Efficient loading of dendritic cells following cryo and radiofrequency ablation in combination with immune modulation induces anti-tumour immunity.

Dendritic cells (DC) are professional antigen-presenting cells that play a pivotal role in the induction of immunity. Ex vivo-generated, tumour antigen-loaded mature DC are currently exploited as cancer vaccines in clinical studies. However, antigen loading and maturation of DC directly in vivo would greatly facilitate the application of DC-based vaccines. We formerly showed in murine models that radiofrequency-mediated tumour destruction can provide an antigen source for the in vivo induction of anti-tumour immunity, and we explored the role of DC herein. In this paper we evaluate radiofrequency and cryo ablation for their ability to provide an antigen source for DC and compare this with an ex vivo-loaded DC vaccine. The data obtained with model antigens demonstrate that upon tumour destruction by radiofrequency ablation, up to 7% of the total draining lymph node (LN) DC contained antigen, whereas only few DC from the conventional vaccine reached the LN. Interestingly, following cryo ablation the amount of antigen-loaded DC is almost doubled. Analysis of surface markers revealed that both destruction methods were able to induce DC maturation. Finally, we show that in situ tumour ablation can be efficiently combined with immune modulation by anti-CTLA-4 antibodies or regulatory T-cell depletion. These combination treatments protected mice from the outgrowth of tumour challenges, and led to in vivo enhancement of tumour-specific T-cell numbers, which produced more IFN-gamma upon activation. Therefore, in situ tumour destruction in combination with immune modulation creates a unique, 'in situ DC-vaccine' that is readily applicable in the clinic without prior knowledge of tumour antigens.

Rejection of intraocular tumors by CD4(+) T cells without induction of phthisis.

Immune privilege of the eye protects against sight-threatening inflammatory events, but can also permit outgrowth of otherwise nonlethal immunogenic tumors. Nonetheless, ocular tumor growth can be controlled by cellular immune responses. However, this will normally result in phthisis of the eye, in case tumor rejection is mediated by a delayed-type hypersensitivity response orchestrated by CD4(+) T cells. We now show that intraocular tumors can be eradicated by CD4(+) Th cells without inducing collateral damage of neighboring ocular tissue. Injection of tumor cells transformed by the early region 1 of human adenovirus type 5 in the anterior chamber of the eye leads to intraocular tumor formation. Tumor growth is transient in immunocompetent mice, but lethal in immunodeficient nude mice, indicating that T cell-dependent immunity is responsible for tumor clearance. Tumor rejection has all the characteristics of a CD8(+) T cell-mediated immune response, as the tumor did not express MHC class II and only tumor tissue was the subject of destruction. However, analysis of the molecular and cellular mechanisms involved in tumor clearance revealed that perforin, TNF-alpha, Fas ligand, MHC class I, and CD8(+) T cells did not play a crucial role in tumor eradication. Instead, effective tumor rejection was entirely dependent on CD4(+) Th cells, as CD4-depleted as well as MHC class II-deficient mice were unable to reject their intraocular tumor. Taken together, these observations demonstrate that CD4(+) T cells are able to eradicate MHC class II-negative tumors in an immune-privileged site without affecting surrounding tissues or the induction of phthisis.

Synergism of cytotoxic T lymphocyte-associated antigen 4 blockade and depletion of CD25(+) regulatory T cells in antitumor therapy reveals alternative pathways for suppression of autoreactive cytotoxic T lymphocyte responses.

Therapeutic efficacy of a tumor cell-based vaccine against experimental B16 melanoma requires the disruption of either of two immunoregulatory mechanisms that control autoreactive T cell responses: the cytotoxic T lymphocyte-associated antigen (CTLA)-4 pathway or the CD25(+) regulatory T (Treg) cells. Combination of CTLA-4 blockade and depletion of CD25(+) Treg cells results in maximal tumor rejection. Efficacy of the antitumor therapy correlates with the extent of autoimmune skin depigmentation as well as with the frequency of tyrosinase-related protein 2(180-188)-specific CTLs detected in the periphery. Furthermore, tumor rejection is dependent on the CD8(+) T cell subset. Our data demonstrate that the CTL response against melanoma antigens is an important component of the therapeutic antitumor response and that the reactivity of these CTLs can be augmented through interference with immunoregulatory mechanisms. The synergism in the effects of CTLA-4 blockade and depletion of CD25(+) Treg cells indicates that CD25(+) Treg cells and CTLA-4 signaling represent two alternative pathways for suppression of autoreactive T cell immunity. Simultaneous intervention with both regulatory mechanisms is therefore a promising concept for the induction of therapeutic antitumor immunity.

Elucidating the autoimmune and antitumor effector mechanisms of a treatment based on cytotoxic T lymphocyte antigen-4 blockade in combination with a B16 melanoma vaccine: comparison of prophylaxis and therapy.

We have previously shown that small B16 melanomas can be successfully treated using a combination of anti-cytotoxic T lymphocyte antigen (CTLA)-4 monoclonal antibody with a granulocyte/macrophage colony-stimulating factor (GM-CSF) producing irradiated tumor cell vaccine. Regression of tumors results in long-lasting immunity and is frequently accompanied by autoimmune depigmentation. Here we examine the cellular and molecular mechanisms of this combined treatment. Histological examination of depigmented lesions revealed infiltration of polymorphonuclear cells and deposition of antibody. The combination therapy also induced tumor rejection and skin depigmentation in B cell-deficient and in CD4(+) T cell-depleted mice. Both effects of the treatment absolutely required CD8(+) T cells. Analysis of the response in successfully treated mice revealed elevated levels of CD8(+) T cells specific for a nonameric peptide consisting of residues 180-188 of the melanocyte differentiation antigen tyrosinase-related protein (TRP)2. There was no evidence of reactivity to the melanocyte antigens gp100, tyrosinase, Mart1/MelanA, or TRP1. Fas-FasL interactions and perforin played a role in mounting the effector response, whereas the tumor necrosis factor pathway was not required. The cellular requirements for tumor rejection in this therapeutic setting were strikingly different from those in a prophylactic setting. In particular, if mice received a prophylactic vaccine consisting of anti-CTLA-4 and B16-GM-CSF before tumor challenge, full protection was obtained even in the absence of CD8(+) T cells. Our data demonstrate that therapeutic autoreactive CD8(+) T cell responses can effectively be generated in tumor-bearing mice and stresses the value of studying tumor immunity in a therapeutic rather than a prophylactic setting.

