Dendritic cells combined with tumor cells and α-galactosylceramide induce a potent, therapeutic and NK-cell dependent antitumor immunity in B cell lymphoma

Invariant natural killer T (iNKT) cells are a small population of lymphocytes characterized by the expression of an invariant T cell receptor (TCR) encoded by Vα14Jα18 and Vβ8 segments in mice, and Vα24Jα18 and Vβ11 segments in humans [1‐3]. These cells have a unique specificity for numerous endogenous and exogenous glycolipid antigens presented by the non-polymorphic CD1d receptor on antigen presenting cells (APCs) [1, 2, 4].

iNKT cells play a central role in tumor immunology since they coordinate innate and adaptive immune responses and can be activated using the synthetic glycolipid α-galactosylceramide (α-GalCer) [1, 2, 5, 6]. The interaction between CD1d-glycolipid complex and the invariant TCR of iNKT cells stimulates interferon gamma (IFN-γ) production and the secretion of a large number of other cytokines (e.g. IL-12, IL-4, IL-17) that promote tumor eradication [7, 8]. In addition, iNKT cell activation contributes to the enhancement of dendritic cell (DC) function and the activation and expansion of NK cells [2, 9] and antigen-specific B and T cells [6].

The capacity of iNKT cells to induce potent innate and antigen-specific immune responses [1, 2, 5, 10] provides the basis for designing an effective immunotherapy to enhance immune responses against tumors. Different iNKT cell-directed therapies has been studied so far, including administration of iNKT cell-activating ligands such as α-GalCer, and the administration of DCs or tumor cells loaded with this glycolipid [7, 11‐14]. Activation of iNKT cells by giving soluble free α-GalCer in vivo has been shown to induce potent antitumor responses in some murine tumor models [11], although it induces a long-term iNKT cell anergy causing unresponsiveness to sequential stimulation with that glycolipid [15, 16]. When iNKT cells are activated with α-GalCer, the interaction of iNKT cells with APCs seems to be a key factor for the development of antitumor activity. Previous studies in murine models suggested that injection of DCs loaded with α-GalCer induces prolonged cytokine responses with an enhancement of antitumor effect compared with injection of free α-GalCer [7, 12]. Additional studies showed that tumor B cells loaded with α-GalCer induced a potent antitumor immunity as a prophylactic treatment [13, 14].

Although these different strategies resulted in promising data in pre-clinical studies their translation to the clinical setting proved to be less effective. α-GalCer was tested in a clinical trial with solid cancer patients and only transient iNKT cell activation was detected in a minority of patients [17, 18]. Other clinical trials in different solid cancer and myeloma patients were carried out using α-GalCer-loaded DCs and, while most of the patients showed an increase of IFN-γ and IL-12 serum levels, no antitumor responses were noted [10, 19‐22].

The lack of clinically relevant antitumor efficacy of α-GalCer or DCs loaded with α-GalCer strategies prompted to search for different approaches. We reasoned that the activation of iNKT cells in the presence of DCs, α-GalCer and tumor cells, as an antigen source, would translate into a highly effective immunotherapy treatment. Hence, we evaluated the antitumor effect of a vaccine that combines DCs and irradiated tumor cells with the iNKT cell agonist α-GalCer in a B cell lymphoma mouse model. We show that this approach induces a strong cytokine production and activation of NK, B and T cells and, more importantly, a potent antitumor efficacy in a therapeutic setting. Our results further support the use of a combination of DCs and α-GalCer mixed with tumor cells as a therapeutic treatment against B cell lymphoma.

iNKT cell activation represents an attractive approach for cancer immunotherapy since iNKT cell stimulation induces a potent innate and adaptive immune system activation that can generates antitumor immunity [1, 2, 5, 10]. Here, we show that a single dose of a vaccine that combined DCs, tumor cells and α-GalCer (Mix + GalCer vaccine) is very effective in eradicating B cell lymphoma in vivo as a therapeutic treatment. Although other studies show that the combination of these three elements, together with the inhibition of regulatory T cells (Tregs) [24] are a good strategy to induce antitumor immune responses, the data presented here demonstrated that just the combination of DCs, tumor cells and α-GalCer prior to injection into tumor-bearing mice can induce the strongest antitumor effect. Our therapy generates a specific, memory and global immune system activation that is able to eradicate B cell lymphoma in vivo. The importance of combined DCs and α-GalCer with stressed tumor cells to improve the specificity and the potency of the antitumor immune response is clearly reflected in the highly percent of tumor-free mice after Mix + GalCer treatment, in comparison with those receiving only DCs and α-GalCer. The addition of tumor cells into the vaccine can induce T and iNKT cell responses toward a high range of MHC class I and II, and CD1d-related tumor antigens, including those antigens which are immunogenic but less representative. Of interest, the administration of α-GalCer alone in our model did not have any antitumor efficacy, in contrast to other studies which showed a considerable antitumor effect [7, 11]. The reduced antitumor efficacy that we observed in our B cell lymphoma model using α-GalCer alone mostly resembles the clinical scenario, where patients treated with this glycolipid did not experiment any antitumor effect although they had a moderate iNKT cell expansion [10, 17, 19, 20].

