Size variations and correlation of different cell cycle events in slow-growing Escherichia coli.

Cell lengths have been determined at which cycle events occur in the slow-growing Escherichia coli B/r substrains A, K, and F26. The radioautographic and electron microscope analyses allowed determination of the variations in length at birth, initiation and termination of DNA replication, and initiation of the constriction process and of cell separation. In all three substrains the standard deviation increased between cell birth and initiation of DNA replication. From there on, the standard deviation remained relatively constant until cell separation. These observations are consistent with the presence of a deterministic phase during the cell cycle in which the cell sizes at initation of DNA replication and at cell division are correlated.     

Cell-cell interactions in conjugating Escherichia coli: role of F pili and fate of mating aggregates.

An electron microscopic radioautographic study was made of tritiated thymidine incorporation into the genome of Escherichia coli PAT 84 and of tritiated meso-D,L-2,6-diaminopimelic acid (DAP) into the cell envelope. Pulse-labeled cells growing at 30 degrees C with a doubling time of 170 min were classified according to length by the method of agar filtration. Mathematical analysis of the length distribution led to the assumption of an exponential relation between length and time. A novel DNA replication pattern was found. Within the cell cycle DNA replication terminates at 70 min; then a gap follows of 64 min, after which DNA replication is initiated at 134 min. Thus, the C period is 106 min and the D period is 100 min. Cell constriction starts at 141 min and coincides with initiation of DNA replication. Detailed quantitative analysis of the [3H]thymidine grain frequency distribution allowed the distinction of three groups of cells. The first group incorporated no label, the second group an amount C, and the third group an amount 2 X C. The relative contribution of each group to a particular length class was determined. The data fitted very well into the DNA replication pattern. The same analysis was carried out on DAP pulse-labeled cells. Again, three groups of cells could be distinguished, and their relative contributions to each length class was determined. The group with the double amount of label was especially prominent at the end of the cell cycle. The emergence of this group might represent the acquisition of new lateral growth areas.     

Three-dimensional analysis of DNA replication foci: a comparative study on species and cell type in situ

Chromatin morphology of interphase nuclei in most cell lines of quail (Coturnix coturnix japonica) and chick (Gallus gallus domesticus) embryos shows typical interspecies differences. This intrinsic marker has been used in quail/chick chimerisation experiments, where also differences between cell types were noted. We asked whether similar differences between species and between cell types could be observed in S phase nuclei in situ. In this report, we used bromodeoxyuridine (BrdU) pulse labelling and anti-BrdU immunofluorescence to detect DNA replication foci in the nuclei of identified cells. In the central nervous system of 5- to 7-day-old quail and chick embryos, mesoderm-derived cells with strikingly different morphology and topographical distribution were studied: endothelial, i.e. polarised cells forming continuous tubes, and macrophages, i.e. non-polarised, ameboid or ramified individual cells. Using confocal microscopy, replication foci in the nuclei were assessed quantitatively and three-dimensional visualisations were produced. We consistently observed that: (1) chick, but never quail, nuclei displayed completely confluent replication sites, independent of cell type, and (2) macrophages, but not endothelial cells, had distinct perinucleolar replication sites, independent of species. We thus demonstrate a new relationship between cell type and spatial arrangement of DNA replication sites, and conclude that interspecies differences of chromatin distribution are conserved throughout S phase. Our results strongly recommend that work done on nuclear structure in vitro should not be extrapolated without reservation to cells in vivo. Accepted: 5 January 2000     

Estimating the Total Rate of DNA Replication Using Branching Processes

Increasing the knowledge of various cell cycle kinetic parameters, such as the length of the cell cycle and its different phases, is of considerable importance for several purposes including tumor diagnostics and treatment in clinical health care and a deepened understanding of tumor growth mechanisms. Of particular interest as a prognostic factor in different cancer forms is the S phase, during which DNA is replicated. In the present paper, we estimate the DNA replication rate and the S phase length from bromodeoxyuridine-DNA flow cytometry data. The mathematical analysis is based on a branching process model, paired with an assumed gamma distribution for the S phase duration, with which the DNA distribution of S phase cells can be expressed in terms of the DNA replication rate. Flow cytometry data typically contains rather large measurement variations, however, and we employ nonparametric deconvolution to estimate the underlying DNA distribution of S phase cells; an estimate of the DNA replication rate is then provided by this distribution and the mathematical model.     

