Chicken beta B1-crystallin gene expression: presence of conserved functional polyomavirus enhancer-like and octamer binding-like promoter elements found in non-lens genes

Pax6 regulation of Math5 during mouse retinal neurogenesis

Activation of the bHLH factor Math5 (Atoh7) is an initiating event for mammalian retinal neurogenesis, as it is critically required for retinal ganglion cell formation. However, the cis-regulatory elements and trans-acting factors that control Math5 expression are largely unknown. Using a combination of transgenic mice and bioinformatics, we identified a phylogenetically conserved regulatory element that is required to activate Math5 transcription during early retinal neurogenesis. This element drives retinal expression in vivo, in a cross-species transgenic assay. Previously, Pax6 was shown to be necessary for the initiation of Math5 mRNA expression. We extend this finding by showing that the Math5 retinal enhancer also requires Pax6 for its activation, via Pax6 binding to a highly conserved binding site. In addition, our data reveal that other retinal factors are required for accurate regulation of Math5 by Pax6.

CD13/APN transcription is regulated by the proto-oncogene c-Maf via an atypical response element

Angiogenic growth factors induce the transcription of the cell surface peptidase CD13/APN in activated endothelial cells of the tumor vasculature. Inhibition of CD13/APN abrogates endothelial invasion and morphogenesis in vitro and tumor growth in vivo suggesting a critical functional role for CD13 in angiogenesis. Experiments to identify the transcription factors responsible for this regulation demonstrated that exogenous expression of the proto-oncogene c-Maf, but not other bZip family members tested, potently activates transcription from a critical regulatory region of the CD13 proximal promoter between -115 and -70 bp which is highly conserved among mammalian species. Using promoter mutation, EMSA and ChIP analyses we established that both endogenous and recombinant c-Maf directly interact with an atypical Maf response element contained within this active promoter region via its basic DNA/leucine zipper domain. However full activity of c-Maf requires the amino-terminal transactivation domain, and site-directed mutation of putative phosphorylation sites within the transactivation domain (serines 15 and 70) shows that these sites behave in a dramatic cell type-specific manner. Therefore, this atypical response element predicts a broader range of c-Maf target genes than previously appreciated and thus impacts its regulation of multiple myeloma as well as endothelial cell function and angiogenesis.

Genetic and epigenetic mechanisms of gene regulation during lens development

Recent studies demonstrated a number of links between chromatin structure, gene expression, extracellular signaling and cellular differentiation during lens development. Lens progenitor cells originate from a pool of common progenitor cells, the pre-placodal region (PPR) which is formed from a combination of extracellular signaling between the neural plate, naïve ectoderm and mesendoderm. A specific commitment to the lens program over alternate choices such as the formation of olfactory epithelium or the anterior pituitary is manifested by the formation of a thickened surface ectoderm, the lens placode. Mouse lens progenitor cells are characterized by the expression of a complement of lens lineage-specific transcription factors including Pax6, Six3 and Sox2, controlled by FGF and BMP signaling, followed later by c-Maf, Mab21like1, Prox1 and FoxE3. Proliferation of lens progenitors together with their morphogenetic movements results in the formation of the lens vesicle. This transient structure, comprised of lens precursor cells, is polarized with its anterior cells retaining their epithelial morphology and proliferative capacity, whereas the posterior lens precursor cells initiate terminal differentiation forming the primary lens fibers. Lens differentiation is marked by expression and accumulation of crystallins and other structural proteins. The transcriptional control of crystallin genes is characterized by the reiterative use of transcription factors required for the establishment of lens precursors in combination with more ubiquitously expressed factors (e.g. AP-1, AP-2alpha, CREB and USF) and recruitment of histone acetyltransferases (HATs) CBP and p300, and chromatin remodeling complexes SWI/SNF and ISWI. These studies have poised the study of lens development at the forefront of efforts to understand the connections between development, cell signaling, gene transcription and chromatin remodeling.

