A Novel Metabolic Reprogramming Strategy for the Treatment of Diabetes‐Associated Breast Cancer

Qiongyu Hao; Zhimin Huang; Qun Li; Dingxie Liu; Piwen Wang; Kun Wang; Jieqing Li; Wei Cao; Wenhong Deng; Ke Wu; Rui Su; Zhongmin Liu; Jay Vadgama; Yong Wu

doi:10.1002/advs.202102303

Advanced Science (Feb 2022)

A Novel Metabolic Reprogramming Strategy for the Treatment of Diabetes‐Associated Breast Cancer

Qiongyu Hao,
Zhimin Huang,
Qun Li,
Dingxie Liu,
Piwen Wang,
Kun Wang,
Jieqing Li,
Wei Cao,
Wenhong Deng,
Ke Wu,
Rui Su,
Zhongmin Liu,
Jay Vadgama,
Yong Wu

Affiliations

Qiongyu Hao: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Zhimin Huang: Key Laboratory of Cell Differentiation and Apoptosis Ministry of Education Department of Pathophysiology Shanghai Jiao‐Tong University School of Medicine Shanghai 200025 China
Qun Li: Department of Oncology Shanghai East Hospital School of Medicine Tongji University Shanghai 200123 China
Dingxie Liu: Bluewater Biotech LLC New Providence NJ 07974 USA
Piwen Wang: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Kun Wang: Department of Breast Cancer Cancer Center Guangdong Provincial People's Hospital & Guangdong Academy of Medical Sciences Guangzhou 510080 China
Jieqing Li: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Wei Cao: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Wenhong Deng: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Ke Wu: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Rui Su: College of Engineering University of California Berkeley CA 94720 USA
Zhongmin Liu: The Institute for Biomedical Engineering & Nano Science Shanghai East Hospital Tongji University School of Medicine Shanghai 200120 China
Jay Vadgama: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA
Yong Wu: Division of Cancer Research and Training Department of Internal Medicine Charles Drew University of Medicine and Science David Geffen UCLA School of Medicine and UCLA Jonsson Comprehensive Cancer Center Los Angeles CA 90095 USA

DOI: https://doi.org/10.1002/advs.202102303
Journal volume & issue: Vol. 9, no. 6
pp. n/a – n/a

Abstract

Read online

Abstract Diabetes is directly related to the risk of breast cancer (BC) occurrence and worsened BC prognosis. Currently, there are no specific treatments for diabetes‐associated BC. This paper aims to understand the fundamental mechanisms of diabetes‐induced BC progression and to develop personalized treatments. It reports a metabolic reprogramming strategy (MRS) that pharmaceutical induction of glucose import and glycolysis with metformin and NF‐κB inhibitor (NF‐κBi) while blocking the export of excessive lactate via inhibiting monocarboxylate transporter 4 (MCT4) leads to a metabolic crisis within the cancer cells. It demonstrates that the MRS shifts the metabolism of BC cells toward higher production of lactate, blocks lactate secretion, prompts intracellular acidification and induces significant cytotoxicity. Moreover, a novel MCT4 inhibitor CB‐2 has been identified by structure‐based virtual screening. A triple combination of metformin, CB‐2, and trabectedin, a drug that impedes NF‐κB signaling, strongly inhibits BC cells. Compared to normal glucose condition, MRS elicits more potent cancer cell‐killing effects under high glucose condition. Animal model studies show that diabetic conditions promote the proliferation and progression of BC xenografts in nude mice and that MRS treatment significantly inhibits HG‐induced BC progression. Therefore, inhibition of MCT4 combined with metformin/NF‐κBi is a promising cancer therapy, especially for diabetes‐associated BC.

Published in Advanced Science

ISSN: 2198-3844 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Science
Website: https://onlinelibrary.wiley.com/journal/21983844

About the journal

Abstract

Keywords