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.     

Identification and purification of a nuclease from Zinnia elegans L.: a potential molecular marker for xylogenesis

A single-strand specific nuclease was identified during a particular stage of a defined cellular differentiation pathway characteristic of xylem development. Using a hormone-inducible system in which cultured mesophyll cells of Zinnia elegans differentiated to xylem cells in synchrony, the enzymatic activity on single-stranded (ss) DNA was highest during the maturation phase of differentiation. Nondifferentiating cells contained little of this activity throughout a similar course of culture. After electrophoresis of extracts from differentiating cells, a 43-kilodalton (kDa) polypeptide was detected by its activity in the gels containing either ssDNA or RNA. Lectins specific for mannose residues on glycoproteins bound to the 43-kDa nuclease and were used to distinguish it from several ribonucleases. The nuclease was purified by a two-step chromatographic procedure: a lectin-affinity column followed by a phosphocellulose column. The purified protein was determined to be a single polypeptide with a relative molecular mass of 43000 by the analysis of its mobility during sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by gel filtration of the native enzyme. A sensitive detection system using biotinylated-concanavalin A and avidin was demonstrated to be specific as a probe for the nuclease protein. An N-terminal amino-acid sequence was derived from 5 pmol of the enzyme. The nuclease was most active on ssDNA at pH 5.5 in the presence of Zn²⁺ and dithiothreitol. The purified preparation hydrolyzed RNA and to a lesser extent, native DNA. It digested closed circular duplex DNA by introducing a single endonucleolytic cleavage followed by random hydrolysis. During the induced pathway of synchronous differentiation in Zinnia the 43-kDa nuclease rapidly increased just prior to the onset of visibly differentiated features, and developed to a maximum level during xylem cell maturation. At this time a similar but slightly smaller nuclease appeared and became dominant as differentiation continued, and subsequently both enzymes decayed. After autolysis, a nuclease of about 37 kDa was found together with the 43-kDa enzyme in the culture medium. Complementing these analyses was the examination of the tissue distribution of the 43-kDa enzyme in Zinnia and other dicotyledonous plants, which also indicated an invivo role of the nuclease in autolysis, the terminal stage of vascular differentiation in plants. The Zinnia nuclease is therefore a potential marker for xylogenesis.Abbreviations Con A Canavalia ensiformis (concanavalin) agglutinin - DNase deoxyribonuclease - DTT dithiothreitol - EDTA ethylenediaminetetraacetic acid - kDa kilodalton - M_r relative molecular mass - RNase ribonuclease - ss single-stranded - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

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.     

Nuclease Activity of Human Interleukin-10

The nuclease activity of human interleukin-10, an immunosuppressive cytokine, was predicted on the basis of structural homology between the 97–105 sequence of human interleukin-10 and the DNA/RNA-hydrolyzing fragment of the endogenous differentiation factor for the HL-60 line of human promyelocyte leukemia cells. The human recombinant interleukin-10 was shown to cleave all forms of plasmid DNA. The role of interleukin-10 in the apoptosis induction in monocytic cells was hypothesized.     

Nuclease activity of human interleukin-10

The nuclease activity of human interleukin-10, an immunosuppressive cytokine, was predicted on the basis of structural homology between the 97-105 sequence of human interleukin-10 and the DNA/RNA-hydrolyzing fragment of the endogenous differentiation factor for the HL-60 line of human promyelocyte leukemia cells. The human recombinant interleukin-10 was shown to cleave all forms of plasmid DNA. The role of interleukin-10 in the apoptosis induction in monocytic cells was hypothesized. The English version of the paper.     

Novobiocin induces the in vivo cleavage of active gene sequences in intact cells

When the topoisomerase II inhibitor, novobiocin, is administered to embryonic chicken red blood cells, it induces the in vivo release of an endogenous nuclease which cleaves specifically within internucleosomal spacer DNA and within nuclease-hypersensitive sites in the active chromatin of intact cells. This in vivo released nuclease activity is induced by novobiocin only in metabolically active immature red blood cells. Little induction occurs in mature erythrocytes and no induction occurs in cells previously treated with 2,4-dinitrophenol. Although novobiocin is required to induce release and/or activation of the nuclease, the activity of the nuclease, once activated, is independent of novobiocin. Analysis of the cleaved DNA in drug-treated immature cells demonstrates that the novobiocin-induced nuclease has an unusual blunt-ended double-stranded mode of cleavage. Because of its special properties and apparent chromatin related function in vivo, the novobiocin-induced nuclease activity offers a novel and useful in vivo and in vitro probe of chromatin structure.     

