Phospholipase A2 Is Necessary for Tumor Necrosis Factor alpha -induced Ceramide Generation in L929 Cells*

(Received for publication, January 21, 1997, and in revised form, March 21, 1997)

Supriya Jayadev Dagger , Heather L. Hayter Dagger , Nathalie Andrieu §, Christopher J. Gamard Dagger , Bin Liu Dagger , Ram Balu Dagger , Makio Hayakawa , Fumiaki Ito and Yusuf A. Hannun Dagger par

From the Dagger  Departments of Medicine and Cell Biology, Duke University Medical Center, Durham, North Carolina 27710, the § Laboratoire de Biochimie, "Maladies Metaboliques," Institut Louis Bugnard, 31054 Toulouse, France, and the  Department of Biochemistry, Setsunan University, Hirakata, Osaka 573-01, Japan

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES


ABSTRACT

The role of cytosolic phospholipase A2 (cPLA2) in the regulation of ceramide formation was examined in a cell line (L929) responsive to the cytotoxic action of tumor necrosis factor alpha (TNFalpha ). In L929 cells, the addition of TNFalpha resulted in the release of arachidonate, which was followed by a prolonged accumulation of ceramide occurring over 5-12 h and reaching 250% over base line. The formation of ceramide was accompanied by the hydrolysis of sphingomyelin and the activation of three distinct sphingomyelinases (neutral Mg2+-dependent, neutral Mg2+-independent, and acidic enzymes). The variant cell line C12, which lacks cPLA2, is resistant to the cytotoxic action of TNFalpha . TNFalpha was able to activate nuclear factor kappa B in both the wild-type L929 cells and the C12 cells. However, TNFalpha was unable to cause the release of arachidonate or the accumulation of ceramide in C12 cells. C6-ceramide overcame the resistance to TNFalpha and caused cell death in C12 cells to a level similar to that in L929 cells. The introduction of the cPLA2 gene into C12 cells resulted in partial restoration of TNFalpha -induced arachidonate release, ceramide accumulation, and cytotoxicity. This study suggests that cPLA2 is a necessary component in the pathways leading to ceramide accumulation and cell death.


INTRODUCTION

The sphingomyelin (SM)1 cycle, first described by Okazaki et al. (1), has gained recognition over the past few years as a key mechanism for regulating anti-mitogenic signals. Activation of this cycle through the regulation of a signal-induced sphingomyelinase (SMase) results in generation of the lipid second messenger ceramide. Ceramide then modulates a number of biological fates, including growth inhibition (1-3), differentiation (2), apoptosis (4-6), and cell cycle arrest (7). Although recent studies have begun to catalogue inducers such as TNFalpha , interleukin-1beta , nerve growth factor, and Fas that are capable of signaling through the SM cycle (see Refs. 5, 6, and 8 for reviews), the mechanisms by which these inducers stimulate SMase activity remain poorly understood.

TNFalpha , through interaction with either a 55- or 75-kDa TNF receptor (9, 10), impacts upon a myriad of intracellular signaling cascades, including protein phosphorylation cascades, transcription factors, and lipid messengers (11). Two classes of lipid mediators have been implicated in TNFalpha signaling, glycerophospholipid metabolites and sphingolipid metabolites (11, 12), and recent evidence suggests that these two classes of lipids may interact (13). In HL-60 cells, a linear correlation was established among TNFalpha stimulation, AA generation, and SM cycle activation: TNFalpha -stimulated AA liberation preceded ceramide generation, and AA reproduced the effects of TNFalpha on the SM cycle (13). Although these studies suggested that AA and/or its metabolites may be involved in activation of SMase, the physiologic role of the PLA2/AA pathway in regulating SMase activity has not been determined.

In this study, we examined the role of PLA2 in SMase activation in the L929 murine fibroblast cell line. In L929 cells, TNFalpha treatment is known to produce potent cytotoxic effects (14). TNFalpha -resistant L929 cells have also been generated via clonal selection from resistant populations of L929 mouse fibroblasts grown in the presence of TNFalpha (14, 15). One of these cell lines, C12, differed from the original L929 cells by the absence of cPLA2 and by the lack of inducibility of AA in response to TNFalpha . However, in all parameters of TNFalpha receptor binding and internalization, this resistant cell line was found to be analogous to the parental L929 line.

