RNA Synthesis during Synchronous Cell Division in Cultured Explants of Jerusalem Artichoke Tuber

Explants of Jerusalem artichoke tuber tissue were cultured innutrient medium with the hormone, 2,4-dichlorophenoxyaceticacid. After a lag period, 90 per cent of the cells divided synchronously.During the first two cell cycles, the rate of ribosomal RNAsynthesis increased sharply in two steps; before the onset ofDNA synthesis for the first division, and early in interphasebefore the second division. Rates of RNA and protein accumulation,and phosphate uptake also increased sharply at these times.From experiments with explants in which DNA synthesis and celldivision had been inhibited, it was concluded that the stepwisepattern of ribosomal RNA synthesis was not caused by the replicationof ribosomal RNA genes, as can happen in mammalian cells. Instead,the periodicity of metabolism was found to be independent ofthe DNA synthesis-cell division cycle. A cause of the stepwisenature of ribosomal RNA synthesis is suggested. It is considered that despite the high synchrony of division,the system is not completely suited for the study of eventsassociated with the cell cycle in higher plants. However, thesynchrony of much of early metabolism suits it to the studyof induction of cell division in previously non-dividing cells,and the consequent process of de-differentiation.     

Regulation of Cell Division in Escherichia coli

The rate of cell division was measured in cultures of Escherichia coli B/r strain after periods of partial or complete inhibition of deoxyribonucleic acid (DNA) synthesis. The rate of DNA synthesis was temporarily decreased by removing thymidine from the growth medium or replacing it with 5-bromouracil. After restoration of DNA synthesis, a temporary period of accelerated cell division was observed. The results were consistent with the idea that chromosome replication begins when an initiator complement of fixed size accumulated in the cell. The increase in the potential for the initiation of new replication points during inhibition of DNA synthesis results in an increase in the rate of cell division after an interval which encompasses the time for the arrival of these replication points to the termini of the chromosomes and the time from this event to division.     

Lactose synthetase activity in mouse mammary glands is controlled by thyroid hormones

Epithelial cells in explants from the mammary glands of euthyroid mature virgin mice are proliferatively dormant. They must undergo DNA synthesis and traverse the cell cycle in vitro before they are able to differentiate fully in response to insulin, hydrocortisone, and prolactin, and synthesize enzymatically active alpha-lactalbumin (measured as lactose synthetase activity). In contrast, glands from hyperthyroid mature virgin mice do not require DNA synthesis in vitro to differentiate. Explants from the euthyroid virgin tissue overcome their dependence on DNA synthesis when 10(-9) M 3,5,3'-triiodo-L-thyronine is added directly to the cultures in addition to the other three hormones. Explants from involuted mammary glands from euthyroid primiparous mice do not require DNA synthesis in vitro to make the milk protein even though they, like explants from mature euthyroid virgin tissue, are proliferatively dormant and do not contain detectable lactose synthetase activity in vivo. Glands from primiparous animals made mildly hypothyroid by ingestion of 0.1% thiouracil in drinking water during 7 wk of involution remain morphologically indistinguishable from glands of their euthyroid counterparts. However, explants from the glands of these hypothyroid animals revert to a state of dependence on DNA synthesis to differentiate functionally. These observations suggest that the dependence on DNA synthesis and cell cycle traversal for hormonal induction of lactose synthetase activity in the mouse mammary gland is controlled by thyroid hormones.     

Unlinking of Cell Division from Deoxyribonucleic Acid Replication in a Temperature-sensitive Deoxyribonucleic Acid Synthesis Mutant of Escherichia coli

