A continuous culture study of the regulation of extracellular protease production in Vibrio SA1

Regulation of Proteolytic Activity in the Hyperthermophile Pyrococcus furiosus

Pyrococcus furiosus was shown to grow on casein or peptides as the sole carbon, energy, and nitrogen sources, while maltose could be used as a carbon and energy source only if peptides were present in the medium. A mixture of all 20 single amino acids could not replace the peptide requirement. Specific intracellular proteolytic activity was induced under low casein or tryptone levels and was decreased by the addition of maltose to both peptide-limiting and peptide-rich media in batch and continuous cultures. In a peptide-limited chemostat, activity towards azocasein and MeO-Suc-Arg-Pro-Tyr-p-nitroanilide reached a maximum at a dilution rate of 0.28 h, while activity toward l-lysine-p-nitroanilide reached a maximum at 0.50 h. Under peptide-limiting conditions, levels of the 66-kDa protease (S66) were enhanced relative to those of other cell proteins. Preliminary evidence suggests that this protease is immunologically related to the eukaryotic multicatalytic proteinase complex (proteosome).

Global physiological analysis of carbon- and energy-limited growing Escherichia coli confirms a high degree of catabolic flexibility and preparedness for mixed substrate utilization

Growth conditions for heterotrophic bacteria in the environment are characterized by low concentrations of carbon and energy sources and complex substrate mixtures. While mechanisms of starvation-survival in the absence of carbon substrates have been studied in considerable detail, information on the physiology of slow growth under oligotrophic conditions is limited. We intended to elucidate general strategies by which Escherichia coli adapts to low concentrations of a mixed carbon and energy source pool. A new screening method based on BIOLOG AN MicroPlates, which allowed us to distinguish repressed and induced catabolic functions in E. coli, was combined with the analysis of periplasmic high-affinity binding proteins. Extending previous findings for E. coli and other microbial species, we found that numerous alternative catabolic functions and high-affinity binding proteins are derepressed under either glucose- or arabinose-limited growth conditions, in spite of the absence of the respective inducers. Escherichia coli cells growing in carbon-limited complex medium chemostat cultures exhibited an even higher degree of catabolic flexibility and were able to oxidize 43 substrates. The BIOLOG respiration pattern indicated simultaneous dissimilation of diverse sugars, amino acids and dipeptides (mixed substrate growth). The observed physiological adaptations of E. coli to low concentrations of carbon and energy substrates presumably are advantageous in many natural growth situations and also offer an explanation why many heterotrophic bacteria have and maintain such a broad carbon substrate range.

Optimum cycle time for intermittent UASB reactors treating dairy wastewater

This work accesses the influence of cycle duration on the intermittent operation of mesophilic UASB reactors inoculated with flocculent sludge and used in dairy wastewater (DWW) treatment. Five cycle lengths ranging from 24 to 144 h were compared for loads between 2.5 and 29.0 gCOD/l/d. COD balances are presented which demonstrate the importance of a feedless period in the conversion to methane of the substrates removed during the feed period. The maximum applicable loads determined for the system were higher for the longer cycle times. The higher conversion to methane of the removed COD was obtained for the 96 h cycle (48 h feed + 48 h feedless) resulting in a more stable operation. The 96 h cycle (48 h feed + 48 h feedless) was considered as the optimum for the treatment of dairy effluents in intermittent UASB reactors. Compared to the maximum applicable loads reported in the literature for continuous systems (3-6 gCOD/l/d) treating dairy effluents the stable operation loads attained with intermittent operation were considerably higher (22 gCOD/l/d).

Effect of extra aeration on extracellular enzyme activities and ATP concentration of dairy Pseudomonas fluorescens

The effect of forced aeration on extracellular enzyme synthesis during batch growth of a Pseudomonas fluorescens strain of dairy origin on pyruvate mineral salts medium at 7 degrees C was studied. Measurement of oxygen tension, electron micrographs to estimate cell volume, luciferase determination of ATP and plate counts were performed in the course of incubation. Cells from the stationary phase of growth had lower energy status (in terms of intracellular ATP concentration) in the cultures receiving surplus aeration. Those cells produced three times more extracellular proteinase and lipase than control cells. Onset time for production of both enzymes coincided with a sharp fall of intracellular ATP levels.

The effect of dilution rate and pH on biomass and proteinase production by Micrococcus sedentarius grown in continuous culture

Micrococcus sedentarius, an organism associated with pitted keratolysis, produced two proteinases in culture supernatant fluids, as shown by non-denaturing PAGE with overlaying with a casein substrate. A mixture had optimal activity at pH 10 with azocasein substrate. At pH 7.1 and 8.1 in continuous culture with varying dilution rates high proteinase production occurred at relative specific growth rates (mu rels) 0.39 and 0.77 and biomass concentrations decreased with increasing dilution rate. One proteinase was constitutive and varied little in production with different growth rates. The other proteinase was under control with high production at low growth rates and no production at high growth rates. With varying pH at mu rels 0.39 and 0.77 maximum biomass concentration and proteinase production occurred between pH 8.0 and 9.0 as did the highest specific growth rate. These results support the hypothesis that Mic. sedentarius produces pitting in the stratum corneum when the skin is hydrated and the pH rises above neutrality.

Enterotoxin synthesis by nonsporulating cultures of Clostridium perfringens

Chemostat-cultured Clostridium perfringens ATCC 3624 and NCTC 10240, and a nonsporulating mutant strain, 8-5, produced enterotoxin in the absence of sporulation when cultured in a chemically defined medium at a 0.084-h-1 dilution rate at 37 degrees C. The enterotoxin was detected by serological and biological assays. Examination of the chemostat cultures by electron microscopy did not reveal sporulation at any stage. The culture maintained enterotoxigenicity throughout cultivation in a continuous system. The enterotoxin was detected in batch cultures of each strain cultivated in fluid thioglycolate medium and a chemically defined medium. No heat-resistant or light-refractile spores were detected in batch cultures during the exponential growth.

