SYNCHRONOUS GROWTH IN THE COLONIAL EUDORINA ELEGANS (CHLOROPHYCEAE)1,2

Eudorina elegans Ehrenberg has been synchronized by growing the organisms at 32 C in an enriched medium on a 16:8 LD cycle. Nuclear division occurred during the light period and 2–4 h was required, for the population to complete the sequence of 4 or 5 divisions each cell normally undergoes. Each cell division required 2–3 min with ca. 15 min as the intermitotic time. The sequence was repealed, every 24 h as long as synchrony was maintained.     

Light-mediated regulation of phospholipid synthesis in Rhodopseudomonas sphaeroides.

The relationship between the culture levels of guanosine-5'-diphosphate-3'-diphosphate (ppGpp) and the rates of synthesis and accumulation of cellular phospholipids was examined in cultures of Rhodopseudomonas sphaeroides that had been subjected to immediate decreases in incident light intensity. After a high-to-low light transition of high-light-adapted cells, an immediate inhibition of total cellular phospholipid production occurred coincident with a rapid accumulation of culture ppGpp. The inhibition of phospholipid accumulation occurred at the level of phospholipid synthesis rather than turnover, and both the extent of ppGpp accumulation and the degree of inhibition of phospholipid synthesis were directly dependent upon the magnitude of the light transition. Maximum inhibition (greater than 90%) of the rate of cellular phospholipid synthesis occurred after transitions from 5,350 to 268 1x and lower, including transitions to the dark, with comparable inhibition being exerted upon the rates of synthesis of individual species of phospholipids. Reinitiation of culture phospholipid accumulation in cultures shifted from 5,350 to 1,070 1x and lower occurred 65 to 70 min subsequent to the downshift in light intensity, apparently irrespective of the culture level of ppGpp.     

Effect of lectins on auxin-induced elongation and wall loosening in oat coleoptile and azuki bean epicotyl segments

A marine unicellular aerobic nitrogen-fixing cyanobacterium Synechococcus sp. strain Miarni BG 043511 was pretreated with different light and dark regimes in order to induce higher growth synchrony. A pretreatment of two dark and light cycles of 16 h each yielded good synchrony for 3 cell division cycles. Longer dark treatments decreased the degree of synchrony and shorter dark treatments caused irregular cell division. Once synchronous culture was established, distinct phases of cellular carbohydrate accumulation and cellular carbohydrate degradation were observed even under continuous illumination. Changes in carbohydrate content were repeated in a cyclic manner with approximately 20 h intervals, the same as the cell division cycle. This change in carbohydrate metabolism provided a good index of growth synchrony under nitrogen-fixing conditions.
Photosynthetic oxygen evolution and nitrogen fixation capabilities and their activities in near, in situ, culture conditions were measured in well synchronized cultures of this strain under continuous illumination. Distinct oscillations of both photosynthetic oxygen evolution and nitrogen fixation capabilities with ca 20-h intervals, similar to the interval of the cell division cycle, were observed for three cycles. However, the activities of photosynthetic oxygen evolution were inversely correlated with those of nitrogen fixation. During the nitrogen fixation period, net oxygen consumption was observed even in the light under conditions approximating in situ culture conditions. The phase of temporal appearance of nitrogenase activity during the cell division cycle coincided with the phase of carbohydrate net degradation. These data indicate that this unicellular cyanobacterium can grow diazotrophically under conditions of continuous illumination by the segregation of photosynthesis and nitrogen fixation within a cell division cycle.     

Effect of cell population density on G2 arrest in Tetrahymena

The ciliated protozoan, Tetrahymena pyriformis strain GL-C, has been used to study the effect of cell population density during starvation on the synchrony obtained after refeeding and on the number of cells arrested in G2 phase of the cell cycle. At high cell densities two peaks of division indices were observed after refeeding while only one was observed at low cell densities. Cell division began earlier in cultures starved at high cell densities. Most importantly, the proportion of cells in G2 was considerably higher in populations starved at high cell densities. When tritiated thymidine was present during the refeeding period, radioautographs of cell samples at different times showed that the first cells to exhibit division furrows contained unlabeled nuclei. The first peak in the division index after refeeding was observed only at higher cell densities and is attributed to the cells arrested in G2. These results suggest that Tetrahymena is an excellent organism to study the concept of resting stages in the cell cycle and their control.     

