Properties of ras-amplified recombinant BHK-21 cells in protein-free culture

We compared serum and protein-free cultures ofa ras-amplified recombinant BHK-21 cell line(ras-rBHK-IgG), which hyperproduces a lungcancer specific recombinant human monoclonal antibody. Ras-rBHK-IgG cells were shown to grow well, evenin protein-free medium and to be morphologicallysimilar to cells cultured in serum containing medium. However, the growth rate of ras-rBHK-IgG cellswas considerably slower in protein-free medium, whichresults in a longer maintenance period compared with cells cultured in serum containing medium. In addition, it was found that antibody production in protein-free culture had a ten times higher maximum than cells cultured in serum containing medium. On theother hand, in high density culture, using the hollowfiber bioreactor system, ras-rBHK-IgG cellscould be maintained for a month in protein-freeculture in contrast with serum culture, which onlylasted for half a month. However, the markedincrease of antibody production was not observed. A total amount of about 15 mg of the recombinantantibody, obtained in protein-free culture, was abouttwo times of that obtained in serum culture, and wasshown to be reactive to lung cancer cells in tissue. From these properties in protein-free medium, it isconcluded that protein-free culture of ras-rBHK-IgG cells is suitable for middle scaleproduction of recombinant human monoclonal antibody.     

Correlation between the high rate of protein synthesis during mitosis and the absence of G1 period in V79-8 cells

The object of this study was to investigate whether modification of culture conditions would induce G1 and G2 periods in the Chinese hamster cell line, V79-8, which has been reported to exhibit neither of these phases in its life cycle. The results of this study indicate that under optimum culture conditions this cell line multiplies rapidly, with a generation time of about 9.5 h, and exhibits no measurable G1 period. However, under conditions of confluent growth, deprivation of isoleucine or inhibition of polyamine biosynthesis, a significant fraction (44–85%) of the cell population is preferentially arrested in the G1 period. Transient G2 arrest can also be induced in these cells by replacing the amino acid phenylalanine by its analog p-fluorophenylalanine. We have observed that decreasing the concentration of serum in the medium from 16 to 1% resulted not only in the prolongation of generation time but also resulted in a significant increase in the length of G1 period. Culturing cells in medium with 1% serum had no measurable effect on the rate of protein synthesis in interphase cells but a 50% reduction was seen in that of mitotic cells. The ratio between the rates of protein synthesis in mitotic and interphase cells in the line V79-8 is considerably higher (0.373) than that of G1-1 (0.218), a variant of V79-8 that has a G1 period of 4.25 h. These data suggest that cell line V79-8 is unique in retaining a relatively high rate of protein synthesis during mitosis under most favorable conditions. Probably this feature allows the synthesis of the factors necessary for the initiation of DNA synthesis while the cells are still in mitosis. However, under subnormal conditions the protein synthesizing machinery in the mitotic cells becomes inefficient and the cells require a longer time to synthesize the inducers of DNA synthesis; hence a G1 period is expressed.     

Growing a stratified,cornified primary culture of rat keratinocytes with epidermis-like water permeation barrier function

Summary The culture of cutaneous keratinocytes grown on a Puropore nylon microporous membrane at the air-liquid interface has been shown to be similar to the epidermis in a number of molecular and morphologic characteristics but to exhibit a significantly greater degree of tritiated water permeation. Various culture conditions have been altered in an effort to improve the water barrier properties. A Kp value in the range of 5.5±1.6×10⁻³ has been obtained for 79% of the culturea) by plating 0.9×10⁶ viable basal cells on a piece (13-mm diameter) of membrane for 7 days of submerged growth,b) by placing two membranes on two stacked glass fiber filters (47-mm extra-thick) in a culture dish (60 mm) for 14 days of growth at the air-liquid interface,c) by replacing the growth medium, i.e., 1 ml of complete minimum essential medium (CMEM) every 24 h after lifting,d) by using 10% fetal bovine serum (FBS) in the CMEM during the submerged culture period and 15% FBS in the CMEM during the lifted culture period, ande) by adding a dialysis membrane on top and a Puropore nylon membrane below the culture when the cultures were inserted in the permeation cell for testing. The percentage of cultures with this value for Kp can be increased to 90% if only cultures with yellow, smooth, and shiny surfaces are tested. This system should be useful as a replacement for skin in testing the cutaneous permeation of some chemicals. To whom correspondence should be addressed at 1528 Public Health, The University of Michigan, Ann Arbor, Michigan 48109-2029.     

