Production of shikonin derivatives by cell suspension cultures of Lithospermum erythrorhizon

Differences in the production of shikonin derivatives by callus and suspension cultures of Lithospermum erythrorhizon Sieb. et Zucc. were examined. When Linsmaier and Skoog medium was used in suspension cultures, cell growth was not accompanied by the production of shikonin compounds. Shikonin derivatives were produced, however, when this medium was used in callus cultures. Differences in shikonin production were examined in terms of the nutrient supply, the effect of the agar itself, and the oxygen supply. Shikonin derivatives could be produced without agar by keeping the cells exposed to air while providing an adequate supply of nutrients. In callus cultures, the production of shikonin compounds was reduced remarkedly when the oxygen concentration in the atmosphere was lowered, evidence that shikonin production during L. erythrorhizon cell growth on Linsmaier and Skoog agar medium is enhanced by an abundant supply of oxygen.     

Extracellular regulation of fibroblast multiplication: A direct kinetic approach to analysis of role of low molecular weight nutrients and serum growth factors

The principles of enzyme kinetic analysis were applied to quantitate the relationships among serum-derived growth factors, nutrients, and the rate of survival and multiplication of human fibroblasts in culture. The survival or multiplication rate of a population of cells plotted against an increasing concentration of a growth factor or nutrient in the medium exhibited a hyperbolic pattern that is characteristic of a dissociable, saturable interaction between cells and the ligands. Parameters equivalent to the K_m and V_max of enzyme kinetics were assigned to nutrients and growth factors. When all nutrient concentrations were optimized and in steady state, serum factors accelerated the rate of multiplication of a normal cell population. The same set of nutrients that supported a maximal rate of multiplication in the presence of serum factors supported the maintenance of non-proliferating cells in the absence of serum factors. Therefore, under this condition, serum factors are required for cell division and play a purely regulatory iole in multiplication of the cell population. The quantitative requirement for 18 nutrients of 29 that were examined was significantly higher (P < 0.001) for cell multiplication in the presence of serum factors than for cell maintenance in the absence of serum factors. This indicated specific nutrients that may be quantitatively important in cell division processes as well as in cell maintenance. The quantitative requirement for Ca²⁺, Mg²⁺, K⁺, Pi, and 2-oxocarboxylic acid for cell multiplication was modified by serum factors and other purified growth factors. The requirement for over 30 other nutrients could not clearly be related to the level of serum factors in the medium. Serum factors also determined the Ca²⁺, K⁺, and 2-oxocarboxylic acid requirement for maintenance of non-proliferating cells. Therefore, when either Ca²⁺, K⁺, or 2-oxocarboxylic acid concentration was limiting, factors in serum played a role as cell “survival or maintenance” factors in addition to their role in cell division as “growth regulatory” factors. However, with equivalent levels of serum factors in the medium, the requirement for Ca²⁺, K⁺, and 2-oxocarboxylic acids was still much higher for multiplication than for maintenance. Kinetic analysis revealed that the concentrations of individual nutrients modify the quantitative requirement for others for cell multiplication in a specific pattern. Thus, specific quantitative relationships among different nutrients in the medium are important in the control of the multiplication rate of the cell population. When all nutrient concentrations were optimal for multiplication of normal cells, the multiplication response of SV40-virus-transformed cells to serum factors was similar to that of normal cells. When serum factors were held constant, transformed cells required significantly less (P < 0.001) of 12 of the 26 nutrients examined. Therefore, the transformed cells only have a growth advantage when the external concentration of specific nutrients limits the multiplication rate of normal cells. Taken together, the results suggest that the control of cell multiplication is intimately related to external concentrations of nutrients. Specific growth regulatory factors may stimulate cell proliferation by modification of the response of normal cells to nutrients. Transforming agents may confer a selective growth advantage on cells by a constitutive alteration of their response to extracellular nutrients.     

