Mutant induced neurons and humanized mice enable identification of Niemann-Pick type C1 proteostatic therapies
Ruth D. Azaria, … , Mark L. Schultz, Andrew P. Lieberman
Ruth D. Azaria, … , Mark L. Schultz, Andrew P. Lieberman
Published August 29, 2024
Citation Information: JCI Insight. 2024;9(20):e179525. https://doi.org/10.1172/jci.insight.179525.
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Research Article Neuroscience

Mutant induced neurons and humanized mice enable identification of Niemann-Pick type C1 proteostatic therapies

Abstract

Therapeutics that rescue folding, trafficking, and function of disease-causing missense mutants are sought for a host of human diseases, but efforts to leverage model systems to test emerging strategies have met with limited success. Such is the case for Niemann-Pick type C1 disease, a lysosomal disorder characterized by impaired intracellular cholesterol trafficking, progressive neurodegeneration, and early death. NPC1, a multipass transmembrane glycoprotein, is synthesized in the endoplasmic reticulum and traffics to late endosomes/lysosomes, but this process is often disrupted in disease. We sought to identify small molecules that promote folding and enable lysosomal localization and functional recovery of mutant NPC1. We leveraged a panel of isogenic human induced neurons expressing distinct NPC1 missense mutations. We used this panel to rescreen compounds that were reported previously to correct NPC1 folding and trafficking. We established mo56-hydroxycholesterol (mo56Hc) as a potent pharmacological chaperone for several NPC1 mutants. Furthermore, we generated mice expressing human I1061T NPC1, a common mutation in patients. We demonstrated that this model exhibited disease phenotypes and recapitulated the protein trafficking defects, lipid storage, and response to mo56Hc exhibited by human cells expressing I1061T NPC1. These tools established a paradigm for testing and validation of proteostatic therapeutics as an important step toward the development of disease-modifying therapies.

Authors

Ruth D. Azaria, Adele B. Correia, Kylie J. Schache, Manuela Zapata, Koralege C. Pathmasiri, Varshasnata Mohanty, Dharma T. Nannapaneni, Brandon L. Ashfeld, Paul Helquist, Olaf Wiest, Kenji Ohgane, Qingqing Li, Ross A. Fredenburg, Brian S.J. Blagg, Stephanie M. Cologna, Mark L. Schultz, Andrew P. Lieberman

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Figure 4

Generation of humanized I1061T NPC1 mice.

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Generation of humanized I1061T NPC1 mice. (A) Depiction of the editing s...
(A) Depiction of the editing strategy used to create the humanized I1061T NPC1 mouse. The human NPC1 cDNA sequence encoding the I1061T NPC1 mutation was inserted into exon 2 of mouse Npc1, downstream of the signal peptide sequence, by CRISPR/Cas9 homology-directed repair. Restriction enzymes (BcII, BspHI) and Southern blot (5′ and 3′ probes) were used to determine proper insertion and PCR (5′ universal forward primer, 3′ humanized reverse primer, 3′ mouse reverse primer) were designed for mouse genotyping. (B) Brain and liver tissue from 6- to 8-week-old WT, knockin mouse I1061T NPC1 (mI10), and humanized I1061T NPC1 (hI10) were analyzed for total NPC1 protein by Western blot. Quantified below. (C) Brain and liver tissue from WT, mI10, and hI10 mice were analyzed for NPC1 mRNA by qPCR. (D) Liver lysates from WT, mI10, and hI10 mice were digested with Endo H and subjected to Western blot. Quantified at right. NT, not treated; E, Endo H digested; P, PNGase F digested. All data are mean ± SEM from the indicated number of independent experiments. *P ≤ 0.05, **P ≤ 0.01, ****P ≤ 0.0001 by (BD) 1-way ANOVA with Tukey’s post hoc test. (B) For brain, n = 5 WT, 5 mI10, 4 hI10; for liver, n = 4 WT, 4 mI10, 3 hI10. (C) For brain, n = 5 WT, 4 mI10, 3 hI10; for liver, n = 5 WT, 3 mI10, 3 hI10; (D) n = 5 WT, 4 mI10, 3 hI10.