Intracellular Generation of Sphingosine 1-Phosphate in Human Lung Endothelial Cells: ROLE OF LIPID PHOSPHATE PHOSPHATASE-1 AND SPHINGOSINE KINASE 1

doi:10.1074/jbc.M701279200

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Intracellular Generation of Sphingosine 1-Phosphate in Human Lung Endothelial Cells

ROLE OF LIPID PHOSPHATE PHOSPHATASE-1 AND SPHINGOSINE KINASE 1^*

Yutong Zhao, Satish K. Kalari, Peter V. Usatyuk, Irina Gorshkova, Donghong He, Tonya Watkins, David N. Brindley^¶, Chaode Sun^||, Robert Bittman^||, Joe G. N. Garcia, Evgeni V. Berdyshev, and Viswanathan Natarajan¹

From the Department of Medicine, Section of Pulmonary and Critical Care Medicine, University of Chicago, Chicago, Illinois 60637, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland 21224, ^¶Department of Biochemistry, University of Alberta, Edmonton, Alberta T6G 2H7, Canada, and ^||Department of Chemistry and Biochemistry, Queens College of The City University of New York, Flushing, New York 11367

Received for publication, February 12, 2007 , and in revised form, March 22, 2007.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Sphingosine 1-phosphate (S1P) regulates diverse cellular functionsthrough extracellular ligation to S1P receptors, and it alsofunctions as an intracellular second messenger. Human pulmonaryartery endothelial cells (HPAECs) effectively utilized exogenousS1P to generate intracellular S1P. We, therefore, examined therole of lipid phosphate phosphatase (LPP)-1 and sphingosinekinase1 (SphK1) in converting exogenous S1P to intracellularS1P. Exposure of ³²P-labeled HPAECs to S1P or sphingosine (Sph)increased the intracellular accumulation of [³²P]S1P in a dose-and time-dependent manner. The S1P formed in the cells was notreleased into the medium. The exogenously added S1P did notstimulate the sphingomyelinase pathway; however, added [³H]S1Pwas hydrolyzed to [³H]Sph in HPAECs, and this was blocked byXY-14, an inhibitor of LPPs. HPAECs expressed LPP1–3,and overexpression of LPP-1 enhanced the hydrolysis of exogenous[³H]S1P to [³H]Sph and increased intracellular S1P productionby 2–3-fold compared with vector control cells. Down-regulationof LPP-1 by siRNA decreased intracellular S1P production fromextracellular S1P but had no effect on the phosphorylation ofSph to S1P. Knockdown of SphK1, but not SphK2, by siRNA attenuatedthe intracellular generation of S1P. Overexpression of wildtype SphK1, but not SphK2 wild type, increased the accumulationof intracellular S1P after exposure to extracellular S1P. Thesestudies provide the first direct evidence for a novel pathwayof intracellular S1P generation. This involves the conversionof extracellular S1P to Sph by LPP-1, which facilitates Sphuptake, followed by the intracellular conversion of Sph to S1Pby SphK1.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Sphingosine 1-phosphate (S1P)² is a bioactive lipid mediatorthat plays an important role in regulating intracellular mobilizationof Ca²⁺, cytoskeletal reorganization, cell growth, differentiation,motility, angiogenesis, and survival (1–5). In biologicalfluids such as plasma, S1P is present at 0.2–0.5 µM,whereas higher concentrations (1–5 µM) in serumare attributed to enhanced release from activated platelets(1, 5). S1P is generated by phosphorylation of free sphingosine(Sph) by two sphingosine kinases (SphKs) 1 and 2, which arehighly conserved enzymes present in most of the mammalian cellsand tissues (6–9). Cellular levels of S1P are regulatedthrough its formation via SphKs and by its degradation by S1Plyase (SPL) (10–12), S1P phosphatases (SPPs) (13–15),and intracellular lipid phosphate phosphatases (LPPs) (16–18).Platelets lack S1P lyase (19), but in most cells the balancebetween S1P formation and degradation translates to low basallevels of intracellular S1P. S1P exerts dual actions in cells;it acts as an intracellular second messenger and functions extracellularlyas a ligand for a family of five G-protein-coupled receptorsformerly known as endothelial differentiation gene (Edg) receptors.To date, five G-protein-coupled receptors, S1P-1 (Edg-1), S1P-2(Edg-5), S1P-3 (Edg-3), S1P-4 (Edg-6), and S1P-5 (Edg-8), havebeen identified. All these receptors bind to and are activatedby extracellular S1P and dihydro-S1P (1, 5, 20–22). Inthe vessel wall extracellular S1P is a potent stimulator ofangiogenesis (23, 24) and is a major chemotactic factor forendothelial cells (ECs). Recently, circulating S1P and the immunosuppressivedrug FTY720, which is also phosphorylated by SphKs, have beenimplicated in lymphocyte homing and immunoregulation (25, 26).In addition to its extracellular action, S1P functions as anintracellular second messenger in the regulation of Ca²⁺ mobilizationand suppression of apoptosis (27, 28).

Unlike platelets (29, 30), ECs do not secrete large amountsof S1P upon stimulation by agonists such as TNF- ${alpha}$ or thrombin(1, 31). Although TNF- ${alpha}$ stimulates endothelial SphK by $~$ 2-fold,it is unclear if intracellular S1P levels are increased in ECs(31). During studies on intracellular S1P formation, we observedthat exogenously added S1P was rapidly converted to intracellularS1P in human lung ECs. This suggested the existence of a novelbut yet to be defined pathway whereby S1P could be taken byECs from the circulation and used for intracellular signaling.Recently, several LPPs have been described in mammalian cells,and they are partly expressed as ectoenzymes on the cell surface(32–35). The LPPs could hydrolyze S1P (16–18), whichcould facilitate the rapid uptake of Sph by ECs. IntracellularSphK1 and SphK2 could then synthesize intracellular S1P andinfluence angiogenesis, EC motility, or survival (23, 24, 36,37). In this study we demonstrate that in lung ECs exogenousS1P is a preferred source for the intracellular production ofS1P compared with several agonists that stimulate sphingomyelinaseactivity. Our results also show that the exogenous S1P is hydrolyzedby ecto-LPP-1 present on human lung ECs to Sph, which is subsequentlyconverted by SphK1 to intracellular S1P.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials—HPAECs, EBM-2 basal media, and Bullet kit wereobtained from Clonetics (San Diego, CA). Phosphate-bufferedsaline was from Biofluids (Rockville, MD). Ampicillin, fetalbovine serum (FBS), trypsin, MgCl_2, EGTA, Tris-HCl, Triton X-100,sodium orthovanadate, aprotinin, Tween 20, Me₂SO, antibodiesto LPP-2, LPP-3, and c-Myc tag (9E10), and Bacillus cereus sphingomyelinasewere from Sigma. D-erythro-C18 Sph, D-erythro-S1P, D-erythro-C17-S1P,and D-erythro-dihydro-S1P were from Avanti%20Polar%20Lipids">AvantiPolar Lipids (Alabaster, AL). N,N-Dimethylsphingosine (DMS)was from Biomol Research Laboratory (Plymouth Meeting, PA).XY-14 was obtained from Echelon (Salt Lake City, UT). SMARTpool siRNA against human SphK1, SphK2, SPP1, SPL, and LPP-1mRNA and scrambled siRNA were purchased from Dharmacon (Lafayette,CA). Antibodies to SphK1 and SphK2 and to FLAG tag were obtainedfrom Oncogene Research Products and Santa Cruz Biotechnology(Santa Cruz, CA), respectively. The antibody to LPP-1 was kindlyprovided by Dr. Andrew Morris (University of Kentucky). Horseradishperoxidase-conjugated goat anti-rabbit, anti-mouse were purchasedfrom Invitrogen/Molecular Probes (Eugene, OR). The enhancedchemiluminescence (ECL) kit was from Amersham Biosciences. Silicagel 60TLC plastic sheets were from EM Chemicals Science (Gibbstown,NJ). [ ${gamma}$ -³²P]ATP in 10 mM Tricine buffer (specific activity 6000C_i/mmol) was purchased from PerkinElmer Life Sciences. D-Ribophytosphingosine1-phosphonate was synthesized as described previously (38).