The effects of several factors on the growth of pure and mixed cultures of Azotobacter chroococcum and Bacillus subtilis

We studied the effect of a clay mineral, palygorskite, on the physiological activity of Azotobacter chroococcum and the phosphate-mobilizing bacterium Bacillus subtilis, as well as their mixed cultures, under various oxygen supply conditions during the utilization of phosphorus from readily and poorly soluble compounds (K₂HPO₄ · 3H₂O) and (Ca₃(PO₄)₂), respectively. During cultivation of the bacteria in a nutrient medium with Ca₃(PO₄)₂, the number of microorganisms was higher than that observed in a medium with K₂HPO₄. An increase in oxygen mass transfer in the nutrient medium was followed by a rise in the number of Bacillus subtilis cells and an inhibition of Azotobacter chroococcum growth. An addition of palygorskite (5 g/l) into the nutrient medium stimulated the growth of both bacteria and stopped the decreasing growth of Azotobacter chroococcum at high values of oxygen mass transfer. The number of Bacillus and, particularly, Azotobacter cells was two to five times lower in a mixed culture than in a monoculture. These differences were less significant during the cultivation of mixed cultures in medium with palygorskite.     

Autoradiographic study of the localization and evolution of growth zones in bacterial colonies.

Incorporation of [3H]leucine in the bacteria of 18 to 48 h-old colonies of Pseudomonas aeruginosa, Pseudomonas putida, Bacillus thuringiensis, Staphylococcus aureus and Escherichia coli enabled the localization of bacterial multiplication sites by means of autoradiography of sagittal sections. In colonies where fast diameter expansion occurred, all the bacteria from the peripheral corona contributed to peripheral growth; in colonies where the expansion was slower, the growth rate of the bacteria in this region was heterogeneous. Besides this peripheral growth, a central region of bacterial multiplication was always found, but with variable localization and extension. In aerobic species, such as P. aeruginosa and P. putida, the central growth site was limited to the zone of oxygen penetration into the bacterial mass. However, in facultatively anaerobic species, bacterial multiplication dependend on nutrient supply. For 48 h-old colonies of S. aureus, a more complex localization of growth seemed to be affected simultaneously by nutrient penetration and accumulation of toxic substances.     

Role of nutrient supply on cell growth in bioreactor design for tissue engineering of hematopoietic cells

In the present study, a dynamic mathematical model for the growth of granulocyte progenitor cells in the hematopoietic process is developed based on the principles of diffusion and chemical reaction. This model simulates granulocyte progenitor cell growth and oxygen consumption in a three-dimensional (3-D) perfusion bioreactor. Material balances on cells are coupled to the nutrient balances in 3-D matrices to determine the effects of transport limitations on cell growth. The method of volume averaging is used to formulate the material balances for the cells and the nutrients in the porous matrix containing the cells. All model parameters are obtained from the literature. The maximum cell volume fraction reached when oxygen is depleted in the cell layer at 15 days and is nearly 0.63, corresponding to a cell density of 2.25 x 10(8) cells/mL. The substrate inhibition kinetics for cell growth lead to complex effects with respect to the roles of oxygen concentration and supply by convection and diffusion on cell growth. Variation in the height of the liquid layer above the cell matrix where nutrient supply is introduced affected the relative and absolute amounts of oxygen supply by hydrodynamic flow and by diffusion across a gas permeable FEP membrane. Mass transfer restrictions of the FEP membrane are considerable, and the supply of oxygen by convection is essential to achieve higher levels of cell growth. A maximum growth rate occurs at a specific flow rate. For flow rates higher than this optimal, the high oxygen concentration led to growth inhibition and for lower flow rates growth limitations occur due to insufficient oxygen supply. Because of the nonlinear effects of the autocatalytic substrate inhibition growth kinetics coupled to the convective transport, the rate of growth at this optimal flow rate is higher than that in a corresponding well-mixed reactor where oxygen concentration is set at the maximum indicated by the inhibitory kinetics.     

