Magnetic and interface properties of Fe(0.82)Ni(0.18)/Co(001) superlattices.

The thickness dependence of the Fe magnetic hyperfine field and the interfacial intermixing of Fe(0.82)Ni(0.18)/Co superlattices, with the same thickness for FeNi and Co layers, have been investigated. A local concentration model using the magnetic hyperfine field values from the [Fe(0.82)Ni(0.18)](1 - x)Co(x) alloys has been used to interpret the field distribution in the superlattices and the Co concentration profiles over the superlattices. A relationship between the Fe magnetic hyperfine field and the Fe magnetic moment has been determined for the unordered [Fe(0.82)Ni(0.18)](1 - x)Co(x) and Fe(1 - x)Co(x) alloys. The magnetic hyperfine fields have been explained using two Fermi contact terms: (i) the core electron term proportional to the Fe magnetic moment with a proportionality constant of - 13 T/µ(B) and (ii) a valence electron term linearly dependent on the Co concentration. The direction of the magnetic moments is found to be in the sample plane except for the 1/1 superlattice, where an angle of about 45° is found.

Local magnetic effects of interface alloying in Fe/Co superlattices.

Effects of interface alloying and the thickness dependence of magnetic properties of Fe/Co(001) multilayers have been investigated. The thicknesses of the Fe layers have been varied between two and 14 monolayers while the Co layers have been held constant at 7 ML. From conversion electron Mössbauer spectroscopy (CEMS) measurements and electronic structure calculations it is found that the magnitude of the Fe magnetic hyperfine field is larger close to the interface and smaller in the middle of thick (≥9 ML) Fe layers. For a thinner Fe layer (≤5 ML) the largest field is found in the centre of the Fe layer. By modelling the effects of interface alloying from earlier data for bulk Fe-Co alloys, and comparing with the experimental results, the degree of interface alloying is estimated to be 2-3 ML at each interface.

Cell cycle progression in serum-free cultures of Sf9 insect cells: modulation by conditioned medium factors and implications for proliferation and productivity.

Cell cycle progression was studied in serum-free batch cultures of Spodoptera frugiperda (Sf9) insect cells, and the implications for proliferation and productivity were investigated. Cell cycle dynamics in KBM10 serum-free medium was characterized by an accumulation of 50-70% of the cells in the G(2)/M phase of the cell cycle during the first 24 h after inoculation. Following the cell cycle arrest, the cell population was redistributed into G(1) and in particular into the S phase. Maximum rate of proliferation (micro(N, max)) was reached 24-48 h after the release from cell cycle arrest, coinciding with a minimum distribution of cells in the G(2)/M phase. The following declining micro(N) could be explained by a slow increase in the G(2)/M cell population. However, at approximately 100 h, an abrupt increase in the amount of G(2)/M cells occurred. This switch occurred at about the same time point and cell density, irrespective of medium composition and maximum cell density. An octaploid population evolved from G(2)/M arrested cells, showing the occurrence of endoreplication in this cell line. In addition, conditioned medium factor(s) were found to increase micro(N,max), decrease the time to reach micro(N,max), and decrease the synchronization of cells in G(2)/M during the lag and growth phase. A conditioned medium factor appears to be a small peptide. On basis of these results we suggest that the observed cell cycle dynamics is the result of autoregulatory events occurring at key points during the course of a culture, and that entry into mitosis is the target for regulation. Infecting the Sf9 cells with recombinant baculovirus resulted in a linear increase in volumetric productivity of beta-galactosidase up to 68-75 h of culture. Beyond this point almost no product was formed. Medium renewal at the time of infection could only partly restore the lost hypertrophy and product yield of cultures infected after the transition point. The critical time of infection correlated to the time when the mean population cell volume had attained a minimum, and this occurred 24 h before the switch into the G(2)/M phase. We suggest that the cell density dependent decrease in productivity ultimately depends on the autoregulatory events leading to G(2)/M cell cycle arrest.

[Treatment of depression and cost efficiency. The cost of a tablet is a poor indicator seen from a socioeconomic perspective]. / Depressionsbehandling och kostnadseffektivitet. Priset per tablett dålig indikator i ett samhällsekonomiskt perspektiv.

