Project description:The lower glucose-responsiveness of neonatal beta cells is generally considered a sign of endocrine immaturity. We compared mRNA profiles of neonatal and 10-weeks old rat beta cells to see how their gene expression changes with functional maturation. Neonatal beta cells showed a lower glucose-inducible increment in insulin production than adult cells. This was in part explained by basal protein synthetic hyperactivity of neonatal cells: while at 2.5mM glucose 80% of neonatal beta cells were recruited into active protein synthesis, 10 mM glucose was required to achieve a similar fraction of active adult beta cells. Besides this progressive recruitment, glucose exerted in both age groups an additional amplifying effect in the recruited cells, but clearly more so in adult beta cells that showed a higher maximal synthetic capacity/cell. Neonatal beta cells balanced an advanced endocrine differentiation as judged by their mRNA expression of conserved beta cell marker genes, with higher expression of genes involved in cell cycle and development. One example, Delta-like 1 homolog (DLK1) was used to investigate if neonatal beta cells with basal hyperactivity corresponded to a more immature subset, as marked by high DLK1. Neonatal pancreas contained distinct subsets of DLK1high and DLK1low insulin-expressing cells, but both showed equal hyperactivity. We conclude that neonatal beta cells combine advanced endocrine maturation with traits of residual developmental immaturity. If DLK1 is used as marker for the latter, the basal hyperactivity which proved to be a cardinal feature of neonatal beta cells is not a direct reflection of their residual immaturity. A genome-wide view on postnatal maturation/differentiation of the rat beta cells The study compares Affymetrix RG230.20 expression profiles of 3 cell subsets: (1) HSSC: a population of cells isolated from post natal day 2-3 rat pancreas that is enriched (65-70%) in insulin cells (n=3), (2) LSSC: a population of cells isolated from postnatal day 2-3 rat pancreas that is mostly devoid of endocrine cells, and selected by its low side scatter (n=3); and (3) adult beta: a reference population of FACS-purified adult rat beta cells (>90% insulin+) freshly isolated from pancreas of 10 weeks-old rats (n=5). RNA was extracted from the cells immediately after isolation, without further treatment or culture. Details of the isolation procedure and extensive microscopic characterization of the preps are described in the accompanying scientific paper by Martens GA et al.

Project description:Neonatal beta cells are considered developmentally immature and hence less glucose-responsive. To study the acquisition of mature glucose-responsiveness, we compared glucose-regulated redox state, insulin synthesis and secretion of beta cells purified from neonatal or 10-weeks old rats to their transcriptomes and proteomes measured by oligonucleotide and LC-MS/MS profiling. Lower glucose-responsiveness of neonatal beta cells was explained by two distinct properties: higher activity at low glucose and lower activity at high glucose. Basal hyperactivity was associated with higher NAD(P)H, a higher fraction of neonatal beta cells actively incorporating 3H-Tyrosine, and persistently increased insulin secretion below 5 mM glucose. Neonatal beta cells lacked the steep glucose-responsive NAD(P)H rise between 5-10 mM glucose characteristic for adult beta cells, and accumulated less NAD(P)H at high glucose. They had 2-fold lower expression of malate/aspartate-NADH shuttle and most glycolytic enzymes. Genome-wide profiling situated neonatal beta cells at a developmental crossroad: they showed advanced endocrine differentiation when specifically analyzed for their mRNA/protein level of classical neuroendocrine markers. On the other hand, discrete neonatal beta cell subpopulations still expressed mRNAs/proteins typical for developing/proliferating tissues. One example, Delta-like 1 homolog (DLK1) was used to investigate if neonatal beta cells with basal hyperactivity corresponded to a more immature subset with high DLK1, but no association was found. In conclusion, the current study supports the importance of glycolytic NADH-shuttling in stimulus-function coupling, presents basal hyperactivity as novel property of neonatal beta cells, and provides potential markers to recognize intercellular developmental differences in the endocrine pancreas.

Project description:Fetal and neonatal beta cells have poor glucose-induced insulin secretion and only gain robust glucose responsiveness several weeks after birth. This unresponsiveness may be due to a generalized immaturity of the metabolic pathways normally found in beta cells. Gene expression profile of neonatal (1 day old) and young adult (6 weeks old) Sprague-Dawley rat islets were evaluated and compared.

Project description:Fetal and neonatal beta cells have poor glucose-induced insulin secretion and only gain robust glucose responsiveness several weeks after birth. This unresponsiveness may be due to a generalized immaturity of the metabolic pathways normally found in beta cells. Gene expression profile of neonatal (1 day old) and young adult (6 weeks old) Sprague-Dawley rat islets were evaluated and compared.

Project description:Fetal and neonatal beta cells have poor glucose-induced insulin secretion and only gain robust glucose responsiveness several weeks after birth. This unresponsiveness may be due to a generalized immaturity of the metabolic pathways normally found in beta cells. Gene expression profile of neonatal (1 day old) and young adult (6 weeks old) Sprague-Dawley rat islets were evaluated and compared. Frozen sections were obtained from pancreases of neonatal (1 day old) and young adult (6 weeks old) Sprague-Dawley rats. The beta cell enriched cores of the islets were excised using laser capture microdissection. RNA was extracted, amplified and subjected to microarray analysis.

