IFN-γ Responses Research Articles

Pathobiont-induced suppressive immune imprints thwart T cell vaccine responses

Pathobionts have evolved many strategies to coexist with the host, but how immune evasion mechanisms contribute to the difficulty of developing vaccines against pathobionts is unclear. Meanwhile, Staphylococcus aureus (SA) has resisted human vaccine development to date. Here we show that prior SA exposure induces non-protective CD4+ T cell imprints, leading to the blunting of protective IsdB vaccine responses. Mechanistically, these SA-experienced CD4+ T cells express IL-10, which is further amplified by vaccination and impedes vaccine protection by binding with IL-10Rα on CD4+ T cell and inhibit IL-17A production. IL-10 also mediates cross-suppression of IsdB and sdrE multi-antigen vaccine. By contrast, the inefficiency of SA IsdB, IsdA and MntC vaccines can be overcome by co-treatment with adjuvants that promote IL-17A and IFN-γ responses. We thus propose that IL-10 secreting, SA-experienced CD4+ T cell imprints represent a staphylococcal immune escaping mechanism that needs to be taken into consideration for future vaccine development.

Immunological impact of intraperitoneal and intravenous chemotherapy in ovarian cancer, translational analyses of the Phase 3 iPocc trial

BackgroundThe iPocc trial, a randomized, global phase 3 study that compared intraperitoneal (IP) and intravenous (IV) carboplatin with dose-dense paclitaxel chemotherapy in epithelial ovarian cancer (EOC) patients, demonstrated improved progression-free survival in patients who received IP chemotherapy. The present study aimed to investigate the role of preexisting tumor immunity in the clinical outcomes of patients receiving IP chemotherapy. MethodsThis study involved analyzing patient data from the iPocc trial, selectively of those whose tumor specimens were preserved at the time of primary surgery. A total of 116 cases ((IP; n = 59), (IV; n = 57)) were subjected to microarray analysis. Single-sample gene set enrichment analyses were performed to evaluate the tumor immune microenvironment. ResultsPatients with enhanced tumor infiltration of T cells, natural killer (NK) cells, and cytotoxic lymphocytes in the IP group had a longer overall survival (OS) than those in the IV group, but not in the group with low infiltration. IP therapy improved the OS of patients with high expression of immune-related genes such as CD8A and FOXP3. In patients' subdivided into “immune Hot” and “immune Cold” groups based on hierarchical clustering analysis using four parameters representing “Innate immunity,” “T cells,” “IFNG response” and “Inhibitory molecules,” IP therapy significantly improved prognosis in the “immune Hot” group, but not in the “immune Cold” group compared to that of IV therapy. ConclusionsIP chemotherapy enhances the survival rates of patients with EOC with an immune-Hot phenotype in the tumor microenvironment prior to treatment.(Japan Registry of Clinical Trials number, jRCTs031180141.)

RNA N6-Methyladenosine-Binding Protein YTHDFs Redundantly Attenuate Cancer Immunity by Downregulating IFN-γ Signaling in Gastric Cancer.

Immunotherapy holds potential as a treatment for gastric cancer (GC), though immune checkpoint inhibitor (ICI) resistance remains an obstacle. One resistance mechanism involves defects in interferon-γ (IFN-γ) signaling, in which IFN-γ is linked to improved responsiveness to ICIs. Herein, the roles of RNA N6-methyladenosine (m6A) modifications in regulation of IFN-γ signaling and the responsiveness to ICIs are unveiled. The m6A-binding protein YTH N6-methyladenosine RNA-binding protein F1 (YTHDF1) is overexpressed in GC tissues, correlating with the suppression of cancer immunity and poorer survival rates. YTHDF1 overexpression impaired the responsiveness to IFN-γ in GC cells, and knockdown studies indicated the redundant effects of YTHDF2 and YTHDF3 with YTHDF1 in IFN-γ responsiveness. RNA immunoprecipitation sequencing revealed YTHDFs directly target interferon regulatory factor 1 (IRF1) mRNA, a master regulator of IFN-γ signaling, leading to reduced RNA stability and consequent downregulation of IFN-γ signaling. Furthermore, in mouse syngeneic tumor models, Ythdf1 depletion in cancer cells resulted in reduced tumor growth and increased tumor-infiltrating lymphocytes, which are attributed to the augmentation of IFN-γ signaling. Collectively, these findings highlight how YTHDFs modulate cancer immunity by influencing IFN-γ signaling through IRF1 regulation, suggesting their viability as therapeutic targets in cancer immunotherapy.

