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

Differential synthesis of rat lens proteins during development

Developmental regulation of crystallin protein synthesis was observed in rat lenses between embryonic day 19 and postnatal day 21. Studies on lenses incubated in [35S]-methionine and on lens messenger RNAs translated in a reticulocyte lysate showed that several new polypeptides were synthesized in the lens beginning approximately 1 week after birth. One new polypeptide which had a molecular weight of 27 000 comigrated with the beta crystallins on SDS-PAGE and became a predominant component in older lenses. By crossed rocket immunoelectrophoresis and isoelectric focusing, synthesis of several native beta crystallins and one gamma crystallin was detected only in the postnatal lens. Many crystallin proteins were synthesized in the embryonic and the postnatal lens and did not change during the time period studied. These data suggest a differential regulation of the crystallin proteins during development. It appears that the lens undergoes a transition from embryonic to adult crystallin expression during the first weeks after birth. Factors such as maturation of the retina may be necessary for this transition.

Two human gamma-crystallin genes are linked and riddled with Alu-repeats

A human genomic cosmid clone, pHcos gamma-1, has been isolated containing two closely linked gamma-crystallin genes, oriented in the same direction. The sequence of these genes and their 5' and 3' flanking regions has been determined. The coding regions of both genes are interrupted by two introns. The first introns (94 and 100 bp, respectively) are located in the 5' region of the genes. The second introns (2.82 and 0.95 kb, respectively) divide the genes into two halves, each encoding a structural domain of the gamma-crystallin protein. The coding regions of the two genes show 80% homology. Due to a mutation in the splice acceptor site of the second intron of the first gene, the coding region of its third exon is 3 bp longer than that of the second gene. In the flanking regions several conserved sequence elements were found, including those elements that are known to be necessary for the correct expression of eukaryotic genes. The flanking and intronic regions of the genes contain 'simple sequence' DNA and Alu repeats. The Alu repeats are usually clustered, contain truncated elements, and are often located near simple sequence DNA.

Gamma-crystallin family of the mouse lens: structural and evolutionary relationships

The heterogeneity inherent among gamma-crystallins of the mouse lens was investigated by sequence analysis of three gamma-crystallin-specific cDNAs. Comparison of the nucleotide sequence of these cDNAs and one previously reported by us revealed that the four gamma-cDNAs share 80-90% homology in nucleotide sequence. The entire 3' half of the coding region shows more variability than the 5' half, whereas the greatest variability is observed in the 3' untranslated region where numerous base substitutions, deletions, and insertions seem to have occurred. Alignment of the amino acid sequences of the four mouse gamma-crystallins according to the known four structural motifs of the major calf gamma-crystallin, gamma-II, suggests that all four mouse polypeptides are structurally very similar to calf gamma-II. However, most of the mouse polypeptides differ from gamma-II by the absence of one amino acid residue, resulting in a shorter connecting peptide between the two globular domains of the protein. Primary sequence alignment also revealed that the four mouse gamma-crystallins are most divergent in the third structural motif of the polypeptide. The significance of these differences in terms of the structure and function of the gamma-crystallins in the mouse lens is discussed.

Immunochemical characterization and quantitative distribution of crystallins in the epithelium and differentiating fibre cell populations of chick embryonic lens

Lenses from 19-day chick embryos are fractionated by a double punch method to obtain the epithelium-annular pad complex (EP), outer fibres (OF), middle fibres (MF) and central fibres (CF). Water-soluble crystallins are characterized by SDS PAGE, isoelectric focusing (IEF) and two-dimensional IEF-SDS PAGE. Crystallins are also characterized by immunoelectrophoresis (IE), rocket IE, IEF-immunoblotting, and quantified by two-dimensional antigen-antibody crossed electrophoresis using antibodies to total 19-day embryonic as well as adult crystallins. In the adult lens, alpha-, beta- and delta-crystallins are 19%, 67% and 14%, respectively, while these are present at concentrations of 9%, 27% and 64%, respectively, in 19-day embryonic lens. In absolute amounts, delta-crystallin increases only by 1.23-fold between 19-day embryonic age and 6 months post-hatching, while total lens protein increases 12.5-fold. The predominance of delta-crystallin in central fibres, located along the optical axis, suggests that this protein is of embryonic origin. delta-Crystallin from fibres is electrofocused as 12 distinct molecular classes (pI 5.2-5.42) which react against anti-delta-crystallin on an immunoblot. Of these, the three most anodal species are not detected in EP. Fibres contain 50 000, 48 000 and 45 000 dalton delta-crystallin subunits while only 50 000 and 48 000 dalton subunits are present in EP.

