Endothelial PROX1 induces blood-brain barrier disruption in the central nervous system
González-Hernández et al. report that ectopic PROX1 expression in brain endothelial cells disrupts the blood-brain barrier (BBB), leading to vascular leakage by inhibiting key BBB-associated gene expression and Wnt/β-catenin signaling. The cover image highlights the BBB permeability phenotype in a mouse with PROX1 overexpression, showing leakage of dextran (red) and endomucin-labeled capillaries (cyan). Image credit: Sara González-Hernández.
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Research Letters
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Abstract
Authors
Filip Hanak, Jessica L. Swanson, Krzysztof Felczak, Prakashkumar Dobariya, Ursula C.H. Girdwood, Kenneth E. Bernstein, Swati S. More, Patrick E. Rothwell
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Authors
Deborah Moser, Alexandra N. Birtasu, Lilli Skaer, Pauline Roth, Lisa Rehm, Mike Wenzel, Julia Bein, Jens Köllermann, Mbuso S. Mantanya, Felix K.H. Chun, Margot P. Scheffer, Achilleas S. Frangakis
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Research Articles
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Abstract
Patients with cutaneous T cell lymphoma (CTCL) experience high morbidity and mortality due to S. aureus skin infections and sepsis, but the underlying mechanisms remain unclear. We have previously identified high levels of LAIR2, a decoy protein for the inhibitory receptor LAIR1, in advanced CTCL. Mice lack a LAIR2 homolog, so we used Lair1-KO mice to model LAIR2 overexpression. In a model of S. aureus skin infection, Lair1-KO mice had significantly larger abscesses and areas of dermonecrosis compared with WT despite similar bacterial burdens. Lair1 KO exhibited a pattern of increased inflammatory responses in infection and sterile immune stimulation, with increased production of proinflammatory cytokines and myeloid chemokines, neutrophil ROS, and collagen/extracellular matrix (ECM) pathway proteins, including collagens and complement factors. These findings support the notion that loss of LAIR1 signaling causes an excessive inflammatory response that exacerbates tissue damage and does not improve infection control. Underscoring the clinical relevance of our findings, CTCL skin lesions exhibited similarly increased expression in cytokine and collagen/ECM remodeling pathways, suggesting that high levels of LAIR2 promote excessive inflammatory tissue damage and compromise host defense against S. aureus infection. LAIR signaling represents a promising target for therapeutic development in CTCL and other inflammatory diseases.
Authors
Hannah K. Dorando, Evan C. Mutic, Kelly L. Tomaszewski, Yulia Korshunova, Ling Tian, Mellisa K. Stefanov, Chaz C. Quinn, Deborah J. Veis, Juliane Bubeck Wardenburg, Amy C. Musiek, Neha Mehta-Shah, Jacqueline E. Payton
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The central nervous system (CNS) parenchyma has conventionally been believed to lack lymphatic vasculature, likely owing to a non-permissive microenvironment that hinders the formation and growth of lymphatic endothelial cells (LECs). Recent findings of ectopic expression of LEC markers including prospero homeobox 1 (PROX1), a master regulator of lymphatic differentiation, and the vascular permeability marker plasmalemma vesicle–associated protein (PLVAP) in certain glioblastomas (GBM) and brain arteriovenous malformations have prompted investigation into their roles in cerebrovascular malformations, tumor environments, and blood-brain barrier (BBB) abnormalities. To explore the relationship between ectopic LEC properties and BBB disruption, we used endothelial cell–specific Prox1 overexpression mutants. When induced during embryonic stages of BBB formation, endothelial Prox1 expression induces hybrid blood-lymphatic phenotypes in the developing CNS vasculature. This effect is not observed when Prox1 is overexpressed during postnatal BBB maturation. Ectopic Prox1 expression leads to significant vascular malformations and enhanced vascular leakage, resulting in BBB disruption when induced during both embryonic and postnatal stages. Mechanistically, PROX1 downregulates critical BBB-associated genes, including β-catenin and claudin-5, which are essential for BBB development and maintenance. These findings suggest that PROX1 compromises BBB integrity by negatively regulating BBB-associated gene expression and Wnt/β-catenin signaling.
Authors
Sara González-Hernández, Ryo Sato, Yuya Sato, Chang Liu, Wenling Li, Zulfeqhar A. Syed, Chengyu Liu, Sadhana Jackson, Yoshiaki Kubota, Yoh-suke Mukouyama
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Serine-rich splicing factor 3 (SRSF3) is crucial for the metabolic functions of the liver. The genetic deletion of SRSF3 in mouse hepatocytes impairs hepatic lipid and glucose metabolism and leads to fibrosis and formation of hepatocellular adenoma that progresses to hepatocellular carcinoma. SRSF3 protein is proteosomally degraded in metabolic-dysfunction associated fatty liver disease (MAFLD) and metabolic-dysfunction-associated steatohepatitis (MASH). We show here that depleting SRSF3 protein in hepatocytes promoted R-loop accumulation and increased DNA damage in the liver. Prevention of SRSF3 degradation in vivo protected hepatocytes from DNA double-strand breaks in mice with MASH. This protection extended to other DNA-damaging agents such as camptothecin, palmitic acid, or hydrogen peroxide when tested on HepG2 cells in vitro. SRSF3 interacted with TRIM28 and MDC1, which are components of the ATM DNA-damage repair complex, and knockdown of any of these 3 proteins reduced the expression of the other 2 proteins, suggesting they form a functional complex. Lastly, by preventing degradation of SRSF3, we were able to reduce tumors in a diethyl-nitrosamine–induced (DEN-induced) model of cirrhotic HCC. These findings suggest that maintenance of SRSF3 protein stability is crucial for preventing DNA damage and protecting liver from early metabolic liver disease and progression to HCC.
