bims-medebr Biomed News
on Metabolism of the developing brain
Issue of 2026–04–12
27 papers selected by
Regina F. Fernández, Johns Hopkins University
  1. Exploring brain glucose metabolism in multiple sclerosis: A deuterium metabolic imaging study.
  2. Temporal Requirement for Stearoyl-CoA Desaturase-1 in Oligodendrocyte Development but Not Myelin Maintenance.
  3. Brain DHA increases in APOE3, but not in APOE4 mice, despite robust brain EPA increase during LPC n-3 supplementation in both genotypes.
  4. Astrocytic glucose metabolism regulates the survival of newborn hippocampal neurons in the adult brain.
  5. Deep profiling of porcine brain gangliosides enabled by TiO2 magnetic nanoparticle-based enrichment and advanced lipidomic analysis.
  6. APOE4 Accelerates Menopause-Associated Brain Metabolic Shift and Disrupts Bioenergetic Adaptation.
  7. Cerebrospinal fluid CEFA composition is enriched in saturated fatty acids and it is altered in Alzheimer's Disease.
  8. Potential crosstalk between Parkinson's disease and glucose metabolism.
  9. Lipid droplets in neurodegenerative diseases: pathological drivers and therapeutic vulnerabilities.
  10. Lactate, an underestimated molecule in nerve regeneration.
  11. TOMM40 suppression promotes neuronal cholesterol imbalance and molecular and behavioral phenotypes of Alzheimer's disease.
  12. Nervonic acid supplementation mitigates disease severity biomarkers in adrenoleukodystrophy.
  13. Tanycyte-derived lactate activates astrocytic HCAR1 to modulate glutamatergic signaling and POMC neuron excitability.
  14. Protein lactylation in Alzheimer's disease: bridging metabolism, pathology, and therapeutic opportunity.
  15. Astrocytic K+ regulation during neurodegenerative diseases.
  16. Mitochondrial dysfunction in neonatal brain injury: from molecular mechanisms to therapeutic interventions.
  17. Simian Immunodeficiency Virus and Antiretroviral Therapy Impact Rhesus Macaque Brain Lipid Distribution.
  18. Discovery of the First Brain-Penetrant Radioligands for Visualizing the GABA Transporter 1 (GAT-1): Synthesis, In Vitro Screening, and In Vivo Evaluation in Nonhuman Primates.
  19. Exploring lipid metabolism reprogramming in meningiomas through lipidomics of matched clinical specimens.
  20. Pathophysiological pathways in mild traumatic brain injury.
  21. Single-Cell Metabolic Profiling in a Glioblastoma Coculture Model Using AP-MALDI-Based Mass Spectrometry Imaging.
  22. Neuroinflammatory stress preferentially impacts synaptic MAPK signaling and mitochondria in excitatory neurons.
  23. Altered lipid profile in mice lacking the DNA repair protein ERCC1.
  24. Elovanoid neuroprotection targets cell transcriptomics and proteomics to sustain synaptic integrity after brain injury.
  25. Ceramide-rich extracellular vesicles as pathogenic biomarkers in traumatic brain injury.
  26. Unveiling the "Glycolysis-Lactate-Lactylation" Axis: A Novel Target in Ischemic Cerebrovascular Disease.
  27. Mitochondrial dysfunction in Alzheimer's disease and related sex differences.
  1. J Cereb Blood Flow Metab. 2026 Apr 04. 271678X261437569
    Exploring brain glucose metabolism in multiple sclerosis: A deuterium metabolic imaging study.
    Alixander S Khan, Kamilla Kørup Trosborg, Michael Vaeggemose, Tobias Gaemelke, Esben S S Hansen, Nichlas Vous Christensen, Jack J Miller, Rolf F Schulte, Caroline Winther Tørring, Ulrik Dalgas, Lars G Hvid, Christoffer Laustsen.
      Axonal demyelination is a key feature in multiple sclerosis (MS), that is, increasingly linked to a state of energetic failure, however current non-invasive methods to probe downstream metabolic changes are lacking. This study aimed to investigate Deuterium Metabolic Imaging (DMI) to measure alterations in glucose metabolism in MS compared to healthy controls (HC). In this prospective study DMI was performed on eight patients with relapsing-remitting MS (RRMS) together with eight age- and sex-matched HC. Following oral administration of [6,6'-2H2] glucose, DMI was acquired on 3 T MRI to quantify the metabolic conversion of glucose (Glc) into glutamate and glutamine (Glx) and lactate. White matter (WM) oxidative metabolism (2H-Glx/2H-Water), showed a negative correlation with the Expanded Disability Status Scale score (EDSS) (Pearson r = -0.71, p = 0.049). Glucose (2H-Glc/2H-Water), remained unchanged across EDSS (Pearson r = -0.13, p = 0.76). Impaired glucose levels and oxidative metabolism in WM correlated negatively with increased number of T2-FLAIR lesions (Pearson r = -0.86 to -0.83, respectively). These in vivo findings provide evidence for a relative failure of oxidative energy production within the WM of RRMS compared to HC offering proof of concept that DMI is a feasible tool for measuring neurodegeneration related metabolic changes.
    Keywords:  MR spectroscopy; MRI; Metabolism; X-nuclei; multiple sclerosis
    DOI:  https://doi.org/10.1177/0271678X261437569
  2. J Neurosci. 2026 Apr 07. pii: e1881252026. [Epub ahead of print]
    Temporal Requirement for Stearoyl-CoA Desaturase-1 in Oligodendrocyte Development but Not Myelin Maintenance.
    Iris Farnum, Thaddeus J Kunkel, Adam M Coombs, Ben Emery, Manideep Chavali.
      Stearoyl-CoA Desaturase 1 (Scd1) is a rate-limiting enzyme in monounsaturated fatty acid synthesis, which is crucial for membrane biosynthesis. Here we show an early requirement for Scd1 in oligodendroglial cells during developmental myelination. Using oligodendrocyte progenitor cell (OPC) specific conditional knockout mouse model of Scd1, we observed a myelination delay during CNS development in both male and female mice. Genetic ablation of OPC-specific Scd1 resulted in oligodendrocyte maturation delay and hypomyelination within forebrain white matter tracts and optic nerve. Interestingly, although expressed at high levels within the mature oligodendrocytes, Scd1 was dispensable in maintenance of oligodendrocytes and axonal myelination, as loss of mature oligodendrocyte specific Scd1 showed no effect on myelin maintenance or oligodendrocyte survival. Together, our results suggest that Scd1 function is temporally restricted to the developmental period when oligodendrocytes undergo differentiation and active myelination but becomes dispensable for maintaining established myelin.Significance Statement Oligodendroglial cells generate lipid rich myelin cell membrane to ensheath axons during brain development. The metabolic pathways that support this initial myelin production, and how the myelin is maintained across lifespan, remain unclear. Using stage-specific cell deletion, we demonstrate that stearoyl-CoA desaturase 1 (SCD1), a key enzyme in monounsaturated fatty acid synthesis, is essential for oligodendrocyte differentiation and developmental myelination, but becomes dispensable for myelin maintenance. This temporal requirement for Scd1 reveals that developing and mature oligodendrocytes have fundamentally different metabolic requirements. Our findings have important implications for identifying the developmental stages most critical for designing treatments for demyelinating disorders.
