Structural function of MIP/aquaporin 0 in the eye lens; genetic defects lead to congenital inherited cataracts.

Aquaporin 0 (AQP0) was originally characterized as a membrane intrinsic protein, specifically expressed in the lens fibers of the ocular lens and designated MIP, for major intrinsic protein of the lens. Once the gene was cloned, an internal repeat was identified, encoding for the amino acids Asp-Pro-Ala, the NPA repeat. Shortly, the MIP gene family was emerging, with members being characterized in mammals, insects, and plants. Once Peter Agre's laboratory developed a functional assay for water channels, the MIP family became the aquaporin family and MIP became known as aquaporin 0. Besides functioning as a water channel, aquaporin 0 also plays a structural role, being required for maintaining the transparency and optical accommodation of the ocular lens. Mutations in the AQP0 gene in human and mice result in genetic cataracts; deletion of the MIP/AQP0 gene in mice results in lack of suture formation required for maintenance of the lens fiber architecture, resulting in perturbed accommodation and focus properties of the ocular lens. Crystallography studies support the notion of the double function of aquaporin 0 as a water channel (open configuration) or adhesion molecule (closed configuration) in the ocular lens fibers. The functions of MIP/AQP0, both as a water channel and an adhesive molecule in the lens fibers, contribute to the narrow intercellular space of the lens fibers that is required for lens transparency and accommodation.

PKC putative phosphorylation site Ser235 is required for MIP/AQP0 translocation to the plasma membrane.

PURPOSE: To investigate the functional significance of MIP/AQP0 phosphorylation at serine(235). METHODS: MIP/AQP0 expression and cellular localization was studied in rat lens epithelia explants induced to differentiate by FGF-2. MIP wild type (WT) and MIP (S235A) mutant expression plasmids were constructed and transiently expressed in RK13 cells. Subcellular localization of endogenous MIP in differentiating lens epithelia explants or of transfected MIP expression vectors in RK13 cells was analyzed by immunofluorescence confocal microscopy. RESULTS: MIP/AQP0 expressed in lens epithelia explants induced to differentiate by FGF-2 localizes to the plasma membrane of elongating cells. However, MIP/AQP0 translocation to the plasma membrane was prevented by inhibiting PKC activity with Go6976, resulting in retention in the cytoplasmic compartment. This effect was specific to MIP/AQP0; localization of AQP1 to the cell membrane was not affected by Go6976. When the consensus PKC phosphorylation site at MIP Ser(235) was mutated to alanine and transiently expressed in transfected RK13 cells, the mutant MIP was retained in the cytoplasmic compartment in contrast to WT MIP that localized to the plasma membrane of the transfected RK13 cells. Colocalization studies indicated that the mutant MIP was retained in the trans-Golgi network. CONCLUSIONS: Our results indicate that serine(235) is required for proper intracellular transport of MIP/AQP0 from the trans-Golgi network to the plasma membrane. A PKC dependent phosphorylation event involving MIP at serine(235) is most likely involved in this process.

Regulation of alphaA-crystallin via Pax6, c-Maf, CREB and a broad domain of lens-specific chromatin.

Pax6 and c-Maf regulate multiple stages of mammalian lens development. Here, we identified novel distal control regions (DCRs) of the alphaA-crystallin gene, a marker of lens fiber cell differentiation induced by FGF-signaling. DCR1 stimulated reporter gene expression in primary lens explants treated with FGF2 linking FGF-signaling with alphaA-crystallin synthesis. A DCR1/alphaA-crystallin promoter (including DCR2) coupled with EGFP virtually recapitulated the expression pattern of alphaA-crystallin in lens epithelium and fibers. In contrast, the DCR3/alphaA/EGFP reporter was expressed only in 'late' lens fibers. Chromatin immunoprecipitations showed binding of Pax6 to DCR1 and the alphaA-crystallin promoter in lens chromatin and demonstrated that high levels of alphaA-crystallin expression correlate with increased binding of c-Maf and CREB to the promoter and of CREB to DCR3, a broad domain of histone H3K9-hyperacetylation extending from DCR1 to DCR3, and increased abundance of chromatin remodeling enzymes Brg1 and Snf2h at the alphaA-crystallin locus. Our data demonstrate a novel mechanism of Pax6, c-Maf and CREB function, through regulation of chromatin-remodeling enzymes, and suggest a multistage model for the activation of alphaA-crystallin during lens differentiation.

