Cellular heterogeneity in the expression of the delta-crystallin gene in non-lens tissue

The cellular and molecular bases of vertebrate lens regeneration

Lens regeneration takes place in some vertebrates through processes of cellular dedifferentiation and transdifferentiation, processes by which certain differentiated cell types can give rise to others. This review describes the principal forms of lens regeneration that occur in vivo as well as related in vitro systems of transdifferentiation. Classic experimental studies are reviewed that define the tissue interactions that trigger these events in vivo. Recent molecular analyses have begun to identify the genes associated with these processes. These latter studies generally reveal tremendous similarities between embryonic lens development and lens regeneration. Different models are proposed to describe basic molecular pathways that define the processes of lens regeneration and transdifferentiation. Finally, studies are discussed suggesting that fibroblast growth factors play key roles in supporting the process of lens regeneration. Retinoids, such as retinoic acid, may also play important roles in this process.

Up-regulation of crystallin mRNAs in form-deprived chick eyes

Form-deprivation of chicks during early postnatal development results in ocular enlargement and great myopic refractive error (form-deprivation myopia). Previous studies have indicated that the retina, RPE and choroid play important roles in ocular enlargement in form-deprivation myopia. We aimed to isolate genes up-regulated in the retina-RPE-choroid of form-deprived chick eyes. A suppression subtractive hybridization method was used to compare mRNA expression in the retina-RPE-choroid of form-deprived and control eyes. One up-regulated cDNA was isolated and identified as part of chick delta1-crystallin cDNA. Northern blot and RT-PCR analyses demonstrated that delta1-crystallin mRNA was up-regulated in the retina-RPE at day 7 after form-deprivation treatment. Semi-quantitative RT-PCE analysis of the expression of several transcription factors indicated that Sox1 and Sox3 were upregulated in parallel with delta1-crystallin mRNA in form-deprived eyes. Northern blot analysis demonstrated that alphaA-, betaA3/A1-, betaB1-, and betaB2-crystallin mRNAs were also up-regulated in form-deprived eyes. Although the detailed mechanisms and functions of the crystallin family genes in the retina-RPE-choroid of form-deprived eyes remain unclear, results of our study suggests that form-deprivation affects the expression of these genes in chick eyes.

Reliability of delta-crystallin as a marker for studies of chick lens induction

Induction of a lens by the optic vesicle of the brain was the first demonstration of how tissue interactions could influence cell fate during development. However, recent work with amphibians has shown that the optic vesicle is not the primary inducer of lens formation. Rather, an earlier interaction between anterior neural plate and presumptive lens ectoderm appears to direct lens formation. One problem with many early experiments was the absence of an unambiguous assay for lens formation. Before being able to test whether the revised model of lens induction applies to chicken embryos, we examined the suitability of using delta-crystallin as a marker of lens formation. Although delta-crystallin is the major protein synthesized in the chick lens, one or both of the two delta-crystallin genes found in chickens is transcribed in many non-lens tissues as well. In studies of lens formation where appearance of the delta-crystallin protein is used as a positive assay, synthesis of delta-crystallin outside of the lens could make experiments difficult to interpret. Therefore, polyacrylamide gel electrophoresis, immunoblotting, and immunofluorescence were used to determine whether the delta-crystallin messenger RNA detected in non-lens tissues is translated into protein, as it is in the lens. On Coomassie-blue-stained gels of several tissues from stage-22 embryos, a prominent protein was observed that co-migrated with delta-crystallin. However, on immunoblots, none of the nonlens tissues tested contained detectable levels of delta-crystallin at this stage. By imunofluorescence, delta-crystallin was observed in Rathke's pouch and in a large area of oral ectoderm near Rathke's pouch, yet none of the cells in these non-lens tissues showed the typical elongated morphology of lens fiber cells. When presumptive lens ectoderm or other regions of ectoderm from stage-10 embryos were cultured and tested for lens differentiation, both cell elongation and delta-crystallin synthesis were observed, or neither were observed. The results suggest that delta-crystallin synthesis and cell elongation together serve as useful criteria for assessing a positive lens response.

Evidence for the extralenticular expression of members of the beta-crystallin gene family in the chick and a comparison with delta-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.

