Suppression and stimulation of DNA synthesis by ADP-ribosylation of nuclear proteins from adult hen and chick embryo liver.

The stimulation of DNA synthesis by ADP-ribosylation of nuclear proteins was observed in chick embryo liver nuclei. In contrast, a significant decrease in template activity was detected in hen liver nuclei treated with NAD. When a 0.35 M NaCl extract from embryo, but not adult, liver nuclei was treated with NAD and then combined with either adult or embryo liver nuclear residue, the ability to activate the template was greatly enhanced. These results indicate that in the chick embryo liver, the ADP-ribosylation of the nuclei plays an important role as a regulator of DNA synthesis.     

The effect of age on the response of the detrusor to intracellular mechanical stimulus: DNA replication and the cell actin matrix.

Benign prostatic hypertrophy and posterior urethral valves present at both extremes of the age spectrum. Both disease processes can obstruct the urinary stream and ultimately have pathophysiological effects on detrusor structure and function. The mechanisms regulating the structural reorganization of the detrusor to a mechanical outflow obstruction are not known. In an attempt to identify maturational differences in myocyte ultrastructure and consequent effects these might have in modifying the response of the detrusor to mechanical stimulus, we studied differences in dynamic nuclear-cytoskeletal interactions in detrusor tissue in an animal model. Using a drug which specifically severs actin, cytochalasin D (CD), as an intracellular mechanical stimulus, we measured changes in nuclear area and the rate of DNA synthesis in detrusor myocytes from young (2-3 week) and old (8-12 mon) guinea pigs. We found that there were age specific differences to intracellular mechanical stimuli in detrusor muscle. Nuclei of myocytes from young animals showed elastic recoil on severing the cell actin matrix and the tissue from young animals increased replicative DNA synthesis with an intracellular stimulus. In contrast, nuclear shape changes in myocytes from old animals suggested less elasticity, and there was no increase in DNA synthesis with disruption of the cell actin matrix. Anti-alpha-smooth muscle actin antibody and rhodamine phalloidin staining of actin in cytochalasin D treated primary explants of detrusor myocytes showed dose dependent disruption of the actin component of the cytoskeleton. These results suggest that there are fundamental modifications in detrusor myocyte ultrastructure with age. These maturational changes might result in differences in the pathophysiological and structural reorganization of the detrusor in response to outflow obstruction in infancy and adulthood. Furthermore, they suggest that 1) a tensile equilibrium exists between the myocyte nucleus and cytoskeleton; 2) there appears to be a decrease in myocyte nuclear elasticity with ageing; 3) release of nuclear template restrictions increases activity of DNA polymerase alpha in young, but not old, detrusor myocytes; and 4) mechanico-chemical signal transduction in detrusor myocytes may be mediated via the cytoskeleton. In addition, based on previous reports of actin within the nucleus, the results suggest that 1) nuclear actin may have a homeostatic structural role, maintaining the tensile equilibrium between nucleus and cytoskeleton, and 2) integrity of nuclear actin may function to maintain the spatial template restriction on DNA polymerase alpha activity.     

The sperm nuclear matrix is required for paternal DNA replication

The mammalian sperm nucleus provides an excellent model for studying the relationship between the formation of nuclear structure and the initiation of DNA replication. We previously demonstrated that mammalian sperm nuclei contain a nuclear matrix that organizes the DNA into loop domains in a manner similar to that of somatic cells. In this study, we tested the minimal components of the sperm nucleus that are necessary for the formation of the male pronucleus and for the initiation of DNA synthesis. We extracted mouse sperm nuclei with high salt and dithiothreitol to remove the protamines in order to form nuclear halos. These were then treated with either restriction endonucleases to release the DNA not directly associated with the nuclear matrix or with DNAse I to digest all the DNA. The treated sperm nuclei were injected into oocytes, and the paternal pronuclear formation and DNA synthesis was monitored. We found that restriction digested sperm nuclear halos were capable of forming paternal pronuclei and initiating DNA synthesis. However, when isolated mouse sperm DNA or sperm DNA reconstituted with the nuclear matrices were injected into oocytes, no paternal pronuclear formation or DNA synthesis was observed. These data suggest that the in situ nuclear matrix attachment organization of sperm DNA is required for mouse paternal pronuclear DNA synthesis.     

