Lens differentiation in vertebrates. A review of cellular and molecular features

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.

Insulin and IGF receptors are developmentally regulated in the chick embryo eye lens

We have previously reported that insulin-like growth factor (IGF) receptors appear to predominate over insulin receptors in early stages of embryogenesis in the chick (days 2-3 whole embryo membranes). Overall, [125I]IGF I and II binding to specific receptors was maximal when the rate of brain growth is highest. In the present study we used the embryonic chick lens, a well-defined tissue composed of a single type of cell, to analyse whether changes of insulin and IGF I binding are correlated with changes in growth rate and differentiation state of the cells. We show that both insulin receptors and IGF receptors are present in the lens epithelial cells, and that each type is distinctly regulated throughout development. While there is a direct correlation between IGF-binding capability and growth rate of the cells, there is less relation to differentiation status and embryo age. Insulin receptors, by contrast, appear to be mostly related to the differentiated state of cells, decreasing sharply in fibers, irrespective of their developmental age.

In situ detection of beta-galactosidase in lenses of transgenic mice with a gamma-crystallin/lacZ gene

Transgenic mice carrying the gamma 2-crystallin promoter fused to the coding region of the bacterial lacZ gene were generated. The offspring of three founder mice expressed high levels of the enzyme solely in the central nuclear fiber cells of the lens as measured by an in situ assay for the detection of beta-galactosidase activity. These results suggest that gamma 2-crystallin sequences between -759 to +45 contain essential information required for appropriate tissue-specific and temporal regulation of the mouse gamma 2-crystallin gene. In a broader context, this study also demonstrates the utility of beta-galactosidase hybrid gene constructs for monitoring the activity of gene regulatory elements in transgenic mice.

Linkage between the beta B2 and beta B3 crystallin genes in man and rat: a remnant of an ancient beta-crystallin gene cluster

Human and rat genomic clones containing beta B2- and/or beta B3-crystallin sequences have been isolated and characterized. Both in the human and the rat genome the single-copy beta B3-crystallin gene is linked to a beta B2-crystallin gene. In both species the linked genes, separated by 20 kb in the human and 11 kb in the rat genome, are oriented head-to-tail with respect to transcription. A single copy of the beta B2-crystallin gene is present in the rat genome, in the human genome two copies of this gene are found. The second human copy could as yet not be linked to the beta B2/beta B3-crystallin gene cluster.

Differential regulation of gamma-crystallin genes during mouse lens development

Using gene-specific probes derived from four mouse gamma-crystallin cDNAs, we have examined the regulation of different members of the mouse gamma-crystallin gene family during lens development. Our analysis revealed that, while the different gamma-crystallin genes appear to be coordinately activated during embryogenesis, the steady-state levels of their corresponding transcripts are differentially regulated, resulting in variations in the relative abundance of individual species at different stages of development. This complex pattern of gene regulation presumably accounts for one of the mechanisms determining the spatial distribution of different gamma-crystallins within the lens.

The eye lens crystallins: ambiguity as evolutionary strategy

Comparative studies of the different families of lens-specific proteins of the vertebrates, the crystallins, and their genes reveal several interesting evolutionary features. The origin of alpha-crystallin can be traced back to the small heat shock proteins, while the superfamily of beta gamma-crystallins shows structural similarities with a bacterial spore coat protein. The crystallins display a great diversity within and between species, as well as during development. Ambiguous transcription, mRNA-processing, and translation contribute to this diversity of the crystallins and their expression. These mechanisms include the occurrence of atypical poly-A addition signals, alternative splicing, and the use of two initiation codons on a single mRNA.

Chromatin condensation and terminal differentiation process in embryonic chicken lens in vivo and in vitro

During embryonic chick lens differentiation, the epithelial cells become transformed into elongated fibres. Concomitantly, the fibre nuclei undergo degeneration and high molecular weight (HMW) DNA breaks down due to nuclear endodeoxyribonuclease activity. An electronmicroscopic study of lens epithelial and fibre nuclei was made at different stages of chick embryonic development, both in vivo and in vitro. The in vitro conditions are conducive to the expression of endogenous endodeoxyribonuclease activity in fibres. In both conditions we observed condensation of chromatin. The organization of some nuclear material into distinct linear arrays followed by streaming of nuclear material into the cytoplasm is recorded only in vitro. Such a condition may lead to acceleration of the process of aging in lens fibres.

Myopia associated with retinopathy of prematurity

A complete analysis of the components of refractive error was performed on ten eyes of five patients with myopia and retinopathy of prematurity (ROP). In comparison to an age-matched control group, these eyes exhibited both lenticular and axial myopia. Only the high crystalline lens powers, which ranged from 22.20 to 44.13 diopters (D) (mean value, 31.27 D), were found to be statistically significant. In two patients, only one eye had high myopia. The lens power in these eyes was approximately 11 D more powerful than the lens of the fellow eye. Further investigation into the ocular changes induced by prematurity and abnormal oxygen metabolism is needed to determine the reason for the high degree of lenticular myopia.

