Growth control in HeLa cells by serum and anchorage

HeLa-S3 cells in suspension cultures arrest in the G1(G0) phase of the cell cycle because DNA synthesis is controlled by serum factor(s). In monolayer cultures of identical cells DNA synthesis is constitutive, i.e. independent of external signals, and cells grow without restraint. These cells reversibly display “normal” or “transformed” properties depending on the culture conditions.     

Growth-mediated, density-dependent inhibition of endocytosis in cultured arterial smooth muscle cells

The effects of cell density and growth upon fluid phase endocytosis were investigated in quiescent and growing cultures of monkey arterial smooth muscle cells. Cells were maintained in a quiescent state of growth in 5% plasma-derived serum. Subsequent exposure of subconfluent cultures to the specific mitogens, platelet-derived growth factor (PDGF), epidermal growth factor (EGF), fibroblast growth factor (FGF), or to whole blood serum, resulted in up to 4-fold increases in the rate of fluid endocytosis/cell. The changes began several hours after entry into G1 phase of the cell cycle and continued through S. The fraction of cells entering the growth cycle was variable (PDGF=FGF>EGF) and a close correlation existed between the rate of endocytosis and the fraction of [³H]thymidine-labelled cells (r = 0.929, p<0.01). At a range of cell densities, the rate of fluid endocytosis/cell was similar in sparse, confluent and post-confluent cultures of quiescent cells; in contrast, in growing cells there was density-dependent inhibition of endocytosis. Furthermore, when quiescent cells were in contact with each other and were then exposed to mitogens, the growth response was diminished and there was only a 25–50% increase in the rate of endocytosis, even in the presence of high concentrations of growth factors.These studies indicate that the influence of cell density upon fluid endocytosis in arterial smooth muscle cells is indirect in that it represents a secondary effect of decreased mitogenic response to specific growth factors.     

Establishment and growth kinetics of the mutant Ehrlich-Lettré ascites cell strain HD33 in permanent suspension culture

Cells of a mutant in vivo subline of the Ehrlich-Lettré mouse ascites tumour (ELAT) were converted to growth in suspension culture. Kinetic analysis revealed the selective character of the conversion process; without a detectable adaptation period, a fraction of about 2 X 10(-5) of the explanted cells continued to grow in vitro. The resulting, mutant Ehrlich-Lettré ascites cell strain was designated HD33 and propagated uninterruptedly from 1974 on. The corresponding in vivo ELAT subline HD33 was derived from the HD33 ascites cell strain by intraperitoneal retransplantation. In HD33 cell suspension cultures, the population doubling time, the average intermitotic interval, as determined by videomonitoring, and the average duration of the cell cycle, as determined from percentage of labelled mitoses (PLM) data, were all measured at 15 hr. Cell loss and quiescent compartments were insignificant. The duration of the G1 phase was effectively zero. Both PLM data and [3H]/[14C] thymidine double-labelling measurements revealed an S-phase duration of between 11 and 12 hr. The G2 phase lasted 3-5 hr. The HD33 strain differs from comparable suspension strains of wild-type Ehrlich ascites cells in the insignificant role of density-dependent inhibition in growth, and the striking prolongation of the S phase which is associated with an excessive, cytoplasmic storage of glycogen by the mutant cells.     

The effect of macrofixation on derepressed sugar transport systems of chick embryo fibroblasts

The large molecular weight polyaldehyde (macrofixative) obtained by periodate oxidation of dextran has been shown to react with the external cell surface. Chick embryo fibroblasts (CEF), which had been treated with macrofixative (MFx), were examined for the effect on the rates of sugar transport. The low “basal” rate of sugar uptake, seen in confluent (high density) cultures of CEF was unaffected by such treatment. Low density (rapidly growing) cultures, oncogenically transformed cultures, and glucose-starved cultures have rates of sugar uptake that are significantly higher than the “basal” level. Macrofixation was found to inhibit the induction of higher rate of glucose transport under all of these conditions. The results indicate that a difference may exist between the sugar transport system in resting (confluent) cells, and that in “derepressed” cells.     