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.

Complete nucleotide sequence of a cDNA derived from calf lens gamma-crystallin mRNA: presence of Alu I-like DNA sequences

The nucleotide sequence of a cloned cDNA derived from gamma-crystallin mRNA of calf lens was determined. The cloned cDNA contains the entire coding region 522 bp long, 30 nucleotides of the 5' noncoding region, and 67 residues in the 3' noncoding region followed by a poly(A) tail of 25 nucleotides. The deduced amino acid sequence directly demonstrates for the first time that the calf gamma-crystallin contains 174 residues. The nucleotide sequence contains a number of interesting features including a 32-bp sequence in the 3' region with 70% complementarity to the 3' end of the first monomer unit of the consensus Alu I DNA. Within this region, a 32-bp sequence shows about 80% homology with a segment of hamster 4.5S RNA. The possible evolutionary and regulatory significance of these sequences is discussed.

Onset of fibre differentiation in cultured rat lens epithelium under the influence of neural retina-conditioned medium

In the intact rat lens, epithelial cells, which are cuboidal and contain alpha-crystallin, give rise to fibre cells, which are elongated and contain alpha-, beta- and gamma-crystallins. Epithelial explants cultured in medium conditioned by bovine neural retinas (BRCM) showed changes analogous to fibre cell differentiation in vivo. The cells became enlarged and elongated and accumulated beta- and gamma-crystallin as well as alpha-crystallin. Labelling studies with [35S]-methionine showed that sequential changes in the synthesis of all three classes of crystallin occurred during culture in BRCM. After two days, synthesis of alpha-crystallin subunits, particularly alpha A and alpha AINS, increased relative to overall protein synthesis. After four days in culture, synthesis of beta-crystallin subunits, identified as beta B1a, beta B4, beta B5 and possibly beta A2, was detected for the first time and between four and eight days gamma-crystallin synthesis became detectable. The time of onset of gamma-crystallin synthesis seemed to show greater experimental variability than did onset of beta-crystallin synthesis. In explants cultured for 10 days in BRCM approximately 25% of new protein synthesis could be attributed to alpha-, beta- and gamma-crystallins. These events were completely dependent on BRCM, suggesting that neural retina secretes a factor(s) which initiates fibre cell differentiation. This culture system appears to be a suitable one for investigating the control of fibre differentiation in vitro.

Analysis of the mouse gamma-crystallin gene family: assignment of multiple cDNAs to discrete genomic sequences and characterization of a representative gene

Blot hybridization analysis of mouse DNA with gamma-crystallin-specific cDNAs has detected the presence of a multigene family comprised of at least four related genes. The detailed structure of one of these genes, mouse gamma 4-crystallin (M gamma 4.1), and its corresponding cDNA has been determined. The gene spans approximately 2.6 kilobases (kb) and contains two introns. The gene predicts a polypeptide of 174 amino acids that shares extensive sequence homology with gamma-crystallin polypeptides of other species. The two similar structural domains of the protein correspond exactly to the second and third exons of the gene, supporting an exon-duplication model of gene evolution. The similarity in structure of this gene to that recently reported for a gamma-crystallin gene of the rat (1) suggests that a common structure may exist for all gamma-crystallin genes of the two species. Moreover, a highly conserved region, 50 nucleotides in length, immediately precedes the TATA box of both the mouse and rat genes, suggesting that this sequence may be important in gene regulation.

