High Dissolved Oxygen Tension Research Articles

Dynamic investigation and modeling of the nitrogen cometabolism in Methylococcus capsulatus ( Bath).

The methanotrophic bacterium Methylococcus capsulatus is capable of assimilating methane and oxygen into protein-rich biomass, however, the diverse metabolism of the microorganism also allows for several undesired cometabolic side-reactions to occur. In this study, the ammonia cometabolism in Methylococcus capsulatus is investigated using pulse experiments. Surprisingly Methylococcus capsulatus oxidizes ammonia to nitrate through a yet unknown mechanism and fixes molecular nitrogen even at a high dissolved oxygen tension. The observed phenomena can be modeled using 14 ordinary differential equations and 18 kinetic parameters, of which 6 were revealed by Morris screening to be identifiable from the experimental data. Monte Carlo simulations showed that the model was robust and accurate even with uncertainty in the parameter values as confirmed by statistical error analysis.

High dissolved oxygen tension triggers outer membrane vesicle formation by Neisseria meningitidis

BackgroundOuter membrane vesicles (OMVs) are nanoparticles released by Gram-negative bacteria and can be used as vaccines. Often, detergents are used to promote release of OMVs and to remove the toxic lipopolysaccharides. Lipopolysaccharides can be detoxified by genetic modification such that vesicles spontaneously produced by bacteria can be directly used as vaccines. The use of spontaneous OMVs has the advantage that no separate extraction step is required in the purification process. However, the productivity of spontaneous OMVs by bacteria at optimal growth conditions is low. One of many methods for increasing OMV formation is to reduce the linkage of the outer membrane to the peptidoglycan layer by knocking out the rmpM gene. A previous study showed that for Neisseria meningitidis this resulted in release of more OMVs. Furthermore, cysteine depletion was found to trigger OMV release and at the same time cause reduced growth and oxidative stress responses. Here we study the effect of growth rate and oxidative stress on OMV release.ResultsFirst, we identified using chemostat and accelerostat cultures of N. meningitidis that increasing the growth rate from 0.03 to 0.18 h−1 has a limited effect on OMV productivity. Thus, we hypothesized that oxidative stress is the trigger for OMV release and that oxidative stress can be introduced directly by increasing the dissolved oxygen tension of bacterial cultures. Slowly increasing oxygen concentrations in a N. meningitidis changestat showed that an increase from 30 to 150% air saturation improved OMV productivity four-fold. Batch cultures controlled at 100% air saturation increased OMV productivity three-fold over batch cultures controlled at 30% air saturation.ConclusionIncreased dissolved oxygen tension induces the release of outer membrane vesicles in N. meningitidis cultures. Since oxygen concentration is a well-controlled process parameter of bacterial cultures, this trigger can be applied as a convenient process parameter to induce OMV release in bacterial cultures. Improved productivity of OMVs not only improves the production costs of OMVs as vaccines, it also facilitates the use of OMVs as adjuvants, enzyme carriers, or cell-specific drug delivery vehicles.

Genetically shaping morphology of the filamentous fungus Aspergillus glaucus for production of antitumor polyketide aspergiolide A.

BackgroundFor filamentous fungi, the basic growth unit of hyphae usually makes it sensitive to shear stress which is generated from mechanical force and dynamic fluid in bioreactor, and it severely decreases microbial productions. The conventional strategies against shear-sensitive conundrum in fungal fermentation usually focus on adapting agitation, impeller type and bioreactor configuration, which brings high cost and tough work in industry. This study aims to genetically shape shear resistant morphology of shear-sensitive filamentous fungus Aspergillus glaucus to make it adapt to bioreactor so as to establish an efficient fermentation process.ResultsHyphal morphology shaping by modifying polarized growth genes of A. glaucus was applied to reduce its shear-sensitivity and enhance aspergiolide A production. Degenerate PCR and genome walking were used to obtain polarized growth genes AgkipA and AgteaR, followed by construction of gene-deficient mutants by homologous integration of double crossover. Deletion of both genes caused meandering hyphae, for which, ΔAgkipA led to small but intense curves comparing with ΔAgteaR by morphology analysis. The germination of a second germ tube from conidiospore of the mutants became random while colony growth and development almost maintained the same. Morphology of ΔAgkipA and ΔAgteaR mutants turned to be compact pellet and loose clump in liquid culture, respectively. The curved hyphae of both mutants showed no remarkably resistant to glass bead grinding comparing with the wild type strain. However, they generated greatly different broth rheology which further caused growth and metabolism variations in bioreactor fermentations. By forming pellets, the ΔAgkipA mutant created a tank environment with low-viscosity, low shear stress and high dissolved oxygen tension, leading to high production of aspergiolide A (121.7 ± 2.3 mg/L), which was 82.2% higher than the wild type.ConclusionsA new strategy for shaping fungal morphology by modifying polarized growth genes was applied in submerged fermentation in bioreactor. This work provides useful information of shaping fungal morphology for submerged fermentation by genetically modification, which could be valuable for morphology improvement of industrial filamentous fungi.

