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

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

Exploiting lymphatic vessels for immunomodulation: Rationale, opportunities, and challenges

Lymphatic vessels are the primary route of communication from peripheral tissues to the immune system; as such, they represent an important component of local immunity. In addition to their transport functions, new immunomodulatory roles for lymphatic vessels and lymphatic endothelial cells have come to light in recent years, demonstrating that lymphatic vessels help shape immune responses in a variety of ways: promoting tolerance to self-antigens, archiving antigen for later presentation, dampening effector immune responses, and resolving inflammation, among others. In addition to these new biological insights, the growing field of immunoengineering has begun to explore therapeutic approaches to utilize or exploit the lymphatic system for immunotherapy. (C) 2017 Published by Elsevier B.V

Recruitment of CD103⁺ dendritic cells via tumor-targeted chemokine delivery enhances efficacy of checkpoint inhibitor immunotherapy

Although a clinical breakthrough for cancer treatment, it remains that a minority of patients respond to checkpoint inhibitor (CPI) immunotherapy. The composition of tumor-infiltrating immune cells has been identified as a key factor influencing CPI therapy success. Thus, enhancing tumor immune cell infiltration is a critical challenge. A lack of the chemokine CCL4 within the tumor microenvironment leads to the absence of CD103+ dendritic cells (DCs), a crucial cell population influencing CPI responsiveness. Here, we use a tumor stroma–targeting approach to deliver CCL4; by generating a fusion protein of CCL4 and the collagen-binding domain (CBD) of von Willebrand factor, we show that CBD fusion enhances CCL4 tumor localization. Intravenous CBD-CCL4 administration recruits CD103+ DCs and CD8+ T cells and improves the antitumor effect of CPI immunotherapy in multiple tumor models, including poor responders to CPI. Thus, CBD-CCL4 holds clinical translational potential by enhancing efficacy of CPI immunotherapy

Recruitment of CD103(+) dendritic cells via tumor-targeted chemokine delivery enhances efficacy of checkpoint inhibitor immunotherapy

Although a clinical breakthrough for cancer treatment, it remains that a minority of patients respond to checkpoint inhibitor (CPI) immunotherapy. The composition of tumor-infiltrating immune cells has been identified as a key factor influencing CPI therapy success. Thus, enhancing tumor immune cell infiltration is a critical challenge. A lack of the chemokine CCL4 within the tumor microenvironment leads to the absence of CD103(+) dendritic cells (DCs), a crucial cell population influencing CPI responsiveness. Here, we use a tumor stroma-targeting approach to deliver CCL4; by generating a fusion protein of CCL4 and the collagen-binding domain (CBD) of von Willebrand factor, we show that CBD fusion enhances CCL4 tumor localization. Intravenous CBD-CCL4 administration recruits CD103(+) DCs and CD8(+) T cells and improves the antitumor effect of CPI immunotherapy in multiple tumor models, including poor responders to CPI. Thus, CBD-CCL4 holds clinical translational potential by enhancing efficacy of CPI immunotherapy

Tumor-associated factors are enriched in lymphatic exudate compared to plasma in metastatic melanoma patients

Liquid biopsies allow monitoring of cancer progression and detection of relapse, but reliable biomarkers in melanoma are lacking. Because secreted factors preferentially drain to lymphatic vessels before dilution in the blood, we hypothesized that lymph should be vastly enriched in cancer biomarkers. We characterized postoperative lymphatic exudate and plasma of metastatic melanoma patients after lymphadenectomy and found a dramatic enrichment in lymphatic exudate of tumor-derived factors and especially extracellular vesicles containing melanoma-associated proteins and miRNAs, with unique protein signatures reflecting early versus advanced metastatic spread. Furthermore, lymphatic exudate was enriched in memory T cells, including tumor-reactive CD137(+) and stem cell-like types. In mice, lymph vessels were the major route of extracellular vesicle transport from tumors to the systemic circulation. We suggest that lymphatic exudate provides a rich source of tumor-derived factors for enabling the discovery of novel biomarkers that may reflect disease stage and therapeutic response

Targeted antibody and cytokine cancer immunotherapies through collagen affinity

Cancer immunotherapy with immune checkpoint inhibitors (CPIs) and interleukin-2 (IL-2) has demonstrated clinical efficacy but is frequently accompanied with severe adverse events caused by excessive and systemic immune system activation. Here, we addressed this need by targeting both the CPI antibodies anti-cytotoxic T lymphocyte antigen 4 antibody (alpha CTLA4) + anti-programmed death ligand 1 antibody (alpha PD-L1) and the cytokine IL-2 to tumors via conjugation (for the antibodies) or recombinant fusion (for the cytokine) to a collagen-binding domain (CBD) derived from the blood protein von Willebrand factor (VWF) A3 domain, harnessing the exposure of tumor stroma collagen to blood components due to the leakiness of the tumor vasculature. We show that intravenously administered CBD protein accumulated mainly in tumors. CBD conjugation or fusion decreases the systemic toxicity of both alpha CTLA4+alpha PD-L1 combination therapy and IL-2, for example, eliminating hepatotoxicity with the CPI molecules and ameliorating pulmonary edema with IL-2. Both CBD-CPI and CBD-IL-2 suppressed tumor growth compared to their unmodified forms in multiple murine cancer models, and both CBD-CPI and CBD-IL-2 increased tumor-infiltrating CD8(+) T cells. In an orthotopic breast cancer model, combination treatment with CPI and IL-2 eradicated tumors in 9 of 13 animals with the CBD-modified drugs, whereas it did so in only 1 of 13 animals with the unmodified drugs. Thus, the A3 domain of VWF can be used to improve safety and efficacy of systemically administered tumor drugs with high translational promise