Species-specific differences in NPC1 protein trafficking govern therapeutic response in Niemann-Pick type C disease
Mark L. Schultz, … , Michael D. Uhler, Andrew P. Lieberman
Mark L. Schultz, … , Michael D. Uhler, Andrew P. Lieberman
Published October 27, 2022
Citation Information: JCI Insight. 2022;7(23):e160308. https://doi.org/10.1172/jci.insight.160308.
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Research Article Neuroscience Therapeutics

Species-specific differences in NPC1 protein trafficking govern therapeutic response in Niemann-Pick type C disease

Abstract

The folding and trafficking of transmembrane glycoproteins are essential for cellular homeostasis and are compromised in many diseases. In Niemann-Pick type C disease, a lysosomal disorder characterized by impaired intracellular cholesterol trafficking, the transmembrane glycoprotein NPC1 misfolds due to disease-causing missense mutations. While mutant NPC1 has emerged as a robust target for proteostasis modulators, drug development efforts have been unsuccessful in mouse models. Here, we demonstrated unexpected differences in trafficking through the medial Golgi between mouse and human I1061T-NPC1, a common disease-causing mutant. We established that these distinctions are governed by differences in the NPC1 protein sequence rather than by variations in the endoplasmic reticulum–folding environment. Moreover, we demonstrated direct effects of mutant protein trafficking on the response to small molecules that modulate the endoplasmic reticulum–folding environment by affecting Ca++ concentration. Finally, we developed a panel of isogenic human NPC1 iNeurons expressing WT, I1061T-, and R934L-NPC1 and demonstrated their utility in testing these candidate therapeutics. Our findings identify important rules governing mutant NPC1’s response to proteostatic modulators and highlight the importance of species- and mutation-specific responses for therapy development.

Authors

Mark L. Schultz, Kylie J. Schache, Ruth D. Azaria, Esmée Q. Kuiper, Steven Erwood, Evgueni A. Ivakine, Nicole Y. Farhat, Forbes D. Porter, Koralege C. Pathmasiri, Stephanie M. Cologna, Michael D. Uhler, Andrew P. Lieberman

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Figure 3

NPC1 protein sequence drives differential trafficking.

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NPC1 protein sequence drives differential trafficking. (A and C) NPC1-de...
(A and C) NPC1-deficient mouse fibroblasts were electroporated with (A) human WT, human I1061T, and mouse I1061T and (C) human R934L and mouse R934L, and total NPC1 was analyzed by Western blot and quantified. (B) Mouse fibroblasts and human Hap1 cells deficient in NPC1 were electroporated with GFP, human WT-NPC1, human I1061T-NPC1, or mouse I1061T-NPC1 plasmids. Lysates were incubated with no treatment (NT) or digested with EndoH (E) or PNGase F (P) and then subjected to Western blot and quantified. (D) NPC1-deficient mouse fibroblasts were electroporated with human WT-NPC1, human R934L-NPC1, or mouse R934L-NPC1 plasmids, and lysates were treated as in B and quantified. (E) Hu-I1061T, Mu-I1061T, or Mu-I1061T containing the human glycosylation sites (Ms-I1061T+HuGlycans) were overexpressed and digested with E or P and quantified. Data are shown as the mean ± SEM from indicated number of independent experiments. *P ≤ 0.05, ***P ≤ 0.001, ****P ≤ 0.0001 by (A, B, D, and E) ANOVA with Tukey’s post hoc test or (C) t test. (A and C) n = 3, F = 6.7, t = 3.8, df = 2,4. (B) Hap1, Mef; n = 4,4; F = 37.8, 104.5; df = 2. (D) n = 4; F = 95.5; df = 2, (E) n = 5, F = 248.2, df = 2. See complete unedited blots in the supplemental material.