Issue published June 1, 2026 Previous issue
- Volume 136, Issue 11
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On the cover: Advancing lung tissue engineering
Rochelle et al. report a new culture approach that enables large-scale expansion of human lung alveolar type 2 cells (AT2s) for downstream use in generating engineered lungs. The cover image shows human AT2s growing on microcarriers in this new culture approach. Cells were stained for AT2 markers (HT2-280, green; pro-SP-C, white; nuclear stain, blue).. Image credit: Richard Ottman.
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Review Series
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Abstract
Identification of the genetic mutations underlying the ultrarare monogenic conditions STING-associated vasculopathy with onset in infancy (SAVI) and coatomer protein complex subunit alpha (COPA) syndrome revealed a role for the stimulator of interferon genes (STING) immune pathway in the pathogenesis of interstitial lung disease (ILD) in these conditions. STING-focused therapeutics could be a potential avenue for the treatment of SAVI and COPA syndrome in the future, yet the relevance of STING to more common types of ILD is not clear. Here, we provide an overview of SAVI and COPA syndrome, the nature of ILD in these conditions, and current evidence regarding STING activity in their pathogenesis. We discuss data from studies of a variety of other ILDs and model systems and explore the potential role for STING in more common forms of ILD.
Authors
Prasad Palani Velu, Gaofeng Zhu, Karen J. Mackenzie
×Abstract
Breakthroughs in rare genetic disease research elucidate the relationships among cytosolic DNA sensing, genome instability, and autoimmune disease phenotypes. Cytosolic self-DNA is a potent trigger of innate immunity, activating the DNA sensor cyclic GMP-AMP synthase (cGAS) and its downstream effector stimulator of interferon genes (STING). This pathway is negatively regulated by the DNA-degrading enzyme three-prime repair exonuclease 1 (TREX1); loss-of-function TREX1 variants lead to accumulation of cytosolic DNA, resulting in STING-mediated autoinflammation. Similarly, STING gain-of-function mutations cause STING-associated vasculopathy with onset in infancy, another disease characterized by multi-organ damage, disability, and premature death. The TREX1-cGAS-STING pathway has also been implicated in regulation of genome stability. Indeed, DNA damage lies at the heart of a separate TREX1-mediated disease, known as retinal vasculopathy with cerebral leukoencephalopathy, where the aberrant nuclear activity of mislocalized TREX1 damages genomic DNA, resulting in multi-organ degeneration syndrome with features of autoimmunity. Thus, monogenic autoimmune diseases and DNA damage syndromes sometimes overlap clinically, and the study of these diseases has created pathways for developing first-in-class small molecule therapeutics.
Authors
Debby J. Park, Kate M. Jones, Jessica B. Anderson, Amanda V. Finck, Jonathan J. Miner
×Abstract
The cyclic GMP-AMP synthase–stimulator of interferon genes (cGAS-STING) pathway is a central mediator of cytosolic DNA–induced innate immune responses, driving the production of type I IFNs and pro-inflammatory cytokines. Beyond its canonical role in cytosolic DNA sensing, increasing attention has been directed toward the noncanonical functions of cGAS and STING, particularly within the nucleus. Recent studies implicate dysregulated cGAS-STING signaling in neurodegenerative diseases and brain aging, with a prominent contribution to glial activation–associated neuroinflammation, a hallmark of many neurological disorders. In this Review, we first summarize the molecular mechanisms underlying the canonical cGAS-STING pathway in DNA sensing and innate immune activation. We then discuss emerging noncanonical roles of cGAS in chromatin organization and RNA metabolism, drawing on insights from evolutionary conservation and protein interactome analyses. Finally, we outline the involvement of cGAS-STING signaling in diverse aspects of brain function, including glial state regulation, neuronal homeostasis, blood-brain barrier integrity, and peripheral immune surveillance, highlighting their contributions to neuroinflammation and neuropathology. We also summarize current pharmacological inhibitors targeting cGAS and STING and discuss their therapeutic potential for modulating cGAS-STING signaling to manage brain disorders.
Authors
Weixi Feng, Abulimiti Aikedan, Subhash C. Sinha, Li Gan
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Commentaries
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Abstract
The Western diet (WD) is a rich source of saturated fatty acids, especially palmitic acid (PA), which has been implicated in the pathogenesis of insulin resistance, oxidative stress, inflammation, diabetes, and multiorgan dysfunction in obesity and diabetes. In this issue of the JCI, a study by Balasubramaniam et al. describes mechanisms linking a WD, PA, ferroptosis (iron-dependent cell death), and loss of colonic motility. Chronic PA exposure drove ferroptosis in murine in vitro systems and human myenteric ganglia. Mice fed a WD for 12 weeks developed enteropathy and loss of colonic motility, which was reversed by adeno-associated virus–mediated (AAV-mediated) overexpression of the transcription factor NFE2L2, preventing ferroptosis and restoring redox balance to enteric neurons. The study provides critical data establishing PA-induced ferroptosis as a mediator and potential therapeutic target in enteric nervous system disorders associated with obesity.
Authors
Rexford S. Ahima
×Abstract
Liver fibrosis is a common pathological outcome of chronic liver disease and is driven by inflammatory responses. However, the early signals that initiate the inflammatory cascade remain poorly understood. Emerging evidence suggests that liver sinusoidal endothelial cells (LSECs) are not merely passive bystanders, but active regulators during liver fibrosis. In this issue of the JCI, Gan et al. demonstrated in multiple preclinical models that BRD4/PML-mediated super-enhancer activation in LSECs drives proinflammatory angiocrine signaling, thereby initiating liver fibrosis. Thus, targeting this endothelial axis may offer a promising therapeutic strategy for the treatment of liver fibrosis.
Authors
Yingfen Chen, Yong He
×Abstract
Cytosolic DNA sensing through the cyclic GMP-AMP synthase (cGAS)–stimulator of interferon genes (STING) pathway has emerged as a promising strategy to elicit antitumor immunity. However, clinical translation of STING agonists has been hindered by limited efficacy and dose-limiting inflammatory toxicity, highlighting that simply providing activating ligands is insufficient to achieve durable immune responses. In this issue of the Journal of Clinical Investigation, Liao et al. showed that intracellular aspartate availability critically shapes STING signaling responsiveness. Aspartate deficiency disrupted pyrimidine synthesis, induced mtDNA stress, and engaged a feed-forward Z-DNA binding protein 1 and receptor interacting serine/threonine kinase 1/3 axis. Rather than directly triggering immunity, this metabolic state primed DNA sensing and fueled downstream signaling, thereby enabling robust and sustained antitumor immune responses. Together, these findings position nucleotide metabolism as a key determinant of innate immune responsiveness and suggest that metabolic conditioning may enhance the efficacy of STING-targeted therapies.