Using these two cell lines, L929 and C12, we investigated the necessity of cPLA2 activation and AA generation for TNFalpha -induced ceramide generation. In the L929 model system, we found that the kinetics of cytokine-induced lipid mobilization occurred much later than previously documented in HL-60 (13, 16) and U937 (17) cells. Although the kinetics of activation were protracted in the L929 system, we found that, similar to HL-60 and U937 cells, the mechanism of ceramide generation was still through the activation of SMase and the subsequent hydrolysis of SM. Furthermore, we found that the generation of ceramide in response to TNFalpha did not occur in the resistant line, which was incapable of liberating AA following cytokine treatment. Finally, we found that TNFalpha -induced AA generation, ceramide generation, and cytotoxicity could be partly re-established in a C12 variant containing a cPLA2 expression vector. This study implicates cPLA2 activation and AA generation as necessary precursors to TNFalpha -induced activation of the SM cycle. The implications of these findings are discussed.


EXPERIMENTAL PROCEDURES

Materials

The L929 cell line and its C12 variant have been previously described (14, 15). Dulbecco's modified Eagle's medium and kanamycin sulfate were purchased from Life Technologies, Inc. Heat-inactivated fetal calf serum was purchased from Summit Biotechnologies (Fort Collins, CO). Arachidonic acid was purchased from BIOMOL Research Laboratories Inc. (Plymouth Meeting, PA). [3H]Choline chloride and [3H]arachidonic acid were purchased from DuPont NEN. TNFalpha was a gift from Hoffmann-La Roche (Basel, Switzerland). All other reagents were obtained from Sigma.

Methods

Cell Culture

All cells were maintained for up to 20 passages at 37 °C in a 5% CO2 incubator. For general maintenance, L929 and C12 cells were cultured in Dulbecco's modified Eagle's medium supplemented with 5% fetal calf serum and 60 mg/liter kanamycin sulfate. L929/neo and CPL4 cells were grown in Dulbecco's modified Eagle's medium supplemented with 5% fetal calf serum and 0.8 mg/ml G418. For studies, cells were plated at 2 × 104/well in 12-well plates, at 5 × 104/well in 6-well plates, or at 1 × 105/well in 10-cm Petri plates. Cells were allowed to grow to 50-70% confluence and then washed, refed, rested for 4 h, and treated as indicated. Time-matched controls were always run concurrently.

Arachidonic Acid Release

Cells seeded in 6- or 12-well plates were grown for 2 days and then labeled with 1 µCi/ml [3H]arachidonic acid for 24 h. Post-labeling, cells were washed, refed, and rested for 4 h. Cells were then treated as indicated, and 1.0-1.2 ml of culture medium was harvested from each treatment well. Non-adherent cells were pelleted out of the harvested medium, and 400-µl aliquots were counted to determine the levels of released label. The total counts associated with cells were ~150,000 dpm, and 7% of the total label (10,500 dpm) was released in response to TNFalpha . The medium was also subjected to TLC to assess whether metabolites such as phospholipids or acylglycerols accounted for the observed counts. We found that minimal counts, if any, were associated with such metabolites.

Ceramide and Diacylglycerol Quantitation

Cells grown in 10-cm Petri plates were grown for 2-4 days, refed, rested, and treated. Following the indicated times of treatment, the media were removed from the plates, and adherent cells were washed with PBS. Cells were then scraped, and the lipids were extracted via the method of Bligh and Dyer (18). In instances where cell floaters were analyzed, the treatment media and the PBS wash were pooled and spun down. The resultant pellet was then considered the "floater" population, and lipids were harvested from these cells. Extracted lipids were dried, resuspended in chloroform, and aliquoted for phosphate (19) and diacylglycerol kinase (13) analyses as described previously. Ceramide and diacylglycerol levels were quantitated using external standards, and the resultant values were normalized against total lipid phosphate.

SM Quantitation

Cells grown in 10-cm Petri plates for 2-4 days were treated as described for the ceramide measurements. Lipids were extracted via the method of Bligh and Dyer (18), and SM was quantitated by the bacterial SMase method described previously (13).

SMase Isolation and Assay

Cells were seeded at 3 × 105/30-cm Petri plate in 30 ml of regular growth medium. Cells were allowed to grow for 3-4 days and then washed, refed, and treated. Following the indicated treatment times, cells were scraped into a minimal volume of serum-free medium and pelleted. Retrieved cells were resuspended in cold lysis buffer (20) and lysed via three cycles of freeze-thawing (one cycle = 3 min in a methanol/dry ice bath, 3 min at room temperature, and vortexing). By this protocol, >= 95% of the cells were lysed. Cells were spun at 2100 rpm (1000 × g) for 10 min to remove nuclei and the few unlysed cells. The resulting homogenate was assayed for SMase activity as described previously (13). Assay conditions for the three different sphingomyelinases were as follows: 1) neutral Mg2+-dependent: 10 nmol of SM (2 × 105 cpm), 0.1% Triton X-100, 0.1 M Tris-HCl, pH 7.4, and 5 mM MgCl2; 2) neutral Mg2+-independent: 10 nmol of SM (2 × 105 cpm), 0.1% Triton X-100, and 0.1 M Tris-HCl, pH 7.4; and 3) acidic: 10 nmol of SM (2 × 105 cpm), 0.1% Triton X-100, and 0.1 M sodium acetate, pH 5.0.

