Sphingosine mediates TNFα-induced lysosomal membrane permeabilization and ensuing programmed cell death in hepatoma cells.

Normally, cell proliferation and death are carefully balanced in higher eukaryotes, but one of the most important regulatory mechanisms, apoptosis, is upset in many malignancies, including hepatocellular-derived ones. Therefore, reinforcing cell death often is mandatory in anticancer therapy. We previously reported that a combination of tumor necrosis factor-α (TNF) and cycloheximide (CHX) efficiently kill HTC cells, a rat hepatoma line, in an apoptosis-like mode. Death is actively mediated by the lysosomal compartment, although lysosomal ceramide was previously shown not to be directly implicated in this process. In the present study, we show that TNF/CHX increase lysosomal ceramide that is subsequently converted into sphingosine. Although ceramide accumulation does not significantly alter the acidic compartment, the sphingosine therein generated causes lysosomal membrane permeabilization (LMP) followed by relocation of lysosomal cathepsins to the cytoplasm. TNF/CHX-induced LMP is effectively abrogated by siRNAs targeting acid sphingomyelinase or acid ceramidase, which prevent both LMP and death induced by TNF/CHX. Taken together, our results demonstrate that lysosomal accumulation of ceramide is not detrimental per se, whereas its degradation product sphingosine, which has the capacity to induce LMP, appears responsible for the observed apoptotic-like death.


Annexin V/propidium iodide staining and FACS analysis
The percentage of apoptotic cells was estimated by counting the phosphatidylserine (PS)-positive/propidium iodide (PI)-negative fraction using the Annexin V/PI kit (ImmunoStep, Salamanca, Spain). Adherent cells were detached with 0.25% trypsin and collected together with fl oating ones, centrifuged, and resuspended in 190 µl of binding buffer (10 mM HEPES-NaOH pH 7.4, 140 mM NaCl, 2.5 mM CaCl 2 ). Annexin V and PI were then added. At least 5,000 cells were analyzed in a FACScan equipped with a 488 nm argon laser (Becton-Dickinson, Milan, Italy) using the CellQuest software (Becton-Dickinson).
TNF-induced cytotoxicity was also found to involve formation of ceramide, achieved by involvement of acid or neutral sphingomyelinases (aSMase, nSMase) or activation of the de novo pathway, yet the role of these enzymes is debated ( 19,20 ). Recently, the role played by ceramide in TNF cytotoxicity was reevaluated because during TNFinduced PCD, sphingolipids other than ceramide, such as sphingosine, are also affected (21)(22)(23)(24)(25). As the latter is a split product of ceramide, it is often not easy to discriminate between the effects of these two sphingolipids.
In a previous article, we described that, in rat hepatomaderived HTC cells, TNF in association with cycloheximide (CHX) induces an apoptosis-like death that involves the lysosomal compartment ( 26 ). As this death was prevented by a putative aSMase inhibitor, desipramine (Dpm), we next investigated whether a ceramide-related mechanism is involved in it ( 23 ). The results indicated that ceramide-induced death mechanistically differs from that triggered by TNF/CHX, thus ruling out a direct role of ceramide in the latter. However, the results from these studies ( 23,26 ) did not satisfactorily answer the question as to whether TNF treatment alters cellular levels of ceramide or other sphingolipids that may be involved in TNF-induced death. This issue is addressed in the present work, showing that ligation of the TNF receptor triggers the generation of ceramide and sphingosine, and that the lysosomotropic and detergent properties of the latter induce LMP, thereby mediating HTC cell death.

Reagents
Unless otherwise indicated, chemicals were from Sigma-Aldrich (Milan, Italy). Human recombinant TNF-␣ was from R Fig. 1. TNF/CHX increase ceramide and sphingosine. HTC cells were exposed (or not) for 6 h to TNF/ CHX. All cells, including fl oating ones, were collected, washed twice with PBS, and then centrifuged. The pellets were lyophilized overnight and then stored at 4°C until LC/MS sphingolipid profi ling was performed. (A) Cellular amount of ceramides with different acyl chains. (B) Relative changes in total ceramide (Cer) and sphingosine (Sph); where indicated, cells were treated with TNF/CHX in the presence or not of 50 µM desipramine (Dpm). Data represent the means ± SD from three independent measurements. *** P < 0.001 versus control cells; § § § P < 0.001 versus TNF/CHX.

