DNAase activities in embryonic chicken lens: in epithelial cells or in differentiating fibers where chromatin is progressively cleaved.

Lens is an organ composed of a layer of epithelial cells and a mass of fibers. During terminal differentiation, epithelial cells from the equatorial region elongate into fibers, nuclei change shape, the chromatin appears much condensed in the last step of differentiation and the DNA breaks down into nucleosomes. The pattern of DNAase activities has been recorded at different chick embryonic stages (11 and 18 days) using polyacrylamide gel electrophoresis with DNA substrate in the gel matrix. Two DNAases (30 and 40 kDa) have been observed in lens epithelia and fibers at both stages. However, the activities of both of the enzymes are augmented in fiber cells. The 30 kDa DNAase requires and Ca2+ and Mg2+ (5-15 mM) to hydrolyze the DNA substrate while the 40 kDa-activity is inhibited by added divalent cations (5-15 mM). The 30 kDa protein is inhibited by Na+ and is probably an endonuclease. Both nuclease activities probably are involved in the cleavage of fiber chromatin into nucleosomes during lens terminal differentiation, but variables such as chromatin configuration, unmasked DNA sequences, presence of cations, and pH gradients probably determine the extent of involvement of each DNAase.     

DNA strand breakage during physiological apoptosis of the embryonic chick lens: Free 3' OH end single strand breaks do not accumulate even in the presence of a cation-independent deoxyribonuclease

Epithelial cells from the lens equator differentiate into elongated fiber cells. In the final steps of differentiation, the chromatin appears quite condensed and chromatin breakdown into nucleosmes occurs. DNA breaks due to an endodeoxyribonuclease activity corresponding to at least two polypeptides of 30 and 40 kDa have been identified. To identify the nature and the developmental appearance of initial breaks, nick translation reaction was followed both biochemically and in situ in fiber and epithelial cells from chick embryonic lenses. There is no accumulation of single-strand breaks (SSB) with 3'OH ends in lens fiber cells during embryonic development. Such damage can be increased in these cells by treatment with DNAase I indicating the absence of an inhibitor of the nick translation reaction in fiber cells. However, there are indications of the presence of DNA breaks with blocked termini when the phosphatase activity of nuclease P1 is used. The presence of breaks is also indicated by the large amounts of (ADP-ribose)_n found in lens fibers particularly at 11 days of embryonic development (E11) as ADP-ribosyl transferase binds to and is activated by DNA strand breaks. Incubation of lens cells in vitro, which causes nucleosomal fragmentation only in fiber cells, produces SSB with 3'OH ends in both epithelia and fibers. Incubation for short periods, observed in experiments in situ, induces SSB first in the central fiber nuclei, which are late in differentiation. This may indicate that these SSB play a physiological role. Long incubations produce larger numbers of SSB in epithelia than fibers. The SSB in the fibers may have been converted into double-strand breaks (D SB), seen as nucleosomal fragments, and therefore no longer act as substrates for nick translation. The nuclease activity responsible for SSB production is independent of divalent cations and could be implicated in lens terminal differentiation. © 1994 Wiley-Liss, Inc.     

Increased sensitivity of various genes to endogenous DNase activity in terminal differentiating chick lens fibers

In the lens, epithelial cells from the equatorial zone differentiate into postmitotic elongated fibers. One aspect of this differentiation is nuclear shape transformation and DNA degradation. This process is controlled by DNase activity which in fiber nuclei increases with development. DNase activity is also present in the epithelial cell nuclei which appears to be non-functional but could be activated in vitro by exogenous addition of Ca2+. We have analyzed the possible selective action of endogenous DNase on 3 genes involved in lens terminal differentiation, namely delta-crystallin, beta-tubulin and vimentin, and on 1 gene not thought to participate in this process, ovalbumin. We have compared restriction DNA patterns of these genes in nuclei isolated from 11-day-old chick embryos and incubated in Ca2+-free medium or in fresh epithelial and fiber lens tissue at 11 and 18 days of development. During incubation in vitro of 11-day fiber nuclei, there is a net increase in the sensitivity of the delta-crystallin, beta-tubulin, ovalbumin and vimentin chromatin to the endogenous DNase. The vimentin gene appears to be more stable than the beta-tubulin and delta-crystallin genes indicating a degree of specificity of the endogenous DNase activity. In the epithelial nuclei, the lens-specific genes appear to be more stable but paradoxically there is a net degradation of the ovalbumin gene. In freshly isolated tissues the 4 genes were detected in epithelial and fiber cells at 11 and 18 days. Furthermore, in the mature fibers in which the nuclei were degenerating, the latter genes were still not completely digested.     

