A Machine-Generated View of the Role of Blood Glucose Levels in the Severity of COVID-19

SARS-CoV-2 started spreading toward the end of 2019 causing COVID-19, a disease that reached pandemic proportions among the human population within months. The reasons for the spectrum of differences in the severity of the disease across the population, and in particular why the disease affects more severely the aging population and those with specific preconditions are unclear. We developed machine learning models to mine 240,000 scientific articles openly accessible in the CORD-19 database, and constructed knowledge graphs to synthesize the extracted information and navigate the collective knowledge in an attempt to search for a potential common underlying reason for disease severity. The machine-driven framework we developed repeatedly pointed to elevated blood glucose as a key facilitator in the progression of COVID-19. Indeed, when we systematically retraced the steps of the SARS-CoV-2 infection, we found evidence linking elevated glucose to each major step of the life-cycle of the virus, progression of the disease, and presentation of symptoms. Specifically, elevations of glucose provide ideal conditions for the virus to evade and weaken the first level of the immune defense system in the lungs, gain access to deep alveolar cells, bind to the ACE2 receptor and enter the pulmonary cells, accelerate replication of the virus within cells increasing cell death and inducing an pulmonary inflammatory response, which overwhelms an already weakened innate immune system to trigger an avalanche of systemic infections, inflammation and cell damage, a cytokine storm and thrombotic events. We tested the feasibility of the hypothesis by manually reviewing the literature referenced by the machine-generated synthesis, reconstructing atomistically the virus at the surface of the pulmonary airways, and performing quantitative computational modeling of the effects of glucose levels on the infection process. We conclude that elevation in glucose levels can facilitate the progression of the disease through multiple mechanisms and can explain much of the differences in disease severity seen across the population. The study provides diagnostic considerations, new areas of research and potential treatments, and cautions on treatment strategies and critical care conditions that induce elevations in blood glucose levels.

New immunomodulatory roles of lymphatic endothelium and implications for immunotherapy

Efthymia Vokali

The lymphatic system serves a critical role in fluid homeostasis, lipid metabolism and immune surveillance. The growing appreciation of its implication in various diseases challenges the conventional view of lymphatics as a passive transport system. Traditionally, the lymphatic endothelium has been perceived as a structural scaffold with certain immunological functions but no active involvement in immunomodulation. In the lymph nodes (LNs), the main sites of immune regulation in the periphery, lymphatic endothelial cells (LECs) come to close contact with immune cells, suggesting potential interactions. Indeed, LECs have been recently shown to suppress dendritic cell maturation and present peripheral tissue and tumor antigen for CD8+ T cell deletion. While LECs have only begun to be acknowledged as active regulators of immunity, their function and relative contribution in shaping immune responses is as yet poorly understood. This thesis aimed to elucidate the direct role of LECs in the induction of CD8+ T cell immunity and tolerance. First, we demonstrated that murine LECs can actively scavenge and cross-present exogenous antigen to cognate CD8+ T cells under non-inflamed conditions. By utilizing an in vitro coculture system and the model antigen ovalbumin, we investigated the antigen-specific interactions between LECs and CD8+ T cells. LEC-educated CD8+ T cells proliferated, exhibiting an activated phenotype, however, they displayed early-generation apoptosis and failed to produce effector cytokines. Our findings establish LECs as antigen-presenting cells and suggest that they may assist in the maintenance of peripheral tolerance during homeostasis. The particular differentiation state of LEC-educated CD8+ T cells prompted us to investigate whether they are terminally tolerized or they could escape the dysfunctional state. We demonstrated that LEC-educated CD8+ T cells adopted a distinct phenotype with central memory-like characteristics and shared multiple functional properties with memory cells. Upon antigen re-encounter, LEC-educated CD8+ T cells mounted proliferative responses and generated cytotoxic effector cells. More importantly, they participated in anti-infectious immunity while preserving a secondary-memory persistent population. Our findings reveal a unique differentiation state of antigen-experienced CD8+ T cells, generated under steady-state conditions, which remain inactive but can be functionally reactivated upon antigenic inflammatory challenge. This previously unanticipated feature of LECs triggered questions for their antigen-presenting function in an inflammatory setting. We asked whether the previously observed extensive proliferation of LECs in the LN during inflammation might directly influence the induction of immunity. We employed an anti-VEGFR3 blocking antibody to inhibit LEC proliferation and thus, reduce the number of LECs following vaccine immunization. Alternatively, we generated the Prox1-Cre-DTR mouse model, allowing for specific ablation of LECs following administration of diphtheria toxin in vivo. Our findings advance our perception of the relative contribution of LECs in the establishment of adaptive immunity. This thesis elucidates the multifaceted immunological role of LECs and strongly suggests the importance of harnessing their immunomodulatory function to enhance current vaccines and immunotherapeutic strategies. Looking forward, our work will contribute to future advances in the clinic.

