporting homeostasis of blood sugar in type 1 diabetes. Optogenetically engineered cells can potentiate their function with exposure to light. Given that cyclic adenosine monophosphate (cAMP) mediates GSIS, we surmised that optoamplification of GSIS is feasible in human β-cells carrying a photoactivatable adenylyl cyclase (PAC). To this end, human EndoC-βH3 cells were engineered to express a blue-light-activated PAC, and a workflow was established combining the scalable manufacturing of pseudoislets (PIs) with efficient adenoviral transduction, resulting in over 80% of cells carrying PAC. Changes in intracellular cAMP and GSIS were determined with the photoactivation of PAC in vitro as well as after encapsulation and implantation in mice with streptozotocin-induced diabetes. cAMP rapidly rose in β-cells expressing PAC with illumination and quickly declined upon its termination. Light-induced amplification in cAMP was concomitant with a greater than 2-fold GSIS vs β-cells without PAC in elevated glucose. The enhanced GSIS retained its biphasic pattern, and the rate of oxygen consumption remained unchanged. Diabetic mice receiving the engineered β-cell PIs exhibited improved glucose tolerance upon illumination compared to those kept in the dark or not receiving cells. The findings support the use of optogenetics for molecular customization of the β-cells toward better treatments for diabetes without the adverse effects of pharmacological approaches.

Mechanisms of lipotoxicity-induced dysfunction and death of human pancreatic beta cells under obesity and type 2 diabetes conditions.

The term "pancreatic beta-cell lipotoxicity" refers to the detrimental effects of free fatty acids (FFAs) on a wide variety of cellular functions. Basic research in the field has primarily analyzed the effects of palmitic acid and oleic acid. The focus on these two physiological FFAs, however, ignores differences in chain length and degree of saturation. In order to gain a comprehensive understanding of the lipotoxic mechanisms, a wide range of structurally related FFAs should be investigated. Structure-activity relationship analyses of FFAs in the human EndoC-βH1 beta-cell line have provided a deep insight into the mechanisms of beta-cell lipotoxicity. This review focuses on the effects of a wide range of FFAs with crucial structural determinants for the development of lipotoxicity in human beta cells and documents an association between increased triglyceride stores in obesity and in type 2 diabetes.

Exploring the role of purinergic receptor P2RY1 in type 2 diabetes risk and pathophysiology: Insights from human functional genomics

ObjectiveHuman functional genomics has proven powerful in discovering drug targets for common metabolic disorders. Through this approach, we investigated the involvement of the purinergic receptor P2RY1 in type 2 diabetes (T2D). MethodsP2RY1 was sequenced in 9,266 participants including 4,177 patients with T2D. In vitro analyses were then performed to assess the functional effect of each variant. Expression quantitative trait loci (eQTL) analysis was performed in pancreatic islets from 103 pancreatectomized individuals. The effect of P2RY1 on glucose-stimulated insulin secretion was finally assessed in human pancreatic beta cells (EndoCβH5), and RNA sequencing was performed on these cells. ResultsSequencing P2YR1 in 9,266 participants revealed 22 rare variants, seven of which were loss-of-function according to our in vitro analyses. Carriers, except one, exhibited impaired glucose control. Our eQTL analysis of human islets identified P2RY1 variants, in a beta-cell enhancer, linked to increased P2RY1 expression and reduced T2D risk, contrasting with variants located in a silent region associated with decreased P2RY1 expression and increased T2D risk. Additionally, a P2RY1-specific agonist increased insulin secretion upon glucose stimulation, while the antagonist led to decreased insulin secretion. RNA-seq highlighted TXNIP as one of the main transcriptomic markers of insulin secretion triggered by P2RY1 agonist. ConclusionOur findings suggest that P2RY1 inherited or acquired dysfunction increases T2D risk and that P2RY1 activation stimulates insulin secretion. Selective P2RY1 agonists, impermeable to the blood–brain barrier, could serve as potential insulin secretagogues.

Structure-Function Analysis of p57KIP2 in the Human Pancreatic Beta Cell Reveals a Bipartite Nuclear Localization Signal.