Study of barley endonucleases and alpha-amylase genes

We have identified an endonuclease(s) that preferentially cleaves the internucleosomal linker regions in the aleurone chromatin producing mono- and oligonucleosomes. This enzyme(s) has been designated as a "linker"-specific nuclease(s). This nuclease does not require divalent cations for activity, and therefore it is not the "Ca2+-Mg2+-DNase" found in mammalian cells. The linker-specific nuclease activity is not detectable in the dry aleurone tissue and in the tissue treated with 0.5 mM cordycepin. The endonuclease activity of the aleurone tissue incubated with gibberellic acid is higher than the level of this endonuclease in tissue treated with abscisic acid or water alone. Nuclei isolated from embryos have lower levels of endonuclease activities compared to those from aleurone tissue. Digestion of the nuclei from embryos with micrococcal nuclease revealed the subunit structure of chromatin. In Southern blots of the HindIII digests of DNA from embryos, five DNA bands hybridized to a nick-translated alpha-amylase cDNA clone. In similar autoradiograms with aleurone DNA, particular bands are less visible, notably in the DNA isolated from the tissue treated with gibberellic acid. This is the first report of the presence of a linker-specific nuclease activity in plant cells.     

Topoisomerase IIB and an extracellular nuclease interact to digest sperm DNA in an apoptotic-like manner

We previously demonstrated that mammalian spermatozoa contain a nuclease activity that cleaves DNA into loop-sized fragments. We show here that this activity is mediated by a nuclear matrix-associated topoisomerase IIB (TOP2B) interacting with an extracellular Mn2+/Ca2+-dependent nuclease. Together, these enzymes cleave all of the DNA into fragments of 50 kb, and this cleavage can be reversed by EDTA. If dithiothreitol is included, the nuclease digests the DNA, and if the protamines are removed the DNA is completely digested. A similar, TOP2B-mediated, chromatin fragmentation, which is reversible, followed by digestion of the DNA by an intracellular nuclease occurs in somatic cells during apoptosis. The extracellular location of the sperm nuclease made it possible to reconstitute the fragmentation activity in isolated spermatozoa, thus allowing us to identify two novel aspects of the mechanism. First, the fragmentation of all of the DNA to 50 kb by TOP2B required the addition of the extracellular nuclease or factor. Second, the subsequent, complete digestion of the DNA by the nuclease could be inhibited by etoposide, suggesting that the nuclease digestion requires TOP2B religation of the cleaved DNA. These data are the first demonstration of an active TOP2B in spermatozoa, suggesting this inert chromatin may be more active than previously thought. They also show that the unique chromatin structure of spermatozoa may provide an important model to study the regulated degradation of chromatin by TOP2B and associated nucleases.     

Role of Gene 52 in Bacteriophage T4 DNA Synthesis

In an attempt to elucidate the mechanism of delayed DNA synthesis in phage T4, Escherichia coli B cells were infected with H17 (an amber mutant defective in gene 52 possessing a "DNA-delay" phenotype). The fate of (14)C-labeled H17 parental DNA after infection was followed: we could show that this DNA sediments more slowly in neutral sucrose than wild-type DNA 3 min postinfection. In pulse-chase experiments progeny DNA was found to undergo detachment from the membrane at 12 min postinfection. Reattachment to the membrane was found to be related to an increase in rate of DNA synthesis. A nucleolytic activity that is absent from cells infected by wild-type phage and from uninfected cells could be detected in extracts prepared from mutant-infected cells. In contrast, degradation of host DNA was found to be less extensive in am H17 compared with wild-type infected cells. Addition of chloramphenicol to mutant-infected cells 10 min postinfection inhibited the appearance of a nuclease activity on one hand and suppressed the "DNA-delay" phenotype on the other hand. We conclude that the gene 52 product controls the activity of a nuclease in infected cells whose main function may be specific strand nicking in association with DNA replication. This gene product might directly attack both E. coli and phage T4 DNA, or indirectly determine their sensitivity to degradation by another nuclease.     