Effect of ruminal ammonia-nitrogen concentration on protein degradation in situ

Two experiments were conducted to determine the effect of ruminal ammonia-nitrogen concentration on rate of ruminal protein degradation. In Experiment 1, four Holstein steers were fed a basal diet of corn grain and corn silage at hourly intervals. Continuous intraruminal infusions of solutions containing sodium bicarbonate and either sodium chloride or ammonium chloride resulted in ruminal ammonia-nitrogen concentrations that averaged 4.8 and 17.3 mg/dl. Ruminal fluid pH, fluid volume, and turnover rate of fluid and molar percentage of acetate, propionate, and butyrate were similar across treatments, reflecting steady state conditions. Rates of nitrogen and dry matter disappearance from polyester bags containing soybean protein supplements with 10.2 or 50.1% soluble nitrogen were not affected by increase of ruminal ammonia-nitrogen concentrations from 4.8 to 17.3 mg/dl. In Experiment 2, Holstein steers were fed twice daily a basal diet of urea-supplemented corn grain and corn silage. Polyester bags containing soybean protein supplements were placed in the rumen at -4, 0, or 4 h with reference to feeding and incubated from 1 to 12 h. Peak ruminal ammonia-nitrogen concentrations occurred during different periods of incubation for each treatment. Ruminal ammonia-nitrogen concentrations ranged from 3 mg/dl at 6 h postfeeding to 46 mg/dl at 1 h postfeeding. Nitrogen and dry matter disappearance rates during 0 to 1 and 1 to 12 h of incubation did not differ among treatments.

Continuous culture studies on the production of staphylocoagulase by Staphylococcus aureus

The production of staphylocoagulase was studied with continuous cultures of various S. aureus strains in a simple salts medium supplemented with mannitol, casein hydrolysate and three vitamins. Conditions of low oxygen availability and magnesium-limitation were required for optimal steady-state staphylocoagulase production. It was demonstrated that the specific rate of staphylocoagulase production was dependent on the growth rate. In two bovine strains, the production rate pattern was similar to that of an inducible enzyme sensitive to catabolite repression, although no specific inductor suppressor could be demonstrated. The human strain, on the other hand, produced staphylocoagulase constitutively. In all strains the specific rate of production of total extracellular protein was strictly proportional to the growth rate. The bovine strains produced 6 times more staphylocoagulase in chemostat culture as compared with batch cultures of the same organisms. It is likely that mannitol functioned as an energy source rather than as a carbon source because it was converted for a major part to acetate and for a minor part to lactate and not to new cell material. Repression and staphylocoagulase production by mannitol, acetate or lactate was not observed. The probable nature of the regulating mechanism(s) underlying staphylocoagulase production is discussed.

Effect of environmental conditions on the production of two extracellular proteolytic enzymes by Vibrio SA1

The production of two extracellular proteases, an endopeptidase and an aminopeptidase, by the marine bacterium Vibrio SA1 was studied in batch cultures. The production of the proteases was induced during growth of the organism in peptone media and by several amino acids during growth in minimal media. It was repressed by easily metabolisable carbon compounds such as glucose, lactate and succinate during growth in peptone media. During growth in a lactate basal medium, phenylalanine was one of the best inducers and this amino acid was therefore used in further experiments. That lactate did not repress the synthesis of the proteases during growth in the lactate basal medium supplement with 2mM phenylalanine as an inducer, appeared to be a consequence of the low iron content of this medium. Growth curves of Vibrio SA1 on such media showed a period of linear growth during which protease production was observed. When the iron concentration was made sufficiently high to prevent linear growth, the synthesis of the proteases remained repressed. Apparently by imposing an iron limitation on the organism, catabolite repression by lactate was relieved. Similarly, when growth was limited by very low values of the dissolved oxygen tension in the medium, a high rate of protease synthesis was found which was immediately repressed when the oxygen limitation was released. The results indicate that the growth rate and/or a factor associated with the energy metabolism play a role in the regulation of the synthesis of the enzymes.

Purification and some properties of two extracellular proteolytic enzymes produced by Vibrio SA1

The purification and characterisation of an extracellular endo and amino-peptidase of the marine Vibrio SA1 is described. The endopeptidase was purified by ammonium sulphate precipitation, gel filtration and affinity chromatography. It had a molecular weight of approximately 31,000, a pH optimum at 7.8 and a temperature optimum at 50 C. The enzyme was rapidly inactivated at 65 C. The aminopeptidase was purified by ammonium sulphate precipitation, gel filtration and preparative polyacrylamide gel electrophoresis. This enzyme had a molecular weight of approximately 21,000, a pH optimum at 8.6 and a temperature optimum at 60 C. Both proteases were inactivated by EDTA while reactivation occurred by Ca2+, Zn2+ and Mg2+ ions. The endopeptidase hydrolysed several peptide bonds in the oxidized B-chain of insulin, particularly those involving amino groups of hydrophobic amino acid residues with bulky side chains. It was unable to hydrolyse synthetic dipeptides, but a number of tripeptides were hydrolysed at a low rate. The aminopeptidase hydrolysed leucinamide and di- and tripeptides containing hydrophobic bulky amino acids as the N-terminal residue. It was concluded that the endopeptidase and the aminopeptidase of Vibrio SA1 possess complementary specificities.