Krishnamurthy Thyagarajan

The Inducible Costimulator Augments Tc17 Cell Responses to Self and Tumor Tissue

The inducible costimulator (ICOS) plays a key role in the development of Th17 cells, but its role in the development and antitumor activity of IL-17–producing CD8+ T cells (Tc17) remains unknown. We found that ICOS costimulation was important for the functional maintenance, but not differentiation, of Tc17 cells in vitro. Blocking the ICOS pathway using an antagonist mAb or by using recipient mice genetically deficient in the ICOS ligand reduced the antitumor activity of adoptively transferred Tc17 cells. Conversely, activating Tc17 cells with an ICOS agonist in vitro enhanced their capacity to eradicate melanoma and induce autoimmune vitiligo when infused into mice. However, ICOS stimulation did not augment the antitumor activity of IL-2 expanded T cells. Additional investigation revealed that ICOS stimulation not only increased IL-2Rα, CXCR3, and IL-23R expression on Tc17 cells, but also dampened their expression of suppressive molecule CD39. Although Tc17 cells activated with an ICOS agonist cosecreted heightened IL-17A, IL-9, and IFN-γ, their therapeutic effectiveness was critically dependent on IFN-γ production. Depletion of IL-17A and IL-9 had little impact on antitumor Tc17 cells activated with an ICOS agonist. Collectively, our work reveals that the ICOS pathway potentiates the antitumor activity of adoptively transferred Tc17 cells. This work has major implications for the design of vaccine, Ab and cell-based therapies for autoimmunity, infectious disease, and cancer.

Reducing CD73 Expression by IL1β-Programmed Th17 Cells Improves Immunotherapeutic Control of Tumors

T cells of the T helper (Th)17 subset offer promise in adoptive T-cell therapy for cancer. However, current protocols for ex vivo programming of Th17 cells, which include TGFβ exposure, increase the expression of CD39 and CD73, two cell surface ATP ectonucleotidases that reduce T-cell effector functions and promote immunosuppression. Here, we report that ATP-mediated suppression of IFNγ production by Th17 cells can be overcome by genetic ablation of CD73 or by using IL1β instead of TGFβ to program Th17 cells ex vivo. Th17 cells cultured in IL1β were also highly polyfunctional, expressing high levels of effector molecules and exhibiting superior short-term control of melanoma in mice, despite reduced stem cell-like properties. TGFβ addition at low doses that did not upregulate CD73 expression but induced stemness properties drastically improved the antitumor effects of IL1β-cultured Th17 cells. Effector properties of IL1β-dependent Th17 cells were likely related to their high glycolytic capacity, since ex vivo programming in pyruvate impaired glycolysis and antitumor effects. Overall, we show that including TGFβ in ex vivo cultures used to program Th17 cells blunts their immunotherapeutic potential and demonstrate how this potential can be more fully realized for adoptive T-cell therapy.

Promoting Thiol Expression Increases the Durability of Antitumor T-cell Functions

Ex vivo-expanded CD8(+) T cells used for adoptive immunotherapy generally acquire an effector memory-like phenotype (TEM cells). With regard to therapeutic applications, two undesired features of this phenotype in vivo are limited persistence and reduced antitumor efficacy, relative to CD8(+) T cells with a central memory-like phenotype (TCM cells). Furthermore, there is incomplete knowledge about all the differences between TEM and TCM cells that may influence tumor treatment outcomes. Given that TCM cells survive relatively longer in oxidative tumor microenvironments, we investigated the hypothesis that TCM cells possess relatively greater antioxidative capacity than TEM cells. Here, we report that TCM cells exhibit a relative increase compared with TEM cells in the expression of cell surface thiols, a key target of cellular redox controls, along with other antioxidant molecules. Increased expression of redox regulators in TCM cells inversely correlated with the generation of reactive oxygen and nitrogen species, proliferative capacity, and glycolytic enzyme levels. Notably, T-cell receptor-transduced T cells pretreated with thiol donors, such as N-acetyl cysteine or rapamycin, upregulated thiol levels and antioxidant genes. A comparison of antitumor CD8(+) T-cell populations on the basis of surface thiol expression showed that thiol-high cells persisted longer in vivo and exerted superior tumor control. Our results suggest that higher levels of reduced cell surface thiols are a key characteristic of T cells that can control tumor growth and that profiling this biomarker may have benefits to adoptive T-cell immunotherapy protocols.

A role for apoptosis-inducing factor in T cell development

The mitochondrial flavoprotein Aif facilitates murine thymocyte development by reducing oxidative stress.

Lack of p53 Augments Antitumor Functions in Cytolytic T Cells.

