Defining a Novel Role for the Pdx1 Transcription Factor in Islet β-Cell Maturation and Proliferation During Weaning.

Spaeth JM, Gupte M, Perelis M, Yang YP, Cyphert H, Guo S, Liu JH, Guo M, Bass J, Magnuson MA, Wright C, Stein R
Diabetes. 2017 66 (11): 2830-2839

PMID: 28705881 · PMCID: PMC5652607 · DOI:10.2337/db16-1516

The transcription factor encoded by the gene is a critical transcriptional regulator, as it has fundamental actions in the formation of all pancreatic cell types, islet β-cell development, and adult islet β-cell function. Transgenic- and cell line-based experiments have identified 5'-flanking conserved sequences that control pancreatic and β-cell type-specific transcription, which are found within areas I (bp -2694 to -2561), II (bp -2139 to -1958), III (bp -1879 to -1799), and IV (bp -6200 to -5670). Because of the presence in area IV of binding sites for transcription factors associated with pancreas development and islet cell function, we analyzed how an endogenous deletion mutant affected expression embryonically and postnatally. The most striking result was observed in male mutant mice after 3 weeks of birth (i.e., the onset of weaning), with only a small effect on pancreas organogenesis and no deficiencies in their female counterparts. Compromised Pdx1 mRNA and protein levels in weaned male mutant β-cells were tightly linked with hyperglycemia, decreased β-cell proliferation, reduced β-cell area, and altered expression of Pdx1-bound genes that are important in β-cell replication, endoplasmic reticulum function, and mitochondrial activity. We discuss the impact of these novel findings to gene regulation and islet β-cell maturation postnatally.

© 2017 by the American Diabetes Association.

MeSH Terms (11)

Animals Cell Proliferation Gene Expression Regulation Homeodomain Proteins Insulin-Secreting Cells Male Mice Mice, Knockout Oxidative Phosphorylation Trans-Activators Weaning

Connections (5)

This publication is referenced by other Labnodes entities:

Links