NR2E3 loss disrupts photoreceptor cell maturation and fate in human organoid models of retinal development
Nathaniel K. Mullin, … , Edwin M. Stone, Budd A. Tucker
Nathaniel K. Mullin, … , Edwin M. Stone, Budd A. Tucker
Published April 23, 2024
Citation Information: J Clin Invest. 2024;134(11):e173892. https://doi.org/10.1172/JCI173892.
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Research Article Development Ophthalmology

NR2E3 loss disrupts photoreceptor cell maturation and fate in human organoid models of retinal development

Abstract

While dysfunction and death of light-detecting photoreceptor cells underlie most inherited retinal dystrophies, knowledge of the species-specific details of human rod and cone photoreceptor cell development remains limited. Here, we generated retinal organoids carrying retinal disease–causing variants in NR2E3, as well as isogenic and unrelated controls. Organoids were sampled using single-cell RNA sequencing (scRNA-Seq) across the developmental window encompassing photoreceptor specification, emergence, and maturation. Using scRNA-Seq data, we reconstruct the rod photoreceptor developmental lineage and identify a branch point unique to the disease state. We show that the rod-specific transcription factor NR2E3 is required for the proper expression of genes involved in phototransduction, including rhodopsin, which is absent in divergent rods. NR2E3-null rods additionally misexpress several cone-specific phototransduction genes. Using joint multimodal single-cell sequencing, we further identify putative regulatory sites where rod-specific factors act to steer photoreceptor cell development. Finally, we show that rod-committed photoreceptor cells form and persist throughout life in a patient with NR2E3-associated disease. Importantly, these findings are strikingly different from those observed in Nr2e3 rodent models. Together, these data provide a road map of human photoreceptor development and leverage patient induced pluripotent stem cells to define the specific roles of rod transcription factors in photoreceptor cell emergence and maturation in health and disease.

Authors

Nathaniel K. Mullin, Laura R. Bohrer, Andrew P. Voigt, Lola P. Lozano, Allison T. Wright, Vera L. Bonilha, Robert F. Mullins, Edwin M. Stone, Budd A. Tucker

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Figure 2

Divergent rods emerge in NR2E3-null organoids.

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Divergent rods emerge in NR2E3-null organoids. (A) PHATE reduction showi...
(A) PHATE reduction showing cells within the photoreceptor lineage. Cells are colored by time point of sample collection. (B) Cells from NR2E3-null and control lines are annotated together based on time point and PHATE-derived cluster. (C) Cells annotated based on PHATE clustering from only the NR2E3-null line. (DF) The proportion of early and intermediate progenitors decreases uniformly across differentiation of all lines. (GI) The proportion of maturing cones follows differentiation time point in all lines. (J) All lines form early rod photoreceptors at D80 (arrow). (K and L) Only ND control and isogenic control lines form immature and mature rod photoreceptors at D120 and D160 (arrows). (M) Divergent rods emerge by D120 and are largely restricted to the NR2E3-null line (arrow). (N) NRL expression is plotted against pseudotime for each lineage on a log scale. NRL expression is observed at comparable levels in rod and divergent rod lineages and is induced at the same point in pseudotime. The pseudotime value at which NRL expression passes 1 is shown as tNRL. (O) NR2E3 expression level across pseudotime is shown. In addition to tNRL (NRL induction pseudotime point), the point at which NR2E3 expression passes 1 is shown as tNR2E3. The timing of NR2E3 induction is similar in rod and divergent rod lineages. (P) THRB expression level across pseudotime is shown.