CD4+ T cell calibration of antigen-presenting cells optimizes antiviral CD8+ T cell immunity.

Antiviral CD8+ T cell immunity depends on the integration of various contextual cues, but how antigen-presenting cells (APCs) consolidate these signals for decoding by T cells remains unclear. Here, we describe gradual interferon-α/interferon-ß (IFNα/ß)-induced transcriptional adaptations that endow APCs with the capacity to rapidly activate the transcriptional regulators p65, IRF1 and FOS after CD4+ T cell-mediated CD40 stimulation. While these responses operate through broadly used signaling components, they induce a unique set of co-stimulatory molecules and soluble mediators that cannot be elicited by IFNα/ß or CD40 alone. These responses are critical for the acquisition of antiviral CD8+ T cell effector function, and their activity in APCs from individuals infected with severe acute respiratory syndrome coronavirus 2 correlates with milder disease. These observations uncover a sequential integration process whereby APCs rely on CD4+ T cells to select the innate circuits that guide antiviral CD8+ T cell responses.

Screening and development of monoclonal antibodies for identification of ferret T follicular helper cells.

The ferret is a key animal model for investigating the pathogenicity and transmissibility of important human viruses, and for the pre-clinical assessment of vaccines. However, relatively little is known about the ferret immune system, due in part to a paucity of ferret-reactive reagents. In particular, T follicular helper (Tfh) cells are critical in the generation of effective humoral responses in humans, mice and other animal models but to date it has not been possible to identify Tfh in ferrets. Here, we describe the screening and development of ferret-reactive BCL6, CXCR5 and PD-1 monoclonal antibodies. We found two commercial anti-BCL6 antibodies (clone K112-91 and clone IG191E/A8) had cross-reactivity with lymph node cells from influenza-infected ferrets. We next developed two murine monoclonal antibodies against ferret CXCR5 (clone feX5-C05) and PD-1 (clone fePD-CL1) using a single B cell PCR-based method. We were able to clearly identify Tfh cells in lymph nodes from influenza infected ferrets using these antibodies. The development of ferret Tfh marker antibodies and the identification of ferret Tfh cells will assist the evaluation of vaccine-induced Tfh responses in the ferret model and the design of novel vaccines against the infection of influenza and other viruses, including SARS-CoV2.

T Cell Help Amplifies Innate Signals in CD8(+) DCs for Optimal CD8(+) T Cell Priming.

DCs often require stimulation from CD4(+) T cells to propagate CD8(+) T cell responses, but precisely how T cell help optimizes the priming capacity of DCs and why this appears to differ between varying types of CD8(+) T cell immunity remains unclear. We show that CD8(+) T cell priming upon HSV-1 skin infection depended on DCs receiving stimulation from both IFN-α/ß and CD4(+) T cells to provide IL-15. This was not an additive effect but resulted from CD4(+) T cells amplifying DC production of IL-15 in response to IFN-α/ß. We also observed that increased innate stimulation reversed the helper dependence of CD8(+) T cell priming and that the innate stimulus, rather than the CD4(+) T cells themselves, determined how "help'" was integrated into the priming response by DCs. These findings identify T cell help as a flexible means to amplify varying suboptimal innate signals in DCs.

Limited Internodal Migration of T Follicular Helper Cells after Peripheral Infection with Herpes Simplex Virus-1.

The ability of CD4 T cells to give rise to specialized T follicular helper cells (TFH) critical to initiating appropriate Ab responses is regulated by environmental cues in lymphoid tissues draining the site of infection. In this study, we used a skin infection with HSV-1 characterized by the successive involvement of interconnected but distinct lymph nodes (LNs), to investigate the anatomical diversification of virus-specific CD4 T cell responses and the migratory capacity of TFH or their precursors. Whereas Th1 effector CD4 T cells expressing peripheral-targeting migration molecules readily migrated from primary to secondary reactive LNs, Bcl6(+) CXCR5(+) PD1(hi) TFH were largely retained at the site of initial activation with little spillover into the downstream LNs involved at later stages of infection. Consistent with this, TFH maintained high-level surface expression of CD69, indicative of impaired migratory capacity. Notably, the biased generation and retention of TFH in primary LNs correlated with a preferential generation of germinal centers at this site. Our results highlight a limited anatomical diversification of TFH responses and germinal center reactions that were imprinted within the first few cell divisions during TFH differentiation in LNs draining the site of initial infection.

NLRP3 inflammasome activation downstream of cytoplasmic LPS recognition by both caspase-4 and caspase-5.

Humans encode two inflammatory caspases that detect cytoplasmic LPS, caspase-4 and caspase-5. When activated, these trigger pyroptotic cell death and caspase-1-dependent IL-1ß production; however the mechanism underlying this process is not yet confirmed. We now show that a specific NLRP3 inhibitor, MCC950, prevents caspase-4/5-dependent IL-1ß production elicited by transfected LPS. Given that both caspase-4 and caspase-5 can detect cytoplasmic LPS, it is possible that these proteins exhibit some degree of redundancy. Therefore, we generated human monocytic cell lines in which caspase-4 and caspase-5 were genetically deleted either individually or together. We found that the deletion of caspase-4 suppressed cell death and IL-1ß production following transfection of LPS into the cytoplasm, or in response to infection with Salmonella typhimurium. Although deletion of caspase-5 did not confer protection against transfected LPS, cell death and IL-1ß production were reduced after infection with Salmonella. Furthermore, double deletion of caspase-4 and caspase-5 had a synergistic effect in the context of Salmonella infection. Our results identify the NLRP3 inflammasome as the specific platform for IL-1ß maturation, downstream of cytoplasmic LPS detection by caspase-4/5. We also show that both caspase-4 and caspase-5 are functionally important for appropriate responses to intracellular Gram-negative bacteria.