Thymidine Incorporation

Cells were grown in 6-well plates for 2 days and then washed, refed, rested, and treated. Four hours prior to harvest, 1 µCi/ml [3H]thymidine was added to each well. Following the indicated treatment times, cells were harvested via a modification of a previously described method (21). Briefly, the medium was removed, and cells were washed twice with cold PBS. Cells remaining in wells were washed twice with 5% trichloroacetic acid and solubilized in 0.5 ml of 0.25 N NaOH, and 0.3 ml was collected and counted.

Crystal Violet Assay

Cells were grown in 6- or 12-well plates for 2 days and then washed, refed, rested, and treated. Following treatment, the medium was removed, and cells were washed with PBS. The amount of cells remaining adhered to the plate was assessed via crystal violet staining as described previously (22).

NF-kappa B Gel Shift

Cells were grown to 70-80% confluence and then treated in the presence of regular culture medium. Following the indicated treatment times, cells were harvested via trypsinization, and the pellets were washed one time with cold PBS. Nuclear extractions and electrophoretic mobility shift assays were run via a modification of methods previously described (23). Briefly, the cell pellets were quick-frozen using an ethanol/dry ice bath, and the pellets were then resuspended in 50-100 µl of hypotonic buffer (10 mM HEPES, pH 7.9, 10 mM KCl, 1.5 mM MgCl2, and 1 mM dithiothreitol). This hypotonic lysis yields ~100% lysis of cells. The lysed cells were then spun, and the nuclear pellet was recovered and resuspended in 15 µl of hypertonic buffer (20 mM HEPES, pH 7.9, 0.4 M NaCl, 1.5 mM MgCl2, 25% glycerol, 0.2 mM EDTA, 1 mM dithiothreitol, and 0.5 mM phenylmethylsulfonyl fluoride). Extraction of the nuclear protein was achieved by gentle mixing of this mixture for 30 min at 4 °C. The debris was then spun down, and the resultant supernatant was diluted with 20-70 µl of dilution buffer (20 mM HEPES, pH 7.9, 50 mM KCl, 20% glycerol, 0.2 mM EDTA, 1 mM dithiothreitol, and 0.5 mM phenylmethylsulfonyl fluoride). Approximately 2-µl aliquots were used for the Bio-Rad protein assay, and the remaining portion was quick-frozen and stored at -80 °C until gel shift assays were run. Protein-DNA reactions were performed in a 20-µl volume and contained 8-10 µg of nuclear extract, 1 µg of poly[d(I·C)], 1 µg of poly[d(N)6], 10 µg of bovine serum albumin, 20 mM HEPES, pH 7.9, 50 mM KCl, 1 mM EDTA, 5 mM dithiothreitol, and 10,000-50,000 cpm radiolabeled oligonucleotide probe (see Ref. 23 for sequences used). Reactions were allowed to proceed for 20 min and then terminated by the addition of 6 µl of 15% Ficoll. Nondenaturing polyacrylamide gels (5%) that had been prerun for 1-1.5 h at 200 V were loaded with equal volumes of reaction mixture and run at 200 V for 1.5-2 h. Gels were then dried and exposed to film. Shown (Fig. 10) is a representation of an autoradiogram obtained in this manner.


Fig. 10. Effects of TNFalpha on NF-kappa B. Nuclear extracts were prepared from TNFalpha -treated cells as described under "Experimental Procedures." The amount of NF-kappa B activation was assessed via gel shift analysis as described. The upper band of the doublet is indicative of nuclear translocated NF-kappa B. The gels shown are representative of multiple experiments. A, time course with 0.2 nM TNFalpha treatment of L929 cells; B, comparison of TNFalpha -induced NF-kappa B activation between L929 and C12 cells. Cells were treated with 0.5 nM TNFalpha for 15 min.
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RESULTS

TNFalpha Is Cytotoxic to L929 Cells

L929 murine fibroblasts are acutely sensitive to the cytotoxic effects of TNFalpha . Treatment with 0.1-30 nM TNFalpha induced significant cell death within 24 h as detected via cell counts, crystal violet assays, and [3H]thymidine uptake measurements (Fig. 1). Interestingly, cytotoxicity in these cells was accompanied by the loss of adhesion to the culture plate at later time points. By 12 h of treatment, a floater population of cells was starting to appear. Following 24 h of treatment, 97% of the cells were found in this floater population, of which almost 99% were dead and only 1% remained viable (Fig. 1B). Of the cells remaining adhered to the culture plate, 50-80% of the cells remained viable as determined by trypan blue exclusion. With increased periods of TNFalpha treatment, fewer cells remained in the viable/adherent population, and more cells were found in the dead/floater population. Thus, loss of adhesion appears to correlate with terminal stages of the L929 death process induced by TNFalpha .


