Omega -crystallin of the scallop lens. A dimeric aldehyde dehydrogenase class 1/2 enzyme-crystallin

While many of the diverse crystallins of the transparent lens of vertebrates are related or identical to metabolic enzymes, much less is known about the lens crystallins of invertebrates. Here we investigate the complex eye of scallops. Electron microscopic inspection revealed that the anterior, single layered corneal epithelium overlying the cellular lens contains a regular array of microvilli that we propose might contribute to its optical properties. The sole crystallin of the scallop eye lens was found to be homologous to Omega-crystallin, a minor crystallin in cephalopods related to aldehyde dehydrogenase (ALDH) class 1/2. Scallop Omega-crystallin (officially designated ALDH1A9) is 55-56% identical to its cephalopod homologues, while it is 67 and 64% identical to human ALDH 2 and 1, respectively, and 61% identical to retinaldehyde dehydrogenase/eta-crystallin of elephant shrews. Like other enzyme-crystallins, scallop Omega-crystallin appears to be present in low amounts in non-ocular tissues. Within the scallop eye, immunofluorescence tests indicated that Omega-crystallin expression is confined to the lens and cornea. Although it has conserved the critical residues required for activity in other ALDHs and appears by homology modeling to have a structure very similar to human ALDH2, scallop Omega-crystallin was enzymatically inactive with diverse substrates and did not bind NAD or NADP. In contrast to mammalian ALDH1 and -2 and other cephalopod Omega-crystallins, which are tetrameric proteins, scallop Omega-crystallin is a dimeric protein. Thus, ALDH is the most diverse lens enzyme-crystallin identified so far, having been used as a lens crystallin in at least two classes of molluscs as well as elephant shrews.     

A complex array of positive and negative elements regulates the chicken alpha A-crystallin gene: involvement of Pax-6, USF, CREB and/or CREM, and AP-1 proteins.

The abundance of crystallins (> 80% of the soluble protein) in the ocular lens provides advantageous markers for selective gene expression during cellular differentiation. Here we show by functional and protein-DNA binding experiments that the chicken alpha A-crystallin gene is regulated by at least five control elements located at sites A (-148 to -139), B (-138 to -132), C (-128 to -101), D (-102 to -93), and E (-56 to -41). Factors interacting with these sites were characterized immunologically and by gel mobility shift experiments. The results are interpreted with the following model. Site A binds USF and is part of a composite element with site B. Site B binds CREB and/or CREM to enhance expression in the lens and binds an AP-1 complex including CREB, Fra2 and/or JunD which interacts with USF on site A to repress expression in fibroblasts. Sites C and E (which is conserved across species) bind Pax-6 in the lens to stimulate alpha A-crystallin promoter activity. These experiments provide the first direct data that Pax-6 contributes to the lens-specific expression of a crystallin gene. Site D (-104 to -93) binds USF and is a negative element. Thus, the data indicate that USF, CREB and/or CREM (or AP-1 factors), and Pax-6 bind a complex array of positive and negative cis-acting elements of the chicken alpha A-crystallin gene to control high expression in the lens and repression in fibroblasts.     

Scallop lens Omega-crystallin (ALDH1A9): a novel tetrameric aldehyde dehydrogenase

Scallop eye lens Omega-crystallin is an inactive aldehyde dehydrogenase (ALDH1A9) related to cytoplasmic ALDH1A1 and mitochondrial ALDH2 that migrates by gel filtration chromatography as a homodimer. Because mammalian ALDH1A1 and ALDH2 are homotetramers, we investigated the native molecular mass of scallop Omega-crystallin by multi-angle laser light scattering. The results indicate that the scallop Omega-crystallin is a tetrameric, not a dimeric protein. Moreover, phylogenetic tree analysis shows that scallop Omega-crystallin clusters with the mitochondrial ALDH2 and ALDH1B1 rather than the cytoplasmic ALDH1A, yet it lacks the mitochondrial N-terminal leader sequence characteristic of the mitochondrial ALDHs. The mitochondrial grouping, enzymatic inactivity, and anomalous gel filtration behavior make scallop cytoplasmic Omega-crystallin an interesting protein for structural studies of evolutionary adaptations to become an enzyme-crystallin.     

Functional redundancy of the DE-1 and alpha A-CRYBP1 regulatory sites of the mouse alpha A-crystallin promoter.

Previous studies have implicated the DE-1 (-111/-106) and alpha A-CRYBP1 (-66/-57) sites for activity of the mouse alpha A-crystallin promoter in transiently transfected lens cells. Here we have used the bacterial chloramphenicol acetyltransferase (CAT) reporter gene to test the functional importance of the putative DE-1 and alpha A-CRYBP1 regulatory elements by site-specific and deletion mutagenesis in stably transformed alpha TN4-1 lens cells and in transgenic mice. FVB/N and C57BL/6 x SJL F2 hybrid transgenic mice were assayed for CAT activity in the lens, heart, lung, kidney, spleen, liver, cerebrum, and muscle. F0, F1, and F2 mice from multiple lines carrying single mutations of the DE-1 or alpha A-CRYBP1 sites showed high levels of CAT activity in the lens, but not in any of the non-lens tissues. By contrast, despite activity of the wild-type promoter, none of the mutant promoter/CAT constructs were active in the transiently transfected and stably transformed lens cells. The mice carrying transgenes with either site-specific mutations in both the DE-1 and alpha A-CRYBP1 sites or a deletion of the entire DE-1 and part of the alpha A-CRYBP1 site (-60/+46) fused to the CAT gene did not exhibit CAT activity above background in any of the tissues examined, including the lens. Our results thus indicate that the DE-1 and alpha A-CRYBP1 sites are functionally redundant in transgenic mice. Moreover, the present data coupled with previous transfection and transgenic mouse experiments suggest that this functional redundancy is confined to lens expression within the mouse and is not evident in transiently transfected and stably transformed lens cells, making the cultured lens cells sensitive indicators of functional elements of crystallin genes.     

