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BackgroundInterleukin-17 (IL-17) family cytokines promote protective inflammation for pathogen resistance,but also facilitate autoimmunity and tumor development. A direct signal of IL-17 to regulatory T cells (Tregs) has not been reported and may help explain these dichotomous responses.MethodsWe generated a conditional knockout of Il17ra in Tregs by crossing Foxp3-YFP-Cre mice to Il17ra-flox mice (Il17ra ΔTreg mice). Subsequently,we adoptively transferred bone marrow cells from Il17ra ΔTreg mice to a mouse model of sporadic colorectal cancer (Cdx2-Cre +/Apc F/+),to selectively ablate IL-17 direct signaling on Tregs in colorectal cancer. Single cell RNA sequencing and bulk RNA sequencing were performed on purified Tregs from mouse colorectal tumors,and compared to those of human tumor infiltrating Treg cells.ResultsIL-17 Receptor A (IL-17RA) is expressed in Tregs that reside in mouse mesenteric lymph nodes and colon tumors. Ablation of IL-17RA,specifically in Tregs,resulted in increased Th17 cells,and exacerbated tumor development. Mechanistically,tumor-infiltrating Tregs exhibit a unique gene signature that is linked to their activation,maturation,and suppression function,and this signature is in part supported by the direct signaling of IL-17 to Tregs. To study pathways of Treg programming,we found that loss of IL-17RA in tumor Tregs resulted in reduced RNA splicing,and downregulation of several RNA binding proteins that are known to regulate alternative splicing and promote Treg function.ConclusionIL-17 directly signals to Tregs and promotes their maturation and function. This signaling pathway constitutes a negative feedback loop that controls cancer-promoting inflammation in CRC. View Publication

IntroductionInnate lymphoid cells (ILCs) are enriched at mucosal surfaces where they respond rapidly to environmental stimuli and contribute to both tissue inflammation and healing. MethodsTo gain insight into the role of ILCs in the pathology and recovery from COVID-19 infection,we employed a multi-omics approach consisting of Abseq and targeted mRNA sequencing to respectively probe the surface marker expression,transcriptional profile and heterogeneity of ILCs in peripheral blood of patients with COVID-19 compared with healthy controls. ResultsWe found that the frequency of ILC1 and ILC2 cells was significantly increased in COVID-19 patients. Moreover,all ILC subsets displayed a significantly higher frequency of CD69-expressing cells,indicating a heightened state of activation. ILC2s from COVID-19 patients had the highest number of significantly differentially expressed (DE) genes. The most notable genes DE in COVID-19 vs healthy participants included a) genes associated with responses to virus infections and b) genes that support ILC self-proliferation,activation and homeostasis. In addition,differential gene regulatory network analysis revealed ILC-specific regulons and their interactions driving the differential gene expression in each ILC. DiscussionOverall,this study provides mechanistic insights into the characteristics of ILC subsets activated during COVID-19 infection. View Publication

SummaryTumor-infiltrating regulatory T cells (TI-Tregs) elicit immunosuppressive effects in the tumor microenvironment (TME) leading to accelerated tumor growth and resistance to immunotherapies against solid tumors. Here,we demonstrate that poly-(ADP-ribose)-polymerase-11 (PARP11) is an essential regulator of immunosuppressive activities of TI-Tregs. Expression of PARP11 correlates with TI-Treg cell numbers and poor responses to immune checkpoint blockade (ICB) in human patients with cancer. Tumor-derived factors including adenosine and prostaglandin E2 induce PARP11 in TI-Tregs. Knockout of PARP11 in the cells of the TME or treatment of tumor-bearing mice with selective PARP11 inhibitor ITK7 inactivates TI-Tregs and reinvigorates anti-tumor immune responses. Accordingly,ITK7 decelerates tumor growth and significantly increases the efficacy of anti-tumor immunotherapies including ICB and adoptive transfer of chimeric antigen receptor (CAR) T cells. These results characterize PARP11 as a key driver of TI-Treg activities and a major regulator of immunosuppressive TME and argue for targeting PARP11 to augment anti-cancer immunotherapies. Graphical abstract Highlights•Tumor-derived factors upregulate PARP11 in the tumor-infiltrating Treg cells•PARP11 supports the immunosuppressive properties of Treg cells•Pharmacologic inhibition of PARP11 inactivates intratumoral Treg cells•PARP11 inhibitor augments the efficacy of immunotherapies Basavaraja et al. demonstrate that induction of PARP11 in the intratumoral regulatory T (Treg) cells is required for their regulatory functions and contributes to the immunosuppressive tumor microenvironment. The selective inhibitor of PARP11 ITK7 inactivates tumor Treg cells and improves the efficacy of immunotherapies against tumors. View Publication