    DOI:  https://doi.org/10.1523/JNEUROSCI.1881-25.2026
  3. J Nutr Biochem. 2026 Apr 08. pii: S0955-2863(26)00118-X. [Epub ahead of print] 110376
    Brain DHA increases in APOE3, but not in APOE4 mice, despite robust brain EPA increase during LPC n-3 supplementation in both genotypes.
    Bijou Andriambelo, Annick Vachon, Marc-André Dansereau, Élizabeth Dumais, Nicolas Flamand, Benoit Laurent, Mélanie Plourde.
       BACKGROUND: In a previous study, we showed that oral supplementation with lysophosphatidylcholine (LPC)-bound omega-3 fatty acids (n-3) increases cortical eicosapentaenoic acid (EPA, C20:5n-3) but not docosahexaenoic acid (DHA, C22:6n-3) in an apolipoprotein E (APOE)- and duration-dependent manner. This may reflect DHA retention in blood-brain interfaces, such as microvessels (MV) and choroid plexus (ChP).
    OBJECTIVE: To assess whether LPC n-3 intake over two or four months modulates the lipid composition of MV and ChP in APOE3 and APOE4 mice.
    METHODS: APOE3 and APOE4 mice received daily gavage of LPC-bound EPA (21.5 mg/day) and DHA (10.4 mg/day) or sunflower oil (control) for two or four months (n=5-8 mice per genotype and treatment). Lipids from plasma, frontal cortex (FCx), ChP, and MV were analyzed by liquid chromatography-tandem mass spectrometry.
    RESULTS: Principal component analysis indicated that phospholipid levels in plasma, ChP, MV and FCx were modulated more by the type of oil administered by gavage (LPC n-3-enriched oil vs. sunflower oil) than by APOE genotype or gavage duration. The ChP was the most responsive tissue to n-3 supplementation. Total DHA increased in the FCx of APOE3 mice receiving LPC n-3, but not in APOE4 mice. In contrast, EPA levels were significantly higher across genotypes and biological compartments in n-3-supplemented mice.
    CONCLUSION: This study reports higher DHA and EPA concentrations in the brain of APOE3 mice supplemented with LPC n‑3 and reinforces evidence of lower DHA accretion in APOE4 mice. It also identifies the ChP as a major site of n‑3 response.
    Keywords:  APOE4; Omega-3 fatty acids; choroid plexus; cortex; lipidomics; lysophosphatidylcholine; microvessels
    DOI:  https://doi.org/10.1016/j.jnutbio.2026.110376
  4. Neuron. 2026 Apr 06. pii: S0896-6273(26)00212-6. [Epub ahead of print]
    Astrocytic glucose metabolism regulates the survival of newborn hippocampal neurons in the adult brain.
    Xinxing Wang, Lu Chen, Thomas A Kim, Zhiyi Wang, Xike Peng, Michelle D Syty, Faye Wang, Yuhan Zhang, Patrick Wehrle, Yusuke Nasu, Qiaojie Xiong, Shaoyu Ge.
      In the adult brain, hippocampal activity precisely regulates the survival of newborn hippocampal neurons. However, the mechanisms by which these neurons acquire metabolites required for survival remain unclear. Using a genetically encoded glucose biosensor and in vivo imaging in freely moving animals, we tracked cellular glucose dynamics during contextual exploration. Newborn neurons recovered intracellular glucose slowly and expressed low levels of glycolysis- and glucose transport-related genes. By contrast, astrocytes surrounding newborn neurons exhibited rapid decreases in intracellular glucose during exploration, followed by prompt recovery afterward. In vivo lactate imaging revealed concurrent increases in astrocytic and extracellular lactate during exploration. Importantly, disrupting astrocytic glucose uptake, lactate production, or lactate transport in astrocytes or newborn neurons impaired activity-dependent survival. These results identify an astrocyte-to-newborn neuron metabolic pathway in which astrocytic glucose metabolism supports newborn neuron survival through lactate, with implications for adult neurogenesis in aging and disease.
    Keywords:  activity-dependent survival; adult hippocampal neurogenesis; astrocyte-newborn neuron metabolic coupling; glucose metabolism; in vivo biosensor imaging; lactate transport
    DOI:  https://doi.org/10.1016/j.neuron.2026.03.021
  5. Analyst. 2026 Apr 07.
    Deep profiling of porcine brain gangliosides enabled by TiO2 magnetic nanoparticle-based enrichment and advanced lipidomic analysis.
    Yichun Wang, Yu Xia.
      Gangliosides are a class of glycosphingolipids highly enriched in the central nervous system and play key roles in neurological functions and pathologies. Deep profiling of gangliosides remains challenging due to their low abundance, high structural complexity, and the matrix effect. Recently, we have developed a method for cellular ganglioside enrichment using TiO2 magnetic nanoparticles; however, the large difference within the brain lipidome demands significant modification of the method. Herein, we introduce a tailored enrichment procedure which selectively depletes major brain-specific interfering lipids, thereby allowing the enrichment of gangliosides with up to four sialic acid residues. Furthermore, the integration of amide-hydrophilic interaction liquid chromatography with trapped ion mobility spectrometry and tandem mass spectrometry greatly facilitates the discovery of new ganglioside structures. When applied to porcine brain total lipid extract, we achieved the identification of 239 species across 40 subclasses, including newly discovered GD1c and O-Ac-GD1c, with 184 of them being characterized at the chain composition level. Compared to the fewer than 15 subclasses identified in brain gangliosides using non-enriched approaches, our data present the most extensive structural atlas of brain gangliosides reported to date. This approach holds promise for investigating the brain ganglioside metabolism involved in neurodevelopment, neurodegeneration, and other neurological contexts.
    DOI:  https://doi.org/10.1039/d6an00100a
  6. bioRxiv. 2026 Mar 14. pii: 2026.03.11.710133. [Epub ahead of print]
    APOE4 Accelerates Menopause-Associated Brain Metabolic Shift and Disrupts Bioenergetic Adaptation.
    Tian Wang, Yuan Shang, John W McLean, Fei Yin, Roberta Diaz Brinton.
       Introduction: Disruption of brain glucose and lipid metabolism contributes to Alzheimer's disease (AD) and often emerges before clinical symptoms. Women are at elevated AD risk due to menopause-associated estrogen decline, which impairs mitochondrial function and glucose metabolism. Women's risk of AD is further elevated by the APOE4 allele, the strongest genetic risk factor for late-onset AD.
    Methods: To investigate the impact of APOE genotype on the menopausal metabolic transition, brain metabolomic and lipidomic profiling was conducted in humanized female APOE3/3, APOE3/4, and APOE4/4 mice across chronological and endocrinological stages of peri-to postmenopausal transition.
    Results: APOE3/3 mice exhibited dynamic regulation of brain metabolic systems that supported postmenopausal bioenergetic demand. In contrast, APOE3/4 and APOE4/4 mice displayed accelerated and altered metabolic shifts, resulting in postmenopausal amino acid depletion, reduced tricarboxylic acid (TCA) cycle intermediates, lipid accumulation, and alterations in brain lipid composition. A single APOE4 allele was sufficient to impair metabolic adaptation, while APOE4 homozygosity resulted in greater severity of deficits.
