Evolution and diversity of the crystallins. Nucleotide sequence of a beta-crystallin mRNA from the mouse lens

Two novel RNA-binding proteins identification through computational prediction and experimental validation

Since RBPs play important roles in the cell, it's particularly important to find new RBPs. We performed iRIP-seq and CLIP-seq to verify two proteins, CLIP1 and DMD, predicted by RBPPred whether are RBPs or not. The experimental results confirm that these two proteins have RNA-binding activity. We identified significantly enriched binding motifs UGGGGAGG, CUUCCG and CCCGU for CLIP1 (iRIP-seq), DMD (iRIP-seq) and DMD (CLIP-seq), respectively. The computational KEGG and GO analysis show that the CLIP1 and DMD share some biological processes and functions. Besides, we found that the SNPs between DMD and its RNA partners may be associated with Becker muscular dystrophy, Duchenne muscular dystrophy, Dilated cardiomyopathy 3B and Cardiovascular phenotype. Among the thirteen cancers data, CLIP1 and another 300 oncogenes always co-occur, and 123 of these 300 genes interact with CLIP1. These cancers may be associated with the mutations occurred in both CLIP1 and the genes it interacts with.

Crystallin gene expression: Insights from studies of transcriptional bursting

Cellular differentiation is marked by temporally and spatially regulated gene expression. The ocular lens is one of the most powerful mammalian model system since it is composed from only two cell subtypes, called lens epithelial and fiber cells. Lens epithelial cells differentiate into fiber cells through a series of spatially and temporally orchestrated processes, including massive production of crystallins, cellular elongation and the coordinated degradation of nuclei and other organelles. Studies of transcriptional and posttranscriptional gene regulatory mechanisms in lens provide a wide range of opportunities to understand global molecular mechanisms of gene expression as steady-state levels of crystallin mRNAs reach very high levels comparable to globin genes in erythrocytes. Importantly, dysregulation of crystallin gene expression results in lens structural abnormalities and cataracts. The mRNA life cycle is comprised of multiple stages, including transcription, splicing, nuclear export into cytoplasm, stabilization, localization, translation and ultimate decay. In recent years, development of modern mRNA detection methods with single molecule and single cell resolution enabled transformative studies to visualize the mRNA life cycle to generate novel insights into the sequential regulatory mechanisms of gene expression during embryogenesis. This review is focused on recent major advancements in studies of transcriptional bursting in differentiating lens fiber cells, analysis of nascent mRNA expression from bi-directional promoters, transient nuclear accumulation of specific mRNAs, condensation of chromatin prior lens fiber cell denucleation, and outlines future studies to probe the interactions of individual mRNAs with specific RNA-binding proteins (RBPs) in the cytoplasm and regulation of translation and mRNA decay.

Cloning and characterization of a cow beta crystallin cDNA

We have isolated and sequenced a beta crystallin cDNA clone derived from the mRNA of cow lenses. Comparisons of the deduced amino acid sequence with the amino acid sequences of the principal beta crystallins of the cow, Beta Bp (1) and the mouse (2,3), confirm the general homology within the beta crystallin family and with the gamma crystallins. This beta crystallin cDNA, designated pBeta25/23, has 96% amino acid homology with the murine beta23 and only 43% amino acid homology with the cow beta Bp. The N-terminal 14 amino acids of the murine beta23, which are composed of a high percentage of hydrophobic amino acid residues, bear no similarity to the predicted amino acid sequence of the cow beta crystallin cDNA clone which we have isolated. The remaining amino acid sequences show greater homology between the mouse and cow beta crystallins than the corresponding alpha and beta globins between the two species. The degree of homology is comparable to that of the alpha crystallins for the cow and mouse. The pBeta25/23 cDNA is interesting for the presence of two potential translation initiation sites which are in phase and, if both are used, would code for two polypeptides of MW 25,100 and 23,200. These correspond to the 25,000 and 23,000 dalton beta crystallins that have been partially sequenced by Berbers et al. (4). This raises the possibility that the beta 25 and the beta23 synthesized in the cow lens are not encoded by two separate genes but may be derived from single mRNA using two translation initiation sites or by post-translational processing of the larger peptide. It is possible also that the two proteins are from two mRNA's derived from a single hnRNA by differential splicing of a intervening sequence at the 5' end of the gene.