Endothelial Cell Culture—For HPAECs, passages between5 and 8 were grown to contact-inhibited monolayers with typicalcobblestone morphology in EGM-2 complete media with 10% FBS,100 units/ml penicillin and streptomycin in a 37 °C incubatorunder 5% CO₂, 95% air atmosphere (39, 40). Cells from T-75 flaskswere detached with 0.05% trypsin and resuspended in fresh completemedium and cultured in 35- or 60-mm dishes or on glass coverslipsfor immunofluorescence studies. All cells were starved overnightin EGM-2 medium containing 1% FBS before exposure to vehicleor agonists.

Generation of Adenoviral Vectors—The SphK1 complete cDNA(GI: 21361087) with FLAG-tag DNA at the C terminus, the SphK1dominant negative G82D with FLAG-tag DNA at C terminus, theSphK2 complete cDNA (GI: 21361698) with c-Myc-tag DNA at C terminus,and mouse LPP-1 (GI: 45592927) with c-Myc-tag DNA at the N terminuswere inserted into an adenoviral expression vector with cytomegaloviruspromoter. The recombinant plasmids were linearized and propagatedin HEK 293 cells, and the high titer-purified preparations ( $~$ 10¹⁰plaque-forming units/ml) were generated by the University ofIowa Gene Transfer Vector Core.

Infection of HPAECs with Adenoviral Vectors—Infectionof HPAECs ( $~$ 60% confluence) with purified adenoviral empty vectors,adenoviral vectors containing cDNA for SphK1 wild type (wt)or SphK2 wt or SphK1 mutant, and wild type LPP-1 were carriedout in 6-well plates as described previously (40, 41). Afterinfection with different m.o.i. in 1 ml of EGM for 24 h, thevirus containing medium was replaced with EBM, and the experimentswere carried out.

Transfection of HPAECs with siRNA—HPAEC grown to $~$ 50% confluencein 6-well plates were transfected with Gene Silencer® (GeneTherapy System, San Diego, CA) transfecting agent with targetspecific siRNA (50 nM) and scrambled siRNA (50 nM) in serum-freeEBM-2 medium according to the manufacturer's recommendation.After 3 h post-transfection, 1 ml of fresh complete EGM-2 mediumcontaining 10% FBS was added, and the cells were cultured foran additional 72 h for analysis of SphK1, SphK2, SPP1, SPL,LPP-1, LPP-2, and LPP-3 mRNA by real-time RT-PCR.

RNA Isolation—Total RNA was isolated from cultured HPAECsusing TRIzol® reagent (Invitrogen) according to the manufacturer'sinstructions. RNA was quantified spectrophotometrically, andsamples with an absorbance of $≥$ 1.8 measured at 260/280 nm wereanalyzed by real-time RT-PCR.

Quantitative RT-PCR and Real-time RT-PCR—RNA (1 µg)was reverse-transcribed using a cDNA synthesis kit (Bio-Rad),and real-time PCR and quantitative PCR were performed to assessexpression of the SphK1, SphK2, SPP1, SPL, LPP-1, LPP-2, andLPP-3 using primers designed for the human mRNA sequences. Ampliconexpression in each sample was normalized to its 18 S RNA content.The relative abundance of target mRNA in each sample was calculatedas 2 raised to the negative of its threshold cycle value times10⁶ after being normalized to the abundance of its corresponding18 S (e.g. 2^{–(sphingosine kinase 1 threshold cycle)}/2^{–(18S threshold cycle)} x 10⁶).

Measurement of Intracellular [³²P]S1P Generation—Controlor HPAECs (35-mm dishes) infected with adenoviral vectors containingcDNA for wild type SphK1, SphK2 wild type, or LPP-1 (10 m.o.i.for 48 h) were labeled with [³²P]orthophosphate (20 µCi/ml)in phosphate-free Dulbecco's modified Eagle's medium (DMEM)media for 3 h. The media was then aspirated, and cells werechallenged with 1 ml of minimum Eagle's medium alone or mediacontaining S1P or Sph (1 µM) in the presence of 0.1% BSAfor 15–60 min. Lipid labeling was terminated by the additionof 100 µlof12 M HCl followed by 2 ml of methanol. Cellswere harvested with a cell scraper, the total extract was transferredto 15-ml glass tubes, and lipids were partitioned after vortexinginto the chloroform phase by the addition of 2 ml of chloroformand 700 µlof1 M HCl (to give a final ratio of 1:1:0.9of chloroform:methanol:acidic aqueous phase). After vortexing,the lower (chloroform) phase was dried under nitrogen, and thelipid extracts were subjected thin layer chromatography (TLC).Lipid extracts were applied at 10 cm from the bottom of 20-cmplastic baked silica gel 60 plates. The plate was developedin chloroform/methanol/NH₄OH (65:35: 7.5, v/v/v), air-driedfor 20 min, and then cut 2.0 cm above the origin. This removedneutral lipids and most of the zwitterionic phospholipids, whereasseveral acidic phospholipids such as phosphatidic acid, S1P,lysophosphatidate and ceramide 1-phosphate remained near theorigin. The top part of the cut plate was discarded, and thebottom of the plate was then developed in the reverse directionwith chloroform/methanol/glacial acetic acid/acetone/water (10:2:3:4:1,v/v/v/v). Dried plates were subjected to autoradiography, thearea corresponding to labeled S1P was excised, and radioactivitywas determined by liquid scintillation counting. The data werenormalized to total radioactivity in the lipid extract or totalcells on the monolayer (42).

Lipid Extraction and Sample Preparation for LC-MS/MS Analysisof S1P, Dihydro-S1P, and Sph—Cellular lipids were extractedby a modified Bligh and Dyer procedure under acidic conditionsusing 0.1 M HCl and C17-S1P (40 pmol) and C17-Sph (30 pmol),which were added as internal standards during the lipid extractionstep. The lipid extracts were dissolved in ethanol (200 µl),and aliquots were analyzed for total lipid phosphate (40, 42)and then subjected to LC-MS/MS for quantification of S1P, dihydro-S1P,and Sph as described previously (40).

S1P Hydrolysis to Sph by Ecto LPP Activity in HPAECs—HPAECswere grown on 35-mm dishes to $~$ 90% confluence. S1P (1 µM)(unlabeled plus [³H]S1P, 100,000 dpm per dish; specific activity2.2 x 10³ dpm/pmol) complexed to 0.1% BSA in 1 ml of EGM mediumwas added to HPAECs, and the cells were incubated at 37 °Cfor various times (0–60 min). After the media (1 ml) weretransferred to glass tubes, 2 ml of methanol, 1 M HCl (100:1v/v) was added, and lipids were extracted by the addition of2 ml of chloroform and 0.8 ml of H₂O and centrifuged to separatethe chloroform and methanol/aqueous phases. The lower (chloroform)phase was transferred to vials and evaporated under N₂, andthe hydrolysis of [³H]S1P to [³H]Sph was determined after separationby TLC in the presence of unlabeled sphingosine, added as carriersto the total lipid extracts (42). The plates were developedin chloroform/methanol/NH₄OH (65:35:7.5, v/v/v) and exposedto iodine vapors to identify Sph band, and radioactivity associatedwith Sph was determined by liquid scintillation counting. Thehydrolysis of [³H]S1P to [³H]Sph was expressed as dpm/dish orpmol/dish.

Surface Labeling of ECs with Biotin—HPAECs (passage 6)grown on T-75-cm² flasks were infected for 24 h with adenoviralempty vector or adenoviral mLPP-1 on the C terminus with Myc(10 m.o.i.). Media were removed, and cells were washed twicewith ice-cold phosphate-buffered saline. Surface labeling ofcells with biotin was performed with the Cell Surface ProteinIsolation kit (Pierce) as per the manufacturer's recommendation.Briefly, HPAECs were incubated with 10 ml of ice-cold phosphate-bufferedsaline containing sulfo-NHS-SS-biotin (0.25 mg/ml) for 30 minat 4 °C with constant rocking, and cells were collected,and lysed by sonication on ice for 5 s using lysis buffer (Pierce).The cell lysates were incubated with Immobilized NeutrAvidin^TMgel for 60 min at room temperature with end-over mixing, andsurface proteins were boiled in 400 µlof SDS-PAGE samplebuffer containing 50 mM dithiothreitol and analyzed by Westernblotting with anti-Myc(10E9) or anti-LPP-1 antibodies.

