Hyperosmotic stimuli activate polycystin proteins to aid in urine concentration
Karla M. Márquez-Nogueras, Ryne M. Knutila, Virdjinija Vuchkovska, Charlie Yang, Patricia Outeda, Darren P. Wallace, Ivana Y. Kuo
Karla M. Márquez-Nogueras, Ryne M. Knutila, Virdjinija Vuchkovska, Charlie Yang, Patricia Outeda, Darren P. Wallace, Ivana Y. Kuo
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Research Article Cell biology Nephrology

Hyperosmotic stimuli activate polycystin proteins to aid in urine concentration

Abstract

Autosomal dominant polycystic kidney disease (ADPKD) is caused by mutations in PKD1 or PKD2, which encode polycystin-1 (PC1) and polycystin-2 (PC2), respectively. These proteins are thought to form a signaling complex that can flux cations, including calcium. One of the earliest symptoms in ADPKD is a decline in the concentrating ability of the kidneys, occurring prior to cyst formation. We reasoned that hyperosmolality stimulates the polycystin complex, and that the loss of this function impairs water reabsorption. We found that hyperosmolality resulted in the phosphorylation of microtubule-associated protein 4 (MAP4) in a PC1-dependent manner, which then elicited ER-localized PC2 calcium signals. ER-localized PC2 hyperosmotic calcium signals were required for trafficking of the water channel aquaporin (AQP2). Precystic PC1-KO and PC2-KO murine kidneys had cytosol-localized AQP2 and diluted urine compared with their respective controls. Kidney tissue sections from ADPKD patients showed decreased AQP2 apical membrane localization in cystic and noncystic tubules. Our study demonstrates that osmolality is a physiological stimulus of the polycystin complex, and loss of polycystin osmosensing results in impaired water reabsorption via AQP2. This likely contributes to the declined concentrating ability of the kidneys and high circulating vasopressin levels in patients with ADPKD.

Authors

Karla M. Márquez-Nogueras, Ryne M. Knutila, Virdjinija Vuchkovska, Charlie Yang, Patricia Outeda, Darren P. Wallace, Ivana Y. Kuo

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Figure 2

Hyperosmotic stimuli induce ER-localized PC2 calcium release.

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Hyperosmotic stimuli induce ER-localized PC2 calcium release. (A) Diagra...
(A) Diagram of the different genetic calcium indicators used for calcium measurements. (B) Representative images of cytosolic calcium (red) increase but not ciliary calcium (green) in IMCD3 CTL cells. Scale bar: 10 μm. (C) Ciliary calcium did not increase in CTL C2C12 cells after stimulation with 400 mOsm but did increase with ionomycin (1 μM), representative of n = 6. (D) Representative images of C2C12 CTL cells expressing the plasma membrane calcium indicator (gCaMP7s-CAAX, top panels) and ER calcium indicator (R-CEPIA, bottom panels). Scale bar: 10 μm. (E) Representative traces of simultaneous calcium changes in R-CEPIA (red line, region a) and plasma membrane calcium (green line, region b) in C2C12 CTL cells after hyperosmotic stimulus. White region on the left indicates ER calcium drops after hyperosmotic stimuli. Green region on the right indicates plasma membrane calcium spark. (F) Membrane calcium AUC decreased in PC2-KO cells. n = 12. Statistical analysis by Mann-Whitney U test. Dark dots represent biological replicates, while light dots represent individual cells. (G) Representative trace of cytosolic calcium changes in CTL (black line), PC2-KO (red line), and PC2-KO+D511V-PC2 variant (orange line) C2C12 cells. (H) Reexpression of full-length PC2 (OE), but not D511V variant, restored the cytosolic calcium response in the C2C12 PC2-KO cells. n = 10–30. Statistical analysis determined by a Kruskal-Wallis test followed by Dunn’s test. Bar graphs represent mean ± SEM. Dark dots represent biological replicates, while light dots represent individual cells. P values listed in each panel.