The effect of feeder type and change of feeder type on growing and finishing pig performance and behaviour

Reduced feed intake and hence lower growth rates commonly occur when the environment of the pig changes, e.g. at weaning and when pigs are moved from growing accommodation to finishing accommodation. It is hypothesised that if environmental factors, such as feeder type, remain the same in the weaning and finishing accommodation this ‘growth check’ may be reduced. A total of 640 pigs in 32 pens of 20 pigs per pen were used to investigate the effects of two feeder types and changing or not changing the feeder type at 10 weeks of age on growth performance and behaviour in the periods from 4 to 10, 10 to finish (22) and from 4 to finish (22) weeks of age, respectively. The two feeder types tested were a ‘wet and dry’ single-space (S) feeder and a ‘dry’ multi-space feeder (M).In the period 4–10 weeks of age feeder type had no significant effect on growth performance though pigs on the ‘dry’ multi-space feeder tended to exhibit significantly better feed efficiency from 4 to 7 weeks of age. In the first week after changing accommodation the growth rate of pigs on all treatments was depressed (compared to the last 3 weeks of the grower period) and was reduced a further 60 g/day when the feeder type was changed. However, the “feeder” effect was transitory and had no effect on overall finisher performance except for pigs changed from a ‘dry’ multi-space feeder to ‘wet and dry’ single-spaced feeder. These animals had significantly faster growth rate over the finisher phase (P<0.05, 886 g/day) and between 4 weeks of age and finish (P<0.05, 730 g/day) than pigs on all other treatments. Feeder treatment had no significant effect on feed intake or feed efficiency in the finisher period or overall from wean to finish. Similarly, the treatments had no effect on the variation in growth rate. Behavioural observations showed that the average number of pigs at the feeder during the finishing period was significantly higher when feed was offered from treatment M–S (1.19 (freq/30 s), P<0.001). In conclusion, the present results suggest that, a change in feeder type, from a ‘dry’ multi-space feeder in growing accommodation to a ‘wet and dry’ single-space feeder in finishing accommodation appears to stimulate improved growth performance in the early finishing period and overall from weaning to finish.     

Multiple cell culture factors can affect the glycosylation of Asn-184 in CHO-produced tissue-type plasminogen activator

Human tissue-type plasminogen activator (t-PA) contains a variably occupied glycosylation site at Asn-184 in naturally produced t-PA and in t-PA produced in recombinant Chinese hamster ovary (CHO) cells. The presence of an oligosaccharide at this site has previously been shown to reduce specific activity and fibrin binding. In this report, the site occupancy of t-PA is shown to increase gradually over the course of batch and fed-batch CHO cultures. Additional cell culture factors, including butyrate and temperature, are also shown to influence the degree of glycosylation. In each of these cases, conditions with decreased growth rate correlate with increased site occupancy. Investigations using quinidine and thymidine to manipulate the cell cycle distribution of cultures further support this correlation between site occupancy and growth state. Comparison of the cell cycle distribution across the range of cell culture factors investigated shows a consistent relationship between site occupancy and the fraction of cells in the G(0)/G(1) phase of the cell cycle. These results support a correlation between growth state and site occupancy, which fundamentally differs from site occupancy trends previously observed and illustrates the importance of the growth profile of CHO cultures in producing consistently glycosylated recombinant glycoproteins.     

Effects of prostaglandin E1 and isoproterenol on cyclic AMP content of human fibroblasts modified by time and cell density in subculture

In confluent cultures of “young” (< 30 generations) human fibroblasts, maximally effective concentrations of prostaglandin E₁ (5.6 μM) and isoproterenol (2 μM) increased cyclic AMP content several hundred-fold and approximately 30-fold, respectively. On the first day after initiation of cultures at either low (approx. 3 · 10⁵ cells) or high (approx. s · 10⁶ cells) cell density the magnitude of the isoproterenol effect was similar to that in confluent cultures. It increased during the next few days, reaching a maximum around day 2–3, and then declined. On any day during the period of subculture, the magnitude of the isoproterenol effect was inversely related to cell density. Alterations in response to prostaglandin E₁ as a function of time in subculture or cell density were less dramatic. The effects of prostaglandin E₁ were, however, smaller at some point during the first few days of subculture than after day 7, and when effects of prostaglandin E₁ were minimal, those of isoproterenol were maximal and approached those of prostaglandin E₁. On any day of subculture, cells in cultures of higher density tended to accumulate more cyclic AMP in response to prostaglandin E₁ than did those in low density cultures. The effects of prostaglandin E₁ and isoproterenol on cyclic AMP content were qualitatively similar in “young” and in “old” (> 60 generations in culture) human fibroblasts although the changes associated with duration of subculture and cell density tended to be less marked with “old” cells. In the “young” fibroblasts responsiveness to isoproterenol and prostaglandin E₁ appears to correlate with cell morphology and with the fractional rate of growth in subcultures. It is suggested that the capacities of the fibroblasts to respond to these two agents may be altered independently during growth of human fibroblasts.     