Authors
Panyisha Wu, Manasi Das, Yanting Wang, Yichun Ji, Yuli Wu, Deepak Kumar, Lily J. Jih, Nicholas J.G. Webster
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Modic type 1 and 2 changes (MC-1 and MC-2) are highly prevalent in individuals with chronic low back pain, yet the cellular and molecular mechanisms underlying vertebral endplate degeneration remain poorly defined. Here, we report that osteoclastogenesis is markedly elevated in MC-1 and MC-2 lesions compared with MC-3 lesions, suggesting an active role for osteoclasts in the early stages of degeneration. Using a lumbar spine instability (LSI) mouse model, we demonstrate enhanced osteoclast activity in degenerating endplates. RNA sequencing of mononuclear cells isolated from the endplate and adjacent subchondral bone identified Gdf15 as a potential upstream regulator of this process. Conditional knockout of Gdf15 in monocytes reduced osteoclast formation, aberrant CD31hiEmcnhi angiogenesis, and pain-associated neurogenesis, ultimately mitigating endplate degeneration and mechanical allodynia. Mechanistically, GDF15 promoted the fusion of preosteoclasts by modulating the expression of Rho family small GTPases. In a humanized GDF15 knockin mouse model, therapeutic neutralization of GDF15 led to a reduction in osteoclast burden, improved endplate structure, and attenuated pain behavior. Together, these findings uncover a previously unrecognized role for GDF15 in driving osteoclast-mediated endplate degeneration and highlight its potential as a therapeutic target for the treatment of endplate-related chronic low back pain.
Authors
Xiaoqun Li, Jinhui Wu, Qingjie Kong, Miao Hu, Yuhong Li, Ziheng Wei, Heng Jiang, Xuhui Zhou, Jun Ma
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BACKGROUND Individuals with autoimmune diseases (ADs) on immunosuppressants often have suboptimal responses to COVID-19 vaccines. We evaluated the efficacy and safety of additional COVID-19 vaccines in those treated with mycophenolate mofetil/mycophenolic acid (MMF/MPA), methotrexate (MTX), and B cell–depleting therapy (BCDT), including the impact of withholding MMF/MPA and MTX.METHODS In this open-label, multicenter, randomized trial, 22 participants taking MMF/MPA, 26 taking MTX, and 93 treated with BCDT who had suboptimal antibody responses to initial COVID-19 vaccines (2 doses of BNT162b2 or mRNA-1273 or 1 dose of AD26.COV2.S) received an additional homologous vaccine. Participants taking MMF/MPA and MTX were randomized (1:1) to continue or withhold treatment around vaccination. The primary outcome was the change in anti–Wuhan-Hu-1 receptor-binding domain (RBD) concentrations at 4 weeks after additional vaccination. Secondary outcomes included adverse events, COVID-19, and AD activity through 48 weeks.RESULTS Additional vaccination increased anti-RBD concentrations in participants taking MMF/MPA and MTX, irrespective of immunosuppressant withholding. BCDT-treated participants also demonstrated increased anti-RBD concentrations, albeit lower than MMF/MPA- and MTX-treated cohorts. COVID-19 occurred in 33% of participants; infections were predominantly mild and included only 3 nonfatal hospitalizations. Additional vaccination was well tolerated, with low frequencies of severe disease flares and adverse events.CONCLUSION Additional COVID-19 vaccination is effective and safe in individuals with ADs treated with immunosuppressants, regardless of whether MMF/MPA or MTX is withheld.TRIAL REGISTRATION ClinicalTrials.gov (NCT05000216; registered August 6, 2021: https://clinicaltrials.gov/ct2/show/NCT05000216).FUNDING The NIH/NIAID supported the study through the Autoimmunity Centers of Excellence and the Intramural Research Program
Authors
Meggan Mackay, Catriona A. Wagner, Ashley Pinckney, Jeffrey A. Cohen, Zachary S. Wallace, Arezou Khosroshahi, Jeffrey A. Sparks, Sandra Lord, Amit Saxena, Roberto Caricchio, Alfred H.J. Kim, Diane L. Kamen, Fotios Koumpouras, Anca D. Askanase, Kenneth Smith, Joel M. Guthridge, Gabriel Pardo, Yang Mao-Draayer, Susan Macwana, Sean McCarthy, Matthew A. Sherman, Sanaz Daneshfar Hamrah, Maria Veri, Sarah Walker, Kate York, Sara K. Tedeschi, Jennifer Wang, Gabrielle Dziubla, Mike Castro, Robin Carroll, Sandeep Narpala, Bob C. Lin, Leonid Serebryannyy, Adrian B. McDermott, ACV01 Study Team, William T. Barry, Ellen Goldmuntz, James McNamara, Aimee S. Payne, Amit Bar-Or, Dinesh Khanna, Judith A. James
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Neutrophils play a pivotal role in the progression of metabolic dysfunction–associated steatohepatitis (MASH) by mediating inflammatory responses. However, the heterogeneity of neutrophil subsets in MASH and their specific contributions to disease progression remain unclear. In this study, analysis of liver biopsies from 265 patients revealed a strong association between elevated neutrophil counts and MASH severity, particularly fibrosis. Five distinct neutrophil subsets were identified in human liver tissue, with PAD4+ neutrophils serving as key drivers in MASH progression. Mechanistically, PAD4+ neutrophils generate neutrophil extracellular traps (NETs) and activate hepatic stellate cells via the TAOK1-dependent MAPK signaling pathway. Inhibition of PAD4+ neutrophils in vivo attenuated the progression of liver fibrosis without exacerbating liver injury. Collectively, these findings elucidate the pivotal involvement of PAD4+ neutrophils in MASH progression and identify them as promising therapeutic targets for mitigating fibrosis and inflammation.
