Effects of o-cresol co-disposal and pH on the methanogenic degradation of refuse

SULISTI, I.A. WATSON-CRAIK AND E. SENIOR. 1996. Both maximum o -cresol degradation and activity of sulphate-reducing bacteria (SRB) were observed at refuse pH values between 7.0 and 8.0. Optimum pH values for methane release were between 6.5 and 7.5. Partial inhibition of methane production was recorded at pH 5.7, 6.0 and 8.0, whilst sulphate reduction was inhibited partially at pH values 5.7–6.5. Both sulphate reduction and methanogenesis were completely inhibited in refuse with initial pH 4.0. The catabolism of acetate occurred under similar conditions to methane production, and was promoted at pH 6.5–7.5. It appeared that propionate oxidation depended upon the activities of SRB. Optimum conditions for the metabolism of propionate and other volatile fatty acids were between pH 7.0 and 8.0.     

The effect of incubation temperature on steady-state concentrations of hydrogen and volatile fatty acids during anaerobic degradation in slurries from wetland sediments

Abstract Increasing the incubation temperature of two swamp slurries from 2°C to37°C resulted in a 8- to 18-fold increase in the H₂ partial pressure. The concentration of volatile fatty acids remained fairly constant except for butyrate, which decreased with increasing temperature. Calculation of Gibbs free energies of syntrophic degradation of butyrate and propionate, and of methanogenesis from acetate and H₂ revealed that these reactions were exergonic after the slurries had stabilized at the incubation temperatures. The changes in H₂ partial pressure and butyrate concentration with temperature were found important to render the processes exergonic within the tested temperature range.     

Quantitative Influences of Butyrate or Propionate on Thermophilic Production of Methane from Biomass

Sodium butyrate and sodium propionate were continuously infused into separate 4-liter thermophilic digesters. These digesters were operated at 55°C, had a retention time of 20 days, and had a pH of 7.8. Infusion rates were started at 10 mM day⁻¹ and were increased incrementally when new stable external organic acid pool sizes and new stable gas production rates were observed. Stable conditions were obtained in both digesters at an infusion rate of 15 mM day⁻¹, with methanogenesis elevated over that of control digesters. Calculations based on expected CH₄ at this infusion rate and measured CH₄ production in the treated and control digesters, however, showed an approximately 25% inhibition of methanogenesis in both digesters. A digester infused with sodium chloride showed little or no inhibition at this infusion rate, but was totally inhibited when its infusion rate was increased to 20 mM day⁻¹, and cumulative added NaCl reached 0.38 M. The butyrate and propionate-amended digesters tolerated addition rates of 20 mM day⁻¹, but both failed when they were increased to 25 mM day⁻¹. These results indicate that the thermophilic digesters could function stably at higher external pool sizes of butyrate or propionate than routinely observed.     

Rapid start-up of thermophilic anaerobic digestion with the turf fraction of MSW as inoculum

This study aims to determine suitable start-up conditions and inoculum sources for thermophilic anaerobic digestion. Within days of incubation MSW at 55 °C, methane was produced at a high rate. In an attempt to narrow down which components of typical MSW contained the thermophilic methanogens, vacuum cleaner dust, banana peel, kitchen waste, and garden waste were tested as inoculum for thermophilic methanogenesis with acetate as the substrate. Results singled out grass turf as the key source of thermophilic acetate degrading methanogenic consortia. Within 4 days of anaerobic incubation (55 °C), anaerobically incubated grass turf samples produced methane accompanied by acetate degradation enabling successful start-up of thermophilic anaerobic digestion. Other essential start-up conditions are specified. Stirring of the culture was not conducive for successful start-up as it resulted specifically in propionate accumulation.     

