Citation Information: JCI Insight. 2025;10(7):e189388. https://doi.org/10.1172/jci.insight.189388.
Abstract
Chlamydia trachomatis (CT) is the most common bacterial sexually transmitted infection globally. Understanding natural immunity to CT will inform vaccine design. This study aimed to profile immune cells and associated functional features in CT-infected women and determine immune profiles associated with reduced risk of ascended endometrial CT infection and CT reinfection. PBMCs from CT-exposed women were profiled by mass cytometry, and random forest models identified key features that distinguished outcomes. CT+ participants exhibited higher frequencies of CD4+ Th2, Th17, and Th17 double-negative (Th17 DN) CD4+ T effector memory (TEM) cells than uninfected participants with decreased expression of T cell activation and differentiation markers. Minimal differences were detected between women with or without endometrial CT infection. Participants who remained follow-up negative (FU–) showed higher frequencies of CD4+ T central memory (TCM) Th1, Th17, Th1/17, and Th17 DN but reduced CD4+ TEM Th2 cells than FU+ participants. Expression of markers associated with central memory and Th17 lineage was increased on T cell subsets among FU– participants. These data indicate that peripheral T cells exhibit distinct features associated with resistance to CT reinfection. The highly plastic Th17 lineage appears to contribute to protection. Addressing these immune nuances could promote efficacy of CT vaccines.
Authors
Kacy S. Yount, Chi-Jane Chen, Avinash Kollipara, Chuwen Liu, Neha V. Mokashi, Xiaojing Zheng, C. Bruce Bagwell, Taylor B. Poston, Harold C. Wiesenfeld, Sharon L. Hillier, Catherine M. O’Connell, Natalie Stanley, Toni Darville
Citation Information: JCI Insight. 2025;10(7):e177084. https://doi.org/10.1172/jci.insight.177084.
Abstract
The role of mesenchymal cells during respiratory infection is not well defined, including whether, which, and how the different types of mesenchymal cells respond. We collected all mesenchymal cells from lung single-cell suspensions of mice that were naive (after receiving only saline vehicle), pneumonic (after intratracheal instillation of pneumococcus 24 hours previously), or resolved from infection (after nonlethal pneumococcal infections 6 weeks previously) and performed single-cell RNA sequencing. Cells clustered into 5 well-separated groups based on their transcriptomes: matrix fibroblasts, myofibroblasts, pericytes, smooth muscle cells, and mesothelial cells. Fibroblasts were the most abundant and could be further segregated into Pdgfra+Npnt+Ces1d+Col13a1+ alveolar fibroblasts and Cd9+Pi16+Sca1+Col14a1+ adventitial fibroblasts. The cells from naive and resolved groups overlapped in dimension reduction plots, suggesting the mesenchymal cells returned to baseline transcriptomes after resolution. During pneumonia, all mesenchymal cells responded with altered transcriptomes, revealing a core response that had been conserved across cell types as well as distinct mesenchymal cell type–specific responses. The different subsets of fibroblasts induced similar gene sets, but the alveolar fibroblasts responded more strongly than the adventitial fibroblasts. These data demonstrated diverse and specialized immune activities of lung mesenchymal cells during pneumonia.
Authors
Alicia M. Soucy, Jourdan E. Brune, Archana Jayaraman, Anukul T. Shenoy, Filiz T. Korkmaz, Neelou S. Etesami, Bradley E. Hiller, Ian M.C. Martin, Wesley N. Goltry, Catherine T. Ha, Nicholas A. Crossland, Joshua D. Campbell, Thomas G. Beach, Katrina E. Traber, Matthew R. Jones, Lee J. Quinton, Markus Bosmann, Charles W. Frevert, Joseph P. Mizgerd
Abstract
The sentinel lymph node (SLN) is the first lymph node encountered by a metastatic cancer cell and serves as a predictor of poor prognosis, as cases with clinically occult SLN metastases are classified as stage III with elevated rates of recurrence and diminished overall survival. However, the dynamics of immune infiltrates in SLNs remain poorly characterized. Here, using an unbiased cellular indexing of transcriptomes and epitopes by sequencing technique, we profiled 97,777 cells from SLN tissues obtained from patients with stages I/II and III cutaneous melanoma. We described the transcriptional programs of a multitude of T, B, and myeloid cell subtypes in SLNs. Based on the proportions of cell types, we determined that SLN subtypes stratified along a naive → activated axis; patients with a “high activated” signature score appeared to be undergoing a robust melanoma antigen–driven adaptive immune response and, thus, could be responsive to immunotherapy. Additionally, we identified transcriptomic signatures of SLN-infiltrating dendritic cell subsets that compromise antitumor immune responses. Our analyses provide valuable insights into tumor-driven immune changes in the SLN tissue, offering a powerful tool for the informed design of immune therapies for patients with high-risk melanoma.
