Corneal disease is the fourth leading cause of blindness. According to the World Health Organization, roughly 1.6 million people globally are blind as a result of this disease. The only current treatment for corneal opacity is a corneal tissue transplant. Unfortunately, the demand for tissue exceeds supply, making a tissue-engineered in vitro cornea highly desirable. For an in vitro cornea to be useful, it must be transparent, which requires downregulation of the light-scattering intracellular protein alpha-smooth muscle actin (αSMA) and upregulation of the native corneal marker, aldehyde dehydrogenase 1A1 (ALDH1A1). This study focuses on the effects of a three-dimensional (3D) matrix on the expression levels of αSMA and ALDH1A1 by a subcultured population of rabbit corneal keratocytes and the comparison of the 3D matrix effects to other culture conditions. We show that, through western blot and quantitative real-time PCR, the presence of collagen strongly downregulates αSMA. Further, 3D cultures maintain low actin expression even in the presence of a proinflammatory cytokine, transforming growth factor-beta (TGF-β). Finally, 3D culture conditions show a partial recovery of ALDH1A1 expression, which has never been previously observed in a serum-exposed subcultured cell population. Overall, this study suggests that 3D culture is not only a relatively stronger signal than both collagen and TGF-β, it is also sufficient to induce some recovery of ALDH1A1 and the native corneal phenotype despite the presence of serum.
Get full access to this article
View all access options for this article.
References
1.
ResnikoffS., PascoliniD., MariottiS.P., PokharelG.P.Global magnitude of visual impairment caused by uncorrected refractive errors in 2004. Bull World Health Organ, 86:63. 2008.
2.
PascoliniD., MariottiS.P. Global estimats of visual impairment: 2010. Br J Opthalmol, 96:614. 2012.
McLaughlinC.R., TsaiR.J., LatorreM.A., GriffithM.Bioengineered corneas for transplantation and in vitro toxicology. Front Biosci, 14:3326. 2009.
5.
JesterJ.V.Corneal crystallins and the development of cellular transparency. Semin Cell Dev Biol, 19:82. 2008.
6.
WilsonS.E., MohanR.R., AmbrosioR.Jr., HongJ., LeeJ.The corneal wound healing response: cytokine-mediated interaction of the epithelium, stroma, and inflammatory cells. Prog Retin Eye Res, 20:625. 2001.
7.
WilsonS.E., LiuJ.J., MohanR.R.Stromal-epithelial interactions in the cornea. Prog Retin Eye Res, 18:293. 1999.
8.
StagosD., ChenY., CantoreM., JesterJ.V., VasiliouV.Corneal aldehyde dehydrogenases: multiple functions and novel nuclear localization. Brain Res Bull, 81:211. 2010
9.
MarchittiS.A., ChenY., ThompsonD.C., VasiliouV.Ultraviolet radiation: cellular antioxidant response and the role of ocular aldehyde dehydrogenase enzymes. Eye Contact Lens, 37:206. 2011.
10.
LassenN., BatemanJ.B., EsteyT., KuszakJ.R., NeesD.W., PiatigorskyJ., DuesterG., DayB.J., HuangJ., HinesL.M., VasiliouV.Multiple and additive functions of ALDH3A1 and ALDH1A1: Cataract phenotype and ocular oxidative damage in Aldh3a1(-/-)/Aldh1a1(-/-) knock-out mice. J Biol Chem, 282:25668. 2007
11.
MyrnaK.E., PotS.A., MurphyC.J.Meet the corneal myofibroblast: the role of myofibroblast transformation in corneal wound healing and pathology. Vet Ophthalmol, 12:25. 2009.
12.
FiniM.E.Keratocyte and fibroblast phenotypes in the repairing cornea. Prog Retin Eye Res, 18:529. 1999.
13.
PhuD., WrayL.S., WarrenR.V., HaskellR.C., OrwinE.J.Effect of substrate composition and alignment on corneal cell phenotype. Tissue Eng Part A, 17:799. 2011.
14.
Martinez-GarciaM.C., Merayo-LlovesJ., Blanco-MezquitaT., SardanaS.Wound healing following refractive surgery in hens. Exp Eye Res, 83:728. 2006.
