Radioisotopic Method for Measuring Cell Division Rates of Individual Species of Diatoms from Natural Populations

Silicon is an essential element for diatom frustule synthesis and is usually taken up only by dividing cells. With ⁶⁸Ge, a radioactive analog of Si, the cell cycle marker event of frustule formation was identified for individual species of diatom. The frequency of cells within a population undergoing this division event was estimated, and the cell division rate was calculated. In laboratory cultures, these rates of cell division and those calculated from changes in cell numbers were similar. By dual labeling with ⁶⁸Ge(OH)₄ and NaH¹⁴CO₃, rates of cell division and photosynthesis were coincidently measured for diatoms both in laboratory cultures and when isolated from natural populations in estuarine, offshore, and polar environments. These techniques permit the coupling between photosynthesis and cell division to be examined in situ for individual species of diatom.     

Linear Cell Growth in Escherichia coli

Growth was studied in synchronous cultures of Escherichia coli, using three strains and several rates of cell division. Synchrony was obtained by the Mitchison-Vincent technique. Controls gave no discernible perturbation in growth or rate of cell division. In all cases, mean cell volumes increased linearly (rather than exponentially) during the cycle except possibly for a small period near the end of the cycle. Linear volume growth occurred in synchronous cultures established from cells of different sizes, and also for the first volume doubling of cells prevented from division by a shift up to a more rapid growth rate. As a model for linear kinetics, it is suggested that linear growth represents constant uptake of all major nutrient factors during the cycle, and that constant uptake in turn is established by the presence of a constant number of functional binding or accumulation sites for each growth factor during linear growth of the cell.     

Cell volume increase in Escherichia coli after shifts to richer media.

Synchronous cultures of Escherichia coli 15-THU and WP2s, which were selected by velocity sedimentation from exponential-phase cultures growing in an acetate-minimal salts medium, were shifted to richer media at various times during the cell cycle by the addition of glucose or nutrient broth. Cell numbers and mean cell volumes were measured electronically. The duration of the division cycle of the shifted generation was not altered significantly by the addition of either nutrient. Growth rates, measured as rates of cell volume increase, were constant throughout the cycle in unshifted acetate control cultures. When glucose was added, growth rates also remained unchanged during the remainder of the cell cycle and then increased abruptly at or after cell division. When nutrient broth was added, growth rates remained unchanged from periods of 0.2 to 0.4 generations and then increased abruptly to their final values. In all cases, the cell volume increase was linear both before and after the growth rate transition. The strongest support for a linear cell volume increase during the cell cycle of E. coli in slowly growing acetate cultures, however, was obtained in unshifted cultures, in complete agreement with earlier observations of cell volumes at much more rapid growth rates. Although cell growth and division are under the control of the synthesizing machinery in the cell responsible for RNA and protein synthesis, the results indicate that growth is also regulated by membrane-associated transport systems.     

A mathematical model for cell size control in fission yeast

Experimental investigations of cell size control in fission yeast Schizosaccharomyces pombe have illustrated that the cell cycle features ‘sizer’ and ‘timer’ phases which are distinguished by a growth rate changing point. Based on current biological knowledge of fission yeast size control, we propose here a model of ordinary differential equations (ODEs) for a possible explanation of the facts and control mechanism which is coupled with the cell cycle. Simulation results of the ODE model are demonstrated to agree with experimental data for the wild type and the cdc2-33 mutant. We show that the coupling of cell growth to cell division by translational control may account for observed properties of size control in fission yeast. As the translational control in the expression of cycle proteins Cdc13 and Cdc25 constructs positive feedback loops, the dynamical activities of the key components undergoes a rapid rising after a preliminary stage of slow increase. The coupling of this dynamical behavior to the elongation of the cell naturally gives rise to a rate change point and to ‘sizer’ and ‘timer’ phases, which characterize the cell cycle of fission yeast.     