Fig. 2.
TNF/CHX and sphingosine, not C 2 -ceramide, induce both LMP and relocation of lysosomal contents in HTC cells. Cells were exposed to 25 µM sphingosine for the indicated times (A), TNF/CHX for 6 h (B), or 50 µM C 2 -cer for 24 h (C), stained for 15 min with 5 µg/ml AO, and analyzed by fl ow cytometry. Cytograms are representative of at least three independent experiments. The fl uorescence peak of control cells was set approximately at 10 3 and retained for all measurements. "Pale" cells, representing cells with fewer than normal intact lysosomes, accumulate to the left of the main peak, just below intensity 10 2 . Quantifi cation of pale cells is shown as bar graphs on the right of each cytogram. (D) For morphological evaluation of lysosomal integrity, HTC cells were exposed to TNF/CHX for 6 h, 25 µM sphingosine for 3 h, or 50 µM C 2 -cer for 24 h as indicated, either loaded with AO (top panels) or fi xed with methanol-acetone , stained with an anti-CB antibody (middle panels), and observed under a fl uorescence microscope. Intact lysosomes appear as a network of fl uorescent discrete dots both in AO and anti-CB-stained cells. LMP abrogates AO punctation of cells and brings about diffusion of CB immunofl uorescence to the whole cell, suggestive of its release from lysosomes to the cytoplasm. Alternatively, cells were transfected with a vector encoding cathepsin B-GFP (bottom panels), which localizes clearly, though not exclusively, to the lysosomes in control cells. TNF/CHX and Sph, but not C 2 -cer, induce LMP that turns CB-GFP fl uorescence from punctate to diffuse, also indicating its lysosomal-cytoplasmic release. Numerical results represent the mean ± SD of at least three independent experiments. ** P < 0.01 and *** P < 0.001, respectively, versus controls; n.s. not signifi cantly different versus control cells. Sph: 25 µM sphingosine ; C 2 -cer: 50 µM C 2 -cer.
N -dodecanoylglucosylsphingosine, and N -dodecanoyl sphingosylphosphorylcholine) to normalize the lipid extraction processes. The analyses were performed on a Waters Aquity UPLC system linked to a Waters LCT Premier orthogonal accelerated-TOF mass spectrometer (Waters, Millford, MA). The analytical LC column was a 100 × 2.1 mm, 1.7 µm C8 Aquity UPLC BEH (Waters), operated with the mobile phases and the gradient conditions as specifi ed in Ref. 27 . For MS-TOF, mass accuracy and reproducibility were ensured using an independent reference spray via LockSpray. The range of linearity was determined by sampling standard sphingolipid mixtures. Identifi cation of the sphingolipid species was achieved by comparison of the mass and LC retention times of signifi cant peaks with relevant standards.

Acridine orange uptake test
Lysosomal membrane permeabilization was assayed with the acridine orange (AO) uptake technique ( 28 ). Following treatments, cells were exposed to AO (5 µg/ml) for 15 min at 37°C in complete growth medium. Both attached and fl oating cells were collected and resuspended in 200 µl PBS. Red AO-induced fl uorescence (from highly concentrated AO in intact lysosomes) was measured by FACS as described above. When appropriate, AO-stained cells were observed under a fl uorescence microscope (see below). Digital images were recorded with an AxioCam CCD camera and composed with Photoshop 7.0 (Adobe Systems Inc., San Jose, CA).

RNA extraction and cDNA synthesis
Total RNA was extracted with the TriPure Isolation Reagent (Roche, Milan, Italy), dissolved in sterile water, and quantifi ed spectrophotometrically. cDNA was synthesized from 1 µg of total RNA with the Reverse Transcription System kit (Promega Italia, Milan, Italy) in a fi nal volume of 20 µl. A volume corresponding to 50 ng of total RNA was used for each amplifi cation reaction.