Authors
Haitao Jiang, Wenyan Wang, Yang-Xin Fu
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Research Articles
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Abstract
Alveolar type 2 cells (AT2s) are critical to lung regeneration, and the absence of large-scale methods to expand AT2s has hindered regenerative medicine efforts. We report a microcarrier-based, large-scale expansion method that was used to generate hundreds of billions of human AT2s. Through our process, expanded AT2s largely retained their phenotype. Furthermore, we showed that culture medium, substrate composition, and stiffness are all critical to the maintenance of AT2s. Finally, we showed that expanded AT2s can differentiate into alveolar type 1–like cells, both in vitro and in a decellularized porcine lung, demonstrating the utility of these cells for lung tissue engineering.
Authors
Lauren K. Rochelle, Rachael S. Van, Richard J. Ottman, Daren F. Robinson, Ashley R. Dockham, Amy K. Smith, Daniel P. Keeley, Jia C. Wang, Darell W. McCoy, Tyler R. Zimmerman, Bryan A. Fioret, Ryan W. Bonvillain, Thomas H. Petersen, Sarah S. Hogan, Laila C. Roudsari
×Abstract
Metabolic dysfunction–associated steatotic liver disease (MASLD) and metabolic dysfunction–associated steatohepatitis (MASH) are leading causes of cirrhosis and hepatocellular carcinoma. Defects in autophagy contribute to the development of MASLD; however, the role of Unc-51–like autophagy-activating kinase 1 (ULK1) in the pathophysiology of MASLD remains unclear. Herein, we show that ULK1, a serine/threonine kinase and core autophagy protein, is significantly repressed in human MASH livers, and that hepatocyte-specific loss of ULK1 promotes, unexpectedly, hepatic steatosis and progression to liver fibrosis, without affecting basal autophagy flux. Phospho-proteomics identified the transcriptional coactivator NCOA3 as a downstream phospho-target of ULK1. Mechanistically, ULK1 phosphorylates NCOA3 to repress its transcriptional activity and restrain the CREB/CBP-mediated de novo lipogenic program. Accordingly, a phosphorylation-deficient NCOA3 mutant drives CREB/CBP-mediated lipogenesis, whereas genetic or pharmacological NCOA3 inhibition prevents steatosis, hepatic inflammation, and profibrotic signaling. Hence, ULK1-mediated NCOA3 phosphorylation is a fundamental and druggable checkpoint against the entire MASLD spectrum.
Authors
Young Do Koo, Romilia Tatiana Castillo, Asha Sukumaran Nair, Michael Garneau, Chad Gochee, Zachary V. Campbell, Tashya Shreyas Vakil, Jua Ha, Alex Marti, Jamie Soto, Debajyoti Das, Nuria Martinez-Lopez, Shipra Sharma, Yennifer Delgado, Callie Phung, Immy A. Ashley, Edmund D. Kapelczak, Rashel Jacobo, Eric T. Weatherford, Dao-Fu Dai, Jihane N. Benhammou, Andrea G. Marshall, Antentor Hinton Jr., Ling Yang, Renata O. Pereira, Tara TeSlaa, Mehdi Bouhaddou, Rajat Singh, E. Dale Abel
×Abstract
CD48 is a surface molecule with immunoregulatory functions. Following our initial report of a patient with a de novo heterozygous variant at amino acid S220 in the CD48 gene, we describe a second, unrelated patient with similar features of immune dysregulation and a missense change affecting the same residue. To further elucidate the specific pathogenic mechanisms of the identified variants, we reviewed patient records, analyzed patient-derived cells, and employed complementary in vitro and in vivo model systems, including transfected cell lines and CD48-deficient mice. We demonstrate that the variants are associated with altered distribution of CD48, characterized by diminished CD48 surface expression, intracellular retention, and activation of ER stress signaling. Patient T cells displayed increased susceptibility to apoptosis, reduced antiviral responses, and enhanced inflammation. Both patients exhibited T cell lymphopenia, a restricted T cell receptor repertoire diversity, and oligoclonal expansions consistent with antigen-driven selection. In parallel, virally infected CD48-deficient mice recapitulate key aspects of the human phenotype, including delayed antiviral immune responses, impaired viral clearance, and pronounced inflammation. We conclude that identified variants compromise CD48 cell surface localization, impair T cell survival and function, and predispose to inflammation, thereby highlighting the role of CD48 in immune regulation and the prevention of excessive inflammation.
Authors
Samantha Milanesi, Tiziana Lorenzini, Tommaso Marchetti, Diana Tintor, Raquel Planas, Ola Sabet, Lars Malmström, Sudip Acharya, Carson D. Williams, Zoe E. Manning, Jack H. Roser, Angelica C. Ehler, Michael Huber, Seraina Prader, Stefano Vavassori, Cullen M. Dutmer, Jordan K. Abbott, Jana Pachlopnik Schmid
×Abstract
The role of the epigenome in age-related neurodegenerative disorders remains understudied. Here, we analyzed circulating cell-free DNA (cfDNA) from blood to detect methylation changes as a liquid biopsy for Amyotrophic Lateral Sclerosis (ALS). Our study included 20 patients with sporadic ALS, 10 patients with C9orf72-associated ALS, 10 asymptomatic carriers of the C9orf72 repeat expansion mutation, and 21 nondisease control individuals. Following targeted enzymatic methyl-sequencing (EM-seq) of approximately 4 million CpG sites, we detected numerous differentially methylated genes, including several implicated in ALS disease risk and pathogenesis. By integrating multiple epigenetic features, we delineated a distinct epigenetic signature, which achieved an average area under the curve (AUC) of 0.91 ± 0.10 upon receiver operator characteristic (ROC) analysis, which enabled detection of approximately 70% of patients with ALS with close to 100% specificity. Furthermore, we also identified a set of genes whose methylation status significantly correlated with clinical disease progression and cerebrospinal fluid (CSF) neurofilament levels. Our results reveal the potential of cfDNA-based biomarkers to accurately diagnose ALS and potentially predict disease progression.
