Discovery Immunology
◐ Oxford University Press (OUP)
Preprints posted in the last 7 days, ranked by how well they match Discovery Immunology's content profile, based on 11 papers previously published here. The average preprint has a 0.01% match score for this journal, so anything above that is already an above-average fit.
Pumpe, C.; Sanderson, A.; Forsyth, B.; Simunovic, J.; Narimatsu, Y.; Clausen, H.; Lauc, G.; Cragg, M.; Bruhns, P.; Gray, M.; Benezech, C.; Hayward, C.; Vermeren, S.
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The IgG Fc chain carries a single N-linked glycan which may undergo changes. Increased agalactosylated N-glycans are associated with rheumatoid arthritis (RA) and regarded as pro-inflammatory. Dysregulated neutrophils can make important contributions to host tissue damage. In RA, immune complexes (ICs) that have precipitated onto synovial joint surfaces activate neutrophils via Fc receptors, promoting localised inflammation. We engineered recombinant human monoclonal IgG with agalactosylated or galactosylated N-glycans, generated immobilised ICs and stimulated healthy donor and RA patient blood-derived neutrophils, comparing reactive oxygen species (ROS) production as read-out of neutrophilic inflammation. Both healthy donor and RA patient neutrophils generated less ROS when stimulated with ICs made from agalactosylated IgG. Mechanistically this was due to poorer binding of agalactosylated ICs to neutrophil FcgammaRs, causing lower activation of Akt and p38 MAPK. Both are required for immobilised IC-mediated stimulation of the neutrophil NADPH oxidase. Taken together, this suggests that disease-associated, agalactosylated IgG does not in fact promote inflammation and host tissue injury, at least not by acting on neutrophils. We propose that rather than promoting inflammation, agalactosylated IgG N-glycans that accompany inflammatory disease may arise as part of a compensatory mechanism that is aimed at reducing excessive inflammation and host tissue injury.
Zafar, A.; Chauhan, G.; Mukherjee, P. K.; Marino-Melendez, A.; Musich, R.; Wang, Y.; Naydenov, N. G.; Rieder, F.; Ivanov, A. I.
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Cell division cycle 42 (Cdc42) is a member of the Rho family of small GTPases, which plays crucial roles in regulating cytoskeletal remodeling, and membrane trafficking. While previous studies implicated Cdc42 in controlling intestinal epithelial homeostasis, the involvement of this small GTPase in the process of intestinal fibrogenesis remains unexplored. Our study was designed to determine whether Cdc42 regulates the fibrogenic activation of intestinal myofibroblasts in vitro. The study was conducted using a CCD-18Co normal human colonic fibroblast cell line, and primary human intestinal myofibroblasts (HIMF) isolated from Crohns disease (CD) patients. CCD-18Co and HIMF cells were stimulated by transforming growth factor-{beta}1 (TGF-{beta}1). Cdc42 was inhibited either genetically, using siRNA-mediated knockdown, or pharmacologically using specific Cdc42 inhibitors, ML141 and CASIN. Genetic and pharmacologic inhibition of Cdc42 markedly reduced TGF-{beta}1 induced expression of the major contractile cytoskeletal proteins, -smooth muscle actin, calponin 1 and L-caldesmon. Furthermore, Cdc42 inhibition significantly attenuated expression of key extracellular matrix (ECM) proteins, fibronectin and collagen I, in activated CCD-18Co cells and HIMF. Interestingly, decreased expression of contractile and ECM proteins in Cdc42-depleted myofibroblasts was not due to downregulation of the TGF-{beta}1 signaling, decreased mRNA transcription or increased lysosomal or proteasomal degradation of these proteins. Such suppressed pro-fibrotic activation of Cdc42-deficient CCD-18Co cells and HIMF involved a selective inhibition of protein translation due to inactivation of the AKT-mammalian target of rapamycin (mTOR) signaling module. These findings highlight Cdc42 as a key regulator of intestinal fibrosis that controls mTOR activation to enhance ECM production and contractile actomyosin cytoskeleton in intestinal myofibroblasts.
Barre, E.; Lourenco-Rodrigues, M.-D.; Zimmermann, L.; Pugliano, M.; Loubiere, C.; Proamer, F.; Rinckel, J.-Y.; Eckly, A.; Qu, Z.; Miao, J.; Zhang, Z.-Y.; Senis, Y. A.; Mazharian, A.
