CTLA-4 is a co-inhibitory receptor with a high degree of sequence similarity to the T cell co-stimulatory receptor, CD28. Blockade of CTLA-4 enhances CD4+ effector T cell activity (32) whilst CTLA-4 expression on Tregs exerts a cell-extrinsic immunosuppressive effect by downregulating CD80 and CD86, the CD28 ligands which are expressed on DC (33) (Figure 2). The ability of CTLA-4 blocking mAbs to enhance anti-tumor immunity in preclinical models (34) has led to their use in the treatment of metastatic melanoma (29).

CTLA-4 is expressed on activated T cells in humans (35). CTLA-4 blockade with mAbs prevents binding of CD80 and CD86 on DC to CTLA-4 on T cells. T cell associated CTLA-4 binding to CD80 or CD86 is required for expression of the immunosuppressive enzyme indoleamine 2,3-dioxygenase (IDO) in DC in vitro (36). IDO exerts an immunosuppressive effect on T cell proliferation, therefore blockade of CTLA-4 is expected to have a positive effect on T cell proliferation via its action on DC. This mechanism has not been verified in vivo with naturally circulating blood dendritic cells (BDC). The cell-intrinsic effect of CTLA-4 blockade on effector T cells has been shown in mice and humans to be the primary mechanism for the anti-tumor effect, rather than its effect on Treg cells (37, 38). The use of an anti-CTLA-4 mAb (tremelimumab or ipilimumab) to treat prostate cancer and melanoma patients results in broadening of the T cell repertoire (39), in keeping with this mechanism of action.

CTLA-4 expressed on MoDC has an emerging immune regulatory role (40). Binding of this receptor by an activating CTLA-4 mAb has an inhibitory effect, enhancing IL-10 secretion and decreasing T cell proliferation. Furthermore, CTLA-4 is secreted and B7 molecules downregulated on bystander MoDC following cytokine stimulation (41).

Combination of anti-CTLA-4 mAbs with DC vaccination is predicted to remove the inhibitory effect of CTLA-4 ligation on DC and act in synergy with the stimulatory effects of CD80 and CD86 which are upregulated by DC maturation. Clinical studies such as the combination of DC pulsed with the tumor antigen NY-ESO with or without CTLA-4 blockade (NCT02070406) will answer the question on the relevance of this mechanism in vivo.

PD-1 was described early on as a marker of programmed cell death in lymphocytes playing a role in limiting inappropriate immune responses (42). When bound by its ligands, PD-L1 (B7-H1/CD274) or PD-L2 (B7-DC/CD273), PD-1 transmits an inhibitory signal in the presence of simultaneous TCR engagement, resulting in inhibition of T cell proliferation and cytokine secretion (IFN-γ, IL-10) (42, 43). The number of PD-1 molecules available to bind its ligands, PD-L1 and PD-L2 determines cytokine production. Ligation of PD-L2 alone inhibits T cell cytokine production to a lesser extent than PD-L1 (43) however selective blocking of PD-L2 is yet to be studied extensively in vivo. Blockade of PD-1 restores the capacity of CD8+ T cells to attack tumors in the presence of inhibitory signals from PD-L1 expressed on tumor cells (44). This has led to the successful use of anti-PD-1 and anti-PD-L1 antibodies for the treatment of melanoma, non-small-cell lung cancer, and renal cell carcinoma (12–14).

PD-1 is expressed on a diverse range of lymphoid and myeloid cells (42, 43, 45). In humans, PD-1 exhibits activation-induced expression on T cells (46). PD-1 expression on DC in mice was more recently described (47). DC from PD-1 knockout mice show increased survival in vitro compared with wild-type mice. Adoptive transfer of DC from PD-1 knock-out mice confers protection against infection and improved tumor control in a hepatocellular carcinoma murine model (48). Therefore, absence of PD-1 expression has downstream effects which improve DC survival and function.