Authors
Sebastian Michels, Chaorong Chen, Wolfgang P. Ruf, M. Madhy Garcia Garcia, Frederick J. Arnold, Zhuoxing Wu, Craig L. Bennett, Daniel Shams, Leslie M. Thompson, Alyssa C. Walker, Dennis W. Dickson, Leonard Petrucelli, Johannes Dorst, Mercedes Prudencio, Wei Li, Albert R. La Spada
×Abstract
Loss-of-function mutations in DNAJC6, encoding the cochaperone auxilin (HSP40 family), cause familial juvenile-onset Parkinson’s disease (PD). Given the chaperone role of DNAJC6 in cellular homeostasis in adult neurons, we hypothesized that DNAJC6 dysfunction may not be limited to juvenile-onset disorders but could also be associated with adult-onset brain diseases. Here, we show that DNAJC6 expression is significantly downregulated in postmortem substantia nigra tissues and transcriptomic datasets from patients with late-onset sporadic PD. Consistently, human pluripotent stem cell–derived midbrain cultures exhibited reduced DNAJC6 expression under multiple PD-associated conditions. Mechanistically, DNAJC6 loss resulted from impaired transcription mediated by the midbrain-specific factors NURR1/FOXA2 and reduced protein stability regulated by LRRK2. Beyond neurons, DNAJC6 was robustly expressed in astrocytes and similarly downregulated in sporadic PD contexts. Astrocytic DNAJC6 deficiency impaired phagocytic, autolysosomal, and mitochondrial functions while promoting a proinflammatory phenotype, thereby exacerbating neurodegenerative pathology. Importantly, epigenetic restoration of DNAJC6 in neurons and astrocytes using a CRISPRa-AAV9 system in the substantia nigra of an α-synuclein–induced PD mouse model alleviated behavioral deficits and neuropathology. These findings provide evidence that DNAJC6 dysregulation is associated with pathogenic processes in sporadic PD and suggest that targeting neuronal and astrocytic DNAJC6 could represent a potential disease-modifying strategy.
Authors
Wahyu Handoko Wibowo Darsono, Yeongran Hwang, Erica Valencia, Leonardo Tejo Gunawan, Seung Jae Hyeon, Hoon Ryu, Thor D. Stein, Mi-Yoon Chang, Noviana Wulansari, Sang-Hun Lee
×Abstract
BORCS5 encodes a subunit of the BLOC-One-Related Complex (BORC), which is known to promote anterograde movement and fusion of lysosomes. We identified 16 individuals from 9 families with bi-allelic BORCS5 variants, revealing a spectrum of neurodevelopmental and neurodegenerative phenotypes. Carriers of homozygous protein-truncating variants (PTVs), resulting in complete loss of BORCS5, presented with prenatally lethal arthrogryposis multiplex congenita, brain malformations, and neuropathological evidence of neuroaxonal dystrophy. Individuals with missense or splice-site variants presented differently, with microcephaly, developmental epileptic encephalopathy, optic atrophy, spasticity, and progressive movement disorders. In this group, brain MRI showed diffuse hypomyelination, corpus callosum abnormalities, and progressive global cerebral atrophy, consistent with neurodegeneration. Borcs5 KO in zebrafish resulted in microcephaly, motor deficits, and increased seizure susceptibility, mirroring the patients’ clinical presentation. At the cellular level, only BORCS5 PTVs, but not missense variants, led to perinuclear lysosomal clustering and impaired lysosomal axonal trafficking in induced pluripotent stem cell–derived forebrain neurons. However, PTVs and missense variants were associated with reduced lysosomal proteolysis and activity of lysosomal hydrolases glucocerebrosidase and cathepsin B, indicating lysosomal dysfunction. Our study reveals a role for BORCS5 in modulation of lysosomal function, in addition to its known role in lysosome movement and fusion, possibly underlying the diverse clinical manifestations in individuals with BORCS5-related disorders.
Authors
Niccolò E. Mencacci, Georgia Minakaki, Reza Maroofian, Raffaella De Pace, Adeline Paimboeuf, Tiago Branco Fonseca, Tatiana Abramova, Patrick Shannon, David Chitayat, Francesca Magrinelli, Wesley J. Peng, Diptaman Chatterjee, Sara H. Eldessouky, Julia Baptista, Tamas Marton, Julie Vogt, Juan Dario Ortigoza-Escobar, Loreto Martorell, Marta Gómez-Chiari, Ingrid M. Wentzensen, Erik-Jan Kamsteeg, Maha S. Zaki, Annarita Scardamaglia, Giovanni Zifarelli, Zuhair Nasser Al-Hassnan, Elka Miller, Shiri Shinar, Lova S. Matsa, Sri Hari Chandan Appikonda, Ghada A. Otaify, Khalid Al-Thihli, Almundher Al-Maawali, Michael Schwake, Mariasavina Severino, Henry Houlden, Shunmoogum A. Patten, Juan S. Bonifacino, Kailash P. Bhatia, Dimitri Krainc
×Abstract
The Western diets (WD), high in saturated fats such as palmitic acid (PA), promotes enteric neurodegeneration and motility disorders. Using murine models, in vitro systems, and human myenteric ganglia, we investigated whether a WD and PA drive iron-dependent ferroptotic injury in the enteric nervous system (ENS). Mice were fed a control diet (CD) or a WD for 12 weeks, with or without systemic AAV9-MaCPNS2 delivery of Nfe2l2 to enteric neurons. Colonic motility was assessed by a bead expulsion assay. We assessed ferroptosis using convergent readouts including iron dysregulation (transferrin receptor 1 [TfR1], ferritin heavy chain 1 [FTH1], labile and mitochondrial iron [Fe2+]), lipid peroxidation (C11-BODIPY and 4-hydroxynonenal [4-HNE]), glutathione peroxidase 4 (GPX4) suppression, and pharmacologic inhibition by ferrostatin 1 (Fer-1) in primary enteric neurons, murine myenteric plexuses, and human networks of myenteric ganglia (nhMPG). WD-fed mice exhibited delayed colonic transit, increased TfR1 and FTH1, and vulnerability of nNOS neurons; these changes were reversed by nuclear factor erythroid 2–related factor 2; (Nfe2l2, also known as Nrf2) overexpression. RNA-seq of PA-treated immortalized murine fetal enteric neurons (IM-FENs) revealed disrupted neurotransmitter signaling, reduced mitochondrial and antioxidant programs, and increased iron import and lipid peroxidation signatures. PA increased labile Fe2+, mitochondrial ROS, membrane depolarization, Ca2+ dysregulation, 4-HNE, and mitoferrin 2 (Mfrn2), whereas Fer-1 preserved mitochondrial integrity, viability, and ENS function. In human nhMPG, PA induced enteric neuronal iron loading and ferroptosis, supporting the translational relevance to diet-associated enteric neuropathy.