The mechanism of regulation of fibroblastic cell replication. I. Properties of the system

Sixty to eighty per cent of the cells in a culture of human diploid fibroblasts may be stimulated from the state of density dependent inhibition of replication to active DNA synthesis and division. The maximum response is effected by 50% serum within the pH range 7.2–8.0. The proportion of cells responding depends on the concentration of serum protein in the medium which may be effectively substituted by crystalling serum albumin. There is a differential sensitivity to the stimulus of cells in the densely packed centers of whorls and in the less dense areas between the whorls. The cell response is parasynchronous and the median durations of the various phases of the cell cycle are: G₁I 6 β ?æ^® ¿ ∞ 8 hours, G₂ = 6 hours and doubling time = 30 hours. The stimulatory effect of fresh medium is lost during contact with dense cultures so that it has only 50% of its initial capacity after 14 hours. It can be restored by dialysis against serum-free medium. The stimulus must be applied for at least ten hours to be effective in inducing DNA synthesis. During the latter half of ten hour induction period subsequent DNA synthesis becomes exquisitely sensitive to actinomycin D. After this time an increasing number of cells become irreversibly committed to replicate. The data are interpreted to indicate that during contact with serum proteins (including albumin) changes in the cell surface, if continued long enough, trigger a mechanism which involves the synthesis of a unique RNA species during the fifth to tenth hours. After this RNA has been synthesized the cells are then committed to DNA synthesis.     

Controls over the timing of DNA replication during the cell cycle of fission yeast

The controls acting over the timing of DNA replication (S) during the cell cycle have been investigated in the fission yeast Schizosaccharomyces pombe. The cell size at which DNA replication takes place has been determined in a number of experimental situations such as growth of nitrogen-starved cells, spore germination and synchronous culture of wee mutant and wild-type strains. It is shown that in wee mutant strains and in wild type grown under conditions in which the cells are small, DNA replication takes place in cells of the same size. This suggests that there is a minimum cell size beneath which the cell cannot initiate DNA replication and it is this control which determines the timing of S during the cell cycle of the wee mutant. Fast growing wild-type cells are too large for this size control to be expressed. In these cells the timing of S may be controlled by the completion of the previous nuclear division coupled with a requirement for a minimum period in G1. Thus in S. pombe there are two different controls over the timing of S, either of which can be operative depending upon the size of the cell at cell division. It is suggested that these two controls may form a useful conceptual framework for considering the timing control over S in mammalian cells.     

Bcl-2 over-expression reduced the serum dependency and improved the nutrient metabolism in a NS0 cells culture

The over-expression of Bcl-2 has greatly improved the culture period, specific growth rate, and maximum viable cell density of NS0 cells culture under low serum condition. Further analysis of these data suggests that a saturation model of the Monod type can be used to represent the relationships of specific growth rate and initial serum concentration. The μ_max andK _s for the Bcl-2 cell line is 0.927 day⁻¹ and 0.947% (v/v) respectively, which are 21% greater and 7% lower respectively than its control counterpart. Study on the amino acid supplementation revealed that Bcl-2 cell lines possess greater improvement in the specific growth rate and maximum viable cell density compared to the control cell lines. A further increase in the amino acid supplementation has resulted a 17% decrease in specific growth rate and no improvement in maximum viable cell density in the control culture. However, the Bcl-2 cell line exhibited a better growth characteristic in this culture condition compared to that of control cell lines. The higher specific growth rate and maximum viable cell density of the Bcl-2 cell line in medium fortified with serum and MEM EAA suggested a more efficient nutrient metabolism compared to that in the control cell line. The low serum and amino acid utilisation rate and the higher cell yield may prove to be important in the development of serum/protein free culture.     