PD-L1 and PD-L2, the ligands for PD-1, are also expressed upon activation (43, 49). PD-L1 is expressed on a minority of resting lymphoid cells and most myeloid cells while PD-L2 has a much more restricted expression pattern, limited to activated monocytes and APC. In humans, PD-L1 is weakly expressed on both myeloid and plasmacytoid blood DC and may be upregulated preferentially on CD11c+ myeloid DC in the presence of Poly I:C (50) while PD-L2 is expressed on MoDC (49).

In vitro targeting of the PD-L1/PD-1 pathway has been achieved with anti-PD-1 mAbs (51) and PD-L1/L2 with Fab fragments (22) and results in increased T cell proliferation and production of cytokines including IFN-γ and IL-10 in MoDC co-cultures. In contrast to the results of mAb experiments, blockade of PD-L1 and PD-L2 with soluble PD-1 inhibits T cell activation via reverse signaling through DC and leading to a suppressive DC phenotype (52). PD-L1 expressed on DC additionally binds to CD80 which is expressed on T cells as well as its expression on DC (53) and has a negative regulatory function. The outcome of PD-L1 blockade is therefore dependent upon the crosstalk between PD-L1 and CD80 on DC and T cells. The expression of PD-L1 on DC has a dual inhibitory effect via PD-L1:PD-1 and PD-L1:CD80 interactions. The addition of soluble PD-1 would only affect the PD-L1: PD-1 pathway, allowing the inhibitory PD-L1: PD-1 and PD-L1:CD80 pathways to predominate. PD-1 blockade alone is unable to overcome T cell tolerance (54), whilst an anti-PD-L1 mAb specific to the PD-L1:CD80 interaction is able to prevent anergy (55). These findings have important clinical implications in cases of intrinsic or acquired resistance to immune checkpoint inhibitors where immune suppressive mechanisms which rely on DC expression of PD-L1. Whether or not anti-PD-L1 mAbs are more effective than anti-PD-1 mAbs in this setting remains to be seen.

PD-1 blockade and DC vaccination is a logical treatment combination which could augment the well-known T cell mediated anti-tumor effect of anti-PD-1 mAbs (44). If given during the DC maturation process (Figure 1), anti-PD-1 mAbs are predicted to improve DC survival (47) (and therefore antigen presentation) and maturation by blockade of reverse signaling through PD-L1 (52). This will lead to production of the Th1 cytokine IFN-γ, conditions which are favorable for anti-tumor immune responses (22).

Further work is needed to determine whether direct targeting of PD-L2 on DC will promote antigen presentation and T cell priming. Specific mAbs to PD-L2 could preferentially target DC and augment their function in addition to disrupting T cell inhibition by tumor-associated PD-L2 (Table 1).

Inducible T-cell costimulator (ICOS) is a co-stimulatory receptor with sequence homology to CD28 (76). ICOS has similar functions to CD28 in its control of T cell proliferation and IL-10 production, but additionally it controls CD40/CD40L dependent antibody class-switching and therefore immunological memory, properties which are desirable for anti-cancer vaccination.

ICOS is expressed on activated T cells, in contrast to the constitutive expression of CD28 (76). Blockade of its ligand, ICOSL, with ICOS-Ig in allogeneic mixed leucocyte reactions between MoDC and T cells leads to reduced T cell proliferation and helper T cell cytokine production for B cell production of IgG and IgM, thereby demonstrating its co-stimulatory role (77). Reduced T cell proliferation in response to recall antigens indicates that that ICOS-L expression on DC is important for controlling T cell responses.

In human BDC subsets, ICOS-L expression is more strongly induced on plasmacytoid DC (pDC) (BDCA-4/CD304+) than mDC in response to activation with the TLR agonist, poly I:C (50) or IL-3 (78). PDC activated by TLR to upregulate ICOS-L induce production of IL-10 by naïve CD4+ T cells (79). Therefore, augmentation of the co-stimulatory effect of ICOS may have the unwanted effect of inducing IL-10 producing Tregs. Further studies are needed to address the expression of ICOS-L on intra-tumoural DC populations and correlate this to expression on BDC. Tumor associated pDC found in close proximity to ICOS+ Treg in breast cancer (80), liver cancer (81), and ovarian cancer (82) are associated with poorer survival. This is indirect evidence that modulation of the ICOS pathway on peripheral pDC negatively affects tumor-associated immunity.

