Abstract
The lysophosphatidylcholine analogue edelfosine is a potent antitumor lipid that targets cellular membranes. The underlying mechanisms leading to cell death remain controversial, although two cellular membranes have emerged as primary targets of edelfosine, the plasma membrane (PM) and the endoplasmic reticulum. In an effort to identify conditions that enhance or prevent the cytotoxic effect of edelfosine, we have conducted genome-wide surveys of edelfosine sensitivity and resistance in Saccharomyces cerevisiae presented in this work and the accompanying paper (Cuesta-Marbán, Á., Botet, J., Czyz, O., Cacharro, L. M., Gajate, C., Hornillos, V., Delgado, J., Zhang, H., Amat-Guerri, F., Acuña, A. U., McMaster, C. R., Revuelta, J. L., Zaremberg, V., and Mollinedo, F. (January 23, 2013) J. Biol. Chem. 288,), respectively. Our results point to maintenance of pH homeostasis as a major player in modulating susceptibility to edelfosine with the PM proton pump Pma1p playing a main role. We demonstrate that edelfosine alters PM organization and induces intracellular acidification. Significantly, we show that edelfosine selectively reduces lateral segregation of PM proteins like Pma1p and nutrient H(+)-symporters inducing their ubiquitination and internalization. The biology associated to the mode of action of edelfosine we have unveiled includes selective modification of lipid raft integrity altering pH homeostasis, which in turn regulates cell growth.
Highlights
The anti-tumor lipid edelfosine alters lipid raft integrity
Our findings clearly show that edelfosine alters the domain organization of the yeast plasma membrane by inducing changes in the distribution of lipids and proteins within domains
This in turn affects pH homeostasis, which emerged from this study as a major contributor to sensitivity toward edelfosine
Summary
The anti-tumor lipid edelfosine alters lipid raft integrity. How this signals inhibition of growth is not understood. The biology associated to the mode of action of edelfosine we have unveiled includes selective modification of lipid raft integrity altering pH homeostasis, which in turn regulates cell growth. It has been well documented that lipid rafts play important roles in membrane trafficking and signaling [1,2,3] Alteration of these lipid domains is expected to interfere with these pathways, eventually leading to a detrimental impact on cell fitness and survival. In this study and the accompanying paper [69], we expanded our genetic screen approach to survey the yeast deletion collection for sensitivity and resistance to edelfosine, respectively The results of these screens further support a key role for lipid rafts and the essential proton pump Pma1p in mediating edelfosine cytotoxicity in yeast. We found that failure to maintain pH homeostasis may be the signal that regulates communication between the PM and intracellular membranes
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