CELL CYCLE COMPARTMENT ANALYSIS OF CHINESE HAMSTER CELLS IN STATIONARY PHASE CULTURES

The distribution of Chinese hamster cells with respect to the compartments of the cell generation cycle was studied in cultures in the stationary phase of growth in two different media. A measure of the state of depletion of the nutrient medium was formulated by defining a quantity termed the nutritive capacity of the medium. This quantity was used to verify that the cessation of cell proliferation is due to nutrient deficiencies and not to density dependent growth inhibition. Cell cultures in stationary phase were diluted into fresh medium and as growth resumed, mitotic index, cumulative mitotic index, label index and viability were measured as a function of time. The distribution of cells with respect to compartments of the cell generation cycle in stationary phase populations was reconstructed from these data. Stationary phase populations of Chinese hamster cells that retained the capacity for renewed growth when diluted into fresh medium were found to be arrested in the G₁ and G₂ portions of the cycle; the relative proportion of these cells in G₁ increased with time in the stationary phase, but the sequence differs in the two media. In early stationary phase, in the less rich medium, more cells are in G₂ than in G₁. Also in this medium a fraction of the population was observed to be synthesizing DNA during stationary phase, but this fraction was not stimulated to renewed growth by dilution into fresh medium.     

Biophysical changes reduce energetic demand in growth factor–deprived lymphocytes

Cytokine regulation of lymphocyte growth and proliferation is essential for matching nutrient consumption with cell state. Here, we examine how cellular biophysical changes that occur immediately after growth factor depletion promote adaptation to reduced nutrient uptake. After growth factor withdrawal, nutrient uptake decreases, leading to apoptosis. Bcl-x_L expression prevents cell death, with autophagy facilitating long-term cell survival. However, autophagy induction is slow relative to the reduction of nutrient uptake, suggesting that cells must engage additional adaptive mechanisms to respond initially to growth factor depletion. We describe an acute biophysical response to growth factor withdrawal, characterized by a simultaneous decrease in cell volume and increase in cell density, which occurs before autophagy initiation and is observed in both FL5.12 Bcl-x_L cells depleted of IL-3 and primary CD8⁺ T cells depleted of IL-2 that are differentiating toward memory cells. The response reduces cell surface area to minimize energy expenditure while conserving biomass, suggesting that the biophysical properties of cells can be regulated to promote survival under conditions of nutrient stress.     

Division and growth of mesophyll cells isolated from Psoralea bituminosa leaves

Mesophyll cells have been isolated from Psoralea bituminosa plant by gentle homogenization in a liquid nutrient medium. Between 60 and 70% of the cells can be isolated from leaves using this method, of which 50 to 60% can be recovered morphologically intact. Under light the separated cells have rates of oxygen evolution under light of 3500 μl O₂ mg^?1 chlorophyll h^?1 (measured with a Clark-type electrode). During growth, this rate decreases rapidly, as does cell pigments (chlorophylls and carotenoids). As a first step in obtaining a photoautotrophic cell suspension, growth factors affecting cell division in free sugar medium were investigated. The starting culture contained between 1 and 2 × 10⁶ cells ml^?1. The best increase in cell number was obtained on a medium composed of Joshi and Ball's elements and vitamins and containing 1 mg l^?1 of naphthalene acetic acid, 0.1 mg l^?1 of benzylaminopurine and the grinding juice. The optimum culture pH was between 5 and 5.3.     

Generation of homogeneous populations of alloreactive T cells in vitro.

The supernatant from Con A-activated spleen cells (CS) can be used to generate homogenous populations of alloreactive T cells in vitro. Subculture of activated cells in CS containing medium is required for the continued proliferation and expression of effector activity. Prolonged subculture in CS containing medium does not result in indefinite growth and proliferation of alloreactive T cells. The activity in CS required to maintain cytotoxic cell growth is not species specific, and is therefore separable from the costimulator activity in CS required for the initiation of the T cell response to alloantigen; this latter activity is species specific.     

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.     

