The Selector Gene Pax7 Dictates Alternate Pituitary Cell Fates Through Its Pioneer Action on Chromatin Remodeling

Overview

Journal Genes Dev

Specialty Molecular Biology

Date 2012 Oct 17

PMID 23070814

Citations 74

Authors

Lionel Budry

Aurelio Balsalobre

Yves Gauthier

Konstantin Khetchoumian

Aurore Lhonore

Sophie Vallette

Thierry Brue

Dominique Figarella-Branger

Bjorn Meij

Jacques Drouin

Affiliations

Soon will be listed here.

Abstract

The anterior and intermediate lobes of the pituitary gland derive from the surface ectoderm. They provide a simple system to assess mechanisms of developmental identity established by tissue determinants. Each lobe contains a lineage expressing the hormone precursor pro-opiomelanocortin (POMC): the corticotropes and melanotropes. The T-box transcription factor Tpit controls terminal differentiation of both lineages. We now report on the unique role of Pax7 as a selector of intermediate lobe and melanotrope identity. Inactivation of the Pax7 gene results in loss of melanotrope gene expression and derepression of corticotrope genes. Pax7 acts by remodeling chromatin and allowing Tpit binding to a new subset of enhancers for activation of melanotrope-specific genes. Thus, the selector function of Pax7 is exerted through pioneer transcription factor activity. Genome-wide, the Pax7 pioneer activity is preferentially associated with composite binding sites that include paired and homeodomain motifs. Pax7 expression is conserved in human and dog melanotropes and defines two subtypes of pituitary adenomas causing Cushing's disease. In summary, expression of Pax7 provides a unique tissue identity to the pituitary intermediate lobe that alters Tpit-driven differentiation through pioneer and classical transcription factor activities.

Citing Articles

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