Retention of lens specificity in long-term cultures of diploid rabbit lens epithelial cells

Rabbit lens epithelial cells from newborn animals exhibited limited growth when cultured under standard conditions. Cell lines were generated when explants from individual lenses were cultured in medium supplemented with conditioned medium or untreated rabbit serum. All lines exhibited a stable epithelial morphology. One line, N/N1003A, was examined extensively with respect to its growth, ploidy, and maintenance of lens-specific functions. Cells at population-doubling level (pdl) 120 exhibited a normal chromosomal banding pattern, were diploid, were non-tumorigenic in vivo, did not grow in suspension culture, and did not exhibit sustained growth in medium supplemented with low concentrations of serum. The shape of the growth curves and the final density for cells at pdl 24 and 181 exposed to various concentrations of serum were identical. The cells showed no diminution in growth as a function of in vitro age. The cells retained lens-specific functions. Proteins were isolated from cells at pdl 40 and 170, and were separated on polyacrylamide gels. Western immunoblot analysis using antiserum to alpha-crystallin, a tissue-specific protein found in lens epithelial cells in vivo, indicated the presence of alpha-A- and alpha-B-crystallin polypeptides. The cells also contained the transcription factors required for activating the murine alpha-A-crystallin gene promoter, which is known to function with precise tissue specificity. When an expression vector including the bacterial chloramphenicol acetyltransferase (CAT) gene controlled by the alpha-A-crystallin gene promoter was introduced into the lens epithelial cells, the CAT gene was expressed.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Lens regeneration from cultured newt irises stimulated by retina-derived growth factors (EDGFs)

It has been shown that lens regeneration from the iris of the newt Notophthalmus viridescens is dependent on the presence of neural retinal tissue in organ culture and in vivo. The recent discovery of various eye-derived growth factors (EDGFs) in the bovine retina [14] prompted us to investigate whether one of these factors may be involved in the stimulation of lens regeneration. Dorsal irises were cultured for 20 days in serum-supplemented diluted Eagle's medium. Growth factors from bovine retina of various degrees of purification were added. Lens regeneration was assessed on the basis of morphological lens-regeneration stages and by immunofluorescent detection of a lens-specific marker protein, alpha-crystallin. Crude isotonic retinal extract at 80-800 micrograms/ml significantly augmented lens regeneration. Very similar results were obtained when EDGF III, the nonretained retinal factor after heparin-affinity chromatography, was present at 2-20 micrograms/ml. Lens regeneration was also significantly increased when EDGF II, the retinal form of acidic fibroblast growth factor (aFGF) at 50-500 ng/ml was added to the cultures. On the other hand, EDGF I at 4-40 ng/ml and brain basic FGF at 5-50 ng/ml did not seem to significantly stimulate lens regeneration under the conditions used. Our results suggest that at least two retina-derived growth factors (EDGF II and III) can stimulate lens regeneration. These growth factors may be the putative signal that is naturally produced by the retina during lens regeneration in the newt.

Lens-specific promoter activity of a mouse gamma-crystallin gene

Crystallins are the major water-soluble proteins in vertebrate eye lenses. These lens-specific proteins are encoded by several gene families, and their expression is differentially regulated during lens cell differentiation. Here we show that a cloned mouse gamma-crystallin promoter is active in lens explants derived from 14-day-old chicken embryos but inactive in a variety of cells of non-lens origin. We also show that sequences required for proper utilization of this promoter are contained between nucleotide positions -392 and +47 relative to the transcription initiation site; deletion of sequences from positions -392 to -171 completely abolishes promoter activity. Since chickens do not have gamma-crystallin genes, the expression of a mouse gamma-crystallin promoter in chicken lens cells suggests that different classes of crystallin genes may be regulated by common lens tissue-specific mechanism(s) independent of species.

Cytodifferentiation and tissue phenotype change during transformation of embryonic lens epithelium to mesenchyme-like cells in vitro

A number of adult and embryonic epithelia, when suspended within native type I collagen gels, give rise to elongate bipolar cells that migrate freely within the three-dimensional matrix. The morphology of these newly formed mesenchyme-like cells is indistinguishable from "true" mesenchymal cells at the light and ultrastructural level. In this report, we extend previous observations on the transformation of embryonic avian lens epithelium to mesenchyme-like cells. Lens epithelia, dissected from 12-day chick embryos, were cultured either within a collagen matrix or on a two-dimensional surface. Cells derived from explants on the surface of type I collagen express the epithelial phenotype. The cells form new basal lamina, continue to express delta-crystallin protein and secrete both type IV collagen and laminin. In contrast, epithelia suspended within collagen gels lose epithelial morphology, phenotype, and cytodifferentiation. The newly formed mesenchyme-like cells lack the ability to synthesize lens-specific delta-crystallin protein, type IV collagen, and laminin. They do, however, express type I collagen de novo, a characteristic of mesenchymal cells. The changes in cytodifferentiation and tissue phenotype which occur during the transformation are stable under the conditions studied here. When mesenchyme-like cells are removed from the gel and replated onto two-dimensional surfaces, they remain bipolar, will invade collagen matrices, and are unable to synthesize delta-crystallin protein.