Specific interaction between lens MIP/Aquaporin-0 and two members of the gamma-crystallin family.

PURPOSE: Major Intrinsic Protein (MIP)/Aquaporin 0 is required for lens transparency and is specifically expressed in lens fiber cell membranes. We have demonstrated previously that in the rat lens MIP interacts specifically with gammaE-crystallin, resulting in its recruitment to the plasma membrane. Our goal was to examine the interaction or lack of interaction between MIP and all members of the gamma-crystallin family and to provide evidence for a physiological role these interactions may play in gamma-crystallin or MIP function. METHODS: Full length MIP was expressed as untagged, enhanced green fluorescent protein (EGFP) tagged, or myc tagged proteins. Members of the gamma-crystallin family were expressed as red fluorescent protein (HcRed) tagged proteins in the rabbit kidney epithelial cell line RK13. Co-localization of tagged proteins was analyzed by confocal fluorescence microscopy. RESULTS: Confocal fluorescence microscopy demonstrated that gammaE- and gammaF-crystallin co-localize specifically with full length MIP in mammalian cells while other gamma-crystallins, including gammaA-, gammaB-, gammaC-, gammaD-, and gammaS-crystallin do not. As a result of this interaction, either gammaE- or gammaF-crystallin was recruited to the plasma membrane from the cytoplasm. MIP does not interact with the Elo mutant of gammaE-crystallin, which has been linked to a dominant cataract phenotype in mice. CONCLUSIONS: These experiments demonstrate that MIP interacts selectively with gammaE- and gammaF-crystallin, and not with other gamma-crystallins. This raises the possibility of MIP playing a structural role in the organization of gamma-crystallins in rodent lens fibers and/or that gammaE- and gammaF-crystallin may have a specific role in MIP function in the rodent lens.

Lens major intrinsic protein (MIP)/aquaporin 0 expression in rat lens epithelia explants requires fibroblast growth factor-induced ERK and JNK signaling.

Lens major intrinsic protein (MIP), exclusive to the vertebrate lens, otherwise known as MIP26 and Aquaporin 0, is abundantly expressed as a lens fiber membrane protein. Although relatively less efficient compared with other aquaporins, MIP is suggested to function as a water channel, as an adhesion molecule, and is required for lens transparency. Because MIP is specifically expressed in lens fiber cells, we investigated in this study the activation of Mip expression after triggering differentiation of rat lens epithelia explants by fibroblast growth factor (FGF)-2. Here, we show that Mip expression in the lens cells is regulated by FGF-2. Using Real time PCR we demonstrate that endogenous Mip levels in the explants were up-regulated upon FGF-2 stimulation, in a concentration-dependent manner. Up-regulation of Mip at the transcriptional level was simultaneous with the activation of the FGF down-stream signaling components, ERK1/2 and JNK. Specific inhibitors, UO126 for ERK1/2 and SP600125 for JNK, abrogated Mip expression in response to FGF-2 in the explants. This inhibition pattern was recapitulated in reporter assays for transfection of the rat lens epithelia explants, driven by the Mip promoter (-1648/+44). Our studies show that ERK1/2 and JNK signaling pathways are required for Mip expression in lens epithelia explants induced to differentiate by FGF-2.

gammaE-crystallin recruitment to the plasma membrane by specific interaction between lens MIP/aquaporin-0 and gammaE-crystallin.

