Increase in cell mass during the division cycle of Escherichia coli B/rA.

Increase in the mean cell mass of undivided cells was determined during the division cycle of Escherichia coli B/rA. Cell buoyant densities during the division cycle were determined after cells from an exponentially growing culture were separated by size. The buoyant densities of these cells were essentially independent of cell age, with a mean value of 1.094 g ml-1. Mean cell volume and buoyant density were also determined during synchronous growth in two different media, which provided doubling times of 40 and 25 min. Cell volume and mass increased linearly at both growth rates, as buoyant density did not vary significantly. The results are consistent with only one of the three major models of cell growth, linear growth, which specifies that the rate of increase in cell mass is constant throughout the division cycle.     

Selection of synchronous bacterial cultures by density sedimentation.

A procedure previously used to select synchronous cultures of Chlorella was found to produce similar results with the bacterium Lineola longa (Bacillus macroides). A midlog culture of L. longa was layered onto a 31-42% dialyzed Ficoll gradient and ceitruged at 51 000 3 g. The culture sedimented into a broad band in 30 min. Continued centrifugation failed to cause further migration. Cells taken from the top of the band and reinoculated into the broth in which they had previously grown, pH adjusted to 7.0, grew without a lag, doubled in optical density at the same rate as midlog cultures, and divided synchronously. Coulter counter sizing of these cells showed a doubling in volume just before division followed by a halving of volume after division. The major advantages of this method are the low osmolarity of Ficoll and the large volume of cells that can be separated.     

A secreted 80 x 10(3) Mr protein mediates sensing of cell density and the onset of development in Dictyostelium.

In submerged monolayer culture, Dictyostelium cells can differentiate into prespore and prestalk cells at high cell densities in response to cAMP but not at low cell densities. However, cells at low densities will differentiate in medium taken from developing cells starved at a high density. The putative factor in the medium was designated CMF for conditioned medium factor (Mehdy and Firtel, Molec. cell. Biology 5, 705-713, 1985). In this report, we size-fractionate conditioned medium and show that the activity that allows low density cells to differentiate can be separated into high and low Mr (relative molecular mass) fractions. Interestingly, the two fractions both have the same activity and do not need to be combined to allow differentiation. The large conditioned medium factor is a protein, as determined by trypsin sensitivity, that can be purified to a single 80 x 10(3) Mr band on a silver-stained SDS-polyacrylamide gel, and has CMF activity at a concentration of approximately 4 pM (0.3 ng ml-1). Our results suggest that CMF is a secreted factor that functions in vivo as an indicator of cell density in starved cells. At high cell densities, the concentration of CMF is sufficient to enable cells to enter the multicellular stage of the developmental cycle. When present below a threshold concentration, cells do not initiate the expression of genes required for early development. This factor plays an essential role in the regulatory pathway necessary for cells to obtain the developmental competence to induce prestalk and prespore gene expression in response to cAMP.     

Survival of Tetrahymena thermophila at Low Initial Cell Densities. Effects of Lipids and Long-Chain Alcohols

ABSTRACT. Cells of the ciliate Tetrahymena thermophila failed to establish cultures in lipid-free standard synthetic nutrient medium if the initial population density was 250 cells per ml or less. These cells died within 10 h, but were saved and formed dense cultures if their medium was supplemented with 10 μg per ml of either certain phospholipids, 1,2-di-, 1-monoglycerides, fatty acids, long-chain alcohols, or sterols. Cell multiplication was followed in cultures in which the standard synthetic medium was supplemented with a selection of the compounds listed above. It was observed that the cells in the supplemented cultures in their exponential phases of growth had about the same average doubling times as control cells starting multiplication at 10-fold higher initial cell densities in lipid-free medium. These cells have been grown for decades in lipid-free synthetic nutrient media at short (ca. two-three h) doubling times. Therefore lipids have been considered nutritionally non-essential for growth and multiplication of these cells. We propose that those compounds that rescue the cells at low cell densities act as "proliferation signals," sensu lato . This effect of lipids and long-chain alcohols has so far remained unnoticed.     

