Omri Erez

Overexpression of antizyme-inhibitor in NIH3T3 fibroblasts provides growth advantage through neutralization of antizyme functions

Antizyme inhibitor (AzI) is a homolog of ornithine decarboxylase (ODC), a key enzyme of polyamine synthesis. Antizyme inhibitor retains no enzymatic activity, but exhibits high affinity to antizyme (Az), a negative regulator of polyamine homeostasis. As polyamines are involved in maintaining cellular proliferation, and since AzI may negate Az functions, we have investigated the role of AzI in regulating cell growth. We show here that overexpression of AzI in NIH3T3 cells increased growth rate, enabled growth in low serum, and permitted anchorage-independent growth in soft agar, while reduction of AzI levels by AzI siRNA reduced cellular proliferation. Moreover, AzI overproducing cells gave rise to tumors when injected into nude mice. AzI overexpression resulted in elevation of ODC activity and of polyamine uptake. These effects of AzI are a result of its ability to neutralize Az, as overexpression of an AzI mutant with reduced Az binding failed to alter cellular polyamine metabolism and growth properties. We also demonstrate upregulation of AzI in Ras transformed cells, suggesting its relevance to some naturally occurring transformations. Finally, increased uptake activity rendered AzI overproducing and Ras-transformed cells more sensitive to toxic polyamine analogs. Our results therefore imply that AzI has a central and meaningful role in modulation of polyamine homeostasis, and in regulating cellular proliferation and transformation properties.

Screening for modulators of spermine tolerance identifies Sky1, the SR protein kinase of Saccharomyces cerevisiae, as a regulator of polyamine transport and ion homeostasis.

ABSTRACT Although most cells are capable of transporting polyamines, the mechanism that regulates polyamine transport in eukaryotes is still largely unknown. Using a genetic screen for clones capable of restoring spermine sensitivity to spermine-tolerant mutants ofSaccharomyces cerevisiae, we have demonstrated that Sky1p, a recently identified SR protein kinase, is a key regulator of polyamine transport. Yeast cells deleted for SKY1 developed tolerance to toxic levels of spermine, while overexpression of Sky1p in wild-type cells increased their sensitivity to spermine. Expression of the wild-type Sky1p but not of a catalytically inactive mutant restored sensitivity to spermine. SKY1 disruption results in dramatically reduced uptake of spermine, spermidine, and putrescine. In addition to spermine tolerance, sky1Δ cells exhibit increased tolerance to lithium and sodium ions but somewhat increased sensitivity to osmotic shock. The observed halotolerance suggests potential regulatory interaction between the transport of polyamines and inorganic ions, as suggested in the case of the Ptk2p, a recently described regulator of polyamine transport. We demonstrate that these two kinases act in two different signaling pathways. While deletion or overexpression of SKY1 did not significantly affect Pma1p activity, the ability of overexpressed Sky1p, Ptk1p, and Ptk2p to increase sensitivity to LiCl depends on the integrity ofPPZ1 but not of ENA1.

The E3 Ubiquitin-Ligase Bmi1/Ring1A Controls the Proteasomal Degradation of Top2α Cleavage Complex – A Potentially New Drug Target

Background The topoisomerases Top1, Top2α and Top2β are important molecular targets for antitumor drugs, which specifically poison Top1 or Top2 isomers. While it was previously demonstrated that poisoned Top1 and Top2β are subject to proteasomal degradation, this phenomena was not demonstrated for Top2α. Methodology/Principal Findings We show here that Top2α is subject to drug induced proteasomal degradation as well, although at a lower rate than Top2β. Using an siRNA screen we identified Bmi1 and Ring1A as subunits of an E3 ubiquitin ligase involved in this process. We show that silencing of Bmi1 inhibits drug-induced Top2α degradation, increases the persistence of Top2α-DNA cleavage complex, and increases Top2 drug efficacy. The Bmi1/Ring1A ligase ubiquitinates Top2α in-vitro and cellular overexpression of Bmi1 increases drug induced Top2α ubiquitination. A small-molecular weight compound, identified in a screen for inhibitors of Bmi1/Ring1A ubiquitination activity, also prevents Top2α ubiquitination and drug-induced Top2α degradation. This ubiquitination inhibitor increases the efficacy of topoisomerase 2 poisons in a synergistic manner. Conclusions/Significance The discovery that poisoned Top2α is undergoing proteasomal degradation combined with the involvement of Bmi1/Ring1A, allowed us to identify a small molecule that inhibits the degradation process. The Bmi1/Ring1A inhibitor sensitizes cells to Top2 drugs, suggesting that this type of drug combination will have a beneficial therapeutic outcome. As Bmi1 is also a known oncogene, elevated in numerous types of cancer, the identified Bmi1/Ring1A ubiquitin ligase inhibitors can also be potentially used to directly target the oncogenic properties of Bmi1.

Deletions of SKY1 or PTK2 in the Saccharomyces cerevisiaetrk1Δtrk2Δ mutant cells exert dual effect on ion homeostasis

Abstract Sky1p and Ptk2p are protein kinases that regulate ion transport across the plasma membrane of Saccharomyces cerevisiae . We show here that deletion of SKY1 or PTK2 in trk 1,2 Δ cells increase spermine tolerance, implying Trk1,2p independent activity. Unexpectedly, trk 1,2 Δsky 1 Δ and trk 1,2 Δptk 2 Δ cells display hypersensitivity to LiCl. These cells also show increased tolerance to low pH and improved growth in low K + , as demonstrated for deletion of PMP3 in trk 1,2 Δ cells. We show that Sky1p and Pmp3p act in different pathways. Hypersensitivity to LiCl and improved growth in low K + are partly dependent on the Nha1p and Kha1p antiporters and on the Tok1p channel. Finally, Dhh1p, a RNA helicase was demonstrated to improve growth of trk 1,2 Δsky 1 Δ cells in low K + . Overexpression of Dhh1p improves the ability of trk 1,2 Δ cells to grow in low K + while dhh 1 Δ cells are sensitive to spermine and salt ions. A model that integrates these results to explain the mechanism of ion transport across the plasma membrane is proposed.

Mechanism of polyamine tolerance in yeast: novel regulators and insights.

Abstract.Polyamines are small charged molecules essential for various cellular functions, but at high levels they are cytotoxic. Two yeast kinases, SKY1 and PTK2, have been demonstrated to regulate polyamine tolerance. Here we report the identification and characterization of additional genes involved in regulating polyamine tolerance: YGL007W, FES1 and AGP2. Deletion of YGL007W, an open reading frame located within the promoter of the membrane proton pump PMA1, decreased Pma1p expression. Deletion of FES1 or AGP2 resulted in reduced polyamine uptake. While high-affinity spermine uptake was practically absent in agp2Δ cells, fes1Δ cells displayed only reduced affinity towards spermine. Despite the reduced uptake, the resistant strains accumulated significant levels of polyamines and displayed increased ornithine decarboxylase activity, suggesting reduced polyamine sensing. Interestingly, fes1Δ cells were highly sensitive to salt ions, suggesting different underlying mechanisms. These results indicate that mechanisms leading to polyamine tolerance are complex, and involve components other than uptake.