Countercurrent distribution and multiple sedimentation of Chlorella pyrenoidosa during its life cycle

Synchronously and normally grown Chlorella pyrenoidosa cell populations were analysed by countercurrent distribution in aqueous two-polymer phase systems and by a multiple sedimentatation technique. Partition of cells in aqueous phases reflects the surface properties of cells (primarily surface charge) and multiple sedimentation reflects the cells' size-density parameters. It was found that:

1. 1. Synchronized cells that have just divided have the lowest partition of any in the population. Surface charge (as reflected by partition) increases with time after cell division. Cells have the highest partition just prior to division.

2. 2. Synchronized cells that have just divided are the smallest of any in the population. Since size and sedimentation rate increase with time after cell division multiple sedimentation permits the separation of cells of different ages.

3. 3. Both countercurrent distribution and multiple sedimentation studies reveal considerable heterogeneity of synchronized Chlorella populations. The increase in both surface charge and size with cell age does not appear to proceed in a continuous fashion. Rather, it seems to go in a stepwise manner.

4. 4. Non-synchronized cells examined by either countercurrent distribution or multiple sedimentation show two distinct sub-populations. One of these corresponds to the youngest, just divided cells; and the other to cells just prior to cell division. It is suggested that a lag time just prior to cell division and just after cell division explains these results.

5. 5. Countercurrent distribution in two-polymer phases and multiple sedimentation at unit gravity in a suspension medium best suited for the cell under investigation seem to be methods of choice for tracing cell changes during division, maturation and aging and for sub-fractionating such cell populations.

     

Changes of Escherichia coli cell cycle parameters during fast growth and throughout growth with limiting amounts of thymine

It is generally accepted that during fast growth of Escherichia coli, the time (D) between the end of a round of DNA replication and cell division is constant. This concept is not consistent with the fact that average cell mass of a culture is an exponential function of the growth rate, if it is also accepted that average cell mass per origin of DNA replication (M_i) changes with growth rate and negative exponential cell age distribution is taken into account. Data obtained from cell composition analysis of E. coli OV-2 have shown that not only (M_i) but also D varied with growth rate at generation times () between 54 and 30 min. E. coli OV-2 is a thymine auxotroph in which the replication time (C) can be lengthened, without inducing changes in , by growth with limiting amounts of thymine. This property has been used to study the relationship between cell size and division from cell composition measurements during growth with different amounts of thymine. When C increased, average cell mass at the end of a round of DNA replication also increased while D decreased, but only the time lapse (d) between the end of a replication round and cell constriction initiation appeared to be affected because the constriction period remained fairly constant. We propose that the rate at which cells proceed to constriction initiation from the end of replication is regulated by cell mass at this event, big cells having shorter d times than small cells.Abbreviations OD₄₅₀ and OD₆₃₀ Optical density at a given wavelength in nm Dedicated to Dr. John Ingraham to honor him for his many contributions to Science     

High-copy bacterial plasmids diffuse in the nucleoid-free space,replicate stochastically and are randomly partitioned at cell division

Bacterial plasmids play important roles in the metabolism, pathogenesis and bacterial evolution and are highly versatile biotechnological tools. Stable inheritance of plasmids depends on their autonomous replication and efficient partition to daughter cells at cell division. Active partition systems have not been identified for high-copy number plasmids, and it has been generally believed that they are partitioned randomly at cell division. Nevertheless, direct evidence for the cellular location of replicating and nonreplicating plasmids, and the partition mechanism has been lacking. We used as model pJHCMW1, a plasmid isolated from Klebsiella pneumoniae that includes two β-lactamase and two aminoglycoside resistance genes. Here we report that individual ColE1-type plasmid molecules are mobile and tend to be excluded from the nucleoid, mainly localizing at the cell poles but occasionally moving between poles along the long axis of the cell. As a consequence, at the moment of cell division, most plasmid molecules are located at the poles, resulting in efficient random partition to the daughter cells. Complete replication of individual molecules occurred stochastically and independently in the nucleoid-free space throughout the cell cycle, with a constant probability of initiation per plasmid.     

