Sequence of a complete chicken delta-crystallin cDNA

Bmp4 mediates apoptotic cell death in the developing chick eye

The bone morphogenetic protein (BMP) expression in vertebrates suggests a reiterative function of these molecules during eye development. However, genetic analysis in mice has provided only partial information. Using the chick embryo as a model system, we have analyzed possible additional functions of BMP4 during optic cup formation. Here we describe the expression pattern of Bmp4 and Bmp7 and we show that, in contrast to the mouse, the prospective lens placode ectoderm expresses high levels of Bmp4 but no Bmp7. After optic vesicle invagination, Bmp4 is expressed in the prospective dorsal neural retina, where BmprIA, BmprII, and Smad1, components of the BMP4 signal transduction pathway, are also expressed. In toto terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end-labeling analysis shows that the dorsal optic cup is the site of a spatiotemporally restricted apoptosis, which parallels the expression not only of Bmp4 but also of Msx1 and Msx2, genes implicated in BMP4-mediated apoptosis. The use of optic vesicle cultures as well as in ovo local addition of BMP4 and its antagonist Noggin proves that the local activity of BMP4 is responsible for programmed cell death in the dorsal optic cup. In addition, we show that Noggin is able to reduce the rate of cell proliferation in the dorsal part of the optic cup whereas BMP4 increases the number of BrdU-positive cells in retina cultures. These results provide evidence that BMP4 contributes to eye development by promoting cell proliferation and programmed cell death.

Bmp4 mediates apoptotic cell death in the developing chick eye

The bone morphogenetic protein (BMP) expression in vertebrates suggests a reiterative function of these molecules during eye development. However, genetic analysis in mice has provided only partial information. Using the chick embryo as a model system, we have analyzed possible additional functions of BMP4 during optic cup formation. Here we describe the expression pattern of Bmp4 and Bmp7 and we show that, in contrast to the mouse, the prospective lens placode ectoderm expresses high levels of Bmp4 but no Bmp7. After optic vesicle invagination, Bmp4 is expressed in the prospective dorsal neural retina, where BmprIA, BmprII, and Smad1, components of the BMP4 signal transduction pathway, are also expressed. In toto terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end-labeling analysis shows that the dorsal optic cup is the site of a spatiotemporally restricted apoptosis, which parallels the expression not only of Bmp4 but also of Msx1 and Msx2, genes implicated in BMP4-mediated apoptosis. The use of optic vesicle cultures as well as in ovo local addition of BMP4 and its antagonist Noggin proves that the local activity of BMP4 is responsible for programmed cell death in the dorsal optic cup. In addition, we show that Noggin is able to reduce the rate of cell proliferation in the dorsal part of the optic cup whereas BMP4 increases the number of BrdU-positive cells in retina cultures. These results provide evidence that BMP4 contributes to eye development by promoting cell proliferation and programmed cell death.

Gene sharing by delta-crystallin and argininosuccinate lyase

The lens structural protein delta-crystallin and the metabolic enzyme argininosuccinate lyase (ASL; L-argininosuccinate arginine-lyase, EC 4.3.2.1) have striking sequence similarity. We have demonstrated that duck delta-crystallin has enormously high ASL activity, while chicken delta-crystallin has lower but significant activity. The lenses of these birds had much greater ASL activity than other tissues, suggesting that ASL is being expressed at unusually high levels as a structural component. In Southern blots of human genomic DNA, chicken delta 1-crystallin cDNA hybridized only to the human ASL gene; moreover, the two chicken delta-crystallin genes accounted for all the sequences in the chicken genome able to cross-hybridize with a human ASL cDNA, with preferential hybridization to the delta 2 gene. Correlations of enzymatic activity and recent data on mRNA levels in the chicken lens suggest that ASL activity depends on expression of the delta 2-crystallin gene. The data indicate that the same gene, at least in ducks, encodes two different functions, an enzyme (ASL) and a structural protein (delta-crystallin), although in chickens specialization and separation of functions may have occurred.

