Hypoxia regulates the degradation of non-nuclear organelles during lens differentiation through activation of HIF1a.

Formation of the eye lens depends on the continuous differentiation of lens epithelial cells into lens fiber cells. To attain their mature structure and transparent function, nascent lens fiber cells must complete a precise cellular remodeling program hallmarked by the complete elimination of organelles to form the core lens organelle-free zone (OFZ). Lacking a blood supply, the lens resides in a hypoxic environment that results in a decreasing oxygen concentration from the lens surface to the lens core. This oxygen gradient results in a hypoxic microenvironment in the region of the lens where immature lens fiber cells initiate loss of organelles to form the core OFZ. These features of the lens suggest a potential role for low lens oxygen levels in the regulation of organelle degradation and other events critical for mature lens fiber cell formation. Hypoxia activates the master regulator of the hypoxic response, hypoxia-inducible factor 1a (HIF1a) that regulates hypoxia-responsive genes. To identify a potential role for hypoxia and HIF1a in the elimination of organelles during lens fiber cell maturation, we tested the requirement for hypoxia in the degradation of non-nuclear organelles in ex vivo cultured embryonic chick lenses by monitoring the degradation of mitochondria (MT), Golgi apparatus (GA) and endoplasmic reticulum (ER) under conditions of low (1% O2) and high (21% O2) oxygen. We also examined the requirement for HIF1a activation for elimination of these organelles under the same conditions using a specific HIF1a activator (DMOG) and a specific HIF1a inhibitor (chetomin) and examined the requirements for hypoxia and HIF1a for regulating transcription of BNIP3L that we previously showed to be required for elimination of non-nuclear lens organelles. We used ChIP-qPCR to confirm direct binding of HIF1a to the 5' untranslated region of the BNIP3L gene. Finally, we examined the effects of expressing an oxygen insensitive mutant form of HIF1a (P402A/P565A) and BNIP3L on non-nuclear organelle degradation. Our data demonstrate that hypoxia and HIF1a are required for the degradation of non-nuclear organelles during lens fiber cell formation and that they regulate this process by governing BNIP3L transcription. Our results also provide evidence that hypoxia and HIF1a are essential for achieving mature lens structure.

The Sumoylation Modulated Tumor Suppressor p53 Regulates Cell Cycle Checking Genes to Mediate Lens Differentiation.

PURPOSE: The tumor suppressor p53 is a master regulator of apoptosis and also plays a key role in cell cycle checking. In our previous studies, we demonstrated that p53 directly regulates Bak in mouse JB6 cells and that p53-Bak signaling axis plays an important role in mediating EGCG-induced apoptosis. Furthermore, we have recently demonstrated that the same p53-Bak apoptotic signaling axis executes an essential role in regulating lens cell differentiation. In addition, we have also shown that p53 controls both transcription factors, C-Maf and Prox-1 as well as lens crystallin genes, αA, ß- and γ-crystallins. Here, we have examined whether p53 also regulates other known target genes during its modulation of lens differentiation. The human and mouse lens epithelial cells, FHL124 and αTN4-1 were cultured in Dulbecco's modified Eagle's medium (DMEM) containing 10% fetal bovine serum (FBS) and 1% Penicillin-Streptomycin. METHODS: Mice used in this study were handled in compliance with the "Protocol for the Care and Use of Laboratory Animals" (Sun Yat-sen University). Adult mice were used for the collection of lens cells. These samples were used for extraction of total proteins. A total of 32 embryonic mice {8 at 14.5 ED, 8 at 17.5 ED and 8 newborns for wild type} were used for immunohistochemistry, which were used for co-localization study. The mRNA levels were analysed with qRT-PCR. The protein levels were determined with western blot analysis and quantitated with Image J. RESULTS: Immunohistochemistry revealed that both the cell cycle checking genes, p21 and Gadd45α and the apoptotic genes, Bcl-2 and PUMA, display developmental changes associated with p53 during mouse lens development. Knockdown of p53 in the mouse lens epithelial cells caused inhibition of lens differentiation. Associated with this inhibition, the cell cycle genes displayed significant downreglation, the apoptotic genes was also attenuated but to a much less degree. In addition, we found that bFGF can induce dose-dependent upregulation of the upstream kinases, CHK1/2 and ERK1/2, both known to phosphorylate p53 and activate the later. Furthermore, We showed that in both developing lens and human lens epithelial cells, p53 can be co-localized with the catalytic subunit of the protein phoshphatase-1 (PP-1), suggesting that PP-1 regulates p53 phosphorylation status both in vivo and in vitro. CONCLUSION: Taken together, our results suggest that during mouse lens development, p53 activity is regulated by ERK and CHK kinases-mediated activation, and by PP-1-mediated inactivation. p53 can regulate multiple groups of genes to mediate lens differentiation.

Possible Role of Amyloid beta- (1-40) -BSA Conjugates in Transdifferentiation of Lens Epithelial Cells

We investigated whether amyloid beta (Abeta) aggregates have transforming growth factor beta- like cytokine activity and cause transdifferention of lens epithelial cells, leading to certain types of cataract. In order to mimic Abetaaggregates, Abeta- (1-40) was crosslinked to bovine serum albumin (BSA) with disuccinimidyl suberate according to a previously described procedure. When human lens epithelial B-3 (HLE B-3) cells were treated with the Abeta- (1-40) -BSA conjugates, we observed the translocation of Smad-3, as well as the induced mRNA levels of fibronectin (FN), collagen type I (Col I), smooth muscle actin (SMA) and matrix metalloproteinase-2 (MMP-2). In addition, we investigated the morphology of rat whole lens cultured for 5 days in the presence of Abeta- (1-40) -BSA, and the immunohistochemical localizations of Abeta- (1-40) /amyloid precursor protein (APP) in human clinical tissues beneath the anterior capsules. In rat whole lens cultures, treatment with Abeta- (1-40) -BSA produced a transformed morphology that had multiple layers of lens epithelial cells. To compare the anterior capsules in anterior subcapsular cataracts with those in nuclear cataracts, immunohistochemical studies of Abeta/APP in human clinical tissues revealed that the predominant immunostaining of Abeta occurs in the anterior epithelial plaques, which likely produces the abnormal extracellular matrix. Thus, these findings suggest that Abeta aggregates in vivo are possibly involved in the regulatory process by which lens epithelial cells may transdifferentiate into fibroblast-like cells, as well as help understand the mechanisms which lead to certain types of cataractogenesis.