Project description:Neonatal beta-cells undergo a maturation process to acquire glucose responsiveness. We hypothesize that in later life, a partial reversal of this maturation might promote beta-cell dysfunction. We previously ascertained that fetuin-A, a fetal glycoprotein downregulated at birth but increasingly secreted when fatty liver develops, inhibits insulin secretion. Here, we evaluate fetuin-A’s impact on beta-cell maturation. In vitro maturation of neonatal porcine islet cell clusters (NICCs) promoted expression of beta-cell markers and TGFBR/SMAD signaling. Fetuin-A reduced both functional and proliferative gene expression and SMAD phosphorylation. Consequently, fetuin-A impaired glucose- and forskolin-dependent secretion, and reduced adaptive beta-cell proliferation. In adult human islets, fetuin-A abolished glucose responsiveness, diminished SMAD phosphorylation and downregulated functional and proliferative genes. Our findings suggest that perinatal decline of fetuin-A relieves TGFBR signaling in neonatal beta-cells, thereby facilitating the onset of postnatal maturation. However, this program remains revocable during adulthood, since fatty liver-derived fetuin-A reverses beta-cells’ maturity, conferring them a neonatal-like phenotype and contributing to their failure.

Project description:Stem cell-derived β (SC-β) cells are an emerging regenerative therapy to compensate for loss of functional β cell mass in diabetes. Glucose-stimulated insulin secretion in SC-β cells is variable in vitro but stabilizes after transplantation and maturation under the kidney capsule of mice. We identified mechanisms correlated with functional maturation using RNA-sequencing and co-expression network analysis. In vivo maturation enhanced glucose-stimulated but not basal insulin secretion, up-regulated β cell hormones IAPP and ADCYAP1, increased expression of maturation markers MAFA, UCN3, and SIX2, and resolved endocrine identity of incompletely specified polyhormonal cells produced during differentiation. Transplantation promoted calcium signalling, induced exocytotic machinery supporting hormone secretion and improved stimulus-secretion coupling that fine-tunes insulin secretion. Growth hormone signalling emerged as candidate driver of in vivo maturation and was confirmed in vitro. Also, a large co-expression module correlated with HbA1c and was enriched in genes up-regulated during in vivo maturation but down-regulated in hyperglycaemic and palmitate stress conditions, suggesting that transcriptional maturation of SC-β cells in vivo mirrors processes lost in diabetic β cells.

Project description:Gene expression analysis of the differentiation process of iPS cells to pancreatic islet cells has revealed that expression of CD82 defines a subset of iPS cell-derived pancreatic endocrine progenitors (EP). While some cell surface proteins such as CD142, CD200 and SUSD2 have been reported as markers of pancreatic progenitor (PP) and EP, CD82+ EP cells are distinct from those PP and EP characterized by the previously identified markers. CD82+ cells isolated from EP cells efficiently differentiated into pancreatic endocrine cells, particularly β cells. Also, CD82+ cells isolated from human cadaver pancreases secreted insulin in response to a high glucose concentration. Furthermore, blocking of CD82 expression by siRNA or inhibition of CD82 in EP by monoclonal antibodies suppressed maturation of β cells, indicating that CD82 plays a role for maturation of EP to β cells. In conclusion, this study identified CD82 not only as a useful marker to isolate β cell precursors but also as an important molecule for functional maturation of β cells.

Project description:During pancreas development, endocrine progenitors differentiate into the islet-cell subtypes, which undergo further functional maturation in postnatal islet development. In islet b-cells, genes involved in glucose-stimulated insulin secretion are activated and glucose exposure increases the insulin response as b-cells mature. Here, we investigated the role of H3K4 trimethylation in endocrine cell differentiation and functional maturation by disrupting TrxG complex histone methyltransferase activity in mouse endocrine progenitors. In the embryo, genetic inactivation of TrxG component Dpy30 in NEUROG3+ cells did not affect the number of endocrine progenitors or endocrine cell differentiation. H3K4 trimethylation was progressively lost in postnatal islets and the mice displayed elevated non-fasting and fasting glycemia, as well as impaired glucose tolerance by postnatal day 24. Although postnatal endocrine cell proportions were equivalent to controls, islet RNA-sequencing revealed a downregulation of genes involved in glucose-stimulated insulin secretion and an upregulation of immature b-cell genes. Comparison of histone modification enrichment profiles in NEUROG3+ endocrine progenitors and mature islets suggested that genes downregulated by loss of H3K4 trimethylation more frequently acquire active histone modifications during maturation. Taken together, these findings suggest that H3K4 trimethylation is required for the activation of genes involved in the functional maturation of pancreatic islet endocrine cells.

Project description:The mouse pituitary gland undergoes vivid maturation immediately after birth. During this process, the local stem cell compartment shows signs of activation including elevated abundance and expression of stemness pathways when compared to adult pituitary stem cells. In addition, we found that the neonatal pituitary displays high regeneration efficiency, as occurring following diphtheria toxin (DT)-triggered endocrine cell-ablation injury using the GHCre/iDTR mouse model (expressing Cre recombinase under control of the growth hormone (Gh) promoter, as well as Cre-inducible (floxed) DT receptor (iDTR)). This regeneration is more pronounced than in older mice, which is in line with the activated (stem cell) nature of the neonatal gland. However, it is not known what molecular mechanisms underlie the stem cell activation status in the neonatal gland. Here, we set out to decode the stem cells’ phenotype during the neonatal pituitary maturation stage starting from single cell RNA-sequencing (scRNA-seq) interrogations of neonatal (postnatal day 7, PD7) normal (undamaged) and damaged pituitary (more specifically, its major endocrine anterior lobe).