Replication foci dynamics: replication patterns are modulated by S-phase checkpoint kinases in fission yeast

Although the molecular enzymology of DNA replication is well characterised, how and why it occurs in discrete nuclear foci is unclear. Using fission yeast, we show that replication takes place in a limited number of replication foci, whose distribution changes with progression through S phase. These sites define replication factories which contain on average 14 replication forks. We show for the first time that entire foci are mobile, able both to fuse and re-segregate. These foci form distinguishable patterns during S phase, whose succession is reproducible, defining early-, mid- and late-S phase. In wild-type cells, this same temporal sequence can be detected in the presence of hydroxyurea (HU), despite the reduced rate of replication. In cells lacking the intra-S checkpoint kinase Cds1, replication factories dismantle on HU. Intriguingly, even in the absence of DNA damage, the replication foci in cds1 cells assume a novel distribution that is not present in wild-type cells, arguing that Cds1 kinase activity contributes to the spatio-temporal organisation of replication during normal cell growth.     

CHANGE OF UBIQUITINATED PROTEINS DURING THE CELL CYCLE IN CHLAMYDOMONAS (CHLOROPHYTA)1

Changes in the amount of heat shock-related ubiquitinated proteins in Chlamydomonas were investigated during the cell cycle and gamete induction. In a division-synchronized culture induced by periodic illumination, the amount of the 28-kDa ubiquitinated protein increased during the dark phase. This increase correlated with the increase of total DNA. Such an increase was repressed when nuclear DNA replication was inhibited with aphidicolin. These results suggest that ubiquitination to form the 28-kDa protein is involved in nuclear DNA replication or during the cell cycle. The amount of 31-kDa ubiquitinated protein gradually increased throughout the light phase and decreased in the dark phase. The amount of 28-kDa ubiquitinated protein also increased during gamete induction caused by nitrogen starvation, while that of the 31-kDa did not. These results suggest that the change of ubiquitination of 28-kDa protein mat play a fundamental role in the cell cycle and gamete induction in Chlamydomonas.     

Cdt1 Interactions in the Licensing Process: A Model for Dynamic Spatio-temporal Control of Licensing

Within each cell cycle, a cell must ensure that the processes of selection of replication origins (licensing) and initiation of DNA replication are well coordinated to prevent re-initiation of DNA replication from the same DNA segment during the same cell cycle. This is achieved by restricting the licensing process to G1 phase when the prereplicative complexes (preRCs) are assembled onto the origin DNA, while DNA replication is initiated only during S phase when de novo preRC assembly is blocked. Cdt1 is an important member of the preRC complex and its tight regulation through ubiquitin-dependent proteolysis and binding to its inhibitor Geminin ensure that Cdt1 will only be present in G1 phase, preventing relicensing of replication origins. We have recently reported that Cdt1 associates with chromatin in a dynamic way and recruits its inhibitor Geminin onto chromatin in vivo. Here we discuss how these dynamic Cdt1-chromatin interactions and the local recruitment of Geminin onto origins of replication by Cdt1 may provide a tight control of the licensing process in time and in space.     

Behavior of mitochondria and their nuclei during amoebae cell proliferation inPhysarum polycephalum