    Discussion: Outcomes of these analyses revealed that APOE4 accelerated menopause-related metabolic decline and compromised bioenergetic adaptation, providing a mechanistic basis for increased AD susceptibility and earlier onset in APOE4-positive women.
    DOI:  https://doi.org/10.64898/2026.03.11.710133
  7. J Lipid Res. 2026 Apr 03. pii: S0022-2275(26)00060-X. [Epub ahead of print] 101034
    Cerebrospinal fluid CEFA composition is enriched in saturated fatty acids and it is altered in Alzheimer's Disease.
    Chiara Pavanello, Alice Ossoli, Chiara Comi, Marta Turri, Lucio Tremolizzo, Elisa Conti, Paolo D'Incecco, Alberto Barbiroli, Paolo Parini, Nico Mitro, Donatella Caruso, Giulia Sierri, Francesca Re, Clizia Chinello, Claudia Fumagalli, Fulvio Magni, Karl Fernandes, Laura Calabresi.
      Cholesterol esterification is a fundamental step in cholesterol metabolism and transport, and in humans it is operated by three enzymes. Lecithin:cholesterol acyltransferase (LCAT) is responsible of cholesterol esterification in plasma and other biological fluids including cerebrospinal fluid (CSF), where it is mainly activated by apolipoprotein E. Esterification of cholesterol within cells is instead operated by sterol O-1 and O-2 acyltransferases (SOAT1 and SOAT2). SOAT1 is expressed in all cell types, while SOAT2 is expressed in hepatocytes and enterocytes, where it produces cholesteryl esters (CEs) to be assembled within VLDL and chylomicrons. LCAT and SOAT1/2 have different substrate specificity; LCAT has a preference for the unsaturated fatty acids, while the SOAT enzymes prefer the saturated and monounsaturated fatty acids. Here we show that CSF CEs have a different composition compared to plasma CEs and specifically are more enriched in saturated and monounsaturated fatty acids, typical substrates of the SOAT2 enzyme, and less frequently used by LCAT. Protein and RNA analysis in astrocytes, the main lipoprotein-producing cells in the central nervous system, excluded the presence of SOAT2, thus suggesting that CSF CEs are product of the LCAT enzyme. In line with this hypothesis, CSF phosphatidylcholine, the substate of LCAT, is enriched in saturated and monounsaturated fatty acids and depleted in polyunsaturated fatty acids. Moreover, we show that in AD patients, CSF CEs are enriched in saturated fatty acids, thus adding new insights into our recent observation that LCAT-mediated cholesterol esterification is hampered in AD. In conclusion, the present findings not only clarify the enzymatic origin of CSF CEs but also open avenues for developing enzyme-specific biomarkers and therapeutic strategies aimed at restoring lipid homeostasis in the brain.
    Keywords:  LCAT; Lecithin; cholesterol acyltransferase; cholesterol esterification; fatty acids
    DOI:  https://doi.org/10.1016/j.jlr.2026.101034
  8. J Biomed Res. 2026 Apr 25. 1-10
    Potential crosstalk between Parkinson's disease and glucose metabolism.
    Yafang Li, Xiongjie He, Jialin Lan, Liping Bai, Tilong Huang, Xianwen Zhang.
      Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by the loss of dopaminergic neurons and alpha-synuclein (α-syn) aggregation. Although current therapies alleviate symptoms, they fail to halt disease progression, and the underlying drivers remain elusive. Cellular metabolic dysfunction, particularly impaired glucose metabolism and reduced adenosine triphosphate production, considerably contributes to PD pathogenesis. This review systematically describes the core features of brain glucose metabolism and the cooperative metabolic network between neurons and astrocytes. Furthermore, it details specific alterations in glycolytic pathways observed in PD, elucidating the mechanisms by which key factors such as dopamine, α-syn, and DJ-1 contribute to this metabolic impairment. Finally, the review critically evaluates emerging therapeutic strategies targeting glycolysis to restore energy homeostasis, underscoring their potential as novel interventions to suppress disease progression. A deeper understanding of these metabolic mechanisms promises new avenues for developing effective PD treatments.
    Keywords:  Astrocytes; Glucose; Glycolysis; Neurons; Parkinson's disease
    DOI:  https://doi.org/10.7555/JBR.39.20250499
  9. Cell Death Discov. 2026 Apr 09.
    Lipid droplets in neurodegenerative diseases: pathological drivers and therapeutic vulnerabilities.
    Ourania Papapanagiotou, Kian Cotton, Christopher Edwards, David Michod, Lucy Crompton, Tim Craig, Maria Victoria Niklison-Chirou.
      Lipid droplets (LDs) are dynamic intracellular organelles traditionally associated with energy storage, which have become increasingly recognised for their versatile roles in cellular metabolism and signalling. In the brain, LDs have emerged as critical regulators in neurodegenerative diseases (NDDs) such as Alzheimer's disease (AD), Parkinson's disease (PD), and Hereditary Spastic Paraplegia (HSP). LDs contribute to neurodegeneration by influencing lipid metabolism, oxidative stress, and inflammatory responses. For instance, in AD, dysregulated lipid metabolism and impaired Apolipoprotein E 4 (ApoE4) function lead to LD accumulation associated with neuroinflammation and amyloid plaque formation. In PD, interactions between LDs and α-synuclein suggest a potential link between lipid dysregulation and neurotoxicity. Mutations in LD-associated proteins, such as spastin and DDH2 in HSP, highlight the importance of proper LD regulation for neuronal health. While LD accumulation can be protective by mitigating lipotoxicity, prolonged dysregulation can exacerbate NDD pathology. Targeting LD metabolism, through enhancing lipophagy or modulating LD-associated proteins, represents a promising therapeutic avenue. This review highlights the dual roles of LDs in the brain, acting both neuroprotectively and neurotoxically, and the therapeutic potential of targeting LD dynamics for NDD treatment.
    DOI:  https://doi.org/10.1038/s41420-026-03096-w
  10. Neurobiol Dis. 2026 Apr 08. pii: S0969-9961(26)00122-1. [Epub ahead of print] 107377
    Lactate, an underestimated molecule in nerve regeneration.
    Huanyi Li, Liu Ming, Zichong Tu, Yulu Zhao, Meili Cheng, Zuhe Zhang, Cheng Gao, Jingjing Jiang.
      Lactate, a crucial metabolite, plays an important role in the nervous system. It not only serves as an intermediate in energy metabolism but also exhibits significant neuroregenerative and neuroprotective properties. This review summarizes the multifaceted roles of lactate in neuroregeneration. First, lactate is involved in both neural damage and protection through lactylation. Second, the two subunits of lactate dehydrogenase (LDH) are respectively involved in damage and protection processes. Meanwhile, the expression and activity of monocarboxylate transporters (MCTs) collectively regulate neuronal energy metabolism and lactate shuttle, thereby influencing neuroregeneration. Furthermore, lactate accelerates axonal growth by modulating growth cone dynamics and guidance, thereby promoting neuroregeneration. Additionally, lactate possesses antioxidant and anti-inflammatory properties, protecting neurons from oxidative stress and inflammatory damage, which further supports neuroregeneration. Although the role of lactate in neuroregeneration is increasingly recognized, its underlying molecular mechanisms require further elucidation. Its potential therapeutic applications in both the central and peripheral nervous systems warrant in-depth investigation.
