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Induction of Lymphocyte Apoptosis by Tumor Cell Secretion of FasL-bearing Microvesicles
2 Unit of Preclinical Chemotherapy and Pharmacology, Istituto Nazionale dei Tumori, Milan 20133, Italy
3 Unit of Immunotherapy and Gene Therapy, Istituto Nazionale dei Tumori, Milan 20133, Italy
4 Laboratory of Immunology, Istituto Superiore di Sanità, Rome 00161, Italy
5 Ultrastructures, Istituto Superiore di Sanità, Rome 00161, Italy
6 Virology Section, Department of Experimental Medicine and Pathology, University of Rome "La Sapienza", Rome 00161, Italy
Address correspondence to Licia Rivoltini, Unit of Immunotherapy of Human Tumors, Istituto Nazionale dei Tumori, Via Venezian 1, 20133 Milan, Italy. Phone: 39-02-2390-3245; Fax: 30-02-2390-2630; E-mail: rivoltini{at}istitutotumori.mi.it
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Key Words: melanoma • apoptosis • T cells • melanosome • microvesicles
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One of the strategies of tumor immune escape is represented by the acquisition of FasL expression that may enable cancer cells to deliver death signals to activated Fas-positive T lymphocytes (2, 3). FasL is a transmembrane type II protein belonging to the TNF protein superfamily, that plays a pivotal role in the induction of receptor (Fas)-mediated apoptosis. In fact, Fas–FasL interaction regulates important immune functions such as downmodulation of immunological responses, T cell activation–induced cell death, clonal downsizing, and control of peripheral tolerance to self-antigens (4). Apart from immunocompetent cells, FasL expression is additionally well documented in organs such as eye, central nervous system, and testis where it is thought to contribute to the maintenance of these immune privileged sites (4). Due to the functional properties of this molecule, it has been thus hypothesized that tumor cells could take advantage of FasL expression for mediating apoptosis of antitumor-activated T cells. Many authors have indeed shown that tumor cells of different histotypes (melanoma, colon, breast, esophageal cancers) do acquire FasL expression as detected both in vivo and in vitro (3). Additionally, such expression has been reported to negatively correlate with patient prognosis when evaluated on breast, ovarian, liver cancers, and melanoma specimens (3, 5, 6).
Although intriguing, this hypothesis is currently under evaluation, animating a debate based on controversial issues, such as the specificity of the different antibodies available for FasL detection or the usage of nonintron spanning primers for FasL detection by RT-PCR. The presence of infiltrating FasL-positive lymphocytes in tumor lesions has been additionally hypothesized to interfere with ex vivo FasL staining (7–10).
However, the recent use of specific reagents for the detection of FasL has indeed confirmed the expression of FasL in some tumor cell types (9, 11). Moreover, the concomitant presence of apoptotic T cells in FasL-expressing tumors (12, 13) and the negative prognostic role of FasL expression by neoplastic cells (5, 6, 14) suggest a potential efficacy of tumor counterattack in influencing in vivo tumor progression.
A relevant mechanism of FasL trafficking, occurring in NK cells and CTL, has been recently reported as involving specific intracellular transport of FasL on lysosomal-like vesicles that are unidirectionally polarized on the membrane of NK and T cells (15, 16) and a mechanism based on the release of FasL-bearing microvesicles (MVs)* has been also described to occur in FasL transfected cells (17). Indeed, melanoma cells contain specialized granules (melanosomes), which are the site of synthesis and storage of melanin and related molecules. These organelles have been clearly demonstrated to share phenotypic and functional features with lysosome vesicles and lytic granules (18). Additionally, a secretory pathway has been described in melanoma cells that involves multivesicular bodies (MVB) containing MVs which express tumor antigens such as MART-1 and tyrosinase (19). The physiologic fate of these vesicles is to be injected by melanocytes into keratinocytes in order to transfer melanin pigments.
