An immobilized cell reactor with simultaneous product separation. II. Experimental reactor performance

The simultaneous separation of volatile fermentation products from product-inhibited fermentations can greatly increase the productivity of a bioreactor by reducing the product concentration in the bioreactor, as well as concentrating the product in an output stream free of cells, substrate, or other feed impurities. The Immobilized Cell Reactor-Separator (ICRS) consists of two column reactors: a cocurrent gas-liquid "enricher" followed by a countercurrent "stripper" The columns are four-phase tubular reactors consisting of (1) an inert gas phase, (2) the liquid fermentation broth, (3) the solid column internal packing, and (4) the immobilized biological catalyst or cells. The application of the ICRS to the ethanol-from-whey-lactose fermentation system has been investigated. Operation in the liquid continuous or bubble flow regime allows a high liquid holdup in the reactor and consequent long and controllable liquid residence time but results in a high gas phase pressure drop over the length of the reactor and low gas flow rates. Operation in the gas continuous regime gives high gas flow rates and low pressure drop but also results in short liquid residence time and incomplete column wetting at low liquid loading rates using conventional gas-liquid column packings. Using cells absorbed to conventional ceramic column packing (0.25-in. Intalox saddles), it was found that a good reaction could be obtained in the liquid continuous mode, but little separation, while in the gas continuous mode there was little reaction but good separation. Using cells sorbed to an absorbant matrix allowed operation in the gas continuous regime with a liquid holdup of up to 30% of the total reactor volume. Good reaction rates and product separation were obtained using this matrix. High reaction rates were obtained due to high density cell loading in the reactor. A dry cell density of up to 92 g/L reactor was obtained in the enricher. The enricher ethanol productivity ranged from 50 to 160 g/L h while the stripper productivity varied from 0 to 32 g/L h at different feed rates and concentrations. A separation efficiency of as high as 98% was obtained from the system.     

Enhanced degradation of caffeine and caffeine demethylase production by <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. in bioreactors under fed-batch mode

The growth of Pseudomonas sp. was studied in fed-batch process with an aim to improve the caffeine degradation rate and caffeine demethylase activity. The effects of varying initial caffeine concentrations in the batch mode, increase in the number of feeds, varying feed flow rates, and added nutrients to the feed on the fed-batch process were investigated. A maximum caffeine degradation rate of 0.82 g/L h and maximum caffeine demethylase activity of 2.6 U/mg were achieved using manual intermittent pulse feeds of caffeine with substrate concentration as feedback parameter for the fed batch started with an initial caffeine concentration of 3 g/L. A slight increase in the caffeine degradation rate (0.85 g/L h) and caffeine demethylase activity (3.4 U/mg) was observed when the additional nutrients were added along with caffeine in the feed. This is the first report showing complete degradation of large magnitudes of caffeine amounting to 237 g in 75 h. These results show that the fed-batch conditions achieved in this study using Pseudomonas sp. facilitate the development of a sustainable bioprocess to degrade the high concentrations of caffeine in industrial effluents.     

Biodegradation of Carbofuran phenol by free and immobilized cells of <Emphasis Type="Italic">Klebsiella pneumoniae</Emphasis> ATCC13883T

The Klebsiella sp. strain ATCC13883T capable of degrading carbofuran phenol (2,3-dihydro-2,2-dimethylbenzofuran-7-ol) has been separated from the soil by enrichment culture technique and immobilized in various, namely polyurethane foam (PUF), polyacrylamide, alginate, agar and alginate-bentonite clay-powdered activated charcoal (PAC). The degradation rates of 20 and 30 mM carbofuran phenol by free and immobilized cells in batch and semi-continuous shaken cultures were compared. The PUF-immobilized cells achieved higher degradation rates in a shorter time than freely suspended cells and the cells immobilized in polyacrylamide, alginate and agar. The PUF- and alginate-bentonite clay-PAC-immobilized cells could be reused for more than 36 cycles, polyacrylamide-entrapped cells for 20 cycles and alginate-bentonite-PAC 28 cycles, without losing any degradation capacity and showed better tolerance to pH, temperature and concentration changes than free cells. These results showed that cells immobilized in modified alginate-bentonite-PAC immobilizers tolerated and completely degraded carbofuran phenol at initial concentrations of 20 and 30 mM and also higher. Such a bacterial strain could be used for bioremediation of environments contaminated with phenolic compounds.     

