Anhydrobiosis in yeast: is it possible to reach anhydrobiosis for yeast grown in conditions with severe oxygen limitation?

The yeast Saccharomyces cerevisiae was shown to be extremely sensitive to dehydration–rehydration treatments when stationary phase cells were subjected to conditions of severe oxygen limitation, unlike the same cells grown in aerobic conditions. The viability of dehydrated anaerobically grown yeast cells never exceeded 2 %. It was not possible to increase this viability using gradual rehydration of dry cells in water vapour, which usually strongly reduces damage to intracellular membranes. Specific pre-dehydration treatments significantly increased the resistance of anaerobic yeast to drying. Thus, incubation of cells with trehalose (100 mM), increased the viability of dehydrated cells after slow rehydration in water vapour to 30 %. Similarly, pre-incubation of cells in 1 M xylitol or glycerol enabled up to 50–60 % of cells to successfully enter a viable state of anhydrobiosis after subsequent rehydration. We presume that trehalose and sugar alcohols function mainly according to a water replacement hypothesis, as well as initiating various protective intracellular reactions.     

Effect of xylitol and trehalose on dry resistance of yeasts

The effects of dehydration/rehydration on two strains of Saccharomyces cerevisiae: S600, a metabolically engineered xylose-utilising strain, and H158, the non-xylose-utilising host strain; and on the naturally xylose-utilising yeast Pachysolen tannophilus CBS 4044, were compared after glucose and xylose utilisation respectively. The yeast strains differed in their ability to excrete and accumulate intracellular xylitol. A high intracellular xylitol content before and after dehydration coincided with a higher viability after a dehydration/rehydration cycle. The intracellular trehalose content increased during dehydration in all three yeast strains, but this did not correspond to enhanced cell viability after dehydration/rehydration. The results are discussed in relation to the ability of xylitol and trehalose to structure water. Received: 9 July 1996 / Received revision: 29 October 1996 / Accepted: 2 November 1996     

Effect of cultivation conditions on trehalose content and viability of brewing yeast following preservation via filter paper or lyophilization methods

The effects of variations in cultivation conditions on trehalose concentration and the viability of brewing yeasts following preservation by filter paper or lyophilization methods were evaluated. In case of filter paper preservation, the cultivation period had no affect on yeast viability, while agitation and aeration during cultivation had a positive effect regarding viability of the bottom-fermenting strains, Rh and Frank. For effective preservation, it was necessary to harvest yeast cells from the stationary phase during cultivation. For lyophilization preservation, the yeast strains tested showed a negative effect on viability, independent of strain or cultivation method. No significant correlation was found between trehalose concentration and yeast viability following either filter paper or lyophilization preservation. However, the filter paper preservation method was suitable for both bottom and top brewing yeast strains with regard to feasibility, viability, and maintenance of the yeast’s specific character.     

Effects of trehalose on stress tolerance and biocontrol efficacy of Cryptococcus laurentii

AIMS: To investigate the effects of internal trehalose on viability and biocontrol efficacy of antagonistic yeast Cryptococcus laurentii under stresses of low temperature (LT), controlled atmosphere (CA) and freeze drying. METHODS AND RESULTS: The content of trehalose in C. laurentii was increased by culturing the yeast in trehalose-containing medium. Compared with yeast cells with low trehalose level, the yeast cells with high level of internal trehalose not only obtained higher viability, but also showed higher population and better biocontrol efficacy against Penicillium expansum on apple fruit both at 1 degrees C and in CA condition (5% O(2), 5% CO(2), 1 degrees C). After freeze drying, survival of the yeast with high trehalose level was markedly increased when stored at 25 degrees C for 0, 15 and 30 days. Meanwhile, high integrity of plasma membrane was detected in the freeze-dried yeast with high trehalose level by propidium iodide staining. CONCLUSIONS: Induced accumulation of internal trehalose could improve viability and biocontrol efficacy of C. laurentii under stresses of LT and CA. Moreover, survival of the yeast was also increased as internal trehalose accumulation after freeze drying, and one of the reasons might be that trehalose gave an effective protection to plasma membrane. SIGNIFICANCE AND IMPACT OF THE STUDY: The results of this experiment show a promising way to improve the biocontrol performance of antagonistic yeasts under the commercial conditions.     

