Hph1p and Hph2p, Novel Components of Calcineurin-Mediated Stress Responses in Saccharomyces cerevisiae

Calcineurin is a Ca²⁺- and calmodulin-dependent protein phosphatasethat plays a key role in animal and yeast physiology. In theyeast Saccharomyces cerevisiae, calcineurin is required forsurvival during several environmental stresses, including highconcentrations of Na⁺, Li⁺, and Mn²⁺ ions and alkaline pH. Onerole of calcineurin under these conditions is to activate geneexpression through its regulation of the Crz1p transcriptionfactor. We have identified Hph1p as a novel substrate of calcineurin.HPH1 (YOR324C) and its homolog HPH2 (YAL028W) encode tail-anchoredintegral membrane proteins that interact with each other inthe yeast two-hybrid assay and colocalize to the endoplasmicreticulum. Hph1p and Hph2p serve redundant roles in promotinggrowth under conditions of high salinity, alkaline pH, and cellwall stress. Calcineurin modifies the distribution of Hph1pwithin the endoplasmic reticulum and is required for full Hph1pactivity in vivo. Furthermore, calcineurin directly dephosphorylatesHph1p and interacts with it through a sequence motif in Hph1p,PVIAVN. This motif is related to calcineurin docking sites inother substrates, such as NFAT and Crz1p, and is required forregulation of Hph1p by calcineurin. In contrast, Hph2p neitherinteracts with nor is dephosphorylated by calcineurin. Ca²⁺-inducedCrz1p-mediated transcription is unaffected in hph1 ${Delta}$ hph2 ${Delta}$ mutants,and genetic analyses indicate that HPH1/HPH2 and CRZ1 act indistinct pathways downstream of calcineurin. Thus, Hph1p andHph2p are components of a novel Ca²⁺- and calcineurin-regulatedresponse required to promote growth under conditions of highNa⁺, alkaline pH, and cell wall stress.

INTRODUCTION

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Introduction

Calcineurin is a Ca²⁺- and calmodulin-regulated serine/threonineprotein phosphatase that is highly conserved throughout evolutionand exists in yeasts and metazoans (for a review see reference3). In mammals, calcineurin plays key roles in the developmentof skeletal and cardiac muscle, angiogenesis, embryonic axonoutgrowth, and T-cell activation (12, 19, 23, 24, 37, 40). Calcineurinis not required for growth of the budding yeast Saccharomycescerevisiae under standard laboratory conditions. It does, however,play a critical role in enabling this yeast to survive highconcentrations of Na⁺, Li⁺, and Mn²⁺ ions, alkaline pH, prolongedexposure to mating factor, and cell wall stress (14, 15, 20,38). Calcineurin consists of a catalytic A subunit and regulatoryB subunit; in S. cerevisiae, the A subunit is encoded by twofunctionally redundant genes, CNA1 and CNA2, and the regulatorysubunit is encoded by CNB1 (15, 16, 30, 32). Upon exposure toenvironmental stresses such as high concentrations of Na⁺, cytosolicCa²⁺ concentrations increase and activate calcineurin.

A key downstream effector of calcineurin in S. cerevisiae isthe zinc finger transcription factor Crz1p (33, 35, 46). Calcineurindephosphorylates Crz1p, enabling its translocation to the nucleus,where it transactivates a number of genes through its bindingto calcineurin-dependent response elements in their promoters(46, 47). Crz1p regulates the expression of genes involved inseveral processes, including ion and small-molecule transport,cell wall maintenance, and vesicular transport (13, 25, 34,36, 41, 51). One calcineurin- and Crz1p-regulated gene, ENA1,encodes a P-type ATPase that plays a critical role in the extrusionof Na⁺ ions under conditions of high extracellular Na⁺ and highpH (25).

The growth of calcineurin mutants is severely reduced at alkalinepH. Under these conditions, the activity of the vacuolar H⁺-ATPaseand other ion pumps is critical for survival of S. cerevisiae.Also, the uptake of nutrients such as phosphate, iron, and copperions, whose solubility decreases at high pH, becomes rate limitingfor growth (1, 22, 43). Calcineurin- and Crz1p-dependent transactivationof a calcineurin-dependent response element-driven reportergene is strongly induced in response to alkaline pH, and thissignaling pathway is responsible for regulating the transcriptionof a subset of the genes induced under these conditions (43).Despite the central role of Crz1p in calcineurin signaling,there is evidence to suggest that it is not the sole mediatorof calcineurin-dependent signaling. crz1 ${Delta}$ cells are less sensitivethan calcineurin-null cells to high concentrations of Na⁺, Li⁺,and Mn²⁺ and particularly to alkaline pH (22, 46), suggestingthat calcineurin regulates additional downstream targets topromote survival under these conditions. Recent microarray analysesindicate that all Ca²⁺- and Na⁺-induced calcineurin-dependentgene expression is mediated via Crz1p (51). This suggests thatadditional calcineurin effectors act via nontranscriptionalmechanisms.

High-throughput yeast-two-hybrid studies performed by Uetz etal. identified an interaction between Cna1p and the proteinencoded by uncharacterized open reading frame (ORF) YOR324C(48). Both this protein and a closely related gene product encodedby YAL028W have been shown to localize to the endoplasmic reticulum(ER), but their function has yet to be elucidated (6). In thisstudy we showed that Yor324Cp interacts with both Cna1p andCna2p and is a novel substrate of calcineurin. Calcineurin regulatesYor324Cp function in vivo and affects its distribution withinthe ER. Mutants lacking both YOR324C and its homologue YAL028Ware sensitive to high concentrations of Na⁺ and cell wall stressand are particularly defective in their ability to grow on alkalinemedium. Thus, we have identified YOR324C, designated HPH1 (highpH), and YAL028W, designated HPH2, as novel components of theyeast stress response.