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The Src homology 2 (SH2) domain-containing non-transmembrane protein-tyrosine phosphatases 1 and 2 (Shp1 and Shp2) have been implicated in regulating signaling from a variety of receptors and cell types, including the thrombopoietin (Tpo) receptor Mpl in megakaryocytes (MKs) and platelets. We previously showed that deletion of Shp1 and Shp2 in the MK/platelet lineage in mice using the Pf4-Cre transgene/loxP system impairs megakaryopoiesis and thrombopoiesis. However, we also observed unexpected phenotypes including a motheaten-like phenotype in Shp1-deficient mice and severe myelofibrosis in mice lacking both phosphatases. To determine whether these were lineage-specific effects, we utilized the Gp1ba-Cre transgenic mouse to delete loxP-flanked Shp1 and Shp2 in mice. Bone marrow-derived MKs from these mice expressed approximately 20-25% of Shp1 and Shp2, whereas platelets contain 5-10% of each phosphatase compared with controls. Minor MK/platelet defects were observed in mice lacking either Shp1 or Shp2 alone, however mice lacking both Shp1 and Shp2 exhibited macrothrombocytopenia, mild bleeding following tail injury, and impaired GPVI-mediated platelet aggregation and Syk phosphorylation, associated with reduction GPVI and integrin 2 subunit expression. Reduced Shp1 and Shp2 expression resulting in a significant reduction in ploidy, a block in MK maturation and proplatelet-producing MKs. Tpo-mediated Ras/MAPK signaling was reduced in Shp1/2-deficient MKs. Treatment of MKs with structurally distinct Shp2 allosteric inhibitors recapitulated key aspects of the Shp2-deficient phenotype, including aberrant megakaryopoiesis and reduced Mpl signaling. Our study highlights the synergistic functions of Shp1 and Shp2 in the MK/platelet lineage, and identifies Shp2 as a potential therapeutic target in myeloproliferative neoplasms. Key PointsO_LIDeletion of Shp1 and Shp2 in the MK/platelet lineage in mice results in macrothrombocytopenia and minor effects on platelet function. C_LIO_LIDefects can be partially explained by reduced Mpl signaling and aberrant megakaryopoiesis in the absence of Shp2 activity. C_LI
thomas, J.; Eyer, K.; Wittner, J.; Rollenske, T.; Roth, E.; Xiang, W.; Schuh, W.; Jaeck, H.-M.; Mielenz, D.; Schulz, S.
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Dimeric immunoglobulin A (dIgA) is generated from IgA monomers (mIgA) via JCHAIN-dependent polymerization. DIgA is transported across epithelial barriers by the poly Ig receptor (PIGR) and confers mucosal protection, while serum contains substantial amounts of IgA monomers. Distinct plasma cell subsets have been proposed to produce either monomeric or dimeric IgA, with bone marrow plasma cells as a primary source of mIgA. Here, we addressed whether IgA plasma cell populations segregate based on mIgA or dIgA production. Flow cytometric analysis of antibody-secreting cells from bone marrow, lymphoid and mucosal tissues revealed universal intracellular JCHAIN expression across isotypes and failed to identify a discrete JCHAIN-negative IgA plasma cell population. To detect polymeric IgA, we generated a recombinant soluble PIGR that selectively bound JCHAIN-containing dIgA in Western blot, ELISA, and flow cytometry. Soluble PIGR binding was detected in all IgA plasma cells irrespective of tissue origin, arguing against a dedicated mIgA-producing plasma cell subset incapable of dIgA formation. Ex vivo cultures and single-cell DropMap secretion assays demonstrated that bone marrow and lamina propria IgA antibody-secreting cells co-secrete mIgA and dIgA. These findings suggest that dIgA assembly and secretion are general properties of IgA plasma cells and disfavor a dedicated mIgA-producing population.
Sheta, D.; Mokhtari, Z.; Strobel, M.; Yu, Y.; Wittmann, P.; Abboud, Z.; Kern, M. A. G.; Amich, J.; Trinks, N.; Reinhard, S.; Hirsch, S.; Aleksic, I.; Drosos, V.; Ibrahim, E. S.; Guenther, K.; Ohlsen, K.; Fraunholz, M. J.; Stigloher, C.; Lopez, A. G.; Schaeuble, S.; Nieuwenhuizen, N.; Koehler, T.; Kurzai, O.; Saliba, A.-E.; Arampatzi, P.; Westermann, A. J.; Jordan, P. M.; Werz, O.; Loeffler, J.; Panagiotou, G.; Einsele, H.; Sauer, M.; Heinze, K. G.; Lutz, M. B.; Hermanns, H. M.; Terpitz, U.; Beilhack, A.
