DNA synthesis —Dependent cell division ofEscherichia coli 15 TAU after arginine and uracil starvation

Extensive cell division after synchronization ofEscherichia coli 15 TAU by arginine and uracil starvation occurs only when DNA synthesis is permitted to proceed by at least a short pulse of thymine applied between 30 and 60 min after transfer of synchronized culture to thymine-free medium with arginine and uracil. The time schedule of synchronized cell division in dependence on the schedule of intervals of DNA synthesis and inhibition of DNA synthesis was determined. The termination of replication cycles which were not completed to the very end during arginine and uracil starvation seems to be the decisive event for subsequent cell division after synchronization.     

Control of cell size at division in fission yeast by a growth-modulated size control over nuclear division

In the fission yeast Schizosaccharomyces pombe, nutritional reduction of growth rate by supplying poor nitrogen, carbon or phosphate sources causes a decrease in cell size. The effect on cell division following three different nutritional shifts-up has been investigated. In all cases, about 20% of the cells divide at the original cell length, and then cell division stops for a period. Cell division then resumes at the new faster rate, cell length at division being characteristic of the new medium. Further investigation reveals that the first effect of the shift is to inhibit nuclear division rapidly and completely. These results are strongly suggestive of the operation of a cell size requirement for entry into nuclear division. The cell size necessary for nuclear division is set, or modulated, by the prevailing growth conditions. This model is confirmed by a nutritional shift-down, where nuclear division and cell division are stimulated after the shift. Cell length at division falls rapidly until the new shorter length is attained, when a new steady state is assumed at a slower growth rate. The control system is compared with that in bacteria, and its implications for various models proposed for the control of timing of mitosis are discussed.     

Changes in calcium and magnesium levels during heat-shock synchronized cell division in Tetrahymena

Calcium and magnesium contents were measured in cells of Tetrahymena pyriformis induced to divide synchronously by a multi-heat-shock procedure. During free-running synchronized cell division in complex proteose peptone medium, significant peaks of both calcium and magnesium were observed at points in the cell cycle just prior to division. No such peaks were detected in cells dividing asynchronously in proteose peptone. When synchronized cell division was followed after transfer to an inorganic medium, cell calcium and magnesium levels were observed to decrease in relation to the corresponding cell number increase, indicating that in concentration terms, calcium and magnesium remain fairly constant. This latter result suggests that neither calcium nor magnesium influxes act as triggers for cell division in Tetrahymena and that the fluctuations of these metals seen during the synchronized division cycle in complex medium represent an effect rather than a cause.     

Diel Division Cycle and Growth Rates of Synechococcus in Lakes Huron and Michigan1

A clone of Synechococcus isolated from Lake Huron and natural populations of Synechococcus from lakes Huron and Michigan were studied in 1989 to examine the diel division cycle and to provide estimates of the in situ growth rate based on the frequency of dividing cells (FDC) method. Cultured populations of Synechococcus exhibited a consistent diel division pattern with a midday/afternoon (1100–1800 h) peak in the percent of dividing cells. The maximum percent of dividing cells varied among cultures (8-27%) and was related to the growth rate. A small fraction of dividing cells (3-5%) remained throughout the dark period, suggesting that some cells were arrested in the doublet stage prior to division. The duration of division (t_d) ranged from 2.6-4.9 h, with a 3.7 h mean for cultures with growth rates ≥0.34 d⁻¹ but increased to 8 h at a lower growth rate of 0.20 d⁻¹. The diel division pattern for natural populations was very similar to the laboratory clone; an afternoon peak (1400-2100 h) in dividing cells and a small fraction of dividing cells (2-5%) remained during the dark period. The maximum percent of dividing cells for natural populations ranged from 6-10%. In situ growth rates, determined from the FDC and assuming a constant t_d of 3.7 h, ranged from 0.30-0.42 d⁻¹. The FDC method may provide accurate estimates of in situ growth, particularly in environments where the growth rate is >0.34 d⁻¹, but in lakes Huron and Michigan where growth rates can be lower and t_d values may increase, FDC-growth rates must be viewed with caution.     