Mutations in CDKN1C, encoding p57KIP2, a canonical cell cycle inhibitor, underlie multiple pediatric endocrine syndromes. Despite this central role in disease, little is known about the structure and function of p57KIP2 in the human pancreatic beta cell. Since p57KIP2 is predominantly nuclear in human beta cells, we hypothesized that disease-causing mutations in its nuclear localization sequence (NLS) may correlate with abnormal phenotypes. We prepared RIP1 insulin promoter-driven adenoviruses encoding deletions of multiple disease-associated but unexplored regions of p57KIP2 and performed a comprehensive structure-function analysis of CDKN1C/p57KIP2. Real-time polymerase chain reaction and immunoblot analyses confirmed p57KIP2 overexpression, construct size, and beta cell specificity. By immunocytochemistry, wild-type (WT) p57KIP2 displayed nuclear localization. In contrast, deletion of a putative NLS at amino acids 278-281 failed to access the nucleus. Unexpectedly, we identified a second downstream NLS at amino acids 312-316. Further analysis showed that each individual NLS is required for nuclear localization, but neither alone is sufficient. In summary, p57KIP2 contains a classical bipartite NLS characterized by 2 clusters of positively charged amino acids separated by a proline-rich linker region. Variants in the sequences encoding these 2 NLS sequences account for functional p57KIP2 loss and beta cell expansion seen in human disease.

Targets for pollutants in rat and human pancreatic beta-cells: The effect of prolonged exposure to sub-lethal concentrations of hexachlorocyclohexane isomers on the expression of function- and survival-related proteins

Decades after most countries banned hexachlorocyclohexane, HCH isomers still pollute the environment. Many studies described HCH as a pro-diabetic factor; nevertheless, the effect of HCH isomers on pancreatic beta-cells remains unexplored. This study investigated the effects of a one-month exposure to α-HCH, β-HCH, and γ-HCH on protein expression in human (NES2Y) and rat (INS1E) pancreatic beta-cell lines. α-HCH and γ-HCH increased proinsulin and insulin levels in INS1E cells, while β-HCH showed the opposite trend. α-HCH altered the expression of PKA, ATF3, and PLIN2. β-HCH affected the expression of GLUT1, GLUT2, PKA, ATF3, p-eIF2α, ATP-CL, and PLIN2. γ-HCH altered the expression of PKA, ATF3, PLIN2, PLIN5, and IDH1. From the tested proteins, PKA, ATF3, and PLIN-2 were the most sensitive to HCH exposure and have the potential to be used as biomarkers.

Angiotensin I-converting enzyme type 2 expression is increased in pancreatic islets of type 2 diabetic donors.

Angiotensin I-converting enzyme type 2 (ACE2), a pivotal SARS-CoV-2 receptor, has been shown to be expressed in multiple cells, including human pancreatic beta-cells. A putative bidirectional relationship between SARS-CoV-2 infection and diabetes has been suggested, confirming the hypothesis that viral infection in beta-cells may lead to new-onset diabetes or worse glycometabolic control in diabetic patients. However, whether ACE2 expression levels are altered in beta-cells of diabetic patients has not yet been investigated. Here, we aimed to elucidate the in situ expression pattern of ACE2 in Type 2 diabetes (T2D) with respect to non-diabetic donors which may account for a higher susceptibility to SARS-CoV-2 infection in beta-cells. Angiotensin I-converting enzyme type 2 immunofluorescence analysis using two antibodies alongside insulin staining was performed on formalin-fixed paraffin embedded pancreatic sections obtained from n=20 T2D and n=20 non-diabetic (ND) multiorgan donors. Intensity and colocalisation analyses were performed on a total of 1082 pancreatic islets. Macrophage detection was performed using anti-CD68 immunohistochemistry on serial sections from the same donors. Using two different antibodies, ACE2 expression was confirmed in beta-cells and in pancreas microvasculature. Angiotensin I-converting enzyme type 2 expression was increased in pancreatic islets of T2D donors in comparison to ND controls alongside with a higher colocalisation rate between ACE2 and insulin using both anti-ACE2 antibodies. CD68+ cells tended to be increased in T2D pancreata, in line with higher ACE2 expression observed in serial sections. Higher ACE2 expression in T2D islets might increase their susceptibility to SARS-CoV-2 infection during COVID-19 in T2D patients, thus worsening glycometabolic outcomes and disease severity.

