Induction of 3T3 cell division at the monolayer stage : Early changes in macromolecular processes

We have previously demonstrated that 3T3 cells at the monolayer stage can be induced to divide by brief treatment with a variety of proteases. We have now used this system to investigate the macromolecular changes occurring in 3T3 cells induced to divide in this manner. Immediately after pronase treatment, 3T3 cells become agglutinable with concanavalin A. This is rapidly followed in order by a decrease in cyclic AMP concentration within the cell, and an increase in RNA synthesis and uridine transport. The increases in RNA synthesis and uridine transport are dependent on concomitant protein synthesis. Specific protein synthesis follows 1 h after protease treatment, with DNA synthesis occurring 24 h after treatment and mitosis 30 h after treatment. This work suggests that following alteration of the surface membrane a variety of intercellular macromolecular processes occur which eventually culminate in DNA synthesis and cell division. Such a series of events may occur during each cell cycle in non-confluent 3T3 cells.     

Measurements and models of synchronous growth of fission yeast induced by temperature oscillations

Pulsing of temperature in a fermentor at intervals coincident with cell generation time was used to induce synchrony in a population of the fission yeast Schizosaccharomyces pombe. Measurements of culture protein, RNA, and DNA during synchronous growth confirm continuous synthesis of protein and RNA and discontinuos synthesis of DNA as previously reported. Flow microfluorometry of populations at different times during the synchrony cycle was used to monitor the changes in single-cell protein. RNA, and DNA frequency functions. These measurements illustrate very clearly the degree of synchrony and patterns of macromolecular synthesis and also confirm previous estimates of the cellular protein contents characteristic of dividing cells. Additional insights into single-cell kinetics and division controls are provided by two-parameter flow microfluorometry measurements and by mathematical modeling of population dynamics. Such data are necessary foundations for robust population balance models of microbial processes.     

PHA stimulation of human lymphocytes during amino acid deprivation. Protein,RNA and DNA synthesis

Resting lymphocytes are in the G₀ phase of the cell cycle. Upon activation by PHA, they progress into G₁ with accompanying increased protein and RNA synthesis, initiate DNA synthesis and divide. We have studied the kinetics of inhibition of macromolecular synthesis during activation in the absence of single amino acids. Three types of kinetics are observed. In the absence of tryptophan or isoleucine, stimulated lymphocytes show a normal increase in protein and RNA synthesis during the first 30 hours of stimulation, initiate DNA synthesis but are subsequently inhibited. In phenylalanine-deficient medium, no DNA synthesis occurs in spite of a slight increase in protein synthesis. No increase in macromolecular synthesis is observed in medium lacking any one of the other essential amino acids (eg: lysine). Our results indicate that the kinetics of macromolecular synthesis in tryptophan-deficient medium is the result of a limited reserve of protein-bound tryptophan which becomes exhausted after 30 hours. On the other hand, delayed inhibition of synthesis in isoleucine-deficient medium probably reflects an initially low requirement for this amino acid followed by inhibition of the synthesis of isoleucine-rich proteins involved in some late event of stimulation. Partial deprivation of lysine results in kinetics of protein synthesis similar to that in tryptophan- or isoleucine-deficient media. The results indicate that the kinetics of macromolecular synthesis during activation of lymphocytes in the absence of an essential amino acid is a function of the quantitative requirement for that amino acid, at a given time during stimulation. Upon replacement of lysine, lymphocytes inhibited by lysine deficiency begin RNA and protein synthesis immediately and at a rate faster than that of unstimulated cultures to which PHA is added. They also initiate DNA synthesis earlier and therefore, are closer to the S phase than resting lymphocytes. It is concluded that lymphocytes stimulated in the absence of lysine are activated even though no overall increase in macromolecular synthesis is observed. Furthermore, the kinetics of DNA synthesis following reversal of inhibition by phenylalanine suggests that lymphocytes stimulated during phenylalanine deprivation become arrested at most six hours before S. These results indicate that amino acid deficiencies lead to arrest of activated lymphocytes at various stages of stimulation, depending on how stringent these deficiencies are.     

REGULATION OF INITIATION OF DNA SYNTHESIS IN CHINESE HAMSTER CELLS : I. Production of Stable, Reversible G1-Arrested Populations in Suspension Culture

Suspension cultures of Chinese hamster cells (line CHO) were grown to stationary phase (approximately 8–9 x 10⁵ cells/ml) in F-10 medium. Cells remained viable (95%) for at least 80 hr in stationary phase, and essentially all of the cells were in G₁ Upon resuspension or dilution with fresh medium, the cells were induced to resume traverse of the life cycle in in synchrony, and the patterns of DNA synthesis and division were similar to those observed in cultures prepared by mitotic selection. Immediately after dilution, the rates of synthesis of RNA and protein increased threefold. This system provides a simple technique for production of large quantities of highly synchronized cells and may ultimately provide information on the biochemical mechanisms regulating cell-cycle traverse.     