Fig. 1. Effects of TNFalpha on L929 growth. Cells grown in 12-well plates were treated with the indicated doses of TNFalpha for 24 h. A, parallel plates were seeded for crystal violet and thymidine incorporation assays. For thymidine incorporation measurements, [3H]thymidine was added 4 h prior to harvest. At the time of harvest, cells were washed twice with PBS, and the number of adherent cells remaining was determined as described under "Experimental Procedures." The results shown are the means of duplicate measurements (with S.D.) and are representative of three to six separate experiments. B, at the time of harvest, media and PBS wash solutions were collected and spun down as a measure of the floater population. Remaining adherent cells were harvested via trypsinization. Both populations of cells were quantitated using a hemocytometer, and trypan blue exclusion was used to measure viability. The results shown are representative of three separate experiments.
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TNFalpha Stimulates Ceramide Production in L929 Cells

TNFalpha treatment of L929 cells also led to maximal increases in ceramide levels within 24 h (Fig. 2A). As early as 5-6 h following treatment with 5 nM TNFalpha , increases in ceramide of 150% were observed (Fig. 2A, inset). This delayed TNFalpha -induced ceramide generation differed from the previously reported effects in which cytokine stimulated ceramide production within seconds or minutes of treatment. In fact, L929 cells showed no fluctuation in ceramide over a period of 1-60 min (data not shown), a time frame in which ceramide levels have been shown to peak and subsequently return to basal levels in HL-60 cells treated with TNFalpha (13). Furthermore, L929 cells demonstrated prolonged elevations of ceramide levels. Instead of attaining a peak level and quickly returning to basal levels, L929 cells were found to maintain almost an 180% increase in ceramide as long as 48 h following TNFalpha treatment.


Fig. 2. Effects of TNFalpha on ceramide generation in L929 cells. Cells grown in 10-cm Petri plates were treated for the indicated times with 5 nM TNFalpha . At the time of harvest, floaters were collected as described under "Experimental Procedures," and adherent cells were collected via scraping. Lipids were extracted and analyzed as described under "Experimental Procedures." A, extended time course with TNFalpha . The results are expressed as time-matched vehicle controls. Basal levels of ceramide were in the 4.2-4.9 pmol/nmol phospholipid range. Inset, short time course of treatment showing actual pmol of ceramide/nmol of phospholipid Pi. Analysis of variance for repeated measurements followed by Tukey's test showed that TNFalpha -treated cells were significantly different from t = 6 h (p < 0.001). B, comparison of changes in the floater and adherent populations of cells treated for 24 h with TNFalpha . The results shown are the means ± S.D.
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More important, ceramide elevations in response to TNFalpha preceded the onset of death. In the adherent population, which showed minimal cell death, maximal ceramide elevations were observed. Also, ceramide elevations were observed as early as 5 h following treatment; in contrast, the presence of floaters was not seen until 12 h (data not shown). Floater populations maintained high levels of ceramide, suggesting that basal levels could not be reattained prior to the onset of death (Fig. 2B).

Prolonged Elevations of Ceramide Are Accompanied by SM Hydrolysis

Since there was such a difference in the kinetics of TNFalpha -induced ceramide elevation in L929 cells compared with previously studied cytokine-stimulated systems, it became important to ascertain whether sphingomyelin was the source of ceramide. We therefore determined whether SM levels decreased in response to TNFalpha stimulation. Indeed, we found that, as early as 2 h following treatment, SM levels had decreased by ~20%, and by 14 h, when ceramide levels had increased to maximal levels, SM levels dropped by 40% as assessed by loss of label (Fig. 3).


Fig. 3. Effects of TNFalpha on SM hydrolysis. [3H]Choline-labeled cells were treated at time 0 with 5 nM TNFalpha or PBS vehicle. Following the indicated times of treatment, cells were harvested, lipids were extracted, and SM was quantitated as described under "Experimental Procedures." Shown are the means of two independent determinations, and the results are representative of four individual experiments with similar results.
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We then investigated whether the difference in the temporal relation between TNFalpha induction and ceramide elevation could be explained by a difference in the type of SMase activated. In HL-60 cells, it has been shown that the rapid elevation of ceramide is the consequence of activation of a neutral cytosolic SMase activity. In contrast, stimulation of L929 cells with TNFalpha was found to increase the activity of not only the two neutral SMase activities (both magnesium-independent and magnesium-dependent), but also the acidic SMase activity (Fig. 4). Although the elevation of all three activities appeared to be analogous (~2-fold) in the adherent population of cells, there were some differences among the three activities in the floater population (Fig. 4). Floater/dead cells appeared to have the greatest increase in neutral magnesium-independent SMase activity (>3-fold). The neutral magnesium-dependent SMase was the first to show increased activity in response to TNFalpha , and its activity was increased ~2-2.5-fold at 4-6 h following treatment (data not shown).