EndoC-βH5 cells are storable and ready-to-use human pancreatic beta cells with physiological insulin secretion

ObjectivesReadily accessible human pancreatic beta cells that are functionally close to primary adult beta cells are a crucial model to better understand human beta cell physiology and develop new treatments for diabetes. We here report the characterization of EndoC-βH5 cells, the latest in the EndoC-βH cell family. MethodsEndoC-βH5 cells were generated by integrative gene transfer of immortalizing transgenes hTERT and SV40 large T along with Herpes Simplex Virus-1 thymidine kinase into human fetal pancreas. Immortalizing transgenes were removed after amplification using CRE activation and remaining non-excized cells eliminated using ganciclovir. Resulting cells were distributed as ready to use EndoC-βH5 cells. We performed transcriptome, immunological and extensive functional assays. ResultsReady to use EndoC-βH5 cells display highly efficient glucose dependent insulin secretion. A robust 10-fold insulin secretion index was observed and reproduced in four independent laboratories across Europe. EndoC-βH5 cells secrete insulin in a dynamic manner in response to glucose and secretion is further potentiated by GIP and GLP-1 analogs. RNA-seq confirmed abundant expression of beta cell transcription factors and functional markers, including incretin receptors. Cytokines induce a gene expression signature of inflammatory pathways and antigen processing and presentation. Finally, modified HLA-A2 expressing EndoC-βH5 cells elicit specific A2-alloreactive CD8 T cell activation. ConclusionsEndoC-βH5 cells represent a unique storable and ready to use human pancreatic beta cell model with highly robust and reproducible features. Such cells are thus relevant for the study of beta cell function, screening and validation of new drugs, and development of disease models.

1732-P: Correlation of Cyclin D2 with Cell Proliferation in Human Pancreatic Beta Cells and Possible Regulation by CCND2-AS1

Though Cyclin D2 (CCND2) has been considered to be essential for rodent beta cell proliferation, its expression in human beta cells is controversial. We reported CCND2 protein was abundantly expressed also in human perinatal beta cells at ADA 2019. This exclusive expression of CCND2 in the perinatal period would implicate a relationship with beta cell proliferation which is by far rare in human adults, while its regulation mechanism is unclear. GWAS studies identified rs76895963 in CCND2 locus as a genotype that reduced the susceptibility for type 2 diabetes by 50%. The SNP is also located in the sequence of CCND2-AS1, an anti-sense RNA. In this study, we explored the relationship between CCND2 and beta cell proliferation in humans, figuring out any possible regulations associated with CCND2-AS1. We obtained 49 pancreas samples from autopsies. Subjects were divided into 6 groups by age; fetus (F: gestational age 24 to 40 weeks), newborn (N: 0 days to1 month), infant (I: 2 to 12 months), toddler (T: 3 months to 4 years), child (C: 5 to 12 years), and adolescent (A: 13 to 19 years). Formalin-fixed paraffin-embedded sections were used for immunostaining and in situ hybridization analysis. Beta cell proliferation labeled with Ki67 was most abundant in N and rapidly decreased after T. Nuclear CCND2 expression was the highest in F followed by I and was almost not detected in C and A, showing a positive correlation with Ki67 though their peaks were different (p<0.01). CCND2 mRNA was abundant in F and N but was also detectable in C and A. The correlation between CCND2 mRNA and protein was linear (p=0.0513). On the other hand, the expression of CCND2-AS1 was significantly correlated with CCND2 protein and Ki67 (p<0.01 and <0.05). Antisense RNAs are reported to show a variety of post-transcriptional regulations on their corresponding mRNA and protein. Our results suggest that CCND2-AS1 may positively regulate CCND2 expression and be a provisional therapeutic target for beta cell proliferation. Disclosure S.Osonoi: None. T.Sasaki: None. Y.Takeuchi: None. H.Mizukami: None.