New miniaturized hollow-fiber bioreactor for in vivo like cell culture, cell expansion, and production of cell-derived products

We have developed a miniaturized hollow-fiber bioreactor system for mammalian cell culture with a volume of 1 mL. Cell and medium compartments of the bioreactor are separated by a semipermeable membrane, and oxygenation of the cell compartment is accomplished using an oxygenation membrane. As a result of the geometry of the transparent housing, cells can be observed by microscopy during culture. The leukemic cell lines CCRF-CEM, HL-60, and REH were cultivated up to densities of 3.5 x 10(7)/mL without medium change or manipulation of the cells. As shown using CCRF-CEM cells, growth in the bioreactor was strongly influenced and could be controlled by the medium flow rate. As a consequence, consumption of glucose and generation of lactate varied with flow rate. Depending on the molecular size cutoff of the membranes used, added growth factors such as GM-CSF, as well as factors secreted from the cells, are retained in the cell compartment for up to 1 week. This new miniaturized hollow-fiber bioreactor offers advantages in tissue engineering by continuous nutrient supply for cells in high density, retention of added or autocrine produced factors, and undisturbed long-term culture in a closed system.     

How does eutrophication affect the role of grazers in harmful algal bloom dynamics?

Population dynamics of harmful algal bloom species are regulated both from the “bottom-up” by factors that affect their growth rate and from the “top-down” by factors that affect their loss rates. While it might seem apparent that eutrophication would have the greatest impact on factors affecting growth rates of phytoplankton (nutrient supply, light availability) the roles of top-down controls, including grazers and pathogens, cannot be ignored in studies of harmful bloom dynamics. Lags between the growth of phytoplankton and zooplankton populations, or disruption of zooplankton populations by adverse environmental conditions may be important factors in the initiation of plankton blooms under eutrophic conditions. Grazers that avoid feeding on harmful species and actively graze on competing species may also play important roles in bloom initiation. Grazers that are not affected by phytoplankton toxins and have growth rates comparable to phytoplankton (e.g. protozoan grazers) may have the potential to control the initiation of blooms. If the inhibition of grazers varies with cell density for blooms of toxic phytoplankton, eutrophication may increase the chances of blooms reaching threshold densities for grazer inhibition. In addition, secondary effects of eutrophication, including hypoxia and change in pH may adversely affect grazer populations, and further release HAB species from top-down control. The Texas brown tide (Aureoumbra lagunensis) blooms provide evidence for the role of grazer disruption in bloom initiation and the importance of high densities of brown tide cells in continued suppression of grazers.     

Micropropagation of the endangered <Emphasis Type="Italic">Kniphofia leucocephala</Emphasis> Baijnath

Summary The species, Kniphofia leucocephala is extant at only one location, Langepan, KwaZulu-Natal in South Africa, where the population is threatened by afforestation and possibly grazing. Consequently, a continuous culture system was established as part of a program for the propagation and re-introduction of plants into the wild. The efficiency of the system in terms of shoot multiplication and, particularly, the frequency and rate of root initiation was strongly influenced by the concentration of benzyladenine in the shoot multiplication medium. The optimum shoot multiplication medium for subsequent root initiation contained 2 mgl⁻¹ (8.9 μM) benzyladenine alone. The shoots were successfully rooted and acclimatized. Approximately 200 shoots can be produced from one shoot after five 4-wk cycles. Thus, large numbers of plantlets can be propagated in this continuous culture system, serving conservation interests.     

Respiratory activity of Candida tropicalis during growth on hexadecane and on glucose

Summary Rates of oxygen uptake and the oxygen demand during growth of Candida tropicalis on hexadecane and glucose were determined in batch experiments. Oxygen demand was 2.5 fold higher for the synthesis of one unit of cell mass from hydrocarbon than from glucose. On the other hand specific respiration is of the same order of magnitude for both substrates, e.g. 12 mmoles O₂xh^-1xg^-1 (dry weight) and seems to be a constant of this organism. Higher rates of oxygen supply into the medium had no effect on the specific rates of respiration. Specific growth rates on hexadecane were 2.4 times lower than on glucose. It is concluded, that rates of synthesis of cell components are controlled by the overall capacity of the respiratory pathways.     

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.     