Moreover, in line with other studies, we observed that a single-dose of Mix + GalCer vaccine induced a significant increase of iNKT cells in the spleen that was greater than the one induced by α-GalCer alone [13]. Interestingly, NK cells had a similar kinetic behavior as iNKT cells, showing a greater increase in the spleen of mice treated with Mix + GalCer vaccine compared to α-GalCer alone. It is possible that the significant expansion of NK cells induced by Mix + GalCer vaccine may be related to iNKT cell activation, in line with data from previous studies [9].

Mix + GalCer vaccine was also able to protect mice from a second tumor challenge, indicating the generation of established adaptive memory immunity against tumor cells, and that it was tumor-specific. Previous studies using DCs or tumor cells loaded with α-GalCer exhibited similar long-lasting immunity in mice models of myeloma and B-cell lymphoma [13, 25], as well as in other non-hematological tumor models [14, 26]. In fact, iNKT cells are able to improve the generation and proliferation of CD4⁺ and CD8⁺ memory T cells [27], as well as to enhance B cell function and memory in mice [28].

Once analyzed the in vivo antitumor effect of Mix + GalCer treatment, we observed that the cytokine profile induced by the therapeutic vaccine was a combination of Th1, Th2 and Th17-type responses, which is consistent with a potent iNKT cell activation [1, 5]. The cytokine that showed the highest level in Mix + GalCer treated mice was IFN-γ, suggesting a critical involvement in the antitumor effect. In line with previous studies, high IFN-γ production is the main common characteristic in α-GalCer based treatments [14, 29]. In our study, we detected a significant increase of IFN-γ secreting iNKT, NK after Mix + GalCer injection, suggesting that all of these cells are involved in the IFN-γ production observed after treatment. Interestingly, in contrast with α-GalCer treatment, we observed that Mix + GalCer vaccine induced the generation of tumor-specific IFN-γ CD4 and CD8 T cells, which can be important to increase the levels of IFN-γ and to improve the antitumor effect and the generation of the memory anti-tumor immune response. Nevertheless, a definitive role of IFN-γ in the antitumor efficacy observed in our tumor model could only be demonstrated using IFN-γ knock-out mice.

In addition, there was a significant increase of IL-12 after Mix + GalCer therapy which may reflects the involvement of DCs in the generation of the antitumor immune response [14, 29]. Very interestingly, Mix + GalCer treated mice showed very high levels of IL-17 in their sera. It is likely that, in our model, the main source of IL-17 comes mostly from activated iNKT cells [30], although the contribution of other T cell subsets (i.e. Th17 cells) was not addressed.

A critical role of NK cells in the antitumor immune response was observed since treated mice depleted for NK cells did not survive after 4TOO tumor injection. Interestingly, 4TOO cells express very high levels of the NKG2D ligand retinoic acid early 1 (Rae-1) (data not shown), a molecule directly involved in NK cell activation, which could contribute to the critical role of NK cells in the observed antitumor effect. This is in line with previous studies describing an involvement of NKG2D ligands in the recognition of tumor cells, as part of the immuno editing process [31].

In contrast to some studies [13], CD4⁺ T cells seem to be dispensable for the antitumor effect, likely reflecting the fact that 4TOO cells do not express MHC II molecules [23]. Surprisingly, treated mice depleted of CD8⁺ T cells were still resistant to 4TOO tumor challenge. This suggests that CD8⁺ T cells are not critically involved in the antitumor effect of the Mix + GalCer approach in our model, despite having found a significant amount of tumor-specific IFN-γ secreting CD8⁺ T cells. It is likely that the strong contribution of NK cells to the antitumor effect overcome the potential antitumor effect of those IFN-γ secreting CD8⁺ T cells.

iNKT cells can induce specific B-cell activation [32]. We were able to demonstrate a significant increase of IgG antibodies in Mix + GalCer treated mice that specifically recognize 4TOO tumor cells. Their contribution to the overall antitumor effect has not been addressed; however, since a small percentage of NK-depleted mice were able to resist the tumor challenge, it is tempting to speculate that the tumor specific antibody response may have played a role.

The synthetic glycolipid α-GalCer was tested in several clinical trials with cancer patients demonstrating that it is safe [17]. Despite of this, only transient iNKT cell activation was detected in a minority of patients when α-GalCer was injected alone as a cancer treatment [10, 17]. Other trials were carried out using DC pulsed α-GalCer and showed improved results, suggesting that is important to enhance α-GalCer presentation using DCs [19, 20]. However, in our model, the antitumor effect of Mix + Galcer was consistently better than the approach using α-GalCer-loaded DCs.

In summary, we show that a combination of DCs and tumor cells pulsed with α-GalCer is a very efficient strategy to induce iNKT activation, with an impressive antitumor therapeutic efficacy as well as a long-lasting and tumor specific immunity, involving T, B and NK cell activation. The use of tumor cells-pulsed DCs combined with iNKT activators represents a highly effective strategy for treating cancer patients.