84-OR: Structure–Function Analysis of p57KIP2 in the Human Pancreatic Beta Cell Reveals a Canonical Bipartite Nuclear Localization Sequence (NLS)

p57KIP2 is a canonical cell cycle inhibitor encoded by the CDKN1C gene on chromosome 11. Mutations in CDKN1C underlie multiple pediatric endocrine syndromes including Beckwith-Wiedemann Syndrome (BWS), the Focal Variant of Congenital Hyperinsulinism (FoCHI), Insulinoma, Russel-Silver Syndrome and IMAGe Syndrome. Despite this central role in disease, little is known about the function of p57KIP2 in any cell type, including the human pancreatic beta cell. We hypothesized that p57KIP2 has functions that extend beyond cell cycle control and are unique to the human beta cell. We prepared RIP1 insulin promoter-driven adenoviruses encoding deletions of multiple putatively important and disease-associated but unexplored regions of p57KIP2 (WTp57, p57ΔPAPA, p57ΔCDKI, p57ΔPCNA and p57ΔNLS), and performed the first comprehensive structure-function analysis of CDKN1C/p57KIP2 in the human beta cell. RT-PCR and immunoblot analyses confirmed p57KIP2 overexpression, construct size and beta cell specificity in human islets. By immunocytochemistry, all constructs demonstrated nuclear localization, with the exception of a deletion mutant removing a putative NLS at amino acids 278-281. Unexpectedly, we identified a second NLS at amino acids 312-316. Further analysis showed that each individual NLS is required for nuclear localization of p57KIP2, but neither alone is sufficient to permit nuclear localization of p57KIP2. Finally, constructs containing both the 278-281 and 312-316 sequences were necessary and sufficient to target heterologous proteins to the nucleus of human beta cells. In summary, we discovered that p57KIP2 contains a classic bipartite NLS characterized by two clusters of positively charged amino acids 278KRKRS281 and 312RKRLR316 separated by a proline-rich linker region. Variants in the sequences encoding these two NLS sequences account for functional p57KIP2 loss and beta cell expansion seen in human disease. Disclosure L. Choleva: None. P. Wang: None. H. Liu: None. O. Wood: None. L. Lambertini: None. E. Karakose: None. A.F. Stewart: None.

1755-P: EndoC-ßH5 Is a Storable and Ready-to-Use Human Pancreatic Beta Cell That Can Model Type 1 and 2 Diabetes

EndoC-βH5 is a newly developed human pancreatic beta cell model and an optimized version among the EndoC-βH (EndoC-βH1/2/3) family. EndoC-βH5 cells are storable and ready-to-use and they robustly and reproducibly secrete insulin in response to glucose and incretins across experiments and laboratories. Specifically, they dose dependently respond to physiological concentrations of glucose. In addition, their response to GLP-1 and GIP receptor agonists is also highly reproducible and dose-dependent. Given the continuously increasing number of diabetes patients worldwide, the need for physiologically relevant human cellular models is greater than ever and EndoC-βH5 cells represent a novel human pancreatic beta cell solution that can help developing human diabetes models and drug screening and validation assays. In this study, we are developing pathological and drug screening models. EndoC-βH5 cells are sensitive to palmitate/high glucose as well as cytokine induced cell loss, recapitulating hallmarks of T2D. In addition, we evaluated impairment of insulin secretion and ER stress in these contexts in order to assess the mechanistic relevance of the models. We then addressed T1D modeling. We generated HLA-A2 expressing EndoC-βH5 cells and evaluated HLA-A2 alloreactive T lymphocyte activation and diabetogenic T lymphocyte induced cytotoxicity. Finally, we determined that EndoC-βH5 cells express functional glucagon (GCG) receptor, which contributes to the modulation of glucose induced insulin secretion, highlighting the potential of EndoC-βH5 as a model to study dual and triple GLP-1/GIP/GCG receptor agonists in a reproducible human cellular model. Overall, EndoC-βH5 cells appear to be a powerful tool to develop Type 1/2 diabetes and drug discovery models. Disclosure H.Olleik: None. B.Blanchi: Employee; Human Cell Design.

760-P: Discovery of GSBR-1290, a Highly Potent, Orally Available, Novel Small Molecule GLP-1 Receptor Agonist

