Reversal of ciliary mechanisms of disassembly rescues olfactory dysfunction in ciliopathies
Chao Xie, … , Robert J. Campbell, Jeffrey R. Martens
Chao Xie, … , Robert J. Campbell, Jeffrey R. Martens
Published June 30, 2022
Citation Information: JCI Insight. 2022;7(15):e158736. https://doi.org/10.1172/jci.insight.158736.
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Research Article Cell biology Genetics

Reversal of ciliary mechanisms of disassembly rescues olfactory dysfunction in ciliopathies

Abstract

Ciliopathies are a class of genetic diseases resulting in cilia dysfunction in multiple organ systems, including the olfactory system. Currently, there are no available curative treatments for olfactory dysfunction and other symptoms in ciliopathies. The loss or shortening of olfactory cilia, as seen in multiple mouse models of the ciliopathy Bardet–Biedl syndrome (BBS), results in olfactory dysfunction. However, the underlying mechanism of the olfactory cilia reduction is unknown, thus limiting the development of therapeutic approaches for BBS and other ciliopathies. Here, we demonstrated that phosphatidylinositol 4,5-bisphosphate [PI(4,5)P2], a phosphoinositide typically excluded from olfactory cilia, aberrantly redistributed into the residual cilia of BBS mouse models, which caused F-actin ciliary infiltration. Importantly, PI(4,5)P2 and F-actin were necessary for olfactory cilia shortening. Using a gene therapeutic approach, the hydrolyzation of PI(4,5)P2 by overexpression of inositol polyphosphate-5-phosphatase E (INPP5E) restored cilia length and rescued odor detection and odor perception in BBS. Together, our data indicate that PI(4,5)P2/F-actin–dependent cilia disassembly is a common mechanism contributing to the loss of olfactory cilia in BBS and provide valuable pan-therapeutic intervention targets for the treatment of ciliopathies.

Authors

Chao Xie, Julien C. Habif, Kirill Ukhanov, Cedric R. Uytingco, Lian Zhang, Robert J. Campbell, Jeffrey R. Martens

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Figure 4

F-actin infiltrates olfactory cilia in Bbs4KO, which is necessary for Bbs4KO olfactory cilia shortening.

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F-actin infiltrates olfactory cilia in Bbs4KO, which is necessary for Bb...
Representative en face images of F-actin (Lifeact7-GFP) ciliary distribution in the WT (A) and Bbs4KO (B) OSNs. The WT and Bbs4KO mice were coinfected with MP-mCherry and Lifeact7-GFP AV and used for en face imaging 10 days after virus infection. MP-mCherry was used to label the full length of the olfactory cilia. Lifeact7-GFP was used to label the endogenous F-actin. (A) F-actin was excluded from the olfactory cilia in the WT group. (B) F-actin lost its restriction in the knob of OSN and was redistributed in the olfactory cilia in Bbs4KO. Scale bars, 10 μm. (C) Quantification data showing that the percentage of F-actin–positive cilia (F-actin–positive cilia/total cilia number × 100) was significantly increased in the Bbs4KO group (n = 38 OSNs; 77.32 ± 2.494) compared with the WT group (n = 34 OSNs; 10.37 ± 1.615). Unpaired t test, ****P < 0.0001. (D) The relative F-actin–positive cilia length (F-actin–positive cilia length/full cilia length × 100) was significantly increased in Bbs4KO (n = 272 cilia from 38 OSNs; 66.31 ± 2.531) compared with the WT group (n = 597 cilia from 34 OSNs; 1.751 ± 0.3133). Unpaired t test, ****P < 0.0001. (E) Representative en face images of the 5HT6-YFP-Tβ4–treated (left) and 5HT6-YFP-Tβ4 (K18E/K19E)–treated (i.e., the actin-binding mutant) (right) Bbs4KO olfactory cilia. Scale bars, 10 μm. (F) Quantification of olfactory cilia length showed that Bbs4KO olfactory cilia length was partially rescued by 5HT6-YFP-Tβ4 treatment (5HT6-YFP-Tβ4 [n = 51 OSNs] vs. 5HT6-YFP-Tβ4 (K18E/K19E) [n = 25 OSNs]: 15.60 ± 0.5596 vs. 8.448 ± 0.4769, respectively). Unpaired t test, ****P < 0.0001. Values represent mean ± SEM.