Screening for Modulators of Spermine Tolerance Identifies Sky1, the SR Protein Kinase of Saccharomyces cerevisiae, as a Regulator of Polyamine Transport and Ion Homeostasis

doi:10.1128/MCB.21.1.175-184.2001

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Molecular and Cellular Biology, January 2001, p. 175-184, Vol. 21, No. 1
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.1.175-184.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Screening for Modulators of Spermine Tolerance Identifies Sky1, the SR Protein Kinase of Saccharomyces cerevisiae, as a Regulator of Polyamine Transport and Ion Homeostasis

Omri Erez and Chaim Kahana^*

Department of Molecular Genetics, The Weizmann Institute of Science, Rehovot 76100, Israel

Received 15 September 2000/Accepted 12 October 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Although most cells are capable of transporting polyamines, the mechanism that regulates polyamine transport in eukaryotesis still largely unknown. Using a genetic screen for clones capableof restoring spermine sensitivity to spermine-tolerant mutantsof Saccharomyces cerevisiae, we have demonstrated that Sky1p,a recently identified SR protein kinase, is a key regulator ofpolyamine transport. Yeast cells deleted for SKY1 developed toleranceto toxic levels of spermine, while overexpression of Sky1p inwild-type cells increased their sensitivity to spermine. Expressionof the wild-type Sky1p but not of a catalytically inactive mutantrestored sensitivity to spermine. SKY1 disruption results in dramaticallyreduced uptake of spermine, spermidine, and putrescine. In additionto spermine tolerance, sky1 $Delta$ cells exhibit increased toleranceto lithium and sodium ions but somewhat increased sensitivityto osmotic shock. The observed halotolerance suggests potentialregulatory interaction between the transport of polyamines andinorganic ions, as suggested in the case of the Ptk2p, a recentlydescribed regulator of polyamine transport. We demonstrate thatthese two kinases act in two different signaling pathways. Whiledeletion or overexpression of SKY1 did not significantly affectPma1p activity, the ability of overexpressed Sky1p, Ptk1p, andPtk2p to increase sensitivity to LiCl depends on the integrityof PPZ1 but not of ENA1.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The polyamines spermine and spermidine and their precursor putrescine are ubiquitous polycations demonstrated to be essentialfor various cellular functions such as growth and proliferation,differentiation, transformation, and apoptosis (39, 40, 51,52, 56). The intracellular concentration of polyamines istightly regulated at many control levels (6, 40, 51). Althoughcells contain highly orchestrated groups of enzymes that modulatethe intracellular concentration of polyamines by controlling theirsynthesis and degradation, most cells also have the capacity totake up polyamines from their environment (17, 41, 47).Drugs interfering with polyamine biosynthesis were demonstratedto have considerable potential for use as therapeutic agents (29,40, 42). Clearly, protocols minimizing uptake of exogenouspolyamines via the polyamine transport system will be needed inorder to reveal the entire potential of such inhibitors. Conversely,protocols increasing selective polyamine uptake will facilitatethe use of polyamine analogues which have potent antiproliferativeactivity and therefore are promising agents for the treatmentof cancer (3, 31, 32).

Polyamine uptake has been characterized in great detail in bacteria. Escherichia coli contains three different polyamine transportpathways (for a review, see reference 16 and references therein).Two are ABC (ATP-binding cassette) transporters; one is specificfor putrescine (PotF-I), while the second displays a preferencefor spermidine (PotA-D). Both transporters consist of a substrate-bindingprotein, two channel-forming proteins, and a membrane-associatedATPase. The third transport system (PotE) is putrescine specific,mediating both uptake andexcretion.

Although mammalian cells lacking polyamine transport activity have been available for quite a while (14, 28), they didnot enable isolation and cloning of the polyamine transportersor regulators of the polyamine transport process (2). The onlymammalian gene implicated presently in the regulation of polyaminetransport is antizyme, a regulator of ornithine decarboxylasedegradation (35, 36) that was also implicated in negativeregulation of polyamine uptake via an as yet unknown mechanism(33, 46, 50).

In the budding yeast Saccharomyces cerevisiae, a vacuolar membrane transporter (Tpo1p) and two protein kinases (Ptk1p andPtk2p) that regulate plasma membrane polyamine transport havebeen identified. Tpo1p, which excretes spermidine, was identifiedbased on its homology to the Bacillus subtilis Blt, a multidrugtransporter (53). The Ptk1p and Ptk2p kinases, which stimulatepolyamine uptake, were identified by genetic screens (20, 21,38). These two kinases belong to a subfamily that is uniqueto S. cerevisiae and regulates plasma membrane transporters (15).This subfamily also includes the Hal4 and Hal5 protein kinasesthat regulate ion homeostasis by activating the potassium transportersTrk1 and Trk2 (34). Another member of this family of kinasesis Npr1, which is required for the derepression of several nitrogenpermeases in low-nitrogen-containing media (54) and was recentlydemonstrated to activate spermidine uptake in NH₄⁺-rich medium (22).

Sky1p is a recently identified SR protein kinase (SRPK) of the budding yeast that, similar to its metazoan counterparts, mayfunction in mRNA maturation by regulating splicing or transportof mRNA from the nucleus to the cytoplasm (49). Here we demonstratethat Sky1 is also a key regulator of polyamine transport. Interestingly,similar to the recently identified Ptk2p, Sky1p is also involvedin regulating ionhomeostasis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains and media. The S. cerevisiae strains used in the present work are listed in Table 1. These strains were routinely maintained in YPDmedium (1% yeast extract, 2% peptone, 2% D-glucose) or in Mg²⁺-limited synthetic complete (MLSC) medium supplemented with 50µM MgSO₄ as described (30) and with the required essential aminoacids. Yeast cells were transformed by the lithium acetate method(18).