Direct costs for treating depression, i.e. the cost of out-patient and in-patient care together with drug costs, have increased by 55 per cent during the period 1987-1997 in Sweden. Drugs incurred the greatest increase, whereas the cost of in-patient care has decreased. Indirect costs, i.e. sick leave, morbidity and premature mortality due to depression, have also increased during this period. Cost-effectiveness calculations comparing mirtazapine with amitriptyline show that it is less expensive to initiate treatment with mirtazapine, both when direct costs are compared and when indirect costs are included. In a comparison between mirtazapine and fluoxetine, initial treatment with fluoxetine is less expensive with respect to direct cost, but these two alternatives are equivalent when indirect costs are taken into consideration. The price of drug is a poor criterion of resource expenditures and of rational pharmacological therapy in the treatment of depression.

Determination of NADH-dependent glutamate synthase (GOGAT) in Spodoptera frugiperda (Sf9) insect cells by a selective 1H/15N NMR in vitro assay.

This is the second of two papers [Drews, M., Doverskog, M., Ohman, L., Chapman, B.E., Jacobsson, U., Kuchel, P.W., Häggström, L., 2000. Pathways of glutamine metabolism in Spodoptera frugiperda (Sf9) insect cells: evidence for the presence of the nitrogen assimilation system, and a metabolic switch by 1H/15N NMR. J. Biotechnol. 78, 23-37]. where the general goal has been to determine and characterise the glutamine metabolism in Sf9 cells. The presence of glutamate synthase (GOGAT) activity was investigated in cell-free extracts of S. frugiperda (Sf9) insect cells by modified 1H/15N spin-echo and gradient enhanced multiple quantum coherence NMR spectroscopy techniques. Cell-free extracts were prepared from cells cultured in a serum-free medium. The assay conditions were based on conventional spectrophotometric and chromatographic methods. NMR data showed that nitrogen from [5-15N] glutamine was selectively incorporated into 2-oxoglutarate forming [2-15N] glutamate with a specific activity of 4.15 +/- 0.21 nmol [2-15N] glutamate min -1 (mg total protein)-1 in the cell-free extracts. The enzyme activity was exclusively dependent on NADH as coenzyme and was completely inhibited by 1 mM azaserine. From the results obtained, we conclude that Sf9 cells possess NADH-GOGAT activity. Furthermore, the high specificity of the NMR method enables distinction of competing reactions from glutaminase and glutamate dehydrogenase.

Pathways of glutamine metabolism in Spodoptera frugiperda (Sf9) insect cells: evidence for the presence of the nitrogen assimilation system, and a metabolic switch by 1H/15N NMR.

1H/15N and 13C NMR were used to investigate metabolism in Spodoptera frugiperda (Sf9) cells. Labelled substrates ([2-15N]glutamine, [5-15N]glutamine, [2-15N]glutamate, 15NH4Cl, [2-15N]alanine, and [1-13C]glucose) were added to batch cultures and the concentration of labelled excreted metabolites (alanine, NH4+, glutamine, glycerol, and lactate) were quantified. Cultures with excess glucose and glutamine produce alanine as the main metabolic by-product while no ammonium ions are released. 1H/15N NMR data showed that both the amide and amine-nitrogen of glutamine was incorporated into alanine in these cultures. The amide-nitrogen of glutamine was not transferred to the amine-position in glutamate (for further transamination to alanine) via free NH4+ but directly via an azaserine inhibitable amido-transfer reaction. In glutamine-free media 15NH4+ was consumed and incorporated into alanine. 15NH4+ was also incorporated into the amide-position of glutamine synthesised by the cells. These data suggest that the nitrogen assimilation system, glutamine synthetase/glutamate synthase (NADH-GOGAT), is active in glutamine-deprived cells. In cultures devoid of glucose, ammonium is the main metabolic by-product while no alanine is formed. The ammonium ions stem both from the amide and amine-nitrogen of glutamine, most likely via glutaminase and glutamate dehydrogenase. 13C NMR revealed that the [1-13C] label from glucose appeared in glycerol, alanine, lactate, and in extracellular glutamine. Labelling data also showed that intermediates of the tricarboxylic acid cycle were recycled to glycolysis and that carbon sources, other than glucose-derived acetylCoA, entered the cycle. Furthermore, Sf9 cell cultures excreted significant amounts glycerol (1.9-3.2 mM) and ethanol (6 mM), thus highlighting the importance of sinks for reducing equivalents in maintaining the cytosolic redox balance.

