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.     

Synthesis of photoreactivating enzyme in synchronous and asynchronous cultures of Escherichia coli

The technique of flash photolysis was used to study cellular variations in the number of photoreactivating enzyme (PRE) molecules during the cell division cycle of the UV-sensitive E. coli strain B_S?1. No variations in the number of PRE molecules per genome were observed throughout the cell division cycle when synchronized cells cultured in either glucose-minimal or succinate-minimal medium were used. This is interpreted to mean that PRE synthesis is continuous throughout the cell cycle for glucose-grown cells, but may stop at the time chromosome replication ceases prior to division, in succinate-grown cells. The effect of growth rate and stage of growth on cellular PRE content in asynchronous cultures was also determined. Variations in the number of PRE per genome were observed for both synchronous and asynchronous cells cultured in different media and occurred in a manner that suggested a dependence on growth rate. PRE per genome increased with generation time. Stationary phase cells from each culture medium (nutrient broth, glucose-minimal, succinate-minimal) had more PRE per genome than did respective log phase cells. It is suggested that PRE synthesis may be controlled by some aspect of chromosome replication.     

PHYTOPLANKTON LIPIDS: INTERSPECIFIC DIFFERENCES AND EFFECTS OF NITRATE,SILICATE AND LIGHT-DARK CYCLES1

The lipid content of various phytoplankton species was measured in response to nitrogen and silicon limitation and over the cell cycle in synchronized cultures. In a survey of 30 species it was found that during log-phase growth, green algae contained an average of 17.1% total lipids (% of total dry weight), whereas diatoms contained an average of 24.5%. Nitrogen deprivation for 4 to 9 days resulted in 2- to 3-fold increases in the lipid content of green algae, whereas both increases and decreases were noted in diatoms, depending on the species. The greatest lipid content measured in the study was 72% in Monallantus salina (strain GSB Sticho) which had been deprived of nitrogen for 9 days. Nitrate replenishment in a nitrogen starved culture of Oocystis polymorpha Groover & Bold showed that the excess cellular lipids do not rapidly disappear during recovery, until cell division occurs. A silicate deprivation experiment with Cyclotella cryptica Reimann, Lewin & Guillard (strain 7c) showed an increase in the total cellular lipid fraction from. 30 to 42% of dry weight within 6 h of the onset of silicon limitation, while the mass of lipid material per cell doubled within 12 h. The total lipid fraction in O. polymorpha was found to remain constant over the cell cycle in synchronized cultures regardless of the light regime. The data presented provided the first internally consistent study of phytoplankton lipids for a wide range of species and several growth conditions.     

Thymidine transport by Novikoff rat hepatoma cells synchronized by double hydroxyurea treatment

Suspension cultures of Novikoff rat hepatoma cells were synchronized by a double hydroxyurea block. About 80% of the cells of the population doubled 5 to 8 h after the reversal of the second hydroxyurea block. At all stages of the cell cycle, thymidine was rapidly incorporated into the acid-soluble pool of the cells (mainly dTTP) and the rate of incorporation was limited by the rate of thymidine transport. The rate of thymidine transport per cell roughly doubled during the S or late S phase and decreased again to the base level during cell division. This was reflected by corresponding changes in V_max for thymidine transport, whereas the apparent K_m remained constant throughout the cell cycle.     

Control of Cell Growth in Bacteria: Experiments with Thymine Starvation

When cells of Escherichia coli THU were starved for thymine, they continued to grow without division for at least two successive volume doublings at their initial rate. Within experimental error this average rate of volume increase, 0.21 mum(3) per hr, was identical with that observed in control cultures during two generations of growth in the presence of thymine. This growth rate was also independent of the age of the cells at the time of starvation. These results are consistent with the hypothesis, proposed earlier, that growth rates are controlled by uptake sites for binding, transport, or accumulation of compounds into the cell, that the number of these sites is constant throughout most of the cell cycle, and that this number doubles near or at cell division.     

Deciliation interferes with cell-cycle progression in Tetrahymena

The impact of ciliary regeneration upon cell-cycle progression of the ciliate Tetrahymena was studied. It was found that cell division ceases during ciliary regeneration, and starts again about 4 h after deciliation. Deciliation of an asynchronously multiplying culture results in a rapid interruption of DNA synthesis, followed by resumption 1 h later. This was shown by pulse-labelling the cells with [3H]thymidine at various times after deciliation. Cytophotometric determinations of the macronuclear DNA content substantiated these observations, since the average DNA content per cell remained constant within the first hour of regeneration, confirming the labelling experiments, after which it rose. At its maximum, the average DNA content was more than doubled as compared with the beginning of the experiment. This indicates that a substantial proportion of the regenerating cells performed two rounds of DNA replication prior to cell division. The massive drop in the average DNA content during the fifth hour after deciliation indicates that the culture becomes partly synchronized for cell division by the deciliation procedure. The division synchrony results from a greater delay of the next cell division when G2 cells are deciliated than occurs in G1 cells. This was shown by deciliating cultures of Tetrahymena thermophila cells in the respective stages of the cell cycle, which had been partly synchronized by elutriator centrifugation. Thus, deciliation followed by ciliary regeneration causes a varying degree of retardation in progression through the cell cycle, being greatest for G2 cells and least for G1 cells.     

