Single-cell Atlas of Developing Murine Adrenal Gland Reveals Relation of Schwann Cell Precursor Signature to Neuroblastoma Phenotype

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2021 Jan 27

PMID 33500353

Citations 35

Authors

Evelyn S Hanemaaijer

Thanasis Margaritis

Karin Sanders

Frank L Bos

Tito Candelli

Hanin Al-Saati

Max M van Noesel

Friederike A G Meyer-Wentrup

Marc van de Wetering

Frank C P Holstege

Hans Clevers

Affiliations

Soon will be listed here.

Abstract

Neuroblastoma is the most common extracranial solid tumor and accounts for ∼10% of pediatric cancer-related deaths. The exact cell of origin has yet to be elucidated, but it is generally accepted that neuroblastoma derives from the neural crest and should thus be considered an embryonal malignancy. About 50% of primary neuroblastoma tumors arise in the adrenal gland. Here, we present an atlas of the developing mouse adrenal gland at a single-cell level. Five main cell cluster groups (medulla, cortex, endothelial, stroma, and immune) make up the mouse adrenal gland during fetal development. The medulla group, which is of neural crest origin, is further divided into seven clusters. Of interest is the Schwann cell precursor ("SCP") and the "neuroblast" cluster, a highly cycling cluster that shares markers with sympathoblasts. The signature of the medullary SCP cluster differentiates neuroblastoma patients based on disease phenotype: The SCP signature score anticorrelates with ALK and MYCN expression, two indicators of poor prognosis. Furthermore, a high SCP signature score is associated with better overall survival rates. This study provides an insight into the developing adrenal gland and introduces the SCP gene signature as being of interest for further research in understanding neuroblastoma phenotype.

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