Constitutive secretion of an endogenous insulin-like peptide binding protein with high affinity for insulin in Spodoptera frugiperda (Sf9) cell cultures.

Serum-free medium from batch cultures of Sf9 insect cells was examined for the occurrence of proteins related to the insulin-like growth factor family. We found that the Sf9 cell line constitutively produced and secreted a soluble protein with a MW of 27 kDa that exerted specific binding to human insulin-like growth factor-I (IGF-I) and -II. Moreover, the secreted protein bound human insulin and human proinsulin with higher affinity than IGF-I and -II. The order of affinity to the insulin peptides, determined by competitive inhibition of ligand binding, was: insulin > proinsulin > IGF-I >> IGF-II. The dissociation constant (k(d)) for IGF-II was 28.5 +/- 1.7 nM and for insulin 7.2 +/- 1.3 nM, as determined by Scatchard plot analysis. The results suggest that the Sf9 cells produce an insulin binding protein similar to the human insulin-like growth factor binding protein-related protein 1 (IGFBP-rP1).

Effects of NH4+ and K+ on the energy metabolism in Sp2/0-Ag14 myeloma cells.

Potassium ions decrease the transport rate of ammonium ions into myeloma and hybridoma cells, one effect of the involved transport processes being an increased energy demand (Martinelle and Häggström, 1993; Martinelle et al., 1998b). Therefore, the effects of K+ and NH4+ on the energy metabolism of the murine myeloma cell line, Sp2/0-Ag14, were investigated. Addition of NH4Cl (10 mM) increased the metabolism via the alanine transaminase (alaTA) pathway, without increasing the consumption of glutamine. As judged by the alanine production, the energy formation from glutamine increased by 155%. The presence of elevated concentrations of KCl (10 mM) was positive, resulting in a decreased uptake of glutamine (45%), and an even larger suppression of ammonium ion formation (70%), while the same throughput via the alaTA pathway (and energy production from glutamine) was retained as in the control culture. However, the simultaneous presence of 10 mM K+ and 10 mM NH4+ was more inhibitory than NH4Cl alone; an effect that could not be ascribed to increased osmolarity. Although the culture with both K+ and NH4+ consumed 60% more glutamine than the culture with NH4+ alone, the energy generation from glutamine could not be increased further, due to the suppression of the glutamate dehydrogenase pathway. Furthermore, the data highlighted the importance of evaluating the metabolism via different energy yielding pathways, rather than solely considering the glutamine consumption for estimating energy formation from glutamine.

Cystine/cysteine metabolism in cultured Sf9 cells: influence of cell physiology on biosynthesis, amino acid uptake and growth.

Spodoptera frugiperda (Sf9) insect cells proliferate in a cystine-free medium, with the same growth rate, reaching the same final cell density, as in a cystine-containing medium, provided that the inoculum is taken from a pre-culture sufficiently early, at 47-53 h. With an inoculum from a 103 h culture an extended lag phase accompanied by cell death was observed during the first 50 h of cystine-free culture, even though the culture had been adapted to cystine-free conditions for 10 passages. Cystine-free cultures seeded with a 103 h inoculum had lower growth rates and reached lower final cell densities than corresponding cystine-supplied cultures. Cysteine biosynthesis occurs from methionine via the ß-cystathionine pathway. More methionine was consumed by the cells in cystine-free media, and cystathionine was secreted when methionine and cystine were supplied in excess. The data suggest that cysteine biosynthesis is up-regulated in proliferating cells but down-regulated when the cells enter the stationary phase.In cultures supplied with cystine (10-100 mg 1(-1)), the specific uptake rate and total consumption of cystine, as well as the uptake of glutamate, glutamine and glucose increased with increasing cystine concentrations. These results are interpreted in view of system x (c) (-) , a concentration dependent amino acid transporter. Similarly, the consumption of amino acids transported by system L (ile, leu, val, tyr) was enhanced in cystine-containing cultures, as compared to cystine-free cultures. Uptake of cystine, methionine and system L amino acids ceases abruptly in all cultures, even before growth ceased. The specific growth rate starts to decline early during the growth phase, but this growth behaviour could not be correlated to the depletion of nutrients. We therefore propose that the observed growth pattern is a result of (auto)regulatory events that control both proliferation and metabolism.