Summary We investigated the manner of mitochondrial DNA (mtDNA) replication and distribution during the culture ofPhysarum polycephalum amoebae cells by microphotometry, anti-BrdU immunofluorescence microscopy, and quantitative hybridization analysis. In amoebae cells ofP. polycephalum, the number of mitochondria per cell and the shape of both mitochondria and mitochondrial nuclei (mt-nuclei) noticeably changed over the culture period. At the time of transfer, about 27 short ellipsoidal shaped mitochondria, which each contained a small amount of DNA, were observed in each cell. The number of mitochondria per cell decreased gradually, while the amount of mtDNA in an mt-nucleus and the length of mt-nuclei increased gradually. Midway through the middle logarithmic growth phase, the number of mitochondria per cell reached a minimum (about 10 mitochondria per cell), but most mtnuclei assumed an elongated shape and contained a large amount of mtDNA. During the late log- and stationary-growth phase, the number of mitochondria per cell increased gradually, while the amount of DNA in an mt-nucleus and mt-nuclei length decreased gradually. Upon completion of the stationary phase, the number and condition of mitochondria within cells returned to that first observed at the time of transfer. The total amount of mtDNA in a cell increased about 1.6-fold the first day, decreased immediately, then maintained a constant level ranging from 130 to 160 T. Except for the fact that mtDNA synthesis began earlier than synthesis of cell nuclei, the rate of increase in mtDNA paralleled that of cell-nuclear DNA throughout the culture. These results indicate that mtDNA is continuously replicated in pace with cell proliferation and the rate of mitochondrial division varies during culture; this mitochondrial division does not synchronize with either mtDNA replication or cell division. Furthermore, we observed the spatial distribution of DNA replication sites along mt-nuclei. Replication began at several sites scattered along an mt-nucleus, and the number of replication sites increased as the length of mt-nuclei increased. These results indicate that mtDNA replication progresses in adjacent replicons, which are collectively termed a mitochondrial replicon cluster.Abbreviations DAPI 4,6-diamidino-2-phenylindole - VIMPCS video-intensified microscope photon counting system - BrdU 5-bromodeoxyuridine - FITC fluorescein isothiocyanate     

Human DNA polymerase epsilon colocalizes with proliferating cell nuclear antigen and DNA replication late, but not early, in S phase.

DNA polymerase epsilon (pol epsilon) has been implicated in DNA replication, DNA repair, and cell cycle control, but its precise roles are unclear. When the subcellular localization of human pol epsilon was examined by indirect immunofluorescence, pol epsilon appeared in discrete nuclear foci that colocalized with proliferating cell nuclear antigen (PCNA) foci and sites of DNA synthesis only late in S phase. Early in S phase, pol epsilon foci were adjacent to PCNA foci. In contrast to PCNA foci that were only present in S phase, pol epsilon foci were present throughout mitosis and the G(1) phase of cycling cells. It is hypothesized from these observations that pol epsilon and PCNA have separate but associated functions early in S phase and that pol epsilon participates with PCNA in DNA replication late in S phase.     

Dynamic relocalization of phage phi 29 DNA during replication and the role of the viral protein p16.7

We have examined the localization of DNA replication of the Bacillus subtilis phage phi 29 by immunofluorescence. To determine where phage replication was localized within infected cells, we examined the distribution of phage replication proteins and the sites of incorporation of nucleotide analogues into phage DNA. On initiation of replication, the phage DNA localized to a single focus within the cell, nearly always towards one end of the host cell nucleoid. At later stages of the infection cycle, phage replication was found to have redistributed to multiple sites around the periphery of the nucleoid, just under the cell membrane. Towards the end of the cycle, phage DNA was once again redistributed to become located within the bulk of the nucleoid. Efficient redistribution of replicating phage DNA from the initial replication site to various sites surrounding the nucleoid was found to be dependent on the phage protein p16.7.     

The consequences of differential origin licensing dynamics in distinct chromatin environments

Eukaryotic chromosomes contain regions of varying accessibility, yet DNA replication factors must access all regions. The first replication step is loading MCM complexes to license replication origins during the G1 cell cycle phase. It is not yet known how mammalian MCM complexes are adequately distributed to both accessible euchromatin regions and less accessible heterochromatin regions. To address this question, we combined time-lapse live-cell imaging with immunofluorescence imaging of single human cells to quantify the relative rates of MCM loading in euchromatin and heterochromatin throughout G1. We report here that MCM loading in euchromatin is faster than that in heterochromatin in early G1, but surprisingly, heterochromatin loading accelerates relative to euchromatin loading in middle and late G1. This differential acceleration allows both chromatin types to begin S phase with similar concentrations of loaded MCM. The different loading dynamics require ORCA-dependent differences in origin recognition complex distribution. A consequence of heterochromatin licensing dynamics is that cells experiencing a truncated G1 phase from premature cyclin E expression enter S phase with underlicensed heterochromatin, and DNA damage accumulates preferentially in heterochromatin in the subsequent S/G2 phase. Thus, G1 length is critical for sufficient MCM loading, particularly in heterochromatin, to ensure complete genome duplication and to maintain genome stability.     