Versatility in the acquisition of energy and carbon sources by the Apicomplexa

Members of the phylum Apicomplexa are motile and rapidly dividing intracellular parasites, able to occupy a large spectrum of niches by infecting diverse hosts and invading various cell types. As obligate intracellular parasites, most apicomplexans only survive for a short period extracellularly, and, during this time, have a high energy demand to power gliding motility and invasion into new host cells. Similarly, these fast‐replicating intracellular parasites are critically dependent on host‐cell nutrients as energy and carbon sources, noticeably for the extensive membrane biogenesis imposed during growth and division. To access host‐cell metabolites, the apicomplexans Toxoplasma gondii and Plasmodium falciparum have evolved strategies that exquisitely reflect adaptation to their respective niches. In the present review, we summarize and compare some recent findings regarding the energetic metabolism and carbon sources used by these two genetically tractable apicomplexans during host‐cell invasion and intracellular growth and replication.     

ROLE OF MULTIPLE FTSZ RINGS IN CHLOROPLAST DIVISION UNDER OLIGOTROPHIC AND EUTROPHIC CONDITIONS IN THE UNICELLULAR GREEN ALGA NANNOCHLORIS BACILLARIS (CHLOROPHYTA,TREBOUXIOPHYCEAE)1

Chloroplasts of the unicellular green alga Nannochloris bacillaris Naumann cultured under nutrient‐enriched conditions have multiple rings of FtsZ, a prokaryote‐derived chloroplast division protein. We previously reported that synthesis of excess chloroplast DNA and formation of multiple FtsZ rings occur simultaneously. To clarify the role of multiple FtsZ rings in chloroplast division, we investigated chloroplast DNA synthesis and ring formation in cells cultured under various culture conditions. Cells transferred from a nutrient‐enriched medium to an inorganic medium in the light showed a drop in cell division rate, a reduction in chloroplast DNA content, and changes in the shape of chloroplast nucleoids as cells divided. We then examined DNA synthesis by immunodetecting BrdU incorporated into DNA strands using the anti‐BrdU antibody. BrdU‐labeled nuclei were clearly observed in cells 48 h after transfer into the inorganic medium, while only weak punctate signals were visible in the chloroplasts. In parallel, the number of FtsZ rings decreased from 6 to only 1. When the cells were transferred from an inorganic medium to a nutrient‐enriched medium, the number of cells increased only slightly in the first 12 h after transfer; after this time, however, they started to divide more quickly and increased exponentially. Chloroplast nucleoids changed from punctate to rod‐like structures, and active chloroplast DNA synthesis and FtsZ ring formation were observed. On the basis of our results, we conclude that multiple FtsZ ring assembly and chloroplast DNA duplication under nutrient‐rich conditions facilitate chloroplast division after transfer to oligotrophic conditions without further duplication of chloroplast DNA and formation of new FtsZ rings.     

Control of cell division in Paramecium tetraurelia. Effects of abrupt changes in nutrient level on accumulation of macronuclear DNA and cell mass

In the cell cycle of Paramecium there are three points of interaction between cell growth-related processes and the processes of macronuclear DNA replication and cell division: initiation of DNA synthesis, regulation of the rates of growth and DNA accumulation, and initiation of cell division. This study examines the regulation of the latter two processes by analysis of the response of each to abrupt changes in nutrient level brought about either by transferring dividing cells from a steady-state chemostat culture to medium with unlimited food, or by transferring well-fed dividing cells to exhausted medium. The rates of DNA accumulation and cell growth respond quickly to changes in nutrient level. The amounts of these cell components accumulated during the cell cycle following a shift in nutrient level are typical of those occurring during equilibrium growth under post-shift conditions. Commitment to division occurs at a fixed interval prior to fission that is similar in well-fed and nutrient-limited cells. Initiation of cell division in Paramecium is associated with accumulation of a threshold DNA increment, whose level is largely independent of nutritive conditions. The amount of DNA accumulated during the cell cycle varies with nutritional conditions because the rates of growth and DNA accumulation are affected by nutrient level; slowly growing cells accumulated relatively little DNA during the fixed interval between commitment to cell division and fission.     