Concerted and divergent evolution within the rat gamma-crystallin gene family

The nucleotide sequences of six rat gamma-crystallin genes have been determined. All genes have the same mosaic structure: the first exons contain a relatively short (25 to 44 base-pair) 5' non-coding region and the first nine base-pairs of the coding sequence, the second exons encode protein motifs I and II, while protein motifs III and IV are encoded by the third exons. The third exons also contain a 60 to 67-base-pair long 3' non-coding region. In the gamma 1-2 gene, the splice acceptor site of the third exon has been shifted three base-pairs upstream. Hence, the protein product of this gene is one amino acid residue longer. The first introns, though varying in length from 85 to 100 base-pairs, are conserved in sequence. The second introns vary considerably in length (0.9 X 10(3) to 1.9 X 10(3) base-pairs) and sequence. The second exons of the genes show concerted evolution and have undergone multiple gene conversions. In contrast, the third exons show divergent evolution. From the sequences of the third exons, an evolutionary tree of the gene family was constructed. This tree suggests that three of the present genes derive directly from the genes that originated from a tandem duplication of a two-gene cluster. Two duplications of the last gene of the four-gene cluster then yielded the other three genes. Region a' of the third exon, encoding protein motif III, is variable, while the region encoding protein motif IV (b') is constant. We postulate that this variability in region a' is due to a period of radiation after each gene duplication. A comparison of the rat sequences with those of orthologous sequences from other species shows that the variation in region a' is now preserved. Hence, it might specify the specific functional property of each gamma-crystallin protein within the lens.

Assignment of the human gamma-crystallin gene cluster (CRYG) to the long arm of chromosome 2, region q33-36

The gamma-crystallins of the human eye lens are encoded by a multigene family of which at least six genes have recently been assigned to chromosome 2. We have now localized these genes to the distal region of the long arm of chromosome 2 (region q33-36, most probably q34-35) using somatic cell hybrids containing different parts of this chromosome and by in situ hybridization. The gamma-crystallin genes map to the same chromosomal region as IDH-1. Similar linkage exists between the loci Len-1 and Idh-1 on mouse chromosome 1.

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.

Intron insertions and deletions in the beta/gamma-crystallin gene family: the rat beta B1 gene

The rat beta B1-crystallin gene is 13.6 kilobases long and contains six exons. The coding region of the gene is divided over five exons. Each functional entity of the protein is encoded by a separate exon except for the carboxyl-terminal extension, which shares the last exon with the fourth protein motif. Exon 2, encoding the amino-terminal extension of the protein, contains two direct repeats with an overall homology of 68% to the rat brain identifier sequence. A copy of the brain identifier sequence is also found in the 3'-flanking region of the gene. The start site of the mRNA was located by S1 nuclease mapping and analysis of the RNA sequence. The 5' end of the gene was shown to be a 27-base-pair noncoding exon, which is separated from the translation start site by 1.36 kilobases of intronic DNA. The 5'-flanking sequence of the beta B1 gene is highly homologous to that of a gamma-crystallin gene.

Phosphorylation of lens intrinsic membrane proteins by protein kinase C

Two intrinsic proteins of bovine lens membranes with apparent relative molecular masses (Mr, app) of 26,000 and 18,000 were phosphorylated in intact membranes by protein kinase C prepared from either bovine brain or lens. The kinase preparations exhibited histone H1 phosphorylation dependent on calcium and phospholipid but not on cAMP. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis of the lens membranes showed a major band at Mr, app = 26,000 (identified as MP26, the main intrinsic protein of lens fiber cells), an intermediate band at Mr, app = 18,000 and several minor bands. Autoradiography of complete assay mixture containing protein kinase C, calcium, magnesium and [gamma-32P]ATP showed major bands at Mr, app = 18,000 and 26,000. Several lines of evidence indicated that the label at Mr, app = 26,000 was associated with MP26, a protein which has been found in lens junctions and which may form cell-cell channels. Treatment of the phosphorylated membranes with chymotrypsin and V8 protease cleaved the major band at Mr, app = 26,000 to fragments of Mr, app .= 22,000 and 24,000. Label was not detected in the resulting Mr, app = 22,000 peptide, but the Mr, app = 24,000 peptide was found to be labeled. Phosphoamino acid analysis of MP26 indicated that approximately 75% of the label was on phosphoserine and 25% was on phosphothreonine. No label was found on phosphotyrosine. These results differ from those reported for cAMP-dependent phosphorylation of lens proteins. Phosphorylation by protein kinase C may account for some of the labeling of MP26 detected in vivo.