Mutation in the betaA3/A1-crystallin encoding gene Cryba1 causes a dominant cataract in the mouse

During the mouse ENU mutagenesis screen, mice were tested for the occurrence of dominant cataracts. One particular mutant was discovered as a progressive opacity (Po). Heterozygotes show opacification of a superficial layer of the fetal nucleus, which progresses and finally forms a nuclear opacity. Since the homozygotes have already developed the total cataract at eye opening, the mode of inheritance is semidominant. Linkage analysis was performed using a set of genome-wide microsatellite markers. The mutation was mapped to chromosome 11 distal of the marker D11Mit242 (9.3 +/- 4.4 cM) and proximal to D11Mit36 (2.3 +/- 2.3 cM). This position makes the betaA3/A1-crystallin encoding gene Cryba1 an excellent candidate gene. Mouse Cryba1 was amplified from lens mRNA. Sequence analysis revealed a mutation of a T to an A at the second base of exon 6, leading to an exchange of Trp by Arg. Computer analysis predicts that the fourth Greek key motif of the affected betaA3/A1-crystallin will not be formed. Moreover, the mutation leads also to an additional splicing signal, to the skipping of the first 3 bp of exon 6, and finally to the deletion of the Trp residue. Both types of mRNA are present in the homozygous mutant lenses. The mutation will be referred to as Cryba1(po1). This particular mouse mutation provides an excellent animal model for a human congenital zonular cataract with suture opacities, which is caused by a mutation in the homologous gene.

Sequence of the human lens beta B2-crystallin-encoding cDNA

This study reports the nucleotide (nt) sequence of the human beta B2-crystallin (h beta B2-Cry)-encoding cDNA (h beta B2-cry). The h beta B2-cry gene encodes a major structural protein in the lens of the vertebrate eye. Sequence information obtained from mouse genomic clones and the mouse beta B2-cry cDNA (m beta B2-cry) sequence was used to design oligodeoxyribonucleotide primers, corresponding to exon 1, transcription start points, and termination and polyadenylation sites, that were used in the polymerase chain reaction (PCR) to generate full-length cDNA clones from total human lens RNA. In addition, cDNA libraries were made with lambda gt11 from both human fetal and adult lens tissue RNAs, and screened with a m beta B2-cry cDNA clone. The full-length h beta B2-cry cDNA is 721 bp and contains an open reading frame of 612 nt. It codes for a 23-kDa protein of 205 amino acid residues. Comparison of the overall nt and deduced aa sequences shows a greater similarity of h beta B2-cry to bovine beta B2-cry than to m beta B2-cry or rat beta B2-cry.

Physicochemical characterization of beta-crystallins from bovine lenses: hydrodynamic and aggregation properties

A detailed investigation of the hydrodynamic and aggregation behaviors has been made on the beta-crystallins of bovine lens. Results from this study indicated that beta H (high-molecular-weight beta-crystallin) and beta L (low-molecular-weight beta-crystallin) exhibited considerable heterogeneity in their native structures and subunit polypeptides. Low-speed sedimentation equilibrium showed a heterogeneous paucidisperse system in each beta-crystallin fraction. Viscosity and circular dichroism studies pointed to a compact and globular shape and the presence of beta-sheet and beta-turns in these crystallins. Dissociation of beta H by urea and guanidinium HCl followed by reassociation during gel-filtration chromatography produced an elution pattern with two fractions corresponding to beta L crystallin and high-molecular-weight aggregates without the formation of native beta H. By contrast, under similar treatment, about 60% beta L reassociated into the correct native structure and the rest into high-molecular-weight fractions. Amino acid analyses of beta H and beta L and their corresponding subunit polypeptides demonstrated the close similarity of these crystallins. Trace element analyses indicated that both Ca and Mg are present in beta H and beta L crystallins and may be involved in maintaining the native quarternary structures of these proteins.

