Effects of ammonia and lactate on hybridoma growth, metabolism, and antibody production

The influence of ammonia and lactate on cell growth, metabolic, and antibody production rates was investigated for murine hybridoma cell line 163.4G5.3 during batch culture. The specific growth rate was reduced by one-half in the presence of an initial ammonia concentration of 4 mM. Increasing ammonia levels accelerated glucose and glutamine consumption, decreased ammonia yield from glutamine, and increased alanine yield from glutamine. Although the amount of antibody produced decreased with increasing ammonia concentration, the specific antibody productivity remained relatively constant around a value of 0.22 pg/cell-h. The specific growth rate was reduced by one-half at an initial lactate concentration of 55 mM. Although specific glucose and glutamine uptake rates were increased at high lacatate concentration, they showed a decrease after making corrections for medium osmolarity. The yield coefficient of lactate from glucose decreased at high lactate concentrations. A similar decrease was observed for the ammonia yield coefficient from glutamine. At elevated lactate concentrations, specific antibody productivities increased, possibly due to the increase in medium osmolarity. The specific oxygen uptake rate was insensitive to ammonia and lactate concentrations. Addition of ammonia and lactate increased the calculated metabolic energy production of the cells. At high ammonia and lactate, the contribution of glycolysis to total energy production increased. Decreasing external pH and increasing ammonia concentrations caused cytoplasmic acidification. Effect of lactate on intracellular pH was insignificant, whereas increasing osmolarity caused cytoplasmic alkalinization.     

Influence of lactate, ammonia, and osmotic stress on adherent and suspension BHK cells.

Adherent and suspension Baby Hamster Kidney (BHK) 21c13 cells were cultivated in a 2.5-1 stirred-tank reactor with indirect aeration. Cell concentration and viability as well as glucose, lactate, ammonia, and protein concentrations in the medium and intracellular and extracellular activities of the intracellular enzymes were determined off-line. The concentrations of glucose, lactate, ammonia, and the activity of lactate dehydrogenase in the culture medium were monitored on-line. The cell/cell fragment size distribution was determined by laser flow cytometer off-line. In several runs, the size distributions were ascertained on-line by a laser flow cytometer. The influence of lactate, ammonia, and osmotic pressure on the viability and biological parameters of the suspension cells was evaluated. In Roux flasks, lactate and ammonia had considerable influence on the cell properties; in stirred tank reactors, these influences were negligible up to 9.5 g l-1 lactate and 150 mg l-1 NH+4 ion concentrations. The influence of high osmolarity on the biological parameters of the cells was much less in the stirred-tank than in the Roux flasks. The adhesion of adherent cells on a surface was impeded neither by the lactate (up to 6 g l-1) nor by the ammonia concentration (up to 150 mg l-1). However, with increasing osmolarity, the fraction of the cells adhered to a surface reduced to below 5% (at 680 mOsmol l-1).     

Two-dimensional versus three-dimensional culture systems: Effects on growth and productivity of BHK cells

The influence of surface growth (two-dimensional microcarriers) and three-dimensional growth (aggregates and macroporous supports) in agitated, suspended batch culture systems upon growth and productivity of BHK was compared. Cultures using three porous microcarriers (CultiSpher G, Cellsnow EX, and Cytocell), one nonporous microcarrier (Cytodex 3) and natural aggregates were performed in stirred tanks using two different agitation rates (60 and 100 RPM). With the exception of Cytocell, cell growth, viability, and productivity were similar when three-dimensional structures (porous microcarriers and aggregates) were used. Nonporous microcarriers only compared well at 60 RPM as growth ceased under overagitation. These results suggest that cultures less susceptible to fluid shear are advantageous for scale-up. (c) 1996 John Wiley & Sons, Inc.     