Long-term effect of inoculum pretreatment on fermentative hydrogen production by repeated batch cultivations: homoacetogenesis and methanogenesis as competitors to hydrogen production

Long-term effects of inoculum pretreatments (heat, acid, loading-shock) on hydrogen production from glucose under different temperatures (37 °C, 55 °C) and initial pH (7 and 5.5) were studied by repeated batch cultivations. Results obtained showed that it was necessary to investigate the long-term effect of inoculum pretreatment on hydrogen production since pretreatments may just temporarily inhibit the hydrogen consuming processes. After long-term cultivation, pretreated inocula did not enhance hydrogen production compared to untreated inocula under mesophilic conditions (initial pH 7 and pH 5.5) and thermophilic conditions (initial pH 7). However, pretreatment could inhibit lactate production and lead to higher hydrogen yield under thermophilic conditions at initial pH 5.5. The results further demonstrated that inoculum pretreatment could not permanently inhibit either methanogenesis or homoacetogenesis, and methanogenesis and homoacetogenesis could only be inhibited by proper control of fermentation pH and temperature. Methanogenic activity could be inhibited at pH lower than 6, both under mesophilic and thermophilic conditions, while homoacetogenic activity could only be inhibited under thermophilic condition at initial pH 5.5. Microbial community analysis showed that pretreatment did not affect the dominant bacteria. The dominant bacteria were Clostridium butyricum related organisms under mesophilic condition (initial pH 7 and 5.5), Thermoanaerobacterium sp. related organisms under thermophilic condition (initial pH 7), and Thermoanaerobacterium thermosaccharolyticum related organisms under thermophilic condition (initial pH 5.5). Results from this study clearly indicated that the long-term effects of inoculum pretreatments on hydrogen production, methanogenesis, homoacetogenesis and dominant bacteria were dependent on fermentation temperature and pH.     

Degradation of high concentrations of cresols by Pseudomonas sp. CP4

Pseudomonas sp. CP₄, a potent phenol-degrading laboratory isolate could mineralize all three isomers of cresol. This strain readily utilized up to 1.4, 1.1 and 2.2 g/l of o- m- and p-cresol, respectively as the sole sources of carbon and energy. These are the highest concentrations of cresols reported to be degraded by a bacterial strain. The rates of degradation of the three isomers were in the order: o- > p- > m-cresol. All the isomers of cresol were catabolized through a meta-cleavage pathway. Fairly high catechol 2,3-dioxygenase (C230) activity against catechol was observed in the cell-free extracts of the culture grown on these compounds and were in the order: m- > o- > p-cresol.     

Thermophilic sulfate-reducing bacteria in cold marine sediment

Abstract Sulfate reduction was measured with the ³⁵SO₄²⁻ -tracer technique in slurries of sediment from Aarhus Bay, Denmark, where seasonal temperatures range from 0° to 15°C. The incubations were made at temperatures from 0°C to 80°C in temperature increments of 2°C to search for presence of psychrophilic, mesophilic and thermophilic sulfate-reducing bacteria. Detectable activity was initially only in the mesophilic range, but after a lag phase sulfate reduction by thermophilic sulfate-reducing bacteria were observed. No distinct activity of psychrophilic sulfate-reducing bacteria was detected. Time course experiments showed constant sulfate reduction rates at 4°C and 30°C, whereas the activity at 60°C increased exponentially after a lag period of one day. Thermophilic, endospore-forming sulfate-reducing bacteria, designated strain P60, were isolated and characterized as D esulfotomaculum kuznetsovii . The temperature response of growth and respiration of strain P60 agreed well with the measured sulfate reduction at 50°–70°C. Bacteria similar to strain P60 could thus be responsible for the measured thermophilic activity. The viable population of thermophilic sulfate-reducing bacteria and the density of their spores was determined in most probable number (MPN) dilutions. The density was 2.8·10⁴ cells·.g⁻¹ fresh sediment, and the enumerations suggested that they were all present as spores. This result agrees well with the observed lag period in sulfate reduction above 50°C. No environment with temperatures supporting the growth of these thermophiles is known in the region around Aarhus Bay.     

