L-Maf, a downstream target of Pax6, is essential for chick lens development.
(1/23)
During lens development in vertebrates, the orchestration of multiple transcriptional regulators is essential for fate determination and terminal differentiation. In early development, Pax6, Sox2 and Six3 are expressed in the head ectoderm, while L-maf, Prox1 and crystallin genes are expressed at a later stage in the lens placode in a more restricted fashion. To uncover the genetic interactions among these factors during lens development, we examined the effects of dominant-negative molecules of Pax6 and L-Maf, which play decisive roles in lens formation. The two dominant-negative isoforms of Pax6 repress L-maf, Prox1 and delta-crystallin expression, resulting in failure of lens formation. These effects of dominant-negative Pax6 are fully rescued by co-expression with wild-type L-Maf. In addition, dominant-negative L-Maf inhibits the expression of Prox1 and delta-crystallin, while misexpression of L-Maf causes ectopic induction of these genes in a Sox-2-dependent fashion. Our results demonstrate that L-Maf is a downstream target of Pax6 and mediates Pax6 activity in developing lens cells. (+info)
The stability of the lens-specific Maf protein is regulated by fibroblast growth factor (FGF)/ERK signaling in lens fiber differentiation.
(2/23)
Fibroblast growth factor (FGF) signaling is necessary for both proliferation and differentiation of lens cells. However, the molecular mechanisms by which FGFs exert their effects on the lens remain poorly understood. In this study, we show that FGF-2 repressed the expression of lens-specific genes at the proliferative phase in primary cultured lens cells. Using transfected cells, we also found that the activity of L-Maf, a lens differentiation factor, is repressed by FGF/ERK signaling. L-Maf is shown to be phosphorylated by ERK, and introduction of mutations into the ERK target sites on L-Maf promotes its stabilization. The stable L-Maf mutant protein promotes the differentiation of lens cells from neural retina cells. Taken together, these results indicate that FGF/ERK signaling negatively regulates the function of L-Maf in proliferative lens cells and that stabilization of the L-Maf protein is important for lens fiber differentiation. (+info)
Quantification of chick lens alphaA- and delta-crystallins in experimentally induced ametropia.
(3/23)
PURPOSE: The role of the lens in experimentally induced ametropia is not known. A recent study of the chick lens demonstrated optical quality deterioration with the induction of refractive errors, without alteration in lens morphology, size or shape. A change in lens gradient of refractive index (which is dependent on alpha-, beta-, and delta-crystallin concentration and arrangement), could underlie this observation. The purpose of this work was to quantify the concentrations of alphaA- and delta-crystallin in lenses from chick eyes with induced high myopia or hyperopia. METHODS: White Leghorn chicks were unilaterally fitted on the day of hatching either with translucent plastic goggles to induce form-deprivation myopia (n=21) or with +15 D defocus goggles to induce hyperopia (n=14). The ungoggled contralateral eyes were used as controls. The chicks were refracted twice, once on the day of hatching and again seven days later, using streak retinoscopy. On day 7 chicks were sacrificed, lenses decapsulated, and soluble proteins were isolated. Western blot assays were optimized and used to assess crystallin concentration. RESULTS: Analysis revealed no significant difference in alphaA- or delta-crystallin concentration in lenses from eyes induced with form-deprivation myopia and hyperopia as compared to their respective control eyes. Analysis of the difference in medians of delta-crystallin between the control and treated groups of the myopia and hyperopia experiments revealed significance (p=0.030). CONCLUSIONS: This study suggests that with the induction of ametropia, the increased lens spherical aberration previously noted is not due to a change in the absolute concentration of lens alphaA- or delta-crystallin. However, results suggest that the myopic and hyperopic treatments had different effects on lens delta-crystallin concentration. Further investigation is necessary to expand the current knowledge of the role played by the lens in experimental ametropia. (+info)
Cooperative action between L-Maf and Sox2 on delta-crystallin gene expression during chick lens development.
