The regulation of nuclear migration and division during pseudo-mycelium outgrowth in the dimorphic yeast Candida albicans.

The relationships of the first nuclear division during pseudo-mycelial outgrowth in the infectious yeast Candida albicans to pseudo-mycelial length and DNA replication have been investigated. Evidence is presented that the first nuclear division does not occur until the pseudo-mycelium grows to a minimum length equal to or greater than the diameter of the mother cell and until the cells pass through a minimum time period of approx. 150 min which probably reflects the time necessary to complete nuclear DNA replication. Evidence is also presented that pseudo-mycelial outgrowth and nuclear migration occur independently of DNA replication, and that nuclear migration is probably regulated by the length rather than by the volume of the growing pseudomycelium. Similarities to the requirements for nuclear division during budding in Saccharomyces are discussed, and a model for nuclear migration is proposed.     

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.     

The cell cycle of Bacillus subtilis as studied by electron microscopy

Bacillus subtilis strain Marburg was grown exponentially with a doubling time of 65 min. To follow the time course of various cell cycle events, cells were collected by agar filtration and were then classified according to length. The DNA replication cycle was determined by a quantitative analysis of radioautograms of tritiated thymidine pulse labeled cells. The DNA replication period was found to be 45 min. This period is preceded and followed by periods without DNA synthesis of about 10 min.The morphology and segregation of nucleoplasmic bodies was studied in thin sections. B. subtilis contains two sets of genomes. DNA replication and DNA segregation seem to go hand in hand and DNA segregation is completed shortly after termination of DNA replication.Cell division and cell separation were investigated in whole mount preparations (agar filtration) and in thin sections. Cell division starts about 20 min after cell birth; cell separation starts at about 45 min and before completion of the septum.     

Autoradiographic studies of chromosome replication during the cell cycle of Streptococcus faecium.

Analysis of the distribution of autoradiographic grains around cells of Streptococcus faecium which had been either continuously or pulse-labeled with tritiated thymidine (mass doubling time, 90 min) showed a non-Poisson distribution even when the distribution of cell sizes in the populations studied was taken into account. These non-Poisson distributions of grains were assumed to reflect the discontinuous nature of chromosome replication. To study this discontinuous process further, we fitted an equation to the grain distribution observed for the pulse-labeled cells that assumed that in any population of cells there were subpopulations in which there were zero, one, or two replicating chromosomes. This analysis predicted an average time for chromosome replication and for the period between completion of rounds of chromosome replication and division of 55 and 43 min, respectively, which were in excellent agreement with estimates made by other techniques. The present investigation extended past studies in indicating that the initiation and completion of rounds of chromosome replication are poorly phased with increases in cell volume and that the amount of chromosome replication may be different in different cell halves.     

Bacillus subtilis Cell Cycle as Studied by Fluorescence Microscopy: Constancy of Cell Length at Initiation of DNA Replication and Evidence for Active Nucleoid Partitioning

Fluorescence microscopic methods have been used to characterize the cell cycle of Bacillus subtilis at four different growth rates. The data obtained have been used to derive models for cell cycle progression. Like that of Escherichia coli, the period required by B. subtilis for chromosome replication at 37°C was found to be fairly constant (although a little longer, at about 55 min), as was the cell mass at initiation of DNA replication. The cell cycle of B. subtilis differed from that of E. coli in that changes in growth rate affected the average cell length but not the width and also in the relative variability of period between termination of DNA replication and septation. Overall movement of the nucleoid was found to occur smoothly, as in E. coli, but other aspects of nucleoid behavior were consistent with an underlying active partitioning machinery. The models for cell cycle progression in B. subtilis should facilitate the interpretation of data obtained from the recently introduced cytological methods for imaging the assembly and movement of proteins involved in cell cycle dynamics.     

Cellular localization of oriC during the cell cycle of Escherichia coli as analyzed by fluorescent in situ hybridization

The origin of replication of Escherichia coli, oriC, has been labeled by fluorescent in situ hybridization (FISH). The E. coli K12 strain was grown under steady state conditions with a doubling time of 79 min at 28 degrees C. Under these growth conditions DNA replication starts in the previous cell cycle at -33 min. At birth cells possess two origins which are visible as two separated foci in fully labeled cells. The number of foci increased with cell length. The distance of foci from the nearest cell pole has been measured in various length classes. The data suggest: i) that the two most outwardly located foci keep a constant distance to the cell pole and they therefore move apart gradually in line with cell elongation; and ii) that at the initiation of DNA replication the labeled origins occur near the center of prospective daughter cells.     