Analysis of the use of fortified medium in continuous culture of mammalian cells

Continuous culture is frequently used in the cultivation of mammalian cells for the manufacturing of recombinant protein pharmaceuticals. In such operations a large volume of medium is turned over each day, especially in the case where cell recycle, or perfusion cultivation, is practiced. In principle, the volumetric throughput of medium can be reduced by using a more concentrated feed while maintaining the same nutrient provision rate. Overall, the medium components are divided into two categories: ‘consumable nutrients' and ‘unconsumable inorganic bulk salts’. In such fortified medium, the concentrations of consumable nutrients, but not bulk salts, are increased. With a stoichiometrically-balanced medium, the large amount of nutrients fed into the culture is largely consumed by cells to give rise to residual concentrations of these nutrients in their optimal range. However, unless care is taken to initiate the continuous culture, overshoot of nutrients may occur during the transient period. The high nutrient concentration during overshoot may be inhibitory by itself, or the resulting high osmolality may retard the growth. Using a mathematical model that incorporates the growth inhibitory effect of high osmolality we demonstrate such a potentially catastrophic effect of nutrient and osmolality overshoot by simulation. To avoid overshoot a controlled nutrient feeding scheme should be devised at the initiation of continuous culture. This revised version was published online in July 2006 with corrections to the Cover Date.     

Automatic Cell Counting in Continuous Flow Cultures of Tetrahymena pyriformis*

This report describes an electronic cell counter constructed for determining cell number in cultures of the ciliate, Tetrahymena pyriformis. The culture chamber has been equipped with a device which determines the number of cells per unit volume and records the number automatically. As cell multiplication is unaffected by the counting procedure the cells are returned to the culture. Furthermore, keeping the culture volume constant we have arranged a continuous flow of fresh nutrient medium through the culture chamber and thus established conditions under which cell multiplication has continued for months while determinations of cell concentrations have been recorded every 10 min. Since the culture volume has been small, ～25 ml, growth studies utilizing this method require less than one liter of fresh medium per week in spite of the fast multiplication (9 generations per 24 hr) occurring in cultures of Tetrahymena pyriformis under optimal conditions.     

Relationship Between Cell Size and Efficiency of Synchronization During Nitrogen-Limited Phased Cultivation of Candida utilis

Under the phased method of cultivation the yeast Candida utilis grew and divided synchronously. The newly formed cells were relatively small, and a new cell cycle was not initiated until the cells could attain a certain minimum size (critical size). Although the cells expanded to some extent after division, the critical size was not reached until a fresh supply of medium was provided. With the arrival of the fresh supply of growth medium at the beginning of the phasing period, the cells expanded rapidly, and new cell cycles were initiated. The cells continued to expand until the growth-limiting nutrient (nitrogen source) was exhausted or until 90 min, which ever occurred first. Usually, buds emerged at a constant time after the start of the phasing period. The time of bud emergence was independent of the size attained by the cells during the expansion phase of growth. The results indicated that it was initiation of the cell cycle that was under size control, and not bud emergence. Bud emergence seemed to be under the control of a timer. The start of this timer seemed to be at or immediately after the beginning of the phasing period. Protein synthesis was essential for the initiation and expansion of buds. However, inhibition of protein synthesis by cycloheximide did not prevent unbudded cells or the parent portion of budded cells from expanding. Cycloheximide seemed to abolish the control mechanism(s) which prevented the cells from expanding after they had reached the maximum size.     

D-valine as a selective agent for normal human and rodent epithelial cells in culture.

A nutrient medium has been developed to enable the growth of normal epithelial cells while selectively inhibiting fibroblast proliferation. In this medium, D-valine is substituted for L-valine; and only those cells containing D-amino acid oxidase can convert the D-amino acid into its essential L-enantiomer. The ability to select for cells with this enzyme has enabled us to maintain epithelial cell populations free from fibroblast overgrowth. The presence of D-amino acid oxidase has been histochemically confirmed in the epithelial cells selected from renal cell suspensions and explants. The ability to proliferate in the selective medium is transmitted to the clonal progeny of these cells. Moreover, epithelial cell proliferation of this medium indicates the presence of D-amino acid oxidase, which we have detected in tissues where it had not previously been reported-fetal human kidney, lung, and cord. Fibroblasts will not grow in the selective medium, but will proliferate normally if the product of the D-amino acid oxidase reaction is supplied.     

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.