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TABLE 1. Yeast strains used in this study

Isolation of spermine transport-deficient mutants. The selection method employed in the present study is based on the sensitivity of yeast cells to spermine, as demonstratedpreviously (20). Briefly, the haploid strains SP1 (MATa)and W303-1b (MAT $alpha$ ) were mutagenized with ethyl methanesulfonate(0.03%, vol/vol) (44). The cells were then plated on YPD agarplates containing 1.5 mM spermine to select resistant clones.Diploids were generated between the tested mutants and the wild-typestrain of the opposite mating type (SP1 or W303-1b) in order todetermine whether the phenotype of the resulting mutants is recessiveor dominant. Complementation groups were determined by crossingSP1-born and W303-1b-born mutants and testing their growth onMLSC agar plates containing 1.5 mM spermine. MLSC agar plateswere used to reduce the inhibitory effect of Mg²⁺ on the uptake of spermine (20).

Isolation of the SKY1 gene. Spermine transport mutant cells of the C complementation group (sptC) were transformed with a yeast genomic DNA library constructedin the single-copy-number plasmid YCP50. The transformed cellswere plated on SC-Leu plates, and the resulting colonies werereplica plated on MLSC-Leu plates containing or lacking 1.5 mMspermine. The plasmid was rescued from clones that regained sensitivityto 1.5 mM spermine and tested in a second round of transformation.The 5' and 3' ends of the cloned inserts were sequenced in orderto determine their positions in the yeastgenome.

Plasmids and gene disruption. The DNA segments containing the SKY1, PTK1, PTK2, and PPZ1 genes were cloned from genomic DNA by PCR and ligated into thepGEM-T Easy vector (Promega). Following sequencing, these fragmentswere transferred into the SalI site of the yeast high-copy-numberexpression vector pAD54, placing them in frame downstream froma hemagglutinin (HA)-tagged segment. The primers used for thePCR are as follows: SKY1, 5'-TGTCGACAATTAACTATCCTGGGTTT-3' and5'-AGTCGACTCAATGTCTTTTATGATCGC-3'; PTK1, 5'-GTCGACAGTCTCACACAATCATT-3'and 5'-GTCGACGACGCTAAAACCGTG-3'; PTK2, 5'-GTCGACGGCGGGAAACGGTAAG-3'and 5'-GTCGACGTCTATCTTGAGATAAAG-3'; and PPZ1, 5'-AATGTCGACTTCAAGTTCAAAATCTTCG-3'and 5'-AAGTCGACGTAAATTAACTGTTGAGATTCG-3'. In order to disruptthe PTK2 gene, the corresponding DNA was digested with AvaI andClaI, and the released fragment was replaced by an AvaI-BamHI-ClaIadapter. Then a 1.1-kb BamHI fragment encompassing the URA3 genewas cloned into the implanted BamHI site. The resulting PTK2::URA3fragment was transfected into wild-type BY4742, sky1 $Delta$ , or ptk1 $Delta$ cells. URA3-positive colonies were selected, and the disruptionof the PTK2 gene was checked by PCR. In order to disrupt the PPZ1gene, the 1.1-kb BamHI URA3 fragment was cloned between the twoBglII sites of PPZ1. The resulting PPZ1::URA3 fragment was transfectedinto cnb $Delta$ cells.

Site-directed mutagenesis. The ATP-binding site SKY1 mutant, K187A, was generated by the uracil incorporation method of site-directed mutagenesis (24).The primer used was 5'-CCGAACAATCGCCATAGCAAC-3', containing analteration of lysine 187 toalanine.

Growth assays. The growth of yeast strains on YPD or MLSC-Leu plates containing different additives was performed by spotting 2 µl from fivefolddilutions of cultures at an optical density at 600 nm (OD₆₀₀)of 1, or by streaking cells on the plates. In order to measuregrowth in liquid medium, exponentially growing cultures were dilutedin YPD medium containing different additives at the indicatedconcentrations. Growth was determined by measuring cell densityat OD₆₀₀ at different timesthereafter.

Polyamine uptake analysis. Cells were grown to the mid-logarithmic phase (OD₆₀₀ = 1.1 to 1.3), washed three times in glucose-citrate buffer (50 mM sodiumcitrate [pH 5.5], 2% D-glucose), and resuspended in the same bufferat a concentration of 10⁸ cells/ml. Transport was initiated by adding 0.2 volume of [¹⁴C]putrescine (10 Ci/mol at 50 µM), [³H]spermidine (50 Ci/mol at 100 µM) (both from Dupont-NEN), or[¹⁴C]spermine (10 Ci/mol at 100 µM) (from Amersham Pharmacia), andthe cells were incubated at 30°C with mild shaking. Uptake wasstopped by transferring 100-µl aliquots (in duplicate) into 1ml of ice-cold stop buffer (glucose-citrate buffer containing2 mM putrescine, spermidine, or spermine). The cells were thenlayered on cellulose-acetate filters (0.45-µm pore size) thathad been washed with stop buffer. The filters were washed threetimes with stop buffer, and the retained radioactivity was determinedby liquid scintillationspectrometry.

Western blot analysis. Cells from 1 ml of culture were collected by centrifugation and resuspended in 50 µl of sample buffer (125 mM Tris-HCl [pH6.8], 4% sodium dodecyl sulfate [SDS], 20% glycerol, 1.4 M $beta$ -mercaptoethanolbromophenol blue). Following 5 min of boiling, 5-µl aliquots werefractionated by SDS-8% polyacrylamide gel electrophoresis (PAGE)and blotted onto a nitrocellulose membrane. The blots were probedwith anti-HA monoclonal antibody (BabCo) and goat anti-mouse immunoglobulinG-horseradish peroxidase conjugate as a secondary antibody. Signalswere detected using the enhanced chemiluminescence system(Pierce).