A lens intercellular junction protein, MP26, is a phosphoprotein

The major protein present in the plasma membrane of the bovine lens fiber cell (MP26), thought to be a component of intercellular junctions, was phosphorylated in an in vivo labeling procedure. After fragments of decapsulated fetal bovine lenses were incubated with [32P]orthophosphate, membranes were isolated and analyzed by SDS PAGE and autoradiography. A number of lens membrane proteins were routinely phosphorylated under these conditions. These proteins included species at Mr 17,000 and 26,000 as well as a series at both 34,000 and 55,000. The label at Mr 26,000 appeared to be associated with MP26, since (a) boiling the membrane sample in SDS led to both an aggregation of MP26 and a loss of label at Mr 26,000, (b) the label at 26,000 was resistant to both urea and nonionic detergents, and (c) two-dimensional gels showed that a phosphorylated Mr 24,000 fragment was derived from MP26 with V8 protease. Studies with proteases also provided for a localization of most label within approximately 20 to 40 residues from the COOH-terminus of MP26. Published work indicates that the phosphorylated portion of MP26 resides on the cytoplasmic side of the membrane, and that this region of MP26 contains a number of serine residues. The same region of MP26 was labeled when isolated lens membranes were reacted with a cAMP-dependent protein kinase prepared from the bovine lens. After the in vivo labeling of lens fragments, phosphoamino acid analysis of MP26 demonstrated primarily labeled serines, with 5-10% threonines and no tyrosines. Treatments that lowered the intracellular calcium levels in the in vivo system led to a selective reduction of MP26 phosphorylation. In addition, forskolin and cAMP stimulated the phosphorylation of MP26 and other proteins in concentrated lens homogenates. These findings are of interest because MP26 appears to serve as a protein of cell-to-cell channels in the lens, perhaps as a lens gap junction protein.

Immunocytochemical localization of the 27K beta-crystallin polypeptide in the mouse lens during development using a specific monoclonal antibody: implications for cataract formation in the Philly mouse

The Philly mouse develops a hereditary cataract about 5 weeks after birth. Although the causative agent is not known, data suggest that there is a correlation between cataract formation and the selective absence of a 27 kilodalton (27K) beta-crystallin lens polypeptide. The ontogeny of the 27K beta-crystallin polypeptide was examined in normal mice in order to evaluate its role in normal development and determine what impact its absence may have on the Philly mouse lens. A monoclonal antibody was used with the PAP method to immunocytochemically localize the 27K polypeptide in lenses of normal mice during development. beta-Crystallins detected with polyclonal antisera were found in differentiated fiber cells throughout the lens. In contrast, the 27K beta-crystallin polypeptide detected with a specific monoclonal antibody was not found in the fiber cells of the inner part of the lens (nucleus), but was specifically localized in the fiber cells of the outer part of the lens called the cortex. The polypeptide was found only in elongating and differentiated fiber cells and not in mitotically active epithelial cells. Although a minor component of the 2-day-old lens, the 27K polypeptide comprised a large portion of the 16-day-old lens including the anterior and posterior poles. These data show that the 27K polypeptide is a minor component of the embryonic lens, but becomes a major contributor to the postnatal lens. The 27K beta-crystallin lens polypeptide is abundant in the fiber cells of the normal postnatal mouse lens. The absence of the 27K polypeptide in the Philly mouse may contribute to the observed failure of fiber cells to differentiate in the Philly mouse after birth or may be deleterious in some other manner to normal lens development. The selective absence of the 27K beta-crystallin polypeptide, a defect which precedes cataract formation in the Philly mouse, is intriguing since it suggests a relationship between this major lens polypeptide and lens clarity.

Lens-specific expression and developmental regulation of the bacterial chloramphenicol acetyltransferase gene driven by the murine alpha A-crystallin promoter in transgenic mice

Two lines of transgenic mice with one to two copies of a DNA fragment containing nucleotides -364 to +45 of the murine alpha A-crystallin gene linked to the bacterial chloramphenicol acetyltransferase (CAT) gene expressed the CAT gene only in their eye lenses. Both CAT activity and alpha A-crystallin were first detected in eyes at approximately 12.5 days of embryonic development, suggesting that the alpha A-CAT fusion gene and the endogenous alpha A-crystallin gene are co-regulated during lens development in the transgenic mice. These experiments show that the murine alpha A-crystallin gene contains a short, cis-acting, tissue-specific regulatory sequence at its 5' end that can target the expression of the bacterial CAT gene, and probably foreign eukaryotic genes, specifically to the ocular lens.

