Proteomic analysis of exosomes derived from human lymphoma cells.

BACKGROUND: Exosomes secreted by tumor cells contain specific antigens that may have immunotherapeutic purposes. The aim of this study was to characterize the proteomic content of lymphoma cell-derived exosomes (LCEXs).
METHODS: In this study, exosomes derived from Raji cells (EXO(Raji)) were purified and proteins of EXO(Raji) were separated by one-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. Protein bands were identified by mass spectrometry. The protein components of EXO(Raji) were analyzed using shotgun technology, and the function proteins of EXO(Raji) were defined and described using the Gene Ontology (GO) database and Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis.
RESULTS: A total of 197 proteins were identified in EXO(Raji); 139 proteins were also identified in Raji cells, showing an overlap of 70.56% of the total proteins in EXO(Raji). Interestingly, the remaining 58 proteins were unique to EXO(Raji). The GO database and KEGG were used to define and describe the function of proteins. The data showed that some important proteins involved in antigen procession and presentation as well as cell migration and adhesion were also identified in EXO(Raji), such as MHC-I and II, HSC70, HSP90, and ICMA-1.
CONCLUSIONS: LCEXs express a discrete set of proteins involved in antigen presentation and cell migration and adhesion, suggesting that LCEXs play an important role in the regulation of immunity and interaction between lymphoma cells and their microenvironment. LCEXs harbor most of the proteins of lymphoma cells and could be one of the sources of lymphoma-associated antigens for immunotherapeutic purposes.

Background

Tumor cells can release exosomes. Exosomes are a type of vesicle secreted by late endosomes in eukaryotic cells and loaded with cell membrane molecules, microRNAs, and proteins [1-4]. Studies on the protein composition of exosomes of dendritic cells (DCs) showed that loaded proteins are mainly involved in regulation of cell physiological activities [5-7]. Moreover, molecules involved in antigen presentation such as major histocompatibility complex (MHC)-I and MHC-II have also been detectable in DC-derived exosomes (DEXs) [6,7].

Although DEXs can induce antigen-specific antitumor immunity, the biological characteristics of tumor cell-derived exosomes (TEXs), especially those from lymphoma cells, remain unclear. Our previous studies and others revealed that DEXs and TEXs can be taken up by DCs and transfer tumor antigens to DCs in vitro and that TEX-targeted DCs can induce stronger antigen-specific antitumor immunity than TEXs alone [5,8-10]. These studies collectively suggest that TEXs harbor tumor antigens and are potential targets in the development of effective antitumor vaccines [11,12].

Burkitt lymphoma (BL) is a highly aggressive B-cell lymphoma with an extremely short cell doubling time and usually presents in extranodal sites or as an acute leukemia [13]. Here, BL tumor cells were chosen as a model system to study the protein components of exosomes derived from human lymphoma cells because few data are available on the protein components of exosomes derived from this tumor type.

Proteomic technologies such as two-dimensional electrophoresis and mass spectrometry (MS) enable us to comprehensively study the protein composition of TEXs. Our previous studies demonstrated that TEXs harbor tumor cell-associated antigens and can induce tumor antigen-specific antitumor immunity [5,10].

Similar to other tumor cells, lymphoma cells can release exosomes [10]. However, the protein constituents of LCEXs have still not been identified. In this study, proteins isolated from EXORaji were separated by one-dimensional SDS-PAGE, and protein bands were identified by mass spectrometry. The protein components of EXORaji were analyzed using shotgun technology. The GO database and KEGG analysis were used to define and describe the function of proteins.

