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Retinol tracing within murine neural retina reveals cell type–specific retinol transport and distribution
Zachary J. Engfer, Grazyna Palczewska, Samuel W. Du, Jianye Zhang, Zhiqian Dong, Carolline Rodrigues Menezes, Jun Wang, Jianming Shao, Budd A. Tucker, Robert F. Mullins, Rui Chen, Philip D. Kiser, Krzysztof Palczewski
Zachary J. Engfer, Grazyna Palczewska, Samuel W. Du, Jianye Zhang, Zhiqian Dong, Carolline Rodrigues Menezes, Jun Wang, Jianming Shao, Budd A. Tucker, Robert F. Mullins, Rui Chen, Philip D. Kiser, Krzysztof Palczewski
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Research Article Cell biology Ophthalmology

Retinol tracing within murine neural retina reveals cell type–specific retinol transport and distribution

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Abstract

11-cis-Retinal is essential for light perception in mammalian photoreceptors (PRs), and aberrations in retinoid transformations cause severe retinal diseases. Understanding these processes is crucial for combating blinding diseases. The visual cycle, operating within PRs and the retinal pigment epithelium (RPE), regenerates 11-cis-retinal to sustain light sensitivity. Retinoids are also present in Müller glia (MG), hypothesized to supply 11-cis-retinol to cone PRs and retinal ganglion cells (RGCs). To trace retinoid movement through retinal cell types, we used cell-specific knockin of lecithin:retinol acyltransferase (LRAT), which converts retinols into stable retinyl esters (REs). Ectopic LRAT expression in murine PRs, MG, and RGCs resulted in RE synthesis, with REs differing in abundance and isomeric composition across cell types under genetic and light-based perturbations. PR inner segments showed high 11-cis-RE content, suggesting a constant 11-cis-retinoid supply for pigment regeneration. In MG expressing LRAT, all-trans-REs were detected, contrasting with 11-cis-REs in PRs. The MG-specific LRAT phenotype mirrored the RE-rich human neural retina, suggesting human MG may utilize LRAT to maintain retinoid reservoirs. Our findings reveal tightly controlled retinoid flux throughout the mammalian retina that supports sustained vision, expanding understanding of the visual cycle to combat retinal diseases.

Authors

Zachary J. Engfer, Grazyna Palczewska, Samuel W. Du, Jianye Zhang, Zhiqian Dong, Carolline Rodrigues Menezes, Jun Wang, Jianming Shao, Budd A. Tucker, Robert F. Mullins, Rui Chen, Philip D. Kiser, Krzysztof Palczewski

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Figure 3

RE structures in mice expressing LRAT under the Gcap1 promoter.

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RE structures in mice expressing LRAT under the Gcap1 promoter.
(A) Cros...
(A) Cross-sectional diagram of the outer retina indicating the RPE, PR-IS (labeled as PR), and outer plexiform layer (OPL). Retinosome-like structures are represented by green oval shapes. (B) TP imaging of intact mouse eyes. Images show examples of 3D retinal visualizations, assembled from 56 frames and acquired every 2 μm along the retinal thickness. The RPE is at z = 0 μm. The top right inset images display RPE en face, and the bottom right inset images display the maximum projection through the PRs. Axes are labeled in μm; inset images correspond to the same region as the 3D reconstructions. Scale bars: 50 μm. (C) Calculated area of PR retinosome-like structures as a function of genotype, quantified in maximum projection images, starting 14 μm beneath the RPE and culminating 110 μm beneath the RPE. Data are shown as the mean ± SD. Significant results are provided, *P ≤ 0.05; **P ≤ 0.01; ***P ≤ 0.001; ****P ≤ 0.0001, Tukey’s multiple comparisons tests post 1-way ANOVA.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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