Transgenic overexpression of connexin50 induces cataracts

To examine the effects of increased expression of Cx50 in the mouse lens, transgenic mice were generated using a DNA construct containing the human Cx50 coding region and a C-terminal FLAG epitope driven by the chicken betaB1-crystallin promoter. Expression of this protein in paired Xenopus oocytes induced gap junctional currents of similar magnitude to wild type human Cx50. Three lines of transgenic mice expressing the transgenic protein were analyzed. Lenses from transgenic mice were smaller than those from non-transgenic littermates, and had cataracts that were already visible at postnatal day 1. Expression of the transgene resulted in a 3- to 13-fold increase in Cx50 protein levels above those of non-transgenic animals. Light microscopy revealed alterations in epithelial cell differentiation, fiber cell structure, interactions between fiber cells and areas of liquefaction. Scanning electron microscopy showed fiber cells of varying widths with bulging areas along single fibers. Anti-Cx50 and anti-FLAG immunoreactivities were detected at appositional membranes and in intracellular vesicles in transgenic lenses. N-cadherin, Cx46, ZO-1 and aquaporin 0 localized mainly at the plasma membrane, although some N-cadherin and aquaporin 0 was associated with the intracellular vesicles. The abundance and solubility/integrity of alphaA-, alphaB-, beta- and gamma-crystallin were unaffected. These results demonstrate that transgenic expression of Cx50 in mice leads to cataracts associated with formation of cytoplasmic vesicles containing Cx50 and decreased or slowed epithelial differentiation without major alterations in the distribution of other integral membrane or membrane-associated proteins or the integrity/solubility of crystallins.

Recapitulation of human betaB1-crystallin promoter activity in transgenic zebrafish

Development of the eye is morphologically similar among vertebrates, indicating that the underlying mechanism regulating the process may have been highly conserved during evolution. Herein we analyzed the promoter of the human betaB1-crytallin gene in zebrafish by transgenic experiments. To delineate the evolutionarily conserved regulatory elements, we performed serial deletion assays in the promoter region. The results demonstrated that the -90/+61-bp upstream proximal promoter region is sufficient to confer lens-tissue specificity to the human betaB1-crystallin gene in transgenic zebrafish. Through phylogenetic sequence comparisons and an electrophoretic mobility shift assay (EMSA), a highly conserved cis-element of a six-base pair sequence TG(A/C)TGA, the consensus sequence for the Maf protein binding site, within the proximal promoter region was revealed. Further, a site-mutational assay showed that this element is crucial for promoter activity. These data suggest that the fundamental transcriptional regulatory mechanism of the betaB1-crystallin gene has been well conserved between humans and zebrafish, and plausibly among all vertebrates, during evolution.

DeltaFosB expression and cataract

DeltaFosB is a truncated form of a FosB transcription factor, which is created by alternative splicing. Previous work has shown that transgenic mice expressing DeltaFosB both in the retina and in the lens developed a posterior subcapsular cataract resulting from the misalignment of the fibres in the suture region. In the previous study, it was not clear whether DeltaFosB expression was required in both tissues to produce the cataract. Therefore, DeltaFosB expression targeted to either the lens or the retina was undertaken in order to clarify the contribution of each tissue to cataract development. For lens expression, the R2betaB1DeltaFosB construct was synthesized (R2, an enhancer; betaB1, a chicken betaB1 crystallin gene promoter fragment). For the retina, RhoDeltaFosB was prepared. As a promoter, the bovine rhodopsin upstream region was used. DeltaFosB expression in heterozygote animals was monitored by Western blotting. Cataract development in heterozygotes of R2betaB1DeltaFosB transgenics and in both heterozygotes and homozygotes of RhoDeltaFosB transgenics was followed by slitlamp examination. The transgenic mice prepared with RhoDeltaFosB expressed DeltaFosB only in the retina and showed no sign of lens opacity. One line of the R2betaB1DeltaFosB transgenic was found to have expression only in the lens and developed posterior subcapsular cataract. We concluded that retinal expression of DeltaFosB is not sufficient to cause cataract while expression exclusively in the lens produces posterior subcapsular cataract.