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Invasive pulmonary aspergillosis poses a life-threatening complication in immunocompromised individuals, including recipients of allogeneic hematopoietic cell transplantation (allo-HCT). By contrast, immunocompetent individuals are usually protected against infection with Aspergillus fumigatus, the causative agent of aspergillosis. The mechanisms underlying pulmonary innate immune protection remain poorly understood. Here, we identify alveolar macrophages (AMs) as key players in pulmonary antifungal defense. In immunocompromised mice, AMs conferred protection against lethal invasive aspergillosis by day 6, but not day 4 post-allo-HCT. To enhance AM function at the earlier time point, we tested cytokine-based interventions and showed that M-CSF, but not IL-34, which both bind to the CSF-1 receptor, promotes migratory activity, phagolysosomal function and fungal killing in both mouse and human primary tissue-resident AMs. In allo-HCT recipient mice, M-CSF treatment preserved lung tissue integrity, suppressed pro-inflammatory cytokines, and protected mice from lethal invasive aspergillosis. The M-CSF-driven protective effect was abrogated upon AM depletion. Our findings demonstrate a critical role of tissue-resident AMs in pulmonary antifungal immunity and suggest that therapeutic modulation of AM activity via M-CSF may offer a promising strategy to combat severe fungal infections in immunocompromised patients.
Leddy, R. S.; Phelan, H. M.; Connolly, C.; Wehrmann, F.; Winter, D. C.; Brennan, L.; O'Connell, D.; Aherne, C. M.; Collins, C. B.
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Cannabinoid receptor 2 (CB2R) is highly expressed on immune cells, but its role in T cell metabolism remains unclear. Here, we show that CB2R activation rapidly increases glucose uptake in human Jurkat T cells and drives a broader metabolic reprogramming away from glycolysis toward oxidative metabolism and the pentose phosphate pathway. Pharmacological CB2R activation increased mitochondrial mass, spare respiratory capacity, proton leak, and NADPH production, while CB2R inverse agonism produced the opposite effects. These metabolic changes were accompanied by upregulation of key pentose phosphate pathway enzymes, including GALT and TALDO1, and were abolished in CNR2-deficient cells, confirming receptor dependence. In primary human lamina propria mononuclear cells, CB2R signalling also influenced memory and gut-homing-associated T cell phenotypes, including integrin 4{beta}7 expression. Together, these findings identify CB2R as a regulator of T cell bioenergetics and suggest that cannabinoid signalling may promote metabolic states linked to memory and tissue-homing functions in chronic intestinal inflammation.
Zimmann, N.; Havelka, M.; Zdrha, A.; Prochazkova, J.; Smutna, T.; Rada, P.; Verner, Z.; Hart, A.; Sharma, J.; Biboy, J.; Vollmer, D.; Vollmer, W.; Tachezy, J.
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A low abundance or absence of protective lactobacilli during acute trichomoniasis is a well-known phenomenon that was reported in multiple studies and is the hallmark of a T. vaginalis (TV) infection. However, a crucial question that remains unanswered is whether alterations in the lactobacilli population precede TV infection or whether the parasite plays an active role in lactobacilli disappearance. Our findings showed that TV efficiently phagocytosed the dominant Lactobacillus species L. jensenii (LJ). Phagocytosis proceeds via a pseudopodia-independent mechanism reminiscent of sinking with a preference for viable cells. The presence of viable LJ leads to an increase in secretion of 27 TV proteins, including TvGH25 lysozyme. This enzyme cleaves peptidoglycan, a major component of the bacterial cell wall. TV overexpressing TvGH25 effectively lowers the bacterial cell count, evidencing the enzyme's antimicrobial potential. These data support the notion that TV cells can suppress the Lactobacillus population through a combination of targeted secretory response and phagocytic activity, revealing novel potential targets for developing alternative therapeutic strategies against trichomoniasis.
Inclan Rico, J.; Napuri, C.; Stephenson, A.; Rossi, H.; Femoe, U. M.; Musaigwa, F.; Hung, L.-Y.; Yu, H.; Luo, W.; Herbert, D.
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Psoriasis is a chronic autoimmune skin disorder marked by IL-17-producing {gamma}{delta} T cell ({gamma}{delta}T17) and pruritus, but immunoregulatory roles of itch-inducing neurons in this context remain unclear. This study addressed whether non-peptidergic (NP) afferents bearing the Mas-related G protein-coupled receptor D (MrgprD/NP1) and MrgprA3/NP2 subsets had differential effects on psoriasiform immunopathology. Data show human NP1 and NP2 neurons basally expressed an array of pattern recognition and cytokine receptor genes, and psoriatic human skin had a profound dysregulation of neuropeptides and their receptors. In mice, imiquimod (IMQ) application reduced the density of MrgprD+ skin afferents, whereas NP1 neuron ablation exacerbated IMQ-induced disease. Strikingly, NP1 activation using either optogenetics or {beta}-alanine before IMQ exposure significantly reduced epidermal thickness, psoriatic clinical score, and {gamma}{delta}T17 cell accumulation. In stark contrast, NP2 activation increased the numbers of {gamma}{delta}T17 cells that co-expressed amphiregulin (Areg) and exacerbated IMQ-driven skin pathology. Instead, pre-emptive NP1 stimulation shifted {gamma}{delta} T cell profiles away from being IL-17 and Areg dominant to IL-13+ {gamma}{delta} T cells expressing the transcription factor GATA3 accompanied by IL-10 secretion. Importantly, IL-10 signaling blockade reversed NP1-mediated suppression of IMQ-induced dermatitis. These data show that sensory neuron subsets can distinctly modulate inflammatory skin disease.