Alteration of the rate of cell division independent of the rate of DNA synthesis in a mutant of Salmonella typhimurium

Summary Salmonella typhimurium strain IIG has a temperature—sensitive DNA synthesis initiation apparatus and completes rounds of DNA replication when shifted to 38°. At this temperature there is a period of apparently normal division followed by a second phase in which DNA-less cells are produced. The rate of division in this second phase can be markedly increased if a culture growing in MM is shifted to nutrient broth at the time of the temperature shift. The extra divisions induced by the nutritional shift are not due to extra replication forks being introduced by this process nor to the rapid growth of ts ⁺ revertants. It is concluded that in this strain at 38°, the rate of division can be increased without altering the rate of DNA synthesis. The extra divisions induced by the shift-up do not take place for about 90 min. The possible occurrence of such a period between the triggering of division and the division event in normal cells is discussed.     

Screening of the common culture conditions affecting crystallinity of bacterial cellulose

By analyzing with X-ray diffraction and FT-IR spectroscopy, the main effective factors among common culture conditions on crystallinity index and I _α fraction of cellulose produced by Gluconacetobacter xylinus were examined with Plackett–Burman design experiment. Varying pH value in the medium by adjusting the composition of citrate buffer or by adding HCl/NaOH solution indicates it is the content of citrate buffer rather than its function of pH buffering that gives the influence on crystallinity. Further experiment reveals that Na⁺ concentration of 0.174 mol/l in medium with citrate buffer added would decrease the crystallinity index significantly. Comparison of carbon sources shows that fructose leads to a higher crystallinity index than glucose, which suggests a relationship between crystallinity and production speed of bacterial cellulose affected by carbon sources. An interesting phenomenon was that a longer period of cultivation would decrease the crystallinity of bacterial cellulose. The reason is assumed to be the dense network of cellulose formed by bacterial cells that restrict the motion of themselves as the incubation period extends. Though the effect of inoculum age is still unclear, the influence on crystallinity of bacterial cellulose caused by variation of some ordinary culture conditions can be drawn out from data of this work.     

Cytological Characterization of a Giant Strain of Euglena gracilis Obtained from Dark-starved Cultures

Euglena gracilis green cells were dark-starved for four months. After this period almost the entire population died, while a few giant, viable cells appeared in the culture. The giantism was maintained after repeated subcultures in growth medium in light or dark conditions. However, the phenomenon was not permanent, and the morphological characteristics of the wild-type Euglena were gradually restored. In giant cells nuclei enlarged greatly, DNA content increased and the Golgi apparatus greatly proliferated. Chloroplasts and mitochondria increased in number and size and often presented structural modifications when compared with normal Euglena. Importantly, in the giant cells that were maintained in darkness in resting or growth conditions chloroplasts persisted as structured organelles which appeared red-fluorescent under UV illumination. Whether giantism is a phenotypic or a genotypic change is still debated. In our case, the evolution of this phenomenon, chiefly the enhanced DNA content, suggests that teratism is a multiploid mutation with the possibility of a return to the normoploid condition. Constitutive chloroplasts are present in most algae, except for a few species, among which is Euglena gracilis. The persistence of differentiated plastids in darkness in giant Euglena is considered to be a return to an ancestral condition and may, therefore, be phylogenetically important.     

Potential use of ageing cultures ofIsochrysis aff.galbana (Isochrysis Tahitian,T. Iso) as starter cultures for live algal food production in tropical aquaculture

When grown in batch culture for a prolonged period (up to 11 months), the cells ofIsochrysis aff.galbana (Isochrysis Tahitian strain T. Iso) lost their capacity to divide and became enlarged, with a reduction in the content of photosynthetic pigment and photosynthetic capacity. Upon returning to fresh medium, the cells of a 11-month-old culture regained their capacity to divide within 3 days under light conditions. The resulting cells possessed similar size, photosynthetic pigment and photosynthetic capacity as those of logarithmic growth phase. The results suggest that the aged cultures ofIsochrysis can be used as starter cultures for the production of live food for aquaculture animals.     

