Hua et al. report that pathogenic variants in the RNA-binding protein CELF2 are associated with at least two distinct neurodevelopmental disorders. The cover image, inspired by the yin-yang principle of interconnected and complementary forces, illustrates the dynamic shuttling of CELF2 between the nucleus and cytoplasm. The two cellular states represent distinct yet interdependent functions of CELF2 that are normally balanced through nucleocytoplasmic transport. The boundary between the domains symbolizes this dynamic equilibrium, while the shift toward cytoplasmic localization reflects the pathological disruption of CELF2 shuttling observed in a newly identified neurodevelopmental disorder characterized by neuronal hyperactivity and seizures. Cover art generated using ChatGPT (OpenAI) based on representative microscopy from the study.
Defective endometrial decidualization is one major cause of female infertility, yet the underlying mechanisms remain elusive. Here, we identified that protein arginine methyltransferase 5 (PRMT5) which was upregulated during decidualization and by progesterone stimulation, is markedly down-regulated in the endometria of patients with recurrent implantation failure (RIF), along with a global reduction of symmetric dimethylarginine (sDMA). Uterine stromal-specific ablation of Prmt5 in mouse severely impaired decidualization leading to infertility. A multi‑omics analysis in human endometrial stromal cells (EnSCs) revealed that PRMT5 promoted decidualization primarily by catalyzing sDMA at arginine 346 (R346) of the orphan nuclear receptor Nur77, which directs its proper chromatin occupancy. Targeting the PRMT5-Nur77 methylation axis, we designed a peptide, Pep‑Nur77-R346K, which rescued the decidualization of multiple preclinical models: PRMT5 deficient human EnSCs, both genetic knockout (Prmt5d/d) and pharmacologically inhibited mouse models, an estrogen deficient mouse model, and, more importantly, the primary RIF EnSCs. In a retrospective cohort of 114 participants, the correlated reductions of endometrial PRMT5/Nur77-R346me2s was confirmed, which demonstrated robust predictive value for pregnancy outcome. Our work establishes the PRMT5‑Nur77 methylation axis as a key regulator of endometrial receptivity, and highlights both a novel diagnostic biomarker and a peptide‑based therapeutic potential for fertility.
Zhiwen Cao, Xinyu Cai, Jie Mei, Na Kong, Yang Liu, Xiaoyue Shen, Min Wu, Xin Zhen, Jianxin Sun, Rong Li, Ruiwei Jiang, Haixiang Sun, Guijun Yan
Epilepsy affects approximately 50 million people worldwide, yet more than half of individuals with a presumed genetic cause still lack a molecular diagnosis despite the identification of over 1,000 monogenic epilepsy genes. This diagnostic gap is unlikely to be resolved by improved variant detection alone, suggesting that variants affecting the same biological pathway may combine to cause disease. By studying epilepsy-associated actin regulatory genes, we identified a conserved “actin-mitochondria-glutamate (AMG) pathway”. We demonstrate that reduced actin polymerization promotes DRP1-mediated mitochondrial fission, increases reactive oxygen species (ROS) levels, and enhances glutamatergic transmission, leading to seizures. The glial innate immune pathway, a recently recognized contributor to epilepsy, is activated when the AMG pathway is affected. Reducing mitochondrial fission with the DRP1 inhibitor Mdivi-1, or suppressing ROS with N-acetyl-L-cysteine amide (NACA), significantly alleviates seizures. Importantly, digenic heterozygous loss‑of‑function variants in AMG‑pathway genes combine to cause seizures, and individuals with epilepsy of unknown etiology show an increased burden of such variants when compared to the controls. Modeling patient‑specific digenic combinations in Drosophila confirms that many combinations promote seizure susceptibility. Together, these findings establish the AMG pathway as a mechanistic framework for identifying digenic etiologies in epilepsy and highlight potential therapeutic targets.
Shenzhao Lu, Mengqi Ma, Shabab B. Hannan, Mingxi Deng, Hu Chen, Zhijian Yu, Lindsey D. Goodman, Haein Kim, Yun Zhao, Sandeep Kumar Dubey, Wen-Wen Lin, Xueyang Pan, Debdeep Dutta, Vishnu Anand Cuddapah, Jill A. Rosenfeld, Xi Luo, Zhandong Liu, Joshua M. Shulman, Hugo J. Bellen
Hepatic stellate cell (HSC) activation can lead to liver fibrosis, for which there are no effective treatments. Aberrant cytoskeletal reorganization is a central driver of HSC activation. Non-muscle myosin II (NM II) is known to regulate cytoskeleton remodeling via its actin cross-linking and contractile properties. However, the molecular players controlling actomyosin assembly and contractility in HSCs during liver fibrosis remain poorly defined. Here, we identified integrin β-like 1 (ITGBL1) as a gatekeeper of HSC quiescence by negatively regulating actomyosin contractility-driven mechanotransduction in HSCs. ITGBL1 expression was markedly elevated in activated HSCs found in patient and mouse fibrotic livers. Unexpectedly, HSC-specific Itgbl1 deficiency worsened liver fibrosis, whereas ITGBL1 overexpression in HSCs limited it, suggesting a protective role for ITGBL1 against a pathogenic HSC activation. Multi-omics and functional analyses revealed that ITGBL1 impaired F-actin filament organization in HSCs by disrupting myosin heavy chain 9 (MYH9, also named NM II heavy chain A)-dependent actomyosin assembly. In line, HSC-specific Myh9 deficiency or silencing of Myh9 in HSCs alleviated liver fibrosis. Taken together, our findings unveil the ITGBL1-MYH9 interaction acts as a critical mechano-regulatory brake that maintains cytoskeletal equilibrium and mechanical homeostasis in HSCs, providing a promising therapeutic strategy to combat liver fibrosis.