Western blotting
Cell pellets were sonicated in PBS containing 1% Igepal CA-630, 0.5% sodium deoxycholate, and 0.1% SDS; 20-70 µg of total lysates, as determined with the Bio-Rad Protein Assay Dye Reagent Concentrate (Bio-Rad Laboratories), were incubated for 10 min at 37°C with 20 µg/ml DNase and RNase and resolved on a 10% (a-and nSMase) or 15% (aCDase) PAGE. For aCDase only, resolved proteins were transferred to 0.2 µm Trans-Blot Transfer Medium (Bio-Rad Laboratories) in a buffer containing 25 mM Tris-Cl, 193 mM glycine, 20% methanol, pH 8.3, supplemented with 2 mM CaCl 2 . The membrane was fi xed for 1 h at room temperature with 2.5% glutaraldehyde, washed twice with PBS, and once with 50 mM ethanolamine in PBS. All the membranes were then saturated for 1 h with TBS 0.05% Tween containing 5% milk and incubated overnight at 4°C with the primary antibodies. Blots were washed three times with TBS-Tween and incubated with the appropriate secondary antibody (1:10000, Relative changes in the sphingolipid amount brought about by gene silencing are expressed with respect to cells transfected with control siRNAs and treated with TNF/CHX for 6 h; for these samples, the levels of ceramide and sphingosine were 880.7 and 21.4 pmoles/mg protein, respectively. (D) HTC were transfected as indicated, left untreated or exposed to TNF/CHX for 6 h. Cells from supernatants and monolayers were then collected, pooled, and analyzed for annexin V exposure (dark bars) or pale cells detection (light bars) by FACS. (E) Cells transfected with control or aCDase siRNAs were treated or not with TNF/CHX for 6 h, then stained with either AO (top panels) or anti-CB antibody (bottom panels) as in Fig. 2 and observed under a fl uorescence microscope. Intact lysosomes appear as intensely fl uorescent cytoplasmic or perinuclear dots, whereas those permeabilized by TNF/CHX in mock-silenced cells (NS plus TNF/CHX) are barely detectable on a more intensely fl uorescent cytoplasmic background due to both acridine orange diffuse in the cytoplasm and immunofl uorescence of CB released from lysosomes. Of interest, aCDase silencing restores the punctate pattern of intact lysosomes as evidenced by both AO staining and CB immunofl uorescence. Results are means ± SD of three independent experiments, each assayed in triplicate (A, C, D) or as means of two independent experiments (B). NS: control siRNAs; aSM, nSM, aCD, nCD: acid and neutral sphingomyelinase and ceramidase siRNAs. aSMase, nSMase, aCDase: acid or neutral sphingomyelinase and acid ceramidase. *** P < 0.001 versus nonspecifi c siRNAs (A) or versus cells transfected with nonspecifi c siRNAs and exposed to TNF/CHX (C); ** P < 0.01 versus TNF/CHX plus controls siRNAs (C); *** P < 0.001 versus TNF/CHX plus controls siRNAs for annexin V/PI assay and § § § P < 0.001 versus TNF/CHX plus controls siRNAs for pale cells assay (D) .
Bio-Rad Laboratories). The total amount of protein loaded in each lane was revealed by probing the same blots with an anti-␤ -actin antibody. Chemiluminescent detection of bands was performed with the Western Blotting Luminol Reagent (Santa Cruz Biotechnology). For densitometric analysis, the TotalLab TL100 Analytical software (Nonlinear Dynamics, Ver. 2006c, Newcastle upon Tine, UK) was used.

Microscopy
Cells were observed and photographed in the phase contrast mode under a Nikon Eclipse TS 1000 inverted microscope equipped with a Nikon Coolpix 4500 digital camera. Fluorescence images were captured with an Axiovert 35 inverted fl uorescence microscope equipped with a 40× long distance objective (Carl Zeiss MicroImaging GmbH, Munich, Germany) connected to an AxioCam camera using AxioVision software (Carl Zeiss MicroImaging GmbH) and composed with Photoshop 7.0.

Statistical analysis
If not otherwise indicated, data represent means ± SD from at least three independent experiments, each assayed in triplicate. Differences between groups were analyzed by one-way ANOVA followed by Student-Newman-Keuls post test (Instat, GraphPad, San Diego, CA).

TNF/CHX alter ceramide and sphingosine levels in HTC cells
We previously reported that TNF/CHX-induced death requires a properly functioning lysosomal compartment ( 26 ). As TNF toxicity and the lysosomal compartment are linked to each other by the production of ceramide ( 16 ), the amount of this lipid messenger was screened. LC/MS confi rmed that TNF/CHX increased the cellular concentration of various forms of ceramide, the most abundant being the 16:0 and the 24:0 species ( Fig. 1A ). In addition to ceramides, TNF/CHX also elevated sphingosine ( Fig. 1B ), another sphingolipid known to be increased by TNF to induce cell death ( 21,22 ). These results confi rm that TNF modulates the metabolism of sphingolipids, markedly increasing both ceramides and sphingosine levels. In a previous study, we demonstrated that the toxic action of TNF and ceramide rely on different pathways ( 23 ). We also evidenced that Dpm signifi cantly protects from TNF/CHX toxicity. Because this drug is a known functional inhibitor of the acid sphingomyelinase (aSMase), we investigated whether this protection was secondary to a change in sphingolipid levels. LC/MS evidenced that Dpm, whose specifi city for aSMase is questionable ( 31 ), further enhanced TNF/ CHX-induced ceramide accumulation ( Fig. 1B ), thus strengthening the fi nding that protection afforded by this drug does not depend upon ceramide decrease. In contrast, Dpm almost totally abrogated the TNF/CHX-induced generation of sphingosine, the concentration of which fell to control levels. Therefore, the sphingolipid fl uctuations confi rm that protection by Dpm refl ects its interference with the formation and accumulation of sphingosine, rather than of ceramide, in the acidic compartment.
In conclusion, the results presented demonstrate that TNF/CHX increase both ceramide and sphingosine in the acidic compartment and confi rm our previous fi ndings that ceramide does not mediate TNF/CHX toxicity in HTC cells.

