European Journal of Immunology

Nuclear factor-{kappa}B (NF-{kappa}B) is a transcription factor with a key role in a great variety of cellular processes from embryonic development to immunity, the outcome of which depends on the fine-tuning of NF-{kappa}B activity. The development of sensitive and faithful reporter systems to accurately monitor the activation status of this transcription factor is therefore desirable. To address this need, over the years a number of different approaches have been used to generate NF-{kappa}B reporter mice, which can be broadly subdivided into bioluminescence- and fluorescence-based systems. While the former enables whole-body visualization of the activation status of NF-{kappa}B, the latter have the potential to allow the analysis of NF-{kappa}B activity at single cell level. However, fluorescence-based reporters frequently show poor sensitivity and excessive background or are incompatible with high-throughput flow cytometric analysis. In this work we describe the generation and analysis of ROSA26 knockin NF-{kappa}B reporter (KappaBle) mice containing a destabilized EGFP, which showed sensitive, dynamic, and faithful monitoring of NF-{kappa}B activity at the single-cell level of various cell types during inflammatory and infectious diseases.

Type I interferons are essential for host response to viral infections, while dysregulation of their response can result in autoinflammation or autoimmunity. Among IFN (alpha) responses, 13 subtypes exist that signal through the same receptor, but have been reported to have different effector functions. However, the lack of available tools for discriminating these closely related subtypes, in particular at the protein level, has restricted the study of their differential roles in disease. We developed a digital ELISA with specificity and high sensitivity for the IFN2 subtype. Application of this assay, in parallel with our previously described pan-IFN assay, allowed us to study different IFN protein responses following cellular stimulation and in diverse patient cohorts. We observed different ratios of IFN protein responses between viral infection and autoimmune patients. This analysis also revealed a small percentage of autoimmune patients with high IFN2 protein measurements but low pan-IFN measurements. Correlation with an ISG score and functional activity showed that in this small sub group of patients, IFN2 protein measurements did not reflect its biological activity. This unusual phenotype was partly explained by the presence of anti-IFN auto-antibodies in a subset of autoimmune patients. This study reports ultrasensitive assays for the study of IFN proteins in patient samples and highlights the insights that can be obtained from the use of multiple phenotypic readouts in translational and clinical studies.

Natural killer (NK) cells play a crucial role in the innate immune response to bacterial infections, including those due to Pseudomonas aeruginosa (P. aeruginosa) and Staphylococcus aureus (S. aureus). In vivo, it has been shown that NK cells are activated by innate accessory cells that detect the presence of bacteria and activate NK cells via a cytokine network. In vitro, several studies have shown that NK cells can also be activated without the help of accessory cells by direct contact with some bacteria species such as extracellular P. aeruginosa. Whether this phenomenon of direct activation is restricted to certain bacterial species, or whether it can be generalized, is still debated, as for example in the case of NK cell activation by S. aureus, which seems to require the intervention of accessory immune cells. Here, we show with co-incubation experiments between NK cells and two bacterial species, that, in the absence of accessory cells, NK cells are able to impede bacterial growth. This has been demonstrated for the P. aeruginosa PA14 strain, which is hypervirulent and known for its deleterious effects on NK cells, as well as for the S. aureus Newman strain. The monitoring of CD107a by flow cytometry suggests that NK cells degranulate after contact with S. aureus bacteria. Our study contributes to the idea that NK cells can be activated in the absence of any accessory cells by various species of bacteria, even an hypervirulent one, and therefore that NKs can directly have an antibacterial effect. This important insight may pave the way for new therapeutic approaches using antibacterial NK-cell engagers.

Th17 cells (CD4+ T cells producing IL-17) are important for clearance of fungal infections and play a critical role in the development and exacerbation of numerous autoimmune diseases. Their differentiation, signalling pathways, cytokine production and metabolism are now well-characterised. As well as CD4+ T cells, CD8+ cells also produce IL-17 family members, and these have been named Tc17 cells. However, much less is known about their development, signalling or metabolism compared to their CD4+ counterparts. Here, we performed a series of in vitro and in vivo analyses of Tc17 cells as well as computational analysis of the published Tabula muris dataset, comparing Tc17 to IL-17- CD8+ T cells and to Th17 cells. We show that murine Tc17 cells are generated in the presence of TGF-{beta} and IL-6, and that cells produced by these culture conditions substantially reflect Tc17 cells seen in vivo; that is, with high expression of PD1, CD6, ICOS and CD161. Tc17 cells show phenotypic and functional differences to their Th17 counterparts, with increased production of IL-2 and IL-22 as well as an increased tendency to produce IL-17F as well as IL-17A. They show a more glycolytic profile than Th17 cells, with lowered mitochondrial membrane potential. This divergent phenotype and cytokine production suggests differential roles in vivo for these two cells.

