Chronic integrated stress response causes dysregulated cholesterol synthesis in white matter disease
Karin Lin, Nina Ly, Rejani B. Kunjamma, Ngoc Vu, Bryan King, Holly M. Robb, Eric G. Mohler, Janani Sridar, Qi Hao, José Zavala-Solorio, Chunlian Zhang, Varahram Shahryari, Nick van Bruggen, Caitlin F. Connelly, Bryson D. Bennett, James J. Lee, Carmela Sidrauski
Karin Lin, Nina Ly, Rejani B. Kunjamma, Ngoc Vu, Bryan King, Holly M. Robb, Eric G. Mohler, Janani Sridar, Qi Hao, José Zavala-Solorio, Chunlian Zhang, Varahram Shahryari, Nick van Bruggen, Caitlin F. Connelly, Bryson D. Bennett, James J. Lee, Carmela Sidrauski
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Research Article Cell biology Metabolism Neuroscience

Chronic integrated stress response causes dysregulated cholesterol synthesis in white matter disease

Abstract

Maladaptive integrated stress response (ISR) activation is observed in human diseases of the brain. Genetic mutations of eIF2B, a critical mediator of protein synthesis, cause chronic pathway activation resulting in a leukodystrophy, but the precise mechanism is unknown. We generated N208Y eIF2B-α mice and found that this metabolite binding mutation led to destabilization of eIF2B-α, a systemic ISR, and neonatal lethality. 2BAct, an eIF2B activator, rescued lethality and significantly extended the lifespan of this severe model, underscoring its therapeutic potential in pediatric disease. Continuous treatment was required for survival, as withdrawal led to ISR induction in all tissues and rapid deterioration, thereby providing a model to assess the impact of the ISR in vivo by tuning drug availability. Single nuclei RNA-seq of the CNS identified astrocytes, oligodendrocytes, and ependymal cells as the cell types most susceptible to eIF2B dysfunction and revealed dysfunctional maturation of oligodendrocytes. Moreover, ISR activation decreased cholesterol biosynthesis, a process critical for myelin formation and maintenance. As such, persistent ISR engagement may contribute to pathology in other demyelinating diseases.

Authors

Karin Lin, Nina Ly, Rejani B. Kunjamma, Ngoc Vu, Bryan King, Holly M. Robb, Eric G. Mohler, Janani Sridar, Qi Hao, José Zavala-Solorio, Chunlian Zhang, Varahram Shahryari, Nick van Bruggen, Caitlin F. Connelly, Bryson D. Bennett, James J. Lee, Carmela Sidrauski

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Figure 4

2BAct-treated N208YHOM mice display VWM phenotypes with age.

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2BAct-treated N208YHOM mice display VWM phenotypes with age. (A) Kaplan-...
(A) Kaplan-Meier survival: WT, n = 37; N208YHET, n = 80; N208YHOM, n = 18; WT +2BAct, n = 19; N208YHET +2BAct, n = 20, N208YHOM +2BAct, n = 20. P < 0.0001, Log-rank (Mantel-Cox) test. (B) Body weight of 4-week-old female WT (n = 38) and N208YHOM (n = 31) mice with 2BAct. Student’s t test. (C) Body weight of WT, N208YHET, and N208YHOM mice ± 2BAct. Female WT, n = 3; N208YHET, n = 13; WT +2BAct, n = 2; N208YHET +2BAct, n = 5; N208YHOM +2BAct, n = 2. P = 1.1 × 10–9 for N208YHOM +2BAct vs N208YHET +2BAct, P = 7.75 × 10–8 for N208YHOM +2BAct vs WT +2BAct, not significant for N208YHET +2BAct vs WT +2BAct, Linear mixed model (both sexes) with a post hoc test. (D) Fat/Lean mass ratio of 3-month-old female WT (n = 13) and N208YHOM (n = 7) mice (EchoMRI). Student’s t test. (E) Female food consumption at 5–6 weeks of age. WT +2BAct, n = 9; N208YHOM +2BAct, n = 8. Error bars are SD. Student’s t test. (F) Motor deficit clinical scores of WT, N208YHET, and N208YHOM male and female mice ± 2BAct at 17, 22, and 44 weeks of age. WT, n = 9; N208YHET, n = 27, WT +2BAct, n = 4, N208YHET +2BAct, n = 14; N208YHOM +2BAct, n = 6. (G and H) Representative Luxol Fast Blue staining and OLIG2, IBA1, GFAP, and ATF3 IHC images of the thoracic spinal cord (G) and quantification (H). WT +Ctrl, n = 6; WT +2BAct, n = 4; N208YHOM +2BAct, n = 4. Scale bars: 500 μm (50 μm for insets). Error bars are SD. Kruskal-Wallis test, Dunn’s post-hoc. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.