Fig. 4. Effects of TNFalpha on SMase activities in L929 cells. Cells, treated for 24 h with 5 nM TNFalpha or PBS vehicle, were harvested, and the post-nuclear homogenate was collected and assayed for activity as described under "Experimental Procedures." Shown are representative plots of neutral and acidic enzyme activities in L929 cells.
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AA Generation Temporally Precedes Ceramide Generation

As with other cell systems, TNFalpha stimulation of L929 cells led to an increase in AA release (Fig. 5). AA release in L929 cells demonstrated delayed kinetics, with the earliest increases observed following only 3-4 h of treatment (Fig. 5B) (14). Following 5-60 min of TNFalpha treatment, times in which HL-60 cells have been found to elevate AA levels, almost no change in AA release was found (data not shown). Furthermore, over the time period in which AA release was observed in L929 cells, the maximal level of AA elevation superseded the levels observed in other cell systems. Following 4-8 h of TNFalpha treatment, an almost 2-fold increase in AA release was observed.


Fig. 5. Time course of TNFalpha -stimulated AA release. Cells grown in 6-well plates were [3H]AA-labeled for 24 h. Label was removed, and cells were treated with 3 nM TNFalpha or PBS vehicle for the indicated times. Following treatment, released label was quantitated as described under "Experimental Procedures." The results shown are the means ± S.D. A, extended time course of AA release; B, short time course of AA release.
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Similar to HL-60 cells, cytokine-stimulated AA release temporally preceded ceramide elevations (Fig. 5B versus Fig. 2A, inset). Whereas ceramide increases could not be seen until 5 h following treatment with 5 nM TNFalpha , AA release was seen 1-2 h earlier. Temporally, therefore, the link between AA generation and ceramide generation still holds even with the prolonged kinetics observed in L929 cells.

AA Generation Is Defective in the C12 Cell Line

Although temporal correlations establish AA as a precedent to ceramide generation, the necessity for PLA2 activity/AA generation to modulate TNFalpha -induced ceramide elevation required the use of other tools. The L929 variant line C12 is known to be defective in cPLA2 as evaluated by Northern blot analysis, activity measurements (14), and Western blot analysis (data not shown). In L929 cells, 30 nM TNFalpha caused a 60% decrease in cell numbers as early as 16 h following treatment; in contrast, cytokine treatment of C12 cells resulted in very little cytotoxicity even following extended treatment (Fig. 6). At best, in the C12 cell line, a maximal cytotoxic effect of ~35% decrease in proliferation was observed after prolonged (48 h) stimulation with 30 nM TNFalpha .


Fig. 6. Effects of TNFalpha on proliferation of C12 cells. Cells grown in 12-well plates were treated with 30 nM TNFalpha for the indicated times. At the time of harvest, cells were washed twice with PBS, and the number of adherent cells remaining was determined by the crystal violet assay as described under "Experimental Procedures." A similar quantitation with 30 nM TNFalpha treatment of L929 cells is included as a point of comparison. Parallel plates quantitated via either thymidine incorporation or cell counts yielded identical results. The results shown are the means ± S.D.
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Similar to previous findings (15), we found that the resistance of C12 cells to TNFalpha accompanied the inability to generate AA. Whereas the parental L929 line showed an elevation of AA release that peaked within 3-5 h of treatment (Fig. 5), C12 cells exhibited little or no increase in AA even following prolonged stimulation (Fig. 5A). A decreased amount of total cellular AA could account for the inability of resistant lines to generate AA in response to TNFalpha . Thus, it became important to ascertain whether the mass levels of AA were different in L929 versus C12 cells. As shown in Table I, there was very little difference in the basal mass levels of AA between the two lines, with both L929 and C12 cells containing 50-60 pmol of AA/nmol of phosphate. Similarly, there were no significant differences in the content of other fatty acids between these two cell lines (Table I).

Table I. Mass levels of fatty acid constituents

Logarithmically growing untreated cells were harvested via scraping. Lipids were collected and analyzed as described under "Experimental Procedures." An internal standard was utilized in each of the various fatty acids. To determine absolute mass, lipid quantitations were normalized to phosphate.