Authors
Arun Balasubramaniam, Dmitrii Pavlov, Yunpeng Du, Jeremy Reeves, Alan Harzman, Yunshan Liu, Francesca Cingolani, Xinxu Yuan, Jay M. Patel, Simon Musyoka Mwangi, Peijian He, C. Michael Hart, Wenhui Hu, Fievos L. Christofi, Shanthi Srinivasan
×Abstract
Cellular and molecular heterogeneity in the liver has been increasingly recognized to drive liver fibrosis progression, but the particular events that occur initially in response to liver injury and trigger immune cell recruitment remain unclear. Here, we identify epigenetically aberrant liver sinusoidal endothelial cells (LSECs) as key players in this process. Mechanistically, the epigenetic readers like bromodomain-containing protein 4–dependent (BRD4-dependent) super enhancers (SEs) activate proinflammatory genes, including promyelocytic leukemia (PML). The PML protein, in turn, binds BRD4 and amplifies proinflammatory angiocrine signaling through phase separation–dependent SE activation via PML/BRD4 condensate formation. In mouse models, LSEC-specific depletion of the PML/BRD4 complex mitigates liver inflammation and fibrosis. Single-cell RNA-seq reveals that epigenetically aberrant LSECs exhibit a reprogrammed proinflammatory angiocrine landscape in mouse fibrotic livers. TIMP1+ LSECs promote the recruitment of CD63+ monocyte–derived macrophages (MoMFs) during liver fibrosis progression. Thereby, PML/BRD4 in LSECs governs inflammatory immune cell recruitment in liver fibrosis. Pharmacological BRD4 inhibition or epigenetic PML-SE repression alleviates liver inflammation and fibrosis. In conclusion, PML/BRD4-mediated SE activation via phase separation drives proinflammatory angiocrine signaling in LSECs, initiating the inflammatory cascade and subsequent immune cell recruitment during liver fibrosis.
Authors
Can Gan, Enjiang Lai, Yang Tai, Shuai Chen, Chong Zhao, Wenting Dai, Zhu Yang, Bei Li, Tian Lan, Yang Xiao, Yangkun Guo, Jiaxin Chen, Bo Wei, Zhaodi Che, Sheng Cao, Mengfei Liu, Frank Tacke, Chengwei Tang, Vijay H. Shah, Haopeng Yu, Fei Wang, Zhiyin Huang, Jinhang Gao
×Abstract
Early initiation of antiretroviral therapy (ART) in perinatally HIV-infected children significantly limits the establishment of the viral reservoir. However, the long-term impact of this intervention remains unclear. We measured the frequency of inducible, translation-competent, and replication-competent proviruses in samples from 62 children who initiated ART early and remained virally suppressed for up to 9.9 years. Only a small fraction of HIV genomes produced HIV transcripts, viral proteins, or infectious virions. Accordingly, replication-competent virus was detected in only 11% of the participants. Despite the predominance of naive cells in pediatric blood, most proviruses were detected in memory CD4+ T cells, especially central memory cells. Longitudinal analysis revealed a biphasic decay in HIV DNA: an initial decline followed by long-term stability, which was associated with extensive expansions of infected T cell clones. In contrast, inducible proviruses declined continuously and became undetectable in most children after 5 years. Near full-length sequencing of 1,305 HIV genomes revealed a dramatic reduction in genetically intact proviruses, from pre-ART to after 7 years of ART. Together, these findings suggest that the intact viral reservoir rapidly decays in early-treated children, offering critical insights for pediatric HIV cure strategies.
Authors
Marta Massanella, Caroline Dufour, Amélie Pagliuzza, Audrée Lemieux, Corentin Richard, Jintanat Ananworanich, Louise Leyre, Thidarat Jupimai, Supranee Buranapraditkun, Rapisa Nantanee, Julie L. Mitchell, Panadda Sawangsinth, Mark de Souza, Piyarat Suntarattiwong, Suparat Kanjanavanit, Pope Kosalaraksa, Thitiporn Borkird, Witaya Petdachai, Kulkanya Chokephaibulkit, Lydie Trautmann, Rémi Fromentin, Thanyawee Puthanakit, Nicolas Chomont, on behalf of the HIV Netherlands Australia Thailand Research Collaboration 209 and 194 (HIVNAT209 and HIVNAT194) study groups
×Abstract
Dilated cardiomyopathy (DCM) is a genetically heterogeneous disorder, characterized by ventricular dilatation and impaired systolic function, leading to heart failure and sudden cardiac death. Despite advances in genomic technologies, the genetic cause of DCM remains unidentified in more than half of the cases. Here, we performed an integrative analysis of genomic and transcriptomic data from patient-derived cardiac tissue to identify causative variants in genetically undiagnosed DCM. This approach enabled us to identify a homozygous splice-site variant (c.243+6T>A) in the sarcoglycan gene SGCB, which results in exon 2 skipping. This variant was significantly enriched in patients with DCM compared with the general population, with consistent genotype–phenotype correlations observed across multiple families. Protein-level analysis of cardiac tissue from homozygous individuals revealed loss of β-sarcoglycan, the protein product of SGCB, and destabilization of the sarcoglycan complex. Although SGCB has been previously associated with limb-girdle muscular dystrophy, these homozygous individuals showed no biochemical or clinical signs of skeletal muscle involvement, indicating an absence of myopathy. Compared with variant-negative patients with DCM, homozygous individuals also had a higher risk of early-onset adverse cardiac events. Together, these findings identify c.243+6T>A in SGCB as a cause of isolated DCM associated with unfavorable clinical outcomes.
Authors
Fangfang Li, Haruki Shinomiya, Yuki Kuramoto, Koshiro Kanaoka, Yuji Sakahashi, Yasuki Ishihara, Hidetaka Kioka, Seiko Ide, Yumi Yamaguchi-Kabata, Shu Tadaka, Ikuko N. Motoike, Kengo Kinoshita, Kinuko Ohneda, Hidetoshi Sakurai, Takahiro Okumura, Yohei Miyashita, Kota Jojima, Hisakazu Kato, Ken Matsuoka, Kazuya Tanabe, Shunsuke Nishimura, Seiji Takashima, Yoshihiro Asano, Yasushi Sakata
×Abstract
Typ515 (W515) mutations in the protein MPL are one of the key driver mutations promoting BCR-ABL-negative myeloproliferative neoplasms (MPNs), but, to our knowledge, their effects on hematopoietic stem cells (HSCs) and MPN-related hematological abnormalities have not been studied in physiological contexts. Here, we established a MplW514L knock-in mouse model, which largely mimics human MPLW515L mutation during hematopoiesis. The mutant mice developed an essential thrombocythemia–like (ET-like) MPN phenotype, displaying excess megakaryopoiesis and thrombocytosis and progressive myelofibrosis. Mechanistically, we observed that the MplW514L-conditioned HSC compartment had a unique disease-initiating capacity; however, it did not exhibit a obvious advantage of competitive repopulation over the WT control. Notably, single-cell analysis and flow cytometry profiles support that MplW514L expression led to a significant expansion of megakaryocyte-biased stem cell fate within the HSC pool. Finally, JAK2 inhibitor treatment phenotypically alleviated the ET signs but failed to eliminate the disease-initiating HSCs. These findings underscore the etiology of physiological expression of the MPLW515L mutation in HSCs and also provide a valuable in vivo model to evaluate potential therapeutic options for patients with MPLW515L-positive MPN.