Adaptive control at low glucose concentration of HEK-293 cell serum-free cultures.

Fed-batch cultures were implemented to study the metabolism of HEK-293 cells. Glucose, measured every 30 min by a FIA biosensor system, was maintained at 1 mM throughout the culture using an adaptive nonlinear controller based on minimal process modeling. The controller performed satisfactorily at both low and high cell concentrations without the need for retuning between different culture phases. Overall, lactate production was significantly reduced by maintaining a low glucose concentration, thus decreasing the rate of glycolysis. The rates of glucose and glutamine uptake as well as the lactate and ammonia production were compared to those obtained in batch mode with an initial glucose concentration of 21 mM. Basically, three phases were observed in both culture modes. The metabolic shift from the first to the second phase was characterized by a significant reduction in glucose consumption and lactate production while maximum growth rate was maintained. The specific respiration rate appeared unchanged during the first two phases, suggesting that no change occurred in the oxidative pathway capacity. In the third phase, cell growth became slower very likely due to glutamine limitation.     

Enhanced degradation of naphthalene by immobilization of Pseudomonas sp. strain NGK1 in polyurethane foam

A Pseudomonas sp. strain NGKI (NCIM 5120) capable of degrading naphthalene was immobilized in polyurethane foam. The naphthalene-degrading activity of the freely suspended cells was compared with that of immobilized cells in batches in shaken culture and in a continuous culture system in a packed-bed reactor. Increasing concentrations of naphthalene were better tolerated and more quickly degraded by immobilized cell cultures than by free cells. An initial naphthalene concentration of 25 mM was completely degraded by freely suspended cells (4 x 10(10) cfu ml(-1)) and polyurethane-foam-immobilized cells (0.8-1 x 10(12) cfu g(-1) foam cubes) after 4 days and 2 days of incubation, respectively. Free cells degraded a maximum of 30 mM naphthalene after 4 days of incubation with 50 mM naphthalene, and no further degradation was observed even after 15 days of incubation, whereas foam-immobilized cells brought about the complete degradation of 50 mM initial naphthalene after 6 days of incubation. Furthermore, with 25 mM naphthalene, the polyurethane-foam-immobilized cells were re-used 45 times over a period of 90 days without losing naphthalene-degrading activity. By contrast, with the same amount of naphthalene, alginate-, agar-, and polyacrylamide-entrapped cells could be reused for 18, 12, and 23 times over a period of 44, 28, and 50 days, respectively. During continuous degradation in a packed-bed reactor, foam-immobilized cells degraded 80 mM naphthalene at a rate of 150 ml(-1) h(-1). With the same flow rate and 40 mM naphthalene, this system operated efficiently and continuously for about 120 days, whereas the packed-bed reactor with alginate-, agar-, and polyacrylamide-entrapped cells could be operated only for 45, 40, and 60 days respectively. Thus, more efficient degradation of naphthalene could be achieved by immobilizing cells of Pseudomonas sp. strain NGK1 in polyurethane foam, rather than in the other matrices tested.     

The influence of NaCl on the degradation rate of dichloromethane byHyphomicrobium sp.

The degradation of dichloromethane by the pure strainHyphomicrobium GJ21 and by an enrichment culture, isolated from a continuously operating biological trickling filter system, as well as the corresponding growth rates of these organisms were investigated in several batch experiments. By fitting the experimental data to generally accepted theoretical expressions for microbial growth, the maximum growth rates were determined. The effect of NaCl was investigated at salt concentrations varying from 0 to 1000 mM. Furthermore the dichloromethane degradation was investigated separately in experiments in which a high initial biomass concentration was applied. The results show that microbial growth is strongly inhibited by increased NaCl concentrations (50% reduction of _max at 200–250 mM NaCl), while a certain degree of adaptation has taken place within an operational system eliminating dichloromethane. A critical NaCl concentration for growth of 600 mM was found for the microbial culture isolated from an operational trickling filter, while a value of 375 mM was found for the pure cultureHyphomicrobium GJ21. The substrate degradation appears to be much less susceptible to inhibition by NaCl. Even at 800 mM NaCl relatively high substrate degradation rates are still observed, although this process is again dependent on the NaCl concentration. Here the substrate elimination is due to the maintenance requirements of the microorganisms. The inhibition of the dichloromethane elimination was also investigated in a laboratory scale trickling filter. The results of these experiments confirmed those obtained in the batch experiments. At NaCl concentrations exceeding 600 mM a considerable elimination of dichloromethane was still observed for during several months of operation. These observations indicate that the inhibition of microbial growth offers a significant control parameter against excessive biomass growth in biological trickling filters for waste gas treatment.     