Authors
Eric Engelbrecht, Bryce F. Stamp, Lewis Chew, Omar Sadi Sarkar, Phillip Harter, Sabine J. Waigel, Eric C. Rouchka, Julia Chariker, Andrei Smolenkov, Jason Chesney, Kelly McMasters, Corey T. Watson, Kavitha Yaddanapudi
Abstract
Intervertebral disc degeneration (IDD) is associated with low back pain, a leading cause of disability worldwide. Fibrosis of nucleus pulposus (NP) is a principal component of IDD, featuring an accumulation of myofibroblast-like cells. Previous study indicates that matrix metalloproteinase 12 (MMP12) expression is upregulated in IDD, but its role remains largely unexplored. We here showed that TGF-β1 could promote myofibroblast-like differentiation of human NP cells along with an induction of MMP12 expression. Intriguingly, MMP12 knockdown not only ameliorated the myofibroblastic phenotype but also increased chondrogenic marker expression. Transcriptome analysis revealed that the MMP12-mediated acquisition of myofibroblast phenotype was coupled to processes related to fibroblast activation and osteogenesis and to pathways mediated by MAPK and Wnt signaling. Injury induced mouse IDD showed NP fibrosis with marked increase of collagen deposition and αSMA-expressing cells. In contrast, MMP12-KO mice exhibited largely reduced collagen I and III but increased collagen II and aggrecan deposition, indicating an inhibition of NP fibrosis along with an enhanced cartilaginous matrix remodeling. Consistently, an increase of SOX9+ and CNMD+ but decrease of αSMA+ NP cells was found in the KO. Altogether, our findings suggest a pivotal role of MMP12 in myofibroblast generation, thereby regulating NP fibrosis in IDD.
Authors
Yi Sun, Wai-Kit Tam, Manyu Zhu, Qiuji Lu, Mengqi Yu, Yuching Hsu, Peng Chen, Peng Zhang, Minmin Lyu, Yongcan Huang, Zhaomin Zheng, Xintao Zhang, Victor Y. Leung
Citation Information: JCI Insight. 2025;10(7):e187921. https://doi.org/10.1172/jci.insight.187921.
Abstract
While immune checkpoint inhibition (CPI) has reshaped cancer treatment, the majority of patients with cancer do not benefit from this approach, which can also cause immune-related adverse events. Induction of IFN-γ responses is thought be necessary for antitumor immunity, but growing evidence also implicates IFN-γ as a tumor-intrinsic mediator of CPI resistance. CPI-induced IFN-γ mediates activation-induced cell death in T cells as an immune-intrinsic mechanism of resistance. In this study, we found that transient block of IFN-γ signaling through administration of the JAK1 inhibitor ABT-317 enhanced antitumor T cell responses with CPI in preclinical models. Importantly, sequential but not concomitant ABT-317 treatment led to significantly reduced toxicity and improved tumor efficacy. Sequential treatment reduced activation-induced T cell death and enhanced expansion of tumor-reactive T cell subsets with increased effector function in vivo and ex vivo. Only CPI in combination with ABT-317 also enhanced memory responses by protecting mice from tumor rechallenge. These results demonstrate that JAK inhibition within a discrete time window following CPI addresses an immune-intrinsic mechanism of therapeutic resistance.
Authors
Marcel Arias-Badia, PeiXi Chen, Yee May Lwin, Aahir Srinath, Aram Lyu, Zenghua Fan, Serena S. Kwek, Diamond N. Luong, Ali Setayesh, Mason Sakamoto, Matthew Clark, Averey Lea, Rachel M. Wolters, Andrew Goodearl, Fiona A. Harding, Jacob V. Gorman, Wendy Ritacco, Lawrence Fong
Citation Information: JCI Insight. 2025;10(7):e179928. https://doi.org/10.1172/jci.insight.179928.