On the basis of these data, we have reevaluated the role of FasL in tumor immune escape, taking into account the possibility that melanoma cells may share FasL expression pathway and intracellular trafficking with immunocompetent cells. Expression of FasL in melanoma cells was thus studied by investigating FasL localization in cytoplasmic organelles of various human melanoma cell lines and its possible implication in the counterattack of melanoma against immune cells. Here we report that melanoma cells do express FasL intracellularly, with a localization confined to MVB that contains melanosomes. FasL-bearing MVs can be released extracellularly, retaining their FasL expression and proapoptotic activity on Fas-sensitive lymphoid cells.
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ß; Becton Dickinson), followed by the FITC-conjugated anti–mouse IgG, was used as negative control. Melanosomes and MVs were resuspended in 0.1 µ-filtered PBS (100 µl per sample) and primary mAb were added at a concentration of 10–30 µg/ml. After 1 h at 4°C, samples were then incubated with FITC-conjugated anti–mouse IgG (10 µg/ml) for 30 min at 4°C. Labeled melanosome and microvesicle suspensions were then diluted to 300 µl with filtered PBS and samples were analyzed by FACSCaliburTM and CELLQuestTM software. Melanosomes were detected as granules of the approximate mean size of 1 µm, while MVs had a size range of 100–600 nm, relative to standard beads of 6 µm size (CaliBRITE beads; Becton Dickinson).
Immunocytochemistry.
Human melanoma cells were attached to poly-L-lysine-covered glass chamber slides (Labtek) or spun onto glass slides (Shandon), as appropriate, fixed with 70% ethanol (EtOH) 10 min at 4°C, and stained by immunocytochemistry for anti-FasL (clones G247 and NOK-1) using the alkaline phosphatase anti-alkaline phosphatase (Dako) method or the peroxidase-anti-peroxidase (PAP) (Dako) method, in single and double staining, as appropriate (21). In single staining, cells were counterstained with Mayer's haematoxylin.
Electron and Immunoelectron Microscopy.
For transmission electron microscopy, melanoma cells, fixed with 2.5% glutaraldehyde, and postfixed in 1% OsO4, were dehydrated in alcohol and embedded in epoxy resin. For immunoelectron microscopy cells were fixed, after two washes in 0.1 M cacodylate buffer, with 3% paraformaldehyde in 0.1 M cacodylate buffer for 2 h. Then, they were embedded in 2% agar Noble in H2O, at 37°C. For subsequent embedding, the samples were dehydrated with increasing concentrations of EtOH. Infiltration of the samples was performed with increasing concentrations of Lowicryl HM20 resin (Taab) in 100% EtOH and finally in pure Lowicryl. The polymerization was performed in beem capsules by indirect UV irradiation (360 nm) at 4°C. For FasL immunolocalization in postembedding procedure, thin sections, collected on gold grids, were treated for 5 min with PBS containing 0.15% (wt/vol) glycin. After washing by quickly floating the grids on PBS drops containing 0.1% (wt/vol) BSA (Sigma-Aldrich), the sections were incubated overnight at 4°C with mAb G247 (1:10 diluted). After washing by floating the grids on PBS drops containing 0.1% (wt/vol) BSA for 1 h at room temperature, the sections were preincubated with PBS 0.1% (wt/vol) BSA for 10 min, washed in PBS containing 0.1% (wt/vol) BSA, and then labeled with a goat anti–mouse IgG 10-nm gold conjugate (1:10 diluted; Sigma-Aldrich) for 20 min, then washed in PBS containing 0.1% BSA for 20 min at room temperature. As negative control, sections were incubated with an irrelevant isotype-matched mAb or with a goat anti–mouse IgG gold alone.