Phorbol ester-induced inhibition of proliferation of Daudi Burkitt's lymphoma cells by impairment of cytokinesis

The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) exerts a dose-dependent effect on Daudi cell proliferation. A low concentration has a slight mitogenic effect but higher concentrations inhibit proliferation. The inhibitory effect is associated with increases in cell size, macromolecular content, and incorporation of precursors into RNA and protein. Cell cycle analysis indicates that TPA at 1–10 nM leads to an apparent accumulation of cells in G₂/M phase. However, within this population a significant proportion of cells undergo nuclear division but fail to carry out cytokinesis, giving rise to cells with two or more nuclei. Consistent with this, DNA synthesis continues in cells which cease to divide in the presence of TPA. The ability of the phorbol ester to inhibit proliferation can thus be attributed mainly to an inhibition of cytokinesis rather than DNA replication     

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.     

Growth regulation in irradiance limited marine Synechococcus sp. WH 7803

Examinations of the macromolecular components of the protein synthesizing system (RNA, DNA and protein) have been made in the marine cyanobacterium, Synechococcus sp. WH 7803. Slowly growing, irradiance limited cells have less RNA and lower rates of RNA synthesis than do those growing at rapid rates. RNA content and synthesis increase in conjunction with division rate. Protein content is variable. Protein synthesis increases up to a plateau at division rates less the maximum observed. The results imply that there is extra protein synthetic capacity produced at high, irradiance limited growth rates. Synechococcus sp. WH 7803 responds to an increase in irradiance through a rapid shiftup in macromolecular synthesis. RNA, protein and DNA increase in a sequential fashion which precedes the onset of cell division. After decreases in irradiance, protein synthesis is maintained despite reductions in RNA. This suggests that there is some degree of physiological buffering which occurs in this species. These studies indicate that, as in more extensively studied procaryotic models, the protein synthesizing system plays a central role in the global mechanisms regulating growth in Synechococcus sp. WH 7803.Abbreviations PSS protein synthesizing system - HMW high molecular weight - LMW low molecular weight - TCA trichloroacetic acid     

Synthesis of protein and mRNA is necessary for transition of suspension-cultured Catharanthus roseus cells from the G1 to the S phase of the cell cycle

The effects of inhibition of the synthesis of protein, mRNA or rRNA on the progression of the cell cycle have been analyzed in cultures of Catharanthus roseus in which cells were induced to divide in synchrony by the double phosphate starvation method. The partial inhibition of protein synthesis at the G₁ phase by anisoniycio or cycloheximide caused the arrest of cells in the G₁ phase or delayed the entry of cells into the S phase. When protein synthesis was partially inhibited at the S phase, cell division occurred to about the same extent as in the control. When asynchronously dividing cells were treated with cycloheximide, cells accumulated in the G₁ phase, as shown by flow-cytometric analysis. The partial inhibition of mRNA synthesis by α-amanitin at the G₁ phase caused the arrest of cells in the G₁ phase, although partial inhibition of mRNA synthesis at the S phase had little effect on cell division. In the case of inhibition of synthesis of rRNA by actinomycin D at the G₁ phase, initiation of DNA synthesis was observed, but no subsequent DNA synthesis or the division of cells occurred. However, the addition of actinomycin D during the S phase had no effect on cell division. These results suggest that specific protein(s), required for the progression of the cell cycle, are synthesized in the G₁ phase, and that the mRNA(s) that encode these proteins are also synthesized at the G₁ phase.     

Radiosensitivity of Mammalian Cells: I. Timing and Dose-Dependence of Radiation-Induced Division Delay

The time of onset and duration of division delay induced by exposure to 250-kvp x-irradiation have been measured in several mammalian cell lines grown in suspension culture. Unique times of action (i.e. interval from irradiation to cessation of division) late in G₂ are characteristic for HeLa, L-5178Y, and Chinese hamster cells, and the time of action is independent of dose over the range 25-800 rads. The duration of delay was directly proportional to dose; all irradiated cells divided at least once and maintained their relative positions in the life cycle for periods exceeding one generation time. Neither random nor synchronous cultures exposed at varying times in the life cycle exhibited differences in radiation sensitivity measured either by onset or duration of the delay period. The time of action was experimentally indistinguishable from the point marking completion of protein synthesis essential for division, leading to speculation that division delay involves a translation defect.     