Batal, A.; Pamnani, S.; Zhou, S.; Bou-Gharios, G.; Philip, A.
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Fibroproliferative diseases such as systemic sclerosis are complex conditions characterized by chronic skin inflammation and progressive fibrosis, with fibroblast activation as a central feature. While Transforming Growth Factor Beta (TGF-{beta}) signaling is a well-established driver of fibrosis in SSc, inflammatory pathways such as Nuclear Factor Kappa B (NF-{kappa}B) also contribute substantially to disease morbidity. We previously identified CD109 as a TGF-{beta} co-receptor and negative regulator of fibrotic signaling; however, its role in inflammatory signaling remains unknown. Here, we investigate the function of CD109 in regulating inflammatory signaling in skin fibroblasts. We show that, CD109 co-localizes and associates with Toll-like receptors (TLR2, TLR4) and tumor necrosis factor receptors (TNFRI, TNFRII), and that loss of CD109 enhances TNF--induced NF-{kappa}B activation and reprograms cytokine production in human dermal fibroblasts. Furthermore, both global and fibroblast-specific CD109 knockout mice exhibit increased immune cell infiltration and skin inflammation. In parallel, single-cell transcriptomic analyses across a pan-disease fibroblast atlas show that CD109 expression is preferentially maintained in structural and homeostatic fibroblast subtypes, whereas immune-interacting fibroblast subsets consistently display decreased CD109 levels. Pathway-level analyses of fibroblast pseudobulk samples reveal altered activity of canonical inflammatory pathways in SSc compared to healthy skin. Together, these findings identify CD109 as a fibroblast-intrinsic negative regulator of inflammatory signaling and suggest a broader role for CD109 in modulating inflammatory responses in systemic sclerosis. O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=102 SRC="FIGDIR/small/736423v1_ufig1.gif" ALT="Figure 1"> View larger version (53K): org.highwire.dtl.DTLVardef@be9e08org.highwire.dtl.DTLVardef@794173org.highwire.dtl.DTLVardef@b81eb5org.highwire.dtl.DTLVardef@1e811f5_HPS_FORMAT_FIGEXP M_FIG Graphical Abstract: CD109 Restrains Fibroblast-Driven Inflammation by Modulating NF-{kappa}B Signaling. Generated using FigureLabs.ai and edited using Adobe Photoshop. C_FIG
Himsworth, C.; Jackson, T.; Bowers, C.; Munnings-Tomes, S.; Nair, G.; Muller, H.; Tucker, E.; Erbe-Gurel, A. K.; Sondel, P.; Chesler, L.; Mazjner, R.; Anderson, J.
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CD47 delivers a dominant "Dont Eat Me" signal that inhibits macrophage-mediated clearance of tumour cells. Using immune competent, chemoresistant neuroblastoma (NB) models, we tested a Fc-silent CD47 blocker (ALX301) with anti-GD2 antibody alone and in combination with a clinically aligned temozolomide/irinotecan chemoimmunotherapy backbone. Tumours expressed GD2 and CD47, and bound ALX301. In macrophage coculture assays, anti-GD2 antibody induced dose-dependent phagocytosis, whereas ALX301 or an anti-CD47 antibody alone did not. CD47 blockade in combination with a suboptimal concentration of anti-GD2 antibody showed an additive effect on phagocytosis in vitro. In vivo, however, ALX301 failed to improve tumour control or survival when added to anti-GD2 or to chemoimmunotherapy in two models. Toxicity was acceptable, showing only mild, expected red-cell changes without organ injury. This form of CD47 inhibition is therefore mechanistically active in vitro but insufficient to enhance anti-GD2 antibody-based therapy in immune competent mice bearing a chemoresistant NB, highlighting the potential need for myeloid-reprogramming partners.
van der Hoeven, N.; Holborough-Kerkvliet, M. D.; Bao, Y.; Bentlage, A. E.; de Heer-Ooijevaar, P.; Derksen, N. I.; Damelang, T.; de Kreuk, B.-J.; Labrijn, A. F.; Vidarsson, G.; Rispens, T.