Membrane preparation and ATPase activity determination. Total membrane fractions were prepared essentially as described (55). Briefly, log-phase cells from 100 ml of culture werepelleted, washed, and resuspended in ice-cold lysis buffer (10mM Tris [pH 7.4], 0.3 M sorbitol, 0.1 M NaCl, 5 mM MgCl₂, andprotease inhibitors; in some experiments sorbitol was replacedwith 250 mM glucose). Cells were then lysed at 4°C using glassbeads, and the lysate was centrifuged at 600 × g for 5 min toremove unbroken cells. Membranes were then pelleted at 4°C bycentrifugation for 1 h at 100,000 × g. The membranes were washedtwice and stored at $-$ 80°C in storage buffer (10 mM Tris [pH 7.4],0.1 mM EDTA, 0.1 mM dithiothreitol, 20% glycerol). Vanadate-sensitiveATPase activity was measured in the presence or absence of 100mM sodium orthovanadate. Equal amounts of proteins from the membranefractions were added to the assay mixture containing 10 mM MOPS(morpholinepropanesulfonic acid)-Tris (pH 6.5), 5 mM disodiumATP, 5 mM MgCl₂, 5 mM NaN₃, 5 mM phosphoenolpyruvate, and 25 µgof pyruvate kinase. The reaction was carried out for 10 to 30min at 30°C. Free phosphate was determined according to the Fiske-Subbarowprocedure (9). Activity is expressed as arbitrary units basedon absorption at 820nm.

Sequence analysis. SKY1 genomic DNA was amplified by PCR using genomic DNA isolated from sptC and wild-type cells and using the oligonucleotides5'-GAGGTTGAAGAGATAGAGTAAAG and 5'-TCAATGTCTTTTATGATCGCGG as 5'and 3' primers, respectively. The resulting DNA was purified usingthe Qiagen Qiaquick PCR purification kit. The purified fragmentwas subjected to automated sequencing using primers scatteredalong theDNA.

RNA analysis. Yeast cells from 50-ml cultures were harvested by centrifugation, and RNA was prepared by phenol extraction with glass beads(19). Formaldehyde-agarose gel electrophoresis and blot hybridizationwere performed using a Gene-screen-plus membrane (NEN) accordingto the manufacturer'sinstructions.

	RESULTS

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Yeast serine/threonine kinase Sky1 is involved in regulating spermine transport. We have utilized a previously described selection scheme for the isolation of spermine-tolerant yeast mutant cells (20,38). Cells of the haploid strains SP1 (MATa) and W303-1b(MAT $alpha$ ) were subjected to ethyl methanesulfonate mutagenesis andplated on YPD plates containing 1.5 mM spermine. Sixty spermine-tolerant(spt) mutants of each strain were tested for carrying a dominantor recessive mutation by crossing them with wild-type cells ofthe other strain and testing the ability of the resulting diploidsto grow in the presence of 1.5 mM spermine. All the mutants weredemonstrated to carry a recessive mutation. Next, by crossingmutants from one strain to mutants of the other strain, we haveso far identified seven independent complementation groups (sptAto sptG). A single-copy-number vector (YCP50) carrying a yeastgenomic library was then transfected into the mutant cells, andthe transformants were plated as duplicates on MLSC-Leu plateseither containing or lacking 1.5 mM spermine. Colonies that failedto grow on plates containing 1.5 mM spermine were identified,and the plasmids within them were rescued. Several plasmids havebeen isolated so far by screening three of the mutants (sptA tosptC) which, upon retransformation, restored sensitivity to spermine.One of these plasmids, which was rescued from the sptA mutant,harbors a genomic segment encoding several open reading frames(ORFs), among them the previously described PTK2, encoding a serine/threoninekinase shown to be involved in regulating polyamine transport(21, 38). The other plasmids isolated from both the sptB andsptC mutants harbor a genomic insert containing several ORFs whichwere not previously implicated in polyamine transport. One ofthese plasmids (rescued from the sptC mutant) contains a genomicsegment from chromosome 13, encompassing four ORFs (Fig. 1A).These ORFs encode a component of a protein complex associatedwith the splicing factor Prp19p (CEF1), a dnaJ homolog (SCJ1),a hypothetical ORF (YMR215W), and a serine protein kinase (SKY1).In order to determine which of these ORFs is involved in regainingspermine sensitivity, we obtained strains containing deletionsof three of these ORFs. Deletion of the fourth ORF (CEF1) wasnot tested because of its haploid lethality. Cells containingdeletions of these three ORFs as well as Ptk2 $Delta$ cells (servingas a positive control) were tested for growth in the presenceof 1.5 mM spermine. As demonstrated in Fig. 1B, of the testedstrains, only sky1 $Delta$ cells grow efficiently on the spermine-containingplates.

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FIG. 1. Isolation and demonstration of the involvement of SKY1 in spermine tolerance. (A) Structure of the genomic clone selected for restoring spermine sensitivity to the spermine-tolerant sptC mutant. The four ORFs are shown as boxes and their names are indicated. (B) Deletion of SKY1 confers spermine tolerance. Yeast strains containing a disruption of three of the four indicated ORFs were tested for spermine tolerance by streaking on YPD agar plates containing 1.5 mM spermine (Spm). ptk2 $Delta$ cells, which were previously demonstrated to confer spermine tolerance, served as a positive control.

The Sky1 protein was recently identified as an SRPK of the budding yeast (47). Sky1p may function similarly to its metazoancounterparts in mRNA maturation by regulating splicing or transportof mRNA from the nucleus to the cytoplasm (49). The SRPKs phosphorylateserine residues within serine/arginine-rich domains of membersof the SR family of splicing factors. Sky1 appears to be the onlySRPK in budding yeast (49).

