The effect of temperature,pH, and initial glucose concentration on the kinetics of ethanol production by Zymomonas mobilis in batch fermentation

Summary Zymomonas mobilis, strain ATCC 10988, was used to evaluate the effects of pH (5.0 to 8.0), temperature (30°C to 40°C), and initial glucose concentration (75 g/l to 150 g/l) on the kinetics of ethanol production from glucose using batch fermentation. Specific ethanol production rate was maximum and nearly constant over a pH range of 6.0 to 7.5. End-of-batch ethanol yield and specific growth rate were insensitive to pH in the range of 5.0 to 7.5. End-of-batch ethanol yield was maximum and nearly constant between 30°C and 37°C but decreased by 24% between 37°C and 40°C. All other kinetic parameters are greatest at 34°C. End-of-batch ethanol yield is maximum at an initial glucose concentration of 100 g/l. Specific growth rate reaches a maximum at 75 g/l, but specific ethanol production rate decreases throughout the range. The optimum initial glucose concentration of 100 g/l gives the highest ethanol yield at a specific ethanol production rate less than 10% below the maximum observed.     

Continuous culture of a recombinantEscherichia coli and plasmid maintenance for tryptophan production

Summary Production of tryptophan by a temperature sensitive recombinant microorganism (Escherichia coli W3110 trpLDtrpR ^ts tna ^– (pCRT185)) was investigated. In a single-stage continous culture, at an elevated temperature, 42°C (derepressed condition), tryptophan concentration increased in an early phase of the fermentation, and then gradually decreased with time. The reduction in the production rate was mostly due to the segregation of the plasmid and subsequent increase of plasmid-free cells. However, the plasmid could be maintained stable at 37°C, with repressed condition oftrp-operon, over 200 generations. A two-stage continuous culture system, i.e. cell growth was maintained in the first stage at 37°C and gene expression was induced in the second stage at 42°C, was therefore tested to improve the performance of the fermentation system. Operation of the two-stage system showed that the plasmid stability was significantly improved, and the specific rate of tryptophan production was maintained almost constant for more than 500 hours in the second stage.     

Effluent treatment by anAzotobacter sp.

Summary The effect of pH, temperature and carbon source on the specific growth rate of anAzobacter sp. was studied in nitrogen-deficient media. The optimum pH and temperature were 7.0 and 30°C respectively, with COD removal 27–85%. The strain was also used for treating effluents of a pharmaceutical industry, with 37–45% COD removal.     

Production of dextranase byLipomyces starkeyi

Summary The optimal growth rate ofLipomyces starkeyi, with dextran as sole carbon source, was found within the pH range 2.5–4.0, and temperature between 25–30°C. This yeast was unable to grow above 33°C. Dextranase production optima paralleled growth optima, except at pH 2.5. Decrease in enzyme yield at this pH could not be attributed to poor yeast growth or enzyme stability.     

Ethanol production by zymomonas mobilis: Effect of temperature on cell growth,ethanol production and intracellular ethanol accumulation

Summary The kinetic behaviour of Zymomonas mobilis is studied at temperatures from 27 °C to 34.5 °C. Increases of temperature (above a critical value) have a negative effect on the yield of ethanol, mainly by raising the maintenance coefficient. Cell growth is less inhibited by the ethanol accumulation inside the cell than is the fermentative pathway. The specific rate of ethanol production is depressed when the intracellular ethanol concentration is maximal. An increase of temperature enhances this phenomenon.     

Effect of temperature on sucrose to ethanol conversion by Zymomonas mobilis strains

Summary Two strains of Zymomonas mobilis were tested for their ability to ferment sucrose to ethanol at elevated temperatures (30–42.5°C). The optimal temperature for efficient sucrose to ethanol conversion was 35°C with 22–27 h fermentation time and 75% conversion efficiency. Increases in magnesium concentration improved one of the strains at 40°C from 38 to 76% ethanol yield efficiency.     

Comparison of the optimal culture conditions for cell growth and tissue plasminogen activator production by human embryo lung cells on microcarriers

Optimization of culture conditions such as the dissolved O₂ (DO) concentration, temperature and pH was attempted regarding both cell growth and the production of tissue plasminogen activator (TPA) in a microcarrier cell culture of human embryo lung cells. The growth rate was suppressed at a DO concentration below 30% saturation. From the pH range 7.2–7.6, both the specific growth rate and maximal cell concentration decreased. At a lower temperature than 37°C, although both the specific growth rate and the maximal cell concentration decreased, the cell concentration was maintained for a longer time during the production period, high TPA productivity being maintained. As the optimal conditions for culture growth, a DO concentration of 30% saturation or over, temperature of 37°C and pH of 7.4 are recommended. However, for TPA production after cell culture growth, the DO concentration should be in the range 20–30% O₂ saturation, and the temperature and pH should be lowered to 33°C and 6.8, respectively.     