The distribution of the main intrinsic membrane polypeptide in ocular lens

The Main Intrinsic Polypeptide (MIP) of the ocular lens fiber cell plasma membrane was immunocytochemically localized at the ultrastructural level on ultrathin frozen sections of rat lens, and on extracted, gradient-purified bovine lens membranes. The results indicate that both the junctional and non-junctional membrane domains of the cortical lens fiber cell are MIP immunoreactive. Frozen thin section immunocytochemistry of the lens epithelium and hepatocytes, also using anti-MIP antibodies, revealed that these cells, and their intercellular junctions, are not MIP-immunoreactive. From these findings we conclude that 1) MIP, a putative fiber cell junctional protein, is present throughout the plasma membrane of the lens fiber cell, and is not confined to the fiber cell junctional domain, 2) MIP is not a detectable component of the lens epithelial cell membrane, or its intercellular junctions, 3) MIP is not detectable in gap junctions of hepatocytes.

Structural and evolutionary relationships among five members of the human gamma-crystallin gene family

We have characterized five human gamma-crystallin genes isolated from a genomic phage library. DNA sequencing of four of the genes revealed that two of them predict polypeptides of 174 residues showing 71% homology in their amino acid sequence; the other two correspond to closely related pseudogenes which contain the same in-frame termination codon at identical positions in the coding sequence. Two of the genes and one of the pseudogenes are oriented in a head-to-tail fashion clustered within 22.5 kilobases. All three contain a TATA box 60 to 80 base pairs upstream of the initiation codon and a highly conserved segment of 44 base pairs in length immediately preceding the TATA box. The two genes and the two pseudogenes are similar in structure: each contains a small 5' exon encoding three amino acids followed by two larger exons that correspond exactly to the two similar structural domains of the polypeptide. The first intron varies from 100 to 110 base pairs, and the second intron ranges from 1 to several kilobases, rendering an overall gene size of 1.7 to 4.5 kilobases. At least one of the two pseudogenes appears to have been functional before inactivation, suggesting that their identical mutation was generated by gene conversion.

Lens-specific promoter activity of a mouse gamma-crystallin gene

Crystallins are the major water-soluble proteins in vertebrate eye lenses. These lens-specific proteins are encoded by several gene families, and their expression is differentially regulated during lens cell differentiation. Here we show that a cloned mouse gamma-crystallin promoter is active in lens explants derived from 14-day-old chicken embryos but inactive in a variety of cells of non-lens origin. We also show that sequences required for proper utilization of this promoter are contained between nucleotide positions -392 and +47 relative to the transcription initiation site; deletion of sequences from positions -392 to -171 completely abolishes promoter activity. Since chickens do not have gamma-crystallin genes, the expression of a mouse gamma-crystallin promoter in chicken lens cells suggests that different classes of crystallin genes may be regulated by common lens tissue-specific mechanism(s) independent of species.

Antiserum to lens antigens immunostains Müller glia cells in the neural retina

Antiserum to a lens fraction enriched for alpha-crystallin selectively immunostains Müller glia cells in the neural retina of several vertebrate species. Also, in embryonic retina (chicken), this antiserum reacts with Müller cells and, at early stages of development, with their apparent precursors. Thus, antibodies to a lens product(s) detect a Müller glia cell marker that begins to be expressed very early in their ontogeny and can be useful in studies on differentiation, function, and pathologies of this cell type.

Structural and evolutionary relationships among five members of the human gamma-crystallin gene family

We have characterized five human gamma-crystallin genes isolated from a genomic phage library. DNA sequencing of four of the genes revealed that two of them predict polypeptides of 174 residues showing 71% homology in their amino acid sequence; the other two correspond to closely related pseudogenes which contain the same in-frame termination codon at identical positions in the coding sequence. Two of the genes and one of the pseudogenes are oriented in a head-to-tail fashion clustered within 22.5 kilobases. All three contain a TATA box 60 to 80 base pairs upstream of the initiation codon and a highly conserved segment of 44 base pairs in length immediately preceding the TATA box. The two genes and the two pseudogenes are similar in structure: each contains a small 5' exon encoding three amino acids followed by two larger exons that correspond exactly to the two similar structural domains of the polypeptide. The first intron varies from 100 to 110 base pairs, and the second intron ranges from 1 to several kilobases, rendering an overall gene size of 1.7 to 4.5 kilobases. At least one of the two pseudogenes appears to have been functional before inactivation, suggesting that their identical mutation was generated by gene conversion.

delta- and beta-Crystallin mRNA levels in the embryonic and posthatched chicken lens: temporal and spatial changes during development

The levels of delta- and beta-crystallin mRNAs were examined by cDNA hybridization in the embryonic and posthatched chicken eye lens. Four different cloned beta-crystallin cDNAs were used, allowing discrimination among different members of the beta-crystallin family. Each crystallin mRNA displayed a characteristic temporal and spatial pattern in the developing lens. delta-Crystallin mRNA accumulated rapidly during early embryonic development; by contrast, the beta-crystallin mRNAs began to accumulate rapidly near the end of embryogenesis. Both delta- and beta-crystallin mRNAs increased in the lens for the first month after hatching and began to decrease 3 months after hatching. The levels of the delta- and the different beta-crystallin mRNAs were also differentially regulated in cultured embryonic lens epithelia. The most fiber cell specific crystallin gene product in the differentiating lens was the beta 35 mRNA. These experiments provide a quantitative basis for exploring the differential expression of the delta- and beta-crystallin gene families in the chicken lens.