In order to make a quantitative assessment of the role of Sky1p in regulating tolerance to spermine, we characterized thegrowth of sky1 $Delta$ cells in the presence of various concentrationsof spermine. Under standard conditions in nutrient-rich medium,the growth rate of the sky1 $Delta$ mutant cells was indistinguishablefrom that of wild-type cells (Fig. 2A), indicating that SKY1 disruptiondoes not affect cell viability or growth in nutrient-rich medium.In the presence of 1.5 mM spermine, the growth of wild-type cellswas strongly inhibited, while the growth of sky1 $Delta$ cells was practicallyunaffected (Fig. 2B). The growth of sky1 $Delta$ cells was indistinguishablefrom that of ptk2 $Delta$ cells (Fig. 2B). sky1 $Delta$ and ptk2 $Delta$ cells alsodemonstrated similar tolerance to increasing spermine concentrations(Fig. 2C). In contrast, the growth of ptk1 $Delta$ cells was inhibitedby spermine to the same extent as that of wild-type cells. Overexpressionof all three kinases in wild-type cells significantly increasedtheir sensitivity to spermine (Fig. 2D). Forced expression ofwild-type Sky1p but not of a catalytically inactive mutant ofit (the ATP-binding site mutant Sky1p K187A (57) restored sensitivityto spermine in sky1 $Delta$ and sptC cells (Fig. 3), demonstrating thatthe kinase activity of Sky1p is essential for mediating sperminesensitivity.

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FIG. 2. Effect of SKY1 disruption and Sky1p overexpression on growth tolerance to spermine. (A) Basal growth rate of wild-type (WT), sky1 $Delta$ , and ptk2 $Delta$ cells. (B) Effect of 1.5 mM spermine on the growth of wild-type, sky1 $Delta$ , and ptk2 $Delta$ cells. (C) Effect of spermine concentration on the growth of wild-type, sky1 $Delta$ , ptk1 $Delta$ , and ptk2 $Delta$ cells as determined after 16 h of incubation. (D) Sky1p as well as Ptk1p and Ptk2p were overexpressed in wild-type cells from the pAD54 expression vector. Fivefold dilutions of the resulting transformants were spotted on MLSC plates with and without 0.1 mM spermine (SPM).

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FIG. 3. Kinase activity of Sky1p is required for reversing the spermine-tolerant phenotype of sky1 $Delta$ cells. The growth of sky1 $Delta$ cells and of the sptC cells that were transformed with empty vector (pAD54) or with constructs encoding wild-type SKY1 or its catalytically inactive variant K187A (both with an amino-terminal HA tag) was determined on solid MLSC plates containing 1.5 mM spermine (Spm). The expression of wild-type Sky1 protein and of the catalytically inactive K187A mutant protein was determined by Western blot analysis using anti-HA antibodies as described in the text. Sizes are shown in kilodaltons.

SKY1 disruption inhibits polyamine transport. Next we set out to determine whether the resistance of sky1 $Delta$ cells to toxic levels of spermine is caused by their reducedability to take up polyamines. For this purpose, we directly measureduptake of polyamines by sky1 $Delta$ and wild-type cells. Deletion ofSKY1 almost completely eliminated the accumulation of sperminein the cells (Fig. 4A) and severely inhibited the accumulationof spermidine and putrescine (Fig. 4B and C, respectively). Kineticanalysis demonstrated that the disruption of SKY1 reduced V_maxby fivefold (7.83 pmol/min per 10⁷ cells for sky1 $Delta$ cells compared to 40.5 pmol for wild-type cells)and decreased the affinity towards spermidine (K_m = 48.5 µM forsky1 $Delta$ cells versus 8.18 µM for wild-type cells) (Fig. 5). We thereforeconclude that the Sky1 protein kinase is involved in regulatingpolyamine transport.

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FIG. 4. Effect of SKY1 disruption on the time course of putrescine, spermidine, and spermine uptake. The uptake of [¹⁴C]spermine, [³H]spermidine (both at 20 µM), and [¹⁴C]putrescine (10 µM) by wild-type (WT) and sky1 $Delta$ cells was determined at the indicated times as described in Materials and Methods. The results presented are averages of three determinations ± standard deviation.

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FIG. 5. Initial velocity of [³H]spermidine uptake in wild-type (WT) and sky1 $Delta$ cells. The uptake of [³H]spermidine (Spd) at the indicated concentrations was determined after 1.5 min of incubation as described in Materials and Methods. The results presented are averages of three determinations ± standard deviation. The insert presents a double reciprocal plot of the initial rate of [³H]spermidine uptake in wild-type and sky1 $Delta$ cells.

Disruption of SKY1 leads to salt tolerance but increases sensitivity to osmotic shock. Ptk1p and Ptk2p belong to a subfamily of kinases that include Hal4p and Hal5p, which are involved in regulating halotolerance.It is therefore not entirely surprising that in addition to sperminetolerance, PTK2 disruption also provokes resistance to NaCl andLiCl (21). We therefore tested whether disruption of SKY1 alsoconfers tolerance to salt and osmotic insults. As shown in Fig.6A, sky1 $Delta$ cells tolerated 0.2 M LiCl and 1.2 M NaCl, similar toptk2 $Delta$ cells, while the growth of wild-type and ptk1 $Delta$ cells wasseverely inhibited. As would be expected, overexpression of Sky1p,Ptk2p, and, to a somewhat lesser extent, also Ptk1p increasedthe sensitivity of wild-type cells to LiCl and NaCl (Fig. 6B).Disruption of SKY1 but not of PTK1 and PTK2 resulted in sensitivityto osmotic shock caused by 1.5 M KCl and to a somewhat lesserextent by 1.5 M sorbitol (Fig. 6C).