Infinite-cis kinetics support the carrier model for erythrocyte glucose transport

It has been claimed that the Km for infinite-cis uptake of glucose in human erythrocytes is so low that the carrier model for transport must be rejected. We redetermined this parameter for three experimental conditions and found instead that the Km values were in good agreement with the model. For each of a variety of cis glucose concentrations, cells were preequilibrated with various concentrations of glucose, and the apparent Km was determined as the intracellular concentration reducing the initial rate of net uptake by half. The dependence of the apparent Km values on the cis glucose was as predicted by the carrier model; the infinite-cis Km was determined from both this concentration dependence and the extrapolated value at infinite cis glucose. The resulting values were 15 mM for fresh blood at 0 degrees C, 39 mM for outdated blood at 0 degrees C, and 11 mM for outdated blood at 25 degrees C. Previous measurements of the Km at room temperature yielded values of 2-3 mM. These earlier studies used a time course procedure that indicated rapid changes in rates during the initial 10 s of uptake but did not directly measure such changes. We examined the uptake of 60 mM glucose at 20 degrees C into cells containing 0 and 5 mM glucose; rapid changes in rates were not observed in the first few seconds, and the time courses were more consistent with our higher Km values. Our new values, together with other initial rate measurements in the literature, support the adequacy of the carrier model to account for the kinetics of glucose transport in human erythrocytes.     

In vitro reaggregation of dissociated mouse cerebellar cells : I. Demonstration of different aggregation mechanisms

Reaggregation of mechanically dissociated mouse cerebellar cells (M cells) was compared with cells that received an additional trypsinization either before (T cells) or after (MT cells) the dissociation step. Reaggregation behaviour was followed by measuring the number and size distribution of particles with a Coulter counter. Aggregation rates which were calculated as percentage of decrease of particles could be measured reproducibly. Since the percentage of very large particles (> 100 cells) formed during aggregation varied considerably from one experiment to the next, size distribution curves of particles were used more to distinguish qualitative differences in a less quantitative way.Whereas aggregation rates and size distribution of particles with M cells were almost identical when aggregation occurred in medium of high (1.1 mM) or low (0.1 mM) Ca²⁺ concentrations, T and MT cells aggregated better at high Ca²⁺ concentration. Their aggregation rates were reduced by approx. 50% at low Ca²⁺ concentrations and larger aggregates were hardly formed under these conditions. The aggregation rates of T and MT cells showed a clear dependence on Ca²⁺ concentration, being half maximal at approx. 0.1 mM Ca²⁺.The ability of M cells to aggregate at low or high Ca²⁺ concentrations was influenced by subsequent trypsinization to produce MT cells. When the trypsin concentration was changed from 0.001 to 0.1% during this procedure the aggregation rates at high Ca²⁺ concentration were reduced to approx. 80% of the maximal value, whereas those at low Ca²⁺ concentrations were reduced to 35%. Variation of the Ca²⁺ concentration between 1.1 and 0.1 mM during the trypsinization step (0.015% trypsin) revealed no difference on the aggregation rates.We propose that M cells aggregate mainly or exclusively by a Ca²⁺-independent binding mechanism, whereas T or MT cells aggregate using a Ca²⁺-dependent one which may be functionally silent in M cells.     