Alterations in the cell cycle of Drosophila imaginal disc cells precede metamorphosis

Flow cytometric analyses of imaginal disc and brain nuclei of Drosophila melanogaster have been made throughout the third larval instar. In wing, haltere, and leg discs the proportion of cells in the G₂M phase of the cell cycle (tetraploid cells) increases with larval age. In contrast, in the eye disc and in brain the proportion of tetraploid cells, already low at the outset of the instar, declines further. Measurement of growth rates for disc and brain tissue during the same developmental period was carried out by the cell counting procedure of Martin (1982). Our results are consistent with the conclusion that imaginal discs grow exponentially with an apparent doubling time of 5–10 hr from the resumption of cell division (in the first or second larval instar) until about 95 hr, when the apparent doubling time increases. Cell numbers increase until at least 5 hr after formation of white prepupae (122 hr), but during the preceding 10 hr the rate of increase is low. Thus, for wing and leg discs, but not for the eye disc and brain, the declining growth rate is associated with an increase in the proportions of tetraploid cells. In conjunction with cell counts and flow cytometry, fluorometric determination of disc DNA content at 112 hr indicated that the diploid DNA content of imaginal disc nuclei is 0.45 pg.     

Gametic differentiation in Chlamydomonas reinhardi: cell cycle dependency and rates in attainment of mating competency

Withdrawal of a utilizable nitrogen source during mid G₁ of the cell cycle induces gametic differentiation in synchronously grown vegetative cultures of Chlamydomonas reinhardi. Cell division accompanies gametic differentiation in such cultures, and the ability of mid G₁ vegetative cells to form gametes is matched by their ability to undergo a round of cell division after nitrogen withdrawal. Synchronously grown cultures require up to 19 hr in nitrogen-free medium to complete a round of division and to form mating-competent cells. Asynchronously grown liquid cultures require less time after nitrogen withdrawal (generally 5–8 hr) to achieve mating competency. In these cultures cell division did not necessarily accompany gametic differentiation since gametic differentiation took place in induced cultures at high cell concentrations which prevented cell division. Maximum mating competency was achieved in less than 2 hr after induction of vegetative cells grown on agar plates. Little cell division was observed during that short induction interval. The relationship between the attainment of mating competency (gametogenesis) and other physiological events resulting from nitrogen withdrawal is discussed.     

CELL DIVISION RATES OF EUCARYOTIC ALGAE MEASURED BY TRITIATED THYMIDINE INCORPORATION INTO DNA: COINCIDENT MEASUREMENTS OF PHOTOSYNTHESIS AND CELL DIVISION OF INDIVIDUAL SPECIES OF PHYTOPLANKTON ISOLATED FROM NATURAL POPULATIONS1

The cell cycle marker event of DNA replication in eucaryotic algae was identified using ³H-Thymidine (³H-TdR) incorporation. The frequency of cells (F) within a population undergoing DNA replication was estimated and the cell division rate (μF) calculated. In laboratory cultures the rates of cell division calculated from changes in cell numbers (μN) and μF were similar. Dual labelling with ³H-TdR and NaH¹⁴CO₃ enabled rates of cell division and photosynthesis to be coincidently measured for individual species of algae. Using these single species radioisotope techniques, several distinct photosynthesis irradiance and cell division irradiance relationships were found for: (1) different species of phytoplankton isolated from the same sample, and (2) the same species isolated from different environments. These techniques allow the coupling between photosynthesis and cell division to be examined with high resolution for algae in situ.     

Mathematical modeling of fission yeast Schizosaccharomyces pombe cell cycle: exploring the role of multiple phosphatases

Cell cycle is the central process that regulates growth and division in all eukaryotes. Based on the environmental condition sensed, the cell lies in a resting phase G0 or proceeds through the cyclic cell division process (G1??S??G2??M). These series of events and phase transitions are governed mainly by the highly conserved Cyclin dependent kinases (Cdks) and its positive and negative regulators. The cell cycle regulation of fission yeast Schizosaccharomyces pombe is modeled in this study. The study exploits a detailed molecular interaction map compiled based on the published model and experimental data. There are accumulating evidences about the prominent regulatory role of specific phosphatases in cell cycle regulations. The current study emphasizes the possible role of multiple phosphatases that governs the cell cycle regulation in fission yeast S. pombe. The ability of the model to reproduce the reported regulatory profile for the wild-type and various mutants was verified though simulations.     