Chronic inflammation degrades CD4 T cell immunity to prior vaccines in treated HIV infection

To date, our understanding of how HIV infection impacts vaccine-induced cellular immunity is limited. Here, we investigate inflammation, immune activation and antigen-specific T cell responses in HIV-uninfected and antiretroviral-treated HIV-infected people. Our findings highlight lower recall responses of antigen-specific CD4 T cells that correlate with high plasma cytokines levels, T cell hyperactivation and an altered composition of the T subsets enriched with more differentiated cells in the HIV-infected group. Transcriptomic analysis reveals that antigen-specific CD4 T cells of the HIV-infected group have a reduced expression of gene sets previously reported to correlate with vaccine-induced pathogen-specific protective immunity and further identifies a consistent impairment of the IFNα and IFNγ response pathways as mechanism for the functional loss of recall CD4 T cell responses in antiretroviral-treated people. Lastly, in vitro treatment with drugs that reduce inflammation results in higher memory CD4 T cell IFNγ responses. Together, our findings suggest that vaccine-induced cellular immunity may benefit from strategies to counteract inflammation in HIV infection.

Household contact antigen-specific TNF and IL-2 T-cell responses and impact of index case Mycobacterium tuberculosis aerosolization and HIV Co-infection.

Exposure to pulmonary tuberculosis (PTB) culminates in heterogeneous outcomes, including variation in Mtb antigen-specific interferon-gamma (IFN-γ) T-cell responses. IFN-γ-independent cytokines, including tumor necrosis factor (TNF) and interleukin (IL-2), offer potential diagnostic improvements and insights into pathogenesis. We hypothesized that ESAT6/CFP10 TNF and IL-2 responses improve Mtb infection detection among exposed household contacts (HHCs) and are associated with index case Mtb aerosolization (i.e., cough aerosol culture positive for Mtb growth, CAC+]) and HIV co-infection. We enrolled individuals with PTB and their HHCs in a longitudinal study in Nairobi, Kenya. We measured TNF and IL-2 in HHCs from QuantiFERON-TB Plus TB1 tube supernatants. An additional 9.2% (25) HHCs beyond the 58.6% (129) with an IFN-γ response demonstrated an antigen-specific increase in IL-2 and TNF. HHCs of CAC + participants were more likely to have positive IL-2 (84.6% vs. 53.8%, p = 0.02) and IFN-γ (88.0% vs. 54.9%, p = 0.01), but not TNF responses, compared to CAC-negative individuals. While HIV co-infection in the index was negatively associated with IFN-γ responses in HHCs (35.7% vs. 62.3%, p = 0.03), IL-2 and TNF responses did not differ. Antigen-specific ESAT6/CFP10 IL-2 and TNF may increase rates of Mtb infection detection and provide insights into Mtb transmission and pathogenesis.

IMMU-26. TARGETING CHK2-YBX1/3 INTERACTION TO OVERCOME IMMUNOSUPPRESSION IN GLIOMAS

Abstract Whereas the contribution of tumor microenvironment to the profound immune suppression of glioblastoma (GBM) is clear, tumor-cell intrinsic mechanisms that regulate resistance to CD8 T cells are less studied. We performed an in vivo CRISPR screen to identify glioma intrinsic kinases that contribute to evasion of tumor cells from CD8 T cells. The screen revealed a DNA damage response gene-checkpoint kinase 2 (Chek2) to be the most important kinase contributing to escape from CD8 T-cell recognition. Genetic depletion or pharmacological inhibition of Chek2 with blood-brain-barrier permeable drugs that are in the clinical trials, in combination with PD-1/PD-L1 blockade, led to survival benefit in preclinical glioma models. Analysis of human GBMs demonstrated that Chek2 expression is inversely associated with antigen presentation and T-cell activation. However, the mechanism underlying the immunosuppressive function of Chek2 in gliomas is unknown. Here, we identified that glioma tumor cell intrinsic Chek2 interacts with Y-Box Binding Protein 1 and 3 (Ybx1&3) in ex vivo gliomas using immunoprecipitation followed by mass spectrometry. Independently, YBX3 was also identified as one of the most significantly phosphorylated protein upon Chek2 knockout using phosphoproteomics analysis. The YBX1&3 are DNA/RNA binding proteins implicated in transcriptional regulation of immune-modulatory genes. In silico docking using Alphafold and PIPER tool in Schrodinger revealed that the YBX1 cold-shock domain interacted near the ATP/ADP binding site in CHK2. This interface was also part of the CHK2-CHK2 dimer interface. Consistent with our model, disruption of CHK2 dimerization using prexasertib led to increased colocalization of CHK2-YBX1 in human GBM patient derived xenograft cells. Further, targeting of CHK2-YBX1 interaction with YBX1 inhibitor SU056 reversed the repression of IFNγ response genes in glioma cells. Together this study unveils a kinase independent (non-catalytic) function of CHK2, providing insight into the non-canonical immunosuppressive role of CHK2 in gliomas.