SummaryA tissue resident-like phenotype in tumor infiltrating T cells can limit systemic anti-tumor immunity. Enhanced systemic anti-tumor immunity is observed in head and neck cancer patients after neoadjuvant PD-L1 immune checkpoint blockade (ICB) and transforming growth factor β (TGF-β) neutralization. Using T cell receptor (TCR) sequencing and functional immunity assays in a syngeneic model of oral cancer,we dissect the relative contribution of these treatments to enhanced systemic immunity. The addition of TGF-β neutralization to ICB resulted in the egress of expanded and exhausted CD8+ tumor infiltrating lymphocytes (TILs) into circulation and greater systemic anti-tumor immunity. This enhanced egress associated with reduced expression of Itgae (CD103) and its upstream regulator Znf683. Circulating CD8+ T cells expressed higher Cxcr3 after treatment,an observation also made in samples from patients treated with dual TGF-β neutralization and ICB. These findings provide the scientific rationale for the use of PD-L1 ICB and TGF-β neutralization in newly diagnosed patients with carcinomas prior to definitive treatment of locoregional disease. Graphical abstract Highlights•TGF-β blockade reduces Znf683 and CD103 in αPDL1-activated TILs•Reduced TIL CD103 expression associates with egress into circulation•The addition of TGF-β blockade to αPDL1 enhances systemic anti-tumor immunity•Circulating CD8+ T cells express greater CXCR3 after dual TGF-β and PDL1 blockade Natural sciences; Biological sciences; Immunology ; Immune response; Systems biology; Cancer systems biology; Cancer View Publication

BackgroundAt present,hepatic ischemia-reperfusion injury (IRI) is an important complication of partial hepatectomy and liver transplantation,and it is an important cause of poor prognosis. Spleen tyrosine kinase(SYK) plays an important role in a variety of signaling pathways in the liver,but its role in hepatic IRI is still unclear. This study aims to investigate the role and mechanism of SYK in hepatic IRI and tumor recurrence.MethodsWe first observed the activation of SYK in the liver of mice in response to hepatic IRI. Subsequently,Pharmacological inhibitions of SYK were used to evaluated the effect of SYK on neutrophil recruitment and NETosis,and further explored the effect of SYK on IRI and tumor recurrence.ResultsOur study shows that SYK is activated in response to hepatic IRI and aggravates liver injury. On the one hand,neutrophils SYK during the early stage of liver reperfusion increases neutrophil extracellular traps (NETs) production by promoting Pyruvate kinase M2(PKM2) nuclear translocation leading to upregulation of phosphorylated STAT3,thereby exacerbating liver inflammation and tumor recurrence. On the other hand,macrophages SYK can promote the recruitment of neutrophils and increase the activation of NLRP3 inflammasome and IL1β,which further promotes the formation of NETs.ConclusionsOur study demonstrates that neutrophil and macrophage SYK synergistically promote hepatic IRI and tumor recurrence,and SYK may be a potential target to improve postoperative hepatic IRI and tumor recurrence.Supplementary InformationThe online version contains supplementary material available at 10.1186/s10020-024-00907-7. View Publication

BackgroundMacrophage-based cell therapies have shown modest success in clinical trials,which can be attributed to their phenotypic plasticity,where transplanted macrophages get reprogrammed towards a pro-tumor phenotype. In most tumor types,including melanoma,the balance between antitumor M1-like and tumor-promoting M2-like macrophages is critical in defining the local immune response with a higher M1/M2 ratio favoring antitumor immunity. Therefore,designing novel strategies to increase the M1/M2 ratio in the TME has high clinical significance and benefits macrophage-based cell therapies.MethodsIn this study,we reprogrammed antitumor and proinflammatory macrophages ex-vivo with HDAC6 inhibitors (HDAC6i). We administered the reprogrammed macrophages intratumorally as an adoptive cell therapy (ACT) in the syngeneic SM1 murine melanoma model and patient-derived xenograft bearing NSG-SGM3 humanized mouse models. We phenotyped the tumor-infiltrated immune cells by flow cytometry and histological analysis of tumor sections for macrophage markers. We performed bulk RNA-seq profiling of murine bone marrow-derived macrophages treated with vehicle or HDAC6i and single-cell RNA-seq profiling of SM1 tumor-infiltrated immune cells to determine the effect of intratumor macrophage ACT on the tumor microenvironment (TME). We further analyzed the single-cell data to identify key cell-cell interactions and trajectory analysis to determine the fate of tumor-associated macrophages post-ACT.ResultsMacrophage ACT resulted in diminished tumor growth in both mouse models. We also demonstrated that HDAC6 inhibition in macrophages suppressed the polarization toward tumor-promoting phenotype by attenuating STAT3-mediated M2 reprogramming. Two weeks post-transplantation,ACT macrophages were viable,and inhibition of HDAC6 rendered intratumor transplanted M1 macrophages resistant to repolarization towards protumor M2 phenotype in-vivo. Further characterization of tumors by flow cytometry,single-cell transcriptomics,and single-cell secretome analyses revealed a significant enrichment of antitumor M1-like macrophages,resulting in increased M1/M2 ratio and infiltration of CD8 effector T-cells. Computational analysis of single-cell RNA-seq data for cell-cell interactions and trajectory analyses indicated activation of monocytes and T-cells in the TME.ConclusionsIn summary,for the first time,we demonstrated the potential of reprogramming macrophages ex-vivo with HDAC6 inhibitors as a viable macrophage cell therapy to treat solid tumors.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13046-024-03182-w. View Publication