Attachment and growth kinetics of anchorage-dependent BHK cells on microcarriers

Anchorage-dependent Baby Hamster Kidney (BHK) cells were cultivated on polyhydroxyethylmethacrylate (PHEMA), polystyrene (PS), and Cytodex microcarriers. Analysis of the experimental data indicated that there were a finite number of sites on the microcarrier surfaces, available for anchorage. The number of these sites was determined by the chemical and physical structure of the surface. A small fraction of these sites were suitable for attachment of the cells before proliferation. A larger fraction of these sites did not support attachment but the cells could proliferate on them by the help of previously attached mother cells. The attachment and proliferation of the BHK cells on these microcarriers were satisfactorily modeled by surface saturation type of mathematical expressions.     

Effects of ammonia and norvaline on lactate metabolism by hepatocytes from starved rats. The use of 14C-labelled lactate in studies of hepatic gluconeogenesis

1. Hepatocytes from starved rats were incubated with l-lactate and NH(4)Cl or norvaline, and the rates of the tricarboxylic acid cycle and of gluconeogenesis were calculated from changes in metabolite concentrations or from radioisotopic data from incubations with labelled lactate or propionate. 2. Gluconeogenesis was stimulated by the addition of 10mm-NH(4)Cl, 5mm-norvaline or 1mm-oleate by 27, 45 and 59% respectively. NH(4)Cl or norvaline also increased lactate uptake. Norvaline inhibited urea synthesis from NH(4)Cl by 85%. 3. The effects of NH(4)Cl and norvaline were not additive. However, NH(4)Cl inhibited and norvaline was without effect on gluconeogenesis from pyruvate, indicating that the two compounds act by different mechanisms. 4. The tricarboxylic acid-cycle flux was increased 80% by lactate, and NH(4)Cl caused a further 25% stimulation. Norvaline had no effect on the tricarboxylic acid-cycle flux. NH(4)Cl and norvaline tripled and doubled, respectively, flux through pyruvate dehydrogenase. 5. Total ATP formation was calculated to range from 470 to 830mumol/h per 100mg of protein, of which the basic metabolic activity accounted for 400-450mumol/h per 100mg of protein. ATP formation does not seem to be rate-limiting for gluconeogenesis. 6. Pyruvate recycling was estimated from the (14)C yield from [1-(14)C]propionate in lactate and glucose to be 10-30% of the flux of phosphoenolpyruvate to glucose. The further addition of NH(4)Cl more than doubled the recycling of pyruvate. 7. [1,4-(14)C]Succinate was rapidly metabolized by hepatocytes. About 20% of the radioactivity was recovered in glucose, indicating that succinate is also metabolized by intact (non-damaged) hepatocytes. 8. It is concluded that the metabolism of lactate by the liver is too complex to allow simple rate measurements with labelled compounds.     

Enhanced productivity during controlled proliferation of BHK cells in continuously perfused bioreactors

A perfused cell-culture process was developed to investigate the stability of IRF-1-mediated proliferation control in BHK cells and to evaluate the efficacy of a novel promoter in these cells. The cell density of proliferation-controlled producer cells was effectively regulated for over 7 weeks in a microcarrier-based continuously perfused bioreactor. An IRF-1-inducible promoter was employed to express a heterodimeric IgG antibody as a relevant model protein. Basal expression levels were equivalent to that of a highly active viral promoter, while productivity increased up to sixfold during growth arrest. However, no stably expressing clone was isolated in this study. Protein expression decreased gradually with time and could not be induced further in subsequent growth-repression cycles. The results demonstrate that the regulatory system is sufficiently stable to allow controlled growth in a continuous scalable reactor system and that productivity increases can be achieved in a proliferation controlled microcarrier culture.     