    Keywords:  Growth cone; Lactate; Lactate dehydrogenase (LDH); Lactylation; Monocarboxylate transporters (MCTs); Neuroregeneration
    DOI:  https://doi.org/10.1016/j.nbd.2026.107377
  11. Alzheimers Dement. 2026 Apr;22(4): e71306
    TOMM40 suppression promotes neuronal cholesterol imbalance and molecular and behavioral phenotypes of Alzheimer's disease.
    Neil V Yang, Shaowei Wang, Boyang Li, Jeffrey Simms, Linsey Dinh, Annie Huang, Jacob H Oei, Hussein N Yassine, Ronald M Krauss.
       INTRODUCTION: While the apolipoprotein E (APOE) ε4 allele is a major risk factor for Alzheimer's disease (AD), the role of translocase of outer mitochondrial membrane 40 (TOMM40)-an adjacent gene involved in mitochondrial protein import-is not known.
    METHODS: Human brain tissue, human induced pluripotent stem cell-derived neurons (iNeurons), and mice were used for study of gene expression, cholesterol metabolism, mitochondrial function, and animal cognition.
    RESULTS: Human brain transcriptomics showed reduced TOMM40 expression that correlated with cholesterol regulatory gene expression, amyloid burden, and clinical AD diagnosis. In human iNeurons, TOMM40 knockdown (KD) disrupted mitochondria-endoplasmic reticulum contact sites (MERCs), causing mitochondrial dysfunction and promoting reactive oxygen species that led to activation of liver X receptor beta (NR1H2), upregulation of APOE and low-density lipoprotein receptor (LDLR), and increased cellular cholesterol and amyloid beta (Aβ)42 independent of APOE ε4. Consistently, Tomm40 KD in mice induced increased brain cholesterol, Aβ42 content, and impaired memory.
    DISCUSSION: TOMM40 is a novel mediator of AD pathology through dual effects on MERCs that regulate cholesterol homeostasis and mitochondrial function.
    Keywords:  Alzheimer's disease; apolipoprotein E; cholesterol metabolism; mitochondria; mitochondria–endoplasmic reticulum contact sites; translocase of outer mitochondrial membrane 40
    DOI:  https://doi.org/10.1002/alz.71306
  12. Neurotherapeutics. 2026 Apr 07. pii: S1878-7479(26)00060-7. [Epub ahead of print] e00890
    Nervonic acid supplementation mitigates disease severity biomarkers in adrenoleukodystrophy.
    Chenxu Li, Kai Braaten, Ann B Moser, Wedad Fallatah, Maggie Lorentson, Suzette Huguenin, Anna Torrey, Marcia R Terluk, Willa Durose, Erin Nolan, Christopher Staley, Subbaya Subramanian, Troy C Lund, Reena V Kartha.
      X-linked adrenoleukodystrophy (ALD) is a severe neurometabolic disorder caused by mutations in the ABCD1 gene, leading to impaired peroxisomal β-oxidation of very long-chain fatty acids (VLCFAs). The accumulation of saturated VLCFAs, predominantly C26:0, in plasma and across all tissues, contributes to adrenal dysfunction and progressive neurodegeneration. No approved therapy addresses the diverse spectrum of ALD manifestations, underscoring the urgent need for safe, accessible, and preventive treatments. Nervonic acid (NA), a monounsaturated fatty acid, is potentially beneficial for ALD through its neuroprotective effects. Here, we report the safety and therapeutic efficacy of NA in a 4-week dietary intervention study using a mouse model of ALD. NA treatment significantly decreased plasma C26:0-lysophosphatidylcholine, a diagnostic and disease-severity biomarker of ALD, by about 60% as early as one week after intervention. After 4-week treatment, NA markedly reduced free C26:0 and total saturated VLCFA levels in plasma and tissues. Moreover, we observed approximately 56% reduction in brain C26:0-lysophosphatidylcholine levels in NA-fed mice, an effect not reported with other drug intervention. Through comparative microbiome analysis, we show for the first time distinct baseline differences between ALD and wild-type mice, with dietary fatty acid supplementation preventing further dysbiosis. No adverse effects on body weight or food intake were observed throughout the study. Overall, this is the first report demonstrating that an oral dietary fatty acid can ameliorate the hallmark biochemical abnormalities of ALD in plasma and brain, highlighting its potential as a safe and effective therapy, particularly for presymptomatic individuals carrying this genetic defect.
    Keywords:  Adrenoleukodystrophy; C26:0-lysophosphatidylcholine; Dietary therapy; Microbiome; Nervonic acid; Very long-chain fatty acids
    DOI:  https://doi.org/10.1016/j.neurot.2026.e00890
  13. Proc Natl Acad Sci U S A. 2026 Apr 14. 123(15): e2537810123
    Tanycyte-derived lactate activates astrocytic HCAR1 to modulate glutamatergic signaling and POMC neuron excitability.
    Sergio López, Roberto Elizondo-Vega, Vinka Azócar, Vania Sepúlveda, Valentina Opazo-Mellado, Walter Vásquez, Juan C Sáez, Ricardo C Araneda, María de Los Ángeles García-Robles.
      Astrocytes and tanycytes play essential roles in hypothalamic metabolic sensing, yet how glial-glial communication translates metabolic cues into neuronal activity remains poorly understood. We previously demonstrated that tanycytes release lactate and that this metabolite modulates the activity of arcuate pro-opiomelanocortin (POMC) neurons. Here, we identify the lactate receptor, HCAR1, as a key mediator of tanycytes-astrocyte-neuron signaling in the arcuate nucleus. We show that HCAR1 is highly expressed in hypothalamic astrocytes and present in a subset of NPY neurons. In primary hypothalamic cultures, L-lactate, the endogenous agonist of HCAR1, elicited increases in astrocytic cytosolic Ca2+ and stimulated glutamate release; both effects were abolished by HCAR1 silencing using siRNA. In parallel, L-lactate and 3Cl-HBA increased connexin hemichannel activity, and hemichannel inhibition reduced glutamate release. Consistent with these in vitro observations, focal intracellular glucose delivery to a single tanycyte in acute hypothalamic slices triggered rapid Ca2+ elevations in neighboring astrocytes, revealing functional glial-glial communication in situ. Importantly, activation of astrocytic HCAR1 enhanced NMDA receptor-dependent slow inward currents and excitability in POMC neurons, an effect reproduced by pharmacological HCAR1 agonists and abolished by astrocytic HCAR1 silencing. Together, these findings uncover a glial metabolic relay in which tanycyte-derived lactate activates astrocytic HCAR1, promotes glutamate release, and enhances POMC neuron excitability, providing a mechanistic link between cerebrospinal fluid-borne glucose fluctuations and hypothalamic control of feeding.
    Keywords:  POMC neurons; connexin hemichannels; glutamate; lactate; lactate receptor
    DOI:  https://doi.org/10.1073/pnas.2537810123
  14. Front Aging Neurosci. 2026 ;18 1790090
    Protein lactylation in Alzheimer's disease: bridging metabolism, pathology, and therapeutic opportunity.