Acquisition of synchronous beating between embryonic heart cell aggregates and layers

Synchronous beating between chick embryonic heart cell aggregates and heart cell layers was used to study the relationship between intercellular adhesion and ionic coupling. Adhesion was measured by counting the proportion of aggregates which were not to be removed from cell layers by gentle washing after a 30 min incubation. Synchrony between bound aggregates and contiguous layers was assessed by phase microscopy. The first evidence of synchrony was seen 1.5 h after addition of aggregates to layers, following which there was an increase in the percentage of aggregates beating synchronously, reaching over 50% at 7 h and slowly increasing to a maximum of 65% by 24 h. Scanning electron microscopy and autoradiography of thymidine-labeled cells suggest that synchrony does not depend on cell movement at the interface between aggregate and layer. Acquisition of synchrony can be prevented completely by inhibiting protein synthesis, although pulsation of aggregates and layers continues in proportions unchanged from controls. After reversal of protein synthesis inhibition, synchrony is acquired at a rate and to an extent closely resembling that of newly adherent controls. These data indicate that ionic coupling is neither an inevitable nor an immediate consequence of adhesion. Since ionic coupling has been shown to correlate with the presence of gap junctions, the findings suggest that gap junctions are not involved in the initial events responsible for intercellular adhesion in vitro and that their formation following adhesion in this system may depend upon protein synthesis.     

A Continuous Synchronous Culture and Sampling System for Algae

A system has been developed for the culture of algae on a 3–5l scale under controlled axenic conditions. Light/dark regimescan be altered for the induction of synchrony and an automaticculture dilution system with new media has been developed. Theresults are shown for Platymonas striata. It was possible toinduce synchrony by a regime of 14 h light and 10 h darknessper 24 h. This synchrony could be maintained for many cyclesby the removal of half the culture daily and its replacementwith fresh medium 4 h after the onset of the light period. Cellseparation commenced at the onset of the light period and wascompleted after 4 h. No cell separation occurred during theremainder of the 24 h cycle. A system for automatic samplingof the axenic culture at known time intervals is described.     

Wall structure of a bitunicate ascus

Summary Ultraviolet light-induced, bleached Euglena clones exhibit synchronous steps of cell division in response to daily cycles of light and dark. The cyclic division activity, in the bleached cells, will persist in constant lighting conditions with a period, independent of temperature, of about 24 h. This persisting rhythm of cell division supports the hypothesis that this phase of the cell cycle may be coupled to the fluctuations of the endogenous circadian clock of the cell.Newly isolated bleached clones are sensitive to light in their growth rates and metabolic characteristics, showing light induced difference in substrate-stimulated respiration, and production of the polyglucan, paramylon. After repeated subculturing of a bleached clone the photosensitivity of the metabolic characteristics and of the growth rate are diminished along with the ability to photo-entrain division synchrony. Division control and the induction of cell synchrony in this organism apparently involve both the temporal influence of the endogenous cell clock and one or more other photosensitive reactions in the metabolism of the cell.A unique culture mixing technique utilizing the bleached Euglena, failed to support the hypothesis of the involvement of intercellular communication in the maintenance of cell synchrony in constant lighting conditions.     

Synchrony induced by double phosphate starvation in a suspension culture of Catharanthus roseus

A synchronous cell division system was established using the double phosphate starvation method, based on the observation that one of the limiting factors in the growth of a suspension culture of Catharanthus roseus (L.) G. Don cells in the medium of Murashige and Skoog was phosphate. In the system, an increase in cell number took place in a short period of only 4 h, while the cell number remained almost constant during other periods of the cell cycle. The synchrony of the culture was confirmed by changes in mitotic index, which increased sharply prior to the increase in cell number. The S phase was determined by measuring incorporation of [³H]-thymidine into the DNA fraction during the cell cycle and synchrony of DNA synthesis was verified likewise. Synchronization by phosphate starvation is discussed in relation to the function of phosphate as a nutrient. The synchronous system thus established will be useful in biochemical studies of the cell cycle in higher plants.     