For ultrathin cryosections cells were fixed with 4% paraformaldehyde plus 0.1% glutaraldehyde in PBS, pH 7.4, for 2 h at 4°C, washed, and embedded in 2% agarose low melting point (LMP) that was solidified on ice. Agarose blocks were infused with 2.3 M sucrose in PBS for 3 h at 4°C, frozen in LN2, and cryosectioned following the method by K.T. Tokuyasu (22), as described previously (23). Ultrathin cryosections were collected using sucrose and methyl-cellulose and incubated with specific mAb, then revealed with protein A-gold conjugates of different size (10 or 20 nm, as appropriate). Finally, ultrathin cryosections were stained with the solutions of 2% methylcellulose and 0.4% uranyl acetate before EM examination.
For electron microscopy of the isolated microvescicles, droplets of RPMI 1640 with suspended membranes from 70,000 g pellets were fixed with 2% paraformaldehyde in PBS and put on thin carbon film-coated grids for TEM observation and air-dried. FasL labeling was performed by the immunonegative stain technique. Briefly, the grids were incubated at 4°C overnight with the anti–human FasL mAb, G247, diluted 1:10, in PBS containing 1.0% BSA (Sigma-Aldrich). After washing with PBS, the grids were incubated with anti–mouse IgG-gold conjugate (Sigma-Aldrich; average diameter of gold particles 5 nm), and diluted 1:10 in PBS at room temperature for 1 h. Negative controls were performed by incubating samples with anti–mouse IgG2a or with immunoconjugate alone (data not shown). After washing with PBS, grids were negatively stained with 2.0% aqueous phosphotungstic acid for 2 min. Samples were examined with a Philips 208 transmission electron microscope (FEI Company).
Immunoprecipitation.
Adherent melanoma cells (106) were surface-labeled with sulfo-N-hydroxysuccinimide-biotin according to the manufacturer's instructions (Amersham Pharmacia Biotech). After extensive washing, the cells were lysed with lysing buffer (1% Triton X-100, 150 mM NaCl, 1 mM Tris-HCl, 1 mM EDTA, 1 mM EGTA, 1 mM PMSF, 10 µg/ml aprotinin, 10 µg/ml leupeptin, and 30 µg/ml KB8301).
Proteins corresponding to 106 cells equivalent were used for each specific immunoprecipitation. After preclearing with control mouse IgG, the supernatant was specifically immunoprecipitated using 2 µg/ml of NOK-1, G247 (BD PharMingen), W6.32 (an anti–HLA-class I monomorphic determinant), or control mouse IgG1. After washing with lysing buffer, the eluates were subjected to SDS-PAGE and electroblotted. The membrane was then incubated with strepavidin-HPR and developed with ECL detection system (Amersham Pharmacia Biotech).
Supernatants, Total Cell Lysates, Cytoplasmic-enriched Preparations and Isolation of Melanosomes, and MVs.
Supernatants from melanoma cell lines were harvested from 72 h confluent melanoma cell cultures, concentrated with centrifuge filter devices, Centricon (Millipore), with a cut off of 50 kD to enrich for soluble molecules <50 kD, aliquoted, and stored at -80°C. Jurkat cells (4 x 105 cells per milliliter) were stimulated with 50 µg/ml PHA for 5 min; after PHA removal by centrifugation and washing, they were resuspended in complete medium and cultured at 37°C for 1 h (16). Supernatants from resting or activated cells were collected, concentrated, and stored as described previously.
Total cell lysates were obtained lysing cells by an hypotonic solution (10 mM hepes, pH 6.9, 10 mM KCl, 0.3% aprotinin, and 0.1 mM PMSF), extensively homogenizing using a Potter-Elvehjem homogenizer and centrifuging the suspension for 10 min at 600 g. Total cell lysates were obtained from confluent melanoma cell cultures or from Jurkat cells, activated as described previously. Cytoplasm-enriched preparations were prepared by differential centrifugation starting from the homogenate. After 3 min at 1,000 g at 4°C, the supernatant containing cytoplasma, cytoskeleton and membrane fractions was centrifuged at 11,000 g for 30 min at 4°C in order to separate the cytoplasma (supernatant) from cell surface membranes and cytoskeleton (pellet).