ICOS potentiates anti-tumor immunity mediated by CTLA-4 blockade in murine models of prostate cancer and melanoma (59). A possible mechanism for this is that CTLA-4 blockade on tumor infiltrating lymphocytes leads to ICOS upregulation allowing binding by ICOS-L expressing cells. Anti-CTLA-4 mAbs mediate Fc-receptor dependent depletion of Tregs in mice (83) but not in humans treated with anti-CTLA-4 mAbs (38). Therefore, concomitant administration of anti-CTLA-4 mAbs and DC vaccination under maturation conditions which promote ICOS-L expression is likely to enhance the effect of anti-CTLA-4 mAbs alone. Induction of ICOS-L on DC and the role the ICOS pathway in antibody class switching implies a role for manipulation of DC to promote memory responses when used as vaccine therapy. The use of ex vivo DC maturation factors which preferentially upregulate ICOS-L on mDC over pDC will minimize the potential for production of the Th1 inhibitory cytokine, IL-10.

TIM-3 is one of 8 TIM gene family receptors, of which only three (TIM-1, TIM-3 and TIM-4) are found in humans (84). The expression of TIM-3 as a marker of T cell exhaustion in association with other tumor-associated T-cell exhaustion markers (e.g., PD-1, CTLA-4) (85) has led to its investigation as a target for cancer immunotherapy. However, the characterization of TIM-3 as a T cell exhaustion marker does not take into account its wide expression pattern on other leucocytes such as DC where it is responsible for other immunological effects.

In humans, TIM-3 is expressed on Th1-polarized CD4+ and CD8+ cytotoxic T cells (Tc1) where it acts as a negative regulator of Th1 responses (86). It is a pattern recognition receptor for phosphatidylserine residues and is important for recognition of apoptotic cells (84). Binding to TIM-3 on Th1 cells, however, does not account for all the function of one of its ligands, galectin-9, as it also binds to TIM-3 on DC. The putative function of galectin-9 in this context is to maintain peripheral tolerance to necrotic antigens (87).

The expression of TIM-3 in human DC is dependent upon the subset being examined. TIM-3 is expressed on CD11c+ PBMC (63). The level of its expression is high on the CD1c+ and CD141+ myeloid BDC subsets and MoDC, but low on pDCs (49, 88). This contrasts with a report suggesting high TIM-3 expression from tumor-associated MoDC in a murine colon cancer model and low expression on MoDC generated from healthy human donors (62).

The ability to take up and cross-present necrotic cells is an important mechanism by which DC sample tumor antigens. A positive regulatory role for TIM-3 on DC was initially reported as galectin-9 co-cultured with mature murine splenic DC increased TNF secretion (63). In contrast, other reports suggest that that antibody-mediated cross-linking of Tim-3 in bone marrow derived murine DC inhibited activation and maturation of DCs (89). TIM-3 blockade on CD103+ CD141+ DC enhances the effect of chemotherapy in a mouse model of breast cancer by improving CD8+ T cell effector cell infiltration in the presence of CXCL9 upregulation on DC (90), demonstrating a DC associated mechanism of TIM-3 targeting in addition to its role in T cells.

The function of TIM-3 may therefore be inhibiting or activating, depending on the immunological context. Blockade of TIM-3 in combination with blockade of CD28 family members such as PD-1 or CTLA-4 is rational as this reverts effector T cell function absent in exhausted cells (91). Blockade of TIM-3 on DC has direct effects which could be used to further enhance immune activation, e.g., by combining TIM-3 blockade with other treatments likely to increase tumor necrosis (e.g., chemotherapy) and uptake of necrotic antigens. Recent work suggests that anti-TIM-3 antibodies must bind to phosphatidylserine and CEACAM1 to have functional effects (92), therefore further work on defining important epitopes in in mAb blockade is required to optimize combination therapy with DC.