Methods

Chemicals and reagents

AIM-V serum-free conditioning medium, RPMI 1640 medium, and fetal bovine serum were purchased from Invitrogen (Grand Island, Shanghai, China). Deuterium oxide (D2O) was purchased from Tenglong Weibo Technology (Qingdao, China). Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) buffer and 3-[(3-cholamidopropyl) dimethylamino]-1- propanesulfonate (CHAPS) were purchased from Sigma Aldrich (Sigma Aldrich, Shanghai, China). TPCK-trypsin was purchased from Promega (Promega, Shanghai, China). Acetonitrile (GC purity) was purchased from Merck (Merck, Shanghai, China). Lysis buffer, 4× separating gel buffer, and balanced salt solution were sterilized by passing through a 0.22-μm membrane filter before sub-packaging and storing at −80°C.

Preparation of exosome purification

Raji cells were cultured in RPMI 1640 medium containing 10% inactivated fetal bovine serum at 37°C in a 5% CO2 humidified incubator. After 24–72 h in serum-free conditioned medium, cell viability was >95% as determined by a trypan blue exclusion assay. Exosomes were prepared as previously described [10,14]. The supernatant was centrifuged at a series of successively lower forces to remove cells and cellular debris. The resultant clarified supernatant was concentrated by centrifugation at 100,000 g at 4°C for 60 min. The pellets were washed with 0.01 M phosphate-buffered saline, transferred to a 10-ml ultracentrifuge tube underlaid with a 1.5-ml 30% sucrose/D2O density cushion (density: 1.210 g/cm3), and ultracentrifuged (Beckman Coulter, Shanghai, China) at 100,000 g at 4°C for 1 h. Finally, the exosomes were concentrated by centrifugation at 1,000 g for 60 min in a pre-rinsed 100-kDa molecular weight Ultra capsule filter (Millipore, Billerica, Shanghai, China). The concentration of exosomal proteins was determined using a Quick Start™ Bradford Protein Assay Kit (Bio-Rad®, Shanghai, China). The exosomes were stored at −80°C until use.

Morphological characteristics of EXORaji

Exosomes derived from Raji cells (10 μg) were washed in cacodylate buffer, fixed in 2.5% glutaraldehyde (Polysciences, Shanghai, China) in cacodylate buffer overnight at 4°C, dehydrated by graded alcohol processing, and flat embedded in LX-112 epoxy resin. Sections were cut with an ultramicrotome. Mounted sections were collected on copper grids, stained with a saturated solution of uranyl acetate, and submitted for observation and imaging under a Philips CM12 transmission electron microscope (TEM) (Philips, Shanghai, China) [15]. To characterize the exosomes, ER-residing molecules such as ER-residing protein Grp94 in exosomes derived from Raji cells were examined by Western blot.

Two-dimensional SDS-PAGE

Isoelectronic focusing (IEF) was performed with 18-cm immobilized strips with pH values from 3–10 and 4–9 in an IPGphor electrophoresis device (Amersham Bioscience, Shanghai, China). Briefly, samples of EXORaji and Raji cells were diluted into 350 ml buffer and loaded onto an IPG strip. IEF was carried out at 20°C according to the following schedule: 12 h at 30 V, 2 h at 100 V, 1 h at 500 V, 1 h at 1,000 V, 1 h of a linear gradient to 8,000 V, and 10 h at 8,000 V. After IEF, the strips were equilibrated in 6 M urea, 30% glycerol, 2% SDS, and 50 mM Tris-HCl (pH 6.8) containing 1% 1,4-dithiothreitol for 15 min followed by 2.5% (w/v) iodoacetamide. The strips were transferred onto the gel and sealed in place with 1% agarose. The two-dimensional SDS-PAGE was performed using 12% polyacrylamide gels at 20 mA and 16 V on Bio-Rad Protein II (Bio-Rad, Shanghai, China) and was terminated when the bromophenol blue front had migrated to the lower end of the gels. The gels were then stained with silver [16] and scanned by the ImageScanner (Amersham Pharmacia, Shanghai, China).