Measurement of [³H]Ceramide Formation—HPAECs grown to $~$ 90% confluence in 35-mm dishes were labeled with L-[³H]serine(100 µCi/ml) in serine-free medium for 24 h to label sphingomyelin.L-[³H]Serine was removed by washing, and cells were challengedwith medium alone or medium containing TNF- ${alpha}$ (20 ng/ml), S1P(1 µM), H₂O₂ (100 µM), or bacterial sphingomyelinase(1 units/ml) for 30 min. The medium was aspirated, cells werescraped into 2 ml of methanol, 1 M HCl (100:1 v/v), and lipidswere extracted by the addition of 2 ml of chloroform and 1.8ml of 1 M HCl. Tubes were then centrifuged to separate the chloroformand methanol/aqueous phases. The lower (chloroform) phase wasremoved and dried under nitrogen, and the formation of [³H]ceramidewas determined after separation by TLC with chloroform/methanol/glacialacetic acid/acetone/water (10:2:3:4:1 v/v/v/v). [³H]Ceramidewas identified with an authentic standard visualized under I₂vapors, and radioactivity was determined by liquid scintillationcounting.

Western Blotting—Cells were rinsed twice with ice-coldphosphate-buffered saline and lysed in 200 µl of buffercontaining 20 mM Tris-HCl, pH 7.4, 150 mM NaCl, 2 mM EGTA, 5mM $beta$ -glycerophosphate, 1 mM MgCl₂, 1% Triton X-100, 1 mM sodiumorthovanadate, 10 µg/ml protease inhibitors, 1 µg/mlaprotinin, 1 µg/ml leupeptin, and 1 µg/ml pepstatin.Cell lysates were incubated at 4 °C for 10 min, sonicatedon ice for 10 s, and centrifuged at 5000 x g for 5 min at 4°C in a microcentrifuge. Protein concentrations were determinedwith a BCA protein assay kit (Pierce) using BSA as standard.Equal amounts of protein (20 µg) or concentrated media(20 µl) were analyzed on 10% SDS-PAGE gels, transferredto polyvinylidene difluoride membranes, blocked with 5% (w/v)BSA in TBST (25 mM Tris-HCl, pH 7.4, 137 mM NaCl, and 0.1% Tween20) for 1 h, and incubated with primary antibodies in 5% (w/v)BSA in TBST for 1–2 h at room temperature. The membraneswere washed at least 3 times with TBST at 15-min intervals andthen incubated with mouse, rabbit, or goat horseradish peroxidase-conjugatedsecondary antibody (1:3000) for 1 h at room temp. The membraneswere developed with the enhanced chemiluminescence detectionsystem according to the manufacturer's instructions.

Statistical Analyses—The results were analyzed by a Student-Newman-Keulstest. Data are expressed as the means ± S.D. of triplicatesamples from two or more experimental groups, and statisticalsignificance was taken to be p < 0.05.

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FIGURE 1.
Agonist-induced intracellular generation of S1P in HPAECs. Panel A, HPAECs grown to $~$ 95% confluence in 35-mm dishes were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h. The radioactive medium was aspirated, and cells were rinsed in DMEM without serum and challenged with medium alone or medium containing TNF- ${alpha}$ (20 ng/ml), thrombin (10 ng/ml), vascular endothelial growth factor (VEGF;20 ng/ml), phorbol ester (TPA, 25 nM), ionophore A23187 (1 µM), or H₂O₂ (250 µM). In panel B cells were treated with human PPP or lipids extracted from human PPP for 30 min. The reaction was terminated by the addition of 100 µl of 12 M HCl; lipids were extracted under acidic condition and separated by TLC for [³²P]S1P generation. In panel C total lipids were extracted from PPP or prelipidated PPP, and sphingoid bases were quantified by LC-MS/MS as described under "Experimental Procedures." Values are the means ± S.D. of six independent experiments. *, significantly different from cells exposed to medium alone (p < 0.05). Veh, vehicle.

	RESULTS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

Agonist-induced Generation of S1P in ECs—Although activatedplatelets generate and secrete micromolar levels of S1P, severalother circulating and non-circulating cells have the abilityto produce intracellular S1P. S1P is a key angiogenic factorin the endothelium; however, the ability of ECs to generateintracellular S1P and its signaling effects has not been welldefined. Therefore, several agonists that activate EC signaltransduction and their effects on intracellular S1P formationwere tested. As shown in Fig. 1A, among numerous agonists suchas thrombin, vascular endothelial growth factor, phorbol ester,the calcium ionophore A23187 [GenBank] , and TNF- ${alpha}$ , only TNF- ${alpha}$ increased[³²P]S1P production ( $~$ 1.4-fold increase over control) in HPAECs.Interestingly, incubation of ³²P-labeled HPAECs with human PPPor lipids derived from PPP showed a statistically significantincrease in intracellular S1P production (Fig. 1B). By contrast,charcoal-treated PPP, as compared with lipids from charcoaltreated PPP, failed to show any significant change in intracellularS1P (Fig. 1B). Analysis of the lipid extracts derived from thePPP fraction by LC-MS/MS revealed the presence of substantialamounts of S1P (1973 ± 97 pmol/ml of PPP), whereas charcoaltreatment of PPP reduced the S1P levels by $~$ 75% (597 ±38 pmol/ml) (Fig. 1C). Sph levels in the PPP fraction were verylow (23 ± 6 pmol/ml of PPP), and charcoal treatment ofPPP reduced the sphingosine levels by $~$ 50% (10 ± 2 pmol/mlof PPP). These results indicate that circulating Sph and/orS1P could serve as a source of intracellular S1P in ECs.

Conversion of Exogenous Sph and S1P to Intracellular S1P—HPAECswere labeled with [³²P]orthophosphate for 3 h and then exposedto either Sph or S1P, and the medium as well as the total celllysates were analyzed to detect the relative [³²P]S1P production.As shown in Fig. 2, A and B, exposure of cells to either Sphor S1P resulted in the accumulation of [³²P]S1P in a dose- andtime-dependent manner. At all concentrations of the exogenouslyadded substrate, formation of [³²P]S1P from Sph was higher thanthat of S1P (Figs. 2, A and B). Furthermore, analysis of themedium and cells exposed to either exogenous S1P or Sph showedthat >95% of the [³²P]S1P generated was recovered in thetotal cell lysates with statistically insignificant levels presentin the medium (Fig. 2C). In independent experiments, cells wereincubated with Sph, and total cell lysates and medium were analyzedfor S1P using LC-MS/MS (40). As shown in Fig. 2D, no S1P wasdetected in the medium, and >95% of the S1P generated wasrecovered in total cell lysates. Next, we investigated the abilityof various mammalian cells to convert exogenously added S1Pto intracellular S1P. Among the various cell types we investigated,which included epithelial cells, monocytes, and macrophages,only the ECs from various vascular beds demonstrated high ratesof intracellular S1P production; however, all the cell typesinvestigated utilized exogenous Sph to generate intracellularS1P (Table 1). These results show that ECs from macro- and microvesselsexhibit increased generation of S1P from extracellular S1P.Little of this S1P was released to external milieu.

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TABLE 1
Intracellular [³²P]S1P formation in different cell types

Confluent cells were labeled with [³²P]orthophosphate (20 µCi/ml) in DMEM phosphate-free medium for 3 h, radioactive medium was aspirated, and cells were rinsed with medium and challenged with medium alone or medium containing Sph (1 µM) or S1P (1 µM) complexed to 0.1% BSA for 30 min. Lipids were extracted, and radioactivity associated with S1P was determined. Values are the means ± S.E. of three independent experiments in triplicate. HLMVECs, human lung microvascular endothelial cells; HBEpCs, human bronchial epithelial primary cells.