Lymphocyte activation gene 3 (LAG-3) is a receptor found on activated T and NK cells, which has sequence homology to CD4 (93). It binds to MHC Class II molecules abundantly expressed on DC. LAG-3 has a negative regulatory role in antigen-dependent T cell proliferation, particularly CD4+ T cells (93). LAG-3 is expressed in association with other immune checkpoint molecules in the tumor microenvironment, therefore chronic viral infection serves as a model for T cell exhaustion in tumor-associated lymphocytes (94). This has led to the development of antibodies against LAG-3 for clinical use in treatment of cancer alone or in combination with anti-PD-1 mAbs (Table 1).

Based on the inhibitory role of LAG-3 signaling in T cells, LAG-3: MHC-II interactions might be expected to be similarly inhibitory for DCs. However, experiments using soluble LAG-3-Ig reveal a stimulatory role in APC (95). In human MoDC, administration of soluble LAG-3-Ig fusion protein induces production of inflammatory cytokines (IL-8, MIP-1α/CCL3) and migratory chemokines (MDC/CCL22, TARC/CCL17 and CCR7) (65) which is not produced by an MHC II specific mAb, implicating the LAG3:MHC II interaction. LAG-3 expressed by activated T cells (96) directly stimulates MoDC to produce IL-12 and TNF without additional stimulation or co-stimulatory signals.

In addition to its role as a ligand for MHC Class II molecules on DC, LAG-3 is expressed by DC themselves. pDC are of particular importance in LAG-3 signaling. In humans, LAG-3+ pDCs in melanoma have been implicated in tumor-associated immunosuppression where tumor-associated MHC-II expression induces TLR-independent activation, production of inhibitory cytokines and recruitment of myeloid derived suppressor cells (MDSCs). Circulating human pDC are activated through LAG-3 in a TLR independent fashion with limited IFN-α and enhanced IL-6 production (97, 98), confirming a similar phenotype to tumor-associated suppressive pDC. Therefore, blockade of LAG-3 is a mechanism which has the potential to improve tumor control via either a DC or T cell mediated mechanism.

LAG-3 has direct effects on DC which promote their pro-inflammatory and migratory capacity. Whilst the development of anti-LAG-3 mAbs is of interest to enhance T cell responses, sLAG-3 is a preferable mechanism to target when used in combination with DC vaccination as an adjuvant. This is expected to promote DC stimulatory signals, migration and ultimately augment T cell function (Table 1).

CD40 is constitutively expressed on B cells, DCs, monocytes, and epithelial cells (100). It is unique amongst TNFRSF members due to its expression on DC rather than T cells. Its multiple functions include induction of B cell proliferation, isotype class switching and T cell help and is useful as a biomarker for disease progression in breast cancer, head and neck cancer and melanoma (66–68).

The ligand for CD40, CD40L (TRAP/T-BAM/CD154), is present on activated CD4+ T cells and is upregulated on human BDC by stimulation with anti CD40 antibody (100). Murine studies show that CD40L is upregulated on pDC stimulated via TLR-9 with CpG and is essential for licensing mDC to produce the pro-inflammatory cytokine, IL-12 (101). CD40 ligation on BDC results in production of IL-12, upregulation of the co-stimulatory molecules CD80 and CD86 and enhancement of CD8+ T cell priming (21).

CD40 fulfills the important roles of regulating T cell effector function, co-stimulatory molecule expression and Th1 polarization of naïve T cells via secretion of cytokines in addition to its use as a marker of DC activation. It is a unique TNFRSF molecule which modulates immune responses by production of cytokines which enhance T cell effector or B cell help functions (102) rather than via co-stimulation of antigenic signals through the TCR.