Altered lymph node composition in diphtheria toxin receptor-based mouse models to ablate dendritic cells.

Dendritic cells (DCs) are key regulators of innate and adaptive immunity. Our understanding of immune function has benefited greatly from mouse models allowing for selective ablation of DCs. Many such models rely on transgenic diphtheria toxin receptor (DTR) expression driven by DC-restricted promoters. This renders DCs sensitive to DT but is otherwise thought to have no effect on immune physiology. In this study, we report that, unexpectedly, mice in which DTR is expressed on conventional DCs display marked lymph node (LN) hypocellularity and reduced frequency of DCs in the same organs but not in spleen or nonlymphoid tissues. Intriguingly, in mixed bone marrow chimeras the phenotype conferred by DTR-expressing DCs is dominant over control bone marrow-derived cells, leading to small LNs and an overall paucity of DCs independently of the genetic ability to express DTR. The finding of alterations in LN composition and size independently of DT challenge suggests that caution must be exercised when interpreting results of experiments obtained with mouse models to inducibly deplete DCs. It further indicates that DTR, a member of the epidermal growth factor family, is biologically active in mice. Its use in cell ablation experiments needs to be considered in light of this activity.

IL-17 regulates systemic fungal immunity by controlling the functional competence of NK cells.

Interleukin 17 (IL-17)-mediated immunity plays a key role in protection from fungal infections in mice and man. Here, we confirmed that mice deficient in the IL-17 receptor or lacking the ability to secrete IL-17 are highly susceptible to systemic candidiasis, but we found that temporary blockade of the IL-17 pathway during infection in wild-type mice did not impact fungal control. Rather, mice lacking IL-17 receptor signaling had a cell-intrinsic impairment in the development of functional NK cells, which accounted for the susceptibility of these mice to systemic fungal infection. NK cells promoted antifungal immunity by secreting GM-CSF, necessary for the fungicidal activity of neutrophils. These data reveal that NK cells are crucial for antifungal defense and indicate a role for IL-17 family cytokines in NK cell development. The IL-17-NK cell axis may impact immunity against not only fungi but also bacteria, viruses, and tumors.

Genetic tracing via DNGR-1 expression history defines dendritic cells as a hematopoietic lineage.

Mononuclear phagocytes are classified as macrophages or dendritic cells (DCs) based on cell morphology, phenotype, or select functional properties. However, these attributes are not absolute and often overlap, leading to difficulties in cell-type identification. To circumvent this issue, we describe a mouse model to define DCs based on their ontogenetic descendence from a committed precursor. We show that precursors of mouse conventional DCs, but not other leukocytes, are marked by expression of DNGR-1. Genetic tracing of DNGR-1 expression history specifically marks cells traditionally ascribed to the DC lineage, and this restriction is maintained after inflammation. Notably, in some tissues, cells previously thought to be monocytes/macrophages are in fact descendants from DC precursors. These studies provide an in vivo model for fate mapping of DCs, distinguishing them from other leukocyte lineages, and thus help to unravel the functional complexity of the mononuclear phagocyte system.

Influenza viruses differ in ability to infect macrophages and to induce a local inflammatory response following intraperitoneal injection of mice.

Strains of influenza A virus show marked differences in their ability to infect murine macrophages (MPhi) such that strain A/PR/8/34 (PR8; H1N1) infects MPhi poorly while strain BJx109 (H3N2) infects MPhi to high levels. Given the central role of MPhi in initiating and regulating inflammatory responses, we hypothesized that virus strains that infect MPhi poorly may also be poor at initiating inflammatory responses. Studies to compare the inflammatory response of mice after intranasal inoculation with either BJx109 or PR8 were confounded by the rapid growth of the PR8 virus in lung tissues. Consequently, we have characterized the cellular inflammatory response following inoculation into the peritoneal cavity, as influenza viruses do not replicate at this site. Herein, we report marked differences in the local inflammatory response to BJx109 or PR8 in the peritoneal cavity with strain PR8 being particularly poor in its ability to recruit and activate peritoneal leukocytes, including NK cells and MPhi. In vitro BJx109, but not PR8, stimulated release of high levels of type I IFNs and TNF-alpha from PEC MPhi, and treatment of mice with neutralizing antibodies to either cytokine inhibited the ability of BJx109 to recruit and activate NK cells and MPhis in the peritoneal cavity. Together, these data suggest that the ability of influenza virus strains to infect MPhi and stimulate cytokine release is an important factor governing the nature of the acute inflammatory response.

NK cells contribute to the early clearance of HSV-1 from the lung but cannot control replication in the central nervous system following intranasal infection.

While infection of the respiratory tract with herpes simplex virus type 1 (HSV-1) can have severe clinical complications, little is known of the immune mechanisms that control both the replication and spread of HSV-1 in this site. To better understand the contribution of innate immunity and in particular natural killer (NK) cells to the control of infection at this site, we have utilized a mouse model of intranasal HSV-1 infection. NK cell numbers increased in the lung following intranasal infection and they produced IFN-gamma and acquired an enhanced cytotoxic capacity. While depletion of NK cells resulted in increased HSV-1 titres in the lung, the time taken to clear the virus was unaffected. Interestingly, HSV-1 was also effectively cleared from the lungs of RAG-1-/- mice that lack both B and T cells. However, RAG-1-/- mice could not control the spread of virus to the central nervous system and its subsequent replication in the brain. Together, these data demonstrate that NK cells are recruited, activated and contribute to early protection of the lung during acute HSV-1 infection of the respiratory tract, but in the absence of adaptive immunity are unable to control the replication and spread of virus in the nervous system.