Biochemical characterization of crystallins from frog lenses

Lens crystallins were isolated from the homogenate of frog (Rana catesbeiana) eye lenses by gel permeation chromatography and characterized by gel electrophoresis, amino acid analysis and circular dichroism. Four well-defined fractions corresponding to alpha/beta-, beta-, frog 39.5 kDa and gamma-crystallins comprising the relative weight percentages in the total soluble cytoplasmic proteins of 18%, 15%, 14% and 48% respectively were obtained. The native molecular masses for each purified fraction were determined to be 432, 207, 40 and 23 kDa, respectively. The polypeptide compositions as determined by SDS-gel electrophoresis revealed the typical subunit structures of mammalian crystallins with the exception of 39.5 kDa monomeric crystallin, which has not been shown in other classes of vertebrate lenses. The spectra of circular dichroism indicate a predominant beta-sheet structure in all four fractions, which also bears a resemblance to the secondary structure of mammalian crystallins. Comparison of the amino acid compositions of frog crystallins with those of mammalian and fish crystallins suggests that gamma-crystallin from the frog is more closely related to that of porcine than fish crystallins, and the frog 39.5 kDa, frog beta- and lamprey 48 kDa crystallins are probably mutually interrelated.     

Sequence comparison of gamma-crystallins from the reptilian and other vertebrate species

Lens crystallins were isolated from homogenates of reptilian eye lenses (Caiman crocodylus apaporiensis) by gel-permeation chromatography and characterized by gel electrophoresis, and amino acid and N-terminal sequence analyses. Four fractions corresponding to alpha-, delta/epsilon/beta-, beta- and gamma-crystallins were identified on the basis of their electrophoretic patterns as revealed by SDS gel electrophoresis. Comparison of the amino acid contents of reptilian crystallins with those of mammals suggests that each orthologous class of crystallins from the evolutionarily distant species still exhibits similarity in their amino acid compositions and probably sequence homology as well. All fractions except that of gamma-crystallin were found to be N-terminally blocked. N-terminal sequence analysis of the purified gamma-crystallin subfractions showed extensive homology between the reptilian gamma-crystallin polypeptides themselves and also those from other vertebrate species, suggesting the existence of a multigene family and their close relatedness to gamma-crystallins of other vertebrates.     

Comparison of the gamma-crystallins isolated from eye lenses of shark and carp. Unique secondary and tertiary structure of shark gamma-crystallin

gamma-Crystallin isolated from the shark of cartilaginous fishes was compared with the cognate gamma-crystallin from the carp of bony fishes. Distinct differences in amino acid compositions, primary, secondary and tertiary structures were found. The most salient features of shark gamma-crystallin lie in the fact that this crystallin possessed a significant alpha-helical structure in the peptide backbone as revealed by circular dichroism study, in contrast to those orthologous gamma-crystallins from other vertebrate species including bony fishes which all show a predominant beta-sheet secondary structure. The tertiary structure as reflected in the intrinsic microenvironments of various aromatic amino acids in the native crystallins also shows unambiguous differences between these two classes of gamma-crystallins. N-Terminal sequence analysis corroborates the structural differences between shark and carp gamma-crystallins. gamma-Crystallin from the more primitive shark seems to be more in line with the main evolutionary phylogeny leading to the modern mammalian gamma-crystallin.     

Characterization of lens crystallins and their mRNA from the carp lenses

Crystallins from carp eye lenses have been isolated and characterized by gel permeation chromatography, SDS-gel electrophoresis, immunodiffusion and amino acid analysis. gamma-Crystallin is the most abundant class of crystallins and constitutes over 55% of the total lens cytoplasmic proteins. It is immunologically distinct from the alpha- and beta-crystallins isolated from the same lens and its antiserum shows a very weak cross-reaction to total pig lens antigens. Comparison of the amino acid compositions of carp gamma-crystallin with those of bovine gamma-II, haddock gamma- and squid crystallins indicates that gamma-crystallin from the carp is very closely related to that of the haddock, and probably also related to the invertebrate squid crystallin. In vitro translation of total mRNAs isolated from carp lenses confirms the predominant existence of gamma-crystallin. The genomic characterization of carp crystallin genes should provide some insight into the mechanism of crystallin evolution in general.     