Fc-gamma receptor (Fc{gamma}R) activation by soluble IgG immune complexes (sICs) represents a major mechanism of inflammation in certain autoimmune diseases such as systemic lupus erythematosus (SLE). A robust and scalable test system allowing for the detection and quantification of sIC bioactivity is missing. Previously described Fc{gamma}R interaction assays are limited to certain Fc{gamma}Rs, lack scalability and flexibility, are not indicative of receptor activation or lack sensitivity towards sIC size. We developed a comprehensive reporter cell panel detecting individual activation of Fc{gamma}Rs from humans and the mouse. The reporter cell lines were integrated into an assay format that provides flexible read-outs enabling the quantification of sIC reactivity via ELISA or a fast detection using flow cytometry. This identified Fc{gamma}RIIA(H) and Fc{gamma}RIIIA as the most sIC-sensitive Fc{gamma}Rs in our test system. Applying the assay we demonstrate that sICs versus immobilized ICs are fundamentally different Fc{gamma}R-ligands with regard to Fc{gamma}R preference and signal strength. Reaching a detection limit in the very low nanomolar range, the assay proved also to be sensitive to sIC stoichiometry and size enabling for the first time a complete reproduction of the Heidelberger-Kendall precipitation curve in terms of immune receptor activation. Analyzing sera from SLE patients and mouse models of lupus and arthritis proved that sIC-dependent Fc{gamma}R activation has predictive capabilities regarding severity of SLE disease. The new methodology provides a sensitive, scalable and comprehensive tool to evaluate the size, amount and bioactivity of sICs in all settings. One Sentence SummaryIn this study we established a comprehensive Fc{gamma}R reporter cell assay enabling the detection and quantification of soluble immune complexes generated in experimental and clinical settings.

Mucosal associated invariant T (MAIT) cells are abundant unconventional T cells that recognize microbe-derived riboflavin metabolites presented by MR1. Upon recognition, they become activated, produce proinflammatory cytokines, chemokines and cytotoxic molecules. MAIT cells are also activated by cytokines independently of T cell receptor (TCR) engagement, however these two signals can also act in concert to finetune MAIT cell functions. Additionally, multiple other co-stimulatory signals have also been reported that can boost MAIT cell effector responses to TCR or cytokine stimulation. However, a comprehensive study exploring the role of surface bound TNF receptor superfamily (TNFRSF) molecule 4-1BB, well known for its co-stimulatory function during conventional T cell activation, is lacking in the context of MAIT cells. In this study, we show that 4-1BB is the earliest and most highly expressed TNFRSF co-stimulatory molecule on MAIT cells upon activation by Escherichia coli, with expression seen as early as six hours where it was predominantly MR1 mediated. 4-1BB expression on MAIT cells following late activation was due to both TCR signaling and cytokine signaling. We found marked differences in MAIT cell activation and cytokine expression between 4-1BB+ and 4-1BB- MAIT cells suggesting 4-1BB expression on MAIT cells is associated with functional superiority. By blocking 4-1BB signaling or co-culturing with a 4-1BBL overexpressing cell line we demonstrated an important role of co-stimulation via 4-1BB in MAIT cells during activation. Expression and signaling via 4-1BB also enhanced T-bet and Blimp1 expression. In summary, our study confirms a role for 4-1BB signaling during MAIT cell activation.

