Nonretinoid chaperones improve rhodopsin homeostasis in a mouse model of retinitis pigmentosa
Abhishek Vats, Yibo Xi, Bing Feng, Owen D. Clinger, Anthony J. St. Leger, Xujie Liu, Archisha Ghosh, Chase D. Dermond, Kira L. Lathrop, Gregory P. Tochtrop, Serge Picaud, Yuanyuan Chen
Abhishek Vats, Yibo Xi, Bing Feng, Owen D. Clinger, Anthony J. St. Leger, Xujie Liu, Archisha Ghosh, Chase D. Dermond, Kira L. Lathrop, Gregory P. Tochtrop, Serge Picaud, Yuanyuan Chen
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Research Article Neuroscience Ophthalmology

Nonretinoid chaperones improve rhodopsin homeostasis in a mouse model of retinitis pigmentosa

Abstract

Rhodopsin-associated (RHO-associated) retinitis pigmentosa (RP) is a progressive retinal disease that currently has no cure. RHO protein misfolding leads to disturbed proteostasis and the death of rod photoreceptors, resulting in decreased vision. We previously identified nonretinoid chaperones of RHO, including YC-001 and F5257-0462, by small-molecule high-throughput screening. Here, we profile the chaperone activities of these molecules toward the cell-surface level of 27 RP-causing human RHO mutants in NIH3T3 cells. Furthermore, using retinal explant culture, we show that YC-001 improves retinal proteostasis by supporting RHO homeostasis in RhoP23H/+ mouse retinae, which results in thicker outer nuclear layers (ONL), indicating delayed photoreceptor degeneration. Interestingly, YC-001 ameliorated retinal immune responses and reduced the number of microglia/macrophages in the RhoP23H/+ retinal explants. Similarly, F5257-0462 also protects photoreceptors in RhoP23H/+ retinal explants. In vivo, intravitreal injection of YC-001 or F5257-0462 microparticles in PBS shows that F5257-0462 has a higher efficacy in preserving photoreceptor function and delaying photoreceptor death in RhoP23H/+ mice. Collectively, we provide proof of principle that nonretinoid chaperones are promising drug candidates in treating RHO-associated RP.

Authors

Abhishek Vats, Yibo Xi, Bing Feng, Owen D. Clinger, Anthony J. St. Leger, Xujie Liu, Archisha Ghosh, Chase D. Dermond, Kira L. Lathrop, Gregory P. Tochtrop, Serge Picaud, Yuanyuan Chen

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Figure 1

Pharmacological chaperones rescue numerous rhodopsin (RHO) mutants trafficking to the plasma membrane in vitro.

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Pharmacological chaperones rescue numerous rhodopsin (RHO) mutants traff...
NIH3T3 cells transfected with hRHO mutants were treated with either DMSO as vehicle control, 5 μM 9-cis-retinal, 40 μM YC-001, or 20 μM F5257-0462 for 24 hours, and high-content images were taken for RHO immunofluorescence on the cell surface. (A) Heatmap of cell surface immunofluorescence intensity of WT and 27 RHO mutants per cell under different treatments. n = 3, red **** under DMSO, P < 0.0001 comparing any mutants versus RHOWT with DMSO by 1-way ANOVA. In the heatmap, *, **, ***, and **** signify P < 0.05, 0.01, 0.001, and 0.0001, respectively, comparing compound treated versus DMSO by the Kruskal-Wallis test followed by a multiple comparison test. Black and red asterisks represent significantly higher or lower levels, respectively, in compound treated versus DMSO. WT and RHO mutants that were seen on the plasma membrane under all conditions are marked in red (PM); mutants unseen on the cell surface under any condition are marked in blue (ER); and mutants absent on the cell surface under DMSO treatment but rescued to the plasma membrane by at least 1 pharmacological chaperone are marked in yellow (ER-PM). N-term loop, N-terminal loop; ECL, extracellular loop; TM, transmembrane helix. (B) Representative immunofluorescence cell-surface staining of WT and mutant RHO (italics in A). Scale bar: 50 μm. Chemical structures are shown on the top. All images are shown in Supplemental Figure 1. (C) Residues that were mutated are color labeled on the crystal structure of bovine RHO (PDB ID:1f88). Orange sticks, 11-cis-retinal.