Author
Listed:
- Benjamin D. Hopkins
(Weill Cornell Medicine)
- Chantal Pauli
(University Hospital Zurich
Weill Cornell Medicine-New York Presbyterian Hospital)
- Xing Du
(Columbia University Medical Center and New York Presbyterian Hospital)
- Diana G. Wang
(Weill Cornell Medicine
Weill Cornell Medicine/Rockefeller University/Sloan Kettering Tri-Institutional MD-PhD Program)
- Xiang Li
(Weill Cornell Graduate School of Medical Sciences)
- David Wu
(Weill Cornell Medicine)
- Solomon C. Amadiume
(Weill Cornell Medicine)
- Marcus D. Goncalves
(Weill Cornell Medicine
Weill Cornell Medicine)
- Cindy Hodakoski
(Weill Cornell Medicine)
- Mark R. Lundquist
(Weill Cornell Medicine)
- Rohan Bareja
(Weill Cornell Medicine
Weill Cornell Medicine-New York Presbyterian Hospital
Institute for Computational Biomedicine, Weill Cornell Medicine)
- Yan Ma
(Columbia University Medical Center and New York Presbyterian Hospital)
- Emily M. Harris
(Columbia University Medical Center and New York Presbyterian Hospital)
- Andrea Sboner
(Weill Cornell Medicine
Weill Cornell Medicine-New York Presbyterian Hospital
Institute for Computational Biomedicine, Weill Cornell Medicine
Weill Cornell Medicine)
- Himisha Beltran
(Weill Cornell Medicine
Weill Cornell Medicine-New York Presbyterian Hospital
Weill Cornell Medicine)
- Mark A. Rubin
(Weill Cornell Medicine-New York Presbyterian Hospital
University of Bern and the Inselspital)
- Siddhartha Mukherjee
(Columbia University Medical Center and New York Presbyterian Hospital)
- Lewis C. Cantley
(Weill Cornell Medicine)
Abstract
Mutations in PIK3CA, which encodes the p110α subunit of the insulin-activated phosphatidylinositol-3 kinase (PI3K), and loss of function mutations in PTEN, which encodes a phosphatase that degrades the phosphoinositide lipids generated by PI3K, are among the most frequent events in human cancers1,2. However, pharmacological inhibition of PI3K has resulted in variable clinical responses, raising the possibility of an inherent mechanism of resistance to treatment. As p110α mediates virtually all cellular responses to insulin, targeted inhibition of this enzyme disrupts glucose metabolism in multiple tissues. For example, blocking insulin signalling promotes glycogen breakdown in the liver and prevents glucose uptake in the skeletal muscle and adipose tissue, resulting in transient hyperglycaemia within a few hours of PI3K inhibition. The effect is usually transient because compensatory insulin release from the pancreas (insulin feedback) restores normal glucose homeostasis3. However, the hyperglycaemia may be exacerbated or prolonged in patients with any degree of insulin resistance and, in these cases, necessitates discontinuation of therapy3–6. We hypothesized that insulin feedback induced by PI3K inhibitors may reactivate the PI3K–mTOR signalling axis in tumours, thereby compromising treatment effectiveness7,8. Here we show, in several model tumours in mice, that systemic glucose–insulin feedback caused by targeted inhibition of this pathway is sufficient to activate PI3K signalling, even in the presence of PI3K inhibitors. This insulin feedback can be prevented using dietary or pharmaceutical approaches, which greatly enhance the efficacy/toxicity ratios of PI3K inhibitors. These findings have direct clinical implications for the multiple p110α inhibitors that are in clinical trials and provide a way to increase treatment efficacy for patients with many types of tumour.
Suggested Citation
Benjamin D. Hopkins & Chantal Pauli & Xing Du & Diana G. Wang & Xiang Li & David Wu & Solomon C. Amadiume & Marcus D. Goncalves & Cindy Hodakoski & Mark R. Lundquist & Rohan Bareja & Yan Ma & Emily M., 2018.
"Suppression of insulin feedback enhances the efficacy of PI3K inhibitors,"
Nature, Nature, vol. 560(7719), pages 499-503, August.
Handle:
RePEc:nat:nature:v:560:y:2018:i:7719:d:10.1038_s41586-018-0343-4
DOI: 10.1038/s41586-018-0343-4
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Citations
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Cited by:
- Nishanth Ulhas Nair & Patricia Greninger & Xiaohu Zhang & Adam A. Friedman & Arnaud Amzallag & Eliane Cortez & Avinash Das Sahu & Joo Sang Lee & Anahita Dastur & Regina K. Egan & Ellen Murchie & Miche, 2023.
"A landscape of response to drug combinations in non-small cell lung cancer,"
Nature Communications, Nature, vol. 14(1), pages 1-19, December.
- Ziwei Dai & Weiyan Zheng & Jason W. Locasale, 2022.
"Amino acid variability, tradeoffs and optimality in human diet,"
Nature Communications, Nature, vol. 13(1), pages 1-13, December.
- Miyuki Nomura & Mai Ohuchi & Yoshimi Sakamoto & Kei Kudo & Keisuke Yaku & Tomoyoshi Soga & Yuki Sugiura & Mami Morita & Kayoko Hayashi & Shuko Miyahara & Taku Sato & Yoji Yamashita & Shigemi Ito & Nao, 2023.
"Niacin restriction with NAMPT-inhibition is synthetic lethal to neuroendocrine carcinoma,"
Nature Communications, Nature, vol. 14(1), pages 1-15, December.
- Meredith L. Jenkins & Harish Ranga-Prasad & Matthew A. H. Parson & Noah J. Harris & Manoj K. Rathinaswamy & John E. Burke, 2023.
"Oncogenic mutations of PIK3CA lead to increased membrane recruitment driven by reorientation of the ABD, p85 and C-terminus,"
Nature Communications, Nature, vol. 14(1), pages 1-14, December.
- Xiao-Li Wei & Fu-Rong Liu & Ji-Hong Liu & Hong-Yun Zhao & Yang Zhang & Zhi-Qiang Wang & Miao-Zhen Qiu & Fei Xu & Qiu-Qiong Yu & Yi-Wu Du & Yan-Xia Shi & De-Sheng Wang & Feng-Hua Wang & Rui-Hua Xu, 2022.
"First-in-human phase Ia study of the PI3Kα inhibitor CYH33 in patients with solid tumors,"
Nature Communications, Nature, vol. 13(1), pages 1-10, December.
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