Mating-Type Regulation of Methyl Methanesulfonate Sensitivity in SACCHAROMYCES CEREVISIAE

Heterozygosity at the mating-type locus (MAT) in Saccharomyces cerevisiae has been shown previously to enhance X-ray survival in diploid cells. We now show that a/α diploids are also more resistant to the radiomimetic agent methyl methanesulfonate (MMS) than are diploids that are homozygous at MAT (i.e., either a/a or α/α). Log-phase a/α cultures exhibit biphasic MMS survival curves, in which the more resistant fraction consists of budded cells (those cells in the S and G2 phases of the cell cycle). Survival curves for log-phase cultures of a/a or α/α diploids have little if any biphasic nature, suggesting that the enhanced S- and G2-phase repair capacity of a/α cells may be associated with heterozygosity at MAT. The survival of cells arrested at the beginning of the S phase with hydroxyurea indicates that MAT-dependent MMS repair is limited to S and G2, whereas MAT-independent repair can occur in G1.     

Towards a further understanding of the growth-inhibiting action of oxygen deficiency. Evaluation of the effect of antimycin on proliferating Ehrlich ascites tumour cells

The effect of 1 microM antimycin on the proliferative properties, metabolism and basic cell composition of Ehrlich ascites tumour cells cultured in the second in vitro passage was studied. Continuous drug exposure of asynchronous cells caused rapid cessation of cell growth, characterized by the cell number and DNA, RNA and protein content of cultures. Cells cease to consume oxygen and enhance their glycolytic activity. Uptake of labelled thymidine into acid-insoluble material was far below that of the controls, whereas incorporation of labelled uridine exceeded that of controls, as was also observed with other inhibitors of the respiratory chain (sodium cyanide, 2-thenoyltrifluoroacetone, or anaerobiosis). The influence of antimycin on cells at different stages of the cell cycle was tested using cells enriched in either G1, S or G2 phase by centrifugal elutriation. DNA histograms (flow cytometry) and pulse-labelling index curves gave detailed insight into cell-cycle progression of antimycin-treated cells: G1 and early S cells remained stationary; G2 cells still passed from G2 into mitosis to remain subsequently in a non-growing state in G1; S cells were either slowed or halted. Supplementation of antimycin-containing cultures with exogenous pyrimidine nucleosides stimulated reprogression of G1 cells without changing their ATP content. The results of the current experiments are interpreted as supporting the concept that growth cessation of G1 cells under respiratory insufficiency is not predominantly caused by impairment of respiratory phosphorylation but may be the consequence of a lack of precursors for DNA and RNA synthesis.     

Tumour cell proliferation in relation to the vasculature.

The proliferation pattern of a transplantable mouse mammary carcinoma has been studied in relation to its macroscopic and microscopic structure. No significant differences were seen in the labelling or mitotic indices or in the percentage labelled mitoses curves for the peripheral 2.0 mm rim or for the central tumour core. When these parameters were scored for cells classified according to their position in relation to capillaries or to necrotic regions, marked differences were observed in all the parameters. Higher labelling and mitotic indices and higher grain counts were seen adjacent to the capillaries. These appear to result from a shorter cell cycle duration and a higher growth fraction. The variation in cell cycle is mainly due to a change in the duration of G1.     

Cell cycle model for growth rate and death rate in continuous suspension hybridoma cultures

As a result of recent advances in flow cytometry, renewed interest is shown in modeling the kinetic behavior of cells in culture on the basis of cell cycle parameters. An important but often overlooked kinetic variable in hybridoma cultures is the cell death rate. Not only the overall cell growth but also the kinetics of nutrient metabolism and monoclonal antibody production have been shown to depend on the cell death rate in continuous suspension hybridoma cultures. The present study shows that the death rate in hybridoma cultures is proportional to the fraction of cells arrested in the G(1) phase of the cell cycle. The steady-state cell age distributions in the various phases of the division cycle have been calculated analytically. A simple mathematical model has been used to produce the profiles of the cycling and arrested cell fractions with respect to the dilution rate. The calculated steady-state growth rate, death rate, and viability profiles are shown to be in agreement with recently published experimental data from continuous suspension hybridoma cultures. (c) 1992 John Wiley & Sons, Inc.     

p53 mediates density-dependent growth arrest

While the stress-response-associated importance of the p53 tumor suppressor is well established, recent studies have also linked p53 with several basic parameters in the normal behavior of cells. Here, we present evidence that basal p53 expression in WI38 human embryonic lung fibroblasts restricts growth rate and mediates density-dependent inhibition of growth and the associated G1 phase arrest of the cell cycle by affecting the density-dependent regulation of p16/INK4a. Additionally, we show that prolonged culturing of hTert-immortalized WI38 cells leads to a loss of density-dependent growth inhibition that correlates with p27/KIP deregulation as well as the previously shown INK4a locus silencing, and to an onset of contact-induced, p53-dependent cell death.     