(4/23)
Lens development is regulated by a variety of transcription factors with distinct properties. The lens-specific transcription factor, L-Maf, is essential for lens formation and induces lens-specific markers, such as the crystallin genes. In this study, we analyzed the mechanism by which L-Maf regulates delta-crystallin expression. Misexpression of L-Maf in the head ectoderm of lens placode-forming embryos by in ovo electroporation induced delta-crystallin only in the region surrounding the lens. To define this restricted expression, we misexpressed L-Maf together with other transcription factors implicated in delta-crystallin expression. Sox2 plus L-Maf expanded the delta-crystallin-inducible domain to the entire head ectoderm and simultaneously increased the quantity of delta-crystallin mRNA expressed. In contrast, co-expression of L-Maf with other factors such as Pax6, Six3 and Prox1 had little or no effect on delta-crystallin. We also observed that L-Maf and Sox2 cooperatively enhanced the transactivation of a reporter gene bearing the delta-crystallin enhancer in ovo, implying that L-Maf and Sox2 can induce delta-crystallin through the same enhancer. In conclusion, we report here that L-Maf and Sox2 cooperatively regulate the expression of delta-crystallin during chick lens development. (+info)
Stimulation of lens cell differentiation by gap junction protein connexin 45.6.
(5/23)
PURPOSE: The present study was undertaken to explore the roles gap junctions play in lens epithelial cell differentiation. METHODS: Recombinant retroviruses expressing three chick lens connexins (Cx)-Cx43, Cx45.6, and Cx56-were prepared and used to infect isolated chick lens primary cultures. The expression and distribution of proteins was determined using immunoblots and confocal immunofluorescence microscopy. Intercellular couplings were assessed by single cell microinjection and scrape-loading dye transfer, and cell proliferation was evaluated by [(3)H]thymidine labeling. RESULTS: Of the three lens connexins, only the cultures overexpressing exogenous Cx45.6 displayed the advancement of lens epithelial-fiber cell differentiation. The lentoids, a unique morphologic structure that is an indicative of lens fiber formation, were formed earlier in Cx45.6 overexpressed cultures; however, the rate of lens cell proliferation was not affected. The expression of the lens differentiation marker proteins, major intrinsic protein (MIP) and delta-crystallin, was also increased in Cx45.6-overexpressing cells. The cells overexpressing Cx45.6 displayed similar levels of intercellular couplings as did the controls. Moreover, exogenously expressed connexins were mostly colocalized with their endogenous counterparts and the overexpression of Cx45.6 had no impact on the expression of endogenous Cx43 and Cx56. CONCLUSIONS: These results suggest that Cx45.6 plays an important role in stimulating lens cell differentiation and fiber formation, which is different from the other lens connexins, Cx43 and Cx56. This stimulatory effect is independent of gap junction-mediated intercellular communication and lens cell proliferation. (+info)
Differential activation of phosphatidylinositol 3-kinase signaling during proliferation and differentiation of lens epithelial cells.