Studies on the biochemistry and fine structure of silica shell formation in diatoms

Summary Cell division in Navicula pelliculosa (Bréb.) Hilse, strain 668 was synchronized with an alternating regime of 5 h light and 7 h dark. Cell volume and dry weight increased only during the light period. DNA synthesis, which began during the third h of light, was followed sequentially by mitosis, cytokinesis, silicic acid uptake, cell wall formation, and cell separation. Silicification and a small amount of net synthesis of DNA, RNA and protein occurred during the dark at the expense of carbohydrate reserves accumulated during the light period. Cells kept in continuous light, after synchronization with the light-dark regime, remained synchronized through a second division cycle; the sequence of morphological events was the same as that in the light-dark division cycle, but the biosynthesis of macromolecular components changed from a stepwise to a linear pattern. The silicon-starvation synchrony was improved by depriving light-dark synchronized cells of silicic acid at the beginning of their division cycle, then resupplying silicic acid to cells blocked at wall formation.Abbreviation L light - D dark Portions based on a thesis submitted by W.M.D. to the University of California, San Diego in partial fulfillment of the requirements for the PH.D degree     

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.     

Inductive and Inhibitory Effects of Light on Cell Division in Chattonella antiqua

The cell division of a red tide flagellate, Chattonella antiqua,was synchronously induced under light and dark regimes of 10L14D(a light period, L, for 10 h followed by a dark period, D, for14 h), 12L12D and l4L10D. In all regimes cell number began toincrease ca. 14 h after the onset of L and almost doubled duringone LD cycle. When the light-off timing of the last L was changedor the whole L was shifted, cells that had been synchronizedunder 12L12D invariably began to divide ca. 14 h after the onsetof L. This shows that the timing of cell division was determinedby the time of the onset of L. When cells were continuously exposed to light after a cell division,the subsequent cell division was inhibited. This effect waslimited to cells that had been synchronized under short-dayconditions. Thus it can be concluded that light has both inductive and inhibitoryeffects on cell division in this alga, the latter effect dependingupon the previously given light and dark regimes. (Received December 21, 1984; Accepted February 28, 1985)     

A model of cell cycle control: effects of thymidine on synchronous cell cultures.

Further evidence is presented in support of a model for growth control in which commitment for cell division is determined by an event in the preceding cell cycle. A study was made of conditions affecting synchronous growth following treatment of murine mastocytoma cells with excess thymidine at different phases of the cell cycle. Cells were synchronized by a physical procedure involving velocity sedimentation in a zonal rotor. Pulse treatment of such cultures with thymidine at times corresponding to the S, G2, and M periods had no effect on further growth. However, addition at G1, although having no immediate effect, arrested cell growth in the next cell cycle. This temporal effect may account for the decay of synchrony observed during double thymidine blockade or thymidine-FUdR blockade. When the time interval between two such blocks was 7 hr or less, P815Y cells were arrested after one synchronous division. At this critical time a majority of cells were at, or near, G1. It is suggested that thymidine exerts a hitherto unrecognized effect at the G1 interval.     

The "Point of no Return" Concept in Cell Division. The Effects of Some Metabolic Inhibitors on Synchronized Chlorella pyrenoidosa

The coarse of growth and cell division in synchronized cultures of Chlorella pyrenoidosa was studied after the addition of metabolic inhibitors at differing times during the cell cycle (14 h light - 10 h darkness with nitrate as nitrogen source. 12 h light: 12 h darkness with urea as nitrogen source). Dinitrophenol (DNP) added to a final concentration of 0.3 mM at any time in the synchronization cycle, the compound remaining in the suspension from the time of addition to the end of the dark period, inhibited spore formation completely. Growth measured as increase in cell volume was less sensitive to the action of the inhibitor. Chloramphenicol (CAP) added dining the 0–5 h interval to a final concentration of 0.1 mM resulted in 80 per cent inhibition of cell division. Similar treatment started at successive times thereafter resulted in a gradual decrease of the inhibition. Treatment at the 14th hour and during the dark period did not affect the sporulation. Similar experiments with 0.9 mM puromycin added at various times during the illumination period gave almost complete inhibition of cell division, while the growth was reduced by only 25 per cent. para-Fluorophenylalanine (p-FPhe) at 3.3 × 10^?2 mM stopped cell division nearly completely irrespective of addition time in the light period. Addition during the dark period also prevented an increase in the number of tree cells. In this case about half of the cells produced spores which were not released. It is concluded that DNP inhibits all stages of preparation for cell division, as well as the division process itself. With CAP a genuine transition point of preparation for cell division was observed, although its interpretation as related to protein synthesis is somewhat uncertain. With puromycin and p-FPhe no transitions were observed.     