Purification of 14C-labelled deoxyribonuclease II from HeLa S3 lysosomes and its use as a marker for the study of nuclear deoxyribonuclease II

Deoxyribonuclease II (DNAase II) in mammalian cells has generally been considered to be located in the lysosomes. Several recent studies have indicated that some DNAase II activity is present in purified nuclei; this, however, could have been due to some contamination of the nuclear fraction by lysosomes, or alternatively, it could have been caused by specific binding of lysosomal DNAase II to the nuclear fraction during isolation. Our previous studies have eliminated the possibility that lysosomal contamination was the cause of the presence of DNAase II in isolated nuclei. In this study I have purified (14)C-labelled lysosomal DNAase II and added it to cells during isolation of their nuclei. This study demonstrates that there is no specific binding of lysosomal DNAase II to the nuclear fraction and concludes that DNAase II activity observed in isolated nuclei represents an intrinsic activity that might be involved in nuclear DNA metabolism.     

Differentiation of lens and neural cells in chicken embryos is accompanied by simultaneous decay of DNA replication machinery

DNA polymerase alpha was detected in cells of developing chicken embryos by an immunofluorescent method using a monoclonal antibody specific for the high molecular weight polypeptide of chicken DNA polymerase alpha, and DNA polymerase beta was detected using a rabbit anti-chicken DNA polymerase beta antibody. In lens tissue of the 3- to 4-day chicken embryo, fluorescence with anti-DNA polymerase alpha antibody was detected in nuclei of lens epithelial cells but not in nuclei of lens fiber cells which had differentiated from epithelial cells. The localization of cells containing DNA polymerase alpha coincided with the distribution of cells capable of DNA replication as detected by [3H]thymidine autoradiography. Similar results were obtained during the differentiation of neural matrix cells to neuroblasts in the developing neural tube. In contrast to DNA polymerase alpha, DNA polymerase beta was detected in nuclei of both undifferentiated and differentiated cells of these tissues. Since the disappearance of DNA polymerase alpha was very rapid after the onset of differentiation, the DNA replication machinery in which DNA polymerase alpha plays a central role is thought to decay almost simultaneously with the onset of cellular differentiation in these tissues.     

Decrease of DNA per cell during development of the lens in chickens.

Developmental changes in the amount and conformation of DNA in chicken lens were studied. For this, DNA in situ in lens fiber cell nuclei of chickens was examined by microfluorometry with Hoechst 33258 (Hoe) fluorochrome. On 1 M NaCl-aided Hoe staining, by which the amount of DNA can be determined accurately, the fluorescence intensity of lens fiber cells was found to decrease with no change in that of the lens epithelial cells during development. On the contrary, on normal NaCl-free Hoe staining the fluorescence intensity of the lens cells was found to increase gradually during development. These results suggest that during development the amount of DNA in lens fiber cells decreases in association with some change in its conformation.     

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.     

Decrease of DNA per cell during development of the lens in chickens

Summary Developmental changes in the amount and conformation of DNA in chicken lens were studied. For this, DNA in situ in lens fiber cell nuclei of chickens was examined by microfluorometry with Hoechst 33258 (Hoe) fluorochrome. On 1 M NaCl-aided Hoe staining, by which the amount of DNA can be determined accurately, the fluorescence intensity of lens fiber cells was found to decrease with no change in that of the lens epithelial cells during development. On the contrary, on normal NaCl-free Hoe staining the fluorescence intensity of the lens cells was found to increase gradually during development. These results suggest that during development the amount of DNA in lens fiber cells decreases in association with some change in its conformation.     

Chromatin condensation and terminal differentiation process in embryonic chicken lens in vivo and in vitro

During embryonic chick lens differentiation, the epithelial cells become transformed into elongated fibres. Concomitantly, the fibre nuclei undergo degeneration and high molecular weight (HMW) DNA breaks down due to nuclear endodeoxyribonuclease activity. An electronmicroscopic study of lens epithelial and fibre nuclei was made at different stages of chick embryonic development, both in vivo and in vitro. The in vitro conditions are conducive to the expression of endogenous endodeoxyribonuclease activity in fibres. In both conditions we observed condensation of chromatin. The organization of some nuclear material into distinct linear arrays followed by streaming of nuclear material into the cytoplasm is recorded only in vitro. Such a condition may lead to acceleration of the process of aging in lens fibres.     

Developmental analysis of the eye lens obsolescence (Elo) gene in the mouse: cell proliferation and Elo gene expression in the aggregation chimera.