    Huawen Cao, Junyi Liang, Xiaohong Dong, Zhiqi Xia, Xiaoting Luo, Bin Liu.
      Lactate, long regarded as a mere by-product of glycolysis, is increasingly recognized as a signaling metabolite and epigenetic regulator through protein lactylation. This lysine-specific post-translational modification functionally couples cellular metabolic states to gene regulatory programs and orchestrates cell type-specific functions across neurons, astrocytes, and microglia, thereby shaping synaptic plasticity, neuroinflammatory responses, and protein aggregation. Accumulating evidence implicates dysregulated lactylation in the pathogenesis of Alzheimer's disease (AD), where it modulates amyloid-β deposition, tau aggregation, and glial reactivity. In this Review, we summarize the enzymatic regulation of protein lactylation, delineate its context-dependent roles in distinct central nervous system cell types, and highlight its function as a metabolic-epigenetic-immune nexus in AD progression. We further discuss emerging therapeutic strategies targeting lactate metabolism and lactylation pathways, and outline critical knowledge gaps that must be addressed to translate these insights into innovative diagnostic and therapeutic approaches. By integrating metabolic reprogramming, epigenetic control, and cell-specific mechanisms, this Review positions lactylation as a compelling and emerging frontier in AD research.
    Keywords:  Alzheimer’s disease; cell-specific mechanisms; epigenetic control; lactate metabolism; lactylation pathways; metabolic reprogramming
    DOI:  https://doi.org/10.3389/fnagi.2026.1790090
  15. Front Aging Neurosci. 2026 ;18 1782460
    Astrocytic K+ regulation during neurodegenerative diseases.
    Evgeniia Samokhina, Yossi Buskila.
      Neurodegenerative diseases are a group of chronic, progressive disorders characterized by the gradual loss of neurons in specific areas of the central nervous system. Historically, a "neurocentric" paradigm viewed glial cells, such as astrocytes, as cells that provided adequate support for neuronal energy metabolism and controlled local cerebral blood flow. However, studies from the past two decades found that astrocytes are involved in synaptic function through different mechanisms, including the uptake of extracellular glutamate molecules and potassium ions following synaptic neuronal transmission. Also, astrocytes respond to neurotransmitters and neuromodulators through alterations of intracellular ion concentrations (e.g., Na+, Ca2+, K+) and the release of gliotransmitters. Astrocytes play a pivotal role in preserving potassium homeostasis within the central nervous system through their potassium channels, a process known as "potassium clearance." Impaired astrocytic potassium clearance mechanisms can result in neuronal hyperexcitability, leading to increased glutamate release, overactivation of glutamate receptors, and cytotoxicity. Recent studies suggest that these factors can cause cell death and neurodegeneration, and further indicate a region-specific glial dysfunction in neurodegeneration, which reflects the heterogeneity of glial cell function and sensitivity across different brain regions. Overall, this manuscript offers novel insights into a relatively new concept that glial cells can actively shape neuronal activity and survival.
    Keywords:  ALS; Alzheimer's disease; astrocytes; homeostasis; neurodegeneration; potassium
    DOI:  https://doi.org/10.3389/fnagi.2026.1782460
  16. J Transl Med. 2026 Apr 10.
    Mitochondrial dysfunction in neonatal brain injury: from molecular mechanisms to therapeutic interventions.
    Chengqian Teng, Jianjie Wei, Yixiao Zhu, Andi Chen, Xiaohui Chen.
       BACKGROUND: Neonatal brain injury, including hypoxic-ischemic encephalopathy, preterm brain injury, and neonatal infectious brain injury, remains a major cause of death and long-term neurodevelopmental disability worldwide. The immature brain is highly dependent on oxidative metabolism yet particularly vulnerable to energy failure and oxidative stress, placing mitochondria at the core of injury cascades. By integrating disturbances in energy production, redox balance, calcium homeostasis, and cell death signaling, mitochondrial dysfunction is increasingly recognized as a unifying driver of diverse neonatal brain injury phenotypes.
    MAIN BODY: This narrative review synthesizes current knowledge on the main clinical forms of neonatal brain injury and their developmental context, alongside an overview of mitochondrial physiology in neural cells, including the regulation of bioenergetics, reactive oxygen species, calcium signaling, mitochondrial dynamics, and inter‑organelle communication. It critically examines how mitochondrial dysfunction contributes to injury across hypoxic-ischemic, preterm, and infectious or inflammatory insults, emphasizing links between impaired oxidative phosphorylation, excessive oxidative and nitrosative stress, calcium overload with pathological opening of the mitochondrial permeability transition pore, activation of apoptosis and regulated necrosis, disrupted mitochondrial fusion-fission balance and biogenesis, and defective mitophagy and mitochondrial quality control. These mitochondrial disturbances precipitate acute neuronal and oligodendroglial injury and hinder the long-term maturation and connectivity of neural circuits. Finally, we review emerging mitochondria‑targeted neuroprotective strategies, focusing on approaches that enhance mitochondrial biogenesis, reduce mitochondrial oxidative stress, and target mitochondrial dynamics to restore mitochondrial homeostasis and improve cellular resilience in the immature brain.
    CONCLUSION: By linking specific patterns of mitochondrial dysfunction to distinct forms and stages of neonatal brain injury, this review provides a mechanistic framework for identifying high‑risk infants, refining pathophysiological understanding, and guiding the rational development of mitochondria‑targeted interventions aimed at improving neurological outcomes in vulnerable newborns.
    Keywords:  Energy metabolism; Hypoxic–ischemic encephalopathy; Mitochondrial dynamics and mitophagy; Mitochondrial dysfunction; Mitochondria‑targeted therapy; Neonatal brain injury; Neuroprotection; Oxidative stress
    DOI:  https://doi.org/10.1186/s12967-026-08104-2
  17. bioRxiv. 2026 Apr 04. pii: 2026.04.03.716347. [Epub ahead of print]
    Simian Immunodeficiency Virus and Antiretroviral Therapy Impact Rhesus Macaque Brain Lipid Distribution.
    Cory J White, Kyle A Vanderschoot, Dalton R Brown, Alyssa F Espley, Elizabeth K Neumann, Caitlin M Tressler, Dionna W Williams.
      Human immunodeficiency virus (HIV) infection promotes considerable bioenergetic, spatially heterogenous strain to the brain that is incompletely ameliorated through viral suppression afforded by antiretroviral therapy (ART). Disrupted homeostasis of brain lipids after HIV in humans or simian immunodeficiency virus (SIV) infection in rhesus macaques occurs due to elevated energetic demands, neuroinflammation, reactive oxygen species, and barrier leakiness. Brain lipids are particularly vulnerable to HIV-associated dysregulation due to their high abundance, unique composition, and specialized functional roles. Using rhesus macaques exposed to SIV and ART (tenofovir disoproxil fumarate (TDF), emtricitabine (FTC), and dolutegravir (DTG), we investigated the spatial distribution and abundance of lipids across brain regions and metabolically relevant peripheral tissues using mass spectrometry imaging. When comparing lipid abundance, individual lipids representing a multitude of species were more varied across tissues than by treatment condition. Further, we discerned either solely SIV infection or ART outweighed one another in altering phospholipids in different tissues Presence of ART had a greater influence on phospholipid homeostasis in the temporal cortex and hippocampus than in the midbrain, possibly due to differences in penetrance and turnover of ART across brain regions. Overall, these data demonstrate ART robustly increased phospholipids across brain regions while SIV infection had a varied impact depending on the brain region. These findings inform the need to further evaluate the neurologic consequences that may result in the brain due to disrupted lipid homeostasis across ART regimens.