Roles of Maf family proteins in lens development

Lens provides a good model for studying developmental cues relevant to cellular and molecular interactions. Basic region/leucine zipper (bZIP) transcription factors have been found to play key roles during eye formation in various species, including human, mouse, rat, Xenopus, zebrafish, chick, and quail. Different ocular developmental anomalies associated with MAF mutation in human implicate its active role during eye development. Several members of the maf gene family with this bZIP motif participate directly in lens morphogenesis. One vital Maf protein, L-Maf, is expressed in developing lens cells of chick embryos. Its homolog recently has been detected in lens placode of Xenopus embryos and regulates expression of lens fiber-specific genes in this species. Ectopic expression of L-Maf can induce lens-specific genes in cultured retina cells and embryonic ectoderm. The dominant-negative form of L-Maf causes the suppression of crystallin expression and subsequently inhibits lens formation, indicating that L-Maf plays a central role in chick lens development.

Suppression of lens growth by alphaA-crystallin promoter-driven expression of diphtheria toxin results in disruption of retinal cell organization in zebrafish

In order to study lens-retina relationships during development, we cloned the zebrafish alphaA-crystallin cDNA and its promoter region. Using a 2.8-kb fragment of the zebrafish alphaA-crystallin promoter (z(alpha)Acry), we expressed the diphtheria toxin A fragment (DTA) in zebrafish embryos in a lens-specific manner. Injection of the z(alpha)Acry-DTA plasmid into eggs at the one-or two-cell stage resulted in the formation of small eyes, in which both lens and retina were reduced in size. In the DTA-expressing lenses, their fiber structure was disorganized, indicating that normal lens development had been abrogated. The neural retina also showed abnormal development, although this tissue did not express DTA. Lamination in the retina did not develop well, and molecular markers for the outer and inner plexiform layers were either abnormally expressed or absent. However, cell type-specific markers of ganglion and bipolar cells, as well as photoreceptors, were expressed in appropriate positions, indicating that initial differentiation of these retinal subpopulations occurred in the DTA-expressing embryos. Cell proliferation also proceeded normally in these embryos, although apoptosis was enhanced. These results suggest that the differentiated lens plays a critical role in the morphogenetic organization of retinal cells during eye development in zebrafish embryos.

The mouse beta B1-crystallin promoter: strict regulation of lens fiber cell specificity

Previous studies have shown that the chicken beta B1-crystallin promoter (-434/+30) contains all of the signals necessary to specifically direct high level expression of heterologous genes to the lens fiber cells of mice. In the present study, the mouse beta B1-crystallin gene was cloned, and its regulation was investigated to further elucidate the mechanisms controlling lens fiber cell-specific gene expression. Phylogenetic footprinting analysis of the 5' flanking sequence from the mouse, rat, human and chicken beta B1-crystallin genes identified several known and putative functional cis elements including the PL2 element which is required for lens-specific expression of the chicken beta B1 promoter. Surprisingly, however, all six mouse beta B1-crystallin/CAT constructs tested (-1493/+44, -1493/+30, -870/+30, -250/+30, -135/+30 and -98/+30) were inactive in three different mammalian lens-derived cell lines while only the -870/+30 and -98/+30 constructs were active in chicken primary patched lens epithelial cells. In contrast, the chicken beta B1-crystallin promoter (-434/+30) was transcriptionally active in all lens-derived cells tested. Transgenic mice harboring a mouse beta B1-crystallin -1493/+44 CAT construct did express the transgene specifically in lens fiber cells, however, at lower levels than that previously reported for a chicken -434/+30 CAT construct. These data suggest that, as in other crystallin genes, the regulatory signals controlling lens fiber cell-specific expression are conserved between chicken and mouse. However, the inability of the mouse beta B1-crystallin promoter to function in mammalian lens-derived cultured cells implies that this gene has acquired additional cis-regulatory elements to ensure lens fiber cell specificity.