Authors
Shujing Zhang, Jingjing Liu, Yuan Li, Yi Wang, Lingling Wang, Miaomiao Xu, Yanxia Li, Ge Dong, Shanshan Wang, Yanmei Li, Zhigang Cai, Baobing Zhao
×Abstract
Metabolic signals critically shape innate immune responses. Through pharmacological screening of metabolic pathways, we identified aspartate metabolism as a key regulator of cyclic GMP-AMP synthase (cGAS)–stimulator of interferon genes (STING) signaling. Genetically or aminooxyacetic acid–mediated (AOA-mediated) pharmacologically reducing aspartate levels markedly potentiated the cGAS-STING pathway, leading to stronger upregulation of type I interferons and interferon-stimulated genes. Mechanistically, disruption of de novo pyrimidine synthesis, a major downstream pathway of aspartate, induced mtDNA replication stress and increased mtDNA double-strand breaks, promoting mtDNA release into the cytosol. Cytosolic mtDNA synergized with cGAS-STING agonists to upregulate Z-DNA binding protein 1 (ZBP1), which recruits RIPK1/3 to sustain IRF3 phosphorylation, forming a positive feedback loop that amplifies innate immune signaling. In immunocompetent mouse models, AOA enhanced the antitumor efficacy of STING agonists, chemotherapy, or radiotherapy, whereas aspartate supplementation abrogated these effects. Consistently, aspartate levels negatively correlated with antitumor immunity in colorectal cancer patient samples. Together, our study identifies aspartate–pyrimidine metabolism as a critical metabolic checkpoint that licenses STING signaling by enabling mtDNA stress to cooperate with agonist stimulation, driving type I interferon–dependent ZBP1 induction and feed-forward amplification of STING signaling, thus offering a promising strategy to enhance antitumor immunity.
Authors
Yuheng Liao, Hanze Wang, Hengxin Liu, Xi Chen, Renqiang Sun, Xie Li, Zhen Yang, Chenying Liu, Wei Wu, Ziqian He, Yuzheng Zhao, Ying Mao, Dan Ye, Hui Yang
×Abstract
Immunotherapies achieve durable responses in several cancers but show limited efficacy in refractory hepatocellular carcinoma (HCC). The mechanisms by which hepatoma cells evade immune recognition and limit immune checkpoint blockade (ICB) efficacy are incompletely defined. Here, we identified tumor-intrinsic tescalcin (TESC) as a previously unrecognized phagocytic checkpoint that contributes to immune evasion and ICB resistance in HCC. Mechanistically, H3K4 methylation drove TESC expression in hepatoma cells, facilitating cytosolic Ca2+ buffering and attenuating endoplasmic reticulum (ER) stress–induced calreticulin (CALR) plasma membrane exposure, an essential “eat-me” signal. Consequently, this process abrogated membrane CALR-directed phagocytosis by antigen-presenting cells (APCs), including macrophages and DCs, thereby impairing antigen presentation and subsequent T cell activation. Clinically, we found that elevated H3K4me3-TESC signaling was a promising prognostic biomarker for a poor ICB response in HCC. Importantly, in vivo disruption of this axis restored APC phagocytic function and enhanced the antitumor effects of ICB therapy. Therefore, targeting TESC-driven immune escape and its underlying epigenetic regulation may restore APC function and offer a precise therapeutic strategy to enhance immunotherapeutic efficacy in HCC.
Authors
Jiong-Liang Wang, Jun-Cheng Wang, Yangxun Pan, Minrui He, Zhikai Zheng, Hao Zou, Tianqing Wu, Yuhan Zhang, Zili Hu, Yizhen Fu, Wei Peng, Zhenyun Yang, Li Xu, Yao-Jun Zhang, Min-Shan Chen, Dandan Hu, Jinbin Chen, Ming Zhao, Dong-Ping Chen, Zhong-Guo Zhou
×Abstract
Cancers reprogram their metabolism to provide anabolic needs without driving excessive oxidative stress. Attention has focused on glucose metabolism, yet amino acid synthesis and degradation also promote tumor cell states and growth. Here, we assessed amino acids that maintain cancer stem cells in glioblastoma and found increased proline levels relative to differentiated tumor progeny through increased proline synthesis. Cancer stem cells preferentially expressed the signaling molecule FAM3C induced by the stem cell transcription factor SOX2 to drive expression of proline synthesis enzymes. FAM3C classically mediated cellular responses as a secreted protein but gained intracellular functions in cancer stem cells through binding the histone reader spindlin 1 (SPIN1), thereby preventing its lysosomal degradation, assisting its nuclear localization, and promoting epigenetic regulation of proline synthesis. Proline synthesis depleted ROS, and genetic targeting of FAM3C attenuated ROS scavenging, whereas SPIN1 OE restored ROS levels. Molecular docking identified tucatinib as a brain-penetrant pharmacologic disruptor of FAM3C-SPIN1 interactions, promoting SPIN1 degradation and reducing intracellular proline levels. Thus, cancer stem cells induced a favorable metabolic state through proline synthesis and ROS depletion, revealing potential therapeutic dependencies.
Authors
Weichi Wu, Po Zhang, Donghai Wang, Xujia Wu, Qiulian Wu, Daqi Li, Tengfei Huang, Rui Wang, Huan Li, Hailong Mi, Suchet Taori, Fanen Yuan, Tingting Duan, Zhiye Chen, Huairui Yuan, Jeremy N. Rich
×Abstract
Metastatic castration-resistant prostate cancer (mCRPC) remains lethal with limited treatment options. Antibody–drug conjugates (ADCs) have emerged as a transformative class across multiple solid tumors, yet their clinical application in prostate cancer has been limited. Izalontamab brengitecan (Iza-bren; BL-B01D1) is a bispecific ADC-targeting EGFR and HER3 that has demonstrated activity in other malignancies. Here, we evaluated its therapeutic potential in the treatment of prostate cancer. Multi-omics analyses revealed frequent EGFR and HER3 expression in CRPC adenocarcinoma but not in neuroendocrine subtypes. BL-B01D1 exerted potent, target-dependent cytotoxicity in prostate cancer cell lines, xenografts, and patient-derived organoids (PDOs). We highlight a representative patient with mCRPC with high EGFR/HER3 expression whose disease rapidly and durably mounted a clinical and radiologic response to BL-B01D1, concordant with matched PDO sensitivity. Mechanistic studies identified ABCG2 upregulation as a driver of acquired resistance, with genetic or pharmacologic inhibition restoring BL-B01D1 sensitivity. Importantly, tumor tissue obtained at progression after BL-B01D1 treatment confirmed ABCG2 upregulation, validating a clinically relevant resistance mechanism. These findings support BL-B01D1 as a promising therapeutic strategy in mCRPC and indicate ABCG2 may be a rational target for overcoming resistance.