IL-17A+ CD8+ T-cells, often referred to as Tc17 cells, have been identified at sites of inflammation in several immune-mediated inflammatory diseases including psoriasis and spondyloarthritis. Whilst much of our understanding of IL-17A+ CD8+ T-cells has been discerned from murine studies, human IL-17A+ CD8+ T-cells remain less-well characterised. We optimised an in vitro polarisation protocol to expand human IL-17A+ CD8+ T-cells from PBMC or bulk CD8+ T-cell populations for phenotypic and functional assessment. We show that T-cell activation in the presence of IL-1{beta} and IL-23 significantly increased the frequencies of IL-17A+ CD8+ T-cells, which was not further enhanced by the addition of IL-6, IL-2 or anti-IFN{gamma} mAb. In vitro-generated IL-17A+ CD8+ T-cells from healthy donors displayed a distinct type-17 profile compared with IL-17A- CD8+ T-cells, as defined by transcriptional signature (IL17A, IL17F, RORC, RORA, MAF, IL23R, CCR6, CXCR6); high surface expression of CCR6 and CD161; and polyfunctional production of IL-17A, IL-17F, IL-22, IFN{gamma}, TNF and GM-CSF. A significant proportion of in vitro-induced IL-17A+ CD8+ T-cells expressed TCRV7.2 and bound MR1 tetramers, indicative of a MAIT CD8+ T-cell population. Using an IL-17A secretion assay, we demonstrate that the in vitro-generated IL-17A+ CD8+ T-cells were biologically functional and induced pro-inflammatory IL-6 and IL-8 production by synovial fibroblasts from patients with psoriatic arthritis. Collectively, we report an in vitro culture system to expand IL-17A+ CD8+ T-cells and further characterise their phenotype, transcriptional regulation and functional relevance to human health and disease.

Antigen (ag)-specific T cell analysis is an important step for investigation of cellular immunity in many settings, such as infectious diseases, cancer and vaccines. Multiparameter flow cytometry has advantages in studying both the rarity and heterogeneity of these cells. In the cellular immunologists toolbox, the expression of activation-induced markers (AIM) following antigen exposure has made possible the study and sorting of ag-specific T cells without using human leukocyte antigen (HLA)-multimers. In parallel, assessing the cytokine profile of responding T cells would support a more comprehensive description of the ongoing immune response. Here, a method and flow cytometry panel were optimized to combine the detection of activated CD4+ and CD8+ T cells in a TCR-dependent manner with the evaluation of cytokine production by intracellular staining, without affecting the positivity of activation markers. In particular, the expression of CD134 (OX40) and CD69 have been tested in conjunction with intracellular (ic) CD137 (4-1BB) to detect SARS-Cov-2 Spike protein-specific activated T cells. In our setting, assessing CD134 provided minimal contribution to detect the pool of AIM+ T cells, whereas a key role was described for ic-CD69, which was co-expressed with ic-CD137 in both CD4+ and CD8+ lymphocytes. Moreover, the analysis of TCR-triggered cytokine-producing T cells (IFN{gamma}, TNF and IL-2 were assessed) further confirmed the capacity of ic-CD69 to identify functionally responsive antigen-specific T cells, which were often largely negative or poorly positive for CD134 expression. In parallel, the use of CD45RA, CCR7 and CXCR5 allowed us to describe the T cell matuarion curve and detect T helper follicular CD4+ cells, including the antigen-specific activated subsets. In conclusion, we optimized a method and flow cytometry panel combining assessment of activation induced markers and intracellular cytokines that will be useful for measuring TCR stimulation-dependent activation of CD4+ and CD8+ T cells.

Dendritic cells (DC) are described as immature at the steady state, with a high antigen capture capacity, turning into a mature state with a strong T cell stimulatory capacity upon activation. Using 16 different stimuli in vitro (130 observations), we describe two states of human activated dendritic cells. PDL1highICOSLlow \"secretory DC\" produced large amounts of inflammatory cytokines and chemokines but induced very low levels of T helper (Th) cytokines following DC-T co-culture; conversely PDL1lowICOSLhigh \"helper DC\" produced low levels of secreted factors but induced high levels of Th cytokines characteristic of a broad range of Th subsets. Secretory DC were phenotypically identified in T cell inflamed primary head and neck squamous cell carcinoma. RNAseq analysis showed that they expressed a typical secretory DC signature, including CD40, PVR, IL1B, TNF, and CCL19. This novel and universal functional dichotomy of human DC opens broad perspectives for the characterization of inflammatory diseases, and for immunotherapy.