(6/23)
PURPOSE: To investigate whether phosphatidylinositol 3-kinase (PI-3K) signaling is involved in lens epithelial cell proliferation and differentiation promoted by growth factors. METHODS: Proliferation of rabbit lens epithelial cells grown in culture was measured with a DNA-binding fluorescent dye in a proliferation assay. Primary cultures of embryonic chicken lens epithelial cells that develop lentoids were used for differentiation-related studies, and delta-crystallin synthesis in these cultures was determined by metabolic labeling with [(35)S]methionine. Immunoprecipitation and immunoblot analyses were also used. RESULTS: The PI-3K inhibitors wortmannin and LY294002 blocked the insulin-, insulin-like growth factor (IGF)-1-, and fibroblast growth factor (FGF)-2-promoted cell proliferation in rabbit lens epithelial cells. Inhibition of PI-3K activity by these inhibitors unexpectedly increased the synthesis of early differentiation marker protein delta-crystallin in chicken lens epithelial cells. Insulin and IGF-1 stimulated activation of PI-3K in proliferating and differentiating cultures. FGF-2 showed no direct effect on PI-3K activation. Platelet-derived growth factor (PDGF) did not induce significant proliferation or increased expression of delta-crystallin, but stimulated PI-3K. The presence of FGF-2 in proliferating rabbit lens epithelial cells enhanced the IGF-1-, but not the PDGF-mediated PI-3K activation, suggesting a possible integration of FGF-2 signals with IGF-1. Whereas there was a gradual decrease in insulin/IGF-1-mediated activation of PI-3K and its downstream target Akt, with progression of differentiation in chicken lens epithelial cells, Erk2 phosphorylation induced by these growth factors was not decreased; rather, it remained increased in early stages of differentiation. CONCLUSIONS: The results reveal significant differences in the modulation of PI-3K signaling by different growth factors during proliferation in rabbit lens epithelial cells and differentiation in chicken lens epithelial cells and demonstrate that regulation of the PI-3K pathway plays a key role in these processes. A balance between the nonactivation of PI-3K and the activation of Erk2 may be necessary during early stages of epithelial cell transformation. (+info)
Monomeric molten globule intermediate involved in the equilibrium unfolding of tetrameric duck delta2-crystallin.
(7/23)
Duck delta2-crystallin is a soluble tetrameric lens protein. In the presence of guanidinium hydrochloride (GdnHCl), it undergoes stepwise dissociation and unfolding. Gel-filtration chromatography and sedimentation velocity analysis has demonstrated the dissociation of the tetramer protein to a monomeric intermediate with a dissociation constant of 0.34 microM3. Dimers were also detected during the dissociation and refolding processes. The sharp enhancement of 1-anilinonaphthalene-8-sulfonic acid (ANS) fluorescence at 1 M GdnHCl strongly suggested that the dissociated monomers were in a molten globule state under these conditions. The similar binding affinity (approximately 60 microM) of ANS to protein in the presence or absence of GdnHCl suggested the potential assembly of crystallins via hydrophobic interactions, which might also produce off-pathway aggregates in higher protein concentrations. The dynamic quenching constant corresponding to GdnHCl concentration followed a multistate unfolding model implying that the solvent accessibility of tryptophans was a sensitive probe for analyzing delta2-crystallin unfolding. (+info)
Disruption of a salt bridge dramatically accelerates subunit exchange in duck delta2 crystallin.
(8/23)
Intragenic complementation is a unique property of oligomeric enzymes with which to study subunit-subunit interactions. Complementation occurs when different subunits, each possessing distinct mutations that render the individual homomutant proteins inactive, interact to form a heteromutant protein with partial recovery of activity. In this paper, complementation events between human argininosuccinate lyase (ASL) and its homolog, duck delta2 crystallin, were characterized. Different active site mutants in delta2 crystallin complement by the regeneration of native-like active sites as reported previously for ASL. The complementarity of the ASL and delta2 crystallin subunit interfaces was illustrated by the in vivo formation of active hybrid tetramers from inactive ASL and inactive delta2 crystallin mutants. Subunits of both ASL and delta2 crystallin do not dissociate and reassociate in vitro at room temperature, even after 6 days of incubation, indicating that the multimerization interface is very strong. However, disruption of a salt bridge network in the tetrameric interface of delta2 crystallin caused a drastic acceleration of subunit dissociation. Double mutants combining these interface mutants with active site mutants of delta2 crystallin were able to dissociate and reassociate to form active tetramers in vitro within hours. These results suggest that exchange of subunits may occur without unfolding of the monomer. Intragenic complementation in these interface mutants occurs by reintroducing the native salt bridge interaction upon hetero-oligomerization. Our studies demonstrate the value of intragenic complementation as a tool for investigating subunit-subunit interactions in oligomeric proteins. (+info)