Rat lens beta-crystallins are internally duplicated and homologous to gamma-crystallins

The nucleotide sequence of two cloned rat lens beta-crystallin cDNAs pRL beta B3-2 and pRL beta B1-3 has been determined. pRL beta B3-2 contains the complete coding information for a beta-crystallin, designated beta B3, of 210 amino acid residues. pRL beta B1-3 is incomplete at its 5' end; the 5' codogenic information which is not present in this cDNA clone was deduced from the cloned gene. pRL beta B1-3 codes for a beta-crystallin polypeptide, designated beta B1, whose full length is 247 amino acid residues. Considerable sequence homology is noted between the amino- and carboxy-terminal halves of each protein. The two rat beta-crystallins show a substantial sequence homology with each other (60%) as well as with the published sequences of rat gamma-crystallin (37%) and bovine and murine beta-crystallins (55 and 45%). All these proteins have a two-domain structure which, like the bovine gamma II-crystallin, might be folded into four remarkably similar protein motifs. Our data further indicate that the beta-crystallins can be subdivided into two groups which are evolutionarily related. Both groups are, although more distantly, also related to the gamma-crystallins.

Comparison of the crystallin mRNA populations from rat, calf and duck lens. Evidence for a longer alpha A2-mRNA and two distinct alpha B2-mRNAs in the birds

Total cytoplasmic poly(A)-containing RNA from rat, calf and duck lens was fractionated by electrophoresis in methylmercury hydroxide-containing agarose gels. RNA electrophoresed in parallel lanes was either transferred onto nitrocellulose and hybridized with total cDNA synthesized on the initial mRNA or was recovered from individual gel fractions for in vitro translation in a reticulocyte cell-free system. This allowed the identification and size-characterization of individual mRNA species encoding alpha-, beta-, gamma- and delta-crystallin polypeptides. The 14 S mRNA fraction of rat lens comprises two alpha A2-mRNAs of approximately 1250 and 1350 nucleotides and the alpha AIns-mRNA with a size similar to that of the largest alpha A2-mRNA. The calf lens 14 S mRNA fraction harbors a heterogeneous population of alpha A2-mRNA. In the same fraction another mRNA encoding a polypeptide, designated X, has been found sharing no homology with alpha A sequences. The duck lens alpha A2-mRNA appears to be 400-450 bases longer than the rat and calf lens alpha A2-mRNAs. Furthermore, in contrast to the single alpha B2-mRNA in rat and calf lens, two alpha B2-mRNAs have been identified in duck lens, one, the major species, similar in size to the alpha B2-mRNA in rat and calf lens (800 bases), and the other species 700 nucleotides longer. The large size differences among the alpha A2- and alpha B2-mRNAs most likely reside in their 3'-untranslated sequences.

Characterization of the rat gamma-crystallin gene family and its expression in the eye lens

Rat genomic clones, which together contain all of the rat genomic gamma-crystallin sequences, have been characterized. Five gamma-crystallin genes are located on a contiguous DNA region, 63 X 10(3) base-pairs long. These genes, named (5') gamma 1-1, gamma 1-2, gamma 2-2 and gamma 3-1 (3'), are all oriented head to tail. A sixth gamma-crystallin gene, named the gamma 4-1 gene, could not be linked to the gamma-crystallin gene cluster with our present set of genomic clones. Mapping experiments using single copy sequences which form the extreme 5' or 3' region of the gene cluster showed that, if the gamma 4-1 gene is located on the same chromosome, then it must be separated from the gene cluster by at least 25 X 10(3) base-pairs of DNA. All gamma-crystallin genes have a similar mosaic structure. They contain a large (0.9 X 10(3) to 1.88 X 10(3) base-pairs) intron in the middle of the gene and are further interrupted close to the 5' end of the gene. The length of the first exon varies from about 40 to about 50 base-pairs. The complementary DNA clone pRL-gamma-3 used in this study is a copy of the transcript of the gamma 3-1 gene, while the second complementary DNA clone, pRL-gamma-2, is most likely a copy of the transcript of the gamma 2-1 gene. It is further shown that rat lens messenger RNA protects fragments from the 3' ends of the four other gamma-crystallin genes against degradation by S1 nuclease, hence all six gamma-crystallin genes present in the rat genome must be transcribed in the lens. Repetitive sequences were found to be present between and around the gamma-crystallin genes. Mapping with cloned repetitive sequences showed that three different repeats, designated A, B and C, occur more than once in the gamma-crystallin gene cluster. Repeat C is also found in the gamma 4-1 region. A repetitive region 3' to the gamma 3-1 gene contains members of all three repeat families.