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FIG. 6. sky1 $Delta$ cells are tolerant to LiCl and NaCl and sensitive to osmotic shock. (A) Fivefold dilutions of wild-type (WT), sky1 $Delta$ , ptk1 $Delta$ , and ptk2 $Delta$ cells were spotted on YPD plates containing 0.2 M LiCl or 1.2 M NaCl. (B) Fivefold dilutions of wild-type cells transformed with the expression vector pAD54, encoding Sky1p, Ptk1p, and Ptk2p. The resulting transformants were spotted on MLSC plates with similar additives as in A. (C) Fivefold dilutions of wild-type, sky1 $Delta$ , ptk1 $Delta$ , and ptk2 $Delta$ cells were spotted on YPD plates containing 1.5 M KCl or 1.5 M sorbitol.

Sky1p and Ptk2p modulate spermine tolerance via two distinct signaling pathways. We next set out to test for possible relationships between Sky1p and the previously described polyamine uptake-regulatingkinase Ptk2p. Overexpression of Sky1p and Ptk2p in sky1 $Delta$ cellssuppressed their spermine- and LiCl-tolerant phenotype (Fig. 7A).In contrast, overexpression of Sky1p in ptk2 $Delta$ cells efficientlysuppressed their tolerance to LiCl but only partially suppressedtheir tolerance to spermine (Fig. 7A). The greater ability ofPtk2p to suppress the spermine-tolerant phenotype of sky1 $Delta$ cellscompared to the ability of Sky1p to suppress the tolerance ofptk2 $Delta$ cells suggested that Ptk2p may act downstream from Sky1p.

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FIG. 7. Complementation analysis reveals that SKY1 and PTK2 act in two parallel signaling pathways. (A) sky1 $Delta$ and ptk2 $Delta$ cells were transformed with empty vector (pAD54) or with constructs that overexpress Sky1p or Ptk2p. Spermine tolerance of the resulting transformants was determined by drop tests in MLSC plates containing 1.5 mM spermine and SC plates containing 0.2 M LiCl. The growth of wild-type (WT), sky1 $Delta$ , ptk2 $Delta$ , and sky1 $Delta$ ptk2 $Delta$ double mutant cells was tested in the presence of the indicated concentrations of spermine (B) and LiCl (C).

To address this possibility more directly, we tested the spermine and LiCl tolerance of sky1 $Delta$ ptk2 $Delta$ double mutant cells. Asshown in Fig. 7B, the spermine tolerance displayed by sky1 $Delta$ ptk2 $Delta$ double mutant cells was actually greater than additive. This resultstrongly implies that the two kinases act in parallel pathways.In the case of salt tolerance, the situation is somewhat lessclear, since although being higher than that of the single mutant,the LiCl tolerance displayed by the double mutant cells was lowerthan that expected from simple additivity (Fig. 7C). The spermineand LiCl tolerance of the ptk1 $Delta$ ptk2 $Delta$ double mutant was not significantlydifferent from the tolerance displayed by ptk2 $Delta$ cells (notshown).

Sky1p modulates spermine and salt tolerance without significantly altering Pma1p activity. It is tempting to suggest that the phenotype observed in sky1 $Delta$ or ptk2 $Delta$ cells or in cells overexpressing Sky1p or Ptk2p ismediated at least in part by changes in membrane potential. Themajor generator of membrane potential in yeast cells is the plasmamembrane H⁺/ATPase Pma1p. We therefore measured Pma1p activity in sky1 $Delta$ cells,in ptk2 $Delta$ cells, and in wild-type cells overproducing Sky1p orPtk2p. Pma1p activity was slightly increased in sky1 $Delta$ and slightlydecreased in Sky1p-overproducing cells (Fig. 8A). Although theseminimal changes were consistently observed, it is unlikely thatthese changes are the cause of the observed SKY1-related phenotypes.In contrast, Pma1p activity was quite significantly increasedin Ptk2p-overproducing cells and significantly decreased in ptk2 $Delta$ cells (Fig. 8A). Since these changes in Pma1p activity are notaccompanied by changes in the amount of the protein (Fig. 8B),it is possible that Ptk2p modulates Pma1p activity by specificphosphorylation of the protein that is already located at theplasma membrane (4, 8). As it was demonstrated that Pma1pis activated by glucose (7, 8, 48), we replaced sorbitolwith glucose in the lysis buffer to ensure that the enzyme ismaintained in its active state. The use of glucose in the lysisbuffer gave essentially the same results.

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FIG. 8. H⁺-ATPase activity in plasma membranes of sky1 $Delta$ and ptk2 $Delta$ cells and in wild-type cells overproducing Sky1p or Ptk2p. Plasma membranes were prepared from wild-type (WT) cells transformed with empty vector (WT) or SKY1 (WT+SKY1) or PTK2 (WT+PTK2)-overexpressing vectors and from sky1 $Delta$ or ptk2 $Delta$ cells transformed with empty vector (sky1 $Delta$ and ptk2 $Delta$ , respectively). ATPase activity was assayed (A) and the Pma1p protein was determined (B) as described under Materials and Methods.

LiCl sensitivity provoked by overexpressed Sky1p, Ptk1p, and Ptk2p requires Ppz1p but not Ena1p. The yeast RNA-binding protein Np13p, which contains a glycine/arginine-rich domain and has been implicated in mRNA export(26) and rRNA processing (45), was shown to be a substrateof Sky1p and of metazoan SRPKs (49). Although no other proteinhas been identified so far as a direct target of Sky1p, thereare additional yeast proteins, some involved in splicing, whichcontain serine/arginine-rich or glycine/arginine-rich segmentswhich can therefore be considered potential substrates of Sky1p.These include Mud2p, an ortholog of the human splicing factorU2AF⁶⁵ (1), and Gbp2p, an RNA-binding domain-containing protein (25).Our present results demonstrate that in contrast to sky1 $Delta$ cells,np13 $Delta$ , mud2 $Delta$ , and gbp2 $Delta$ cells fail to grow in the presence of1.5 mM spermine (not shown). This result suggests that the roleof Sky1p in mediating spermine tolerance is manifested throughphosphorylation of either other SR proteins (49) or a non-SRprotein(s) or due to redundancy in the function of yeast SRproteins.