Sphingosine mediates TNF/CHX-induced cytotoxicity by triggering lysosomal membrane permeabilization
The mechanisms by which sphingosine mediates TNF/ CHX-induced toxicity were subsequently analyzed. As sphingosine toxicity has been reported to rely on induction of LMP ( 22 ), occurrence of the latter was next investigated. HTC cells were found sensitive to sphingosine, which determined the onset of the classical signs of LMP, namely, the appearance of a population of cells with a reduced number of intact lysosomes, accounting for the lower intracellular red fl uorescence following exposure to AO ( Fig. 2A ); such cells, whose number increases timedependently, are referred to as "pale" cells ( 28 ). It was then observed that TNF/CHX treatment also raised a clearly defi ned population of pale cells, indicating that LMP occurs in HTC cells treated with the cytokine ( Fig. 2B ). However, no evidence of LMP was found in cells treated with C 2 -cer ( Fig. 2C ), demonstrating that TNF/CHXinduced LMP does not result from intralysosomal ceramide accumulation and thus supporting a role for sphingosine. As a further confi rmation, the integrity of lysosomal compartment of HTC cells treated with TNF/ CHX, sphingosine, or C 2 -cer was evaluated by AO staining and visualization under a fl uorescence microscope ( Fig. 2D , top panels). AO-stained lysosomes were abundant and intact in controls, but they almost vanished in both TNF/ CHX-and sphingosine-treated cells, which is suggestive of low lysosomal dye accumulation due to occurrence of LMP. By contrast, C 2 -cer-treated cells showed extensive AO uptake (also see Fig. 2C ) and no LMP. We subsequently verifi ed whether, in addition to increasing the permeability to small molecules like AO, TNF/CHX-or sphingosine-induced LMP would grant relocation to the cytoplasm of higher molecular weight lysosomal contents. LMP was thus evaluated also by immunofl uorescent detection of subcellular localization of cathepsin B (CB; Fig. 2D , middle panels). In control cells, CB was detected in discrete fl uorescent dots representing intact lysosomes. Both TNF/CHX and Sph, but not C 2 -cer, shifted the punctate fl uorescence of controls to diffuse, rather indicative of CB release from permeabilized lysosomes and of its diffusion to the cytoplasm. In C 2 -cer-treated cells, however, CB immunofl uorescence displayed again as a fi ne cytoplasmic granularity similar to that of control cells. To further support the above fi ndings, HTC cells were transiently transfected with a cathepsin B-GFP (CB-GFP) construct ( Fig. 2D , bottom panels). In control cells, the resulting green fl uorescence predominantly clustered in a number of granules, conferring a punctate pattern characteristic of cells with intact lysosomes. Exposure to TNF/CHX or sphingosine, but not to C 2 -cer, changed this pattern to a diffuse one, indicative of lysosomal-cytoplasmic relocation of CB-GFP. The results thus demonstrate that sphingosine, but not ceramide, induces a LMP that allows relocation of lysosomal contents to the cytoplasm.
