Biguanides Antithetically Regulate Tumor Properties by the Dose-dependent Mitochondrial Reprogramming-driven C-Src Pathway

Overview

Journal Cell Rep Med

Publisher Cell Press

Specialties Biology
General Medicine

Date 2025 Feb 11

PMID 39933530

Authors

Jun Hyoung Park

Kwang Hwa Jung

Dongya Jia

Sukjin Yang

Kuldeep S Attri

Songyeon Ahn

Divya Murthy

Tagari Samanta

Debasmita Dutta

Meron Ghidey

Somik Chatterjee

Seung Yeop Han

Diego A Pedroza

Abha Tiwari

Joyce V Lee

Caitlin Davis

Shuting Li

Vasanta Putluri

Chad J Creighton

Nagireddy Putluri

Lacey E Dobrolecki

Michael T Lewis

Jeffrey M Rosen

Jose N Onuchic

Andrei Goga

Benny Abraham Kaipparettu

Affiliations

Soon will be listed here.

Abstract

The biguanide metformin attenuates mitochondrial oxidation and is proposed as an anti-cancer therapy. However, recent clinical studies suggest increased proliferation and fatty acid β-oxidation (FAO) in a subgroup of patients with breast cancer (BC) after metformin therapy. Considering that FAO can activate Src kinase in aggressive triple-negative BC (TNBC), we postulate that low-dose biguanide-driven AMPK-ACC-FAO signaling may activate the Src pathway in TNBC. The low bioavailability of metformin in TNBC xenografts mimics metformin's in vitro low-dose effect. Pharmacological or genetic inhibition of FAO significantly enhances the anti-tumor properties of biguanides. Lower doses of biguanides induce and higher doses suppress Src signaling. Dasatinib and metformin synergistically inhibit TNBC patient-derived xenograft growth, but not in high-fat diet-fed mice. This combination also suppresses TNBC metastatic progression. A combination of biguanides with Src inhibitors provides synergy to target metastatic TNBC suffering with limited treatment options.

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