We screened the yeast genome database for additional proteins that contain SR segments and therefore may be substrates forSky1p. We noted that the protein phosphatases Ppz1p and Ppz2p,which were implicated in modulating salt tolerance (43), containSR-rich segments located at their amino-terminal regions thatmay be phosphorylated by Sky1p. This region of Ppz1p was demonstratedto have a regulatory role (5). Although ppz1 $Delta$ and ppz2 $Delta$ cellswere not resistant to toxic levels of spermine (not shown), weset out to test for possible involvement of the Ppz phosphatasesin mediating the effect of Sky1p, Ptk1p, and Ptk2p by their overexpressionin ppz1 $Delta$ or ppz2 $Delta$ cells. While overexpression of the three kinasesincreased spermine sensitivity in both ppz1 $Delta$ and ppz2 $Delta$ cells,increased LiCl sensitivity was observed only in ppz2 $Delta$ cells (Fig.9A). Therefore, it appears that the ability of the three kinasesto increase salt sensitivity may at least in part be mediatedby Ppz1p. Since the ppz1 mutant is very tolerant to LiCl, it canbe argued that it may not be possible to detect alteration inthe displayed tolerance. That this is not the case is clearlydemonstrated by the reduced LiCl tolerance displayed by ppz1 $Delta$ cells with a deletion of the gene encoding the calcineurin-regulatory $beta$ subunit CNB1 (Fig. 9B). If Sky1p and Ptk2p both act throughPpz1p, it is expected that the salt tolerance displayed by ppz1 $Delta$ cells will be at least equivalent to that displayed by sky1 $Delta$ ptk2 $Delta$ double mutant cells. As shown in Fig. 9C, both cell types displayedpractically identical tolerance to a range of LiCl concentrations,suggesting that both kinases fulfill their role via Ppz1p.

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FIG. 9. PPZ1 but not PPZ2 or ENA1 is required for the effect of SKY1, PTK1, and PTK2 on lithium tolerance phenotype. (A) ppz1 $Delta$ and ppz2 $Delta$ cells were transformed with the expression vector pAD54, encoding Sky1p, Ptk1p, and Ptk2p. The resulting transformants were spotted in fivefold dilutions on SC plates containing 0.2 M LiCl or MLSC plates containing 1.5 mM spermine. (B) The PPZ1 gene was deleted from cnb1 $Delta$ cells. The growth of the resulting double mutant cells was compared to that of wild-type (WT), cnb1 $Delta$ , and ppz1 $Delta$ cells. (C) Effect of LiCl concentration on the growth of ppz1 $Delta$ and sky1 $Delta$ ptk2 $Delta$ double mutant cells. (D) ena1-4 $Delta$ cells were transformed with an empty pAD54 vector or with this vector encoding Sky1p, Ptk1p, and Ptk2p, and the growth of the resulting transformants was tested on plates contains 17 mM LiCl as in panel A.

The Ppz phosphatases have been suggested to regulate cation efflux by downregulating the plasma membrane Na⁺/ATPase Ena1p, leading to sodium and lithium hypersensitivity(43). ENA1 is the first and only gene of four tandemly arrangedrelated genes, ENA1 to ENA4, that is induced upon exposure toLiCl and NaCl. Deletion of ENA1 results in cellular hypersensitivityto LiCl and NaCl (11, 13). We therefore overexpressed Sky1p,Ptk1p, and Ptk2p in ena1-4 $Delta$ cells and tested for LiCl sensitivity(Fig. 9D). Interestingly, overexpression of each of the threekinases further increased the LiCl sensitivity of the ena1-4 $Delta$ cells, suggesting that Ppz1p mediates the effect of the testedkinases via a mechanism that is different from that involved inthe suppression of ENA1expression.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Using a highly specific genetic screen that is based on spermine toxicity, we have demonstrated that Sky1, a recently identifiedyeast SR kinase, is involved in regulating polyamine transport.Two other serine/threonine kinases, Ptk1p and Ptk2p, were demonstratedto be regulators of polyamine transport in S. cerevisiae (20,21, 38). These kinases belong to a yeast-specific subfamilyof kinases that regulate the transport of salt ions and aminoacids (15). Npr1p, another member of this kinase family, wasalso shown to affect polyamine uptake in addition to regulatingamino acid permeases (54). Finally, Tpo1p, a member of the multidrugresistance family that was selected based on its homology to B.subtilis Blt, was demonstrated to transport polyamines into vacuoles(53). Here we demonstrate that a mutant strain with a disruptedSKY1 gene tolerates toxic concentrations of spermine in the growthmedium. The spermine-tolerant phenotype of sky1 $Delta$ cells was completelyreversed by transfection of the wild-type SKY1 gene, while thecatalytically inactive Sky1p mutant in which lysine-187 was convertedto alanine failed to restore spermine sensitivity. Furthermore,overexpression of Sky1p in wild-type cells increased their sensitivityto spermine. We have demonstrated that deletion of SKY1 conferstolerance to spermine by dramatically reducing its uptake by thecells. Deletion of SKY1 also dramatically inhibited the uptakeof spermidine and putrescine. Kinetic analysis demonstrated thatdisruption of SKY1 significantly reduced the V_max of spermidineuptake and increased the K_m.