Effects of ammonia on CHO cell growth, erythropoietin production, and glycosylation

The effect of ammonium chloride was determined on a culture of CHO cells transfected with the human erythropoietin (EPO) gene. Cell growth was inhibited above a culture concentration of 5 mM NH(4)Cl with an IC-50 determined to be 33 mM. The specific production of EPO increased with the addition of NH(4)Cl above 5 mM. At 10 mM NH(4)Cl, the final cell density after 4 days in culture was significantly lower but the final yield of EPO was significantly higher. This appeared to be due to continued protein production after cell growth had ceased. The metabolic effects of added NH(4)Cl included higher specific consumption rates of glucose and glutamine and an increased rate of production of alanine, glycine, and glutamate. The EPO analyzed from control cultures had a molecular weight range of 33-39 kDa and an isoelectric point range of 4.06-4.67. Seven distinct isoforms of the molecule were identified by two-dimensional electrophoresis. This molecular heterogeneity was ascribed to variable glycosylation. Complete enzymatic de-glycosylation resulted in a single molecular form with a molecular mass of 18 kDa. Addition of NH(4)Cl to the cultures caused a significant increase in the heterogeneity of the glycoforms as shown by an increased molecular weight and pI range. Enzymatic de-sialylation of the EPO from the ammonia-treated and control cultures resulted in identical electrophoretic patterns. This indicated that the effect of ammonia was in the reduction of terminal sialylation of the glycan structures which accounted for the increased pI. Selective removal of the N-glycan structures by PNGase F resulted in two bands identified as the O-glycan linked structure (19 kDa) and the completely de-glycosylated structure (18 kDa). The proportion of the O-linked glycan structure was reduced, and its pI increased in cultures to which ammonia was added. Thus, the glycosylation pattern altered by the presence of ammonia included a reduction in terminal sialylation of all the glycans and a reduction in the content of the O-linked glycan. The addition of a sialidase inhibitor to the cultures had no effect on the ammonia-induced increase in EPO heterogeneity. Also, the effect of ammonia on glycosylation could not be mimicked using the weak base chloroquine in our system.     

Effects of gamma-irradiation on survival, growth and productivity of broiler chicken

In experiments with broiler chicken the influence of gamma-irradiation (137Cs) to survive and productivity of meat poultry was studied. LD50/30 increased from 10.0 to 18.7 Gy with increasing of the age of the irradiated chicken from 3 to 40 days and reduced from 18.3 to 11.9 Gy with increasing of a dose rate from 1.0 to 40.0 Gy/h. As a rule, death of chicken was observed between 4th and 15th days after the exposure; the most early dates of poultry death were found at irradiation dose rate of 40.0 Gy/h. The exposure to doses of 8-20 Gy resulted in stunted growth; in comparison with control group the mass reduced by 22-32 g per each 1 Gy, lowering of meat productivity by 36%.     

Effects of dieldrin, picrotoxin and Telodrin on the metabolism of ammonia in brain

1. Increases in the concentrations of lactic acid and pyruvic acid in rat brain during acute dieldrin poisoning are associated with hyperactivity of the brain, whereas an increase in the cerebral alanine concentration occurs before the convulsions. Throughout the dieldrin-induced seizure pattern, fluctuations in the concentration of brain ammonia are out of phase with the actual convulsions. 2. Increases in the concentrations of alanine, ammonia and lactic acid in rat brain accompany picrotoxin-induced seizures; there is no increase in the concentration of glutamine. These changes are consistent with the inhibition of glutamine synthesis. 3. In addition to previously reported changes in the concentrations of intermediary metabolites of the brain after the administration of Telodrin (Hathway & Mallinson, 1964), increases have now been found in the alanine and lactic acid concentrations. Since increases in the alanine and glutamine concentrations occur before the convulsions, liberation of ammonia also occurs before the onset of convulsions and throughout their course. Ammonia-binding mechanisms later become inadequate and free ammonia accumulates in cerebral tissues. 4. An increase in the pyruvic acid concentration of the brain after the intraperitoneal injection of either dieldrin or Telodrin is endogenous in origin. 5. The parenteral administration of a small dose of glutamine increases the cerebral concentrations of alanine and glutamic acid. Some animals previously treated with glutamine resisted Telodrin convulsions. 6. Mechanisms for the disposal of ammonia liberated in brain are discussed.     