Production of 3-hydroxypropionaldehyde using a two-step process with Lactobacillus reuteri

3-Hydroxypropionaldehyde (3-HPA) produced by Lactobacillus reuteri is a broad-spectrum antimicrobial substance of glycerol conversion. The aim of the present work was to optimize 3-HPA production by Lb. reuteri ATCC 53608 using a two-step process. The first step was the production of Lb. reuteri cells in optimal conditions. Cells were then harvested by centrifugation and suspended in glycerol solution, which the resting cells bioconverted to 3-HPA. The effect of biomass concentration, temperature, glycerol concentration, anaerobic/micro-aerophilic conditions, and incubation time was studied for high 3-HPA production. 3-HPA accumulation was limited by the death of cells in contact with high concentrations of 3-HPA. However, a very high 3-HPA concentration of 235±3 mM was obtained after 45 min of incubation at 30°C in 400 mM glycerol for an initial free-cell concentration of 1.6±0.3×10¹⁰ viable cells/ml. A high viability was maintained at low temperatures in the range 5–15°C, but with a slightly lower yield of 3-HPA at 5°C compared with higher temperatures, up to 37°C. Successive 1-h incubations of Lb. reuteri cells in 200 mM glycerol at 15°C to tentatively reuse the cells resulted in decreasing 3-HPA concentrations at the end of each cycle, with two successful production cycles yielding high 3-HPA concentrations of 147±1 mM and 128±2 mM.     

Kinetics of iron absorption by excised rice roots

Summary Studies on the rate of iron absorption by excised rice roots from solutions of different concentrations of FeSO₄ showed the presence of two patterns, one in the low (0.005–0.5 mM) and the other in the high (1–30 mM) concentration range. The presence of CaSO₄ or MnSO₄ at 0.5 mM enhanced Fe⁺⁺ absorption in the low concentration range, while CaSO₄ at 10 mM inhibited Fe absorption in the high concentration range in a competitive manner. Fe⁺⁺ absorption at both low and high concentrations was sensitive to metabolic inhibitors. The isotherm for Fe⁺⁺ absorption at O° exhibited an initial absorption shoulder in both low and high concentrations and was suggestive of a latent ion-transport capacity for Fe⁺⁺ in rice roots.     

Calcium-mediated regulation of the low density lipoprotein receptor and intracellular cholesterol synthesis in human epidermal keratinocytes

Unlike cells cultured under physiological Ca2+ concentrations (1-2 mM), keratinocytes cultured in media containing Ca2+ in low concentrations (less than 0.1 mM) do not stratify. The latter cells also differ with respect to several features of the regulation of cholesterol synthesis. In keratinocytes cultured in medium containing high Ca2+ concentrations (1.6 mM) and fetal calf serum, the rate of cholesterol synthesis was 20-30 times higher than in keratinocytes exposed to a low Ca2+ concentration. The rate of cholesterol synthesis did not change when high-calcium cells were deprived of extracellular sources of cholesterol but increased (8-10 fold) in deprived low-calcium cells. Furthermore, the addition of low density lipoprotein (LDL) reduced cholesterol synthesis markedly in low-calcium cells but had no effect on high-calcium cells. Finally, in keratinocytes cultured at low calcium concentrations the association and degradation of 125I-LDL was 20-30 times higher than in keratinocytes cultured under high-calcium conditions. Switching of the cells from the low-calcium to the high-calcium medium resulted in the induction of terminal differentiation within 15 hours and was accompanied by increased cholesterol and protein synthesis, increased competence of cells to form cornified envelopes, and reduced association of 125I-LDL. A gradual increase of the extracellular Ca2+ concentration was accompanied by a corresponding increase of cholesterol and protein synthesis and a decrease of the response of intracellular cholesterol synthesis to changes in the extracellular concentrations of lipoprotein. Various morphological techniques showed virtually no binding and internalization of LDL by keratinocytes cultured at the high-calcium level, whereas both were observed at the low-calcium level. Once internalized, the LDL was delivered to dense bodies representing lysosomes. It is concluded that in human epidermal keratinocytes, the expression of the LDL receptor and the endogenous synthesis of cholesterol are regulated by the conditions determined by the differentiation stage of the cells.     

