<p>Lipofuscin is an autofluorescent material that accrues in brain tissues with age and in Neuronal Ceroid Lipofuscinosis (NCL), a neurodegenerative disease with pediatric onset. The distribution, composition, and organellar origin of lipofuscin have remained unclear despite its widespread presence in aged tissues and involvement in neurodegeneration. Here, we elucidate lipofuscin composition in mouse and human brain and assemble a reference neuroanatomical atlas of lipofuscin accumulation with age and NCL (Type 1; <i>CLN1</i>) progression across 425 fine brain regions. We identify a primary role of the lysosomal-mitochondrial axis in the formation of lipofuscin pathology via multimodal mass spectrometry, ultrastructural analyses, and assays of cellular and enzymatic metabolism. We find the protein and lipid composition of lipofuscin in the aged and <i>CLN1</i> brain to be remarkably similar. Dissection of implicated molecular pathways reveals protein S-acylation and unsaturated lipid homeostasis as central processes involved in lipofuscin deposition during aging and <i>CLN1</i>. Notably, &gt; 95% of lipofuscin resident proteins can be S-acylated and many are substrates of the enzyme PPT1, validating a seminal hypothesis that <i>CLN1</i> lipofuscin contains these lipid-modified proteins. Further, we discover deficient de-S-acylation is correlated with lipofuscin load in healthy aging, as the specific de-S-acylation enzyme activity of PPT1 is found to decline with advancing age. Finally, we identify lipid metabolite biomarkers of lipofuscin, including long-chain polyunsaturated fatty acids, bis(monoacylglycerol)phosphate (BMP), and oxidized phosphatidylethanolamine (OxPE) lipid species. Overall, we provide a comprehensive redefinition of lipofuscin neuropathology and a resource for studying aging, lysosomal storage disorders, and neurodegeneration.</p>

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Lipofuscin accumulation in aging and CLN1 is associated with deficient de-S-acylation, lyso-mitochondrial dysfunction, and lipid dyshomeostasis

  • Sofia Massaro Tieze,
  • Alexander Esqueda,
  • Rachel McAllister,
  • Matija Lagator,
  • Betül Yücel,
  • Eric Sun,
  • Katherine B. Henke,
  • TuKiet T. Lam,
  • Nicholas Lockyer,
  • Kallol Gupta,
  • Sreeganga S. Chandra

摘要

Lipofuscin is an autofluorescent material that accrues in brain tissues with age and in Neuronal Ceroid Lipofuscinosis (NCL), a neurodegenerative disease with pediatric onset. The distribution, composition, and organellar origin of lipofuscin have remained unclear despite its widespread presence in aged tissues and involvement in neurodegeneration. Here, we elucidate lipofuscin composition in mouse and human brain and assemble a reference neuroanatomical atlas of lipofuscin accumulation with age and NCL (Type 1; CLN1) progression across 425 fine brain regions. We identify a primary role of the lysosomal-mitochondrial axis in the formation of lipofuscin pathology via multimodal mass spectrometry, ultrastructural analyses, and assays of cellular and enzymatic metabolism. We find the protein and lipid composition of lipofuscin in the aged and CLN1 brain to be remarkably similar. Dissection of implicated molecular pathways reveals protein S-acylation and unsaturated lipid homeostasis as central processes involved in lipofuscin deposition during aging and CLN1. Notably, > 95% of lipofuscin resident proteins can be S-acylated and many are substrates of the enzyme PPT1, validating a seminal hypothesis that CLN1 lipofuscin contains these lipid-modified proteins. Further, we discover deficient de-S-acylation is correlated with lipofuscin load in healthy aging, as the specific de-S-acylation enzyme activity of PPT1 is found to decline with advancing age. Finally, we identify lipid metabolite biomarkers of lipofuscin, including long-chain polyunsaturated fatty acids, bis(monoacylglycerol)phosphate (BMP), and oxidized phosphatidylethanolamine (OxPE) lipid species. Overall, we provide a comprehensive redefinition of lipofuscin neuropathology and a resource for studying aging, lysosomal storage disorders, and neurodegeneration.