N-terminal sequences of gamma-crystallins from the amphibian lens and their homology with gamma-crystallins of other major classes of vertebrates

gamma-Crystallins were isolated from the homogenate of frog eye lenses (Rana catesbeiana) by exclusion gel chromatography and further purified by cation-exchange chromatography. They were the only group of crystallins possessing free amino groups amenable to sequence analysis by Edman degradation. Comparison of the amino acid contents of the purified subfractions of gamma-crystallins indicated their close relatedness in amino acid compositions and probably sequence homology as well. The amino-terminal sequence analysis of the purified gamma-crystallin subfractions showed extensive homology between these amphibian gamma-crystallin polypeptides themselves and also those from other vertebrate species, suggesting the existence of a multigene family and their close relatedness to gamma-crystallins of other vertebrates. The sequence comparison of the gamma-crystallin polypeptides from all major classes of vertebrates has provided strong support for the divergent evolution of gamma-crystallin family.     

Bovine lens crystallins do contain helical structure: a circular dichroism study.

In order to settle a recent discussion on the secondary structure of lens crystallins, we have measured the circular dichroism (CD) spectra of alpha-, beta(H)-, and beta(L)-crystallin from 178 to 250 nm and of gamma-crystallin from 168 to 250 nm. The results were analysed by means of a newly developed algorithm that almost doubles the reliability of secondary structure prediction and that allows discrimination between alpha- and 3(10)-helical, and between extended and polyproline beta-type structure. The results indicate that the crystallins studied contain a non-negligible amount of alpha-helical structure, although at least 50% of it is in the form of single and/or distorted loops. In alpha-crystallin, which is related to the chaperones, the helical content is lower than in beta- and gamma-crystallin. In some cases, the helices may play a role in DNA binding by the crystallins.     

Spectroscopic studies on human lens crystallins

Human lens crystallins were studied by absorption, circular dichroism and fluorescence spectroscopy. The absorption spectra in the near-ultraviolet region show some differences in intensity, but spectral features are similar, except for the alpha-crystallin, which gives a fine structure due to phenylalanine between 250 and 270 nm. Tryptophan fluorescence and near-ultraviolet circular dichroism indicate that tryptophan residues are more exposed in alpha-crystallin than in either beta- or gamma-crystallin, and that the degree of exposure decreases in the order of alpha less than beta 1 greater than beta 2 greater than beta 3 greater than gamma. The far ultraviolet CD suggests that these proteins exist mainly in a beta-sheet conformation and that the amount does not vary much among them. The greater exposure of the tryptophan residues in the high-molecular-weight crystallins may reflect greater unfolding in their protein domains. Spectroscopic measurements are thus useful in predicting protein tertiary structure in the absence of the complete sequence and X-ray data. The fact that the high-molecular-weight proteins exist in a more unfolded state may render them more vulnerable to exogeneous insults, and these effects may be studied by spectroscopic measurements.     

A differential scanning calorimetric study of the bovine lens crystallins

Differential scanning calorimetry was performed on the five major lens crystallin fractions [HM-alpha, alpha, beta H, beta L, and (beta s + gamma)] of the bovine lens as well as on more purified forms of alpha- and gamma-crystallins. All were found to be relatively thermally stable although the alpha-crystallin were found to at least partially unfold at an approximately 10 degrees C lower temperature than the beta and gamma fractions. Increasing protein concentration had little effect on gamma-crystallin thermograms but had marked effects on those of the alpha- and beta-crystallins. Increases in the thermal stability with increasing protein concentration for the beta-crystallins can be explained most simply by the known beta L/beta H equilibrium, but, in the case of the alpha-crystallins, excluded volume effects may be an important factor. In both cases, the increased stability at high concentrations could be of physiological relevance. As well as the expected endothermic unfolding transitions, all of the lens crystallins revealed exothermic peaks that correlate with protein precipitation. Interestingly, this phenomenon occurs only after extensive structural alteration in the case of the alpha-crystallins but is present very early in the initial stages of structural perturbation of the beta- and gamma-crystallins.     

Rat lens gamma-crystallins. Characterization of the six gene products and their spatial and temporal distribution resulting from differential synthesis