Cell cycle characteristics of crenarchaeota: unity among diversity

The hyperthermophilic archaea Acidianus hospitalis, Aeropyrum pernix, Pyrobaculum aerophilum, Pyrobaculum calidifontis, and Sulfolobus tokodaii representing three different orders in the phylum Crenarchaeota were analyzed by flow cytometry and combined phase-contrast and epifluorescence microscopy. The overall organization of the cell cycle was found to be similar in all species, with a short prereplicative period and a dominant postreplicative period that accounted for 64 to 77% of the generation time. Thus, in all Crenarchaeota analyzed to date, cell division and initiation of chromosome replication occur in close succession, and a long time interval separates termination of replication from cell division. In Pyrobaculum, chromosome segregation overlapped with or closely followed DNA replication, and further genome separation appeared to occur concomitant with cellular growth. Cell division in P. aerophilum took place without visible constriction.     

Organization of DNA replication in Physarum polycephalum. Attachment of origins of replicons and replication forks to the nuclear matrix.

We have investigated the attachment of the DNA to the nuclear matrix during the division cycle of the plasmodial slime mold Physarum polycephalum. The DNA of plasmodia was pulse labelled at different times during the S phase and the label distribution was studied by graded DNase digestion of the matrix-DNA complexes prepared from nuclei isolated by extraction with 2 M NaCl. Pulse labelled DNA was preferentially recovered from the matrix bound residual DNA at any time of the S phase. Label incorporated at the onset of the S phase remained preferentially associated with the matrix during the G2 phase and the subsequent S phase. The occurrence of the pulse label in the matrix associated DNA regions was transiently elevated at the onset of the subsequent S phase. Label incorporated at the end of the S phase was located at DNA regions which, in the G2 phase, were preferentially released from the matrix by DNase treatment. From the results and previously reported data on the distribution of attachment sites it can be concluded that origins of replicons or DNA sites very close to them are attached to the matrix during the entire nuclear cycle. The data further indicate that initiations of DNA replication occur at the same origins in successive S phases. Replicating DNA is bound to the matrix, in addition, by the replication fork or a region close to it. This binding is loosened after completion of the replication.     

Nuclear reorganization of mammalian DNA synthesis prior to cell cycle exit

In primary mammalian cells, DNA replication initiates in a small number of perinucleolar, lamin A/C-associated foci. During S-phase progression in proliferating cells, replication foci distribute to hundreds of sites throughout the nucleus. In contrast, we find that the limited perinucleolar replication sites persist throughout S phase as cells prepare to exit the cell cycle in response to contact inhibition, serum starvation, or replicative senescence. Proteins known to be involved in DNA synthesis, such as PCNA and DNA polymerase delta, are concentrated in perinucleolar foci throughout S phase under these conditions. Moreover, chromosomal loci are redirected toward the nucleolus and overlap with the perinucleolar replication foci in cells poised to undergo cell cycle exit. These same loci remain in the periphery of the nucleus during replication under highly proliferative conditions. These results suggest that mammalian cells undergo a large-scale reorganization of chromatin during the rounds of DNA replication that precede cell cycle exit.     

S-phase patterns of cyclin (PCNA) antigen staining resemble topographical patterns of DNA synthesis. A role for cyclin in DNA replication?

