The role of de novo ceramide synthesis in the mechanism of action of the tricyclic xanthate D609

doi:10.1194/jlr.M300300-JLR200

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The role of de novo ceramide synthesis in the mechanism of action of the tricyclic xanthate D609

Ryan J. Perry and Neale D. Ridgway¹

Departments of Pediatrics and Biochemistry and Molecular Biology, Atlantic Research Centre, Dalhousie University, Halifax, Nova Scotia, Canada

Published, JLR Papers in Press, September 16, 2003. DOI 10.1194/jlr.M300300-JLR200

^¹ To whom correspondence should be addressed. e-mail: nridgway{at}dal.ca

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cytotoxic effects of several chemotherapeutic drugs havebeen linked to elevated de novo ceramide biosynthesis. However,the relationship between the intracellular site(s) of ceramideaccumulation and cytotoxicity is poorly understood. Here weexamined the relationship between the site of ceramide depositionand inhibition of protein translation and induction of apoptosisby the antitumor/antiviral xanthate, D609. In Chinese hamsterovary (CHO)-K1, HEK-293, and NIH-3T3 cells, D609 caused rapid(1–5 min) and sustained eukaryotic initiation factor 2 ${alpha}$ (eIF2 ${alpha}$ ) phosphorylation followed by apoptosis after 24 h. Concurrently,D609 stimulated de novo ceramide synthesis and increased ceramidemass 2-fold by 2 h in CHO-K1 cells. In D609-treated CHO-K1 cells,sphingomyelin synthesis was stimulated by brefeldin A, and C₅-DMB-ceramidetransport to the Golgi apparatus was blocked, indicating ceramideaccumulation in the endoplasmic reticulum (ER). However, D609-mediatedeIF2 ${alpha}$ phosphorylation, inhibition of protein synthesis, and apoptosisin CHO-K1 cells were not attenuated by fumonisin B1 or L-cycloserine.Interestingly, short-chain ceramide promoted eIF2 ${alpha}$ phosphorylationand inhibited protein synthesis in CHO-K1 cells, indicatingthat the effectiveness of endogenous ceramide could be limitedby access to signaling pathways.

Thus, expansion of the ER ceramide pool by D609 was not implicatedin early (eIF2 ${alpha}$ phosphorylation) or late (apoptotic) cytotoxicevents.

Abbreviations: BFA, brefeldin A; CHO, Chinese hamster ovary; DAG, diacylglycerol; eIF2 ${alpha}$ , eukaryotic initiation factor 2 ${alpha}$ ; ER, endoplasmic reticulum; OSBP, oxysterol binding protein; PARP, poly(ADP-ribose) polymerase; PLC, phospholipase C; PKR, double-stranded RNA-dependent protein kinase; PtdCho, phosphatidylcholine; RAX, PKR activator X; SM, sphingomyelin; SPT, serine palmitoyltransferase

Supplementary key words eukaryotic initiation factor 2 ${alpha}$ • protein translation • fumonisin B1 • brefeldin A • endoplasmic reticulum export • serine palmitoyltransferase • apoptosis

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ceramide is recognized as a key mediator of cell stress andapoptosis. Numerous studies have demonstrated that generationof ceramide, as either an early or a late response to variousstimuli, is involved in subsequent downstream events that controlcell survival [reviewed in refs. (1, 2)]. An emerging themesuggests that ceramide acts as an index or coordinator of cellularstress responses whereby elevation of ceramide beyond a certainthreshold regulates protein phosphatases (3, 4) or kinases (5–7)involved in mitogenesis, apoptosis, or senescence.

By virtue of its central position in sphingolipid metabolism,ceramide is regulated by multiple synthetic and catabolic processes.Initially, ceramide generation in response to cytokine-activatedneutral sphingomyelinases (SMases) (8–10) was identifiedas an important feature of signaling cascades. More recently,genotoxic drugs and environmental stress have been shown toincrease ceramide by de novo biosynthesis (11). A variety ofapoptotic and cytotoxic agents, such as etoposide (11), SDZPSC 833 (12), daunorubicin (13), phorbol ester (14), and CPT-11(15) have been shown to stimulate de novo ceramide synthesisby increasing serine palmitoyltransferase (SPT) or ceramidesynthase activity. In etoposide-treated cells, ceramide accumulationoccurred primarily by post-translational activation of SPT (11).Blockage of ceramide accumulation by fumonisin B1 treatmentdid not affect etoposide-mediated apoptosis, but appeared tobe involved in a pathway that affected membrane permeability.Daunorubicin also elevated de novo ceramide synthesis and massin leukemic cells, but in this case, by increasing the V_maxfor ceramide synthase by 70% (13). Fumonisin B1 completely orpartially inhibited DNA laddering and nuclear fragmentationin two leukemic cell lines treated with daunorubicin. Anotherstudy confirmed that daunorubicin elevated de novo ceramidesynthesis, but concluded that ceramide was not involved in theactivation of nuclear factor (NF)- ${kappa}$ B by this drug (16). Thus,induction of cell stress and apoptosis by these chemotherapeuticagents involves activation of the biosynthetic pathway and elevationof endogenous ceramide levels, which then engage downstreamsignaling targets.