Nuclear ultrastructure: Condensed chromatin in plants is species-specific (karyotypical), but not tissue-specific (functional)

Summary In contrast to mammalian cell nuclei those of plants display nearly an identical ultrastructure in all developmental stages and tissues. This indicates that the gross organization of chromatin is species-specific, but not tissue-specific and function-dependent. The species-specific nuclear ultrastructure is determined by the basic nuclear DNA content (2 C value). The higher the DNA content, the more the euchromatin remains in the condensed state during interphase, but to a lower coiling order than the heterochromatin.Some difficulties in the interpretation of electron micrographs of cell nuclei, and the possible role of repetitive DNA sequences in the karyotypical condensation of euchromatin in plants are discussed.     

Biochemical aspects of cardiac muscle differentiation. Determination of deoxyribonucleic acid template availability and 3′-hydroxyl termini in nuclei and chromatin by using exogenous deoxyribonucleic acid polymerases

Experiments were designed to determine whether DNA synthesis ceases in terminally differentiating cardiac muscle of the rat because the activity of the putative replicative DNA polymerase (DNA polymerase alpha) is lost or whether the activity of this enzyme is lost because DNA synthesis ceases. DNA-template availability and 3'-hydroxyl termini in nuclei and chromatin, isolated from cardiac muscle at various times during the developmental period in which DNA synthesis and the activity of DNA polymerase alpha are decreasing, were measured by using Escherichia coli DNA polymerase I, Micrococcus luteus DNA polymerase and DNA polymerase alpha under optimal conditions. Density-shift experiments with bromodeoxyuridine triphosphate and isopycnic analysis indicate that DNA chains being replicated semi-conservatively in vivo continue to be elongated in isolated nuclei by exogenous DNA polymerases. DNA template and 3'-hydroxyl termini available to exogenously added DNA polymerases do not change as cardiac muscle differentiates and the rate of DNA synthesis decreases and ceases in vivo. Template availability and 3'-hydroxyl termini are also not changed in nuclei isolated from cardiac muscle in which DNA synthesis had been inhibited by administration of isoproterenol and theophylline to newborn rats. DNA-template availability and 3'-hydroxyl termini, however, were substantially increased in nuclei and chromatin from cardiac muscle of adult rats. This increase is not due to elevated deoxyribonuclease activity in nuclei and chromatin of the adult. Electron microscopy indicates that this increase is also not due to dispersal of the chromatin or disruption of nuclear morphology. Density-shift experiments and isopycnic analysis of DNA from cardiac muscle of the adult show that it is more fragmented than DNA from cardiac-muscle cells that are, or have recently ceased, dividing. These studies indicate that DNA synthesis ceases in terminally differentiating cardiac muscle because the activity of a replicative DNA polymerase is lost, rather than the activity of this enzyme being lost because DNA synthesis ceases.     

Characteristics of DNA replication in isolated nuclei initiated by an aprotinin-binding protein

Isolated cell nuclei were used as the source of template DNA to investigate the role of a cytosolic aprotinin-binding protein (ADR) in the initiation of eukaryotic DNA replication. Computerized image cytometry demonstrated that the DNA content of individual nuclei increased significantly following incubation with ADR-containing preparations, and the extent of DNA synthesis is consistent with that allowed by the limiting concentration of dTTP. Thus, dTTP incorporation into isolated nuclei represents DNA synthesis and not parent strand repair. We found that dTTP incorporation into the isolated nuclei is dependent on DNA polymerase α (a principal polymerase in DNA replication) but that DNA polymerase β (a principal polymerase in DNA repair processes) does not play a significant role in this system. Finally, neither aprotinin nor a previously described cytosolic ADR inhibitor can block the replication of nuclease-treated calf thymus DNA, while both strongly inhibit replication of DNA in isolated nuclei. This result, coupled with the relative ineffectiveness of nuclease-treated DNA compared with nuclear DNA to serve as a replicative template in this assay, argues against a significant contribution from repair or synthesis which initiates at a site of DNA damage. These data indicate that ADR-mediated incorporation of ³H-dTTP into isolated nuclei results from DNA replicative processes that are directly relevant to in vivo S phase events. © 1993 Wiley-Liss, Inc.     