Hybridoma Ped-2E9 cells cultured under modified conditions can sensitively detect <Emphasis Type="Italic">Listeria monocytogenes</Emphasis> and <Emphasis Type="Italic">Bacillus cereus</Emphasis>

Lymphocyte origin hybridoma Ped-2E9 cell-based cytotoxicity assay can detect virulent Listeria or Bacillus species, and its application in a cell-based biosensor for onsite use would be very attractive. However, maintaining enough viable cells on a sensor platform for a prolonged duration is a challenging task. In this study, key factors affecting the survival and growth of Ped-2E9 cells under modified conditions were investigated. When the Ped-2E9 cells were grown in media containing 5% fetal bovine serum in sealed tubes without any replenishment of nutrients or exogenous CO₂ supply, a large portion of the cells remained viable for 6 to 7 days and cells entered into G0/G1 resting phase. The media pH change was negligible and no cell death was observed in the first 4 days, then cells sequentially underwent apoptotic (fourth day onward) phase until day 7 after which a majority was dead. Subsequent cytotoxicity testing of 3- to 7-day stored Ped-2E9 cells sensitively detected virulent Listeria and Bacillus species. These data strongly suggest that Ped-2E9 cells can be maintained in viable state for 6 days in a sealed tube mimicking the environment in a potential sensor device for onsite use without the need for expensive cell culture facilities.     

Use of hepatocytes in primary culture for biochemical studies on liver functions

Summary Rat parenchymal hepatocytes isolated with collagenase were cultured as monolayers in Williams medium E supplemented with calf serum. Freshly isolated cells showed very low activities of various liver functions, and they had to be cultured for 6-24 h to allow recovery of these functions. Insulin and dexamethasone greatly increased cell viability in primary culture. After culture for 24 h, these cells showed various liver functions as seen in vivo and responded well to various added hormones and amino acids. The concentrations of amino acids in the medium regulated synthesis of serum proteins and insulin stimulated lipogenesis, which in turn regulated synthesis of lipoproteins. Insulin also stimulated glycogen synthesis and the stimulation was parallel with the number of insulin receptors. Glucagon stimulated glycogenolysis and its stimulation involved the function of the cytoskeleton. Glucagon and dexamethasone induced various enzymes of amino acid catabolism, such as tryptophan oxygenase, tyrosine aminotransferase and serine dehydratase. These inductions were inhibited by insulin or catecholamine. The effect of catecholamine was due to its -adrenergic action. The -action of isoproterenol was low in freshly isolated cells, but increased during culture of the cells. Acquirement of hormonal responses during neonatal development can be studied in this culture system. Mature hepatocytes in culture are usually quiescent, but when insulin and epidermal growth factor were added, DNA synthesis by the cells increased markedly and they showed density-dependent growth. In this culture system, serum could be omitted for 2 days when the dishes were coated with fibronectin without appreciable change of functions, but serum was needed for longer culture of the cells. A factor that increased cell survival was found in serum and in pituitary gland.These results show that hepatocytes in primary culture are a simple and useful system for studies of liver functions in vitro and related works were also reviewed.     

Growth-promoting effects of gastrin on mouse colon cancer cells in vitro: Absence of autocrine effects