MATERIALS AND METHODS

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Materials and Methods

Yeast strains and media. Yeast media and culture conditions were essentially as previouslydescribed (44) except that twice the level of amino acids andnucleotides was used in synthetic media. Yeast transformationswere performed with the lithium acetate method (4). Yeast strainsare listed in Table 1; strains from the yeast deletion collectionwere purchased from Open Biosystems. VHY60 was constructed bymating strain 1621 with 10380 (BY4739 MAT ${alpha}$ hph2 ${Delta}$ ::KAN) (yeastdeletion collection). The diploids were sporulated and tetradswere dissected to generate a strain that contained both hph1 ${Delta}$ ::KANand hph2 ${Delta}$ ::KAN and was isogenic with BY4741. VHY74.1 was generatedby transforming VHY60 with a cassette containing a HIS3-disruptedallele of CRZ1 from the previously described plasmid pIMG38(35). VHY87 was generated by integrating a cassette for expressinghigh levels of a gene encoding Kar2 presequence-DsRed.T1-HDEL(7) into the TRP1 locus of EG123 (MAT ${alpha}$ leu2-3,112 ura3-52 trp1-1his4 canl) (gift of D. Levin). This cassette was generated bydigesting the YIplac204/TKC-DsRed-HDEL plasmid with EcoRV (giftof B. Glick).

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TABLE 1. Strains used in this study

Plasmids. The plasmids used in this study are reported in Table 2. RecombinantDNA procedures were performed as previously described (4). Inall cases, genes were cloned by amplification of genomic DNAwith vent polymerase (New England Biolabs) to create fragmentsflanked by restriction sites for cloning into the vector ofinterest. Sequencing reactions with ET Terminator (Amersham)and ABI Big Dye sequencing chemistry (Amersham) were performedto ensure that all amplified DNA fragments had the correct sequence.

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TABLE 2. Plasmids used in this study

N-terminal green fluorescent protein (GFP) fusions of HPH1 andHPH2 were created by cloning the ORF of HPH1 (YOR324C) as aBamHI-HindIII fragment and HPH2 (YAL028W) as a BamHI-XhoI fragmentinto pUG36 (CEN URA3 pMET25-yEGFP3; gift of U Güldenerand J. H. Hegemann) to create pVH1 and pVH2, respectively. Inorder to create pVH10, the CFP-HPH1 fusion yEGFP3 of pUG36 wasfirst replaced with cyan fluorescent protein (CFP) amplifiedfrom pDH3 (provided by the National Center for Research ResourcesYeast Resource Center, University of Washington) and flankedby XbaI and BamHI sites; the HPH1 BamHI-HindIII fragment wasthen cloned into this vector. In order to create pVH11 containingthe YFP-HPH2 fusion, HPH2 was first subcloned from pUG36 intopUG34 (CEN HIS3 pMET25-yEGFP3) and then yEGFP3 was replacedwith yellow fluorescent protein (YFP) amplified from pDH5 (providedby the National Center for Research Resources Yeast ResourceCenter) flanked with XbaI and BamHI.

For yeast-two-hybrid studies, the pACTII and pGBT9 vectors wereused to create GAL4 activation and binding domain fusions, respectively.A SmaI-BamHI fragment of HPH2 was cloned into pACTII to createpVH4, and a SmaI-BamHI fragment of CNA2 was cloned into pGBT9to create pVH7. A SmaI-BamHI fragment of HPH1 was cloned intopACTII and pGBT9 to create pVH3 and pVH6, respectively. A PCR-basedmutagenesis strategy was used to delete amino acids 72 to 77of HPH1, encoding PVIAVN. Two fragments were amplified, whichwere then ligated together into pACTII. Fragment 1 comprisedthe 5' end of HPH1 flanked by a BamHI site at the N terminusand the endogenous unique XbaI site at position 205. Fragment2 was generated with a forward primer of nucleotides 195 to213 and 232 to 251 of HPH1 (this contained the endogenous XbaIsite and encoded the deletion of the PVIAVN motif) and a reverseprimer with a flanking XhoI site. BamHI-XbaI fragment 1 andXbaI-XhoI fragment 2 were cloned into pACTII digested with BamHIand XhoI to create pVH5.

Construction of pVH12 (GFP-Hph1- ${Delta}$ PVIAVN) was performed by simultaneouslyligating BamHI-XbaI fragment 1 and XbaI-XhoI fragment 2 (describedabove) with pUG36 digested with BamHI and XhoI. In order tocreate pVH8, a fragment comprising the HPH1 ORF and preceding797 nucleotides was amplified from genomic DNA, flanked withBamHI and HindIII sites, and cloned into pRS315. To constructpVH9, the BamHI-XbaI DNA fragment with the promoter and 5' 205bp of HPH1 from pVH8 and the XbaI-XhoI fragment from the constructionof pVH5 were simultaneously ligated into pRS315 cut with BamHIand XhoI.

Immunoblot analysis. Yeast cells expressing GFP-Hph1p or GFP-Hph2p cultures weregrown to log phase in synthetic medium lacking uracil and methionine.In order to assess the mobility of GFP-Hph1p and GFP-Hph2p aftertreatment with CaCl₂, 10 optical density units at 600 nm ofcells were treated or not with CaCl₂ at a final concentrationof 200 mM at 30°C for 10 min. Cells were pelleted and frozenin liquid nitrogen prior to preparation of extract. Extractwas prepared by a method modified from that previously describedby Davis et al. (18). Cells were thawed by resuspension in 100µl of SBS buffer (40 mM Tris-HCl [pH 6.8], 8 M urea, 0.1mM EDTA, 1% 2-mercaptoethanol, 5% sodium dodecyl sulfate [SDS])and added to an 80-µl volume of glass beads. Samples werethen mixed by vortexing for 10 min at room temperature and incubatedat 37°C for 10 min; 100 µl of 2x SDS-polyacrylamidegel electrophoresis (PAGE) sample buffer was added, and thesamples were vortexed for a further 2 min at room temperature.Finally they were centrifuged at 16,000 x g for 5 min. Sampleswere further diluted by adding equal volumes of supernatantwith 2x SDS-PAGE sample buffer. Samples were run on 5 to 12%or 7 to 11% polyacrylamide-SDS gradient gels and transferredto nitrocellulose. Blots were incubated with JL8 monoclonalanti-GFP antibody (Becton Dickinson) and then with horseradishperoxidase-conjugated anti-mouse immunoglobulin (Amersham) andvisualized with an ECL kit (Amersham).