Interleukin-12 decorated nanosized semiflexible Immunofilaments enable directed targeting and augmented IFNγ responses of natural killer cells

Immunotherapies are a powerful strategy to treat cancer by modulating the immune system to raise an anti-tumor immune response. A prime example of immunotherapies are cytokines - small immunomodulatory molecules that are widely used to stimulate immune cells. Undirected administration of cytokines, however, can cause severe side effects, preventing the use of potent cytokines, such as Interleukin (IL)-12, which induces IFNγ responses by cytotoxic effector lymphocytes, including NK cells. Biomaterials, like nanoparticles, can encapsulate IL-12 and accumulate at the tumor site to alleviate side effects. Yet, the released IL-12 might not be directly targeted to extracellular IL-12 receptors on the specific effector cells, thereby potentially compromising the cytokine's therapeutic efficacy. Here, we develop a polymer-based platform to target NK cells, which we call immunofilaments. Immunofilaments are nanosized linear polymers that present an anti-CD16 antibody and IL-12 effectively to NK cells and lead to synergistic NK cell activation as highlighted by an increase in TNFα and IFNγ production and upregulation of multiple activation markers, including CD25, CD69, and degranulation marker CD107a. NK cell proliferation is enhanced in the presence of both anti-CD16 antibody and IL-12 compared to giving IL-12 separately. Finally, we demonstrate that the IF platform is suitable for in vivo applications, as immunofilaments readily activate human NK cells upon administration to mice. Statement of SignificanceIL-12 is a potent cytokine that stimulates IFNγ responses in NK cells, which supports an anti-tumor immune response. Due to its high potency, the delivery of IL-12 needs to be highly controlled to prevent severe adverse side effects, which can be achieved by using biomaterials. This study shows that nanosized polymers termed Immunofilaments can be used to immobilize IL-12 and effectively target and activate NK cells by co-conjugation of anti-CD16 antibodies. This work is a prime example of careful engineering of innovative biomaterials to improve immunotherapy.

Development of a Nomogram Based on Transcriptional Signatures, IFN-γ Response and Neutrophils for Diagnosis of Tuberculosis.

Tuberculosis (TB) is a major global health threat and its diagnosis remains challenging. This study aimed to develop a nomogram that incorporated peripheral blood transcriptional signatures and other blood tests for the diagnosis of tuberculosis. Patients with TB, patients with other definite pulmonary diseases (OPD), individuals with latent tuberculosis infection (LTBI), and healthy controls (HC) were retrospectively enrolled between May 2017 and April 2018. The results of the interferon-γ release assay (IGRA) and blood counts were obtained from medical records, and the transcripts of 10 genes were detected using reverse transcription polymerase chain reaction (RT-PCR). Variable selection was performed using least absolute shrinkage and selection operator regression (LASSO) and multivariate logistic regression was performed for the optimal prediction model with backward direction. The model was displayed as a nomogram, and its performance was evaluated for discrimination ability, calibration ability, and clinical usefulness. Internal validation of the prediction model was conducted using bootstrap resampling. A total of 185 participants were enrolled, including 84 patients with TB and 101 controls. A prediction nomogram composed of IGRA, percentage of neutrophils, and expression levels of CD64, granzyme A (GZMA), and PR/SET domain 1 (PRDM1) was established. The nomogram demonstrated good discrimination, with an unadjusted area under the curve (AUC) of 0.914 (95% CI: 0.875-0.954) and a bootstrap-corrected AUC of 0.914 (95% CI: 0.874-0.947). With a cutoff value of 0.519, the sensitivity and specificity for discriminating PTB from controls were 0.81 and 0.871, respectively. The nomogram also showed good calibration with the Hosmer-Lemeshow test (P=0.58) and good clinical practicality displayed by the decision curve analysis. A nomogram composed of IGRA, percentage of neutrophils, and expression of CD64, GZMA, and PRDM1 was established. The nomogram demonstrated a sensitivity and specificity of 81% and 87%, respectively, for differentiating TB from controls.

