Yoshihiro Miyahara

“Default” Generation of Neonatal Regulatory T Cells

CD4+Foxp3+ regulatory T (Treg) cells were shown to control all aspects of immune responses. How these Treg cells develop is not fully defined, especially in neonates during development of the immune system. We studied the induction of Treg cells from neonatal T cells with various TCR stimulatory conditions, because TCR stimulation is required for Treg cell generation. Independent of the types of TCR stimulus and without the addition of exogenous TGF-β, up to 70% of neonatal CD4+Foxp3− T cells became CD4+Foxp3+ Treg cells, whereas generally <10% of adult CD4+Foxp3− T cells became CD4+Foxp3+ Treg cells under the same conditions. These neonatal Treg cells exert suppressive function and display relatively stable Foxp3 expression. Importantly, this ability of Treg cell generation gradually diminishes within 2 wk of birth. Consistent with in vitro findings, the in vivo i.p. injection of anti-CD3 mAb to stimulate T cells also resulted in a >3-fold increase in Treg cells in neonates but not in adults. Furthermore, neonatal or adult Foxp3− T cells were adoptively transferred into Rag1−/− mice. Twelve days later, the frequency of CD4+Foxp3+ T cells converted from neonatal cells was 6-fold higher than that converted from adult cells. Taken together, neonatal CD4+ T cells have an intrinsic “default” mechanism to become Treg cells in response to TCR stimulations. This finding provides intriguing implications about neonatal immunity, Treg cell generation, and tolerance establishment early in life.

Role of SEREX-defined immunogenic wild-type cellular molecules in the development of tumor-specific immunity

Recognition of altered self-antigens in tumor cells by lymphocytes forms the basis for antitumor immune responses. The effector cells in most experimental tumor systems are CD8+ T cells that recognize MHC class I binding peptides derived from molecules with altered expression in tumor cells. Although the need for CD4+ helper T cells in regulating CD8+ T cells has been documented, their target epitopes and functional impact in antitumor responses remain unclear. We examined whether broadly expressed wild-type molecules in murine tumor cells eliciting humoral immunity contributed to the generation of CD8+ T cells and protective antitumor immune responses to unrelated tumor-specific antigens [mutated ERK2 (mERK2) and c-erbB2/HER/neu (HER2)]. The immunogenic wild-type molecules, presumably dependent on recognition by CD4+ helper T cells, were defined by serological analysis of recombinant cDNA expression libraries (SEREX) using tumor-derived λ phage libraries screened with IgG antibodies of hosts bearing transplanted 3-methylchoranthrene-induced tumors. Coimmunization of mice with plasmids encoding SEREX-defined murine wild-type molecules and mERK2 or HER2 led to a profound increase in CD8+ T cells specific for mERK2 or HER2 peptides. This heightened response depended on CD4+ T cells and copresentation of SEREX-defined molecules and CD8+ T cell epitopes. In tumor protection assays, immunization with SEREX-defined wild-type molecules and mERK2 resulted in an inhibition of pulmonary metastasis, which was not achieved by immunization with mERK2 alone.

HER2-Specific T-Cell Immune Responses in Patients Vaccinated with Truncated HER2 Protein Complexed with Nanogels of Cholesteryl Pullulan

Purpose: We developed a complex of tumor antigen protein with a novel nanoparticle antigen delivery system of cholesteryl pullulan (CHP). To target HER2 antigen, we prepared truncated HER2 protein 1-146 (146HER2) complexed with CHP, the CHP-HER2 vaccine. We designed a clinical study to assess the safety of the vaccine and HER2-specific T-cell immune responses measured by the newly developed enzyme-linked immunospot assay with mRNA-transduced phytohemagglutinin-stimulated CD4+ T cells in HLA-A2402-positive patients with therapy-refractory HER2-expressing cancers. Experimental Design: Nine patients with various types of solid tumors were enrolled. Each patient was s.c. vaccinated biweekly with 300 μg of CHP-HER2 vaccine for three times followed by booster doses. HER2-specific T-cell responses were evaluated by enzyme-linked immunospot assay by targeting autologous phytohemagglutinin-stimulated CD4+ T cells transduced with 146HER2-encoding mRNA to cover both identified peptides and unknown epitopes for MHC class I and class II that might exist in the sequence of the vaccine protein. Results: CHP-HER2 vaccine was well tolerated; the only adverse effect was grade 1 transient skin reaction at the sites of vaccination. HER2-specific CD8+ and/or CD4+ T-cell immune responses were detected in five patients who received four to eight vaccinations, among whom both T-cell responses were detected in these patients. In four patients with CD8+ T-cell responses, two patients reacted to previously identified HER263-71 peptide and the other two reacted only to 146HER2 mRNA-transduced cells. Conclusions: CHP-HER2 vaccine was safe and induced HER2-specific CD8+ and/or CD4+ T-cell immune responses.