Authors
Jiajia Shen, Shanshan Huang, Yaohui Wang, Qingyuan Wang, Shibo Lin, Wei Guan, Yingyun Gong, Yiming Si, Ming Zhao, Hongwen Zhou, Hui Liang
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Although well-differentiated thyroid carcinoma (WDTC) is characterized by a robust treatment response, aggressive subtypes, such as anaplastic thyroid carcinoma (ATC), remain highly lethal. To understand thyroid cancer evolution in both children and adults, we analyzed single-cell transcriptomes of 423,733 cells from 81 samples and spatially resolved key tumor and microenvironment populations across 28 tumors with spatial transcriptomics, including rare and unique composite WDTC/ATC tumors and pediatric diffuse sclerosing thyroid carcinomas. Additionally, we identified gene signatures of stromal cell populations in 5 large thyroid cancer bulk RNA-sequencing cohorts. Through this multi-institutional effort, we defined a population of POSTN+ myofibroblast cancer-associated fibroblasts (myCAFs) that are intimately associated with invasive tumor cells and correlate with poor prognosis, lymph node metastasis, and disease progression in thyroid carcinoma. We also revealed a population of inflammatory CAFs that are distant to tumor cells and are found in the inflammatory stromal microenvironment of autoimmune thyroiditis. Together, our study provides spatial profiling of thyroid cancer evolution in samples with mixed WDTC/ATC histopathology and identifies a prognostic myCAF subtype with potential clinical utility in predicting aggressive disease in both children and adults.
Authors
Matthew A. Loberg, George J. Xu, Sheau-Chiann Chen, Hua-Chang Chen, Claudia C. Wahoski, Kailey P. Caroland, Megan L. Tigue, Heather A. Hartmann, Jean-Nicolas Gallant, Courtney J. Phifer, Andres A. Ocampo, Dayle K. Wang, Reilly G. Fankhauser, Kirti A. Karunakaran, Chia-Chin Wu, Maxime Tarabichi, Sophia M. Shaddy, James L. Netterville, Sarah L. Rohde, Carmen C. Solórzano, Lindsay A. Bischoff, Naira Baregamian, Barbara A. Murphy, Jennifer H. Choe, Jennifer R. Wang, Eric C. Huang, Quanhu Sheng, Luciane T. Kagohara, Elizabeth M. Jaffee, Ryan H. Belcher, Ken S. Lau, Fei Ye, Ethan Lee, Vivian L. Weiss
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The activation of the NLRP3 inflammasome is a pivotal step in hyperinflammation in sepsis; however, the regulatory mechanisms underlying its activation are not fully understood. In this study, we found that 14-3-3ε facilitates NLRP3 inflammasome activation by enhancing NLRP3 K63 deubiquitination and promoting its translocation to the mitochondria-associated ER membranes (MAMs) for full activation. Mass spectrometry revealed that 14-3-3ε binds to NLRP3 in macrophages during sepsis. Plasma 14-3-3ε levels were elevated in patients with sepsis and were positively associated with disease severity. 14-3-3ε promoted NLRP3 inflammasome activation by facilitating NLRP3 aggregation and NLRP3–ASC assembly. The interaction between 14-3-3ε and NLRP3 was dependent on phosphorylation at the S194 site of NLRP3 NACHT domain. The NLRP3–14-3-3ε interaction promoted K63 deubiquitination and enhanced the translocation of NLRP3 to MAMs, which is necessary for full activation of NLRP3 inflammasome. Furthermore, macrophage-conditional KO of 14-3-3ε or treatment with BV02, a 14-3-3 inhibitor, improved the survival rate and alleviated organ injuries in septic mice. Taken together, our data indicate that 14-3-3ε functions as a positive regulator of the NLRP3 inflammasome and could be a target for sepsis treatment.
Authors
Xingyu Li, Siqi Ming, Can Cao, Yating Xu, Jingxian Shu, Ning Tan, Xi Huang, Yongjian Wu
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Glioblastoma (GBM) is an aggressive brain tumor that often progresses despite resection and treatment. Timely and continuous assessment of GBM progression is critical to expedite secondary surgery or enrollment in clinical trials. However, current progression detection requires costly and specialized MRI examinations, which, in the absence of new symptoms or signs, are usually scheduled every 2–3 months. Here, we hypothesized that changes in daily activity are associated with GBM growth and disease progression. We found that wheel-running activity in GBM-bearing mice declined as tumors grew and preceded weight loss and circadian breakdown by over a week. Temozolomide treatment in the morning, but not evening, significantly reduced tumor size and restored daily locomotion in mice. In a pilot study of 6 patients with GBM wearing an actigraphy watch, wrist movement provided a feasible and continuous longitudinal indicator of daily activity with 1-minute resolution. After tumor resection and radiation, daily activity declined in 2 patients 19 and 55 days before detection of progression by MRI but did not change for the 4 patients with stable disease. These results suggest that daily activity tracking using wearable devices may serve as a real-time indicator and potential monitoring tool for GBM progression and treatment efficacy.