Production of ethanol at high temperatures in the fermentation of Jerusalem artichoke juice and a simple medium byKluyveromyces marxianus

Summary Temperatures as high as 36°C and 40°C did not negatively affect the ethanol productivity of Jerusalem artichoke (J.a.) juice batch fermentation and the final concentrations of ethanol were close to those produced at lower temperatures. At higher process temperatures (36–40°C), ethanol toxicity inKluyveromyces marxianus was less important during the fermentation of J.a. juice as compared with a simple medium. In simple medium, the heat-sticking of fermentation was observed and the percentage of unfermented sugars steeply increased from 28°C up to 40°C.     

Studies on the alkalophilicStreptomyces with extracellular xylanolytic activity

Summary An alkalophilicStreptomyces which produced xylanase, isolated from soil, grew in a temperature range of 15–37°C. The pH optimum for growth was 10 and no growth occurred at pH 7. On a simple wheat bran medium the microorganism exhibited maximum enzyme secretion of 12 U/ml at pH 10. The enzyme had a broad pH optimum of 4.8–10 and the optimum temperature of 50°C. It was completely inactivated at 60°C in 2 h. The enzyme hydrolyzed xylan to a mixture of oligomeric products indicating that the main activity was of the endoxylanase type. The culture filtrate had no cellulase activity.     

The effect of temperature on the ethanol tolerance of the yeast,Saccharomyces uvarum

The optimum temperature for fermentation by Saccharomyces uvarum was found to be higher than that for its growth. Fermentation continued at temperatures above the growth maximum (40°C). S.uvarum was most resistant to growth inhibition by ethanol at temperatures 5°C and 10°C below its growth optimum (35°C). Fermentation became more resistant to ethanol inhibition with increasing temperature.     

Effect of calcium and sodium salts on ethanol production in high sugar fermentation by free cells ofZymomonas mobilis

Summary Addition of calcium carbonate enhanced ethanol production byZymomonas mobilis ZM4 and a mutant (ZMI₂), especially at higher concentrations (200–400 g/L) of glucose and sucrose, as well as at higher temperature (42°C) by the mutant. Calcium and sodium carbonates neutralized the acid produced in the medium and enhanced the ethanol production. The Na salts were less effective in the parent strain and were not favourable for the mutant. Ca²⁺ ions played a direct role in augmenting ethanol production as evidenced by the effect of calcium chloride at controlled pH (5.5).     

Halophilic n-alkane utilizing yeast from the Arabian gulf

Summary A facultative halophilic yeastTorulopsis candida (Saito) Lodder, isolated from the Arabian Gulf, was oua to grow on n-alkanes (C₁₃–C₁₉) at 37°C and pH 3–7 in media containing 1.4- 3M NaCl or 30–90% seawater. The influence of pH, temperature, growth factors, salt and pure n-alkanes on its growth were studied. Its amino acid profile and crude protein were compatible with those of commercial n-alkane yeast products.     

A new control strategy for yeast production based on the L/A* approach

Summary We studied the effect of temperature on the production of an extracellular neutral metalloproteinase of Bacillus megaterium in a laboratory fermentor under constant aeration and pH. The optimal temperature for growth (35–38° C) was higher than that for the synthesis of proteinase during exponential growth (below 31° C). The critical biomass concentration at which the exponential growth terminated decreased with increase in cultivation temperature. The specific rate of proteinase synthesis decreased when the critical biomass concentration was achieved. The observed decrease in proteinase synthesis was related to the cultivation temperature. The temperature also influenced the level of mRNA coding for proteinase. We formulated a mathematical model of cultivation describing the dependence of growth and proteinase synthesis on dissolved oxygen and temperature. The parameters of the model were identified for temperature intervals from 21 to 41° C using a computer. The optimum temperature for the enzyme production was 21° C. The productivity (enzyme activity/time) was maximal at 24–28° C. When optimizing the temperature profile of cultivation, we designed a suboptimal solution represented by a linear temperature profile. We have found that under conditions of continuous decrease in temperature, the maximal production of the proteinase was achieved at a broad range of temperature (26–34° C) when the rate of temperature decrease was 0.2–0.8° C/h. The initial optimal temperature for the enzyme productivity was in the range of 32–34° C. The optimum temperature decrease was 0.8° C/h. Offprint requests to: J. Chaloupka     

Influence of media and temperature on bacteriocin production by<Emphasis Type="Italic"> Bacillus cereus</Emphasis> 8A during batch cultivation

Cerein 8A is a bacteriocin produced by the soil bacterium Bacillus cereus 8A, isolated from native woodlands of Brazil. The influence of temperature and media on the growth of B. cereus 8A and the production of this bacteriocin was studied during batch cultivation. Maximum activity was detected by cultivation in brain/heart infusion broth, reaching 3200 activity units ml^–1. Bacteriocin was also produced in peptone, MRS, Mueller–Hinton and nutrient broth, while no activity was observed during cultivation in thioglycollate or tryptic soy broth. Temperature had a strong influence on bacteriocin production, which was higher at 30 °C than at 25 °C. An important decrease in bacteriocin activity was observed at 37 °C. The relationship between growth and specific production rates, as a function of the temperature, showed different kinetics of production and there were several peaks in the specific production rates during growth. Bacteriocin was produced at the stationary phase, indicating it is synthesized as a secondary metabolite.     