Improvement in Production and Quality of Gellan Gum by Sphingomonas paucimobilis Under High Dissolved Oxygen Tension Levels

The effect of agitation rate and dissolved oxygen tension (DOT) on growth and gellan production by Sphingomonas paucimobilis was studied. Higher cell growth of 5.4 g l(-1) was obtained at 700 rpm but maximum gellan (15 g l(-1)) was produced at 500 rpm. DOT levels above 20% had no effect on cell growth but gellan yield was increased to 23 g l(-1 )with increase in DOT level to 100%. Higher DOT levels improved the viscosity and molecular weight of the polymer with change in acetate and glycerate content of the polymer.

High dissolved oxygen tension enhances heterologous protein expression by recombinant Pichia pastoris

The effect of dissolved oxygen (DO) tension on heterologous protein expression by the Pichia system was investigated by applying DO control bands of different set points and bandwidths in the DO-stat fed-batch fermentation. The model protein was elastase inhibiting peptide (EIP) that showed strong inhibitory activity against human neutrophil elastase with very high specificity. In the alcohol oxygenase 1 derepression phase, more frequent glycerol feeding by keeping the DO control band narrower resulted in a higher cell growth rate (0.10 h −1). In the methanol induction phase, maintaining a higher DO set point and allowing more frequent feeding significantly enhanced EIP expression. The EIP expression titre was increased about threefold to 846 mg l −1 on average by raising the lower set point from 10 to 30% air-saturation. Both specific expression titre and methanol consumption rates were increased about threefold, which indicated that higher DO tension stimulated the methanol utilization pathway and improved the expression efficiency. To operate the DO-stats with higher DO set points, an oxygen enriching membrane system that could generate up to 38% oxygen partial pressure from the regular air was used as an alternative oxygen supplier to the traditional gas-mixing system consisting of an air compressor and a pure oxygen cylinder.

Morphological and enzymatic responses of a recombinant Aspergillus niger to oxidative stressors in chemostat cultures

Continuous chemostat cultures of a recombinant strain of Aspergillus niger (B1-D), engineered to produce the marker protein hen egg white lysozyme, were investigated with regard to their susceptibility to oxidative stress. The culture response to oxidative stress, produced either by addition of exogenous hydrogen peroxide (H 2O 2) or by high dissolved oxygen tension (DOT), was characterised in terms of the activities of two key defensive enzymes: catalase (CAT) and superoxide dismutase (SOD). Since the morphology is so critical in submerged fungal bioprocesses, the key morphological indices were analysed using a semi-automated image analysis system. Both oxidant stressors, H 2O 2 and elevated DOT, increased both enzyme activities, however, the extent was different: exogenous H 2O 2 led mainly to increased CAT activity, whereas gassing with O 2 enriched air, which resulted in a DOT of 165% of air saturation, increased both enzyme activities more than 2-fold compared with the control steady state culture. Addition of exogenous H 2O 2 resulted in shorter hyphae compared with control steady state cultures. These findings indicate that it is unsound to use exogenous H 2O 2 to simulate oxidative stress induced by elevated dissolved oxygen levels since the response to each might be quite different, both in terms of enzymatic (defensive) responses and in terms of culture morphology.

