Neuroscience
Abstract
Cuproptosis involves accumulation of intracellular copper that triggers mitochondrial lipoylated protein aggregation and destabilization of iron–sulfur cluster proteins, leading to cell death. Pharmacologic induction of cuproptosis has been proposed as a cancer therapy. Here, we find that glioblastoma (GBM) stem cells (GSCs) displayed relative resistance to cuproptosis with circadian variation of intracellular copper levels. CRISPR screening of copper regulators under concurrent treatment with copper ionophore or clock disruption revealed dependency on ATPase copper transporting alpha (ATP7A). Circadian control of copper homeostasis was mediated by the core clock transcription factor, brain and muscle ARNT-like 1 (BMAL1). In turn, ATP7A promoted tumor cell growth through regulation of fatty acid desaturation. Copper levels negatively fed back into the circadian circuitry through sequestosome 1/p62–mediated lysosomal degradation of BMAL1. Targeting the circadian clock or fatty acid desaturation augmented cuproptosis antitumor effects. Crosstalk between the core circadian clock and copper sustains GSCs, reshaping fatty acid metabolism and promoting drug resistance, which may inform development of combination therapies for GBM.
Authors
Fanen Yuan, Xujia Wu, Huairui Yuan, Donghai Wang, Tengfei Huang, Po Zhang, Hailong Mi, Weichi Wu, Suchet Taori, Priscilla Chan, Kenji Miki, Maged T. Ghoche, Linjie Zhao, Kalil G. Abdullah, Steve A. Kay, Qiulian Wu, Jeremy N. Rich
Abstract
Neuromyelitis optica (NMO) is an autoimmune disorder characterized by autoantibodies against the astrocyte water channel aquaporin-4 (AQP4) that cause demyelination in the optic nerves and spinal cord. How astrocytopathy leads to myelination deficits remains unclear. Chitinase-3–like protein 1 (CHI3L1, also known as YKL-40) is predominantly secreted by activated astrocytes, serves as a robust NMO biomarker, and plays a role in immune responses, but how it is induced and shapes astrocyte activation in NMO is not well defined. Using ex vivo and in vivo NMO mouse models together with mice with astrocyte-specific CHI3L1 knockout, we demonstrated that CHI3L1 directly contributed to demyelinating lesions elicited by AQP4 autoantibody–activated astrocytes. With complementary in vitro assays and inducible transgenic lines, we uncovered an astrocyte-intrinsic cascade in which AQP4 autoantibody exposure activated STAT3, which in turn drove CHI3L1 expression and secretion. Secreted CHI3L1 then engaged the astrocytic receptor RAGE in an autocrine manner, activating downstream NF-κB signaling that drove proinflammatory gliosis and damaged myelination. Pharmacological blockade of this pathway in NMO models rescued demyelinating pathology and improved motor function. These findings reveal an astrocyte-intrinsic CHI3L1 pathway that contributed to demyelination in NMO and identify actionable therapeutic targets.
Authors
Huiming Xu, Wei Jiang, Li Xu, Haoyang Li, Xin Yang, Fan Zhu, Pengyan He, Yanna Song, Yuhan Li, Yu-Wen Alvin Huang, Wei Qiu, Changyong Tang
Abstract
Mutations in DNA mismatch repair (MMR) pathway genes (MSH2, MSH6, MLH1, and PMS2) are linked to acquired resistance to temozolomide (TMZ) and high tumor mutation burden (TMB) in high-grade gliomas (HGG), including glioblastoma (GBM). However, the specific roles of individual MMR genes in the initiation, progression, TMB, microsatellite instability (MSI), and resistance to TMZ in glioma remain unclear. Here, we developed de novo mouse models of germline and somatic MMR-deficient (MMRd) HGG. Surprisingly, loss of Msh2 or Msh6 does not lead to high TMB, MSI, nor confer response to anti-PD-1 in GBM. Similarly, human GBM shows discordance between MMR gene mutations and TMB/MSI.Germline MMRd leads to promoted progression from low-grade to HGG and reduced survival compared to MMR-proficient (MMRp) tumor-bearing mice. This effect is not tumor cell intrinsic but is associated with MMRd in the tumor immune microenvironment, driving immunosuppressive myeloid programs, reduced lymphoid infiltration, and CD8+ T cell exhaustion. Both MMR-reduced (MMRr) and MMRd GBM are resistant to temozolomide (TMZ), unlike MMRp tumors. Our study shows that KL-50, a imidazotetrazine-based DNA targeting agent inducing MMR-independent cross-link–mediated cytotoxicity, was effective against germline and somatic MMRr/MMRd GBM, offering a potential therapy for TMZ-resistant HGG with MMR alterations.
