The Molecular Mechanisms behind Advanced Breast Cancer Metabolism: Warburg Effect, OXPHOS, and Calcium

Mitaishvili, Erna; Feinsod, Hanna; David, Zachary; Shpigel, Jessica; Fernandez, Chelsea; Sauane, Moira; de la Parra, Columba

doi:10.31083/j.fbl2903099

Front. Biosci. (Landmark Ed)

2024

DOI: 10.31083/j.fbl2903099

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The Molecular Mechanisms behind Advanced Breast Cancer Metabolism: Warburg Effect, OXPHOS, and Calcium

Erna Mitaishvili,

Hanna Feinsod,

Zachary David

et al.

Abstract: Altered metabolism represents a fundamental difference between cancer cells and normal cells. Cancer cells have a unique ability to reprogram their metabolism by deviating their reliance from primarily oxidative phosphorylation (OXPHOS) to glycolysis, in order to support their survival. This metabolic phenotype is referred to as the “Warburg effect” and is associated with an increase in glucose uptake, and a diversion of glycolytic intermediates to alternative pathways that support anabolic processes. These pr… Show more

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Cited by 4 publications

References 132 publications

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Mechanism of the Warburg effect and its role in breast cancer immunotherapy

Saheed,

Aromolaran,

Atoyebi

et al. 2024

Discov Med

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Breast cancer remains a significant global health concern affecting millions of women annually. An essential aspect of this disease is the Warburg effect, which is a metabolic characteristic exhibited in cancer cells. It involves an elevated uptake of glucose and the diversion of glycolytic intermediates toward alternative pathways that facilitate anabolic activities. This distinctive metabolic change sustains rapid cell division and survival, establishing a conducive environment for tumor expansion and spread, altering the tumor microenvironment, fostering immune evasion, angiogenesis, and resistance to treatments. Studying the Warburg effect presents a promising opportunity in the fight against breast cancer. Exploring the relationship between the Warburg effect and immune responses is a promising prospect for immunotherapy, to reinstate the body's inherent capacity to combat cancer. The Warburg effect has provided valuable insights into the management of nonaggressive breast cancer subtypes. This review examines the complex mechanisms of the Warburg effect and its impact on breast cancer treatment. This review discusses innovative strategies to suppress this effect to improve the management and fight against this destructive disease.

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Mechanism of the Warburg effect and its role in breast cancer immunotherapy

Saheed,

Aromolaran,

Atoyebi

et al. 2024

Discov Med

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Novel Inhibition of Central Carbon Metabolism Pathways by Rac and CDC42 inhibitor MBQ167 and Paclitaxel

Cruz-Collazo,

Katsara,

Grafals-Ruiz

et al. 2024

Molecular Cancer Therapeutics

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Triple negative breast cancer (TNBC) represents a therapeutic challenge where standard chemotherapy is limited to paclitaxel. MBQ-167, a clinical stage small molecule inhibitor that targets Rac and Cdc42, inhibits tumor growth and metastasis in mouse models of TNBC. Herein, we investigated the efficacy of MBQ-167 in combination with paclitaxel in TNBC pre-clinical models, as a prelude to safety trials of this combination in advanced breast cancer patients. Individual MBQ-167 or combination therapy with paclitaxel was more effective at reducing TNBC cell viability and increasing apoptosis compared to paclitaxel alone. In orthotopic mouse models of human TNBC (MDA-MB-231 and MDA-MB-468), individual MBQ-167, paclitaxel, or the combination reduced mammary tumor growth with similar efficacy, with no apparent liver toxicity. However, paclitaxel single agent treatment significantly increased lung metastasis, while MBQ-167, single or combined, reduced lung metastasis. In the syngeneic 4T1/BALB/c model, combined MBQ-167 and paclitaxel decreased established lung metastases by ~80%. To determine the molecular basis for the improved efficacy of the combined treatment on metastasis, 4T1 tumor extracts from BALB/c mice treated with MBQ-167, paclitaxel, or the combination were subjected to transcriptomic analysis. Gene set enrichment identified specific downregulation of central carbon metabolic pathways by the combination of MBQ-167 and Paclitaxel but not individual compounds. Biochemical validation, by immunoblotting and metabolic Seahorse analysis, shows that combined MBQ-167 and paclitaxel reduces glycolysis. This study provides a strong rationale for the clinical testing of MBQ-167 in combination with paclitaxel as a potential therapeutic for TNBC and identifies a unique mechanism of action.

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Targeting PGK1: A New Frontier in Breast Cancer Therapy Under Hypoxic Conditions

Cui,

Chai,

Liu

et al. 2024

CIMB

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Breast cancer represents one of the most prevalent malignant neoplasms affecting women, and its pathogenesis has garnered significant scholarly interest. Research indicates that the progression of breast cancer is intricately regulated by glucose metabolism. Under hypoxic conditions within the tumor microenvironment, breast cancer cells generate ATP and essential biosynthetic precursors for growth via the glycolytic pathway. Notably, phosphoglycerate kinase 1 (PGK1) is intimately associated with the regulation of hypoxia-inducible factors in breast cancer and plays a crucial role in modulating glycolytic processes. Further investigation into the role of PGK1 in breast cancer pathogenesis is anticipated to identify novel therapeutic targets and strategies. This review consolidates current research on the regulation of glucose metabolism and the function of PGK1 in breast cancer within hypoxic conditions. It aims to offer a significant theoretical foundation for elucidating the mechanisms underlying breast cancer progression and metastasis, thereby facilitating the development of innovative treatment approaches.

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The Molecular Mechanisms behind Advanced Breast Cancer Metabolism: Warburg Effect, OXPHOS, and Calcium

Cited by 4 publications

References 132 publications

Mechanism of the Warburg effect and its role in breast cancer immunotherapy

Mechanism of the Warburg effect and its role in breast cancer immunotherapy

Novel Inhibition of Central Carbon Metabolism Pathways by Rac and CDC42 inhibitor MBQ167 and Paclitaxel

Targeting PGK1: A New Frontier in Breast Cancer Therapy Under Hypoxic Conditions

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