Freeze Preservation of Cultured Plant Cells. III. The Pregrowth Phase

There is an inverse relationship between cell size and capacity to survive the freeze-preservation protocol. Pregrowth of cell suspensions in media rendered more negative in water potential by addition of mannitol enhances the survival capacity of Acer pseudoplatanus and Capsicum annuum cells but this effect can only partially be explained in terms of the associated reduction in mean cell size. Studies with cell suspensions of Daucus carota indicate the importance for successful freeze-preservation of the stage in the growth cycle of suspensions propagated in batch culture; highest survival was recorded for cells taken at lag phase or early exponential phase. Regrowth of recovered cells depends upon the establishment of an appropriate inoculum density of cells which have retained the capacity to divide. The dividing cells only achieve a growth rate equal to that of untreated cells after a number of cell generations. A proportion of the recovered cells giving an initial positive fluorescein diacetate reaction lose this capacity rapidly (within 24 h), others lose the capacity more slowly and others, in which the positive reaction persists, are incapable of division. These observations indicate that different levels of injury are inflicted by the freeze-preservation protocol and that only in a proportion of the cells is the injury reparable or compatible with growth by cell division.     

<Emphasis Type="Italic">Chlamydomonas reinhardtii:</Emphasis> duration of its cell cycle and phases at growth rates affected by light intensity

In the cultures of the alga Chlamydomonas reinhardtii, division rhythms of any length from 12 to 75 h were found at a range of different growth rates that were set by the intensity of light as the sole source of energy. The responses to light intensity differed in terms of altered duration of the phase from the beginning of the cell cycle to the commitment to divide, and of the phase after commitment to cell division. The duration of the pre-commitment phase was determined by the time required to attain critical cell size and sufficient energy reserves (starch), and thus was inversely proportional to growth rate. If growth was stopped by interposing a period of darkness, the pre-commitment phase was prolonged corresponding to the duration of the dark interval. The duration of the post-commitment phase, during which the processes leading to cell division occurred, was constant and independent of growth rate (light intensity) in the cells of the same division number, or prolonged with increasing division number. It appeared that different regulatory mechanisms operated through these two phases, both of which were inconsistent with gating of cell division at any constant time interval. No evidence was found to support any hypothetical timer, suggested to be triggered at the time of daughter cell release.     

Effects of copper and zinc on growth,morphology, and metabolism of Asterionella japonica (Cleve) 1

When exposed to elevated levels of copper or zinc, the diatom Asterionella japonica (Cleve) showed a reduced cell division rate and a marked increase in cell size. Metal-treated cells had greater cell volumes, dry weights, carbon, nitrogen, chlorophyll, and DNA contents, all in approximately the same proportion as control cells. Two protoplasts often appeared to be contained within one frustule. Metal-treated cells photosynthesized at near-normal rates on a per chlorophyll basis and above normal rates on a per cell basis. Excretion of photosynthetically fixed carbon was depressed by metal treatment; 10–22% of fixed carbon was excreted in control cells and typically less than 1% in treated cells. Thus, metal-treated cells showed an uncoupling of photosynthesis from cell division and continued to enlarge when fixed carbon could not be excreted or utilized in cell division.Uptake of sulphate and silicic acid proceeded at slower rates than other processes (e.g., nitrogen uptake or photosynthesis) in copper-treated cells. Free amino acids in copper-treated cells totalled ≈ 10% of control cell levels, with greatest proportional declines in methionine, cysteine, aspartic acid, valine, and isoleucine. Copper-treated cells resuspended in fresh medium shrank to normal size when exposed to methionine (which they accumulated), although cell division rates did not return to normal. These cells excreted 2–3 times as much fixed carbon as comparable EDTA-treated or untreated cells, neither of which decreased in size. Copper-treated cells appeared indistinguishable from silicon-limited cells (i.e., cells not dividing for lack of silicon) in a copper-free medium. Cells treated with the sulfhydryl binder PCMB divided at reduced rates and also swelled in a manner comparable to copper-treated cells. The results suggest that toxic metals may bind to sulfhydryl groups on cell membranes, impairing normal membrane function and reducing silicic acid uptake and amino-acid synthesis, thereby resulting in depressed cell division rates.     

Inhibition of cell division in Escherichia coli K-12 by the R-factor R1 and copy mutants of R1.

