Mapping replicational sites in the eucaryotic cell nucleus

We have used fluorescent microscopy to map DNA replication sites in the interphase cell nucleus after incorporation of biotinylated dUTP into permeabilized PtK-1 kangaroo kidney or 3T3 mouse fibroblast cells. Discrete replication granules were found distributed throughout the nuclear interior and along the periphery. Three distinct patterns of replication sites in relationship to chromatin domains in the cell nucleus and the period of S phase were detected and termed type I (early to mid S), type II (mid to late S) and type III (late S). Similar patterns were seen with in vivo replicated DNA using antibodies to 5-bromodeoxyuridine. Extraction of the permeabilized cells with DNase I and 0.2 M ammonium sulfate revealed a striking maintenance of these replication granules and their distinct intranuclear arrangements with the remaining nuclear matrix structures despite the removal of greater than 90% of the total nuclear DNA. The in situ prepared nuclear matrix structures also incorporated biotinylated dUTP into replication granules that were indistinguishable from those detected within the intact nucleus.     

Fine structure of interphase nuclei

The initiation and replication sites of DNA synthesis in the plasmodial nuclei of Physarum polycephalum were studied with electron microscopic autoradiography. By using both thin sectioning and whole mount techniques, it was shown that the dense chromatin masses in the nucleus consisted of predominantly elementary chromatin-like fibrils, approximately 300 Å in diameter while the electron transparent region in the nucleus consisted of predominantly finer fibrils, less than 100 Å in diameter. With electron microscopic autoradiography it was found that (1) the initiation sites of DNA synthesis were definitely in the boundary regions between the dense chromatin masses and the electron transparent region, (2) the initiation and replication sites of DNA synthesis were definitely not on the nuclear membrane, (3) within a few minutes, replication sites migrated from the initiation sites to the electron transparent region and (4) in this electron transparent region, almost all of the nuclear DNA was synthesized.     

Fine Structural in Situ Analysis of Nascent DNA Movement Following DNA Replication

Nascent DNA (newly replicated DNA) was visualized in situ with regard to the position of the previously replicated DNA and to chromatin structure. Localization of nascent DNA at the replication sites can be achieved through pulse labeling of cells with labeled DNA precursors during very short periods of time. We were able to label V79 Chinese Hamster cells for as shortly as 2 min with BrdU; Br-DNA, detected by immunoelectron microscopy, occurs at the periphery of dense chromatin, at individual dispersed chromatin fibers, and within dispersed chromatin areas. In these regions DNA polymerase α was also visualized. After a 5-min BrdU pulse, condensed chromatin also became labeled. When the pulse was followed by a chase, a larger number of gold particles occurred on condensed chromatin. Double-labeling experiments, consisting in first incubating cells with IdU for 20 min, chased for 10 min and then labeled for 5 min with CldU, reveal CldU-labeled nascent DNA on the periphery of condensed chromatin, while previously replicated IdU-labeled DNA has been internalized into condensed chromatin. Altogether, these results show that the sites of DNA replication correspond essentially to perichromatin regions and that the newly replicated DNA moves rapidly from replication sites toward the interior of condensed chromatin areas.     

DNA replication and nuclear architecture

The model of in situ DNA replication provided by immunofluorescence and confocal imaging is compared with observations obtained by electron microscopic studies. Discrepancies between both types of observations call into question the replication focus as a persistent nuclear structure and as a replication entity where DNA replication takes place. Most electron microscopic analyses reveal that replication sites are confined to dispersed chromatin areas at the periphery of condensed chromatin, and the distribution of replication factors exhibits the same localization pattern. Moreover, rapid migration of newly synthesized DNA from the replication sites towards the interior of condensed chromatin regions obviously takes place during S-phase. It implies modifications of replication domains, hardly detectable by fluorescence microscopy. The confrontation of different observations carried out at light microscopic or electron microscopic levels of resolution lead to a conclusion that a combination of in vivo fluorescence analysis with a subsequent ultrastructural investigation performed on the same cells will represent an optimal approach in future studies of nuclear functions in situ.     

Early and late replicating DNA involved in the G1 to S transition in Allium cepa L meristematic cells.

