Regulation of GSH in {{alpha}}A-Expressing Human Lens Epithelial Cell Lines and in {{alpha}}A Knockout Mouse Lenses

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Regulation of GSH in ${alpha}$ A-Expressing Human Lens Epithelial Cell Lines and in ${alpha}$ A Knockout Mouse Lenses

Ram Kannan¹, Bin Ouyang¹, Eric Wawrousek², Neil Kaplowitz¹ and Usha P. Andley³

¹ From the Division of Gastrointestinal and Liver Diseases, University of Southern California Keck School of Medicine, Los Angeles; ² National Eye Institute, Bethesda, Maryland; and ³ Department of Ophthalmology and Visual Sciences, Washington University School of Medicine, St. Louis, Missouri.

PURPOSE. To study the mechanism of regulation of GSH in HLE-B3cells expressing ${alpha}$ A-crystallin ( ${alpha}$ A) and in ${alpha}$ A knockout mouse lenses.

METHODS. GSH levels and maximal rates of GSH synthesis weremeasured in immortalized, ${alpha}$ A-transfected HLE-B3 cells containingvarying amounts of ${alpha}$ A. The mRNA and protein for the rate-limitingenzyme for GSH synthesis, ${gamma}$ -glutamylcysteine synthetase (GCS),were also determined in ${alpha}$ A- and mock-transfected cells by Northernblot analysis and Western blot analysis of heavy (GCS-HS) andlight (GCS-LS) subunits. The effect of absence of ${alpha}$ A and ${alpha}$ B onlens GSH concentrations was evaluated in whole lenses of ${alpha}$ A knockoutand ${alpha}$ B knockout mice as a function of age. GCS-HS mRNA and proteinwere determined in young, precataractous and cataractous ${alpha}$ A knockoutlenses.

RESULTS. GSH levels were significantly higher in HLE-B3 cellsexpressing ${alpha}$ A- compared with mock-transfected cells and werecorrelated positively with ${alpha}$ A content. Mean rate of GSH synthesiswas also higher in ${alpha}$ A-expressing cells than in mock controls(0.84 vs. 0.61 nmol · min^-1 per mg protein, respectively).GCS-HS mRNA and GCS-LS mRNA were approximately twofold higherin ${alpha}$ A-expressing cells, whereas the heavy and light GCS subunitproteins increased by 80% to 100%. In ${alpha}$ A(-/-) mouse lenses, GSHlevel was not different from that of wild type up to 2 monthsfrom birth, after which it dropped to $~$ 50% of controls. On theother hand, GCS-HS and GCS-LS proteins showed a significantdecrease before cataract formation as early as 15 days afterbirth. GSH level in cataract-free ${alpha}$ B(-/-) lenses was similarto that of wild type for up to 14 months.

CONCLUSIONS. Expression of ${alpha}$ A caused an increase in cellularGSH, in part, because of an increase in mRNA and protein ofboth GCS subunits. GSH levels decreased with increasing agein cataractous ${alpha}$ A(-/-) lenses but not in the noncataractous ${alpha}$ B(-/-)lenses. It is suggested that neonatal precataractous lenses(with normal GSH and decreased GCS) may maintain their GSH levelby other compensatory mechanisms such as increased GSH transport.

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Regulation of GSH in A-Expressing Human Lens Epithelial Cell Lines and in A Knockout Mouse Lenses

Regulation of GSH in ${alpha}$ A-Expressing Human Lens Epithelial Cell Lines and in ${alpha}$ A Knockout Mouse Lenses