Sequential activation of transcription factors in lens induction

Since the pioneering work of the early 1900s, the lens has been used as a model system for the study of tissue development in vertebrates. A number of embryological transplantation experiments designed to elucidate the role of tissue interactions in the formation of the lens have led to the proposal of a stepwise determination model. This model has recently been refined through the identification of certain transcription factor genes, which exhibit distinct expression patterns and functional properties in the lens cell lineage. Otx2, Pax6, and Lens1 are induced by the adjacent anterior neural plate and expressed in predifferentiated lens ectoderm. Contact between the optic vesicle and lens ectoderm promotes expression of mafs, Soxs, and Prox1, which are responsible for the initiation of lens differentiation programs including crystallin expression, cell elongation, and cell cycle arrest. Further analysis of the expression and functional characteristics of these transcription factors will allow greater detail when describing the orchestration of genetic programs, which control tissue development from induction to maturation.

Molecular cloning and characterization of the mouse Ecm1 gene and its 5' regulatory sequences

The mouse Ecm1 (extracellular matrix protein 1) gene codes for an extracellular protein of 85kDa. We have determined the primary structure of this gene and analysed 1665 bases of its 5' upstream regulatory region. The gene is approximately 5kb long and contains 11 exons. The exons range in size from 45 to 375bp, whereas the intron sizes ranges from 95 to 1115bp. All splice donor/acceptor sites conform to the GT/AG rule. The 5' upstream sequences contain a TATA-box, a CCAAT-box and an inverted CCAAT-box. We have analysed the Ecm1 regulatory elements by reporter gene constructs and transient transfections in the stromal osteogenic cell line MN7. Progressive deletion of the Ecm1 promoter revealed the presence of a region with a repressive activity between -110 and -317 and showed that a 110-bp fragment, containing potential binding sites for AP1, Sp1, GATA and Ets family of transcription factors, is sufficient for CAT expression in MN7 cells. Except for the GATA binding site, these regulatory sequences are conserved in the human promoter. Point mutation analysis revealed that the AP1, Sp1 and Ets binding sites are absolutely necessary for Ecm1 expression in MN7.

Transcription factor CP2 is essential for lens-specific expression of the chicken alphaA-crystallin gene

BACKGROUND

Lens-specific transcriptional activation of the chicken alphaA-crystallin gene is controlled by the distal and proximal enhancers, alphaCE1 and alphaCE2, respectively. Analysis using specific monoclonal antibodies against purified alphaCE1-binding factor alphaCEF1 revealed that alphaCEF1 is composed of two distinct subunits.

RESULTS

We have demonstrated that one of the subunits of alphaCEF1 is encoded by chicken ubiquitous transcription factor CP2 (cCP2), which is homologous to mouse CP2, and human CP2/LBP-1/LSF-1. Electrophoretic mobility shift assays and cross-linking experiments showed that alphaCEF1 and bacterially expressed cCP2 form a tetramer. Overexpression of cCP2 activates transcription through alphaCE1, but a mutant cCP2 lacking the DNA-binding domain reduced the transcription to basal levels. Although cCP2 binds to the CP2 template from the mouse alpha-globin promoter, it fails to promote transcription through this template. Element substitution experiments between alphaCE1 and the CP2 template revealed that the lens-specific enhancer activity of alphaCE1 is due to the 6 bp sequence (-139/-134; lens-specific element (LSE)) adjacent to the 3' of the cCP2 binding site within alphaCE1.

CONCLUSION

We have shown that the tetrameric transcription factor cCP2 is essential for lens-specific transcription of the chicken alphaA-crystallin gene, although it is ubiquitously expressed. We propose a model where cCP2 cooperates with a putative lens-specific factor which binds to LSE.