Toxicity and biodegradation of formaldehyde in anaerobic methanogenic culture

Formaldehyde is present in several industrial wastewaters including petrochemical wastes. In this study, the toxicity and degradability of formaldehyde in anaerobic systems were investigated. Formaldehyde showed severe toxicity to an acetate enrichment methanogenic culture. As low as 10 mg/L (0.33 mM) of formaldehyde in the reactor completely inhibited acetate utilization. Formaldehyde, however, was degraded while acetate utilization was inhibited. Degradation of formaldehyde (Initial concentration /=60 mg/L), formaldehyde degradation was inhibited and partial degradation was possible. The initial formaldehyde to biomass ratio, S(0)/X(0), was useful to predict the degradation potential of high formaldehyde concentrations in batch systems. When S(0)/X(0) /= 0.29, formaldehyde at higher than 60 mg/L was only partially degraded. The inhibition of formaldehyde degradation in batch systems could be avoided by repeated additions of low concentrations of formaldehyde (up to 30 mg/L). Chemostats (14-day retention time) showed degradation of 74 mg/L-d (1110 mg/L) of influent formaldehyde with a removal capacity of 164 mg/g VSS-day. A spike of 30 mg/L (final concentration in the chemostat) formaldehyde to the chemostat caused only a small increase in effluent acetate concentration for 3 days. But a spike of 60 mg/L (final concentration in the chemostat) formaldehyde to the chemostat resulted in a dramatic increase in acetate concentration in the effluent. The results also showed that the acetate enrichment culture was not acclimated to formaldehyde even after 226 days. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 727-736, 1997.     

Improved Tolerance of Three Saudi Pearl Millet Cultivars (<i>Pennisetum spicatum</i>) to Salt Stress by Mycorrhiza

Seeds of three Saudi pearl millet cultivars (Pennisetum spicatum) from three regions (Madinah, Khulais and Jaizan) were inoculated with arbuscular mycorrhizal fungus Glomus mosseae obtained from the Agriculture Research Center of Giza, Egypt to enhance their salt tolerance. Five different NaCl concentrations (0, 30, 60, 90, and 120 mM) were used for treating cultivars with and without mycorrhiza. Growth rates, chlorophyll content, chlorophyll fluorescence (Fv/Fm), proline content and gas exchange were measured to determine the effect of salinity on these cultivars. The results indicated that compared to cultivars without mycorrhiza, all cultivars with mycorrhiza had enhanced growth and physiological parameters including shoot and root length, area and number of leaves, fresh and dry weights of shoots and roots, chlorophyll contents and gas exchanges at 0 and 30 mM of salinity. In addition, the measurements of the different growth rates showed higher growth performance of the cultivars from Madinah and Khulais than the cultivar from Jaizan. However, all cultivars with and without mycorrhiza showed significant reductions in growth rates, chlorophyll contents and gas exchanges at a salinity of 60 mM than those grown at 0 and 30 mM. Moreover, the values of Fv/Fm were significantly reduced in all cultivars with and without mycorrhiza grown at 60 mM than in those grown at 0 mM and 30 mM. Proline contents indicated a progressive increase with the elevation of NaCl concentration stress. The proline contents in the mycorrhiza-inoculated cultivars were significantly higher than those in the non-inoculated cultivars. On the other hand, all cultivars with and without mycorrhiza underwent senescence within four weeks of growth at salinity concentrations of 90 mM and 120 mM. Therefore, relatively low salinity must be maintained to achieve high growth rates and gas exchanges of these inoculated cultivars.     

Cellular uptake of L-lactate in mouse diaphragm.

Early uptake curves of L-lactate and of mannitol were measured in quartered, incubated mouse diaphragms. Uptake was determined at 15, 30, and 45 s for various concentrations of lactate in the external solution as well as in the presence and absence of the competitive inhibitor of lactate transport, alpha-cyano-4-hydroxycinnimate. In normal preparations, when the external lactate concentration was 10 mM or less, the ratio of lactate-to mannitol space in the tissue was 1.7. This value was nearly independent of time and of external concentration. In normal preparations, when the external lactate concentration was greater than 10 mM, the ratio of lactate-to-mannitol space rose with time. At a fixed time, however, this ratio fell with increasing lactate concentration. In the inhibited preparations, the ratio of lactate-to-mannitol space rose with time at all concentrations. When lactate concentration was greater than 5 mM, this ratio was independent of the external concentration. The results suggest that there are two modes of lactate entry into these muscle cells. Entry can occur by means of a saturable system. When external lactate concentration is low, entry rates for this process are rapid compared with diffusional rates. This system probably saturates at concentrations near 10 mM and can facilitate transport in either direction. In addition, an appreciable passive leak is present. This leak accounts for about one fourth of the membrane transfer when external lactate is low, but is equal to the carrier transfer when lactate concentration is 30 mM. A model was developed to describe the entry of a permeating solute, such as lactate, into an isolated tissue.     

