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The Journal of Clinical Investigation logoLink to The Journal of Clinical Investigation
. 1993 Sep;92(3):1349–1356. doi: 10.1172/JCI116708

Pancreatic gastrin stimulates islet differentiation of transforming growth factor alpha-induced ductular precursor cells.

T C Wang 1, S Bonner-Weir 1, P S Oates 1, M Chulak 1, B Simon 1, G T Merlino 1, E V Schmidt 1, S J Brand 1
PMCID: PMC288276  PMID: 8376589

Abstract

Gastrin is transiently expressed in fetal islets during a critical period of their development from protodifferentiated islet precursors in fetal pancreatic ducts. To examine the possible role of gastrin as an islet cell growth factor, postnatal islet growth was studied in transgenic mice which overexpress gastrin and TGF alpha in their pancreas. Overexpression of a TGF alpha transgene causes metaplastic ductules containing numerous insulin expressing cells that resemble protodifferentiated precursors of the fetal pancreas. However, islet mass of the TGF alpha transgenic mice was not increased. Pancreatic overexpression of gastrin from a chimeric insulin/gastrin transgene transcribed from the insulin promoter markedly decreased the TGF alpha-stimulated increase in pancreatic duct mass. Furthermore, pancreatic coexpression of both gastrin and TGF alpha significantly increased islet mass in mice expressing both transgenes. These findings indicate that TGF alpha and gastrin can act synergistically to stimulate islet growth, although neither peptide alone is sufficient. Islet growth may possibly be stimulated through gastrin promoting the differentiation of insulin-positive cells in the TGF alpha-induced metaplastic ducts. This transgenic study suggests that islet neogenesis can be reactivated in the ductular epithelium of the adult pancreas by local expression of two growth factors, gastrin and TGF alpha.

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Selected References

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