Mode of high temperature injury to wheat during grain development

High temperature stress adversely affects wheat growth in many important production regions, but the mode of injury is unclear. Wheat ( Triticum aestivum L. cv. Newton) was grown under controlled conditions to determine the relative magnitude and sequences of responses of source and sink processes to high temperature stress during grain development. Regimes of 25°C day/15°C night, 30°C day/20°C night, and 35°C day/25°C night from 5 days after anthesis to maturity differentially affected source and sink processes. High temperatures accelerated the normal decline in viable leaf blade area and photosynthetic activities per unit leaf area. Electron transport, as measured by Hill reaction activity, declined earlier and faster than other photosynthetic processes at the optimum temperature of 25/15 °C and at elevated temperatures. Changes in RUBP carboxylase activities were similar in direction but smaller in magnitude than changes in photosynthesic rate. Increased protease activity during senscence was markedly accentuated by high temperature stress. Specific protease activity increased 4-fold at 25/15 °C and 28-fold at 35/25 °C from 0 to 21 days after initiation of temperature treatments. Grain-filling rate decreased from the lowest to the highest temperature, but the change was smaller than the decrease in grain-filling duration at the same temperatures. We concluded that a major effect of high temperature is acceleration of senescence, including cessation of vegetative and reproductive growth, deterioration of photosynthetic activities, and degradation of proteinaceous constituents.     

Thermophilic methanogens in rice field soil

The soil temperature in flooded Italian rice fields is generally lower than 30°C. However, two temperature optima at ≈ 41°C and 50°C were found when soil slurries were anoxically incubated at a temperature range of 10–80°C. The second temperature optimum indicates the presence of thermophilic methanogens in the rice field soil. Experiments with ¹⁴C-labelled bicarbonate showed that the thermophilic CH₄ was exclusively produced from H₂/CO₂. Terminal restriction fragment length polymorphism (T-RFLP) of archaeal SSU rRNA gene fragments revealed a dramatic change in the archaeal community structure at temperatures > 37°C, with the euryarchaeotal rice cluster I becoming the dominant group (about 80%). A clone library of archaeal SSU rRNA gene fragments generated at 49°C was also dominated (10 out of 11 clones) by rice cluster I. Our results demonstrate that Italian rice field soil contains thermophilic methanogenic activity that was most probably a result of members of the as yet uncultivated euryarchaeotal rice cluster I.     

Proteolytic activity from a thermophilic Streptomyces megasporus strain SDP4

Multiple proteases secreted by a thermophilic actinomycete Streptomyces megasporus SDP4 after 18 h of growth at 55 °C are reported. The enzyme preparation exhibited activity over a broad pH and temperature range of pH 6–12 and 25–85 °C, respectively. Optimum activity was observed at pH 8·0, pH 10·0 and 55 °C and was calcium independent. Thermostability was enhanced in the presence of 0·01 mol l⁻¹ calcium ions and half-life was 30 min at 85 °C. The enzyme was active in the presence of SDS. Both, EDTA and PMSF were partially inhibitory, indicating the presence of serine and metal requiring proteases. Three active zones in the range of 90–30 kDa were detected post-electrophoretically.     

Thermophilic (55-65 degrees C) and extreme thermophilic (70-80 degrees C) sulfate reduction in methanol and formate-fed UASB reactors

The feasibility of thermophilic (55-65 degrees C) and extreme thermophilic (70-80 degrees C) sulfate-reducing processes was investigated in three lab-scale upflow anaerobic sludge bed (UASB) reactors fed with either methanol or formate as the sole substrates and inoculated with mesophilic granular sludge previously not exposed to high temperatures. Full methanol and formate degradation at temperatures up to, respectively, 70 and 75 degrees C, were achieved when operating UASB reactors fed with sulfate rich (COD/SO4(2-)=0.5) synthetic wastewater. Methane-producing archaea (MPA) outcompeted sulfate-reducing bacteria (SRB) in the formate-fed UASB reactor at all temperatures tested (65-75 degrees C). In contrast, SRB outcompeted MPA in methanol-fed UASB reactors at temperatures equal to or exceeding 65 degrees C, whereas strong competition between SRB and MPA was observed in these reactors at 55 degrees C. A short-term (5 days) temperature increase from 55 to 65 degrees C was an effective strategy to suppress methanogenesis in methanol-fed sulfidogenic UASB reactors operated at 55 degrees C. Methanol was found to be a suitable electron donor for sulfate-reducing processes at a maximal temperature of 70 degrees C, with sulfide as the sole mineralization product of methanol degradation at that temperature.     

Factors affecting the consumption of 2,3-butanedione by Saccharomyces cerevisiae

Production and degradation of diacetyl by a commercial Saccharomyces cerevisiae strain was studied. This yeast did not produce diacetyl but could consume it. Diacetyl degradation activity was biological and was present even when the yeast was grown in the absence of diacetyl. Maximum specific activity was obtained when the yeast was grown in 280 μmol of diacetyl, 1 vvm of aeration and 37°C.     

