Cytoskeletal and contractile structures in bovine lens cell differentiation

Bovine lenses from animals of different ages were separated into two epithelial sections, a cortical region and the lens nucleus. Both the 10000 g supernatant fraction and pellet of these sections were analysed by electrophoresis in SDS-containing polyacrylamide gels. When comparing total protein patterns of the cytoskeletal preparations from the different parts of lenses of different ages a decrease in the amount of vimentin, the protein subunit of lens intermediate-sized filaments (IF), was observed upon lens cell differentiation and aging. Amounts of monomeric (G) and filamentous (F) actin in the different stages of lens cell differentiation were quantitated using the DNase I inhibition technique. A significant increase in the relative amount of F-actin was observed upon fibre cell formation. A slight, but significant increase in the total amount of actin relative to the total amount of cellular protein was observed when passing from the central part of the lens epithelium to the epithelial cells in the elongation zone. In the fibre cells the amount of total actin decreased from cortex to nucleus. A possible function of microfilament-assembly in the process of lens cell differentiation is suggested.     

Degradation of nuclear DNA by DNase II-like acid DNase in cortical fiber cells of mouse eye lens

The eye lens is composed of fiber cells that differentiate from epithelial cells on its anterior surface. In concert with this differentiation, a set of proteins essential for lens function is synthesized, and the cellular organelles are degraded. DNase II-like acid DNase, also called DNase IIbeta, is specifically expressed in the lens, and degrades the DNA in the lens fiber cells. Here we report that DNase II-like acid DNase is synthesized as a precursor with a signal sequence, and is localized to lysosomes. DNase II-like acid DNase mRNA was found in cortical fiber cells but not epithelial cells, indicating that its expression is induced during the differentiation of epithelial cells into fiber cells. Immunohistochemical and immunocytochemical analyses indicated that DNase II-like acid DNase was colocalized with Lamp-1 in the lysosomes of fiber cells in a relatively narrow region bordering the organelle-free zone, and was often found in degenerating nuclei. A comparison by microarray analysis of the gene expression profiles between epithelial and cortical fiber cells of young mouse lens indicated that some genes for lysosomal enzymes (cathepsins and lipases) were strongly expressed in the fiber cells. These results suggest that the lysosomal system plays a role in the degradation of cellular organelles during lens cell differentiation.     

Benzpyrene groups bind preferentially to the DNA of active chromatin in human lung cells.

The cells of the bronchial epithelium of man are targets for benzo(a)pyrene carcinogenesis. When cultures of these cells, and of non-target fibroblasts, are exposed to [3H]-benzo(a)pyrene, we find that the epithelial cells metabolise and bind to DNA far greater amounts of benzpyrene than do fibroblasts. By analysis of nuclei of benzpyrene-treated cells for sensitivity to limited digestion with pancreatic DNase I, we have shown that benzpyrene groups bind initially to the DNA of expressed (DNase I sensitive) regions of chromatin in both cell types. Covalent binding of benzpyrene groups to non-expressed (DNase I resistant) regions follows rapidly in the target epithelial cells. These maintain high levels of carcinogen adducts in their DNA. In fibroblasts, benzpyrene group binding to non-expressed DNA occurs more slowly and active removal of adducts from the DNA is evident.     

The synthesis and localization of crystallins in different cell compartments of the crystalline lens in adult frogs: immunoautoradiographic and immunofluorescent research