Pharmacological activation of STAT1-GSDME pyroptotic circuitry reinforces epigenetic immunotherapy for hepatocellular carcinoma.

Genomic screening uncovered interferon-gamma (IFNγ) pathway defects in tumours refractory to immune checkpoint blockade (ICB). However, its non-mutational regulation and reversibility for therapeutic development remain less understood. We aimed to identify ICB resistance-associated druggable histone deacetylases (HDACs) and develop a readily translatable combination approach for patients with hepatocellular carcinoma (HCC). We correlated the prognostic outcomes of HCC patients from a pembrolizumab trial (NCT03419481) with tumourous cell expressions of all HDAC isoforms by single-cell RNA sequencing. We investigated the therapeutic efficacy and mechanism of action of selective HDAC inhibition in 4 ICB-resistant orthotopic and spontaneous models using immune profiling, single-cell multiomics and chromatin immunoprecipitation-sequencing and verified by genetic modulations and co-culture systems. HCC patients showing higher HDAC1/2/3 expressions exhibited deficient IFNγ signalling and poorer survival on ICB therapy. Transient treatment of a selective class-I HDAC inhibitor CXD101 resensitised HDAC1/2/3high tumours to ICB therapies, resulting in CD8+T cell-dependent antitumour and memory T cell responses. Mechanistically, CXD101 synergised with ICB to stimulate STAT1-driven antitumour immunity through enhanced chromatin accessibility and H3K27 hyperacetylation of IFNγ-responsive genes. Intratumoural recruitment of IFNγ+GZMB+cytotoxic lymphocytes further promoted cleavage of CXD101-induced Gasdermin E (GSDME) to trigger pyroptosis in a STAT1-dependent manner. Notably, deletion of GSDME mimicked STAT1 knockout in abolishing the antitumour efficacy and survival benefit of CXD101-ICB combination therapy by thwarting both pyroptotic and IFNγ responses. Our immunoepigenetic strategy harnesses IFNγ-mediated network to augment the cancer-immunity cycle, revealing a self-reinforcing STAT1-GSDME pyroptotic circuitry as the mechanistic basis for an ongoing phase-II trial to tackle ICB resistance (NCT05873244).

Immunologic Mechanisms of BCc1 Nanomedicine Synthesized by Nanochelating Technology in Breast Tumor-bearing Mice: Immunomodulation and Tumor Suppression.

The side effects of anti-cancer chemotherapy remain a concern for patients. So, designing alternative medications seems inevitable. In this research, the immunological mechanisms of BCc1 nanomedicine on tumor-bearing mice were investigated. BALB/c mice underwent tumor transplantation and were assigned into four groups. Group 1 was orally administered with PBS buffer, Group 2 was orally administered BCc1 10 mg/kg, and Group 3 was orally administered BCc1 40 mg/kg daily, respectively. In addition, a group of mice was administered Cyclophosphamide, 20 mg/kg daily. The weight and tumor volume of mice were evaluated bi-weekly. After 24 days of treatment, cytokines and CTL assay in the spleen cell and the tumor were assessed. Furthermore, the spleen, liver, kidney, lung, gut, and uterine tissue were stained with hematoxylin and eosin. Finally, the tumor samples were stained and analyzed for FOXP3. The survival rate of mice was recorded. The results confirmed the histological safety of BCc1. This nanomedicine, especially BCc1 10 mg/kg, led to a strong IFN-γ response and suppressed TGF-β cytokine. The frequency of Treg in the tumor tissue of BCc1 nanomedicine groups was decreased. In addition, nanomedicine repressed tumor volume and tumor weight significantly, which was comparable to Cyclophosphamide. These immunologic events increased the survival rate of BCc1-treated groups. The results indicate that BCc1 nanomedicine can suppress tumor growth and thereby increase the survival rate of experimental mice. It seems a modulation in the tumor microenvironment and polarization toward a Th1 response may be involved. So, BCc1 nanomedicine is efficient for human cancer therapy.

