Opposing Wnt Signals Regulate Cervical Squamocolumnar Homeostasis and Emergence of Metaplasia

Overview

Journal Nat Cell Biol

Specialty Cell Biology

Date 2021 Jan 19

PMID 33462395

Citations 47

Authors

Cindrilla Chumduri

Rajendra Kumar Gurumurthy

Hilmar Berger

Oliver Dietrich

Naveen Kumar

Stefanie Koster

Volker Brinkmann

Kirstin Hoffmann

Marina Drabkina

Panagiota Arampatzi

Dajung Son

Uwe Klemm

Hans-Joachim Mollenkopf

Hermann Herbst

Mandy Mangler

Jorg Vogel

Antoine-Emmanuel Saliba

Thomas F Meyer

Affiliations

Soon will be listed here.

Abstract

The transition zones of the squamous and columnar epithelia constitute hotspots for the emergence of cancer, often preceded by metaplasia, in which one epithelial type is replaced by another. It remains unclear how the epithelial spatial organization is maintained and how the transition zone niche is remodelled during metaplasia. Here we used single-cell RNA sequencing to characterize epithelial subpopulations and the underlying stromal compartment of endo- and ectocervix, encompassing the transition zone. Mouse lineage tracing, organoid culture and single-molecule RNA in situ hybridizations revealed that the two epithelia derive from separate cervix-resident lineage-specific stem cell populations regulated by opposing Wnt signals from the stroma. Using a mouse model of cervical metaplasia, we further show that the endocervical stroma undergoes remodelling and increases expression of the Wnt inhibitor Dickkopf-2 (DKK2), promoting the outgrowth of ectocervical stem cells. Our data indicate that homeostasis at the transition zone results from divergent stromal signals, driving the differential proliferation of resident epithelial lineages.

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