The Novel Family of Warbicin Compounds Inhibits Glucose Uptake Both in Yeast and Human Cells and Restrains Cancer Cell Proliferation

Overview

Journal Front Oncol

Specialty Oncology

Date 2024 Sep 6

PMID 39239276

Authors

Ward Vanthienen

Juan Fernandez-Garcia

Maria Francesca Baietti

Elisa Claeys

Frederik Van Leemputte

Long Nguyen

Vera Goossens

Quinten Deparis

Dorien Broekaert

Sophie Vlayen

Dominique Audenaert

Michel Delforge

Alessandro DAmuri

Griet Van Zeebroeck

Eleonora Leucci

Sarah-Maria Fendt

Johan M Thevelein

Affiliations

Soon will be listed here.

Abstract

Many cancer cells share with yeast a preference for fermentation over respiration, which is associated with overactive glucose uptake and breakdown, a phenomenon called the Warburg effect in cancer cells. The yeast mutant shows even more pronounced hyperactive glucose uptake and phosphorylation causing glycolysis to stall at GAPDH, initiation of apoptosis through overactivation of Ras and absence of growth on glucose. The goal of the present work was to use the yeast strain to screen for novel compounds that would preferentially inhibit overactive glucose influx into glycolysis, while maintaining basal glucose catabolism. This is based on the assumption that the overactive glucose catabolism of the strain might have a similar molecular cause as the Warburg effect in cancer cells. We have isolated Warbicin A as a compound restoring growth on glucose of the yeast mutant, showed that it inhibits the proliferation of cancer cells and isolated structural analogs by screening directly for cancer cell inhibition. The Warbicin compounds are the first drugs that inhibit glucose uptake by both yeast Hxt and mammalian GLUT carriers. Specific concentrations did not evoke any major toxicity in mice but increase the amount of adipose tissue likely due to reduced systemic glucose uptake. Surprisingly, Warbicin A inhibition of yeast sugar uptake depends on sugar phosphorylation, suggesting transport-associated phosphorylation as a target. and evidence confirms physical interaction between yeast Hxt7 and hexokinase. We suggest that reversible transport-associated phosphorylation by hexokinase controls the rate of glucose uptake through hydrolysis of the inhibitory ATP molecule in the cytosolic domain of glucose carriers and that in yeast cells and cancer cells reversibility is compromised, causing constitutively hyperactive glucose uptake and phosphorylation. Based on their chemical structure and properties, we suggest that Warbicin compounds replace the inhibitory ATP molecule in the cytosolic domain of the glucose carriers, preventing hexokinase to cause hyperactive glucose uptake and catabolism.

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