Author
Listed:
- Moran Amit
(The University of Texas MD Anderson Cancer Center)
- Hideaki Takahashi
(The University of Texas MD Anderson Cancer Center
Yokohama City University)
- Mihnea Paul Dragomir
(The University of Texas MD Anderson Cancer Center)
- Antje Lindemann
(The University of Texas MD Anderson Cancer Center)
- Frederico O. Gleber-Netto
(The University of Texas MD Anderson Cancer Center)
- Curtis R. Pickering
(The University of Texas MD Anderson Cancer Center)
- Simone Anfossi
(The University of Texas MD Anderson Cancer Center)
- Abdullah A. Osman
(The University of Texas MD Anderson Cancer Center)
- Yu Cai
(The University of Texas MD Anderson Cancer Center)
- Rong Wang
(The University of Texas MD Anderson Cancer Center)
- Erik Knutsen
(The University of Texas MD Anderson Cancer Center
UiT, The Arctic University of Norway)
- Masayoshi Shimizu
(The University of Texas MD Anderson Cancer Center
The University of Texas MD Anderson Cancer Center)
- Cristina Ivan
(The University of Texas MD Anderson Cancer Center
The University of Texas MD Anderson Cancer Center)
- Xiayu Rao
(The University of Texas MD Anderson Cancer Center)
- Jing Wang
(The University of Texas MD Anderson Cancer Center)
- Deborah A. Silverman
(The University of Texas MD Anderson Cancer Center)
- Samantha Tam
(The University of Texas MD Anderson Cancer Center)
- Mei Zhao
(The University of Texas MD Anderson Cancer Center)
- Carlos Caulin
(University of Arizona
University of Arizona)
- Assaf Zinger
(Houston Methodist Research Institute
Houston Methodist Hospital)
- Ennio Tasciotti
(Houston Methodist Research Institute
Houston Methodist Hospital)
- Patrick M. Dougherty
(The University of Texas MD Anderson Cancer Center)
- Adel El-Naggar
(The University of Texas MD Anderson Cancer Center)
- George A. Calin
(The University of Texas MD Anderson Cancer Center
The University of Texas MD Anderson Cancer Center)
- Jeffrey N. Myers
(The University of Texas MD Anderson Cancer Center
The University of Texas MD Anderson Cancer Center)
Abstract
The solid tumour microenvironment includes nerve fibres that arise from the peripheral nervous system1,2. Recent work indicates that newly formed adrenergic nerve fibres promote tumour growth, but the origin of these nerves and the mechanism of their inception are unknown1,3. Here, by comparing the transcriptomes of cancer-associated trigeminal sensory neurons with those of endogenous neurons in mouse models of oral cancer, we identified an adrenergic differentiation signature. We show that loss of TP53 leads to adrenergic transdifferentiation of tumour-associated sensory nerves through loss of the microRNA miR-34a. Tumour growth was inhibited by sensory denervation or pharmacological blockade of adrenergic receptors, but not by chemical sympathectomy of pre-existing adrenergic nerves. A retrospective analysis of samples from oral cancer revealed that p53 status was associated with nerve density, which was in turn associated with poor clinical outcomes. This crosstalk between cancer cells and neurons represents mechanism by which tumour-associated neurons are reprogrammed towards an adrenergic phenotype that can stimulate tumour progression, and is a potential target for anticancer therapy.
Suggested Citation
Moran Amit & Hideaki Takahashi & Mihnea Paul Dragomir & Antje Lindemann & Frederico O. Gleber-Netto & Curtis R. Pickering & Simone Anfossi & Abdullah A. Osman & Yu Cai & Rong Wang & Erik Knutsen & Mas, 2020.
"Loss of p53 drives neuron reprogramming in head and neck cancer,"
Nature, Nature, vol. 578(7795), pages 449-454, February.
Handle:
RePEc:nat:nature:v:578:y:2020:i:7795:d:10.1038_s41586-020-1996-3
DOI: 10.1038/s41586-020-1996-3
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