Authors
Bangwei Fang, Xiaomeng Li, Ying Lu, Weiwei Ma, Hualei Gan, Tingwei Zhang, Qi Liu, Beihe Wang, Zixian Wang, Yi Zhu, Hai Zhu, Sa Xiao, Xiaojie Bian, Gonghong Wei, Dingwei Ye, Yao Zhu
×Abstract
The cyclic dinucleotide 2′3′–cyclic guanosine monophosphate–adenosine monophosphate (2′3′-cGAMP) serves as a central immunotransmitter that propagates stimulator of interferon gene–dependent (STING-dependent) innate immunity across tissues; however, how microenvironmental metabolites regulate its spatiotemporal dynamics remains unknown. Here, we identified polyamines (spermine and spermidine) as critical rheostats controlling 2′3′-cGAMP functionality. Mechanistically, polyamines sequestered 2′3′-cGAMP into polymer-like aggregates, blocking intercellular propagation and suppressing intracellular STING activation by reducing ligand-receptor binding affinity. Deficiency of spermidine and spermine N1-acetyltransferase 1 (SAT1), the rate-limiting enzyme in polyamine catabolism, elevated polyamine levels to entrap extracellular 2′3′-cGAMP and inhibit STING activation. Synergistic administration of endogenous 2′3′-cGAMP with SAT1 stabilizer N1,N11-diethylnorspermine restored 2′3′-cGAMP bioavailability and STING signaling, facilitated type I interferon responses to reprogram immunologically suppressive tumors into immunologically active states and enhanced tumor clearance. Our study established polyamine–cGAMP interactions as a critical spatiotemporal regulatory mechanism for tissue-level immunity, providing a unified model for metabolite-mediated cyclic GMP-AMP synthase–STING (cGAS-STING) regulation across diseases.
Authors
Yunjin Ma, Chunyuan Zhao, Jiacheng Guo, Yue Fu, Wei Wang, Jiangong Zhang, Kun Zhao, Xiangbo Meng, Zhongshang Yuan, Chengjiang Gao, Mutian Jia, Ying Qin, Hui Song, Wei Zhao
×Abstract
Mucociliary clearance (MCC) is an innate defense mechanism that normally keeps airways clean but is dysfunctional in cystic fibrosis (CF) and other muco-obstructive pulmonary diseases. Previously we discovered that activating adenyl cyclase in combination with a cholinergic agonist increased MCC velocity (MCCV) synergistically in ex vivo WT and CF ferret and WT piglets. For what we believe is the first time, we show in vivo synergistic MCC using FDA approved β-adrenergic and cholinergic drugs delivered to the apical surface of WT and CF rats and a CF sheep model. Also, a single dose of the combined drugs is tolerated by humans. As for mechanisms, via ex vivo experiments, we show the combined agonists increased net fluid secretion mainly by stimulating gland secretion and by inhibiting surface absorption, consequently increasing airway surface liquid depth. They also increased net base secretion and increased ciliary beat frequency. Additional ex vivo and in vitro experiments show that the combined agonists had additive effects when combined with highly effective CF transmembrane conductance regulator modulator therapy. The synergistic increase in MCCV induced by this combination of agonists offers therapeutic potential for treating muco-obstructive pulmonary diseases, including CF.
Authors
Nam Soo Joo, Susan E. Birket, Johnathan D. Keith, Juan P. Ianowski, Xiaojie Luan, Jacquelyn Spano, Jennifer B. Bollyky, Marissa N. Dobry, Juan R. Sabater, Ryan W. Williams, John F. Engelhardt, Jeffrey J. Wine, Carlos E. Milla
×Abstract
CoA facilitates fatty acid synthesis, energy production, gene regulation, and antioxidant function. While CoA biosynthesis is well characterized, the mechanisms governing CoA degradation remain poorly understood. Here, we identify the Metazoan Homolog of SpoT, MESH1, as a CoA phosphatase that dephosphorylates CoA at the 3′ position of the ribose ring to form dephospho-CoA. Recent studies have shown that CoA, similar to glutathione, is a cysteine-derived metabolite that protects cells against ferroptosis. Ferroptosis induced by blocking cystine import depletes CoA biosynthesis, while CoA restoration rescues cells from ferroptosis. We found that MESH1 knockdown preserved CoA levels by preventing its degradation, contributing to ferroptosis protection, indicating the bifunctional role of MESH1 in regulating CoA and previously reported NADPH. Mechanistically, MESH1 knockdown elevates CoA levels, maintaining a functional mitochondrial thioredoxin system, thereby preventing mitochondrial lipid peroxidation. In Drosophila, we found that dMesh1 overexpression leads to ferroptosis-mediated muscle atrophy, which can be rescued by increasing CoA and NADPH levels. Taken together, these findings establish MESH1 as a key phosphatase that governs ferroptosis sensitivity by coordinating CoA and NADPH homeostasis, unveiling a link between CoA degradation, mitochondrial integrity, and muscle health.
Authors
Chao-Chieh Lin, Joshua Rose, Alexander A. Mestre, Chien-Kung Cornelia Ding, Ssu-Yu Chen, Sze Mun Choy, Kah Yong Goh, Weiyi Jiang, Wen Xing Lee, Qizhou Jiang, Yanting Chen, Tianai Sun, Jianli Wu, Yueqi Chen, Yunju Oh, Pyeonghwa Jeong, Jiyong Hong, Kenon Chua, Michael C. Fitzgerald, Guo-Fang Zhang, Hong-Wen Tang, Pei Zhou, Jen-Tsan Chi
×Abstract
BACKGROUND Current diagnosis and surveillance of bladder cancer rely on cystoscopy, which is invasive and user dependent. The urine mRNA panel, uRNAp, measures expression of 3 genes for identification of bladder cancer. Here we report validation of uRNAp for patients undergoing initial workup for suspected bladder cancer and surveillance for bladder cancer.METHODS Urine specimens were prospectively collected prior to cystoscopy at 2 health care systems from patients without (detection cohort) or with (surveillance cohort) a history of bladder cancer. RNA was isolated from urine sediment for RT-qPCR to determine roundabout guidance receptor 1, corticotropin releasing hormone, and insulin-like growth factor 2 expression and calculate the uRNAp bladder cancer probability score.RESULTS In the detection cohort, 547 samples were collected from 529 patients. There were 123 new diagnoses of bladder cancer in the detection cohort, and uRNAp demonstrated 98% sensitivity and 51% specificity for identification of bladder cancer. In the surveillance cohort, 1,543 samples were collected from 447 patients with 286 recurrences. uRNAp demonstrated 94% overall sensitivity with 43% specificity and 99% sensitivity for high-grade recurrence. The receiver operating characteristic area under the curve was 0.92 in the detection and 0.81 in the surveillance cohort. uRNAp scores significantly increased with tumor size and grade.CONCLUSION Prospective validation of uRNAp demonstrated a strong potential clinical utility as a noninvasive adjunct to cystoscopy for management of bladder cancer. uRNAp may be a useful triage tool to defer or expedite cystoscopy for patients undergoing detection or surveillance of bladder cancer.FUNDING Department of Veterans Affairs BLR&D Merit Review I01 BX004962 to JCL.