On plasmid incompatibility

In this paper is presented a brief review of the current state of information on plasmid incompatibility followed by a detailed mathematical model dealing with incompatibility between autonomous homogenic plasmids and based on the assumption that the intracellular plasmid copy pool is randomized with respect to assortment during cell division. Two cases are considered: one in which each plasmid copy replicates once in each generation of cell growth (regular replication) and one in which plasmids are chosen at random for replication from a common pool, irrespective of their replication history (random replication). In both cases, it is assumed that the partition of plasmid copies to daughter cells at cell division is regular—existing plasmid copies are divided equally among the two daughter cells (equipartition). In the case of regular replication coupled with equipartition, it is shown that the survival of heteroplasmid cells (cells containing at least one copy of each of two incompatible plasmids) during exponential growth in a nonselective medium is given by H = H₀[1 − 1/(2N − 1)]ⁿ, where H₀ and H are the numbers of heteroplasmid cells after 0 and n generations of growth, respectively, and N is the plasmid copy number in newborn cells. In the second case, (random replication-equipartition), it is shown that the survival of the heteroplasmid population during exponential growth under nonselective conditions is given by H = H₀[(N − 1)(2N + 1)/(2N − 1)(N + 1)ⁿ. Sample calculations are presented to show that segregation is more rapid in the latter than in the former case. Finally, some of the plasmid-linked genetic determinants that might be expected to affect the expression of incompatibility between nonisogenic plasmids are briefly considered. These determinants include recognition specificity for replication origins, recognition specificity, specific activity of copy number control systems, and recognition specificity of partition systems.     

Cell division after inhibition of chromosome replication in Escherichia coli

The residual cell divisions after thymine starvation of exponential cultures of TJK16, a thymine-requiring derivative of Escherichia coli B/r, were evaluated. The results indicate that under the conditions used (glucose minimal medium 37 °), (1) only cells that had terminated a round of replication divided; (2) once termination had occurred, thymine starvation and replication no longer affected the time of cell division; (3) synchronously terminating subpopulations of cells began to divide about 17 min after termination; after that time, the rate of division decreased exponentially. The results confirm the previously inferred asymmetric distribution of D-periods in an exponential population of E. coli bacteria and suggest that an event associated with termination of replication is required for cell division. The method of data evaluation presented can be used to determine the duration of the D-period and to find the parameter values (halflife and onset) of the stochastic phase of the D-period in exponential cultures, eliminating the need for synchronization procedures.     

Bacterial cell division: regulating Z-ring formation

The earliest stage of cell division in bacteria is the formation of a Z ring, composed of a polymer of the FtsZ protein, at the division site. Z rings appear to be synthesized in a bi‐directional manner from a nucleation site (NS) located on the inside of the cytoplasmic membrane. It is the utilization of a NS specifically at the site of septum formation that determines where and when division will occur. However, a Z ring can be made to form at positions other than at the division site. How does a cell regulate utilization of a NS at the correct location and at the right time? In rod‐shaped bacteria such as Escherichia coli and Bacillus subtilis, two factors involved in this regulation are the Min system and nucleoid occlusion. It is suggested that in B. subtilis, the main role of the Min proteins is to inhibit division at the nucleoid‐free cell poles. In E. coli it is currently not clear whether the Min system can direct a Z ring to the division site at mid‐cell or whether its main role is to ensure that division inhibition occurs away from mid‐cell, a role analogous to that in B. subtilis. While the nucleoid negatively influences Z‐ring formation in its vicinity in these rod‐shaped organisms, the exact relationship between nucleoid occlusion and the ability to form a mid‐cell Z ring is unresolved. Recent evidence suggests that in B. subtilis and Caulobacter crescentus, utilization of the NS at the division site is intimately linked to the progress of a round of chromosome replication and this may form the basis of achieving co‐ordination between chromosome replication and cell division.     

Regulation of Deoxyribonucleic Acid Replication and Cell Division in Escherichia coli B/r

Synchronous cultures of Escherichia coli strain B/r were used to investigate the relationship between deoxyribonucleic acid (DNA) replication and cell division. We have determined that terminal steps in division can proceed in the absence of DNA synthesis. Inhibition of DNA replication with nalidixic acid prior to the start of a new round of replication does not stop cell division, which indicates that the start of the round is not essential in triggering cell division. Inhibition of DNA replication at any time prior to the termination of a round of replication completely blocks cell division, which suggests that there may be a link between the end of the replication cycle and the commitment of the cell to divide. Studies that use a temperature-sensitive mutant which is unable to synthesize DNA at the nonpermissive temperature are in complete agreement with those that use nalidixic acid to inhibit DNA synthesis. This adds support to the idea that the treatments employed limit their action to DNA synthesis. Investigation of minicell production indicates that the production of minicells is blocked when DNA synthesis is inhibited with nalidixic acid. Although nuclear segregation is not required for cell division, DNA synthesis is still required to trigger division. The evidence presented suggests strongly that (i) DNA synthesis is essential for cell division, (ii) the end of a round of replication triggers cell division, and (iii) there is considerable time lapse (one-half generation) between the completion of a round of DNA replication and physical separation of the cells.     

