The presence of D-beta-aspartic acid-containing peptides in elastic fibers of sun-damaged skin: a potent marker for ultraviolet-induced skin aging

Biologically uncommon d-aspartyl residues have been reported in proteins of various elderly tissues. We prepared a polyclonal antibody against d-beta-Asp-containing peptide and examined its immunoreactivity in the skin. The antibody recognized integrated or disintegrated elastic fibers in the sun-exposed skin but not in the sun-protected skin of the elderly donors. Western blot analysis of the proteins isolated from sun-damaged skin demonstrated that the 50 kDa protein was immunoreactive with both antibodies for d-beta-Asp-containing peptide and elastin. Ultraviolet (UV) irradiation on normal skin caused the appearance of d-beta-Asp-containing peptide-immunoreactive fibers in the dermis. These results suggest that UV irradiation is closely related to the formation of d-beta-Asp in the elastic fibers of skin. We propose that the antibody could be a useful indicator for sun damage of the skin.     

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.     

Three-dimensional model and quaternary structure of the human eye lens protein gamma S-crystallin based on beta- and gamma-crystallin X-ray coordinates and ultracentrifugation.

A 3-dimensional model of the human eye lens protein gamma S-crystallin has been constructed using comparative modeling approaches encoded in the program COMPOSER on the basis of the 3-dimensional structure of gamma-crystallin and beta-crystallin. The model is biased toward the monomeric gamma B-crystallin, which is more similar in sequence. Bovine gamma S-crystallin was shown to be monomeric by analytical ultracentrifugation without any tendency to form assemblies up to concentrations in the millimolar range. The connecting peptide between domains was therefore built assuming an intramolecular association as in the monomeric gamma-crystallins. Because the linker has 1 extra residue compared with gamma B and beta B2, the conformation of the connecting peptide was constructed by using a fragment from a protein database. gamma S-crystallin differs from gamma B-crystallin mainly in the interface region between domains. The charged residues are generally paired, although in a different way from both beta- and gamma-crystallins, and may contribute to the different roles of these proteins in the lens.     

Quaternary interactions in eye lens beta-crystallins: basic and acidic subunits of beta-crystallins favor heterologous association

beta-Crystallins are complex eye lens proteins made up of several related basic and acidic subunits that combine to form differently sized oligomers each displaying extensive polydispersity. As the sequences are homologous to the X-ray-determined bilobal structure of gamma-crystallin, beta-subunits are visualized as having a similar structure with additional N- and C-terminal extensions. Two basic (beta B2 and beta B3) and two acidic (beta A3 and beta A4) subunits have been isolated in deaggregating media, refolded, and reassociated in various combinations to determine which components favor dimers or higher oligomers. Homopolymers were compared with beta B2 homodimer in terms of charge, using Mono Q fast protein liquid chromatography, and size, using Superose 12 chromatography. Heterooligomeric formations were monitored by their intermediate charge properties compared with homooligomers. beta B2 associates with either beta B3- or beta A4-forming heterodimers whereas a larger oligomer is formed with beta A3. Naturally occurring beta-crystallin oligomers were analyzed by Mono Q chromatography and PhastGel electrophoresis. Whereas beta B2, beta B3, and beta A4 can each be reassociated to homodimers, beta A4 dimers are not found in native beta-crystallins. beta B2-beta A3 is a major component of intermediate-sized beta L1-crystallin and is absent from dimeric beta L2-crystallin. It is suggested that the pH dependence of the size of beta L1-crystallin is due to a dimer to tetramer equilibrium. By following dimer interactions using Superose 12 chromatography, beta B2-beta A4 was shown to interact with beta B2-beta A3. A model of beta-crystallin structure is proposed based on beta-subunits forming dimers with the next level of organization requiring an acidic subunit, beta A3, with a long N-terminal extension.     