Anti CD40 mAb have direct anti-tumor efficacy which relies on activation of DC to induce anti-tumor T cell responses (103). CD40 mAb have been tested in clinical trials of B-cell lymphomas (104), pancreatic cancer (105) and other solid tumors as monotherapy (106), or in combination with chemotherapy (107). The mechanism of action for agonistic mAb is via licensing of DC to enhance anti-tumor T cell responses. The majority of CD40mAb are IgG1 and therefore bind to a wide range of FcγR and induce ADCC in target cells. Combination of DC vaccination with CD40 agonistic mAbs is expected to work in synergy generating tumor antigens for uptake by host DC via direct cytotoxicity as well as activation of those DC through CD40. This combination should be tested in a clinical trial of DC vaccination together with an IgG1 CD40 agonistic antibody to take advantage of host ADCC. However, the anti CD40 mAb, CP-870,893, which as an IgG2 has relatively poor activity via FcγR would not be predicted to be as effective.

CD27 is co-stimulatory receptor which is expressed in humans on naïve and central memory T cells and progressively downregulated in effector memory cells (108). It contributes to the magnitude of both primary and memory responses to viral infection, acting either independently or together with CD28 to promote survival of primed CD8+ T cells (23). The agonistic CD27 mAb, varlimumab, promotes T-cell dependent tumor rejection in human CD27 transgenic mice (109), demonstrating that enhanced CD27 signaling can augment anti-tumor responses.

The ligand for CD27, CD70 (CD27L) is inducible on MoDC when they are exposed to TLR although the cytokine cocktail of PGE₂, TNF, IL-1β, and IL-6 induces the strongest levels of CD70 (110). A similar effect is observed with human BDC (111). Myeloid DCs and pDCs stimulated with CD40L or PGE₂ express CD70. Naïve CD4+ T cells stimulated with CD70+ MoDC produce Th1 and Th2 cytokines to a similar degree as CTLA-4/Fc, except that CD70mAbs prevented induction of IL-10.

The importance of CD27 in determining the magnitude of primary immune responses has implications for optimal priming of antigen-specific immune responses (23). As DC have the capacity to be loaded with antigens for therapeutic vaccination, the combination of antigen-loaded DC (Figure 1) enhanced with CD27 stimulating mAbs could have applications as a vehicle to enhance anti-tumor responses to defined tumor neo-antigens by exploiting the effects of the CD27 pathway on T cell priming.

In a murine model using OVA as a model antigen, CD27 agonistic mAbs preferentially generate antigen-specific CD8+ effector responses which are short-lived compared with those generated by 4-1BB activation, (112). These data suggest that CD27 ligation will stimulate a primary immune response that does not translate into effective T cell memory. An ideal combination of CD27 agonism with DC vaccination would be in boosting immune responses to low frequency antigens (e.g., tumor antigens) prior to co-stimulation through receptors with delayed expression and memory responses such as ICOS or 4-1BB. Experiments in the murine model showed that the combination of CD27 and 4-1BB activation abrogated the effect of 4-1BB activation alone on CD8+ T cell expansion.

In order to effectively translate this strategy into the clinic, further experiments with both low and high frequency antigens are required. The effect of CD27 activation in combination with DC vaccination is currently being tested in a phase I trial of a peptide vaccine plus the varlimumab for low grade glioma (NCT02924038).

OX40 is a TNFRSF co-stimulatory receptor transiently expressed on activated CD4+ T cells within 12–24 h, with activation peaking after 2–3 days (30). Antigen-specific memory T cells re-express OX40 within 4 h following re-activation. It exerts direct functional effects on effector T cells via DC co-stimulation with its ligand, OX40L (CD252). Ligation of OX40 by CD252 promotes survival and expansion of CD4+ and CD8+ T cells and is essential for induction of Th2 responses (72). OX40L is expressed on CD4+ tumor infiltrating Tregs (71), where anti-OX40 mAb causes ADCC-dependent Treg depletion. The depletion of Tregs by OX40 mAb is reminiscent of a similar mechanism by CTLA-4. Agonistic OX40 mAbs have been evaluated extensively, showing anti-tumor activity in murine models of glioma, sarcoma, melanoma, and colon cancer (70). Therefore, OX40 represents a target of interest for clinical development of novel cancer immunotherapies.