Abstract
The deleterious consequences of chronic synovitis on cartilage, tendon, and bone in rheumatoid arthritis (RA) are well described. In contrast, its effects on periarticular skeletal muscle are under-studied. Furthermore, while TNF inhibition is an effective therapy for RA synovitis, it exacerbates fibrosis in muscle injury models. We aimed to investigate whether myositis and muscle fibrosis are features of inflammatory arthritis and evaluate whether targeted RA therapies influence these disease features. Periarticular muscle was analyzed in murine models of poly- and monoarticular inflammatory arthritis: serum transfer–induced arthritis, collagen-induced arthritis, K/BxN, and antigen-induced arthritis (AIA). Periarticular myositis and an increase in muscle fibroadipocyte progenitors (FAPs) were observed in all models, despite diverse arthritogenic mechanisms. Periarticular muscle fibrosis was observed from day 15 in AIA. Neither etanercept nor baricitinib suppressed periarticular myositis or subsequent fibrosis compared to vehicle, despite reducing arthritis. Notably, etanercept failed to prevent muscle fibrosis even when initiated early, but this was not linked to increased FAP survival or collagen production. Corroborating these data, radiographic and histological analyses revealed periarticular myositis in patients with RA. We conclude that periarticular myositis and fibrosis are under-recognized features of inflammatory arthritis. Targeted RA therapies may not prevent periarticular muscle sequelae, despite controlling arthritis.
Authors
Jessica Day, Cynthia Louis, Kristy Swiderski, Angus Stock, Huon Wong, Wentao Yao, Bonnia Liu, Suba Nadesapillai, Gordon S. Lynch, Ian P. Wicks
Citation Information: JCI Insight. 2025;10(7):e174600. https://doi.org/10.1172/jci.insight.174600.
Abstract
This study aimed to explore the potential correlation between the metabolic intermediate L-2-hydroxyglutarate (L-2-HG) and T cell exhaustion, as well as the underlying mechanisms involved. In this study, we investigated the presence of exhausted T (Tex) cells in patients under certain conditions: HIV infection, chronic leukemia, and hepatocellular carcinoma. To gain insights into the epigenetic signatures and transcriptome changes in Tex cells, we employed a combination of RNA-seq and ATAC-seq analyses. To evaluate the impact of L-2-HG on mitochondrial function, differentiation, and antitumor capacity of Tex cells, we utilized in vitro cell culture experiments and animal tumor models. We observed mitochondrial depolarization and metabolic dysfunction in Tex cells, accompanied by a significant reduction in L-2-HG levels. Moreover, altered epigenetic characteristics were observed in Tex cells, including a substantial increase in H3K27me3 abundance. Culturing Tex cells with L-2-HG demonstrated improved mitochondrial metabolism, reduced H3K27me3 abundance, and enhanced memory T cell differentiation. In a mouse melanoma tumor model, L-2-HG–treated CD8+ T cells for adoptive therapy led to significantly reduced tumor volume and significantly enhanced effector function of T cells. The study revealed that L-2-HG acted as an immune metabolite through epigenetic modifications of Tex cells.
Authors
Yanying Yang, Xiaoyan Li, Fangming Liu, Mingyue Ma, Ying Yang, Chengchao Ruan, Yan Lu, Xiaoyang Li, Xiangdong Wang, Yinghong Shi, Zheng Zhang, Hua Wang, Zhouli Cheng, Duojiao Wu
Citation Information: JCI Insight. 2025;10(7):e182232. https://doi.org/10.1172/jci.insight.182232.
Abstract
Metabolic dysfunction–associated steatotic liver disease (MASLD) — characterized by excess accumulation of fat in the liver — now affects one-third of the world’s population. As MASLD progresses, extracellular matrix components including collagen accumulate in the liver, causing tissue fibrosis, a major determinant of disease severity and mortality. To identify transcriptional regulators of fibrosis, we computationally inferred the activity of transcription factors (TFs) relevant to fibrosis by profiling the matched transcriptomes and epigenomes of 108 human liver biopsies from a deeply characterized cohort of patients spanning the full histopathologic spectrum of MASLD. CRISPR-based genetic KO of the top 100 TFs identified ZNF469 as a regulator of collagen expression in primary human hepatic stellate cells (HSCs). Gain- and loss-of-function studies established that ZNF469 regulates collagen genes and genes involved in matrix homeostasis through direct binding to gene bodies and regulatory elements. By integrating multiomic large-scale profiling of human biopsies with extensive experimental validation, we demonstrate that ZNF469 is a transcriptional regulator of collagen in HSCs. Overall, these data nominate ZNF469 as a previously unrecognized determinant of MASLD-associated liver fibrosis.