A question that remains unanswered is the intracellular localizationof the ceramide that is synthesized in response to these drugs.The active sites for the enzymes of ceramide synthesis are localizedto the cytoplasmic surface of the endoplasmic reticulum (ER)(17). Ceramide is then transported to the Golgi apparatus byan ATP-dependent mechanism, where it is converted to sphingomyelin(SM) by SM synthase (18). In most cases, induction of ceramidesynthesis is not accompanied by proportionate increases in SMor glucosylceramide synthesis (12, 19). This suggests that ceramidesynthesis either exceeds its conversion to complex sphingolipidsby subsequent steps in the pathway and accumulates in the ER,or is transported to sites where sphingolipid biosynthetic enzymesdo not reside. This has important ramifications for ceramide-mediatedsignaling, as it appears that generation of ceramide in variousorganelles by targeted expression of bacterial SMase has differentialeffects on apoptosis (20).

D609 (tricyclodecan-9-yl xanthate) was recently shown to inhibitSM synthase, suggesting that it could be a useful agent to elevateceramide levels and monitor subsequent effects on signalingpathways (21). D609 was originally identified as an antiviral/antitumoragent and inhibitor of bacterial phosphatidylcholine (PtdCho)-specificphospholipase C (PLC) (22). This observation has led to thewidespread use of the drug to inhibit mammalian PtdCho-specificPLC, even though a mammalian form of this enzyme has not beenconclusively identified or shown to be specifically inhibitedby D609. D609 has been used extensively in cultured cell modelsto counteract the effects of other drugs or stimuli proposedto act via PtdCho-PLC (23–25), but in few instances havethe primary targets of D609 been investigated. In this regard,it was recognized that xanthates are strong antioxidants (26,27) and zinc chelators (28). Recently, a zinc-independent PtdCho-PLCwas isolated from Pseudomonas aeruginosa that was insensitiveto D609 (29), suggesting that the activity of D609 could berelated to its chelation properties. Still others have suggestedthat D609 could have other primary targets involved in lipidsignaling (21, 30, 31). Thus D609 may have mechanism(s) of actionother than PtdCho-PLC inhibition that account for its antiviral/antitumoractivity.

Here we report that D609 stimulates ceramide synthesis and inducesa rapid phosphorylation of eukaryotic initiation factor 2 ${alpha}$ (eIF2 ${alpha}$ )within minutes, followed by apoptosis after 24 h. However, elevatedendogenous ceramide synthesis and ceramide mass accumulationin the ER was not involved in eIF2 ${alpha}$ phosphorylation, inhibitionof protein synthesis, or apoptosis. We conclude that the cytotoxic/apoptoticeffects of D609 could be linked to stress-induced phosphorylationof eIF2 ${alpha}$ and inhibition of protein synthesis, while effects onsphingolipid metabolism are a more generalized response to drug-inducedcell stress. This also demonstrates that the intracellular siteof ceramide accumulation is an important determinant of itsbiological activity.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials
The potassium salt of D609, C₂-ceramide, and C₂-dihydroceramidewere purchased from Biomol Research Laboratories, Inc. (PlymouthMeeting, PA). N-[5-(5,7-dimethyl boron dipyrromethene difluoride)-1-pentanoyl]-D-erythro-sphingosinewas from Molecular Probes, Inc. (Eugene, OR). Fumonisin B1 andL-cycloserine were from Sigma Aldrich. Brefeldin A (BFA) andrecombinant Escherichia coli sn-1,2-diacylglycerol (DAG) kinaseand z-VAD-fmk were purchased from Calbiochem (La Jolla, CA).Chelerytherine was purchased from LC laboratories. [³H(G)]serineand [ ${gamma}$ -³²P]ATP were from NEN/Mandel Life Science. L-[³⁵S]methioninewas from Amersham Biosciences. Tissue culture reagents and mediawere from Gibco-BRL. Silica gel 60 TLC plates were from BDH.

Cell culture
Chinese hamster ovary (CHO)-KI, HEK-293, and NIH-3T3 cells weregrown in monolayers at 37°C in 5% CO₂. CHO-KI and HEK-293cells were cultured in DMEM containing 5% (v/v) FCS and 33 µgprotein/ml (medium A). NIH-3T3 cells were cultured in DMEM containing10% (v/v) FBS. Cells were subcultured in 60 mm dishes in 3 mlof medium. Cells received fresh medium on day 3, and experimentswere started 18–24 h later. Stock solutions of reagentswere prepared in the following manner: D609 (25 mg/ml stockor 93 mM) was freshly prepared in water and added directly todishes at the indicated final concentrations; BFA (1 mg/ml stock)was dissolved in ethanol and added directly to dishes for afinal concentration of 1 µg/ml; fumonisin B1 (10 mM stock)was dissolved in phosphate-buffered saline (PBS) and added directlyto dishes at a final concentration of 50 µM or 100 µM;and L-cycloserine (500 mM) was dissolved in water and addeddirectly to dishes.