We have isolated, purified and characterized six individual gamma-crystallin polypeptides present in the rat lens. Comparison of their amino acid compositions with the known structure of the six gamma-crystallin genes permits a one-to-one correspondence to be made between each protein synthesized and the encoding gene. This demonstrates that each of the six genes is actually expressed in vivo. Two classes of three gamma-crystallins each, which we have designated classes gamma ABC and gamma DEF, are known to exist, on the basis of internal sequence homology. We have measured the temperature-dependent phase-separation characteristics of solutions of the six purified gamma-crystallins, and find that the three members of the gamma DEF class (gamma 2-2, gamma 3-1 and gamma 4-1) are all cryo-proteins with relatively high phase-separation temperatures, whereas the three gamma ABC crystallins (gamma 1-1, gamma 1-2 and gamma 2-1) do not show phase separation above -7 degrees C. We have measured the spatial distribution in rat lens of each of the alpha-, beta- and gamma-crystallins as a function of age from 1 to 420 days, using size-exclusion and ion-exchange high-pressure liquid chromatography (HPLC). Our findings in the cortical layer permit us to establish the differential synthesis of each of the crystallins during lens development. Particular attention has been devoted to the spatial and temporal distribution of the six individual gamma-crystallins. Up to birth, synthesis of the three components of the gamma DEF class predominates, and in particular that of gamma 2-2. In subsequent development the three components of the gamma ABC class assume a greater proportion of monomeric crystallins synthesized, while beta s-crystallin synthesis predominates in late development. Our analysis of different layers within single lenses provides novel information on spatial gradients of the water-soluble and water-insoluble protein fractions as a function of age. We consider the consequences of these findings for lens transparency and opacity in both rat and mouse lens. We show that the high concentrations of gamma DEF-crystallins appear to be responsible for the opacity known to occur in young rat lenses. We conclude from these observations that close control of the differential synthesis of gamma-crystallins plays an important role in maintaining lens transparency during development.     

Structure and stability of gamma-crystallins. I. Spectroscopic evaluation of secondary and tertiary structure in solution

The three major bovine gamma-crystallin fractions (gamma-II, gamma-III and gamma-IV) are known to have closely related (80-90%) amino acid sequences and three-dimensional folding of the polypeptide backbone. Their chiroptical and emission properties, as measured by circular dichroism (CD) and fluorescence, are now shown to differ distinctly. The far-ultraviolet CD spectra indicate that all three gamma-crystallins have predominantly beta-sheet conformation (45-60%) with only subtle differences in secondary structure. The fluorescence emission maxima of gamma-II, gamma-III and gamma-IV, due to the four tryptophan residues, appear at 324, 329 and 334 nm, respectively, suggesting that tryptophan residues are buried in environments of decreasing hydrophobicity. Corresponding differences in quantum yield may be due to fluorescence quenching by neighboring sulfur-containing residues. Titratable tyrosines are maximal for gamma-III, as manifested from difference absorption spectra at alkaline pH. The near-ultraviolet CD spectra differ in position, magnitude and sign of tryptophan and tyrosine transitions. In addition, a characteristic CD maximum at 235 nm, presumably due to tyrosine-tyrosine exciton interactions, differs in magnitude for each gamma-crystallin. This study shows that the environment and interactions of the aromatic residues of the individual gamma-crystallin fractions are quite different. These variations in tertiary structure may be significant, in terms of stability of gamma-crystallins towards aggregation and denaturation, for understanding lens transparency and cataract formation in general.     

Isolation and physical characterization of bovine lens crystallins.

The soluble proteins from bovine lens homogenate were separated on Sepharose CL-6B (2 X 200 cm) in 0.05 M tris-NaHSO3 pH 8.2 buffer containing 20 mM EDTA. Five sharp and defined fractions (HM alpha, alpha, beta H, beta L, gamma) were obtained. Each crystallin fraction was further purified by rechromatography on the same column. Each protein fraction was pure as judged by ultracentrifugation and SDS-gel electrophoresis. The molecular weights of the five fractions were 3.04 x 10(6), 5.83 x 10(5), 1.58 x 10(5) , 4.59 x 10(4), 2.14 x 10(4) as determined from sedimentation coefficient and intrinsic viscosity data by Scheraga-Mandelkern equation, which was in close agreement with that obtained by gel filtration. The polypeptide composition of crystallins as determined by SDS-gel electrophoresis revealed one band for high molecular weight alpha (HM alpha) and alpha, three for beta H, two for beta L and one for gamma. The gross CD patterns of crystallins were about the same in the peptide region (200 nm similar to or approximately 250 nm) with a minimum centered at about 217 nm, indicative of a beta-sheet structure in all crystallins. The [theta] values at 217 nm ranged from --1700 to --3700 degrees cm2 per decimole. The CD spectra of these crystallins in the aromatic region (250 nm similar to or approximately 300 nm) were different, reflecting the different contributions of aromatic amino acids to the tertiary structure of crystallins.     

