Engineering T Cell Trafficking and Function for Enhanced Cancer Immunotherapy

In the past decades, breakthroughs in cancer immunotherapy have led to unprecedented clinical responses in patients with advanced-stage cancers that would otherwise be fatal. However, treatment of many solid organ malignancies with highly immunosuppressive tumor microenvironment (TME) remains challenging. Tumors develop a number of mechanisms to prevent effector T-cells from reaching tumors and to suppress their function. T-cell infiltration into solid tumor, a key limiting factor for efficacious cancer immunotherapy, has been demonstrated to be associated with good clinical outcomes in various cancer immunotherapies. Safe and effective strategies to improve T-cell infiltration and augment T-cell expansion and function in solid tumors are highly desired to enhance the clinical response rate of cancer immunotherapies in the treatment of solid tumors. Disruption of chemotaxis of lymphocytes is likely a main contributing factor for effector T-cell exclusion; chemokines are known to play a critical role in orchestrating T-cell trafficking and tumor infiltration. Here, we developed a TME-responsive nanogel (NG) based on a novel carrier-free delivery strategy to effectively and specifically co-deliver T-cell recruiting chemokines and immunostimulatory cytokines in order to enhance infiltration and function of effector T-cells in solid tumors. In the preliminary studies, a chemokine (e.g. CCL19) and a cytokine (IL-2) were chemically co-crosslinked with a redox responsive linker to form the binary protein nanogels (BNGs). These BNGs had exceptionally high loading capacity of cytokines and chemokines and controlled size. BNGs released native cytokine/chemokine proteins in response to increased reduction which is one of the biochemical characteristics of TME, and thus enabled tumor-specific delivery of the incorporated cytokines and chemokines. In vitro chemotaxis assays showed that the released chemokines from BNG possessed the similar chemotactic ability in recruiting activated T-cells. Preliminary in vivo study in subcutaneous B16F10 mouse melanoma in C57BL/6 mice showed that intratumorally administration of BNG enhanced T-cell infiltration and improved immunosuppressive TME compared to free cytokines or chemokines at equivalent doses. In future, we first plan to further improve the controlled formulation of chemokine NG by complexing chemokines with anionic polysaccharides and stabilizing chemokines with non-functional proteins/polymers or recombinantly expressing chemokine-Fc fusion. Then, we plan to enhance the potency of NG for T-cell infiltration and function by delivery combinational chemokines and by activating LTÎ²R signaling with LIGHT delivery. Furthermore, to improve the tumor-targeting effect of NG, we will synthesize cross-linkers in response to different characteristics of TME, prolong the half-life of NG for increased tumor targeting and hijack tumor-related immune cells. Finally, we will try to overcome the immunosuppression in TME by combining NG with checkpoint blockade or adoptive T-cell immunotherapies.

Therapeutic Immunomodulation of the Lymphoid-like Tumor Environment Using Nanoparticulate Formulations