Transgenic analyses reveal developmentally regulated neuron- and muscle-specific elements in the murine neurofilament light chain gene promoter

We report here the developmental activity of regulatory elements that reside within 1.7 kilobases of the murine neurofilament light chain (NF-L) gene promoter. NF-L promoter activity is first detected at embryonic day 8.5 in neuroepithelial cells. Neuron-specific gene expression is maintained in the spinal cord until embryonic day 12.5 and at later developmental stages in the brain and sensory neuroepithelia. After day 14.5, the promoter becomes active in myogenic cells. Transgene expression in both neurons and muscle is consistent with the detection of endogenous NF-L transcript in both neuronal and myogenic tissues of neonates by reverse transcriptase-polymerase chain reaction. Neuron- and muscle-specific activities of the NF-L promoter decrease and are nearly undetectable after birth. Thus, the 1.7-kilobase NF-L promoter contains regulatory elements for initiation but not maintenance of transcription from the NF-L locus. Deletion analyses reveal that independent regulatory elements control the observed tissue-specific activities and implicate a potential MyoD binding site as the muscle-specific enhancer. Our results demonstrate that the NF-L promoter contains distinct regulatory elements for both neuron- and muscle-specific gene expression and that these activities are temporally separated during embryogenesis.

The cooperation between two silencers creates an enhancer element that controls both the lens-preferred and the differentiation stage-specific expression of the rat beta B2-crystallin gene

The rat beta B2-crystallin gene is active only during a specific stage of the differentiation of rat lens fibre cells directed by basic fibroblast growth factor. The regulatory elements that determine the transient activity of this gene are located in the -750/-123 region and in the first intron. Singly, these elements act as silencers, together they constitute an enhancer that is active only during the specific differentiation stage. An additional silencer is found between -123 and -77. The proximal promoter region contains a Pax-6 binding site at -65/-51. In vitro, binding to this site could be detected but, according to in vivo footprinting experiments, this site is not occupied in the endogenous gene. Furthermore, co-expression of Pax-6 did not enhance promoter activity. Finally, mutation or deletion of this site did not affect promoter activity: the region -37/+10 sufficed for basal promoter activity. The cooperation between the -750/ -123 region and the first intron of the beta B2-crystallin gene not only determines the differentiation stage-specific activity of the gene, but also contributes to the highly increased expression in lens cells compared with non-lens cells.

Developmental regulation of the chicken beta B1-crystallin promoter in transgenic mice

The cis-elements responsible for the high-level, lens-specific expression of the chicken beta B1-crystallin gene were investigated by generating mice harboring beta B1-crystallin promoter/chloramphenicol acetyl transferase (CAT) transgenes. Deletion of promoter sequences -434/-153 and -152/-127 as well as site-directed mutagenesis of the PL1 (-116/-102) and Pl2 (-90/-76) elements significantly decreased CAT gene expression in the lenses of adult transgenic mice. Transfection studies using multimerized PL1 and PL2 elements fused to the chicken beta-actin basal promoter indicated that PL1 is a general activating element while PL2 is involved in the lens-specificity of the chicken beta B1-crystallin promoter. CAT histochemistry demonstrated that the chicken beta B1-crystallin promoter (-434/+30) was active in both primary and secondary lens fiber cells from 12.5 days post coitum (dpc) until adulthood. Activity of the -152/+30/CAT transgene was relatively low and confined to the primary lens fiber cells of 16.5 dpc mice. Together, these data suggest that the reduced activity of this promoter in the adult lens is due both to this developmentally restricted expression pattern and a reduction in promoter activity. RNA hybridization studies demonstrated that the chicken beta B1-crystallin/CAT (-434/+30) transgene was expressed at similar levels in the same cells as the endogenous mouse beta B1-crystallin gene in 16.5 dpc transgenic mouse embryos. These data show a strict conservation of the lens-specific spatial and temporal regulation of the chicken and mouse beta B1-crystallin genes.