Growth study of lactate and ammonia double-resistant clones of HL-60 cells

The possibility that lactate and ammonia accumulation may have less detrimental effect on cell growth than usually admitted is investigated. We report here the isolation of several HL-60 subclones able to proliferate in the presence of 60 mM sodium lactate and 4 mM ammonium chloride, concentrations usually considered to be toxic for cell proliferation. Growth kinetics and final cell densities of these clones in suspension cultures were similar to the HL-60 cell population in control medium as well as in medium containing ammonia and lactate in which control cells were unable to grow. The metabolic pattern of the double-resistant clones revealed that lactate and ammonia formation was inhibited in the presence of lactate and ammonia in the medium, while alanine production and arginine consumption were enhanced irrespective of the medium.     

Significant contribution of liver nonparenchymal cells to metabolism of ammonia and lactate and cocultivation augments the functions of a bioartificial liver

A bioartificial liver (BAL) will bridge patients with acute liver failure (ALF) to either spontaneous regeneration or liver transplantation. The nitrogen metabolism is important in ALF, and the metabolism of nonparenchymal liver cells (NPCs) is poorly understood. The scope of this study was to investigate whether cocultivation of hepatocytes with NPCs would augment the functions of a BAL (HN-BAL) compared with a BAL equipped with only hepatocytes (H-BAL). In addition, NPCs were similarly cultivated alone. The cells were cultivated for 8 days in simulated microgravity with serum-free growth medium. With NPCs, initial ammonia and lactate production were fivefold and over twofold higher compared with later time periods despite sufficient oxygen supply. Initial lactate production and glutamine consumption were threefold higher in HN-BAL than in H-BAL. With NPCs, initial glutamine consumption was two- to threefold higher compared with later time periods, whereas initial ornithine production and arginine consumption were over four- and eightfold higher compared with later time periods. In NPCs, the conversion of glutamine to glutamate and ammonia can be explained by the presence of glutaminase, as revealed by PCR analysis. Drug metabolism and clearance of aggregated gamma globulin, probes administered to test functions of hepatocytes and NPCs, respectively, were higher in HN-BAL than in H-BAL. In conclusion, NPCs produce ammonia by hydrolysis of amino acids and may contribute to the pathogenesis of ALF. High amounts of lactate are produced by NPCs under nonhypoxic conditions. Cocultivation augments differentiated functions such as drug metabolism and clearance of aggregated gamma-globulin.     

Changes in monoclonal antibody productivity of recombinant BHK cells immobilized in collagen gel particles

Animal cell perfusion high density culture is often adopted for the production of biologicals in industry. In high density culture sometimes the productivity of biologicals has been found to be enhanced. Especially in immobilized animal cell culture, significant increase in the productivity has been reported. We have found that the specific monoclonal antibody (MAb) productivity of an immobilized hybridoma cell is enhanced more than double. Several examples of enhancing productivities have been also shown by collagen immobilized cells. Immobilized cells involve some different points from non-immobilized cells in high density culture: In immobilized culture, some cells are contacted together, resulting in locally much higher cell concentration more than 10⁸ cells/ml. Information originating from a cell can be easily transduced to the others in immobilized culture because the distance between cells is much nearer. Here we have performed collagen gel immobilized culture of recombinant BHK cells which produce a human IgG monoclonal antibody in a protein-free medium for more than three months. In this high density culture a stabilized monoclonal antibody production was found with around 8 times higher specific monoclonal antibody productivity compared with that in a batch serum containing culture. No higher MAb productivity was observed using a conditioned medium which was obtained from the high density culture, indicating that no components secreted from the immobilized cells work for enhancing monoclonal antibody production. The MAb productivity by the non-immobilized cells obtained by dissolving collagen using a collagenase gradually decreased and returned to the original level in the batch culture using a fresh medium. This suggests that the direct contact of the cells or a very close distance between the cells has something to do with the enhancement of the MAb productivity, and the higher productivity is kept for a while in each cell after they are drawn apart.     