Authors
Maria F. Gonzalez-Aponte, Sofia V. Salvatore, Anna R. Damato, Ruth G.N. Katumba, Grayson R. Talcott, Omar H. Butt, Jian L. Campian, Jingqin Luo, Joshua B. Rubin, Olivia J. Walch, Erik D. Herzog
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BACKGROUND Fecal microbiota transplantation (FMT) is the most effective therapy for recurrent Clostridioides difficile infection (rCDI), yet its mechanism of action remains poorly understood.METHODS We report the results of a clinical trial of patients undergoing FMT therapy for rCDI (n = 16), which analyzed colon biopsies, plasma, PBMCs, and stool at the time of FMT and 2-month follow-up. Plasma and colon biopsy samples were also collected from healthy controls for comparison with patients with rCDI. Microbiome composition, colonic gene expression, and immune changes were evaluated through high-throughput sequencing and immunoprofiling via flow cytometry.RESULTS No patients experienced recurrence at follow-up. FMT significantly altered the intestinal microbiome but had no significant impact on the systemic immune system. In contrast, FMT promoted broad changes in colonic transcriptional profiles compared with both pre-FMT and healthy control biopsies, inhibiting genes associated with proinflammatory signaling and upregulating type 2 immunity and proliferative pathways (Myc and mTORC1). FMT increased expression of IL-33 and the type 2 immune EGFR family ligand amphiregulin, potentially explaining upregulation of Myc and mTORC1 pathways. Spatial transcriptomics demonstrated that these changes were localized to the colonic epithelium. Comparison of transcriptional profiles with available single-cell gene sets determined that post-FMT biopsies were enriched in signatures associated with proliferative cell types while repressing signatures of differentiated colonocytes.CONCLUSION We conclude that FMT promotes proliferation of the colonic epithelium in patients with rCDI, which may drive regeneration and protect against subsequent CDI.TRIAL REGISTRATION Clinicaltrials.gov NCT02797288.FUNDING This work was funded by grants from the NIH.
Authors
G. Brett Moreau, Jiayi Tian, Nick R. Natale, Farha Naz, Mary K. Young, Uma Nayak, Mehmet Tanyüksel, Isaura Rigo, Gregory R. Madden, Mayuresh M. Abhyankar, Nicholas Hagspiel, Savannah Brovero, Mark Worthington, Brian Behm, Chelsea Marie, William A. Petri Jr., Girija Ramakrishnan
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FGF13, a noncanonical fibroblast growth factor (FGF) and member of the fibroblast growth factor homologous factor (FHF) subset, lacks a signal sequence and was previously reported to remain intracellular, where it regulates voltage-gated sodium channels (VGSCs) at least in part through direct interaction with the cytoplasmic C-terminus of VGSCs. Recent reports suggest FGF13 is secreted and regulates neuronal VGSCs through interactions with extracellular domains of integral plasma membrane proteins, yet supportive data are limited. Using rigorous positive and negative controls, we show that transfected FGF13 is not secreted from cultured cells in a heterologous expression system, nor is endogenous FGF13 secreted from cultured neurons. Furthermore, using multiple unbiased screens including proximity labeling proteomics, our results suggest FGF13 remains within membranes and is unavailable to interact directly with extracellular protein domains.
Authors
Mattia Malvezzi, Haiying Zhang, Patrick Towers, David C. Lyden, Steven O. Marx, Geoffrey S. Pitt
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Metabolic inflammation is closely linked to dynamic changes in circulating monocyte populations, yet how nutritional signals regulate this process remains unclear. ANGPTL8, a hepatokine rapidly induced by refeeding, emerged as a key regulator of postprandial monocyte dynamics. We examined ANGPTL8 expression in human and murine fasting-refeeding models and manipulated ANGPTL8 expression specifically in hepatocytes to assess its role in metabolic inflammation and insulin resistance in obese mice. ANGPTL8 overexpression elevated levels of circulating monocytes and proinflammatory cytokines, while its deletion reduced these parameters and conferred metabolic benefits. Mechanistically, recombinant ANGPTL8 stimulated CCL5 production in bone marrow–derived macrophages via P38 signaling activation, promoting monocyte recruitment and proinflammatory macrophage polarization. These effects were mitigated by CCR5 antagonism. Rescue experiments demonstrated that CCL5 supplementation in Angptl8-deficient mice restored monocyte levels and inflammatory responses. Functionally, ANGPTL8 worsened insulin resistance and glucose intolerance in obese mice, effects that were reversed by its deletion and recapitulated by CCL5 administration. These findings suggest that ANGPTL8 functions as a nutritional checkpoint that links feeding status to monocyte-mediated inflammation through the CCL5-CCR5 axis. By driving monocytosis and proinflammatory macrophage activation, ANGPTL8 exacerbates metabolic dysfunction. Targeting the ANGPTL8-CCL5-CCR5 pathway may therefore offer a promising therapeutic strategy for managing obesity-related metabolic diseases.