The involvement of portions of the genome replicated at different times of the S period in the regulation of the G1 to S transition was analyzed in Allium cepa L meristem cells. For this, DNA bromosubstitution confined to discrete portions of a previous S period followed by anoxic UVA irradiation (300-400 nm light) was performed in synchronous cells. Sequences replicated in late S appeared to be involved in the positive regulation of the initiation of replication. Hence, cells were prevented from initiating replication if irradiated at mid G1 only when the DNA sequences replicated in the last third of the previous S period were bromosubstituted. Cycloheximide-induced inhibition of protein synthesis at late G1 also prevented the G1 to S transition. Sequences replicated in mid S appeared unrelated to any control of the initiation of replication. On the other hand, sequences replicated in the first third of the S period seemed to be involved in the negative regulation of the initiation of replication, since irradiation after previous bromosubstitution of early replicating DNA sequences advanced G1 cells into the next S phase and increased the proliferative fraction of the population. Finally, the simultaneous inactivation of DNA sequences involved in both positive and negative regulation of replication allowed the cells to enter into S.     

Fine structural in situ analysis of nascent DNA movement following DNA replication

Nascent DNA (newly replicated DNA) was visualized in situ with regard to the position of the previously replicated DNA and to chromatin structure. Localization of nascent DNA at the replication sites can be achieved through pulse labeling of cells with labeled DNA precursors during very short periods of time. We were able to label V79 Chinese Hamster cells for as shortly as 2 min with BrdU; Br-DNA, detected by immunoelectron microscopy, occurs at the periphery of dense chromatin, at individual dispersed chromatin fibers, and within dispersed chromatin areas. In these regions DNA polymerase alpha was also visualized. After a 5-min BrdU pulse, condensed chromatin also became labeled. When the pulse was followed by a chase, a larger number of gold particles occurred on condensed chromatin. Double-labeling experiments, consisting in first incubating cells with IdU for 20 min, chased for 10 min and then labeled for 5 min with CldU, reveal CldU-labeled nascent DNA on the periphery of condensed chromatin, while previously replicated IdU-labeled DNA has been internalized into condensed chromatin. Altogether, these results show that the sites of DNA replication correspond essentially to perichromatin regions and that the newly replicated DNA moves rapidly from replication sites toward the interior of condensed chromatin areas.     

Different types of plant chromatin associated with modified histones H3 and H4 and methylated DNA

Eukaryotic chromosomes are organized into two large and distinct domains, euchromatin and heterochromatin, which are cytologically characterized by different degrees of chromatin compaction during interphase/prophase and by post-synthesis modifications of histones and DNA methylation. Typically, heterochromatin remains condensed during the entire cell cycle whereas euchromatin is decondensed at interphase. However, a fraction of the euchromatin can also remain condensed during interphase and appears as early condensing prophase chromatin. 5S and 45S rDNA sites and telomere DNA were used to characterize these regions in metaphase and interphase nuclei. We investigated the chromosomal distribution of modified histones and methylated DNA in the early and late condensing prophase chromatin of two species with clear differentiation between these domains. Both species, Costus spiralis and Eleutherine bulbosa, additionally have a small amount of classical heterochromatin detected by CMA/DAPI staining. The distribution of H4 acetylated at lysine 5 (H4K5ac), H3 phosphorylated at serine 10 (H3S10ph), H3 dimethylated at lysine 4 or 9 (H3K4me2, H3K9me2), and 5-methylcytosine was compared in metaphase, prophase, and interphase cells by immunostaining with specific antibodies. In both species, the late condensing prophase chromatin was highly enriched in H4K5ac and H3K4me2 whereas the early condensing chromatin was very poor in these marks. H3K9me2 was apparently uniformly distributed along the chromosomes whereas the early condensing chromatin was slightly enriched in 5-methylcytosine. Signals of H3S10ph were restricted to the pericentromeric region of all chromosomes. Notably, none of these marks distinguished classical heterochromatin from the early condensing euchromatin. It is suggested that the early condensing chromatin is an intermediate type between classical heterochromatin and euchromatin.     

DNS-Replikation und Morphologie der X-Chromosomen während der Syntheseperiode bei Microtus agrestis

X-chromosome behaviour of female Microtus agrestis in interphase nuclei with and without large chromocenters was examined in cultured epithelial and fibroblast cells. By means of pulse-labeling, the configuration of the X-chromosomes in these nuclei can be illustrated; staining with pararosaniline-methylgreen seems to be most suitable. According to the replication behaviour, three types of chromatin can be discerned in the X-chromosomes: early replicating euchromatin, late replicating sex chromatin, and very late replicating heterochromatin. In fibroblasts only the sex chromatin forms a single, small chromocenter; in epithelial cells both the sex chromatin and the remaining heterochromatin form large chromocenters. Both types of heterochromatin replicate their DNA in the condensed state. It seems likely that the late replicating segments of the X-chromosomes (sex chromatin and remaining heterochromatin) are condensed in every cell, but they may not always be configurated or even visible as typical chromocenters; these segments could be distributed over a wide range of compact to more or less diffuse superstructures.     

