An inducible transgenic mouse model for immune mediated hepatitis showing clearance of antigen expressing hepatocytes by CD8+ T cells

An immune-based tool platform for in vivo cell clearance

Immunological targeting of pathological cells has been successful in oncology and is expanding to other pathobiological contexts. Here, we present a flexible platform that allows labeling cells of interest with the surface-expressed model antigen ovalbumin (OVA), which can be eliminated via either antigen-specific T cells or newly developed OVA antibodies. We demonstrate that hepatocytes can be effectively targeted by either modality. In contrast, pro-fibrotic fibroblasts associated with pulmonary fibrosis are only eliminated by T cells in initial experiments, which reduced collagen deposition in a fibrosis model. This new experimental platform will facilitate development of immune-based approaches to clear potential pathological cell types in vivo.

Improved Functionality of Exhausted Intrahepatic CXCR5+ CD8+ T Cells Contributes to Chronic Antigen Clearance Upon Immunomodulation

Chronic hepatotropic viral infections are characterized by exhausted CD8+ T cells in the presence of cognate antigen in the liver. The impairment of T cell response limits the control of chronic hepatotropic viruses. Immune-modulatory strategies are attractive options to re-invigorate exhausted T cells. However, in hepatotropic viral infections, the knowledge about immune-modulatory effects on the in-situ regulation of exhausted intrahepatic CD8+ T cells is limited. In this study, we elucidated the functional heterogeneity in the pool of exhausted CD8+ T cells in the liver of mice expressing the model antigen Ova in a fraction of hepatocytes. We found a subpopulation of intrahepatic CXCR5+ Ova-specific CD8+ T cells, which are profoundly cytotoxic, exhibiting efficient metabolic functions as well as improved memory recall and self-maintenance. The intrahepatic Ova-specific CXCR5+ CD8+ T cells are possibly tissue resident cells, which may rely largely on OXPHOS and glycolysis to fuel their cellular processes. Importantly, host conditioning with CpG oligonucleotide reinvigorates and promotes exhausted T cell expansion, facilitating complete antigen eradication. The CpG oligonucleotide-mediated reinvigoration may support resident memory T cell formation and the maintenance of CXCR5+ Ova-specific CD8+ T cells in the liver. These findings suggest that CpG oligodinucleotide may preferentially target CXCR5+ CD8+ T cells for expansion to facilitate the revival of exhausted T cells. Thus, therapeutic strategies aiming to expand CXCR5+ CD8+ T cells might provide a novel approach against chronic liver infection.

Inducible de novo expression of neoantigens in tumor cells and mice

Inducible expression of neoantigens in mice would enable the study of endogenous antigen-specific naïve T cell responses in disease and infection, but has been difficult to generate because leaky antigen expression in the thymus results in central T cell tolerance. Here we develop inversion-induced joined neoantigen (NINJA), using RNA splicing, DNA recombination and three levels of regulation to prevent leakiness and allow tight control over neoantigen expression. We apply NINJA to create tumor cell lines with inducible neoantigen expression, which could be used to study antitumor immunity. We also show that the genetic regulation in NINJA mice bypasses central and peripheral tolerance mechanisms and allows for robust endogenous CD8 and CD4 T cell responses on neoantigen induction in peripheral tissues. NINJA will enable studies of how T cells respond to defined neoantigens in the context of peripheral tolerance, transplantation, autoimmune diseases and cancer.

Mechanistic mathematical representation of CD8+ T cell mediated drug-induced liver injury (DILI) Part 1: initial development using experimental antigen, ovalbumin (OVA)

Idiosyncratic DILI (iDILI), rare liver injury not dependent on drug dose, is poorly understood and costly to patients and drug developers. Some iDILI events appear immune-mediated. This work builds on the established hepatocyte life cycle and intrinsic injury models in DILIsym, utilizing quantitative systems toxicology methods to incorporate direct activation of liver CD8+ T cells by OVA-expressing hepatocytes.