Authors
Ran-Ran Kan, Si-Yi Wang, Xiao-Yu Meng, Li Huang, Yu-Xi Xiang, Bei-Bei Mao, Hua-Jie Zou, Ya-Ming Guo, Li-Meng Pan, Pei-Qiong Luo, Yan Yang, Zhe-Long Liu, De-Lin Ma, Wen-Jun Li, Yong Chen, Dan-Pei Li, Xue-Feng Yu
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Acute rheumatic fever (ARF) and associated rheumatic heart disease are serious sequelae after infection with group A Streptococcus (Strep A). Autoantibodies are thought to contribute to pathogenesis, with deeper exploration of the autoantibody repertoire needed to improve mechanistic understanding and identify new biomarkers. Phage immunoprecipitation sequencing (PhIP-Seq) with the HuScan library (>250,000 overlapping 90-mer peptides spanning the human proteome) was utilized to analyze autoreactivity in sera from children with ARF, uncomplicated Strep A pharyngitis, and matched healthy controls. A global proteome-wide increase in autoantigen reactivity was observed in ARF, as was marked heterogeneity between patients. Public epitopes, common between individuals with ARF were rare, and comprised less than 1% of all enriched peptides. Differential analysis identified both unknown and previously identified ARF autoantigens, including PPP1R12B, a myosin phosphatase complex regulatory subunit expressed in cardiac muscle, and members of the collagen protein family, respectively. Pathway analysis found antigens from the disease-relevant processes encompassing sarcomere and heart morphogenesis were targeted. In sum, PhIP-Seq has substantially expanded the spectrum of autoantigens in ARF, and reveals the rarity of public epitopes in the disease. It provides further support for the role of epitope spreading in pathogenesis and has identified PPP1R12B as an enriched autoantigen.
Authors
Reuben McGregor, Lauren H. Carlton, Timothy J. O’Donnell, Elliot Merritt, Campbell R. Sheen, Florina Chan Mow, William John Martin, Michael G. Baker, Nigel Wilson, Uri Laserson, Nicole J. Moreland
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Herpes Simplex Virus 2 (HSV-2) infection results in variable rates of local viral shedding in anogenital skin. The effect of episodic viral exposures on immune cells in adjacent mucosal tissues, including the genital tract, is unknown. However, any immune responses at this site could affect protective mucosal immunity, tissue homeostasis, and adverse health outcomes. To investigate the effect of HSV-2 on cervicovaginal tract immunity, we applied flow cytometry, immunofluorescence imaging, analysis of soluble immune factors, and spatial transcriptomics to cervicovaginal tissue and blood samples provided by a total of 232 HSV-2–seropositive and seronegative participants, with genital HSV-2 shedding evaluated at the time of biopsy. This unique dataset was used to define and spatially map immune cell subsets and localized gene expression via spatial transcriptomics. HSV-2 seropositivity alone was associated with minimal differences in cervicovaginal and circulating T cell phenotypes. However, the vaginal mucosa during active HSV-2 shedding was associated with alterations in T cell, macrophage, and DC localization and gene expression, consistent with increased immune surveillance, with immune activating and suppressing signals potentially reinforcing mucosal tissue homeostasis.
Authors
Finn MacLean, Rachael M. Zemek, Adino Tesfahun Tsegaye, Jessica B. Graham, Jessica L. Swarts, Sarah C. Vick, Nicole B. Potchen, Irene Cruz Talavera, Lakshmi Warrier, Julien Dubrulle, Lena K. Schroeder, Anna Elz, David Sowerby, Ayumi Saito, Katherine K. Thomas, Matthias Mack, Joshua T. Schiffer, R. Scott McClelland, Keith R. Jerome, Bhavna H. Chohan, Kenneth Ngure, Nelly Rwamba Mugo, Evan W. Newell, Jairam R. Lingappa, Jennifer M. Lund, Kinga Study Team
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Juvenile idiopathic arthritis (JIA) is the most prevalent chronic inflammatory arthritis of childhood, yet the spatial organization in the synovium remains poorly understood. Here, we perform subcellular-resolution spatial transcriptomic profiling of synovial tissue from patients with active JIA. We identify diverse immune and stromal cell populations and reconstruct spatially defined cellular niches. Applying a newly developed spatial colocalization analysis pipeline, we uncover microanatomical structures, including endothelial-fibroblast interactions mediated by NOTCH signaling, and a CXCL9/CXCR3 signaling axis between inflammatory macrophages and CD8+ T cells, alongside the characterization of other resident macrophage subsets. We also detect and characterize tertiary lymphoid structures marked by CXCL13/CXCR5 and CCL19-mediated signaling from Tph cells and immunoregulatory DCs, analogous to those observed in other autoimmune diseases. Finally, comparative analysis with rheumatoid arthritis reveals JIA-enriched cell states, including NOTCH3+ and CXCL12+ sublining fibroblasts, suggesting potentially differential inflammatory programs in pediatric versus adult arthritis. These findings provide a spatially resolved molecular framework of JIA synovitis and introduce a generalizable computational pipeline for spatial colocalization analysis in tissue inflammation.
