Abstract
Diabetic cataracts can occur at an early age, causing visual impairment or blindness. The detailed molecular mechanisms of diabetic cataract formation remain incompletely understood, and there is no well-documented prophylactic agent. Galactose-fed rats and ex vivo treatment of lenses with galactose are used as models of diabetic cataract. To assess the role of histone acetyltransferases, we conducted cataract prevention screening with known histone acetyltransferase (HAT) inhibitors. Ex vivo treatment with a HAT inhibitor strongly inhibited the formation of lens turbidity in high-galactose conditions, while addition of a histone deacetylase (HDAC) inhibitor aggravated turbidity. We conducted a microarray to identify genes differentially regulated by HATs and HDACs, leading to discovery of a novel cataract causative factor, Plk3. Plk3 mRNA levels correlated with the degree of turbidity, and Plk3 inhibition alleviated galactose-induced cataract formation. These findings indicate that epigenetically controlled Plk3 influences cataract formation. Our results demonstrate a novel approach for prevention of diabetic cataract using HAT and Plk3 inhibitors.
Highlights
Diabetic cataracts can occur at an early age, causing visual impairment or blindness
We initially investigated the effect of histone deacetylase (HDAC) inhibitors on lens turbidity to assess the role of histone acetylation in diabetic-like cataract formation
When lenses were cultured in medium containing 30 mM galactose for 4 days, cortical cataract formation occurred, and was further increased by addition of the HDAC inhibitor Trichostatin A (TSA) (Fig. 1b)
Summary
Diabetic cataracts can occur at an early age, causing visual impairment or blindness. Plk[3] mRNA levels correlated with the degree of turbidity, and Plk[3] inhibition alleviated galactose-induced cataract formation. Increased intracellular osmotic pressure due to accumulation of polyol and lens epithelial cell (LEC) apoptosis are major contributing pathologies of diabetic cataract. The cellular events contributing to diabetic cataract formation have been reported[4,5,6,8], the detailed molecular mechanisms for these events remain incompletely understood. Tgf-β induced cataracts in rats causes lens surface turbidity, which is inhibited by TSA18,19. These reports suggest that epigenetic modifications are involved in cataract formation, and that preventing these modifications suppresses cataract formation. The roles of epigenetic modifications in diabetic cataract are unknown
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