Isolation of melanosomes was performed as described previously (24). Briefly, the homogenate from 109 melanoma cells resuspended in a solution of 0.25 M sucrose, underwent serial centrifugations (600 g for 10 min x 2; 11,000 g for 10 min x 2). The sediment was then suspended in 0.25 M sucrose. The suspension was layered over 1.7 M sucrose and centrifuged at 37,000 g for 1 h using the swing-out SW 41 rotor of the Beckman ultracentrifuge (Beckman Coulter). The sediment was suspended in 0.25 M sucrose, layered over 2.0 M sucrose, and centrifuged again at 37,000 g for 1 h. The obtained sediment contained isolated melanosomes.
Microvesicles from melanoma and resting/PHA-activated Jurkat cells were separated according to Martinez-Lorenzo et al. (16). After centrifugation at 10,000 g for 30 min at 4°C, the obtained supernatant was further ultracentrifugated at 100,000 g for 18 h at 4°C. The pellet, containing isolated MVs, was then resuspended in appropriate medium according to following treatments. Quantification of total proteins contained in melanosome or microvesicle preparations was evaluated by Lowry assay (Bio-Rad Laboratories) on organelle lysates. The mean protein recovery was 0.98 mg (range 0.28–1.7) for melanosomes, and 0.75 mg (range 0.31–1.2) for exosome-derived vesicles.
Western Blot Analysis.
Supernatants, total cell lysates, and subcellular fractions (cytoplasma, melanosomes, and microvesicles) from melanoma and Jurkat cells were analyzed for FasL protein expression by Western blot analysis. Isolated melanosomes and microvesicles were resuspended in lysis buffer (1% Triton X-100, 0.1% SDS in 0.1 M Tris/HCL, pH 7) with the addition of the 10 µM matrix metalloproteinase inhibitor KB8301 (BD PharMingen). After protein determination using the Lowry assay (Bio-Rad Laboratories), 75 µg of total protein of the different preparations were boiled for 6 min in SDS sample buffer containing ß-mercaptoethanol, separated on a 10% SDS-PAGE, and then electroblotted onto a PVDF membrane. As a positive control 1 ng of rFasL (Alexis) was used. The membrane was stained using 2 µg/ml anti–human FasL mAb G247, developed with a secondary mouse anti–human IgG conjugated to horseradish peroxidase (BD Transduction Laboratories), and detected by SuperSignal detection system (Pierce Chemical Co.).
To further check purity of melanosome and microvesicle preparations, the following additional molecules were analyzed in Western blot analysis under reducing conditions: gp100 (on a 15% SDS-PAGE gel) protein; and markers specific for endoplastic reticulum, Golgi, mitochondria, and plasma membrane. The following mAb were used: anti–human gp100/pmel17 (clone HMB45; Dako); BiP/GRP78 (BD Transduction Laboratories); GM130 (BD Transduction Laboratories); mitochondria (clone MAB1273; Chemicon International, Inc.); HLA-class I (L31; provided by P. Giacomini, Istituto Regina Elena, Rome, Italy); and anti–caveolin-1 (Santa Cruz Biotechnology, Inc.).
To exclude any possible contamination, isolated microvesicles from FBS and from RPMI supplemented with 10% FBS were also analyzed for FasL expression in Western blot analysis, but the protein was never detected (data not shown).
Analysis of Apoptotic Activity.
