Project description:To better understand the mechanism by which HES1 regulates pancreas development we took advantage of recent developments in directed differentiation of human embryonic stem cells (hESCs) to the pancreatic endocrine lineage via a series of progenitor stages (Figure 1 and (Rezania et al., 2014). Using the iCRISPR platform (González et al., 2014), we introduced indels in the HES1 and NEUROG3 genes, either singly or in combination in iCRISPR H1 cells. Using previously described gRNAs (Zhu et al., 2016) to target exon2 of the NEUROG3 gene and exon2 of the HES1 gene we detected by Sanger and RNA-sequencing a 2 bp insertion and a T insertion, respectively, resulting in premature STOP codons in two/multiple clonal cell lines carrying the introduced mutation and the loss of NEUROG3 by immunostaining We then subjected two or more clonal lines of H1-iCRISPR (wildtype), HES1−/−, NEUROG3−/− and HES1−/−NEUROG3−/− (abbreviated H1N3-dKO or H1−/−N3−/−) to differentiation to β-like cells using a modified version of the protocol from Rezania et al. (2014). Marker analysis showed that all cell lines maintained pluripotency (OCT4+) as hESC and were able to differentiate to FOXA2+ and SOX17+ co-positive definitive endoderm (DE, Day 3), PDX1+ cells at the posterior foregut stage (PF, Day 7), to bipotent progenitors marked by PDX1+ and NKX6-1+ at the Pancreatic Endoderm stage (PE, Day 10), and the Endocrine Precursor stage (EP, Day 13)

Project description:Human pluripotent stem cells were differentiated into PDX1+/NKX6-1+ Pancreatic Progenitors (PPd15 cells), which were subsequently captured and expanded in culture. These culture Pancreatic Progenitors (cPP cells) were capable of self-renewal and could be passaged up to 20 times. Furthermore, cPP cells were capable of differentiation into multiple pancreatic lineages, including c-peptide+ beta-like cells, both in vitro and in vivo.

Project description:Insm1 cooperates with Neurod1 and Foxa2 to maintain mature pancreatic β-cell function (Insm1, Neurod1 and Foxa2 ChipSeq data from pancreatic beta cell)

Project description:To investigate transcriptomic changes associated with Nkx6-2, we overexpressed Nkx6-2 in murine IPMN-associated pancreatic cancer cells by lentivirus transduction and performed bulk RNA-sequencing

Project description:Pancreatic β-cells are responsible for production and secretion of insulin in response to increasing blood glucose levels. Therefore, defects in pancreatic β-cell function lead to hyperglycemia and diabetes mellitus. Understanding the molecular mechanisms governing β cell function is crucial for development of novel treatment strategies for this disease. The aim of this project was to investigate the role of Cnot3, part of CCR4-NOT complex, major deadenylase complex in mammals, in pancreatic β cell function. Cnot3βKO islets display decreased expression of key regulators of β cell maturation and function. Moreover, they show an increase of progenitor cell markers, β cell-disallowed genes and genes relevant to altered β cell function. Cnot3βKO islets exhibit altered deadenylation and increased mRNA stability, partly accounting for the increase of those genes. Together, these data reveal that CNOT3-mediated mRNA deadenylation and decay constitute previously unsuspected post-transcriptional mechanisms essential for β cell identity.

Project description:Aims/hypothesis Pancreatic beta cells maintain glucose homeostasis and beta cell dysfunction is a major risk factor in developing diabetes. Therefore, understanding the developmental regulatory networks that define a fully functional beta cell is important for elucidating the genetic origins of the disease. Aldehyde dehydrogenase activity has been associated with stem/progenitor cells and we have previously shown that Aldh1b1 is specifically expressed in pancreas progenitor pools. Here we address the hypothesis that Aldh1b1 may regulate the timing of the appearance and eventual functionality of beta cells. Methods We generated an Aldh1b1-knockout mouse line (Aldh1b1tm1lacZ) and used this to study pancreatic development, beta cell functionality and glucose homeostasis in the absence of Aldh1b1 function. Results Differentiation in the developing pancreas of Aldh1b1tm1lacZ null mice was accelerated. Transcriptome analyses of newborn and adult islets showed misregulation of key beta cell transcription factors and genes crucial for beta cell function. Functional analyses showed that glucose-stimulated insulin secretion was severely compromised in islets isolated from null mice. Several key features of beta cell functionality were affected, including control of oxidative stress, glucose sensing, stimulus-coupling secretion and secretory granule biogenesis. As a result of beta cell dysfunction, homozygous mice developed glucose intolerance and age-dependent hyperglycaemia. Conclusions/interpretation These findings show that Aldh1b1 influences the timing of the transition from the pancreas endocrine progenitor to the committed beta cell and demonstrate that changes in the timing of this transition lead to beta cell dysfunction and thus constitute a diabetes risk factor later in life.

