Dense growth of aerobic bacteria in a bench-scale fermentor

Escherichia coli B, Escherichia coli MRE 600, Escherichia coli K 12-3300, Pseudomonas fluorescens, and Aerobacter aerogenes were grown exponentially in a bench-scale fermentor to cell concentrations in the range of 20 to 41 g dry cells/liter at 30°C and 30 to 55 g dry cells/liter at 25°C. The high cell concentrations were achieved in a growth system previously described for growth of Escherichia coli W (Biotechnol. Bioeng., 16 , 933 (1974); ibid. 17 , 227 (1975)). Various enzyme activity levels in the high-concentration cells were compared to those in cells grown in conventional low-density cultures. No significant differences were found. The culture supernatants were found to be essentially free of high-molecular weight metabolic or cell lysis products. Yield constants for glucose, nitrogen, oxygen, and phosphorus were also determined in the dense cultures and some of their relations to the growth conditions are discussed.     

The effect of respiratory chain composition on the growth efficiencies of aerobic bacteria

The relationship between respiratory chain redox carrier composition and the efficiency of aerobic growth in continuous culture under carbon-limited conditions has been investigated for nine species of bacteria.True molar growth yields with respect to molecular oxygen ( ) or dissimilated carbon source (Y _{substrate ox.} ^max ) were not significantly affected by the nature either of the major quinone component (ubiquinone or menaquinone), of the major cytochrome oxidase moiety (cytochrome aa ₃ or o) or of the transhydrogenase segment (energy-dependent transhydrogenase, energy-independent transhydrogenase or no transhydrogenase), but were significantly influenced by the presence or absence of a high potential, membrane-bound cytochrome c. Under glycerol-limited conditions the presence of cytochrome c raised the average from 51.1 to 84.3 g cells · mole O ₂ ^–1 , and the average Y _{glycerol ox.} ^max from 154.6 to 233.2 g cells · mole glycerol oxidised^–1; the presence of this redox carrier also elicited increases in and Y _{substrate ox.} ^max of a similar order during growth under lactate, and glucose-limited conditions.The average efficiencies of aerobic energy conservation calculated from these true molar growth yields were 3.4 mole ATP equivalents · mole O ₂ ^–1 for organisms with respiratory chains which were deficient in cytochrome c and 5.9 mole ATP equivalents · mole O ₂ ^–1 for organisms with respiratory chains which contained cytochrome c.It is concluded from these data, and from parallel measurements of whole cell H⁺/O ratios, that bacterial respiratory systems invariably exhibit energy conservation at sites 1 and 2 but that the presence of a highpotential, membrane-bound cytochrome c is an obligatory prerequisite for energy conservation at site 3.     

Nitrite inhibition of aerobic bacteria

Nitrite was shown to inhibit active transport, oxygen uptake, and oxidative phosphorylation byPseudomonas aeruginosa. The evidence strongly suggested that nitrite exerted its inhibitory effect by oxidizing ferrous iron of an electron carrier(s), such as cytochrome oxidase, to ferric iron. The inhibitory effect of nitrite was readily reversible by washing the cells. Glucose transport byStreptococcus faecalis andS. lactis was not inhibited by nitrite, presumably because these species lack cytochromes and because glucose is transported by the phosphoenolpyruvate: phosphotransferase system rather than by active transport.     

The effect of temperature and pH on the growth of aerobic alkalithermophilic bacteria from hot springs in Buryatia

Growth parameters (temperature and pH) were determined for collection cultures of aerobic heterotrophic bacteria. Analysis of the experimental data with the use of the Rosso model made it possible to calculate the extreme values of temperature and pH permissive for culture growth. The examined cultures were subdivided into three groups with respect to their growth temperature and pH. The first group is represented by the cultures with minimum, maximum, and optimal growth temperatures of < 20, 60-64, and 38-40 degrees C, respectively, and with the optimal growth pH 8.0-8.5. Bacteria of the second group are true alkalithermophilic organisms with a temperature optimum of 45-50 degrees C and pH optimum of 8.5-9.0. The third group includes a culture of a thermophilic alkalitolerant bacterium.     

