Project description:Human pancreas development remains incompletely characterized due to restricted sample access. We investigate whether pigs resemble humans in pancreas development, offering a complementary large-animal model. As pig pancreas organogenesis is unexplored, we first annotate developmental hallmarks throughout its 114-day gestation. Building on this, we construct a pig single-cell multiome pancreas atlas across all trimesters. Cross-species comparisons reveal pig closely resembles human in developmental tempo, epigenetic and transcriptional regulation, and gene regulatory networks. This further extends to progenitor dynamics and endocrine fate acquisition. Transcription factors regulated by NEUROG3, the endocrine master regulator, are over 50% conserved between pig and human, many being validated in human stem cell models. Notably, we uncover that during embryonic development, emerging beta-cell heterogeneity coincides with a species-conserved primed endocrine cell (PEC) population alongside NEUROG3-expressing cells. Overall, our work lays the foundation for comparative investigations and offers unprecedented insights into evolutionary-conserved pancreas organogenesis mechanisms across animal models.

Project description:Human pancreas development remains incompletely understood due to limited sample access constrained by ethical and practical considerations. Here we investigate whether pigs resemble humans in pancreas development more closely than rodents, and as such, offer a valuable alternative large-animal model. As pig pancreas organogenesis is unexplored, we first annotated developmental hallmarks and lineage markers of pancreas differentiation and morphogenesis throughout the 114-day gestation. Building on this detailed roadmap, we further constructed a pig single-cell multiome atlas capturing temporal resolution across all three trimesters. Cross-species comparisons with human and mouse time-resolved integrated pancreas atlases accentuated that pig closely resembled human in developmental tempo, epigenetic and transcriptional regulation, gene expression patterns and gene regulatory networks (GRNs). Specifically, pig mimicked the dynamics of progenitor status, differentiation trajectories and GRNs governing endocrine fate acquisition in human. In pig multiome GRN, over 40% of transcription factors targeted by NEUROG3, the endocrine master regulator, were confirmed in human stem cell models. Most notably, we uncovered beta-cell heterogeneity arising during embryonic development, owing to endocrine induction in pancreatic progenitors with temporally altered epigenetic and transcriptional identity. Overall, our work lays the foundation for using pigs to model human pancreas biology and provides unprecedented insights into developmental principles and mechanisms across species.

Project description:Human pancreas development remains incompletely understood due to limited sample access constrained by ethical and practical considerations. Here we investigate whether pigs resemble humans in pancreas development more closely than rodents, and as such, offer a valuable alternative large-animal model. As pig pancreas organogenesis is unexplored, we first annotated developmental hallmarks and lineage markers of pancreas differentiation and morphogenesis throughout the 114-day gestation. Building on this detailed roadmap, we further constructed a pig single-cell multiome atlas capturing temporal resolution across all three trimesters. Cross-species comparisons with human and mouse time-resolved integrated pancreas atlases accentuated that pig closely resembled human in developmental tempo, epigenetic and transcriptional regulation, gene expression patterns and gene regulatory networks (GRNs). Specifically, pig mimicked the dynamics of progenitor status, differentiation trajectories and GRNs governing endocrine fate acquisition in human. In pig multiome GRN, over 40% of transcription factors targeted by NEUROG3, the endocrine master regulator, were confirmed in human stem cell models. Most notably, we uncovered beta-cell heterogeneity arising during embryonic development, owing to endocrine induction in pancreatic progenitors with temporally altered epigenetic and transcriptional identity. Overall, our work lays the foundation for using pigs to model human pancreas biology and provides unprecedented insights into developmental principles and mechanisms across species.

