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	Fig. 2. Change in gene expression in the exocrine pancreas during metamorphosis. (A–D and I–L) In situ hybridization with amylase (A–D) and Ptf1a (I–L) probes. Every mRNA encoding a “terminally differentiated” exocrine protein that we have tested is extinguished at metamorphic climax (NF62) to the same extent as these 2 mRNAs (see discussion). (E–H) Although amylase mRNA is extinguished at climax, amylase protein was still detected by immunohistochemistry, confirming the dedifferentiation stages of previously differentiated exocrine cells. (Scale bar: 40 μm.)
	Fig. 3. Change in gene expression in the exocrine pancreas during metamorphosis. (A–C) In situ hybridization with PDX-1 probes. PDX-1 is expressed exclusively in islet cells in the tadpole (A) and frog pancreases (C), and at climax expression is extended to the dedifferentiated exocrine cells (B). (D–I) Notch-1 (D–F) and Hes-1 (G–I) genes are activated at climax, although low level of expression of Notch-1 and Hes-1 has been observed at premetamorphic and adult frogs. (Scale bar: 40 μm.)
	Fig. 7. Schematic representation of morphological and gene expression changes in the exocrine pancreas during X. laevis metamorphosis. The adult frog pancreas has all of the types of ducts that have been described for adult vertebrates. Tadpoles lack the intercalated ducts. At the climax of metamorphosis, TH induces dedifferentiation of the exocrine pancreas to a progenitor state that has extinguished the mRNAs encoding terminally differentiated proteins (represented by amylase). PDX-1, Notch-1, and Hes-1 are up-regulated. Late in climax Ptf1a is reactivated followed by the differentiation of acinar and duct cells. Abbreviations: ac-acinar; ld-lobular duct, icd-intercalated duct. Figure is not drawn to scale.

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