DNA replication and the nuclear membrane

To investigate the relationship between the nuclear membrane and DNA replication, Chinese hamster cells were labeled with tritiated thymidine and examined by electron microscope autoradiography. Unsynchronized cells were labeled for periods ranging from 0.5 to 20 minutes. There was no relative increase in the frequency of membrane-associated grains with the shorter labeling times, indicating that the replication point is not necessarily close to the nuclear membrane. When cells were synchronized to the beginning of the S period with mitotic selection and hydroxyurea, the percentage of membrane-associated grains was very low, indicating that DNA synthesis is not initiated at the nuclear membrane. When cells synchronized by mitotic selection were labeled at various times throughout the cell cycle, the percentage of peripheral grains was low in early S period and became progressively higher toward late S period as heterochromatin began to replicate. The labeling of Unsynchronized Microtus agrestis cells indicated that much of the peripheral labeling is due to the replication of intercallary heterochromatin. The results indicate that there is no association between the nuclear membrane and DNA replication.     

Deoxyribonucleic Acid Synthesis During Exponential Growth and Microcyst Formation in Myxococcus xanthus

Myxococcus xanthus in exponential phase with a generation time of 270 min contained a period of 50 min during which deoxyribonucleic acid (DNA) synthesis did not take place. After induction of microcysts by the glycerol technique, the DNA content increased 19%. Autoradiographic experiments demonstrated that the DNA made after glycerol induction was not evenly distributed among the microcysts. The distribution of grains per microcyst fits the following model of chromosome replication: in exponential phase, each daughter cell receives two chromosomes which are replicated sequentially during 80% of the divison cycle; after microcyst induction, no chromosomes are initiated. Mathematical formulas were derived which predict the kinetics and discrete probability distribution for several chromosome models.     

Cell cycle parameters of Proteus mirabilis: interdependence of the biosynthetic cell cycle and the interdivision cycle.

We investigated the time periods of DNA replication, lateral cell wall extension, and septum formation within the cell cycle of Proteus mirabilis. Cells were cultivated under three different conditions, yielding interdivision times of approximately 55, 57, and 160 min, respectively. Synchrony was achieved by sucrose density gradient centrifugation. The time periods were estimated by division inhibition studies with cephalexin, mecillinam, and nalidixic acid. In addition, DNA replication was measured by thymidine incorporation, and murein biosynthesis was measured by incorporation of N-acetylglucosamine into sodium dodecyl sulfate-insoluble murein sacculi. At interdivision times of 55 to 57 min murein biosynthesis for reproduction of a unit cell lasted longer than the interdivision time itself, whereas DNA replication finished within 40 min. Surprisingly, inhibition of DNA replication by nalidixic acid did not inhibit the subsequent cell division but rather the one after that. Because P. mirabilis fails to express several reactions of the recA-dependent SOS functions known from Escherichia coli, the drug allowed us to determine which DNA replication period actually governed which cell division. Taken together, the results indicate that at an interdivision time of 55 to 57 min, the biosynthetic cell cycle of P. mirabilis lasts approximately 120 min. To achieve the observed interdivision time, it is necessary that two subsequent biosynthetic cell cycles be tightly interlocked. The implications of these findings for the regulation of the cell cycle are discussed.     

Dependence of Cell Division on the Completion of Chromosome Replication in Caulobacter crescentus

The relationship between chromosome replication and cell division in the stalked bacterium Caulobacter crescentus has been investigated. Two compounds, hydroxyurea and mitomycin C, were found to inhibit completely deoxyribonucleic acid (DNA) synthesis while allowing continued cell growth and elongation. When these inhibitors were added to exponentially growing cultures, cell division stopped after 38 min when hydroxyurea was used and after 33 min when mitomycin C was used. The period of continued cell division corresponds closely to the period previously determined for the postsynthetic gap (G2) in the DNA cycle of this organism. These results indicate that cell division is coupled to the completion of chromosome replication in C. crescentus.     