Colligative and non-colligative freezing damage to thylakoid membranes

When spinach thylakoid membranes were frozen in vitro in solutions containing constant molar ratios of cryotoxic to cryoprotective solute, maintenance of functional integrity strongly depended on initial osmolarities. Optimum cryopreservation of cyclic photophosphorylation was observed when the membranes were suspended in solutions of intermediate osmolarities (approx. 50–100 mM NaCl, 75–150 mM sucrose). Both higher and lower initial osmolarities were found to result in decreased cryopreservation. In the absence of added salt, more than 100 mM sucrose were needed for full cryopreservation of the membranes. When thylakoids were frozen in solutions containing low concentrations of NaCl (2 mM), the ratio of sucrose to salt necessary to give full protection was high (up to 50). When the salt concentration was about 60 mM, ratios as low as 1.5 were sufficient for maintaining membrane integrity. This ratio increased again, as the initial NaCl concentration was increased beyond 60 mM. During freezing, proteins dissociated from the membranes, and the amount of the released proteins was correlated linearly with inactivation of photophosphorylation. The gel electrophoretic pattern of proteins released at low initial osmolarities differed from that of proteins released at high initial osmolarities. Cryopreservation was also found to depend on membrane concentration. Concentrated membrane suspensions suffered less inactivation than dilute suspensions. The protective effect of high membrane concentrations was particularly pronounced at high initial solute concentrations. It is proposed that damage at low initial osmolarities is caused predominantly by mechanical stress and by osmotic contraction/expansion. Damage at high initial osmolarities is thought to be caused mainly by solute effects. Under these conditions, both the final volume of the unfrozen solution in coexistence with ice and the membrane concentration affect membrane survival by influencing the extent of the loss of membrane components through dissociation reactions. Membrane protection by sugars is caused by colligative action under these circumstances.     

Structural and physiological effects of calcium and magnesium in Emiliania huxleyi (Lohmann) Hay and Mohler

In organisms which perform both photosynthesis and calcification, the fact that calcification proceeds faster in the light than in the dark has led to the long-established view that photosynthesis and calcification are closely coupled. It is now clear that calcification does not promote photosynthesis, but an enhancement of calcification by photosynthesis could still explain why calcification is faster in the light. To test this, the kinetics of the two processes were monitored over a wide range of calcium concentrations (0-50 mM) in the coccolithophore Emiliania huxleyi. The addition of 50 mM calcium strongly inhibited both processes, but when incubated in lower concentrations, rates of calcification increased up to 20 mM calcium whilst those of photosynthesis remained constant over the same range of calcium concentrations. So, rates of calcification are able to rise without a concomitant increase in photosynthetic rates. In addition, calcification rate and coccolith morphology responded similarly to changes in calcium concentrations; low calcification rates were associated with poor coccolith structure (undercalcification) and high calcification rates with perfectly formed coccoliths. Calcium concentration thus strongly influences calcification affecting both crystal structure and rate of calcite deposition. A similar structural analysis of coccoliths from cells grown in different magnesium concentrations showed that this ion is also essential for calcification, since strong signs of coccolith malformation and undercalcification were apparent at both low and high magnesium concentrations. In contrast with the calcium results, coccoliths were flawless only in the normal seawater concentration of 58 mM magnesium. We conclude that photosynthesis and calcification are not closely coupled and that calcification depends on a precise balance of both calcium and magnesium concentrations.     

