Embryonic cell commitment by a simultaneous alteration in nucleo/cytoplasmic ratio in sibling cells between subsequent cell cycles

Studies on murine embryonal carcinoma (EC) cell lines have revealed a mechanism for commitment of early embryonic cells. By means of a particular intraclonal cell surface glycoprotein and intermitotic time heterogeneity found in the EC lines used, we have devised a cell cycle model and written a computer program for cell cycle stimulation. In the present investigation experimental tissue culture data obtained from the EC lines were inserted into the computer program and the simulations represent a good fit to experimental data. It is shown that the dynamics of the driving forces in the 'cell growth cycle' and the 'DNA-division cycle', when assumed to be loosely coupled and analyzed in subsequent cell cycles, reveal a mechanism that can commit the mother cell to impel her daughter cells into the next stage in embryonic development by altering the relationship between those two uncoupled subcycles. Thereby the nucleo/cytoplasmic ratio (DNA/mass) is altered in a similar way in the two daughter cells. The simulations increase the reliability of the model and open up possibilities to test other embryonic cell systems.     

Cell Growth and Cell Division: Dissociated and Random Initiated?

Abstract. The 'random transition probability' cekycle models have so far failed to convincingly link the transition events with phenomena describable by biochemical methods. the study presented was carried out on the F9 and PCC3 N/1 embryonal carcinoma (EC) cell lines. We now report an extended analysis of the two-random transition probability (TP) model and preliminary results are presented showing that the deterministic L period in that model can be regarded as reflecting the 'cell-growth cycle'. Evidence is presented that suggests that the 'cell-growth cycle' is a supramitotic deterministic phase—i.e. starting in one cell cycle and being completed in the next following G₁ period and dissociated from the 'DNA-division cycle'. This phenomenon makes an interesting contribution to the old knowledge of a stepwise G₁ prolongation during early embryogenesis in yielding a mechanism by which the cell can alter the ratio of nucleus to cytoplasm prior to the onset of gene expression.     

Regulation of DOPA Decarboxylase Activity in Brain of Living Rat

Abstract: To test the hypothesis that l -DOPA decarboxylase (DDC) is a regulated enzyme in the synthesis of dopamine (DA), we developed a model of the cerebral uptake and metabolism of [³H]DOPA. The unidirectional blood-brain clearance of [³H]DOPA ( K ^D₁) was 0.049 ml g⁻¹ min⁻¹. The relative DDC activity ( k ^D₃) was 0.26 min⁻¹ in striatum, 0.04 min⁻¹ in hypothalamus, and 0.02 min⁻¹ in hippocampus. In striatum, 3,4-[³H]dihydroxyphenylacetic acid ([³H]DOPAC) was formed from [³H]DA with a rate constant of 0.013 min⁻¹, [³H]homovanillic acid ([³H]HVA) was formed from [³H]DOPAC at a rate constant of 0.020 min⁻¹, and [³H]HVA was eliminated from brain at a rate constant of 0.037 min⁻¹. Together, these rate constants predicted the ratios of endogenous DOPAC and HVA to DA in rat striatum. Pargyline, an inhibitor of DA catabolism, substantially reduced the contrast between striatum and cortex, in comparison with the contrast seen in autoradiograms of control rats. At 30 min and at 4 h after pargyline, k ^D₃ was reduced by 50% in striatum and olfactory tubercle but was unaffected in hypothalamus, indicating that DDC activity is reduced in specific brain regions after monoamine oxidase inhibition. Thus, DDC activity may be a regulated step in the synthesis of DA.     

Cell density downregulates DNA synthesis and proliferation during osteogenesis in vitro

Abstract. The classical models of in vitro cell culture comprise fibroblasts and epithelial cells. Osteogenic cells represent another interesting cell model; however, it is not known whether during osteogenesis cell density regulates cell growth as seen in cultures of fibroblasts and epithelial cells. We selected MC3T3-E1 cells for study because they are an osteogenic cell line that, when subcultured, grow to confluence and form multilayers of cells in conventional cultures by continued proliferation, as do fibroblasts. Once maximum cell density is obtained, proliferation is down regulated resulting in a mixed population of quiescent and dividing cells. We used this model to determine whether downregulation of proliferation as expressed by cell number and DNA synthesis is cell density-dependent. MC3T3-E1 cells were cultured over a period of 34 days to determine their kinetics, viability, ability to synthesize DNA, distribution within phases of the cell cycle and cell number-response relationships. Our results show that (1) viability ranged between 92% and 96% and the cell number 2.5 x 10⁵ per cm² once cultures reached steady state, (2) most cells entered the G₀/G₁ phase of the cell cycle on day 7, (3) there was no correlation between the proportion of cells in S phase and downregulation of DNA synthesis, (4) a direct relationship exists between cell density and downregulation of DNA synthesis on day 8, (5) the minimum time for cells to be cultured before downregulation of DNA synthesis begins is independent of cell number, and (6) downregulation of DNA synthesis is reversible. These results suggest that density-dependent downregulation of DNA synthesis may be a mechanism of growth control for osteogenic cells in vitro that operates more like density-dependent growth control in cultures of fibroblasts rather than epithelial cells.     