One-dimensional protein electrophoresis

One-dimensional electrophoresis of EXORaji on 10% SDS-PAGE gels was performed according to the manufacturer’s instructions (BioRad Laboratories, Shanghai, China). Then 10 μg of each sample was taken up in 8 M urea, 2% CHAPS, 20 mM dithiothreitol, and 0.01% bromophenol blue and transferred onto 1.0-mm-thick 10% SDS-PAGE gels. A constant current of 7 mA per gel was applied at 10°C. After 16 h, the gels were stained using the Novex Colloidal Blue Staining Kit according to the manufacturer’s instructions (Invitrogen, Shanghai, China).

Enzymatic digestion of protein and capillary

Stained electrophoresis gels loaded with Raji cells and EXORaji were excised into four parts and submitted for enzymatic digestion. Proteins were first enzymolyzed into peptides. Enzymatic digestion of proteins in the gels was performed as previously described [14]. Briefly, the Ettan™ MDLC system (GE Healthcare, Shanghai, China) was used to desalt and separate the tryptic peptides mixtures. In this system, samples are desalted on reversed phase (RP) trap columns (Agilent Technologies, Shanghai, China) and subsequently separated on RP columns (Column Technology Inc., Shanghai, China). Mobile phase A (0.1% formic acid in HPLC-grade water) and mobile phase B (0.1% formic acid in acetonitrile) were selected. The tryptic peptide mixture (20 μg) was loaded onto the column, and separation was performed at a flow rate of 2 μl/min with a linear gradient of 4–50% B for 120 min. A Finnigan LTQ™ linear ion trap MS (Thermo Electron, Shanghai, China) equipped with an electrospray interface was connected to the LC setup to detect eluted peptides. Data-dependent MS/MS spectra were obtained simultaneously. Each scan cycle consisted of one full MS scan in the profile mode followed by five MS/MS scans in the centroid mode with the following Dynamic Exclusion™ settings: repeat count: 2; repeat duration: 30 s; exclusion duration: 90 s. Each sample was analyzed in triplicate.

Mass spectrometry data acquisition and analysis

MS/MS spectra were automatically searched against the non-redundant International Protein Index human protein database (version 3.26, 67 687 entries) using the Bioworks Browser 3.1. The peptides were constrained to be tryptic, and up to two missed cleavages were allowed. Carbamidomethylation of cysteines was treated as a fixed modification, whereas methionine residue oxidation was considered a variable modification. The mass tolerances allowed for precursor and fragment ions were 2.0 and 0.0 Da, respectively. The protein identification criteria were based on Delta CN (≥0.1) and cross-correlation scores (Xcorr, one charge ≥1.9; two charges ≥2.2; three charges ≥3.75).

Western blotting

Western blotting was performed following one-dimensional SDS-PAGE as follows. Protein samples from EXORaji and Raji cells were electroblotted onto Immobilon P membranes (Millipore Corp, Shanghai, China) and incubated with specific antibodies, followed by horseradish peroxidase-conjugated secondary antibodies, and detected using SuperSignal West Pico chemiluminescent substrate (Pierce Perbio Science, Shanghai, China). Antibodies used in this study to confirm the proteins detected by MS were: anti-HSC70 (clone 13D3; Thorma Scientific, Shanghai, China), anti-ICAM-1 (clone 9H21L19; Thorma Scientific, Shanghai, China), and anti-actin (clone 15G5A11/E2, Thorma Scientific, Shanghai, China).

Results

Morphology of exosomes derived from lymphoma cells

We first assessed whether exosomes derived from Raji cells were similar to those released by other tumor cell lines. The supernatant was centrifuged at up to 100,000 g, and the pellet was similar to previously reported exosomes, as determined by electron microscopy [17]. The vesicles were <100 nm in diameter and had a dimpled, cup-shaped morphology, characteristic of exosomes (see Figure 1a). To characterize EXORaji, we also examined the presence of the ER-residing protein Grp94 by Western blot. Data showed that Grp94 was absent in EXORaji (see Figure 1b). Taken together, these results indicate that vesicles obtained from cell-free supernatants of Raji lymphoma cells exhibit characteristic biophysical properties of exosomes.