Simultaneous analysis of T cell receptor repertoire and T cell phenotype is of high relevance to gain a deeper understanding on the T cell response in terms of differentiation, kinetics and persistence. Also it is currently unknown how the repertoire of immune checkpoints on T cells evolves over time. To fully capture the heterogenous response, TCR repertoire and T cell phenotype analysis is preferably performed at the single-cell level, but this is costly and analytically challenging. Therefore, we developed a flow cytometry based method that allows for simultaneous characterization of the T cell TCR V{beta} and the phenotype. We generated a 9-tube 24-color panel with antibodies against maturation and activation markers, and 24 TCR V{beta} chains. Peripheral blood mononuclear cells from 5 healthy controls were analyzed, revealing the presence of oligoclonal expansions. Within the CD27+CD28+ memory T cell population, oligoclonal expansions were characterized by a T regulatory, or KLRG1+CCR7-CD27low phenotype. Within the late CD27- and/or CD28-memory T cells, the populations with the lowest TCR V{beta} diversity expressed CX3CR1. As a proof of principle, we demonstrate the dynamics of circulating oligoclonal T cell expansions that emerged following hematopoietic stem cell transplantation in the presence of CMV in 2 patients. We provide evidence that oligoclonal T cells transferred from donor to recipient can be traced up to at least 2.5 years while maintaining its phenotype. Mostly TIGIT and PD-1 were critical in defining T cell expansions, while CD45RA, CD57, CD56 and NKG2A were variably expressed. Overall, we developed a phenotype based method to trace T cell populations, that is widely applicable to different settings in which the T cell response needs to be monitored.

IL-23 is an IL-12 family cytokine that is important in promoting Th17 responses and has been strongly linked to autoimmunity and psoriasis. It is a heterodimeric cytokine made up of a p19 subunit unique to IL-23 and a p40 subunit that is shared with IL-12. We show here that in response to LPS, the induction of IL-23p19 mRNA is regulated by a MSK1/2 - CREB dependent pathway downstream of ERK1/2 and p38 MAPK. Knockout of MSK1/2 resulted in a decrease in both IL-23p19 mRNA transcription and IL-23 secretion in GM-CSF differentiated bone marrow cells. Similar effects were seen when the MSK1/2 phosphorylation site in CREB was mutated to alanine. Stimulation with PGE2 promotes the nuclear localisation of CRTC3, a co-activator for CREB. In combination with LPS, PGE2 promoted IL-23p19 mRNA transcription and this was blocked by knockdown of CRTC3. Imiquimod induced skin inflammation in mice has been used as a model for psoriasis and is dependent on IL-23. While MSK1/2 knockout reduced the induction of IL-23 in vivo following i.p. injection of LPS, the knockout mice were not protected from Imiquimod induced skin inflammation. MSK1/2 knockout did not reduce the induction of IL-17 producing {gamma}{delta}T cells following Imiquimod treatment, although MSK1/2 knockout did reduce the levels of these cells in mice receiving a control cream. The lack of protection in the Imiquimod model may be due to the known anti-inflammatory roles or MSKs, such as its contribution to the induction of IL-10.

Human Cytomegalovirus (HCMV) is a betaherpesvirus that causes severe disease in immunocompromised transplant recipients. Immunotherapy with CD8 T cells specific for HCMV antigens presented on HLA class-I molecules is explored as strategy for long-term relief to such patients, but the antiviral effectiveness of T cell preparations cannot be efficiently predicted by available methods. Therefore, we developed an Assay for Rapid Measurement of Antiviral T-cell Activity (ARMATA) by real-time automated fluorescent microscopy and used it to study the ability of CD8 T cells to neutralize HCMV and control its spread. As a proof of principle, we used TCR-transgenic T cells specific for the immunodominant HLA-A02-restricted tegumental phosphoprotein pp65. pp65 expression follows an early/late kinetic, but it is not clear at which stage of the virus cycle it acts as an antigen. We measured control of HCMV infection by T cells as early as 6 hours post infection (hpi). The timing of the antigen recognition indicated that it occurred before the late phase of the virus cycle, but also that virion-associated pp65 was not recognized during virus entry into cells. Monitoring of pp65 gene expression dynamics by reporter fluorescent genes revealed that pp65 was detectable as early as 6 hpi, and that a second and much larger bout of expression occurs in the late phase of the virus cycle by 48 hpi. Since transgenic (Tg)-pp65 specific CD8 T cells were activated even when DNA replication was blocked, our data argue that pp65 acts as an early virus gene for immunological purposes. Therefore, ARMATA does not only allow same-day identification of antiviral T-cell activity, but also provides a method to define the timing of antigen recognition in the context of HCMV infection.

