Innervation of the pancreas in development and disease.

The autonomic nervous system innervates the pancreas by sympathetic, parasympathetic and sensory branches during early organogenesis, starting with neural crest cell invasion and formation of an intrinsic neuronal network. Several studies have demonstrated that signals from pancreatic neural crest cells direct pancreatic endocrinogenesis. Likewise, autonomic neurons have been shown to regulate pancreatic islet formation, and have also been implicated in type I diabetes.

Quantifying spatial position in a branched structure in immunostained mouse tissue sections.

We have developed a protocol to quantify the position of a cell in a branched structure based on two-dimensional microscopy images of tissue sections. Biological branched structures include organs such as the lungs, kidneys, and pancreas. In these organs, cell fate has been correlated with position, based on a qualitative estimate.

Flow cytometry detection of surface and intracellular antigens in pancreas from a single mouse embryo.

We here report a flow-cytometry-based protocol to measure single-cell protein expression in small samples. The protocol is optimized for simultaneous detection of fluorescent proteins and intracellular and surface antigens in the embryonic pancreas from the mouse. Owing to low cell numbers, current protocols for flow cytometric analysis of embryonic tissues rely on tissue pooling.

p120ctn-Mediated Organ Patterning Precedes and Determines Pancreatic Progenitor Fate.

The mechanism of how organ shape emerges and specifies cell fate is not understood. Pancreatic duct and endocrine lineages arise in a spatially distinct domain from the acinar lineage. Whether these lineages are pre-determined or settle once these niches have been established remains unknown.

Erratum: EGFR signalling controls cellular fate and pancreatic organogenesis by regulating apicobasal polarity.

This corrects the article DOI: 10.1038/ncb3628.

EGFR signalling controls cellular fate and pancreatic organogenesis by regulating apicobasal polarity.

Apicobasal polarity is known to affect epithelial morphogenesis and cell differentiation, but it remains unknown how these processes are mechanistically orchestrated. We find that ligand-specific EGFR signalling via PI(3)K and Rac1 autonomously modulates apicobasal polarity to enforce the sequential control of morphogenesis and cell differentiation. Initially, EGF controls pancreatic tubulogenesis by negatively regulating apical polarity induction.

Growth Factor Independence-1 () Is Required for Pancreatic Acinar Unit Formation and Centroacinar Cell Differentiation.

Background & Aims: The genetic specification of the compartmentalized pancreatic acinar/centroacinar unit is poorly understood. Growth factor independence-1 () is a zinc finger transcriptional repressor that regulates hematopoietic stem cell maintenance, pre-T-cell differentiation, formation of granulocytes, inner ear hair cells, and the development of secretory cell types in the intestine. As / is expressed in human and rodent pancreas, we characterized the potential function of in mouse pancreatic development.

Notch-mediated post-translational control of Ngn3 protein stability regulates pancreatic patterning and cell fate commitment.

Ngn3 is recognized as a regulator of pancreatic endocrine formation, and Notch signaling as an important negative regulator Ngn3 gene expression. By conditionally controlling expression of Ngn3 in the pancreas, we find that these two signaling components are dynamically linked. This connection involves transcriptional repression as previously shown, but also incorporates a novel post-translational mechanism.

Fibroblast growth factor 10 represses premature cell differentiation during establishment of the intestinal progenitor niche.

Spatio-temporal regulation of the balance between cell renewal and cell differentiation is of vital importance for embryonic development and adult homeostasis. Fibroblast growth factor signaling relayed from the mesenchyme to the epithelium is necessary for progenitor maintenance during organogenesis of most endoderm-derived organs, but it is still ambiguous whether the signal is exclusively mitogenic. Furthermore, the downstream mechanisms are largely unknown.

Conditional control of the differentiation competence of pancreatic endocrine and ductal cells by Fgf10.

Fgf10 is a critical component of mesenchymal-to-epithelial signaling during endodermal development. In the Fgf10 null pancreas, the embryonic progenitor population fails to expand, while ectopic Fgf10 expression forces progenitor arrest and organ hyperplasia. Using a conditional Fgf10 gain-of-function model, we observed that the timing of Fgf10 expression affected the cellular competence of the arrested pancreatic progenitors.

FGF10 maintains distal lung bud epithelium and excessive signaling leads to progenitor state arrest, distalization, and goblet cell metaplasia.

Background: Interaction with the surrounding mesenchyme is necessary for development of endodermal organs, and Fibroblast growth factors have recently emerged as mesenchymal-expressed morphogens that direct endodermal morphogenesis. The fibroblast growth factor 10 (Fgf10) null mouse is characterized by the absence of lung bud development. Previous studies have shown that this requirement for Fgf10 is due in part to its role as a chemotactic factor during branching morphogenesis.

ETS-family genes in pancreatic development.

ETS-family factors play major roles in development and cancer, notably as critical targets for extra-cellular signaling pathways, including MAPK-signaling. Given the presently limited knowledge on the role of ETS-factors in pancreatic development, we here sought to characterize all 26 individual members of the ETS-family in relation to pancreatic development using a combination of genomics, RT-PCR, and histological techniques. This analysis uncovers 22 ETS family genes displaying select spatial and temporal expression patterns in the developing pancreas.

FGF10 signaling controls stomach morphogenesis.

Maintenance of progenitor cell properties in development is required for proper organogenesis of most organs, including those derived from the endoderm. FGF10 has been shown to play a role in both lung and pancreatic development. Here we find that FGF10 signaling controls stomach progenitor maintenance, morphogenesis and cellular differentiation.