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.

A comparison of the changing patterns of crystallin expression in vivo, in long-term primary cultures in vitro and in response to a carcinogen

Changes in the differentiation of day-old chick lens epithelium in long-term primary culture conditions were investigated by sodium dodecyl sulphate-polyacrylamide electrophoresis, using integrating densitometry to assess the relative levels of accumulated crystallin and non-crystallin polypeptides and fluorography to assess their relative levels of synthesis. The main changes during the culture period included a relative decline in the proportion of actin and other non-crystallins, an initial increase in 48K delta-crystallin expression followed by a decline and a shift in beta-crystallin expression from a relative preponderance of the 24K and 23K polypeptides to a relative preponderance of the 24K and 22K polypeptides. At all stages the level of the 19K alpha-crystallin was higher than that of the 20K alpha-crystallin polypeptide. In general, the changes in the pattern of expression of these polypeptides in culture were similar to those observed in vivo in the post-hatch chick, suggesting an intrinsic programme of crystallin expression. The changes in gene expression were also tested indirectly by brief exposure of the cells in vitro to a carcinogen, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) which is known to produce, in some systems, effects related to the status of the cell at the time of treatment. The effects were found to depend on the stage of differentiation of the culture at the time of treatment. Treatment on day 1 of culture prevented later lentoid formation and severely reduced the expression of all crystallins with the exception of the 34K beta-crystallin polypeptide. Actin was the most abundant soluble cell component, and a proportion of the cells acquired a fibroblast-like morphology. Treatment with MNNG on day 7 led to a delay in lentoid formation and a differential reduction of the synthesis of crystallin polypeptides, whereas the treatment of already differentiated cultures on day 18 and to lesser extents on days 27, 45 and 55, respectively, led to an increase in crystallin synthesis relative to controls. These results suggest that this programme of crystallin gene expression becomes more resistant to change with increasing epithelial differentiation.

Ontogeny of human lens crystallins

The soluble proteins from prenatal and neonatal human lenses were fractionated by gel filtration into four distinct size classes viz. high molecular weight alpha-crystallin (HM-alpha), alpha-crystallin, intermediate molecular weight (IMW) proteins and low molecular weight (LMW) proteins. Extinction coefficients of the isolated proteins were determined and used to calculate the proportions of each fraction on a weight basis. The distributions of polypeptides within each of these fractions were analyzed by SDS gel electrophoresis and isoelectric focussing, followed by densitometric scanning of the gels. HM-alpha is detectable as early as the 14th week of gestation and its proportions increase rapidly, to about 9% of the total protein in the 1 year postnatal lens. The alpha-crystallin, IMW and LMW fractions show concomitant decreases and by 1 year they represent about 34, 35 and 18%, respectively. However, the proportions of IMW and LMW proteins do not accurately reflect those of the beta- and gamma-crystallins, as is often assumed. Substantial levels of non-crystallin polypeptides were found in the IMW protein fractions, including a group of very basic polypeptides (VBP) which comprised up to one-third of this material in the youngest lenses. Moreover, in postnatal lenses beta s-crystallin accounted for almost half of the LMW proteins. These points considered, alpha-crystallin is the major protein in the neonatal lens (approximately 42%, including HM-alpha), followed by the beta-crystallin (approximately 36% at most and probably less), the gamma-crystallins (approximately 11%) and beta s-crystallin (approximately 9%). Substantial changes in the proportions of specific polypeptides were observed throughout early development. These appear to result from changes at the level of protein synthesis and from postsynthetic modification. The A:B subunit ratio of alpha-crystallin drops from about 12 to below 3 during early development. This coincides with increasing levels of various deamidated and degraded subunits. The major beta-crystallin polypeptide also undergoes rapid deamidation and evidence is presented suggesting that the gamma-crystallins are subject to similar modification. The most dramatic changes were observed in the constituents of the LMW proteins. The synthesis of gamma-crystallins virtually ceases at some time around birth. At the same time, the levels of beta s-crystallin undergo an explosive increase. These and other changes are discussed in terms of their possible functional significance. They are also related to the complex protein status found in old lenses.