PURPOSE: Major intrinsic protein (MIP), also called aquaporin-0, is essential for lens transparency and is specifically expressed in the lens fiber cell membranes. The goal of the current study was to identify and characterize proteins that interact with MIP and to elucidate the role of these interactions in MIP functions. METHODS: The C-terminal 74-amino-acid fragment of MIP was used as bait to screen a rat lens cDNA yeast two-hybrid library. The full-length MIP was expressed as enhanced green fluorescent protein (EGFP)-tagged or myc-tagged proteins, and gammaE-crystallin was expressed as FLAG-tagged or red fluorescent protein (HcRed)-tagged proteins, respectively, in the RK13 rabbit kidney epithelial cell line. Protein-protein interactions were analyzed by coimmunoprecipitation assays and visualized by confocal fluorescence microscopy. RESULTS: gammaE-Crystallin, a water-soluble protein that is specifically expressed in lens fibers, was identified as a binding protein to the MIP C-terminal peptide. Coimmunoprecipitation assays demonstrated that gammaE-crystallin interacts specifically with full-length MIP in mammalian cells. MIP did not interact with gammaD-crystallin, another member of the highly conserved gamma-crystallin gene family. Confocal fluorescence microscopy demonstrated that MIP interacted with gammaE-crystallin in individual mammalian cells and that this interaction resulted in the recruitment of gammaE-crystallin from the cytoplasm to the plasma membrane. CONCLUSIONS: These experiments provide the first demonstration of MIP interaction with other lens proteins at the molecular level and raise the possibility of a structural role of MIP in the organization of gamma-crystallins in lens fibers.

Activation of STAT signaling pathways and induction of suppressors of cytokine signaling (SOCS) proteins in mammalian lens by growth factors.

PURPOSE: This study was conducted to examine whether the effects of growth factors are mediated in the lens by Janus kinase/signal transducers and activators of transcription (JAK/STAT) pathways and whether they induce expression of suppressors of cytokine signaling (SOCS), a novel family of feedback regulators of cytokine and growth factor activities. METHODS: STAT activation and SOCS expression were analyzed in transgenic or wild-type mouse lens and lens epithelial cells stimulated with growth factors by immunohistochemistry, RT-PCR, Northern, Western, proliferation, or transient reporter assays. RESULTS: STATs were constitutively expressed at low levels and activated by insulin-like growth factor (IGF)-1, platelet-derived growth factor (PDGF)-aa, and FGF-1 or -2 in the lens. The Intensity of STAT signaling increased at high FGF-2 concentration and FGFs act in synergy with IGF-1 or PDGFaa to enhance STAT signaling and SOCS expression. Growth factor-induced proliferation of lens cells is inhibited by AG-490, a specific inhibitor of JAK2/STAT3. CONCLUSIONS: This is the first report that FGFs activate STAT pathways in the lens and that SOCS proteins are constitutively expressed and upregulated by growth factors in this tissue. Physiological relevance of STAT pathways in the lens is underscored by inhibition of lens cell proliferation by inhibitors of JAK/STAT pathways and by the aberrant proliferation of lens epithelium in the posterior pole of transgenic mice with constitutively activated STAT1 in the lens. Common activation of STAT pathways by FGF-1, FGF-2, IGF-1, or PDGFaa and their synergistic activation of STATs and SOCS in lens cells suggest that activities and crosstalk between these factors are sensitive to the steady state levels of activated STATs in the lens and may be under feedback regulation by SOCS family proteins.

Characterization of the roles of STAT1 and STAT3 signal transduction pathways in mammalian lens development.

PURPOSE: IGF-1 and PDGF are implicated in regulating lens proliferation and/or providing spatial cues that restrict lens proliferation to germinative and transition zones of the lens. However, very little is known about how IGF-1- or PDGF-induced signals are transduced and coupled to gene transcription in lens cells. Therefore, we examined whether these growth factors mediate their effects in the lens through the evolutionarily conserved JAK/STAT signal transduction pathway and if STAT signaling is essential for mammalian lens development. METHODS: Expression of STAT1 and STAT3 was analyzed in mouse lens and lens epithelial cells by RT-PCR and western blot analysis. Activation of the STAT signaling pathway was examined by a combination of gel-shift, super-shift, and western blotting assays. Regulation of lens proliferation and gene transcription by STAT pathways was assessed by 3H-Thymidine incorporation or RT-PCR assays with lens explants treated or untreated with Genistein or the JAK2 and STAT3 inhibitor, AG-490. Mice with targeted deletion of STAT3 in the lens were generated by Cre/lox recombination and STAT1-/-, STAT3-/- deficient as well as normal lenses were characterized by histology. RESULTS: We show that PDGF and IGF1 induce proliferation in 1AMLE6 lens cells and couple their extracellular signals to gene transcription, in part through activation of STAT3 and to a lesser extent STAT1 signal transduction pathways. We further show that targeted deletion of STAT3 in E10.5 lens does not produce overt developmental lens defects. STAT1 knockout mice also exhibit a normal lens phenotype. CONCLUSIONS: Our results showing that deletion of either STAT1 or STAT3 does not affect the normal development of the lens is surprising in view of the fact that STAT pathways are activated in developing chick or mouse lens and inappropriate activation of STAT1 pathway in the lens by ectopic lens expression of IFN? inhibits lens differentiation and induces cataract in transgenic mice. Our data thus suggest that although STAT-signaling pathways may contribute to activation of gene transcription in the lens, it may not be essential for normal lens development or STAT proteins may be functionally redundant during lens development. However, because several growth factors and cytokines present in the lens activate STATs in mouse lens explants and 1AMLE6 lens epithelial cells, it may well be that this evolutionarily conserved signaling pathway is under stringent control in the mammalian lens. Whereas deficiency in any particular STAT pathway can be compensated for by any of the functionally redundant STAT proteins induced by a wide array of growth factors in the lens, chronic or prolonged activation of a particular STAT protein may perturb homeostatic balance in STAT-dependent growth factor signaling, culminating in pathologic lens changes.