A new type of temperature-sensitive deoxyribonucleic acid (DNA) synthesis mutant, which can divide without a completion of DNA replication, was isolated from a thymidine-requiring Escherichia coli strain by means of photo-bromouracil selection after nitrosoguanidine mutagenesis. In this mutant, in spite of the fact that DNA synthesis stopped immediately after the temperature shift from 30 to 41 C, cells could continue to divide, though at a reduced rate. This cell division without DNA synthesis at 41 C is further supported by the following results. (i) Cell division took place at high temperature without addition of thymidine but not at all at 30 C. The parent strain of the mutant did not divide at 41 C without thymidine. (ii) Smaller cells isolated from the culture grown at 41 C did not contain DNA. This was shown by chemical analysis of the smaller cells and on electron micrographs. Ability of cells to divide was examined according to sizes of cells. By using the culture at 30 C, cells of various sizes were separated by means of sucrose-density gradient centrifugation. It was found that all cell fractions, including the smallest one, could divide at high temperature. These results suggest that in this mutant the completion of DNA replication is not required for triggering cell division at high temperature. Heat sensitivity of a factor which links cell division with DNA replication appears to be responsible. Some possible mechanisms of the coordination between cell division and DNA replication are discussed.     

Pleiotropic Effect of the recA Gene of Escherichia coli: Uncoupling of Cell Division from Deoxyribonucleic Acid Replication

A defective recA gene, which is involved in recombination, is shown in this article to permit limited cell division, when deoxyribonucleic acid (DNA) synthesis is blocked. Thymidine starvation or nalidixic acid blocked DNA synthesis, and stopped cell division of a rec(+)thy(-) strain of Escherichia coli. However, with the same treatments, a recAthy(-) strain could continue to divide for at least 5 hr, and cell numbers increased 2.5- to 4-fold. After several hours of thymidine starvation, the culture contained very long cells (snakes) and small (normal-sized) cells. The short cells contained very little, if any, DNA. Cells of all ages divided in the absence of thymidine. Specific differences in membrane proteins were observed between thymidine-starved rec(+) and recA cells, as expected from previous experiments in which these proteins were associated with cell division and DNA synthesis. It is proposed that septum formation is controlled negatively by the recA(+) gene.     

The action of 5-amino uracil on log growth and division-synchronized Tetrahymena

The influence of 5-amino uracil (5-AU) was investigated on the cell cycle of log growth and division-synchronized Tetrahymena pyriformis GL. The division index of log growth phase Tetrahymena was suppressed by 50% after 40 min in 8 mM 5-AU. Cells division-synthronized by one heat shock per generation were also treated with 5-AU. Cells treated either prior to the first synchronous division (80 min EH) or up to 25 min prior to the second synchronous division (after 160 min EH) were not delayed in their progress through the cell cycle. Cells treated during the S phase of the first free running cell cycle, however, were delayed 5-30 min from reaching the second synchronous division. The effect of 5-AU on DNA and RNA synthesis was also examined. Incorporation of [3H]thymidine into acid-precipitable material was reduced in the presence of 5-AU; the rate of DNA synthesis was also reduced. The depression in the rate of DNA synthesis was greater at the beginning of S than at the end of S. The size of the thymidine pool (nucleosides + nucleotides) did not change during 5-AU treatment; however, an accumulation of thymidine tri-phosphate and a decrease in the amount of thymidine nucleoside was observed. A suppression of [14C]uridine incorporation resulting from 5-AU treatment was observed throughout the cell cycle. The rate of RNA synthesis as monitored by [14C]uridine incorporation into acid precipitable material was also reduced during 5-AU treatment. No change in either the size or the composition of the pool of uridine (nucleoside + nucleotide) was detected in 5-AU treated cells as compared to controls.     

Effects of abscisic acid on nucleic acid metabolism in maize coleoptiles

Summary Following treatment with ABA an inhibition of total RNA synthesis was observed after 30 hours. Total soluble ribonuclease activity did not change during the first 8 hours, after which an increase could be observed.Separation of nucleic acids with polyacrylamide gel electrophoresis indicated that synthesis of soluble RNA was less inhibited by ABA than synthesis of ribosomal RNA.Effects of 5-FU and ABA on ribosomal RNA precursor were investigated. It could be shown that 5-FU did not inhibit ribosomal precursor synthesis, but that ABA did so.     