Quantitative assessment of apoptosis was performed by cytofluorimetric analysis of propidium iodide (PI)-stained cells as described previously (25) with minor modifications and by annexin V binding assay. The occurrence of apoptosis was also monitored by Western blot analysis of caspase-8 activation. Briefly, Jurkat cells (106 cells per milliliter) were seeded in 24-well plates in 10% FBS RPMI 1640. rFasL at the concentration of 50–100 ng/ml or different concentrations of melanosomes or microvesicles were added. For assessing Fas-involvement, cells were preincubated for 30 min at 42°C with different concentrations of anti-Fas mAb (ZB4; Upstate BioTechnology). Apoptosis was analyzed after 15–18-h incubation. For analysis of PI-staining, PBS-washed cells were suspended in hypotonic solution containing 10 µg/ml PI, 0.1% sodium citrate, 0.1% Triton X-100, and RNase A (66 U/ml), and incubated 4 h at 4°C. The red fluorescence of individual nuclei was measured with a FACSCaliburTM flow cytometer (Becton Dickinson). Annexin V binding was measured using the Annexin V-Biotin Apoptosis Detection kit (Oncogene Research Products) according to manufacturer's instructions. After the final incubation in binding buffer containing FITC-streptavidin (Amersham Pharmacia Biotech) and PI (0.6 µg/ml), cells were incubated on ice and immediately analyzed by flow cytometry. Caspase-8 activation was monitored by the appearance of the activated form of 40 kD, using Western blot analysis. Proteins were separated on SDS-PAGE and immunoblotted. The nitrocellulose membrane was then incubated overnight at 4°C with a polyclonal Ab to caspase-8 (BD PharMingen). A rabbit antiactin Ab was used as control for loading. Ab binding was detected by enhanced chemiluminescence (Amersham Pharmacia Biotech).
For detecting lymphocyte FasL-mediated apoptosis induced by tumor cells, melanoma cells (at 105 cells per well, in U-bottomed 96-well plates) were cultured in 10% FBS RPMI 1640 for 2 h at 37°C, for allowing cell adhesion. 51[Cr]-labeled Jurkat cells (at 103 cells per well), in the presence or absence of neutralizing anti-Fas mAb ZB4 (50 ng/ml), were then added as target cells and the plates were incubated for 16 h 0.50 µl per well of supernatant were harvested, counted, and killing was calculated as percentage of lysis (26). Comparable results were obtained using targets labeled with 3[H]-TdR or 125IdU (data not shown). Melanoma supernatant was harvested from 72 h confluent melanoma cell cultures, concentrated with centrifuge filter devices, Centricon (Millipore), with a cut off of 50 kD to enrich for soluble molecules <50 kD, aliquoted, and stored at -80°C. Different dilutions of supernatant (starting from 1:2) were added to the cytotoxic assay. rFasL (at 100 ng/ml) was also used as positive control.
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Altogether, these data strongly indicate that the expression of FasL molecules in these tumor cells is mostly confined to the intracellular compartment.
Immunoelectron microscopy analysis was used to further investigate FasL subcellular localization in human melanoma cells. The results showed that FasL immunolabeling was clearly confined to MVB (Fig. 4 A), specialized cellular compartments displaying internal membrane-bound vesicles (29). Within the MVB, FasL was expressed by vesicles that contain melanin in various stages of maturation (Fig. 4 B), suggesting the melanosomal origin of these structures. With the aim of further evaluating the nature of the FasL-expressing vesicles, we performed double-labeling experiments on cryosectioned cells. The results showed that FasL positive vesicles coexpressed both markers of lysosomes (i.e., CD63) and melanosomes (i.e., gp100). Fig. 4 C shows that MVB of melanoma cells are double labeled for FasL and CD63, while Fig. 4 D reports both coexpression of FasL and gp100 by MVB and the absence of staining in other vesicular structures, such as endoplasmic reticulum (ER). Figs. 4 E shows a colocalization of CD63 and gp100 in MVB, that was consistent with the costaining of FasL with either CD63 or gp100. Fig. 4 F is a higher magnification of a MVB showing the staining for FasL and gp100 in this structure. This set of results strongly indicates that FasL is localized in MVs coexpressing lysosome and melanosome markers and that its expression can be detected in MVB of melanoma cells.