Buoyant density fluctuations during the cell cycle of Bacillus subtilis

A simple rapid method for preparing synchronous cultures of Bacillus subtilis has been used to investigate changes in density during the cell cycle. Asynchronous cells separated on a stepped Percoll density gradient had a mean cell density of 1.117 g ml^-1±0.004. Samples from a synchronous culture exhibited variation (ca. 1.5%) in mean cell density which was greatest at the onset of cell division. An asynchronous control culture showed little variation in density. These results are discussed in relation to previous work on Escherichia coli.     

Evaluation of production of recombinant human interleukin-2 in fluidized bed bioreactor

The production of recombinant human interleukin-2 in a fluidized bed bioreactor containing porous glass carriers is described. Cultivations were carried out with different medium formulations over 80 days. Maximal cell densities and product yield could be maintained even when protein free medium was perfused, with less than 10% cell washout. Due to this effective immobilization of the cells in the reactor, continuous operation was easy to perform. Final cell densities on the order of 3.8 x 10(8) mL(-1) intrasphere volume were reached while the interleukin-2 production rate was 0.75 mg L(-1) d(-1). The production rate showed a maximum of a 1.9 fold decrease compared with a homogeneous stirred bubble-free aerated system. This result was in contrast to that achieved with hybridoma cell lines, where better performance was obtained with the fluidized bed bioreactor. The situation may reflect the problems caused by the dense cell culture with adherent cells, as previously shown in a hollow-fiber bioreactor with the same cell line.     

Altered growth properties of normal human cells induced by phorbol 12,13-didecanoate

The tumor promoter phorbol 12,13-didecanoate (PDD) significantly altered the growth properties of early passage normal human skin cells in vitro in culture medium supplemented with elevated concentrations of selected amino acids. Continuous treatment of cells with 10(-7) or 10(-8) M PDD resulted in a 5 to 10-fold increase in saturation density at early passages followed by a long-term two- to fourfold increase. The PDD-treated cultures remained in exponential growth at cell densities greater than 10-fold higher than the control cultures. Removal of PDD from the culture medium while the cells were at a high cell density resulted in a return to near-normal saturation density by the subsequent passage. Anchorage independent growth of normal human cells in methylcellulose was also promoted by PDD in a dose dependent manner, with prior subculturing in the presence of PDD being required for maximal colony formation. The structural analog 4 alpha-phorbol 12,13-didecanoate failed to elicit similar cellular responses.     

Effects of culture density on the kinetics of germ tube formation in Candida albicans

The relationship between culture density or phase of growth at 24.5 degrees C and the ability of Candida albicans to form germ tubes when shifted to 37 degrees C was investigated. Evidence is presented demonstrating germ tube production from liquid synthetic medium cultures at all phases of growth. Previous studies reported that only cells from stationary phase cultures were competent to form germ tubes. Comparisons between exponential and stationary phase cultures indicate more rapid and more synchronous germ tube production from cells growing in the exponential phase.     

Effects of plating density and age in culture on growth and cell division of neonatal rat heart primary cultures

Summary The cell-type composition of the initial cell population from protease-dispersed neonatal rat heart tissue has been evaluated using time lapse photography and identification of cell type-specific functions. The effects of two commonly employed plating densities on growth and cell division of the two major cell types were examined. Total protein synthesis rates were not affected by plating density but did change with age in culture. Maximum protein synthesis rates were observed during the period of maximum cell division and cell growth (increase in total cell protein), which was from 24 h in culture to the 4th d in culture. After 6 d in culture, synthesis rates for total proteins remained constant for at least 2 wk. Sizing of cells by Coulter counter analysis indicated that essentially all the cells were increasing in size with age in culture. Measurements of cell numbers and rate of DNA synthesis indicated that the extent of cell division was dependent on plating density. Cells disaggregated from neonatal rat hearts consisted of approximately 75% muslce cells and 25% nonmuscle cells. This composition approximates the cell-type composition of the intact neonatal rat heart. In high density cultures there is little cell division and the relative proportionsof the cell types are preserved with time in culture. In low density cultures, proliferation of nonmuscle cells is a significant process and the composition of the cell population changes drastically during the first 2 to 3 d in culture. These results suggest that the low plating density used by many researchers may limit correlation of data derived from such cultures with the physiological state. It also indicates that plating densities should be given in published accounts for comparisons to be made with results from other laboratories. This work was supported in part by U.S. Public Health Service Grant HL10018 and The Pennsylvania State University Agricultural Experiment Station and was authorized for publication as Paper 5490 in the journal series of the Pennsylvania Agricultural Experiment Station.     