The Action of Mercaptoethanol on Cell Division in Synchronized Tetrahymena1

SYNOPSIS. Action of mercaptoethanol (ME) on cell division and macromolecular synthesis was examined in Tetrahymena synchronized for division. Cells continuously exposed to increasingly higher concentrations of ME divided with progressively longer division delays showing a dosage-dependent response to the agent. Division was blocked in 2 × 10^?2 M ME. Many cells cytolyzed in high concentrations of ME (4 × 10^?2 M); others became spherical and motility decreased. Non-delaying concentrations of ME (2 × 10^?2 M) had little or no effect on protein synthesis but decreased DNA and RNA synthesis 10 and 35%, respectively. Blocking concentrations inhibited incorporation of phenylalanine, thymidine and uridine 35, 60, and 85%, respectively. It is suggested that the mode of action of ME is mediated thru inhibition of macromolecular synthesis essential for cell division and thru inhibition of formation of disulfide bridges between protein subunits.     

Effect of Light on Cell Division in Developing Callus Cultures

Explants removed from the Jerusalem artichoke tuber and exposedto white light in the presence of 2, 4-D, when cultured in liquidmedia, exhibit much smaller dividing populations than similartissue not exposed to light. White light, which is effectiveonly in the presence of 2, 4-D and during the period beforethe onset of DNA replication, is required only in small amountsto promote a maximum effect, although inhibition of cell divisionwas never complete Light does not interfere with the timingof the cell cycle but exerts an influence on the size of thedividing population. The results presented are consistent witha hypothesis which postulates that a substance or substancesessential for cell division is reduced in amount by exposureto light. The extent of the first synchronous division is probablytherefore determined by the supply of this substance.     

A Requirement for DNA Synthesis during Auxin Induction of Cell Enlargement in Tobacco Pith Tissue

IAA (indoleacetic acid) is known to induce cell enlargement without cell division in tobacco pith explants grown on an agar medium without added cytokinin. The very long lag period before IAA (2 × 10^?5M) stimulates growth, about 3 days, can be useful to study the metabolic changes which lead to the promotion of growth. When the disks are transferred to a medium without IAA after 2 days or less of treatment with IAA, the IAA does not stimulate growth. Disks transferred after 3 days, subsequently show an auxin response, almost as great as those given IAA continuously. At 5 × 10^?4M, 5-fluorodeoxyuridine (FUDR), which inhibits DNA synthesis by blocking formation of thymidylate, completely suppresses the lAA-induced growth if it is added together with the IAA or 1 day later. When the FUDR is given 2 days after the IAA, there is a small increment of auxin-induced growth, and an even greater amount if added after 3 days. The period when exogenous auxin must be present to stimulate growth corresponds to the period of FUDR sensitivity. The FUDR inhibition is prevented by thymidine but not by uridine. Other inhibitors of DNA synthesis, hydroxyurea and fluorouracil, also inhibit auxin-induced growth. Thus DNA synthesis seems to be required for auxin induction of cell enlargement in tobacco pith explants. In contrast, FUDR does not inhibit auxin-induced growth in corn coleoptile and artichoke tuber sections.     

The ribosomes of Drosophila

Summary The assembly of proteins and RNA into mature ribosomal subunits has been studied in Drosophila cell cultures by pulse-chase experiments. Pulse labeled rRNA has a transit time of 3 h, while the transfer of ribosomal protein occurs completely within 30 min. Inhibition of protein synthesis by cycloheximide results in an almost immediate cessation of ribosome assembly, a result which indicates that no large pool of free ribosomal proteins exists in the cell. Substituting pre-ribosomal RNA with the analogue 5-fluorouridine (5-FU) results in a cessation of ribosome maturation. Under these conditions at least three large subunit proteins continue to accumulate on pre-existing cytoplasmic subunits, indicating an exchange. A portion of ribosomal subunit proteins synthesized in the presence of 5-FU can be recovered in cytoplasmic subunits once the effect of 5-FU has been reversed. This is most easily interpreted in terms of their stabilization on substituted pre-rRNA within the nucleolus, and subsequent utilization on unsubstituted RNA.Work supported by a grant from the NIH (GM 22866)     

Control of Cell Division in Escherichia coli: Experiments with Thymine Starvation