Structure and stability of gamma-crystallins. Denaturation and proteolysis behavior

The denaturation behavior of bovine lens gamma-crystallin fractions II, III, and IV and their susceptibility to proteolysis in vitro was compared to determine whether differences in their stability could play a role in cataract formation. Tertiary and secondary structure changes induced by increasing concentrations of urea, guanidine hydrochloride, and sodium dodecyl sulfate and by increasingly alkaline pH were followed by near-UV and far-UV circular dichroism, Trp fluorescence emission, and exposure of sulfhydryl groups. Major differences were found in the denaturation and proteolysis behavior of the three gamma-crystallin fractions. In general, the unfolding of gamma-II and gamma-III crystallins is rather gradual, suggesting the presence of intermediate unfolding states; in contrast, the order-disorder transition of gamma-IV crystallin is abrupt. The gamma-IV crystallin fraction is the most stable in urea and guanidine hydrochloride, but is most susceptible to nonspecific proteolysis and alkaline pH denaturation. Differences in denaturation and proteolysis behavior are attributed to the inherent differences in the tertiary structures of these crystallins.     

Physicochemical characterization of high-molecular-weight alpha-crystallin subpopulations from the calf lens nucleus

Calf lens nuclear alpha-crystallin was separated into five molecular weight subpopulations by exclusion chromatography on Bio-Gel A-5m. These subpopulations were compared by amino acid analysis, ultraviolet absorption analysis, fluorescence, far- and near-ultraviolet circular dichroism, isoelectric focusing, SDS-polyacrylamide gel electrophoresis and sedimentation velocity analysis. Although only minor differences were detectable in most physicochemical properties, progressive changes were found in the near-ultraviolet circular dichroism spectra and in pellet hardness after centrifugation. Minute amounts of beta-crystallin polypeptides and a 43 kDa component were present in all five subpopulations. In addition, the highest molecular weight aggregates contain some gamma-crystallin polypeptides. A slow re-equilibration of separated subpopulations towards the initial distribution was observed by rechromatography.     

A novel crystallin from octopus lens

Lens crystallins were isolated from cephalopods, octopus and squid. Two protein fractions were obtained from the octopus in contrast to only one crystallin from the squid. The native molecular mass for these purified fractions and their polypeptide compositions were determined by gel filtration, sedimentation analysis, and SDS-gel electrophoresis. Octopod and decapod lenses share one common major squid-type crystallin of 29 kDa, with one additional novel crystallin present only in the octopus lens. This newly-characterized crystallin (termed omega-crystallin) exists as a tetrameric protein of 230 kDa, consisting of 4 identical subunits of approx. 59 kDa. It is distinct from the previously known crystallins both in amino acid composition and subunit structure. N-terminal sequence analysis indicated that the omega-crystallin is N-terminally blocked, whereas the major octopus crystallin is identical to the reported squid crystallin with regard to the first 25 residues of protein sequence. Sequence similarity between this major cephalopod crystallin and glutathione S-transferase were found, which suggested some enzymatic role of crystallins inside the cephalopod lens.     

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.     

Domain swapping in human alpha A and alpha B crystallins affects oligomerization and enhances chaperone-like activity

alphaA and alphaB crystallins, members of the small heat shock protein family, prevent aggregation of proteins by their chaperone-like activity. These two proteins, although very homologous, particularly in the C-terminal region, which contains the highly conserved "alpha-crystallin domain," show differences in their protective ability toward aggregation-prone target proteins. In order to investigate the differences between alphaA and alphaB crystallins, we engineered two chimeric proteins, alphaANBC and alphaBNAC, by swapping the N-terminal domains of alphaA and alphaB crystallins. The chimeras were cloned and expressed in Escherichia coli. The purified recombinant wild-type and chimeric proteins were characterized by fluorescence and circular dichroism spectroscopy and gel permeation chromatography to study the changes in secondary, tertiary, and quaternary structure. Circular dichroism studies show structural changes in the chimeric proteins. alphaBNAC binds more 8-anilinonaphthalene-1-sulfonic acid than the alphaANBC and the wild-type proteins, indicating increased accessible hydrophobic regions. The oligomeric state of alphaANBC is comparable to wild-type alphaB homoaggregate. However, there is a large increase in the oligomer size of the alphaBNAC chimera. Interestingly, swapping domains results in complete loss of chaperone-like activity of alphaANBC, whereas alphaBNAC shows severalfold increase in its protective ability. Our findings show the importance of the N- and C-terminal domains of alphaA and alphaB crystallins in subunit oligomerization and chaperone-like activity. Domain swapping results in an engineered protein with significantly enhanced chaperone-like activity.     