The DNA binding domain of a papillomavirus E2 protein programs a chimeric nuclease to cleave integrated human papillomavirus DNA in HeLa cervical carcinoma cells

Viral DNA binding proteins that direct nucleases or other protein domains to viral DNA in lytically or latently infected cells may provide a novel approach to modulate viral gene expression or replication. Cervical carcinogenesis is initiated by high-risk human papillomavirus (HPV) infection, and viral DNA persists in the cancer cells. To test whether a DNA binding domain of a papillomavirus protein can direct a nuclease domain to cleave HPV DNA in cervical cancer cells, we fused the DNA binding domain of the bovine papillomavirus type 1 (BPV1) E2 protein to the catalytic domain of the FokI restriction endonuclease, generating a BPV1 E2-FokI chimeric nuclease (BEF). BEF introduced DNA double-strand breaks on both sides of an E2 binding site in vitro, whereas DNA binding or catalytic mutants of BEF did not. After expression of BEF in HeLa cervical carcinoma cells, we detected cleavage at E2 binding sites in the integrated HPV18 DNA in these cells and also at an E2 binding site in cellular DNA. BEF-expressing cells underwent senescence, which required the DNA binding activity of BEF, but not its nuclease activity. These results demonstrate that DNA binding domains of viral proteins can target effector molecules to cognate binding sites in virally infected cells.     

Nuclear endogenous Ca2+-dependent endodeoxyribonuclease in differentiating chick embryonic lens fibers

During terminal differentiation of lens epithelial cells into fiber cells, nuclei become pycnotic and DNA degradation occurs. We investigated the putative role in this process of an endogenous DNAase. After incubation of isolated nuclei of both cell types at 37 degrees C, DNAase activity was revealed by DNA size analysis on 0.3-1% neutral and alkaline agarose, one- and two-dimensional gels. This DNAase activity is more prominent in lens fiber nuclei than in epithelial nuclei at all the embryonic stages probably because of a preexisting higher concentration of divalent cations in the former. This activity is calcium or magnesium dependent in both types of nuclei.     

Different conformations of ribosomal DNA in active and inactive chromatin in Xenopus laevis

The chromatin structure of the ribosomal DNA in Xenopus laevis was studied by micrococcal nuclease digestions of blood, liver and embryonic cell nuclei. We have found that BglI-restricted DNA from micrococcal nuclease-digested blood cell nuclei has an increased electrophoretic mobility compared to the undigested control. Micrococcal nuclease digestion of liver cell nuclei causes a very slight shift in mobility, only in the region of the spacer containing the "Bam Islands". In contrast, the mobility of ribosomal DNA in chromatin of embryonic cells, under identical digestion conditions, remains unaffected by the nuclease activity. Denaturing gels or ligase action on the nuclease-treated DNA abolishes the differences in the electrophoretic mobility. Ionic strength and ethidium bromide influence the relative electrophoretic migration of the two DNA fragment populations, suggesting that secondary structure may play an important role in the observed phenomena. In addition, restriction analysis under native electrophoretic conditions of DNA prepared from blood, liver and embryonic cells shows that blood cell DNA restriction fragments always have a faster mobility than the corresponding fragments of liver and embryo cell DNA. We therefore propose that nicking activity by micrococcal nuclease modifies the electrophoretic mobility of an unusual DNA conformation, present in blood cell, and to a lesser extent, in liver cell ribosomal chromatin. A possible function for these structures is discussed. The differences of the ribosomal chromatin structures in adult and embryonic tissues may reflect the potential of the genes to be expressed.     

Similar actions of glucocorticoids and calcium on the regulation of apoptosis in S49 cells