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Then, we performed experiments aimed at evaluating the functional role of FasL expressed in melanosomes. To investigate the possible proapoptotic activity of melanoma-derived melanosomes, purified preparations were tested for induction of Fas-mediated apoptosis in FasL-sensitive Jurkat cells. Indeed, melanosomes induced significant and dose-dependent apoptosis of Jurkat cells, as detected by cytofluorimetric analysis with propidium and annexin staining (Fig. 6 A). The observed apoptosis was indeed FasL-mediated, since it could be significantly inhibited by preincubation of target cells with different concentrations of the anti-Fas mAb ZB4 (Fig. 6 A and B). ZB4-mediated inhibition of apoptosis appeared to be more effective with rFasL as compared with melanosomes, suggesting the presence in melanosome preparations of a higher concentration either of bioactive FasL or bystander proteins, possibly impairing Ab binding efficiency. In any case, these results provide evidence for the presence of functionally active FasL molecules in melanosomes derived from melanoma cells.
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Analysis of MVs isolated from melanoma cell supernatant, as performed by Western blot, showed that FasL was indeed detectable (Fig. 9
A, lanes 4, 6, and 7) in such preparations, with an 
35-kD band, highly resembling the one observed in MVs from PHA-activated Jurkat cells (Fig. 9 A, lane 2).
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On particulate, ultracentrifugable fractions from melanoma cell supernatants we additionally performed FACS® analysis, which confirmed the presence of MVs (with a diameter 
100 nm) expressing FasL, in addition to melanosomal and lysosomal antigens (gp100, LAMP-2, and CD63) (Fig. 9 C).
Experiments were finally performed to assess the proapoptotic activity of the MVs by exploiting the same approach used for melanosomes. The results clearly showed that purified MVs from melanoma cells expressed bioactive FasL and induced ZB4-blockable, thus Fas-mediated apoptosis of Jurkat cells, as detected by propidium and annexin staining (Fig. 10 A). However, the observed apoptosis was significantly lower than that mediated by MVs derived from PHA-activated Jurkat cell supernatants, suggesting a less efficient activity in melanoma as compared with immune competent cells. Specificity of Jurkat apoptosis induced by melanoma-derived MVs was further confirmed by the dose-dependent inhibition obtained in the presence of the anti-Fas mAb ZB4 (Fig. 10 B). An additional evidence for the induction of a specific apoptotic pathway was provided by the analysis of caspase-8 activation, that showed the appearance of the cleaved activated form of 40 kD after incubation with both melanoma-derived MVs and isolated melanosomes, undetectable though when Jurkat cells were pretreated with ZB4 (Fig. 10 C).
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The expression of FasL in lysosome-related vesicles or other secretory granules has been indeed reported as a feature of immunocompetent cells (15, 16). However, the MVB of melanoma cells showed some peculiarities, such as the presence of melanosome-like electrondense vesicles, secreted in the extracellular environment as FasL-positive vesicles detectable by both immunocytochemistry and immunoelectron microscopy. Microvescicles can be separated from melanoma cell culture supernatant and are able to trigger Fas-mediated apoptosis of sensitive human lymphoid target cells. Notably, these MVs displayed lysosomal features in terms of expression of lysosomal antigens such as CD63 and LAMP-2 and showed morphological features similar to those described in immunocompetent cells (15, 16). On the basis of our data, we cannot rule out the possibility that vesicles of a size inferior to the detection limit of cytofluorimetric analysis (presently classified as ‘exosomes’) could be also present in our melanoma supernatants. In fact, the evidence of MVB formation in melanoma cells, together with the information from immunoelectron microscopy on supernatant ultracentrifugates, suggest that exosome-like particles, known to be released by melanoma cells (19) and by other cell types (29, 31), may contribute to the phenomenon of microvesicle-induced FasL-mediated apoptosis here described.