Lens crystallins of invertebrates--diversity and recruitment from detoxification enzymes and novel proteins

The major proteins (crystallins) of the transparent, refractive eye lens of vertebrates are a surprisingly diverse group of multifunctional proteins. A number of lens crystallins display taxon-specificity. In general, vertebrate crystallins have been recruited from stress-protective proteins (i.e. the small heat-shock proteins) and a number of metabolic enzymes by a gene-sharing mechanism. Despite the existence of refractive lenses in the complex and compound eyes of many invertebrates, relatively little is known about their crystallins. Here we review for the first time the state of knowledge of invertebrate crystallins. The major cephalopod (squid, octopus, and cuttlefish) crystallins (S-crystallins) have, like vertebrate crystallins, been recruited from a stress protective metabolic enzyme, glutathione S-transferase. The presence of overlapping AP-1 and antioxidant responsive-like sequences that appear functional in transfected vertebrate cells suggest that the recruitment of glutathione S-transferase to S-crystallins involved response to oxidative stress. Cephalopods also have at least two taxon-specific crystallins: omega-crystallin, related to aldehyde dehydrogenase, and omega-crystallin, related to a superfamily of lipid-binding proteins. L-crystallin (probably identical to O-crystallin) is the major protein of the lens of the squid photophore, a specialized structure for emitting light. The use of L/omega-crystallin in the ectodermal lens of the eye and the mesodermal lens of the photophore of the squid contrasts with the recruitment of different crystallins in the ectodermal lenses of the eye and photophore of fish. S-and omega-crystallins appear to be lens-specific (some S-crystallins are also expressed in cornea) and, except for one S-crystallin polypeptide (SL11/Lops4; possibly a molecular fossil), lack enzymatic activity. The S-crystallins (except SL11/Lops4) contain a variable peptide that has been inserted by exon shuffling. The only other invertebrate crystallins that have been examined are in one marine gastropod (Aplysia, a sea hare), in jellyfish and in the compound eyes of some arthropods; all are different and novel proteins. Drosocrystallin is one of three calcium binding taxon-specific crystallins found selectively in the acellular corneal lens of Drosophila, while antigen 3G6 is a highly conserved protein present in the ommatidial crystallin cone and central nervous system of numerous arthropods. Cubomedusan jellyfish have three novel crystallin families (the J-crystallins); the J1-crystallins are encoded in three very similar intronless genes with markedly different 5' flanking sequences despite their almost identical encoded proteins and high lens expression. The numerous refractive structures that have evolved in the eyes of invertebrates contrast markedly with the limited information on their protein composition, making this field as exciting as it is underdeveloped. The similar requirement of Pax-6 (and possibly other common transcription factors) for eye development as well as the diversity, taxon-specificity and recruitment of stress-protective enzymes as crystallins suggest that borrowing multifunctional proteins for refraction by a gene sharing strategy may have occurred in invertebrates as did in vertebrates.

Sequence, initial functional analysis and protein-DNA binding sites of the mouse beta B2-crystallin-encoding gene

An 800-bp fragment of genomic DNA upstream from the origin of transcription of the mouse beta B2-crystallin-encoding gene (beta B2-Cry) has been isolated and its nucleotide sequence determined. Promoter fragments 275 to +30 or -110 to +30, fused to cat reporter gene, activated transcription in transiently transfected rabbit lens epithelial cells, but not in various non-lens cells. The beta B2-Cry mouse promoter contains a typical TATA-box located approx. 25 bp upstream from the transcription start point. Binding sites (upstream from the TATA-box) for transcription factors possibly involved in the regulation of gene expression have been identified by DNaseI footprinting analysis and lens cell nuclear extracts. Most notably is the binding of the Pax-6 paired domain (PrD) which correlates with the binding of lens cell nuclear proteins at the -80 to -40 region.

Beta B2-crystallin in the mammalian retina

beta-crystallins are abundant lens proteins in most, if not all vertebrate species. We have previously reported the presence of low levels of beta-crystallins in chick non-lens tissues, both ocular and extra-ocular, including the expression of beta B2-crystallin in the retina. Here we report that extralenticular beta-crystallin expression is also found in mammals. beta B2-crystallin is expressed in mouse and cat neural and pigmented retinas and in cat iris. Although present at levels lower than those found in the lens, the appearance and accumulation of beta B2-crystallin in the neural retina coincides with the functional maturation of this tissue.