Collagen synthesis in normal BHK cells and temperature-sensitive chemically transformed BHK cells

Summary Collagen synthesis in normal BHK 21/cl 13 and chemically transformed temperature-sensitive BHK 21/cl 13 cells (Me₂N4) was assessed by examination of hydroxyproline formation and collagenase-susceptible protein. The Me₂N4 cells lost their ability to synthesize collagen at both permissive and nonpermissive temperatures for transformation. These conclusions were confirmed by polyacrylamide-gel electrophoresis and CM-cellulose chromotography. Prolyl hydroxylase activity was present in both normal and transformed cells even when no collagen could be demonstrated. The production of noncollagen protein, although decreased in the transformed cell, did not change as drastically as the collagen synthesis. This paper was supported in part by a grant from the Public Health Service (AG00001), and by the Medical Research Service of the Veterans Administration.     

Relationship of lactate dehydrogenase specificity and growth rate to lactate metabolism by Selenomonas ruminantium.

A lactate-fermenting strain of Selenomonas ruminantium (HD4) and a lactatenonfermenting strain (GA192) were examined with respect to the stereoisomers of lactate formed during glucose fermentation, the stereoisomers of lactate fermented by HD4, and the characteristics of the lactate dehydrogenases of the strains. GA192 formed L-lactate and HD4 formed L-lactate and small amounts of D-lactate from glucose. HD4 fermended L- but not D-lactate. Both strains contain nicotinamide adenine dinucleotide (NAD)-specific lactate dehydrogenases, and no NAD-independent lactate oxidation was detected. Continuous cultures of both strains grown with limiting glucose produced mainly propionate and acetate and little lactate at dilution rates less than 0.4/h, with shifts to increasing amounts of lactate and less acetate and propionate as the dilution rate was increased from 0.4/h to approximately 1/h.     

Enhanced growth in NS0 cells expressing aminoglycoside phosphotransferase is associated with changes in metabolism, productivity, and apoptosis

Prior work has reported that cotransfecting a gene of interest with the selectable marker neo can seriously perturb a number of cellular processes. In this study the influence of the neo gene on the growth, death, and metabolism of a murine myeloma NS0 cell line, expressing a chimeric antibody, was investigated. A pool of neo transfectants, 6A1-NEO, was selected with 500 microg/mL G418. Quantitative PCR analysis revealed that 6A1-NEO contained, on average, three copies of the neo gene per cell. Batch cultivation of 6A1-NEO showed that there was a 36% increase in maximum viable cell concentration, a 20% increase in the maximum apparent growth rate, and a 134% increase in cumulative cell hours as compared with the parent, 6A1-(100)3. Batch cultivation of five randomly selected clones illustrated that 6A1-NEO's advantage over the parent was not due to clonal variation. Neither the use of G418 during the selection process nor the cultivation of cells in the presence of G418 were responsible. This implied that the neo gene product, APH(3')-II, was causing the changes in proliferative capacity. Analysis of the cell cycle revealed that there were no differences in the distribution of cells in the G(1), S, and G(2) phases. When cell growth was synchronized, there were no observed differences in cell-cycle duration. 6A1-NEO resisted the onset of apoptosis during the growth phase. Consequently, there was a larger viable population of 6A1-NEO cells available for proliferation as compared with the parent. However, 6A1-NEO died at the same rate as the parent when resuspended in spent media or after treatment with staurosporin. Expression of the anti-apoptotic protein Bcl-2 was upregulated in 6A1-NEO, indicating that APH(3')-II could be acting by modulating endogenous gene expression. Analysis of key metabolites showed that 6A1-NEO's specific glucose consumption rate was 133% higher, whilst its specific glutamate consumption rate was 45% lower than the parent. 6A1-NEO's efficient utilization of glutamate and shift towards glucose metabolism may have contributed to the rise in proliferative capacity. However, this was accompanied by a 70% drop in the specific antibody production rate. These results show that the increase in growth rate and proliferative capacity caused by the expression of recombinant APH(3')-II was associated with changes in metabolism, apoptosis, and endogenous gene expression.     