The sequence of cyclin (proliferating cell nuclear antigen, PCNA), antigen staining throughout the cell cycle of African green monkey kidney cells (BS-C-1) has been determined by indirect immunofluorescence using PCNA autoantibodies specific for this protein. Patterns of cyclin staining observed between the beginning of S-phase and maximum DNA synthesis are similar to those reported in human AMA cells [(1985) Proc. Natl. Acad. Sci. USA 82, 3262-3266], while those detected thereafter are significantly different; the most striking feature being the continuous staining of the nucleoli up to or very near the S/G2 border of the cell cycle. Using [3H]thymidine autoradiography and indirect immunofluorescence of the same cells we show a remarkable correlation between cyclin antigen distribution and topographical patterns of DNA synthesis. In addition, we present evidence showing that DNase I treatment of Triton-extracted monolayers abolishes cyclin antigen staining but does not result in a substantial release of this protein. Taken together the above observations argue for a role of cyclin in some aspect of DNA replication.     

Farnesyl Acetate, a Derivative of an Isoprenoid of the Mevalonate Pathway, Inhibits DNA Replication in Hamster and Human Cells

Cells treated with compactin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, the enzyme which catalyzes the rate-limiting step of the mevalonate pathway, are arrested prior to the DNA synthesis (S) phase of the cell cycle. Identification of a specific pathway product or products with a role in DNA replication, however, has remained elusive. In this report we demonstrate that farnesyl acetate, a derivative of the key isoprenoid pathway intermediate farnesyl pyrophosphate, inhibits DNA replication in both Chinese hamster ovary cells and human (HeLa) cells. This effect is revealed by measurement of DNA content using fluorescence-activated cell sorter analysis and by measurement of [³H]thymidine incorporation. We show that cells treated with farnesyl acetate retain protein synthesis capacity as DNA replication is inhibited and remain intact as viewed with the vital stain propidium iodide. The inhibition of DNA replication by farnesyl acetate occurs in cells treated with high levels of compactin and in cells lacking HMG-CoA reductase. These results indicate that farnesyl acetate action is not dependent on metabolism through the isoprenoid pathway and is not the result of the loss of a metabolite required for replication nor the accumulation of a metabolite which is inhibitory. In addition, cells treated with farnesyl acetate for over 6 h are irreversibly blocked from progressing through S phase, a phenomenon which differs sharply from the results with compactin, removal of which results in synchronous progression through S phase. Farnesyl acetate also blocks protein prenylation in cells, to a degree comparable to a known farnesylation inhibitor, BZA-5B. We propose that farnesyl acetate is acting in a manner quite different from the metabolic block caused by compactin, causing a rapid and irreversible block of DNA replication.     

Circadian and ultradian rhythms of proliferation in human ovarian cancer

Synchronous waves of proliferation in tumor cells taken from patients with ovarian cancer were observed using flow cytometry to measure the fraction of cells undergoing DNA replication and displaying tumor-cell-specific immunofluorescence. When saline washings of the abdominal cavity were analyzed at 2-4 hr intervals round-the-clock, the percentage of cells in the chromosome replication cycle (S + G2 percentage) showed 12-hr and often higher frequency rhythms in proliferation. These higher frequency rhythms in DNA replication show a relatively constant phase relationship to the patient's circadian clock with peak proliferation occurring most commonly at 10 a.m. to 12 noon and again at 10 p.m. This proliferation rhythm is therefore partially out of phase with the 24-hr rhythms in proliferation seen in normal cells. The findings on human cancer reveal a fundamental difference in the temporal organization of normal and tumor cell growth that should be exploited for therapeutic benefit.     

Stability and nuclear distribution of mammalian replication protein A heterotrimeric complex

Replication protein A (RPA), a stable complex of three polypeptides, is the single-stranded DNA-binding protein essential for DNA replication in eukaryotic cells. Previous studies of the subcellular distribution and stability of the RPA heterotrimer during the mammalian cell cycle have produced conflicting results. Here, we present evidence that these inconsistencies can be accounted for by the presence of an extractable pool of soluble RPA within the nucleus. Indirect immunofluorescence experiments in both CHO and HeLa cells showed that all three RPA subunits associated specifically with sites of ongoing DNA synthesis, similar to the replication fork protein proliferating cell nuclear antigen. Furthermore, we found no evidence for disassembly of the chromatin-bound heterotrimeric RPA complex in vivo. Our results are consistent with a role for RPA in the initiation and elongation steps of replication, as previously defined in the viral in vitro replication systems.