Crystalline silica (CS) particle exposure leads to silicosis which is characterized as progressive fibrosis. Fibroblasts are vital effector cells in fibrogenesis. Emerging studies have identified immune sentinel roles for fibroblasts in chronic disease,while their immune-modulatory roles in silicosis remain unclear. Herein,we show that group 2 innate lymphoid cell (ILC2) conversion to ILC1s is closely involved in silicosis progression,which is mediated by activated fibroblasts via interleukin (IL)−18. Mechanistically,Notch3 signaling in mechanics-activated fibroblasts modulates IL-18 production via caspase 1 activity. The mouse-specific Notch3 knockout in fibroblasts retards pulmonary fibrosis progression that is linked to attenuated ILC conversion. Our results indicate that activated fibroblasts in silicotic lungs are regulators of ILC2–ILC1 conversion,associated with silicosis progression via the Notch3–IL-18 signaling axis. This finding broadens our understanding of immune-modulatory mechanisms in silicosis,and indicates potential therapeutic targets for lung fibrotic diseases. Crystalline silica particle exposure in the airways can lead to lung silicosis and progressive fibrosis. Here the authors use mouse silicosis models to show mechanics activated fibroblasts promote conversion of ILC2 to ILC1-like cells pulmonary fibrosis and that this is associated with a Notch3-IL-18 signalling pathway. View Publication

Primary antiphospholipid syndrome (PAPS) is a life-threatening clotting disorder mediated by pathogenic autoantibodies. Here we dissect the origin of self-reactive B cells in human PAPS using peripheral blood and bone marrow of patients with triple-positive PAPS via combined single-cell RNA sequencing,B cell receptors (BCR) repertoire profiling,CITEseq analysis and single cell immortalization. We find that antiphospholipid (aPL)-specific B cells are present in the naive compartment,polyreactive,and derived from the natural repertoire. Furthermore,B cells with aPL specificities are not eliminated in patients with PAPS,persist until the memory and long-lived plasma cell stages,likely after defective germinal center selection,while becoming less polyreactive. Lastly,compared with the non-PAPS cells,PAPS B cells exhibit distinct IFN and APRIL signature as well as dysregulated mTORC1 and MYC pathways. Our findings may thus elucidate the survival mechanisms of these autoreactive B cells and suggest potential therapeutic targets for the treatment of PAPS. Primary antiphospholipid syndrome (PAPS) is a clotting disorder attributed to autoreactive antibodies produced by B cells. Here the authors show,using single cell omics and B cell repertoire data,that autoreactive B cells originate from the natural B cell repertoire and escape germinal center selection to persist in PAPS patient via potential dysregulation of mTORC1 and MYC pathways. View Publication

