Linda K. Mrock

PURPOSE: To characterize the constitutively activated epidermal growth factor receptor in a lens epithelial cell population experiencing initial stages of lens fiber formation, the chick lens annular pad. METHODS: Phosphotyrosine levels of the receptor were examined with western blot analysis and immunoprecipitation after ligand stimulation. Endogenous receptor ligands were immunologically identified in whole cell lysates of freshly isolated cells. The expression of lens fiber-specific differentiation marker proteins was examined with western blot analysis and enzyme-linked immunosorbent assay (ELISA) in short-term primary cultures of annular pad cells exposed to ligand. RESULTS: The major phosphotyrosine-containing protein in annular pad cells comigrated with the epidermal growth factor receptor and increased its phosphotyrosine content after epidermal growth factor treatment. Both time- and dose-dependent responses were noted. The constitutive activation of the receptor was determined in the presence of phosphatase inhibitors. Endogenous transforming growth factor-alpha, but not epidermal growth factor, was detected in freshly isolated cells. Transforming growth factor-alpha (TGF-alpha) treatment produced greater increases in receptor phosphotyrosine levels than equimolar levels of epidermal growth factor. Finally, TGF-alpha treatment induced increased expression of the beaded filament protein filensin when compared with control cells. Filensin expression was increased further when cells were costimulated with TGF-alpha and cAMP analogs. CONCLUSIONS: At least in the postnatal lens, endogenous TGF-alpha may affect overall growth patterns by modulating differentiation-specific protein expression. Furthermore, signaling pathways elicited by TGF-alpha and cAMP analogs converge to cooperatively enhance lens fiber differentiation.

TGFalpha is hypothesized to be an endogenous regulator of lens fiber terminal differentiation. With immunofluorescence, TGFalpha was localized to differentiating cells in the lens epithelium and superficial fiber cell mass of the adult chicken. A similar pattern of localization was also noted when differentiating epithelial cells were cultured. Immunoneutralization of endogenous TGFalpha inhibited the accumulation of filensin, a unique intermediate filament protein subunit restricted to developing vertebrate lens fibers. ELISA assays quantified the effects of TGFalpha on filensin expression. Surprisingly, inhibition of the TGFalpha receptors' tyrosine kinase activity with nanomolar concentrations of PD153035 increased the accumulation of differentiated characteristics in the presence or absence of ligand. Morphologically, PD153035-treated cells grew as aggregated masses and spread less well onto the substrate. Accompanying these morphologic changes was a complete inhibition of cell division. Post-receptor signaling events were examined with cAMP assays and Western blotting. TGFalpha did not affect cAMP levels while isoproterenol, an additional mediator of lens cell differentiation, caused significant increases in cAMP levels. Activation of ERK2 via dual phosphorylation was noted in response to TGFalpha but not isoproterenol. PD153035 reduced, but did not eliminate, ERK2 phosphorylation in response to TGFalpha. Phosphorylation of the CREB transcription factor was also observed in response to TGFalpha or isoproterenol. These data indicate that endogenous ligands can influence the expression of differentiated characteristics in cultured chick lens cells. A focus of multiple signaling pathways affecting filensin expression is the CREB transcription factor. While increased ERK2 activation may be involved in stimulating cell division, lower levels of persistent ERK2 activation promotes differentiation thus indicating some form of signaling pathway compartmentalization. This could also mean that additional receptors for TGFalpha not inhibited by PD153035 are responsible for promoting differentiation in chick lens cells.