We demonstrate here that, as in the case of ptk2 $Delta$ cells (17, 18), sky1 $Delta$ cells also tolerate both LiCl and NaCl. Whileincreasing salt tolerance, SKY1 disruption but not PTK2 disruptionincreased sensitivity to osmotic shock caused by 1.5 M KCl or1.5 M sorbitol. These observations suggest that both Ptk2p andSky1p are involved in regulating salt homeostasis but only Sky1pis involved in regulatingosmolarity.

Overexpression of Ptk2p in sky1 $Delta$ cells and of Sky1p in ptk2 $Delta$ cells both restored spermine sensitivity. However, the effectof Ptk2p in sky1 $Delta$ cells was more profound than that of Sky1p inptk2 $Delta$ cells. To some extent this result suggests that Ptk2p mayact downstream of Sky1p. To determine more directly the relationshipsbetween these two kinases, we generated sky1 $Delta$ ptk2 $Delta$ double mutantcells and tested their tolerance to spermine and lithium. Sincethe spermine tolerance displayed by the double mutant cells waseven greater than additive, we conclude that the two kinases actin two parallel signaling pathways. In the case of LiCl, the situationis less clear, since although being greater than that displayedby the two single mutants, the tolerance of the double mutantwas clearly less thanadditive.

A prominent possibility is that Sky1p and Ptk2p affect the membrane potential. The proton gradient at the plasma membranegenerated by the Pma1p H⁺/ATPase is an important determinant regulating the uptake andexcretion of various ions. Since the effect of SKY1 deletion orSky1p overexpression on Pma1p activity is very minimal, it isunlikely that Pma1p mediates the effect of Sky1p. In contrast,Pma1p activity is significantly increased in Ptk2p-overproducingcells and significantly decreased in ptk2 $Delta$ cells. This suggeststhat, at least in part, Ptk2p affect spermine and ion transportby altering membranepotential.

Sky1p, which was recently identified as the only SRPK of S. cerevisiae, may function like its metazoan counterparts in mRNAmaturation by regulating splicing or transport of mRNA from thenucleus to the cytoplasm (49). Therefore, it is possible thatthe effect of Sky1p on the process of polyamine transport maybe mediated through its effect on splicing or RNA transport. Insuch a case, it can be expected that the deletion of SR-containingsplicing factors may also result in a spermine-tolerant phenotype.Although only Np13p has so far been directly demonstrated to bea substrate for Sky1p, additional splicing-related proteins thatcontain SR-rich segments are encoded in the yeast genome. We havetested npl3 $Delta$ cells and cells containing disruptions of the genesencoding two additional putative Sky1p substrates, Gbp2p and Mud2p,for their ability to tolerate a toxic concentration of spermine.None of these deletion mutants tolerated spermine. These resultsmay indicate that the tested genes are not involved in regulatingspermine uptake, that there is redundancy in the function of thesegenes, that phosphorylation by Sky1p actually inhibits the activityof these proteins, which may act as inhibitors of the sperminetransport (in such a case, one should expect that their overexpression,rather than their deletion, will confer spermine tolerance), orthat other SR-containing proteins (splicing related or not) orproteins that lack SR segments mediate the effect of Sky1p. Inline with the fourth possibility, we have noted that Ppz1p andPpz2p, two protein phosphatases previously demonstrated to beimportant determinants of salt tolerance in S. cerevisiae, containSR-rich segments in their amino-terminal regions. We demonstratehere that overexpression of Sky1p as well as of Ptk1p and Ptk2pin ppz1 $Delta$ and ppz2 $Delta$ cells increased spermine sensitivity. In contrast,overexpression of these proteins increased LiCl sensitivity onlyin ppz2 $Delta$ cells, suggesting that Ppz1p is required for mediatingthe ability of these three kinases to increase LiCl sensitivity.In contrast, the ability of these kinases to increase sperminesensitivity may be mediated by either of the two Ppz proteinsor by a completely different mediator. To account for the firstpossibility, the deletion of both PPZ genes may be required toprevent the ability of the overexpressed kinases to increase sperminesensitivity. These possibilities as well as the possibility thatthe Ppz phosphatases are directly phosphorylated by Sky1p, Ptk1p,and Ptk2p are underinvestigation.

In the case of the induced sensitivity to lithium, it was tempting to speculate that Ppz1p mediates the action of each ofthe three kinases via its ability to suppress ENA1 expressionand thus reduce lithium efflux. However, since overexpressionof Sky1p, Ptk1p, and Ptk2p in ena1-4 $Delta$ cells increased their LiClsensitivity, we conclude that, if at all, Ppz1p mediates the effectof these kinases only partially via modulation of Ena1p activity.It is possible that the effect is manifested by regulating othercomponents involved in modulating ion transport across the plasmamembrane (such as the Trk1-Trk2 potassium transporters 10, 23,27) or into vacuoles. Ptk1p and Ptk2p are related to two otheryeast protein kinases, Hal4 and Hal5, that were demonstrated toregulate the Trk1-Trk2 transporters (34). However, if Ptk1pand Ptk2p and the presently identified kinase Sky1p are capableof modulating the Trk1-Trk2 potassium transporters, they do itin a manner opposite that manifested by Hal4p and Hal5p. Thispossibility is also underinvestigation.