Specificity of Sphingoid Bases on Intracellular Formation ofSphingoid Phosphates in HPAECs—Next we investigated theability of HPAECs to utilize different sphingoid bases providedexogenously in the intracellular generation of the correspondingsphingoid phosphates. As shown in Table 2, exogenous S1P wasa better substrate than dihydro-S1P and phyto-S1P, whereas thenon-hydrolysable analog, D-Ribophytosphingosine phosphonate(PHS-C-P) could not be converted to phytosphingosine. Conversionof Sph to S1P was higher than that of dihydro-Sph to dihydro-S1P.These results indicate that among the various sphingoid phosphatesinvestigated, S1P is a preferred substrate, and hydrolysis ofthe sphingoid phosphate to a free sphingoid base is a necessarystep in the intracellular production of S1P by HPAECs.

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TABLE 2
Intracellular formation of sphingoid phosphates in HPAECs

HPAECs ( $~$ 90% confluence) were labeled with [³²P]orthophosphate (20 µC_i/ml) in DMEM phosphate-free medium for 3 h, medium was aspirated, and the cells were rinsed in medium before challenge with medium alone or medium containing Sph (1 µM), dihydro-Sph (1 µM), D-ribophytosphingosine 1-phosphonate (1 µM), S1P (1 µM), dihydro-S1P (1 µM), or phyto-S1P (1 µM) complexed to 0.1% BSA for 30 min. Lipids were extracted, and accumulation of sphingoid phosphates was quantified. Values are the means ± S.E. of three independent experiments in triplicate.

Extracellular S1P Does Not Stimulate Ceramide Formation in HPAECs—Theintracellular generation of S1P from extracellular S1P couldarise via activation of sphingomyelinase (generating ceramideand subsequently Sph via ceramidase and S1P via SphK) or viaLPPs (forming Sph and then S1P via SphK) in ECs. To determinewhether extracellular S1P stimulated sphingomyelinase to generateceramide, HPAECs were labeled with 10 µM L-[³H]serine(100 µCi/ml) in EGM-2 medium containing growth factorsand 10% FBS for 24 h. Cells were rinsed in complete medium beforebeing exposed to either vehicle, S1P (1 µM), TNF- ${alpha}$ (100ng/ml), H₂O₂ (250 µM), or neutral sphingomyelinase (B.cereus, 1 unit/ml) for 30 min. After the lipids were extracted,[³H]ceramide formed was separated by TLC, and the radioactivitywas quantified. Although TNF- ${alpha}$ , H₂O₂, and sphingomyelinase treatmentresulted in increased [³H]ceramide formation from cells labeledin sphingomyelin with L-[³H]serine, cells challenged with S1Pshowed no change in [³H]ceramide accumulation (Fig. 3). Theseresults indicate that exogenous S1P does not stimulate hydrolysisof sphingomyelin to ceramide via sphingomyelinase in HPAECs.

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FIGURE 2.
Dose- and time-dependent formation of intracellular S1P from exogenous sphingosine or S1P. HPAECs grown to $~$ 95% confluence in 35-mm dishes were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h, the radioactive medium was aspirated, and cells were rinsed in DMEM without serum. In panel A, cells were challenged with medium alone or medium containing different concentrations of Sph or S1P in the presence of 0.1% BSA for 30 min; in panel B cells were challenged with medium alone or medium Sph (1 µM) or S1P (1 µM) in the presence of 0.1% BSA for 5, 10, 15, 30, and 60 min. The medium was removed, cell lipids were extracted, and intracellular [³²P]S1P was quantified. In panel C, HPAECs labeled with [³²P]orthophosphate (20 µCi/ml) for 3 h as described in panel A were exposed to either Sph (1 µM) or S1P (1 µM) for 30 min, and the lipids were extracted and quantified from the media and cells. The distribution of [³²P]S1P in medium and cells was measured. Panel D shows LC-MS/MS quantification of S1P in media and HPAECs after exposure to Sph (100 nM) for 30 min. The values are the means ± S.D. of six independent experiments. *, significantly different compared with cells exposed to medium alone (p < 0.05); **, significantly different compared with cells exposed to medium alone (p < 0.01). NS, not significant; Veh, vehicle.

Hydrolysis of Exogenous [³H]S1P to [³H]Sph Is Mediated by LPPActivity—We investigated if exogenous S1P was hydrolyzedto Sph by HPAECs. Cells ( $~$ 95% confluent) were exposed to [³H]S1P(10⁵ dpm, specific activity 100 dpm/pmol) for varying timesperiods, cells plus medium were extracted with 1-butanol underacidic conditions, and the radioactivity associated with [³H]Sphand non-hydrolyzed [³H]S1P was determined after separation byTLC. The addition of [³H]S1P to HPAECs resulted in the generationof [³H]Sph; $~$ 12% of the added [³H]S1P was hydrolyzed to [³H]Sphin 1 h (Fig. 4A). The generation of Sph was correlated withthe loss of [³H]S1P that was added to the cells. A small percentof [³H]Sph formed (<0.1%) was incorporated into sphingomyelinvia the de novo pathway (data not shown). These results showthat exogenous S1P is hydrolyzed to free Sph, most likely byLPPs present on the cell surface of HPAECs. This was confirmedby using the compound XY-14 as an inhibitor of LPPs (43). HPAECswere treated with 10 µM XY-14 for 5 min before the additionof [³H]S1P (1 µM, specific activity (SA) = 100 dpm/pmol)and then incubated for 5, 30, and 60 min. Fig. 4B shows thatXY-14 inhibited the hydrolysis of [³H]S1P to [³H]Sph.

To further investigate the role of LPPs in intracellular generationof S1P from exogenous S1P, we designed primers for LPP-1, -2,and -3 based on previous work on human LPPs (35). Using theseprimers, we found that RT-PCR of total RNA from HPAECs showedexpression of LPP-1, -2, and -3 and SPP-1 transcripts, with $beta$ -actin as an internal standard (data not shown). The RT-PCRdata were quantified by real-time RT-PCR (Fig. 5A). Westernblotting of cell lysates with specific LPP antibodies showedprotein expression of all the three LPPs in HPAECs (Fig. 5B).These results show that HPAECs express all three LPP isoforms.

Next, the role of LPPs in intracellular production of S1P wasinvestigated by overexpression of wild type LPP-1 followed byexposure of cells to exogenous [³H]S1P. HPAECs were infectedwith cDNA for Myc-tagged human LPP-1 (10 m.o.i.) using adenoviralconstructs for 24 h before the addition of [³H]S1P (1 µM,SA = 100 dpm/pmol) for 30 min. As shown in Fig. 6A, Myc-taggedmLPP-1 was efficiently overexpressed in HPAECs after 24 h ofadenoviral infection, as evidenced by Western blotting. In unstimulatedcells, the overexpressed mLPP-1 wild type was localized at thecell surface and also in intracellular organelles, includingthe perinuclear membrane, as evidenced by confocal immunocytochemistrywith anti-Myc antibody (Fig. 6B). To further evaluate localizationof LPP-1 to the cell surface, we examined susceptibility ofthe protein to labeling with a cell-impermeant biotin derivative.As shown in Fig. 6C, in resting Myc-tagged LPP-1 overexpressingor control cells, we detected Myc or LPP-1 in Western blotsof avidin-captured proteins. These results indicate that theoverexpressed and native LPP-1 are present at the surface ofresting HPAECs. Having established the surface localizationof LPP-1, we investigated the effect of overexpression of Myc-taggedLPP-1 on hydrolysis of [³H]S1P. Overexpression of LPP-1 enhancedthe hydrolysis of exogenously added S1P to Sph (by $~$ 2-fold) comparedwith vector-infected cells (Fig. 6D). These results confirma role for LPPs in the hydrolysis of exogenous S1P to Sph inHPAECs.

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FIGURE 3.
Agonist-induced generation of [³H]ceramide in HPAECs. HPAECs grown to $~$ 95% confluence in 35-mm dishes were labeled with L-[³H]serine (100 µCi/ml) in serine-free DMEM for 24 h. The radioactive medium was aspirated, and cells were rinsed and challenged with medium alone or medium containing S1P (1µM), TNF- ${alpha}$ (20 ng/ml), H₂O₂ (250µM), or sphingomyelinase (SMase; 1 units/ml) for 30 min. Lipids were extracted, and accumulation of [³H]ceramide was calculated from the averages of two independent experiments in triplicate. Veh, vehicle.