Kinetics of photoautotrophic growth of Marchantia polymorpha cells in suspension culture

Chlorophyllous, cultured cells of Marchantia polymorpha L. (HYA-2 cell line) grow actively under photoautotrophic (lithotrophic) conditions. The maximum specific growth rate (μ_cell) was 0.64 day⁻¹ and the doubling time was 1.08 days under optimum conditions (165 μmol m⁻² s⁻¹, 1% carbon dioxide enriched atmosphere, 25^°C). The photosynthetic activity was 1.30 μmol CO₂-fixed (10⁶ cells)⁻¹ h⁻¹ [66 μmol (mg chlorophyll)⁻¹ h⁻¹] in the exponential phase. The growth course has two distinct phases, an exponential and a linear one. The exponential phase is observed as long as the population density is sufficiently low (less than 7.9 × 10⁶ cells ml⁻¹), so that practically all individual cells directly receive the full incident light. The effect of light on the specific growth rate is a linear function of photon flux density. Linear growth occurs after the population density is so high that the incident light is almost completely absorbed by the cell suspension. The growth rate is a logarithmic function of photon flux density, in contrast to the specific growth rate, and saturates at high photon flux densities. The conditions of maximum growth, however, are not wellbalanced between cell mass production and cell division. Therefore, the maximum growth does not continue for a long time.     

Cyclic AMP-Elevating Agents Inhibit Proliferation of Keratinizing Guinea Pig Epidermal Cells

Cultured guinea pig epidermal cells and dermal fibroblasts were chosen as model systems to study possible growth inhibition by cyclic AMP (cAMP)-elevating drugs. The rate of DNA synthesis was used to assay growth rate in control cultures and those treated with agents which increase intracellular cAMP, including dibutyryl cAMP, the phosphodiesterase inhibitors papaverine and theophylline and agents which stimulate adenylate cyclase, iso-proterenol and prostaglandin E₂ methyl ester. Treatment for 24 h with dibutyryl cAMP (10⁻⁴ to 10⁻² M) inhibited cell growth by 50 to 95%, whereas butyrate(10⁻⁴M) showed essentially no effect. This inhibition could not be attributed to decreased precursor transport or to drug toxicity. Papaverine (10⁻⁶ to 10⁻⁴ M) and theophylline (10⁻⁴ to 10⁻³ M) also gave dose-dependent growth inhibition as did isoproterenol and prostaglandinE₂methyl ester. Radioautographic analysis of grain density after dibutyryl cAMP treatment and ³H-thymidine incorporation indicated no S-phase inhibition. Cyclic AMP-elevating drugs appear to inhibit growth of guinea-pig epidermal cells and dermal flbroblasts by blocking the cell cycle in G₋₂, M₁, or G. ₋₁     

The HAL1 function on Na+ homeostasis is maintained over time in salt-treated transgenic tomato plants, but the high reduction of Na+ in leaf is not associated with salt tolerance