Glucocorticoid-induced lymphocyte cell death is a programmed process which is thought to involve the calcium-dependent degradation of DNA into multiples of 180 basepairs, characteristic of internucleosomal degradation. We have used the glucocorticoid-sensitive mouse lymphoma cell line S49.1 [wild-type (wt)] and the glucocorticoid-resistant cell line S49.22r (nt-) to evaluate the role of both glucocorticoid receptors and calcium in the regulation of internucleosomal DNA degradation and expression of calcium-dependent deoxyribonuclease activity. DNA was isolated from untreated (control) and dexamethasone (dex)-treated viable cells and analyzed for internucleosomal DNA degradation by agarose gel electrophoresis, followed by ethidium bromide staining. Glucocorticoid treatment resulted in substantial internucleosomal DNA degradation in wt cells, but not in nt- cells. This effect was inhibited by coincubation of cells with dex and the glucocorticoid receptor antagonist RU486. In contrast to the glucocorticoid response, administration of either of two calcium ionophores, ionomycin or A23187, produced internucleosomal degradation of DNA in both wt and nt- cells, although the latter were less sensitive to ionophore treatment. Interestingly, A23187 treatment also resulted in a loss of cell viability in HeLa S3 cells, a cell line that does not exhibit glucocorticoid-induced apoptosis. No internucleosomal DNA degradation was detected in HeLa S3 cells killed by A23187. To determine whether similar nucleases are associated with this internucleosomal DNA degradation resulting from both glucocorticoid and calcium ionophore treatment, 0.3 M NaCl nuclear protein extracts were prepared from control and treated cells and analyzed for protein composition or nuclease activity. To assay for nuclease activity, nuclear extracts were electrophoresed in sodium dodecyl sulfate-polyacrylamide gels impregnated with [32P]DNA. Nuclease activity was detected by removal of sodium dodecyl sulfate from the gel, activation with calcium, and subsequent visualization of the loss of [32P]DNA by autoradiography. Dex treatment of wt cells resulted in the appearance of several proteins within the mol wt range of 12-18 kDa, only one of which (16-18 kDa) exhibited calcium-dependent nuclease activity. The appearance of these proteins in nuclear extracts was inhibited by coincubation of glucocorticoid-treated cells with RU 486. Glucocorticoid treatment did not result in the appearance of nuclease activity in nuclear extracts from nt- cells. Interestingly, A23187 or ionomycin treatment resulted in an increase in activity of the 16- to 18-kDa nuclease in both wt and nt- cells. These findings indicate that both glucocorticoid receptors and calcium may share common features in the regulation of apoptosis in lymphoid cells.     

Fractionation of chick oviduct chromatin. Nuclease-resistant deoxyribonucleic acid.

Chromatin isolated from several chick tissues was treated with micrococcal nuclease. A limited degree of tissue specificity of chromatin DNA resistance to nuclease digestion was observed. No difference in the extent of nuclease resistance of chromatin DNA was detected during oestrogen-induced oviduct differentiation. This suggested that the amount of non-histone chromosomal protein does not play an important role in the sensitivity of chromatin DNA to nuclease digestion. Studies of nuclease resistance of chromatin DNA after dissociation and reconstitution of chromatin proteins and ethanol extraction of chromatin indicate that the histones protect the DNA from nuclease attack. Slow thermal denaturation of nuclease-resistant DNA suggests that the protected DNA sequences may be (A+T)-rich, and the (G+C)-rich satellites present in total chick DNA are sensitive to nuclease.     

Identification and characterization of glucocorticoid-regulated nuclease(s) in lymphoid cells undergoing apoptosis

Apoptosis is a physiological process by which selected cells are deleted from a population in response to specific regulatory signals. A hallmark of apoptosis is the internucleosomal degradation of DNA prior to cell death. We are studying glucocorticoid-induced lymphocytolysis as a model system for apoptosis within the immune system. In rat thymocytes, the internucleosomal DNA cleavage which occurs following glucocorticoid treatment is both time- and dose-dependent, and is blocked by the glucocorticoid antagonist RU 486, indicating that this effect is mediated by the glucocorticoid receptor. Similar experiments using glucocorticoid-responsive (wt) and glucocorticoid-resistant (nt⁻) S49.1 lymphoma cell lines confirm that internucleosomal DNA degradation and cell death are glucocorticoid receptor-mediated events and thus reflect the direct effects of glucocorticoids on lymphocytes. In an effort to identify the nuclease(s) responsible for the DNA degradation, we have developed two assays to detect nucleases whose activity is altered by glucocorticoid treatment. The first assay involves electrophoresing extracts of nuclear protein from control and glucocorticoid-treated lymphoid cells into SDS-polyacrylamide gels containing [³²P]DNA within the gel matrix. This assay is used to estimate the molecular mass of the nuclease, based on the observed in situ nuclease activity. The second assay uses HeLa nuclei as a substrate to detect internucleosomal cleavage activity present in nuclear extracts of control and glucocorticoid-treated lymphoid cells. Using these assays we have identified a novel Ca²⁺, Mg²⁺-dependent nuclease with an apparent molecular weight of 18 kDa in both S49 wt cells and rat thymocytes treated with glucocorticoids. Furthermore, nuclear extracts of glucocorticoid-treated, but not control, rat thymocytes and S49 wt cells were capable of cleaving HeLa chromatin at internucleosomal sites. In an effort to determine the identity of the nuclease capable of internucleosomal cleavage of DNA, nuclear extracts from dex-treated rat thymocytes were fractionated by gel filtration chromatography under non-denaturing conditions, and the fractions were analyzed using the [³²P]DNA SDS-PAGE and HeLa nuclei assays. When analyzed under native conditions, the 18 kDa nuclease described previously appears to exist as a 25 kDa protein which may be part of a high molecular weight complex. Interestingly, only the 25 kDa form of the protein was associated with internucleosomal DNA cleavage activity where as the high molecular weight form of the enzyme was devoid of this activity.     