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FIGURE 4.
Time course and effect of XY-14 on hydrolysis of [³H]S1P in HPAECs. In panel A, HPAECs ( $~$ 90% confluence) in 35-mm dishes were incubated with [³H]S1P (1 µM; specific radioactivity, 100 dpm/pmol) complexed with 0.1% BSA in BEGM medium (Clonetics) for up to 60 min. At each time point the medium was removed, and lipids were extracted and analyzed for [³H]Sph and [³H]S1P by TLC. Values are from two independent experiments in triplicate and expressed as dpm/dish. In panel B, HPAECs were pretreated with XY-14 (10 µM) before exposure to [³H]S1P (1 µM; specific activity 100 dpm/pmol) for 5, 30, and 60 min. At each time point, medium was removed, and the formation of [³H]Sph from [³H]S1P was quantified. Values are from three independent experiments in triplicate and are expressed as a percentage of total radioactivities (dpm) in the lipid extract.

Overexpression of LPP-1 Potentiates Intracellular [³²P]S1P Formation—Becausethe above results established a role for LPPs in hydrolyzingexogenous S1P, we examined the effect of overexpressing LPP-1wt on the intracellular production of S1P. LPP-1-overexpressingHPAECs were labeled with [³²P]orthophosphate (20 µCi/ml)for 3 h and exposed to either S1P (1 µM) or phyto-S1P(1 µM) for 15 min. As shown in Fig. 7, overexpressionof LPP-1 potentiated the formation of intracellular [³²P]S1Por ³²P-labeled phyto-S1P (vector: vehicle, 1470 ± 95;S1P, 3447 ± 143; phyto-S1P, 2662 ± 92; LPP-1 wt:vehicle, 2047 ± 343; S1P, 6140 ± 100; phyto-S1P,5586 ± 71). The effect of overexpressed LPP-1 was specificto exogenously added S1P because it did not alter either TNF- ${alpha}$ -or Sph-mediated production of intracellular S1P. These resultsshow that overexpression of LPP-1 specifically enhanced theintracellular production of S1P or phyto-S1P from exogenousS1P or phyto-S1P, respectively, in HPAECs.

Gene Silencing of LPP-1 Attenuates Intracellular S1P Formation—BecauseLPP-1 enhanced intracellular S1P production, we examined whethergene silencing of LPP-1 affects intracellular S1P formationfrom extracellular S1P and Sph. Transfection of HPAECs withdouble-stranded RNAs targeted at the human LPP-1 mRNA sequencedecreased LPP-1 mRNA and protein expression to greater than90% without reducing LPP-2 or LPP-3 mRNA or protein levels (Fig. 8, A and B).Furthermore, transfection of cells with LPP-1 siRNA was accompaniedby a decrease of $~$ 60% of total LPP activity as measured by activityassays employing LPP-1 immunoprecipitates and [³H]S1P as substrate(data not shown). Down-regulation of LPP-1 mRNA partially attenuatedintracellular S1P generation from extracellular S1P, whereasthe conversion of exogenous Sph to S1P was not altered (Fig. 8C).These results demonstrate that LPP-1 is essential for the hydrolysisand subsequent conversion of exogenous S1P to intracellularS1P in HPAECs.

Role of SphK1 wt, SphK2 wt, or SphK1 mutant on the Productionof Intracellular S1P and Dihydro-S1P Production in HPAECs—mRNAexpressions for SphK1 and SphK2 in HPAECs were detected by RT-PCR(Fig. 9A). Additionally, real-time PCR analysis suggested thatthe relative expression of SphK1 message was higher comparedwith that of SphK2 (Fig. 9B), and Western blotting with specificantibodies revealed expression of both SphK1 and SphK2 in HPAECs(Fig. 9C). Having established the presence of SphK1 and SphK2in HPAECs, we next investigated the role of SphK1 and SphK2in intracellular production of S1P. First, DMS, an inhibitorof SphK, partially blocked S1P- and Sph-dependent formationof [³²P]S1P in HPAECs labeled with [³²P]orthophosphate, indicatingthe involvement of SphK in S1P generation (Fig. 10). To furtherestablish a role for SphK1 in S1P formation, HPAECs were infectedwith adenoviral FLAG-tagged SphK1 or Myc-tagged SphK2 (25 m.o.i.)for 24 and 48 h. Analysis of the cells by immunocytochemistryor cell lysates by Western blotting showed increased expressionof the proteins (Fig. 11, A–D). The effect of overexpressionof SphK1 and SphK2 wt and SphK1 mutant on SphK activity wasexamined in the 100,000 x g cytosol fraction. In vitro phosphorylationof Sph (5 µM) by [ ${gamma}$ -³²P]ATP for 30 min was $~$ 4 and $~$ 2-foldhigher in SphK1- and SphK2 overexpressing cells, respectively,compared with vector controls (Fig. 12A). However, the cytosolfraction from cells infected with the mutant SphK1 exhibiteda marked reduction ( $~$ 50%) in phosphorylation activity (Fig. 12A).In intact cells, overexpression of SphK1 increased [³²P]S1Pformation when exogenous S1P was added, whereas the catalyticallyinactive mutant of SphK1 did not increase S1P formation significantly(Fig. 12B).

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FIGURE 5.
Detection of LPPs by real-time RT-PCR and Western blotting in HPAECs. In panel A total RNA was extracted from HPAECs, and expression of LPPs was normalized to 18 S and quantified by real-time RT-PCR. Values are the average of three independent experiments. In panel B cell lysates (30 µg of protein) were subjected to SDS-PAGE and analyzed by Western blotting with anti-LPP-1, -LPP-2, and -LPP-3 antibodies. The figure shows a representative Western blot of three independent experiments.

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FIGURE 6.
Effect of overexpression of adenoviral construct of LPP-1 wt on hydrolysis of [³H]S1P in HPAECs. HPAECs ( $~$ 60% confluence in 35-mm dishes) were infected with adenoviral construct (10 m.o.i.) for the empty vector or vector containing cDNA for Myc-tagged mLPP-1 for 24 h. Panel A, cell lysates were subjected to SDS-PAGE and Western blotting with anti-LPP-1 antibody (Ab). Panel B, HPAECs grown on glass coverslips to $~$ 60% confluence were infected with cDNA for Myc-tagged mLPP-1 for 24 h, and cells were subjected to immunostaining with anti-Myc antibody (9E10) and examined by confocal fluorescent microscopy. Panel C, HPAECs (passage 6) grown on T-75 cm² flasks were infected with adenoviral construct (10 m.o.i.) for the empty vector or vector containing cDNA for Myc-tagged mLPP-1 for 24 h. Surface labeling of cells with biotin was performed with the Cell Surface Protein Isolation kit (Pierce) as described under "Experimental Procedures." Surface proteins were analyzed by Western blotting with anti-Myc (10E6) or anti-LPP-1 antibodies. Panel D, [³H]S1P (1 µM; specific activity 100 dpm/pmol) complexed with 0.1% BSA in BEGM was added to each dish, and hydrolysis was examined at the end of a 60-min incubation. Lipids were extracted and separated by TLC. Values for sphingosine production are the means ± S.D. of three independent experiments. *, significantly different compared with empty vector infected cells (p < 0.05). IB, immunoblot.

Because overexpression of SphK1, but not SphK2, resulted inpredominant up-regulation of de novo biosynthesis of dihydro-S1P(6–9, 40), we evaluated the effects of overexpressionof SphK1 wt, SphK2 wt, or SphK1 mutant on intracellular accumulationof S1P and dihydro-S1P by LC-MS/MS in the absence or presenceof exogenous sphingosine. Overexpression of SphK1, but not SphK2,revealed a significant accumulation of C18-S1P ( $~$ 10-fold increaseover vector control) and C18 dihydro-S1P ( $~$ 900-fold increaseover vector control) without exogenous addition of sphingosine(Fig. 12, C and D). In the presence Sph, overexpression of SphK1wtand SphK2 wt further enhanced intracellular S1P formation ascompared with without sphingosine addition (Fig. 12C); however,sphingosine addition had no effect on accumulation of dihydro-S1Pin SphK1- or SphK2 wt-expressing cells (Fig. 12D). Overexpressionof SphK1 mutant blocked intracellular conversion of sphingosineto S1P in HPAECs but had no effect on dihydro-S1P formation(Fig. 12D).