Peptidic glucagon-like peptide 1 receptor agonists (GLP-1RAs) are established treatments for patients with Type 2 Diabetes Mellitus (T2DM) and obesity. However, the need for injection and cold chain storage may limit the utility of most peptidic GLP-1RAs. An oral small molecule GLP-1RA that offers enhanced bioavailability and stability could be more convenient and accessible to patients. Here we report the discovery of GSBR-1290, a highly potent, orally available, novel small molecule GLP-1RA and the characterization of its in vitro and in vivo pharmacology profiles. GSBR-1290 is a small molecule GLP-1RA with high binding affinity to human GLP-1R. GSBR-1290 strongly activated GLP-1R Gαs cAMP pathway without inducing measurable β-arrestin recruitment signaling, which indicates it is a fully biased agonist. The insulin secretion stimulation effect of GSBR-1290 was evaluated in a functional human pancreatic beta cell line, in which GSBR-1290 showed dose dependent induction of insulin secretion. The in vivo efficacy of GSBR-1290 on insulin secretion, glucose control and food intake were evaluated in nonhuman primates (NHPs). In an acute intravenous glucose tolerance test (ivGTT), a single dose of GSBR-1290 strongly induced insulin secretion and glucose clearance. In a repeated dosing study, GSBR-1290 administered orally once daily for 7-day demonstrated robust increase in insulin secretion and glucose clearance in ivGTT and a dose dependent reduction of food intake and body weight. Overall, GSBR-1290 demonstrated potent in vivo efficacy in stimulating insulin secretion, improving glucose tolerance, and reducing food intake and body weight. In conclusion, GSBR-1290 is a highly potent, orally available, fully biased GLP-1RA. Human clinical trials are underway to further evaluate GSBR-1290 as a potential therapy for T2DM and obesity. Disclosure T.Mao: Employee; Structuretx. X.Lin: Employee; Structure Therapeutics. Q.Meng: Employee; Beijing Stonewise Technology, Structure Therapeutics Inc. H.Zhang: Employee; Structuretx. J.J.Zhang: Employee; Structure Therapeutics Inc. S.Shi: Employee; Structure Therapeutics Inc. Z.Guan: Employee; Structure Therapeutics. X.Jiang: Employee; Structure Therapeutics. F.Zhang: Employee; Structure Therapeutics, Eternity BioSciences, Stock/Shareholder; Novo Nordisk. H.Lei: Employee; Structure Therapeutics.

Control of human pancreatic beta cell kinome by glucagon-like peptide-1 receptor biased agonism.

To determine the kinase activity profiles of human pancreatic beta cells downstream of glucagon-like peptide-1 receptor (GLP-1R) balanced versus biased agonist stimulations. This study analysed the kinomic profiles of human EndoC-βh1 cells following vehicle and GLP-1R stimulation with the pharmacological agonist exendin-4, as well as exendin-4-based biased derivatives exendin-phe1 and exendin-asp3 for acute (10-minute) versus sustained (120-minute) responses, using PamChip protein tyrosine kinase and serine/threonine kinase assays. The raw data were filtered and normalized using BioNavigator. The kinase analyses were conducted with R, mainly including kinase-substrate mapping and Kyoto Encyclopedia of Genes and Genomes pathway analysis. The present analysis reveals that kinomic responses are distinct for acute versus sustained GLP-1R agonist exposure, with individual responses associated with agonists presenting specific bias profiles. According to pathway analysis, several kinases, including JNKs, PKCs, INSR and LKB1, are important GLP-1R signalling mediators, constituting potential targets for further research on biased GLP-1R downstream signalling. The results from this study suggest that differentially biased exendin-phe1 and exendin-asp3 can modulate distinct kinase interaction networks. Further understanding of these mechanisms will have important implications for the selection of appropriate anti-type 2 diabetes therapies with optimized downstream kinomic profiles.

GLP-1R agonists demonstrate potential to treat Wolfram syndrome in human preclinical models

Aims/hypothesisWolfram syndrome is a rare autosomal recessive disorder caused by pathogenic variants in the WFS1 gene. It is characterised by insulin-dependent diabetes mellitus, optic nerve atrophy, diabetes insipidus, hearing loss and neurodegeneration. Considering the unmet treatment need for this orphan disease, this study aimed to evaluate the therapeutic potential of glucagon-like peptide 1 receptor (GLP-1R) agonists under wolframin (WFS1) deficiency with a particular focus on human beta cells and neurons.MethodsThe effect of the GLP-1R agonists dulaglutide and exenatide was examined in Wfs1 knockout mice and in an array of human preclinical models of Wolfram syndrome, including WFS1-deficient human beta cells, human induced pluripotent stem cell (iPSC)-derived beta-like cells and neurons from control individuals and individuals affected by Wolfram syndrome, and humanised mice.ResultsOur study shows that the long-lasting GLP-1R agonist dulaglutide reverses impaired glucose tolerance in WFS1-deficient mice, and that exenatide and dulaglutide improve beta cell function and prevent apoptosis in different human WFS1-deficient models including iPSC-derived beta cells from people with Wolfram syndrome. Exenatide improved mitochondrial function, reduced oxidative stress and prevented apoptosis in Wolfram syndrome iPSC-derived neural precursors and cerebellar neurons.Conclusions/interpretationOur study provides novel evidence for the beneficial effect of GLP-1R agonists on WFS1-deficient human pancreatic beta cells and neurons, suggesting that these drugs may be considered as a treatment for individuals with Wolfram syndrome.Graphical abstract