Changes in Cell Size and DNA Content in Sulfolobus Cultures during Dilution and Temperature Shift Experiments

Stationary-phase cultures of different hyperthermophilic species of the archaeal genus Sulfolobus were diluted into fresh growth medium and analyzed by flow cytometry and phase-fluorescence microscopy. After dilution, cellular growth started rapidly but no nucleoid partition, cell division, or chromosome replication took place until the cells had been increasing in size for several hours. Initiation of chromosome replication required that the cells first go through partition and cell division, revealing a strong interdependence between these key cell cycle events. The time points at which nucleoid partition, division, and replication occurred after the dilution were used to estimate the relative lengths of the cell cycle periods. When exponentially growing cultures were diluted into fresh growth medium, there was an unexpected transient inhibition of growth and cell division, showing that the cultures did not maintain balanced growth. Furthermore, when cultures growing at 79 degrees C were shifted to room temperature or to ice-water baths, the cells were found to "freeze" in mid-growth. After a shift back to 79 degrees C, growth, replication, and division rapidly resumed and the mode and kinetics of the resumption differed depending upon the nature and length of the shifts. Dilution of stationary-phase cultures provides a simple protocol for the generation of partially synchronized populations that may be used to study cell cycle-specific events.     

The cell cycle in Escherichia coli B/r

Cell division and DNA synthesis were measured in synchronous cultures of E. coll B/r growing in glucose minimal medium at 37 °. The kinetic curves were analysed in order to find the variability of replication initiation, termination, and cell division events during the cell cycle. It is inferred that under the conditions used, cells begin to divide 17 min (D₀ = minimum D-period) after each termination of chromosome replication with a constant probability per unit of time (half-life = 4·5–6 min). This randomness produces an asymmetric frequency distribution of D-periods, similar but mirror-symmetric frequency distributions of initiation and termination periods, a symmetric, non-Gaussian distribution of interdivision intervals, and complex kinetic changes in the rate of DNA synthesis as a function of cell age. The results suggest that replication and division are precisely controlled with respect to mass accumulation, and the apparent variability of cell cycle events would only result from the use of the time of cell separation as a reference point for the definition of cell age rather than initiation or termination of replication.     

Plasmid replication and partition in Escherichiacoli: is the cell membrane the key?

The DNA–membrane complex has been the subject of intensive investigation for over 35 years as the possible site for DNA replication in the prokaryotic cell and the site through which newly synthesized chromosomes are segregated into daughter cells. However, the molecular mechanisms which control these phenomena are, for the most part, poorly understood despite genetic, biochemical, and morphologic evidence in favour of their existence. This is probably due to the transient nature and non-covalent interactions that occur between DNA and the membrane. In addition, there is a paucity of knowledge concerning the nature of the membrane receptors for DNA and whether the membrane plays simply a structural or metabolic role in the two processes. Plasmids can provide important insights into the role of the membrane in replication and partitioning because the plasmid life cycle is relatively simple, with replication occurring during the cell cycle and partitioning during cell division. The replicon model of Jacob et al. (1963, Cold Spring Harbor Symp Quant Biol 28: 329–348) still represents a good conceptual framework (with modifications) to explain how plasmid replication and partitioning are linked by the membrane. In its simplest form, the model focuses on specific membrane binding sites (possibly along the equator of the cell) for plasmid (or bacterial) replication, with the membrane acting as a motive force to separate the newly synthesized replicons and their attached sites into daughter cells. Indeed, proteins involved in both plasmid replication and partitioning have been found in membrane fractions and some plasmids require membrane binding for initiation and an active partitioning. We propose that several factors are critical for both plasmid DNA replication and partitioning. One factor is the extent of negative supercoiling (brought about by an interplay of various topoisomerases, but most importantly by DNA gyrase). Supercoiling is known to be critical for initiation of DNA replication but may also be important for the formation of a partition complex in contact with the cell membrane. Another factor is the presence of specific subdomains of the membrane which can interact specifically with origin DNA and possibly other regions involved in partitioning. Such domains may be induced transiently or be present at all times during the cell cycle.     

