Author
Listed:
- Holly Newton
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Yi-Fang Wang
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Laura Camplese
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Joao B. Mokochinski
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Holger B. Kramer
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- André E. X. Brown
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Louise Fets
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
- Susumu Hirabayashi
(Medical Research Council London Institute of Medical Sciences
Imperial College London)
Abstract
Cancer cells demand excess nutrients to support their proliferation, but how tumours exploit extracellular amino acids during systemic metabolic perturbations remain incompletely understood. Here, we use a Drosophila model of high-sugar diet (HSD)-enhanced tumourigenesis to uncover a systemic host-tumour metabolic circuit that supports tumour growth. We demonstrate coordinate induction of systemic muscle wasting with tumour-autonomous Yorkie-mediated SLC36-family amino acid transporter expression as a proline-scavenging programme to drive tumourigenesis. We identify Indole-3-propionic acid as an optimal amino acid derivative to rationally target the proline-dependency of tumour growth. Insights from this whole-animal Drosophila model provide a powerful approach towards the identification and therapeutic exploitation of the amino acid vulnerabilities of tumourigenesis in the context of a perturbed systemic metabolic network.
Suggested Citation
Holly Newton & Yi-Fang Wang & Laura Camplese & Joao B. Mokochinski & Holger B. Kramer & André E. X. Brown & Louise Fets & Susumu Hirabayashi, 2020.
"Systemic muscle wasting and coordinated tumour response drive tumourigenesis,"
Nature Communications, Nature, vol. 11(1), pages 1-13, December.
Handle:
RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-18502-9
DOI: 10.1038/s41467-020-18502-9
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