The chicken beta A4- and beta B1-crystallin-encoding genes are tightly linked

Analysis of the 5' flanking region of the chicken beta B1-crystallin-encoding gene (beta B1-cry) revealed regions of sequence homology with the bovine beta A4-crystallin-encoding gene (beta A4-cry). Subsequently, the chicken beta A4-cry cDNA sequence was determined, and it was demonstrated that beta A4- and beta B1-cry are linked head to head in the chicken chromosome with 2147 nucleotides (nt) of intergenic spacer. Chicken beta A4-cry contains six exons, with the first exon being noncoding. Chicken beta A4-cry is the smallest beta-cry ever described, due to the small size of its introns which range in length from 68 to 96 nt. While three polymorphisms were noted between some cDNA clones and the genomic sequence, Southern blot analysis demonstrated that beta A4-cry exists as a single copy in the chicken genome. Northern blot analysis indicated that beta A4-cry is a lens-specific transcript which is expressed at higher levels in the embryo than in the adult. The beta A4-cry mRNA is present at 400-fold lower levels than the beta B1-cry mRNA in the 14-day embryonic chicken lens, and at 2000-fold lower levels than the beta B1-cry mRNA in the adult lens. These results are consistent with the idea that the beta-cry family was once clustered in the chromosome as the gamma-cry family is today, and raises the possibility that the relatively low expression of beta A4-cry is mechanistically linked to the high expression of beta B1-cry in the chicken lens.

Chicken beta B1 crystallin: gene sequence and evidence for functional conservation of promoter activity between chicken and mouse

The complete sequence was determined for the chicken beta B1-crystallin gene and 2.2 kbp of its 5' flanking region; the chicken gene was then compared to its rat ortholog. Although both have a 5' non-coding exon followed by 5 protein coding exons, the chicken gene is only 2.2 kbp while the rat gene is 13.6 kpb due to longer introns. The coding exons of the chicken beta B1-crystallin gene, like those of the rat and other beta-crystallin genes, each correspond to one of the four 'Greek key' motifs of the encoded protein. The only obvious similarity between the 5' flanking sequences of the chicken and rat beta B1-crystallin gene is associated with the TATA box. A CR1 repetitive element is present at positions -559 to -730 of the chicken beta B1-crystallin gene. In vivo footprinting using dimethyl sulfate/ligation mediated PCR showed that the PL-1 (-116/-102), PL-2 (-90/-76), OL-2 (-75/-68) and OL-1 (-125/-118) control elements identified previously (Roth et al. (1991) Mol. Cell. Biol. 11, 1488-1499) bind proteins within the chromatin of cultured embryonic chicken lens cells. Both -2448/+30 and -434/+30 promoter fragments from the chicken beta B1-crystallin gene directed lens-specific CAT gene expression in a copy number and position independent manner in transgenic mice. These data indicate that the structure and lens-specific expression of this gene are highly conserved although, like other crystallin genes, the 5' flanking sequences have diverged appreciably during evolution.

Functional analysis of chicken vimentin distal promoter regions in cultured lens cells

Synthesis of the cytoskeletal intermediate filament protein vimentin (Vim) in the lens is unexpected due to the mesenchymal preference of Vim-encoding gene (Vim) expression and the epithelial origin of the lens. Previous studies indicated that chicken Vim gene expression in cultured lens cells is regulated by both positive- and negative-acting sequence elements within the first -767 nucleotides (nt) of its promoter. Here, we demonstrate the existence of additional upstream chicken Vim promoter elements which function in transfected lens cells. Sequences within the nt -1360/-1156 region repressed promoter activity in transfected lens cells to levels lower than that observed for the previously defined more proximal repressor elements. The -1612/-1360 region activated promoter activity to levels similar to those observed for the strongest previously defined proximal promoter. The nt sequence analysis of the upstream promoter region revealed the presence of multiple consensus repressor and activator transcription-factor-binding sites. Several of these sites have been implicated for lens expression of enzyme-crystallin-encoding genes (cry), suggesting that Vim expression may share features with the cry genes for recruitment and high-level expression in the lens.