Highly efficient transduction of human monocyte-derived dendritic cells with subgroup B fiber-modified adenovirus vectors enhances transgene-encoded antigen presentation to cytotoxic T cells.

The efficiency of dendritic cells (DC) as immunotherapeutic vaccines critically depends on optimal delivery of target Ags. Although DC modified by subgroup C type 5 recombinant adenoviruses (rAd5) provide encouraging results, their clinical application is hampered by the need for high viral titers to achieve sufficient gene transfer, due to the lack of the Ad5 fiber receptor. We now demonstrate that rAd5 carrying subgroup B Ad fibers are up to 100-fold more potent than classical rAd5 for gene transfer and expression in human DC, rAd5 with a type 35 fiber (rAd5F35) being the most efficient vector. This improvement relates to a greater and faster virus entry and to an increased transgene expression especially following DC maturation. Furthermore, these new vectors possess enhanced synergistic effects with other activation signals to trigger DC maturation. Consequently, rAd5F35-infected DC engineered to express the gp100 melanoma-associated Ag largely exceed rAd5-infected DC in activating gp100-specific CTL. Finally, the DC infection pattern of rAd5F35 is fully conserved when DC are in the vicinity of primary skin-derived fibroblasts, suggesting this vector as a candidate for in vivo targeting of DC. Thus, subgroup B fiber-modified rAd5 constitute a major breakthrough in the exploitation of ex vivo rAd-targeted DC as clinically relevant vaccines and may also be suitable for in vivo genetic modification of DC.

Adoptive T cell immunotherapy of human uveal melanoma targeting gp100.

HLA-A*0201-restricted CTL against human gp100 were isolated from HLA-A*0201/K(b) (A2/K(b))-transgenic mice immunized with recombinant canarypox virus (ALVAC-gp100). These CTL strongly responded to the gp100(154-162) epitope, in the context of both the chimeric A2/K(b) and the wild-type HLA-A*0201- molecule, and efficiently lysed human HLA-A*0201(+), gp100(+) melanoma cells in vitro. The capacity of the CTL to eradicate these tumors in vivo was analyzed in A2/K(b)-transgenic transgenic mice that had received a tumorigenic dose of human uveal melanoma cells in the anterior chamber of the eye. This immune-privileged site offered the unique opportunity to graft xenogeneic tumors into immunocompetent A2/K(b)-transgenic mice, a host in which they otherwise would not grow. Importantly, systemic (i.v.) administration of the A2/K(b)-transgenic gp100(154-162)-specific CTL resulted in rapid elimination of the intraocular uveal melanomas, indicating that anti-tumor CTL are capable of homing to the eye and exerting their tumoricidal effector function. Flow cytometry analysis of ocular cell suspensions with HLA-A*0201-gp100(154-162) tetrameric complexes confirmed the homing of adoptively transferred CTL. Therefore, the immune-privileged state of the eye permitted the outgrowth of xenogeneic uveal melanoma cells, but did not protect these tumors against adoptive immunotherapy with highly potent anti-tumor CTL. These data constitute the first direct indication that immunotherapy of human uveal melanoma may be feasible.

Recombinant virus vaccination against "self" antigens using anchor-fixed immunogens.

To study the induction of anti-"self" CD8+ T-cell reactivity against the tumor antigen gp100, we used a mouse transgenic for a chimeric HLA-A*0201/H-2 Kb molecule (A2/Kb). We immunized the mice with a recombinant vaccinia virus encoding a form of gp100 that had been modified at position 210 (from a threonine to a methionine) to increase epitope binding to the restricting class I molecule. Immunogens containing the "anchor-fixed" modification elicited anti-self CD8+ T cells specific for the wild-type gp100(209-217) peptide pulsed onto target cells. More important, these cells specifically recognized the naturally presented epitope on the surface of an A2/Kb-expressing murine melanoma, B16. These data indicate that anchor-fixing epitopes could enhance the function of recombinant virus-based immunogens.

Functional analysis of the T-cell-restricted protein tyrosine kinase Txk.

T lymphocytes express a range of tyrosine kinases that are involved in signalling processes driving cell activation, proliferation and differentation. Two tyrosine kinases expressed only in T cells, the Itk/Emt and Txk gene products, are members of the Tec family of kinases. The role of Tec kinases in cellular function is poorly understood, although a Tec kinase specific to B cells, Btk, is essential for B-cell development. To explore the contribution of the T-cell-specific Tec kinases to lymphocyte function, we have expressed human Txk in the baculovirus system and conducted the first characterization of its activity. We find that Txk exhibits a substrate preference in vitro quite distinct from that of the major T-cell kinases Lck and ZAP70, suggesting that Tec-family kinases might act on a distinct range of substrates. We also investigated the interactions of Txk with the cytoplasmic domains of the key signalling molecules CD3zeta, CD28 and CTLA4 and find that none of these are phosphorylated by Txk, nor are they ligands for the SH2 or SH3 domains of Txk. We conclude that it is unlikely that Txk has a role in the early signal transduction events associated with these key pathways controlling T-cell activation.