Calcium binding properties of gamma-crystallin: calcium ion binds at the Greek key beta gamma-crystallin fold

The beta- and gamma-crystallins are closely related lens proteins that are members of the betagamma-crystallin superfamily, which also include many non-lens members. Although beta-crystallin is known to be a calcium-binding protein, this property has not been reported in gamma-crystallin. We have studied the calcium binding properties of gamma-crystallin, and we show that it binds 4 mol eq of calcium with a dissociation constant of 90 microm. It also binds the calcium-mimic spectral probes, terbium and Stains-all. Calcium binding does not significantly influence protein secondary and tertiary structures. We present evidence that the Greek key crystallin fold is the site for calcium ion binding in gamma-crystallin. Peptides corresponding to Greek key motif of gamma-crystallin (42 residues) and their mutants were synthesized and studied for calcium binding. These peptides adopt beta-sheet conformation and form aggregates producing beta-sandwich. Our results with peptides show that, in Greek key motif, the amino acid adjacent to the conserved aromatic corner in the "a" strand and three amino acids of the "d" strand participate in calcium binding. We suggest that the betagamma superfamily represents a novel class of calcium-binding proteins with the Greek key betagamma-crystallin fold as potential calcium-binding sites. These results are of significance in understanding the mechanism of calcium homeostasis in the lens.     

Rise and fall of crystallin gene messenger levels during fibroblast growth factor induced terminal differentiation of lens cells.

Explanted rat lens epithelial cells differentiate synchronously in vitro to lens fiber cells in the presence of basic fibroblast growth factor (bFGF). We have monitored the expression of the three rat crystallin gene families, the alpha-, beta-, and gamma-crystallin genes, during this process. The expression of these gene families is sequentially activated, first the alpha-crystallin genes at Day 1, then the beta-crystallin genes at Day 3, and finally the gamma-crystallin genes at Day 8. The steady state levels of alpha- and beta-crystallin mRNA are not affected by incubation with actinomycin D, suggesting that these mRNAs are stable. Nevertheless, all crystallin mRNAs disappear from the differentiated explants between Days 10 and 11, a process signaled by bFGF. At this time a novel abundant mRNA appears. Cloning and sequencing showed that this mRNA encoded aldose reductase. Our results suggest a novel model for the regulation of crystallin synthesis during lens cell differentiation: a gene pulse delivers a certain amount of stable mRNA, this mRNA is removed at a later stage of differentiation by a stage-specific breakdown mechanism. Each of these regulatory steps requires a signal from bFGF.     

Unfolding of human lens recombinant betaB2- and gammaC-crystallins

betaB2- and gammaC-crystallins belong to the betagamma-crystallin superfamily and have very similar structures. Molecular spectroscopic techniques such as UV-visible absorption, circular dichroism, and fluorescence indicate they have similar biophysical properties. Their structures are characterized by the presence of two domains consisting of four Greek key motifs. The only difference is the connecting peptide of the two domains, which is flexible in gamma-crystallin but extended in beta-crystallin; thus, an intradomain association and a monomer are formed in gamma-crystallin and an interdomain association and a dimer are formed in beta-crystallin. The difference may be reflected in the thermodynamic stability. In the present study, we calculated the standard free-energy by equilibrium unfolding transition in guanidine hydrochloride using three spectroscopic parameters: absorbance at 235nm, Trp fluorescence intensity at 320nm, and far-UV circular dichroism at 223nm. Global analyses indicate that both dimeric betaB2- and monomeric gammaC-crystallins are a better fit to a three-state model than to a two-state model. In terms of standard free-energy, deltaG(0)(H(2)O,i) both betaB2-crystallin and gammaC-crystallin are stable proteins and dimeric betaB2-crystallin is more stable than the monomeric gammaC-crystallin. The significance of the thermodynamic stability for betaB2- and gammaC-crystallins may be related to their functions in the lens.     

Evidence for the extralenticular expression of members of the β-crystallin gene family in the chick and a comparison with δ-crystallin during differentiation and transdifferentiation

The beta-crystallins are major water soluble proteins of vertebrate lens fibre cells and have previously been regarded as lens-specific proteins: however beta B2-and beta A3/A1-crystallin RNAs are transcribed and beta-crystallin polypeptides are detectable in the developing chick retina. The beta-crystallin RNA is transcribed in a subpopulation of retina cells and the number of transcribing cells and the level of beta-crystallin polypeptides increase during the differentiation of the retina. Several tissues express beta-crystallin polypeptides, but individual tissues are characterised by qualitative and quantitative differences in the beta- and delta-crystallin polypeptides expressed. The expression of beta-crystallins appears to be non-random as defined by tissue distribution, cellular localisation and ontogeny, implying a function for extralenticular beta-crystallins and a complex mechanism for the regulation of their expression.     