Authors
Montserrat Puigdelloses Vallcorba, Nishant Soni, Seung-Won Choi, Kavita Rawat, Tanvi Joshi, Sam Friedman, Alice Buonfiglioli, Angelo Angione, Zhihong Chen, Gonzalo Piñero, Gabrielle Price, Mehek Dedhia, Raina Roche, Emir Radkevich, Anne M. Bowcock, Deepti Bhatt, Winfried Edelmann, Robert M. Samstein, Timothy E. Richardson, Nadejda M. Tsankova, Alexander M. Tsankov, Ranjit S. Bindra, Raul Rabadan, Juan C. Vasquez, Dolores Hambardzumyan
Abstract
BACKGROUND. Axonal degeneration is believed to be an early hallmark of Alzheimer’s disease (AD). This study investigated the temporal trajectory of axonal loss and its association with cognitive and functional decline using diffusion MRI-derived Axonal Density Index (dMRI-ADI). METHODS. Longitudinal dMRI, CSF and PET data from the ADNI were analyzed, including 117 cognitively normal (CN) and 88 impaired (CI) subjects, consisting of 74 mild cognitive impairment (MCI) and 14 AD individuals. Linear mixed-effects models examined group differences as well as associations between baseline and longitudinal changes in ADI, CSF or PET biomarkers and clinical outcomes. Results derived from larger CSF (n=527) and PET (tau-PET: n=870; amyloid-PET: n=1581) data were also presented. RESULTS. Compared to CN, the CI group exhibited significantly lower baseline ADI values and steeper longitudinal decline (p<10–⁶). Lower baseline ADI predicted faster cognitive and functional decline in the CI group (MMSE: p=0.03; CDR-SB: p<10–⁴), and longitudinal decreases in ADI were associated with worsening clinical outcomes (MMSE: p=0.001; CDR-SB: p<10–¹²). Compared to CSF and PET biomarkers, ADI demonstrated superior sensitivity in tracking disease progression and matched these biomarkers in predicting future cognitive and functional decline. Furthermore, decreases in ADI were significantly associated with declines in clinical outcomes; an association observed only with amyloid-PET, but not CSF biomarkers. CONCLUSION. Axonal degeneration is an early and clinically meaningful feature of AD. ADI is a promising noninvasive biomarker for early detection, prognosis, and disease monitoring. TRIAL REGISTRATION. ClinicalTrials.gov NCT00106899. FUNDING. This work was supported by the National Institute on Aging IRP.
Authors
Zhaoyuan Gong, John P. Laporte, Alexander Y. Guo, Murat Bilgel, Jonghyun Bae, Noam Y. Fox, Angelique de Rouen, Nathan Zhang, Aaliya Taranath, Rafael de Cabo, Josephine M. Egan, Luigi Ferrucci, Mustapha Bouhrara
Abstract
Epstein-Barr virus (EBV) is of growing interest for its potential role in neurodegenerative diseases such as multiple sclerosis (MS) and its possible utility as a therapeutic target in herpesvirus-associated chronic diseases. The effects of brincidofovir (BCV) on EBV reactivation were evaluated in vitro using EBV-infected spontaneous lymphoblastoid cell lines (SLCLs) and peripheral blood mononuclear cells (PBMCs) derived from MS patients and healthy controls. In addition, a B lymphoblastoid cell line and PBMCs from common marmosets (Callithrix jacchus) naturally infected with an EBV-related gammaherpesvirus (Callitrichine herpesvirus 3, CalHV-3) were used to measure BCV efficacy in a nonhuman primate model. BCV significantly inhibited gammaherpesvirus reactivation, with decreased lytic and latent viral transcript expression. These results suggest that BCV may be a useful antiviral for inhibiting EBV activity in MS patients. Additionally, this work further validates the utility of CalHV-3 in marmosets as a translational model for the investigation of successful EBV-targeting therapeutics.