A novel role for Notch ligand Delta-1 as a regulator of human Langerhans cell development from blood monocytes.

Human Langerhans cells (LCs) are of hematopoietic origin, but cytokine regulation of their development is not fully understood. Notch ligand Delta‐1 is expressed in a proportion of the skin. Granulocyte‐macrophage colony‐stimulating factor (GM‐CSF) and transforming growth factor‐β1 (TGF‐β1) are also secreted in the skin. We report here that Delta‐1, in concert with GM‐CSF and TGF‐β1, induces the differentiation of human CD14+ blood monocytes into cells that express LC markers: CD1a, Langerin, cutaneous lymphocyte‐associated antigen, CC chemokine receptor 6, E‐cadherin, and Birbeck granules. The resulting cells display phagocytic activity and chemotaxis to macrophage inflammatory protein‐1α (MIP‐1α). In response to CD40 ligand and tumor necrosis factor α, the cells acquire a mature phenotype of dendritic cells that is characterized by up‐regulation of human leukocyte antigen (HLA)‐ABC, HLA‐DR, CD80, CD86, CD40, and CD54 and appearance of CD83. These cells in turn show chemotaxis toward MIP‐1β and elicit activation of CD8+ T cells and T helper cell type 1 polarization of CD4+ T cells. Thus, blood monocytes can give rise to LCs upon exposure to the skin cytokine environment consisting of Delta‐1, GM‐CSF, and TGF‐β1, which may be, in part, relevant to the development of human epidermal LCs. Our results extend the functional scope of Notch ligand δ‐1 in human hematopoiesis.

Determination of Cellularly Processed HLA-A2402-Restricted Novel CTL Epitopes Derived from Two Cancer Germ Line Genes, MAGE-A4 and SAGE

Purpose: For identification of CTL epitopes useful for cancer vaccines, it is crucial to determine whether cognate epitopes are presented on the cell surface of target cancer cells through natural processing of endogenous proteins. For this purpose, we tried to use the cellular machinery of both mice and human to define naturally processed CTL epitopes derived from two “cancer germ line” genes, MAGE-A4 and SAGE. Experimental Design: We vaccinated newly produced HLA-A2402 transgenic mice with DNA plasmids encoding target antigens. Following screening of synthesized peptides by splenic CD8+ T cells of vaccinated mice, we selected candidate epitopes bound to HLA-A2402. We then examined whether human CD8+ T cells sensitized with autologous CD4+ PHA blasts transduced by mRNA for the cognate antigens could react with these selected peptides in an HLA-A2402-restricted manner. Results: After DNA vaccination, murine CD8+ T cells recognizing MAGE-A4143-151 or SAGE715-723 in an HLA-A2402-restricted manner became detectable. Human CTLs specific for these two peptides were generated after sensitization of HLA-A2402-positive CD8+ T cells with autologous CD4+ PHA blasts transduced with respective mRNA. CTL clones were cytotoxic toward tumor cell lines expressing HLA-A2402 and cognate genes. Taken together, these CTL epitopes defined in HLA-A24 transgenic mice are also processed and expressed with HLA-A2402 in human cells. The presence of SAGE715-723-specific precursors was observed in HLA-A2402-positive healthy individuals. Conclusions: Two novel HLA-A2402-restricted CTL epitopes, MAGE-A4143-151 and SAGE715-723, were identified. Our approach assisted by cellular machinery of both mice and human could be widely applicable to identify naturally processed CTL epitopes.