Summary We have previously demonstrated trophic effects of gastrin on mouse colon cancer (MC-26) cells, in vivo, and demonstrated the presence of gastrin receptors (GR) on these cells. The cellular and intracellular mechanism by which gastrin expresses trophic effects on colon cancer cells is, however, as yet unknown. For us to start investigating the possible mechanisms involved, it was important that we first develop an in vitro model, in which gastrin expresses its trophic effects directly on the MC-26 cells. The growth-promoting effects of gastrin on the MC-26 cells were examined in various in vitro culture models, in terms of [³H]thymidine incorporation and cell number. A significant trophic effect of gastrin could be demonstrated on quiescent cells in culture, in the absence of serum. The optimal cell-culture conditions for observing trophic effects of gastrin were defined and included a 24-h period of rapid growth of MC-26 cells in serum-supplemented normal growth medium, followed by a 24-h period of culture in serum-free medium containing an optimal dose (1.0 mM) of thymidine, to achieve growth-arrest of the cells. Addition of gastrin (0.5 to 25 nM) to the quiescent, growth-arrested cells resulted in significant dose-dependent increases in both the incorporation of [³H]thymidine uptake by the cells, and a significant increase in cell number. The concentration of GR on the growth-arrested quiescent MC-26 cells in culture was significantly increased compared to the GR concentration on the control, asynchronized cells. The increased presence of GR on the growth-arrested, synchronized MC-26 cells may have allowed us to observe a significant trophic effect of gastrin on the MC-26 cells, in vitro itself. To determine if gastrin was functioning as an autocrine growth factor for MC-26 cells, we examined the effect of gastrin antibodies on the growth of MC-26 cells; no significant effect of the antigastrin IgG on the growth of MC-26 cells was observed. Supported by grants from the National Institutes of Health, Bethesda, MD (PO1 DK 35608 and CA 38651, and a grant from the American Cancer Society, Washington, DC (PDT-220).     

Identification of Major Factors Influencing ELISpot-Based Monitoring of Cellular Responses to Antigens from Mycobacterium tuberculosis

A number of different interferon-γ ELISpot protocols are in use in laboratories studying antigen-specific immune responses. It is therefore unclear how results from different assays compare, and what factors most significantly influence assay outcome. One such difference is that some laboratories use a short in vitro stimulation period of cells before they are transferred to the ELISpot plate; this is commonly done in the case of frozen cells, in order to enhance assay sensitivity. Other differences that may be significant include antibody coating of plates, the use of media with or without serum, the serum source and the number of cells added to the wells. The aim of this paper was to identify which components of the different ELISpot protocols influenced assay sensitivity and inter-laboratory variation. Four laboratories provided protocols for quantifying numbers of interferon-γ spot forming cells in human peripheral blood mononuclear cells stimulated with Mycobacterium tuberculosis derived antigens. The differences in the protocols were compared directly. We found that several sources of variation in assay protocols can be eliminated, for example by avoiding serum supplementation and using AIM-V serum free medium. In addition, the number of cells added to ELISpot wells should also be standardised. Importantly, delays in peripheral blood mononuclear cell processing before stimulation had a marked effect on the number of detectable spot forming cells; processing delay thus should be minimised as well as standardised. Finally, a pre-stimulation culture period improved the sensitivity of the assay, however this effect may be both antigen and donor dependent. In conclusion, small differences in ELISpot protocols in routine use can affect the results obtained and care should be given to conditions selected for use in a given study. A pre-stimulation step may improve the sensitivity of the assay, particularly when cells have been previously frozen.     

Effect of endogenous methylglyoxal on Chinese hamster ovary cells grown in culture

Methylglyoxal is a ketoaldehyde that reacts readily under physiological conditions with biologically relevant ligands, such as amine and sulfhydryl groups. It is produced in mammalian cells primarily as a by-product of glycolysis. The level of glucose, L-glutamine and fetal bovine serum in culture media was found to significantly affect levels of intracellular methylglyoxal in Chinese hamster ovary cells. Medium with 25 mM glucose and 5 mM L-glutamine caused an increase in free methylglyoxal levels of 90 to 100% relative to medium containing 5 mM glucose and 2 mM L-glutamine. Both of these media compositions are representative of those found in commercially available media. Pseudomonas putida glyoxalase I was expressed in Chinese hamster ovary cells to enhance methylglyoxal detoxification. The Chinese hamster ovary cell clones showed an 80 to 90% decrease in free methylglyoxal levels. The colony-forming ability of these cells was compared to wild-type Chinese hamster ovary cells under conditions found to cause elevated methylglyoxal levels. The wild-type cells showed a 10% decrease in colony-forming ability relative to the clones. This decrease was found to be statistically significant (P>0.99) by analysis of variance. The variation in colony-forming ability amongst the clones was statistically insignificant. More importantly, the clones shoed increased colony-forming ability relative to the wild-type cells under conditions of higher methylglyoxal production with fair to good statistical significance (P>0.75 to P>0.95). This result is the first quantifiable evidence that endogenously produced methylglyoxal can negatively affect cell function under conditions found in animal cell culture.Abbreviations ANOVA analysis of variance - CHO Chinese hamster ovary cells - CFA colony-forming ability - dhfr gene for dihydrofolate reductase - DHAP dihydroxyacetone phosphate - FBS fetal bovine serum - G-3-P glyceraldehyde-3-phosphate - GloI glyoxalase I - GloII glyoxalase II - GSH reduced glutathione - HPLC high-performance liquid chromatography - IMDM Iscove's modified Dulbecco's medium - MTX methotrexate - 2-MQ 2-methylquinoxaline - 5-MQ 5-methylquinoxaline - MEM minimal essential medium - P_i inorganic phosphate - PCA perchloric acid - o-PD o-phenylenediamine     