Project description:Human pancreas development remains incompletely understood due to limited sample access constrained by ethical and practical considerations. Here we investigate whether pigs resemble humans in pancreas development more closely than rodents, and as such, offer a valuable alternative large-animal model. As pig pancreas organogenesis is unexplored, we first annotated developmental hallmarks and lineage markers of pancreas differentiation and morphogenesis throughout the 114-day gestation. Building on this detailed roadmap, we further constructed a pig single-cell multiome atlas capturing temporal resolution across all three trimesters. Cross-species comparisons with human and mouse time-resolved integrated pancreas atlases accentuated that pig closely resembled human in developmental tempo, epigenetic and transcriptional regulation, gene expression patterns and gene regulatory networks (GRNs). Specifically, pig mimicked the dynamics of progenitor status, differentiation trajectories and GRNs governing endocrine fate acquisition in human. In pig multiome GRN, over 40% of transcription factors targeted by NEUROG3, the endocrine master regulator, were confirmed in human stem cell models. Most notably, we uncovered beta-cell heterogeneity arising during embryonic development, owing to endocrine induction in pancreatic progenitors with temporally altered epigenetic and transcriptional identity. Overall, our work lays the foundation for using pigs to model human pancreas biology and provides unprecedented insights into developmental principles and mechanisms across species.

Project description:Although a large set of data is available concerning organogenesis in animal models, information remains scarce on human organogenesis. In this work, we performed temporal mapping of human fetal pancreatic organogenesis using cell surface markers. We demonstrate that in the human fetal pancreas at 7 weeks of development, the glycoprotein 2 (GP2) marks a multipotent cell population that will differentiate either into the acinar, ductal and endocrine lineages. Development towards the acinar lineage is paralleled by a substantial increase in GP2 expression. Conversely, a subset of the multipotent GP2+ population undergoes endocrine differentiation by down-regulating GP2 and CD142 and turning on NEUROG3, an early marker of endocrine differentiation. Endocrine maturation will progress by up-regulating SUSD2 and lowering ECAD levels. Finally, we show that in vitro differentiation of pancreatic endocrine cells derived from human pluripotent stem cells mimics key in vivo events. Our work constitutes a powerful approach to more precisely define intermediate cell population during conversion of multipotent progenitors into the 3 main human pancreatic cell types (acinar, ductal and endocrine) in vivo. As such, the data pave the way to extend our understanding of the origin of mature human pancreatic cell types and how such lineage decisions are regulated.

Project description:Retinoic acid (RA) signaling is essential for multiple developmental processes, including appropriate pancreas formation from the foregut endoderm. RA is also required to generate pancreatic progenitors from human pluripotent stem cells. However, the role of RA during the later stages of pancreas development is not well understood. In this study, we generated an inducible system to block RA signaling and demonstrate that disruption of the RA pathway within the Neurog3-expressing endocrine progenitor population is required for appropriate mouse b cell differentiation and repression of critical d cell genes, including Somatostatin. In addition, inhibition of the RA pathway in hESC-derived pancreatic progenitors downstream of NEUROG3 induction impairs INSULIN expression. We further determined that RA-regulation of endocrine cell differentiation is mediated through Wnt pathway components. Together, these data demonstrate the importance of RA signaling in endocrine specification and identify conserved mechanisms by which RA signaling directs endocrine cell fate.

Project description:Since loss of Hes1 and Notch signalling drives progenitors to the endocrine lineage, we set up a pancreas explant system with crosses of heterozygous Neurog3tTA/+, a knock-in allele which makes the homozygote Neurog3tTA/tTA embryos deficient in Neurog3 (hereafter Neurog3-null). Hereby endocrine differentiation is impeded and we can study the Neurog3-independent role of Notch signalling by DAPT inhibition of γ-secretase. E12.5 wildtype and Neurog3-null pancreata were explanted on fibronectin, grown for 3 days, and then treated with vehicle control (0.1% DMSO) or DAPT for 24h. RNA was isolated and subjected to Agilent microarray analysis

Project description:Atoh8 is a transcription factor of the basic-helix-loop-helix (bHLH) family that is expressed in multiple tissues during embryonic development but whose specific functions remain unknown. The gene encoding Atoh8 is induced by various lineage- determining bHLH transcription factors in cell culture, suggesting a possible common role of this gene in multiple bHLH-driven differentiation programs. In the pancreas, the pro-endocrine bHLH factors Neurogenin3 (Neurog3) and NeuroD1 activate Atoh8 expression. Moreover, Atoh8 is expressed in the embryonic pancreas confirming its participation in the pancreatic transcriptional cascade. This work aims at gaining insight into the molecular function of Atoh8 during the endocrine differentiation program initiated by Neurog3 in the pancreas. To this aim, we have generated a recombinant adenovirus encoding an Atoh8-specific shRNA (Ad-shAtoh8) and used it to down-regulate expression of the Atoh8 gene in Neurog3-expressing pancreatic ductal cells (mPAC), a cellular model of endocrine cell differentiation. Thus, we have compared global changes in gene expression profiles between cells treated with Ad-Neurog3+shControl and cells treated with Ad-Neurog3+shAtoh8 using Affymetrix microarrays. Our results show that Atoh8 silencing significantly affects the expression of 293 genes in Neurog3-expressing mPAC cells. Gene Ontology analysis has revealed cell cycle as the biological function most significantly represented among the modified genes. These results uncover a potential function of Math6 as a regulator of cell cycle progression and provide novel insights into the link between Neurog3 and the regulation of the cell cycle.