High-resolution detection of newly synthesized DNA by anti-bromodeoxyuridine antibodies identifies specific chromatin domains

We analyzed the incorporation of bromodeoxyuridine (BrdUrd) into DNA in exponentially growing murine erythroleukemia cells (FLC-745), using fluorescent anti-BrdUrd antibodies with light microscopy and flow cytometry. The fine localization of the DNA replicating sites was investigated at the ultrastructural level by using a second antibody conjugated with colloidal gold. The latter approach, which does not require acidic denaturation of the DNA, enables preservation of good morphology and obtains a better resolution power than that of electron microscopic autoradiography, the percentage of labeled cells obtained with the two techniques being comparable. After short BrdUrd pulses, characteristic distribution of the labeling can be identified in the heterochromatin, in interchromatin domains, or at the boundary between the dispersed and the condensed chromatin. Similar patterns are also observable in the nuclear structures which condense after acid denaturation, suggesting that DNA replication takes place at fixed sites associated with the nuclear matrix.     

Cycle specific association of nascent chromatin with nuclear envelope components in Physarum polycephalum.

The action of heparin on isolated nuclei derived from different phases of the mitotic cycle in plasmodia of Physarum polycephalum was studied. Heparin addition at two-fold excess over DNA concentration to nuclei in Mg-free low ionic strength buffer (10 mM TRIS-HC1, 10 mM Na2 HPO4, pH = 8) releases 60-80% of chromatin from S, G2, and mitotic phase nuclei. The RNA/protein ratio of herparin-solubilized cromatin is constant through S and G2 phases, but rises about two-fold at early prophase coincident with nucleolar breakdown. Purified nuclear envelopes were obtained from heparin-treated nuclei by sedimentation according to Bornens procedures (Nature 244, 28, 1973), and examined by transmission electron microscopy. Residual chromatin is seen at all stages with fine network of DNA fibrils in contact with the envelop. Regardless of time in S, 80% of 3H-labeled DNA was released into soluble chromatin with identical 3H/14C ratios. The residual chromatin in nuclear envelopes exhibited a preferential association of early S-DNA in nuclei engaged in early S replication, and late S preferential association in nuclei engaged in late S replication.     

Premature replication of late S period DNA regions in early S nuclei transferred to late S cytoplasm by fusion in Physarum polycephalum.

Fusion of a late S period plasmodium of Physarum polycephalum to an early S period plasmodium causes premature replication of late S replicating regions in the nuclei of the early S plasmodium. The extent of ahead-of-schedule replication of late S replicating regions in early S period nuclei increases to a plateau of 16-20% for fusions with 40-70 min of phase difference, then declines for larger phase differences. The stimulatory factors for late S replicative units are present only in late S plasmodia and appear to act only on late S regions. Once replicated, early S replicating regions are not stimulated to replicate again by fusion to a plasmodium entering the S period. Our data do not discriminate between anti-termination of replication by factors of stop sites on long replicons, and a sequential initiation of replication on new, possibly non-adjacent regions, but does provide evidence that the stimulatory factors are distinct from one another and specific for certain target replicative units.     

Microautoradiographic study of cell proliferation in compensatory renal growth.

DNA synthesis in the renal parenchyma was studied by electron microscopic autoradiography 48 and 72 hours after unilateral nephrectomy in mice and weanling rats. The proportion of labelled nuclei belonging to the epithelium, endothelium, interstitial areas, or circulating cells was evaluated. Most of cells showing DNA synthesis were epithelial but many belonged to stroma. All the nephron segments were found to participate in compensatory hyperplasia, with a greater contribution, however, of the proximal convoluted tubules. DNA synthesis by the capillary endothelial cells occurred later than the peak epithelial mitotic activity. The site of DNA synthesis in nuclei was the euchromatin, the silver grains being uniformly distributed throughout the nuclear areas with condensed chromatin, and more seldom in the nuclear envelope areas or that of the perinucleolar satellites.     

Nuclear matrix involvement in sperm head structural organization

Summary— In the sperm nuclei the DNA is packaged into a highly condensed form and is not organized into nucleosome and solenoid but is bound and stabilized mainly by the protamines that arrange the DNA in an almost crystalline state. As demonstrated for somatic cells, the sperm DNA has been reported to be organized in loop domains attached to the nuclear matrix structures. However, the possible role of the sperm head matrix in maintaining the loop organization in absence of a typical nucleosomal structures has not been fully elucidated. By using in situ nick translation at confocal and electron microscope level, we analyzed the organization of the DNAprotamine complex and its association with the sperm nuclear matrix. The data obtained indicate that the chromatin organization in sperm nuclei is maintained during the sperm condensation by means of interactions with the nuclear matrix at fixed sites. The fine stucture of sperm nucleus and of sperm nuclear matrix, investigated on sections and replicas of freeze-fractured specimens, suggests that the lamellar array, observed by freeze-fracturing in the sperm nuclei, could depend on the inner matrix which presents a regular organization of globular structures possibly involved in the maintenance of chromatin domains in highly condensed sperm nuclei also.     