EPFL2016

The contribution of the host stress response to the pathogenesis of Pseudomonas entomophila in the Drosophila intestine

Sveta Chakrabarti

Recently, several studies done in Drosophila have revealed that efficient and rapid recovery from bacterial infection in the gut is possible only when bacterial clearance by the immune system is coordinated with repair through renewal of the epithelium damaged by infection. In this thesis, I have analyzed how the entomopathogenic bacterium Pseudomonas entomophila affects the immune response and epithelium renewal. A microarray analysis first showed that P. entomophila is recognized by the Drosophila immune system since ingestion of this bacterium stimulated the expression of antimicrobial peptide genes by the Imd pathway. In addition, stress and damage related pathways were strongly induced by P. entomophila, which correlate with its capacity to inflict severe damage. While antibacterial genes were induced in the gut following infection with P. entomophila, the immune response was not productive due to a general inhibition of translation that affected all the newly synthesized transcripts. Furthermore, the blockage of translation also inhibited the repair program by blocking the production of JAK-STAT ligands (upd3, upd2) and growth factors, which stimulate the intestinal stem cells proliferation and differentiation. I next analyzed the pathways that link cellular damage to reduction of translation. Using a genetic approach, I showed that inhibition of translation was induced by two signaling pathways: i) the phosphorylation of elongation initiation factor 2α (eIF2α) by the stress kinase GCN2 and ii) the inhibition of the TOR pathway by the AMPK kinase. Both kinases sense metabolic deprivation, suggesting that cellular damages induced by P. entomophila induce a state of “starvation”. Inhibition of translation is usually an adaptive cellular response to adjust the metabolism to the energy status of the cells. The observation that GCN2-deficient flies survived better than wild-type flies to P. entomophila indicates that pathogenesis is linked to an over-activation of stress pathways that usually help to endure the consequence of an infection. In this in vivo model of infection, I also showed that the reduction of translation was a consequence of cellular damage to the intestine caused by host-derived reactive oxygen species (through the activity of Duox) and by the direct action of a pore-forming toxin produced by the pathogen. As a consequence of this translational arrest, flies succumbed P. entomophila infection because they were unable to repair gut damage. Finally, I showed that inhibition of translation also had a strong influence on innate immune responses observed upon P. entomophila infection. The specific activation of a systemic immune response (antimicrobial peptides produced by the fat body) observed upon P. entomophila infection could be recapitulated by feeding flies with a non-lethal pathogen and an inhibitor of translation. Hence, I showed translation inhibition could be an important feature that shapes the immune response. The p38 MAPK family is involved in stress and immunity in both mammals and Drosophila. In Drosophila, three p38-MAPK-encoding genes, p38a, p38b and p38c, have been identified but their function in the gut immune response is poorly characterized. In the second part of my thesis, I have analyzed the role of these three p38 MAPKs in Drosophila intestinal immunity, especially p38c, which is strongly enriched in the gut. I first confirmed that the three p38 are involved kinases are involved in the defense to oral infection with pathogenic (but non-lethal) bacteria such as Erwinia carotovora 15. Surprisingly, p38c mutant flies were more resistant to P. entomophila and did not show the reduction in translation observed in wild-type flies. Interestingly, the transcription of the ROS producing enzyme Duox was reduced in p38c raising the hypothesis that p38 contributes to P. entomophila pathogenicity by activating Duox. Furthermore, I have obtained preliminary data indicating that p38c and the transcription factor ATF-3 act in the same pathway contributing the host immune response and lipid metabolism. Together, my thesis reveals the complex cross-talks between stress and immune pathways during microbial infection. While, it shows that stress pathways usually contribute to endure the damage caused by infection, excessive activation of these pathways can contribute to pathogenesis.