Figure 1

Morphology of EXO and one-dimensional electrophoresis of samples from EXO and Raji cells. a. Transmission electron microscope image of EXORaji (×100 K). b. Western blot analysis demonstrating the absence of Grp94 in EXORaji. c. Protein samples from EXORaji and Raji cells were separated by SDS-PAGE for further MS analysis. Lanes 1 and 2 represent Raji cell-derived exosomes, and lanes 3 to 6 represent Raji cells.

Mass spectrometric analysis of proteins in EXORaji

Protein samples were then separated by one-dimensional SDS-PAGE for further MS analysis. The gels were stained with Coomassie Blue R-250, and protein bands were digested for capillary high-performance liquid chromatography analysis. As shown in Figure 1, protein bands showed similar patterns between the preparations from EXORaji and Raji cells. Two-dimensional electrophoresis was also used to compare the protein contents from EXORaji and Raji cells (see Figure 2). Although the protein spots of EXORaji were slightly less than those of the Raji cells, more than 70% of the protein spots in Raji cells were also found in EXORaji. To further explore the proteomic characteristics of EXORaji, EXORaji samples were separated by one-dimensional SDS-PAGE for further MS analysis, the base peak maps of Raji cells and EXORaji were collected according to the mass-to-charge ratios of the peptides and peptide fragments.

Figure 2

Two-dimensional electrophoresis of samples from Raji cells (a) and EXO (b).

All collected base peak data were analyzed by DeCyder MS and BuildSummary 4.9.0 software to output all identified proteins. According to shotgun protein identification, 322 proteins were identified in Raji cell samples, while 197 proteins were identified in EXORaji. Among the proteins in EXORaji samples, 139 were identified in both samples, showing an overlap of 70.56% of the total proteins in EXORaji samples, indicating that more than 70% of proteins in EXORaji were derived from their parental cells. Interestingly, the remaining 58 proteins, accounting for about 30% of proteins in EXORaji, were not identified in Raji cells, indicating that some proteins in EXORaji may be obtained from the extracellular microenvironment or enriched in the process of exosome development (see Figure 3). Most of these proteins are a composition of HLA class I and II molecules, such as HLA-B, HLA-C histocompatibility antigen, B-15 alpha chain, B-39 alpha, A-26 alpha China, HLA-DQA1 MHC class II antigen, HLA class II histocompatibility antigen, DQ(1) beta China, HLA-C antigen, Cw-4 alpha and Cw-3 alpha chain, HLA-DPB1 major histocompatibility complex, class II, DP beta1, CD81, CD82 antigen and intercellular adhesion molecule 1, etc. These proteins play an important role in antigen processing and presentation and regulation of cell interactions.

Figure 3

Distribution of identified proteins in Raji cells and EXO . Shotgun protein identification reveals 322 proteins in Raji cell samples (white) and 197 in EXORaji samples (gray); 139 proteins are identified in both samples, accounting for 70.56% of the total identified proteins in EXORaji samples, while the remaining 58 proteins are unique to EXORaji.

Analysis of protein function in EXORaji using GO analysis

Next, we analyzed the function of proteins in EXORaji according to the biological process, molecular function, and cell components with GO analysis. As shown in Table 1, among the 139 proteins in EXORaji, 46.7% and 43.2% were involved in localization and establishment of localization, respectively; 41.7% of the proteins were involved in response to stimulus, 38.1% of the proteins were involved in cellular component organization, and more than 20% of proteins were involved in immune system processes. Similarly, among 58 proteins unique to EXORaji, more than 30% were involved in localization, establishment of localization, and response to stimulus (see Table 2), indicating that LCEX plays an important role in biological process including response to stimuli and establishment of localization. In terms of molecular function, all proteins identified in EXORaji were involved in protein binding, more than 45% of which were involved in nucleotide binding, and 20% were involved in nucleoside binding and hydrolase activity. Similarly, more than 60% of the proteins unique to EXORaji were involved in protein binding (Table 2), suggesting that LCEX plays an important role in protein binding.