Comparative analysis of innate immune responses in Sonali and broiler chickens infected with tribasic H9N2 low pathogenic avian influenza virus

BackgroundH9N2 avian influenza viruses have been circulating in Bangladesh since 2006, affecting multiple avian species and resulting in economic losses. The recent emergence of tribasic strains, along with co-infections, has increased the risk to poultry health. Therefore, the study aimed to compare the immune responses of Sonali (crossbred) and commercial broiler chickens infected with tribasic H9N2 low pathogenic avian influenza (LPAI) virus.MethodsFollowing H9N2 infection, proinflammatory (IL-6, IL-8, IL-1β and TNF-α) and antiviral (IFN-β and IFN-γ) cytokine expressions were observed in the trachea, lungs, intestine, and lymphoid tissues in Sonali and broiler chickens from 1 day post infection (dpi) to 10 dpi by qPCR.ResultsSonali chickens exhibited significantly higher proinflammatory and antiviral cytokine expressions in the trachea at 3–7 days post infection (dpi), while broiler chickens showed lower immune responses. Broiler chickens displayed prolonged IL-6, IL-8, and IL-1β expression in lungs at 3–10 dpi compared to Sonali chickens. In the intestine, broiler chickens showed higher IL-6 and IL-8 expression that peaks at 1–3 dpi, while in Sonali chickens only IL-1β elevated at 10 dpi. In response to the H9N2 viruses, broiler chickens exhibited a stronger early IFN-β responses and a delayed IFN-γ responses in their lymphoid organs compared to Sonali chickens.ConclusionThis suggests distinct immune profiles between the chicken types in response to the H9N2 infection. The information sheds light on the function of innate immunity in the pathophysiology of currently circulating tribasic H9N2 virus and could assist in effective controlling of avian influenza virus spread in poultry and designing vaccines.

Schistosome and malaria exposure and urban–rural differences in vaccine responses in Uganda: a causal mediation analysis using data from three linked randomised controlled trials

Vaccine immunogenicity and effectiveness vary geographically. Chronic immunomodulating parasitic infections including schistosomes and malaria have been hypothesised to be mediators of geographical variations. We compared vaccine-specific immune responses between three Ugandan settings (schistosome-endemic rural, malaria-endemic rural, and urban) and did causal mediation analysis to assess the role of Schistosoma mansoni and malaria exposure in observed differences. We used data from the control groups of three linked randomised trials investigating the effects of intensive parasite treatment among schoolchildren. All participants received the BCG vaccine (week 0); yellow fever (YF-17D), oral typhoid (Ty21a), human papillomavirus (HPV; week 4); and HPV booster and tetanus-diphtheria (week 28). Primary outcomes were vaccine responses at week 8 and, for tetanus-diphtheria, week 52. We estimated the total effect (TE) of setting on vaccine responses and natural indirect effect (NIE) mediated through current or previous infection with S mansoni or malaria, and baseline vaccine-specific responses. We included 239 (43%) participants from the schistosomiasis-endemic setting, 171 (30%) from the malaria-endemic setting, and 151 (27%) from the urban setting. At week 8, vaccine responses were lower in rural settings: schistosomiasis-endemic versus urban settings (TE geometric mean ratio for YF-17D plaque reduction neutralisation at 50% (PRNT50) titres 0·58 [95% CI 0·37 to 0·91], for S Typhi O-lipopolysaccharide-specific IgG 0·61 [0·40 to 0·93], and for tetanus-specific IgG 0·33 [0·22 to 0·51]); malaria-endemic versus urban settings (YF-17D 0·70 [0·49 to 0·99], S Typhi O-lipopolysaccharide-specific IgG 0·29 [0·20 to 0·43], and tetanus-specific IgG 0·53 [-0·35 to 0·80]). However, we found higher BCG-specific IFNγ responses in the malaria-endemic versus urban setting (1·54 [1·20 to 1·98]). The estimated NIEs of setting on vaccine responses mediated through previous and current S mansoni and malaria were not statistically significant. For malaria-endemic versus urban settings, baseline vaccine-specific responses contributed to some but not all differences: S Typhi O-lipopolysaccharide-specific IgG at week 8 (57.9% mediated [38·6 to 77·2]) and week 52 (70·0% mediated [49·4 to 90·6]) and BCG at week 52 (46.4% mediated [-4·8 to 97·7]). We found significant variation in vaccine response between urban and rural settings but could not confirm a causal role for schistosome or malaria exposure. Other exposures require consideration. UK Medical Research Council.

Relative Importance of Defined Mycobacterium Tuberculosis Antigens in the T Cell Recognition Repertoire of Latently Infected Individuals not Progressing to Active Disease.