Elevated glutamate dehydrogenase flux in glucose-deprived hybridoma and myeloma cells: evidence from 1H/15N NMR.

The glutamine metabolism was studied in glucose-starved and glucose-sufficient hybridoma and Sp2/0-Ag14 myeloma cells. Glucose starvation was attained by cultivating the hybridoma cells with fructose instead of glucose, and the myeloma cells with a low initial glucose concentration which was rapidly exhausted. Glutamine used in the experiments was labeled with 15N, either in the amine or in the amide position. The fate of the label was monitored by 1H/15N NMR analysis of released 15NH+4 and 15N-alanine. Thus, NH+4 formed via glutaminase (GLNase) could be distinguished from NH+4 formed via glutamate dehydrogenase (GDH). In the glucose-sufficient cells a small but measurable amount of 15NH+4 released by GDH could be detected in both cell lines (0.75 and 0.31 micromole/10(6) cells for hybridoma and myeloma cells, respectively). The uptake of glutamine and the total production of NH+4 was significantly increased in both fructose-grown hybridoma and glucose-starved myeloma cells, as compared to the glucose-sufficient cells. The increased NH+4 production was due to an increased throughput via GLNase (1.6 -1.9-fold in the hybridoma, and 2.7-fold in the myeloma cell line) and an even further increased metabolism via GDH (4.8-7.9-fold in the hybridoma cells, and 3.1-fold in the myeloma cells). The data indicate that both GLNase and GDH are down-regulated when glucose is in excess, but up-regulated in glucose-starved cells. It was calculated that the maximum potential ATP production from glutamine could increase by 35-40 % in the fructose-grown hybridoma cells, mainly due to the increased metabolism via GDH.

Physiology of cultured animal cells.

The physiology of cultured animal cells, in particular hybridoma, myeloma and insect cells, with respect to growth and proliferation, amino acid metabolism, energy metabolism and cellular responses to environmental stress is discussed in this paper. The rate of proliferation of hybridoma cells in serum-containing media is limited by growth factors at a surprisingly early stage of growth. To maintain exponential growth in a batch culture, it is necessary to stimulate cell proliferation with repeated additions of serum or pure growth factor. It is further suggested that proliferation of Spodoptera frugiperda (Sf9 insect cells), a normal cell line able to grow in a serum-free medium without any added growth factors, is regulated by autocrine growth factors and possibly by other regulatory mechanisms, as Sf9 cells secrete a growth factor (IGF-I) and the medium still appears nutritionally sufficient at the time of cessation of growth. The uptake and metabolism of amino acids is one of the determinants of growth and production. Wasteful overproduction of amino acids in myeloma and hybridoma cells is a result of excess glutamine, and can be avoided by glutamine limitation. Synthesis of amino acids may be conditional, as in Sf9 cells which synthesise glutamine provided that ammonium is supplied to the medium; and cysteine (from methionine) provided that a sufficiently young inoculum is used. Uptake of amino acids in Sf9 cells appears regulated in relation to the proliferative status as there is a distinct cessation of uptake even before growth ceases. The energy metabolism in myeloma, hybridoma and insect cells is a typically substrate-concentration-dependent overflow metabolism. Substrate limitation (glucose and glutamine) decreases by-product formation and increases metabolic efficiency in all these cell lines. However, glutamine limitation, as used in fed-batch cultures (or chemostat cultures) provokes cell death (in parallel to growth) in hybridoma cells in the concentration range below 0.05 mM.

Metabolic engineering of animal cells.