Effective immune responses depend on efficient antigen uptake in the periphery, transport of those antigens to, and presentation in draining lymph nodes (LNs). These processes have been studied intensively using stable fluorescent proteins (FPs) as model antigens. To date, ZsGreen is the only FP that can be tracked efficiently towards LNs, hence, it is difficult to compare studies using alternated tracking proteins. Here, we systematically compared six different FPs. We included ZsGreen, ZsYellow, DsRed, AsRed, mCherry, and mRFP based on sequence homology and/or origin species, and generated FP-expressing tumor cell lines. Stability of fluorescent signal was assessed in vitro over time, across different pH environments, and in vivo through FP antigen uptake and transfer to immune cells isolated from tumors and tumor-draining LNs. ZsGreen could be detected in high percentages of all analyzed tumor-infiltrating immune cells, with highest amounts in tumor-associated macrophages (TAMs) and type 2 conventional dendritic cells (cDC2s). ZsYellow, AsRed, and DsRed followed a similar pattern, but percentages of FP-containing immune cells in the tumor were lower than for ZsGreen. Strikingly, mRFP and mCherry demonstrated a non-canonical antigen uptake pattern where percentages of FP-positive tumor-infiltrating immune cells were highest for cDC1s not TAMs and cDC2s despite comparable stabilities and localization of all FPs. Analysis of antigen-containing cells in the LN was hindered by intracellular degradation of FPs. Only ZsGreen could be efficiently tracked to the LN, though some signal was measurable for ZsYellow and DsRed. In summary, we find that detection of antigen uptake and distribution is subject to variabilities related to fluorophore nature. Future experiments need to consider that these processes might be impacted by protein expression, stability, or other unknown factors. Thus, our data sheds light on potential under-appreciated mechanisms regulating antigen transfer and highlights potential uses and necessary caveats to interpretation based on FP use.

{beta}T cells engineered to express a defined {gamma}{delta}TCR (TEG) to attack cancer cells have shown great promise when using a {gamma}9{delta}2TCR to redirect {beta}T cells (1-9). Reports by us (1-9) and recent reports by others (10, 11) support the key role of the {gamma}9{delta}2TCR in cancer recognition. We further emphasized the crucial role of the {delta}TCR chain and that differences in CDR3 sequences of the {delta}TCR chain modulates functional avidity of TEGs (2, 8). We and others demonstrated that also {delta}2 negative {gamma}{delta}TCRs are able to redirect {beta}T cells towards different tumor cell lines (12-15). However, some studies suggest that {delta}2 negative {gamma}{delta}TCRs play a minor role in the tumor recognition by {delta}2 negative {gamma}{delta}T cells (16, 17). In addition for both modes of action for tumor-recognition, {delta}2 negative {gamma}{delta}TCR-dependent and -independent, it has been suggested that CMV infection is not only a major driver of {delta}2 negative {gamma}{delta}T cell expansion (18) but also induces tumor-cross reactive {delta}2 negative {gamma}{delta}T cells (19-21). Therefore, we aimed to systematically explore frequencies of tumor reactive {delta}2 negative {gamma}{delta}T cells in naive repertoires (cord blood) and patients with or without CMV infection and examined the potential role the parental {delta}2 negative {gamma}{delta}TCR in anti-tumor reactivity of selected clones. We observed that approximately 30% of all tested clones were tumor-reactive, though no differences were observed between different sources. Surprisingly, none of the so far tested {gamma}{delta}TCR did mediate strong anti-tumor reactivity of the parental clones. Though numbers of tested TCR sequences are still low, our data imply that tumor-reactivity of {delta}2 negative {gamma}{delta}T cells is frequently not mediated by the {delta}2 negative {gamma}{delta}TCR alone.