Steroid production,cell proliferation,and apoptosis in cultured bovine antral and mural granulosa cells: Development of an in vitro model to study estradiol production

This study was undertaken to characterize the relationship between changes in steroid production, cell cycle activity (ie, cell proliferation) and apoptosis in antral and mural bovine granulosa cells cultured in vitro. This was done to select conditions promoting optimal estradiol production by bovine granulosa cells cultured in completely defined conditions. In the first experiment, antral granulosa cells were cultured over the entire 4 days of the culture period in the presence of either 0, 2, or 10 ng/ml of FSH (chronic conditions) or were maintained under minimal FSH support (0.5 ng/ml FSH) for the first 3 days of culture and then were challenged over the fourth day of culture with either 0, 2, or 10 ng/ml FSH (challenged conditions). Compared with cells exposed to constant FSH levels (chronic conditions), the FSH-induced production of estradiol was higher (P < 0.006) and that of progesterone was lower (P < 0.02) over the last 24 h of culture, when antral granulosa cells were maintained under minimal FSH support during the first 3 days of culture (challenged conditions). In the second experiment, dynamics of estradiol and progesterone productions, conversion of [¹⁴C]androstenedione into subsequent steroid metabolites, DNA content, cell cycle activity, and apoptosis (as assessed by flow cytometry) of antral and mural granulosa cells over the first 3 days of culture under minimal FSH support and in response to a challenge with FSH during the last 24 h of culture were evaluated. Estradiol production as well as the conversion of androstenedione into testosterone and estradiol were greater (P< 0.01) in antral than in mural granulosa cells cultured under challenged conditions. A higher proportion of mural than antral granulosa cells were in the proliferative state at the end of culture (P < 0.03). This may be related to the decreased ability of mural cells to produce estradiol. FSH suppressed (P < 0.05) the spontaneous onset of apoptosis in both cell types. These results suggest that functional differences between these two cell compartments need to be considered in studying bovine granulosa cells in vitro. Because of their large (400 to 600%) FSH-induced estradiol production, antral granulosa cells cultured under challenged conditions provide a model that can be used to examine substances for their ability to alter estradiol production and apoptosis in bovine granulosa cells. Mol. Reprod. Dev. 50:170–177, 1998. © 1998 Wiley-Liss, Inc.     

ACTIVITY AND ISOENZYME PATTERN OF LACTATE DEHYDROGENASE IN ASTROBLASTS CULTURED FROM BRAINS OF NEWBORN MICE

Lactate dehydrogenase activity and isoenzyme distribution was determined in primary cultures of astroblasts as a function of the culture period. The specific activity increased during this period with a peak value (1.91 ± 0.18μmol x min^-1 x mg^-1 cell protein) after 2 weeks in culture. The isoenzyme pattern changed during 3 weeks in culture towards a higher proportion of the H₄ (LDH-1) isoenzyme which is analogous to the in vivo pattern. Omission of serum with or without dBcAMP (0.5 mM) in the culture medium during the third week of culture further enhanced this prominence of the H₄ isoenzyme. The specific activity (1.58 × 0.06 μmol x min^-1 x mg^-1 cell protein) of cultures grown in the presence of 0.5 mM-dBcAMP and absence of serum was close to the activity in the adult brain.     