Differential localization by in situ hybridization of specific crystallin transcripts during mouse lens development

The embryonic development of the mammalian lens is well known at the biochemical and histological level. However few data are available at the molecular level concerning gene expression during the continuous differentiation of the lens. In the present study, we have investigated by in situ hybridization the changes in the distribution of mouse crystallin mRNA as a marker of differentiated lens cells, during development of the lens primordium, when tissue interactions are known to be essential. The transcripts of alpha and beta crystallins are first detected at the early elongation stage of primary fibres; gamma-crystallin-transcripts do not appear until the late elongation phase. All areas of the lenses exhibited crystallin mRNA until the beginning of secondary fiber formation at 18 days of development. Hybridization for alpha and beta crystallin is confined at that time to the equatorial part of the lens. The gamma crystallin transcripts are no longer found in the equatorial region after 1 post-natal day, but remain in the lens core, decreasing gradually. A possible mechanism is discussed.

Delta-crystallin gene expression and patterns of hypomethylation demonstrate two levels of regulation for the delta-crystallin genes in embryonic chick tissues

In this study we address two questions regarding the control of delta-crystallin gene expression in chick embryos. First we have determined whether delta-crystallin mRNA is found outside of the developing lens, in which it is the predominant mRNA. We find that this mRNA can be detected, although at relatively low levels, in all embryonic tissues we have examined (from the definitive streak stage onward). This low level of transcription may be related to a second function for one or both of the delta-crystallin genes: both genes have a high degree of sequence identity to the enzyme argininosuccinate lyase. This result led us to a second set of experiments in which we reevaluated the possible role of hypomethylation in the expression of the delta-crystallin genes. Previous work showed that particular HhaI and HpaII sites in the crystallin genes undergo hypomethylation early in the process of lens differentiation when there is a burst of delta-crystallin mRNA accumulation. We not find that these sites remain methylated in nonlens tissues, implying that they cannot be required for the delta-crystallin gene activity found in these tissues. Other sites are constitutively hypomethylated, however, and may be functionally linked to this low level of gene activity. From an analysis of the kinetics of the developmentally regulated hypomethylation of HhaI and HpaII sites we also find that complete hypomethylation of these sites is not required for activating high levels of delta-crystallin transcription during lens differentiation. We do find, however, that these sites approach a fully hypomethylated state later in the lens differentiation process. Our analyses of mRNA levels and hypomethylation together lead us to propose that the delta-crystallin genes are regulated by two different mechanisms, one that leads to high levels of expression in the lens and the other which is responsible for low level expression in all other tissues in the chick embryo.

Independent regulation of two coexpressed delta-crystallin genes in chick lens and nonlens tissues

It is known that delta-crystallin is super-abundant in the early chick lens, but it is found at lower levels in certain other tissues. Ninety-nine percent of the lens delta-crystallin poly(A)+ RNA is from the delta 1-crystallin gene. We report here that the delta 1- and delta 2-crystallin genes are both transcribed in the chick lens and retina throughout embryonic development and that both RNAs are found in embryo adenohypophysis and epiphysis and in day-old posthatch chick tibiofemoral chondrocytes and striated muscle. delta 1-crystallin RNA is more abundant in lens tissues, while delta 2-crystallin RNA is more abundant in all nonlens tissues. However, delta 1-crystallin RNA is processed more efficiently than delta 2-crystallin RNA in all early embryonic tissues examined. A comparison of lens epithelium and fibers established that levels of delta 2-crystallin RNA are the same but those of delta 1-crystallin RNA are over 100-fold higher in fibers compared to epithelial cells. The evidence implies independent regulation both of transcription and of post-transcriptional events for these two genes.

Localization of acidic fibroblast growth factor (aFGF) mRNA in mouse and bovine retina by in situ hybridization

Acidic fibroblast growth factor (aFGF) mRNA has been detected in adult mouse or bovine retina by in situ hybridization with bovine aFGF cDNA clones. It is localized on ganglion cell layer, inner nuclear layer, photoreceptors and slightly on pigmented epithelium. This synthesis of aFGF in highly specialized retinal cell types is discussed in the framework on current views about the role of FGF in retinal cell biology.

Immunological studies on gamma crystallins from Xenopus: localization, tissue specificity and developmental expression of proteins

In an effort to understand the spatio-temporal regulation of crystallins and their genes during lens development, the gamma crystallins from the frog lens have been isolated, purified and characterized. Using an immunological approach, they were found to be localized exclusively in the lens fiber cells and were not detected in any other lens cells or non-lens tissues including mature oocytes. During embryogenesis, the antigens were first detected in stage 25 embryos (but not in stage 20 embryos). Their level first decreased and then increased during subsequent stages of development. A different member of the family was also found to be expressed during later stages of embryogenesis.