Table 1

Categories of proteins identified in Raji cells and EXO by GO analysis

Biological process				Molecular function
	E&R	EXO Raji	Raji cells		E&R	EXO Raji	Raji cells
Response to stimulus	45	60	108	Hydrolase activity	39	43	82
Immune system process	18	32	16	Nucleoside binding	40	42	91
Cell killing	3	3	3	Nucleotide binding	58	60	143
Localization	46	65	77	Protein binding	105	139	250
Multi-organism process	11	20	25	Nitric-oxide synthase regulator activity	2	2	2
Establishment of localization	43	62	74	Proteasome activator activity	2	2	2
Cellular component organization	44	57	86	Nucleobase binding	2	2	3
Cellular component biogenesis	23	27	58	Cell surface binding	4	5	4
Cell component				Carboxylic acid binding	5	5	7
	E&R	EXO Raji	Raji cells	Translation factor activity	5	5	10
Ribonucleo protein complex	8	10	61	Lyase activity	8	8	11
Protein complex	47	52	98	Cofactor binding	9	9	15
Organelle lumen	24	24	100
Non-membrane bounded	45	51	113
Organelle part	52	56	162
Intracellular organelle	86	105	241
Intracellular part	107	139	292
Organelle membrane	14	17	33
Vesicle	24	32	34
Organelle envelope	11	14	34

The protein constituents of Raji cell and EXORaji were analyzed by GO software according to the biological pathways, molecular function, and cell components. Table 1 shows the analysis results. The numbers of protein kinds presented in each sample or in both samples were listed.

Table 2

Category of proteins uniquely identified in EXO by GO analysis

Molecular function		Biological process		Cell component
Pattern binding	3	Reproduction	9	Protein-lipid complex	3
Carbohydrate binding	6	Reproductive process	9	Protein complex	13
Signal transducer activity	14	Immune system process	11	Cell surface	5
Protein binding	36	Establishment of localization	18	Extracellular space	7
		Localization	20	Vesicle	8
		Response to stimulus	22
		Multiorganism process	11

The protein constituents of 58 kinds of proteins unique to EXORaji were analyzed by GO software according to the biological pathways, molecular function, and cell components. Table 2 shows the analysis results. The numbers of proteins presented according to the categories of functions were listed.

Other and our previous studies have demonstrated that exosomes may harbor proteins and associated antigens of their parental cells [5,10,18,19]. In this study, more than 90% of the proteins in EXORaji were involved in intracellular components, approximately 75% of proteins were involved in intracellular organelles, and approximately 47% of proteins were involved in intracellular organelle components and organelle components. Among the proteins uniquely identified in EXORaji, more than 40% were involved in the membrane and membrane components. Taken together, these data suggest that LCEX is involved in various biological activities associated with biological processes, molecular functions, and cellular components, which provides further evidence that LCEXs harbor intracellular and membrane proteins from their parental cells.

KEGG pathway analysis

The KEGG provides an operating platform based on the building blocks of genome information (i.e., GENES) and chemical substance information (i.e., LIGAND), linking the genome to biological systems via metabolic networks (i.e., PATHWAY), subsequently categorizing proteins according to the functional level (i.e., BRITE) [20]. In this study, KEGG pathway analysis was used to analyze the proteins identified in EXORaji. We found that 12 proteins identified in EXORaji are involved in antigen processing and presenting, such as PA28, heat shock protein (HSP) 70 and 90, MHC-I, T-cell receptor, and killer-cell immunoglobulin-like receptor (see Figure 4a). Ten proteins in EXORaji are involved in several metabolic pathways such as glycolysis/gluconeogenesis, and eight proteins are involved in cell adhesion (see Figure 4b). Western blotting also confirmed the presence of HSP 70 and ICAM-1 in EXORaji (see Figure 5). Taken together, our data indicate that LCEXs harbor some immunological and adhesion molecules and may play an important role in immune regulation and cell adhesion.