Studies on the decondensation of human, mouse, and bull sperm nuclei by heparin and other polyanions

We report heparin-induced decondensation of human, mouse, and bull sperm nuclei. Decondensation did not occur if the spermatozoa were intact but only if the membranes were severely damaged by freezing and thawing or by treatment with a detergent. If a disulphide bond reducing agent (thiol) was absent, decondensation of human sperm nuclei was usually a relatively slow process, with large interindividual variation. Mouse and bull sperm nuclei did not decondense in the absence of a thiol. With a thiol relatively low concentrations of heparin induced a rapid decondensation of the sperm nuclei of all three species. The decondensation activity was not specific for heparin; other polyanions were also active, with heparin being the most effective compound. It is supposed that heparin and other polyanions induce sperm nuclear decondensation because they deplete protamines from the chromatin. Thus the negatively charged phosphate groups of the DNA are no longer opposed by positively charged protamines. Consequently the mutual repulsion of unopposed phosphate groups causes the DNA molecules to stretch, which results in an increase of the sperm nuclear volume. Since heparin and other polyanions induce decondensation under physiological pH and temperature, polyanions might also be active in the oocyte.     

Reconstitution of endogenous DNA synthesis in isolated nuclei and template activity of chromatin with respect to mode of inhibition by aphidicolin

We succeeded in reconstituting the endogenous nuclear DNA synthesis of the sea urchin. Endogenous DNA synthesis of isolated nuclei was reconstituted by mixing the salt-treated nuclei (chromatin exhibiting essentially no endogenous DNA synthesis) and the salt extract containing DNA polymerase-alpha. DNA synthesis in this reconstitution system showed a level of activity and a mode of inhibition by aphidicolin similar to those of the original isolated nuclei (noncompetitive with respect to dCTP). On the other hand, the inhibitory mode was competitive with respect to dCTP in DNA synthesis in the reconstituted system obtained from the chromatin and purified DNA polymerase-alpha, indicating that some other factor(s) in addition to DNA polymerase-alpha is necessary for the reconstitution with reference to the inhibitory mode of aphidicolin. We also studied the template activity of the chromatin. When chromatin was used as a template, inhibition by aphidicolin of DNA polymerase-alpha was noncompetitive and uncompetitive with respect to the template at high and low concentrations, respectively. Treatment of chromatin with 5 M urea gave urea-treated chromatin (nonhistone protein-deprived chromatin) and the extract (mainly nonhistone protein fraction). Inhibition by aphidicolin of DNA polymerase-alpha was uncompetitive with respect to the urea-treated chromatin. However, when chromatin reconstituted from the urea-treated chromatin and the extract was used as a template, the inhibitory mode by aphidicolin was similar to that with original chromatin, indicating that the nonhistone protein fraction contained factor(s) which modified the inhibitory mode of aphidicolin. Thus, the inhibitory mode of aphidicolin is a useful parameter for monitoring the resolution and reconstitution of endogenous DNA synthesis of isolated nuclei.     

