Embryonic Appearance of α, β, and γ Crystallins in the Periodic Albinism (ap) Mutant of Xenopus laevis

The appearance of the crystallins during lens development in the periodic albinism (a^p/a^p) mutant of Xenopus laevis has been studied. Using antibodies specific for total crystallins, α+β crystallins, and γ crystallins in the immunofluorescence technique, the first positive reaction for all could be demonstrated in the Nieuwkoop-Faber Stage 31 lens rudiment. The antibody to α+β crystallins exhibited differences in intensity from cell to cell in the early rudiment, while the reaction to the other antibodies was uniform throughout the rudiment. As lens differentiation progressed, immunofluorescence was restricted in all cases to the lens fiber area, up to and including Nieuwkoop-Faber Stage 45. The lens epithelium of the one-year-old adult a^p/a^p was positive, however, for total lens crystallins.
These results are at variance with earlier studies on lens development and the crystallins in wild-type (+/+) X. laevis , where a positive reaction for y and total crystallins could be detected earlier, and in the lens epithelium of Nieuwkoop-Faber Stage 41 embryos for total lens crystallins. That this divergence in the mutant is due to a pleiotropic effect or directly to the inductive failure of the endomesoderm to initiate melanogenesis, is discussed.     

Immunochemical study of the water-soluble lens proteins in the embryo of Xenopus laevis with the mutation of periodic albinism]

The crystallins of ap mutants of Xenopus laevis have been studied in comparison with those of normal embryos and adults using the complex of immunochemical methods (immunoelectrophoresis, immunodiffusion, immunoadsorption, immunofluorescence, isoelectrofocusing with immunoidentification). The analysis was carried out with antisera to electrophoretic fractions of the mutant lens. 11 organ-specific antigens were found in the lens of both the normal and mutant animals. These proteins are heterogenous by electrophoretic mobility, isoelectrical point, antigenic and species specificity. Each class of crystallins contains antigens which are specific: a) for amphibians only, b) for lower vertebrates, c) for vertebrates in general. No qualitative differences were found between crystallins of the normal and mutant animals. Immunofluorescence analysis has shown that crystalins appear in the normal and mutant embryos practically at the same time. No significant differences in the appearance of specific immunofluorescence between the normal and mutant embryos were found (with various antisera). gamma-crystallins and, perhaps, a part of the primary lens fibers. Alpha-crystallins appear later. gamma-crystallins are first identified the synthesis of which manifests itself at the advanced developmental stages. The quantitative predominance of some beta--gamma-crystallins in the mutant lens detected by us (electrophoresis, isoelectrofocusing) is not related to their earlier synthesis in the embryogenesis.     

The appearance of alpha-crystallin in relation to cell cycle phase in the embryonic mouse lens

Specific protein synthesis in the embryonic mouse lens was studied by immunofluorescence with antisera to adult mouse lens or crystallin fractions. Positive reactions were first detected in a few cells of the lens cup 18-24 hr after contact between optic vesicle and presumptive lens ectoderm had been established. During formation of the lens vesicle a rapidly increasing fraction of cells produced crystallins. At the time of detachment of the vesicle from the surface all cells of its posterior wall showed immunofluorescence. After fiber elongation became distinct cells of the anterior epithelium began to fluoresce and shortly afterwards the entire rudiment produced crystallins. The early reactions were due entirely to the presence of alpha-crystallin. Reactions were restricted to the lens. Thus, in the mouse as in other species crystallins were detectable by immunofluorescence in vivo only after lens morphogenesis was well underway and only in the lens rudiment itself. Cells first synthesizing crystallins always had an elongated shape and their nuclei were in a basal position. A few hours later mitotic cells displayed fluorescence. Taking into account earlier found relations between cell morphology and cell cycle phase, this indicates that alpha-crystallin is first demonstrable in the S-or early G-2 phase of the cell cycle, and that the start of its synthesis does not preclude continued cell replication. It is interesting that the cellular location, cell cycle phase, and developmental stage, in which crystallins first appear, are comparable in mouse and chick embryo. Yet, entirely different proteins are involved: alpha-crystallin in the first, delta-crystallin in the latter. Implications of this for our understanding of lens induction are discussed.     