Effects of CO2 and osmolality on hybridoma cells: growth, metabolism and monoclonal antibody production

CO2 partial pressure (pCO2) in industrial cell culture reactors may reach 150–200 mm Hg, which can significantly inhibit cell growth and recombinant protein production. Due to equilibrium with bicarbonate, increased pCO2 at constant pH results in a proportional increase in osmolality. Hybridoma AB2-143.2 cell growth rate decreased with increasing pCO2 in well-plate culture, with a 45% decrease at 195 mm Hg with partial osmolality compensation (to 361 mOsm kg- 1). Inhibition was more extensive without osmolality compensation, with a 63% decrease in growth rate at 195 mm Hg and 415 mOsm kg-1. Also, the hybridoma death rate increased with increasing pCO2, with 31- and 64-fold increases at 250 mm Hg pCO2 for 401 and 469 mOsm kg- 1, respectively. The specific glucose consumption and lactate production rates were 40–50% lower at 140 mm Hg pCO2. However, there was little further inhibition of glycolysis at higher pCO2. The specific antibody production rate was not significantly affected by pCO2 or osmolality within the range tested. Hybridomas were also exposed to elevated pCO2 in continuous culture. The viable cell density decreased by 25–40% at 140 mm Hg. In contrast to the well-plate cultures, the death rate was lower at the new steady state at 140 mm Hg. This was probably due to higher residual nutrient and lower byproduct levels at the lower cell density (at the same dilution rate), and was associated with increased cell-specific glucose and oxygen uptake. Thus, the apparent effects of pCO2 may vary with the culture system. VMdZ and RK contributed equally to the results in this article. This revised version was published online in August 2006 with corrections to the Cover Date.     

Effects of ammonia on carbon metabolism in photosynthesizing isolated mesophyll cells from Papaver somniferum L.

Addition of ammonia to a suspension of photosynthesizing isolated mesophyll cells from P. somniferum quantitatively alters the pattern of carbon metabolism by increasing rates of certain key ratelimiting steps leading to amino-acid synthesis and by decreasing rates of rate-limiting steps in alternative biosynthetic pathways. Of particular importance is the stimulation of reactions mediated by pyruvate kinase and phosphoenolpyruvate carboxylase. The increased rates of these two reactions, which result in an increased flow of carbon into the tricarboxylic-acid cycle, correlate with a rapid rise in glutamine (via glutamine synthetase) which draws carbon off the tricarboxylic-acid cycle as -ketoglutarate. Increased flux of carbon in this direction appears to come mainly at the expense of sucrose synthesis. The net effect of addition of ammonia to mesophyll cells is thus a redistribution of newly fixed carbon away from carbohydrates and into amino acids.     

Collagen synthesis in normal BHK cells and temperature-sensitive chemically transformed BHK cells.

Collagen synthesis in normal BHK 21/cl 13 and chemically transformed temperature sensitive BHK 21/cl 13 cells (Me2N4) was assessed by examination of hydroxyproline formation and collagenase-susceptible protein. The Me2N4 cells lost their ability to synthesize collagen at both permissive and nonpermissive temperatures for transformation. These conclusions were confirmed by polyacrylamide-gel eletrophoresis and CM-cellulose chromatography. Prolyl hydroxylase activity was present in both normal and transformed cells even when no collagen could be demonstrated. The production of noncollagen protein, although decreased in the transformed cell, did not change as drastically as the collagen synthesis.