Secondary human lymphoid tissue immune reactions take place in a highly coordinated environment with compartmentalization representing a fundamental feature of this organization. In situ profiling methodologies are indispensable for the understanding of this compartmentalization. Here, we propose a complementary experimental approach aiming to reveal different aspects of this process. The analysis of human tonsils, using a combination of single cell phenotypic analysis based on flow cytometry and multiplex imaging and mass spectrometry-based methodologies, revealed a compartmentalized organization at cellular and molecular level. More specifically, the skewed distribution of highly specialized immune cell subsets and relevant soluble mediators was accompanied by a compartmentalized localization of several lipids across different anatomical areas of the tonsillar tissue. The performance of such combinatorial experimental approaches could lead to the identification of novel in situ interactions and molecular targets for the in vivo manipulation of lymphoid organ, particularly the germinal center, immune reactions.

{gamma}{delta} T cells are important components of the immune system due to their ability to elicit a fast and strong response against infected and transformed cells. Because they can specifically and effectively kill target cells in an MHC independent fashion, there is great interest to utilize these cells in anti-tumor therapies where antigen presentation may be hampered. Since only a small fraction of T cells in the blood or tumor tissue are {gamma}{delta} T cells, they require extensive expansion to allow for fundamental, preclinical and ex vivo research. Although expansion protocols can be successful, most are based on depletion of other cell types rather than {gamma}{delta} T cell specific isolation, resulting in unpredictable purity of the isolated fraction. Moreover, the primary focus only lies with expansion of V{delta}2+ T cells, while V{delta}1+ T cells likewise have anti-tumor potential. Here, we investigated whether {gamma}{delta} T cells directly isolated from blood could be efficiently expanded while maintaining function. {gamma}{delta} T cell subsets were isolated using MACS separation, followed by FACS sorting, yielding >99% pure {gamma}{delta} T cells. Isolated V{delta}1+ and V{delta}2+ T cells could effectively expand immediately after isolation or upon freeze/thawing and reached expansion ratios between 200 to 2000-fold starting from varying numbers using cytokine supported feeder stimulations. After expansion, potential effector functions of {gamma}{delta} T cells were demonstrated by IFN-{gamma}, TNF- and granzyme B production upon PMA/ionomycin stimulation and effective killing capacity of multiple tumor cell lines was confirmed in killing assays. In conclusion, pure {gamma}{delta} T cells can productively be expanded while maintaining their anti-tumor effector functions against tumor cells. Moreover, {gamma}{delta} T cells could be expanded from low starting numbers suggesting that this protocol may even allow for expansion of cells extracted from tumor biopsies.

T cell receptor (TCR) V{gamma}4+ expressing {gamma}{delta} T cells can be divided into IFN-{gamma} and IL-17-producing effector T cell subsets. A bias towards {gamma}{delta}17 effector fate decisions is observed during early ontogeny. In contrast, the existence of V{gamma}4+ {gamma}{delta}17 cells derived from adult thymus is still controversial. In the present work, we used a mouse model where T cells are exclusive generated within an adult thymus. Additionally, we employed single-cell chromatin state analysis from thymocytes of normal mice. A small, but considerable population of immature Cd24+ Gzma+ V{gamma}4 cells was found that exhibit molecular programs of {gamma}{delta}17 cells. These adult thymus-derived immature Cd24a+ cMaf+ V{gamma}4 cells secrete small amounts of IL-17A and IL-17F. Interestingly, do not reach the periphery under steady-state conditions. Furthermore, de novo generated {gamma}{delta}17-like cells from adult thymus lack transcriptional activity of the Scart2 encoding gene, suggesting that Scart2 is a distinct trait of fetal {gamma}{delta} T cell precursors. Together, this study provides valuable insights into developmental traits of V{gamma}4 cells during adulthood and raises the question on signals suppressing the full maturation and/or thymic export of {gamma}{delta}17-like cells within the adult thymus. HighlightsO_LITranscriptional and epigenetic profiling identifies developmental plasticity of Gzma+ Cd24a+ V{gamma}4 cells in adult thymus. C_LIO_LIThymic c-Maf+ and ROR{gamma}t+ V{gamma}4 T cells can be generated during adulthood, but do not reach the periphery under steady-state conditions. C_LIO_LIInnate CD44highCD45RBneg {gamma}{delta}17 cells are completely absent upon induction of T cell development during adulthood. C_LIO_LIScart2 expression might be a key molecule to track developmental traits of fetal-derived {gamma}{delta}17 cell precursors. C_LI