The release of membrane-associated FasL through secretion of intracellular organelles represents an effective mechanism for mediating apoptosis, given the higher efficiency in triggering Fas-mediated apoptosis of membrane-linked FasL as compared with its soluble form (32) and the evidence that conversion of membrane FasL to its soluble form leads to downregulation of the proapoptotic activity (33). A vectorial transport of FasL has been recently described on lysosomal-like vesicles in NK and T cells (15, 16). On the basis of these data it has been hypothesized that this targeting of FasL to the secretory lysosomes is specific to cells of hematopoietic lineage, as a sort of tight regulatory mechanism of FasL expression in cells that are committed to kill target cells through the Fas-mediated pathway (15). This is further supported by studies showing that FasL is stored in the secretory granules of monocytes (34). However, it is well known that melanosomes, as well as lytic granules of NK cells and phagosomes, belong to the family of the lysosomal-like organelles, expressing the same lysosomal-associated antigens (18). We describe here FasL-expressing melanosome-like organelles secreted by human melanoma cells as vesicles able to deliver a Fas-mediated cell death to Fas-sensible lymphoblastoid cells. These data suggest that melanoma cells may share with NK cells, and probably with monocytes, (i) a similar pathway of FasL targeting to lysosomal-like particles and (ii) a similar secretory pathway of these particles mediating a Fas-mediated cell death that does not necessarily imply a cell-to-cell contact. It seems hence conceivable that secretion of FasL-expressing MVs can be a more efficient mechanism in inducing apoptosis of Fas-expressing cells, and that this mechanism may well operate in physiologic (NK, CTL, monocytes, dendritic cells) as well as in aberrant (tumor cells) conditions. In fact, it has been suggested that the cytoplasmic tail of FasL expressed in hematopoietic cells contains a sorting motif that targets the protein to secretory lysosomes. Additionally, this specialized motif appears to be shared by other members of the TNF family (e.g., CD40L; reference 35). On the basis of these considerations it has been further speculated that the accumulation of proteins in the secretory lysosomes may represent a generalized mechanism for the control of the release of proteins involved in the regulation of the immune response. Since tumor cells may lack such type of tight control, it is thus conceivable that melanoma cells could mediate a continuous release and/or degranulation of FasL-bearing vesicles that indiscriminately kill all the Fas-sensible cells encountered in the extracellular environment. This phenomenon would have no consequences on melanoma cells, being these cells insensitive to Fas triggering, and therefore refractory to the autocrine FasL-vesicles-induced cell death (26, 36, 37). On the basis of our data, it is still unclear whether the induction of lymphocyte death by FasL-bearing MVs could be a specific feature of melanoma cells or it could be shared by other tumors. In fact, although in some histological types (e.g., colon carcinoma) this molecule has been located exclusively in the cytoplasm, other tumors, such as squamous cell carcinoma, have been clearly shown to stably express FasL at the plasma membrane level (11).
Our data support the relevance of FasL-mediated apoptosis in tumor evasion from immunological control. Other mechanisms can play a significant role in reducing the in vivo efficacy of CTL response to melanoma antigens (1) and antitumor T cell subpopulations resistant to FasL-induced apoptosis have been identified at least in vitro (26). However, this functional pathway of inducing lymphocyte apoptosis through the release of FasL-positive MVs may indeed play a significant role in eliminating the most effective component of the antitumor T cell response in vivo.
While we cannot rule out the possibility that FasL-bearing granules could instead deliver proinflammatory signals, as indeed described in other experimental systems (38, 39), it is likely, given the natural history of neoplastic disease, that this mechanism may contribute in tilting the balance toward an immunosuppressive environment at tumor site. Thus, we believe that future studies aimed at understanding the mechanism responsible for this phenomenon, together with the identification of therapeutical strategies for specifically inhibiting tumor exocytosis, could contribute to ameliorate immunological control of tumor growth in cancer patients.
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This work was supported by grants from AIRC (Associazione Italiana per la Ricerca sul Cancro), Milano, Italy and from the Italian Ministry of Health, Rome, Italy.
Submitted: September 21, 2001
Revised: March 7, 2002
Accepted: April 5, 2002
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* Abbreviations used in this paper: ER, endoplasmic reticulum; EtOH, ethanol; LAMP, lysosome-associated membrane protein; MVB, multivesicular bodies; MV, microvesicle; PAP, peroxidase-anti-peroxidase; PI, propidium iodide.
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