To achieve a deeper knowledge on the function of HAL1 gene in tomato ( Solanum lycopersicum ) plants submitted to salt stress, in this study, we studied the growth and physiological responses to high salt stress of T3 transgenic plants (an azygous line without transgene and both homozygous and hemizygous lines for HAL1 ) proceeding from a primary transformant with a very high expression level of HAL1 gene. The homozygous plants for HAL1 gene did not increase their salt tolerance in spite of an earlier and higher reduction of the Na⁺ accumulation in leaves, being moreover the Na⁺ homeostasis maintained throughout the growth cycle. The greater ability of the homozygous line to regulate the Na⁺ transport to the shoot to long term was even shown in low accumulation of Na⁺ in fruits. By comparing the homozygous and hemizygous lines, a higher salt tolerance in the hemizygous line, with respect to the homozygous line, was observed on the basis of fruit yield. The Na⁺ homeostasis and osmotic homeostasis were also different in homozygous and hemizygous lines. Indeed, the Na⁺ accumulation rate in leaves was greater in hemizygous than in homozygous line after 35 days of 100 m M NaCl treatment and only at the end of growth cycle did the hemizygous line show leaf Na⁺ levels similar to those found in the homozygous line. With respect to the osmotic homeostasis, the main difference between lines was the different contribution of inorganic and organic solutes to the leaf osmotic balance. Taken together, these results suggest that the greater Na⁺ exclusion ability of the homozygous line overexpressing HAL1 induces a greater use of organic solutes for osmotic balance, which seems to have an energy cost and hence a growth penalty that reverts negatively on fruit yield.     

Photosynthesis and photoassimilation of glucose during photomixotrophic growth of Marchantia polymorpha cells in suspension culture

Even in the presence of glucose the growth of Marchantia polymorpha L. (cell line HYH-2F) requires light, and growth is more sensitive to 10⁻⁶ M 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea than to 10⁻⁴ Antimycin A. The inability of the cells to grow in the dark is due to the low level of respiration. The respiration rate under light increased to four times the dark value. The values of the compensation ratio (the photosyntehtic rate/the respiration rate) for the oxygen exchange were below 1.0 daring the growth period, although oxygen evolution was found. At the early exponential phase, oxygen evolution was 0.373 μmol (mg cell dry weight)⁻¹ h⁻¹ [61.7 μmol (mg chlorophyll)⁻¹ h⁻¹]. M. polymorpha cells are unable to grow anaerobically in the light without a supply of carbon dioxide. When 1% carbon dioxide in nitrogen is supplied, photochemically produced oxygen and energy are sufficient for sustained growth although at significantly reduced yields in both cell dry weight and chlorophyll. Photosyntehtic CO₂ assimilation rate was 0.13 μmol (mg cell dry weight)⁻¹ h⁻¹[11.3 μmol (mg chlorophyll)⁻¹ h⁻¹]. At least one-third of the carbon atoms in cellular constituents seem to be derived from atmospheric carbon dioxide, which indicates that M. polymorpha cells grow photomixotrophicaily.     

Relationships between bone growth rate, body mass and resting metabolic rate in growing amniotes: a phylogenetic approach

We explored the factors that explain the variation in resting metabolic rates (RMR) in growing amniotes by using the phylogenetic comparative method. For this, we measured raw RMR (mL O₂ h⁻¹), body mass, body mass growth rate, and periosteal bone growth rate in a sample of 44 growing individuals belonging to 13 species of amniotes. We performed variation partitioning analyses, which showed that phylogeny explains a significant fraction of the variation of mass-specific RMR (mL O₂ h⁻¹ g⁻¹), and that the cost of growth is much higher than the cost of maintenance. Moreover, we tested the hypothesis of the independence of energy allocation, and found that maintenance metabolism and growth rates are not significantly related. Finally, we calculated the statistical parameters of the relationship between geometry-corrected RMR (mL O₂ h⁻¹ g^−0.67) and bone growth rate. This relationship could potentially be used in palaeobiology to infer RMR from bone tissue samples of fossil species by assuming Amprino's rule (according to which bone tissue types reflect bone growth rates). These estimates would be especially interesting for Mesozoic non-avian theropod dinosaurs and Permian and Triassic therapsids to investigate, respectively, the origin of avian and mammalian endothermy.  © 2007 The Linnean Society of London, Biological Journal of the Linnean Society , 2007, 92 , 63–76.     

Growth pattern of the human promyelocytic leukaemia cell line HL60

Abstract. In order to characterize the growth pattern of the human promyelocytic leukaemia cell line HL60, its kinetic parameters were studied. The doubling time was calculated from serial cell counts, the duration of the various cell cycle phases from the analysis of the labelled mitoses curve, and quiescent population from continuous labelling experiments. Proliferation in culture was exponential up to a saturation density of about 3.0 × 10⁶ cells/ml, with a doubling time of 34.0 hr. The cell cycle duration was 24.3 ± 4.1 hr (SD), and that of the cell cycle phases was: G₁, 3.8 ± 2.2 hr; S, 15.1 ± 3 hr; and G₂, 5.4 ± 1.2 hr. The growth fraction was 0.85, and cell loss was restricted to the quiescent cells. The HL60 cell line, with fully characterized kinetics, provides a useful tool for the in vitro study of substances which may affect human leukaemic myelopoietic proliferation.     