In this study, we have mapped the relative importance of well-defined recombinantly expressed Mycobacterium tuberculosis antigens in the T cell recognition repertoire of latently infected individuals not progressing to active disease. Peripheral blood mononuclear cells from healthy latently infected long term non-progressors were screened for antigen-induced proliferation and Th1 cytokine, Interferon- (IFN-γ) responses. The panel of antigens tested showed a clear spectrum of responsiveness and lead to the identification of a subgroup of frequently recognized antigens (MPT59, CFP7, CFP10, CFP21, TB37.6 /PPE68, ESAT-6, MPT51, and DnaK) with a high cellular response level as measured in both proliferation and IFN-γ assays. Among a subgroup of antigens also screened for responses in tuberculosis patients, CFP21 was identified as differentially recognized in non-progressors. For both cellular assays, we found a positive correlation between responder frequency and magnitude of response. A significant correlation between the level of antigen-specific proliferation and INF-γ secretion was also observed. We have identified a defined set of M. tuberculosis antigens frequently recognized by T cells at a high response level from latently infected long term non-progressors which warrant further investigation for a potential role in immune regulation and protection against progression to active disease.

Caspase-1 in Cx3cr1-expressing cells drives an IL-18-dependent T cell response that promotes parasite control during acute Toxoplasma gondii infection.

Inflammasome activation is a robust innate immune mechanism that promotes inflammatory responses through the release of alarmins and leaderless cytokines, including IL-1α, IL-1β, and IL-18. Various stimuli, including infectious agents and cellular stress, cause inflammasomes to assemble and activate caspase-1. Then, caspase-1 cleaves targets that lead to pore formation and leaderless cytokine activation and release. Toxoplasma gondii has been shown to promote inflammasome formation, but the cell types utilizing caspase-1 and the downstream effects on immunological outcomes during acute in vivo infection have not been explored. Here, using knockout mice, we examine the role of caspase-1 responses during acute T. gondii infection globally and in Cx3cr1-positive populations. We provide in vivo evidence that caspase-1 expression is critical for, IL-18 release, optimal interferon-γ (IFN-γ) production, monocyte and neutrophil recruitment to the site of infection, and parasite control. Specifically, we find that caspase-1 expression in Cx3cr1-positive cells drives IL-18 release, which potentiates CD4+ T cell IFN-γ production and parasite control. Notably, our Cx3cr1-Casp1 knockouts exhibited a selective T cell defect, mirroring the phenotype observed in Il18 knockouts. In further support of this finding, treatment of Cx3cr1-Casp1 knockout mice with recombinant IL-18 restored CD4+ T cell IFN-γ responses and parasite control. Additionally, we show that neutrophil recruitment is dependent on IL-1 receptor accessory protein (IL-1RAP) signaling but is dispensable for parasite control. Overall, these experiments highlight the multifaceted role of caspase-1 in multiple cell populations contributing to specific pathways that collectively contribute to caspase-1 dependent immunity to T. gondii.

Innate cells and STAT1-dependent signals orchestrate vaccine-induced protection against invasive Cryptococcus infection.

Fungal pathogens are underappreciated causes of significant morbidity and mortality worldwide. In previous studies, we determined that a heat-killed, Cryptococcus neoformans fbp1-deficient strain (HK-fbp1) is a potent vaccine candidate. We determined that vaccination with HK-fbp1 confers protective immunity against lethal Cryptococcosis in an interferon γ (IFNγ)-dependent manner. In this study, we set out to uncover cellular sources and relevant targets of the protective effects of IFNγ in response to the HK-fbp1 vaccine. We found that early IFNγ production peaks at day 3 and that monocytes and neutrophils are important sources of this cytokine after vaccination. Neutralization of IFNγ at day 3 results in impaired CCR2+ monocyte recruitment and reduced differentiation into monocyte-derived dendritic cells (Mo-DC). In turn, depletion of CCR2+ cells prior to immunization results in impaired activation of IFNγ-producing CD4 and CD8 T cells. Thus, monocytes are important targets of innate IFNγ and help promote further IFNγ production by lymphocytes. We employed monocyte-fate mapper and conditional STAT1 knockout mice to uncover that STAT1 activation in CD11c+ cells, including alveolar macrophages, Mo-DCs, and monocyte-derived macrophages (Mo-Mac) is essential for HK-fbp1 vaccine-induced protection. Altogether, our aggregate findings suggest critical roles for innate cells as orchestrators of vaccine-induced protection against Cryptococcus infection.IMPORTANCEThe number of patients susceptible to invasive fungal infections across the world continues to rise at an alarming pace yet current antifungal drugs are often inadequate. Immune-based interventions and novel antifungal vaccines hold the promise of significantly improving patient outcomes. In previous studies, we identified a Cryptococcus neoformans mutant strain (Fbp1-deficient) as a potent, heat-inactivated vaccine candidate capable of inducing homologous and heterologous antifungal protection. In this study, we used a combination of methods together with a cohort of conditional knockout mouse strains to interrogate the roles of innate cells in the orchestration of vaccine-induced antifungal protection. We uncovered novel roles for neutrophils and monocytes as coordinators of a STAT1-dependent cascade of responses that mediate vaccine-induced protection against invasive cryptococcosis. This new knowledge will help guide the future development of much-needed antifungal vaccines.