Controls over the timing of DNA replication during the cell cycle of fission yeast

The controls acting over the timing of DNA replication (S) during the cell cycle have been investigated in the fission yeast Schizosaccharomyces pombe. The cell size at which DNA replication takes place has been determined in a number of experimental situations such as growth of nitrogen-starved cells, spore germination and synchronous culture of wee mutant and wild-type strains. It is shown that in wee mutant strains and in wild type grown under conditions in which the cells are small, DNA replication takes place in cells of the same size. This suggests that there is a minimum cell size beneath which the cell cannot initiate DNA replication and it is this control which determines the timing of S during the cell cycle of the wee mutant. Fast growing wild-type cells are too large for this size control to be expressed. In these cells the timing of S may be controlled by the completion of the previous nuclear division coupled with a requirement for a minimum period in G1. Thus in S. pombe there are two different controls over the timing of S, either of which can be operative depending upon the size of the cell at cell division. It is suggested that these two controls may form a useful conceptual framework for considering the timing control over S in mammalian cells.     

Mutational bias suggests that replication termination occurs near the dif site, not at Ter sites

In bacteria, Ter sites bound to Tus/Rtp proteins halt replication forks moving only in one direction, providing a convenient mechanism to terminate them once the chromosome had been replicated. Considering the importance of replication termination and its position as a checkpoint in cell division, the accumulated knowledge on these systems has not dispelled fundamental questions regarding its role in cell biology: why are there so many copies of Ter, why are they distributed over such a large portion of the chromosome, why is the tus gene not conserved among bacteria, and why do tus mutants lack measurable phenotypes? Here we examine bacterial genomes using bioinformatics techniques to identify the region(s) where DNA polymerase III‐mediated replication has historically been terminated. We find that in both Escherichia coli and Bacillus subtilis, changes in mutational bias patterns indicate that replication termination most likely occurs at or near the dif site. More importantly, there is no evidence from mutational bias signatures that replication forks originating at oriC have terminated at Ter sites. We propose that Ter sites participate in halting replication forks originating from DNA repair events, and not those originating at the chromosomal origin of replication.     

Noc protein binds to specific DNA sequences to coordinate cell division with chromosome segregation

Coordination of chromosome segregation and cytokinesis is crucial for efficient cell proliferation. In Bacillus subtilis, the nucleoid occlusion protein Noc protects the chromosomes by associating with the chromosome and preventing cell division in its vicinity. Using protein localization, ChAP‐on‐Chip and bioinformatics, we have identified a consensus Noc‐binding DNA sequence (NBS), and have shown that Noc is targeted to about 70 discrete regions scattered around the chromosome, though absent from a large region around the replication terminus. Purified Noc bound specifically to an NBS in vitro. NBSs inserted near the replication terminus bound Noc–YFP and caused a delay in cell division. An autonomous plasmid carrying an NBS array recruited Noc–YFP and conferred a severe Noc‐dependent inhibition of cell division. This shows that Noc is a potent inhibitor of division, but that its activity is strictly localized by the interaction with NBS sites in vivo. We propose that Noc serves not only as a spatial regulator of cell division to protect the nucleoid, but also as a timing device with an important role in the coordination of chromosome segregation and cell division.     

Cell cycle coordination and regulation of bacterial chromosome segregation dynamics by polarly localized proteins

What regulates chromosome segregation dynamics in bacteria is largely unknown. Here, we show in Caulobacter crescentus that the polarity factor TipN regulates the directional motion and overall translocation speed of the parS/ParB partition complex by interacting with ParA at the new pole. In the absence of TipN, ParA structures can regenerate behind the partition complex, leading to stalls and back‐and‐forth motions of parS/ParB, reminiscent of plasmid behaviour. This extrinsic regulation of the parS/ParB/ParA system directly affects not only division site selection, but also cell growth. Other mechanisms, including the pole‐organizing protein PopZ, compensate for the defect in segregation regulation in ΔtipN cells. Accordingly, synthetic lethality of PopZ and TipN is caused by severe chromosome segregation and cell division defects. Our data suggest a mechanistic framework for adapting a self‐organizing oscillator to create motion suitable for chromosome segregation.     