Although Sky1p, Ptk1p, and Ptk2p are likely to display different site specificities, they appear to similarly modulate spermineand salt tolerance. This is likely due to their ability to phosphorylatethe same proteins or proteins that belong to the same signalingpathway. Identification of the substrates of these kinases isa major focus of the present studies. Although Sky1p, Ptk1p, andPtk2p appear to act similarly, there are some notable differencesbetween them. Ptk1p affects spermine and salt tolerance only whenoverexpressed. It has been suggested that Ptk1p affects vacuolartransporters (53). PTK1 disruption only marginally affects sensitivityto norspermine, a toxic polyamine analog (21), and does notconfer tolerance to a toxic spermine concentration (Fig. 2C).Ptk2p and Sky1p differ in two aspects: sky1 $Delta$ cells but not ptk2 $Delta$ cells display sensitivity to osmotic shock provoked by 1.5 M KCland, to a lesser extent, by 1.5 M sorbitol, and ptk2 $Delta$ cells displayedabout a 35% reduction in Pma1p activity, while increased Pma1pactivity was measured in Ptk2p-overproducing cells. In contrast,a marginal reduction or increase in Pma1p activity was noted inSky1p-overproducing and in sky1 $Delta$ cells, respectively (Fig. 8).

While Northern blot analysis revealed that SKY1 mRNA is normally expressed in sptC mutant cells, sequence analysis of SKY1DNA (amplified by PCR using sptC and wild-type DNA as templates)demonstrated that these transcripts encode a mutant protein inwhich leucine-301 was converted to phenylalanine. The mutatedleucine is an invariant residue fully conserved in catalytic domainVI of all SRPKs and clk/sty SRPKs (12, 37).

The present study expands our understanding of intracellular signaling that regulates the process of polyamine and ion transportin yeast cells. However, additional studies are required in orderto achieve comprehensive understanding of the underlying signalingpathways. Moreover, the identity of the plasma membrane polyaminetransporters is still an enigma. Identification and isolationof these transporters are major goals of our presentstudies.

	ACKNOWLEDGMENTS

We thank C. W. Slayman and K. Allen for anti-Pma1p antibody; A. Rodriguez-Navarro for the ena1-4 $Delta$ cells; and O. Giladi, J.Gerst, M. Marash, and N. Wender for their help and valuablediscussions.

This study was supported by a grant from the Leo and Julia Forchheimer Center for Molecular Genetics at the Weizmann Instituteof Science and by a research grant from the Jean-Jacques Brunschwigmemorialfund.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Genetics, The Weizmann Institute of Science, Rehovot 76100,Israel. Phone: 972-8-9342745. Fax: 972-8-9466599 or 972-8-9344108.E-mail: chaim.kahana{at}weizmann.ac.il.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Abovich, N., X. C. Liao, and M. Rosbash. 1994. The yeast MUD2 protein: an interaction with PRP11 defines a bridge between commitment complexes and U2 snRNP addition. Genes Dev. 8:843-854[Abstract/Free Full Text].
2.	Byers, T. L., R. Wechter, M. E. Nuttall, and A. E. Pegg. 1989. Expression of a human gene for polyamine transport in Chinese-hamster ovary cells. Biochem. J. 263:745-752[Medline].
3.	Casero, R. A., Jr., A. R. Mank, N. H. Saab, R. Wu, W. J. Dyer, and P. M. Woster. 1995. Growth and biochemical effects of unsymmetrically substituted polyamine analogues in human lung tumor cells 1. Cancer Chemother. Pharmacol. 36:69-74[Medline].
4.	Chang, A., and C. W. Slayman. 1991. Maturation of the yeast plasma membrane [H+]ATPase involves phosphorylation during intracellular transport. J. Cell Biol. 115:289-295[Abstract/Free Full Text].
5.	Clotet, J., F. Posas, E. de Nadal, and J. Arino. 1996. The NH₂-terminal extension of protein phosphatase PPZ1 has an essential functional role. J. Biol. Chem. 271:26349-26355[Abstract/Free Full Text].
6.	Cohen, S. 1998. A guide to the polyamines. Oxford University Press, New York, N.Y.
7.	Eraso, P., and F. Portillo. 1994. Molecular mechanism of regulation of yeast plasma membrane H⁺-ATPase by glucose. J. Biol. Chem. 269:10393-10399[Abstract/Free Full Text].
8.	Estrada, E., P. Agostinis, J. R. Vandenheede, J. Goris, W. Merlevede, J. Francois, A. Goffeau, and M. Ghislain. 1996. Phosphorylation of yeast plasma membrane H⁺-ATPase by casein kinase I. J. Biol. Chem. 271:32064-32072[Abstract/Free Full Text].
9.	Fiske, C. H., and Y. Subbarow. 1925. The colorimetric determination of phosphorus. J. Biol. Chem. 66:375-400[Free Full Text].
10.	Gaber, R. F., C. A. Styles, and G. R. Fink. 1988. TRK1 encodes a plasma membrane protein required for high-affinity potassium transport in Saccharomyces cerevisiae. Mol. Cell. Biol. 8:2848-2859[Abstract/Free Full Text].
11.	Garciadeblas, B., F. Rubio, F. J. Quintero, M. A. Banuelos, R. Haro, and A. Rodriguez-Navarro. 1993. Differential expression of two genes encoding isoforms of the ATPase involved in sodium efflux in Saccharomyces cerevisiae. Mol. Gen. Genet. 236:363-368[CrossRef][Medline].
12.	Hanks, S. K., A. Quin, and T. Hunter. 1988. The protein kinase family: conserved features and deduced phylogeny of the catalytic domains. Science 241:42-51[Abstract/Free Full Text].
13.	Haro, R., B. Garciadeblas, and A. Rodriguez-Navarro. 1991. A novel P-type ATPase from yeast involved in sodium transport. FEBS Lett. 291:189-191[CrossRef][Medline].
14.	Heaton, M. A., and W. F. Flintoff. 1988. Methylglyoxal-bis(guanylhydrazone)-resistant Chinese hamster ovary cells: genetic evidence that more than a single locus controls uptake. J. Cell. Physiol. 136:133-139[CrossRef][Medline].
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