Regulation of the Synthesis of the Lactose Repressor

Measurements of the lactose repressor over a tenfold range of cell growth rates were made on protein extracts from Escherichia coli cultures grown in media with various carbon energy sources. The concentration of lactose repressor varied with the number of genome equivalents per cell over this range in growth rates, suggesting that the number of lactose molecules within the cell is determined by the number of I gene copies present. The timing of repressor synthesis during the cell division cycle and its correlation with deoxyribonucleic acid synthesis was examined by synchronizing the cell division cycle of E. coli ED1039, in which the Lac region has been transposed from 10 to 36 min on the genetic map. Measurements of lactose repressor in the synchronized culture revealed a burst of repressor synthesis at the time of I gene duplication. The concentration of lactose repressor was found to decrease as a function of total cell protein during the division cycle until an increase in synthesis occurred, suggesting that repressor synthesis probably does not occur throughout the division cycle. A model for I gene regulation is proposed.     

Mitochondrial growth and division during the cell cycle in HeLa cells

The growth and division of mitochondria during the cell cycle was investigated by a morphometric analysis of electron micrographs of synchronized HeLa cells. The ratio of total outer membrane contour length to cytoplasmic area did not vary significantly during the cell cycle, implying a continuous growth of the mitochondrial outer membrane. The mean fraction of cytoplasmic area occupied by mitochondrial profiles was likewise found to remain constant, indicating that the increase in total mitochondrial volume per cell occurs continuously during interphase, in such a way that the mitochondrial complement occupies a constant fraction( approximately 10-11(percent)) of the volume of the cytoplasm. The mean area, outer membrane contour length, and axis ratio of the mitochondrial profiles also did not vary appreciably during the cell cycle; furthermore, the close similarity of the frequency distributions of these parameters for the six experimental time-points suggested a stable mitochondrial shape distribution. The constancy of both the mean mitochondrial profile area and the number of mitochondrial profiles per unit of cytoplasmic area was interpreted to indicate the continuous division of mitochondria at the level of the cell population. Furthermore, no evidence was found for the occurrence of synchronous mitochondrial growth and division within individual cells. Thus, it appears that, in HeLa cells, there is no fixed temporal relationship between the growth and division of mitochondria and the events of the cell cycle. A number of statistical methods were developed for the purpose of making numerical estimates of certain three-dimensional cellular and mitochondrial parameters. Mean cellular and cytoplasmic volumes were calculated for the six time-points; both exhibited a nonlinear, approx. twofold increase. A comparison of the axis ratio distributions of the mitochondrial profiles with theoretical distributions expected from random sectioning of bodies of various three-dimensional shapes allowed the derivation of an "average" mitochondrial shape. This, in turn, permitted calculations to be made which expressed the two-dimensional results in three-dimensional terms. Thus, the estimated values for the number of mitochondria per unit of cytoplasmic volume and for the mean mitochondrial volume were found to remain constant during the cell cycle, while the estimated number of mitochondria per cell increase approx. twofold in an essentially continuous manner.     

Constancy of Uptake During the Cell Cycle in Escherichia coli

Rates of uptake of several labeled compounds were measured during the cell cycle for three strains of Escherichia coli in balanced growth. Uptake rates were constant during more than the first two-thirds of the cycle, or reasonably so, for all of these compounds: glycine, leucine, glucose, acetate, phosphate, sulfate, and thymidine. When added de novo, uptake of glycine and leucine were not constant, but appeared to be proportional to mean cell volume. These results are in agreement with the finding that cell sizes increase linearly during most of the cell cycle for E. coli. They support the hypothesis, for cultures in balanced growth, that linear growth during the cell cycle is due to constant rates of uptake of all major growth factors. They also support the interpretation that uptake is limited by the presence of a constant number of functional binding or accumulation sites for these growth factors.     