Authors
Jun Inamo, Roselyn Fierkens, Michael R. Clay, Anna Helena Jonsson, Clara Lin, Kari Hayes, Nathan Rogers, Heather Leach, Kentaro Yomogida
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BACKGROUND Cannabidiol (CBD) is increasingly used for pain management, including in transplant recipients with limited analgesic options. Its immunomodulatory effects in humans are not well defined at a single-cell level at CBD steady state with concomitant tacrolimus treatment.METHODS In a phase I ex vivo study, peripheral blood mononuclear cells from 23 participants who received oral CBD (Epidiolex) up to 5 mg/kg twice daily for 11 days were collected before CBD (pre-CBD) and at steady state (post-CBD). Lymphocytes were isolated and stimulated with anti-CD3/CD28 antibodies, with or without tacrolimus (5 ng/mL). Pharmacodynamic responses were assessed using CellTiter-Glo proliferation, single-cell and single-nucleus RNA sequencing, cytokine assays, and flow cytometry. Steady-state plasma concentrations of CBD were quantified via tandem mass spectrometry.RESULTS We identified an increased proportion of T effector memory (TEM) cells post-CBD (22% increase), which correlated with CBD plasma concentrations (R = 0.77, P = 0.01). CBD reduced proliferation of T (37% decrease) and CD70hi B (17% decrease) lymphocytes with additive immunosuppressive effects to tacrolimus. Single-cell RNA sequencing revealed reduced IL2 and TNF signaling and altered receptor-ligand networks in TEM cells. Post-CBD cytokine assays revealed elevated proinflammatory IL-6 protein levels and antiinflammatory IL-10 levels, with reduced TNF-α, LTA, and IL-2. In flow cytometry, the proportion of TEM and TEMRA cells increased post-CBD with tacrolimus.CONCLUSION CBD exerts mixed immunomodulatory effects in humans, combining antiproliferative and pro- and antiinflammatory responses. Understanding the clinical safety of CBD use is important given the paucity of pain control options available for immunocompromised transplant populations.TRIAL REGISTRATION ClinicalTrials.gov NCT05490511FUNDING NIH/National Center for Complementary and Integrative Health (R01AT011463); NIH/National Institute of General Medical Sciences (NIGMS) (R35GM145383); Intramural Research Program of the NIH; NIH/NIGMS (T32GM008425).
Authors
Debora L. Gisch, Sachiko Koyama, Jumar Etkins, Gerald C. So, Daniel J. Fehrenbach, Jessica Bo Li Lu, Ying-Hua Cheng, Ricardo Melo Ferreira, Evan Rajadhyaksha, Kelsey McClara, Mahla Asghari, Asif A. Sharfuddin, Pierre C. Dagher, Laura M. Snell, Meena S. Madhur, Rafael B. Polidoro, Zeruesenay Desta, Michael T. Eadon
×Abstract
Cytomegalovirus (CMV) is a prevalent β-herpesvirus that persists asymptomatically in immunocompetent hosts. In people with HIV-1 (PWH), CMV is associated with HIV-1 persistence and particular inflammatory-related comorbidities. The true causative role of CMV in HIV-associated pathologies, however, remains unclear given that nearly all PWH are coinfected with CMV. In this study, we examined acute phase immune and virological dynamics in cohorts of SIV-infected rhesus macaques (RMs) that were naturally seropositive or -negative for rhesus CMV (RhCMV). We observed prior to SIV, RhCMV expanded a polyclonal population of target CCR5+CD4+ T cells in gut and lymph nodes that expressed the chemotactic receptor CXCR3 and were largely not specific for RhCMV. Upon SIV infection, RhCMV+ RMs exhibited higher peak viremia and elevated levels of SIV DNA in the upper and lower intestine. Greater seeding of SIV DNA was associated with a maintenance of CCR5-expressing CD4+ T cells that were enriched within the RhCMV+ gut along a CXCR3/CXCL9 chemotactic axis. Overall, the data suggest that RhCMV can promote SIV susceptibility within a diverse, polyclonal pool of CD4+ T cells that are not entirely RhCMV specific.
Authors
Chrysostomos Perdios, Naveen Suresh Babu, Celeste D. Coleman, Anna T. Brown, Shevon N. Alexander, Matilda J. Moström, Carolina Allers, Lara Doyle-Meyers, Christine M. Fennessey, Lori A. Rowe, Brandon F. Keele, Amitinder Kaur, Michael L. Freeman, Joseph C. Mudd
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Autoimmune diabetes encompasses rapidly progressive type 1 diabetes mellitus (T1D) and indolent latent autoimmune diabetes in adults (LADA), which represent distinct inflammatory set points along a shared autoimmune spectrum. Yet, the immunological mechanisms that determine these divergent inflammatory states remain unresolved. We performed single-cell RNA sequencing with paired T and B cell receptor profiling on over 400,000 PBMCs from patients with LADA, newly diagnosed T1D, and individuals acting as healthy controls. PBMC composition was comparable across cohorts, indicating that qualitative rather than quantitative immune differences underlie disease heterogeneity. In T1D, pan-lineage activation of NF-κB, EGFR, MAPK, and hypoxia pathways, coupled with a TNF-centered communication hub, enhanced MHC signaling, disrupted adhesion, and promoted systemic inflammation. LADA, by contrast, exhibited global suppression of NF-κB/EGFR activity, retention of moderate JAK/STAT tone, reinforced NK cell inhibitory checkpoints via HLA-C–KIR2DL3/3DL1 interaction, and stabilized CD8+ T cell synapses through HLA-C–CD8 binding, collectively restraining effector activation. Single-cell V(D)J analysis revealed multiclonal, patient-unique adaptive repertoires, emphasizing the primacy of signaling context over receptor convergence. These findings define autoimmune diabetes as an inflammatory-inhibitory set-point continuum, positioning the NF-κB/EGFR–JAK/STAT gradient and HLA-C–KIR axis as potential therapeutic targets to preserve residual β cell function.