The induction of OX40L on DC exploits the requirement for DC in induction of Th2 responses. Soluble CD40L induces OX40L and stimulates production of the pro-inflammatory cytokines, TNF, IL-1β, IL-6, and IL-12 (113). On BDC, OX40L is upregulated by sCD40L and associated with production of the cytokines IL-12p40 and IL-12p75 which are required for differentiation of naïve T cells into Th1 cells (113). Human mDCs upregulate OX40L when stimulated with thymic stromal lymphopoietin (114) whilst PGE₂ similarly upregulates OX40L in CD1c+ mDCs (115). Furthermore, the CD141+ subset of mDC induces production of Th2 cytokines in CD4+ T cells in an OX40L dependent fashion (99).

The ability to preferentially induce CD4+ memory T cells capable of ensuring long-lasting antigen-specific responses through the modulation of signaling through OX40L on DC has strong translational potential in cancer immunotherapy. MoDC and CD1c+ and CD141+ BDC subsets upregulate OX40L when stimulated and produce pro-inflammatory cytokines necessary for T cell activation, supporting further in vivo studies to confirm that mature DC can be used to achieve anti-tumor responses in the same manner as agonistic OX40 mAbs.

OX40 activation skews T cell responses toward a Th2 phenotype rather than Th1, which is more commonly associated with anti-tumor cytotoxicity (116). OX40 agonists drive different responses depending on the cytokine milieu present at the time of administration (117). Administration of OX40 agonists during T cell priming drives Treg expansion and enhancement of experimental autoimmunity in contrast to what happens when administered at the time of priming in combination with a vaccine. Therefore, OX40 agonists administered in combination with DC vaccines should ideally be administered at the time of antigen priming. Further work defining the contribution of optimal ex vivo DC maturation factors to the cytokine milieu and therefore T cell phenotype is required before further translation.

4-1BB (CD137/TNFRSF9) is a co-stimulatory receptor that exhibits inducible expression predominantly on activated CD8+ T cells which peaks at around 48 h. CD137 has multiple effects, including co-stimulation of CD4+ and CD8+ T cells, increase in T cell proliferation and IFN-γ production, and reduction of Treg infiltration in tumors (118, 119). Agonistic anti-41BB mAbs have shown anti-tumor efficacy in mice (120) mediated predominantly by CD8+ cells. This has led to clinical trials alone and in combination with T cell co-inhibitory blocking mAbs such as anti-PD-1 mAbs in advanced solid cancers (Table 1).

As in the case of OX40, DC enhance the anti-tumor immune responses generated by anti-4-1BB mAbs (120). Therefore, inducing the expression of the ligand for 4-1BB, 4-1BB-L during ex vivo priming of DC is of potential interest for translation of DC therapies in combination with 4-1BB receptor targeting.

In humans, 4-1BBL is expressed on MoDC activated with CD40L (121) whilst reverse signaling through 4-1BBL induces IL-12p70 secretion. This expression is functionally significant as co-culture with 4-1BB leads to cytokine production and co-stimulatory molecule up-regulation in DC. Furthermore, 4-1BB-L is able to induce proliferation and IFN-γ secretion by MoDC-stimulated antigen-specific T lymphocytes in vitro (121). However, the expression and function of 4-1BBL in BDC is yet to be fully addressed. The contribution of 4-1BB/4-1BB-L signaling, like that of CD27/CD70 and OX40/OX40L interactions described above, is in co-stimulation of effector T cell responses as well as polarization of T cell responses.

Lastly, 4-1BB activation induces memory T cells, with a particularly strong effects when administered during the priming phase (112). Combining 4-1BB activation with DC vaccination is therefore expected to act at the DC level by stimulating production of pro-inflammatory cytokines as well as improving the magnitude of memory responses elicited to specific antigens loaded onto DC during the priming phase. These factors are favorable for effective anti-cancer vaccination.

GC is a Director of DendroCyte Biotech Pty Ltd. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.