Different growth patterns of a cancer cell population as a function of its starting growth characteristics: analysis by mathematical modelling

The growth kinetics of a cancer cell population as a function of the total number of cells and the proportion of proliferating and resting cells at the beginning of the growth has been analysed by a mathematical model. The model takes into account the processes of cell division, death and transition from proliferation to rest and backwards. It is shown that a single cell population growing under the same environmental conditions has an extremely broad spectrum of growth patterns. The whole multiplicity of possible growth patterns has been determined by the inherent cellular growth characteristics of the population, while the growth pattern actually realized of the variety of growth curves depends on the total number of cells and the proportion of proliferating and resting cells at the initial moment of growth. The model is shown to provide a good prediction of experimentally measured kinetics of regrowth of tumour cells subcultured after various times of the growth in unfed cultures, and the kinetics of tumour cell growth after severe hypoxia. The role of cell transitions between proliferating and resting stages in the problem of growth control is discussed.     

Induction of the photosynthetic membranes of Rhodopseudomonas sphaeroides: biochemical and morphological studies

Cells of Rhodopseudomonas sphaeroides grown in a 25% O2 atmosphere were rapidly subjected to total anaerobiosis in the presence of light to study the progression of events associated with the de novo synthesis of the inducible intracytoplasmic membrane (ICM). This abrupt change in physiological conditions resulted in the immediate cessation of cell growth and whole cell protein, DNA, and phospholipid accumulation. Detectable cell growth and whole cell protein accumulation resumed ca. 12 h later. Bulk phospholipid accumulation paralleled cell growth, but the synthesis of individual phospholipid species during the adaptation period suggested the existence of a specific regulatory site in phospholipid synthesis at the level of the phosphatidylethanolamine methyltransferase system. Freeze-fracture electron microscopy showed that aerobic cells contain small indentations within the cell membrane that appear to be converted into discrete ICM invaginations within 1 h after the imposition of anaerobiosis. Microscopic examination also revealed a series of morphological changes in ICM structure and organization during the lag period before the initiation of photosynthetic growth. Bacteriochlorophyll synthesis and the formation of the two light-harvesting bacteriochlorophyll-protein complexes of R. sphaeroides (B800-850 and B875) occurred coordinately within 2 h after the shift to anaerobic conditions. Using antibodies prepared against various ICM-specific polypeptides, the synthesis of reaction center proteins and the polypeptides associated with the B800-850 complex was monitored. The reaction center H polypeptide was immunochemically detected at low levels in the cell membrane of aerobic cells, which contained no detectable ICM or bacteriochlorophyll. The results are discussed in terms of the oxygen-dependent regulation of gene expression in R. sphaeroides and the possible role of the reaction center H polypeptide and the cell membrane indentations in the site-specific assembly of ICM pigment-protein complexes during the de novo synthesis of the ICM.     

Asynchronization of Cell Division is Concurrently Related with Ciliogenesis in Sea Urchin Blastulae

During the early development of the sea urchins, Temnopleurus toreumaticus, Temnopleurus hardwickii and Hemicentrotus pulcherrimus , the division synchrony in all blastomeres lasted only until the 4th cleavage and a regional synchrony or a graded activity of cell division appeared. In the midblastula stage prior to hatching, the regional synchrony vanished simultaneously with the formation of cilia, then the division proceeded asynchronously. The analysis of cell pedigrees confirmed that a variable extension of intercleavage times occurred after the ciliogenesis. In blastomeres derived from mesomeres of T. toreumaticus embryos, the mean intercleavage time extended from 48 min of the 8th cycle (pre-ciliated) to 115 min of the 9th cycle (ciliated), and the coefficient of variation increased from 15% to 39%. We attempted a kinetic analysis of cell proliferation on the basis of the transition probability model of cell cycle control. We concluded that the minimum time required for the completion of the cell cycle was the decisive factor in the cell cycle succession of pre-ciliated blastomeres, and that a sudden and sharp decrease in the transition probability of the ciliated blastomeres probably interpreted the abrupt slowing and asynchronization of the cleavage cycle at the time of ciliogenesis.     

