Stearoyl-CoA desaturase inhibition normalizes brain lipid saturation, α-synuclein homeostasis, and motor function in mutant Gba1-Parkinson mice
Silke Nuber, … , Dennis J. Selkoe, Saranna Fanning
Silke Nuber, … , Dennis J. Selkoe, Saranna Fanning
Published June 3, 2025
Citation Information: JCI Insight. 2025;10(13):e188413. https://doi.org/10.1172/jci.insight.188413.
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Research Article Cell biology Neuroscience

Stearoyl-CoA desaturase inhibition normalizes brain lipid saturation, α-synuclein homeostasis, and motor function in mutant Gba1-Parkinson mice

Abstract

Loss-of-function mutations in the GBA1 gene are a prevalent risk factor for Parkinson’s disease (PD). Defining features are Lewy bodies that can be rich in α-synuclein (αS), vesicle membranes, and other lipid membranes, coupled with striatal dopamine loss and progressive motor dysfunction. Of these, lipid abnormalities are the least understood. An altered lipid metabolism in PD patient-derived neurons — carrying mutations in either GBA1, encoding for glucocerebrosidase (GCase), or αS — shifted the physiological αS tetramer/monomer (T:M) equilibrium, resulting in PD phenotypes. We previously reported inhibition of stearoyl-CoA desaturase (SCD), the rate-limiting enzyme for fatty acid desaturation, stabilized αS tetramers and improved motor deficits in αS mice. Here we show that mutant GBA1-PD cultured neurons have increased SCD products (monounsaturated fatty acids [MUFAS]) and reduced αS T:M ratios that were improved by inhibiting SCD. Oral treatment of symptomatic L444P and E326K Gba1 mutant mice with 5b also improved the αS T:M homeostasis and dopaminergic striatal integrity. Moreover, SCD inhibition normalized GCase maturation and dampened lysosomal and lipid-rich clustering, key features of neuropathology in GBA-PD. In conclusion, this study supports that brain MUFA metabolism links GBA1 genotype and WT αS homeostasis to downstream neuronal and behavioral impairments, identifying SCD as a therapeutic target for GBA-PD.

Authors

Silke Nuber, Harrison Hsiang, Esra’a Keewan, Tim E. Moors, Sydney J. Reitz, Anupama Tiwari, Gary P.H. Ho, Elena Su, Wolf Hahn, Marie-Alexandre Adom, Riddhima Pathak, Matthew Blizzard, Sangjune Kim, Han Seok Ko, Xiaoqun Zhang, Per Svenningsson, Dennis J. Selkoe, Saranna Fanning

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Figure 6

5b treatment reduces PK-resistant and vesicle/lipid-rich αS aggregates and normalizes lysosomal clustering and biogenesis.

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5b treatment reduces PK-resistant and vesicle/lipid-rich αS aggregates a...
(A and B) Representative images of PK-resistant pS129+ aggregates in the cortex of Plb- and 5b-treated Gba1 mice and quantification (n = 2–3 sections, n = 3–4 mice per cohort). Note only background staining was seen in Ctl mice independent of treatment. (C and D) Confocal microscopy of cortical and midbrain (S. Nigra) region labeled with Plin2 (red) and quantification of puncta sizes in cortex and S. Nigra. (E and F) Midbrain sections triple labeled with pS129 (red), LAMP1 (green), and DAPI (blue) and quantification of LAMP1+pS129 clusters. (G and H) Adjacent sections were additionally stained for lysosomal biogenesis marker TFEB and tyrosine hydroxylase and graphs quantify the relative proportion of dopaminergic neurons displaying nuclear TFEB immunolabeling. Data are shown as mean ± SEM. Two-way ANOVA, Tukey’s post hoc test (B, D, F, and H, left panels). Two-tailed, unpaired 2-tailed t test comparing in Gba1 (E326K+L444P) Plb versus 5b (B, D, F, and H, right panels). *P < 0.05, **P < 0.01, ***P < 0.001; ****P < 0.0001. Scale bars: 25 μm.