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FIGURE 7.
LPP-1 wt overexpression enhances intracellular accumulation of [lsqb]³²P]S1P and [³²P]phyto-S1P. HPAECs ( $~$ 60% confluence) were infected with adenoviral constructs (10 m.o.i.) that contained cDNA for the empty vector or Myc-tagged LPP-1 for 24 h. Cells were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h before exposure to either S1P (1 µM) or phyto-S1P (1 µM) for 30 min. The formation of ³²P-labeled S1P or phyto-S1P was determined after separation by TLC. Values are expressed as the means ± S.D. of three independent experiments in triplicate. *, significantly different compared with cells infected with empty vector adenoviral construct (p < 0.05); **, significantly different compared with empty vector infected cells (p < 0.05); ***, significantly different compared with Myc-tagged LPP-1 wt-infected cells without S1P or phyto-S1P treatment (p < 0.01).

Effect of SphK, S1P Phosphatase, and S1P Lyase siRNA on IntracellularS1P and Dihydro-S1P Formation in HPAECs—Accumulation ofS1P in cells is a balance between its formation via SphK andcatabolism catalyzed by SPP and SPL (10–12). To examinethe relative role of these enzymes in intracellular S1P formationfrom exogenous sphingosine or S1P, HPAECs were transfected withsiRNA specific for SphK1, SphK2, SPP1, or SPL. As shown in Fig. 13A,the mRNA and protein expressions of SphK1 and SphK2 were down-regulatedby SphK1 or SphK2 siRNA, as determined by real-time PCR andWestern blotting. Similarly, siRNA for SPP and SPL also reducedthe mRNA levels of SPP and SPL (Fig. 13B). Down-regulation ofSphK1, but not SphK2, expression by siRNA significantly attenuatedintracellular [³²P]S1P formation with Sph or S1P as an extracellularsubstrate (Fig. 13C). In contrast to SphK1 siRNA, down-regulationof SPP1 and SPL with siRNA increased accumulation of C18-S1Pand C18-dihydro-S1P from exogenous sphingosine as compared withscrambled siRNA transfected cells (Fig. 13, D and E). Theseresults suggest a significant role for SphK1, but not SphK2,in the generation of intracellular S1P by HPAECs exposed toexogenous S1P or Sph. Furthermore, experiments with SPP1 andSPL siRNA indicate that the intracellularly generated S1P isdegraded by SPP and SPL in HPAECs.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The present study provides the first evidence that both humanlung ECs and ECs from other vascular beds utilize and convertextracellular S1P to intracellular S1P. Conversion of exogenousS1P to intracellular S1P required the hydrolysis of the addedS1P to Sph, a process that was mediated by LPPs and subsequentphosphorylation of Sph by intracellular SphK1, but not SphK2,in HPAECs. Our conclusions about the roles of LPPs and SphK1in intracellular S1P production are supported by experimentsin which we increased or decreased LPP-1 and SphK1 activitiesusing LPP-1 wt/LPP-1 and SphK1 adenoviral constructs or siRNA.

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FIGURE 8.
Knock down of LPP-1 by siRNA decreases intracellular generation of [³²P]S1P from exogenous S1P but not from Sph. Panel A, total RNA was extracted from HPAECs transfected with scrambled siRNA or LPP-1 siRNA for 72 h, and transcription of the mRNA was determined by real-time RT-PCR. Panel B, cell lysates from scrambled and LPP-1 siRNA-transfected cells were analyzed by Western blotting (IB) for LPP-1, LPP-2, and LPP-3 protein expression using LPP-specific antibodies. Panel C, HPAECs were transfected with scrambled siRNA or LPP-1 siRNA for 72 h as described under "Experimental Procedures." The transfected media was aspirated, and cells were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM before exposure to exogenous S1P (1 µM) or Sph (1 µM) complexed with 0.1% BSA for 30 min. The accumulation of [³²P]S1P was determined after separation by TLC. Values are the means ± S.D. of six independent experiments. *, significantly different compared with scrambled siRNA transfected cells (p < 0.05); **, significantly different compared with cells exposed to scrambled siRNA + S1P (p, 0.05); ***, not significantly different compared with cells transfected with scrambled siRNA + sphingosine (p > 0.05).

Generation of Sph is the rate-limiting step in S1P productioncatalyzed by SphK1 or SphK2 in mammalian cells (1, 2, 7). Severalearlier studies have documented agonist-dependent generationof S1P in PC12, HEK 293, and NG108 cells (44–46). We showedthat in HPAECs only TNF- ${alpha}$ , but not vascular endothelial growthfactor, 12-O-tetradecanoylphorbol-13-acetate, thrombin, or A23187 [GenBank] ,increased [³²P]S1P accumulation ( $~$ 1.5-fold) compared with vehicletreatment (Fig. 1A). Although TNF- ${alpha}$ (31, 39, 47), angiotensinII (48), or growth factors (49–51) increase intracellularS1P levels via the sphingomyelinase/ceramide pathway, S1P didnot activate sphingomyelinase in HPAECs (Fig. 3), indicatingparticipation of a sphingomyelinase-independent pathway in theproduction of Sph. Interestingly, incubation of HPAECs withhuman PPP or lipids isolated from PPP stimulated intracellularproduction of [³²P]S1P (Fig. 1C). Analysis of human PPP by LC-MS/MSrevealed the presence of S1P and Sph at levels of 1973 and 23pmol/ml, respectively, suggesting that circulating S1P in plasmacould act as a source of intracellular S1P for ECs lining thevessel walls. The source of circulating plasma S1P is unclear;however, platelets can convert Sph to S1P and release it intothe blood (29, 30). Platelets and cells such as HEK 293, mastcells, or NG108 secrete part of S1P (44–46), whereas theS1P that is generated intracellularly in HPAECs from eitherSph or extracellular S1P is not released into the medium (Fig. 2, C and D).Although platelets or other circulating cells could serve asa major source of S1P in the blood, the possibility that smallamounts of free Sph is phosphorylated to S1P by extracellularSphKs cannot be ruled out. In this context, release of overexpressedSphK1 wild type, but not SphK2 wild type, into the cell culturemedium was observed in human umbilical vein ECs (51) and inHPAECs.³ In recent studies of the five SphK isoforms expressedin ECs, only SphK1a isoform was selectively secreted in HEK293, and HUVECs and human plasma were shown to contain SphK1activity (45, 51, 52). Thus, ECs generate intracellular S1Pand also secrete into circulation SphK1a (51, 52), which couldgenerate small but significant levels of S1P from Sph (51, 52).

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FIGURE 9.
Detection of SphK1 and SphK2 by RT-PCR, real-time RT-PCR, and Western blotting in HPAECs. Panel A, total RNA was extracted from $~$ 95% confluent HPAECs and transcription of the genes encoding SphK1 and SphK2 was assessed by RT-PCR (–indicates the absence of reverse transcriptase, and + indicates the presence of reverse transcriptase during RT reaction) with primers indicated to SphKs. Panel B, one-step realtime RT-PCR was performed with total RNA from HPAECs. The relative abundance of target mRNA was calculated as 2 raised to the negative of its threshold cycle value multiplied by 10⁶ normalized to the abundance of 18 S. Panel C, cell lysates (30 µg of protein) from HPAECs were subjected to SDS-PAGE and analyzed by Western blotting with anti-SphK1 and anti-SphK2 antibodies. Each Western blot is representative of three independent experiments.

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FIGURE 10.
Effect of DMS on intracellular generation of [³²P]S1P. HPAECs ( $~$ 95% confluence) were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h before pretreatment with DMS (5 µM) for 1 h. The medium was aspirated, and cells were exposed to medium alone or medium containing either S1P (1 µM) or Sph (1 µM) complexed with 0.1% BSA for 30 min. Cellular lipids were extracted, and accumulation of [³²P]S1P was measured after separation by TLC. Values are given as the means ± S.D. of three independent experiments in triplicate. *, significantly different compared with vehicle treatment (p < 0.05); **, significantly different compared either S1P or Sph exposed cells without DMS (p < 0.01).