Authors
Abaigeal Donaldson, Madeleine R. Druker, Maria Chiara Monaco, Emily H. Stack, Paige Zimmerman, Amanda Lee, Izabela Bialuk, William Frazier, Irene Cortese, Heather Narver, Masatoshi Hazama, Fuminori Yoshida, Xiaofan Li, Laurie T. Krug, Stacey L. Piotrowski, Steven Jacobson
Abstract
Authors
Antonio Carlos Tallon-Cobos, Konstantinos Vazaios, Piotr Waranecki, Marliek van Hoesel, Annelisa M. Cornel, Benjamin Schwalm, Norman Mack, Ella de Boed, Jasper van der Lugt, Stefan Nierkens, Marcel Kool, Eelco W. Hoving, Dennis S. Metselaar, Esther Hulleman
Abstract
Disorders of GABRA3, the only epilepsy-associated GABA-A receptor subunit gene on the X chromosome, have eluded clinical clarity due to ambiguous inheritance patterns and variable phenotypes. The long-standing assumption that all pathogenic variants cause loss-of-function further obscured genotype-phenotype relationships and hindered progress. Here, we curated a cohort of individuals with a GABRA3 variant, integrating deep phenotyping, genotyping, family history, electrophysiology, with a targeted mouse model. Among 43 individuals with 19 GABRA3 variants, functional analyses revealed both gain- and loss-of-function effects, each linked to distinct clinical profiles. Gain-of-function variants were associated with severe, treatment-resistant epilepsy and severe-profound intellectual disability, disproportionately affecting males, who were often non-ambulant and had cortical visual impairment. Loss-of-function variants produced milder phenotypes, with epilepsy rarely observed; affected males showed behavioural issues and language delay, while females were unaffected carriers. Our gain-of-function (Gabra3Q242L/+) mouse model mirrored these sex-specific differences, showing increased seizure susceptibility, early death, and marked cortical hyperexcitability. These insights not only resolve longstanding uncertainties surrounding GABRA3 but also redefine how X-linked disorders are interpreted. They demonstrate that it is the functional impact of a variant, not its mere presence, that determines whether a condition manifests dominantly or recessively. This distinction carries important implications for genetic counselling, precision medicine, and the broader interpretation of X-linked neurodevelopmental disorders.
Authors
Katrine M. Johannesen, Khaing Phyu Aung, Vivian W.Y. Liao, Nathan L. Absalom, Han C. Chua, Xue N. Gan, Miaomiao Mao, Chaseley E. McKenzie, Hian M. Lee, Sebastian Ortiz, Rebecca C. Spillmann, Vandana Shashi, Rodney A. Radtke, Ghayda M. Mirzaa, P. Anne Weisner, Josue Flores Daboub, Caroline Hagedorn, Pinar Bayrak-Toydemir, Desiree DeMille, Jian Zhao, Nandita Bajaj, Yline Capri, Boris Keren, Miriam Schmidts, Ingrid M.B.H. van de Laar, Marjon A. van Slegtenhorst, Rafal Ploski, Marta Bogotko, Danielle K. Bourque, Ebba Alkhunaizi, Lauren Chad, Nada Quercia, Houda Elloumi, Ingrid M. Wentzensen, Michael C. Kruer, Pritha Bisarad, Carolina I. Galaz-Montoya, Violeta Rusu, Dominique Braun, Katie Angione, Jessica C. Win, Camilo Espinosa-Jovel, Pia Zacher, Konrad Platzer, Samuel F. Berkovic, Ingrid E. Scheffer, Mary Chebib, Guido Rubboli, Rikke S. Møller, Christopher A. Reid, Philip K. Ahring
Abstract
Demyelination associated microglia (DMAM) orchestrate the regenerative response to demyelination by clearing myelin debris and promoting oligodendrocyte maturation. Peroxisomal metabolism has emerged as a candidate regulator of DMAMs, though the cell-intrinsic contribution in microglia remains undefined. Here we elucidate the role of peroxisome integrity in DMAMs using cuprizone mediated demyelination coupled with conditional knockout of peroxisome biogenesis factor 5 (PEX5) in microglia. Absent demyelination, PEX5 conditional knockout (PEX5cKO) had minimal impact on homeostatic microglia. However, during cuprizone-induced demyelination, the emergence of DMAMs unmasked a critical requirement for peroxisome integrity. At peak demyelination, PEX5cKO DMAMs exhibited increased lipid droplet burden and reduced lipophagy suggestive of impaired lipid catabolism. Although lipid droplet burden declined during the remyelination phase, PEX5cKO DMAMs accumulated intralysosomal crystals and curvilinear profiles, which features were largely absent in controls. Aberrant lipid processing was accompanied by elevated lysosomal damage markers and downregulation of the lipid exporter gene Apoe, consistent with defective lipid clearance. Furthermore, the disruptions in PEX5cKO DMAMs were associated with defective myelin debris clearance and impaired remyelination. Together, these findings delineate a stage-specific role for peroxisomes in coordinating lipid processing pathways essential to DMAM function and necessary for enabling a pro-remyelinating environment.