Temperature response of the cell cycle of Haplopappus gracilis in suspension culture and its significance to the G1 transition probability model

The effects of temperature on the cell cycle of Haplopappus gracilis suspension cultures were analysed by the fraction of labelled mitoses method. Sphase in these cultures shows a different temperature optimum as compared to optima derived for G₂ and mitosis. G₁ phase has a much lower Q₁₀ than the other cell cycle phases and shows no temperature optimum between 22 and 34° C. These results are discussed in relation to a transition probability model of the cell cycle proposed by Smith and Martin (Proc. Natl. Acad. Sci. USA 70, 1263–1267, 1973), in which each cell has a time independent probability of initiating the transition into another round of DNA replication and division. The implications of such a model for cell cycle analysis are discussed and a tentative model for a probabilistic transition trigger is advanced.Abbreviations FLM Fraction of labelled mitoses - T_B Total B-phase     

Cell Kinetic Characteristics In Different Parts of Multicellular Spheroids of Human Origin

The growth fraction, the cell cycle time, and the duration of the individual cell cycle phases were determined as a function of distance from the surface of multicellular spheroids of the human cell line NHIK 3025. the techniques employed were percentage of labelled mitoses and labelling index measurements after autoradiography and flow cytometric measurements of DNA histograms. to separate cell populations from the different parts of the spheroid, fractionated trypsinization was employed. The results were compared with corresponding values in NHIK 3025 cell populations grown as monolayer cultures. While practically all cells in exponentially growing monolayer populations are proliferating, the growth fraction was between 0.6 and 0.7 in the outer parts of the spheroid. the inner region was mainly occupied by a necrotic mass. the proliferating fraction of the recognizable cells in the inner region was slightly below 0.5. the mean cell cycle time of NHIK 3025 cells in monolayer culture is 18 hr. the mean cell cycle time of proliferating cells in the periphery of the spheroid was 30 hr, compared to 41 hr in the inner region (150 μm from the spheroid surface). All phases of the cell cycle were prolonged compared to populations of exponentially growing monolayer cells. Within each part of the spheroid the distribution of cell cycle times was considerably broadened compared with monolayer populations.     

Interference of a synthetic C18 juvenile hormone with mammalian cells in vitro. II. Effects on cell cycle

Interference of a synthetic C18 juvenile (JH) with the cell cycle of mouse embryo cells (ME-cells) and mouse cells of established cell line (L-cells) was examined. After 3 hour in the medium with JH (20 mg/ml) the cells were transfered to the regular culture medium and labelled with H3-thymidine then incubated for 1 to 48 hours before processing them for autoradiography. The percentage of labelled mitosis was then calculated for all cells samples examined and the labelled mitosis curves were drown and analyzed. It was shown that in contrast to the solvent which had no effect on duration of any of the component phases of the cell cycle of ME-cells, the juvenile hormone under conditions of these experiments prolonged G1 and G2 intervals what resulted in prolongation of the total cell cycle of these cells. On the other hand it shortened G1 and prolonged G2 intervals of L-cells without changing duration of the total cell cycle. Thus, in the examined mouse cells, they were the G1 and G2 intervals which are affected by JH. This findings are considered as an argument for pleiotropic nature of the juvenile hormone interference with mouse cells, the more so as it interfered with both protein and DNA synthesis in these cells.     