Frog lens beta A1-crystallin: the nucleotide sequence of the cloned cDNA and computer graphics modelling of the three-dimensional structure

Four recombinant cDNA clones coding for a 23 kDa beta-crystallin polypeptide of the frog (Rana temporaria) were identified in a collection of cloned cDNA and two of them were sequenced. The cDNA present in these clones codes for a polypeptide 198 amino-acid residues in length, which appears to be the frog beta A1-crystallin because of its high homology with the sequences of beta A1-crystallins from other species. Furthermore, the nucleotide sequence coding for the compact folded region of the protein is highly conserved. Virtually no homology was found in the 3' nontranslated regions of the mRNA. The amino-acid sequence of the Rana beta A1-crystallin was used to build a three-dimensional model based on the coordinates of the homologous bovine gamma II. An analysis of the model shows that the surface residues of the beta A1-crystallin (amphibian, mammalian and bird) are more highly conserved than the buried residues. It is suggested that this is related to the oligomeric nature of the lens beta-crystallins.

The mouse eye lens obsolescence (Elo) mutant: studies on crystallin gene expression and linkage analysis between the mutant locus and the gamma-crystallin genes

Previous studies showed that the mouse Elo (eye lens obsolescence) mutation is located on chromosome 1, at a site near the Len-1 locus, which is defined by a set of polymorphic gamma-crystallin proteins. To investigate further the relationship between Elo and the gamma-crystallins, we have examined the steady-state levels of gamma-crystallin transcripts in normal and mutant eyes and analyzed the linkage relationship between the Elo locus and the gamma-crystallin genes. Our data showed that, while gamma-crystallin mRNA levels are preferentially reduced in the mutant eyes, the mutation does not seem to map within the gamma-crystallin gene cluster. The distance between Elo and the gamma 6 gene (the most proximal gamma-crystallin gene member) is estimated to be 1.4 +/- 0.9 cM, whereas that between gamma 6 and the distantly linked gamma 2 gene is 2.7 +/- 1.3 cM. Our data also suggest the possibility of recombination hot spots with the gamma-crystallin gene cluster.

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.

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.

Preferential conservation of the globular domains of the beta A3/A1-crystallin polypeptide of the chicken eye lens

The primary structure of the beta 19/26-crystallin polypeptide of the chicken lens has been determined by cDNA sequencing and primer extension experiments. In addition, a primer extension experiment has corrected the sequence for the N-terminal arm of the murine beta 23 polypeptide, which is the homologue of the chicken beta 19/26 polypeptide. We also show that, in the chicken and mouse, the N-terminal arm of the polypeptide is encoded on two separate exons. For simplicity, we have changed the names of both chicken beta 19/26 and murine beta 23 to beta A3/A1, which is the name of the homologous bovine polypeptide. The deduced sequence of the chicken beta A3/A1 polypeptide fits the predicted three-dimensional structure involving two homologous domains, each folded into two 'Greek key' motifs, common to the beta gamma-crystallin superfamily of proteins. Comparison of the amino acid sequence of the chicken and mammalian beta A3/A1 polypeptides indicates that different regions of the protein, which are encoded on different exons, are diverging at different rates. The N-terminal extension is the fastest evolving region of the beta A3/A1 polypeptide. Hybrid-selected translation coupled with primer extension experiments suggest that a single chicken beta A3/A1 mRNA synthesizes two polypeptides, beta A3 (25 kDa) and beta A1 (23 kDa) by utilization of different translation initiation sites.

tau-Crystallin from the turtle lens: purification and partial characterization

A lens protein with a molecular mass near 46 000 daltons has been purified from the turtle lens. It is a monomeric protein which differs from other lens crystallins in its antigenicity, near-UV circular dichroism spectrum and amino acid composition. Like delta-crystallin, it has appreciable secondary structure (52% alpha-helix). This lens protein has been named tau-crystallin. tau-Crystallin cross-reacts with the novel 48 000 dalton protein identified recently in lenses of the sea lamprey. Although distinct, the possibility that tau-crystallin shares an ancestral relationship with delta-crystallin is discussed.

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.

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.