The appearance of α, β and γ crystallins in an anophthalmic strain of mice

Abstract. A certain percentage of congenitally anophthalmic mouse embryos have the ability to generate small lens vesicles that have previously been shown to produce alpha crystallin at 13-day gestation. Further immunohistological analysis of 13- and 15-day-gestation anophthalmia embryos indicates that beta crystallin is present in those 13-day embryos which have lens vesicles with lens-fiber formation. Also, 15-day embryos with lenses demonstrating fiber elongation can produce both beta and gamma crystallins. The conclusion is drawn that the genetic potential to produce at least three characteristic biochemical markers of normal lens differentiation is present in the anophthalmia mutant. The spatial distribution patterns of the crystallins in normal and anophthalmia embryos were similar. However, there appeared to be a transposition in the temporal appearance of beta and gamma crystallins in the anophthalmia mutant. Optic cups and associated lenses in 15-day anophthalmia specimens were much smaller than those in controls. The optic and lens rudiments in these anophthalmia embryos were fairly proportional in size, which indicates that some degree of allometric growth compensation had occurred during the course of development. This ability for differential growth compensation in the mouse eye appears to be restricted to the predifferentiative stages of eye formation.     

Immunofluorescent studies on aphakia,a mutation of a gene involved in the control of lens differentiation in the mouse embryo

Aphakia, an autosomal recessive single gene mutation in the mouse, seriously affects the development of the ocular lens. Up to advanced stages of lens invagination morphogenesis proceeds normally. In the late lens cup and early lens vesicle stage, however, the epithelium of the lens rudiment becomes disorganized and the lumen of the vesicle fills up with rounded cells, apparently released from the epithelium. The lens stalk persists frequently. Probably as a consequence of the aphakic state other parts of the eye secondarily become abnormal.Immunofluorescent studies were done on embryonic normal and aphakia eyes with antisera against adult mouse crystallins. In the normal embryo the first positive reactions were found in the late lens cup stage ($\text{10}\text{3}\text{4}\text{–11}$ days of gestation). By Day 12 all cells of the lens vesicle were brightly fluorescent. A day later the cells of the posterior wall, now lens fibers, had elongated sufficiently to obliterate the lumen of the vesicle. The entire organ was highly fluorescent, indicating that all of its cells contained large amounts of crystallins. The mutant lens, studied over the same time span, showed no reaction at all. The most likely explanation is, that the multiple structural genes, which normally must be involved in the production of the crystallins, are not expressed up to this time in the mutant.The combination of morphological and biochemical defects suggests that the gene involved in the mutation somehow functions in the control of lens differentiation.     

Crystallins in Retinal Ganglion Cell Survival and Regeneration

Crystallins are heterogeneous proteins classified into alpha, beta, and gamma families. Although crystallins were first identified as the major structural components of the ocular lens with a principal function to maintain lens transparency, further studies have demonstrated the expression of these proteins in a wide variety of tissues and cell types. Alpha crystallins (alpha A and alpha B) share significant homology with small heat shock proteins and have chaperone-like properties, including the ability to bind and prevent the precipitation of denatured proteins and to increase cellular resistance to stress-induced apoptosis. Stress-induced upregulation of crystallin expression is a commonly observed phenomenon and viewed as a cellular response mechanism against environmental and metabolic insults. However, several studies reported downregulation of crystallin gene expression in various models of glaucomatous nerodegeneration suggesting that that the decreased levels of crystallins may affect the survival properties of retinal ganglion cells (RGCs) and thus, be associated with their degeneration. This hypothesis was corroborated by increased survival of axotomized RGCs in retinas overexpressing alpha A or alpha B crystallins. In addition to RGC protective functions of alpha crystallins, beta and gamma crystallins were implicated in RGC axonal regeneration. These findings demonstrate the importance of crystallin genes in RGC survival and regeneration and further in-depth studies are necessary to better understand the mechanisms underlying the functions of these proteins in healthy RGCs as well as during glaucomatous neurodegeneration, which in turn could help in designing new therapeutic strategies to preserve or regenerate these cells.     

Immunochemical markers of embryonic lens differentiation in Rana temporaria. I. Composition and properties of water-soluble lens antigens]

Antisera were obtained to the total extract and individual electrophoretic fractions of lens proteins: alpha-, beta-, gamma1- and gamma2-crystallins. The crystallins under study are immunochemically heterogenous: each class of lens proteins contains 2--4 antigens. Using the indirect method of fluorescent antibodies, it was established that the appearance of crystallins during development coincided with the onset of formation of the presumptive lens fibers. No crystallins were found in the lens placode and early lens vesicle. gamma-Crystallins appear later than the other lens proteins and are characteristic, mainly, for the lens fibers; at the advanced stages of organogenesis gamma-crystallins are regularly found in the epithelial cells of the developing lens as well.     