Cell cycle studies in chorionic villi

Summary We have studied the cell cycle of cells obtained from chorionic villi in direct and culture preparations by incorporation of the thymidine analogue BrdU to produce latelabelling or sister chromatid differentiation patterns. We have, therefore, been able to estimate the duration of the cell cycle and, more specifically, the length of some of its phases. While results for chorionic villus sample cells in culture resembled those obtained for fibroblasts, data for the spontaneously dividing trophoblastic cells in direct preparations were different. Villi exposed to BrdU immediately after sampling showed a slight delay in the incorporation of the analogue and a lower percentage of labelled cells compared to villi treated after an overnight incubation, probably due to a temporary effect of the sampling technique. Results from semi-direct protocols suggest that cells have a G2 of no more than 4h, and a mid-S phase of 10–16h. The G1 period is very variable. After 48 h incubation with BrdU, only 4% of cells reach their second generation, whereas this percentage increases up to 70% after 72h, indicating that under these experimental conditions most cells have a cell cycle of approximately 36 h. The average number of sister chromatid exchanges was similar in both direct preparations and cultures: 5.2±2.1 SCE per cell.     

Dynamic state of concanavalin a receptor interactions on fibroblast surfaces

Cultured normal and transformed fibroblasts were treated “in situ” by the concanavalin A-peroxidase labelling technique. It is known that peroxidase recognizes only a fraction of the bound lect in depending on the cell type. Kinetics studies revealed that 80 to 95% of the peroxidase and only 10% of the lectin are released from the cell surface when the labelled cells were reincubated at 37 °C. It is shown that it is mostly the concanavalin traced by peroxidase that is released and also that the lectin and the enzyme are shed as a complex or concomitantly. Consequently, the shedding pattern of the enzyme is used to demonstrate heterogeneity in the lectin binding sites: there are two main components labelled by concanavalin and peroxidase, one which has a short period (from 6 to 16 min) and another one with a much longer one (1.3 to 3 h).It is shown that when cells are incubated at 37 °C after a lectin treatment, secondary binding forces occur between the lectin and cell surface components which render the lectin unavailable for inhibiting sugars. Under the same conditions, some peroxidase can still be bound and a slight agglutination can still occur.     

Trypsinized Placental Cell Cultures for the Propagation of Viruses and as “Feeder Layers”

The preparation and properties of cell cultures derived from human placental tissue are described and their usefulness for the propagation of animal viruses and as “feeder layers” is indicated.     

Cannabinoids Regulate Bcl-2 and Cyclin D2 Expression in Pancreatic β Cells

Recent reports have shown that cannabinoid 1 receptors (CB1Rs) are expressed in pancreatic β cells, where they induce cell death and cell cycle arrest by directly inhibiting insulin receptor activation. Here, we report that CB1Rs regulate the expression of the anti-apoptotic protein Bcl-2 and cell cycle regulator cyclin D2 in pancreatic β cells. Treatment of MIN6 and βTC6 cells with a synthetic CB1R agonist, WIN55,212–2, led to a decrease in the expression of Bcl-2 and cyclin D2, in turn inducing cell cycle arrest in G0/G1 phase and caspase-3-dependent apoptosis. Additionally, genetic deletion and pharmacological blockade of CB1Rs after injury in mice led to increased levels of Bcl-2 and cyclin D2 in pancreatic β cells. These findings provide evidence for the involvement of Bcl-2 and cyclin D2 mediated by CB1Rs in the regulation of β-cell survival and growth, and will serve as a basis for developing new therapeutic interventions to enhance β-cell function and growth in diabetes.     

Measuring cell proliferation by relative movement. I. Introduction and in vitro studies

This paper presents two new ways of analysing data which may be obtained from pulse labelling a population of cells with bromodeoxyuridine and analysing that population as a function of time with bivariate flow cytometry. The progression of cells is measured by the change in position in the cell cycle, as shown by a change in the mean DNA content of the labelled and unlabelled cells. The particular measures of the mean DNA content used are extensions of the relative movement of the labelled undivided cells, RMlu(t), which was introduced by Begg and co-workers to measure the DNA synthesis time, TS. In general, the relative movement is defined as the mean DNA fluorescence of a population of cells less the DNA fluorescence of the cells in G1 and divided by the difference in DNA fluorescence of the cells in G2 + M and G1. In this paper we examine the relative movements of all the labelled cells and all of the unlabelled cells, denoted RML(t) and RMU(t) respectively. It is found that RML(t) and RMU(t) exhibit clear cyclic behaviour and distinguishable characteristics which depend directly on the transit times (T) of the cell cycle phases, i.e. TG1, TS and TG2 + M. Furthermore, the peak heights of the RMU(t) curve are shown to depend strongly on the growth fraction of the population under consideration. A theoretical treatment of the curves so obtained is presented, and is shown to yield values in close agreement with those from other methods for measuring these transit times and a lower limit to values for the growth fraction of Chinese hamster ovary cells grown in vitro.