The effect of the copy number of plasmid R1drd-19 on cell division of Escherichia coli K-12 was studied in populations growing as steady-state cultures at different growth rates, the growth rate being varied by use of different carbon sources. The plasmid copy number was also varied by using copy mutants of the R-factor. The mean cell size was larger in populations carrying an R-factor than in R-factorless populations, an effect that was more pronounced at low growth rates and in populations carrying R-factor copy mutants. The increased cell size was due to formation of elongated cells in a fraction of the population and to an increase in the diameter of all cells. The majority of the cells divided at a normal cell length, but the presence of an R-factor caused some cells to elongate, probably by the uncoupling of chromosome replication and cell division. This can be explained as a competition between the chromosome and plasmid replicons for some replication factor(s), presumably acting on both initiation and elongation of replication. The formation of elongated cells was a reversible process, but occasionally some of the elongated cells reached lengths 20 times that of newborn cells. If cell division did not occur at the normal cell size, the septum was not formed until the cell size was four times that of a newborn cell. When an elongated cell divided, it usually formed a polar septum, thus producing a newborn cell of normal cell length. The ability of plasmid-containing cells to omit one cell division but to retain the capacity of dividing one mass doubling later is compatible with a mechanical model for septum formation and cell division.     

A serum factor requirement for the passage of cultured Vero cells through G2.

When Vero cells, a line derived from and African Green Monkey kidney, are grown under conditions where the saturation density is limited by serum, they deplete the growth medium of a factor necessary for cell division. The factor is a component of serum. When Vero cells are plated at low density (2 X 10(4)/cm2) in this depleted growth medium (after dialysis against serum-free Dulbecco's Modified Eagle's Medium) they initiate an unbalanced program of growth. Protein synthesis proceeds at the same rate as parallel cells in fresh serum, and and the cells accumulate protein as a function of time. DNA synthesis is also initiated in these cells, and the amount of DNA per cell increases for the next four days plating. However the cells quickly stop dividing. Measurements of DNA per cell using microspectrofluorometry show that the cells are accumulating in the late S and G2 period during this time. Thus we conclude that these cells cannot pass through a transition point in G2. When fresh serum is added to cells after three days in depleted growth medium, they divide before they begin to synthesize DNA. This further confirms that they are in late S and G2. Cell division is promoted in Vero cells in depleted growth medium by bovine fetuin, and to a lesser extent by bovine albumin. Cell division is not promoted by insulin, hydrocortisone, dexamethasone, linolenic acid, calcium, and typsin inhibitor form ovomucoid. From these data we conclude that transit through G2 requires the prescence of an extracellular factor.     

Neuronal and glial enzyme studies in cell culture

Summary Newborn BALB/c mouse brain was cultured as disaggregated cells after serial trypsin dissociations. The ontogeny of the cultures was followed by assays of cell number, deoxyribonucleic acid, and protein content and by the activities of three enzymes considered to be markers of neuronal differentiation. Aliquots of the freshly dissociated cells were assayed for choline acetylase, acetylcholinesterase, and glutamic acid decarboxylase activities and compared with intact brain. The percentages of recovery of activities, expressed as¹⁴C product formed per mg of protein per 10 min, at pH 6.8 and 37°C, were 37% for choline acetylase, 54% for acetylcholinesterase, and 24% for glutamic acid decarboxylase. The remainder of the freshly dissociated cells were placed into culture; enzyme assays were performed as the cells multiplied and then when the cultures became static. Choline acetylase activity increased as the cells rapidly divided, and glutamic acid decarboxylase activity increased only after the cultures became confluent. Under the culture conditions, acetylcholinesterase was not induced, despite active synthesis of acetylcholine. Neuroblastoma clone N18, C1300 cell line, was grown in cell culture, and the activity of acetylcholinesterase was measured as the cells multiplied and came to confluency. The specific activity of mouse neuroblastoma acetylcholinesterase increased 25-fold when the rate of cell division was restricted. The rate of cell division could be regulated by adjusting the serum concentration. By removing fetal calf serum during the growth period, cell division ceased, and acetylcholinesterase activity was significantly and rapidly induced. Choline-O-acetyltransferase specific activity was measured in rapidly dividing and in static cultures. Its specific activity was highest in nondividing cultures, compared to cultures containing actively dividing cells (6-fold), and the specific activity of thymidylate synthetase was increased 2.5-fold in actively dividing cultures, compared to static cultures. Glioblastoma cells obtained from the rat astrocytoma, clone C6, were grown in culture, and glucose metabolism was measured in control cultures, and in cultures containing norepinephrine (0.017 mg per ml). Norepinephrine produced a 50% inhibition in the incorporation ofd-[¹⁴C]glucose. Cells incubated for 2 hr in the presence ofd-[¹⁴C]glucose, washed and then incubated in control medium or in medium containing norepinephrine, resulted in the release of greater than 50% of radioactive metabolites in the norepinephrine treated plates. Norepinephrine caused a 50% increase in¹⁴CO₂ production in glioblastoma cells incubated withd-[1-¹⁴C]glucose. Norepinephrine, under similar conditions, did not affect the metabolism of glucose in clone C46, C1300 mouse neuroblastoma cells. Portions of this work were supported by a research grant (6-444946-58605) from the American Cancer Society.     