Authors
Kathleen E. Mach, Zachary Kornberg, Eugene Shkolyar, Jin Long, Timothy J. Lee, Vinh La, Ihna Yoo, Gabriela Rodriguez, Alan E. Thong, Kris B. Prado, Jay B. Shah, John T. Leppert, Eila C. Skinner, Joseph C. Liao
×Abstract
BACKGROUND Functional B cell responses for both prevention and control of hepatitis B virus (HBV) infection remain poorly understood, including in the context of HBV/HIV coinfection.METHODS Here, we employed high-dimensional single-cell analysis to assess global and hepatitis B surface antigen–specific (HBsAg-specific) B cells in a longitudinal cohort of incident HBV from the Multicenter AIDS Cohort Study, with a subset of the cohort living with HIV-1.RESULTS We observed that prior HIV infection has negative consequences for B cell function in early post-acute HBV infection, including increased frequencies of atypical memory B cells and regulatory B cells, expression of the activation marker CD86 on multiple B cell subsets in chronic HBV (CHB), and restricted expansion of HBsAg-specific B cells. In contrast, in HBV monoinfection, we observed no changes in the global B cell population from prior to infection and robust expansion of HBsAg-specific B cells. These expanded antigen-specific B cells resembled class-switched intermediate and resting memory B cells, with activation phenotypes that may contribute to ongoing HBV control.CONCLUSION HIV infection has a significant impact on B cell responses to subsequent HBV infection that may promote development of CHB in HBV/HIV coinfection.FUNDING Vaccine Research Center, NIAID, Bill & Melinda Gates Foundation, and NIH.
Authors
Katherine Cascino, Thomas Liechti, Eric C. Seaberg, Kathleen E. Stevens, Steven M. Wolinsky, Mallory D. Witt, Robbie B. Mailliard, Mario Roederer, Justin R. Bailey, Chloe L. Thio, Andrea L. Cox
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Abstract
Gene therapy-based biological pacemakers have been proposed as an alternative to their hardware-based counterparts. In this context, short-term ectopic expression of the T-box transcription factor 18 (TBX18) in the ventricle has been reported to generate potent short-term pacemaker function in various animal models. Here, we investigated the impact of adeno-associated virus (AAV)-mediated long-term expression of TBX18, and compared the outcomes to those of the pacemaker ion channel Hcn2. Our findings revealed that CMV-driven ectopic TBX18 expression in mouse hearts led to severe cardiac fibrosis. At lower, non-fibrogenic levels, TBX18 maintained its transcriptional function but failed to induce pacemaker phenotypes. TBX18-expressing cells showed suppressed expression of key working myocardial genes, but the pacemaker gene program was not induced. Electrophysiological studies showed abnormal automaticity in TBX18-expressing cells, combined with prolonged repolarization and various current changes. However, no hyperpolarization-activated funny current was detected. In a complete AV-block rat model, AAV-mediated Hcn2 expression induced robust ectopic pacemaker activity in the presence of isoproterenol, whereas TBX18 expression neither generated such activity nor augmented Hcn2-mediated pacing. In conclusion, at functionally non-fibrogenic levels, TBX18 is neither sufficient nor necessary to induce pacemaker activity. In contrast, Hcn2 generates reliable pacing, making it a more viable candidate for biological pacemaker development.
Authors
Jianan Wang, Mathilde R. Rivaud, Mischa Klerk, Arie R. Boender, Ruud N. Visser, Rinske Sparrius, Hee Young Lee, Karel van Duijvenboden, Huiling Zhou, Yuting Yang, Emiel J.M. Kramer, Kyung Ho Park, Larry C. Park, Silke Schrödel, Christian Thirion, Eric Ehrke-Schulz, Anja Ehrhardt, Osne F. Kirzner, Klaus Neef, Hanno L. Tan, Arie O. Verkerk, Vincent M. Christoffels, Gerard J.J. Boink
Abstract
De novo heterozygous variants in CELF2 have recently been associated with a rare neurodevelopmental disorder, yet the mechanisms linking specific variants to distinct clinical phenotypes remain poorly understood. Here, we reported a cohort of 18 individuals and provided evidence that variants causing CELF2 mislocalization, but not protein-null variants, were associated with seizures. Using proband-derived human cortical neurons and transgenic mouse models, we demonstrated that CELF2 underwent activity-dependent nucleocytoplasmic shuttling in excitatory neurons and that its cytoplasmic retention caused neuronal hyperactivity, elevated seizure susceptibility, and learning and memory deficits. We further found that cytoplasmic CELF2 regulated mRNAs critical for synaptic function and neuronal excitability and implicated in epileptic seizures and intellectual disability. Drug screening further identified AKT signaling as a key regulator of CELF2 nucleocytoplasmic shuttling and a candidate target for reversing neuronal hyperactivity. Together, our findings expand the clinical and genetic spectrum of CELF2-related neurodevelopmental disorders and establish a variant-specific mechanism that links CELF2 mislocalization to neuronal hyperactivity, seizures, and cognitive impairment.
Authors
Michelle Hua, Mohamad-Reza Aghanoori, Melissa J. MacPherson, Yi Ren, Shehani V. Siripala, Yifan Yang, Yvonne Yan Yan Or, Malea Nguyen, Robert Duba-Kiss, Daniel Feng, Laura Williams, Christopher J. Gafuik, GengYi Wang, Chloe Quelin, Boris Keren, Sarah Schuhmann, Georgia Vasileiou, Alexia Bourgois, Antonio Vitobello, Christophe Philippe, Zornitza Stark, Richard J. Leventer, George McGillivray, Frederic Tran Mau-Them, Marine Tessarech, Clément Prouteau, Phillis Lakeman, Mahdi M. Motazacker, Donald R. Latner, Raymond C. Caylor, Yvette van Ierland, Eloise Prijoles, Angie Lichty, Evangelos Theodorou, David A. Sweetser, Edward Steel, Jan Cobben, Majed J. Dasouki, Daniel G. Calame, Bertrand Isidor, Benjamin Cogné, Mitchell Kesler, Brooke Rackel, Isabel Clark, Deborah M. Kurrasch, G. Campbell Teskey, James Ellis, Guiqiong He, Scott D. Ryan, Douglas J. Mahoney, A. Micheil Innes, Jonathan R. Epp, Guang Yang
Abstract
Chromatin remodeling is a dynamic epigenetic process that alters chromatin structure to gauge gene accessibility, enabling precise spatiotemporal gene expression, with disruptions often underlying neurodevelopmental disorders (NDDs), although the mechanistic underpinning remains incompletely understood. Despite essential roles in chromatin remodeling processes such as DNA methylation, and histone acetylation and deposition, DMAP1 has not been implicated in human disease. We identified 20 individuals from 16 families with a syndromic NDD carrying homozygous or compound heterozygous variants in DMAP1. Neural-specific knockdown of its Drosophila ortholog, dDMAP1, caused pupal lethality, structural defects in the mushroom body (MB), decreased dendrite length, abnormal social behavior and mechanical-induced seizures. Human reference DMAP1 could largely compensate for the loss of dDMAP1 in knockdown flies, whereas patient variants failed to restore or differentially rescued the phenotypes, confirming their pathogenicity with differing severity. Transcriptome profiling of dDMAP1 knockdown fly brains nominated Cbl and SF1 as downstream targets. Their overexpression rescued the aforementioned lethality and MB defects. Finally, a DNA methylation episignature was identified, leading to the molecular diagnosis of an additional patient. Our findings demonstrate that biallelic inactivating variants in DMAP1 cause a syndromic NDD, expanding the short list of recessive disease-causing genes within the epigenetic machinery.