Mafs, Prox1, and Pax6 can regulate chicken betaB1-crystallin gene expression.

During lens fiber cell differentiation, the regulation of crystallin gene expression is coupled with dramatic morphological changes. Here we report that Mafs, Prox1, and Pax6, which are essential transcription factors for normal lens development, bind to three functionally important cis elements, PL1, PL2, and OL2, in the chicken betaB1-crystallin promoter and may cooperatively direct the transcription of this lens fiber cell preferred gene. Gel shift assays demonstrated that Mafs bind to the MARE-like sequences in the PL1 and PL2 elements, whereas Prox1, a sequence-specific DNA-binding protein like its Drosophila homolog Prospero, interacts with the OL2 element. Furthermore, Pax6, a known repressor of the chicken betaB1-crystallin promoter, binds to all three of these cis elements. In transfection assays, Mafs and Prox1 activated the chicken betaB1-crystallin promoter; however, their transactivation ability was repressed when co-transfected with Pax6. Taken together with the known spatiotemporal expression patterns of Mafs, Prox1, and Pax6 in the developing lens, we propose that Pax6 occupies and represses the chicken betaB1-crystallin promoter in lens epithelial cells, and is displaced by Prox1 and Mafs, which activate the promoter, in differentiating cortical fiber cells.

Heterologous expression and topography of the main intrinsic protein (MIP) from rat lens.

Wild type rat lens main intrinsic protein (MIP) and MIP mutated (F73I, F75L) to resemble the glycerol facilitator of Escherichia coli in the region of the NPA1 box were used to investigate the topology of MIP in the membrane of Spodoptera frugiperda (Sf21) cells using the baculovirus expression system and expression in mouse erythroid leukaemia cells (MEL C88). Differential fixation for staining was used, with paraformaldehyde for externally exposed antigenic sites, and acetone for both externally and internally exposed protein antigenic sites. Immunofluorescence using antibodies to synthetic MIP peptides showed that wild type MIP had a six transmembrane topography. The N- and C-termini were intracellular in both expression systems, and both NPA boxes were found to be extracellular. These results show that residues around the NPA1 box can influence the folding of the MIP in the membrane, and provide structural evidence for the poor water transport properties of MIP, as the NPA boxes lie outside the plane of the membrane.

pH-Dependent channel activity of heterologously-expressed main intrinsic protein (MIP) from rat lens.

Wild-type rat lens main intrinsic protein (MIP) was heterologously expressed in the membrane of Spodoptera frugiperda (Sf21) cells using the baculovirus expression system and in mouse erythroid leukaemia cells (MEL C88). Both MEL and Sf21 cell lines expressing wild-type MIP were investigated for the conductance of ions using a whole cell patch clamp technique. An increase in conductance was seen in both expression systems, particularly on lowering the pH to 6.3. In Sf21 cells, addition of antibodies to the NPA1 box resulted in a reduction of current flow. These results suggest that MIP has pH-dependent ion channel activity, which involves the NPA1 box domain.