This study investigates the primary effect of the eye lens obsolescence (Elo) gene of the mouse. Morphological features of the Elo lens were defined as follows: (1) deficient elongation of lens fiber cells, (2) morphological abnormality of nuclei of lens fiber cells, (3) lack of eosinophilic granules in the central fiber cells and (4) rupture of lens capsule in the posterior region. We have immunohistologically examined, by means of an in vivo BrdU incorporation system, whether or not the Elo gene regulates cell proliferation during lens development. The lens fiber cells were morphologically abnormal in day 13 embryonic Elo lens. However, there were no significant differences in morphology or cell proliferation between normal and Elo lens epithelium until day 14 of gestation. After day 15, the total cell number in the Elo lens epithelium was significantly less than that in the normal, but the total numbers of S-phase cells in the two genotypes were not significantly different. The ratio of the total S-phase cell number to the total number of lens epithelial cells may be affected by the developmental stage, but not directly by the genotype. The genotype, however, may be having a direct influence at later ages because malformation of Elo lens fiber cells must cause reduction of the total number of lens epithelial cells in older embryos. Although, at 30 days old, Elo lens cells were externally extruded through the ruptured capsule into the vitreous cavity, BrdU-labelled lens epithelial cells were detectable. To investigate whether the Elo lens phenotype is determined by its own genotype or by its cellular environment, we produced aggregation chimeras between C3H-Elo/+(C/C) and BALB/c(c/c). Most lenses of BALB/c dominant chimeras were oval in shape without the ruptured lens capsule. However, they were opaque in the center and slightly smaller in size than normal. The lenses of C3H-Elo/+ dominant chimeras were morphologically similar to the Elo lens. Although normal nuclei were regularly arranged in the anterior region, Elo-type nuclei were located in the posterior region. Immunohistological staining by using anti-C3H strain-specific antibody demonstrated that the lens fiber cells with abnormal nuclei were derived only from C3H-Elo/+, not from BALB/c. These observations suggest that the primary effect of the Elo gene in the developing lens may be specific to the fiber cell differentiation rather than to the cell proliferation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential solubilization of nuclear glucocorticoid receptors by DNAase I and DNAase II

This study analyzes the sensitivity of nuclear bound glucocorticoid receptors to solubilization from nuclei by DNAase I and DNAase II. Thymocytes were incubated with 10(-8) M [3H]dexamethasone, [3H]cortisol or [3H]triamcinolone acetonide, without or with 10(-6) M unlabelled dexamethasone, for 30 min at 37 degrees C and nuclei from these cells were digested with either DNAase I and DNAase II. DNAase I for 2 h at 3 degrees C leads to solubilization of 60% of the nuclear DNA and release of 10--20% triamcinolone acetonide-receptor, 30--40% dexamethasone-receptor and 85--90% cortisol-receptor. DNAase II at the same enzymatic concentration solubilizes only 10--20% of the nuclear DNA, but releases 40--50% triamcinolone-receptor, 60--70% dexamethasone-receptor and 100% cortisol-receptor. Release of nuclear bound dexamethasone-receptor by DNAase I parallels the solubilization of DNA, reaching maximum values by 2 h at 3 degrees C, whereas maximal release by DNAase II is obtained within 45 min when DNA solubilization is not complete. When nuclei initially extracted with DNAase I are re-extracted with DNAase II, greater than 65% of the DNAase I residual dexamethasone-receptors are solubilized, whereas DNAase I is ineffective in solubilizing DNAase II residual dexamethasone-receptors. DNAase I solubilizes only 30% of the 0.4 M KCl residual dexamethasone-receptor whereas DNAase II digests over 90% of this fraction. DNAase I extracts of nuclear dexamethasone-receptor chromatograph on G-100 Sephadex as a single radioactive peak just after the void volume, whereas DNAase II extracts of nuclear dexamethasone-receptor chromatograph as two peaks of radioactivity, one which is similar to the DNAase I solubilized receptor and a second broad peak of macromolecular bound radioactivity which is smaller in size.     

Effect of Ca2+, Mg2+-dependent deoxyribonuclease on DNA synthesis in cell nuclei from embryos of the sea urchin Strongylocentrotus intermedius

The sea urchin embryo nuclei which retained their ability to maintain the DNA synthesis in an in vitro system were isolated. The DNA synthesis isolated nuclei was shown to be an ATP-dependent process which is inhibited by low concentrations of actinomycin D, a polymerase alpha araCTP inhibitor. The newly synthesized DNA is represented by short fragments of about 4S. After addition of Ca2+, Mg2+-dependent DNAase to sea urchin embryo nuclei, the synthesis of short DNA fragments is enhanced. This stimulating effect of Ca2+, Mg2+-dependent DNAase is ATP-dependent and is observed only within a narrow range of enzyme concentrations (of the order of 1-5 units of DNAase activity per ml of incubation sample). The increase in the enzyme concentration to 10 or more units of activity results in the depression of DNA synthesis. It is concluded that DNA replication in sea urchin embryo nuclei depends on the presence of active DNAases as well as on the number of accessible initiation sites of DNA replication.     