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.     

Growth characteristics of hormone and vitamin independent photoautotrophic cell suspension cultures fromChenopodium rubrum

Summary This communication reports the photoautotrophic growth of hormone and vitamin independent cell suspension cultures ofChenopodium rubrum. The transfer of cells from stationary growth into fresh culture medium results in a high protein formation, followed by an exponential phase of cell division, whereas the onset of rapid chlorophyll formation is delayed for 4 days. At the stage of most rapid cell division there is no net synthesis of starch and sugar. When the cells enter stationary growth, there is a progressive accumulation of chlorophyll, sugar, and starch.Photoautotrophic cell cultures assimilate about 80–90 mol CO₂/mg chlorophyll X hour. Dark CO₂ fixation is about 3.7% to 2.2% of the light values during exponential and stationary growth, respectively. As shown by short-term¹⁴CO₂ fixation, CO₂ is predominantly assimilated through ribulosebisphosphate carboxylase via the Calvin pathway. There is a significant increase in the¹⁴C label of C₄ carboxylic acids in exponentially dividing cells as compared to cells from stationary growth. Thein vitro activity of phosphoenolpyruvate carboxylase and ribulosebisphosphate carboxylase is almost equal during exponential cell division. A decrease in cell division activity is accompanied by a significant change in the specific activities of both carboxylation enzymes. In non dividing cells from stationary growth the activity of ribulosebisphosphate carboxylase is greately enhanced and that of phosphoenolpyruvate carboxylase is reduced, documenting the development of carboxylation capacities typical for C₃-plants.The experimental results provide evidence that phosphoenolpyruvate carboxylase activity might be regulated by ammonia and could be involved in anaplerotic CO₂ fixation which supplies carbon skeletons of the citric acid cycle.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - EDTA ethylene-diamine-tetraacetic acid - FDP fructose bisphosphate - F-6-P fructose-6-phosphate - G-6-P glucose-6-phosphate - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - PGA 3-phosphoglyceric acid - PEP phosphoenolpyruvate - RuDP ribulosebisphosphate     

Characterisation of protoplasts from hypocotyls of Helianthus annuus in relation to their tissue origin

Cells and protoplasts isolated from three different tissues of sunflower hypocotyls and cultured either in liquid or agarose medium were compared in terms of their volume, DNA content, division potential and embryoid formation. Epidermal and external cortical cells differ from other tissue cells by their small size, their weak response to plasmolysis and their low DNA content (around 1C). They contribute only very weakly to the dividing protoplast population. In contrast, protoplasts from cortical and medullar cells both have similar division potential, reaching 50%. The nuclear DNA content of these two cell types, as well as their corresponding protoplasts, has a 2C value, taking root tip cells in G0 phase as standard. The culture conditions induce the same specific response in protoplasts isolated from both tissues: exclusively loose colony formation in liquid medium, and mainly production of embryoids in agarose medium.     

A Millifluidic Study of Cell-to-Cell Heterogeneity in Growth-Rate and Cell-Division Capability in Populations of Isogenic Cells of Chlamydomonas reinhardtii

To address possible cell-to-cell heterogeneity in growth dynamics of isogenic cell populations of Chlamydomonas reinhardtii, we developed a millifluidic drop-based device that not only allows the analysis of populations grown from single cells over periods of a week, but is also able to sort and collect drops of interest, containing viable and healthy cells, which can be used for further experimentation. In this study, we used isogenic algal cells that were first synchronized in mixotrophic growth conditions. We show that these synchronized cells, when placed in droplets and kept in mixotrophic growth conditions, exhibit mostly homogeneous growth statistics, but with two distinct subpopulations: a major population with a short doubling-time (fast-growers) and a significant subpopulation of slowly dividing cells (slow-growers). These observations suggest that algal cells from an isogenic population may be present in either of two states, a state of restricted division and a state of active division. When isogenic cells were allowed to propagate for about 1000 generations on solid agar plates, they displayed an increased heterogeneity in their growth dynamics. Although we could still identify the original populations of slow- and fast-growers, drops inoculated with a single progenitor cell now displayed a wider diversity of doubling-times. Moreover, populations dividing with the same growth-rate often reached different cell numbers in stationary phase, suggesting that the progenitor cells differed in the number of cell divisions they could undertake. We discuss possible explanations for these cell-to-cell heterogeneities in growth dynamics, such as mutations, differential aging or stochastic variations in metabolites and macromolecules yielding molecular switches, in the light of single-cell heterogeneities that have been reported among isogenic populations of other eu- and prokaryotes.     