Replication of Xenopus erythrocyte nuclei in a homologous egg extract requires prior proteolytic treatment

Reactivation and reinitiation of DNA replication in quiescent frog erythrocyte nuclei has been analyzed following incubation in extracts prepared from activated Xenopus eggs. Nuclear decondensation and DNA synthesis only occurred if nuclei were pretreated with low doses of trypsin. This protease treatment did not digest histones, but did degrade several nonhistone proteins. Activated erythrocyte nuclei swell and begin DNA synthesis by 30 min after being mixed with the egg extract. In some extracts virtually complete genome replication was achieved in all nuclei after 2-3 hr. Addition of several protease inhibitors during sperm nuclear isolation significantly reduced the template efficiency of these preparations. We concluded that proteolytic alteration of nonhistone nuclear structural proteins may be a general mechanism which permits quiescent nuclei to reenter the replication cycle. Erythrocyte nuclei and egg extracts provide an excellent experimental system in which to investigate the processes of nuclear reactivation.     

The effect of phospholipase C on DNA synthesis, morphology and phospholipid content of isolated HeLa cell nuclei.

Isolated HeLa cell nuclei have been treated with purified phospholipase C (Bacillus cereus) and sphingomyelinase (Staphylococcus aureus). The phospholipids of untreated nuclei consisted of about 67% phosphatidylcholine, 23% phosphatidylethanolamine, 7% sphingomyelin, 2% phosphatidylserine and 1% phosphatidylinositol. Phospholipase C degraded 80-90% of the total phospholipids of the nuclei. Such nuclei seemed ultrastructurally intact, and had an average diameter and a protein loss during incubation which were not significantly different from those of controls. Their rate of DNA synthesis was only slightly reduced after treatment with phospholipase C alone and slightly more reduced when phospholipase C was used in combination with sphingomyelinase. This suggests that the polar head-groups of the nuclear phospholipids are of very limited importance in DNA synthesis. Since it has been reported that phospholipase C treatment releases nascent DNA from a membrane complex, the absence of a concommitant reduction in DNA synthesis may suggest that this complex is not necessary for the replication of DNA. Phospholipase C did not significantly influence the stability of the DNA product and gave only a slight inhibition of cytosol and nuclear DNA polymerases when tested with exogenous template.     

DNA synthesis in nuclei and nuclear matrices of regenerating rat liver: Effect of whole-body gamma irradiation

Summary Partial hepatectomy (PH) of rats (Wistar strain) resulted in acceleration of DNA synthesis in liver which reached a maximum at 36 h after PH. Whole-body radiation exposure (10 Gy) of the rats at 12 h after PH completely arrested this stimulation in DNA synthesis. The elevation of DNA synthetic rate in response to PH and complete obliteration of this stimulation by whole-body radiation exposure were found to be the reflection of levels of DNA polymerase-alpha in nuclei and nuclear matrices isolated from the rat livers. Studies based on assays of DNA polymerase in nuclei and nuclear matrices, with and without exogenous DNA template (activated calf thymus DNA), revealed that whole-body irradiation blocked induction of DNA polymerase-alpha and, in turn, assembling of DNA polymerizing apparatus. Irradiation of nuclei (suspended in buffer) in vitro at doses as high as 500 Gy did not have any inhibitory effect on DNA polymerase-alpha activitiy.     

Ultrastructure of meristematic cells of dormant and released buds in Tradescantia paludosa

The lateral bud meristems of Tradescantia paludosa show a characteristic cytohistological zonation during dormancy. The cells comprising this so called ‘zone of inhibition’, which is located at the extreme tip of the bud apex, rarely synthesize nuclear DNA or undergo mitotic division. These nuclei are as large as prophase nuclei, yet contain only telophase (2C) amounts of DNA and significantly lower amounts of histone as compared to the 2C nuclei of the actively dividing cells.Ultrastructural observations of the nuclei in the ‘zone of inhibition’ show that a large proportion of the chromatin is organized as less condensed, diffuse, euchromatin fibrils; however, the chromatin of the actively dividing nuclei of the cells outside the ‘zone of inhibition’ or in the released bud meristems is organized to a greater extent as condensed clumps of heterochromatin. When the dormancy is released, the nuclei in the ‘zone of inhibition’ synthesize DNA and histone and undergo cell division in approx. 4 days. Striking changes in the organization of chromatin fibrils take place during this transition period. The diffuse chromatin fibrils of the nuclei in the ‘zone of inhibition’ progressively become more and more condensed as the cell prepares to undergo the first mitotic division after the release of dormancy. This change which is coupled with the synthesis of histones in the nuclei of the ‘zone of inhibition’ suggests a prominent structural role of these basic proteins in the organization of the chromatin. The large volume of 2C nuclei of the ‘zone of inhibition’ seems, therefore, to result not from a great nuclear mass, but probably from a relatively small degree of condensation of chromatin.     