Adoptive Transfer of MAGE-A4 T-cell Receptor Gene-Transduced Lymphocytes in Patients with Recurrent Esophageal Cancer

Purpose: Preparative lymphodepletion, the temporal ablation of the immune system, has been reported to promote persistence of transferred cells along with increased rates of tumor regression in patients treated with adoptive T-cell therapy. However, it remains unclear whether lymphodepletion is indispensable for immunotherapy with T-cell receptor (TCR) gene–engineered T cells. Experimental Design: We conducted a first-in-man clinical trial of TCR gene-transduced T-cell transfer in patients with recurrent MAGE-A4–expressing esophageal cancer. The patients were given sequential MAGE-A4 peptide vaccinations. The regimen included neither lymphocyte-depleting conditioning nor administration of IL2. Ten patients, divided into 3 dose cohorts, received T-cell transfer. Results: TCR-transduced cells were detected in the peripheral blood for 1 month at levels proportional to the dose administered, and in 5 patients they persisted for more than 5 months. The persisting cells maintained ex vivo antigen-specific tumor reactivity. Despite the long persistence of the transferred T cells, 7 patients exhibited tumor progression within 2 months after the treatment. Three patients who had minimal tumor lesions at baseline survived for more than 27 months. Conclusions: These results suggest that TCR-engineered T cells created by relatively short-duration in vitro culture of polyclonal lymphocytes in peripheral blood retained the capacity to survive in a host. The discordance between T-cell survival and tumor regression suggests that multiple mechanisms underlie the benefits of preparative lymphodepletion in adoptive T-cell therapy. Clin Cancer Res; 21(10); 2268–77. ©2015 AACR.

siRNA-mediated silencing of PD-1 ligands enhances tumor-specific human T-cell effector functions

Adoptive cell therapy using tumor-specific T cells is a promising strategy for treating patients with malignancy. However, accumulating evidences have demonstrated that optimal function of tumor-reactive T cells is often attenuated by negative regulatory signal(s) delivered through receptors, such as cytotoxic T-lymphocyte antigen 4 (CTLA-4), programmed death 1 (PD-1), and their cognate ligands. Although systemic blocking of these molecules needs careful attention on the risk of uncontrolled immune activation, selective inhibition of negative signals in tumor-specific T cells by their genetic modification is an attractive approach to overcome immunological suppression in cancer patients. Here, we demonstrate the improved effector functions of tumor-specific CD4+ and CD8+ human T cells by small interfering RNA (siRNA) -mediated silencing of PD-1 ligands, PD-L1 or PD-L2. Tumor antigen MAGE-A4-specific human T-cell clones upregulated the expression of PD-1 ligands upon activation. siRNA-mediated knockdown of PD-L1 or -L2 enhanced the interferon-γ production and antigen-specific cytotoxicity of these cells. Peripheral blood mononuclear cells transduced with a retroviral vector encoding MAGE-A4-specific T-cell receptor α/β chains also increased their effector functions by this modification. These results suggest that siRNA-mediated knockdown of PD-1 ligands is an attractive strategy to inhibit a negative regulatory mechanism of tumor-specific T cells resulting in enhanced efficacy of adoptive T-cell therapy of cancer using genetically modified autologous lymphocytes.