Oxygen toxicity in a fission yeast

Continuous exposure of synchronous cultures of Schizosaccharomyces pombe to 2.0 atmospheres oxygen beginning at any point in the first two-thirds of the cell cycle prevented subsequent cell division. Similar exposure during the last one-third of the cell cycle did not prevent cell division. The inhibition of division was totally reversible. Exposure to 2.0 atmospheres oxygen for 2.5 hours did not affect oxygen consumption. Oxygen at 1.0 atmospheres reduced growth rate and protein synthesis by 44%. Similar exposure to 1.0 atmospheres reduced transport of glycine-¹⁴C, L-leucine-¹⁴C, and uracil-¹⁴C by 95%, 73%, and 89% respectively. Analysis of the kinetics of uptake of these materials showed noncompetitive inhibition of transport by oxygen. The primary effect in rapidly appearing oxygen toxicity apparently involved interference with the transport capabilities of the cell membrane.     

Approximation of the cell cycle in synchronized populations of Streptococcus faecium.

Slowly growing populations (TD = 70 to 80 min) of Streptococcus faecium (S. faecalis ATCC 9790) were synchronized by selection after sucrose gradient fractionation. The cell cycle was approximated by correlating the patterns of DNA accumulation and cell division. More specifically, the beginning of cell cycle was equated with the beginning of a rapid linear increase in DNA accumulation. The DNA content of the culture approximately doubled during the period of accumulation, which lasted about 51 min. The period of rapid DNA accumulation, was followed by a period of reduced accumulation that lasted about 24 min. During synchronized growth, cell numbers increased rapidly in coordination with the period of rapid DNA accumulation and exhibited a plateau during the period of reduced DNA accumulation. In contrast, RNA and protein appeared to accumulate exponentially throughout the cell cycle at the same rate as culture mass.     

Initiation of DNA replication in chromosomes of Chinese hamster ovary cells

The initiation of DNA replication and the subsequent chain elongation were studied using Chinese hamster ovary cells synchronized at the beginning of S phase. The cells were synchronized by a combination of mitotic selection and treatment with 5-fluorodeoxyuridine (FdU). The use of this drug at a concentration of 10^–5 M was found to effectively prevent the leakage of cells into S phase. Reversal of the FdU block by supplying thymidine resulted in the synchronous onset of initiation at multiple sites in each cell. The length of the nascent chains, as determined by autoradiography and velocity sedimentation in alkaline gradients, increased linearly with time during the first twenty minutes of S phase after release. — We applied these procedures to study the effects of the length of an FdU block on the number of functional origins per cell, the rate of chain growth, and the rate of DNA synthesis per cell following reversal of the block. Although no change was noted in the rate of DNA synthesis in cells held at the beginning of S phase from 10.5 to 24 h after division, the rate of chain growth decreased from 0.94 to 0.28 microns per min. This decrease indicated that the number of functional origins increased markedly with length of FdU block. The calculated number of utilized origins per cell increased from 1,900 to 5,700. We also presented arguments that 1,900 origins per cell represents the approximate number of origins utilized by any cell held at the beginning of S phase for less than 10.5 h after division.     

Drifts in DNA level in the cyanobacterium Anacystis nidulans during synchrony induction and in synchronous culture

Cultures of the cyanobacterium Anacystis nidulans were synchronized by using alternating light-dark cycles. The DNA level in the cells was determined, at intervals, during pre-synchrony treatment and subsequent synchronous growth. The DNA content/cell gradually increased during synchrony induction and reached a maximum value after about 9–10 dark-light cycles, coinciding with the minimum length of pre-synchrony treatment necessary for obtaining good synchrony of cell division in our system. DNA synthesis was found to be discontinuous in the synchronous cultures. The results suggest two gaps in DNA synthesis, one occurring before and one after cell division. The results are compared with the relevant data published on the life cycle of other prokaryotic microorganisms.     

PERIODIC CHANGES IN RATE OF AMINO ACID UPTAKE DURING YEAST CELL CYCLE

Uptake of amino acids is a complex process but in cells growing with ammonia as sole nitrogen source the initial uptake rate of amino acids is a measure of the transport capacity of the uptake system (permease). In synchronous cultures of Saccharomyces cerevisiae amino acids were transported at all stages of the cell cycle. However, for any one amino acid the initial uptake rate was constant for most of the cycle and doubled during a discrete part of the cycle. Thus, for a variety of amino acids the functioning amino acid transport capacity of the membrane doubles once per cycle at a characteristic stage of the cycle. Arginine, valine, and phenylalanine exhibit periodic doubling of uptake rate at different stages of the cell cycle indicating that the transport of these amino acids is mediated by three different systems. Serine, phenylalanine, and leucine exhibit periodic doubling of the uptake rate at the same stage of the cycle. However, it is unlikely that serine and phenylalanine share the same transport system since the uptake of one is not inhibited by the other amino acid. This phenomenon is analogous to the periodic synthesis of soluble enzymes observed in S. cerevisiae.     