Substrate-limited fed-batch cultures were used to study growth and overflow metabolism in hybridoma and insect cells. In hybridoma cells a glucose-limited fed-batch culture decreased lactate formation but increased glutamine consumption and ammonium formation. Glutamine limitation decreased ammonium and alanine formation but did not enhance glucose consumption. Instead lactate formation was reduced, indicating that glucose was used more efficiently. The formation of lactate, alanine, and ammonium was negligible in a dual substrate-limited fed-batch culture. The efficiency of the energy metabolism increased, as judged by the increase in the cellular yield coefficient for glucose of 100% and for glutamine of 150% and by the change in the metabolic ratios lac/glc, ala/gln, and NHx/gln, in the combined fed-batch culture. Insect cell metabolism was studied in Spodoptera frugiperda (Sf-9) cells. A stringent relation between glucose excess and alanine formation was found. In contrast, glucose limitation induced ammonium formation, while, at the same time, alanine formation was completely suppressed. Simultaneous glucose and glutamine limitation suppressed both alanine and ammonium formation. Alanine formation appears as wasteful as lactate formation because the growth rate of insect cells in substrate-limited cultures was the same as in batch cultures with substrate excess. In batch and fed-batch cultures of both cell lines, mu reaches it maximum early during growth and decreases thereafter so that no exponential growth occurs. The growth rate limiting factor for hybridoma cells was found to be a component of serum, because intermittent serum additions to batch cultures resulted in a high and constant growth rate. Insulin was identified as the main cause, inasmuch as intermittent insulin additions gave the same result as serum.

Ammonium ion transport-a cause of cell death.

Ammonium can be transported into the cell by ion pumps in the cytoplasmic membrane. Ammonia then diffuse out through the cell membrane. A futile cycle is created that results in cytoplasmic acidification and extracellular alkalinisation. Ammonium transport can be quantified by measuring the extracellular pH changes occurring in a cell suspension (in PBS) after addition of ammonium. By using this technique, in combination with specific inhibitors of various ion pumps, it was shown that ammonium ions are transported across the cytoplasmic membrane by the Na(+)K(+)2Cl(-)-cotransporter in both hybridoma and myeloma cells. Further, the Na(+)/H(+) exchanger, which regulates intracellular pH by pumping out protons, was shown to be active during ammonium exposure. The viability of hybridoma cells suspended in PBS and exposed to NH (inf4) (sup+) for only 90 min, was reduced by 11% (50% necrosis and 50% apoptosis). A control cell suspension did not loose viability during this time. Turning off the activity of the Na(+)/H(+) exchanger (by amiloride) during ammonium exposure decreased viability further, while inhibiting transport itself (by bumetanide) restored viability to the same level as for the control experiment with bumetanide alone. These results show that one effect of ammonia/ammonium on cell physiology is specifically related to the inward transport of ammonium ions by membrane bound ion pumps.

Induction of a metabolic switch in insect cells by substrate-limited fed batch cultures.

Insect cell metabolism was studied in substrate-limited fed batch cultures of Spodoptera frugiperda (Sf-9) cells. Results from a glucose-limited culture, a glutamine-limited culture, a culture limited in both glucose and glutamine, and a batch culture were compared. A stringent relation between glucose excess and alanine formation was found. In contrast, glucose limitation induced ammonium formation, while, at the same time, alanine formation was completely suppressed. Simultaneous glucose and glucosamine limitation suppressed both alanine and ammonium formation. Although the metabolism was influenced by substrate limitation, the specific growth rate was similar in all cultures. Alanine formation must involve incorporation of free ammonium, if ammonium formation is mediated by glutaminase and glutamate dehydrogenase, as our data suggest. On the basis of the results, two possible pathways for the formation of alanine in the intermediary metabolism are suggested. The cellular yield on glucose was increased 6.6 times during glucose limitation, independently of the cellular yield on glutamine, which was increased 50-100 times during glutamine limitation. The results indicate that alanine overflow metabolism is energetically wasteful and that glutamine is a dispensable amino acid for cultured Sf-9 cells. Preliminary data confirm that glutamine can be synthesized by the cells themselves in amounts sufficient to support growth.

Specific growth rate as a parameter for tracing growth-limiting substances in animal cell cultures.