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FIGURE 11.
Overexpression of adenoviral constructs of FLAG-tagged SphK and Myc-tagged SphK2 in HPAECs. Panels A and C, HPAECs ( $~$ 60% confluence in 35-mm dishes) were infected with empty vector or with cDNA for FLAG-tagged SphK1 or Myc-tagged SphK2 adenoviral constructs (10 m.o.i.) in complete BEGM for 24 and 48 h. At the indicated time points cell lysates were prepared and subjected to SDS-PAGE and Western blotting (IB) with anti-FLAG or anti-Myc (9E10) antibodies; Panels B and D, HPAECs grown on glass coverslips to $~$ 70% confluence were infected with cDNA for FLAG-tagged SphK1 or Myc-tagged SphK2 adenoviral constructs (10 m.o.i.) for 24 h. Cells were subjected to immunostaining with anti-FLAG or anti-Myc (9E10) antibody and examined by fluorescent microscopy. The Western blots and immunofluorescence images are representative of three independent experiments.

S1P in the plasma seems to be metabolically stable because ofits interaction with albumin and lipoprotein fractions (29,53); however, the level of this bioactive lipid is regulatedby ecto-LPPs that degrade S1P to Sph. The addition of [³H]S1Pto HUVECs or whole blood resulted in marked degradation of theadded substrate with concomitant formation of [³H]Sph, whichwas blocked by the phosphatase inhibitor, vanadate; however,a definitive role for LPPs in the metabolism of [³H]S1P to [³H]Sphwas not demonstrated, although HUVECS were shown to expressmRNAs for LPP1–3 (54). The present study provides thefirst compelling evidence that LPPs present on the surface ofHPAECs regulate the degradation of exogenously added S1P toSph, which subsequently transported into the cell and phosphorylatedby SphK1 to intracellular S1P. In support of this conclusion,exogenously added [³H]S1P was hydrolyzed in a time-dependentfashion primarily to [³H]Sph, and the reaction was blocked byXY-14, an inhibitor of the LPPs (43, 55). The involvement ofLPPs in the generation of intracellular S1P from exogenous S1Pwas also confirmed by decreasing LPP-1 activity using siRNA,which attenuated intracellular accumulation of S1P in HPAECs(Fig. 9C). Overexpression of LPP-1 enhanced the hydrolysis of[³H]S1P to [³H]Sph by 2–3-fold compared with cells infectedwith control adenoviral vector (Fig. 6C). In addition to LPP-1,HPAECs also expressed LPP-2 and LPP-3 as determined by real-timePCR and Western blotting (Fig. 5). However, unlike LPP-1 thatis expressed on the cell surface and internal organelles (Fig. 6B),it is unclear if LPP-2 and LPP-3 are also localized on the extracellularside of the plasma membrane or if they are expressed only withinintracellular cytoplasmic organelles of HPAECs. Our resultswith LPP-1 siRNA (Fig. 9C) indicate that LPP-2 and LPP-3 maybe localized on the cell surface to degrade S1P or other lipidphosphate substrates. Therefore, down-regulation of LPP-1 alonemay not be sufficient to completely block the hydrolysis ofexogenous S1P and its conversion to intracellular S1P in HPAECs.Furthermore, the importance of LPPs in mediating the hydrolysisof exogenous S1P and generation of intracellular S1P is evidentfrom experiments in which HPAECs were provided with a phosphonateanalog of phyto-S1P (PHS-C-P), which failed to generate intracellularphyto-S1P. Interestingly, PHS-C-P was a weak inhibitor of LPPactivity and partly attenuated intracellular S1P or phyto-S1Pproduction from extracellular S1P without affecting the utilizationof Sph. Exposure of HPAECs to PHS-C-P (1 µM) for 30 minpartly attenuated S1P-induced ERK activation, suggesting a rolefor intracellular S1P in signal transduction.³ Further studiesare necessary to address the mechanism(s) of action of PHS-C-Pin attenuating LPP activity and signaling in ECs.

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FIGURE 12.
Effect of overexpression of SphK1 or SphK2 or SphK1 mutant on S1P formation in vitro and in vivo. HPAECs ( $~$ 70% confluence in 100-mm dishes) were infected with cDNA for FLAG-tagged SphK1, Myc-tagged SphK2 or FLAG-tagged SphK1 mutant (10 m.o.i.) for 24 h. Panel A, aliquots of 100 µg of protein were incubated with Sph (1 µM) complexed to 0.1% BSA and [ ${gamma}$ -³²P]ATP (10 µM, specific activity 1 x 10⁴ dpm/pmol) for 30 min at 37 °C. The formation of [³²P]S1P was determined by TLC. Results are expressed as pmol of S1P formed/µg of protein/min. In panel B, cells were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h before challenge with S1P (1 µM) for 30 min. The intracellular accumulation of [³²P]S1P was measured after separation by TLC. Values are the means ± S.D. of three independent experiments. *, significantly different from empty vector without S1P addition (p < 0.05); **, significantly different compared with empty vector (p < 0.01); ***, significantly different compared with cells infected with empty vector plus S1P (p < 0.05). In panels C and D cells were infected with SphK1 wt, SphK2 wt, or sphK1 mutant as described in panel A. Cells were challenged with DMEM or DMEM plus C18-sphingosine (1 µM) for 30 min, and intracellular accumulation of C18-S1P or C18-dihydro (DH)-S1P was measured by LC-MS/MS as described under "Experimental Procedures." Values are the means ± S.D. of three independent experiments. *, significantly different from vector control in the absence or presence of sphingosine (p < 0.05); **, significantly different from vector control in the absence or presence of sphingosine (p < 0.01). Veh, vehicle.

LPPs influence physiological responses mediated by lipid phosphatessuch as S1P or lysophosphatidate through regulating the availabilityof the extracellular ligand and also by controlling the accumulationof bioactive lipid phosphates downstream of G-protein receptoractivation (35). Recent studies show that changing the expressionof different LPPs modulates the S1P- or lysophosphatidate-mediatedactivation of extracellular signal-regulated kinase 1/2, phospholipaseD, DNA synthesis, cell migration, changes in [Ca²⁺]_i, I ${kappa}$ B phosphorylation,and translocation of NF- ${kappa}$ B to the nucleus from the cytoplasmand interleukin-8 secretion (32, 35, 41, 56). However, partof S1P- or lysophosphatidate-mediated signal transduction doesnot depend upon the ecto-LPP activity (41, 18, 58, 59). As afurther function for the LPPs, we show that the hydrolysis ofextracellular S1P by ecto-LPP activity is one of the criticalsteps involved in the intracellular generation of S1P and, consequently,its signaling effects. This work compliments that of Morrisand co-workers (60) who showed that increasing LPP activityenhances the uptake of diacylglycerol by cells treated withexternal phosphatidate. Thus, the LPPs convert lipid phosphatesthat have very limited ability to enter cells into productsthat more readily traverse the plasma membrane and which canthen signal directly or after phosphorylation.