Protection of bioreactor from microbial contamination by high dissolved oxygen tension

Repeated batch hydrolysis of casein using immobilized protease were carried out at various do tensions and pH. At any of the pH tested, microbial contamination could be satisfactorily suppressed by maintaining high do. In continuous reaction, contamination could be suppressed throughout 40 days under the do of 190 ppm, whereas contamination was observed after 24 hours with the do of 2.5 ppm.

Hydrogen oxidation and efficiency of nitrogen fixation in succinate-limited chemostat cultures ofRhizobium ORS 571

Rhizobium ORS 571, isolated from stem nodules of the tropical legumeSesbania rostrata is able to grow in the chemostat with molecular nitrogen as sole nitrogen source at a specific growth rate of 0.1 h-1. Samples from nitrogenfixing cultures showed high acetylene reduction activities: 1,500 nmol ethylene formed per milligram dry weight per hour. Under nitrogen-fixing conditions an uptake hydrogenase is induced. Ammonia-assimilating cultures, without additional hydrogen, did not induce hydrogenase. The addition of hydrogen to succinate-limited nitrogen-fixing cultures resulted in an increase in the molar growth yield on succinate (Ysuccinate) from 27 to 35 and a slight decrease in the molar growth yield on oxygen (\(Y_{O_2 }\)), showing that hydrogen oxidation is less energy-yielding than the oxidation of endogenous substrates. Respiration-driven proton translocation measured with starved cells indicated the functioning of site 1 and 2 of oxidative phosphorylation. Cytochrome spectra showed that cytochromea600, present at high dissolved oxygen tension (d.o.t.) almost completely disappeared at low d.o.t. In flash-photolysis spectra only thea-type cytochrome could be detected as an oxidase in cells both grown at high and low d.o.t. Growth yields in ammonia-assimilating cultures were higher than those measured in nitrogen-fixing cultures. Assuming two sites of oxidative phosphorylation, a molar growth yield on ATP (YATP) of about 3 and 6 was calculated for respecticely nitrogen-fixing and ammonia-assimilating cultures. TheYATP under nitrogen-fixing conditions is dependent on the amount of H2 formed per mol N2 fixed (H2/N2 ratio). A method has been described to calculate the total amount of ATP use by nitrogenase during the fixation of 1 mol N2 (ATP/N2 ratio) and H2/N2 ratios in aerobic nitrogen fixing organisms. This calculation yielded that nitrogen fixation inRhizobium ORS 571 is a high ATP-consuming process. The calculated ATP/N2 and H2/N2 ratios were respectively 42 and 7.5.

Oxygen metabolism by the anaerobic bacterium veillonella alcalescens.

Veillonella alcalescens contained a membrane-bound lactate oxidase system. Studies on the effect of inhibitors on lactate oxidase showed the participation of non-heme iron, quinone and cytochromesb andd. Superoxide anion radicals (\(O_2^{\bar \cdot } \)) and H2O2 were shown to be formed at lactate oxidation and presumably arose from cyanide- and azide-resistant side chains of the respiratory system. The →H+/O ratio withL-lactate as a hydrogen donor was 2.3. When an anaerobic culture growing on lactate was shifted to a high dissolved oxygen tension (d.o.t.=15 kPa) rapid inhibition of growth and lactate conversion occurred. This could be correlated with a rapid inactivation of lactate dehydrogenase. The effects of high d.o.t.'s on lactate dehydrogenase, lactate conversion and growth were reversible. After a shift to low d.o.t.'s (<2.5 kPa) growth ofV. alcalescens continued for one or two doublings whereafter lysis did occur. Acetate and pyruvate were the main fermentation products. P/O ratio's were calculated from molar growth yields and fermentation balances. A P/O value of 0.66 was found after a shift to a very low oxygen supply at which the d.o.t. presumably was zero. Shifts to higher d. o. t.'s gave much lower growth yields. Presumably, under these conditions uncoupling between growth and energy production occurred. Accumulation of toxic oxygen compounds was given as an explanation for the behaviour ofV. alcalescens at low d.o.t.'s.