BRAIN METABOLISM AT LOW TEMPERATURES

Abstract— Levels of ATP, ADP, phosphocreatine, glycogen, glucose, lactic acid and inorganic phosphate in the rabbit brain were determined after cerebral hypothermia to 24, 22, 20, 18 and 16°C brain temperature. Hypothermia was induced by isolated head perfusion by means of an extracorporeal device including a donor animal of the same species. In two experiments brains were cooled to 24 and 16°C, followed by rewarming to nearly normothermic values before brain biopsy was performed. In all experiments the electrical activity of the cerebral cortex was recorded intermittently.
No metabolic disturbances could be observed in 25 out of a total number of 26 experiments. Only one experiment showed a marked decrease in cerebral content of high-energy phosphates, glycogen and glucose and a corresponding increase of lactic acid and inorganic phosphate. These metabolic changes were caused in our opinion by convulsive activity of the brain induced by hypothermia. This was recorded in an electrocorticogram at a brain temperature ranging from 18·9 to 17·8°C over a 150 s period, 5 min before this brain was removed from the animal. These findings demonstrate that hypothermia per se to 24–16°C under our experimental conditions does not cause damage to the rabbit brain, generally, but under special conditions can provoke an increase in energy requirement which exceeds the energy available.     

Nitrogenase activity (acetylene reduction) in root-associated, cold-climate species of Azospirillum, Enterobacter, Klebsiella and Pseudomonas growing at various temperatures

Abstract 23 Strains of diazotrophic root-associated bacteria isolated from various parts of Finland were tested for nitrogenase activity during growth at various temperatures. Nitrogenase activity was optimal at 20–37°C in cultures of Klebsiella pneumoniae , and at 14–20°C in cultures of Klebsiella terrigena and Enterobacter agglomerans . Strains of K. terrigena and E. agglomerans showed no activity at 37°C, and K. pneumoniae only minimal or no activity at 14°C. Azospirillum lipoferum exhibited high nitrogenase activity at both 28–37°C, but less than 25% of optimal activity at 20°C and no activity at 14°C. Pseudomonas sp. expressed nitrogenase activity at 14–28°C. None of the strains manifested nitrogenase activity at 4 or 42°C. There were only small local variations within a species between strains isolated at different locations.     

The effect of temperature, pH and medium in a surface adhesion immunofluorescent technique for detection of Listeria monocytogenes

A rapid surface adhesion-based immunofluorescence technique was used to detect Listeria monocytogenes from inoculated culture systems. The effect of culture type (pure, mixed and meat), pH (7·00, 6·40, 4·76 and 3·13), acids (citric and HCl) and temperature (25°, 30° and 37°C) on the adhesion of Listeria to the polycarbonate membrane used in this technique was determined. It was found that pH had a significant effect ( P < 0·05) with higher numbers of Listeria adhering at low pH values (4·76). Culture type was also important with significantly higher numbers of Listeria ( P < 0·05) adhering to membranes immersed in meat cultures than in pure or mixed cultures. This effect was seen at 30°C but not at 25° or 37°C. The total viable count (TVC) on the membrane was unaffected by pH but temperature had an influence with optimum adhesion occurring at 25°C. The reasons for observed differences and their implications for the surface adhesion immunofluorescent rapid method are discussed.     

Effects of hydrogen and formate on the degradation of propionate and butyrate in thermophilic granules from an upflow anaerobic sludge blanket reactor.