Authors
Ivan I. Golodnikov, Elizaveta S. Podshivalova, Vadim I. Chechekhin, Anatoliy V. Zubritskiy, Alina A. Matrosova, Nikita A. Sergeev, Margarita D. Samsonova, Yaroslav V. Dvoryanchikov, Tatiana V. Nikonova, Ekaterina V. Bondarenko, Marina Yu. Loguinova, Yulia A. Medvedeva, Dmitry N. Laptev, Rita I. Khusainova, Ildar R. Minniakhmetov, Marina V. Shestakova, Natalia G. Mokrysheva, Ivan I. Dedov
×Abstract
The 2 main subgroups of autoimmune myasthenia gravis, a neuromuscular junction disorder associated with muscle weakness, are early- and late-onset forms, defined by onset before or after 50 years of age. Both carry acetylcholine-receptor autoantibodies but differ in sex ratios, genetics, and occurrence of disease-specific thymus inflammation. To distinguish the 2 forms by cellular immune phenotyping, we applied multimodal techniques, including deep spectral cytometric phenotyping and single-cell sequencing. Analysis of 2 independent cohorts identified immunological differences driven by 3 main lymphocyte populations. Lower frequencies of mucosa-associated invariant T cells and naive CD8+ T cells were observed in late-onset myasthenia, suggesting enhanced immune senescence. A highly differentiated, canonical NK cell population was reduced in early-onset myasthenia and negatively correlated with the degree of thymic hyperplasia. Using only the frequency of these 3 populations, correct myasthenia subgroup assignment could be predicted with 90% accuracy. These distinct immunocellular endophenotypes for early- and late-onset disease suggest differences in immunopathogenic processes. Along with demographic factors and other disease subgroup–specific features, the frequency of the identified cell subpopulations may improve clinical classification.
Authors
Jakob Theorell, Nicolas Ruffin, Andrew Fower, Chiara Sorini, Philip Ambrose, Valentina Damato, Lahiru Handunnetthi, Isabel Leite, Sarosh R. Irani, Susanna Brauner, Adam E. Handel, Fredrik Piehl
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Abstract
Commotio retinae (CR) resulting from retinal trauma can lead to focal photoreceptor degeneration and permanent vision loss. Currently no therapies exist for CR-induced retinal degeneration, in part due to a lacking large animal model that replicates human injury pathology and allows testing of therapeutics. Severe CR is clinically characterized by subretinal fluid and focal photoreceptor outer nuclear layer thinning. To develop a porcine CR model, we developed a laser-guided projectile apparatus and optimized projectile delivery procedure using porcine cadaveric eyes embedded in a 3D-printed porcine skull. Scleral and corneal impacts, resulted in retinal damage consistent with patient injury but corneal impacts also led to cornea damage and opacification, which precluded follow up imaging. In live porcine eyes, scleral impacts of 39.5 m/s induced transient blood retinal barrier breakdown evidenced by subretinal fluid on optical coherence tomography (OCT), leakage observed on fluorescein and indocyanine green angiography, and transient photoreceptor outer segment disruption seen by OCT and multifocal electroretinography. Impacts above 39.5 m/s induced longer-lasting photoreceptor degeneration, but only transient blood retinal barrier breakdown. This porcine model, combined with clinically relevant imaging and diagnostic modalities will be valuable for testing the safety and efficacy of therapies to restore vision after focal photoreceptor degeneration.
Authors
Juan Amaral, Irina Bunea, Arvydas Maminishkis, Maria M. Campos, Francesca Barone, Rohan Gupta, Mitra Farnoodian, Jonathan Newport, M. Joseph Phillips, Ruchi Sharma, David M. Gamm, Kapil Bharti, Richard J. Blanch
Abstract
Ulcerative colitis (UC) is a chronic inflammatory condition of the colon that primarily affects the mucosal layer. Previously, we identified autoantibodies against integrin αvβ6 in patients with UC. In this study, we established monoclonal antibodies (mAbs) from patients with UC to reveal the features and functions of these anti-integrin αvβ6 autoantibodies. We identified two shared heavy chain complementarity-determining region (CDR) 3 amino acid sequences among different patients with UC. Notably, several mAbs contained the RGD sequence in their heavy chain CDR3 that mimicked the key recognition sequence of integrin αvβ6 ligands such as fibronectin. Almost all mAbs selectively reacted with integrin αvβ6 in the presence of divalent cations (Ca²⁺ and Mg²⁺) and blocked fibronectin–integrin αvβ6 binding. MAbs that shared the same heavy chain CDR3 amino acid sequence showed differences in reactivity to integrin αvβ6, indicating that the reactivity of these mAbs is also affected by the light chain. Some of the mAbs showed varying degrees of cross-reactivity with integrin αvβ3. The identification of shared CDR3 amino acid sequences in anti-integrin αvβ6 antibodies from several patients with UC suggests a common mechanism underlying their production, which may help elucidate the pathogenesis of UC.