Intratumoral Injection of Propionibacterium acnes Suppresses Malignant Melanoma by Enhancing Th1 Immune Responses

Malignant melanoma (MM) is an aggressive cutaneous malignancy associated with poor prognosis; many putatively therapeutic agents have been administered, but with mostly unsuccessful results. Propionibacterium acnes (P. acnes) is an aerotolerant anaerobic gram-positive bacteria that causes acne and inflammation. After being engulfed and processed by phagocytes, P. acnes induces a strong Th1-type cytokine immune response by producing cytokines such as IL-12, IFN-γ and TNF-α. The characteristic Th2-mediated allergic response can be counteracted by Th1 cytokines induced by P. acnes injection. This inflammatory response induced by P. acnes has been suggested to have antitumor activity, but its effect on MM has not been fully evaluated. We analyzed the anti-tumor activity of P. acnes vaccination in a mouse model of MM. Intratumoral administration of P. acnes successfully protected the host against melanoma progression in vivo by inducing both cutaneous and systemic Th1 type cytokine expression, including TNF-α and IFN-γ, which are associated with subcutaneous granuloma formation. P. acnes-treated tumor lesions were infiltrated with TNF-α and IFN-γ positive T cells. In the spleen, TNF-α as well as IFN-γ producing CD8+T cells were increased, and interestingly, the number of monocytes was also increased following P. acnes administration. These observations suggest that P. acnes vaccination induces both systemic and local antitumor responses. In conclusion, this study shows that P. acnes vaccination may be a potent therapeutic alternative in MM.

IL-2-deprivation and TGF-β are two non-redundant suppressor mechanisms of CD4+CD25+ regulatory T cell which jointly restrain CD4+CD25− cell activation

The benefits of immunotherapy by regulatory T (Treg) cells are unpredictable partially due to the uncertainty of their suppressive mechanism. In fact, various suppressive mechanisms have been proposed but each remains controversial. To better understand Treg-mediated suppression, we have investigated factors which may influence the suppressive effects. In an in vitro suppression assay, over-expression of anti-apoptotic Bcl2 enhancing survival of conventional T responder cells (Tconvs) did not subvert Treg-mediated suppression. In contrast, enhancing activation of Tconvs by increasing the potency of calcium signals completely abrogated Treg-mediated suppression. While Tregs were incapable of suppressing already activated Tconvs, they prevented expression of activation markers on naïve Tconvs during activation, thereby indicating that Tregs mediate suppression through controlling early activation stage. Interestingly, IL-2 deprivation or TGF-beta, two suppressive mechanisms, did not effectively inhibit Tconv activation and proliferation when applied alone. In contrast, IL-2 deprivation combined with TGF-beta suppressed Tconv activation as potently as Tregs. More importantly, in the transwell system, that separates Tregs from Tconvs, TGF-beta contributed to Treg suppression under IL-2 depriving condition. In conclusion, these two suppressive mechanisms acting in concert may be necessary to effectively restrain the early activation of Tconvs.

A Dynamic Dual Role of IL-2 Signaling in the Two-Step Differentiation Process of Adaptive Regulatory T Cells

The molecular mechanism of the extrathymic generation of adaptive, or inducible, CD4+Foxp3+ regulatory T cells (iTregs) remains incompletely defined. We show that exposure of splenic CD4+CD25+Foxp3− cells to IL-2, but not other common γ-chain cytokines, resulted in Stat5 phosphorylation and induced Foxp3 expression in ∼10% of the cells. Thus, IL-2/Stat5 signaling may be critical for Foxp3 induction in peripheral CD4+CD25+Foxp3– iTreg precursors. In this study, to further define the role of IL-2 in the formation of iTreg precursors as well as their subsequent Foxp3 expression, we designed a two-step iTreg differentiation model. During the initial “conditioning” step, CD4+CD25−Foxp3− naive T cells were activated by TCR stimulation. Inhibition of IL-2 signaling via Jak3–Stat5 was required during this step to generate CD4+CD25+Foxp3− cells containing iTreg precursors. During the subsequent Foxp3-induction step driven by cytokines, IL-2 was the most potent cytokine to induce Foxp3 expression in these iTreg precursors. This two-step method generated a large number of iTregs with relatively stable expression of Foxp3, which were able to prevent CD4+CD45RBhigh cell–mediated colitis in Rag1−/− mice. In consideration of this information, whereas initial inhibition of IL-2 signaling upon T cell priming generates iTreg precursors, subsequent activation of IL-2 signaling in these precursors induces the expression of Foxp3. These findings advance the understanding of iTreg differentiation and may facilitate the therapeutic use of iTregs in immune disorders.