Simulated hepatocyte OVA expression leads to activation of naïve OVA-specific CD8+ T cells. Activated T cells differentiate to effector, memory, or exhausted T cells. T cell cytotoxicity induces apoptosis in antigen-presenting hepatocytes, with resultant ALT release. By design, the model reproduces a differential CD8+ T cell response to low vs. high levels of hepatocyte OVA expression consistent with data 1,2. Mechanistically, the differential response is driven by effector T cell mediated clearance of low antigen vs. persistent high antigen and differentiation of exhausted T cells3. Reducing T cell functional avidity by 70x, as described for OVA altered peptide ligands4, reduced IFN-γ production and T cell cytotoxicity consistent with data5.

By reproducing these results, DILIsym establishes proof-of-concept in the quantitative relationships among antigen-expressing hepatocytes, antigen-specific T cell number, cytotoxicity, and ALT release. These quantitative relationships set the stage for translation to drug-mediated CD8+ T cell cytotoxicity6.

Targeting cardiac fibrosis with engineered T cells

Fibrosis is observed in nearly every form of myocardial disease¹. Upon injury, cardiac fibroblasts (CF) in the heart begin to remodel the myocardium via extracellular matrix deposition, resulting in increased tissue stiffness and reduced compliance. Excessive cardiac fibrosis is an important factor in the progression of various forms of cardiac disease and heart failure². However, clinical interventions and therapies targeting fibrosis remain limited³. In this study, we demonstrate the efficacy of redirected T-cell immunotherapy to specifically target pathologic cardiac fibrosis. We find that cardiac fibroblasts expressing a xenogeneic antigen can be effectively targeted and ablated by adoptive transfer of antigen-specific CD8⁺ T cells. Through expression analysis of cardiac fibroblast gene signatures from healthy versus diseased human hearts, we identified an endogenous CF target; fibroblast activation protein (FAP). Adoptive transfer of T cells expressing a chimeric antigen receptor (CAR) against FAP, results in a significant reduction in cardiac fibrosis and restoration of function after injury in mice. These results provide the proof-of-principle basis for a novel immunotherapeutic avenue for the treatment of cardiac disease.

CpG-ODN Facilitates Effective Intratracheal Immunization and Recall of Memory against Neoantigen-Expressing Alveolar Cells

Intrapulmonary immune reactions are impaired by the tolerogenic environment of the lung. This is manifested by the absence of effective endogenous T cell responses upon neoantigen expression. This tolerance is considered to contribute to lung cancer and inefficient immune therapeutic interventions. To investigate the mechanisms contributing to lung tolerance and to overcome these restrictions, we developed a transgenic mouse model with induction of a neoantigen (OVA) exclusively in alveolar type II epithelial cells. This model is characterized by the absence of functional endogenous T cell responses upon OVA neoantigen induction. Standard DNA and protein vaccination protocols resulted in the accumulation of high numbers of antigen-specific CD8 T cells in the lung. However, clearance of antigen-expressing cells was not achieved. To overcome this tolerance, we induced inflammatory conditions by coapplication of the TLR ligands LPS and CpG-ODN during intrapulmonary vaccinations. Both ligands induced high numbers of neoantigen-specific T cells in the lung. However, only coapplication of CpG-ODN was sufficient to establish functional cytotoxic responses resulting in the elimination of neoantigen presenting target cells. Remarkably, CpG-ODN was also crucial for functional memory responses upon re-induction of the neoantigen. The results highlight the need of TLR9 co-stimulation for overcoming tolerization, which might be a key factor for therapeutic interventions.

TLR9-Mediated Conditioning of Liver Environment Is Essential for Successful Intrahepatic Immunotherapy and Effective Memory Recall

Immune defense against hepatotropic viruses such as hepatitis B (HBV) and hepatitis C (HCV) poses a major challenge for therapeutic approaches. Intrahepatic cytotoxic CD8 T cells that are crucial for an immune response against these viruses often become exhausted resulting in chronic infection. We elucidated the T cell response upon therapeutic vaccination in inducible transgenic mouse models in which variable percentages of antigen-expressing hepatocytes can be adjusted, providing mosaic antigen distribution and reflecting the varying viral antigen loads observed in patients. Vaccination-induced endogenous CD8 T cells could eliminate low antigen loads in liver but were functionally impaired if confronted with elevated antigen loads. Strikingly, only by conditioning the liver environment with TLR9 ligand prior and early after peripheral vaccination, successful immunization against high intrahepatic antigen density with its elimination was achieved. Moreover, TLR9 immunomodulation was also indispensable for functional memory recall after high frequency antigen challenge. Together, the results indicate that TLR9-mediated conditioning of liver environment during therapeutic vaccination or antigen reoccurrence is crucial for an efficacious intrahepatic T cell response.