Analysis of labeled sphingolipids and phospholipids
To assess the effect of D609 on de novo sphingolipid and phospholipidsynthesis, cells were preincubated for 4 h in serine-free mediumA prior to pulse labeling with [³H]serine (5 µCi/ml) inthe same medium. After incubation with [³H]serine and variouspharmacological agents (refer to figure legends for times andconcentrations), cells were rinsed twice with cold PBS and harvestedin methanol-water (5:4; v/v). [³H]serine incorporation intosphingolipids and phospholipids was quantified after extractionof total lipid with chloroform-methanol (1:2;v/v) (32). [³H]serineincorporation into phospholipids was determined by TLC of totallipid extracts on silica gel 60 plates in a solvent system ofchloroform-methanol-acetic acid-water (60:40:4:1; v/v/v/v).To measure [³H]serine incorporation into SM, ceramide, glucosylceramide,and sphinganine, total lipid extracts were subjected to hydrolysisin 0.1 N potassium hydroxide for 1 h at 37°C. Sphingolipidswere extracted with chloroform-methanol (2:1; v/v) and separatedby TLC in a solvent system of chloroform-methanol-2-N-ammoniumhydroxide (40:10:1; v/v/v) (33). Following TLC, phospholipidsand sphingolipids were identified by fluorography and/or comigrationwith an authentic standard, scraped into vials, and quantifiedby scintillation counting

Quantification of cellular DAG and ceramide mass
DAG and ceramide mass from total lipid extracts were measuredby the DAG kinase assay (34) and expressed relative to totalcell protein (35).

Enzyme assays
Following D609 or mock treatments, cells were rinsed twice withcold PBS, scraped in the same buffer, and collected by centrifugationat 2,000 g for 5 min. The cell pellets were homogenized in 20mM Tris-HCl (pH 7.7) and 10 mM EDTA (buffer A) by 10 passagesthrough a 23-gauge needle, and total membrane fraction was preparedby centrifugation of the homogenate at 400,000 g for 15 minat 4°C. The membrane fraction (pellet) was resuspended inbuffer A to a final concentration of $~$ 1 mg/ml. SM synthase andSPT activities were then measured as previously described (36,37).

C₅-DMB-ceramide transport
The fluorescent ceramide analog C₅-DMB-ceramide was used toassess ceramide transport from the ER to the Golgi apparatusby a modified protocol (38). Briefly, CHO-KI cells were culturedin medium A on glass coverslips. Fresh medium A was added tocells on day 2, and experiments were started 18–24 h later.Following treatments (see legend of Fig. 7 for specific details),cells were labeled with 1.25 µM C₅-DMB-ceramide complexedwith 1.25 µM fatty acid-free BSA in DMEM for 30 min at4°C. Cells were washed three times with DMEM at 4°C,followed by incubation with DMEM containing 0.34 mg/ml fattyacid-free BSA for 0–30 min at 37°C. The experimentwas terminated by rinsing cells twice with cold PBS and fixingthe cells in 3% (w/v) formaldehyde for 15 min. Finally, cellswere washed twice with 5 mM ammonium chloride, rinsed with distilledwater, and mounted on slides in 50 mM Tris-HCl (pH 9.0) containing2.5% (w/v) 1,4-diazabicyclo-[2.2.2]octane and 90% glycerol.Cell images were acquired using a Zeiss Axiovert 200 fluorescencemicroscope equipped with an Axiocam digital camera and importedinto Photoshop 5.0.

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Fig. 7. D609 interferes with C₅-DMB-ceramide export from the endoplasmic reticulum (ER). CHO-K1 cells were treated with 375 µM D609, D609 (375 µM) plus fumonisin B1 (100 µM), or no addition for 30 min prior to loading with C₅-DMB-ceramide. Transport of C₅-DMB-ceramide from the ER to the Golgi apparatus was monitored by fluorescence microscopy after 30 min at 37°C. The Golgi apparatus was visualized in cells similarly treated with a giantin polyclonal antibody and a goat anti-rabbit-Alexafluor 555-conjugated secondary antibody. NA, no addition; FB1, fumonisin B1.

Immunoblotting and antibodies
Total and serine 51-phosphorylated eIF2 ${alpha}$ were detected by immunoblottingwith monoclonal antibodies (New England Biolabs). Endogenousoxysterol binding protein (OSBP) was detected with a pan-OSBPantibody (39). Full-length and caspase-proteolyzed poly(ADP-ribose)polymerase (PARP) were detected by immunoblotting using a polyclonalantibody (Santa Cruz Biotechnology, Inc.). For PARP detection,cells were extracted in 10 mM sodium phosphate (pH 7.4), 500mM NaCl, 2 mM EDTA, 1 mM DTT, 100 µM PMSF, 1% (w/v) TritonX-100, and 1x protease cocktail (Pierce Biotechnology), anda soluble fraction prepared by centrifugation at 10,000 g for10 min. Following transfer of proteins from SDS-polyacrylamidegels to nitrocellose, filters were incubated with primary antibodiesfor 1 h in Tris (pH 7.4), 150 mM NaCl, 0.1% (v/v), Tween 20,and 5% (w/v) skim milk powder. For total and phospho-eIF2 ${alpha}$ detection,filters were incubated with primary antibodies in Tris-HCl (pH7.4), 150 mM NaCl, 0.04% (w/v) Tween 20, and 5% (w/v) BSA for12 h at 4°C. Filters were incubated with secondary goatanti-mouse or goat anti-rabbit secondary antibodies coupledto horseradish peroxidase, and proteins were detected by thechemiluminescence method (Amersham Biosciences).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