A second polymorphic lens crystallin (LEN-2) in the mouse: genetic and biochemical analysis of LEN-1 and LEN-2

Two electrophoretic polymorphisms affecting lens crystallins, designated LEN-1 and LEN-2, have been discovered among inbred strains of mice. Analysis by isoelectric focusing demonstrated that both crystallins are monomeric proteins with isoelectric points at or above pH 7. Both proteins eluted in the low molecular weight (LM) fraction upon Sephadex G-200 gel filtration but LEN-2 was shown to be larger than LEN-1 by G75SF gel filtration and denaturing gel electrophoresis. Linkage analysis demonstrated that the genes encoding LEN-1 and LEN-2 assort independently. Amino acid analysis of the allelic products of the two genes revealed that genetic variants of each respective crystallin were very similar in amino acid compositions but that LEN-1 and LEN-2 were dissimilar crystallins.

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.

Bovine beta-crystallin complementary DNA clones. Alternating proline/alanine sequence of beta B1 subunit originates from a repetitive DNA sequence

A library of recombinant plasmids carrying complementary DNA sequences synthesized from bovine lens messenger RNAs was constructed. Clones coding for five different beta-crystallin subunits: beta B1, beta B3, beta Bp, beta s, beta A3 (and beta A1), were identified by means of hybridization selection, followed by one- and two-dimensional gel electrophoresis of the translational products. Under rather stringent conditions each of these clones hybridizes with its corresponding mRNA and does not show significant cross-hybridization with mRNAs coding for other beta-crystallins, except in the case of the homologous beta A3 and beta A1-crystallins. The beta A3 and beta A1 subunits seem to be encoded by one mRNA using two different AUG codons as start position for translation. We have also determined the nucleotide sequence of a beta B1-crystallin cDNA (pBL beta B1) which enabled us to deduce the complete amino acid sequence of the protein. The beta B1-crystallin, a characteristic component of the high molecular weight crystallin aggregate (beta H), is internally homologous both at DNA and protein level as has been reported for gamma- and other beta-crystallins. This is in agreement with the idea that these proteins had a common ancestral precursor gene that internally duplicated. The G + C content of the coding sequence of beta B1 is very high: 67% overall and even 84.2% for the first 170 nucleotides, due to a remarkable non-random codon usage. A proline/alanine repetition in the N-terminal domain of the protein is encoded by a repetitive "simple" DNA sequence.

Evidence against gamma-crystallin DNA or RNA sequences in the chicken

A cloned cDNA (pM gamma 1 Crl) encoding about two-thirds of a gamma-crystallin polypeptide from the murine lens was used as a hybridization probe to search for the presence of gamma-crystallin-like RNA or DNA sequences in the chicken. The 15-day-old chicken lens did not contain any RNA sequences homologous to the murine gamma-crystallin cDNA, as judged by Northern blot hybridization. An approximate 2.3 Kbp (kilobase pair) Bam HI fragment from the chicken genome hybridized to the murine gamma-crystallin cDNA in Southern blots. Cloning and sequencing of this genomic fragment, however, did not reveal any homology with gamma- or beta-crystallin sequences. A stretch of 22 dG: dC nucleotides was present in the cloned DNA fragment and possibly this hybridized to the cloned gamma-crystallin cDNA via its dG:dC nucleotide tails introduced during the cloning procedure. These data support those of McDevitt and Croft (1977) indicating that the chicken lens lacks gamma-crystallin and provide evidence against gamma-crystallin mRNA or a gamma-crystallin gene or pseudogene in the chicken. The absence of gamma-crystallin mRNA in the embryonic chicken lens cells makes them potentially useful recipients for investigating the expression of cloned gamma-crystallin genes.

Isolation and characterization of beta- and gamma-crystallin genes from rat genomic cosmid libraries

Two libraries, together containing about 10(6) colonies, have been constructed by cloning different size fractions of a partial Sau3A digest of rat genomic DNA in the cosmid vector pTM. Upon screening with two cDNA clones, one containing alpha A2-crystallin and one containing beta B1-crystallin sequences, 14 cosmid clones were isolated which were beta B1-crystallin-specific; none was found which contained alpha A2-crystallin sequences. The inserts of the beta B1 clones, which range from 35 to 45 kb in length, contain overlapping DNA segments covering more than 60 kb of rat genomic DNA. The composite BamHI restriction map of this region shows a single beta B1-crystallin gene, which is interrupted by several intronic sequences. Five recombinants hybridizing with two different rat lens gamma-crystallin cDNA clones were also isolated from these libraries. Four of these contain 31- to 41-kb inserts, whereas the fifth recombinant contains a 12.2-kb insert. Hybridization analysis with 5' and 3'-specific cDNA fragments indicates that altogether these inserts contain six gamma-crystallin genes, three of which are located on one insert of only 31 kb.