Figure 4

KEGG analysis in EXO reveals proteins involved in antigen processing and presenting (a) and cell adhesion (b). KEGG used for pathway analysis of proteins expressed in EXORaji shows 12 proteins involved in antigen processing and presenting and eight proteins involved in cell adhesion. Indicated molecules are marked with stars.

Figure 5

The presence of actin, HSP70 (a), and ICAM-1 (b) is confirmed by Western blot analysis of EXO . The primary antibodies were anti-actin (1:10,000) and anti-HSP70 (1:1,000), followed by horseradish peroxidase-conjugated goat anti-mouse IgG1. Blots were incubated with SuperSignal West Pico chemiluminescent substrate and exposed to Hyperfilm ECL (Amersham Biosciences, Shanghai, China).

Discussion

To date, tumor exosomes have not yet been characterized. While much is known about dendritic cell-derived exosomes, no studies have reported extensive protein characterization of LCEXs. In this study, exosome-like vesicles were isolated from the culture supernatant of the Raji lymphoma cell line through successive centrifugation. Electron microscopy showed vesicles measuring 60–150 nm in diameter. Western blot revealed the absence of ER-residing protein Grp94 in EXORaji, while acetyl cholinesterase activity was detectable in EXORaji. Taken together, these data indicate that vesicles obtained from cell-free supernatants of Raji lymphoma cells exhibit similar biophysical properties to those of exosomes.

Mass spectrometry is a classical method in proteomics that facilitates the identification of complex protein profiles. This technique requires small samples but outputs data of high resolution with high detection sensitivity [21]. In this study, MS was used to analyze the protein components of EXORaji and to determine the differences and similarities of protein components between Raji cells and EXORaji to investigate the functional role of EXORaji proteins. More than 70% of proteins in EXORaji were derived from its parental Raji cells, consistent with the data from two-dimensional electrophoresis. These data indicate that LCEXs harbor the majority of proteins derived from the cellular components of their parental cells. Meanwhile, we also demonstrated that some of surface molecules of Raji cells, such as CD19, CD20, and CD22, also were identified in EXORaji. These surface molecules of Raji cells are not only surface antigens, but also are targets of treatment; for example, rituximab, an anti-CD20 antibody, has been widely used in the treatment of adult Burkitt and Burkitt-type lymphoma or acute lymphoblastic leukemia [22]. Previous and our studies have shown that exosomes derived from mouse tumors contain a large proportion of tumor antigens and MHC class I molecules loaded with tumor peptides [9,10,23]; these studies have demonstrated that tumor cell-derived exosomes could induce tumor antigen-specific antitumor immunity. Taken together, we speculate that LCEXs may be a potential source of lymphoma cell-associated antigens for immunotherapy. However, 58 proteins were uniquely identified in EXORaji, indicating that some proteins may be enriched in LCEXs and acquired from the extracellular microenvironment. LCEXs may play a role in antigen processing and presentation and regulation of cell interactions since most of the proteins in EXORaji are composed of HLA class I and II molecules and CD81, CD82, and intercellular adhesion molecule-1.

Few studies have described the functions of proteins in LCEXs. To the best of our knowledge, this is the first study to demonstrate that EXORaji-derived proteins are involved in many biological activities such as response to stimuli, establishment of localization, and protein and nucleotide binding. Because the LCEX vesicle is mainly formed in the cell lumen, it contains the largest proportion of protein molecules involved in the formation of intracellular components including organelle components such as the organelle lumen. In addition, such structures contain the majority of proteins involved in the formation of intracellular components.