Fatty acid L929 C12

(pmol/nmol Pi) (pmol/nmol Pi)
14:0 56 59
16:0 700 581
16:1 47 50
18:0 1,122 961
18:1 761 663
18:2 26 23
18:3 12 9
20:0 18 17
20:1 17 11
20:3 13 9
20:4 62 50
22:0 6 4
22:4 18 14
22:6 33 27
24:0 5 4

Ceramide Generation Does Not Occur in the Absence of AA Generation

We next assessed the ability of TNFalpha to stimulate SM hydrolysis and ceramide generation in the resistant cells. We found that, similar to AA release, ceramide generation was perturbed in C12 cells. In L929 cells, TNFalpha was able to induce a 2-fold elevation of ceramide levels within 14 h of treatment with 30 nM TNFalpha . In contrast, C12 cells exhibited no change in ceramide levels during the same time period (Fig. 7). Neither extended (24 h) nor short-term treatment with cytokine (data not shown) elicited any change in ceramide in these resistant cells. Furthermore, we found that TNFalpha treatment did not lead to a decrease in SM levels (Fig. 3) or to an elevation of any of the three SMase activities that have been linked with signaling, the neutral magnesium-independent, neutral magnesium-dependent, and acidic activities (Fig. 8). The basal specific activities of all three enzymes (neutral magnesium-independent, ~1000 cpm/mg/h; neutral magnesium-dependent, ~2000 cpm/mg/h; and acidic, ~20,000 cpm/mg/h) were equivalent in L929 and C12 cells. Indeed, treatment with TNFalpha in C12 cells caused a decrease in the activity of the SMases, possibly a result of activation of anti-apoptotic pathways in C12 cells (such as NF-kappa B) that remain responsive in this cell line (see below).


Fig. 7. Effects of TNFalpha on ceramide in C12 cells. Cells grown in 10-cm Petri plates were treated for the indicated times with 5 nM TNFalpha . At the time of harvest, floaters were collected as described under "Experimental Procedures," and adherent cells were collected via scraping. Lipids were extracted and analyzed as described under "Experimental Procedures." Shown are the means ± S.D. from an extended time course. KRH, Krebs-Ringer HEPES buffer.
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Fig. 8. Effects of TNFalpha on SMase activities in C12 cells. Cells, treated for 24 h with 5 nM TNFalpha or PBS vehicle, were harvested, and the post-nuclear homogenate was collected and assayed for activity as described under "Experimental Procedures." Shown are representative plots of neutral and acidic enzyme activities. A similar quantitation with L929 cells is included as a point of comparison.
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Ceramide Does Not Induce AA Generation, but Does Induce Cytotoxicity

The above results suggest that the generation of AA is coupled to ceramide generation. To establish that perturbation of ceramide generation is not the reason for the aberrant response of C12 cells in generating AA, we determined whether exogenous ceramide addition affected AA levels. In L929 cells, we found that treatment with 10 µM C6-ceramide had no stimulatory effect on AA release (Fig. 9A). In contrast, treatment of L929 cells with equivalent concentrations of C6-ceramide caused death (Fig. 9B). Concentrations as low as 1 µM C6-ceramide induced a 30% decrease in proliferation within 24 h, and concentrations of 10-40 µM caused as much as a 50-90% decrease in growth within 24 h. Thus, ceramide is able to elicit the same biological end point as TNFalpha without stimulating AA production, demonstrating that ceramide generation is not upstream of AA generation.


Fig. 9. Effects of ceramide on AA release and proliferation. A, cells were prelabeled with [3H]AA for 24 h and then treated with vehicle, 1 nM TNFalpha , or 20 µM C6-ceramide. Following 24 h of treatment, label release was quantitated as described under "Experimental Procedures." The results shown are the means of duplicate samples and are representative of three separate experiments. B, cells grown in 12-well plates were treated with the indicated concentrations of ceramide for 24 h. Quantitation of proliferation was done via the crystal violet assay as described under "Experimental Procedures." The data shown are the means ± S.D.
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Ceramide Overrides the Resistance of C12 Cells

C12 cells, similar to L929 cells, did not release AA in response to 10 µM C6-ceramide (Fig. 9A). However, concentrations of 1-40 µM C6-ceramide were able to elicit cytotoxicity in both of these cells (Fig. 9B). Notably, C6-ceramide was more cytotoxic to C12 cells than to L929 cells. Thus, the defect in C12 cells could be rectified via exogenous treatment with ceramide, suggesting that ceramide functions downstream of PLA2 activation and AA generation.