In vitro phosphatase assay. DD12 cells expressing GFP-Hph1p were grown to log phase in 200ml of synthetic medium lacking uracil and methionine and harvestedat an optical density at 600 nm of 1. Cells were washed andresuspended in 2 ml of TL buffer (40 mM Tris-HCl [pH 7.5], 100mM KCl, 1 mM MgCl₂, 250 mM sorbitol, 1 mM dithiothreitol, 0.1%NP-40) containing protease inhibitors (1 µg of pepstatinper ml, 2 µg of leupeptin per ml, 2 µg of aprotininper ml, 1 mM phenylmethylsulfonyl fluoride, 1.25 mM benzamidine-HCl)and phosphatase inhibitors (5 mM sodium phosphate, 10 mM sodiummolybdate, 20 mM sodium fluoride, 10 mM sodium pyrophosphate,5 mM EGTA, and 5 mM EDTA), and extracts were prepared by glassbead lysis (50).

The resulting extract was incubated with 100 µl of a 50%slurry of washed protein A-agarose beads (Sigma) and 10 µlof polyclonal rabbit anti-GFP (Becton Dickinson) for 2 h withrotation at 4°C. Immunoprecipitates were washed twice inTL buffer containing protease inhibitors and phosphatase inhibitors,twice in TL buffer containing protease inhibitors only, andtwice in CP buffer (50 mM Tris-HCl [pH 7.5], 1 mM MgCl₂, 1 mMdithiothreitol) containing protease inhibitors. Washed beadswere divided among five tubes prior to different phosphatasetreatments. Phosphatase assays were performed in a total of100 µl in CP buffer for calcineurin and in the suppliedbuffer for ${lambda}$ -phosphatase (New England Biolabs); 500 U of recombinanthuman calcineurin (Calbiochem), 2,600 U of calmodulin (Calbiochem),or 10 µl of ${lambda}$ -phosphatase (New England Biolabs) was usedper assay. Where indicated, CaCl₂ was added to a final concentrationof 40 mM and EGTA to 10 mM. Phosphatase assays were incubatedat 30°C for 30 min; the supernatant was then removed, andSDS-PAGE sample buffer was added to the beads. Samples werethen run on a 5 to 12% gradient polyacrylamide-SDS gel and blottedas described above. Blots were visualized with SuperSignal reagent(Pierce).

Spot assays. Growth of various mutants was assessed by spotting serial dilutionsof stationary-phase yeast cultures on plates containing variousions or chemicals. Cultures were diluted to an optical densityat 600 nm of 0.5, and five fivefold serial dilutions were prepared.Plates were prepared with YPD containing 50 mM Tris-HCl (pH8.4 or 8.8), 50 mM morpholineethanesulfonic acid (MES, pH 5.5),1 M NaCl, 2 mg of Congo Red or 0.188 mg of Calcofluor White(fluorescent brightener 28 [Sigma]) per ml. Where indicated,FK506 (Fujisawa) was added to a concentration of 2 µg/ml.Plates were incubated at room temperature for 3 days for YPDand YPD pH 5.5, 4 days for YPD pH 8.5 and pH 8.8, CalcofluorWhite, and Congo Red, and 5 days for NaCl.

Yeast two-hybrid assays. Yeast two-hybrid assays were performed by introducing combinationsof Gal4p activation and binding domain fusions into strain PJ69-4A,which contains a GAL1 promoter-HIS3 reporter gene. To performthe yeast two-hybrid assays, these strains were grown in selectivemedium and spotted onto synthetic medium containing and lackinghistidine. These spot assays were set up exactly as describedabove, and the plates were incubated for 3 days at 30°C.

Microscopy. To examine the localization of GFP-Hph1p and GFP-Hph2p in wild-type(YPH499) cells, this strain was transformed with plasmid pVH1and pVH2, respectively. Liquid cultures were set up in syntheticmedium lacking uracil and with either low levels of methionine(3 mg/liter) for expression of GFP-Hph1p or no methionine forexpression of GFP-Hph2p. In order to investigate the localizationof Hph1p and Hph2p relative to the ER, strain VHY87.1, expressingHDEL-DsRed, was transformed with plasmid pVH1 or pVH2, respectively,and cultures were prepared as described above. To localize Hph1pand Hph2p in the same cell, wild-type cells (YPH499) were transformedwith plasmids pVH10 and pVH11, expressing CFP-Hph1p and YFP-Hph2p,respectively. In this case, cultures were grown in syntheticmedium lacking uracil, histidine, and methionine. Log-phasecultures at an optical density at 600 nm of 1.0 were concentratedby brief centrifugation and mounted on microscope slides precoatedwith a 25% gelatin solution made with the corresponding medium.

Cells expressing a single GFP fusion were visualized with aNikon Eclipse E600 microscope with fluorescence optics and anHB100 mercury lamp. Fluorescein filter sets (Chroma) were usedto visualize GFP. Photos were taken with a Hammamatsu digitalcharge-coupled device 47420-95 camera and QED software (QEDImaging). For colocalization studies, cells were imaged witha Nikon TE200 inverted microscope with a 100x 1.3NA objectivelens. Independent excitation (CFP, 436 ± 10 nm; YFP;493 ± 17 nm; and red fluorescent protein [RFP], 580 ±20 nm) and emission (CFP, 465 ± 30 nm; YFP, 530 ±40 nm; and RFP, 630 ± 60 nm) filters were used in conjunctionwith a three-pass dichroic mirror (Chroma 28311). GFP was imagedeither with the YFP filter combination or with the same YFPand RFP excitation filters in combination with the Chroma 13699three-pass emitter and Chroma 20597 three-pass beam splitter.Image acquisition, controlled via MetaMorph software (UniversalImaging Corporation), ranged from 50 to 1,500 ms with a PrincetonInstruments PE1300 cooled charge-coupled device camera. Colocalizationstudies were performed with sequential acquisitions having 30ms of dead time between images.

For estimation of the total number of foci in a cell, wild-type(YPH499) and cnb1 ${Delta}$ (DD12) cells expressing GFP-Hph1p (pVH1) weregrown to log phase in synthetic medium lacking uracil and containingmethionine at 3 mg/liter as described above. Cells were eitherimaged directly or treated with CaCl₂ (200 mM) for 10 min priorto visualization with the Nikon TE200 inverted microscope incombination with MetaMorph software, as described above. A throughseries of 18 images at 0.5-µm steps was taken with a calibratedstepper motor to adjust focus. Images were projected into asingle plane, with the maximum values at each pixel position.For each cell, fluorescent foci were counted and then dividedby the area of the cell in pixels to give the value for thenumber of foci per unit area. Data from 30 to 40 cells werecollected for each condition, and the mean was determined.