Vaccinia virus nicking-joining enzyme is encoded by K4L (VACWR035)

Vaccinia virus encodes an enzyme with DNA modifying activity that cleaves and inefficiently cross-links cruciformic DNA. This enzyme is contained within the virion, expressed at late times postinfection, and processes DNA in an energy-independent, Mg2+ ion-independent manner. Viral nuclease activity was measured in extracts from cells infected with well-defined viral mutants. Since some viral extracts lacked nuclease activity, the gene encoding the activity was postulated to be one of the open reading frames absent in the viruses lacking activity. Inducible expression of each candidate open reading frame revealed that only the gene VACWR035, or K4L, was required for nuclease activity. A recombinant virus missing only the open reading frame for K4L lacked nuclease activity. Extracts from a recombinant virus expressing K4L linked to a FLAG polypeptide were able to cleave and cross-link cruciformic DNA. There were no significant differences between the virus lacking K4L and wild-type vaccinia virus WR with respect to infectivity, growth characteristics, or processing of viral replicative intermediate DNA, including both telomeric and cross-linked forms. Purification of the K4L FLAG polypeptide expressed in bacteria yielded protein containing nicking-joining activity, implying that K4L is the only vaccinia virus protein required for the nicking-joining enzymatic activity.     

The endogenous differentiation factor of the HL-60 cells shows a nuclease activity

A structural homology between the endogenous differentiation factor of the HL-60 cell line of promyelocyte leukemia (HLDF) and several DNA/RNA-binding and DNA/RNA-hydrolyzing proteins was revealed, and expression of the hldf gene in prokaryotic systems was studied. On the basis of these experiments, the amino acid sequence of an 8-membered fragment of HLDF with potential nuclease activity was identified. The synthetic octapeptide RRWHRLKE was shown to be capable of the cleavage of RNA, linear DNA from phage lambda, and all forms of plasmid DNA. We established that treatment of the HL-60 cell culture with this peptide (10(-6) M) results in an increase in the number of apoptotic cells and suggested that HLDF is involved in processes of apoptosis.     

Transformation in Bacillus subtilis: involvement of the 17-kilodalton DNA-entry nuclease and the competence-specific 18-kilodalton protein.

A protein complex, consisting of a 17-kilodalton (kDa) nuclease and an 18-kDa protein, is believed to be involved in the binding and entry of donor DNA during transformation of Bacillus subtilis (H. Smith, K. Wiersman, S. Bron, and G. Venema, J. Bacteriol. 156:101-108, 1983). In this paper, the nucleotide sequences of the genes encoding both the nuclease and the 18-kDa protein are presented. The genes are encoded by a 904-base-pair PstI-HindIII fragment. The open reading frames encoding both proteins are partly overlapping. A B. subtilis mutant was constructed by insertion of a Cmr marker into the gene encoding the nuclease. This mutant lacked the competence-specific nuclease activity and the 18-kDa protein but retained 5% residual transformation. The total DNA association of the mutant was higher than that of the wild-type cells, and DNA entry was reduced to 30% of the wild-type level. These results suggest that an alternative pathway exists for the internalization of transforming DNA. A mutant, exclusively deficient for the 18-kDa protein, previously suggested to be involved in the binding of transforming DNA, was constructed by insertion of a kanamycin resistance gene into the coding sequence of the gene. Since the mutant showed wild-type DNA-binding activity, the 18-kDa protein is probably not involved in the binding of donor DNA to competent cells. The transforming activity of the mutant was reduced to 25% of the wild-type level, indicating that the 18-kDa protein has a function in the transformation process. In vitro experiments showed that the 18-kDa protein is capable of inhibiting the activity of the competence-specific nuclease. Its possible role in transformation is discussed.