Regulation by polyamines of ornithine decarboxylase activity and cell division in the unicellular green alga Chlamydomonas reinhardtii

Polyamines are required for cell growth and cell division in eukaryotic and prokaryotic organisms. In the unicellular green alga Chlamydomonas reinhardtii, biosynthesis of the commonly occurring polyamines (putrescine, spermidine, and spermine) is dependent on the activity of ornithine decarboxylase (ODC, EC 4.1.1.17) catalyzing the formation of putrescine, which is the precursor of the other two polyamines. In synchronized C. reinhardtii cultures, transition to the cell division phase was preceded by a 4-fold increase in ODC activity and a 10- and a 20-fold increase, respectively, in the putrescine and spermidine levels. Spermine, however, could not be detected in C. reinhardtii cells. Exogenous polyamines caused a decrease in ODC activity. Addition of spermine, but not of spermidine or putrescine, abolished the transition to the cell division phase when applied 7 to 8 h after beginning of the light (growth) phase. Most of the cells had already doubled their cell mass after this growth period. The spermine-induced cell cycle arrest could be overcome by subsequent addition of spermidine or putrescine. The conclusion that spermine affects cell division via a decreased spermidine level was corroborated by the findings that spermine caused a decrease in the putrescine and spermidine levels and that cell divisions also could be prevented by inhibitors of S-adenosyl-methionine decarboxylase and spermidine synthase, respectively, added 8 h after beginning of the growth period. Because protein synthesis was not decreased by addition of spermine under our experimental conditions, we conclude that spermidine affects the transition to the cell division phase directly rather than via protein biosynthesis.     

Acute transient SO2-induced airway hyperreactivity: effects of nedocromil sodium

The effect of nedocromil sodium given as an aerosol on the immediate lung hyperreactivity and lung inflammation caused by a 2-h exposure to 400 ppm SO2 has been studied in dogs. Exposure to SO2 caused an immediate increase in bronchial responsiveness to histamine aerosol that lasted for approximately 2 h. The total number of cells recovered by bronchial lavage increased postexposure. Initially this increase was caused by epithelial cells (0.25 and 1 h) and later by neutrophils (1, 2, 3, and 4 h). There was no significant change in the numbers of lymphocytes, macrophages, eosinophils, goblet cells, or mast cells in the lavages. Nedocromil sodium (approximately 8 mg) given as a nebulized aerosol before and after SO2 exposure prevented the increase in lung reactivity and attenuated the increase in the total number of cells (epithelial cells and neutrophils) in the lung lavages for the 4 h after exposure. Nedocromil sodium did not affect the reactivity of normal dogs to histamine aerosol. Nedocromil sodium appears to act as an anti-inflammatory agent in this model of lung inflammation, preventing an increase in lung reactivity and reducing cell infiltration. The mechanism of action of nedocromil sodium in this model is unknown.     

Growth and cell division of Mycobacterium avium

The rates of cell division and of protein, DNA and RNA synthesis upon transition of Mycobacterium avium to and from rich medium were examined. The changes in cell morphology (elongation) were also examined by optical and electron microscopy. Upon transfer from poor to rich medium, the rate of synthesis of RNA increased rapidly, followed by an increase in protein synthesis within 3 h and by an increase in DNA synthesis within 7 h; cell division began after a lag of about 10 h. Upon transfer from rich to poor medium, the preshift rates for protein and DNA synthesis changed to postshift rates after 3 h and 7 h, respectively; RNA synthesis stopped immediately, there was a transient fall in total RNA, and synthesis was resumed at a new rate only after 24 h. After the period of adjustment to new medium, the bacteria entered the postshift growth in which cell size, the increase in cell mass (absorbance at 650 nm) and viable counts, and the rates of synthesis of protein, DNA and RNA were constant. Ultrastructural examination of elongated cells during the adjustment period showed that they had septa at different stages of formation, but no evidence of fragmentation was found. It was concluded that cell division in M. avium was by binary fission, and that the notion of a life-cycle was not supported by present findings.     

THE DEPENDENCE OF CELL DIVISION IN CHLORELLA ON TEMPERATURE AND LIGHT INTENSITY

The effects of temperature and light on cell division were studied in synchronized suspensions of the high-temperature strain Chlorella 7–11–05. It was found that the time for incipient cell division, the progress in the process after it started, and the number of cells produced are influenced by temperature and light intensity. Within limits, cell division is generally favored by the increase in temperature. The increase in light intensity first favors cell division then, after the optimal light intensity is attained, a further increase in light intensity inhibits cell division. Observations are discussed in connection with the findings of other investigators. The limitations of cell division by temperature and light intensity are considered to be separate from the effects of these factors on growth.