Authors
Qin Wang, Andrew K. Sobering, Christian Tirrito, Sadegheh Haghshenas, Tina Duelund Hjortshøj, Konrad Platzer, Silke Redler, Michael E. March, Leticia S. Matsuoka, Hang Xi, Josiah Zoodsma, Yuanhua Chen, Mari Mori, Marco L. Leung, Nathalie Couque, Alain Verloes, Antoine Pouzet, Noor A.A. Giesbertz, Marleen E.H. Simon, Ashley K. Yearwood, Dominique L. Assing, Tzung-Chien Hsieh, Jing-Mei Li, Michael A. Levy, Jennifer Kerkhof, Haley McConkey, Jessica Rzasa, Carolyn Lauzon-Young, Raashda A. Sulaiman, Firdous Abdulwahab, Hanan E. Shamseldin, Naif A.M. Almontashiri, Manal Afqi, Vettaikorumakankav Vedanarayanan, Maria J. Guillen Sacoto, Ingrid M. Wentzensen, Nadirah S. Damseh, Rivka Birnbaum, Babeth van Ommeren, Saskia M.J. Hopman, Maha S. Zaki, Gehad Elmakkawy, Erum Afzal, JiHye Kim, Stephanie Efthymiou, Henry Houlden, Ambreen Nusrat, Mathias Toft, Uzma Abdullah, Zafar Iqbal, Shannon Terek, Fowzan S. Alkuraya, Elizabeth J. Bhoj, Reza Maroofian, Bekim Sadikovic, Hakon Hakonarson, Yuanquan Song, Dong Li
Abstract
Obesity is associated with impaired wound healing, but the mechanisms linking excess adiposity to aberrant tissue repair remain unresolved. Heterotopic ossification (HO) is a severe example of pathologic tissue repair in which mesenchymal progenitor cells (MPCs) undergo aberrant osteochondral differentiation within soft tissue, leading to joint contractures and pain. Here, we show that accumulation of dietary omega-6 (ω-6) lipids in the injury site is a key mechanism linking obesity to HO. Specifically, in mice fed a high-fat diet (HFD), injured tissues were enriched in linoleic and arachidonic acids, providing substrate for myeloid cyclooxygenase-2 (COX-2)-dependent prostaglandin E2 (PGE2) production. PGE2 then drove a transcriptional program in mesenchymal progenitor cells that promoted osteochondral differentiation. An isocaloric, low linoleic acid HFD reduced HO despite comparable obesity, demonstrating that dietary lipid composition, rather than adiposity alone, drove pathological repair. Clinical data mirrored these findings, showing that obesity conferred increased HO risk, and COX-2 inhibition reduced HO exclusively in obese patients. Together, these findings identify injury site ω-6 lipid enrichment as the key signal linking the diet to MPC reprogramming, pointing to dietary lipid modulation as an actionable strategy to limit HO in obesity.
Authors
Stefanie L. Moye, Monisha Mittal, Tarun Srinivasan, Sneha Korlakunta, Chase A. Pagani, Ayelet Dar, Oromo Geshow, Dylan Feist, Lauren G. Zacharias, Zhao Li, Aaron W. James, Gerta Hoxhaj, Andrew M. Smith, Katherine A. Gallagher, Thomas P. Mathews, Robert J. Tower, Benjamin Levi
Abstract
Enhanced TGFβ signaling caused by mutations in Fibrillin-1 (FBN1) in patients with Marfan syndrome (MFS) leads to myxomatous degeneration of the mitral valve (MDMV). MDMV can result in mitral valve prolapse, severe regurgitation, and sudden cardiac death. However, it remains unknown whether lymphatic vessel (LV) dysfunction contributes to MDMV development in MFS. Here, we show that lymphangiogenesis in murine mitral valves (MVs) begins postnatally. However, this process is inhibited in a mouse MFS model, Fbn1 mutant (Fbn1C1039G/+) mice, accompanied by disrupted lymphatic cell-cell junctions, impaired lymphatic drainage, and an abnormally widespread distribution of MHCII+ infiltrating macrophages. Treatment of Fbn1 mutant mice with VEGF-C156S, a selective VEGFR3 agonist, stimulates the ERK and Akt pathways, increases LV density in MVs, and ameliorates MDMV. Fbn1 mutant MVs display disorganized valvular endothelial cells (VECs) and decreased expression of the anti-inflammatory modulator Zfp36 (zinc finger protein 36) in VECs and immune cells. Treatment with FTY720 (Fingolimod), a ZFP36 activator and S1P antagonist, rescues MDMV phenotypes in Fbn1 mutant mice by reducing immune cell infiltration and restoring lymphatic cell junctions and drainage. These findings suggest that the Fbn1 mutation causes LV hypoplasia and defective lymphatic drainage in MVs, driven in part by pro-inflammatory VECs, leading to MFS-related MDMV.
Authors
Can Tan, Ziyou Ren, Shreya Kurup, Xianpeng Liu, Zhi-Dong Ge, Shodai Suzuki, Pritika Jakka, Cheryl Tang, M. Luisa Iruela-Arispe, Tsutomu Kume
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Series edited by Alexander Stegh
The cGAS-STING pathway: DNA sensing in health and disease
Series edited by Alexander Stegh
The cyclic GMP-AMP synthase (cGAS)–stimulator of interferon genes (STING) pathway is a key component of innate immunity, linking DNA detection to inflammatory and antiviral responses. Originally identified as a sensor for microbial DNA, cGAS is now understood to also respond to endogenous cytosolic DNA, and the pathway has been implicated in a wide range of physiological and pathological processes, including cancer, autoimmunity, neuroinflammation, and aging. This review series, organized by Dr. Alex Stegh, consolidates current knowledge and highlights emerging developments that may lead to therapeutic targeting of the cGAS-STING pathway across a range of disorders.
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ISSN: 0021-9738 (print), 1558-8238 (online)