    DOI:  https://doi.org/10.64898/2026.04.03.716347
  18. J Med Chem. 2026 Apr 07.
    Discovery of the First Brain-Penetrant Radioligands for Visualizing the GABA Transporter 1 (GAT-1): Synthesis, In Vitro Screening, and In Vivo Evaluation in Nonhuman Primates.
    Jiwei Gu, Chao Wang, Luca Gobbi, Michael Honer, Ming-Qiang Zheng, Paul Gravel, Hong Gao, Li Zhang, Jim Ropchan, Nabeel Nabulsi, Edilio Borroni, Gilles Tamagnan, Richard Carson, Yiyun Huang.
      The γ-aminobutyric acid (GABA) system regulates neuronal excitability in the central nervous system and is implicated in multiple neuropsychiatric and neurodegenerative disorders. GABA transporter 1 (GAT-1) is a key regulator of synaptic GABA levels but has been difficult to image in vivo due to the lack of blood-brain barrier (BBB)-permeable radioligands for positron emission tomography (PET). Here, we report the design, synthesis, and evaluation of novel tiagabine-based derivatives as brain-penetrant radioligands for GAT-1. Screening of 105 compounds identified four candidates (GATT-31, GATT-34, GATT-39, and GATT-44) with high GAT-1 affinity, appropriate lipophilicity, and low P-glycoprotein efflux liability. These ligands were radiolabeled via copper-mediated 18F-radiofluorination. PET imaging in nonhuman primates demonstrated good brain uptake of the radioligands. Among them, [18F]GATT-44 appeared to be the most promising with good metabolic stability and high GAT-1 binding specificity. The discovery of BBB-penetrating radioligands enables, for the first time, in vivo imaging of GAT-1 in the brain.
    DOI:  https://doi.org/10.1021/acs.jmedchem.5c03014
  19. Prostaglandins Other Lipid Mediat. 2026 Apr 03. pii: S1098-8823(26)00018-3. [Epub ahead of print]184 107073
    Exploring lipid metabolism reprogramming in meningiomas through lipidomics of matched clinical specimens.
    Jichao Chen, Xiangyue Mo, Meng Lv, Yang Lei, Hai Wang, Shengke Li, Binghui Qiu, Yun Bao, Jiashu Du, Leyi Liao, Ti Yang, Chen Xie, Cuiting Liu, Kai Wang, Songtao Qi, Chuanping Huang.
       BACKGROUND: Meningiomas, among the most common primary intracranial tumors, present significant clinical challenges, particularly due to the propensity for recurrence in higher-grade variants and the paucity of effective non-surgical therapies.Lipid metabolism plays a critical role in tumor progression; however, the specific lipid dysregulation underlying meningioma biology remains incompletely understood.
    METHODS: In this study, meningioma tissues and patient-matched arachnoid membrane tissues were collected from 12 patients undergoing meningioma resection surgery. A comprehensive lipidomic analysis was performed on these tissues, and lipid metabolic differences between meningioma and arachnoid tissues were evaluated using multiple t-tests with appropriate correction for multiple comparisons.
    RESULTS: Our analyses revealed pronounced lipidomic remodeling in meningiomas, characterized by an overall increase in total lipid abundance compared with arachnoid tissues. Specifically, phospholipids such as phosphatidylcholine (PC), phosphatidylethanolamine (PE), and cardiolipin (CL) were significantly elevated, whereas phosphatidylinositol (PI) levels were reduced. Fatty acid composition also displayed distinct alterations, with decreased saturated fatty acids (SFAs) and increased polyunsaturated fatty acids (PUFAs). In addition, glycerophospholipids and sphingolipids, including sphingomyelin (SM) and ceramide (Cer), exhibited significant remodeling, reflecting profound metabolic reprogramming in meningiomas. Correlation analyses further suggested associations between specific lipid species (e.g., MePC and SM) and clinicopathological features such as tumor size and patient age.
    CONCLUSION: These findings highlight the pivotal role of lipid metabolic reprogramming in meningioma pathogenesis and underscore the potential of lipidomic profiling to identify biologically relevant biomarkers and therapeutic targets through comparison with arachnoid tissue.
    Keywords:  Lipid metabolism; Lipidomics; Meningioma; Phospholipids; Sphingolipid
    DOI:  https://doi.org/10.1016/j.prostaglandins.2026.107073
  20. Semin Pediatr Neurol. 2026 Apr;pii: S1071-9091(26)00001-X. [Epub ahead of print]57 101257
    Pathophysiological pathways in mild traumatic brain injury.
    Mugdha Mohanty, Alcy R Torres.
      Mild traumatic brain injury (mTBI) is a disorder of physiologic dysfunction of the brain from trauma, and is the most common form of traumatic brain injury across all age groups.1,2,3,6 Its clinical manifestations are diverse, ranging from loss of consciousness, dizziness, seizures, headache, irritability, lethargy which are immediately recognized, but a small subset of patients are left with prolonged somatic and cognitive symptoms affecting their quality of life and academic functioning.4,9,10 Insight into the pathophysiology of mTBI has shown that it is a complex process where mechanical force to the neuron triggers a cascade of multiple reactions at the cellular and molecular level, starting with disruption of ionic homeostasis, glutamate-mediated excitotoxicity, mitochondrial dysfunction, altered cerebral blood flow, neuroinflammation, glial activation, and traumatic axonal injury.5,13-19,21-24 There is a mismatch between energy supply and demand of the brain, which further potentiates the injury.16,30 Although the standard consideration is that mTBI is not accompanied by structural changes, insight into pathophysiological mechanisms reveals that structural changes, some of which are permanent are also seen in mild TBI. This review summarizes the key pathophysiological alterations and processes in mTBI and briefly discusses biomarkers and advanced imaging techniques that may support clinical detection, especially in patients with protracted and prolonged symptoms.
    Keywords:  TBI; Traumatic Brain Injury; mTBI
    DOI:  https://doi.org/10.1016/j.spen.2026.101257
  21. Anal Chem. 2026 Apr 06.
    Single-Cell Metabolic Profiling in a Glioblastoma Coculture Model Using AP-MALDI-Based Mass Spectrometry Imaging.
    Une Kontrimaite, Kei F Carver Wong, Sandra Martínez-Jarquín, Phoebe McCrorie, Ruman Rahman, Dong-Hyun Kim.