D609 stimulates phosphorylation of eIF2 ${alpha}$
Phosphorylation of eIF2 ${alpha}$ on serine 51 results in inhibition ofprotein translation initiation via its sequestration of theguanine nucleotide exchange factor eIF2B (40). Phosphorylationof eIF2 ${alpha}$ can be catalyzed by four kinases in response to a varietyof stress signals including viral infection, heat shock, serumwithdrawal, heme deficiency, oxidative stress, and cytokines[as reviewed in ref. (41)]. Because D609 was reported to haveantiviral and antitumor activity, we tested whether the activityof this drug could be mediated via phosphorylation of eIF2 ${alpha}$ andsubsequent suppression of protein translation. Preliminary dose-responsestudies indicated that 375 µM D609 (100 µg/ml) hadmaximal effects on eIF2 ${alpha}$ phosphorylation and sphingolipid metabolism(see later figures) and as such, this concentrations was usedin all experiments. Three cell lines (CHO-K1, HEK-293, and NIH-3T3)were treated with D609 for up to 2 h, and the phosphorylationof eIF2 ${alpha}$ on serine 51 was monitored using a phospho-specificantibody (Fig. 1A) . Phosphorylation of serine 51 was detectible1 min after D609 addition to cells, and depending on the celltype, reached a maximum between 5 min and 30 min. The extentof eIF2 ${alpha}$ phosphorylation in response to thapsigargin, an inhibitorof calcium reuptake into ER stores and a known activator ofeIF2 ${alpha}$ phosphorylation (42), after 2 h was similar to D609 treatmentat 1–2 h. Stimulation of eIF2 ${alpha}$ phosphorylation by D609was accompanied by a 50% decrease in protein synthesis at 30min that was sustained for 2 h (Fig. 1B). To assess whetherD609 induced the phosphorylation of other proteins in additionto eIF2 ${alpha}$ , we examined OSBP phosphorylation (Fig. 1C). Phosphorylationof serines 381, 384, and 387 in OSBP results in an apparentincrease in molecular mass by SDS-PAGE, and is regulated bythe cholesterol and sphingolipid content of the cell (39, 43)and by oxidative stress (Perry and Ridgway, unpublished observations).D609 increased phosphorylation of OSBP, albeit slightly delayedrelative to eIF2 ${alpha}$ , as indicated by a shift to the higher molecularmass form (44). Thapsigargin treatment for 2 h did not affectOSBP phosphorylation. Thus an early event following D609 treatmentis phosphorylation of eIF2 ${alpha}$ and inhibition of protein synthesis.

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Fig. 1. D609 stimulates rapid phosphorylation of eukaryotic initiation factor 2 ${alpha}$ (eIF2 ${alpha}$ ) in Chinese hamster ovary (CHO)-KI, HEK 293, and NIH 3T3 cells. A: Cells were treated with 375 µM D609 for the indicated times, cell extracts were prepared, and proteins (10 µg) were separated on SDS-8% PAGE and immunoblotted for phospho- or total eIF2 ${alpha}$ as described in Materials and Methods. As a positive control, cells were treated with thapsigargin (20 µM) for 2 h. B: CHO-K1 cells were treated with 375 µM D609 (open circle) or solvent control (closed circle) for up to 2 h and pulse labeled with [³⁵S]methionine for the last 30 min of each treatment time. Total cell lysates were prepared and analyzed for [³⁵S]methionine incorporation into TCA-precipitated protein. Results are the mean and SEM for three independent experiments. C: Treatments were as described in A. Immunoblots were probed with an oxysterol binding protein (OSBP)-specific antibody to detect the hyper- and hypophosphorylated forms of OSBP.

Regulation of ceramide synthesis by D609
A recent report showed that eIF2 ${alpha}$ phosphorylation was stimulatedby short-chain ceramide via phosphorylation of PKR activatorX (RAX), an activator of the double-stranded RNA-dependent proteinkinase (PKR) (4). Because exogenous ceramides can stimulatestress kinases (5, 7, 38), it was proposed that this pathwaycould be responsible for activation of RAX/PKR, phosphorylationof eIF2 ${alpha}$ , and inhibition of translation. This, coupled with reportsthat various chemotherapeutic drugs activate ceramide synthesis,suggested that D609 could stimulate eIF2 ${alpha}$ phosphorylation byincreasing endogenous ceramide levels. Initial studies in CHO-K1cells confirmed that D609 (180–375 µM) caused apartial delay in SM resynthesis after bacterial SMase treatment(results not shown), consistent with inhibition of SM synthaseactivity involved in a salvage pathway for SM resynthesis (21).However, the effects of D609 on de novo sphingolipid synthesishave not been reported, raising the possibility that activationof ceramide synthesis or inhibition of SM synthase could contributeto the observed changes in sphingolipid metabolism in responseto this drug. To test this possibility, ceramide and sphingolipidsynthesis was measured in CHO-K1 cells treated with D609 forup to 2 h by pulse-labeling with [³H]serine (Fig. 2A) . D609caused a rapid enhancement of [³H]serine incorporation intoceramide that reached a maximum of 10-fold by 1 h. Interestingly,D609 increased [³H]serine incorporation into SM by 2- to 3-fold.D609 also caused a dramatic inhibition of phosphatidylserinesynthesis but did not affect [³H]serine incorporation into phosphatidylethanolamine.The effect of D609 on SM and ceramide metabolism appeared tobe a common response in cultured cells, because a similar increasein [³H]serine incorporation into SM and ceramide was observedin HEK-293 and, to a lesser extent, NIH-3T3 cells (Fig. 2B).