Fine structures of interphase nuclei : III. Replication site analysis of DNA during the S period of Crepis capillaris

The replication sites and morphological steps of chromosomal condensation during S period in the nuclei of Crepis capillaris root tip cells have been studied with light and electron microscopic autoradiography. From light microscopic autoradiographic observations, the S period can be divided with three portions, early S, mid S, and late S period. Labelled nuclei for each portion of the S period have also been found by using electron microscopic autoradiography. With electron microscopic autoradiography it has been found that in early, mid, and late S period, the replication sites are distributed in the electron transparent regions, interspersed with dense chromatin masses of variable size which are distributed throughout the nucleus. The time-dependent behavior of the label indicates that when compared with either mid or early replicated DNA, a majority of this chromatin, which contains predominantly late replicated DNA, is the earliest chromatin to be organized into the condensed chromatin. They are organized into the condensed chromatin within 15 min after the termination of replication.     

Microphotometric Determination of DNA Contents of Early Developmental Pollen Grains in Tobacco Anther Culture

The Feulgen-DNA contents of microspores, vegetative and generative nuclei of tobacco pollen grains in vivo and in anther culture have been determined by microphotometry. 1. The values of DNA content of vegetative and generative nuclei of the pollen grains selected at definite developmental stages vary between 1C and 2C levels, which coincide with the role of the dynamics of DNA in haploid cell cycle. This method applied in the study of androgenesis in anther culture is proved successful and valid. 2. By the cytomorphological investigation on androgenesis, the pollen embryoid in this experiment results from repeated divisions of the vegetative cell within the pollen grains. 3. In mature pollen grains of the same variety of tobacco in vivo, DNA replication has not occured in vegetative nuclei, in which the level of DNA remains in 1C. 4. In the cultured anthers after 8 days innoculation, 30% of the total pollen grains measured indicate that the vegetative nuclei have completed DNA replication and show 2C level. The pollen grains which have the potential to differentiate into the embryogenie pollen grains, may be distinguished from non-embryogenie ones by this method before any cytomorphological sign appears. The significance of this method in the study of the mechanism of androgenesis is discussed.     

Haploid genome reactivation and recovery by cell hybridization

DNA replication in haploid spermatid nuclei has been induced by hybridization of mouse early spermatids to proliferating HeLa cells. Use of polyethylene glycol rather than inactivated Sendai virus as the cell fusion agent was found to be essential to the production of large numbers of heterokaryons containing spermatid nuclei. DNA replication was detected in the heterokaryons by autoradiography. Density of silver grains over spermatid nuclei closely approximated the grain density over labelled HeLa nuclei in the same heterokaryons. Mouse centromeric heterochromatin appeared to be labelled last during the spermatid DNA synthetic period. On the average, HeLa nuclei in heterokaryons began DNA synthesis before spermatid nuclei. Results indicated, however, that DNA synthesis by HeLa nuclei might not be a prerequisite for spermatid DNA synthesis. These experiments demonstrate induction of DNA synthesis in spermatid nuclei, the first major step toward reactivation and recovery of their haploid genome by cell hybridization.     

Requirements for DNA replication preceding cell division in Tetrahymena pyriformis

Populations of Tetrahymena pyriformis were synchronized by 30 min heat shocks at 34 °C separated by 160 min intervals at the normal growth temperature. The cells initiate DNA synthesis immediately after the cellular division, and the S period of the population lasts about 80 min. It was found that DNA replication is a prerequisite for the following synchronous division. Inhibition of the DNA synthesis in early S by starvation of the cells for thymidine prevents the forthcoming division. However, inhibition in the latter half of S does not prevent the subsequent division. Thus the cells have synthesized enough DNA to permit cell division before the end of a normal S period. These results are discussed in relation to the organization of the genome replication in the highly polyploid macronucleus.     

Morphological analysis of the division cycle of two Escherichia coli substrains during slow growth.