Evidence for positive and negative regulation in the promoter of the chicken delta 1-crystallin gene

We investigated the role of sequences flanking the transcription initiation site of the delta 1-crystallin gene in transient transfection assays of primary embryonic chicken lens epithelial cells or fibroblasts. Varying lengths of the 5' flanking sequence of the delta 1-crystallin gene (containing some untranslated sequence from exon 1) were fused to the bacterial chloramphenicol acetyltransferase (CAT) gene in the pSVOCAT plasmid. A plasmid carrying the bacterial beta-galactosidase gene driven by the Rous sarcoma virus (RSV) promoter was used as an internal control. Standardized results showed that the sequence located between -120 to -43 exhibited strong promoter activity; however, the promoter activity was markedly reduced (20-fold) when the upstream sequence between -603 and -120 was included in the construct. The delta 1-crystallin promoter displayed little lens preference. This upstream sequence did not reduce the activity of the Simian virus 40 (SV40) early promoter (with or without its enhancer) or the Herpes thymidine kinase promoter in transfection tests, indicating some specificity in its effect. Evidence for a delta 1-crystallin negative trans-acting factor was provided by competition experiments. Our data raise the possibility that expression of the delta 1-crystallin gene involves a negative cis-acting transcription element, a speculation which may deserve further attention in view of the gradual decrease in delta-crystallin synthesis in the developing lens.

Gene sharing by delta-crystallin and argininosuccinate lyase

The lens structural protein delta-crystallin and the metabolic enzyme argininosuccinate lyase (ASL; L-argininosuccinate arginine-lyase, EC 4.3.2.1) have striking sequence similarity. We have demonstrated that duck delta-crystallin has enormously high ASL activity, while chicken delta-crystallin has lower but significant activity. The lenses of these birds had much greater ASL activity than other tissues, suggesting that ASL is being expressed at unusually high levels as a structural component. In Southern blots of human genomic DNA, chicken delta 1-crystallin cDNA hybridized only to the human ASL gene; moreover, the two chicken delta-crystallin genes accounted for all the sequences in the chicken genome able to cross-hybridize with a human ASL cDNA, with preferential hybridization to the delta 2 gene. Correlations of enzymatic activity and recent data on mRNA levels in the chicken lens suggest that ASL activity depends on expression of the delta 2-crystallin gene. The data indicate that the same gene, at least in ducks, encodes two different functions, an enzyme (ASL) and a structural protein (delta-crystallin), although in chickens specialization and separation of functions may have occurred.

Expression of the delta-crystallin genes in the embryonic chicken lens

The amounts of lens mRNA derived from the delta 1- and delta 2-crystallin genes of the chicken were determined by primer extension experiments using gene-specific synthetic oligonucleotides. The primer extended products were sequenced to establish the identity of the resulting cDNAs. The results indicated that most of the delta-crystallin mRNA in the 14-day-old embryonic lens contained transcripts derived from the delta 1 gene. Importantly, however, about 1-2% of the extended products were derived from delta 2 mRNA. Although not quantitative, the primer extension experiments suggested that the delta 1/delta 2 mRNA ratio may differ in the lens fiber cells during development between 6 days of embryogenesis and 3 weeks after hatching. These data provide the first demonstration for the presence of delta 2-crystallin mRNA in the chicken lens and raise the possibility that the two linked, extremely similar delta-crystallin genes are differentially regulated during development.

Developmental expression of crystallin genes: in situ hybridization reveals a differential localization of specific mRNAs

The time and place of the accumulation of alpha A-, beta B1- and gamma-crystallin RNA in the developing rat lens have been studied by in situ hybridization. alpha A- and gamma-crystallin RNA were first detected in the lens vesicle, while beta B1-crystallin RNA could be seen only after elongation of the primary fiber cells. Both beta B1- and gamma-crystallin RNA were confined to the fiber cells of fetal lenses, while alpha A-crystallin mRNA could also be detected in the epithelial cells. A quantification of the hybridization pattern obtained in the differentiation zone of the newborn rat lens showed that alpha A-crystallin RNA is concentrated in the cortical zone. alpha B-crystallin mRNA has the same distribution pattern. beta B1-crystallin RNA was relatively poorly detectable by in situ hybridization in both fetal and newborn rat lenses. The grain densities obtained with this probe increased from the periphery of the lens toward the interior, indicating that beta B1-crystallin RNA accumulated during differentiation of the secondary fiber cells. A similar accumulation pattern was obtained for gamma-crystallin mRNA, but, unexpectedly, this RNA could also be detected in the elongating epithelial cells. Our results show that gamma-crystallin RNA starts to accumulate as soon as visible elongation of epithelial cells occurs, during differentiation of the primary as well as the secondary fiber cells.