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Fig. 2. Stimulation of de novo ceramide synthesis in D609-treated cells. A: CHO-KI cells were cultured in serine-free medium A for 4 h prior to addition of 375 µM D609 (open circle) or no addition (closed circle) for 15 min followed by [³H]serine (5 µCi/ml) for the indicated times. [³H]serine incorporation into ceramide (Cer), sphingomyelin (SM), phosphatidylserine (PtdSer), and phosphatidylethanolamine (PtdEtn) was measured as described in Materials and Methods. Results are the mean and SEM from three independent experiments performed in triplicate. B: CHO-KI, HEK-293, and NIH-3T3 cells were cultured in serine-free medium for 4 h, and treated with (black bars) or without (gray bars) 375 µM D609 for 15 min prior to the addition of [³H]serine (5 µCi/ml) for 2 h. Results are the mean and SEM from a representative experiment.

To determine whether increased de novo ceramide synthesis resultedin increased ceramide mass, CHO-K1 cells were treated with D609for up to 2 h and ceramide and DAG mass in lipid extracts wasanalyzed by the DAG kinase method (Fig. 3A) . D609 caused asignificant increased in ceramide mass by 1 h and a continuedincrease to 2-fold by 2 h. The increase in ceramide mass inresponse to D609 was completely blocked by fumonisin B1, aninhibitor of ceramide synthase, confirming that it was derivedsolely from de novo synthesis. D609 also significantly decreasedDAG levels to a maximum of 50% by 30 min. The decrease in DAGmass was not affected by fumonisin B1, suggesting it occursindependently of D609 effects on sphingolipid metabolism.

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Fig. 3. Increased ceramide mass in D609-treated CHO-KI cells is blocked by fumonisin B1. CHO-KI cells were treated with 50 µM fumonisin B1 (triangle), 375 µM D609 (circle), or both (square). Control cells (0 h) were mock treated with appropriate solvent for 2 h. Total lipids were extracted from cells at the indicated times and ceramide and diacylglycerol (DAG) mass determined by the E. coli DAG kinase assay as described in Materials and Methods. Results are the mean and SEM for three independent experiments. * P < 0.05 compared with untreated cells.

To establish which enzyme(s) in ceramide biosynthesis were affectedby D609, CHO-K1 cells were treated with D609 or D609 plus fumonisinB1, and [³H]serine incorporation into ceramide and sphinganinewas measured (Fig. 4) . As expected, fumonisin B1 inhibitedceramide synthesis and elevated [³H]sphinganine production,consistent with inhibition of ceramide synthase. Pretreatmentof cells with fumonisin B1 completely blocked the increase in[³H]serine incorporation into ceramide caused by D609. Moreover,the decrease in ceramide synthesis following D609 and fumonisinB1 treatment was accompanied by a reciprocal 10-fold increasein [³H]sphinganine levels, suggesting that biosynthetic stepsprior to ceramide synthase were stimulated by D609.

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Fig. 4. Fumonisin B1 blocks the D609-mediated increase in ceramide synthesis. CHO-KI cells were preincubated in medium A for 4 h before treatment with 50 µM fumonisin B1 (open circle), 375 µM D609 (closed triangle), D609 and fumonisin B1 (open triangle), or no addition (closed circle). Fumonisin B1 was added 30 min prior to the addition of D609, which was added 15 min prior to the addition of [³H]serine (5 µCi/ml) to the media. The indicated times are for incubation with [³H]serine. [³H]serine incorporation into sphinganine (Spa) and ceramide (Cer) was measured as described in Materials and Methods. The results are mean and SEM for triplicate determinations from a representative experiment that was repeated twice with similar results.

The activity of SPT, which catalyzes the initial step in sphingolipidsynthesis, is stimulated by genotoxic drugs by unknown mechanisms(11). To determine whether D609 had a similar effect, membranesisolated from CHO-K1 cells treated with D609 were assayed forSPT activity. SPT activity in membranes from CHO-K1 cells treatedwith D609 was increased by 25–30% between 30 min and 120min, but was only significant at the 30 min time point. (Fig.5A) . SPT activity returned to control values by 4 h. Additionof D609 (375 µM) to untreated CHO-K1 cell membranes didnot affect SPT activity, thus ruling out a direct effect ofthe drug (result not shown). The in vitro activity of SM synthasein membranes from D609-treated CHO-K1 cells was unchanged overthe first 2 h and was slightly inhibited by 4 h (Fig. 5B). Weconfirmed the results of Luberto et al. (21) that D609 (375µM) inhibited SM synthase activity by >80% when addeddirectly to the in vitro assay (results not shown). Collectively,the results in Figs. 4 and 5 show that D609 stimulates sphingolipidsynthesis and ceramide mass accumulation primarily via increasedSPT activity.

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Fig. 5. Effect of D609 on serine palmitoyltransferase (SPT) and SM synthase activity. CHO-K1 cells were treated with 375 µM D609 for up to 4 h. The 0 h point refers to cells treated with solvent alone for 4 h. Total membrane fractions were prepared and assayed for SPT (A) and SM synthase (B) activity as described in Materials and Methods. Results are the mean and SEM for six experiments (SPT) or a representative experiment (SM synthase). * P < 0.05 compared with untreated controls.