Organization in the cell nucleus: divalent cations modulate the distribution of condensed and diffuse chromatin

The organization of rat liver nuclei in vitro depends on the ionic milieu. Turbidity measurements of nuclear suspensions in the presence of varying concentrations of divalent cations have been correlated with nuclear ultrastructure. The concentration of MgCl2 (2 mM) at which turbidity of nuclear suspensions is maximal and chromatin condensation appears most extensive is the same concentration that reportedly (Gottesfeld et al., 1974, Proc. Natl. Acad. Sci. U. S. A. 71:2193-2197) precipitates "inactive" chromatin. Thus, a mechanism is suggested by which chromatin activity and ultrastructural organization within the nucleus may be mediated. The nuclear organizational changes attendant upon the decrease in divalent cation concentration were not entirely reversible.     

DNA synthesis in the fertilizing hamster sperm nucleus: sperm template availability and egg cytoplasmic control

To assess the role of the availability of sperm nuclear templates in the regulation of DNA synthesis, we correlated the morphological status of the fertilizing hamster sperm nucleus with its ability to synthesize DNA after in vivo and in vitro fertilization. Fertilized hamster eggs were incubated in 3H-thymidine for varying periods before autoradiography. None of the decondensed sperm nuclei nor early (Stage I) male pronuclei present after in vivo or in vitro fertilization showed incorporation of label, even in polyspermic eggs in which more advanced pronuclei were labeled. In contrast, medium-to-large pronuclei (mature Stage II pronuclei) consistently incorporated 3H-thymidine. To investigate the contribution of egg cytoplasmic factors to the regulation of DNA synthesis, we examined the timing of DNA synthesis by microinjected sperm nuclei in eggs in which sperm nuclear decondensation and male pronucleus formation were accelerated experimentally by manipulation of sperm nuclear disulfide bond content. Although sperm nuclei with few or no disulfide bonds decondense and form male pronuclei faster than nuclei rich in disulfide bonds, the onset of DNA synthesis was not advanced. We conclude the the fertilizing sperm nucleus does not become available to serve as a template for DNA synthesis until it has developed into a mature Stage II pronucleus, and that, as with decondensation and pronucleus formation, DNA synthesis also depends upon egg cytoplasmic factors.     

Release of template restriction for DNA synthesis by poly ADP(ribose) polymerase during the HeLa cell cycle.

The degree of complexing between DNA and chromosomal proteins and the ability of poly adenosine diphosphate ribosylation (ADP-ribosylation) of nuclear proteins to release this template restriction and expose DNA primer site changes during the HeLa cell cycle. Primer site exposure by NAD and poly ADP(ribose) polymerase was assessed with intact nuclei by single deoxynucleotide incorporation into DNA in the presence of saturating bacterial DNA polymerase. The most marked in vitro enhancement of primer site exposure by ADP-ribosylation occurred in early G1 phase, where cellular template restriction was the greatest. Cytoplasmic DNA polymerase also had high activity in early G1 phase of the cell cycle. Streptozotocin reduces NAD pools in HeLa cells; a concomitant stimulation of nuclear poly ADP(ribose) polymerase activity is noted.     