The KEGG provides an operating platform based on the building blocks of genome information and chemical substance information, subsequently categorizing proteins according to the functional level. In this study, the KEGG database was used to identify the detected proteins, revealing that eight of the proteins found in LCEX were cell adhesion molecules (CAMs), mainly ICAM and MHC molecules, while 12 proteins were involved in antigen processing and presenting, belonging to the heat shock cognate protein (HSP)70 and HSP90 family and PA28. These molecules had higher credibility in the identification of proteins loaded on LCEX; ICAM-1 and HSP70 indeed presented in LCEX according to our Western blotting results. Consistent with our findings, Thery et al. suggested that exosomes contain HSP70, while Nylandsted et al. reported the expression of HSP70 in endosome-lysosomal compartments [7,24]. HSPs are a group of common proteins that play a role in the cell response to elevated temperature, infection, cytokine stimulation, and other environmental stresses. HSPs are normally present in small amounts within the cytoplasm of all cells in all life forms, but can also be released into the extracellular environment in the absence of cellular necrosis [25]. The precise mechanisms by which HSPs are actively released by viable cells have not yet been elucidated, but we propose that exosomes play a role in releasing HSPs from cells. Inside cells, HSPs are involved in protein trafficking, whereby they regulate the proper folding of other proteins, maintain their correct and functional shape, and transport them from one location to another [26]. These proteins thus act as chaperones, bringing along with them small fragments or peptides derived from other proteins expressed in the cell, providing a “fingerprint” of the cell’s content [27]. Therefore, exosomes carrying large amounts of HSPs from tumor cells may be optimal candidates for cancer immunotherapy without the need to identify the antigens themselves. In vivo, HSPs in exosomes can be taken up by DCs and macrophages via CD91 receptor-mediated endocytosis [28,29] and then processed for presentation to the immune system in lymph nodes. Tumor-specific antigens are released from the HSP inside the cell and presented to cytotoxic T cells (CTL), or “killer cells”, which are then activated. Many studies have shown that immune cells stimulated with HSPs can eliminate different kinds of cancer cells [30-33].

While intercellular adhesion molecule-1 (ICAM-1) is a transmembrane protein, two types of extracellular ICAM-1 have been detected in cell culture supernatants as well as in the serum: a soluble form of ICAM-1 (sICAM-1) and a membranous form of ICAM-1 (mICAM-1) associated with exosomes. Previous observations have demonstrated that sICAM-1 cannot exert potent immune modulatory activity because of its low affinity for leukocyte function-associated antigen-1 (LFA-1) or membrane attack complex-1. A previous study has demonstrated that mICAM-1 on exosomes retained its topology similarly to that of cell surface ICAM-1 and could bind to leukocytes, indicating that mICAM-1 on exosomes exhibits potent immunomodulatory activity [34]. Other studies and our previous one also demonstrated that exosomes loaded with tumor antigen can be taken up by dendritic cells (DCs) and transfer tumor antigen to DCs in vitro; activated T cells also can recruit dendritic cell-derived exosomes via LFA-1. Taken together, LFA-1/ICAM-1 interactions play an important role in exosome uptake by antigen-presenting cells and T cells [5,35].

PA28, an 180,000-Da protein, is a proteasome activator that is strongly induced by the major immunomodulatory cytokine IFN-γ [36,37] and has been implicated in the regulation of MHC class I Ag processing [16]. PA28 may accelerate the production of MHC class I ligand from longer precursor peptides by the 20S proteasome in vitro [38], regulate the proteasome’s hydrolysis of small nonubiquitinated peptides as a positive allosteric effector, and modulate the proteasome-catalyzed production of antigenic peptides presented to the immune system on MHC class I molecules [16,39]. Therefore, we hypothesized that HSC70 and CAMs presented by LCEX may promote the combination, endocytosis, and internalization of LCEX into APCs in a receptor-mediated manner, thereby enhancing immune responses.

Conclusion

In conclusion, LCEXs express a discrete set of proteins involved in antigen presentation, signal transduction, and adhesion and thereby may provide an important pathway in the communication between cells. On the other hand, LCEXs harbor most of proteins expressed in their parental lymphoma cells and may be a potential source of lymphoma cell antigens for immunotherapy.