THE EFFECT OF HYDROXYUREA AND FLUORODEOXYURIDINE ON CELL CYCLE EVENTS IN THE CHLOROCOCCAL ALGA SCENEDESMUS QUADRICAUDA (CHLOROPHYTA)1

The effect of hydroxyurea and 5-fluorodeoxyuridine (FdUrd) on the course of growth (RNA and protein synthesis) and reproductive (DNA replication and nuclear and cellular division) processes was studied in synchronous cultures of the chlorococcal alga Scenedesmus quadricauda (Turp.) Bréb. The presence of hydroxyurea (5 mg·L^?1)from the beginning of the cell cycle prevented growth and further development of the cells because of complete inhibition of RNA synthesis. In cells treated later in the cell cycle at the time when the cells were committed to division, hydroxyurea present in light affected the cells in the same way as a dark treatment without hydroxyurea; i. e. RNA synthesis was immediately inhibited followed after a short time period by cessation of protein synthesis. Reproductive processes including DNA replication to which the commitment was attained, however, were initiated and completed. DNA synthesis continued until the constant minimal ratio of RNA to DNA was reached. FdUrd (25 mg·L^?1) added before initiation of DNA replication in control cultures prevented DNA synthesis in treated cells. Addition of FdUrd at any time during the cell cycle prevented or immediately stopped DNA replication. However, by adding excess thymidine (100 mg·L^?1), FdUrd inhibition of DNA replication could be prevented. FdUrd did not affect synthesis of RNA, protein, or starch for at least one cell cycle. After removal of FdUrd, DNA synthesis was reinitiated with about a 2-h delay. The later in the cell cycle FdUrd was removed, the longer it took for DNA synthesis to resume. At exposures to FdUrd longer than two or three control cell cycles, cells in the population were gradually damaged and did not recover at all.     

<Emphasis Type="Italic">Wolbachia</Emphasis> Replication and Host Cell Division in <Emphasis Type="Italic">Aedes albopictus</Emphasis>

Wolbachia pipientis is an obligate intracellular endosymbiont of a range of arthropod species. The microbe is best known for its manipulations of host reproduction that include inducing cytoplasmic incompatibility, parthenogenesis, feminization, and male-killing. Like other vertically transmitted intracellular symbionts, Wolbachias replication rate must not outpace that of its host cells if it is to remain benign. The mosquito Aedes albopictus is naturally infected both singly and doubly with different strains of Wolbachia pipientis. During diapause in mosquito eggs, no host cell division is believed to occur. Further development is triggered only by subsequent exposure of the egg to water. This study uses diapause in Wolbachia-infected Aedes albopictus eggs to determine whether symbiont replication slows or stops when host cell division ceases or whether it continues at a low but constant rate. We have shown that Wolbachia densities in eggs are greatest during embryonation and then decline throughout diapause, suggesting that Wolbachia replication is dependent on host cell replication.     

A new gene controlling the frequency of cell division per round of DNA replication in Escherichia coli

Summary A novel mutant of Escherichia coli, named cfcA1, was isolated from a temperature-sensitive dnaB42 strain, and found to have the following characteristics. Division arrest and lethality induced by inhibition of DNA replication was reduced and delayed in the cfcA1 dnaB42 strain, as compared with the parental dnaB42 strain. Two types of inhibition of division induced by the addition of nalidixic acid or hydroxyurea were suppressed by the cfcA1 mutation. Under permissive conditions for DNA replication, the colony forming ability of cfcA1 cells was significantly reduced as compared with that of cfc ⁺ cells; conversely the division rate of cfcA1 cells was higher than that of cfc ⁺ cells. The cfcA1 mutation partially restored division arrest induced in the thermosensitive ftsZ84 mutant at the restrictive temperature and suppresed the UV sensitivity of the lon mutation. The mutation was mapped at 79.2 min on the E. coli chromosome. Taking these properties into account, it is hypothesized that the cfcA gene is involved in determining the frequency of cell division per round of DNA replication by interacting with the FtsZ protein which is essential for cell division.     

Chloroplast replication in synchronously dividing Euglena gracilis

Summary Chloroplast replication was studied in Euglena gracilis Klebs, strain Z, synchronized by appropriate light-dark cycles. The chloroplasts divide synchronously, at the time of cytokinesis, but with a tighter synchrony than cell division itself. The chloroplasts within one cell are not noticeably better synchronized than those in the whole population. Chloroplast replication and cell division could not be separated by resetting the time of the light-dark cycle which induces the synchrony. These results are discussed for their implications concerning the mechanisms of integrating cell and plastid division.