Macromolecular syntheses and the course of cell cycle events in the chlorococcal algaScenedesmus quadricauda under nutrient starvation: Effect of phosphorus starvation

Daughter cells of the chlorococcal algaScenedesmus quadricauda incubated under photosynthesizing conditions in a phosphate-free medium accomplished one cell cycle but divided into a lower number of daughter cells compared to the control. RNA synthesis was restricted early in the cell cycle while protein synthesis was retarded as compared to the control only at the end of the cycle. The number of DNA replication rounds (and consequently the number of divisions) was reduced in proportion to the lower content of RNA per cell. Daughter cells produced by phosphorus-starved mother cells and grown further in a phosphorus free medium performed no net RNA, DNA and protein synthesis within the period corresponding to the duration of control cell cycle an o were unable to develop. They accumulated, however, about half the amount of starch found in normally developed mother cells. In a complete medium, the phosphorus-starved daughter cells resumed macromolecular syntheses with a lag of about 5 h. Thereafter, their development and reproductive processes were comparable to those in a healthy population. A similar course of recovery was obtained with starved daughter cells exposed to light in phosphorus-free medium for the period corresponding to one cell cycle. Thanks to the large amount of starch accumulated in these cells, they were able to run through an entire cell cycle in the dark after being supplied with phosphorus. The first response to phosphorus withdrawal from the nutrient medium was the restriction of RNA synthesis. This occurred in spite of the fact that phosphorus reserves in the cell were still abundant, which suggests an intimate link between the supply of exogenous phosphorus to the cell and RNA synthesis.     

Generation of asymmetry during development. Segregation of type-specific proteins in Caulobacter.

An essential event in developmental processes is the introduction of asymmetry into an otherwise undifferentiated cell population. Cell division in Caulobacter is asymmetric; the progeny cells are structurally different and follow different sequences of development, thus providing a useful model system for the study of differentiation. Because the progeny cells are different from one another, there must be a segregation of morphogenetic and informational components at some time in the cell cycle. We have examined the pattern of specific protein segregation between Caulobacter stalked and swarmer daughter cells, with the rationale that such a progeny analysis would identify both structurally and developmentally important proteins. To complement the study, we have also examined the pattern of protein synthesis during synchronous growth and in various cellular fractions. We show here, for the first time, that the association of proteins with a specific cell type may result not only from their periodicity of synthesis, but also from their pattern of distribution at the time of cell division. Several membrane-associated and soluble proteins are segregated asymmetrically between progeny stalked and swarmer cells. The data further show that a subclass of soluble proteins becomes associated with the membrane of the progeny stalked cells. Therefore, although the principal differentiated cell types possess different synthetic capabilities and characteristic proteins, the asymmetry between progeny stalked and swarmer cells is generated primarily by the preferential association of specific soluble proteins with the membrane of only one daughter cell. The majority of the proteins which exhibit this segregation behavior are synthesized during the entire cell cycle and exhibit relatively long, functional messenger RNA half-lives.     

Inhibitor effects during the cell cycle in Chlamydomonas reinhardtii. Determination of transition points in asynchronous cultures

A wide variety of inhibitors (drugs, antibiotics, and antimetabolites) will block cell division within an ongoing cell cycle in autotrophic cultures of Chlamydomonas reinhardtii. To determine when during the cell cycle a given inhibitor is effective in preventing cell division, a technique is described which does not rely on the use of synchronous cultures. The technique permits the measurement of transition points, the cell cycle stage at which the subsequent cell division becomes insensitive to the effects of an inhibitor. A map of transition points in the cell cycle reveals that they are grouped into two broad periods, the second and fourth quarters. In general, inhibitors which block organellar DNA, RNA, and protein synthesis have second-quarter transition points, while those which inhibit nuclear cytoplasmic macromolecular synthesis have fourth-quarter transition points. The specific grouping of these transition points into two periods suggests that the synthesis of organellar components is completed midway through the cell cycle and that the synthesis of nonorganellar components required for cell division is not completed until late in the cell cycle.     