Lack of AA Generation Does Not Perturb Other TNFalpha -induced Signaling Cascades

Since disruption of PLA2 activity/AA generation should exclusively affect downstream events regulated by AA, other signaling events not associated with AA should remain unperturbed. We therefore determined whether TNFalpha signaling to NF-kappa B remained intact. TNFalpha -induced NF-kappa B activation in L929 cells exhibited very different kinetics from the mobilization of AA or ceramide. Nuclear translocation of NF-kappa B was observed via gel shift analysis as early as 5 min following stimulation with 0.2 nM TNFalpha (Fig. 10A). Treatment of L929 cells over a period of hours showed that nuclear translocation of NF-kappa B was maintained over 4 h, but unlike AA and ceramide liberation, began to decline markedly by 12 h. More important, C12 cells, similar to L929 cells, showed nuclear translocated NF-kappa B within 15 min of treatment with 0.5 nM TNF (Fig. 10B). The level of NF-kappa B activation seen in the TNFalpha -sensitive versus -resistant fibroblasts was nearly identical. Thus, NF-kappa B stimulation, a TNFalpha -responsive signaling event, appears to be intact even in cells incapable of signaling through PLA2 and AA. These results establish a specificity to the perturbation of ceramide generation in resistant cells.

cPLA2 Activity Is Necessary for Ceramide Generation

C12 cells, which had been found to lack TNFalpha -responsive cPLA2 activity, were transfected with an expression plasmid containing cPLA2 to generate the CPL4 cell line (15). These cells express PLA2 activity (14) and cPLA2 protein as evaluated by Western blot analysis (data not shown). These CPL4 cells were utilized to assess the necessity of cPLA2 activity for ceramide generation. When treated with TNFalpha , CPL4 cells responded similarly to both the parental L929 and control vector-transfected L929/neo cell lines; however, CPL4 cells displayed delayed kinetics and decreased responsiveness to TNFalpha . Concentrations of 5 nM TNFalpha stimulated only 60% death within 24 h (versus 90% death in L929/neo cells) in CPL4 cells (Fig. 11A). CPL4 cells, like L929 cells, also responded to TNFalpha by stimulating AA release. At 1 h of TNFalpha treatment, when the vector (positive) controls were beginning to show a response (138%), CPL4 cells showed lower than basal levels of AA release (90%). However, by 4 h of treatment with 5 nM TNFalpha , CPL4 cells showed levels of AA release (150%) comparable to those seen in L929/neo cells (190%) (Fig. 11B). CPL4 cells also responded to exogenous ceramide treatment much like the other lines, with doses of 1-40 µM having potent effects within 12-24 h (Fig. 11C). Finally, CPL4 cells were able to respond to TNFalpha treatment with generation of ceramide. Ceramide generation corresponded to the other changes in CPL4; thus, elevations occurred later than in L929/neo cells and never reached the full extent of response attained in the vector controls. Following 5 h of treatment with 5 nM TNFalpha , L929/neo cells showed a response of an almost 125% ceramide increase; in contrast, CPL4 cells exhibited basal levels of ceramide at this time. By 24 h, CPL4 cells still showed decreased responsiveness compared with L929/neo cells; however, they did produce significantly more (180%) ceramide than control untreated cells (Fig. 11D). Since C12 cells did not show any level of ceramide responsiveness to cytokine, the increase in ceramide generation can be attributed to the expression of cPLA2. The attenuation in the responses of CPL4 cells may be related to the incomplete restoration of PLA2 levels in this cell line as seen by activity measurements (14) and by Western blot analysis (data not shown). Since CPL4 cells showed significant enhancement of cytokine-induced lipid generation and growth inhibition compared with the precursor C12 line, which differs only in the expression of cPLA2, these results establish the necessity of cPLA2 activity/AA generation for ceramide generation and growth inhibition.


Fig. 11. Effects of reintroducing cPLA2 activity into C12 cells. A, cells grown in 12-well plates were treated with the indicated concentrations of TNFalpha for 24 h. Following treatment, wells were washed, and the remaining cells were quantitated via the crystal violet assay. The results shown are the means ± S.D. B, cells prelabeled with [3H]AA for 24 h were treated with 5 nM TNFalpha for 4 h. Released label was quantitated as described under "Experimental Procedures." C, cells grown in 12-well plates were treated with the indicated concentrations of C6-ceramide for 24 h. Quantitation was done via the crystal violet assay. Shown are the means ± S.D. D, cells grown in 10-cm plates were treated with 5 nM TNFalpha for 24 h. Following treatment, cells were harvested, and lipids were extracted and analyzed as described under "Experimental Procedures." Shown are means ± S.D. Student's t test showed significance in both the L929/neo (p = 0.01) and CPL4 (p < 0.001) lines.
[View Larger Version of this Image (21K GIF file)]


DISCUSSION

This study demonstrates the importance of PLA2 to ceramide generation and cytotoxicity. Previous studies in the HL-60 cell system suggested a link between AA and the SM cycle in TNFalpha signaling (13); however, the L929 system, used here, has allowed the further development of these initial studies. L929 cells vary markedly from the HL-60 model in two critical respects. First, the temporal correlation between receptor activation and lipid mobilization (both AA release and ceramide release) is greatly attenuated in L929 cells, taking hours as opposed to minutes. Second, the magnitude of change in ceramide elicited by TNFalpha stimulation of L929 cells (2-4-fold changes) exceeds the levels attainable upon cytokine stimulation of HL-60 cells (at best, 1.5-1.8-fold changes) (13, 16). Despite these differences, both systems show TNFalpha -induced PLA2 activation/AA generation to occur prior to SM hydrolysis and ceramide generation. Thus, the L929 model demonstrates that AA-mediated signaling to ceramide is not restricted to one cell system, but is indeed a cascade that may have greater implications.