Gene expression profile analysis in astaxanthin-induced Haematococcus pluvialis using a cDNA microarray

The unicellular green alga Haematococcus pluvialis (Volvocales) is known for the ketocarotenoid astaxanthin (3, 3′-dihydroxy-β, β-carotene-4, 4′-dione) accumulation, which is induced under unfavorable culture conditions. In this work, we used cDNA microarray analysis to screen differentially expressed genes in H. pluvialis under astaxanthin-inductive culture conditions, such as combination of cell exposure to high irradiance and nutrient deprivation. Among the 965 genes in the cDNA array, there are 144 genes exhibiting differential expression (twofold changes) under these conditions. A significant decrease in the expression of photosynthesis-related genes was shown in astaxanthin-accumulating cells (red cells). Defense- or stress-related genes and signal transduction genes were also induced in the red cells. A comparison of microarray and real-time PCR analysis showed good correlation between the differentially expressed genes by the two methods. Our results indicate that the cDNA microarray approach, as employed in this work, can be relied upon and used to monitor gene expression profiles in H. pluvialis. In addition, the genes that were differentially expressed during astaxanthin induction are suitable candidates for further study and can be used as tools for dissecting the molecular mechanism of this unique pigment accumulation process in the green alga H. pluvialis. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Direct evidence for the response of B and T cells to pokeweed mitogen

Chicken spleen cells containing chromosomally marked thymus derived (T) and bursa-derived (B₂) cells were evaluated for their ability to respond to pokeweed mitogen (PWM), concanavalin A (Con A), and to anti-immunoglobulin serum during a 4-day culture period. The results indicate that soluble PWM induces a proliferative response of B₂ cells in addition to a predominant T cell response. The PWM-induced B₂ cell proliferative response was clearly detected only at 4 days after culture initiation. Soluble Con A did not induce detectable proliferation of B₂ cells and stimulated T cells exclusively. In contrast, anti-immunoglobulin serum was a specific stimulant for B₂ cells under the culture conditions used.     

Feasibility study on the use of hyperosmolar medium for improved antibody production of hybridoma cells in a long-term,repeated-fed batch culture

To test the feasibility of using hyperosmolar medium for improved antibody production in a long-term, repeated fed-batch culture, the influence of various culture conditions (serum concentration and cultivation method) on the hybridoma cells' response to hyperosmotic stress resulting from sodium chloride addition was first investigated in a batch culture. The degree of cell growth depression resulting from hyperosmotic stress was dependent on serum concentrations and cultivation methods (static and agitated cultures). Depression of cell growth was most significant in agitated cultures with low serum concentration. However, regardless of serum concentrations and cultivation methods used, the hyperosmotic stress significantly increased specific antibody productivity (q _MAb). Increasing osmolality from 284 to 396 mOsm kg^–1 enhanced the q_MAb in agitated cultures with 1% serum by approximately 124% while the similar osmotic stress enhanced the q _MAb in static cultures with 10% serum by approximately 153%. Next, to determine whether this enhanced q_MAb resulting from hyperosmotic stress can be maintained after adaptation, long-term, repeated-fed batch cultures with hyperosmolar media were carried out. The cells appeared to adapt to hyperosmotic stress. When a hyperosmolar medium (10% serum, 403 mOsmkg^–1) was used, the specific growth rate improved gradually for the first four batches and thereafter, remained constant at 0.040±0.003 (average ± standard deviation) hr^–1 which is close to the value obtained from a standard medium (10% serum, 284 mOsmkg^–1) in the batch culture. While the cells were adpating to hyperosmotic stress, the q_MAb was gradually decreased from 0.388×10^–6 to 0.265×10^–6 g cell hr^–1 and thereafter, remained almost constant at 0.272±0.014× 10^–6 g cell^–1 hr^–1. However, this reduced q _MAb after adaptation is still approximately 98% higher than the q_MAb obtained from a standard medium in the batch culture.The authors would like to thank Dr.M. Kaminski for providing the hybridoma cell line used in this study. This work was supported by the Korea Science and Engineering Foundation.