This paper describes the kinetics of cell division in populations of cells which have been grown first under conditions which specifically inhibit deoxyribonucleic acid (DNA) synthesis (in the absence of thymine or the presence of nalidixic acid) and subsequently under conditions which allow DNA synthesis to recommence. Cell division does not take place during inhibition of DNA synthesis. There is a delay between recommencement of DNA synthesis and recommencement of cell division. The length of this delay increases as a function of the length of the preceding period of inhibition of DNA synthesis. The first division after this delay is partly synchronous, but all subsequent division is asynchronous. These observations are explained in terms of a model which supposes that the formation of initiator of chromosome replication during a period when DNA synthesis is inhibited results in a block to cell division. Division does not then occur until this "extra" round of DNA synthesis is completed.     

DNA synthesis in the elongating nondividing cells of the lentil epicotyl and its promotion by gibberellin

Two-day-old lentil seedlings, (Lens culinaris Med.) were incubated for a 48-hour period with and without gibberellin (GA) in the presence and absence of 5-fluorodeoxyuridine (FUDR). The number of cells per epicotyl did not increase during this period. Growth of the epicotyl was thus due to cell elongation alone.

The elongating cells of this tissue synthesized DNA. GA promoted and FUDR inhibited cell elongation, DNA synthesis, and RNA synthesis in the tissue.

FUDR promoted uptake of thymidine and thymidine incorporation into cellular DNA, presumably by inhibiting synthesis of endogenous thymidine. Presence of GA promoted thymidine incorporation into cellular DNA and uridine incorporation into cellular RNA. In either case, there was no effect on the uptake of the precursor into the tissue.

Fractionation of thymidine-labeled nucleic acids on a MAK column showed that thymidine was exclusively incorporated into the DNA fraction. Presence of GA promoted thymidine incorporation into this fraction and also increased the amount of ribosomal RNA.

The data provide direct evidence for the conclusion that DNA synthesis is necessary for elongation of certain plant cells.

     

RELATIONSHIP BETWEEN RNA SYNTHESIS, CELL DIVISION, AND MORPHOLOGY OF MAMMALIAN CELLS : I. Puromycin Aminonucleoside As An Inhibitor of RNA Synthesis and Division in HeLa Cells

Logarithmically growing HeLa cell monolayers were treated with a range of concentrations of puromycin aminonucleoside (AMS). The effects of AMS were studied by the following means: microscope examination of treated cells; enumeration of the cell number using an electronic particle counter; analyses for DNA, RNA, and protein content; incorporation of P³² and H³-thymidine into nucleic acids; and fractionation of nucleic acids by column chromatography. Taking the rate of incorporation of the isotopic precursor as a measure of nucleic acid synthesis, it was found that concentrations of the inhibitor which had a rapid effect on the rate of cell division inhibited the synthesis of all types of nucleic acids and of protein, but depressed ribosomal RNA synthesis most markedly. Lower concentrations of AMS selectively inhibited ribosomal RNA and, to a lesser extent, transfer RNA synthesis. Partial inhibition of ribosomal RNA synthesis with low doses had no effect on the rate of cell division within the period studied (3 generation times). The cell content of RNA returned to normal when the inhibitor was removed.     

Functional differentiation in mouse mammary gland epithelium is attained through DNA synthesis,inconsequent of mitosis