Growth kinetics and nitrogen-nutrition of the marine diatom Phaeodactylum tricornutum in continuous dialysis culture

The growth kinetics and nitrogen (N)-nutrition of the marine pennate diatom Phaeodactylum tricornutum Bohlin were determined in continuous dialysis culture at different cell densities. Inflow nutrient medium was supplied as natural unenriched estuarine seawater to a dialysis culture system with a high ratio of membrane surface area/culture volume (Am/Vc). Under the experimental conditions, the supply of inorganic macronutrients (NO ₃ ^? + NO ₄ ^? and PO ₄ ^?3 ) by diffusion (Nd) was markedly greater than that provided by the dilution (FfCN) of the culture (Nd ? FfCN), thereby establishing an inverse relationship between the cell density and the dilution rate (D). This continuous dialysis system allows for the maintenance of prolonged growth (> two weeks) at various cell densities (1.4 to 27.2 × 10⁹ cells 1^?1) within a range of dilution rates between 0.30 to 1.08 d^?1. In high cell density cultures, where the extracellular medium was characterized as nutrient deficient, a lower growth rate (μ_e) was exhibited than in cultures with lower cell densities. The growth rate (μ_e) remained equivalent to the dilution rate (D) throughout the culture cycle, indicating that equilibrated growth was achieved. High cell density cultures yielded higher productivity (P), relative to that of cultures grown at lower cell densities, in terms of cell-N and ?C produced per unit time. However, cell quotas of both N and C declined with increasing cell concentrations. Denser cultures were characterized by an enhanced N-conversion efficiency (Y_N) and a higher cellular N/C atomic ratio. The nutritional response of this diatom in dense cultures reveals an efficient use of N-nutrients, presumably as a result of cellular nutrient adaptation to oligotrophic conditions.     

Continuous-Dilution Method for the Mass Culture of Synchronized Cells

A new mass-culturing technique for synchronized cells is described. Continuous dilution with fresh culture medium provides the cells with nearly constant environmental conditions (continuous resupply of nutrients, constant adjustment of pH, maintenance of a nearly constant cell mass-to-culture volume ratio, etc.) at high cell densities, thereby resulting in the yield of ample cellular material for most biochemical studies during the cell cycle. The new mass-culturing system, when utilized to culture synchronous Chlorella pyrenoidosa, yielded approximately three times as much cellular material as a previous nondilution method, in the same time period and in less than one-tenth the culture volume. Although the newly developed mass-culture method was tested with a unicellular green alga, the basic method should be readily adaptable to synchronous cultures of other microorganisms and to cells in tissue culture.     

An attempt to stimulate mitosis in Saccharomyces cerevisiae with the ultraviolet luminescence from exponential phase cultures of this yeast

Neither cell division nor growth of Saccharomyces cerevisiae were stimulated by the ultraviolet luminescence produced by adjacent exponential phase cultures of the yeast. The study included experiments in which the inocula (density = 5 X 10(7) cells cm-3) were irradiated and in which lag phase cultures (densities = 1 X 10(6) or 5 X 10(6) cells cm-3) were irradiated for 30 min with the yeast luminescence. These results do not support the claims of earlier workers that dividing cells can stimulate mitosis in optically coupled cultures by the so-called "mitogenetic effect."     

Changes in protein content per cell during growth of mouse L cells

The relationship between cell density and protein content per cell was examined in monolayer and suspension cultures of mouse L cells. In monolayer cultures, the protein content per cell reached a maximum at 6 h after plating and retained this level for 18 h. Thereafter, the protein content per cell declined gradually during the exponential growth phase and finally returned to the initial level at the stationary phase. The changes were neither due to the effect of trypsinization nor to the exhaustion of the medium. The protein content per cell in a sparse culture was always greater than that in a dense culture for monolayer culture of L cells. In suspension culture the increase of protein content per cell during the lag phase was similar to that found in monolayer cultures. However, the gradual decline of protein content per cell observed during the exponential phase of monolayer cultures was not detected during that of a suspension culture. The results suggest that the decrease of protein content per cell in monolayer cultures may be related to some function of cell plasma membrane which could be inhibited by a cell-to-cell contact.     