Iraklis Kourtis

Cancer is a leading cause of death worldwide. Understanding the underlying mechanisms that lead to tumor escape and evasion is pivotal for the design of new therapeutic applications. This thesis takes an immunobioengineering approach, and navigates through identifying the immunological parameters relevant in the tumor microenvironment, proposing and developing a strategy in response to address these parameters using nanosized drug and antigen carriers. It is widely accepted that changes in the immunological equilibriumof the tumor microenvironment are crucial for the progression, dissemination and metastasis of a developing tumor. Motivated by tumors' natural secretion of CCL21, a chemokine known for dendritic (DC) migration towards the lymphatics, and for attracting DC and T cells in the lymph node (LN), we perturbed the physiological secretion of CCL21 of B16-F10 melanomas, deriving both a knock-down (CCL21low) and an over-expressing (CCL21high) variant. Interestingly, in immunocompetent mice, growth in CCL21-secreting tumors had an advantage over the CCL21low sub-clones and was CCR7 dependent. CCL21low tumors harbored more antigen specific T cells, while CCL21-secreting, more T regulatory cells (Tregs), which also correlated with subsequent biochemical polarization. Moreover, CCL21-secreting tumors formed a reticular fibroblastic (FRC) network (ERTR7+gp38+CCL21+) reminiscent of the lymphoid tissue of the paracortex (T cell zone) within LNs. The lymphoidlike stroma was orchestrated by the recruitment of CCR7+ adult lymphoid tissue inducers (LTis), responsible for LN formation during embryogenesis, present only in the CCL21-secreting tumors. In mice lacking LTis (Rorc(γt)-deficient) control tumors displayed impaired growth, suggesting that tumor growth is stroma dependent. In addition, the stroma of control or CCL21high tumors was infiltrated by more myeloid suppressor cells (MDSCs) than in CCL21low variant. MDSCs are a heterogeneous population of immature myeloid precursor cells that repress T cell activation and antigen presentation in chronic inflammation and cancer, hampering the efficacy of anti-tumoral vaccinations. CCL21's ability to protect allografts was further demonstrated in non-syngeneic recipients and in ectopically CCL21 transduced βTC tumor models. By mimicking secondary lymphoid organs, tumors may hi-jack and modulate the immune response from immunogenic to tolerogenic to allow for growth and metastasis. Intrigued by the excessive stroma infiltration of MDSCs in CCL21-secreting tumors, we performed a detailed spatiotemporal biodistribution analysis of ultrasmall (sub 50 nm) nanoparticles (NPs) in naïve and tumor bearing mice. Intradermally administered NPs rapidly drained to the LNs and spleen and persistently targetedmajor phagocytic populations that play a key role in hosting an immune response in naïve and tumor bearing mice. Furthermore, tumor-induced myeloid compartments, mainlyMDSCs, were highly targeted naturally within the tumormicroenvironment and spleen (tumor macroenvironment) 12 h post administration, without the use of site specific ligand. Following the MDSCs' natural preference towards phagocytosing NPs, and taking advantage of their excessive reductive cytoplasm, we designed a macromolecular pro-drug formulation that bears a cytotoxic payload and can be released in highly reductive microenvironments. Specifically, we engineered a reducible delivery system of 6-tioguanine (TG) in various formulations. Remarkably, bothMDSC compartments were ablated, monocytic ∼20 fold (CD11b+Ly6c+), polymorphonuclear ∼100 fold (CD11b+Ly6g+), for at least 7 d after administration in tumor bearing mice. As the bioidstribution revealed that apart from MDSCs, other antigen presenting cells (APCs) have phagocytosed NPs, we observed only a ∼2 fold decrease in APCs, suggesting that the rest could be used for vaccination. Taking into account that cancer vaccines and cancer immunotherapy rely on the efficient antigen presentation and education of naïve T cells by professional APCs, we explored the ability of NPs to deliver antigens in the appropriate sub-cellular compartment for antigen presentation and activation of T cells. Using the model antigen ovalbumin, we illustrated that exogenous antigen coupled to NPs by reducible bonds were internalized by DCs in vivo and in vitro. The conjugated antigen was preferentially released from the NPs with a reducible formulation, and was successfully presented in the major histocompatibility complex (MHC) I and II, which lead to activation and proliferation of antigen specific CD8+ and CD4+ T cells in vivo, respectively. Taking together, the nanoparticle platformcould be used efficiently for both inducing cytotoxicity and invoking an immune response. From discovery of new suppressive niches to therapeutical applications, we envisioned a two prong strategy that combined I) a modulatory regime to upset the balance of theMDSC populations both within the tumor microenvoronent and systemically with II) a cancer vaccine with the potential to significantly improve anti-tumoral therapeutic applications. This thesis demonstrated that such an approach is both possible and probable.