The specific growth rate (mu) reaches its maximum very early during culture (at 20 h), but declines again thereafter so that no exponential growth phase occurs in batch cultures of hybridoma cells. This growth rate limitation depends neither on exhaustion of any of the macro-nutrients, nor on inhibition by metabolic byproducts (Ljunggren and Häggström, 1994). Intermittent additions of serum, after 20 and 40 h of culture, resulted in exponential growth throughout the growth phase. Insulin was found to be the main component responsible for the growth rate increasing effect. Intermittent additions of serum or insulin to a dual substrate (glucose and glutamine) limited fed batch culture increased the growth rate also here, and the results indicate the existence of a minimum growth rate (about 0.02 h-1) at a threshold glutamine level (0.005 mM). Serum and insulin additions markedly enhanced the glucose consumption and lactate formation rates, a metabolic effect that was not coupled to the increase in mu. The reduced concentrations of glucose and glutamine in substrate limited fed batch cultures suppressed substrate consumption rates and byproduct formation (lactate, ammonium, alanine, other amino acids) even in the serum and insulin stimulated cultures and rendered the energy metabolism much more efficient than in batch culture. Further, the serum and insulin stimulated cells growing in substrate limited fed batch culture produced almost 4-times more antibodies, from the same amount of nutrients as supplied to the batch grown cells.

Influence of substrate oscillations on acetate formation and growth yield in Escherichia coli glucose limited fed-batch cultivations.

A Large bioreactor is an inhomogenous system with concentration gradients which depend on the fluid dynamics and the mass transfer of the reactor, the feeding strategy, the saturation constant, and the cell density. The responses of Escherichia coli cells to short-term oscillations of the carbon/energy substrate in glucose limited fed-batch cultivations were studied in a two-compartment reactor system consisting of a stirred tank reactor (STR) and an aerated plug flow reactor (PFR) as a recycle loop. Short-term glucose excess or starvation in the PFR was simulated by feeding of glucose to the PFR or to the STR alternatively. The cellular response to repeated short-term glucose excess was a transient increase of glucose consumption and acetate formation. But, there was no accumulation of acetate in the culture, because it was consumed in the STR part where the glucose concentration was growth limiting. However, acetate accumulated during the cultivation if the oxygen supply in the PFR was insufficient, causing higher acetate formation. The biomass yield was then negatively influenced, which was also the case if the PFR was used to simulate a glucose starvation zone. The results suggest that short-term heterogeneities influence the cellular physiology and growth, and can be of major importance for the process performance. (c) 1995 John Wiley & Sons, Inc.

Catabolic control of hybridoma cells by glucose and glutamine limited fed batch cultures.

Substrate limited fed batch cultures were used to study growth and overflow metabolism in hybridoma cells. A glucose limited fed batch, a glutamine limited fed batch, and a combined glucose and glutamine limited red batch culture were compared with batch cultures. In all cultures mu reaches its maximum early during growth and decreases thereafter so that no exponential growth and decreases thereafter so that no exponential growth rate limiting, although the glutamine concentration (>0.085mM) was lower than reported K(s) vales and glucose was below 0.9mM; but some other nutrients (s) was the cause as verified by simulations. Slightly more cells and antibodies were produced in the combined fed batch compared with the batch culture. The specific rates for consumption of glucose and glutamine were dramatically influenced in fed batch cultures resulting in major metabolic changes. Glucose limitation decreased lactate formation, but increased glutamine consumption and ammonium formation. Glutamine limitation decreased ammonium and alanine formation of lactate, alanine, and ammonium was negligible in the dual-substrate limited fed batch culture. The efficiency of the energy metabolism increased, as judged by the increase in the cellular yield coefficient for glucose by 100% and for glutamine by 150% and by the change in the metabolic ratios lac/glc, ala/ln, and NH(x)/ln, in the combined fed culture. The data indicate that a larger proportion of consumed glutamine enters the TCA cycle through the glutamate dehydrogenase pathway, which releases more energy from glutamine than the transamination pathway. We suggest that the main reasons for these changes are decreased uptake rates of glucose and glutamine, which in turn lead to a reduction of the pyruvate pool and a restriction of the flux through glutaminase and lactate dehydrogenase. There appears to be potential for further cell growth in the dual-substrate-limited fed batch culture as judged by a comparison of mu in the different cultures. (c) 1994 John Wiley & Sons, Inc.