Influence of temperature on solvents production from whey

Summary The influence of temperature on solvent production from whey was investigated by using strains ofClostridium acetobutylicum andbutylicum. Higher yields of solvents were observed at 37°C or at 30°C depending on the strain used.     

Effect of temperature on plasmid stability and expression of cloned cellulase gene in a recombinantBacillus megaterium

Summary The expression of carboxymethyl cellulase gene inBacillus megaterium (pCK108) was investigated with respect to temperature in batch culture. The suboptimal temperature supporting maximal cell growth rate was determined to be 30 °C at which stability of the plasmid pCK108 could be maintained stable. However, cellular plasmid contents, production rate of cellulase of the cell, and efficiency of the gene expression increased significantly with increase of the temperature from 30 °C to 44 °C, even though the plasmid stability decreased up to 60% level at the end of the culture.     

Ethanol production from glucose byClostridium thermosaccharolyticum strains: Effect of pH and temperature

Summary The fermentation of glucose byClostridium thermosaccharolyticum strains IMG 2811^T, 6544 and 6564 was studied in batch culture in a complex medium at different temperatures in defined and free-floating pH conditions. All the strains ferment 5 g glucose.l^–1 completely. The yield of the fermentation products turned out to be independent of the incubation temperature for strain IMG 2811^T. Strain IMG 6544 produced at 60°C significantly more ethanol and less acetic acid, butyric acid, hydrogen gas and biomass than at lower temperatures. With strain IMG 6564, the opposite effect occurred: ethanol appeared to be the main fermentation product at 45°C; at 60°C less ethanol and more acetic acid, butyric acid and hydrogen gas was formed.Experiments, carried out with strain IMG 6564, at defined pH conditions (between 5.5 and 7) and different temperatures (45, 55 and 60°C) revealed no effect of the incubation temperature, but an important effect of the pH on the product formation. At pH 7, ethanol was the main fermentation product while minor amounts of hydrogen gas, acetic and butyric acid were produced. Lowering the pH gradually to 5.5 resulted in a decrease of ethanol and an increase of biomass, hydrogen gas, acetic, butyric and lactic acids. At pH higher than 7 no growth occurred. Similar conclusions could be drawn for strains IMG 2811^T and 6544.     

Selection of yeast able to produce ethanol from glucose at 40° C

Summary A total of 55 yeast strains selected from 7 genera known to ferment carbohydrates to ethanol were screened for their ability to ferment glucose to ethanol in shaken flask culture at 37°, 40° and 45°C. Yields of more than 50% of the theoretical maximum were obtained with 28 strains at 37°C, but only 12 at 40°C. Only 6 could grow at 45°C, but they produced poor yields. In general Kluyveromyces strains were more thermotolerant than Saccharomyces and Candida strains, but Saccharomyces strains produced higher ethanol yields. The 8 strains with the highest yields at 40°C were evaluated in batch fermentations. Three of these, two Saccharomyces and one Candida, were able to meet minimum commercial targets set at 8% (v/v) ethanol from 14% (w/v) glucose at 40°C.     

A cellulase-free xylanase from alkali-tolerantAspergillus fischeri Fxn1

Summary An alkali-tolerant fungusAsperqillus fischeri Fxn1 isolated from xylan enrichment grew in the pH range 5–10 and secreted an extracellular cellulase-free xylanase. Arabinose, lactose, maltose, cellobiose and glucose induced low levels of xylanase (1.8–9.0 IU/ml), whereas xylose, xylan and wheat bran induced higher level (34–45 IU/ml).CMcellulose and FPcellulose did not support growth. The optimum pH of xylanase was 6.0–6.5 and it was stable in a wide range of pH 5–9.5. The optimum temperature was 60°C and it was stable upto 55°C. The half-lives at 50 and 55 °C were 240 and 40 min. respectively. This enzyme released reducing sugars from pulp at pH 9.0 and 40°C.     

Xylanase ofChaetomium cellulolyticum: Its nature of production and hydrolytic potential

Summary Maximum xylanase production byChaetomium cellulolyticum was obtained in the culture supernatant after 30 h of growth at 37°C in basal medium containing 1% xylan at pH maintained between 6.5 and 7.5. Addition of 0.05% Tween 80 to the medium increased the enzyme production considerably. Xylanase production was found to be growth associated. The optimal conditions for enzymatic hydrolysis of xylan were found to be pH 6.0 and 50°C. During enzymatic hydrolysis, xylose, xylobiose and other xylooligosaccharides were liberated from xylan. The pH values for xylanase production and for xylan hydrolysis were closely related to the utilization of hemicelluloses of aspen wood for fungal protein production by this organism as reported in our earlier work.