The Role of MMPs, Smad3 and Heat Shock Proteins in TGF-β-Induced Anterior Subcapsular Cataract Development

Banh, Alice

January 2007

Transforming growth factor beta (TGF-β) has been implicated in anterior subcapsular cataract (ASC) development. In the first section of this thesis, an in-vitro rat lens model was used to determine the role of matrix metalloproteinases during TGF-β-induced ASC. In the second part, an in-vivo TGF-β transgenic and Smad3 knockout model was used to examine the role of Smad3 signaling pathway in TGF-β-induced ASC development. Lastly, an in-vitro rat lens epithelial explant culture model was used to investigate the potential role of heat shock proteins (Hsps) in TGF-β-induced epithelial-mesenchymal transition (EMT). Optical, morphological and molecular changes were analyzed in theses studies. Results from cultured rat lenses show a significant increase of back vertex distance variability (decrease of sharpness and focus) during ASC development. Inhibition of MMPs eliminated the TGF-β-induced plaque formation. Similarly, the overexpression of TGF-β1 in transgenic mouse lenses leads to ASC formation and a decrease in lens optical quality in comparison to wild-type lenses, while TGF-β1/Smad3-/- (null) lenses show diminished TGF-β-induced effects. The plaques formed in the TGF-β1/Smad3-/- lenses are substantially smaller than in the TGF-β1/Smad3+/+ lenses. The morphological and molecular changes of TGF-β2/FGF-2 treated rat lens epithelial explants are similar to those found in the TGF-β2 treated rat lenses and transgenic TGF-β1 mouse lenses. Heat shock treatment prior to TGF-β treatment significantly reduced the effects of EMT in rat LECs. In conclusion, MMP inhibition prevented TGF-β-induced ASC formation whereas heat shock treatment and the absence of Smad3 protein expression only reduced the severity of TGF-β-induced effects.

anterior subcapsular cataract formation

transforming growth factor beta

transgenic mouse

rat lens culture

lens epithelial cells

Smad3

MMPs

heat shock proteins

Vision Science and Biology

The Role of MMPs, Smad3 and Heat Shock Proteins in TGF-β-Induced Anterior Subcapsular Cataract Development

Banh, Alice

January 2007

Transforming growth factor beta (TGF-β) has been implicated in anterior subcapsular cataract (ASC) development. In the first section of this thesis, an in-vitro rat lens model was used to determine the role of matrix metalloproteinases during TGF-β-induced ASC. In the second part, an in-vivo TGF-β transgenic and Smad3 knockout model was used to examine the role of Smad3 signaling pathway in TGF-β-induced ASC development. Lastly, an in-vitro rat lens epithelial explant culture model was used to investigate the potential role of heat shock proteins (Hsps) in TGF-β-induced epithelial-mesenchymal transition (EMT). Optical, morphological and molecular changes were analyzed in theses studies. Results from cultured rat lenses show a significant increase of back vertex distance variability (decrease of sharpness and focus) during ASC development. Inhibition of MMPs eliminated the TGF-β-induced plaque formation. Similarly, the overexpression of TGF-β1 in transgenic mouse lenses leads to ASC formation and a decrease in lens optical quality in comparison to wild-type lenses, while TGF-β1/Smad3-/- (null) lenses show diminished TGF-β-induced effects. The plaques formed in the TGF-β1/Smad3-/- lenses are substantially smaller than in the TGF-β1/Smad3+/+ lenses. The morphological and molecular changes of TGF-β2/FGF-2 treated rat lens epithelial explants are similar to those found in the TGF-β2 treated rat lenses and transgenic TGF-β1 mouse lenses. Heat shock treatment prior to TGF-β treatment significantly reduced the effects of EMT in rat LECs. In conclusion, MMP inhibition prevented TGF-β-induced ASC formation whereas heat shock treatment and the absence of Smad3 protein expression only reduced the severity of TGF-β-induced effects.

anterior subcapsular cataract formation

transforming growth factor beta

transgenic mouse

rat lens culture

lens epithelial cells

Smad3

MMPs

heat shock proteins

Vision Science and Biology