Modeling of high cell density fed batch cultivation.

Escherichia coli was grown in carbon- and energy source-limited fed batch cultures to study the effect of osmotic stress and different feed rates on the growth kinetics. An unstructured model based on the linear equation for substrate consumption provided an adequate description of the bacterial growth during the first phase of biomass production (20 h), except for cultures exposed to osmotic stress by the addition of 0.5 M NaCl. The addition of salt to the culture media had a large effect on the energetics, that could not simply be described in terms of an increased maintenance requirement. In the later phase of growth, an extensive decline in viability for all cultures was observed. Coincidentally, the specific sugar uptake rate approached a lower limit. It is concluded that the total obtainable biomass in a fed batch culture is strongly affected by the magnitudes of the substrate feed rate and the ionic strength of the culture medium.

Complementary Mössbauer and EPR studies of iron(III) in diferric human serum transferrin with oxalate or bicarbonate as synergistic anions.

The spectral and magnetic properties of iron(III) bound in the metal binding sites of human serum transferrin with oxalate or bicarbonate as synergistic anions has been studied with Mössbauer spectroscopy and electron paramagnetic resonance (EPR). The Mössbauer spectra of the iron(III) in diferric transferrin with oxalate have been described using a spin Hamiltonian with the values of the zero field splitting parameter, D = 0.55 +/- 0.05 cm-1, and the rhombicity of the crystal field, E/D = 0.045 +/- 0.005. The EPR spectrum can be described with D = 0.58 cm-1 and E/D = 0.057, using a g-strain model for the lineshape that is based on a Gaussian distribution of D and E/D with Gaussian widths sigma(D) = 0.35 cm-1 and sigma(E/D) = 0.013, respectively. The rhombicity of the iron surroundings for the transferrin-oxalate complex is almost one order of magnitude smaller than for the bicarbonate complex and the zero field splitting parameter is twice as large in the oxalate as in the bicarbonate complex. We conclude that the crystal field symmetry of the iron site is almost tetragonal in the oxalate complex but rhombohedral in the bicarbonate complex, reflecting the different geometries of the oxalate and bicarbonate coordination. The isomer shift delta = 0.56 +/- 0.01 mm s-1 and the quadrupole splitting delta EQ = 0.2 +/- 0.1 mm s-1, on the other hand, are very close to the values found for the bicarbonate complex. No differences between the Mössbauer spectra of the two iron(III) ions in diferric transferrin with oxalate were found. The homogeneity of the diferric transferrin samples was controlled by capillary zone electrophoresis in the presence of urea.

Mechanisms of ammonia and ammonium ion toxicity in animal cells: transport across cell membranes.

A model for transport of ammonia and ammonium ions across cell membranes is presented. The model suggests that ammonium ions compete with potassium ions for inward transport, over the cytoplasmic membrane, via potassium transport proteins like the Na+/K(+)-ATPase and the Na+K+2Cl(-)-cotransporter. It also explains the difference between the ammonia/ammonium that is added to the cells and which is formed by the cells during metabolism of amino acids, especially glutamine and glutamate. The ammonium transport and subsequent events lead to predictable intracellular and extracellular pH (pHe) changes. Experiments which verified the model and the predicted consequences were performed by measurements of the pHe in concentrated cell suspensions. Addition of ammonium ions caused a time-dependent pHe increase which was inhibited by potassium ions. The test system is not per se specific for transport measurements but the effect of potassium ions on the pHe strongly favors our suggested model. Simple diffusion of ammonium ions would not be counteracted by potassium ions. The results show that ammonium ion transport in the murine myeloma cell line (Sp2/0-Ag14) used is inhibited by an excess of potassium ions. Results from experiments with specific inhibitors of suggested transport proteins were not conclusive. It is postulated that one important toxic effect of ammonia/ammonium is an increased demand for maintenance energy, caused by the need to maintain ion gradients over the cytoplasmic membrane. The results also suggest that potassium ions can be used to detoxify ammonia/ammonium in animal cell cultivations.