Morphological parameters of the cell division cycle have been examined in Escherichia coli B/r A and K. Whereas the shape factor (length of newborn cell/width) of the two strains was the same at rapid growth (doubling time, tau, less than 60 min), with decreasing growth rate the dimensions of the two strains did change so that B/r A cells became more rounded and B/r K cells became more elongated. The process of visible cell constriction (T period) lasted longer in B/r A than in B/r K during slow growth, reaching at tau = 200 min values of 40 and 17 min, respectively. The time between termination of chromosome replication and cell division (D period) was found to be longer in B/r A than in B/r K. As a result, in either strain completion of chromosome replication seemed always to occur before initiation of cell constriction. Nucleoplasmic separation did not coincide with termination as during rapid growth but occurred in both strains within the T period, about 10 min before cell division.     

Chromosome replication does not trigger cell division in E. coli

An essential part of the chromosome replication origin of E. coli K-12 and B/r was replaced by the plasmid pOU71. The average initiation mass of replication for pOU71 decreases with increasing temperature. The constructed strains were grown exponentially at different temperatures, and cell sizes and DNA content were measured by flow cytometry. The average DNA content increased with increasing temperature, but the cell size distribution was largely unaffected. Furthermore, cells in which DNA replication had not yet initiated (cells in the B period) became less abundant with increasing temperature. The increased DNA content could not be explained by an increase in the length of the C period. It is concluded that chromosome replication does not trigger cell division in E. coli, but that the chromosome replication and cell division cycles of E. coli run in parallel independently of each other.     

Two discrete modes of histone gene expression during oogenesis in Drosophila melanogaster

We have used in situ hybridization to ovarian tissue sections to study the pattern of histone gene expression during oogenesis in Drosophila melanogaster. Our studies suggest that there are two distinct phases of histone gene expression during oogenesis. In the first phase, which occurs during early to middle oogenesis (stages 5-10A), we observe a mosaic pattern of histone mRNA in the 15 nurse cells of the egg chamber: some cells have very high levels of mRNA, while others have little or no mRNA. Our analysis suggests that there is a cyclic accumulation and subsequent degradation of histone mRNA in the egg chamber and that very little histone mRNA is transported into the growing oocyte. Moreover, since the endomitotic replication cycles of the nurse cells are asynchronous during this period, the mosaic distribution of histone message would suggest that the expression of the histone genes in each nurse cell nucleus is probably coupled to DNA replication as in most somatic cells. The second phase begins at stage 10B. During this period, histone gene expression appears to be "induced" in all 15 nurse cells of the egg chamber, and instead of a mosaic pattern, high levels of histone mRNA are found in all cells. Unlike the earlier phase, this expression is apparently uncoupled from the endomitotic replication of the nurse cells (which are completed by the end of stage 10A). Moreover, much of the newly synthesized histone mRNA is transported from the nurse cells into the oocyte where it accumulates and is stored for use during early embryogenesis. Finally, we have also observed tightly clustered grains within nurse cell nuclei in non-denatured tissue sections. As was the case with cytoplasmic histone mRNA, there is a mosaic distribution of nuclear grains from stages 5 to 10A, while at stage 10B, virtually all nurse cell nuclei have grain clusters. These grain clusters appear to be due to the hybridization of nurse cell histone gene DNA to our probe, and are localized in specific regions of the nucleus.     

Escherichia coli DNA distributions measured by flow cytometry and compared with theoretical computer simulations.

A computer simulation routine has been made to calculate the DNA distributions of exponentially growing cultures of Escherichia coli. Calculations were based on a previously published model (S. Cooper and C.E. Helmstetter, J. Mol. Biol. 31:519-540, 1968). Simulated distributions were compared with experimental DNA distributions (histograms) recorded by flow cytometry. Cell cycle parameters were determined by varying the parameters to find the best fit of theoretical to experimental histograms. A culture of E. coli B/r A with a doubling time of 27 min was found to have a DNA replication period (C) of 43 min and an average postreplication period (D) of 22 to 23 min. Similar cell cycle parameters were found for a 60-min B/r A culture. Initiations of DNA replication at multiple origins in one and the same cell were shown to be essentially synchronous. A slowly growing B/r A culture (doubling time, 5.5 h) had an average prereplication period (B) of 2.3 h; C = 2.4 h and D = 0.8 h. It was concluded the the C period has a constant duration of 43 min (at 37 degrees C) at fast growth rates (doubling times, less than 1 h) but increases at slow growth rates. Thus, our results obtained with unperturbed exponential cultures in steady state support the model of Cooper and Helmstetter which was based on data obtained with synchronized cells.