Loss of CLN3 in microglia leads to impaired lipid metabolism and myelin turnover
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Loss-of-function mutations in CLN3 cause juvenile Batten disease, featuring neurodegeneration and early-stage neuroinflammation. How loss of CLN3 function leads to early neuroinflammation is not yet understood. Here, we have comprehensively studied microglia from Cln3∆ex7/8 mice, a genetically accurate disease model. Loss of CLN3 function in microglia leads to lysosomal storage material accumulation and abnormal morphology of subcellular organelles. Moreover, pathological proteomic signatures are indicative of defects in lysosomal function and abnormal lipid metabolism. Consistent with these findings, CLN3-deficient microglia are unable to efficiently turnover myelin and metabolize the associated lipids, showing defects in lipid droplet formation and cholesterol accumulation. Accordingly, we also observe impaired myelin integrity in aged Cln3∆ex7/8 mouse brain. Autophagy inducers and cholesterol-lowering drugs correct the observed microglial phenotypes. Taken together, these data implicate a cell-autonomous defect in CLN3-deficient microglia that impacts their ability to support neuronal cell health, suggesting microglial targeted therapies should be considered for CLN3 disease.
SEEK ID: http://lmmeisd-2.srv.mwn.de/studies/98
Projects: SyNergy: Published Datasets
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Created: 2nd Dec 2024 at 14:24
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Projects: SyNergy: Published Datasets, SyNergy: Unpublished Datasets
Institutions: DZNE
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Projects: SyNergy: Published Datasets, SyNergy: Unpublished Datasets
Institutions: LMU Klinikum
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Projects: SyNergy: Published Datasets, SyNergy: Unpublished Datasets
Institutions: DZNE
Please visit the 'Related items' tab within the profile page to explore associated studies in more detail.
Neurological diseases are on the rise – and as societies age, they affect an ever-increasing number of people, not only in Europe, but worldwide.
The Munich Cluster for Systems Neurology (SyNergy) investigates how complex neurological diseases such as Alzheimer's disease, stroke, and multiple sclerosis develop. Even though these diseases differ in their clinical manifestations, overlapping mechanisms are involved in their development. For example, the immune system gets activated in dementia, ...
Projects: SyNergy: Published Datasets, SyNergy: Unpublished Datasets
Web page: https://www.synergy-munich.de
This project serves as a centralized repository for omics datasets published by research groups within the SyNergy Cluster. It encompasses investigations such as proteomics and transcriptomics, which are further divided into individual studies led by SyNergy members. Each study is linked to relevant publications, assays and data files (with links to external repositories).
To explore investigations and their associated studies in more detail, please visit the 'Related items' tab on the Project ...
Programme: Munich Cluster for Systems Neurology (SyNergy)
Public web page: Not specified
Submitter: Rainer Malik
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Assays: Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Affinity purification coupled with mass spectrometry proteomics (human), Bottom-up proteomics (E. coli, human), Bottom-up proteomics (human), Bottom-up proteomics (human), Bottom-up proteomics (human), Bottom-up proteomics (human), Bottom-up proteomics (human), Bottom-up proteomics (macaque), Bottom-up proteomics (mouse), Bottom-up proteomics (mouse), Bottom-up proteomics (mouse), Bottom-up proteomics (mouse), Bottom-up proteomics (mouse), Bottom-up proteomics (mouse), Gel-based experiment (human), Phosphoproteomics / Bottom-up proteomics (mouse), Proximity-proteomics-based autophagosome content profiling (human), SWATH MS (human), SWATH MS (human, mouse), SWATH MS (mouse), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human), Shotgun proteomics (human, mouse), Shotgun proteomics (human, mouse), Shotgun proteomics (human, mouse), Shotgun proteomics (human, mouse), Shotgun proteomics (macaque), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (mouse), Shotgun proteomics (rat), Untargeted Proteomics (mouse)
Submitter: Aditi Methi
Assay type: Proteomics
Technology type: Mass Spectrometry
Investigation: Proteomics (Published)
The microglial proteome of homozygous Cln3Δex7/8/Δex7/8 was compared with those of littermate control heterozygous (Cln3Δex7/8/+) or wildtype (Cln3+/+) mice at 3 (Cln3Δex7/8/Δex7/8 n=5 vs controls n=7) and 12 months (Cln3Δex7/8/Δex7/8 n=4 vs controls n=5) of age. Microglia were acutely isolated using MACS with CD11b microbeads (Miltenyi Biotec) as previously described in Colombo et al. 36 Sample preparation and mass spectrometric measurements using data independent acquisition were performed as ...
Creators: None
Submitter: Aditi Methi
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Abstract (Expand)
Authors: Seda Yasa, Elisabeth S Butz, Alessio Colombo, Uma Chandrachud, Luca Montore, Sarah Tschirner, Matthias Prestel, Steven D Sheridan, Stephan A Müller, Janos Groh, Stefan F Lichtenthaler, Sabina Tahirovic, Susan L Cotman
Date Published: 22nd Oct 2024
Publication Type: Journal