Ubiquitous lens alpha-, beta-, and gamma-crystallins accumulate in anuran cornea as corneal crystallins

Corneal epithelium is known to have high levels of some metabolic enzymes such as aldehyde dehydrogenase in mammals, gelsolin in zebrafish, and alpha-enolase in several species. Analogous to lens crystallins, these enzymes and proteins are referred to as corneal crystallins, although their precise function is not established in any species. Although it is known that after lentectomy, the outer cornea undergoes transdifferentiation to regenerate a lens only in anuran amphibians, major proteins expressed in an anuran cornea have not been identified. This study therefore aimed to identify the major corneal proteins in the Indian toad (Bufo melanostictus) and the Indian frog (Rana tigrina). Soluble proteins of toad and frog corneas were resolved on two-dimensional gels and identified by matrix-assisted laser desorption ionization time-of-flight/time-of-flight and electrospray ionization quadrupole time-of-flight. We report that anuran cornea is made up of the full complement of ubiquitous lens alpha-, beta-, and gamma-crystallins, mainly localized in the corneal epithelium. In addition, some taxon-specific lens crystallins and novel proteins, such as alpha- or beta-enolase/tau-crystallin, were also identified. Our data present a unique case of the anuran cornea where the same crystallins are used in the lens and in the cornea, thus supporting the earlier idea that crystallins are essential for the visual functions of the cornea as they perform for the lens. High levels of lens alpha-, beta-, and gamma-crystallins have not been reported in the cornea of any species studied so far and may offer a possible explanation for their inability to regenerate a lens after lentectomy. Our data that anuran cornea has an abundant quantity of almost all the lens crystallins are consistent with its ability to form a lens, and this connection is worthy of further studies.     

Structural and functional consequences of the mutation of a conserved arginine residue in alphaA and alphaB crystallins.

A point mutation of a highly conserved arginine residue in alphaA and alphaB crystallins was shown to cause autosomal dominant congenital cataract and desmin-related myopathy, respectively, in humans. To study the structural and functional consequences of this mutation, human alphaA and alphaB crystallin genes were cloned and the conserved arginine residue (Arg-116 in alphaA crystallin and Arg-120 in alphaB crystallin) mutated to Cys and Gly, respectively, by site-directed mutagenesis. The recombinant wild-type and mutant proteins were expressed in Escherichia coli and purified. The mutant and wild-type proteins were characterized by SDS-polyacrylamide gel electrophoresis, Western immunoblotting, gel permeation chromatography, fluorescence, and circular dichroism spectroscopy. Biophysical studies reveal significant differences between the wild-type and mutant proteins. The chaperone-like activity was studied by analyzing the ability of the recombinant proteins to prevent dithiothreitol-induced aggregation of insulin. The mutations R116C in alphaA crystallin and R120G in alphaB crystallin reduce the chaperone-like activity of these proteins significantly. Near UV circular dichroism and intrinsic fluorescence spectra indicate a change in tertiary structure of the mutants. Far UV circular dichroism spectra suggest altered packing of the secondary structural elements. Gel permeation chromatography reveals polydispersity for both of the mutant proteins. An appreciable increase in the molecular mass of the mutant alphaA crystallin is also observed. However, the change in oligomer size of the alphaB mutant is less significant. These results suggest that the conserved arginine of the alpha-crystallin domain of the small heat shock proteins is essential for their structural integrity and subsequent in vivo function.     

Homology models of human gamma-crystallins: structural study of the extensive charge network in gamma-crystallins

The lens is composed of highly stable and long-lived proteins, the crystallins which are divided into alpha-, beta-, and gamma-crystallins. Human gamma-crystallins belong to the betagamma superfamily. A large number of gamma-crystallins have been sequenced and have been found to share remarkable sequence homology with each other. Some of the gamma-crystallins from various sources have also been elucidated structurally by X-ray crystallographic or NMR spectroscopic experiments. Their three-dimensional structures are also similar having consisted of two domains each possessing two Greek key motifs. In this study we have constructed the comparative or homology models of the four major human gamma-crystallins, gammaA-,gammaB-, gammaC-, and gammaD-crystallins and studied the charge network in these crystallins. Despite an overall structural similarity between these crystallins, differences in the ion pair formation do exist which is partly due to the differences in their primary sequence and partly due to the structural orientation of the neighboring amino acids. In this study, we present an elaborate analysis of these charged interactions and their formation or loss with respect to the structural changes.     

Gamma-crystallin genes in carp: cloning and characterization.

The carp gamma-crystallin gene family was found to be composed of at least three members: gamma m1, gamma m2 and gamma m3. The encoded products are very similar to other known gamma-crystallins but with their own peculiarities: (1) they all have a high methionine content: 12.4%, 14% and 8.4% in gamma m1, gamma m2 and gamma m3, respectively; and (2) the amino acid sequences are aberrant in the region before connecting peptides and its corresponding region in motif 4. Their protein structures might remain the same as those of other gamma-crystallins since they retain all the conserved amino acid residues essential for maintaining the loops in the protein structures.