PKA Signaling Drives Reticularis Differentiation and Sexually Dimorphic Adrenal Cortex Renewal

Overview

Journal JCI Insight

Specialties Biomedical Engineering
General Medicine

Date 2018 Jan 26

PMID 29367455

Citations 42

Authors

Typhanie Dumontet

Isabelle Sahut-Barnola

Amandine Septier

Nathanaelle Montanier

Ingrid Plotton

Florence Roucher-Boulez

Veronique Ducros

Anne-Marie Lefrancois-Martinez

Jean-Christophe Pointud

Mohamad Zubair

Ken-Ichirou Morohashi

David T Breault

Pierre Val

Antoine Martinez

Affiliations

Soon will be listed here.

Abstract

The adrenal cortex undergoes remodeling during fetal and postnatal life. How zona reticularis emerges in the postnatal gland to support adrenarche, a process whereby higher primates increase prepubertal androgen secretion, is unknown. Using cell-fate mapping and gene deletion studies in mice, we show that activation of PKA has no effect on the fetal cortex, while it accelerates regeneration of the adult cortex, triggers zona fasciculata differentiation that is subsequently converted into a functional reticularis-like zone, and drives hypersecretion syndromes. Remarkably, PKA effects are influenced by sex. Indeed, testicular androgens increase WNT signaling that antagonizes PKA, leading to slower adrenocortical cell turnover and delayed phenotype whereas gonadectomy sensitizes males to hypercorticism and reticularis-like formation. Thus, reticularis results from ultimate centripetal conversion of adult cortex under the combined effects of PKA and cell turnover that dictate organ size. We show that PKA-induced progenitor recruitment is sexually dimorphic and may provide a paradigm for overrepresentation of women in adrenal diseases.

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