Low doses of sodium iodate (NaIO3) impair visual function in experimental animals with selective damage to retinal pigment epithelium (RPE) and serve as a useful model to study diseases caused by RPE degeneration. Mitochondrial dysfunction and defective autophagy have been suggested to play important roles in normal aging as well as many neurodegenerative diseases. In this study, we examined whether NaIO3 treatment disrupted the mitochondrial-lysosomal axis in cultured RPE.
Methods:
The human RPE cell line, ARPE-19, was treated with low concentrations (≤500 μM) of NaIO3. The expression of proteins involved in the autophagic pathway and mitochondrial biogenesis was examined with Western blot. Intracellular acidic compartments and lipofuscinogenesis were evaluated by acridine orange staining and autofluorescence, respectively. Mitochondrial mass, mitochondrial membrane potential (MMP), and mitochondrial function were quantified by MitoTracker Green staining, tetramethylrhodamine methyl ester staining, and the MTT assay, respectively. Phagocytosis and the degradation of photoreceptor outer segments (POS) were assessed by fluorescence-based approaches and Western blot against rhodopsin.
Results:
Treatment with low concentrations of NaIO3 decreased cellular acidity, blocked autophagic flux, and resulted in increased lipofuscinogenesis in ARPE-19 cells. Despite increases in protein levels of Sirtuin 1 and PGC-1α, mitochondrial function was compromised, and this decrease was attributed to disrupted MMP. POS phagocytic activities decreased by 60% in NaIO3-treated cells, and the degradation of ingested POS was also impaired. Pretreatment and cotreatment with rapamycin partially rescued NaIO3-induced RPE dysfunction.
Conclusions:
Low concentrations of NaIO3 disrupted the mitochondrial-lysosomal axis in RPE and led to impaired phagocytic activities and degradation capacities.
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References
1.
BrunkU.T., and TermanA.The mitochondrial-lysosomal axis theory of aging: accumulation of damaged mitochondria as a result of imperfect autophagocytosis. Eur. J. Biochem., 269:1996–2002, 2002.
2.
KevanyB.M., and PalczewskiK.Phagocytosis of retinal rod and cone photoreceptors. Physiology (Bethesda). 25:8–15, 2010.
3.
ZarbinM.A.Current concepts in the pathogenesis of age-related macular degeneration. Arch. Ophthalmol., 122:598–614, 2004.
4.
van Lookeren CampagneM., LeCouterJ., YaspanB.L., and YeW.Mechanisms of age-related macular degeneration and therapeutic opportunities. J. Pathol., 232:151–164, 2014.
5.
JarrettS.G., LinH., GodleyB.F., and BoultonM.E.Mitochondrial DNA damage and its potential role in retinal degeneration. Prog. Retin. Eye Res., 27:596–607, 2008.
6.
MitterS.K., RaoH.V., QiX., CaiJ., SugrueA., DunnW.A.Jr., GrantM.B., and BoultonM.E.Autophagy in the retina: a potential role in age-related macular degeneration. Adv. Exp. Med. Biol., 723:83–90, 2012.
7.
TerlukM.R., KapphahnR.J., SoukupL.M., GongH., GallardoC., MontezumaS.R., and FerringtonD.A.Investigating mitochondria as a target for treating age-related macular degeneration. J. Neurosci., 35:7304–7311, 2015.
8.
FeherJ., KovacsI., ArticoM., CavallottiC., PapaleA., and Balacco GabrieliC.Mitochondrial alterations of retinal pigment epithelium in age-related macular degeneration. Neurobiol. Aging., 27:983–993, 2006.
9.
NordgaardC.L., BergK.M., KapphahnR.J., ReillyC., FengX., OlsenT.W., and FerringtonD.A.Proteomics of the retinal pigment epithelium reveals altered protein expression at progressive stages of age-related macular degeneration. Invest. Ophthalmol. Vis. Sci., 47:815–822, 2006.
10.
WangA.L., LukasT.J., YuanM., DuN., TsoM.O., and NeufeldA.H.Autophagy and exosomes in the aged retinal pigment epithelium: possible relevance to drusen formation and age-related macular degeneration. PLoS One. 4:e4160, 2009.
KrohneT.U., StratmannN.K., KopitzJ., and HolzF.G.Effects of lipid peroxidation products on lipofuscinogenesis and autophagy in human retinal pigment epithelial cells. Exp. Eye Res., 90:465–471, 2010.