Structural homology of lens crystallins. A method to detect protein structural homology from primary sequences

The X-ray crystallographic structure of bovine gamma-crystallin shows four similar folding motifs each composed of about 42 residues arranged as four topologically sequential, anti-parallel beta-strands. Since the beta and gamma-crystallin sequences show good homology, proposals for a four-motif beta-crystallin model have been made. The other bovine eye-lens protein species, alpha-crystallins, are not homologous to beta or gamma-crystallin in primary structure. In the present work, smoothed plots of amino acid sequence number versus a residue characteristic (e.g. hydrophobicity) were calculated for the various crystallins. Cross-correlation coefficients were then determined between pairs of crystallin plots for various registers of the curves. The correlation plots were then combined for several characteristics and for pairwise comparisons between beta or gamma-crystallin and the alpha-crystallins. The resulting plots showed four peaks separated by about 42 residues for the alpha-crystallins, suggesting that they also possess a four-motif beta-barrel structure. The physical parameter comparison technique appears generally applicable in suggesting a structural and functional relationship amongst proteins that show no primary sequence homology.     

A comparison of structural relationships among α-crystallin, human Hsp27, γ-crystallins and βB2-crystallin

The 3D structures of α-crystallin, a major eye lens protein, and related small heat shock proteins are unresolved. It has been assumed that α-crystallin is primarily a β-sheet globular protein similar to γ-crystallin (Siezen and Argos, Biochim. Biophys. Acta, 1983, 748, 56–67) containing sequence repeats in its two domains (Wistow, FEBS Lett. 1985, 181, 1–6). Positional flexibility of amino acid residues and far UV-circular dichroism spectroscopy were used to investigate structural relationships among these proteins. The utility of flexibility plots for predicting protein structure is demonstrated by the excellent correlation of these plots with the known 3D X-ray structures of β/γ-crystallins. Similar analyses of α-crystallin subunits, αA and αB, and human heat shock protein 27 show that the C-terminal domains and connecting segments of these proteins are very similar while the N-terminal domains have significant structural differences. Unlike β/γ-crystallins, both Hsp27 and α-crystallin subunits are asymmetrical with highly flexible C-terminal domains. Flexibility is considered essential for protein functional activity. Therefore, the C-terminal region may play an active role in α-crystallin and small heat shock protein function. Differences in flexibility profiles and estimated secondary structure distribution in α-crystallin by three recent/updated algorithms from far UV-CD spectra support our predicted 3D structure and the concept that α-crystallin and members of β/γ-superfamily are structurally dissimilar.     

Investigation of the mechanisms of crystallin aggregation induced by pulsed laser UV irradiation at 308 nm

The results of the investigations of photoaggregation of the main eye lens proteins alpha-, beta- and gamma-crystallins and the model protein carbonic anhydrase in response to pulsed irradiation by a XeCI laser at 308 nm in the wide range of pulse energy densities (w) and pulse repetition rates (F) have been reviewed. A nonlinear dependence of aggregation efficiency on the values of w, F, and the concentration of protein solution was found. A theoretical model that qualitatively describes the experimental results was developed. The aggregation of N-amino-arm truncated beta A3-crystallin was analyzed. It was found that the loss of the N-amino-arm as a result of mutation or eye lens aging increases the probability of UV-induced beta-crystallin aggregation, thereby increasing the predisposition of eye lens to senile cataract. The influence of some short-chain peptides on the aggregation efficiency of beta-crystallin and beta-crystallin in solution with alpha-crystallin was investigated. Based on the results obtained, a combination of peptides (called "a new preparation") was found that most effectively delays the crystallin aggregation. The preparation has been probed on experimental animals. The trials showed that the preparation increases the delay in the development of UV-induced cataract in rats. The possibility of designing a drug for the prophylaxis of the development of cataract in humans based on this preparation is discussed.     

Beta B1 crystallin is an amine-donor substrate for tissue transglutaminase

The effects of tissue transglutaminase on the water-soluble proteins in bovine lens homogenates are described. Addition of liver transglutaminase and Ca2+ to calf lens homogenates resulted not only in the appearance of 50- and 57-kDa dimers, but also in a decrease in the amount of beta B1 crystallin and the almost complete disappearance of beta B3 and beta A3. This is not the result of Ca2+-induced proteolysis, since histamine completely inhibits this phenomenon. It may be concluded that these polypeptides are involved in beta-crystallin crosslinking by transglutaminase. This notion was confirmed by using beta B1- and beta Bp-specific antisera. Both sera reacted with the 57-kDa dimer; the beta Bp-specific antiserum also reacted with the 50-kDa dimer. No reaction in the region 50-57 kDa was detectable when EDTA was used instead of Ca2+. Using reconstituted mixtures of beta B1- and beta Bp-crystallin chains, and N-terminally truncated derivatives thereof, it was shown that in the beta B1/beta Bp dimer, glutamine residue -9 of beta Bp crosslinks to one of the lysine residues in the N-terminal extension of beta B1.     