      Mass spectrometry imaging enables spatially resolved, label-free detection of metabolites in tissue and culture systems, providing insight into their metabolic landscapes and spatial distribution. However, conventional approaches often lack the spatial resolution and specificity needed to investigate metabolic heterogeneity at the single-cell level, particularly in physiologically relevant models. Here, we present a single-cell ambient mass spectrometry imaging platform, enabling direct chemical mapping of metabolites at a 10 μm resolution. This method integrates cell labeling, high-resolution microscopy, and AP-MALDI Orbitrap mass spectrometry imaging to achieve cell-type-specific metabolite profiling. To demonstrate its application, we applied this approach to glioblastoma (GBM), an aggressive adult brain tumor characterized by cellular heterogeneity, metabolic adaptation, and infiltrative growth within the tumor microenvironment. A coculture model combining patient-derived glioblastoma invasive margin cells with human cortical astrocytes was used to recapitulate the invasive niche. Distinct metabolic signatures emerged upon glioblastoma-astrocyte interaction, involving pathways related to nucleotide metabolism, phospholipid turnover, and tyrosine metabolism. These findings suggest cell-type-specific metabolic activity and a potential intercellular metabolic interplay. Overall, this workflow offers a broadly accessible and robust approach for investigating metabolic heterogeneity at cellular resolution, enabling insights into metabolic interactions of heterogeneous cell types in both disease and nondisease settings.
    DOI:  https://doi.org/10.1021/acs.analchem.5c07924
  22. Mol Neurodegener Adv. 2026 ;2(1): 17
    Neuroinflammatory stress preferentially impacts synaptic MAPK signaling and mitochondria in excitatory neurons.
    Claudia Espinosa-Garcia, Upasna Srivastava, Prateek Kumar, Dilpreet Kour, Sneha Malepati, Brendan R Tobin, Hailian Xiao, Sydney Sunna, Christine A Bowen, Lihong Cheng, Pritha Bagchi, Duc M Duong, Ted J Whitworth, Xinran Liu, Nicholas T Seyfried, Levi B Wood, Victor Faundez, Srikant Rangaraju.
       Background: Understanding synapse-specific effects of neuroinflammation can provide mechanistic and therapeutically relevant insights across the spectrum of neurological diseases.
    Methods: We applied neuron-specific proteomic biotinylation in vivo, differential centrifugation of brain for crude synaptosome enrichment (P2 fraction) and mass spectrometry (MS) analysis of biotinylated proteins to derive native-state proteomes of Camk2a-positive neurons and their corresponding P2 synaptic compartments. Next, in an in vivo model of systemic lipopolysaccharide (LPS) dosing, we examined the effects of neuroinflammation on whole neuron and synaptic compartments using a combination of MS, network analysis, confirmatory biochemical and ultrastructural assays and integrative approaches across our mouse-derived and existing human datasets.
    Results: Ultrastructural and biochemical analyses of P2 fractions verified enrichment in synaptic elements, including synaptic vesicles and mitochondria. MS of biotinylated proteins from Camk2a-specific bulk brain homogenates (whole neuron) and P2 fractions (synaptosome) showed enrichment of > 1000 proteins, consistent with neuron-specific biotinylation, also confirmed by immunofluorescence microscopy. Camk2a-specific synaptic proteome revealed molecular signatures related to mitochondrial function, synaptic transmission, protein translation. LPS-treated mice displayed body weight loss and neuroinflammation, characterized by glial activation, increased pro-inflammatory cytokine levels and upregulated expression of Alzheimer's disease (AD)-related microglial genes. LPS-induced neuroinflammation exerted distinct effects on the synaptic proteome, including increased mitochondrial and reduced cytoskeletal-synaptic proteins, while suppressed synaptic MAPK signaling. Importantly, these changes were not observed at the whole neuron level, indicating unique vulnerability of the synapse to neuroinflammation. In line with synapse proteomic and signaling changes, LPS altered the ultrastructure of asymmetric synapses, suggesting dysregulation of excitatory neurotransmission. Co-expression network analysis of Camk2a neuronal proteins further resolved mitochondria- and synapse-specific protein modules, some of which were neuroinflammation-dependent. Neuroinflammation increased levels of a mitochondria-enriched module, and decreased levels of a pre-synaptic vesicle module, without impacting a post-synaptic membrane module. LPS-dependent mitochondrial and LPS-independent post-synaptic modules in mouse neurons mapped to post-mortem human AD brain proteomic modules which were decreased in cases with AD dementia and positively correlated to cognitive function, including pro-resilience markers for AD.
    Conclusion: Our findings using native-state proteomics of Camk2a neurons combined with synaptosome enrichment identify proteome-level mechanisms of early synaptic vulnerability to neuroinflammation relevant to AD.
    Graphical Abstract:
    Supplementary Information: The online version contains supplementary material available at 10.1186/s44477-026-00024-1.
    Keywords:  Alzheimer's disease; Cognitive resilience; Excitatory neuron; MAPK signaling; Mitochondria; Native-state proteomics; Neuroinflammation; Synapse vulnerability; Synaptosome
    DOI:  https://doi.org/10.1186/s44477-026-00024-1
  23. DNA Repair (Amst). 2026 Apr 05. pii: S1568-7864(26)00014-5. [Epub ahead of print]161 103935
    Altered lipid profile in mice lacking the DNA repair protein ERCC1.
    Dorota Dziuban-Lech, Agata Lipko, Andria R Robinson, Jolanta Czerwińska-Kostrzewska, Barbara Tudek, Laura J Niedernhofer, Ewa Swiezewska, Elżbieta Speina.
      Mutations in the Ercc1 gene, essential for DNA repair, are associated with accelerated aging and metabolic disturbances, but data on lipid composition under its deficiency remain limited. To address this gap, we analyzed the fatty acid (FA) profiles and lipids of the mevalonate pathway in mouse embryonic fibroblasts (MEFs) and in brains, livers, and kidneys of Ercc1-/- and wild-type (WT) mice. Ercc1-/- MEFs showed significantly reduced FA levels, while in brains and livers, differences vs. WT were not significant, though males tended to have lower values. Isoprenoids exhibited more pronounced changes. Squalene content was higher in Ercc1-/- MEFs and in female brains. Meanwhile, cholesterol levels decreased in MEFs and male brains but increased in livers. These findings indicate tissue- and sex-specific disruptions of sterol homeostasis. Notably, dolichols, recognized markers of aging, were significantly elevated in the brains and livers of Ercc1-/- mice, accompanied by shifts in their chain-length distribution. Only subtle sex-dependent differences were observed in the kidneys, without consistent changes in sterol, cholesterol and dolichol levels. Gene expression analysis partially supported these findings. In brains, Srd5a3 upregulation corresponded with dolichol accumulation; however, reduced Dhcr24 expression did not lower cholesterol levels. In livers, increased NgBR and Dhdds expression corresponded with higher dolichol levels. Kidneys displayed broad downregulation of mevalonate pathway genes, yet metabolite levels remained essentially unchanged. Overall, Ercc1 deficiency causes significant tissue- and sex-dependent disturbances in lipid metabolism, particularly affecting dolichol synthesis. Such alterations may contribute to the hallmarks of accelerated aging and neurodegeneration, associated with impaired DNA repair.
    Keywords:  Cholesterol; Dolichol; Fatty acids; Lipids/Oxidation; Monounsaturated fatty acids; Omega-3 fatty acids; Polyunsaturated fatty acids; Premature aging; Saturated fatty acids; Squalene
    DOI:  https://doi.org/10.1016/j.dnarep.2026.103935
  24. Commun Biol. 2026 Apr 10.
    Elovanoid neuroprotection targets cell transcriptomics and proteomics to sustain synaptic integrity after brain injury.