Repetitive stimulation of T-cell receptor (TCR) with cognate antigen results in robust proliferation and expansion of the T cells, and also imprints them with replicative senescence signatures. Our previous studies have shown that life-span and antitumor function of T cells can be enhanced by inhibiting reactive oxygen species (ROS) or intervening with ROS-dependent JNK activation that leads to its activation-induced cell death. Because tumor suppressor protein p53 is also a redox active transcription factor that regulates cellular ROS generation that triggers downstream factor-mediating apoptosis, we determined if p53 levels could influence persistence and function of tumor-reactive T cells. Using h3T TCR transgenic mice, with human tyrosinase epitope-reactive T cells developed on p53 knockout (KO) background, we determined its role in regulating antitumor T-cell function. Our data show that as compared with h3T cells, h3T-p53 KO T cells exhibited enhanced glycolytic commitment that correlated with increased proliferation, IFNγ secretion, cytolytic capacity, expression of stemness gene signature, and decreased TGF-β signaling. This increased effector function correlated to the improved control of subcutaneously established murine melanoma after adoptive transfer of p53-KO T cells. Pharmacological inhibition of human TCR-transduced T cells using a combination of p53 inhibitors also potentiated the T-cell effector function and improved persistence. Thus, our data highlight the key role of p53 in regulating the tumor-reactive T-cell response and that targeting this pathway could have potential translational significance in adoptive T-cell therapy. Cancer Res; 76(18); 5229-40. ©2016 AACR.

A Superantigen Interacts with Leishmanial Infection in Antigen-Presenting Cells to Regulate Cytokine Commitment of Responding CD4 T Cells

Germ-line retroviral insertions in vertebrate genomes are implicated in the modulation of host immune responses. We demonstrate that CBA/J mice, which carry the proviral integrants mammary tumor virus locus 6 (Mtv6) and mammary tumor virus locus 7 (Mtv7), are less resistant to infection with the protozoan pathogen Leishmania major compared with closely related but Mtv6-negative and Mtv7-negative CBA/CaJ mice. Although both strains generated comparable L. major-specific CD4 T cell frequencies, T cells from CBA/J mice made much less interferon γ (IFN-γ). L. major-infected CBA/CaJ dendritic cells primed L. major-specific and allospecific IFN-γ-producing CD4 T cells better in vivo and in vitro, respectively, than CBA/J dendritic cells did. L. major susceptibility appeared to be associated with Mtv7, and v-Sag-7 superantigen expression and L. major infection together reduced the ability of an antigen-presenting cell line to prime alloresponder CD4 T cells for IFN-γ commitment. These data show that an endogenous superantigen can interact with L. major infection to alter antigen-presenting cell properties and modulate T cell cytokine commitment, with implications for human susceptibility to infectious diseases.

Anti-oxidant capacity and anti-tumor T cell function: A direct correlation.

Improving persistence and sustained function of effector CD8+ T cell response is key for achieving significant tumor control in adoptive T cell immunotherapy protocols. Our recent report shows that high anti-oxidant property is central to potent anti-tumor effector T cells, and directly correlates to CD62Lhi central memory, low glycolytic and low mitochondrial membrane potential phenotype, all of which may be linked and contribute to better tumor control.

Hematopoietic Stem Cells as a Novel Source of Dental Tissue Cells

While earlier studies have suggested that cells positive for hematopoietic markers can be found in dental tissues, it has yet to be confirmed. To conclusively demonstrate this, we utilized a unique transgenic model in which all hematopoietic cells are green fluorescent protein+ (GFP+). Pulp, periodontal ligament (PDL) and alveolar bone (AvB) cell culture analysis demonstrated numerous GFP+ cells, which were also CD45+ (indicating hematopoietic origin) and co-expressed markers of cellular populations in pulp (dentin matrix protein-1, dentin sialophosphoprotein, alpha smooth muscle actin [ASMA], osteocalcin), in PDL (periostin, ASMA, vimentin, osteocalcin) and in AvB (Runx-2, bone sialoprotein, alkaline phosphatase, osteocalcin). Transplantation of clonal population derived from a single GFP+ hematopoietic stem cell (HSC), into lethally irradiated recipient mice, demonstrated numerous GFP+ cells within dental tissues of recipient mice, which also stained for markers of cell populations in pulp, PDL and AvB (used above), indicating that transplanted HSCs can differentiate into cells in dental tissues. These hematopoietic-derived cells deposited collagen and can differentiate in osteogenic media, indicating that they are functional. Thus, our studies demonstrate, for the first time, that cells in pulp, PDL and AvB can have a hematopoietic origin, thereby opening new avenues of therapy for dental diseases and injuries.

Quality of CTL Therapies: A Changing Landscape

The identification and cloning of tumor-associated antigens (TAA) has led to clinical trials using vaccines designed to boost the host anti-tumor immune response. Impressive clinical responses have also been documented in melanoma patients treated with these tumor-reactive T cells. These studies and others indicate the potential of T cells for their use in the adoptive therapy of cancer. However, technical issues related to the generation of a large number of tumor-specific T cells have significantly restricted the use of this promising approach. Moreover, only limited success has been achieved in terms of tumor regression or patient survival in numerous other immunotherapy trials. Evidences suggest that various tumor-escape strategies such as defects in antigen presentation, tumor-induced immunosuppression, induction of T-cell death, T-cell receptor dysfunction, the presence of tolerogenic dendritic cells and regulatory T cells undermine the effectiveness of adoptively transferred T cells. Thus, a better understanding for eliciting effective anti-tumor immunity that leads to cancer regression in all patients is needed. Herein, we discuss the recent developments aimed at overcoming the constraints that exist and are changing the landscape for effectively employing adoptive T cell therapy to treat cancer.