ER deposition of ceramide in D609-treated cells
The biological activity of endogenous ceramide is probably dependenton transport to other locations in the cell where it can affectvarious signaling processes or be further metabolized. It ispresently unknown whether ceramide accumulation following stimulationof de novo synthesis is retained in the ER or transported toother sites. If ceramide accumulation in D609-treated cellswas restricted to the ER, then BFA could be used to merge theER and Golgi compartments and make ER-associated ceramide accessibleto SM synthase (45). Consistent with previous reports in CHO-K1cells (46, 47), BFA increased SM synthesis but had no effecton [³H]serine incorporation into ceramide (Fig. 6) . As expected,D609 caused a marked elevation in synthesis of ceramide, andto a lesser extent, of SM and sphinganine. Treatment of cellswith BFA and D609 resulted in a 60% reduction in [³H]ceramideaccumulation with a corresponding rise in SM synthesis, suggestingthat more than one-half of the ceramide in the ER was now availableto the SM synthase. Interestingly, under conditions of BFA andD609 treatment, [³H]serine incorporation into sphinganine increasedby 4-fold. However, the increase in [³H]sphinganine was relativelyminor compared with the reciprocal changes in labeled ceramideand SM. Addition of D609 or BFA also promoted a 3-fold increasein glucosylceramide synthesis, but the effect of the two agentswas not additive.

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Fig. 6. Brefeldin A (BFA) stimulates conversion of ceramide to SM in D609-treated cells. CHO-KI cells were cultured in serine-free medium A for 4 h before treatment with 1 µg BFA/ml (open circle), 375 µM D609 (closed triangle), D609 and BFA (open triangle), or no addition (closed circle). BFA was added to cells 15 min prior to the addition of D609, which was added 15 min prior to the addition of [³H]serine (5 µCi/ml) to the media. The indicated times are for incubation with [³H]serine. [³H]serine incorporation into Cer, SM, Spa, and glucosylceramide (GluCer) was measured as described in Materials and Methods. Results are the mean and SEM from a representative experiment repeated two other times with similar results. In some cases, error bars are hidden by symbols.

The accumulation of ceramide in the ER of D609-treated cells(Fig. 6) and the relatively poor conversion to SM (Figs. 1,6) implies that ceramide export from the ER is inhibited orsaturated. To distinguish between these two possibilities, thefluorescent ceramide analog C₅-DMB-ceramide was used as a markerof ceramide transport to the Golgi apparatus (48). CHO-K1 cellswere treated with or without D609 for 2 h prior to loading withC₅-DMB-ceramide for 30 min at 4°C. Subsequent transportof the fluorescent analog to the Golgi apparatus was then monitoredafter incubation at 37°C for 30 min. (Fig. 7) . In controlcells, C₅-DMB-ceramide exited the ER network and appeared incompact perinuclear regions corresponding to the Golgi apparatusafter 30 min at 37°C. In D609-treated cells, C₅-DMB-ceramidewas initially found in a diffuse perinuclear region and reticularnetwork. There was no evidence of compact Golgi-perinuclearstaining after 30 min at 37°C, suggesting that transportto the Golgi apparatus was inhibited. Finally, to determinewhether inhibition of C₅-DMB-ceramide export was the resultof dilution in a large ER pool of endogenous ceramide in D609-treatedcells, CHO-K1 cells were pretreated with fumonisin B1 to preventendogenous ceramide accumulation. However, this explanationseems unlikely, because the C₅-DMB-ceramide staining patternin D609/fumonisin B1-treated cells was similar to that of D609-treatedcells at 0 min and 30 min. D609 and fumonisin B1 had a minimaleffect on the structure of the Golgi apparatus, as determinedby immunostaining for giantin (Fig. 7, right panels). Giantinlocalization was similar to that of C₅-DMB-ceramide in controlcells at 30 min, but not to the diffuse perinuclear stainingobserved in D609- or D609/fumonisin B1-treated cells at either0 min or 30 min.

Elevated endogenous ceramide is not linked to D609-mediated phosphorylation of eIF2 ${alpha}$ or apoptosis
Having established that D609 elevates endogenous ceramide levelsin the ER primarily by stimulation of de novo synthesis, wenext assessed whether this was linked to the phosphorylationof eIF2 ${alpha}$ shown in Fig. 1. In these experiments, eIF2 ${alpha}$ phosphorylationon serine 51 was measured in D609-treated CHO-K1 cells thatwere pretreated with fumonisin B1 or the SPT inhibitor L-cycloserinein order to block the increase in ceramide and sphinganine (Fig.8A) . As expected, D609 treatment increased phosphorylationof eIF2 ${alpha}$ after 30 min. However, neither L-cycloserine nor fumonisinB1 had any effect on D609 activation of eIF2 ${alpha}$ phosphorylation.CHO-K1 cells also displayed a significant increase in eIF2 ${alpha}$ phosphorylationwhen exposed to exogenous C₂-ceramide, but not the dihydro analog,indicating that signaling pathways that respond to exogenousceramide were intact in these cells. Changes in phosphorylationstatus of eIF2 ${alpha}$ shown in Fig. 8A were correlated with proteintranslation as measured by [³⁵S]methionine incorporation (Fig. 8B).Fumonisin or L-cycloserine did not block the inhibitionof protein translation by D609; and C₂-ceramide, but not thedihydro analog, inhibited translation. The exception was bacterialSMase treatment, which did not affect eIF2 ${alpha}$ phosphorylation (Fig. 8A)but partially inhibited protein synthesis (Fig. 8B).