The purpose of this study was to analyze immunochemically the synthesis and distribution of tissue-specific proteins, i.e., alpha-, beta- gamma- and rho-crystallins, in morphologically distinct regions of the frog (Rana temporaria L.) lens which consist of cells at various stages of differentiation, maturation and aging. Five such cell compartments can be distinguished in the lens: (1) central zone of lens epithelium (stem/clonogenic cells); (2) equatorial epithelial cells (differentiating cells); (3) lens fibers of the outer cortex (post-mitotic differentiated cells); (4) lens fibers of the deep cortex (cells without nuclei at terminal stage of differentiation); and (5) cells of the lens "nucleus" (cells formed during embryogenesis). Intact lenses and isolated lens epithelium were cultured in vitro in the presence of 35S-methionine. Then lens epithelium, outer and deep cortex, and lens nucleus were extracted with buffered saline and extracts used for immunoautoradiography. Distribution of crystallins in paraffin sections of the whole lens or isolated lens epithelium was studied using indirect immunofluorescence. Synthesis of alpha-crystallins was observed in lens epithelium and cortex, but not in lens nucleus. According to immunohistochemistry, these proteins were absent from central part of the lens epithelium: positive fluorescence was observed only in elongating cells at its periphery and in lens fibers. The data on beta-crystallins are similar except that synthesis of these proteins (traces) was detected also in lens nucleus. Synthesis of gamma-crystallins was detected in lens cortex and nucleus (traces) but not in epithelium. Immunohistochemistry showed that these proteins are absent from all regions of lens epithelium and found only in fiber cells of cortex and nucleus. Rho-crystallin was synthesized in all cell compartments of the adult lens, and all lens cells contained this protein. Our results show that cells of central lens epithelium do not contain alpha- beta- or gamma-crystallins (or the rate of their synthesis is insignificant). While cells are moving towards lens equator and elongating, synthesis of alpha- and beta-crystallins is activated. Gamma-crystallins are synthesized later, first in young lens fibers near lens equator. During embryonic development in amphibia, in contrast, gamma- and beta-crystallins are detected at earlier stages than alpha- and rho-crystallins (Mikha?lov et al., 1988). These data suggest that different mechanisms are involved in differentiation on lens fibers from embryonic precursor cells, on one hand, and from epithelial stem cells of adult lens, on the other.     

Band 4.1-like proteins of the bovine lens. Effects of differentiation, distribution and extraction characteristics.

Bovine lens epithelium, cortex and nucleus were screened for the presence of red-cell-membrane band 4.1-like proteins by using an immunoblot method. Lens epithelial cells were found to contain proteins of Mr 78 000 and higher (approximately 150 000) that cross-reacted with anti-(protein 4.1) sera. Fibre cells of the superficial cortex were also found to contain these two proteins, as well as an additional protein of approx. 80 000 Mr. In contrast, deep layers of the cortex and the lens nucleus contained no detectable cross-reactive protein at these Mr values. Treatment of a crude membrane fraction prepared from superficial bovine cortices with a low-ionic-strength buffer resulted in release of the high-Mr band 4.1-like protein. The 80 000- and 78 000-Mr proteins remained with the membrane fraction in low-ionic-strength buffer, but were released into solution by high-ionic-strength-buffer treatment. We have also demonstrated that the human red-blood-cell membrane, like lens epithelial cells and fibre cells, also contains a high-Mr band 4.1-like protein that is released from membranes by low-ionic-strength-buffer treatment.     

Characterisation of eye-lens DNases: long term persistence of activity in post apoptotic lens fibre cells

Fibre cells in the ocular lens exhibit a constitutive apoptotic process of nuclear degradation that includes chromatin breakage, generating a ladder pattern of DNA fragments. This process is intrinsic to the normal terminal differentiation program. Despite the loss of nucleus and cytoplasmic organelles, the terminal differentiated fibre cells remain in the lens during the whole life span of the individual. The lens cells thus provide a unique system in which to determine the presence and fate of endonucleases once the chromatin has been cleaved. We report here on the presence of DNase activity in nucleated and anucleated lens cells. Using a nuclease gel assay and double-stranded DNA as substrate, we found active 30 and 60 kDa DNases. The enzymatic activities were Ca(2+), Mg(2+) dependent, and active at neutral pH. The relative amount of these forms changed during development and aging of the lens fibre cells. Both forms were inhibited by Zn(2+), aurintricarboxylic acid, and G-actin. The proteins were also separated by SDS-PAGE, renatured after removing SDS and incubated in the presence of native DNA adsorbed to a membrane. Therefore it was possible to demonstrate, by means of a nick translation reaction, that the enzymes produced single strand cuts. Based on these findings we propose that these chick lens nucleases are probably related to DNase I.     

Expression of lipocortins in human bronchial epithelial cells: effects of IL-1beta , TNF-alpha, LPS and dexamethasone

In this study, we investigated the expression of lipocortin I and II (annexin I and I in the human bronchial epithelium, both in vivo and in vitro. A clear expression of lipocortin I and II protein was found in the epithelium in sections of bronchial tissue. In cultured human bronchial epithelial cells we demonstrated the expression of lipocortin I and II mRNA and protein using Northern blotting, FACScan analysis and ELISA. No induction of lipocortin I or II mRNA or protein was observed after incubation with dexamethasone. Stimulation of bronchial epithelial cells with IL-1beta, TNF-alpha or LPS for 24 h did not affect the lipocortin I or II mRNA or protein expression, although PGE(2) and 6-keto-PGF(1alpha) production was significantly increased. This IL-1beta- and LPS-mediated increase in eicosanoids could be reduced by dexamethasone, but was not accompanied by an increase in lipocortin I or II expression. In human bronchial epithelial cells this particular glucocorticoid action is not mediated through lipocortin I or II induction.     