Degradation of propionate and butyrate in whole and disintegrated granules from a thermophilic (55 degrees C) upflow anaerobic sludge blanket reactor fed with acetate, propionate, and butyrate as substrates was examined. The propionate and butyrate degradation rates in whole granules were 1.16 and 4.0 mumol/min/g of volatile solids, respectively, and the rates decreased 35 and 25%, respectively, after disintegration of the granules. The effect of adding different hydrogen-oxidizing bacteria (both sulfate reducers and methanogens), some of which used formate in addition to hydrogen, to disintegrated granules was tested. Addition of either Methanobacterium thermoautotrophicum delta H, a hydrogen-utilizing methanogen that does not use formate, or Methanobacterium sp. strain CB12, a hydrogen- and formate-utilizing methanogen, to disintegrated granules increased the degradation rate of both propionate and butyrate. Furthermore, addition of a thermophilic sulfate-reducing bacterium (a Desulfotomaculum sp. isolated in our laboratory) to disintegrated granules improved the degradation of both substrates even more than the addition of methanogens. By monitoring the hydrogen partial pressure in the cultures, a correlation between the hydrogen partial pressure and the degradation rate of propionate and butyrate was observed, showing a decrease in the degradation rate with increased hydrogen partial pressure. No significant differences in the stimulation of the degradation rates were observed when the disintegrated granules were supplied with methanogens that utilized hydrogen only or hydrogen and formate. This indicated that interspecies formate transfer was not important for stimulation of propionate and butyrate degradation.     

Partial purification and characterization of phospholipase C from Yersinia enterocolitica

About 34% of the strains of Yersinia enterocolitica isolated from raw milk were found to produce lecithinase. A selected strain produced phospholipase C at 22°C and 37°C; production was optimum at 37°C in the stationary phase (14–16 h). A decrease in phospholipase C activity at various storage temperatures (—5°C, 4°C, 37°C) was also observed, although the enzyme was active over a wide range of temperature (5–65°C) and pH (3mD5–7mD5). The phospholipase C was partially purified by ammonium sulphate precipitation and Sephadex column chromatography, and characterized.     

Rapid small scale preparation of bacterial genomic DNA, suitable for cloning and hybridization analysis

The uptake of noxythiolin by a urinary isolate of Escherichia coli was examined initially at 37°C but the adsorption isotherm was complicated by the concomitant degradation of the compound. When drug adsorption was investigated at 4°C, to reduce the degradation rate of the compound, it was observed that noxythiolin was taken up by the urinary isolate in a linear fashion. The resulting adsorption patterns are discussed in relation to their possible classification. The implications of this uptake are considered with respect to the antimicrobial activity of noxythiolin.     

Generation of a membrane-bound, oligomerized pre-pore complex is necessary for pore formation by Clostridium septicum alpha toxin

Low-temperature inhibition of the cytolytic activity of alpha toxin has facilitated the identification of an important step in the cytolytic mechanism of this toxin. When alpha toxin-dependent haemolysis was measured on erythrocytes at various temperatures it was clear that at temperatures ≤15°C the haemolysis rate was significantly inhibited with little or no haemolysis occurring at 4°C. Alpha toxin appeared to bind to and oligomerize on erythrocyte membranes with similar kinetics at 4°C and 37°C. The slight differences in these two processes at 4°C and 37°C could not account for the loss of cytolytic activity at low temperature. At 4°C alpha toxin neither stimulated potassium release from erythrocytes nor formed pores in planar membranes. In contrast, at temperatures ≥25°C both processes proceeded rapidly. Pores that were opened in osmotically stabilized erythrocytes could not be closed by low temperature. Therefore, low temperature appeared to prevent the oligomerized complex from forming a pore in the membrane. These data support the hypothesis that alpha toxin oligomerizes into a membrane-bound, pre-pore complex prior to formation of a pore in a lipid bilayer.     

Influence of growth temperature on the production of extracellular virulence factors and pathogenicity of environmental and human strains of Aeromonas hydrophila

The biochemical properties, virulence for mice and trout, and the extracellular virulence factors at 28° and 37°C of 11 environmental and nine human strains of Aeromonas hydrophila were compared. All the environmental isolates and four of the human group were virulent for trout at 3 x 10⁷ cfu, but only human strains were able to cause death or lesions in mice by the intramuscular route. Extracellular virulence factors such as haemolysins, cytotoxins and proteases were also investigated in supernatant fluids of cultures grown at 28°C and 37°C. The production of haemolysins, caseinases, elastases and growth yields of environmental strains decreased sharply during cultivation at 37°C but cytotoxins were produced to the same extent, or slightly less, than at 28°C. The human strains differed from the environmental strains in response to growth temperatures: protease activity decreased at 37°C, although growth yield was not affected, but more haemolysins and cytotoxins were produced by the virulent strains at this temperature than at 28°C. Sodium caseinate SDS-PAGE of culture supernatant fluids of selected human strains revealed that temperature selectively inhibited the production of certain proteases.