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Fig. 8. Increased endogenous ceramide synthesis in D609-treated cells is not required for eIF2 ${alpha}$ phosphorylation. A: CHO-K1 cells were treated with 375 µM D609, D609 (375 µM) plus fumonisin B1 (100 µM), D609 plus L-cycloserine (2 mM), C₂-ceramide (100 µM), C₂-dihydroceramide (100 µM), bacterial sphingomyelinase (SMase) (50 mU), thapsigargin (20 µM), or appropriate solvent controls for 2 h. Cell extracts were prepared and total or serine 51-phosphorylated eIF2 ${alpha}$ was quantitated by immunoblotting, followed by densitometry. The ratio of phospho- to total eIF2 ${alpha}$ was expressed as fold-increase relative to the water control. B: Cells were treated as described in A for 1 h. Protein synthesis (expressed relative to water-treated control) was determined by pulse labeling with [³⁵S]methionine for the final 30 min. Results are the mean and SEM for three independent experiments. FB1, fumonisin B1; L-CS, L-cycloserine; C₂-Cer, C₂-ceramide; C₂-dihydro, C₂-dihydroceramide; bSMase, bacterial SMase; thaps, thapsigargin.

Elevation of ceramide levels by increased de novo synthesisor SM hydrolysis is often associated with or required for apoptosis.Thus it was feasible that ceramide production in response toD609, while not affecting protein translation, could triggerapoptosis. Detection of caspase proteolysis of 116 kDa PARPinto the characteristic 85 kDa fragment revealed that D609 treatmentfor 24 h caused limited induction of apoptosis in the threecell lines compared with a 2 h treatment with the protein kinaseinhibitor chelerytherine (Fig. 9) . Treatment of cells withfumonisin B1 or L-cycloserine did not prevent PARP cleavagein D609-treated CHO-K1 or NIH 3T3 cells. In HEK 293 cells, thesmall amount of PARP cleavage induced by D609 was inhibitedby fumonisin B1 but not by L-cycloserine. Cleavage of PARP inD609- and chelerytherine-treated cells was blocked by the broad-spectrumcaspase inhibitor z-VAD-fmk. Thus, caspase activation and apoptosisin response to D609 is not dependent on de novo ceramide generation.

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Fig. 9. Endogenous ceramide synthesis is not linked to D609-induced caspase cleavage of poly(ADP-ribose) polymerase (PARP). CHO-K1 cells were treated with D609 (375 µM), fumonisin B1 (50 µM), L-cycloserine (2 mM), D609 plus fumonisin B1, D609 plus L-cycloserine, z-VAD-fmk (20 µM), D609 plus zVAD-fmk, or no addition for 24 h. As a control for PARP cleavage, cells were treated with chelerytherine (20 µM), or chelerytherine plus z-VAD-fmk for 2 h. Cell extracts were prepared and immunoblotted for PARP using a polyclonal antibody as described in Materials and Methods.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We have investigated the relationship between activation ofceramide synthesis in the ER and its subsequent transport tothe Golgi apparatus, and phosphorylation of eIF2 ${alpha}$ and inhibitionof protein translation by the xanthate D609. Results show thatalthough D609 strongly stimulated flux through the sphingolipidbiosynthetic pathway, leading to elevated ceramide mass, thiswas not required for stimulation of eIF2 ${alpha}$ phosphorylation andapoptosis. Indeed, ceramide mass accumulation in the presenceof D609 was restricted primarily to the ER, and D609 eliciteda ceramide-independent stress response that resulted in rapidinhibition of translation and later induction of apoptosis.Inhibition of protein synthesis and induction of apoptosis couldbe related to the reported antiviral and antitumor activityof D609.

D609 was originally identified as a putative inhibitor of mammalianPtdCho-specific PLC based on inhibition of the Bacillus cereusenzyme. Although widely used as a pharmacological inhibitorof this enzyme, mammalian PtdCho-PLC has not been isolated orshown to be specifically inhibited by D609, except indirectlyby changes in cellular phosphocholine and DAG levels. Recentevidence indicated that inhibition by D609 of an SM synthaseactivity involved in a salvage (SM resynthesis) pathway couldpotentially elevate ceramide and reduce DAG levels (21, 49).Our examination of the effects of D609 on de novo sphingolipidsynthesis indicated that the drug caused rapid [³H]serine incorporationinto ceramide, accompanied by a modest increase in [³H]sphinganinelevels. Although de novo ceramide synthesis was stimulated byD609, the drug did not inhibit the SM synthase activity involvedin de novo synthesis. This conclusion is based primarily onthe observations that D609 stimulated SM synthesis (Figs. 2,6), albeit much less than the total increase in ceramide, andSM synthesis was stimulated 10-fold by D609 in the presenceof BFA (Fig. 6). Moreover, total SM synthase activity in membranesfrom D609-treated cells was either not affected or weakly inhibitedat late time points. This is contrary to the reported inhibitionof SM synthase by D609 in transformed lung fibroblasts (21).However, we confirmed that D609 inhibited SM synthase activityin CHO-K1 cell membranes in vitro, and in CHO-K1 cells, D609caused a 20–40% inhibition of SM resynthesis followinghydrolysis of [³H]serine-labeled SM by bacterial SMase (resultsnot shown). A plausible explanation for these discrepanciesis that different SM synthase enzymes are involved in salvageand de novo synthetic pathways, or excess de novo ceramide generationin response to D609 interfered with the measurement of SM resynthesisfollowing bacterial SMase treatment.