7820 Immune system adaptation during gender-affirming testosterone treatment

Abstract Disclosure: T. Lakshmikanth: None. C. Consiglio: None. F. Sardh: None. R. Forlin: None. J. Wang: None. Z. Tan: None. H. Barencilla: None. L. Rodriguez: None. J. Sugrue: None. P. Noori: None. M. Ivanchenko: None. L. Piñero Páez: None. L. Gonzalez: None. C. Habimana Mugabo: None. A. Johnsson: None. H. Ryberg: None. Å. Hallgren: None. C. Pou: None. Y. Chen: None. J. Mikeš: None. A. James: None. P.M. Dahlqvist: None. J. Wahlberg Hughes: None. A. Hagelin: None. M. Holmberg: None. M. Degerblad: None. M. Isaksson: None. D. Duffy: None. O. Kampe: None. N. Landegren: None. P. Brodin: None. Immune system adaptation during gender-affirming testosterone treatment Infectious, inflammatory and autoimmune conditions present differently in males and females. Following SARS-CoV-2 infection, male sex is associated with increased risk of death, while female sex is associated with increased risk of the postinfectious disorder, long COVID. Similar trends are seen in other infections. Female immune responses to vaccines are typically stronger, and adverse reactions are more frequent, like most autoimmune diseases. Immunological sex-differences stem from genetic, hormonal and behavioural factors but their relative importance is poorly understood. To understand the consequences of changing sex-hormones in vivo, we performed longitudinal, systems-level analyses in 22 adults, assigned female at birth, and undergoing gender-affirming testosterone treatment (trans-men). We find that sex hormones modulate a cross-regulation axis of type-I interferon (IFN-I) and TNFα in humans. This is mediated by a reduced frequency of plasmacytoid dendritic cells (pDC), and functional attenuation of IFN-I responses in both pDCs and monocytes. Conversely, testosterone potentiates monocyte responses to lipopolysaccharide (LPS) leading to increased TNFα, IL-6 and IL-15 production and downstream epigenetic opening of NFκB regulated genes and potentiation of IFNγ responses, primarily by NK cells. IFNγ in turn feeds back onto monocytes leading to upregulation of SLAMF7 and further enhanced TNFα responses by myeloid cells. These results are corroborated by sex-divergent responses in multiple public datasets and collectively illustrate the dynamic recalibration of human immune systems by sex hormones with implications for individuals undergoing gender-affirming hormone therapy, but also better understanding of divergent responses to infection, vaccines and self-antigens in cisgender individuals. Presentation: 6/2/2024

7820 Immune system adaptation during gender-affirming testosterone treatment

Abstract Disclosure: T. Lakshmikanth: None. C. Consiglio: None. F. Sardh: None. R. Forlin: None. J. Wang: None. Z. Tan: None. H. Barencilla: None. L. Rodriguez: None. J. Sugrue: None. P. Noori: None. M. Ivanchenko: None. L. Piñero Páez: None. L. Gonzalez: None. C. Habimana Mugabo: None. A. Johnsson: None. H. Ryberg: None. Å. Hallgren: None. C. Pou: None. Y. Chen: None. J. Mikeš: None. A. James: None. P.M. Dahlqvist: None. J. Wahlberg Hughes: None. A. Hagelin: None. M. Holmberg: None. M. Degerblad: None. M. Isaksson: None. D. Duffy: None. O. Kampe: None. N. Landegren: None. P. Brodin: None. Infectious, inflammatory and autoimmune conditions present differently in males and females. Following SARS-CoV-2 infection, male sex is associated with increased risk of death, while female sex is associated with increased risk of the postinfectious disorder, long COVID. Similar trends are seen in other infections. Female immune responses to vaccines are typically stronger, and adverse reactions are more frequent, like most autoimmune diseases. Immunological sex-differences stem from genetic, hormonal and behavioural factors but their relative importance is poorly understood. To understand the consequences of changing sex-hormones in vivo, we performed longitudinal, systems-level analyses in 22 adults, assigned female at birth, and undergoing gender-affirming testosterone treatment (trans-men). We find that sex hormones modulate a cross-regulation axis of type-I interferon (IFN-I) and TNFα in humans. This is mediated by a reduced frequency of plasmacytoid dendritic cells (pDC), and functional attenuation of IFN-I responses in both pDCs and monocytes. Conversely, testosterone potentiates monocyte responses to lipopolysaccharide (LPS) leading to increased TNFα, IL-6 and IL-15 production and downstream epigenetic opening of NFκB regulated genes and potentiation of IFNγ responses, primarily by NK cells. IFNγ in turn feeds back onto monocytes leading to upregulation of SLAMF7 and further enhanced TNFα responses by myeloid cells. These results are corroborated by sex-divergent responses in multiple public datasets and collectively illustrate the dynamic recalibration of human immune systems by sex hormones with implications for individuals undergoing gender-affirming hormone therapy, but also better understanding of divergent responses to infection, vaccines and self-antigens in cisgender individuals. Presentation: 6/2/2024