RESULTS

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Results

Hph1p but not Hph2p interacts with Cna1p and Cna2p and is a substrate of calcineurin. Genomewide yeast two-hybrid analyses demonstrated an interactionbetween the calcineurin A subunit, Cna1p, and the uncharacterizedORF YOR324C (now designated HPH1) and between YOR324C and itsclose homolog YAL028W (designated HPH2) (48). We used a directedyeast two-hybrid approach to confirm and extend these observations.N-terminal fusions were created between the Gal4p activationdomain with Hph1p and Hph2p and the Gal4p binding domain withCna1p and Cna2p. Combinations of the constructs, as indicatedin Fig. 1, were expressed in strain PJ69-4A, containing a GAL1promoter-HIS3 reporter, and interactions were assayed by determiningthe extent of growth on medium lacking histidine. Hph1p butnot its homolog Hph2p interacted with both calcineurin A subunits,Cna1p and Cna2p. Furthermore, using a Gal4p activation domainHph2p fusion and a Gal4p binding domain Hph1p fusion, we reproducedthe interaction seen previously between Hph1p and Hph2p (Fig.1). We have also found by yeast two-hybrid assays that Hph2pis able to interact with itself (data not shown). In contrast,self-association of Hph1p could not be assessed due to toxicityof the Hph1p Gal4p activation domain fusion in combination witheither the Hph1p or Hph2p Gal4p binding domain fusions.

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FIG. 1. Hph1p but not Hph2p interacts with Cna1p and Cna2p in yeast two-hybrid assays, and Hph1p and Hph2p interact with each other. A strain (PJ69-4A) containing a GAL1-HIS3 reporter gene was transformed with combinations of GAL4 binding domain fusions of CNA1 (BJP2014), CNA2 (pVH7) or HPH1 (pVH6) (BD) and GAL4 activation domain fusions of HPH1 (pVH3) and HPH2 (pVH4) (AD), as indicated. Cells were grown as described in Materials and Methods, plated on synthetic medium containing (+His) or lacking (–His) histidine, and incubated for 3 days at 30°C.

Since Hph1p can interact with both calcineurin A subunits, wedetermined whether it is a substrate of calcineurin. FunctionalN-terminal GFP fusions of Hph1p and Hph2p were created (seeMaterials and Methods), and their electrophoretic mobility wasexamined by SDS-PAGE. Calcium treatment of wild-type cells resultedin an increased electrophoretic mobility of GFP-Hph1p. No changein mobility was observed in CaCl₂-treated calcineurin-null cells(cnb1 ${Delta}$ , lacking the calcineurin regulatory B subunit), and inthese cells GFP-Hph1p exhibited a slower-migrating form (Fig.2A). Similar results were seen with epitope-tagged Hph1p expressedat endogenous levels (data not shown). These data indicate thatthe calcium-induced mobility shift of Hph1p is calcineurin dependent,and in vitro assays demonstrated that Hph1p is a direct substrateof calcineurin (Fig. 2B). GFP-Hph1p immunoprecipitated fromcalcineurin-deficient cells showed an increased mobility whentreated with recombinant calcineurin, calmodulin, and CaCl₂,and this could be blocked by the additionof the Ca²⁺ chelatorEGTA (Fig. 2B). Though this in vitro calcineurin-mediated increasein mobility of GFP-Hph1p is smaller than that seen in vivo,it was reproducible. Treatment with ${lambda}$ -phosphatase resulted inan increased mobility of GFP-Hph1p compared with the calcineurintreatment, suggesting that there are phosphorylated residuesof Hph1p that are not removed by calcineurin.

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FIG. 2. Hph1p but not Hph2p is dephosphorylated upon CaCl₂ treatment in a calcineurin-dependent manner. (A) Wild-type (WT, YPH499) and cnb1 ${Delta}$ (DD12) cells expressing GFP-Hph1p (pVH1) or GFP-Hph2p (pVH2) were grown to log phase and either mock treated or treated with 200 mM CaCl₂ for 10 min. Cells were then frozen in liquid N₂ and extracts were prepared (see Materials and Methods). Extracts were subjected to SDS-PAGE and Western blotted with an anti-GFP antibody. (B) Extracts were prepared from wild-type (YPH499) and cnb1 ${Delta}$ (DD12) cells expressing GFP-Hph1p (pVH1). Immunoprecipitated (ip) GFP-Hph1p from cnb1 ${Delta}$ cells was treated with recombinant calcineurin (CN), calmodulin (CMD), CaCl₂, EGTA, or ${lambda}$ -phosphatase ( ${lambda}$ -pptase) as indicated in the left-hand lanes (see Materials and Methods). These samples, together with untreated immunoprecipitates of GFP-Hph1p from wild-type and cnb1 ${Delta}$ cells, were then subjected to SDS-PAGE and Western blotted with an anti-GFP antibody.

No change in the electrophoretic mobility of GFP-Hph2p was observedwhen wild-type or calcineurin-null cells were treated with CaCl₂,suggesting that Hph2p is not a substrate of calcineurin. Thisis consistent with the lack of interaction observed betweencalcineurin and Hph2p in yeast two-hybrid analysis. Thus, Hph1pinteracts with and is dephosphorylated by calcineurin. Hph2pbinds Hph1p but does not interact with and is not dephosphorylatedby calcineurin.

Hph1p and Hph2p are required for growth under high NaCl, alkaline pH, and cell wall stress. In order to further elucidate the functions of Hph1p and Hph2p,we examined strains lacking each of these genes as well as anhph1 ${Delta}$ hph2 ${Delta}$ double mutant. Since Hph1p is a substrate of calcineurin,we examined the phenotypes of these strains in a number of conditionsunder which calcineurin-deficient cells exhibit growth defects.We found no growth defect for the hph1 ${Delta}$ and hph2 ${Delta}$ single mutantstrains, but the hph1 ${Delta}$ hph2 ${Delta}$ strain showed reduced growth on alkalinemedia, media containing high levels of Na⁺ ions, and media containingthe cell wall disruptants Calcofluor White and Congo Red. Theseeffects were more pronounced when cells were grown at 25°C(Fig. 3). No growth defects were observed on medium containinghigh levels of Mn²⁺, Li⁺, or Ca²⁺ ions or sorbitol or at hightemperature (data not shown).