Several lines of evidence lead us to conclude that D609 stimulatedde novo ceramide synthesis at the SPT catalyzed step. First,treatment with the ceramide synthase inhibitor fumonisin B1completely blocked elevated ceramide synthesis (by [³H]serinelabeling) and mass in response to D609. Second, the additionof fumonisin B1 to D609-treated cells resulted in a reciprocalrise in [³H]sphinganine levels, indicating that a step priorto ceramide synthase was stimulated. And finally, in vitro assaysof membranes from D609-treated cells revealed a modest but significantincrease in SPT activity similar to that reported for otherapoptotic agents (11, 50). Collectively, these results showthat D609 activates the initial and rate-limiting step in sphingolipidsynthesis, leading to a global increase in sphingolipid synthesisand elevated ceramide mass. Although the mechanism of SPT activationis unknown, the rapidity of activation in response to diversepharmacological agents suggests a post-transcriptional mechanisminvolving a common apoptotic or stress-induced pathway.

The disparity between [³H]serine incorporation into ceramideversus that of SM and glucosylceramide indicated that ceramideexport from the ER was inhibited by D609. This conclusion issupported by experiments with BFA, which enhanced SM synthesisin D609-treated cells by merging the ER and Golgi apparatusand effectively bringing expanded ceramide pools into contactwith SM synthase. BFA was effective in reducing labeled ceramidelevels by 60%. The incomplete conversion to SM indicates eitherthat SM synthase was saturated with substrate, that not allER ceramide was equally available to the enzyme, or that ceramidehad been transported from the ER and was not affected by BFA.Regardless of the explanation, these results show that upregulationof de novo ceramide synthesis by D609 results in a substantialportion remaining in the ER. Ceramide accumulation in the ERcould have resulted from either inhibition of export, transbilayermovement, or saturation of the export pathway (18). Like endogenousceramide, transport of the fluorescent ceramide analog C₅-DMB-ceramidefrom the ER to the Golgi was inhibited in the presence of D609and not restored by reducing ceramide levels with fumonisinB1 (Fig. 7). This supports the idea that D609 blocks transportof ceramide from the ER or a preGolgi compartment to the Golgiapparatus. D609 may have other general effects on lipid andprotein trafficking, because it has also been reported to inhibitprosaposin transport to the lysosomes in CHO-K1 cells (31).

Treatment with exogenous C₂-ceramide stimulated phosphorylationof eIF2 ${alpha}$ by an unknown stress-activated kinase (4). The proposedmechanism involves phosphorylation of RAX(PACT), which enhancesits binding to and activation of the double-stranded RNA-dependentkinase PKR, one of several eIF2 ${alpha}$ kinases (42, 51). Contrary toresults with short-chain ceramide analogs, which in CHO-K1 cellsstimulated phosphorylation of eIF2 ${alpha}$ and inhibited protein translation(Fig. 9), endogenous generation of long-chain ceramides in responseto D609 was not linked to eIF2 ${alpha}$ phosphorylation. This conclusionis based on the lack of effect of fumonisin B1 and L-cycloserineon D609-mediated eIF2 ${alpha}$ phosphorylation and inhibition of proteintranslation, and a delay between significant ceramide accumulation(30–60 min) and eIF2 ${alpha}$ phosphorylation (1–5 min).In addition, we show that prolonged treatment with D609 (24h) induced apoptosis, as indicated by partial processing ofthe caspase 3 substrate, PARP. Although D609 appeared to weaklyinduce apoptosis, decreasing ceramide synthesis with fumonisinB1 or L-cycloserine did not attenuate PARP cleavage. This apparentdichotomy between in vivo effects with endogenous ceramide versusexogenous analogs could be explained by differential accessto signaling pathways. Exogenous short-chain ceramide can diffusefreely into cells and rapidly access cellular compartments andsignaling pathways. In contrast, our results show that endogenouslong-chain ceramides made via the de novo pathway can be restrictedin their movement from the ER and are not involved in subsequentsignaling events. This lack of effect of ER-localized ceramideis supported by a recently reported study examining ceramidegeneration by targeted expression of bacterial SMase in differentorganelles (20). In that study, ER expression of SMase in MCF7cells increased ceramide levels significantly but did not induceapoptosis.

The results of the current study show that the site of generationand movement of endogenous ceramide are important considerationswhen examining its biological activity. A functional dichotomyprobably exists between the effects of exogenous ceramide analogsor ceramide generated at the PM by SM hydrolysis and ceramidemade in the ER. In the case of D609, stimulation of ceramideproduction generates a relatively static pool of ER ceramidethat has restricted access to other compartments of the celland is not involved in stress or apoptotic responses.

ACKNOWLEDGMENTS

Technical assistance with tissue culture was provided by RobertZwicker and Glady Keddy. The authors thank Drs. David Byers,Christopher McMaster, and Harold Cook for helpful comments duringthe course of this work. This work was supported by a CanadianInstitutes of Health Research program grant (PG-11476) and Scientistaward (N.D.R.) and a Heart and Stroke Foundation of Canada studentship(R.J.P.).

Manuscript received July 3, 2003 and in revised form September 2, 2003.

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				R. J. Perry and N. D. Ridgway Oxysterol-binding Protein and Vesicle-associated Membrane Protein-associated Protein Are Required for Sterol-dependent Activation of the Ceramide Transport Protein Mol. Biol. Cell, June 1, 2006; 17(6): 2604 - 2616. [Abstract] [Full Text] [PDF]

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