T cell differentiation model based on the expression of T cell receptor chains and genes--study in the human leukemia/lymphoma cell lines

A total of 33 human leukemia/lymphoma cell lines were classified into 4 groups with respect to the pattern of cell membrane (sm) expression of the CD3 and T cell receptor (TCR) molecules; (i) smCD3+TCR alpha beta (16 cell lines), (ii) smCD3+TCR beta delta (1 cell line), (iii) smCD3+TCR gamma delta (3 cell lines) amd (iv) smCD3-TCR- (13 cell lines), respectively. Using monoclonal antibodies (MoAbs) specific to CD3 (NU-T3), TCR alpha chain (alpha F1), TCR beta chain (beta F1), and TCR gamma chain (C gamma M1), respectively, cytoplasmic (cy) expression of these molecules was determined by immunofluorescence test. Expression of cyCD3 was present in all cell lines regardless of groups. In group (i), all 16 cell lines expressed both TCR alpha and beta chains. While only TCR beta chain was expressed in group (ii), TCR gamma chain was expressed in all 3 cell lines of group (iii). One (PEER) of the three in group (iii) expressed TCR beta chain as well. In group (iv), we found 8 cell lines with cyTCR alpha expression, 11 cell lines with cyTCR beta expression, and 10 cell lines with cyTCR gamma expression, respectively. For TCR genes, except 1 cell line all cell lines were found to present rearranged C beta gene and its mRNA, including all 3 TCR gamma/delta cell lines of group (iii). One of the TCR alpha beta cell lines exhibited rearranged C delta and J delta genes as well as its mRNA. Two cell lines of the 13 CD3-TCR- of group (iv) exhibited rearranged C delta and J delta and its mRNA. An NK-like activity and IL-2 production were induced in the TCR beta delta and gamma delta cell lines [group (ii) and (iii)] by treatment with PHA and PMA.     

Epidermal fucosylation of cell surface glycoprotein

The formation of covalently linked, high molecular weight protein aggregates has been thought to play an important role in opacification of the human lens. Antisera were used in Western blot analysis to demonstrate the involvement of all major classes of lens proteins (alpha, beta and gamma crystallin; the major intrinsic membrane polypeptide) in covalent aggregation. Of these classes, aggregation of gamma and beta crystallins via intermolecular disulfide bonding and aggregation of the major intrinsic membrane polypeptide via intermolecular, non-disulfide bonding were more pronounced in cataractous as compared with normal lenses.     

Structural homology of lens crystallins. II. Homology expressed by correlation coefficients and hydropathy profiles

Bovine lens alpha A- and alpha B-crystallin polypeptides show extensive sequence homology with each other, but apparently none with beta Bp- and gamma 2-crystallin. Despite only 30% sequence homology, the latter two proteins are assumed to have a strong correspondence in tertiary structure, consisting of four structurally similar folding units of antiparallel beta-sheet. We have tested for internal structural repeats in all crystallins, and structural homology between crystallins, by comparing various physical properties of the amino acid residues, such as bulkiness and propensity to form beta-sheet and beta-turn structure. Two procedures used a combination of five physical parameters to calculate correlation coefficients. The 4-fold structural repeat in gamma 2-crystallin and the internal duplication in beta Bp-crystallin were readily detectable, as was also the strong structural homology between corresponding folding units in beta Bp- and gamma 2-crystallin. However, for alpha-crystallin polypeptides, no conclusive support was obtained for either a four-unit or a six-unit folding, the two models previously considered by us. The third procedure compared smoothened hydropathy plots, representing hydrophilic and hydrophobic regions along the polypeptide sequences. Hydropathy profiles were found to show strong correspondence, particularly between alpha B-crystallin and beta Bp-crystallin. These observations support a similar 4-fold folding pattern for all bovine crystallins. A possible role in subunit interactions of the N-terminal folding unit, which has hydrophobic surface characteristics in both alpha- and beta-crystallin polypeptides, is proposed.     

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.     

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.     