The crystallin gene families

Recent work from our laboratory on the structure and the genetic organization of the lens beta- and gamma-crystallin gene families is reviewed briefly. In the rat six different gamma-crystallin genes are present which all have an identical distribution of exons and introns, namely a small intron after the third translation codon and a larger one within the coding region for the connecting peptide which links the two domains of the gamma-crystallins. We find five rat genes physically linked and located on a DNA segment of only 50 kilobases, whereas the sixth gene is more distant. The polypeptide sequences, as deduced from DNA sequence analysis, of these six rat and two human gamma-crystallin genes are compared and discussed in terms of structural and evolutionary aspects. The gene coding for rat beta B1a-crystallin appears to be a single-copy gene of much larger size than the gamma-crystallin genes. The beta B1 gene is not physically linked to the other beta-crystallin genes, even though the various beta genes are evolutionarily related and in that sense constitute a gene family. In contrast to the gamma-crystallin genes, the beta B1 gene has an intron not only between the domain sequence but also between the motif sequences. In addition, the exon coding for the N-terminal extension of the protein is separated by an intron from the first protein motif sequence. We anticipate that structural and genetic investigations on lens crystallin genes and their expression might provide a framework for revealing the basis of (some) hereditary disorders in the visual system.

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.

Partial sequence homologies between cytoskeletal proteins, c-myc, Rous sarcoma virus and adenovirus proteins, transducin, and beta- and gamma-crystallins

Computer based sequence comparisons indicate partial sequence homology between human c-myc, Rous sarcoma virus, adenovirus 7, and simian sarcoma virus proteins and the cytoskeletal proteins d9smin, keratin and vimentin. In addition, sections of the oncogene proteins showed partial but significant homology to alpha and gamma subunits of transducin. gamma-II and beta-BP crystallins showed partial but significant homology to the cytoskeletal proteins keratin, vimentin, desmin, alpha and beta-tubulin, and to adenovirus 7 and simian sarcoma virus transforming gene proteins. Beta-BP crystallin showed partial but significant homology to Rous sarcoma virus protein, and to alpha and gamma subunits of transducin. Both crystallins showed partial sequence homology to the GTP-binding protein elongation factor TU from Escherichia coli. These sequence homologies suggest a link between the mechanisms of normal lens cell differentiation, involving modifications to the cytoskeleton and subsequent changes to the pattern of protein synthesis, and mechanisms of neoplastic transformation. Furthermore, the transducin-like region on beta-crystallin may be important for its interaction with lens membranes and the maintenance of short-range order for lens transparency.

Appearance of new variants of membrane skeletal protein 4.1 during terminal differentiation of avian erythroid and lenticular cells

The erythrocyte plasma membrane is lined with a network of extrinsic proteins, mainly spectrin and actin, which constitute a reticulum tethered to the intrinsic anion transport protein of the lipid bilayer through a linker protein, ankyrin. Protein 4.1 forms a stable ternary complex with spectrin and actin, thereby strengthening the reticulum and anchoring it directly to the lipid bilayer or to another intrinsic protein, glycophorin. It has been found recently that spectrin, ankyrin and protein 4.1 are not erythrocyte-specific; this has elucidated further the mechanisms of plasma membrane assembly and modelling during the differentiation of diverse tissues. We have shown previously that protein 4.1 in chickens is most abundant in erythrocytes and lens cells, but is scarce or absent from other spectrin-rich cell types. In addition, it exists as a family of related polypeptides showing differential expression in these two tissues, suggesting variant-specific functions. Here we show that the pattern of protein 4.1 variants changes during the terminal differentiation of erythroid and lenticular cells, with novel variants appearing in postmitotic cells. The accumulation of these variants may lead to the final stabilization of the plasma membrane skeletons of these cells.

Expression of the intermediate-filament-associated protein synemin in chicken lens cells

Synemin, a 230-kilodalton polypeptide component of avian muscle and erythrocyte intermediate filaments, is also found in association with the vimentin filaments of lens tissue. In chicken lens cells, synemin is bound to the core vimentin polymer with the same 180-nm periodicity that it exhibits in erythrocytes. Its solubility properties are characteristic of those of intermediate filaments in general and similar to those of synemin in muscle cells and erythrocytes. Synemin appears at an early stage of lens development and undergoes a dramatic accumulation as the epithelial cells elongate and differentiate into fiber cells. In contrast to synemin in cultured skeletal muscle, lens synemin is not confined to postmitotic, terminally differentiating cells but is present in proliferative cells as well. It is lost from the fibers near the center of the lens, as are many other cellular structures including intermediate filaments. These findings provide new information about the occurrence and expression of avian synemin and new insight regarding its presumptive role as a modulator of intermediate-filament function.

Selective loss of a family of gene transcripts in a hereditary murine cataract

The eye lens of the Fraser mouse contains a dominantly inherited cataract with reduced amounts of seven distinct but homologous gamma crystallins encoded by a family of gamma-crystallin genes. The results of experiments with cultured lenses, cell-free RNA translation, and Northern blot hybridization indicated a specific loss of the family of gamma-crystallin messenger RNA's in the Fraser mouse lens. Southern blot hybridization of genomic DNA's from normal and Fraser mice showed no differences in gamma-crystallin coding sequences.