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Fc receptor-like protein 5 (FCRL5) is a low-affinity IgG receptor expressed on B cells, with emerging therapeutic relevance due to its expression on multiple myeloma cells, and a potential role in regulating B cell responses. Previous reports on the FCRL5-IgG interaction vary widely in reported affinities, binding differences across IgG subclasses, and molecular requirements for maximal binding. Furthermore, the impact of Fc-engineering strategies, as used in (therapeutic) monoclonal antibodies, remains poorly understood. Here, we provide a comprehensive biochemical analysis of the FCRL5-IgG interaction. We demonstrate that FCRL5 is a true IgG Fc-receptor, binding with very low affinity (60-80 M). FCRL5 binds IgG in a manner involving primarily the two N-terminal domains of FCRL5, and the third domain for maximal binding, but with distinct essential residues in the IgG Fc-tail. Surface plasmon resonance analysis of the binding of FCRL5 to the various IgG subclasses revealed a preference for IgG1 and IgG4. Interestingly, various Fc-engineered IgG variants commonly used for silencing or enhancing of Fc receptor binding do not impact FCRL5 binding. Screening the binding of a set of IgG antibodies carrying defined sets of Fc-mutations to FCRL5 revealed E293 as a key binding determinant and led to the discovery of E293R as a mutation that selectively abrogates FCRL5 binding while preserving binding to other classical Fc{gamma}Rs. Lastly, we show that FCRL5 has considerable preference for binding afucosylated IgG. Together, our results define the essential characteristics of the IgG-FCRL5 interaction and demonstrate the potential of both naturally occurring IgG variants as well as therapeutically explored bioengineered IgG formats to differentially engage FCRL5.
Aguiar, C. F.; Nosenko, M. A.; Corkish, C.; Keane, C.; Skabytska, Y.; Gardiner, C. M.; Brennan, L.; Sinclair, L. V.; Finlay, D. K.
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Natural killer (NK) cells infiltrate many solid tumours, yet the mechanisms that determine their functional heterogeneity across tumour types remain poorly understood. Differences in tumour immunogenicity, inhibitory signalling, and nutrient availability have all been implicated, but unifying explanations are lacking. Here, we compared four syngeneic tumour models implanted at identical anatomical sites to isolate tumour-intrinsic effects on NK-cell fate. Tumour-infiltrating NK cells displayed striking tumour-specific differences in cytokine production, cytotoxic protein expression, and persistence. These differences were not explained by cytokine availability or global features of the tumour metabolic environment. Instead, quantitative proteomics and time-resolved in vivo labelling revealed that NK cells enter tumours in a functionally competent state but rapidly diverge thereafter. In suppressive tumour microenvironments, NK cells undergo early mitochondrial loss, translational repression, and impaired proteostatic responses, accompanied by increased apoptotic priming. These defects result in reduced effector function and failure of intratumoural persistence despite preserved recruitment. In contrast, permissive tumours sustain NK-cell translational capacity, cytokine responsiveness, and long-term residency. Together, these findings identify disruption of translational and mitochondrial homeostasis as a central mechanism limiting NK-cell persistence in solid tumours. This work establishes early tumour-induced defects in protein synthesis and cellular fitness as key constraints on durable NK-cell immunity and provides a framework for restoring effective innate anti-tumour responses.
Nguyen, J.; Peidl, A.; Chitturi, P.; McClintock, S. D.; Knibbs, R.; Zestranjyan, K.; Abdi, B. A.; Denomy, C.; Bhandari, P.; Carter, D. E.; Petitjean, M.; Varga, J.; Khanna, D.; Stratton, R. J.; Aslam, M. N.; Varani, J.; Riser, B. L.; Leask, A.
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An autocrine pro-adhesive/pro-contractile signaling loop, through the mechanosensitive transcriptional cofactor YAP, promotes fibrosis. The CCN family of matricellular proteins modify adhesive signaling. Of these, CCN3 is antifibrotic. We show that BLR-200, a CCN3-derived peptide, has anti-fibrotic properties in the bleomycin-induced model of scleroderma skin fibrosis. In vitro, BLR-200 delayed, but did not abolish, fibroblast adhesion to collagen and nuclear YAP localization. In vivo, BLR-200 prevented/treated bleomycin-induced skin fibrosis, and reduced bleomycin-induced expression of profibrotic genes including alpha-smooth muscle actin, CCN1 and CCN2. Lineage tracing and scRNA-seq analyses revealed that the myofibroblasts in this model were quantitatively derived from collagen-lineage Pi16+/Col15+ve fibroblasts. BLR-200 prevented myofibroblast differentiation in this model and trajectory of fibroblasts toward a Sfrp2-positive subset, a cell type associated with poor clinical outcome. BLR-200 impairs YAP activation in vitro and appearance of translationally-relevant fibroblast subtypes in vivo and is a novel anti-fibrotic agent for SSc skin fibrosis.
Mercado, M. A. B.; Kim, Y.; Li, Q.; Li, L.-X.
