Standing out among the remaining genes are a number involved in the regulation of vacuolar pH, including 10 of 14 V-ATPase subunits and 2 membrane proteins required for V-ATPase assembly. This set of data strongly implicated vacuolar pH in the mechanism of action of dhMotC and led to the demonstration that dhMotC prevents vacuolar acidification. This effect is likely a consequence of inhibition of sphingosine/ceramide synthesis by dhMotC, since

sphingolipids containing long-chain fatty acids Selleckchem INCB018424 are known to be necessary for V-ATPase activity [44]. Chemical-genetic synthetic lethality also revealed a large number of genes involved in vacuolar assembly and intracellular transport. Further experiments showed that dhMotC indeed inhibits the delivery of internalized FM4-64 to the vacuole as well as fluid phase endocytosis. This effect is also likely a downstream consequence of inhibition of sphingolipid synthesis since sphingolipids are important for protein trafficking [45] and endocytosis is blocked upon interruption of de novo sphingolipid biosynthesis [46]. Defects

in vacuolar acidification and endocytosis caused by dhMotC occur in ρ 0 cells and are therefore independent of effects on mitochondria. Interestingly, motuporamines also inhibited lysosome acidification and intracellular trafficking after endocytosis in cancer cells, demonstrating the capaCity of this approach to predict targets in human cells. These results also provide insight into the mechanism by which dhMotC inhibits cancer cell LY2157299 nmr invasion. EGF signaling plays an important role in cell migration [47]. Stimulation of cultured cancer cells with EGF increases invasion and motility and modulates cell adhesion to extracellular matrix components in vitro [48] and in vivo [49]. Overexpression of EGFR causes why increased intravasation and lung metastasis from tumors implanted in the mammary fat pad, and cells

overexpressing EGFR are more motile in vivo than adjacent cells not overexpressing EGFR [50]. By interfering with vesicle-mediated trafficking of EGFR, motuporamines considerably reduce plasma membrane-associated EGFR, and consequently its ability to control cancer cell migration. In summary, this study demonstrates the value of using chemical genomics approaches in Saccharomyces cerevisiae to understand the mechanism of action of biologically active chemicals that may have human therapeutic value. However, reliance on a single genome-wide approach may often provide an incomplete picture of the mechanism of action of drugs. Different chemical genomics screens can provide complementary information and their combined use is probably necessary to provide a comprehensive understanding of the spectrum of different cellular effects a drug can have on cells. Methods Yeast strains, plasmids and growth conditions The haploid set of viable yeast deletion mutants (mat_alpha_041902) was purchased from Invitrogen.

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