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FIG. 3. hph1 ${Delta}$ hph2 ${Delta}$ cells are sensitive to growth in conditions of high pH and high NaCl and with Calcofluor White and Congo Red. Wild-type (WT, BY4741), hph1 ${Delta}$ (strain 1621), hph2 ${Delta}$ (strain 380), and hph1 ${Delta}$ hph2 ${Delta}$ (strain VHY60) strains were grown to stationary phase in YPD. Cultures were then diluted to an optical density at 600 nm of 0.5, and fivefold serial dilutions were spotted on YPD plates with no addition, 50 mM Tris-HCl at pH 8.8, 50 mM MES at pH 5.5, 1 M NaCl, 2 mg of Congo Red per ml, or 0.188 mg of Calcofluor White per ml. Plates were incubated at room temperature for 3 days for YPD and pH 5.5, 4 days for pH 8.8, Calcofluor White, and Congo Red, and 5 days for NaCl.

An uncharacterized ORF, YOR325W, is located within the codingsequence of HPH1 on the opposite strand. A DNA fragment thatcontained the complete sequence of YOR325W but only part ofthe YOR324C (HPH1) ORF failed to complement the growth defectsof hph1 ${Delta}$ hph2 ${Delta}$ mutants at alkaline pH or high Na⁺ (data not shown).Thus, the growth defects that we observed can be attributedto elimination of the protein encoded by YOR324C (Hph1p) andnot that encoded by YOR325W.

Genetic interactions of HPH1, HPH2, calcineurin, and CRZ1. We examined the genetic interactions between HPH1, HPH2, CRZ1,and calcineurin (CNB1) to clarify the role of HPH1 and HPH2in the calcineurin signaling pathway. CRZ1 encodes a calcineurin-dependenttranscription factor, and crz1 ${Delta}$ mutants exhibit a growth defectat high pH that is less severe than that seen with a calcineurinmutant. hph1 ${Delta}$ hph2 ${Delta}$ crz1 ${Delta}$ mutants are more sensitive to high pHthan crz1 ${Delta}$ or hph1 ${Delta}$ hph2 ${Delta}$ strains (Fig. 4), establishing that Crz1pacts independently of Hph1p and Hph2p to promote growth at highpH. Furthermore, Crz1p- and calcineurin-dependent transcriptioncan be measured with a reporter gene (CDRE::lacZ) in which theß-galactosidase gene is controlled by the Crz1p bindingsite (calcineurin-dependent response element) (46). hph1 ${Delta}$ hph2 ${Delta}$ cells exhibit no defect in Ca²⁺- and calcineurin-dependent CDRE::lacZexpression (data not shown), confirming that Hph1p and Hph2pfunction independently of Crz1p. In contrast, when grown inthe presence of the calcineurin inhibitor FK506, wild-type,hph1 ${Delta}$ hph2 ${Delta}$ , and crz1 ${Delta}$ strains exhibit identical growth defectsat high pH. Thus, a defect in calcineurin is epistatic to defectsin crz1 or hph1 and hph2. This observation is consistent witha role for calcineurin in controlling the functions of Crz1p,Hph1p, and Hph2p. Together with biochemical studies that establishCrz1p and Hph1p as substrates of calcineurin, these geneticobservations confirm that Crz1p, Hph1p, and Hph2p act independentlyof each other and are downstream of (i.e., controlled by) calcineurin.

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FIG. 4. Phenotypic analysis shows that the high-pH growth defects of hph1 ${Delta}$ , hph2 ${Delta}$ , and crz1 ${Delta}$ mutations are additive and that loss of calcineurin function is epistatic to hph1 ${Delta}$ , hph2 ${Delta}$ , and crz1 ${Delta}$ . Cells were plated as described for Fig. 3 to compare growth between wild-type (WT), hph1 ${Delta}$ , hph2 ${Delta}$ , hph1 ${Delta}$ hph2 ${Delta}$ , cnb1 ${Delta}$ (strain 5040), crz1 ${Delta}$ (strain 5353) and hph1 ${Delta}$ hph2 ${Delta}$ crz1 ${Delta}$ (strain VHY74.1) strains on YPD at pH 5.5 (50 mM MES) and YPD at pH 8.4 (50 mM Tris) containing either solvent (–) or the calcineurin inhibitor FK506 (+) at 2 µg/ml. Plates were incubated at room temperature for 3 days for pH 5.5 and 4 days for pH 8.4.

To further examine the physiological relevance of the calcineurin-dependentdephosphorylation of Hph1p, we constructed a mutant allele ofHPH1 that is defective in its regulation by calcineurin. Calcineurinhas been shown to interact with substrates via a docking sitethat is distinct from sites of dephosphorylation. Furthermore,mutant substrates that lack this docking site are defectivefor calcineurin-dependent regulation (2, 11). We sought to identifythe sequence in Hph1p that is required for its interaction withcalcineurin as follows. Using a series of two-hybrid constructs,we established that a sequence between amino acids 50 and 100is required for Hph1p interaction with calcineurin (data notshown). We examined this region and identified a sequence (aminoacids 72 to 77), PVIAVN, that is conserved in HPH1 fungal homologsbut is not present in HPH2 or its homologs. This sequence isrelated to the PxIxIT calcineurin-binding motif defined in NFATand the equivalent site, PIISIQ, that mediates interaction betweenCrz1p and yeast calcineurin (2, 11). We therefore deleted thissequence to create the hph1- ${Delta}$ PVIAVN allele.