Continuous cultivation of fission yeast: Analysis of single-cell protein synthesis kinetics

A fundamental problem in microbial reactor analysis is identification of the relationship between environment and individual cell metabolic activity. Population balance equations provide a link between experimental measurements of composition frequency functions in microbial populations on the one hand and macromolecular synthesis kinetics and cell division control parameters for single cells on the other. Flow microfluorometry measurements of frequency functions for single-cell protein content in Schizosaccharomyces pombe in balanced exponential growth have been analyzed by two different methods. One approach utilizes the integrated form of the population balance equation known as the Collins-Richmond equation, and the other method involves optimization of parameters in assumed kinetic and cell division functional forms in order to best fit measured frequency functions with corresponding model solutions. Both data interpretation techniques indicate that rates of protein synthesis increase most in small protein content cells as the population specific growth rate increases, leading to parabolic single-cell protein synthesis kinetics at large specific growth rates. Utilization of frequency function data for an asynchronous population is shown in this case to be a far more sensitive method for determination of single-cell kinetics than is monitoring the metabolic dynamics of a single cell or, equivalently, synchronous culture analyses.     

Arrest of Chinese hamster cells in G 2 following treatment with the anti-tumor drug bleomycin

Upon addition of bleomycin (BLM) to suspension cultures of Chinese hamster cells (line CHO), cells closer to prophase than 56 minutes continue dividing at the normal rate, whereas cells at earlier positions in the cell cycle either fail to reach mitosis altogether (at 200 μg/ml) or enter mitosis and divide at a reduced rate at lower drug concentrations. At 100 μg/ml of BLM (the rate of cell division slowed to a doubling time of 167 hours), initiation and termination of DNA synthesis occur at normal rates, resulting in an accumulation of cells with a G₂ DNA content in the first 130 minutes of G₂. Bleomycin effects are not readily reversible. The rates of incorporation of leucine, uridine, or thymidine into cells treated for six hours with 100 μg/ml of BLM were 90, 85, and 80%, respectively, of the values obtained in control cultures, suggesting that the effects of BLM on cell-cycle traverse cannot be correlated with gross inhibition of macromolecular synthesis.     

Synchronous Cell Division in Cultured Explants of Jerusalem Artichoke Tubers: the Effects of 5-Fluorouracil on Messenger RNA Synthesis and the Induction of Cell Division

Explants of secondary xylern parenchyma tissue from Jerusalemartichoke tubers were induced to undergo cell division and de-differentiateby culture in nutrient medium. The first division was inherentlysynchronous. The system was used to study the involvement ofmessenger RNA synthesis in the induction and continuance ofcell division in previously non-dividing cells. The base analogue 5-fluorouracil (5-FU) inhibited ribosomalRNA synthesis and the processing of ribosomal RNA precursorto mature 25 S and 18 S RNAs. The synthesis of messenger-likeRNAs (heterogeneous in size, labelled to a high specific activityin a pulse incubation, and containing a polyadenylic acid sequence)was less inhibited by 5-FU. Explants grown in 5-FU did not synthesize DNA and did not divide.A direct inhibition of DNA synthesis by 5-FU added late in culturewas reversed by thymidine. An indirect inhibition of DNA synthesisoccurred when 5-FU was present from the start of culture andwas not reversed by thymidine. Because ribosomal RNA synthesisis not necessary for the induction of cell division (Fraser,1975) and because 5-FU was incorporated into mENA, probablyinterfering with its function, these results suggest that 5-FUinhibited the metabolism of mRNA which was required for DNAsynthesis and cell division. The timing of mRNA synthesis required for DNA synthesis andcell division was investigated by adding 5-FU plus thymidineto cultures at various times. By the beginning of DNA synthesisfor the first division, explants were competent, in terms ofmRNA synthesized, to complete the first division. MessengerRNA synthesis occurring before the end of the first divisionallowed explants to undergo at least three more divisions.     

Synthesis of Protein, Ribonucleic Acid, and Ribosomes by Individual Bacterial Cells in Balanced Growth

Relative rates of protein synthesis in individual cells were determined by allowing random populations to incorporate tritiated leucine for very short periods (pulses) and then examining autoradiographs of these cells to assess the amount of incorporation (grains per cell) as a function of cell size. Relative rates of ribonucleic acid (RNA) synthesis were determined in the same way by using tritiated uracil. Unless the uracil pulse was very short (less than 1/20 generation), the RNA labeled during the pulse was predominantly ribosomal. The rate of protein synthesis in individual cells is directly proportional to cell size. The rate of RNA synthesis also increases linearly with size in larger cells, but there appears to be a slight delay in RNA synthesis immediately after cell division. Total cellular content of protein, RNA, and ribosomes is directly proportional to cell size. Thus, we conclude that, in individual cells during the cell cycle (i) the average rate of protein synthesis per ribosome is constant and (ii) the increase in macromolecular mass of the cell is exponential with age.