Synchronized cultures of a cell wall-less mutant of Chlamydomonas reinhardii

Synchronization and synchronous growth of a cell wall-less mutant of Chlamydomonas reinhardii have been described. The following growth conditions were used: A modified Sueokas' high salt minimal medium, 1410 h light-dark cycle, growth temperature 30°C, light intensity 12–18 Klux and dilution of the culture at the end of the dark to a constant cell density of 1.0·10⁶ cells/ml. The time course of increase and distribution of cell volume, cytoplasmic and nuclear division, release of motile cells after the division period and accumulation of DNA, RNA and protein are reported. These mutant cells did not make any sporangium in which the dividing cells were kept as a unit inside a mother cell wall. However, they usually adhered during the period of division, thus making clumps containing 2, 4 and 8 cells. Several of these cell clumps dissolved releasing either single or couples of 2 and 4 cells. After the end of division the cells became flagellated and motile and thereby releasing themselves from the aggregate.Non-Standard Abbreviations AWV average weighed cell volume - MM minimal medium - HSM high salt medium - TCA trichloroacetic acid     

The interrelationship of cell growth and division in haploid and diploid cells of Saccharomyces cerevisiae

The coordination of cell growth and division has been examined in isogenic haploid and diploid strains of Saccharomyces cerevisiae. The average cell volume of the haploid and diploid cells was unaffected by a range of environmental conditions and generation times. For most environments and generation times the mean cell volume of diploid cells was between 1.52 and 1.83 of the haploid cell volume. Both haploid and diploid cell volumes were reduced drastically when the cells were grown in the chemostat with glucose as the limiting substrate. In this environment diploid cells have the same mean cell volume as haploid cells. Diploid cells are more elongated than haploid cells, and the characteristic shape (eccentricity) of the cells is unaffected by all environmental conditions and generation times tested. Mother cell volume increased during the cell cycle, although the pattern of this increase was affected by the environmental conditions. Under most growth conditions detectable mother cell volume increase occurred only during the budding phase, whereas under conditions of carbon limitation detectable increase only occurred during the unbudded phase. A consequence of this result is that the mean cell volume of haploids at bud initiation is relatively constant in all environments, including carbon limitation. This suggests that there is a critical size for bud initiation for haploids which is constant and independent of environmental conditions. The results for diploids are more complex. Coordination of growth and division in haploid cells can be explained by a simple model initially developed for prokaryotes by Donachie. A modification of this model is proposed to account for the results with diploids.     

Analysis of Cell Division and Elongation Underlying the Developmental Acceleration of Root Growth in Arabidopsis thaliana

To investigate the relation between cell division and expansion in the regulation of organ growth rate, we used Arabidopsis thaliana primary roots grown vertically at 20°C with an elongation rate that increased steadily during the first 14 d after germination. We measured spatial profiles of longitudinal velocity and cell length and calculated parameters of cell expansion and division, including rates of local cell production (cells mm⁻¹ h⁻¹) and cell division (cells cell⁻¹ h⁻¹). Data were obtained for the root cortex and also for the two types of epidermal cell, trichoblasts and atrichoblasts. Accelerating root elongation was caused by an increasingly longer growth zone, while maximal strain rates remained unchanged. The enlargement of the growth zone and, hence, the accelerating root elongation rate, were accompanied by a nearly proportionally increased cell production. This increased production was caused by increasingly numerous dividing cells, whereas their rates of division remained approximately constant. Additionally, the spatial profile of cell division rate was essentially constant. The meristem was longer than generally assumed, extending well into the region where cells elongated rapidly. In the two epidermal cell types, meristem length and cell division rate were both very similar to that of cortical cells, and differences in cell length between the two epidermal cell types originated at the apex of the meristem. These results highlight the importance of controlling the number of dividing cells, both to generate tissues with different cell lengths and to regulate the rate of organ enlargement.