Phosphorylation of beta-crystallin B2 (beta Bp) in the bovine lens

Three major 32P-labeled polypeptides were found in the soluble fraction of bovine lenses cultured in a medium containing [32P]orthophosphate. Two of the polypeptides corresponded to the phosphorylated A and B chains of alpha-crystallin. In this communication, the third polypeptide is now identified. This polypeptide is characterized by a molecular weight of 27,000 and a pI of 6.6, eluted exclusively in the beta Low fraction of a CL-6B gel filtration separation of lens soluble material, and could be further purified by DE52 anion exchange chromatography. The only 32P-labeled amino acid detected was phosphoserine. A single 32P-labeled peptide was observed after tryptic digestion and two-dimensional mapping. The amino acid sequence of the purified peptide is Gly-Ala-Phe-His-Pro-Ser-Ser. This sequence exactly matches the expected C-terminal tryptic fragment, residues 198-204, of the bovine beta-crystallin B2. The results of carboxypeptidase A digestion of the 32P-labeled peptide suggest that only Ser203 is phosphorylated. By using the catalytic subunit of the cAMP-dependent protein kinase, purified beta B2 was phosphorylated in vitro, generating a single 32P-labeled polypeptide with the identical pI as the phosphorylated polypeptide obtained from lens culture. On the basis of these data, the Mr 27,000 32P-labeled polypeptide is identified as the phosphorylated form of the beta-crystallin B2.     

Relationship between proteins encoded by three human gamma-crystallin genes and distinct polypeptides in the eye lens.

Although individual gamma-crystallins from the human eye lens have not been successfully purified and sequenced, most of the genes coding for these lens-specific structural proteins have been cloned and characterized. To investigate the relationship between these genes and the gamma-crystallins of the human lens, we made use of mouse cell lines which contain stably integrated copies of the coding sequences for three of the human gamma-crystallin genes coupled to the human metallothionein IIA promoter. The proteins produced by these hybrid genes in cell culture were detected immunologically and compared by physical characteristics with the gamma-crystallins from the human lens. The protein encoded by the G3 gene showed properties identical to those of the 21,000-molecular-weight gamma-crystallin from 11-month-old lens. The protein isolated from the cells expressing the G4 gene was similar to a 19,000-molecular-weight lens gamma-crystallin, while gene G5 encodes a highly basic gamma-crystallin which may be synthesized in only limited amounts in the human lens. These correlations provide a basis for future investigations on the relationship between putative mutations in human gamma-crystallin genes and altered proteins in hereditary lens cataracts.     

Calcium-binding to lens betaB2- and betaA3-crystallins suggests that all beta-crystallins are calcium-binding proteins

Crystallins are the major proteins of a mammalian eye lens. The topologically similar eye lens proteins, beta- and gamma-crystallins, are the prototype and founding members of the betagamma-crystallin superfamily. Betagamma-crystallins have until recently been regarded as structural proteins. However, the calcium-binding properties of a few members and the potential role of betagamma-crystallins in fertility are being investigated. Because the calcium-binding elements of other member proteins, such as spherulin 3a, are not present in betaB2-crystallin and other betagamma-crystallins from fish and mammalian genomes, it was argued that lens betagamma-crystallins should not bind calcium. In order to probe whether beta-crystallins can bind calcium, we selected one basic (betaB2) and one acidic (betaA3) beta-crystallin for calcium-binding studies. Using calcium-binding assays such as 45Ca overlay, terbium binding, Stains-All and isothermal titration calorimetry, we established that both betaB2- and betaA3-crystallin bind calcium with moderate affinity. There was no significant change in their conformation upon binding calcium as monitored by fluorescence and circular dichroism spectroscopy. However, 15N-1H heteronuclear single quantum correlation NMR spectroscopy revealed that amide environment of several residues underwent changes indicating calcium ligation. With the corroboration of calcium-binding to betaB2- and betaA3-crystallins, we suggest that all beta-crystallins bind calcium. Our results have important implications for understanding the calcium-related cataractogenesis and maintenance of ionic homeostasis in the lens.     