Interferon-induced factor 16 is essential in metastatic melanoma to maintain STING levels and the immune responses upon IFN-γ response pathway activation

BackgroundImmune checkpoint inhibitor (ICIs)-based therapies are the standard of care treatment for patients with metastatic melanoma (MM). The stimulator of interferon genes (STING) signaling pathway is critical in controlling immune...

Impact of AIM2 on HNSCC Development.

Head and neck squamous cell carcinoma (HNSCC) constitutes 90% of head and neck cancers. HNSCC development is linked to chronic inflammation, while established HNSCC tumors are often immune suppressive. However, both occur through mechanisms that are not fully understood. The cytosolic double-stranded DNA sensor Absent in Melanoma 2 (AIM2) is an inflammasome forming protein that also has inflammasome-distinct roles in restricting tumorigenesis by limited PI3K signaling. Here, we used an experimental mouse model of HNSCC, involving treatment of wild type (WT) and Aim2 -/- mice with the carcinogen 4NQO in drinking water. Compared to WT mice, 4NQO-treated Aim2 -/- mice exhibited larger tumor sizes and increased tissue dysplasia. 4NQO-treated wild type and Aim2 -/- mice displayed similar tongue Il6, Tnf, Il1b, Il12, and Il10 expression and no consistent differences in PI3K or inflammasome activation, suggesting AIM2 may not regulate these factors during HNSCC. Instead, Ifng and Irf1 was elevated in 4NQO-treated Aim2 -/- mice, suggesting AIM2 restricts IFNγ. In line with this, RNA-sequencing of total tongue RNA from 4NQO-treated mice revealed Aim2 -/- mice had enhanced expression of genes related to the MHC protein complex, cell killing, and T cell activation compared to wild type mice. In addition, we observed increased macrophage infiltration into the tongue epithelium of 4NQO-treated Aim2 -/- mice. Lastly, using Aim2 -/- / Rag1 -/- -double deficient animals, we found that the adaptive immune compartment was necessary for the enhanced tumorigenesis during AIM2 deficiency. Taken together, these findings suggest AIM2 limits the progression of oral tumor development partially through regulating IFNγ and adaptive immune responses.

Therapy modulates the response to T cell epitopes over the spectrum of tuberculosis infection

Identifying stage-specific antigens is essential for developing tuberculosis (TB) diagnostics and vaccines. In a low TB endemic country, we characterized, the Mycobacterium tuberculosis (Mtb)-specific immune response to a pool of Mtb-derived epitopes (ATB116), demonstrated as associated with TB disease. In this prospective observational cross-sectional study, we enrolled healthy donors (HD), subjects with TB disease, and TB infection (TBI) at baseline and therapy completion. T-cell response after whole blood stimulation with the peptide pools was characterized by ELISA, flow cytometry, and multiplex assay. ATB116-specific IFN-γ response (by ELISA) significantly associates with Mtb regardless of infection/disease (p<0.0001) and decreases during TB therapy (p=0.0002). Flow cytometry confirms that ATB116-specific CD4+ T-cell response associated with Mtb regardless of infection/disease (p<0.0001) and shows a significantly higher frequency of IFN-γ/IL-2 and central memory T-cells in TBI compared to TB (p=0.016; p=0.0242, respectively). CD4+ T cell-specific response decreases after TB therapy completion. The antigen-specific CD8+ T-cell response mirrors the CD4+ response. Finally, the multiplex assay analysis showed that ATB116 induces several immune factors in both TB and TBI. We characterized the immune response to Mtb peptide pools that is modulated by TB therapy. These results are important for our understanding of TB immunopathogenesis and vaccine design.