Hph1- ${Delta}$ PVIAVNp failed to interact with Cna1p or Cna2p (calcineurincatalytic subunits) in two-hybrid assays, and the protein encodedby hph1- ${Delta}$ PVIAVN did not display a Ca²⁺- and calcineurin-dependentincrease in electrophoretic mobility (Fig. 5A and B). Thesetwo observations indicate that the protein encoded by hph1- ${Delta}$ PVIAVNis not dephosphorylated by calcineurin. Note, however, thatthe mutant protein was present at levels similar to that ofHph1p (Fig. 5B). To determine the contribution of calcineurinto Hph1p function, hph1- ${Delta}$ PVIAVN was introduced into hph1 ${Delta}$ hph2 ${Delta}$ cells, and the resulting strain was tested for its ability togrow at high pH. The results indicate that Hph1- ${Delta}$ PVIAVNp is partiallyfunctional, i.e., the strain containing Hph1- ${Delta}$ PVIAVNp grew betterthan the hph1 ${Delta}$ hph2 ${Delta}$ strain but not as well as a strain containinga wild-type copy of HPH1 (Fig. 5C). Similar results were observedfor growth of cells on medium containing Na⁺ or Calcofluor White(data not shown). This suggests that calcineurin modulates Hph1pfunction but is not completely required for its activity.

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FIG. 5. Hph1p lacking the motif PVIAVN does not bind Cna1p or Cna2p, is not dephosphorylated upon treatment with CaCl₂, and only partially complements the growth defects of the hph1 ${Delta}$ hph2 ${Delta}$ mutant at high pH. (A) A yeast two-hybrid assay was set up with PJ69-4A cells expressing CNA1 (BJP2014) or CNA2 (pVH7) GAL4 binding domain fusions (BD) in combination with GAL4 activation domain fusions (AD) of wild-type HPH1 (pVH3) or HPH1- ${Delta}$ PVIAVN (Hph1*) (pVH5), as indicated. Cells were plated on medium containing (+His) and lacking (–His) histidine and incubated for 3 days at 30°C. (B) Wild-type (WT, YPH499) cells expressing GFP-Hph1p (pVH1) or GFP-Hph1- ${Delta}$ PVIAVNp (GFP-Hph1*) (pVH12) were grown to log phase and then either mock treated or treated with 200 mM CaCl₂ for 10 min. Samples were then frozen in liquid N₂, extracts were prepared, and SDS-PAGE followed by Western blotting with an anti-GFP antibody was performed (see Materials and Methods). (C) Wild-type (WT, BY4741) and hph1 ${Delta}$ hph2 ${Delta}$ (VHY60) cells were transformed with either empty vector (–) (pRS315) or plasmids to express endogenous levels of wild-type Hph1p (pVH8) or Hph1- ${Delta}$ PVIAVN (Hph1*) (pVH9). Cultures were grown in selective synthetic medium to the stationary phase, diluted as described for Fig. 3, plated on YPD at pH 5.5 (50 mM MES) and YPD at pH 8.8 (50 mM Tris), and incubated at room temperature for 3 and 4 days, respectively.

Hph1p and Hph2p are integral membrane proteins associated with the endoplasmic reticulum. Analysis of the predicted coding sequences of Hph1p and Hph2prevealed the presence of one putative membrane-spanning domainnear the C terminus of each protein. We confirmed that GFP-Hph1pand GFP-Hph2p associated with the P13 pellet during fractionationand found that they cosedimented with Dpm1p, a resident ER protein,in a sucrose gradient (data not shown). Additionally, consistentwith previous studies, treatment with detergent was requiredto solubilize Hph1p and Hph2p (data not shown) (6). These observationssuggest that Hph1p and Hph2p are both integral membrane proteinsand are found in the ER.

To further investigate Hph1p and Hph2p localization, we examinedcells containing functional GFP fusions of these proteins. GFPwas fused to the N terminus of Hph1p and Hph2p, and expressionwas controlled by the MET25 promoter. In the case of GFP-Hph1p,a small amount of methionine was added to partially reduce expressionof this fusion protein. It was not possible to visualize Hph1por Hph2p expressed under their own promoters even when a fusionto three tandem copies of GFP was created. Experiments performedto determine the localization of all yeast genes and ORFs alsofailed to visualize Hph1p and Hph2p tagged genomically withGFP (27).

Consistent with previous observations, GFP-Hph1p localized tothe cell and nuclear periphery in a pattern characteristic ofproteins resident in the ER, although it exhibited a punctatelocalization that is not typical of ER proteins (Fig. 6A) (6).These punctate foci of GFP-Hph1p colocalized with the establishedHDEL-DsRed marker, which uniformly labels the ER (Fig. 6B).Characterization of GFP-Hph1p by time-lapse imaging revealedthat the GFP-Hph1p foci moved rapidly in live cells and thattheir movements were constrained by and correlated with movementsof the ER (data not shown). GFP-Hph2p also localized to theER and, consistent with previous observations, exhibited a morediffuse distribution than that seen with GFP-Hph1p (Fig. 6A)(6). Similarly, GFP-Hph2p colocalized with the HDEL-DsRed marker,though in some cells small cytoplasmic foci were also observedexclusive of the ER marker (Fig. 6B). When coexpressed, CFP-Hph1pand YFP-Hph2p colocalized to discrete foci within the ER (Fig.6C). We conclude, therefore, that Hph1p and Hph2p are componentsof the ER. Both proteins exhibit a similar localization patternand colocalize within an individual cell. This observation,together with two-hybrid studies showing that Hph1p and Hph2pinteract, suggests that the proteins can form a complex.

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FIG. 6. Hph1p and Hph2p localize to the ER. (A) Wild-type yeast cells (YPH499) expressing GFP-Hph1p (pVH1) or GFP-Hph2p (pVH2) under a methionine-repressible promoter were grown to log phase and visualized by fluorescence microscopy and differential interference microscopy (DIC) (see Materials and Methods). (B) GFP-Hph1p (pVH1) or GFP-Hph2p (pVH2) was expressed in wild-type yeast cells expressing HDEL-DsRed (VHY87) to mark the ER. In the third panel, the two images were merged, and yellow regions indicate areas of overlapping localization. (C) Wild-type cells (YPH499) were transformed with plasmids to express CFP-Hph1p (pVH10) and YFP-Hph2p (pVH11) and visualized by fluorescence microscopy. In the third panel, the two images were merged, and yellow regions indicate areas of overlapping localization.