Mapping spatial proximities of sulfhydryl groups in proteins using a fluorogenic cross-linker and mass spectrometry

Chemical cross-linking of proteins in combination with mass spectrometric analysis of the reaction products has gained renewed interest as a method of obtaining distance constraints within a protein and determining a low-resolution three-dimensional structure. We present a method for identifying spatially close sulfhydryl groups in proteins employing chemical cross-linking with the fluorogenic, homobifunctional cross-linker dibromobimane, which cross-links thiol pairs within approximately 3-6A. The applicability of our strategy was demonstrated by cross-linking the sulfhydryl groups of Cys-18 and Cys-78 in gamma-crystallin F, which are within a distance of 3.57A according to the X-ray structure. Intramolecularly cross-linked gamma-crystallin was first separated from reaction side products by reversed-phase chromatography on a C-4 column. Subsequently, the fraction containing the reacted protein was enzymatically digested with trypsin, and the resulting peptide mixture was separated by a second reversed-phase chromatographic step on a C-18 column, in which the cross-linked peptides were tracked by their fluorescence. The cross-linking product between Cys-18 and Cys-78 in gamma-crystallin F was identified by matrix-assisted laser desorption/ionization-time of flight mass spectrometry. This strategy presents a rapid method for mapping sulfhydryl groups separated by a distance of approximately 3-6A within a protein.     

State of differentiation of bovine epithelial lens cells in vitro : Modulation of the synthesis and of the polymerization of specific proteins (crystallins) and non-specific proteins in relation to cell divisions

Maintenance of the state of differentiation in serially cultured bovine epithelial lens cells has been investigated. The radioactive labelled soluble proteins were studied by gel filtration and gel electrophoresis. 1. In the lens epithelium on its capsule, preferential synthesis of alpha B2 vs alpha A2 crystallin subunits and synthesis of beta-crystallins (mainly beta Bp) were observed. 2. Epithelial lens cells cultured on plastic Petri dishes for up to 35 divisions still synthesized alpha B2 and beta Bp, but no longer alpha A2. Conversely, the same cells injected into nude mice synthesized alpha B and alpha A, but no beta-crystallin could be detected. 3. The ratio of non-crystallin proteins to crystallin polypeptides increased drastically with the number of cell divisions. Among these proteins, both Mr 45 000 and Mr 57 000 proteins are probably constituents of the water-soluble cytoskeletal proteins, respectively actin and vimentin. A Mr 17 000 polypeptide was observed and its relationship with a metabolic product of alpha-crystallin is proposed. 4. The polymerization process of crystallin polypeptides in these cells was studied and compared with crystallin aggregates found in the lens. Newly synthesized alpha crystallins were readily involved in high molecular aggregates. This process does not seem to require alpha A, since only alpha B was detected. Interestingly, non-crystallin-soluble proteins form the bulk of proteins found in high molecular weight (HMW) polymers. The time course of crystallin aggregate formation, in long-term culture cells, seems to be different for alpha- vs beta-polypeptides. These results allowed us to conclude that bovine epithelial lens cells in vitro, although they do not undergo terminal differentiation into fibers, are not dedifferentiated, since they still express specific features of the epithelium in situ.     

Deletion mutation in an eye lens beta-crystallin. An animal model for inherited cataracts.

The most prevalent proteins in the lens of the eye are called crystallins, and it is thought that aberrant crystallins may cause opacification of lens tissue. The Philly mouse, a strain with an inherited cataract, has an abnormal beta B2-crystallin, the principal beta-crystallin in the mouse. The cDNA that codes for the beta B2-crystallin protein has been cloned and sequenced from both the normal and the cataractous Philly mouse. The normal mouse beta B2 cDNA is 756 nucleotides in length with 618 nucleotides of open reading frame. An in-frame deletion of 12 nucleotides has occurred in the Philly mouse cDNA, which results in the loss of 4 amino acids. The sequence of the mutant beta B2 was analyzed against the reported structure of the normal bovine beta B2-crystallin determined by x-ray crystallography. The region, in which the deletion of the amino acids occurs near the COOH terminus, is essential for the formation of the tertiary structure of the beta B2-crystallin. The loss of these residues could explain the alterations that are seen with the Philly beta B2 protein and may account for the instability of the Philly beta B2 protein. This abnormal beta B2-crystallin may be the cause of the cataract in this animal.