INFLUENCE OF PHOSPHORUS LIMITATION ON TOXICITY AND PHOTOSYNTHESIS OF ALEXANDRIUM MINUTUM (DINOPHYCEAE) MONITORED BY IN‐LINE DETECTION OF VARIABLE CHLOROPHYLL FLUORESCENCE1

The effects of phosphorus (P) limitation on growth, toxicity, and variable chl fluorescence of Alexandrium minutum were examined in batch culture experiments. Cell division was greatly impaired in P‐limited cultures, but P spiking of these cultures after 9 days stimulated high levels of cell division equivalent to P‐replete cultures. The cellular concentration of paralytic shellfish toxins was consistent over the growth cycle of control cultures from lag phase into logarithmic growth phase, with toxins repeatedly lost to daughter cells during division. The low level of cell division in P‐limited cultures resulted in a 10‐fold increase of cellular toxin compared with controls, but this dropped upon P spiking due to increased rates of cell division. The history of phosphorus supply had an important effect on toxin concentration, with the P‐limited and the P‐spiked cultures showing values 2‐fold higher than the P‐replete cultures. Toxin profiles of the A. minutum strain used in these experiments were dominated by the N₁‐hydroxy toxins, gonyautoxins (GTX) GTX1 and GTX4, which were approximately 40 times more abundant than their analogues, GTX2 and GTX3, in P‐limited cultures. The dominance of the N₁‐hydroxy toxins increased significantly in control cultures as they advanced through logarithmic growth. In‐line measurements of the variable chl fluorescence of light‐adapted cells indicated consistent photochemical efficiency under P‐replete conditions. P limitation induced a drop in fluorescence‐based photochemical efficiency that was reversible by P spiking. There was an inverse linear relationship between in‐line fluorescence and cell toxin quota (r = ?0.88). Monitoring fluorescence in‐line may be valuable in managing efficient biotechnological production of toxins.     

Identification of new cell size control genes in <Emphasis Type="Italic">S. cerevisiae</Emphasis>

Cell size homeostasis is a conserved attribute in many eukaryotic species involving a tight regulation between the processes of growth and proliferation. In budding yeast S. cerevisiae, growth to a “critical cell size” must be achieved before a cell can progress past START and commit to cell division. Numerous studies have shown that progression past START is actively regulated by cell size control genes, many of which have implications in cell cycle control and cancer. Two initial screens identified genes that strongly modulate cell size in yeast. Since a second generation yeast gene knockout collection has been generated, we screened an additional 779 yeast knockouts containing 435 new ORFs (~7% of the yeast genome) to supplement previous cell size screens. Upon completion, 10 new strong size mutants were identified: nine in log-phase cells and one in saturation-phase cells, and 97% of the yeast genome has now been screened for cell size mutations. The majority of the logarithmic phase size mutants have functions associated with translation further implicating the central role of growth control in the cell division process. Genetic analyses suggest ECM9 is directly associated with the START transition. Further, the small (whi) mutants mrpl49Δ and cbs1Δ are dependent on CLN3 for cell size effects. In depth analyses of new size mutants may facilitate a better understanding of the processes that govern cell size homeostasis.     

Cell cycle analysis by culture fractionation

The isolation of age-related cell size classes from cultures of the yeast, Schizosaccharomyces pombe, was carried out in a reorienting gradient zonal rotor. Measurements on cell growth, septa formation, and cell division from time-lapse studies were used to establish the average ages of fractions following culture fractionation. DNA levels for the fractions were used to establish the midpoint of DNA synthesis. This method for studying the cell cycle has the advantage over synchronous growth in that it involves no artificial entrainment of the cells before measurements are made.     

Effects of environmental stresses on the cell cycle of two marine phytoplankton species

Cell cycle phase durations of cultures of Hymenomonas carterae Braarud and Fagerl, a coccolithophore, and Thalassiosira weissflogii Grun., a centric diatom, in temperature-, light- or nitrogen-limited balanced growth were determined using flow cytometry. Suboptimal temperature caused increases in the duration of all phases of the cell cycle (though not equally) in both species, and the increased generation time of nitrogen-limited cells of both species was due almost wholly to expansion of G₁ phase. In H. carterae light limitation caused only G₁ phase to expand, but in T. weissflogii both G₂ + M and G₁ were affected. These results are discussed in relation to cell division phasing patterns of these two species and to models of phytoplankton growth. Simultaneous measurements of protein and DNA on individual cells indicated that under all conditions, the protein content of cells in G₁ was a constant proportion of that of G₂ + M cells. Simultaneous measurements of RNA and protein on each cell indicated that the amounts of these two cell constituents were always tightly correlated. Under conditions of nitrogen limitation both protein and RNA per cell decreased to less than one-third of the levels found in nonlimited cells. This indicates, at least for nitrogen-replete cells, that neither protein nor RNA levels are likely to act as the trigger for cell cycle progression. Strict control by cell size is also unlikely since mean cell volume decreased as growth rates were limited by light and nitrogen supply, but increased with decreasing temperature.     