Interference with generation of sphingosine protects from TNF/CHX toxicity Next it was investigated whether decreasing lysosomal sphingosine or its precursor ceramide protects from TNF/ CHX. To this aim, siRNAs targeting acid and neutral sphingomyelinase (a-and nSMase) and ceramidase (a-and nCDase) were transfected into HTC cells for 24 h before TNF/CHX treatment. siRNAs reduced the amount of their specifi c mRNA targets by about 75-80% without affecting other transcripts ( Fig. 3A ) and the content of their related proteins by about 60-80% ( Fig. 3B ). Remarkably, in these cells, the nCDase mRNA was undetectable, whereas it was abundantly present in a total rat liver RNA preparation used as a control (not shown). This fi nding thus reveals that nCDase is not present in these hepatoma cells. As expected, silencing changed the sphingolipid levels: both ceramide and sphingosine were markedly reduced by knockdown of aSMase, but they were almost unaffected by silencing nSMase ( Fig. 3C ). aCDase silencing selectively depressed sphingosine, whereas in agreement with the lack of nCDase expression in HTC cells, siRNAs against the latter enzyme did not affect the levels of ceramide or sphingosine, ruling out any activation of the neutral pathway of ceramide breakdown following TNF/CHX treatment.
To verify the effects of the sphingolipid modulation on TNF/CHX toxicity, silenced cells were exposed for 6 h to the cytokine and then analyzed for annexin V-binding and LMP. Although exposure to neither control nor specifi c siRNAs was intrinsically toxic, knockdown of the acidic SMase and CDase signifi cantly reduced both PS externalization and the appearance of pale cells ( Fig. 3D ). aCDase silencing also increased the morphological integrity of lysosomal compartment, as demonstrated by both the restored AO uptake ( Fig. 3E , upper panels) and the reversion to a punctate pattern of CB immunofl uorescence ( Fig. 3E , lower panels), as a consequence of attenuation of TNF/CHX-induced LMP. These results thus demonstrate that preventing the formation of sphingosine in the lysosomal compartment markedly attenuates LMP and TNF/ CHX-induced death.
We subsequently investigated whether these observed lysosomal mechanisms are peculiar to HTC cells or may also occur in other hepatoma cells of human origin, such as the SK-HEP-1, Hep G2, and Huh7 lines. SK-HEP-1 cells, in particular, exhibited pronounced LMP (about 30% of total cell population; see histograms in Fig. 4A , right) and lysosomal alterations following TNF/CHX treatment for 24 h ( Fig. 4A , cytogram and inserts). This effect, although not signifi cantly modifi ed by control siRNAs ( Fig. 4B , plus inserts and histograms), was prevented by siRNAs targeting aCDase ( Fig. 4C , plus inserts and histograms), which reduced the aCDase protein by about 60% ( Fig. 4D ). As a further confi rmation, aCDase-specifi c siRNAs, yet not the scrambled ones, effectively reverted the cytoplasmic CB relocation brought about by TNF/CHX, as evidenced by immunofl uorescence analysis of its subcellular localization ( Fig. 4E ). Eventually, aCDase silencing strikingly attenuated death of SK-HEP-1 cells, as demonstrated by the reduced number of annexin V-positive cells determined by TNF/CHX. This fi nding, in particular, demonstrates that LMP and ensuing PCD brought about by TNF-induced sphingosine generation in the acidic compartment is of physiological relevance, rather than a general response to amphiphilic compounds. LMP was also observed in both Hep G2 and Huh7 cell lines, yet it was not signifi cantly modifi ed by aCDase silencing (not shown), thus refl ecting the heterogeneity of hepatoma cells responses to deathinducing agents.