Autoregulation of fos: the dyad symmetry element as the major target of repression.

Fos and Jun co-operatively repress the fos promoter. Removal of all putative Fos/Jun binding sites from the fos promoter neither obliterates the repression by Fos/Jun in transient cotransfection experiments in NIH3T3 cells nor the turn-off kinetics of serum-induced fos expression in stably transfected NIH3T3 cells. The dyad symmetry element (DSE) suffices to subject a promoter to this type of repression. However, one of the putative Fos/Jun binding sites (-292 to -299 and thus located immediately adjacent to the DSE), determines the very low level of basal expression.     

Identification of multiple cis-acting elements mediating the induction of prostaglandin G/H synthase-2 by phorbol ester in murine osteoblastic cells

The tumor promoter phorbol 13-myristate 12-acetate (PMA), the best characterized protein kinase C agonist, frequently regulates gene expression via activation of Fos/Jun (AP-1) complexes. PMA rapidly and transiently induces prostaglandin G/H synthase-2 (PGHS-2) expression in murine osteoblastic MC3T3-E1 cells, but no functional AP-1 binding motifs in the 5'-flanking region have been identified. In MC3T3-E1 cells transfected with -371/+70 bp of the PGHS-2 gene fused to a luciferase reporter gene (Pluc), PMA stimulates luciferase activity up to eightfold. Computer analysis of the sequence of the PGHS-2 promoter region identified three potential AP-1 elements in the -371/+70 bp region, and deletion analysis suggested that the sequence 5'-aGAGTCA-3' at -69/-63 bp was most likely to mediate stimulation by PMA. Mutation of the putative AP-1 sequence reduces the ability of PMA to stimulate Pluc activity by 65%. On electrophoretic mobility shift analysis (EMSA), PMA induces binding to a PGHS-2 probe spanning this sequence, binding is blocked by an unlabeled AP-1 canonical sequence, and antibodies specific for c-Jun and c-Fos inhibit binding. Mutation of this AP-1 site also causes a small (22%) but significant reduction in the serum stimulation of Pluc activity in transiently transfected MC3T3-E1 cells. On EMSA, serum induces binding to a PGHS-2 probe spanning the AP-1 site, binding is blocked by an unlabeled AP-1 canonical sequence, and antibodies specific for c-Jun and c-Fos inhibit binding. Joint mutation of this AP-1 site and the nearby CRE site at -56/-52 bp, previously shown to mediate serum, v-src and PDGF induction of PGHS-2 in NIH-3T3 cells, blocks both PMA and serum induction of Pluc activity in MC3T3-E1 cells. Hence, the AP-1 and CRE binding sites are jointly but differentially involved in both the PMA and serum stimulation of PGHS-2 promoter activity.     

Evidence that functional interactions of CREB and SF-1 mediate hormone regulated expression of the aromatase gene in granulosa cells and constitutive expression in R2C cells

The proximal promoter of the rat aromatase CYP19 gene contains two functional domains that can confer hormone/cAMP inducibility in primary cultures of rat granulosa cells and constitutive expression in R2C Leydig cells. Region A contains a hexameric sequence that binds steroidogenic factor-1 (SF-1). Region B contains a CRE-like sequence that binds CREB and two other factors, X and Y. To determine if CRE binding factors X and Y had overlapping functions with CREB, and to determine if the CREB and SF-1 binding sites exhibited functional interactions in the context of the intact promoter, mutations within the CRE and hexameric SF-1 binding site were generated. Mutations within the CRE showed that CREB but not factors X and Y mediated cAMP-dependent activity of chimeric transgenes in primary granulosa cell cultures. Granulosa cells transfected with constructs that bound CREB but not SF-1 (or the converse) resulted in a loss of approximately 50% cAMP-dependent CAT activity. Transgenes that did not bind CREB or SF-1 exhibited no cAMP-dependent CAT activity. When these same constructs where transfected into R2C Leydig cells, mutation of either the CREB or SF-1 binding sites resulted in a greater than 90% loss of CAT activity. Western blot and immunocytochemistry analyses revealed that the amount of phosphorylated CREB increased in response to hormone/cAMP in granulosa cells and was high in R2C Leydig cells, coinciding with expression of the transgenes and endogenous aromatase mRNA in each cell type. Therefore, in both cell types the aromatase promoter is dependent upon a functional CRE and the presence of phosphoCREB. The CREB and SF-1 binding sites interact in an additive manner to mediate cAMP transactivation in granulosa cells, whereas they interact synergistically to confer high basal transactivation in R2C Leydig cells. Taken together, the results indicated that the molecular mechanisms or pathways that activate CREB, SF-1 or their interaction are different in granulosa cells and R2C cells.