Authors
Masahiro Shiokawa, Yoshihiro Nishikawa, Ikuhisa Takimoto, Takeshi Kuwada, Sakiko Ota, Darryl Joy C. Juntila, Takafumi Yanaidani, Kenji Sawada, Ayako Hirata, Muneji Yasuda, Koki Chikugo, Risa Nakanishi, Masataka Yokode, Yuya Muramoto, Shimpei Matsumoto, Tomoaki Matsumori, Tsutomu Chiba, Hiroshi Seno
Abstract
Cardiomyocyte growth is tightly controlled by multiple signaling pathways. Identification of master kinases in this process is essential in exploring potential targets for the treatment of pathological cardiac hypertrophy and heart failure. Here we identified the mTOR-independent activation of ribosomal protein S6 kinase b1 (Rps6kb1/S6K1) during cardiomyocyte growth. By utilizing phosphoproteomics in primary neonatal rat ventricular myocytes (NRVMs), we revealed Rps6kb1 as one of most activated kinases under growth stimulation. We further demonstrated the role of Rps6kb1 phosphorylation in pathological cardiac hypertrophy and heart failure. We showed that the phosphorylation of multiple sites at Rps6kb1, including T367 in the kinase domain and S418/T421/S424 in the C-terminal domain, is not directly regulated by the activity of mTOR, rather coupled with the activation of the MEK1-ERK axis. In mice, cardiomyocyte-specific deletion of Rps6kb1 significantly inhibited both constitutively active ERK- and pressure overload-induced cardiac hypertrophy. In contrast, cardiomyocyte-specific overexpression of wild-type Rps6kb1, rather than the phosphorylation-defective mutant, elevated cardiac hypertrophy and augmented pressure overload-induced heart failure. In conclusion, our findings reveal that the MEK-ERK axis primes Rps6kb1 activation through phosphorylation of two separate domains of Rps6kb1, which may play an essential role in cardiac hypertrophy and heart failure under hemodynamic stress.
Authors
Chao Li, Pengfei Zhang, Kai Zhang, Jane A. Cook, Weidan Song, Megan Virostek, Lily A. Slotabec, Nadiyeh Rouhi, Mohammed Hazari, Michael I. Adenawoola, Xiaofei Liu, Hao Zhang, Guangyu Zhang, Erica L Niewold, Qinfeng Li, Yong Fang, Waleed M. Elhelaly, Xue-Nan Sun, Xuejiang Guo, Andrew Lemoff, Yingfeng Deng, Thomas G. Gillette, Ji Li, Philipp E. Scherer, Zhao V. Wang
Abstract
Radiotherapy is a critical modality in cancer treatment, not only to eradicate cancer cells but also to trigger anti-tumor immunity. Interleukin-21 (IL-21), an immunomodulatory cytokine with potential in cancer therapy, has unexplored synergy with radiotherapy. Our study, leveraging human cancer databases and tissue microarrays, identified a positive correlation between IL-21 and radiotherapy outcomes, particularly in tumor microenvironment (TME) activation. In mouse tumor models, IL-21 combined with radiation significantly enhances TME, boosting CD8+ T cell activation and function, reducing tumor burden, and extending survival. Single-cell transcriptome sequencing revealed that the combination of IL-21 and radiation increased the cytotoxicity of effector and memory CD8+ T cells and prevented their exhaustion. These effects were further validated in humanized mice, where IL-21 combined with radiation reduced A549 tumor growth and enhanced CD8+ T cell function. Post-neoadjuvant radiotherapy samples from patients with esophageal cancer showed a positive correlation between IL-21 levels and CD8+ T cell infiltration. Our findings suggest that IL-21 is a promising adjuvant to radiotherapy, potentially improving the treatment efficacy through TME enhancement. This study provides a foundation for future clinical exploration of IL-21 for enhancing radiotherapy.
Authors
Xinyang Li, Xueqi Xie, Baochao Wei, Xiaozheng Sun, Minxin Chen, Rufei Liu, Qingxu Tao, Yiheng Huang, Qian Wang, Shuangshuang Ma, Ling Wei, Rong Xiao, Zhaoyun Liu, Jinming Yu, Meng Wu, Dawei Chen
Abstract
Congenital long QT syndrome (LQTS) promotes risk for life-threatening cardiac arrhythmia and sudden death in children and young adults. Pathogenic variants in the voltage-gated potassium channel KCNQ1 are the most frequently discovered genetic cause. Most LQTS-associated KCNQ1 variants cause loss-of-function secondary to impaired trafficking of the channel to the plasma membrane. There are currently no therapeutic approaches that address this underlying molecular defect. Using a high-throughput screening paradigm, we identified VU0494372, a small molecule that increases total and cell surface levels and trafficking efficiency of WT KCNQ1 as well as three LQTS-associated variants. Additionally, 16-hour treatment of cells with VU0494372 increased IKs (KCNQ1-KCNE1 current) for WT KCNQ1 and the LQTS-associated variant V207M in cells co-expressing KCNE1. VU0494372 had no impact on KCNQ1 transcription, degradation, or thermal stability, and increased the rate of KCNQ1 reaching the cell surface. We identified a potential direct interaction site with KCNQ1 at or near the binding site of the KCNQ1 potentiator ML277. Together, these findings demonstrate that small molecules can increase the expression levels and cell surface trafficking efficiency of KCNQ1 and introduce a potential new pharmacological approach for treating LQTS.
Authors
Katherine R. Clowes Moster, Carlos G. Vanoye, Ana C. Chang-Gonzalez, Ian M. Romaine, Katherine M. Stefanski, Mason C. Wilkinson, Joshua A. Bauer, Thomas P. Hasaka, Emily L. Days, Reshma R. Desai, Kathryn R. Butcher, Gary A. Sulikowski, Alex G. Waterson, Jens Meiler, Kaitlyn V. Ledwitch, Alfred L. George, Jr., Charles R. Sanders