Cell cycle regulation and the timing of chromosome replication in a marine synechococcus (cyanobacteria) during light- and nitrogen-limited growth

Cell cycle behavior in the marine Synechococcus strain WH8101 was examined in detail over a wide range of light- and nitrogen-limited growth rates. The presence of bimodal DNA frequency distributions under all conditions confirms that the overlapping rounds of DNA replication that characterize E. coli and other fast-growing prokaryotes are not present in this organism. Although chromosome replication time, C , was constrained to a fairly narrow range of values overall, it nevertheless did vary with growth rate and limiting factor. Light-limited cells growing at moderate rates had higher C values than did N-limited cells growing at comparable rates (by as much as a factor of 2). As these cells became light saturated, however, C decreased sharply to the level observed under N limitation. The post-replication period, D , decreased monotonically with growth rate under both light and N limitation, approaching a constant value at moderate to high growth rates. Average cell volume at the time of initiation of DNA replication was calculated from the values of C and D , combined with directly measured mean cell volume, and was found to be constant at all growth rates above ∼0.7 d⁻¹. This pattern was confirmed by estimates of initiation volume based on flow cytometric light scatter measurements, and suggests that as has been found in other prokaryotic systems, cell mass may play an important role in regulating the timing of chromosome replication in cyanobacteria. Furthermore, because the magnitude of C + D influences average cell mass (given a constant mass at initiation), changes in these parameters (particularly C ) may be responsible for the previously reported nonlinear relationship between light-limited growth rate and both RNA cell⁻¹ and average cell volume.     

A mathematical model of the regulation of the G1 phase of Rb+/+ and Rb−/− mouse embryonic fibroblasts and an osteosarcoma cell line

A mathematical model integrating the roles of cyclin D, cdk4, cyclin E, cdk2, E2F and RB in control of the G₁ phase of the cell cycle is described. Experimental results described with murine embryo fibroblasts (MEFs), either Rb+/+ or Rb−/−, and with the RB-deficient osteosarcoma cell line, Saos-2, served as the basis for the formulation of this mathematical model. A model employing the known interactions of these six proteins does not reproduce the experimental observations described in the MEFs. The appropriate modelling of G₁ requires the inclusion of a sensing mechanism which adjusts the activity of cyclin E/cdk2 in response to both RB concentration and growth factors. Incorporation of this sensing mechanism into the model allows it to reproduce most of the experimental results observed in Saos-2 cells, Rb−/− MEFS, and Rb+/+ MEFs. The model also makes specific predictions which have not been tested experimentally.     

A novel growth stimulating activity from BRL-3A cell conditioned medium

The R⁻ cell line is a 3T3-like cell line originating from mouse embryos with a homozygous disruption of the type 1 insulin-like growth factor receptor (IGF-IR) genes. Although R⁻ cells cannot grow at all in serum-free medium (SFM) supplemented by several known growth factors, either singly or in combination, they are able to grow in 10% serum, albeit at a reduced rate. These findings suggested that serum contains an unknown, or unidentified, growth factor that can promote cell growth even in cells devoid of IGF-IRs. In an effort to identify such growth factor, we searched, using R⁻ cells, for a growth and DNA synthesis stimulating activity in SFM conditioned by different cell lines. We found that the BRL-3A cell line secreted an activity capable of stimulating DNA synthesis and cell proliferation in R⁻ cells. This activity (which is concentration-dependent) can be collected and concentrated by ultrafiltration, it is heat-labile, proteinase K-sensitive and has a size larger than 10 kDa. Because of the resistance of R⁻ cells to stimulation by known growth factors, we believe that this activity is due to a novel polypeptide secreted by BRL-3A cells. Further characterization of the active component(s) is in progress.     