Density-dependent growth control of adult rat hepatocytes in primary culture

Adult rat hepatocytes in primary culture, which show various liver functions, did not show any mitosis at confluent cell density, although they entered the S phase and remained in the G2 phase, judging by cytofluorometry, when insulin and epidermal growth factor (EGF) were added to 2-day cultures (Tomita, Y., Nakamura, T., & Ichihara, A. (1981) Exp. Cell Res. 135, 363-371). However, when the cell density was decreased by half or one third, the number of nuclei and cell number increased to 1.5-2.0 times that after culture for 35 h with insulin and EGF. Moreover, at these lower densities, DNA synthesis started much earlier, although at the usual high density DNA synthesis with these two hormones did not start until the hepatocytes had been cultured for over 40 h. These results suggest that proliferation of mature rat hepatocytes is regulated by the cell density. First, cells in G0 enter the G1 phase density-dependently; then cells in the G1 phase seem to be stimulated to enter the S phase by insulin and EGF, and a low cell density may permit cells after DNA synthesis to enter the M phase. DNA synthesis of rat hepatocyte cultures at low cell density was strongly inhibited by co-culture with a dense culture. Therefore, the density-dependent mechanism of hepatocyte proliferation seems to involve regulation by a soluble inhibitor(s) secreted by the hepatocytes into the culture medium.     

Manganese(II) induces cell division and increases in superoxide dismutase and catalase activities in an aging deinococcal culture.

Addition of Mn(II) at 2.5 microM or higher to stationary-phase cultures of Deinococcus radiodurans IR was found to trigger at least three rounds of cell division. This Mn(II)-induced cell division (Mn-CD) did not occur when the culture was in the exponential or death phase. The Mn-CD effect produced daughter cells proportionally reduced in size, pigmentation, and radioresistance but proportionally increased in activity and amount of the oxygen toxicity defense enzymes superoxide dismutase and catalase. In addition, the concentration of an Mn-CD-induced protein was found to remain high throughout the entire Mn-CD phase. It was also found that an untreated culture exhibited a growth curve characterized by a very rapid exponential-stationary transition and that cells which had just reached the early stationary phase were synchronous. Our results suggest the presence of an Mn(II)-sensitive mechanism for controlling cell division. The Mn-CD effect appears to be specific to the cation Mn(II) and the radioresistant bacteria, deinococci.     

Metabolism of hybridoma cells and antibody secretion at high cell densities in dialysis tubing.

The experimental setup, consisting of a bundle of dialysis tubing 2.5 mm in diameter [10-15 kD cutoff, mean pore size 25 A, 20 microns (dry) and 40 microns (wet) wall thickness] inserted into a 1-l glass bioreactor supplied with oxygen and pH electrodes, a porous gas distributor, a sampling tube, and a holder for the eight pieces of dialysis tubing, was developed to investigate the properties and the microenvironment of hybridoma cells enclosed in the tubing during their batch cultivation. The concentrations of low-molecular-weight medium components were the same inside and outside the tubing, and it was possible to control the microenvironment of the cells in the tubing easily. The cell damage caused by mechanical stress was less in the dialysis tubing than in stirred spinner flasks. The influence of the initial cell density in the range from 4 X 10(5) to 1 X 10(8) cells ml-1 and the cultivation time were evaluated according to the total and viable cell concentrations and the cell/cell fragment size distributions. Furthermore, the cell membrane properties, glucose consumption rate, lactate, ammonia and lipid storage material, and the monoclonal antibody production rates as well as intracellular enzyme activities in the culture medium were measured and compared to those in reference cultures in spinner flasks with the same inoculum at low initial cell densities. In dialysis tubing in a concentration range of 5 X 10(6) to 10(8) cells ml-1, the total and viable concentrations of cells remained the same during cultivation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Density dependent regulation of growth in L-cell suspension cultures. IV. Adaptive and nonadaptive respiratory decline