Promoter activity of the two chicken delta-crystallin genes in a Hela cell extract

The in vitro transcriptional activity of the two delta-crystallin genes (5'-delta 1-delta 2-3') of the chicken was studied in a whole Hela cell extract. Both the delta 1 and delta 2 promoters were recognized by RNA polymerase II in this heterologous system. The major RNA initiation site from the delta 1 promoter was the same in vitro as that which occurs in vivo, as judged by mapping with S1-nuclease, although other minor initiation sites upstream and downstream of the major initiation site were noted. A primer extension experiment showed that the longest RNA synthesized in vitro from a delta 2 template initiated near the beginning of the first exon. The delta 1 promoter was several-fold stronger than that of delta 2 under the present in vitro conditions. Transcription from the delta 1 promoter was abolished by a competitor fragment (c'-II; includes -328 to -63) purified from the delta 2 promoter, indicating that one or more common transcription factors binding upstream from the TATA box are required for in vitro function of the two delta-crystallin promoters. Thus, in the Hela cell extract both delta-crystallin genes contain a functional promoter. We consider the possibility that the single 5'CCAAT3' sequence present in the delta 1 promoter (but lacking in the delta 2 promoter) may contribute to its greater core activity under our conditions. The greater promoter activity of the delta 1-crystallin gene in the Hela cell extract was not sufficient to account for the large ratio of delta 1 to delta 2 mRNA (approximately 50 to 100) in the embryonic chicken lens.

Lens-specific enhancer in the third intron regulates expression of the chicken delta 1-crystallin gene

We have previously shown that the tissue specificity determinant of the chicken delta 1-crystallin gene lies 3' of position -100 (Hayashi et al. 1985). Since the promoter of the gene (delta 1-crystallin promoter) did not show any tissue specificity, we examined various segments of the delta 1-crystallin gene for a tissue-specific enhancer activity by placing each segment downstream of a heterologous transcriptional unit coding for chloramphenicol acetyltransferase (CAT) and by transfecting chicken tissues in primary culture. We found that a segment spanning the third intron bears a strong lens-specific enhancer activity. This "delta 1-crystallin enhancer" activates transcription from the delta 1-crystallin promoter 20- to 40-fold in lens cells and to various degrees with other promoters. Deletion analysis of the enhancer region indicated that it covered nearly 1 kb but did not indicate clear-cut boundaries. For its enhancer effect the core region of 120 bp and associations with certain adjoining regions were required. Removal of the enhancer from the gene totally abolished delta 1-crystallin expression, and reinsertion of the enhancer in either upstream, internal, or downstream positions restored expression. We conclude that the delta 1-crystallin enhancer is an essential and major determinant for lens-specificity of delta 1-crystallin expression.

Conservation of delta-crystallin gene structure between ducks and chickens

A cloned chicken delta-crystallin cDNA was used to identify two putative delta-crystallin genes in the duck by Southern blot hybridization. A DNA fragment containing most of one of these genes was isolated from a library made in bacteriophage lambda Charon 28A containing genomic DNA from 14-day-old embryonic ducks. Electron microscopy, partial gene sequencing, primer extension analysis using duck mRNA, and comparison with the well-characterized chicken delta-crystallin genes suggest that our cloned duck delta-crystallin gene, like the chicken delta-crystallin genes, is 8-10 kb long and contains 17 exons. Hybridization and sequencing data show great similarity between the homologous 5' untranslated and coding exons of the duck and chicken delta-crystallin genes. Overall, the homologous introns also appear to have approximately 30% sequence similarity, and have been subject to deletion/insertion events. Our partial characterization of duck delta-crystallin gene sequences suggests that this avian and reptilian crystallin family has been conserved during evolution, as have the other crystallin gene families that are expressed in the eye lens.

In vivo competition of delta-crystallin gene expression by DNA fragments containing a GC box

Expression of the chicken delta-crystallin gene 1 injected into the nuclei of mouse cells is lens specific. Coinjection of GC box-containing DNA fragments from delta-crystallin, simian virus 40 early, and herpes simplex virus type 1 tk promoters effectively suppressed delta-crystallin expression in the lens, but coinjection with DNA fragments not containing the GC box did not. This suppression was likely due to the competition of an Sp1-like transcription factor(s) and indicates involvement of the apparently ubiquitous factor(s) in the tissue-specific expression of the delta-crystallin gene.

