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.     

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.     

Microbial reduction of ethyl acetoacetate using Sclerotium rolfsii

Summary A method for the quantitative enantioselective bioreduction of ethyl acetoacetate [1] to optically pure (+)-S-ethyl-3 hydroxybutyrate [II] usingSclerotium rolfsii mycelium is described. In a synthetic medium 1 g mycelium (dry weight) could convert 1 g of I to II within 2–3 days of fermentation (pH 5.8, 30°C). This is the first report demonstrating use ofS. rolfsii biomass for asymmetric reduction to get chiral building blocks.     

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.     

Kinetic behavior of Candida rugosa in the batch fermentation of sugar beet stillage; Temperature dependence of growth and flocculation characteristics

Summary The aerobic fermentation of sugar beet stillages to yeast biomass was carried out byC.rugosa at 20, 30, and 40°C. At 40°C,C.rugosa grew faster with corresponding COD-reduction, and showed better flocculation characteristics.     

Production of acetone - butanol from acid whey

Summary Clostridium acetobutylicum ATCC 824 was used to produce butanol and acetone by fermenting acid whey. Results showed that both autoclaving and agitation played roles in solvent production. Maximum production was obtained in 120 h using autoclaved, pH adjusted (6.0) acid whey at 37 °C in a fermentor that was not agitated.     

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.     

Novel supplements enhance the ethanol production in cane molasses fermentation by recycling yeast cell

Summary Eight alcohol producing yeast strains were screened for their sedimentation rates and it was found thatS.cerevisiae NCIM 3526 was a better flocculant strain. This strain was employed in cane molasses fermentation with yeast recycle, supplemented with skim milk, chitin and fungal mycelium individually or in combination, at 30°C, using fermentable sugars 15%. On the completion of ten 16 h cycles, 20–30% more ethanol was produced in presence of these supplements and the efficiency of the process was improved from 66 to 87%.     

Inhibition of psychrotrophic bacteria in raw milk by immobilized lactic acid bacteria

Summary Cells ofLactococcus lactis orLactobacillus helveticus were immobilized in calcium-alginate beads, added to raw milk, and incubated 48 h at 7°C. The addition of 2.7×10⁷ immobilizedLc.lactis or 13×10⁷ immobilizedLb. helveticus cells per mL reduced the development of the psychrotrophic bacteria of raw milk by approximately 50%. The pH of the raw milk dropped 0.10 to 0.22 units under these conditions. Periodic agitation of the seeded raw milk increased the inhibitory activity of the immobilized lactic acid bacteria (LAB). Free LAB cells in the system were only of 0.5% of total LAB. The use of immobilized LAB to inhibit psychrotrophic bacteria might be extended to raw milks destined to the manufacture of non-fermented dairy products.     

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.     

Induction of freezing tolerance in microspore-derived embryos of winter Brassica napus

Freezing tolerance was induced in microspore derived embryos of winter Brassica napus cv. Jet neuf by the addition of ABA or mefluidide to the culture media during embryogenesis. Survival after freezing was estimated by culture of frozen-thawed embryos to plantlets. A higher freezing tolerance (50% survival at –15°C) was induced when 50 M ABA or 3.2 M mefluidide was incorporated initially into the medium during embryogenesis at 25°C followed by culture at 2°C for 3 weeks. When embryos were induced in the absence of ABA or mefluidide and maintained at 2°C for even as long as 12 weeks a lower degree of freezing tolerance (10% survival at –15°C) was obtained. Plants regenerated from embryos hardened maximally by a combination of either ABA or MFD with low temperature did not require further vernalization for flowering.Abbreviations ABA abscisic acid - MFD mefluidide - 2,4-D 2,4-dichlorophenoxyacetic acid - LT₅₀ killing temperature for 50% of the embryos     

Top and bottom yeasts together accelerate ethanol production in molasses fermentation

Summary Alcohol producing top and bottom yeasts were employed individually and together to assess their role in enhancing the rate of ethanol production, in cane molasses fermentation, at 30°C. The combination of top yeastS.cerevisiae NCIM 3281, and bottom yeastS.uvarum NCIM 3509, improved the enthanol production rate by 32.6% in batch fermentation and 25.2% in recycling yeasts cell fermentation as compared to their mean value of individual ethanol production activity.     

Temperature effects in ethanol fermentation high corn media

Summary A relationship between temperature and high ethanol yields has been found using whole corn mashes saccharified with Aspergillus oryzae wheat bran koji. Decreased ethanol yields were obtained at 34.5°C with high concentration corn mashes in contrast to high ethanol yields with the same medium at lower temperatures. The decreased yields appear to be related to mass and/or heat transfer problems rather than primary ethanol toxicity. Scale-up of the high corn medium will require a re-evaluation of alcohol fermentation technology.     