Respiration as an index of oxidative energy production was investigated in a L-cell suspension culture system previously shown to exhibit density-dependent inhibition of growth. It was found that as cultures progressed from exponential growth to high density nongrowing populations (6^?10 × 10⁶ cells/ml) over a 2-week period, the respiratory rate determined from the total amount of oxygen consumed during the daily medium renewal cycle, declined from 5.4 to 1.8 fmoles O₂/cell/min. There are two components in this decrement. The first consists of a daily recurrent decline of oxygen uptake resulting from decreased availability of medium oxygen and glutamine and is readily reversed by medium supplementation. The second component which is refractory to medium supplementation and accounts for approximately 50% of the total respiratory decline, is considered to indicate an adaptive change of the respiratory capacity of the cells. This change is reversed during the lag period which precedes resumption of exponential growth upon subculture to low cell densities. The significance of these results is discussed in relation to recent reports indicating a marked depression of respiratory activity in nongrowing dense attached cultures as well.     

Reduction of selenite and detoxification of elemental selenium by the phototrophic bacterium Rhodospirillum rubrum.

The effect of selenite on growth kinetics, the ability of cultures to reduce selenite, and the mechanism of detoxification of selenium were investigated by using Rhodospirillum rubrum. Anoxic photosynthetic cultures were able to completely reduce as much as 1. 5 mM selenite, whereas in aerobic cultures a 0.5 mM selenite concentration was only reduced to about 0.375 mM. The presence of selenite in the culture medium strongly affected cell division. In the presence of a selenite concentration of 1.5 mM cultures reached final cell densities that were only about 15% of the control final cell density. The cell density remained nearly constant during the stationary phase for all of the selenite concentrations tested, showing that the cells were not severely damaged by the presence of selenite or elemental selenium. Particles containing elemental selenium were observed in the cytoplasm, which led to an increase in the buoyant density of the cells. Interestingly, the change in the buoyant density was reversed after selenite reduction was complete; the buoyant density of the cells returned to the buoyant density of the control cells. This demonstrated that R. rubrum expels elemental selenium across the plasma membrane and the cell wall. Accordingly, electron-dense particles were more numerous in the cells during the reduction phase than after the reduction phase.     

Cell cycle of Chlorella vulgaris can deviate from the synchronous binary division model

Conditioned medium from high density Chlorella vugaris cultures was freeze dried extracted into ethanol. The ethanol was volatilized and the resulting powder then introduced with C. vulgaris photoautotrophic cultures which underwent asynchronous DNA replication forming cells with two, three, four, and six autospores instead of 2 n characteristic of synchronous DNA replication. These cells were blocked at the division stage of the cell cycle.     

TES and HEPES buffers in mammalian cell cultures and viral studies: Problem of carbon dioxide requirement

In order to evaluate TES and HEPES as a buffer system for cell culture, the proliferative capacities of cells of several mammalian cell lines in the medium buffered with either of these compounds were examined in cultures in stoppered and open flasks at high and low cell densities. When cultivated in stoppered flasks, cells grew equally well or even better in TES- and HEPES-buffered medium than in NaHCO₃-buffered medium irrespective of cell culture density. In open flasks or Petri dishes in TES- or HEPES-buffered medium, however, the proliferative capacity of cells in low density cultures was limited. The inhibition of cell growth in the latter condition was restored (1) as the cell density of the cultures increased; (2) by feeding continuously the cultures with the gas produced by high density cultures; (3) by introducing a small amount of CO₂ to the environment.These and other evidences presented suggest that, in agreement with the prevailing notions, CO₂ is required by cells as an essential nutrient for growth, and that the desired level of CO₂ in culture can be maintained efficiently by its production by even a small number of cells in culture as long as the culture flasks are stoppered. If flasks are not stoppered, however, the level of CO₂ tension is determined by an equilibrium between the rate of its production by the cells and that of escape from culture to air, resulting in the observed failure in growth of cells in TES- and HEPES-buffered medium at low cell densities unless cultures were further supplemented with added CO₂.