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CD4 T cells are essential for protective immunity against Chlamydia in the female reproductive tract (FRT), yet the characteristics of protective mucosal effector CD4 T cells remain poorly defined. We previously identified the transcription factor BHLHE40 as a key regulator of polyfunctional effector CD4 T cell differentiation during Chlamydia infection. Here, we identify the chemokine receptor CXCR6 as a marker of these protective T cells. Following intravaginal Chlamydia muridarum infection, Bhlhe40-deficient mice exhibited reduced frequencies of CXCR6 CD4 T cells that correlated with impaired bacterial control. CXCR6 expression on T cells was associated with loss of stem-like features and acquisition of an effector phenotype. Compared with CXCR6- cells, CXCR6 CD4 T cells displayed enhanced proliferation and polyfunctionality by co-producing cytokines IFN-{gamma}, IL-17A, and GM-CSF. Although CXCR6 was dispensable for CD4 T cell homing to the FRT, it promoted localization to the infected epithelium and the emerging memory lymphoid clusters. Importantly, depletion of CXCR6 CD4 T cells reduced polyfunctional effectors and impaired bacterial clearance. Collectively, these findings identify CXCR6 as a marker of protective polyfunctional CD4 T cells and implicate CXCR6-dependent tissue positioning as a key component of effective mucosal immunity, highlighting CXCR6 as a potential biomarker for Chlamydia vaccine development.
Akter, M.; Sun, L.; Chi, C.; Hyder, I.; Fu, Z.; Jin, L.; Huang, S.
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Ferroptosis, an intracellular iron-catalyzed form of programmed cell death (PCD) driven by lipid reactive oxygen species induced membrane damage, is mechanistically uncharacterized in its execution process. Here, we investigated ferroptosis execution in mesenchymal-like ovarian cancer cells treated with ferroptosis inducers ML162 and erastin. We showed that YVAD (a pyroptosis-associated inflammatory caspase inhibitor) and disulfiram (preventing gasdermin pore formation on plasma membrane) deterred ferroptotic cell death. Moreover, we also observed LDH release and IL-1{beta} secretion from ferroptotic cells, suggesting that ferroptosis involves a pore-forming process. Intriguingly, ferroptosis is independent of the canonical inflammasome pathway because caspase-1 is dispensable and not activated upon ferroptosis induction. In contrast, we found that caspase-5 was activated while caspase-4 was not during ferroptosis. In addition, depletion of caspase-5 rendered cells not responding to ferroptosis inducers. Also intriguingly, GSDMD, the well-established caspase-5 substrate, was not involved in ferroptosis. We instead detected GSDME cleavage upon ferroptosis induction and knockdown of GSDME reduced cell death induced by ferroptosis inducers. As caspase-5 activity was necessary for ferroptosis and caspase-5 directly cleaved GSDME, we conclude that the axis of caspase-5/GSDME executes ferroptosis in ovarian cancer cells.
Fontecilla-Escobar, J.; Flores-Montero, K.; Buzza, H. H.; Acuna Astudillo, R.; Hernandez, I.; Bellomo Perazza, A. I.; Elhalem, E.; Bigatti, G.; Croci, D. O.; Ezquer, M.; Ruete, M. C.
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Background: Chronic and non-healing wounds remain a major clinical challenge with limited therapeutic options. Angiogenesis and inflammation are central to tissue repair, and mesenchymal stem cells (MSC) contribute to these processes through their trophic and immunomodulatory secretome. Cannabidiol (CBD) exhibits antioxidant and immunomodulatory properties. However, whether CBD-rich Cannabis sativa extract stimulate MSC toward a pro-angiogenic secretome remains unclear. Purpose: This study aims to determine whether purified CBD or a phytochemically CBD-rich full spectrum extract stimulate umbilical cord-derived human MSC (UC-hMSC) to secrete pro-angiogenic factors and enhance endothelial responses relevant to wound healing. Methods: UC-hMSC were preconditioned with either purified CBD or a CBD-rich full-spectrum extract. Transcriptional changes were assessed by qPCR. The functional impact of the resulting secretome was evaluated in vitro using HUVEC-based proliferation and tube formation assays, and in vivo through the chick chorioallantoic membrane assay. To explore underlying mechanisms, we examined HIF-1 stabilization and VEGFA release in UC-hMSC, and VEGFR-2/ERK signaling in HUVEC. Results: Purified CBD and full-spectrum CBD extract preconditioned UC-hMSC secretomes, increased HUVEC proliferation, tube formation, and enhanced vascular branching in the CAM assay. Mechanistic analyses indicated activation of the HIF-1/VEGF axis in UC-hMSC, and ERK1/2 activation in HUVEC that was sensitive to VEGFR-2 blockade. Conclusion: Purified CBD and CBD-rich full-spectrum extract prime UC-hMSC toward a pro-angiogenic secretome that promotes endothelial activation and neovascularization. These findings suggest that cannabinoid-based preconditioning of UC-hMSC involves the HIF-1/VEGF axis and VEGFR-2/ERK signaling pathways in endothelial cells, supporting further investigation of this approach in wound healing and regenerative therapies.