Contrasting patterns of c-myc and N-myc expression in proliferating, quiescent, and differentiating cells of the embryonic chicken lens.

The present study uses the polymerase chain reaction and in situ hybridization to examine c-myc and N-myc mRNA in the embryonic chicken lens at 6, 10, 14 and 19 days of development and compares the pattern of expression obtained with the developmental pattern of cell proliferation and differentiation. In the central epithelium, c-myc mRNA levels were proportional to the percentage of proliferating cells throughout development. N-myc mRNA expression in this region was relatively low and showed no correlation with cell proliferation. The ratio of N-myc to c-myc mRNA increased markedly with the onset of epithelial cell elongation and terminal fiber cell differentiation, although both c-myc and N-myc mRNAs continued to be expressed in postmitotic, elongating cells of the equatorial epithelium and in terminally differentiating lens fiber cells. Thus, increased expression of N-myc, a gene whose protein product may compete with c-myc protein for dimerization partners, accompanies the dissociation of c-myc expression and cell proliferation during terminal differentiation of lens fiber cells.     

Differential expression of the HMGN family of chromatin proteins during ocular development

The HMGN proteins are a group of non-histone nuclear proteins that associate with the core nucleosome and alter the structure of the chromatin fiber. We investigated the distribution of the three best characterized HMGN family members, HMGN1, HMGN2 and HMGN3 during mouse eye development. HMGN1 protein is evenly distributed in all ocular structures of 10.5 days post-coitum (dpc) mouse embryos however, by 13.5dpc, relatively less HMGN1 is detected in the newly formed lens fiber cells compared to other cell types. In the adult, HMGN1 is detected throughout the retina and lens, although in the cornea, HMGN1 protein is predominately located in the epithelium. HMGN2 is also abundant in all ocular structures of mouse embryos, however, unlike HMGN1, intense immunolabeling is maintained in the lens fiber cells at 13.5dpc. In the adult eye, HMGN2 protein is still found in all lens nuclei while in the cornea, HMGN2 protein is mostly restricted to the epithelium. In contrast, the first detection of HMGN3 in the eye is in the presumptive corneal epithelium and lens fiber cells at 13.5dpc. In the lens, HMGN3 remained lens fiber cell preferred into adulthood. In the cornea, HMGN3 is transiently upregulated in the stroma and endothelium at birth while its expression is restricted to the corneal epithelium in adulthood. In the retina, HMGN3 upregulates around 2 weeks of age and is found at relatively high levels in the inner nuclear and ganglion cell layers of the adult retina. RT-PCR analysis determined that the predominant HMGN3 splice form found in ocular tissues is HMGN3b which lacks the chromatin unfolding domain although HMGN3a mRNA is also detected. These results demonstrate that the HMGN class of chromatin proteins has a dynamic expression pattern in the developing eye.     

Nuclease sensitivity of the mouse HPRT gene promoter region: differential sensitivity on the active and inactive X chromosomes.

We investigated the conformation of the X-linked mouse hypoxanthine-guanine phosphoribosyltransferase gene (HPRT) promoter region both in chromatin from the active and inactive X chromosomes with DNase I and in naked supercoiled DNA with S1 nuclease. A direct comparison of the chromatin structures of the active and inactive mouse HPRT promoter regions was performed by simultaneous DNase I treatment of the active and inactive X chromosomes in the nucleus of interspecies hybrid cells from Mus musculus and Mus caroli. Using a restriction fragment length polymorphism to distinguish between the active and inactive HPRT promoters, we found a small but very distinct difference in the DNase I sensitivity of active versus inactive chromatin. We also observed a single DNase I-hypersensitive site in the immediate area of the promoter which was present only on the active X chromosome. Analysis of the promoter region by S1 nuclease digestion of supercoiled plasmid DNA showed an S1-sensitive site which maps adjacent to or within the DNase I-hypersensitive site found in chromatin but upstream of the region minimally required for normal HPRT gene expression.