Deconstructing the principles of ductal network formation in the pancreas.

The mammalian pancreas is a branched organ that does not exhibit stereotypic branching patterns, similarly to most other glands. Inside branches, it contains a network of ducts that undergo a transition from unconnected microlumen to a mesh of interconnected ducts and finally to a treelike structure. This ductal remodeling is poorly understood, both on a microscopic and macroscopic level.

Stochastic priming and spatial cues orchestrate heterogeneous clonal contribution to mouse pancreas organogenesis.

Spatiotemporal balancing of cellular proliferation and differentiation is crucial for postnatal tissue homoeostasis and organogenesis. During embryonic development, pancreatic progenitors simultaneously proliferate and differentiate into the endocrine, ductal and acinar lineages. Using in vivo clonal analysis in the founder population of the pancreas here we reveal highly heterogeneous contribution of single progenitors to organ formation.

The molecular and morphogenetic basis of pancreas organogenesis.

The pancreas is an essential endoderm-derived organ that ensures nutrient metabolism via its endocrine and exocrine functions. Here we review the essential processes governing the embryonic and early postnatal development of the pancreas discussing both the mechanisms and molecules controlling progenitor specification, expansion and differentiation. We elaborate on how these processes are orchestrated in space and coordinated with morphogenesis.

Cell cycle-dependent differentiation dynamics balances growth and endocrine differentiation in the pancreas.

Organogenesis relies on the spatiotemporal balancing of differentiation and proliferation driven by an expanding pool of progenitor cells. In the mouse pancreas, lineage tracing at the population level has shown that the expanding pancreas progenitors can initially give rise to all endocrine, ductal, and acinar cells but become bipotent by embryonic day 13.5, giving rise to endocrine cells and ductal cells.

TH17 cell induction and effects of IL-17A and IL-17F blockade in experimental colitis.

Background: T helper (TH) 17 cells are believed to play a pivotal role in development of inflammatory bowel disease, and their contribution to intestinal inflammation has been studied in various models of colitis. TH17 cells produce a range of cytokines, some of which are potential targets for immunotherapy. However, blockade of IL-17A alone with secukinumab was not effective in Crohn's disease.

B cells exposed to enterobacterial components suppress development of experimental colitis.

Background: B cells positively contribute to immunity by antigen presentation to CD4(+) T cells, cytokine production, and differentiation into antibody secreting plasma cells. Accumulating evidence implies that B cells also possess immunoregulatory functions closely linked to their capability of IL-10 secretion.

Methods: Colitis development was followed in CD4(+) CD25(-) T cell transplanted SCID mice co-transferred with B cells exposed to an enterobacterial extract (ebx-B cells).