mTOR-mediated dedifferentiation of the retinal pigment epithelium initiates photoreceptor degeneration in mice
Chen Zhao, … , Matthew M. LaVail, Douglas Vollrath
Chen Zhao, … , Matthew M. LaVail, Douglas Vollrath
Published December 6, 2010
Citation Information: J Clin Invest. 2011;121(1):369-383. https://doi.org/10.1172/JCI44303.
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mTOR-mediated dedifferentiation of the retinal pigment epithelium initiates photoreceptor degeneration in mice

Abstract

Retinal pigment epithelial (RPE) cell dysfunction plays a central role in various retinal degenerative diseases, but knowledge is limited regarding the pathways responsible for adult RPE stress responses in vivo. RPE mitochondrial dysfunction has been implicated in the pathogenesis of several forms of retinal degeneration. Here we have shown that postnatal ablation of RPE mitochondrial oxidative phosphorylation in mice triggers gradual epithelium dedifferentiation, typified by reduction of RPE-characteristic proteins and cellular hypertrophy. The electrical response of the retina to light decreased and photoreceptors eventually degenerated. Abnormal RPE cell behavior was associated with increased glycolysis and activation of, and dependence upon, the hepatocyte growth factor/met proto-oncogene pathway. RPE dedifferentiation and hypertrophy arose through stimulation of the AKT/mammalian target of rapamycin (AKT/mTOR) pathway. Administration of an oxidant to wild-type mice also caused RPE dedifferentiation and mTOR activation. Importantly, treatment with the mTOR inhibitor rapamycin blunted key aspects of dedifferentiation and preserved photoreceptor function for both insults. These results reveal an in vivo response of the mature RPE to diverse stressors that prolongs RPE cell survival at the expense of epithelial attributes and photoreceptor function. Our findings provide a rationale for mTOR pathway inhibition as a therapeutic strategy for retinal degenerative diseases involving RPE stress.

Authors

Chen Zhao, Douglas Yasumura, Xiyan Li, Michael Matthes, Marcia Lloyd, Gregory Nielsen, Kelly Ahern, Michael Snyder, Dean Bok, Joshua L. Dunaief, Matthew M. LaVail, Douglas Vollrath

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Figure 8

Rapamycin inhibits mTOR/S6K-mediated RPE dedifferentiation and subsequent retinal degeneration induced by NaIO3 in B6 mice.

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Rapamycin inhibits mTOR/S6K-mediated RPE dedifferentiation and subsequen...
(A) Immunoblot of proteins from eyecups shows elevated phosphorylation of P70SK6Thr389 and S6Ser235/236 and loss of RPE markers 2 days PI of NaIO3 (2 middle lanes). (B) At day 5 PI, an immunoblot detects persistent activation of P70SK6Thr389 and S6Ser235/236 and diminished RPE markers in isolated RPE cells (middle lane). The effects are inhibited by rapamycin treatment (A, 2 right lanes; B, right lane). (C) Quantification of RPE proteins 5 days PI of NaIO3 (triplicates) shows preservation of several RPE markers after rapamycin treatment (red bars) (normalized to PBS and vehicle-treated controls). (D and E) Quantification of the length of normal retina (RPE and neural retina) at PI days 17 and 20 (D), and outer nuclear layer thickness and cone density at PI day 17 (E). Rapamycin treatment (red bars, n = 6) results in a striking preservation of retinal morphology relative to that of vehicle treatment (green bars, n = 6) in NaIO3-injected mice. In E, the mean value of outer nuclear layer and cones of vehicle-treated mice was defined as 1. Data represent the relative fold increase of the corresponding value obtained from rapamycin-treated, NaIO3-injected mice. (F) Electroretinography demonstrates significantly increased scotopic and photopic responses at PI day 17 in NaIO3-injected B6 mice treated with rapamycin (red, n = 5), compared with those in vehicle-treated NaIO3-injected controls (green, n = 6). The dashed curve represents control mice (PBS + vehicle, n = 7). Verticle bars clarify the 2 groups of values used for statistical comparison. Data represent mean ± SEM. *P < 0.05; §P < 0.01; #P < 0.001.