Nucleocytoplasmic sorting of macromolecules following mitosis: fate of nuclear constituents after inhibition of pore complex function

PtK2 cells in which pore complex-mediated transport is blocked by microinjection early in mitosis of a monoclonal antibody (specific for an Mr 68,000 pore complex glycoprotein) or of wheat germ agglutinin (WGA) complete cytokinesis. However, their nuclei remain stably arrested in a telophase-like organization characterized by highly condensed chromatin and the absence of nucleoli, indicating a requirement for pore-mediated transport for the reassembly of interphase nuclei. We have now examined this requirement more closely by monitoring the behavior of individual nuclear macromolecules in microinjected cells using immunofluorescence microscopy and have investigated the effect of microinjecting the antibody or WGA on cellular ultrastructure. The absence of nuclear transport did not affect the sequestration into daughter nuclei of components such as DNA, DNA topoisomerase I and the nucleolar protein fibrillarin that are carried through mitosis on chromosomes. On the other hand, lamins, snRNAs and the p68 pore complex glycoprotein, all cytoplasmic during mitosis, remained largely cytoplasmic in the telophase-arrested cells. Electron microscopy showed the nuclei to be surrounded by a double-layered membrane with some inserted pore complexes. In addition, however, a variety of membranous structures with associated pore complexes was regularly noted in the cytoplasm, suggesting that chromatin may not be essential for the postmitotic formation of pore complexes. We propose that cellular compartmentalization at telophase is a two-step process. First, a nuclear envelope tightly encloses the condensed chromosomes, excluding non-selectively all macromolecules not associated with the chromosomes. Interphase nuclear organization is then progressively restored by selective pore complex-mediated uptake of nuclear proteins from the cytoplasm.     

Co-amplified markers alternate in megabase long chromosomal inverted repeats and cluster independently in interphase nuclei at early steps of mammalian gene amplification.

Two-colour in situ hybridization with probes for two co-amplified markers located several megabases apart on chromosome 1 has been used to analyse early stages of adenylate deaminase 2 (AMPD2) gene amplification in Chinese hamster cells. In the amplified chromosomal structures, the distribution of hybridization spots identifies megabase-long inverted repeats. Their organization is remarkably well accounted for if breakage-fusion-bridge cycles involving sister chromatids drive the amplification process at these early stages. During interphase the markers often segregate into distinct nuclear domains. Many nuclei have bulges or release micronuclei, carrying several copies of one or both markers. These observations indicate that the amplified units destabilize the nuclear organization and eventually lead to DNA breakage during interphase. We propose a model in which interphase breakage has a role in the progression of gene amplification.     

ADP-ribosylation of nuclear proteins in rat ventral prostate during ageing

Poly(ADPR)polymerase activity and poly(ADP-ribosyl)ation of nuclear proteins have been investigated in ventral prostate nuclei of different aged rats (14, 28, 60, 180, 360 day old animals), by reverse-phase HPLC and acetic acid-urea polyacrylamide gel electrophoresis. The major ADP-ribose acceptor proteins were identified as histone H1 and H2b. It is concluded that concomitant with major changes to chromatin organization, poly(ADP-ribosyl)ation reaction is progressively inhibited during aging of rat ventral prostate. These results support the hypothesis that prostatic dysfunction in senescent animals is related to a failure of DNA repair mechanisms and deregulated template activity.     

Microtubule-associated protein-2 stimulates DNA synthesis catalyzed by the nuclear matrix

Microtubule-associated protein-2 (MAP-2) isolated from porcine brains stimulated DNA synthesis catalyzed by the nuclear matrix isolated from Physarum polycephalum in the presence of activated DNA as exogenous templates. The degree of the stimulation depended on the amount of the nuclear matrix, but not on that of the template. MAP-2 also stimulated DNA polymerase alpha activity solubilized from nuclei, but not DNA polymerase beta activity. These results suggest that MAP-2 stimulates DNA synthesis by interacting with the putative DNA replication machinery including DNA polymerase alpha bound to the matrix. Similar stimulation occurred in the nuclear matrix isolated from HeLa and rat ascites hepatoma cells, which strongly suggests that MAP-2 is involved in the control of DNA replication in eukaryotic cells.