Authors
Sebastian Steinhauser, David Estoppey, Dennis P. Buehler, Yanhua Xiong, Nicolas Pizzato, Amandine Rietsch, Fabian Wu, Nelly Leroy, Tiffany Wunderlin, Isabelle Claerr, Philipp Tropberger, Miriam Müller, Alexandra Vissieres, Lindsay M. Davison, Eric Farber-Eger, Quinn S. Wells, Quanhu Sheng, Sebastian Bergling, Sophia Wild, Pierre Moulin, Jiancong Liang, Wayne J. English, Brandon Williams, Judith Knehr, Marc Altorfer, Alejandro Reyes, Johannes Voshol, Craig Mickanin, Dominic Hoepfner, Florian Nigsch, Mathias Frederiksen, Charles R. Flynn, Barna D. Fodor, Jonathan D. Brown, Christian Kolter
Citation Information: JCI Insight. 2025;10(7):e188014. https://doi.org/10.1172/jci.insight.188014.
Abstract
Dravet syndrome is a developmental and epileptic encephalopathy associated with pathogenic variants in SCN1A. Most disease-causing variants are located within coding regions, but recent work has shed light on the role of noncoding variants associated with a poison exon in intron 20 of SCN1A. Discovery of the SCN1A poison exon known as 20N has led to the first potential disease-modifying therapy for Dravet syndrome in the form of an antisense oligonucleotide. Here, we demonstrate the existence of 2 additional poison exons in introns 1 and 22 of SCN1A through targeted, deep-coverage long-read sequencing of SCN1A transcripts. We show that inclusion of these poison exons is developmentally regulated in the human brain, and that deep intronic variants associated with these poison exons lead to their aberrant inclusion in vitro in a minigene assay or in iPSC-derived neurons. Additionally, we show that splice-modulating antisense oligonucleotides can ameliorate aberrant inclusion of poison exons. Our findings highlight the role of deep intronic pathogenic variants in disease and provide additional therapeutic targets for precision medicine in Dravet syndrome and other SCN1A-related disorders.
Authors
Sheng Tang, Hannah Stamberger, Jeffrey D. Calhoun, Sarah Weckhuysen, Gemma L. Carvill
Citation Information: JCI Insight. 2025;10(7):e187025. https://doi.org/10.1172/jci.insight.187025.
Abstract
The functional plasticity of tumor-infiltrating lymphocyte B–cells (TIL-B) spans from antitumor responses to noncanonical immune suppression. Yet, how the tumor microenvironment (TME) influences TIL-B development is still underappreciated. Our current study integrated single-cell transcriptomics and B cell receptor (BCR) sequencing to profile TIL-B phenotypes and clonalities in hepatocellular carcinoma (HCC). Using trajectory and gene regulatory network analysis, we were able to characterize plasma cells and memory and naive B cells within the HCC TME and further revealed a downregulation of BCR signaling genes in plasma cells and a subset of inflammatory TNF+ memory B cells. Within the TME, a nonswitched memory B cell subset acquired an age-associated B cell phenotype (TBET+CD11c+) and expressed higher levels of PD-L1, CD25, and granzyme B. We further demonstrated that the presence of HCC tumor cells could confer suppressive functions on peripheral blood B cells that in turn, dampen T cell costimulation. To the best of our knowledge, these findings represent novel mechanisms of noncanonical immune suppression in HCC. While previous studies identified atypical memory B cells in chronic hepatitis and across several solid cancer types, we further highlighted their potential role as regulatory B cells (Bregs) within both the TME and peripheral blood of HCC patients.
Authors
Shi Yong Neo, Timothy Wai Ho Shuen, Shruti Khare, Joni Chong, Maichan Lau, Niranjan Shirgaonkar, Levene Chua, Junzhe Zhao, Keene Lee, Charmaine Tan, Rebecca Ba, Janice Lim, Joelle Chua, Hui Shi Cheong, Hui Min Chai, Chung Yip Chan, Alexander Yaw Fui Chung, Peng Chung Cheow, Prema Raj Jeyaraj, Jin Yao Teo, Ye Xin Koh, Aik Yong Chok, Pierce Kah Hoe Chow, Brian Goh, Wei Keat Wan, Wei Qiang Leow, Tracy Jie Zhen Loh, Po Yin Tang, Jayanthi Karunanithi, Nye Thane Ngo, Tony Kiat Hon Lim, Shengli Xu, Ramanuj Dasgupta, Han Chong Toh, Kong-Peng Lam
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