15.
IvarsenA., LaurbergT., Moller-PedersenT.Role of keratocyte loss on corneal wound repair after LASIK. Invest Ophthalmol Vis Sci, 45:3499. 2004.
WatskyM.A., WeberK.T., SunY., PostlethwaiteA.New insights into the mechanism of fibroblast to myofibroblast transformation and associated pathologies. Int Rev Cell Mol Biol, 282:165. 2010.
18.
KawakitaT., EspanaE.M., HeH., SmiddyR., ParelJ.M., LiuC.Y., TsengS.C. Preservation and expansion of the primate keratocyte phenotype by downregulating TGF-beta signaling in a low-calcium, serum-free medium. Invest Ophthalmol Vis Sci, 47:1918. 2006.
19.
MasurS.K., DewalH.S., DinhT.T., ErenburgI., PetridouS.Myofibroblasts differentiate from fibroblasts when plated at low density. Proc Natl Acad Sci U S A, 93:4219. 1996.
20.
PetridouS., MaltsevaO., SpanakisS., MasurS.K.TGF-beta receptor expression and smad2 localization are cell density dependent in fibroblasts. Invest Ophthalmol Vis Sci, 41:89. 2000.
SowaM.B., ChrislerW.B., ZensK.D., AshjianE.J., OpreskoL.K.Three-dimensional culture conditions lead to decreased radiation induced cytotoxicity in human mammary epithelial cells. Mutat Res, 687:78. 2010.
23.
ImD.D., KrugerE.A., HuangW.R., SayerG., RudkinG.H., YamaguchiD.T., JarrahyR., MillerT.A.Extracellular-signal-related kinase 1/2 is responsible for inhibition of osteogenesis in three-dimensional cultured MC3T3-E1 cells. Tissue Eng Part A, 16:3485. 2010.
24.
DuggalS., FronsdalK.B., SzokeK., ShahdadfarA., MelvikJ.E., BrinchmannJ.E.Phenotype and gene expression of human mesenchymal stem cells in alginate scaffolds. Tissue Eng Part A, 15:1763. 2009.
25.
OchsnerM., TextorM., VogelV., SmithM.L.Dimensionality controls cytoskeleton assembly and metabolism of fibroblast cells in response to rigidity and shape. PLoS One, 5:e9445. 2010.
26.
JesterJ.V.et al.Myofibroblast differentiation of normal human keratocytes and hTERT, extended-life human corneal fibroblasts. Invest Ophthalmol Vis Sci, 44:1850. 2003.
27.
BerryhillB.L., KaderR., KaneB., BirkD.E., FengF., HassellJ.R.Partial restoration of the keratocyte phenotype to bovine keratocytes made fibroblastic by serum. Invest Ophthalmol Vis Sci, 43:3416. 2002.
28.
EsquenaziS., BazanH.E.P.Role of platelet-activating factor in cell death signaling in the cornea: a review. Mol Neurobiol, 42:32. 2010.
29.
PatelS., McLarenJ., HodgeD., BourneW.Normal human keratocyte density and corneal thickness measurement by using confocal microscopy in vivo. Invest Ophthalmol Vis Sci, 42:333. 2001.
30.
MusselmannK., AlexandrouB., KaneB., HassellJ.R.Maintenance of the keratocyte phenotype during cell proliferation stimulated by insulin. J Biol Chem, 280:32634. 2005.
EspanaE.M., HeH., KawakitaT., Di PascualeM.A., RajuV.K., LiuC.Y., TsengS.C.Human keratocytes cultured on amniotic membrane stroma preserve morphology and express keratocan. Invest Ophthalmol Vis Sci, 44:5136. 2003.
33.
Gonzalez-AndradesM., de la Cruz CardonaJ., IonescuA.M, CamposA., Del Mar PerezM., AlaminosM.Generation of bioengineered corneas with decellularized xenografts and human keratocytes. Invest Ophthalmol Vis Sci, 52:215. 2011.
34.
ScottS.G., JunA.S., ChakravartiS.Sphere formation from corneal keratocytes and phenotype specific markers. Exp Eye Res, 93:898. 2011.
