The Simultaneous Loss of Arx and Pax4 Genes Promotes a Somatostatin-producing Cell Fate Specification at the Expense of the Alpha- and Beta-cell Lineages in the Mouse Endocrine Pancreas

Overview

Journal Development

Specialty Biology

Date 2005 Jun 3

PMID 15930104

Citations 96

Authors

Patrick Collombat

Jacob Hecksher-Sorensen

Vania Broccoli

Jens Krull

Ilaria Ponte

Tabea Mundiger

Julian Smith

Peter Gruss

Palle Serup

Ahmed Mansouri

Affiliations

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Abstract

The specification of the different mouse pancreatic endocrine subtypes is determined by the concerted activities of transcription factors. However, the molecular mechanisms regulating endocrine fate allocation remain unclear. In the present study, we uncover the molecular consequences of the simultaneous depletion of Arx and Pax4 activity during pancreas development. Our findings reveal a so far unrecognized essential role of the paired-box-encoding Pax4 gene. Specifically, in the combined absence of Arx and Pax4, an early-onset loss of mature alpha- and beta-cells occurs in the endocrine pancreas, concomitantly with a virtually exclusive generation of somatostatin-producing cells. Furthermore, despite normal development of the PP-cells in the double-mutant embryos, an atypical expression of the pancreatic polypeptide (PP) hormone was observed in somatostatin-labelled cells after birth. Additional characterizations indicate that such an expression of PP was related to the onset of feeding, thereby unravelling an epigenetic control. Finally, our data provide evidence that both Arx and Pax4 act as transcriptional repressors that control the expression level of one another, thereby mediating proper endocrine fate allocation.

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