Structure and lens expression of the gene encoding chicken beta A3/A1-crystallin

The beta A1- and beta A3-crystallins are major polypeptides in the lenses of vertebrates. We present evidence that a single beta A3/A1 gene encodes these two proteins in the chicken. The beta A3/A1 gene has been sequenced and its functional promoter identified in transfection experiments. The chicken beta A3/A1 gene has the same structure as the human orthologue: six exons with standard splice sites and two alternative start codons from which the protein products are apparently translated. Northern analysis revealed an abundant 0.9-kb transcript in the lenses of 1-2-day-old chickens and no detectable transcripts in the rest of the eye, brain, heart, kidney, liver or skeletal muscle. The 5'-flanking sequence of the chicken beta A3/A1 gene is very similar to that of the human and mouse genes, suggesting conservation of important putative regulatory sequences in addition to the TATA box. A thymidine-rich element (bp -218 to -163) and a potential AP-1-binding site (bp -264 to -258) are present within the chicken 5'-flanking region. A DNA fragment from -382 to +22 of the chicken beta A3/A1 gene is sufficient to promote expression of the bacterial cat gene in transfected chicken primary lens epithelial cells, but not in transfected dermal fibroblasts.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular analyses of carbonic anhydrase-II expression and regulation in the developing chicken lens

The expression of carbonic anhydrase-II (CA-II) in the developing chicken lens was examined and compared with that in the retina of the chicken embryo. CA-II expression was measured by immunohistochemistry and radioimmunoassay during development, and CA-II mRNA was quantified by Northern blot and densitometric scanning and localized by in situ hybridization. A functional promoter of the chicken CA-II gene was identified by transfection of primary embryonic chicken lens epithelial cells and analyzed in deletion mutants. The results establish that CA-II makes up about 0.1% of the total soluble protein of the embryonic chicken lens, an amount insufficient to make it a candidate for an enzyme crystallin in this species. Lens fiber differentiation coincided with a loss of CA-II mRNA and protein; by contrast, CA-II persisted in the epithelial cells of the embryonic and mature lens. This and previous studies showed that CA-II amounts to as much as 3% of the protein of the embryonic chicken retina and follows a different developmental time course of expression; like the lens, CA-II decreases until day 10 in the embryonic retina, but, unlike the lens, it increases thereafter and plateaus at hatching. Progressive deletions of the 5' flanking regions (from position -1314 to +32) of the CA-II gene fused to the bacterial chloramphenicol acetyltransferase (CAT) reporter gene resulted in a gradual loss of promoter activity, consistent with an additive effect of putative cis-regulatory elements found in many crystallin genes. These experiments provide the foundation for a molecular analysis of the developmental and differential regulation of the CA-II gene in lens and retina.

Structure and expression of the duck alpha-enolase/tau-crystallin-encoding gene

In the duck, the glycolytic enzyme, alpha-enolase (alpha ENO) and the lens structural protein, tau-crystallin (tau CRY), are products of the same gene, an example of protein multi-functionality. We report that duck alpha ENO/tau CRY mRNA levels are developmentally regulated: alpha ENO/tau CRY mRNA levels in the lens increase over those in the liver by embryonic day 14 and, within the lens, are higher in the lens epithelium than in fiber cells. We determined the structure of the duck alpha ENO/tau CRY-encoding gene (alpha ENO/tau CRY), sequenced 1 kb of 5'-flanking region, and demonstrated that this region contains a functional promoter. The gene is 13 kb in size and is composed of twelve exons; the exon organization is identical to that of mammalian enolase-encoding genes. A fragment of 5'-flanking region (-803/+3) containing three CCAAT boxes and a TATA box was able to activate transcription of a heterologous reporter gene when transfected into cultured lens cells. However, in spite of greater quantities of alpha ENO/tau CRY mRNA and protein in the lens, the promoter was equally active in primary cultures of embryonic lens, liver and fibroblast cells. Since the cultured cells unexpectedly lost the restricted pattern of alpha ENO/tau CRY mRNA levels observed in vivo, evaluation of the promoter's tissue specificity was precluded.