Ziyaeyan, A.; Rasti, M.; Gandhi, R.; Oikonomopoulou, K.; Chandran, V.; Viswanathan, S.
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Objective We developed a patient- and joint-specific explant co-culture system to model active psoriatic arthritis (PsA) and capture donor-specific tissue responses to therapeutic interventions. Methods Based on convergent joint pathology between end-stage osteoarthritis (OA) and PsA, OA cartilage-bone and synovium tissues from arthroplasty patients were exposed to synovial fluid (SF) obtained from PsA and OA patients. Histological outcomes (synovitis, proteoglycan distribution), curated gene expression, soluble mediators, and proteinase activity were assessed over 7-21-days. Model responses to dexamethasone (DEX) and the anti-tumor necrosis factor antibody adalimumab (ADA) were evaluated. Results PsA SF induced distinct inflammatory and tissue remodeling responses compared to OA SF and control conditions, including altered cartilage proteoglycan distribution, increased synovitis, and tissue-specific transcriptional changes. Multivariate analyses identified distinct osteochondral and synovial transcriptional responses to PsA SF, characterized by reduced osteochondral COL2A1 expression and increased synovial expression of inflammatory and matrix-remodeling genes, including MMP1 and CXCL8. DEX and ADA elicited donor-specific responses across histological, transcriptional, and protein readouts. Among multivariable model outputs, histologic synovitis scores emerged as the most clinically aligned parameter, demonstrating associations with baseline PsA donor disease activity, active joint counts, pain, high-sensitivity C-reactive protein (hsCRP), and radiographic scores. Synovitis score changes to DEX and ADA treatments also aligned with corresponding PsA SF donor clinical improvements to corticosteroid and TNF-modifying therapies. Conclusion This osteochondral-synovial explant co-culture model captured donor-specific inflammatory and treatment-responsive features of PsA SF-induced pathology, thereby providing a clinically relevant ex vivo platform for studying patient-specific therapeutic responses in PsA.
Hussain, A.; Tajdaran, K.; Katturajan, R.; Mirmoeini, K.; Crabtree, J.; Quddam, A. I.; Wu, X.; Blum, N.; Konig, D. J.; Pepose, J. S.; Ali, A.; Shalom-Feuerstein, R.; Gordon, T.; Kaplan, D. R.; Borschel, G. H.; Feinberg, K.
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Corneal epithelial integrity depends on continuous epithelial renewal by limbal epithelial stem cells (LESCs), a process tightly linked to sensory innervation. Loss or impairment of innervation causes neurotrophic keratopathy (NK), a sight-threatening degenerative disease for which rhNGF, the only FDA-approved pharmacologic therapy, often has limited efficacy in advanced or refractory disease. The mechanistic basis for this limited response remains unclear. Using surgical, genetic, and pharmacologic approaches in a rodent model of NK with corneal Schwann cell ablation or structural and functional denervation, together with primary human LESCs, we examined how denervation alters NGF receptor signaling during epithelial repair. In innervated corneas, NGF promoted epithelial regeneration through TrkA. Denervation, however, increased expression of a second NGF receptor, anti-regenerative p75NTR, and activation of its effector JNK, and reduced the activity of the TrkA effector AKT in LESCs. In this altered receptor context, denervation-induced elevation of endogenous NGF amplified p75NTR signaling, thereby explaining the failure of topical rhNGF to rescue severely denervated NK phenotype corneas. Conversely, selective TrkA activation, either with the clinical-stage agonist tavilermide, or pharmacologic or genetic inhibition/ablation of p75NTR, restored AKT signaling and rescued epithelial healing in denervated corneas independent of reinnervation. These findings identify a nerve-dependent NGF receptor switch as a key regulator of corneal epithelial renewal and establish receptor-selective modulation as a mechanistically rational therapeutic strategy for treating NK. One Sentence SummaryCorneal denervation shifts limbal epithelial stem cell signaling from pro-regenerative TrkA-AKT toward anti-regenerative p75NTR-JNK, explaining the limited efficacy of recombinant human nerve growth factor (rhNGF; cenegermin), the only approved pharmacologic therapy for neurotrophic keratopathy, in severely denervated corneas and identifying receptor-selective modulation as a mechanistically distinct therapeutic strategy.
Dourlens, C.; Vanderliek, K.; Geiger, L.; Burzan, N.; Tomiuk, S.; Droste, M.; Felsberger, A.; Hubrich, H.; Winkler, J.; Hardt, O.; Schaefer, D.