Authors
Joseph A. Barnes-Vélez, Xiaohong Zhang, Yaren L. Peña Señeriz, Kiersten A. Scott, Yinglu Guan, Jian Hu
Abstract
BACKGROUND. Amyotrophic lateral sclerosis (ALS), the major adult-onset motor neuron disease, is preceded by an early period unrelated to motor symptoms, including altered sleep, with increased wakefulness and decreased deep NREM. Whether these alterations in sleep macroarchitecture are associated with, or even precede abnormalities in sleep-related EEG features remains unknown. METHODS. Here, we characterised sleep microarchitecture using polysomnography in patients with ALS (n=33) and controls (n=32), and in asymptomatic carriers of SOD1 or C9ORF72 mutations (n=57) and non-carrier controls (n=30). Patients and controls with factors that could confound sleep structure, including respiratory insufficiency, were prospectively excluded. Results were complemented in three ALS mouse models (Sod1G86R , Fus∆NLS/+ and TDP-43Q331K ). RESULTS. We observed a brain-wide reduction in the density of sleep spindles, slow oscillations and K-complexes in both early-stage ALS patients and presymptomatic gene carriers. These defects in sleep spindles and slow oscillations correlate with cognitive performance in both cohorts, particularly with scores on memory, verbal fluency and language function. Alterations in sleep microarchitecture were replicated in three mouse models and decreases in sleep spindles were rescued following intracerebroventricular supplementation of MCH or by the oral administration of a dual orexin receptor antagonist. CONCLUSION. Sleep microarchitecture is associated with cognitive deficits and is causally linked to aberrant MCH and orexin signalling in ALS. FUNDING. This work was funded by Agence Nationale de la Recherche (ANR-24-CE37-4064, ANR-10-IDEX-0002, ANR-20-SFRI-0012), Fondation Thierry Latran, Association Francaise de Recherche sur la sclérose latérale amyotrophique, Association Française contre les Myopathies (#28944), TargetALS and JPND.
Authors
Christina Lang, Simon J. Guillot, Dorothee Lule, Luisa T. Balz, Antje Knehr, Patrick Weydt, Johannes Dorst, Katharina Kandler, Hans-Peter Müller, Jan Kassubek, Laura Wassermann, Sandrine Da Cruz, Francesco Roselli, Albert C. Ludolph, Matei Bolborea, Luc Dupuis
Abstract
The increased prevalence of GluA2-lacking, Ca2+-permeable AMPA receptors (CP-AMPARs) at spinal cord sensory synapses amplifies nociceptive transmission and maintains chronic neuropathic pain. Nerve injury–induced upregulation of α2δ-1 disrupts the assembly of GluA1/GluA2 heteromers, favoring the synaptic incorporation of GluA1 homotetramers in the spinal dorsal horn. Although GluA1-GluA3 subunits are broadly expressed, whether α2δ-1 regulates GluA3-containing AMPARs remains unknown. Here, we unexpectedly found that coexpression with α2δ-1—but not α2δ-2 or α2δ-3—diminished GluA3 AMPAR currents and protein levels, an effect blocked by pregabalin, an α2δ-1 C-terminus peptide, or proteasome inhibition. Both nerve injury and α2δ-1 overexpression reduced protein levels of GluA3 and GluA2/GluA3 heteromers in the spinal cord. Furthermore, α2δ-1 coexpression or nerve injury increased GluA3 ubiquitination, with Lys-861 at the C terminus of GluA3 identified as a key ubiquitination site mediating α2δ-1–induced GluA3 degradation. Additionally, intrathecal delivery of the Gria3 gene reversed nerve injury–induced nociceptive hypersensitivity and synaptic CP-AMPARs by restoring protein levels of GluA3 and GluA2/GluA3 heteromers in the spinal cord. These findings reveal that α2δ-1 promotes GluA1 homotetramer assembly and synaptic CP-AMPAR expression by driving ubiquitin-proteasomal degradation of GluA3, providing insights into the molecular mechanisms of neuropathic pain and the therapeutic actions of gabapentinoids.
Authors
Meng-Hua Zhou, Shao-Rui Chen, Daozhong Jin, Yuying Huang, Hong Chen, Guanxing Chen, Jiusheng Yan, Hui-Lin Pan
Copyright © 2025 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)