Evaluation of methods of synchronization of cell division in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Synchronization of cell division in yeast cultures of Saccharomyces cerevisiae is widely used in studies on regulation of eukaryotic gene expression and biochemical processes at different stages of the cell cycle. In this study, we compared the efficacy of modern widely used methodologies to achieve and assess the degree of synchronization of cell division in yeast. Based on the literature and our own data, we propose practical recommendations for synchronization of cell divisions in S. cerevisiae using chemical reagents (alpha-factor, hydroxyurea, nocodazole), and a genetic cell-cycle block (temperature-sensitive mutation cdc28-4).     

Mutagenesis of yeast by hydrazine: dependence upon post-treatment cell division.

Hydrazine was found to be mutagenic for yeast (Saccharomyces cerevisiae) at exposures (concentration × time) ranging over nearly three orders of magnitude. Little or no forward mutation from CAN1 to can1 was detectable upon immediate plating following treatment in neutral buffer suspension. Post-treatment cell division in yeast extract peptone dextrose complex growth medium was required for expression of induced mutation to canavanine resistance. Frequencies of induced mutation rose to levels approximately 10-fold higher than spontaneous levels for exposures between 0.1 and 12.0 min mol/l. Survival remained at 100%. For exposures greater than 80 min mol/l viability and mutation frequency began to decrease sharply. By contrast, single treatments of ethyl methanesulfonate, methyl methanesulfonate, N-methyl-N′-nitro-N-nitro-soguanidine, nitrous acid, hydroxylamine, and ultraviolet light were able to increase mutation frequency with this system upon immediate assay. Further growth-dependent increases in mutation frequency were not observed with HA and UV.Expression of HZ-induced mutation was detectable after treated cells had undergone less than one population doubling in YEPD. Such mutation expression could be blocked by the inhibitors cycloheximide and hydroxyurea, which block protein synthesis and DNA synthesis respectively. Results were similar to those obtained previously with Haemophilus influenzae and similarly suggest that, in this eukaryote, HZ-induced lesions lead to mutation by causing base mispairing at DNA replication rather than by means of an error-prone repair mechanism.     

Potassium Uptake in Synchronous and Synchronized Cultures of Escherichia coli

Criteria are presented for distinguishing between synchronous and synchronized cultures (natural vs. forced synchrony) on the basis of characteristics of growth and division during a single generation. These criteria were applied in an examination of the uptake of potassium during the cell growth and division cycle in synchronous cultures and in a synchronized culture of Escherichia coli. In the synchronous cultures the uptake of ⁴²K doubled synchronously with cell number, corresponding to a constant rate of uptake per cell throughout the cell cycle. In the synchronized culture, uptake rates also remained constant during most of the cycle, but rates doubled abruptly well within the cycle. This constancy of ⁴²K uptake per cell supports an earlier interpretation for steady-state cultures that uptake is limited in each cell by a constant number of functional sites for binding, transport, or accumulation of compounds from the growth medium, and that the average number of such sites doubles late in each cell cycle. The abrupt doubling of the rate of uptake of potassium per cell in the synchronized culture appears because of partial uncoupling of cell division from activation or synthesis of these uptake sites.     

A bimolecular mechanism for the cell size control of the cell cycle

A molecular model for the control of cell size has been developed. It is based on two molecules, one (I) acts as an inhibitor of the entrance into S phase, and it is synthetised just after cell separation in a fixed amount per nucleus. The other (A) is an activator of the S phase, and it is synthetised at a ratio proportional to the overall protein accumulation. The activator reacts stoichiometrically with (I), and after all the (I) molecules have been titrated, (A) begins to accumulate. When it reaches a threshold value, it triggers the onset of DNA replication. This model was tested by simulation and when applied to the case of unequal division explains a number of features of an exponentially growing yeast cell population: (a) the lengths of TP (cycle time of parent cells) and TD (cycle time of daughter cells) verify the condition exp(- KTP ) + exp(- KTD ) = 1; (b) the changes of the average cell size of populations at different growth rates; (c) the frequency of parents and daughters at various growth rates; (d) the increase of cell size at bud initiation for cells of increasing genealogical age; (e) the existence of a TP - TB period (difference between the cycle time of parents and the length of budded phase) that depends linearly upon the doubling time of the population.