Furthermore, the L929 model has been used here to extend our studies from the correlative level to establish the necessity of AA liberation for ceramide generation. These studies were possible because of the availability of L929 clones resistant to the cytotoxic effects of TNFalpha that are defective in cPLA2. We found that, whereas L929 cells responded to TNFalpha stimulation by elevating AA levels within 2-4 h, C12 cells showed little if any elevation of AA release. Likewise, we found that, unlike the parental L929 line, this resistant line was incapable of responding to TNFalpha through the production of ceramide. In contrast, TNFalpha -stimulated NF-kappa B activation appeared to be intact, suggesting that only AA-dependent cascades were affected in the resistant cells. Thus, initial observations with the resistant lines illustrated the specificity of the interplay between AA and ceramide. We further established the necessity for AA generation through utilization of a variant strain of C12, the CPL4 line, which differed from C12 only with respect to the presence of an expression plasmid containing the murine cPLA2 gene. We found that, through recapitulating PLA2 activity in the CPL4 lines, we were able to re-establish 1) cytokine-induced AA generation, 2) TNFalpha -induced ceramide generation, and 3) TNFalpha -induced growth inhibition. Although the CPL4 system did not fully restore cytokine responsiveness, it did serve to demonstrate the interconnection among AA, ceramide, and growth.

A number of key points emerge from this study. First, it becomes apparent that the kinetics of ceramide generation are dependent upon the type of SMase activated. Whereas rapid ceramide mobilization has been attributed to the activation of one enzyme (depending on the system, a neutral, cytosolic, or acidic SMase), more prolonged ceramide generation appears to be the consequence of multiple activities perhaps acting together: a neutral Mg2+-dependent SMase, a neutral Mg2+-independent SMase, and an acidic SMase. Whether all three of these enzyme activities can be regulated by AA remains to be determined. Also, since the long-term accumulation of ceramide involves multiple enzymes, multiple pools of SM could be implicated. At a first level of examination, however, the ceramide generated in both the L929 and HL-60 systems appears to be similar (as determined by TLC) (data not shown). Whether all three SMase activities found to be stimulated by TNFalpha in L929 cells can act on the same pool of SM, however, remains unknown.

Second, these results raise the question of how PLA2/AA couples to SMase. The exact links between PLA2 activation/AA generation and ceramide generation remain elusive. Furthermore, other components that may be involved in regulating the signaling cascade between TNF receptor stimulation and SMase activation remain to be determined. It is important to note in this context that Fas ligand-induced death, in contrast to TNF, may not require cPLA2 (27).

Finally, the prolonged kinetics of ceramide generation raise a possibility that ceramide may function as a long-term regulator of cell growth/viability. Indeed, most studies examining the changes in ceramide associated with cell death or growth suppression disclose similar long-term changes in ceramide. These include serum withdrawal, fas stimulation, and dexamethasone-induced apoptosis (7, 24, 25). These studies have raised the question whether ceramide generation is a precedent to cell death and differentiation or whether ceramide elevations are a consequence of the biological fate and serve more as a marker of phenotype. The kinetics established in this study clearly show that both SMase activation and ceramide elevation precede the appearance of a dead/floater population of cells. The observed increase in ceramide in the adherent population of cells demonstrates cytokine-responsive SM hydrolysis prior to the onset of death, suggesting that ceramide precedes cell death. Ongoing studies also support a role for ceramide prior to the onset of actual cell death. In cells overexpressing the anti-apoptotic protein Bcl2, it appears that ceramide generation in response to chemotherapeutic agents is not perturbed, although cell death is greatly reduced (26). Such studies continue to expand our understanding of where AA and ceramide fit in the overall scheme between cell stimulation and onset of response, whether it be death, differentiation, or cell cycle arrest.


FOOTNOTES

*   This work was supported in part by National Institutes of Health Grant GM-43825.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
par    To whom correspondence should be addressed: P. O. Box 3355, DUMC, Durham, NC 27710. Tel.: 919-684-2449; Fax: 919-684-8253.
1   The abbreviations used are: SM, sphingomyelin; SMase, sphingomyelinase; TNFalpha , tumor necrosis factor alpha ; AA, arachidonic acid; PLA2, phopholipase A2; cPLA2, cytosolic PLA2; PBS, phosphate-buffered saline; NF-kappa B, nuclear factor kappa B.

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