Epigenetic Changes Induced by High Glucose in Human Pancreatic Beta Cells.

Epigenetic changes in pancreatic beta cells caused by sustained high blood glucose levels, as seen in prediabetic conditions, may contribute to the etiology of diabetes. To delineate a direct cause and effect relationship between high glucose and epigenetic changes, we cultured human pancreatic beta cells derived from induced pluripotent stem cells and treated them with either high or low glucose, for 14 days. We then used the Arraystar 4x180K HG19 RefSeq Promoter Array to perform whole-genome DNA methylation analysis. A total of 478 gene promoters, out of a total of 23,148 present on the array (2.06%), showed substantial differences in methylation (p < 0.01). Out of these, 285 were hypomethylated, and 193 were hypermethylated in experimental vs. control. Ingenuity Pathway Analysis revealed that the main pathways and networks that were differentially methylated include those involved in many systems, including those related to development, cellular growth, and proliferation. Genes implicated in the etiology of diabetes, including networks involving glucose metabolism, insulin secretion and regulation, and cell cycle regulation, were notably altered. Influence of upstream regulators such as MRTFA, AREG, and NOTCH3 was predicted based on the altered methylation of their downstream targets. The study validated that high glucose levels can directly cause many epigenetic changes in pancreatic beta cells, suggesting that this indeed may be a mechanism involved in the etiology of diabetes.

Validating expression of beta cell maturation-associated genes in human pancreas development.

The identification of genes associated with human pancreatic beta cell maturation could stimulate a better understanding of normal human islet development and function, be informative for improving stem cell-derived islet (SC-islet) differentiation, and facilitate the sorting of more mature beta cells from a pool of differentiated cells. While several candidate factors to mark beta cell maturation have been identified, much of the data supporting these markers come from animal models or differentiated SC-islets. One such marker is Urocortin-3 (UCN3). In this study, we provide evidence that UCN3 is expressed in human fetal islets well before the acquisition of functional maturation. When SC-islets expressing significant levels of UCN3 were generated, the cells did not exhibit glucose-stimulated insulin secretion, indicating that UCN3 expression is not correlated with functional maturation in these cells. We utilized our tissue bank and SC-islet resources to test an array of other candidate maturation-associated genes, and identified CHGB, G6PC2, FAM159B, GLUT1, IAPP and ENTPD3 as markers with expression patterns that correlate developmentally with the onset of functional maturation in human beta cells. We also find that human beta cell expression of ERO1LB, HDAC9, KLF9, and ZNT8 does not change between fetal and adult stages.

A genome-wide CRISPR screen identifies CALCOCO2 as a regulator of beta cell function influencing type 2 diabetes risk

Identification of the genes and processes mediating genetic association signals for complex diseases represents a major challenge. As many of the genetic signals for type 2 diabetes (T2D) exert their effects through pancreatic islet-cell dysfunction, we performed a genome-wide pooled CRISPR loss-of-function screen in a human pancreatic beta cell line. We assessed the regulation of insulin content as a disease-relevant readout of beta cell function and identified 580 genes influencing this phenotype. Integration with genetic and genomic data provided experimental support for 20 candidate T2D effector transcripts including the autophagy receptor CALCOCO2. Loss of CALCOCO2 was associated with distorted mitochondria, less proinsulin-containing immature granules and accumulation of autophagosomes upon inhibition of late-stage autophagy. Carriers of T2D-associated variants at the CALCOCO2 locus further displayed altered insulin secretion. Our study highlights how cellular screens can augment existing multi-omic efforts to support mechanistic understanding and provide evidence for causal effects at genome-wide association studies loci.