Although PD-1 was shown to be a hallmark of T cells exhaustion, controversial studies have been reported on the role of PD-1 on NK cells. Here, we found by flow cytometry and single cell RNA sequencing analysis that PD-1 can be expressed on MHC class I-deficient tumor-infiltrating NK cells in vivo. We also demonstrate distinct alterations in the phenotype of PD-1-deficient NK cells which in part could be attributed to a decrease in tumor-infiltrating NK cells in PD-1-deficient mice. NK cells from PD-1-deficient mice exhibited a more mature phenotype which might reduce their capacity to migrate and kill in vivo. Finally, our results demonstrate that PD-L1 molecules in membranes of PD-1-deficient NK cells migrate faster than in NK cells from wildtype mice, suggesting that PD-1 and PD-L1 form cis interactions with each other on NK cells.

Innate lymphoid cells (ILCs), the complements of diverse CD4 T helper cells, help maintain tissue homeostasis by providing a link between innate and adaptive immune responses. While pioneering studies over the last decade have advanced our understanding how ILCs influence adaptive immune responses to pathogens, far less is known about whether the adaptive immune response feeds back into an ILC response. In this study, we isolated ILCs from blood of healthy donors, fine-tuned culture conditions, and then directly challenged them with human adenoviruses (HAdVs), with HAdVs and host defence proteins (HDPs) or neutralizing antibodies (NAbs), to mimic interactions in a host with pre-existing immunity. Additionally, we developed an ex vivo approach to identify how bystander ILCs respond to the uptake of HAdVs {+/-} neutralizing antibodies by monocyte-derived dendritic cells. We show that ILCs take up HAdVs, which induces phenotypic maturation and cytokine secretion. Moreover, NAbs and HDPs complexes modified the cytokine profile generated by ILCs, consistent with a feedback loop for host antiviral responses and potential to impact adenovirus-based vaccine efficacy. Author SummarySeveral studies have shown the importance of innate lymphoid cells (ILCs) both from an immune and physiological point of view, in particular for their role in the maintenance of tissue integrity, pathogens clearance, or in the establishment of immune tolerance. Our study focuses on the role of ILCs during direct challenge with prototype vaccines based on human adenoviruses (HAdVs) {+/-} host defence proteins (HDPs) or neutralizing antibodies (NAbs) to mimic interactions in a host with pre-existing immunity. In parallel, through an ex vivo approach we observe how bystander ILCs respond to the uptake of HAdVs {+/-} NAbs by monocyte-derived dendritic cells. We show that ILCs take up HAdVs, which induces pro- inflammatory and antiviral responses through phenotypic maturation and cytokine secretion. Moreover, HAdV-NAb and HAdV-HDP complexes modified the cytokine profile generated by ILCs, consistent with a feedback loop for host antiviral responses and potential to impact HAdV vaccine efficacy.

IL-12p70 is crucial for T helper 1 polarization and the generation of type 1 immunity that is required to fight cancer and intracellular pathogens. Therefore, strategies to optimize the production of IL-12p70 by dendritic cells (DCs) may significantly improve the efficacy of vaccines and immunotherapies for cancer. However, the rules governing the production of IL-12p70 remain obscure. Here, we stimulated pattern recognition receptors (PRRs) representing all five families of PRRs, to evaluate their ability to elicit high production of IL-12p70 by human DCs. We used ten well-characterized agonists and stimulated human monocyte-derived DCs in vitro with either single agonists or 26 different combinations. We found that poly(I:C), which engages the RNA-sensing PRRs TLR3 and/or MDA5, was the only agonist that could elicit IL-12p70 production when used alone. Combinations of agonists of cell surface and intracellular PRRs were found to synergize to induce high IL-12p70 production, given that the combination included poly(I:C) or resiquimod, which both are agonists of intracellular, RNA sensing PRRs (TLR3/MDA5 and TLR7/8, respectively). Our data show that production of high IL-12p70 is strictly controlled, which is different from what we observed for IFN{beta}, whose production could be elicited by several intracellular PRRs. In conclusion, we identified six different combinations of PRR ligands able to induce high IL-12p70 production by human DCs. The identified synergistic PRR ligand combinations may represent strong adjuvant candidates in particular for therapeutic cancer vaccines.