Degradation of formaldehyde in packed-bed bioreactor by kissiris-immobilized Ralstonia eutropha

The ability of the Ralstonia eutropha cells to utilize formaldehyde (FA) as the only source of carbon and energy was studied in the kissiris-immobilized cell bioreactor (KICB) in batch-recirculation and continuous modes of operation. In batch-recirculation experiments, the test bacterium could tolerate concentrations of FA up to 1,400 mg/L at 30°C and aeration rate equal to 0.75 vvm (r _S = 7.25 mg/L/h, q S = 0.019 g_FA/g_cell/h). However, further increase of initial FA concentration resulted in degradation reaction of FA to stop at 1,600 mg/L. Results of continuous mode experiments showed that the biodegradation performance of the KICB was dependent on both feed flow rate and inlet FA concentration parameters. The optimum feed flow rate which corresponded to the highest biodegradation rate (r _S = 240.3 mg/L/h) was observed at Q = 18 mL/min when KICB did not operate under the external mass transfer limiting regime. Substrate inhibition kinetics (Edwards and Luong equations) were used to describe the experimental specific degradation rates data. According to the Luong model, the values of the maximum specific degradation rate (q _max), half-saturation coefficient (K _S), the maximum allowable FA concentration (S _m), and the shape factor (n) were 0.178 g_FA/g_cell/h, 250.9 mg/L, 1,600 mg/L, and 1.86, respectively.     

Glucose-limited chemostat culture of Chinese hamster ovary cells producing recombinant human interferon-gamma

A Chinese hamster ovary (CHO) cell line expressing recombinant human interferon-gamma (IFN-gamma) was grown under glucose limitation in a chemostate at a constant dilution rate of 0.015 h(-1) with glucose feed concentrations of 2.75 mM and 4.25 mM. The changes in cell concentration that accompanied changes in the glucose feed concentration indicated that the cells were glucose-limited. The cell yield on glucose remained constant, but there was a decline in residual glucose concentration and a reduced lactate yield from glucose in the latter stages of the culture. The consumption rates for many of the essential amino acids were increased later in the culture. The volumetric rate of interferon-gamma production was maintained throughout the course of this culture, indicating that IFN-gamma expression was stable under these conditions. However, the specific rate of IFN-gamma production was significantly lower at the higher glucose feed concentration. Under glucose limitation, the proportion of fully glycosylated IFN-gamma produced by these cells was less than that produced in the early stages of batch cultures. The proportion of fully glycosylated IFN-gamma increased during transient periods of glucose excess, suggesting that the culture environment influences the glycosylation of IFN-gamma.     

Effect of nitrite concentration and pH on most probable number enumerations of non-growing Nitrobacter spp.

Abstract Enumerations of nitrite-oxidizing bacteria in soil samples by a Most Probable Number technique, often showed relatively high cell numbers at a low nitrite concentration compared with the numbers of ammonium-oxidizing bacteria. It was hypothesized that the high numbers enumerated at low nitrite concentration would represent non-growing or organotrophically growing cells of nitrite-oxidizing species. In this paper, the sensitivity of non-growing Nitrobacter species to high nitrite concentrations as well as to low pH was examined. Different Nitrobacter species were pre-cultured at 0.5 mM nitrite. Non-growing cells differing in age were enumerated at different nitrite concentrations and pH values. The incubation period lasted for 5 months at 20°C. However, during the incubation periods of the older non-growing cells, it appeared that a period of 5 months might have been too short for reaching constant numbers. Early stationary cells of all species that were studied appeared not to be affected by high nitrite concentrations or low pH. Eight- and 18-month-old non-growing cells of Nitrobacter hamburgensis were also insensitive to 5 mM nitrite. The numbers of 8- and 18-month-old resting cells of N. vulgaris were only repressed by a combination of 5 mM nitrite and a low pH. Eight-month-old non-growing cells of N. winogradskyi were sensitive to 5 mM irrespective of pH, but 18-month-old cells only to 5 mM nitrate at low pH. The numbers of 8- and 18-month-old resting cells of N. winogradskyi serotype agilis were repressed by low pH rather than high nitrite concentration. Hence, it was concluded that the large differences in numbers of nitrite-oxidizing bacteria obtained with low and high nitrite concentrations in the incubation medium, was not likely to be due to the presence of non-growing Nitrobacter species in soil samples, but rather to the existence of organotrophically growing Nitrobacter cells.