Ca²⁺ modulates Hph1p distribution. Cells expressing either GFP-Hph1p or GFP-Hph2p were exposedto 200 mM CaCl₂. This treatment is known to activate calcineurin,as it rapidly stimulates calcineurin- and Crz1p-dependent transcription.Within minutes of CaCl₂ addition, the number of bright punctatefoci of GFP-Hph1p increased by approximately 2.5-fold (Fig.7). Colocalization with HDEL-DsRed showed that the foci, thoughmore numerous, were strictly colocalized to the ER (data notshown). Western blots established that the amount of GFP-Hph1pprotein in cells did not change during this time (data not shown).Thus, we conclude that CaCl₂ causes a redistribution of Hph1pin cells such that the number of discrete Hph1p-containing fociwithin the cell increases. In contrast, no change in GFP-Hph2plocalization was observed in response to CaCl₂ treatment, andcells expressing HDEL-DsRed to allow visualization of the ERshowed no morphological changes in response to CaCl₂ (data notshown).

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FIG. 7. Three-dimensional reconstruction of yeast cells expressing GFP-Hph1p in untreated and CaCl₂-treated cells. (A) Wild-type (YPH499) and cnb1 ${Delta}$ (DD12) cells expressing GFP-Hph1p (pVH1) were grown to log phase and treated or not treated with CaCl₂ (200 mM) for 10 min. They were then visualized by fluorescence microscopy by taking a through series of 18 images at 0.5-µm steps as described in Materials and Methods. Images were projected onto a single plane, with the maximum values at each pixel position. (B) The number of foci per unit area was determined from three-dimensional reconstructions of wild-type and cnb1 ${Delta}$ cells, which were either untreated or treated with 200 mM CaCl₂ for 10 to 20 min (see Materials and Methods for details). A Student t test was performed to show that the difference in the number of foci between wild-type cells treated or not with CaCl₂ was highly significant (P = 3.5 E-12).

To investigate whether the Ca²⁺-dependent change in GFP-Hph1pdistribution correlated with calcineurin-dependent dephosphorylationof Hph1p, we quantified the number of GFP-Hph1p foci in calcineurin-deficientcells (cnb1 ${Delta}$ ) before and after Ca²⁺ treatment. Under these conditions,we did not observe a significant change in the number of GFP-Hph1p-containingfoci (Fig. 7). We also treated cells containing GFP-Hph1- ${Delta}$ PVIAVNpwith CaCl₂ and did not observe a significant change in the patternof GFP-Hph1p localization or number of foci (data not shown).Therefore, we conclude that the observed increase in GFP-Hph1pfoci is Ca²⁺- and calcineurin-dependent and reflects a changein Hph1p distribution in the cell rather than a change in proteinlevel.

DISCUSSION

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Discussion

Identification of a novel calcineurin substrate. In this study, we identified Hph1p as a novel substrate of theCa²⁺- and calmodulin-dependent phosphatase calcineurin and characterizethe role of Hph1p and the closely related Hph2p in the responseof S. cerevisiae to environmental stress. In addition to Hph1p,only three other yeast proteins, Crz1p, Rcn1p, and Cch1p, havebeen shown to be direct substrates of calcineurin (9, 26, 47).Studies of mammalian and yeast calcineurin have establishedthat calcineurin interacts with a docking site in its substratesthat is distinct from dephosphorylated residues and that thisinteraction is required for calcineurin to act on the substrate.We have made use of this paradigm to identify Hph1p as a novelcalcineurin substrate based solely on its ability to interactwith the phosphatase. Furthermore, by identifying and deletingthe site within Hph1p that mediates its interaction with calcineurin,we were able to create a special allele of HPH1, hph1- ${Delta}$ PVIAVN,which is specifically defective in its regulation by calcineurin.Characterization of this allele allowed us to assess the contributionof calcineurin to Hph1p function in vivo and establish thatcalcineurin is required for full Hph1p activity. Both of theseapproaches should be generally applicable to the future identificationand characterization of additional calcineurin substrates.

Calcineurin docking sites have been identified in several substrates.The consensus binding motif for mammalian calcineurin definedin NFAT family members is PxIxIT, and direct selection of apeptide optimized for binding to mammalian calcineurin identifiedthe related sequence PVIVIT (2, 3a) Docking sequences for yeastcalcineurin, i.e., PVIAVN in Hph1p and PIISIQ in Crz1p, areclosely related to those for mammalian calcineurin, indicatingthat the substrate interaction domain in calcineurin is highlyconserved (11). Comparison of these sequences allows the consensuscalcineurin binding motif to be further refined and suggestsin particular that the last residue in the docking site canbe any of several hydrophilic amino acids (i.e., T, Q, or N).Ultimately, a detailed understanding of the interaction betweencalcineurin and its substrates could lead to the developmentof compounds that inhibit specific downstream pathways of calcineurin.Such compounds would minimize the unwanted side effects causedby cyclosporine A and FK506, two immunosuppressants currentlyin wide clinical use that act through general inhibition ofcalcineurin.

Role of Hph1p and Hph2p in calcineurin signaling. Like calcineurin mutants, cells lacking both Hph1p and Hph2pdisplay growth defects under conditions of high salinity, highpH, and cell wall stress. A major function of calcineurin inpromoting survival during environmental stress is to activatethe Crz1p transcription factor. Genetic analyses indicate thatHph1p and Hph2p act independently of Crz1p, and Crz1p-dependentgene expression is unaffected in hph1 ${Delta}$ hph2 ${Delta}$ mutants. Thus, Hph1pand Hph2p define a novel branch of the calcineurin-regulatedstress response. Although Hph1p is functionally redundant withHph2p, we provide evidence that the two proteins differ in theirregulation: Hph1p is a calcineurin substrate, whereas Hph2pdoes not interact with and is not dephosphorylated by the phosphatase.Since Hph2p is not a substrate of calcineurin but can substitutefor Hph1p, it must either constitutively perform a functionthat is calcineurin regulated in Hph1p or be regulated by analternative process that we have yet to identify. We also foundthat loss of calcineurin is epistatic to the hph1 ${Delta}$ hph2 ${Delta}$ mutations,suggesting that calcineurin is required in some way for thefunction of both Hph1p and Hph2p. Since calcineurin does notregulate Hph2p directly, this observation suggests that calcineurinacts through an additional, indirect mechanism to regulate Hph1pand Hph2p activity in vivo. In the future, as we learn moreabout the molecular functions of Hph1p and Hph2p, we shouldgain further insight into the relationship between calcineurinand Hph1p and Hph2p.