EPFL2012

New roles of the lymphatic endothelium in modulating adaptive immunity: implications for immune tolerance and cancer immunotherapy

Lambert Charles François Potin

Lymphatic vessels have traditionally been considered as passive conduits for interstitial fluid drainage and for immune cell trafficking to lymph nodes. In the last two decades, many studies have challenged this classical dogma: lymphatic endothelial cells (LECs) were shown to actively interact with immune cells by secreting chemokines and cytokines, and presenting antigens to T cells. These newly described functions pinpoint a multi-faceted role of LECs in orchestrating the immune response through both passive and active mechanisms. Yet, precise mechanisms leading to antigen-specific fine-tuning of the T cell response remain unexplored. Moreover, although lymphatics have been shown to play important roles in cancer, the contributions of LECs in regulating antitumor immunity have been largely overlooked by the biomedical community. This doctoral thesis aimed at filling these gaps. First, in order to investigate the mechanisms and implications of LEC antigen presentation to CD4+ T cells, we engineered a mouse model where LECs lacked the ability to present antigens to CD4+ T cells. In these mice, antigen-specific responses to vaccination were increased when compared to wild-type controls. Moreover, we demonstrated that LECs were poor inducers of CD4+ T cell activation in vitro, and that they could dampen CD4+ T cell activation by dendritic cells. Taken together, these findings suggest that LECs participate to the peripheral immune tolerance of CD4+ T cells. Second, we investigated the immunological consequences of the development of lymphatic vessels, called lymphangiogenesis, in mouse melanoma. Upon induction of tumor lymphangiogenesis, we observed striking tumor enrichment with immune cells, which resulted in a higher sensitivity of those tumors to immunotherapy. We subsequently demonstrated that inducing lymphangiogenesis in a mouse model of cold tumors, which lack immune infiltrates and do not respond to immunotherapies, could restore their responsiveness to immunotherapy treatments. Third, to predict which cancer types were the most likely to replicate the findings we obtained in mouse melanoma, we mined The Cancer Genome Atlas database for gene expression. We identified a set of cancers, such as colon adenocarcinoma and cholangiocarcinoma, where high expression of the lymphangiogenic growth factor was associated with a strong T cell signature. This doctoral thesis unveiled new immunomodulatory functions of LECs by which antigen-specific immune tolerance is induced. Additionally, it opened new avenues to target lymphatics therapeutically in cancer to potentiate immunotherapies. We believe this work contributes to demonstrating the immunological importance of LECs, and hope that lymphatics will be considered as an important immunomodulatory player of the tumor microenvironment when developing novel immunotherapies.

EPFL2018

Redox-responsive interleukin-2 nanogel specifically and safely promotes the proliferation and memory precursor differentiation of tumor-reactive T-cells

Hacer Arik, Li Tang, Lixia Wei, Yuqing Xie

Interleukin-2 (IL-2) is a potent T-cell mitogen that can adjuvant anti-cancer adoptive T-cell transfer (ACT) immunotherapy by promoting T-cell engraftment. However, the clinical applications of IL-2 in combination with ACT are greatly hindered by the severe adverse effects such as vascular leak syndrome (VLS). Here, we developed a synthetic delivery strategy for IL-2 via backpacking redox-responsive IL-2/Fc nanogels (NGs) to the plasma membrane of adoptively transferred T-cells. The NGs prepared by traceless chemical cross-linking of cytokine proteins selectively released the cargos in response to T-cell receptor activation upon antigen recognition in tumors. We found that IL-2/Fc delivered by T-cell surface-bound NGs expanded transferred tumor-reactive T-cells 80-fold more than the free IL-2/Fc of an equivalent dose administered systemically and showed no effects on tumor-infiltrating regulatory T-cell expansion. Intriguingly, IL-2/Fc NG backpacks that facilitated a sustained and slow release of IL-2/Fc also promoted the CD8(+) memory precursor differentiation and induced less T-cell exhaustion in vitro compared to free IL-2/Fc. The controlled responsive delivery of IL-2/Fc enabled the safe administration of repeated doses of the stimulant cytokine with no overt toxicity and improved efficacy against melanoma metastases in a mice model.