Project description:Mediator, a co-regulator required for RNA pol II activity, interacts with tissue-specific transcription factors to regulate development and maintain homeostasis. We sought to understand whether Mediator subunit MED15 acts as a node that controls tissue-specific gene expression, using pancreatic insulin-producing β-cell maturation as a model. We found Med15 to be expressed during mouse pancreatic organogenesis and β-cell maturation; moreover, islets from human T2D donors feature reduced MED15 expression. Loss of Med15 in mouse β-cells caused defects in maturation without affecting β-cell mass or insulin expression. ChIP-seq and co-immunoprecipitation analyses determined that Med15 binds β-cell transcription factors Nkx6-1 and NeuroD1 to regulate key β-cell maturation genes. Human embryonic stem cell derived β-like cells, genetically engineered to express high levels of MED15, had increased maturation markers and improved insulin secretion. We provide the first evidence of the importance of Mediator in β-cell maturation and demonstrate an additional layer of control that tunes transcription factor function.

Project description:The winged helix transcription factor Foxa2 regulates Pdx1 gene expression and fetal endocrine pancreas development. We show here by inducible gene ablation that Foxa2 inactivation in mature beta-cells induces hyperinsulinemic hypoglycemia in Foxa2loxP/loxP, Pdx1-CreERT2 adult mice. Mutant beta-cells exhibited a markedly increased pool of docked insulin granules, some of which were engaged in sequential or compound exocytosis, consistent with an increased first phase glucose-stimulated insulin secretion. Expression of multiple genes involved in vesicular trafficking, membrane targeting and fuel-secretion pathways is dependent on Foxa2. In addition, impaired cytosolic Ca2+ oscillations and elevated intracellular cAMP production accompanied this secretory defect, and were likely contributors to the sensitization of the exocytotic machinery. Thus, in the absence of Foxa2, alterations in intracellular second messenger signaling redistribute the insulin granules into the readily releasable pool. We conclude that Foxa2 is required both for the fetal pancreas development and for the function of mature beta-cells.

Project description:CEL mutation carriers may have increased pancreatic cancer risk. We used microarrays to detail the global programme of gene expression underlying pancreatic cancer progression in a CEL mutation carrier and non-CEL mutation pancreatic cancer patients + controls.

Project description:RXRA regulates transcription as part of a heterodimer with 14 other nuclear receptors, including the peroxisome proliferator-activated receptors (PPARs). Analysis from the TCGA raised the possibility that hyperactive PPAR signaling, either due to PPAR gamma gene amplification or RXRA hot-spot mutation (S427F/Y) drives 20-25% of bladder cancers. Here we characterize mutant RXRA, demonstrating it induces enhancer/promoter activity in the context of RXRA/PPAR heterodimers. Structure-function studies indicate the RXRA substitution allosterically regulates the PPAR AF2 domain via an aromatic interaction with the terminal tyrosine found in PPARs. In urothelium, we find PPAR agonism is sufficient to drive growth factor independent growth, but only after deletion of the tumor suppressors Kdm6a and Trp53. Similarly, mutant RXRA stimulates growth factor independent growth, in a manner reversible by PPAR inhibition. These studies reveal a pro-tumorigenic interaction between loss of tumor suppressors and PPAR activation and implicate PPARs as targetable drivers of bladder cancer.