Virgin mouse mammary gland in explant culture will differentiate and synthesize casein and α-lactalbumin when insulin, hydrocortisone, and prolactin (IFPRL) are present in the culture medium. Explants whose DNA synthesis has been blocked differentiate cytologically, mobilize lipid, synthesize RNA, and incorporate ³H-amino acids into proteins to the same extent as unblocked tissue. Nevertheless, casein synthesis as measured by immunoprecipitation with casein-specific antiserum remains at the zero-time level in blocked explants while unblocked explants produce casein at five- to eightfold greater levels. Electrophoretic analysis of immunoprecipitated radioactive proteins showed that the IFPRL-treated virgin tissue made all four size classes of mouse casein. Immunoperoxidase studies of explants revealed that the number of mammary epithelial cells positive for casein was 2–8% in blocked and 24–31% in unblocked, in good agreement with the radioimmunoprecipitation results. Immunoelectron microscopy demonstrated the accumulation of casein within the cisternae of the granular endoplasmic reticulum and in Golgi vacuoles in the unblocked epithelial cells. Similar accumulation did not occur in blocked cultures despite the secretory appearance of the cells. Autoradiographic analysis of blocked and unblocked explants, incubated in the presence of IFPRL and [³H]thymidine for 72 hr, showed that 53–57% of the epithelial cells synthesized DNA in unblocked explants, whereas only 2% incorporated the label in the presence of cytosine arabinoside. When explants were incubated with IFPRL and various concentrations of colchicine, only 5–6% of the epithelial cells were found to enter mitosis. Since cell duplication cannot account for the severalfold increase in casein-producing cells in the unblocked explants, the results suggest that the requirement for DNA synthesis in this system may involve either polyploid cells or the augmentation of specific sequences necessary for the facilitation of terminal differentiation. Similar requirements for DNA synthesis were not observed in mammary explants from pregnant and primiparous (but nonpregnant) mice.     

Thymidine as a synchronizing agent. I. Nucleic acid and protein formation in synchronous HeLa cultures treated with excess thymidine

Synchronous cultures of HeLa cells obtained by selective detachment of mitoses were treated with high concentrations of thymidine. The inhibitor was added soon after completion of cell division and rates of cell enlargement and accumulation of DNA, RNA and protein were compared for untreated and thymidine-treated cultures at various points of the cell cycle. It was found that concentrations of thymidine which in randomly growing cultures inhibit the rate of cell division by more than 90% allowed a considerable degree of DNA synthesis and did not affect the rate of accumulation of RNA and protein, when applied to cells in the G1 phase of synchronous culture. Treated and untreated cells enlarged at the same rate throughout their life cycle. The results show that concentrations of thymidine commonly employed to produce cell synchrony do not arrest the cells at the G1-S boundary, but allow slow progress through S in respect to DNA synthesis, and near-normal progress towards G2 as regards RNA and protein accumulation and cell enlargement.     

Role of calcium in the insulin-dependent stimulation of DNA synthesis in mouse mammary gland in vitro

The role of extracellular Ca2+ in the control of DNA synthesis in mouse mammary tissue was studied using mammary gland explants maintained under chemically defined conditions in vitro. Chelation of calcium with ethyleneglycol-bis-(beta-aminoethyl ether) or omission of Ca2+ from the incubation media substantially reduced both basal and insulin-stimulated incorporation of [3H]thymidine into DNA. Addition of calcium to the Ca2+-deficient media restored DNA synthesis; other divalent cations could not be substituted for calcium. Insulin reduced by 5-fold the calcium concentration required to achieve half-maximal stimulation of DNA synthesis in explants, thus indicating that the Ca2+-related process may be involved in the mechanism by which insulin exerts its effect on cell multiplication. Evidence is presented that in mammary gland explants, calcium does not stimulate DNA synthesis by action on the thymidine pool size. Neither calcium nor insulin showed any effect on the activity of thymidine kinase in the mammary gland explants. On the other hand, calcium ions were shown to be necessary to maintain the activity of DNA polymerase-alpha, the enzyme involved in nuclear DNA replication.     

Effect of Ethylene on Cell Division and Deoxyribonucleic Acid Synthesis in Pisum sativum

Ethylene and supraoptimal levels of 2,4-dichlorophenoxyacetic acid inhibit the growth of the apical hook region of etiolated Pisum sativum (var. Alaska) seedlings by stopping almost all cell divisions. Cells are prevented from entering prophase. The hormones also retard cell division in intact root tips and completely stop the process in lateral buds. The latter inhibition is reversed partially by benzyl adenine. In root tips and the stem plumular and subhook regions, ethylene inhibits DNA synthesis. The magnitude of this inhibition is correlated with the degree of repression of cell division in meristematic tissue, suggesting that the effect on cell division results from a lack of DNA synthesis. Ethylene inhibits cell division within a few hours with a dose-response curve similar to that for most other actions of the gas. Experiments with seedlings grown under hypobaric conditions suggest that the gas naturally controls plumular expansion and cell division in the apical region.