Crystallin gene expression and lentoid body formation in quail embryo neuroretina cultures transformed by the oncogenic retrovirus Mill Hill 2 or Rous sarcoma virus

The lens-specific proteins alpha and delta crystallins and lentoid bodies, structures that follow a differentiation pathway similar to that of the lens, regularly appear after 4 to 5 weeks in quail embryo neuroretina monolayer cultures. We have investigated the effects of the avian oncogenic retroviruses Mill Hill 2 and Rous sarcoma virus on this process. Quail embryo neuroretina cells transformed by Mill Hill 2 virus were established into permanent cultures that synthesized alpha and delta crystallins and contained stem cells for the production of lentoid bodies. In contrast, transformation with the Rous sarcoma virus mutant tsNY-68 blocked the appearance of mRNA crystallins, but cytoplasmic alpha and delta crystallin mRNA and alpha crystallin appeared 44 h after a shift to the nonpermissive temperature. However, delta crystallins and lentoid bodies were only present after 7 days. The crystallins of transformed quail neuroretina cultures were immunologically indistinguishable from those of quail lenses and of normal quail embryo neuroretina cultures.

Crystallin gene expression and lentoid body formation in quail embryo neuroretina cultures transformed by the oncogenic retrovirus Mill Hill 2 or Rous sarcoma virus

The lens-specific proteins alpha and delta crystallins and lentoid bodies, structures that follow a differentiation pathway similar to that of the lens, regularly appear after 4 to 5 weeks in quail embryo neuroretina monolayer cultures. We have investigated the effects of the avian oncogenic retroviruses Mill Hill 2 and Rous sarcoma virus on this process. Quail embryo neuroretina cells transformed by Mill Hill 2 virus were established into permanent cultures that synthesized alpha and delta crystallins and contained stem cells for the production of lentoid bodies. In contrast, transformation with the Rous sarcoma virus mutant tsNY-68 blocked the appearance of mRNA crystallins, but cytoplasmic alpha and delta crystallin mRNA and alpha crystallin appeared 44 h after a shift to the nonpermissive temperature. However, delta crystallins and lentoid bodies were only present after 7 days. The crystallins of transformed quail neuroretina cultures were immunologically indistinguishable from those of quail lenses and of normal quail embryo neuroretina cultures.

In vivo competition of delta-crystallin gene expression by DNA fragments containing a GC box

Expression of the chicken delta-crystallin gene 1 injected into the nuclei of mouse cells is lens specific. Coinjection of GC box-containing DNA fragments from delta-crystallin, simian virus 40 early, and herpes simplex virus type 1 tk promoters effectively suppressed delta-crystallin expression in the lens, but coinjection with DNA fragments not containing the GC box did not. This suppression was likely due to the competition of an Sp1-like transcription factor(s) and indicates involvement of the apparently ubiquitous factor(s) in the tissue-specific expression of the delta-crystallin gene.

Two delta-crystallin polypeptides are derived from a cloned delta 1-crystallin cDNA

Previous studies have shown that there are 2 similar delta-crystallin genes (delta 1 and delta 2) and at least 2 delta-crystallin polypeptides in the chicken eye lens. We show here that both delta-crystallin polypeptides can be synthesized from mRNA transcribed in vitro from a cloned delta 1-crystallin cDNA. Both polypeptides co-migrate in SDS-urea-polyacrylamide electrophoresis with their authentic counterparts isolated from 15-day-old embryonic chicken lenses, and both react with sheep anti-chicken delta-crystallin serum. Screening nearly 900 delta-crystallin cDNA clones from a 15-day-old embryonic lens library with an oligonucleotide probe specific for exon 2 of the delta 2-crystallin gene failed to detect any delta 2 cDNA clones, indicating that the delta 2 gene produces little or no mRNA in the lens at this stage of development. Our results suggest that both of the observed delta-crystallin polypeptides are derived from mRNA transcribed from the delta 1 gene, with heterogeneity arising at the translational or co-translational level.