Homology between the primary structures of the major bovine beta-crystallin chains

Partial amino acid sequences of six major subunits of bovine beta-crystallin have been determined by automatic liquid-phase Edman degradation and the dansyl-Edman procedure, complemented by amino acid analyses of peptides. The results show that, including the previously established beta Bp sequence [H. P. C. Driessen et al. (1981) Eur. J. Biochem. 121, 83-91], there exist at least seven primary gene products in bovine beta-crystallin, which exhibit 40% or more sequence homology. Two of the gene products are completely identical except for the presence in one of them of 17 additional residues at the N terminus, possibly caused by differential splicing of the same primary RNA transcript. The rate of evolutionary change of the beta chains (4% sequence change per 100 X 10(6) years) is about equally slow as that of alpha-crystallin, and the gene duplications giving rise to the different chains must have occurred very early in vertebrate evolution. The beta chains can be divided into two groups, according to sequence homology and presence of deletions/insertions and C-terminal extension, on which basis a new, rational nomenclature for the beta subunits is introduced. The N-terminal extensions of all beta chains are very different in length and sequence, even between homologous beta chains in different species. Possible explanations for this finding are discussed.

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.

X-ray analysis of the eye lens protein gamma-II crystallin at 1.9 A resolution

We report the X-ray structure analysis and refinement at 1.9 A resolution of calf gamma-II crystallin, a lens-specific protein. The sequence of Croft (1972) has been modified to give a polypeptide chain of 174 residues (cf. 165). The protein has a symmetrical, hierarchical structure of two globular domains each comprising two similar "Greek key" motifs, consecutive along the polypeptide chain, and related by a pseudo 2-fold axis. The two domains pack together with a single connection and are related by a further pseudo 2-fold axis which bisects the angle between the intra-domain dyads. Forty-two pairs of C alpha positions for the two most similar motifs have root-mean-square separation at best fit of 0.69 A. The N and C-terminal domains gave root-mean-square separation of 0.89 A for 82 pairs of C alpha atoms at best fit. In each domain the two Greek key motifs form a pair of four-stranded antiparallel beta-pleated sheets, each sheet composed of three stands from one motif and one from the other. The sheets pack together in a wedge shape, closed at the top by the loops connecting the third and fourth strands of each motif. The first two strands of each motif form an extended beta-hairpin which is folded on to the beta-sheet. The packing of each motif into the globular domains involves a staggered bilayer of side-chains between each pair of beta-sheets which does not preserve the pseudo 2-fold axes observed in the C alpha position topology. In the core of each domain there are interactions between polarizable aromatic groups and sulphur-containing residues which may contribute to stability and may also serve to protect aromatic side-chains from ultraviolet light damage in the lens. At the surface of the molecule over half the ionic side-chains are closely paired, which probably stabilizes the tertiary fold and may reduce the water bound. Crystal lattice interactions are described which may be similar to those occurring in vivo in the lens between crystallins. Seven cysteine residues have been identified in the structure and these may have a role in the thermodynamic stability of the molecule, its intermolecular interactions under the normal reducing conditions of the lens, and also in the aggregation and cross-linking which occur in some forms of cataract. Three of these residues, Cys18, Cys23 and Cys74, form a cluster in the N-terminal domain.(ABSTRACT TRUNCATED AT 400 WORDS)

Proline- and alanine-rich N-terminal extension of the basic bovine beta-crystallin B1 chains

The amino acid sequence of the N-terminal region of the two basic bovine beta-crystallin B1 chains has been analyzed. The results reveal that beta B1b is derived in vivo from the primary gene product beta B1a by removal of a short N-terminal sequence. It appears that the beta B1 chains have the same domain structure as observed in other beta- and gamma-crystallin chains. They have, however, a very long N-terminal extension in comparison with other beta-chains. This extension is mainly composed of a remarkable Pro- and Ala-rich sequence, which suggests an interaction of these structural proteins with the cytoskeleton and/or the plasma membranes of the lens cells.

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.