Diet induced obesity has an influence on intrahepatic T cell responses

AIM

Obesity is accompanied with systemic inflammation and pre-conditions to severe alterations in liver environment and functions. So far, it remains elusive to which extent obesity modulates immune responses during hepatotropic virus infections as well as in autoimmune hepatitis. In this study we investigated the influence of obesity on the intrahepatic immune response, in particular on the function of CD8 T cells as the crucial players in clearance of virus infected hepatocytes.

METHODS

We established high fat induced obesity in transgenic mouse models with hepatocyte specific expression of a model antigen (Ova). We investigated the immune response upon adoptive transfer of antigen specific T cells and in mice with continuous thymic output of antigen specific T cells, mimicking the situations upon acute infection and autoimmunity, respectively.

RESULTS

Irrespective of the metabolic condition, adoptive T cell transfer resulted in a transient hepatitis with no obvious differences concerning the acute T cell response. In the situation of autoimmunity, we observed a transient hepatitis in lean mice, whereas an extended hepatitis with a reduced antigen clearance capacity was found in obese mice.

CONCLUSION

Our results demonstrate that obesity affects T cell function and increases the severity of autoimmune hepatitis while it has no impact on the acute T cell response.

Effective intrahepatic CD8+ T-cell immune responses are induced by low but not high numbers of antigen-expressing hepatocytes

Liver infections with hepatotropic viruses, such as hepatitis B virus and hepatitis C virus are accompanied by viral persistence and immune failure. CD8+ T cells are crucial mediators of the intrahepatic antiviral immune response. Chronic infections of the liver and other organs correlate with T-cell exhaustion. It was previously suggested that high antigen load could result in T-cell exhaustion. We aimed at elucidating the impact of different intrahepatic antigen loads on the quality of CD8+ T-cell-mediated immunity by employing an infection-free transgenic mouse model expressing ovalbumin (Ova) as the target antigen. Adoptive transfer of OT-I cells induced a transient intrahepatic immune response toward both high and low Ova levels. However, antigen clearance was achieved only in mice expressing low antigen levels. In contrast, T cells exposed to high antigen levels underwent exhaustion and became depleted, causing antigen persistence. Moreover, when functional T cells were exposed to high intrahepatic antigen levels, a complete transition toward exhaustion was observed. Thus, this study shows that the antigen expression level in the liver correlates inversely with T-cell immunity in vivo and governs the efficiency of immune responses upon antigen presentation.

Spontaneous proliferation of H2M-/- CD4 T cells results in unusual acute hepatocellular necrosis

Naïve CD4 T cells are triggered to undergo spontaneous proliferation, a proliferative response induced in response to homeostatic stimulation, when exposed to severe lymphopenic environments. They spontaneously acquire proinflammatory effector phenotypes, playing a major role in inducing chronic inflammation in the intestine that is believed to be induced by T cell recognition of commensal antigens. While the antigens inducing the T cell responses and inflammation are being extensively investigated, the role of clonality of T cells involved in this process remains poorly understood. In this study, we utilized naïve CD4 T cells isolated from B6 H2M−/− mice, in which MHCII molecules are complexed with a single CLIP molecule, and examined spontaneous proliferation and intestinal inflammation of CD4 T cells expressing limited T cell receptor repertoire diversity. We found that H2M−/− CD4 T cells undergo robust spontaneous proliferation, differentiate into IFNγ-producing Th1 type effector cells, and, most unexpectedly, induce severe acute hepatocellular necrosis. T cell interaction with MHCII molecule on cells of hematopoietic origin was essential to induce the pathology. Interestingly, B cells are fully capable of preventing necrotic inflammation via IL-10-independent and B7-H1-dependent mechanism. This could be a useful animal model to examine T cell-mediated liver inflammation and B cell-mediated immune regulation.