Chicken embryo lens cultures mimic differentiation in the lens

Embryonic chicken lenses, which had been disrupted by trypsin, were grown in culture. These cultures mimic lens development as it occurred in vivo, forming lens-like structures known as lentoids. Using a variety of techniques including electron microscopic analysis, autoradiography, immunofluorescence, and polyacrylamide gel electrophoresis, it was shown that the lentoid cells had many characteristics in common with the differentiated cells of the intact lens, the elongated fiber cells. These characteristics included a shut off of DNA synthesis, a loss of cell organelles, an increase in cell volume, an increase in delta-crystallin protein, and the development of extensive intercellular junctions. The cultures began as a simple epithelial monolayer but then underwent extensive morphogenesis as they differentiated. This morphogenesis involved three distinctive morphological types which appeared in sequence as an epithelial monolayer of polygonal shaped cells with pavement packing, elongated cells oriented end to end, and the multilayered, multicellular lentoids. These distinct morphological stages of differentiation in culture mimic morphogenesis as it occurs in the lens.

Sequence of a complete chicken delta-crystallin cDNA

A full-length chicken delta-crystallin cDNA (p delta Cr17) was cloned and subjected to sequence analysis. The cDNA was shown to be full-length by both primer extension and S1 and mung bean nuclease experiments. Thus, the complete amino acid sequence of delta-crystallin is now available. The delta-crystallin polypeptide has a molecular mass of 48,542 daltons, as expected from its behavior on NaDodSO4/polyacrylamide gels. delta-Crystallin has one tryptophan, no cysteines, a prevalence of leucines (15%), and a paucity of aromatic residues. High alpha-helical content throughout the protein was predicted from the amino acid sequence. Nucleic acid sequence analysis suggests that delta-crystallin gene 1 encodes the mRNA that gave rise to the cDNA clone. These data provide a basis for the detailed analysis of the two delta-crystallin genes.

Production and characterization of a monoclonal antibody to bovine beta-crystallin

A monoclonal antibody to a bovine lens 27K beta-crystallin polypeptide has been produced from a rat x mouse hybridoma. The antibody reacts with the 27K polypeptide of bovine, mouse, rat, and human lenses, but does not react to the 27K polypeptide of monkey lens nor does it react with any component in the Philly mouse lens which is missing the 27K polypeptide. The antibody does not recognize any of the other major bovine beta-crystallin polypeptides but does recognize a large number of native beta-crystallin proteins. The antigenic specificity and species cross-reactivity of this antibody provides an excellent opportunity to study many aspects of lens development and cataractogenesis.

Direct observation of delta-crystallin accumulation by laser light-scattering spectroscopy in the chicken embryo lens

By using the technique of laser light-scattering spectroscopy, direct observation has been made on the intracellular accumulation of a crystallin protein within the cells of chicken embryo lens during the process of development. Appearance of delta-crystallin has been detected as early as day 4, and its concentration reaches a plateau at day 19. The measurements constitute a noninvasive determination of accumulation of protein molecules that specifically characterize the process of cell differentiation.

Delta crystallins and their nucleic acids

delta-Crystallin is a major structural protein of avian and reptilian lenses that is absent from the lenses of fish, amphibia and mammals. It appears to be a tetrameric protein with a native molecular weight near 200 000 (200K) and polypeptide molecular weight near 50K and 48K) (see Note added in proof). The alpha-crystallin polypeptides are extremely similar, associate in various combinations of four and are held together by hydrophobic interactions. Although principally cytoplasmic, delta-crystallin may associate with the cell membrane. delta-Crystallin differs from other lens crystallins in its alpha-helical content, native and subunit molecular weights, antigenicity, low wavelength of maximum fluorescence emission (315 nm) after excitation at 280 nm and amino acid composition (high in leucine; low in aromatic residues en no cysteine). Analyses of peptides, native and subunit molecular weights, and circular dichroism spectra indicate that the primary, secondary, tertiary and subunit structures of delta-crystallin have been generally conserved during evolution. There are at least two tandemly arranged delta-crystallin containing 13-15 introns in the chicken; a similar structure exists for a cloned delta-crystallin gene in the duck. Experiments with chicken show that delta-crystallin synthesis occurs principally in the embryo, especially during lens fiber cell differentiation. delta-Crystallin synthesis also takes place during lens fiber cell differentiation in culture. There is evidence for both transcriptional and post-transcriptional regulation of delta-crystallin synthesis. Current studies on the crystallographic and primary structures of delta-crystallin, on the structure, evolution and expression of the delta-crystallin genes, and on the translation of delta-crystallin mRNAs make this specialized lens protein an active area of investigation.