13.
KimJ.Y., ZhaoH., MartinezJ., DoggettT.A., KolesnikovA.V., TangP.H., AblonczyZ., ChanC.C., ZhouZ., GreenD.R., and FergusonT.A.Noncanonical autophagy promotes the visual cycle. Cell. 154:365–376, 2013.
14.
GolestanehN., ChuY., XiaoY.Y., StoleruG.L., and TheosA.C.Dysfunctional autophagy in RPE, a contributing factor in age-related macular degeneration. Cell Death Dis. 8:e2537, 2017.
15.
SorsbyA.Experimental pigmentary degeneration of the retina by sodium iodate. Br. J. Ophthalmol., 25:58–62, 1941.
16.
EnzmannV., RowB.W., YamauchiY., KheirandishL., GozalD., KaplanH.J., and McCallM.A.Behavioral and anatomical abnormalities in a sodium iodate-induced model of retinal pigment epithelium degeneration. Exp. Eye Res., 82:441–448, 2006.
17.
KiuchiK., YoshizawaK., ShikataN., MoriguchiK., and TsuburaA.Morphologic characteristics of retinal degeneration induced by sodium iodate in mice. Curr. Eye Res., 25:373–379, 2002.
18.
FrancoL.M., ZulligerR., Wolf-SchnurrbuschU.E., KatagiriY., KaplanH.J., WolfS., and EnzmannV.Decreased visual function after patchy loss of retinal pigment epithelium induced by low-dose sodium iodate. Invest. Ophthalmol. Vis. Sci., 50:4004–4010, 2009.
19.
QinS., LuY., and RodriguesG.A.Resveratrol protects RPE cells from sodium iodate by modulating PPARα and PPARδ. Exp. Eye Res., 118:100–108, 2014.
20.
SachdevaM.M., CanoM., and HandaJ.T.Nrf2 signaling is impaired in the aging RPE given an oxidative insult. Exp. Eye Res., 119:111–114, 2014.
21.
KimJ.W., KangK.H., BurrolaP., MakT.W., and LemkeG.Retinal degeneration triggered by inactivation of PTEN in the retinal pigment epithelium. Genes Dev. 22:3147–3157, 2008.
22.
ZhaoC., YasumuraD., LiX., MatthesM., LloydM., NielsenG., AhernK., SnyderM., BokD., DunaiefJ.L., LaVailM.M., and VollrathD.mTOR-mediated dedifferentiation of the retinal pigment epithelium initiates photoreceptor degeneration in mice. J. Clin. Invest., 121:369–383, 2011.
23.
MachalinskaA., KawaM.P., Pius-SadowskaE., RoginskaD., KlosP., BaumertB., WiszniewskaB., and MachalinskiB.Endogenous regeneration of damaged retinal pigment epithelium following low dose sodium iodate administration: an insight into the role of glial cells in retinal repair. Exp. Eye Res., 112:68–78, 2013.
24.
ZhouP., KannanR., SpeeC., SreekumarP.G., DouG., and HintonD.R.Protection of retina by αB crystallin in sodium iodate induced retinal degeneration. PLoS One. 9:e98275, 2014.
25.
ZhangJ., ZhaoX., CaiY., LiY., YuX., and LuL.Protection of retina by Mini-αA in NaIO(3)-induced retinal pigment epithelium degeneration mice. Int. J. Mol. Sci., 16:1644–1656, 2015.
26.
ZhangX.-Y., NgT.K., BrelénM.E., WuD., WangJ.X., ChanK.P., YungJ.S.Y., CaoD., WangY., ZhangS., ChanS.O., and PangC.P.Continuous exposure to non-lethal doses of sodium iodate induces retinal pigment epithelial cell dysfunction. Sci. Rep., 6:37279, 2016.
27.
LinC.J., LeeC.C., ShihY.L., LinT.Y., WangS.H., LinY.F., and ShihC.M.Resveratrol enhances the therapeutic effect of temozolomide against malignant glioma in vitro and in vivo by inhibiting autophagy. Free Radic. Biol. Med., 52:377–391, 2012.
28.
PaglinS., HollisterT., DeloheryT., HackettN., McMahillM., SphicasE., DomingoD., and YahalomJ.A novel response of cancer cells to radiation involves autophagy and formation of acidic vesicles. Cancer Res. 61:439–444, 2001.