Project description:Atoh8 is a transcription factor of the basic-helix-loop-helix (bHLH) family that is expressed in multiple tissues during embryonic development but whose specific functions remain unknown. The gene encoding Atoh8 is induced by various lineage- determining bHLH transcription factors in cell culture, suggesting a possible common role of this gene in multiple bHLH-driven differentiation programs. In the pancreas, the pro-endocrine bHLH factors Neurogenin3 (Neurog3) and NeuroD1 activate Atoh8 expression. Moreover, Atoh8 is expressed in the embryonic pancreas confirming its participation in the pancreatic transcriptional cascade. This work aims at gaining insight into the molecular function of Atoh8 during the endocrine differentiation program initiated by Neurog3 in the pancreas. To this aim, we have generated a recombinant adenovirus encoding an Atoh8-specific shRNA (Ad-shAtoh8) and used it to down-regulate expression of the Atoh8 gene in Neurog3-expressing pancreatic ductal cells (mPAC), a cellular model of endocrine cell differentiation. Thus, we have compared global changes in gene expression profiles between cells treated with Ad-Neurog3+shControl and cells treated with Ad-Neurog3+shAtoh8 using Affymetrix microarrays. Our results show that Atoh8 silencing significantly affects the expression of 293 genes in Neurog3-expressing mPAC cells. Gene Ontology analysis has revealed cell cycle as the biological function most significantly represented among the modified genes. These results uncover a potential function of Math6 as a regulator of cell cycle progression and provide novel insights into the link between Neurog3 and the regulation of the cell cycle. mPAC cells (mouse pancreatic duct cells) overexpressing Neurogenin3 were divided in 2 groups according to the shRNA encoded by the recombinant adenoviruses used: 1) Scramble shRNA (control for the infection effect), 2) Atonal Homolog 8-specific shRNA. Experiment was performed three independent times (3 independent biological replicates).

Project description:RNA-seq of FACS Sorted E10.5 Pdx1-GFP+ of genotypes wildtype and Hes1-/-. Summary statement The developmental mechanisms that cause ectopic pancreas are poorly understood. We show that aberrant dorsal pancreas morphogenesis in Hes1 mutants leads to ectopic pancreas depending on the pro-endocrine gene Neurog3. Abstract Mutations in Hes1, a target gene of the Notch signalling pathway, lead to ectopic pancreas by a poorly described mechanism. Here we use genetic inactivation of Hes1 combined with lineage tracing in mouse embryos to reveal an endodermal requirement for Hes1 and that most ectopic pancreas tissue is derived from the E8.5 dorsal pancreas primordium. RNA-seq data from sorted E10.5 Pdx1-GFP+ cells from Hes1+/+ and Hes1−/− suggested that upregulation of endocrine lineage genes in Hes1−/− embryos was the major defect in the endoderm and accordingly early pancreas morphogenesis was normalised and the ectopic pancreas phenotype suppressed in Hes1−/−Neurog3−/− embryos. Analysis of other Notch pathway mutants uncovered a total depletion of progenitors in Mib1 deficient dorsal anlage, which was replaced by an anterior Gcg+ extension. Together, our results demonstrate that aberrant morphogenesis is the cause of ectopic pancreas and that a part of the endocrine differentiation program is mechanistically involved in the dysgenesis. Our results suggest that the ratio of endocrine lineage to progenitor cells is important for morphogenesis and that a strong endocrinogenic phenotype without complete progenitor depletion as seen in Hes1 mutants provokes an extreme dysgenesis that causes ectopic pancreas.