    Brian L Giles, Surjyadipta Bhattacharjee, Jeff X Ji, Pranab K Mukherjee, Ludmila Belayev, Carlos M Vieira, Nicolas G Bazan.
      Traumatic brain injury (TBI), a leading cause of death and disability, is the largest non-genetic, non-aging-related contributor to cognitive impairments. Currently, there are limited effective therapies to protect neurons after acute brain injury. Our results suggest that intranasal-delivered (IN) elovanoid (ELV) shortly after TBI elicits neuroprotection that involves synaptic and mitochondrial pathways that mediate neuroprotection. Using a single-cell multiome approach, we found an upregulation of genes involved in synaptic integrity. Furthermore, we discovered that ELVs improve synaptosomal mitochondrial function, reduce lipid peroxidation, and increase the activity of antioxidant transcriptional programs, including the NRF2 pathway, in neurons. We suggest that these changes, together with the induction of cell-type-specific gene regulation in glutamatergic neurons and other cells, underlie ELV-elicited neuroprotection.
    DOI:  https://doi.org/10.1038/s42003-026-09931-1
  25. bioRxiv. 2026 Apr 03. pii: 2026.04.01.715607. [Epub ahead of print]
    Ceramide-rich extracellular vesicles as pathogenic biomarkers in traumatic brain injury.
    Zainuddin Quadri, Zhihui Zhu, Xiaojia Ren, Simone M Crivelli, Liping Zhang, P D Kunjadia, Patrick G Sullivan, Bibi B Broome, Tritia R Yamasaki, Erhard Bieberich.
      Extracellular vesicles (EVs) contribute to the damage caused by traumatic brain injury (TBI) and can cross the blood-brain barrier (BBB). We analyzed plasma-derived EVs from human TBI patients to identify factors potentially contributing to TBI pathology. EVs were isolated using membrane affinity (ExoEasy) and size exclusion chromatography (iZone), both yielding CD9(+) and CD63(+) EVs with minimal contamination by serum albumin and apolipoprotein. Immunoblotting detected GFAP in TBI but not control EVs, indicating astrocyte-derived EVs crossing the BBB. Proteomic analysis and immunoblotting of EVs from TBI samples identified C-reactive protein and 14-3-3 proteins, which were not detected in control EVs, indicating inflammation associated with TBI. Lipidomic analysis showed ceramide enrichment in TBI EVs, validated by anti-ceramide immunoprecipitation. In a mouse closed head-controlled cortical impact model, brain EVs similarly showed elevated ceramide, confirming ceramide-rich EV release after TBI. Immunocytochemistry localized acid sphingomyelinase (ASM), a ceramide-generating enzyme, to ependymal cilia, suggesting these sites as a potential source of EVs. This was further supported by the detection of ASM in both brain- and plasma-derived EVs, along with the ciliary marker Arl13b in the brain. To assess function, we treated murine neuronal (N2a) cells with TBI EVs. Transcriptomics and STRING analyses revealed enrichment of mitochondrial-associated transcripts. Immunoblotting showed increased p53 and voltage-dependent anion channel 1 (VDAC1), which mediate ceramide-induced apoptosis. Seahorse assays showed that TBI EVs suppressed glycolysis, as indicated by reduced ECAR, while mitochondrial respiration (OCR) remained unchanged. LDH assays further indicated that TBI EVs were more neurotoxic than control EVs. Together, these findings identify ceramide-rich EVs as plasma biomarkers of TBI-induced inflammation, potential mediators of neuronal mitochondrial dysfunction, and pharmacological targets to prevent TBI-induced damage.
    DOI:  https://doi.org/10.64898/2026.04.01.715607
  26. Neurosci Bull. 2026 Apr 06.
    Unveiling the "Glycolysis-Lactate-Lactylation" Axis: A Novel Target in Ischemic Cerebrovascular Disease.
    Yi Xie, Mengmeng Dai, Rui Liu, Ying Li, Hao Yan, Jiacheng Li, Xuantong Liu, Zhiyuan Yu, Shabei Xu, Wei Wang, Xiang Luo.
      Ischemic cerebrovascular disease involves complex interactions between metabolic reprogramming and epigenetic regulation. Recent studies indicate that enhanced glycolysis and lactate accumulation under hypoxic conditions not only maintain cell viability by supplying energy but also participate in disease regulation through lactylation. Lactylation regulates gene expression, immune polarization, metabolic enzyme activity, and angiogenesis through epigenetic remodeling. In ischemic cerebrovascular disease, lactylation exerts dual roles: on one hand, it can induce neuronal death, exacerbate neuroinflammation, and form a vicious metabolic cycle; on the other hand, it can influence immune cell function and gene expression, thereby exerting neuroprotective effects. Accordingly, targeting lactate metabolism or lactylation-modifying enzymes holds considerable therapeutic potential. Nevertheless, the spatiotemporal regulation, synergistic effects, and broader physiopathological implications of lactylation warrant further in-depth investigation. This review systematically summarizes the role of the "glycolysis-lactate-lactylation" axis in the pathogenesis of ischemic cerebrovascular disease, and discusses its potential as a therapeutic target.
    Keywords:  Glycolysis; Ischemic cerebrovascular disease; Lactate; Lactylation; Metabolic reprogramming; Neuroinflammation
    DOI:  https://doi.org/10.1007/s12264-026-01622-5
  27. Front Aging Neurosci. 2026 ;18 1761702
    Mitochondrial dysfunction in Alzheimer's disease and related sex differences.
    Afzal Misrani, Conelius Ngwa, Fudong Liu.
      Alzheimer's disease (AD), the most common form of dementia, accounts for 70% of cases and remains a major healthcare challenge due to its rising prevalence and lack of disease-modifying treatments. Clinically, AD is a sexually dimorphic disease. Women exhibit more rapid cognitive decline and accelerated brain atrophy during mild cognitive impairment and early dementia, whereas men more frequently present cardiovascular comorbidities, earlier mitochondrial dysfunction, and greater neuropsychiatric symptoms. AD is marked by amyloid-β (Aβ) plaques, neurofibrillary tangles, neuroinflammation, and neuronal loss, with mitochondrial dysfunction emerging as a key early contributor that exhibits sex specific phenotypes. Mitochondria are vital for neuronal function by generating ATP, maintaining calcium homeostasis, and regulating oxidative stress. However, mitochondria in AD exhibit impaired ATP synthesis, excessive reactive oxygen species (ROS) production, calcium dysregulation, and disrupted fission-fusion dynamics. AD mitochondrial dysfunction can be measured by molecular markers, such as increased expression of fission-related protein Drp1, decreased biogenesis regulator PGC-1α, and elevated oxidative stress markers like malonaldehyde, nitotyrosine and protein carbonyls. Accumulating data suggest that sex differences in mitochondrial dysfunction are attributed to either sex hormonal or sex chromosomal effects, which eventually contribute to sex dichotomic phenotypes of AD. This review collected data regarding mitochondrial dysfunction in AD, with an emphasis on sex differences in oxidative stress, energy metabolism, and regulatory pathways.
    Keywords:  Alzheimer's disease; dementia; mitochondria; oxidative stress; sex differences
    DOI:  https://doi.org/10.3389/fnagi.2026.1761702
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