Strict co-linearity of genetic and protein folding domains in an intragenically duplicated rat lens gamma-crystallin gene

Two complementary DNA clones pRL gamma-2 and pRL gamma-3 of different rat lens gamma-crystallin messenger RNAs have been used to identify gamma-crystallin gene sequences in rat genomic DNA. Subsequently, the DNA present in the 18,000 to 20,000 bases region of the EcoRI digest, giving rise to a strong doublet hybridization signal, was cloned in lambda phage Charon-4A. One of the clones, lambda RCH gamma-3, carrying an insert of 17,500 bases has been characterized in detail. From analysis at the restriction enzyme level with 5'-, "middle" and 3'-specific subprobes of pRL gamma-3 it could be deduced that lambda RCH gamma-3 contains only one gamma-crystallin gene. The coding sequences of this gene are interrupted by intronic DNA. The primary structure of this gene and its flanking regions have been established by sequencing the relevant regions of a subclone of lambda RCH gamma-3, designated pRCH gamma-3 . 1. The sequence data show that the gamma-crystallin gene extends over 2700 bases of rat genomic DNA. The gene is split by two introns, one of 87 base-pairs after the third translation codon and a large one of 1880 base-pairs after codon 84. The mosaic structure of the gene is strictly co-linear with the structure of the gamma-crystallin polypeptide in that the large intron is positioned in a region which specifies the so-called "connecting peptide" and which links the two highly symmetrical and homologous protein domains. Although expected from the cDNA and protein sequence no introns were observed between the coding regions in the DNA specifying the two homologous folding motifs present in each protein domain. The relevance of this phenomenon in terms of the evolution of the mature gamma-crystallin gene is discussed.

Purification and crystallization of mammalian lens gamma-crystallins

Monomeric crystallins, beta s and several members of the gamma-crystallin family, occur in different relative proportions in a way which is related to the age of the lens cells. Methods of purification of large amounts of these different low molecular weight protein components from young and old bovine lenses are described along with details of crystallization of several gamma-fractions. Purification procedures have been developed for rabbit gamma-crystallins. The chromatographic methods achieve separation of several bovine and rabbit gamma-crystallins which have very similar electrophoretic mobilities. However, on storage, many electrophoretic variants are generated from some of these fractions.

Molecular and cell isoforms during development

Development proceeds by way of a discrete yet overlapping series of biosynthetic and restructuring events that result in the continued molding of tissues and organs into highly restricted and specialized states required for adult function. Individual molecules and cells are replaced by molecular and cellular variants, called isoforms; these arise and function during embryonic development or later life. Isoforms, whether molecular or cellular, have been identified by their structural differences, which allow separation and characterization of each variant. These isoforms play a central and controlling role in the continued and dynamic remodeling that takes place during development. Descriptions of the individual phases of the orderly replacement of one isoform for another provides an experimental context in which the process of development can be better understood.

Developmental acquisition of basement membrane heterogeneity: type IV collagen in the avian lens capsule

To investigate potential heterogeneity and developmental changes in basement membranes during embryogenesis, we performed immunohistochemical analyses on lens capsules in chicken embryos of different ages using domain-specific monoclonal antibodies against type IV collagen. We found that the capsule of the newly formed lens stained uniformly with antibodies against this component of basement membranes, but with increasing age and differentiation of the lens cells the anterior lens capsule remained brightly fluorescent while staining of the posterior capsule became relatively much less intense. This antero-posterior gradient of anti-type IV collagen antibody reactivity demonstrated that developmentally-regulated changes can occur within a single, continuous basement membrane.

Gene and protein structure of a beta-crystallin polypeptide in murine lens: relationship of exons and structural motifs

A 23,000 molecular weight beta-crystallin (beta 23) of the murine eye lens is encoded in a 4.1 +/- 0.3-kilobase gene containing three introns. Each of the four exons seems to code for a separate structural motif of the protein, whose tertiary structure was predicted by an interactive computer graphics technique based on the crystallographic structure of bovine gamma II-crystallin. The first exon also encodes a hydrophobic N-terminal peptide resembling membrane anchor sequences of other proteins. Our results indicate structural homology among the beta- and gamma-crystallin polypeptides, and link gene structure with protein structure in this superfamily of lens proteins.