Yixin Li, Yan Wang, Chenhao Tong, Xinghuan Fu, Ningning Ma, Yawen Hao, Zian Feng, Shijia Ling, Zequn Yin, Haodong Li, Shujun Ge, Siting Yang, Peng Xiao, Siyue Dong, Adrien Guillot, Yajun Duan, Yong He
Opioids are essential analgesics for managing severe pain but can paradoxically increase pain sensitivity (hyperalgesia) and diminish analgesic efficacy (tolerance). Hyperactivity of NMDA-type glutamate receptors (NMDARs) at primary afferent terminals in the spinal cord contributes to both phenomena; however, the underlying signaling mechanisms remain unclear. Here, we report that morphine administration in rats promoted the translocation of monomeric BRAF, an oncogenic kinase, from the dorsal root ganglion (DRG) to spinal cord synaptosomes, leading to increased MEK-ERK phosphorylation at nociceptor central terminals. BRAF physically interacted with NMDARs in both rat and human spinal cords. Inhibition of BRAF activity with vemurafenib reversed morphine-induced NMDAR phosphorylation and synaptic localization of α2δ-1–bound NMDARs. Vemurafenib also abolished morphine-induced presynaptic NMDAR hyperactivity in spinal dorsal horn neurons. Correspondingly, conditional Braf knockout in DRG neurons normalized morphine-enhanced NMDAR phosphorylation, synaptic trafficking of α2δ-1–bound NMDARs, and NMDAR hyperactivity in the spinal cord. Furthermore, pharmacological inhibition of BRAF or MEK, or Braf deletion in DRG neurons, enhanced morphine analgesia while mitigated morphine-induced hyperalgesia and tolerance. These findings identify BRAF overactivity at nociceptor central terminals as a key mediator of opioid-induced NMDAR hyperactivity. Clinically approved BRAF inhibitors could be repurposed to enhance opioid analgesia while minimizing adverse effects.
Daozhong Jin, Hong Chen, Yuying Huang, Shao-Rui Chen, Hui-Lin Pan
Systemic lupus erythematosus (SLE) is an autoimmune disease characterized by autoantibody production. Extrafollicular (EF) B cell responses contribute to SLE pathogenesis, with age-associated B cells (ABCs) giving rise to autoantibody-secreting plasmablasts (PBs). However, the migratory cues governing this EF trajectory remain unclear. Here, we identify a distinct ABC state with PB precursor characteristics (pre-PB ABCs) and reveal a migration-dependent program underlying their generation. Single-cell analysis of SLE patients and model mice showed that pre-PB ABCs were enriched in autoreactive clones and poised for PB differentiation. Their frequency correlated with autoantibody titers and disease activity, underscoring their pathogenic relevance. We further demonstrated that the oxysterol receptor EBI2 directed ABCs to EF niches within splenic bridging channels, promoting pre-PB ABC formation and autoreactive PB output. This process depended on the COMMD3/8 complex, a positive regulator of chemoattractant receptor signaling. Beyond EBI2-mediated ABC migration to EF niches, the COMMD3/8 complex was also required for trafficking of autoantibody-secreting cells to the bone marrow and infiltration of ABCs into the kidney. Accordingly, COMMD3/8 complex inhibition ameliorated disease in murine SLE models. These findings define a migration-dependent mechanism driving the EF differentiation of ABCs into autoreactive PBs and shaping the tissue distribution of pathogenic B cells, highlighting this program as a potential therapeutic target in SLE.
Taiichiro Shirai, Kentaro Kuzuya, Mizuki Kishi, Shinya Ichikawa, Shuhei Sakakibara, Akiko Nakai, Sarah Leach, Yu-Chen Liu, Daisuke Motooka, Daisuke Okuzaki, Masashi Narazaki, Atsushi Kumanogoh, Tomohiro Kurosaki, Jun Saegusa, Kazuhiro Suzuki
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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