Altered trafficking and stability of polycystins underlie polycystic kidney disease
Yiqiang Cai, … , Barbara E. Ehrlich, Stefan Somlo
Yiqiang Cai, … , Barbara E. Ehrlich, Stefan Somlo
Published November 3, 2014
Citation Information: J Clin Invest. 2014;124(12):5129-5144. https://doi.org/10.1172/JCI67273.
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Research Article Nephrology

Altered trafficking and stability of polycystins underlie polycystic kidney disease

Abstract

The most severe form of autosomal dominant polycystic kidney disease occurs in patients with mutations in the gene (PKD1) encoding polycystin-1 (PC1). PC1 is a complex polytopic membrane protein expressed in cilia that undergoes autoproteolytic cleavage at a G protein–coupled receptor proteolytic site (GPS). A quarter of PKD1 mutations are missense variants, though it is not clear how these mutations promote disease. Here, we established a cell-based system to evaluate these mutations and determined that GPS cleavage is required for PC1 trafficking to cilia. A common feature among a subset of pathogenic missense mutations is a resulting failure of PC1 to traffic to cilia regardless of GPS cleavage. The application of our system also identified a missense mutation in the gene encoding polycystin-2 (PC2) that prevented this protein from properly trafficking to cilia. Using a Pkd1-BAC recombineering approach, we developed murine models to study the effects of these mutations and confirmed that only the cleaved form of PC1 exits the ER and can rescue the embryonically lethal Pkd1-null mutation. Additionally, steady-state expression levels of the intramembranous COOH-terminal fragment of cleaved PC1 required an intact interaction with PC2. The results of this study demonstrate that PC1 trafficking and expression require GPS cleavage and PC2 interaction, respectively, and provide a framework for functional assays to categorize the effects of missense mutations in polycystins.

Authors

Yiqiang Cai, Sorin V. Fedeles, Ke Dong, Georgia Anyatonwu, Tamehito Onoe, Michihiro Mitobe, Jian-Dong Gao, Dayne Okuhara, Xin Tian, Anna-Rachel Gallagher, Zhangui Tang, Xiaoli Xie, Maria D. Lalioti, Ann-Hwee Lee, Barbara E. Ehrlich, Stefan Somlo

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Figure 1

N-glycosylation and surface expression of PC1.

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N-glycosylation and surface expression of PC1. (A) LLC-PK1 cell lysates ...
(A) LLC-PK1 cell lysates expressing PC1 with NH2-terminal triple-FLAG and COOH-terminal triple-HA epitope tags underwent IP with either nonimmune IgG (IgG) or anti-HA (HA) and IB with anti-HA (left) and anti-FLAG (right). The 2 panels are from a single gel and show PC1-NTF (NTF), PC1-CTF (CTF), and uncleaved full-length PC1 (FL). (B) PC1 IP followed by digestion with endo H, PNGase F (PNG F), or reaction buffer (Control). Panels at right are magnifications of the left panel (original magnification, ×2). PC1-CTF shows endo H–resistant (+) and –sensitive (*) products. PC1-FL shows complete endo H sensitivity. (C) IP of PC1 by anti-FLAG coimmunoprecipitated the endo H–sensitive fraction of PC1-CTF, indicative of the intracellular PC1-NTF/PC1-CTF pool. (D) Shedding of PC1-NTF into the culture medium may explain the absence of a detectable cell-surface PC1-NTF/PC1-CTF complex. Medium was either run directly (No IP) or subjected to IP prior to IB. Lysate, total cell lysate. (E) LLC-PK1 cells grown on semipermeable supports selectively labeled with biotin on the apical or basal surface. Total lysates (left panel) and streptavidin-precipitated biotinylated proteins (right panel) were run on a single gel and analyzed by IB with anti-HA (upper 2 panels) and anti–Na-K-ATPase (lower panel). PC1-CTF was biotinylated on the apical surface. Na-K-ATPase served as a positive control for the basal surface. (F) GPS cleavage–deficient PC1L3040H was entirely endo H sensitive, suggesting that it did not traffic past the middle Golgi apparatus in cells; the 2 panels show noncontiguous lanes on a single gel.