Influence of bovine lactoferrin on the growth of selected probiotic bacteria under aerobic conditions

Bovine lactoferrin (bLf) is a natural glycoprotein, and it shows broad-spectrum antimicrobial activity. However, reports on the influences of bLf on probiotic bacteria have been mixed. We examined the effects of apo-bLf (between 0.25 and 128 mg/mL) on both aerobic and anaerobic cultures of probiotics. We found that bLf had similar effects on the growth of probiotics under aerobic or anaerobic conditions, and that it actively and significantly (at concentrations of >0.25 mg/mL) retarded the growth rate of Bifidobacterium bifidum (ATCC 29521), B. longum (ATCC 15707), B. lactis (BCRC 17394), B. infantis (ATCC 15697), Lactobacillus reuteri (ATCC 23272), L. rhamnosus (ATCC 53103), and L. coryniformis (ATCC 25602) in a dose-dependent manner. Otherwise, minimal inhibitory concentrations (MICs) were 128 or >128 mg/mL against B. bifidum, B. longum, B. lactis, L. reuteri, and L. rhamnosus (ATCC 53103). With regard to MICs, bLf showed at least four-fold lower inhibitory effect on probiotics than on pathogens. Intriguingly, bLf (>0.25 mg/mL) significantly enhanced the growth of Rhamnosus (ATCC 7469) and L. acidophilus (BCRC 14065) by approximately 40–200 %, during their late periods of growth. Supernatants produced from aerobic but not anaerobic cultures of L. acidophilus reduced the growth of Escherichia coli by about 20 %. Thus, bLf displayed a dose-dependent inhibitory effect on the growth of most probiotic strains under either aerobic or anaerobic conditions. An antibacterial supernatant prepared from the aerobic cultures may have significant practical use.     

Filamentous bacteria existence in aerobic granular reactors

Filamentous bacteria are associated to biomass settling problems in wastewater treatment plants. In systems based on aerobic granular biomass they have been proposed to contribute to the initial biomass aggregation process. However, their development on mature aerobic granular systems has not been sufficiently studied. In the present research work, filamentous bacteria were studied for the first time after long-term operation (up to 300 days) of aerobic granular systems. Chloroflexi and Sphaerotilus natans have been observed in a reactor fed with synthetic wastewater. These filamentous bacteria could only come from the inoculated sludge. Thiothrix and Chloroflexi bacteria were observed in aerobic granular biomass treating wastewater from a fish canning industry. Meganema perideroedes was detected in a reactor treating wastewater from a plant processing marine products. As a conclusion, the source of filamentous bacteria in these mature aerobic granular systems fed with industrial effluents was the incoming wastewater.     

Iron respiration-driven proton translocation in aerobic bacteria

Washed cell suspensions of Aquaspirillum magnetotacticum MS-1, A. itersonii E12639, Bacillus subtilis 6633, and Escherichia coli CSH27 translocated protons in response to the added oxidant O2 or NO3-, with triphenylmethylphosphonium bromide as the permeant ion. Iron respiration-driven proton translocation was observed in A. magnetotacticum MS-1, B. subtilis, and E. coli but not in a nonmagnetic strain of A. magnetotacticum (strain NM-1A) or with A. itersonii. Proton translocation to Fe3+ was totally inhibited by 500 microM NaN3 or 0.5 microM carbonyl cyanide m-chlorophenylhydrazone.     

Control of urease formation in certain aerobic bacteria

Summary During nitrogen starvation, a 20- to 250-fold increase in specific urease activity was observed in extracts of P. aeruginosa, P. fluorescens, Hydrogenomonas, M. denitrificans, M. cerificans and B. megaterium. In contrast to these species, high levels of urease were observed in P. vulgaris strains and in S. ureae under all growth conditions. No urease was detectable in strains of E. coli, S. marcescens and B. polymyxa, regardless of growth conditions.Incubated in the absence of an exogenous nitrogen source, the specific urease activity increased during a period of 10 to 20 h in P. aeruginosa, Hydrogenomonas and M. denitrificans. Phosphate starvation did not significantly effect urease formation in these strains. The increase in specific urease activity was found to be repressed by exogenous nitrogen sources, including urea. Inhibition by chloramphenicol, other inhibitors, and by the lack of oxygen or fructose, indicated that a derepressive urease formation may occur in these strains. The involvement of traces of urea possibly released from endogenous sources during starvation is discussed.