Hb switching in chickens

We have taken advantage of the preferential digestion of active genes by DNAase I to investigate the chromosomal structure of embryonic and adult β-globin genes during erythropoiesis in chick embryos, and in particular to examine the question of hemoglobin switching during development. DNA in isolated red cell nuclei was mildly digested with DNAase I to about 10–15 kb, purified and restricted with a variety of restriction enzymes. The DNA was then separated on agarose gels, transferred to nitrocellulose filters and hybridized with an adult-specific β-globin cDNA clone or a genomic clone containing the genes coding for both an embryonic and an adult β-globin chain. Preferential sensitivity of the respective globin genes was monitored by the disappearance of specific restriction bands after DNAase I digestion of nuclei. In embryonic red cells, both adult and embryonic β-globin genes are very sensitive to DNAase I; however, in adult erythroid lines, the embryonic β-globin gene becomes relatively more resistant but the adult gene remains highly sensitive. Controls showed that all globin genes were resistant to DNAase I in brain nuclei and nuclei from lymphoid cells. Thus the switch from embryonic to adult globin expression is associated with an apparent change in the chromosome structure of the embryonic globin gene as reflected in the gene becoming less accessible to DNAase I in adult red cell nuclei. Our results also show that the chromosomal structure of both adult and embryonic genes is altered in embryonic red cell nuclei; thus the nonexpressed globin gene (that is, the adult gene in embryonic red cells) has already been “recognized” to some degree and marked by the erythroid compartment. The sensitivity of the adult globin gene in embryonic cells may represent a “pre-activation” state of the chromosome.     

Effect of X-ray induced DNA damage on DNAase I hypersensitivity of SV40 chromatin: relation to elastic torsional strain in DNA.

The effect of X-irradiation on DNAase I hypersensitivity of SV40 minichromosomes within nuclei or free in solution was investigated. The susceptibility of the specific DNA sites in the control region of minichromosomes to DNAase I decreased in a dose dependent manner after irradiation of isolated nuclei. On the other hand, the irradiation of minichromosomes extracted from nuclei in 0.1 M NaCl-containing buffer almost did not affect the level of their hypersensitivity to DNAase I. This suggests that DNAase I hypersensitivity may be determined by two different mechanisms. One of them may be connected with elastic torsional strain within a fraction of minichromosomes and another seems to be determined by nucleosome free region. The first mechanism may be primarily responsible for the hypersensitivity of minichromosomes within nuclei. After irradiation of the intact cells, DNAase I hypersensitivity tested in nuclei substantially increased. This was connected with activation of endogeneous nucleases by X-irradiation which led to accumulation of single- and double-strand breaks superimposed to DNAase I induced breaks in the control region of SV40 DNA.     

Minireview: Apoptosis as seen through a lens

The lens represents an ideal model system for studying many of the cellular and molecular events of differentiation. It is composed of two ectodermally-derived cell types: the lens epithelial cells and the lens fibre cells, which are derived from the lens epithelial cells by differentiation. Programmed removal of nuclei and other organelles from the lens fibre cells ensures that an optically clear structure is created, while the morphology of the degenerating nuclei is similar to that observed during apoptosis and is accompanied by DNA fragmentation. These observations suggest the existence of biochemical parallels between the process of lens fibre cell organelle loss and classical apoptosis. For example, proteins encoded by the bcl-2 and caspase gene families are expressed in developing lenses and nuclear degeneration in lens fibre cells can be inhibited in vivo by overexpression of bcl-2 and in vitro by incubation of differentiating lens epithelial cell cultures with caspase inhibitors. Thus, the developing lens may represent a particularly useful model system for researchers interested in apoptosis. In this review, the recent literature pertaining to lens fibre cell organelle loss and its relationship to apoptosis is reviewed and possible future research directions are suggested.     

Study of expression of desoxyribonucleases in mammalian cells by a protein renaturation method in polyacrylamide gel

Analysis of enzymatic activity in polyacrylamide gel is based on highly effective separation of proteins by SDS-electrophoresis with their subsequent renaturation and detection of enzymatic activity. This method was used to study an expression of DNAases in culturing of cells HEK293, NIH 3T3, U937. We have found that in HEK293 cells the nucleases with molecular weights 47 and 45 kDa were expressed. The localization of DNAases in the cell nuclei was shown as well. Induction of apoptosis in HEK293 cells increase the level of p47 DNAase and causes the expression of novel 50 kDa DNAase. We suggested that those discovered DNAases could take part in apoptotic DNA degradation.