Decreased turnover of phosphatidylinositol accompanies in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers

The in vivo differentiation of embryonic chicken lens epithelial cells into lens fibers is accompanied by a marked decrease in the rate of degradation of phosphatidylinositol. The present experiments were undertaken to determine whether a similar change in phosphatidylinositol metabolism occurs during in vitro lens fiber formation in cultured explants of embryonic chicken lens epithelia. Lens epithelial cells in the explants differentiate into lens fibers following the addition of fetal calf serum, insulin or chicken vitreous humor to the culture medium. The results show that phosphatidylinositol is degraded with a half-life of 3-6 h in cultured lens epithelia that are not stimulated to differentiate. In contrast, no degradation occurs for at least 6 h in lens epithelia stimulated to form lens fibers. The stabilization of phosphatidylinositol is apparent within 4 h after the onset of fiber cell formation, and thus represents an early event in differentiation. The rapid degradation of phosphatidylinositol in lens epithelia is accompanied by comparably rapid synthesis. During this metabolic turnover only the phosphorylinositol portion of the molecule is renewed, as expected if hydrolysis occurs by the action of a phospholipase C, such as phosphatidylinositol phosphodiesterase. Thus, these data suggest that agents which produce in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers lead to a reduction in either the amount or the activity of phospholipase C.

Differentiation of lens and pigment cells in cultures of brain cells of chick embryos

Dissociated cells of brains (tel- and diencephalons) of 3.5-day-old chick embryos were cultivated in vitro under the cell culture conditions which are known to be permissive for neural retinal cells (NR cells) to transdifferentiate into lens and/or pigmented epithelial cells (PE cells). The differentiation of lentoid bodies (LBs) with lens-specific delta-crystallin and PE cells with melanin granules was observed in such brain cultures. LBs appeared in two different phases, i.e., 2-3 days and 16-30 days of cultivation, and after 40 days of culture these structures were formed in all 60 culture dishes. Sometimes, LBs were observed in foci of PE cells formed during earlier stages of brain cultures. When similar brain cultures were prepared with older embryos of 5-, 8.5-, 14-, and 16-days of incubation, no differentiation of lens and PE cells was observed.

Deficiency of functional messenger RNA for a developmentally regulated beta-crystallin polypeptide in a hereditary cataract

The messenger RNA for a beta-crystallin polypeptide with a molecular size of 27 kilodaltons, first detected 5 to 10 days after birth in the normal mouse lens and the Nakano mouse cataract, was not detected in the Philly mouse cataract with translation in vitro. The heterozygous Philly lens had intermediate levels of the 27-kilodalton beta-crystallin polypeptide and exhibited delayed onset of the cataract. The deficiency of functional 27-kilodalton beta-crystallin messenger RNA is the earliest lesion reported yet for the Philly lens and points to a transcriptional or posttranscriptional developmental defect in this hereditary cataract.

Multiple gamma-crystallins of the mouse lens: fractionation of mRNAs by cDNA cloning

cDNAs made from polyadenylylated RNAs of the mouse lens were cloned by the G.C tailing procedure in the bacterial plasmid pBR322. Four recombinant DNAs containing gamma-crystallin sequences were identified by hybrid selection and translation. Sequence analysis of the in vivo-labeled gamma-crystallin polypeptides that cofocused isoelectrically with the hybrid-selected translation products established that the four cloned cDNAs were derived from mRNAs encoding gamma-crystallin polypeptides with similar NH2 termini. The cDNA clones had different restriction maps and could discriminate among the different gamma-crystallin mRNAs under stringent hybridization conditions. Under relaxed hybridization conditions, the cDNA clones cross-hybridized with all gamma-crystallin mRNAs, and even slightly with beta-crystallin mRNAs, as judged by in vitro translation. RNA blot hybridization showed that the mouse lens gamma-crystallin mRNAs are 840 +/- 100 nucleotides long. These data indicate that there are at least four similar gamma-crystallin mRNAs and suggest (but do not establish) the existence of a closely related family of gamma-crystallin genes.