Transport of glucose and glycine in Schizosaccharomyces pombe during the cell cycle.

Cell growth and uptake of glucose and glycine during the cell cycle were studied in synchronous cultures of Schizosaccharomyces pombe. Rates of accumulation of glucose and glycine were constant during most of the cell cycle, implying a constant rate of cell mass increase. Rates of uptake of glycine appeared to double at an average cell age of 0.9 generations.     

Synchronization of division in vitamin B12-starved Euglena gracilis.

Vitamin B12 deficiency arrests cell division in Euglena gracilis. B12 starvation for short periods made it possible to induce synchronous growth by addition of the vitamin. Culture conditions were established to optimize replenishment synchrony. The DNA content of E. gracilis in steady state culture and vitamin B12 deficiency culture was measured by flow cytofluorometry and was consistent with colorimetric determinations. The cell volume and DNA distributions of E. gracilis in synchronous culture were analyzed and the sequential changes during the division cycle were computed. Synchronous culture permits more definitive studies of shifts in cell volume and DNA distributions, in which the biochemical events required for cell division are presumably synchronized.     

Dynamic aspects of radiorespirometry during the cell cycle of Candida utilis: Some observations in phased culture under carbon-, nitrogen-, and phosphorus-limited growth

Many changes that occur in a cell during the cell cycle can be demonstrated in synchronous cultures and can reveal dimensions of cell metabolism not attainable by the study of balanced growth of asynchronous populations in batch cultures or the steady state in chemostat cultures. The release of ¹⁴CO₂ from specifically labeled glucose by phased (continuously synchronized) cultures follows a characteristic pattern (profile) that depends upon the stage in the cell cycle and the period of labeling used. Successive profiles throughout a cycle showed differences that were altered under different nutrient-limiting growth conditions. Profiles obtained with glucose-1-¹⁴C, glucose-2-¹⁴C, glucose-3,4-¹⁴C, and glucose-6-¹⁴C and phased cells of Candida utilis under N-, P-, and C-limited growth demonstrated the variable character of the metabolic activity that occurred in the cells while contour changes within the profiles across the cycle indicated possible correlations with activities of the hexose monophosphate, Embden-Meyerhof-Parnas, and tricarboxylic acid cycle pathways during the cell cycle. The basis of these changes and their use as elementary parameters for study of problems of physiological changes in vivo are considered.     

Buoyant density fluctuations during the cell cycle of Bacillus subtilis

A simple rapid method for preparing synchronous cultures of Bacillus subtilis has been used to investigate changes in density during the cell cycle. Asynchronous cells separated on a stepped Percoll density gradient had a mean cell density of 1.117 g ml^-1±0.004. Samples from a synchronous culture exhibited variation (ca. 1.5%) in mean cell density which was greatest at the onset of cell division. An asynchronous control culture showed little variation in density. These results are discussed in relation to previous work on Escherichia coli.     

Synchronous Growth and Plastid Replication in the Naturally Wall-less Alga Olisthodiscus luteus

Olisthodiscus luteus is a unicellular biflagellate alga which contains many small discoidal chloroplasts. This naturally wall-less organism can be axenically maintained on a defined nonprecipitating artificial seawater medium. Sufficient light, the presence of bicarbonate, minimum mechanical turbulence, and the addition of vitamin B₁₂ to the culture medium are important factors in the maintenance of a good growth response. Cells can be induced to divide synchronously when subject to a 12-hour light/12-hour dark cycle. The chronology of cell division, DNA synthesis, and plastid replication has been studied during this synchronous growth cycle. Cell division begins at hour 4 in the dark and terminates at hour 3 in the light, whereas DNA synthesis initiates 3 hours prior to cell division and terminates at hour 10 in the dark. Synchronous replication of the cell's numerous chloroplasts begins at hour 10 in the light and terminates almost 8 hours before cell division is completed. The average number of chloroplasts found in an exponentially growing synchronous culture is rather stringently maintained at 20 to 21 plastids per cell, although a large variability in plastid complement (4-50) is observed within individual cells of the population. A change in the physiological condition of an Olisthodiscus cell may cause an alteration of this chloroplast complement. For example, during the linear growth period, chloroplast number is reduced to 14 plastids per cell. In addition, when Olisthodiscus cells are grown in medium lacking vitamin B₁₂, plastid replication continues in the absence of cell division thereby increasing the cell's plastid complement significantly.