Currently, we know little about the role of calcineurin in regulatingevents associated with the ER. Calcineurin signaling is requiredfor the long-term survival of cells undergoing ER stress. Calcineurin-nullmutants but not crz1 ${Delta}$ mutants show decreased viability when treatedwith tunicamycin, a compound that blocks N-glycosylation inthe ER, causing accumulation of misfolded proteins and activationof the unfolded protein response. The downstream effector(s)of calcineurin involved in this pathway has yet to be identified(10). Since Hph1p and Hph2p localize to the ER, we investigateda possible role for these proteins in cells undergoing the unfoldedprotein response. We found, however, no difference between thesurvival of wild-type cells and hph1 ${Delta}$ hph2 ${Delta}$ mutants during exposureto tunicamycin (data not shown). Thus, we conclude that Hph1pand Hph2p do not play a role in the calcineurin-mediated responseto ER stress.

Hph1p and Hph2p localization. Hph1p and Hph2p belong to a family of tail-anchored proteinswhich comprise a cytosolic N-terminal domain tethered to internalmembranes via a single C-terminal transmembrane segment (6).These proteins fold cotranslationally and are inserted posttranslationallyinto the membrane by their C-terminal hydrophobic domain (21,31). In accordance with previous studies, we found that bothHph1p and Hph2p localize to the ER (6). Hph1p displays a punctatepattern of localization, whereas Hph2p is more evenly distributedwithin this organelle. Beilharz et al. (6) showed that the C-terminalhydrophobic transmembrane domain is sufficient to target Hph1pto the ER but that additional determinants in the N-terminalregion drive its punctate distribution within this organelle.Since it has not been possible to visualize either Hph1p orHph2p expressed at endogenous levels, we cannot be certain thatHph1p would form foci when expressed at its natural levels.However, we did find that activating calcineurin potently increasedthe number of Hph1p foci in the ER and that calcineurin-null(cnb1 ${Delta}$ ) cells had fewer foci than wild-type cells. Thus, thepunctate distribution of Hph1p may reflect a physiologicallyrelevant property of the protein that is regulated by phosphorylation.Hph1p and Hph2p interacted in a yeast two-hybrid assay; thisinteraction may be mediated by predicted coiled-coil domainsfound just N-terminal to the transmembrane domain in each protein.Addition of the calcineurin inhibitor FK506 in the yeast two-hybridassays did not affect the interaction between Hph1p and Hph2p,suggesting that the interaction between these two proteins isnot modified by calcineurin (data not shown). When coexpressed,Hph1p and Hph2p colocalized within the ER in foci, suggestingthat Hph1p is able to bind Hph2p in vivo and cause its localizationinto foci.

Function of Hph1p and Hph2p. Future characterization of Hph1p and Hph2p is required to understandtheir physiological roles at a molecular level. Other tail-anchoredtransmembrane proteins include the SNARE proteins of the Vamp/synaptobrevinand syntaxin families, which are involved in mediating vesicletrafficking and small components of the translocon, which mediatesprotein translocation into the ER. Thus, Hph1p and Hph2p mayfunction during the stress response to facilitate protein trafficking.Alternatively, Hph1p and Hph2p may be involved in recruitingenzymes to the ER in response to stress, as other tail-anchoredproteins are known to serve a similar function (for a review,see reference 49). Also, Hph1p and Hph2p have been reportedto interact with Tcp1p, a subunit of the tailless complex polypeptide(TCP1) ring complex/chaperonin (TriC/CCT), via yeast two-hybridstudies (K. Dolinski, R. Balakrishnan, K. R. Christie, M. C.Costanzo, S. S. Dwight, S. R. Engel, D. G. Fisk, J. E. Hirschman,E. L. Hong, L. Issel-Tarver, A. Sethuraman, C. L. Theesfeld,G. Binkley, C. Lane, M. Schroeder, S. Dong, S. Weng, R. Andrada,D. Botstein, and J. M. Cherry, 2004, Saccharomyces genome database,http://www.yeastgenome.org; Doris Ursic, unpublished data).The TRiC/CCT chaperone promotes protein folding and interactswith proteins that undergo posttranslational translocation intothe ER (39). Thus, Hph1p and Hph2p may interact with CCT/TriCcomponents during their insertion into the ER membrane or mayfunction together with TriC/CCT as part of the stress response.Although Hph1p and Hph2p show no significant sequence similarityto any proteins of known function, we have identified severalregions of high sequence conservation by comparing Hph1p andHph2p with closely related proteins from other fungi (data notshown). In the future, functional characterization of theseregions and identification of Hph1p- and Hph2p-interacting proteinsshould provide insight into the mechanisms by which Hph1p andHph2p act.

S. cerevisiae response to alkaline stress. Many yeasts and fungi pose significant threats to human health,especially the health of immunocompromised persons. Fungal pathogenstypically colonize a variety of host environments, and manyof these environments exist at neutral or alkaline pH. Severalstudies of Candida albicans demonstrate an important correlationbetween growth at high pH and pathogenesis; for example, mutantslacking a transcriptional regulator, rim101, are defective forgrowth in alkaline conditions and display attenuated virulence(17). Additionally, calcineurin is required for the pathogenicityof C. albicans, since it is necessary for growth at high pHand survival in the presence of serum (5, 8, 42). Understandingthe role that Hph1p and Hph2p play in promoting the survivalS. cerevisiae at high pH will likely shed light on the pH-adaptiveresponses of other fungi and may ultimately lead to the developmentof novel antifungal therapies.

ACKNOWLEDGMENTS

We thank U Güldener, J. H. Hegemann, B Glick, and I. F.de Larrinoa for generously providing plasmids. We also thankKim Kafadar, Valérie Denis, Kim Williams, and Leila Boustanyfor technical help and useful discussion.

Funding for this work was provided by NIH research grant GM-48729.

FOOTNOTES

* Corresponding author. Mailing address: Dept. of Biological Sciences, 147 Lokey Bldg., 337 Campus Dr., Stanford University, Stanford, CA 94305-5020. Phone: (650) 723-9970. Fax: (650) 724-9945. E-mail: mcyert{at}stanford.edu.

Present address: School of Biosciences, The University of Birmingham,Birmingham B15 2TT, United Kingdom.

Present address: Gladstone Institute of Cardiovascular Disease,San Francisco, CA 94141.

REFERENCES

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