Structure of interphase nuclei in relation to the cell cycle. Chromatin organization in mouse L cells temperature-sensitive for DNA replication

Mutant lines of mouse L cells, TS A1S9, and TS C1, show temperature- sensitive (TS) DNA synthesis and cell division when shifted from 34 degrees to 38.5 degrees C. With TS A1S9 the decline in DNA synthesis begins after 6-8 h at 38.5 degrees C and is most marked at about 24 h. Most cells in S, G2, or M at temperature upshift complete one mitosis and accumulate in the subsequent interphase at G1 or early S as a result of expression of a primary defect, failure of elongation of newly made small DNA fragments. Heat inactivation of TS C1 cells is more rapid; they fail to complete the interphase in progress at temperature upshift and accumulate at late S or G2. Inhibition of both cell types is reversible on return to 34 degrees C. Cell and nuclear growth continues during inhibition of replication. Expression of both TS mutations leads to a marked change in gross organization of chromatin as revealed by electron microscopy. Nuclei of wild-type cells at 34 degrees and 38.5 degrees C and mutant cells at 34 degrees C show a range of aggregation of condensed chromatin from small dispersed bodies to large discrete clumps, with the majority in an intermediate state. In TS cells at 38.5 degrees C, condensed chromatin bodies in the central nuclear region become disaggregated into small clumps dispersed through the nucleus. Morphometric estimation of volume of condensed chromatin indicates that this process is not due to complete decondensation of chromatin fibrils, but rather involves dispersal of large condensed chromatin bodies into finer aggregates and loosening of fibrils within the aggregates. The dispersed condition is reversed in nuclei which resume DNA synthesis when TS cells are downshifted from 38.5 degrees to 34 degrees C. The morphological observations are consistent with the hypothesis that condensed chromatin normally undergoes an ordered cycle of transient, localized disaggregation and reaggregation associated with replication. In temperature-inactivated mutants, normal progressive disaggregation presumably occurs, but subsequent lack of chromatin replication prevents reaggregation.     

Centromere identity in Drosophila is not determined in vivo by replication timing

Centromeric chromatin is uniquely marked by the centromere-specific histone CENP-A. For assembly of CENP-A into nucleosomes to occur without competition from H3 deposition, it was proposed that centromeres are among the first or last sequences to be replicated. In this study, centromere replication in Drosophila was studied in cell lines and in larval tissues that contain minichromosomes that have structurally defined centromeres. Two different nucleotide incorporation methods were used to evaluate replication timing of chromatin containing CID, a Drosophila homologue of CENP-A. Centromeres in Drosophila cell lines were replicated throughout S phase but primarily in mid S phase. However, endogenous centromeres and X-derived minichromosome centromeres in vivo were replicated asynchronously in mid to late S phase. Minichromosomes with structurally intact centromeres were replicated in late S phase, and those in which centric and surrounding heterochromatin were partially or fully deleted were replicated earlier in mid S phase. We provide the first in vivo evidence that centromeric chromatin is replicated at different times in S phase. These studies indicate that incorporation of CID/CENP-A into newly duplicated centromeres is independent of replication timing and argue against determination of centromere identity by temporal sequestration of centromeric chromatin replication relative to bulk genomic chromatin.     

Electron-radioautographic analysis of 3H-thymidine distribution in the cell nuclei of the Chinese hamster

Three types of the label localization in the nuclei of Chinese hamster fibroblasts, growing for 9 and 13 hours with 3H-thymidine, were detected using electron microscopic autoradiography: 1. The label is relatively evenly distributed throughout the karyoplasm. 2. Silver grains are concentrated as stripes through the nucleus; a high label density is also found in the nuclear periphery and around the nucleolus. 3. The label is mainly concentrated over the condensed chromatin adjacent to the nuclear membrane. The cells labeled in the first half of S-phase and selected with colchicine in postsynthetic phase of the 1st and the 2nd cycles are characterized by the second and third types of label distribution. In the cell nuclei fixed in the postsynthetic period of the second cycle, the label localization in stripes is discontinuous. The results indicate that during cell transition from S to G2 the newly-synthetized DNA changes its localization in the nucleus. It is suggested that the second type of label distribution depends on the interphase chromosome concentration in definite zones of the nuclear volume after S-phase termination, and the third type label localization is connected with the formation of prophase chromosomes.