Crystallins during Xenopus laevis free lens formation

Summary The ontogeny and localization of crystallins during free lens development (i.e. lens development without the optic vesicle) were investigated in Xenopus laevis using the indirect immunofluorescence staining method with an antiserum raised against homologous total lens soluble proteins. Since the developing free lenses pass through stages similar to those of the lenses regenerated from the inner cell layer of the outer cornea following lentectomy in the same species Freeman's classification was used to identify the stages of free lens development. The first appearance of a positive reaction occurred at early stage IV in a number of cells in an area where future lens fibre cells would develop. With further differentiation of the free lens more and more cells in the fibre area started to show a positive reaction and the first positive reaction in the epithelium was observed late in stage V. Histological examination revealed that a fully differentiated free lens and a normally developed lens are similar but that the free lens is smaller.     

Evolution of crystallins: expression of lens-specific proteins in the blind mammals mole (Talpa europaea) and mole rat (Spalax ehrenbergi)

The mole (Talpa europaea; Insectivora) and the mole rat (Spalax ehrenbergi; Rodentia) both have degenerated eyes as a convergent adaptation to subterranean life. The rudimentary eye lenses of these blind mammals no longer function in a visual process. The crystallin genes, which display a lens-specific expression pattern, were studied in these blind mammals and in related species with normal eyes by hybridizing their genomic DNAs with probes obtained from cDNA clones for alpha A-, alpha B-, and beta Bp-crystallins from calf and gamma 3- crystallin from the rat. For all crystallin genes examined, the hybridization signals of mole and mole rat genomic DNA were comparable, respectively, with those of shrew and of rat and mouse, normal-vision representatives of the orders Insectivora and Rodentia. The expression of the crystallins at the protein level was tested by using antiserum specific for alpha-crystallin in immunofluorescence reactions on lens sections of mole and mole rat eyes and by using antisera against the beta- and gamma-crystallins on sections of the mole eye. All antisera gave positive fluorescence reactions exclusively with lens tissue of these blind mammals, indicating that the crystallins are still normally expressed despite the fact that these lenses have had no function in a visual process in these mammals for at least many million years. These findings apparently imply that some unknown selective advantage has conserved the crystallin genes and their expression after the loss of normal function of the lenses.      

Formation of a 55 000-weight cross-linked beta crystallin dimer in the Ca2+-treated lens. A model for cataract

Incubation of lens in Ca2+-containing media, considered by several investigators to be a useful model of cataract formation, gave rise to significant alterations in the covalent structures of various proteins. In rabbit lens, when sodium dodecyl sulfate-polyacrylamide gel electrophoresis was used after reduction of disulfides in urea, the most readily observable changes were (i) disappearance of 210K, 95K, and 60K proteins, (ii) modifications of alpha crystallin subunits, (iii) alterations of beta H crystallins, and (iv) de novo production of 55K and higher molecular weight polymers. The addition of leupeptin inhibited the disappearances of 210K, 95K, and 60K proteins and the alteration of alpha crystallins, suggesting that all these were caused by a Ca2+-activated protease. The proteolytically sensitive 60K species was identified as vimentin, a component of intermediate filaments. Formation of the 55K material and of higher molecular weight polymers during Ca2+ treatment of the lens could be prevented by histamine, a compound known to inhibit the transglutaminase-mediated cross-linking of proteins by epsilon-(gamma-glutamyl)lysine peptide bonds in other biological systems. It could also be shown by immunoblotting that an antibody raised against the 55K material reacted selectively with beta crystallins of normal lens. This indicates that the 55K product is in all likelihood an essential intermediate toward higher polymers and that the 55K product is a cross-linked dimer of certain polypeptides of beta crystallin.(ABSTRACT TRUNCATED AT 250 WORDS)     

In Vivo and in Vitro Experimental Analysis of Lens Regeneration in Larval Xenopus laevis

After lentectomy of larval Xenopus laevis , the outer cornea undergoes tissue transformation resulting in formation of a new lens. This lens regeneration is triggered and sustained by neural retina. In the present study, lens-forming transformation of the outer cornea was completed in vitro when the outer cornea was cultured within the lentectomized eye-cup. Well-differentiated lens fiber cells, which showed positive immunofluorescence for total crystallins, were also formed when the outer cornea was cultivated with the retina. No lens tissue was formed when the cornea was cultured alone. Lens-forming transformation, originating from the cornea three and five days after lentectomy, completely regressed when the tissue was isolated in vitro . Fom the present and previous findings, we concluded that, the interaction of corneal cells with the retina plays a decisive role in lens regeneration in situ .