DISCUSSION
TNF is one of the most powerful known inducers of apoptosis and active on a variety of malignant cells. Its cytotoxicity depends on binding to a cell surface death receptor (TNFRI), which triggers a plethora of intracellular events culminating into canonical caspase-dependent apoptosis ( 8 ) or even caspase-independent, but still apoptotic-like, death ( 32,33 ). As reported previously ( 26 ), in HTC hepatoma cells, TNF/CHX trigger an apoptotic-like death that requires the participation of lysosomes. Lysosomes have been postulated to partake in TNF-induced PCD by a variety of mechanisms, including production of ceramide and/or other sphingolipids ( 16 ). The present results show that exposure of HTC cells to TNF/CHX markedly increases levels of ceramide and sphingosine, the latter mainly by activation of the acidic pathway of ceramide breakdown, in agreement with results from other research groups ( 25,(34)(35)(36). We previously demonstrated that, in these cells, ceramide-induced death takes place with characteristics totally different from those typical of TNF/CHX ( 23 ), thus raising concern about the actual role of ceramide in cellular death. It has been proposed, in fact, that intralysosomally generated ceramide could promote the relocation to the cytoplasm of cathepsins, B ( 14 ) and D ( 16 ) in particular, eventually resulting in Bid cleavage and activation of the mitochondrial death pathway. In addition, ceramide has been reported to activate caspase-independent death pathways ( 37 ). By contrast, other evidences strongly argue against these views ( 21,22,38 ) and demonstrate that ceramide per se neither is intrinsically cytotoxic nor sensitizes cells to death. Cells genetically defi cient of aCDase accumulate high levels of ceramide, yet are neither more prone to spontaneous death nor more susceptible to various stress-inducing agents than normal cells ( 39 ). These cells, however, display a higher sensitivity toward receptor-mediated death, a fi nding so far ascribed to plasma membrane ceramide that would affect raft formation ( 40 ), thereby altering death receptor clustering and signal generation or transduction ( 41 ). Hence, the present observation that TNF/CHXinduced ceramide does not directly account for death in our system is consistent with previous results from our as well as other research groups. In addition, the fi nding that Dpm further increases ceramide above the levels attained with TNF/CHX, yet protects against its toxicity, demonstrates that even a large increase of ceramide has no direct damaging effects. Our results point out that C 2 -cer does not elicit LMP, which is, however, triggered by TNF/CHX or exogenous sphingosine, and totally agree with previous reports in which the lysosome-permeabilizing and deathinducing capability of sphingosine was evidenced ( 22 ). Further supporting the privileged role of sphingosine in mediating TNF/CHX toxicity is an earlier fi nding that only TNF/actinomycin D or sphingosine, although not C 6ceramide, induces LMP in hepatocytes or purifi ed lysosomes obtained from normal, but not from cathepsin B Ϫ / Ϫ , mice ( 21 ). Hence, in our hands, neither treatment with exogenous analogs nor intralysosomal accumulation of endogenous ceramide directly promotes LMP. Importantly, we provide, to the best of our knowledge, the fi rst direct demonstration that TNF/CHX-induced LMP is accounted for by sphingosine generated inside the lysosomal compartment following exposure to TNF/CHX. The present observation that TNF/CHX elicit LMP in both rat and human hepatoma cell lines indicates that LMP is not an uncommon response to TNF toxicity and may potentially represent a unifying effector mechanism for TNF and possibly other cytotoxic agents ( 21,42 ). On the other hand, a role for ceramide cannot be totally ruled out when it comes to other death models, such as those based on antiblastic agents, such as daunorubicin, vinblastine, and doxorubicin, in hepatoma cells of various origin ( 43 ). Death triggered by these cytostatics was shown to be mediated by mitochondria, in which a damaging effect of both endogenous and synthetic analogs of ceramide(s) has been described ( 44 ). In the present article, silencing-dependent reduction of the enhanced levels of sphingosine induced by TNF/CHX abrogates the occurrence of LMP and, partly, of cell death. RNA interference confi rmed that the acidic pathway of ceramide breakdown accounts for lysosomal sphingosine accumulation, LMP, and TNF toxicity in both HTC and SK-HEP-1, although not in Hep G2 and Huh7 cells. However, the precise roles of the sphingolipids in determining death or survival in normal and cancer cells are far from being fully elucidated; in particular, information is lacking about the fi ne mechanisms by which TNF affects sphingolipid metabolism. Although beyond the aims of the present investigation, it is worth noting that phosphorylation inhibitors such as genistein suppress the IL-1 ␤ -induced activation of aCDase ( 45 ). As TNF is known to alter the phosphorylation status of many proteins, the possibility that aCDase as well as other enzymes of this metabolic pathway are similarly regulated by the cytokine cannot be excluded.
In agreement with old observations ( 19 ), our data give prominence to the fact that the acidic compartment is one of the main targets of TNF in hepatoma cells and demonstrate that TNF-induced sphingosine, although not ceramide, accounts for LMP and toxicity in rat and human hepatoma cells ( 19,21 ). Here we show that LMP allows the relocation of lysosomal cathepsins, both endogenous CB and a transfected CB-GFP chimera, to the cytoplasm of TNF/CHX-treated cells, thus outlining a potential role for these acidic proteases in TNF-induced death. In fact, it has been evidenced that cathepsins S and H also retain some activity at nearly neutral pH ( 46 ) and are thus capable of degrading substrates in the cytoplasm. However, additional studies are required for a full understanding of the role of LMP in TNF/CHX toxicity on hepatoma cells.
In conclusion, here we show that exposure of HTC cells to TNF/CHX subverts sphingolipid metabolism and brings about the generation of large amounts of ceramide and sphingosine inside the lysosomes. Ceramide, even at high concentrations, does not account for the lethal action and any of the relevant effects of TNF/CHX. The latter, by contrast, can be fully ascribed to the intralysosomal conversion of ceramide into sphingosine, which in turn is responsible for LMP and ensuing cellular death.