EPFL2013

Targeting and Modulating Tumor-Associated Sites with Novel Nanoparticle-Based Immunotherapies

Laura Jeanbart

Cancer is a global disease and a leading cause of death worldwide. While surgery, radiotherapy and chemotherapy comprise the classical tools to eradicate tumors, they do not cure cancer, cannot prevent metastases, lead to side effects, and most importantly they do not instruct the patientʼs immune system to recognize and fight tumor cells. Since the discovery of the immune systemʼs implication in cancer, immunotherapies, which aim at using and educating the immune system to fight and reject cancer, have come to complement classical tumor-debulking methods. A major goal of immunotherapy is to induce or activate effector cytotoxic CD8+ T lymphocytes that can infiltrate and kill the tumor while overcoming immune suppressive mechanisms, which impede their efficacy. Moreover, cancer immunotherapies aim at inducing memory to tumor antigens to prevent relapse or metastases, which traditional therapies cannot do. Dendritic cell (DC) targeting and activation are key for inducing adaptive immunity. Our laboratory has developed synthetic nanoparticles (NPs) capable of draining through lymphatics to target skin-draining lymph nodes (LNs) and being phagocytosed by resident antigen-presenting cells (APCs) upon intradermal injection. We developed a reproducible method to conjugate tumor antigens to NPs and co-delivered them with CpG-conjugated NPs. We found that a NP vaccine composed of a single melanoma-derived peptide (TRP- 2180-188) led to dramatic tumor growth delay in melanoma and was more efficient than a NP vaccine containing several tumor antigens from whole tumor cell lysate (TL). These findings contradicted our hypothesis that immunization with TL might lead to a broader T cell response and hence improved therapeutic outcomes. Additionally, we found that the dose of CpG could modulate the magnitude of the therapeutic outcomes in both single epitope and multiple antigen based NP-vaccines. Considering the efficacy of the developed NP vaccines, we used them as a tool to ask a fundamental and extremely relevant question regarding the influence of vaccine administration site on clinical efficacy: is it therapeutically more beneficial to target a tumor- draining lymph node (tdLN), which is immune suppressed but tumor antigen-primed, or a non-tdLN, which is neither suppressed nor primed by the tumor? We found that targeting the tdLN with NP vaccines led to significantly enhanced therapeutic outcomes in two different tumor models over targeting a non-tdLN, and that efficacy relied on NP conjugation of antigen and adjuvant. This suggested that antigen drainage from the tumor might be available to APCs in the tdLN and we further hypothesized that therapies that lead to immunogenic tumor cell death might synergize with a tdLN-targeted adjuvant approach. While cytotoxic modalities, such as chemotherapy and radiotherapy, have traditionally been used for their ability to kill tumor cells, tumor cells shed antigens and debris upon cell death that drain to the tdLN. Consistent with our hypothesis, targeting an adjuvant to the tdLN enhanced therapeutic benefits of chemo- and radio- therapy, while targeting a non-tdLN did not. We hypothesized that targeting the tdLN with NP vaccines might switch the tdLN microenvironment from a suppressive to an immunogenic one. This suggested that direct targeting of active suppressive mechanisms in the tumor might further improve immunotherapy. We thus engineered a nano-sized micellar carrier loaded with 6-thioguanine (MC-6TG), a cytotoxic drug used in leukemia, and explored its use in targeting T cell- impairing myeloid-derived suppressor cells (MDSCs) in order to enhance the efficacy of therapeutic vaccines. MC-6TG entirely eradicated both Ly6c+ monocytic and Ly6g+ granulocytic MDSCs for up to 7 d in the blood, tumor and tdLN of tumor-bearing mice. Since MC-6TG also targeted certain subsets of macrophages and DCs, depleting MDSCs did not have an impact on the efficacy of a NP vaccine, which relies on APCs for efficacy. However, MC-6TG synergized with adoptively transferred CD8+ T cells, significantly delaying tumor growth and enhancing survival in a murine model of implantable melanoma. Overall, this thesis describes the design and implementation of a novel approach to immunotherapy: we engineered NP-based therapeutic vaccines, optimized their delivery route to enhance efficacy, and simultaneously tackled immune suppressive cells in the tumor microenvironment to allow optimal therapeutic outcomes. The technologies and methods developed in this work are particularly relevant to clinical oncology and have the potential to benefit cancer patients by improving cancer therapy efficacy.

EPFL2013

The contribution of the host stress response to the pathogenesis of Pseudomonas entomophila in the Drosophila intestine

Sveta Chakrabarti

EPFL2013

Targeting and Modulating Tumor-Associated Sites with Novel Nanoparticle-Based Immunotherapies

Laura Jeanbart

EPFL2013

New immunomodulatory roles of lymphatic endothelium and implications for immunotherapy

Efthymia Vokali

EPFL2016