In the present study we also demonstrated that SphK1, but notSphK2, increases intracellular S1P production from exogenousS1P and Sph in HPAECs. Analysis of total RNA by realtime RT-PCRrevealed that both the isoforms were expressed in HPAECs; however,the relative distribution of SphK1 mRNA was relatively highercompared with SphK2 (Fig. 9, A and B). In HPAECs, in vitro phosphorylationof Sph to S1P was higher after overexpression of SphK1 comparedwith SphK2, whereas overexpression of a SphK1 mutant inhibitedphosphorylation of Sph in vitro (Fig. 12A) and intracellulargeneration of S1P from exogenous S1P in HPAECs (Fig. 12B). Arole for SphK1, but not SphK2, in utilizing exogenous S1P asa source for intracellular S1P generation was confirmed by whenSphK1 or SphK2 expression was knocked down with siRNA (Fig. 13C).Agonist-mediated activation of SphK exhibited a biphasic responsewith an early initial phase ( $~$ 2-fold increase) that was independentof new protein synthesis and a late second phase that was dependenton new protein synthesis (50). Our current study shows thatS1P did not stimulate sphingomyelinase; however, it is not knownif SphK1 is activated by exogenous S1P and, if so, which mechanismis involved in the activation. Numerous agonists stimulate SphK1and increase in intracellular S1P; however, no stimulus hasbeen described that specifically affects SphK2 activity (2).Although SphK1 efficiently phosphorylates both Sph and dihydro-Sphto S1P and dihydro-S1P (62), phyto-Sph and the Sph analog FTY720are poor substrates for SphK1 (25, 26). Although most cellsexpress both SphK1 and SphK2, they seem to have opposing functions.It is now well established that SphK1 promotes cell growth andpro-survival, whereas SphK2 inhibits cell growth and enhancesapoptosis (63, 64). Furthermore, overexpression of SphK1 decreasedincorporation of [³H]palmitate into C16-ceramide, whereas SphK2increased it (65). The mechanism(s) responsible for opposingfunctions of SphK1 and sphK2 in ceramide production in NIH 3T3fibroblasts and HEK 293 cells is unclear; however, distinctlocalization of the two proteins or their translocation to differentcompartments within the cell may explain for the opposing effects(65). Accumulation of intracellular S1P is a balance betweenits synthesis through SphK and degradation by SPPs and SPL.Analyses of total RNA revealed expression of SPP-1 and SPL inHPAECs (Fig. 13B). Knocking down the expression of SPP-1 orSPL in HPAECs with siRNA increased the accumulation of C18-S1Pin the presence of Sph (Fig. 13D), suggesting a role for thesetwo enzymes in regulating S1P levels. Our present results showthat overexpression of LPP-1 increased the accumulation of intracellularS1P in response to exogenous S1P because of the ecto-activityof LPP-1.

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FIGURE 13.
Effect of down-regulation of SphK1, SphK2, SPP1, and SPL on intracellular generation of S1P in HPAECs. HPAECs ( $~$ 70% confluence in 35-mm dishes) were transfected with scrambled, SphK1, SphK2, SPP1, or SLP siRNA (100 nM) for 72 h. In panels A and B, total RNA was isolated, and mRNA expression of SphK1, SphK2, SPP1, and SPL, under different transfection, was evaluated by real-time RT-PCR and normalized to 18 S. Values are the averages of six independent experiments. The efficacy of SphK1 and SphK2 siRNA was also evaluated by Western blotting (IB, panel A). In panel C transfected cells were labeled with [³²P]orthophosphate (20 µCi/ml) in phosphate-free DMEM for 3 h before exposure to either Sph (1 µM) or S1P (1 µM) for 30 min. The accumulation of intracellular [³²P]S1P was quantified by TLC. Values given are the means ± S.D. of six independent experiments. *, significantly different compared with scrambled siRNA transfection alone (p < 0.05); **, significantly different compared with scrambled siRNA (p < 0.01); ***, significantly different compared with scrambled siRNA plus S1P or scrambled siRNA + Sph (p < 0.05). In panels D and E, cells were transfected with scrambled, SphK1, SphK2, SPP1, or SPL siRNA for 72 before exposure to medium or medium plus C18-sphingosine (1 µM) for 30 min. The accumulation of intracellular C18-S1P or C18-dihydro-S1P was quantified by LC-MS/MS as described under "Experimental Procedures." *, significantly different compared with scrambled siRNA transfection (p < 0.05); **, significantly different compared with scrambled siRNA plus Sph (p < 0.01). Veh, vehicle.

Recent studies by Giussani et al. (66) show that overexpressionof SPP-1 decreased the levels of S1P and dihydro-S1P in HEK293 cells because of the internal activity of SPP-1, but therewere no concomitant increases in sphingosine and dihydrosphingosine.The present study suggests that the effect of LPP-1 is coupledto SphK1 in intracellular S1P formation in HPAECs, althoughin HEK 293 cells, overexpression of SPP-1 appears to be uncoupledto SphK1 (66). Indeed, LPPs co-localize with SphK1 in Chinesehamster ovary cells (17), further suggesting linkage betweenthese two enzymes. Thus, overexpression of LPP-1 appears tohave the opposite effects on the conversion of exogenous S1Pto intracellular S1P in HPAECs compared with the effects reportedwith SPP-1 in HEK 293 cells (66). Furthermore, overexpressionof SPP-1 increased ceramide levels (61, 66), whereas down-regulatingthis phosphatase increased S1P and reduced Sph levels (57).Therefore, it appears that SPP-1 regulates endoplasmic reticulum-to-Golgitrafficking of ceramide and proteins in HEK 293 cells (66).However, the effect of overexpression of LPP-1 on ceramide levelsand regulation of membrane transport of ceramide and proteinsfrom endoplasmic reticulum to Golgi apparatus has not been studied.In agreement with our findings, overexpression of SPP-1 increasedceramide levels (66), whereas down-regulating this phosphataseincreased S1P and reduced Sph levels (61). Further studies arenecessary to understand the physiological role of SPPs and SLPin regulating intracellular S1P signaling and EC activation.

In summary, this study has examined mechanisms for intracellularproduction of S1P. We have demonstrated that LPP-1 (and probablyother LPPs) plays a critical role in facilitating the uptakeby ECs of Sph formed from circulating S1P. The concentrationof circulating S1P is about 10 times higher than that of Sph,and thus, S1P can provide significant quantities of intracellularSph. This Sph is then converted to S1P by SphK1, but not SphK2,in ECs. Thus, LPPs can modify the balance of signaling by S1Pby three different mechanisms. First, they can decrease extracellularS1P concentrations, thereby lowering the activation of cellsurface receptors. Second, they have been shown to attenuatesignaling downstream of the activation of surface S1P receptors.Third, by promoting the formation of intracellular S1P, theyincrease intracellular signaling by this agonist. These combinedobservations add to our understanding of the complex interplaybetween the roles of S1P as an extracellular versus intracellularsignaling molecule.

FOOTNOTES

^* This work was supported by NHLBI, National Institutes of HealthGrants RO1 HL 79396 (to V. N.) and RO1 HL 803187 (to R. B.)and Canadian Institute of Health Research Grants MOP 49491 and81137 (to D. N. B.). The costs of publication of this articlewere defrayed in part by the payment of page charges. This articlemust therefore be hereby marked "advertisement" in accordancewith 18 U.S.C. Section 1734 solely to indicate this fact.

¹ To whom correspondence should be addressed: Dept. of Medicine, University of Chicago, Center for Integrative Science Bldg., Rm. 408B, 929 East 57th St., Chicago, IL 60637. Tel.: 773-834-2638; Fax: 773-834-2687; E-mail: vnataraj{at}medicine.bsd.uchicago.edu.

² The abbreviations used are: S1P, sphingosine 1-phosphate; DMS,N,N-dimethylsphingosine; EC, endothelial cell; HPAEC, humanpulmonary artery endothelial cell; HUVEC, human umbilical veinendothelial cell; LPP, lipid phosphate phosphatase; mLPP, mouseLPP; PPP, platelet poor plasma; Sph, D-erythro-C18-sphingosine;SphK, sphingosine kinase; SPP, sphingosine 1-phosphate phosphatase;SPL, sphingosine 1-phosphate lyase; PHS-C-P, D-ribophytosphingosine1-phosphonate; XY-14, [(3S)-1,1-difluoro-3,4-bis(oleoyloxy)butyl]phosphonate;DMEM, Dulbecco's modified Eagle's medium; Edg, endothelial differentiationgene; TNF, tumor necrosis factor; FBS, fetal bovine serum; Tricine,N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; wt, wild type;siRNA, small interfering RNA; RT, reverse transcription; m.o.i.,multiplicity of infection; LC-MS/MS, liquid chromatograph-tandemmass spectroscopy; BSA, bovine serum albumin; HEK cells, humanembryonic kidney cells.

³ V. Natarajan, unpublished data.

ACKNOWLEDGMENTS

We thank Dr. Nigel Pyne for helpful discussions.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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