29.
YakesF.M., and Van HoutenB.Mitochondrial DNA damage is more extensive and persists longer than nuclear DNA damage in human cells following oxidative stress. Proc. Natl. Acad. Sci. U. S. A., 94:514–519, 1997.
30.
KrohneT.U., HolzF.G., and KopitzJ.Apical-to-basolateral transcytosis of photoreceptor outer segments induced by lipid peroxidation products in human retinal pigment epithelial cells. Invest. Ophthalmol. Vis. Sci., 51:553–560, 2010.
31.
MoldayR.S., HicksD., and MoldayL.Peripherin. A rim-specific membrane protein of rod outer segment discs. Invest. Ophthalmol. Vis. Sci., 28:50–61, 1987.
32.
MaoY., and FinnemannS.C.Analysis of photoreceptor outer segment phagocytosis by RPE cells in culture. Methods Mol. Biol., 935:285–295, 2013.
33.
WangJ., IacovelliJ., SpencerC., and Saint-GeniezM.Direct effect of sodium iodate on neurosensory retina. Invest. Ophthalmol. Vis. Sci., 55:1941–1953, 2014.
34.
MizushimaN., YoshimoriT., and LevineB.Methods in mammalian autophagy research. Cell. 140:313–326, 2010.
35.
YoonY.H., ChoK.S., HwangJ.J., LeeS.-J., ChoiJ.A., and KohJ.-Y.Induction of lysosomal dilatation, arrested autophagy, and cell death by chloroquine in cultured ARPE-19 Cells. Invest. Ophthalmol. Vis. Sci., 51:6030–6037, 2010.
36.
KomenJ.C., and ThorburnD.R.Turn up the power—pharmacological activation of mitochondrial biogenesis in mouse models. Br. J. Pharmacol., 171:1818–1836, 2014.
37.
EdwardsR.B., and SzamierR.B.Defective phagocytosis of isolated rod outer segments by RCS rat retinal pigment epithelium in culture. Science. 197:1001–1003, 1977.
38.
DuncanJ.L., LaVailM.M., YasumuraD., MatthesM.T., YangH., TrautmannN., ChappelowA.V., FengW., EarpH.S., MatsushimaG.K., and VollrathD.An RCS-like retinal dystrophy phenotype in mer knockout mice. Invest. Ophthalmol. Vis. Sci., 44:826–838, 2003.
39.
MustafiD., KevanyB.M., GenoudC., OkanoK., CideciyanA.V., SumarokaA., RomanA.J., JacobsonS.G., EngelA., AdamsM.D., and PalczewskiK.Defective photoreceptor phagocytosis in a mouse model of enhanced S-cone syndrome causes progressive retinal degeneration. FASEB J. 25:3157–3176, 2011.
40.
RajappaM., GoyalA., and KaurJ.Inherited metabolic disorders involving the eye: a clinico-biochemical perspective. Eye (Lond.)., 24:507–518, 2010.
41.
GeisowM.J.Fluorescein conjugates as indicators of subcellular pH. A critical evaluation. Exp. Cell Res., 150:29–35, 1984.
42.
TermanA., KurzT., NavratilM., ArriagaE.A., and BrunkU.T.Mitochondrial turnover and aging of long-lived postmitotic cells: the mitochondrial-lysosomal axis theory of aging. Antioxid. Redox. Signal., 12:503–535, 2010.
43.
CarrollB., HewittG., and KorolchukV.I.Autophagy and ageing: implications for age-related neurodegenerative diseases. Essays Biochem. 55:119–131, 2013.
44.
KroemerG.Autophagy: a druggable process that is deregulated in aging and human disease. J. Clin. Invest., 125:1–4, 2015.
45.
GamerdingerM., HajievaP., KayaA.M., WolfrumU., HartlF.U., and BehlC.Protein quality control during aging involves recruitment of the macroautophagy pathway by BAG3. EMBO J. 28:889, 2009.
46.
WohlgemuthS.E., SeoA.Y., MarzettiE., LeesH.A., and LeeuwenburghC.Skeletal muscle autophagy and apoptosis during aging: effects of calorie restriction and life-long exercise. Exp. Gerontol., 45:138–148, 2010.
47.