Flow cytometric correlation of the c-myc oncoprotein and cell cycle kinetics of HL60 leukaemia during induced maturation with cytosine arabinoside and dimethylsulphoxide

Abstract The c-myc oncogene codes for a DNA binding protein that functions in a cell cycle-related manner. A useful model for studying the relationship of c-myc expression with cell cycle kinetics is the HL60 cell line. HL60 cells constitutively express high levels of c-myc mRNA; however, the level can be down-regulated as the cells are induced to differentiate. We have developed a flow cytometric assay for correlating c-myc oncoprotein levels with DNA content. C-myc oncoprotein levels were additionally correlated with c-myc mRNA levels as determined by slot blot hybridization. Dimethylsulphoxide (DMSO) and cytosine arabinoside were used to induce granulocytic and monocytic maturation respectively. Treatment of HL60 cells with DMSO leads to an increase in the per cent of cells in G₁/G₀ and a decrease in mean c-myc mRNA and oncoprotein levels. The cells with G₁ DNA content show the greatest decrease in c-myc protein. ARA-c treatment of HL60 cells leads to a slowing and an accumulation of cells in S phase with a moderate decrease in mean mRNA and only a slight decrease in mean c-myc protein levels. These data support the hypothesis that c-myc is involved in the switch from G₁ to G₀.     

Unbalanced growth in mouse cells with amplified dhfr genes

When grown in the absence of methotrexate, cells carrying unstably amplified dihydrofolate reductase ( dhfr ) genes have a growth disadvantage that is a function of their level of gene amplification. Although this growth disadvantage is thought to drive the loss of unstably amplified dhfr genes in the absence of methotrexate, its mechanism is not understood. The present studies of murine cell lines with different levels of dhfr gene amplification demonstrate that such cells experience increased unbalanced growth (excess RNA and protein content relative to DNA content) with increased levels of dhfr gene amplification. Stathmokinetic analysis of a cell line with unstably amplified dhfr genes showed that the unbalanced growth was associated with a very low rate of G₁/S transit, which suggests that amplified DNA sequences may activate a cell cycle checkpoint at the G₁/S boundary. Hydroxyurea, which is known to induce rapid elimination of amplified genes at sub-cytotoxic concentrations, also inhibits the cell cycle at the G₁/S transition and causes unbalanced growth. Earlier work has shown that hydroxyurea selectively targets those cells within the heterogeneous drug resistant cell populations which have the highest amplified gene dosage. The finding that unstable gene amplification and hydroxyurea have similar effects on the cell suggests that hydroxyurea may achieve this selective targeting by pushing those cells with the highest levels of gene amplification over a critical stress threshold to cause growth arrest or cell death.     

Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Abstract. Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G¹, S and G₂+ M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about twofold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle ( T _c) was 15-3 h for PB-3 cells and 12-4 h for PB-1 cells. Shortening in T _c for the transformed cells was due to a decrease of nearly 30% in mean duration of the G ₁ phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G₂+ M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G¹ phase of the cell cycle.     

Exponential growth, random transitions and progress through the G1 phase: computer simulation of experimental data

Abstract. At a time of increasing knowledge of gene and molecular regulation of cell cycle progression, a re-evaluation is presented concerning a phenomenon discussed before the present expanding era of cell cycle research. 'Random transition'and exponential slopes of α- and β-curves were conceived in the 1970s and early 1980s to explain cell cycle progression. An exponential behaviour of the β-curve was claimed as being necessary and sufficient for a 'random transition'in the cell cycle. In our present work, similar slopes of those curves were shown to materialize when the increase in mass of single cells was set as exponential in a structured cell cycle model where DNA replication and increase in cell mass were postulated to be two loosely coupled subcycles of the cell cycle, without introducing any 'random transition'. Findings published in the 1980s demonstrating the effect of serum depletion of 3T3 Balb-c cells were simulated and the shallower slope of the α- and β-curves found experimentally could be attributed to the reduced rate of exponential growth in cell mass, rather than to a reduced 'transition probability'.     

Effects of oxygen, pH and nitrate concentration on denitrification by Pseudomonas species

Abstract The production of nitrogen-containing gases by denitrification in three organisms was examined using membrane inlet mass spectrometry. The effects of O₂ (during both growth and maintenance) and of pH, nitrate concentration and carbon source were tested in non-proliferating cell suspensions. Two strains of Pseudomonas aeruginosa were capable of co-respiration of NO₃⁻ and O₂ and, under controlled O₂ supply, gave oscillatory denitrification. Variations in culture and assay conditions affected both the rate of denitrification and the ratio of end products (N₂O:N₂). Higher rates were seen following anaerobic growth. Optimum values of pH and nitrate concentration for denitrification are given. Generally, the optimum pH was 7.0–7.5, approximately that of the growth medium. Optimum nitrate concentration was generally 20 mM.