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Pancreatic cancer remains a highly lethal malignancy with limited therapeutic options. Chimeric antigen receptor (CAR) therapy has revolutionized the treatment of hematological cancers but still faces major limitations in solid tumors, particularly due to the scarcity of tumor-specific targets. Cutaneous lymphocyte antigen (CLA) recently emerged as a promising PDAC target due to its high tumor expression and limited presence in healthy tissues. However, previously reported CLA-directed CAR constructs lacked antitumor functionality. Here, we investigated multiple strategies to generate functional CLA-targeting CAR approaches. We first hypothesized that impaired activity resulted from fratricide caused by CLA expression on activated T cells. CLA knockout was successfully achieved through deletion of fucosyltransferase-7, but not by knockout of the major CLA carrier backbones CD162, CD44 or CD43, suggesting additional CLA carriers or compensatory regulation. As CLA knockout alone did not restore CAR-mediated killing, we explored whether insufficient binding affinity limited CAR activity. Affinity maturation was performed in silico and in vitro using yeast surface display, identifying 39 candidate mutations, although none restored cytotoxicity. We finally switched to an AdCAR strategy using anti-biotin CAR T cells combined with biotinylated anti-CLA scFv-Fc adapters. This approach enabled efficient, concentration-dependent cytotoxicity with both CLA-targeting binders. Additionally, we identified a dynamic, cell density-dependent regulation of CLA expression. Finally, glycan profiling of CLA binders further revealed broader-than-expected glycan interactions, suggesting a potentially wider definition of the CLA family. Overall, our findings establish CLA as a functional PDAC immunotherapy target while revealing unexpected complexity in its regulation and molecular presentation.
Gonzalez-Alvarez, V.; Caamano, S.; Reimundez, A.; Canas-Martin, J.; Capelo-Diz, A.; Seoane, N.; Pensado-Lopez, A.; Benedikt, P.; Schweiger, M.; Vina, D.; Vieites, A.; Andon, F. T.; Arce, V.; Senaris, R.
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BackgroundCancer-associated cachexia is characterized by progressive loss of skeletal muscle and adipose tissue driven by systemic inflammation and metabolic dysregulation. AMP-activated protein kinase (AMPK) is a central regulator of energy homeostasis, but its role in cachexia and its therapeutic potential remains incompletely defined. We investigated AMPK signaling during cachexia and whether pharmacological AMPK activation alone or combined with ghrelin could ameliorate disease manifestations. MethodsCachexia was induced in male C57BL/6 mice by Lewis lung carcinoma (LLC) implantation. Additional models included fibrosarcoma (CHX and MN/MCA1) and chronic lymphocytic choriomeningitis virus (LCMV) infection. AMPK was activated using AICAR and BC1618 (AB), alone or combined with ghrelin (AB+G). Metabolic, inflammatory, and functional outcomes were assessed in hypothalamus, skeletal muscle, adipose tissue, and serum. ResultsLLC-bearing mice developed cachexia characterized by reduced body weight, lean and fat mass, hypophagia, and elevated circulating IL-6 and corticosterone. Cachectic LLC mice displayed increased Il6 and Il1{beta} expression in hypothalamus, skeletal muscle, and white adipose tissue (WAT). Furthermore, AMPK activation failed to increase in hypothalamus or peripheral tissues despite profound energy deficit. A similar defect in AMPK responsiveness was observed in CHX and LCMV models, indicating a conserved feature of cachexia. AB treatment in LLC mice reduced circulating IL-6 and corticosterone levels and decreased skeletal muscle atrogene expression and IL-6/STAT3 signaling, partially preserving muscle mass, fiber size, and grip strength. However, food intake remained low, and WAT was largely unresponsive, maintaining elevated Il6 expression and tissue loss. Ghrelin alone increased food intake in LLC mice but did not ameliorate the cachectic phenotype. In contrast, AB+G restored food intake and prevented loss of lean and fat mass. LLC AB+G mice exhibited reduced hypothalamic Il6 and serotonin transporter (Slc6a4) expression, normalized adipocyte morphology and serum leptin levels, decreased adipose Il6 and Atgl expression and reduced WAT sympathetic innervation. AB+G further lowered circulating corticosterone levels, and provided greater protection against muscle wasting, with increased Pgc1 expression and improved muscle function. Neither intervention affected tumor growth or tumor inflammatory gene expression. ConclusionsCancer cachexia is associated with a central and peripheral failure to appropriately activate AMPK signaling in response to the energetic stress imposed by cachexia. Combined AMPK activation and ghrelin administration exerted complementary effects on energy homeostasis, inflammation, and tissue wasting, resulting in greater protection against cachexia than either intervention alone. These findings support combined AMPK-ghrelin targeting as a promising therapeutic strategy for cancer cachexia.