Development of a fermentation procedure to produce a tempe-related food using common beans as substrate

Summary A basic procedure was developed to produce a tempe-like product using the mouldRhizopus oligosporus and black common beans (Phaseolus vulgaris) as substrate. The initial pH of the substrate was 5.8, and fermentation was conducted at 37°C with a relative humidity of 70% for 72 hrs. Levels of soluble solids and soluble protein increased dramatically as a result of fermentation. Some changes were as well observed in fatty acid contents of fermented samples. It was concluded that the common bean used was an acceptable substrate for preparing this product.     

Effect of temperature upon growth rate and solvent production in batch cultures ofClostridium acetobutylicum

Summary The effect of temperature on the solvent production byClostridium acetobutylicum has been studied in the range 25 to 40°C. It was found that the solvent yield decreased with increasing temperature; seemingly because of a reduction in acetone production. It appeared that the yield of the other major solvent, butanol, was not affected by the temperature. Considering total solvent yield and productivity only, the optimum fermentation temperature is 35°C.     

The effect of temperature on the kinetics of ethanol production by a thermotolerant strain of Kluveromyces marxianus

Summary The batch fermentation kinetics of a novel thermotolerant strain of the yeast Kluveromyces marxianus were evaluated between 30°C and 48°C. The most significant effects of elevated temperature were reductions in overall biomass and ethanol yields. Decreases in the concentration of ethanol attained, and the presence of unutilized substrate suggested increased ethanol inhibition at the higher temperatures studied.     

Studies on xylan degrading enzyme from Chainia

Summary The sclerotial actinomycete Chainia (NCL 82-5-1) secreted extracellular xylanase in submerged culture in media containing yeast extract and wheat bran or commercial xylan. A high activity (28 IU/ml) of xylanase was obtained in 72 h on a medium containing 3% xylan. Only a single species of xylanase (i.e. without isoenzymes) was detected by polyacrylamide gel electrophoresis. It had an optimum pH of 5.0 and optimum temperature of 65°C. It was stable at pH 6.0 to heating at 60°C for 10 min. Its pI was 8.0 and the K_m was 0.4%. The results are discussed in relation to xylanase reported from actinomycetes such as Streptomyces xylophagus.     

Isolation and improvement of a thermotolerant Saccharomyces cerevisiae strain

The ambient temperature is a drawback in industrial ethanol production in Jaffna due to heat killing of yeast during fermentation. Thus a search was initiated for thermotolerant organisms suitable for fermentation in hot climates. The screening of the best wild-type organisms was undertaken as the first step. Thermotolerant strains were selected from environments where there are chances of organisms being exposed to high temperature. The samples were enriched and screened for thermotolerant organisms which survived at 45 °C for 15 h. Among the yeast strains selected from different sources, thermotolerant strains with the capacity to withstand 45 °C for 15 h were found in samples collected from the compost heap and distillery environments. Three colonies from the distillery environment were selected for further studies and named p1, p2 and p3. Exponential phase (18 h) cultures of p1, p2 and p3 were subjected to 15 temperature treatment cycles (at 50 °C each for 3 h) and thermally adapted strains pt1, pt2 and pt3 were obtained, showing 100, 30 and 20% viability at 50 °C for 30 min respectively. The initial round of thermal adaptation cycles increased the duration of 100% viability from 20 h (p1) to 68 h (pt1) when incubated at 40 °C. Very little benefit was obtained when pt1 was treated with u.v. and ethyl methanesulphonate. The selected strain was identified and designated as Saccharomyces cerevisiae S1. The ethanol produced from 100 g glucose l^–1 by S. cerevisiae S1 was 46 g l^–1 (36 h), 38 g l^–1 (48 h) and 26 g l^–1 (48 h) at 40, 43 and 45 °C respectively in rich nutrient medium.     

Growth conditions of a pectinolyticAspergillus fumigatus for degumming of natural fibres

Summary Optimum growth conditions forA. fumigatus strain 4 when citric pectin was the sole carbon source were at a temperature of 45°C, pH 4.0 and an incubation time from 36 to 42h. Under these conditions no cellulase activity was found. When orange pulp was the sole carbon source, optimum polygalacturonase activities were found when the fungus was cultured for 36 h at 45°C and a pH 3.0 to 4.5.     

Optimization of S-adenosyl-L-methionine production by Kluyveromyces lactis on whey in batch culture using a mathematical model

Growth, lactose utilization and S-adenosyl-l-methionine (AdoMet) production by Kluyveromyces lactis AM-65 on whey in batch fermentation were investigated and an unstructured model of the process has been derived. The optimal set of parameters was estimated by fitting the model to experimental results. After incubation for 20 h the optimal fermentation conditions (28.5 °C, pH 5.3, agitation at 270 rpm) resulted in AdoMet production at 1.55 g l^–1.