The chicken delta 1-crystallin gene promoter: binding of transcription factor(s) to the upstream G+C-rich region is necessary for promoter function in vitro

There are two linked delta-crystallin genes in the chicken (5' delta 1-delta 2 3'). Only the delta 1 gene has been shown definitively to be active in the lens. Transcription of deletion mutants, reported here, shows that the sequences necessary for the functioning of the delta 1 promoter in a HeLa cell extract are located upstream from the RNA initiation site, between nucleotide positions -121 and -38. This region includes a number of G+C-rich motifs, including one hexanucleotide sequence, CCGCCC, that is repeated six times in the simian virus 40 (SV40) promoter. Competition experiments with purified fragments from the delta 1-crystallin gene promoter showed that binding of transcription factor(s) from the HeLa cell extract to this G+C-rich region is required for promoter activity in vitro. Further, competition experiments using three different fragments from the SV40 promoter suggest that the transcription factor(s) is similar to Sp1, which stimulates transcription by binding to the G+C-rich 21-base-pair repeats of the SV40 promoter, and differs from that which interacts with the SV40 enhancer region.

Lens-specific expression of the chloramphenicol acetyltransferase gene promoted by 5' flanking sequences of the murine alpha A-crystallin gene in explanted chicken lens epithelia

We have developed a system using explanted embryonic chicken lens epithelia to express foreign recombinant genes containing crystallin DNA regulatory sequences introduced by calcium phosphate transfection. Optimal results were obtained with lens epithelia from 14-day embryos transfected 1 day after explantation and assayed 3 days later. When DNA sequences (-364 to +45) of the murine alpha A-crystallin gene were inserted in the pSVO-CAT expression vector of Gorman et al. [Gorman, C. M., Moffat, L. F. & Howard, B. H. (1982) Mol. Cell. Biol. 2, 1044-1051] in the same orientation as in the crystallin gene, they promoted chloramphenicol acetyltransferase (CAT; EC 2.3.1.28) activity in the transfected epithelia. Sequences 87 to 364 base pairs upstream from the murine gene cap site were required for CAT gene expression. These crystallin gene regulatory sequences did not promote CAT expression in primary cultures of embryonic chicken fibroblasts or other nonlens cells. By contrast, the long terminal repeat of Rous sarcoma virus and the early promoter of simian virus 40 promoted CAT activity in lens and nonlens cells. Our experiments thus demonstrate that the explanted embryonic chicken lens epithelium is an advantageous recipient for identifying lens-cell-specific regulatory sequences of crystallin genes and implicate a DNA region upstream of the "TATA box" for regulation of the murine alpha A-crystallin gene. These experiments also suggest that explanted epithelia from other tissues may be useful for studying the expression of foreign genes.

Nucleotide sequence of a chicken delta-crystallin gene

We have determined the complete nucleotide sequence of one of the two non-allelic delta-crystallin genes in the chicken, arbitrarily designated delta-gene 1, using a genomic clone (lambda g delta 106) containing the entire gene sequence. By comparison of the genomic sequence and the delta-crystallin cDNA sequence previously determined, we have identified exon sequences in the genomic sequence. Thus, the presence of 17 exons and 16 introns in the gene has been clarified. The delta-crystallin polypeptide deduced from the exon sequences consists of 465 amino acids which is larger, by 19 amino acid residues, than the polypeptide deduced from the cDNA sequence previously reported. Re-examination of the cDNA sequence using the same cDNA clone previously used shows that the present exon sequences are correct and the molecular weight of the deduced delta-crystallin polypeptide is 50,615 daltons instead of the previously reported value of 48,447 daltons. In addition, some structural features of the delta-crystallin gene including putative expression signals are discussed.

Crystallin genes: templates for lens transparency

Analysis of recombinant DNAs provides new information on the basis of crystallin evolution and diversity. All crystallin genes contain introns. Two similar, tandemly linked chicken delta-crystallin genes, which probably arose by gene duplication, contain at least 16-17 introns. In the beta-crystallins three introns are situated between exons encoding the structural motifs of the protein, thus relating gene and protein structure. The structurally similar beta- and gamma-crystallins are coded by separate gene families which apparently arose by successive duplications of a common ancestral gene. The N-termini (5' end of gene) of the beta-crystallins appear to have diverged, while the 3' ends have been conserved. In the single murine alpha A-crystallin gene, coding information (the insert exon) for the alpha Ains peptide is contained within an intron. Alternative RNA splicing of this gene gives both the alpha A2 and the alpha Ains crystallin mRNAs. Thus, molecular genetics is providing a deeper appreciation of evolutionary events and is serving to redefine the crystallins in terms of their genes. Since the crystallins are so abundant in the lens, greater understanding of their polypeptide and gene structure should contribute to our understanding of and ability to treat cataract.