Germinal center (GC) formation,which is an integrant part of humoral immunity,involves energy-consuming metabolic reprogramming. Rag-GTPases are known to signal amino acid availability to cellular pathways that regulate nutrient distribution such as the mechanistic target of rapamycin complex 1 (mTORC1) pathway and the transcription factors TFEB and TFE3. However,the contribution of these factors to humoral immunity remains undefined. Here,we show that B cell-intrinsic Rag-GTPases are critical for the development and activation of B cells. RagA/RagB deficient B cells fail to form GCs,produce antibodies,and to generate plasmablasts during both T-dependent (TD) and T-independent (TI) humoral immune responses. Deletion of RagA/RagB in GC B cells leads to abnormal dark zone (DZ) to light zone (LZ) ratio and reduced affinity maturation. Mechanistically,the Rag-GTPase complex constrains TFEB/TFE3 activity to prevent mitophagy dysregulation and maintain mitochondrial fitness in B cells,which are independent of canonical mTORC1 activation. TFEB/TFE3 deletion restores B cell development,GC formation in Peyer’s patches and TI humoral immunity,but not TD humoral immunity in the absence of Rag-GTPases. Collectively,our data establish the Rag GTPase-TFEB/TFE3 pathway as a likely mTORC1 independent mechanism to coordinating nutrient sensing and mitochondrial metabolism in B cells. Rag-GTPases play roles in sensing nutrient availability,and it is not fully known how they contribute to energy-consuming immunological processes such as the B cell response. Here authors show that genomic deletion fo RagA/RagB distrupts both T-dependent and T-independent humoral immune responses,independent of mechanistic target of rapamycin complex 1 but involving the transcription factors TFEB and TFE3. View Publication

In dynamic systems like the circulatory system,establishing localized cytokine gradients is challenging. Upon lipopolysaccharide (LPS) stimulation,we observed that monocytes release numerous migrasomes enriched with inflammatory cytokines,such as TNF-α and IL-6. These cytokines are transported into migrasomes via secretory carriers,leading to their immediate exocytosis or eventual release from detached migrasomes. We successfully isolated TNF-α and IL-6-enriched,monocyte-derived migrasomes from the blood of LPS-treated mice. Total secretion analysis revealed a substantial amount of TNF-α and IL-6 released in a migrasome-packaged form. Thus,detached,monocyte-derived migrasomes represent a type of extracellular vesicle highly enriched with cytokines. Physiologically,these cytokine-laden migrasomes rapidly accumulate at local sites of inflammation,effectively creating a concentrated source of cytokines. Our research uncovers novel mechanisms for cytokine release and delivery,providing new insights into immune response modulation. View Publication

The fallopian tube undergoes extensive molecular changes during the menstrual cycle and menopause. We use single-cell RNA and ATAC sequencing to construct a comprehensive cell atlas of healthy human fallopian tubes during the menstrual cycle and menopause. Our scRNA-seq comparison of 85,107 pre- and 46,111 post-menopausal fallopian tube cells reveals substantial shifts in cell type frequencies,gene expression,transcription factor activity,and cell-to-cell communications during menopause and menstrual cycle. Menstrual cycle dependent hormonal changes regulate distinct molecular states in fallopian tube secretory epithelial cells. Postmenopausal fallopian tubes show high chromatin accessibility in transcription factors associated with aging such as Jun,Fos,and BACH1/2,while hormone receptors were generally downregulated,a small proportion of secretory epithelial cells had high expression of ESR2,IGF1R,and LEPR. While a pre-menopausal secretory epithelial gene cluster is enriched in the immunoreactive molecular subtype,a subset of genes expressed in post-menopausal secretory epithelial cells show enrichment in the mesenchymal molecular type of high-grade serous ovarian cancer. The fallopian tube undergoes extensive cellular and molecular changes during the menstrual cycle and aging. Here,Weigert et al. present a single-cell atlas of the normal human fallopian tube revealing the transition of secretory epithelial cells throughout the menstrual cycle and menopause. View Publication

Type I Interferons (IFN-I) are central to host protection against viral infections,with plasmacytoid dendritic cells (pDC) being the most significant source,yet pDCs lose their IFN-I production capacity following an initial burst of IFN-I,resulting in susceptibility to secondary infections. The underlying mechanisms of these dynamics are not well understood. Here we find that viral infection reduces the capacity of pDCs to engage both oxidative and glycolytic metabolism. Mechanistically,we identify lactate dehydrogenase B (LDHB) as a positive regulator of pDC IFN-I production in mice and humans; meanwhile,LDHB deficiency is associated with suppressed IFN-I production,pDC metabolic capacity,and viral control following infection. In addition,preservation of LDHB expression is sufficient to partially retain the function of otherwise exhausted pDCs,both in vitro and in vivo. Furthermore,restoring LDHB in vivo in pDCs from infected mice increases IFNAR-dependent,infection-associated pathology. Our work thus identifies a mechanism for balancing immunity and pathology during viral infections,while also providing insight into the highly preserved infection-driven pDC inhibition. Plasmacytoid dendritic cells (pDC) are the major IFN-I-producing cells,but this production returns to baseline soon after viral infection. Here the authors show that this decrease in IFN-I production and related pDC functions may be attributed to suppressed oxidative and glycolytic metabolism of pDCs,with lactate dehydrogenase B identified as a regulator. View Publication