BordiM., BergM.J., MohanP.S., PeterhoffC.M., AlldredM.J., CheS., GinsbergS.D., and NixonR.A.Autophagy flux in CA1 neurons of Alzheimer hippocampus: Increased induction overburdens failing lysosomes to propel neuritic dystrophy. Autophagy. 12:2467–2483, 2016.
48.
BraticA., and LarssonN.-G.The role of mitochondria in aging. J. Clin. Invest., 123:951–957, 2013.
49.
SunN., YouleR.J., and FinkelT.The mitochondrial basis of aging. Mol. Cell., 61:654–666, 2016.
50.
KwongL.K., and SohalR.S.Age-related changes in activities of mitochondrial electron transport complexes in various tissues of the mouse. Arch. Biochem. Biophys., 373:16–22, 2000.
51.
NavarroA., GomezC., Sanchez-PinoM.J., GonzalezH., BandezM.J., BoverisA.D., and BoverisA.Vitamin E at high doses improves survival, neurological performance, and brain mitochondrial function in aging male mice. Am. J. Physiol. Regul. Integr. Comp. Physiol., 289:R1392–R1399, 2005.
52.
GkotsiD., BegumR., SaltT., LascaratosG., HoggC., ChauK.Y., SchapiraA.H., and JefferyG.Recharging mitochondrial batteries in old eyes. Near infra-red increases ATP. Exp. Eye Res., 122:50–53, 2014.
53.
HuangH.-M., FowlerC., XuH., ZhangH., and GibsonG.E.Mitochondrial function in fibroblasts with aging in culture and/or Alzheimer's disease. Neurobiol. Aging., 26:839–848, 2005.
54.
PaascheG., GartnerU., GermerA., GroscheJ., and ReichenbachA.Mitochondria of retinal Muller (glial) cells: the effects of aging and of application of free radical scavengers. Ophthalmic Res. 32:229–236, 2000.
55.
GomesA.P., PriceN.L., LingA.J., MoslehiJ.J., MontgomeryM.K., RajmanL., WhiteJ.P., TeodoroJ.S., WrannC.D., HubbardB.P., MerckenE.M., PalmeiraC.M., de CaboR., RoloA.P., TurnerN., BellE.L., and SinclairD.A.Declining NAD(+) induces a pseudohypoxic state disrupting nuclear-mitochondrial communication during aging. Cell. 155:1624–1638, 2013.
56.
SczeleckiS., Besse-PatinA., AbboudA., KleinerS., Laznik-BogoslavskiD., WrannC.D., RuasJ.L., Haibe-KainsB., and EstallJ.L.Loss of Pgc-1alpha expression in aging mouse muscle potentiates glucose intolerance and systemic inflammation. Am. J. Physiol. Endocrinol. Metab., 306:E157–E167, 2014.
57.
SalminenA., KaarnirantaK., and KauppinenA.Crosstalk between oxidative stress and SIRT1: impact on the aging process. Int. J. Mol. Sci., 14:3834–3859, 2013.
58.
St-PierreJ., DroriS., UldryM., SilvaggiJ.M., RheeJ., JagerS., HandschinC., ZhengK., LinJ., YangW., SimonD.K., BachooR., and SpiegelmanB.M.Suppression of reactive oxygen species and neurodegeneration by the PGC-1 transcriptional coactivators. Cell. 127:397–408, 2006.
59.
BonnardC., DurandA., PeyrolS., ChanseaumeE., ChauvinM.-A., MorioB., VidalH., and RieussetJ.Mitochondrial dysfunction results from oxidative stress in the skeletal muscle of diet-induced insulin-resistant mice. J. Clin. Invest., 118:789–800, 2008.
60.
Vayssier-TaussatM., KrepsS.E., AdrieC., Dall'AvaJ., ChristianiD., and PollaB.S.Mitochondrial membrane potential: a novel biomarker of oxidative environmental stress. Environ. Health Perspect., 110:301–305, 2002.
61.
Vives-BauzaC., AnandM., ShiraziA.K., MagraneJ., GaoJ., Vollmer-SnarrH.R., ManfrediG., and FinnemannS.C.The age lipid A2E and mitochondrial dysfunction synergistically impair phagocytosis by retinal pigment epithelial cells. J. Biol. Chem., 283:24770–24780, 2008.
62.
PennesiM.E., NeuringerM., and CourtneyR.J.Animal models of age related macular degeneration. Mol. Aspects Med., 33:487–509, 2012.
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