Trehalose as cryoprotectant for preservation of yeast strains

Preservation of genetic banks of yeast strains as well as of any kind of eukaryotic cells during dehydration and subsequent rehydration depends upon the maintenance of the integrity of the cell membrane. Trehalose has been successfully used as a non-toxic cryoprotectant for plant cells (Bhandal et al., 1985), as well as for lobster sarcoplasmic vesicles (Rudolph and Crowe, 1985). The hypothesis underlying these observations is that the disaccharide avoids fusion of membranes by replacing water molecules in the bilayer (Crowe et al., 1984). The viability of yeast strains submitted to different drying techniques is reported in this paper. Mutant strains with defects in the regulation of the trehalose-6-phosphate synthase complex were compared. Yeast strains dried in layers at 37°C for 6 h did not lose their viability, however, they died thereafter at 5°C, unless trehalose was used for resuspending the cells before drying. It should be noted that no trehalose accumulation was seen during drying at 37°C under our experimental conditions. In experiments in which cells were frozen at −120°C, addition of 10% trehalose to the suspending buffer had a significant protective effect. On the other hand, a mutant strain with an extremely high trehalose-6-phosphate synthase activity showed an intrinsic capacity for survival which did not depend upon addition of exogenous trehalose. This raises the question of the location of the internal trehalose pool and whether it could replace the externally added cryoprotectant.     

Trehalose synthase and trehalase behaviour in yeast cells in anhydrobiosis and hydrobiosis

• 1.I. Trehalose synthase and trehalase behaviour has been analysed in cultured yeast cells isolated from baker's yeast to increase the understanding of the mechanisms involved in trehalose content modifications observed in anyhydrobiois and hydrobiosis.
• 2.2. After desiccating yeast cells to a constant weight, trehalose levels sharply increased, whereas the glycogen content decreased, trehalose synthase was stimulated and trehalase was significantly inhibited.
• 3.3. In desiccated cells after a rehydration for 15 min, trehalose levels dropped, the glycogen content further decreased, the activity of trehalose synthase declined while that of trehalase was dramatically stimulated.
• 4.4. After rehydration for 12hr, while the trehalose and glycogen content decreased even more, the behaviour of the two enzymes was completely reversed, trehalose synthase being activated and trehalase inhibited.
• 5.5. The reasons for such impressive enzyme activity alterations in desiccated and rehydrated cells for the moment remain unknown.

     

Freeze-drying of live attenuated Vibrio anguillarum mutant for vaccine preparation

Vibrio anguillarum MVAV6203 is a mutant strain as a candidate of live attenuated vaccine. In vaccine preparation, the freeze-drying conditions of the strain were investigated to improve the survival after freeze-drying, including the protectant, rehydration medium, freezing temperature, and initial cell concentration. Vibrio anguillarum MVAV6203 is sensitive to freeze-drying and the viability was only 0.03% in the absence of protectant. Of the tested protectants, 5% trehalose with 15% skimmed milk gave the highest viability of 34.2%. Higher cell survival was obtained by quick freezing at -80 degrees C than slow freezing at -20 degrees C. Initial cell concentration was another important factor, preferable for 1-3 x 10(10)CFU/ml. The supplementation of 10% skimmed milk in rehydration medium improved obviously freeze-drying viability. The combination of the optimal conditions achieved 51.4% cell viability after freeze-drying.     

Optimisation and comparison of liquid and dry formulations of the biocontrol yeast <Emphasis Type="Italic">Pichia anomala</Emphasis> J121

The biocontrol yeast Pichia anomala J121 can effectively reduce mould growth on moist cereal grains during airtight storage. Practical use of microorganisms requires formulated products that meet a number of criteria. In this study we compared different formulations of P. anomala. The best way to formulate P. anomala was freeze-drying. The initial viability was as high as 80%, with trehalose previously added to the yeast. Freeze-dried products could be stored at temperatures as high as 30 °C for a year, with only a minor decrease in viability. Vacuum-drying also resulted in products with high storage potential, but the products were not as easily rehydrated as freeze-dried samples. Upon desiccating the cells using fluidised-bed drying or as liquid formulations, a storage temperature of 10 °C was required to maintain viability. Dependent on the type of formulation, harvesting of cells at different nutritional stresses affected the initial viabilities, e.g. the initial viability for fluidised-bed-dried cells was higher when the culture was fed with excess glucose, but for freeze-drying it was superior when cells were harvested after depletion of carbon. Using micro-silos we found that the biocontrol activity remained intact after drying, storage and rehydration for all formulations.     

Factors affecting the survival of Bradyrhizobium applied in liquid cultures to soya bean [Glycine max (L.) Merr.] seeds

AIMS: To determine the impact of medium composition, bacterial strain, trehalose accumulation, and relative humidity during seed storage on the survival of Bradyrhizobium japonicum on soya bean [Glycine max (L.) Merr.] seeds. METHODS AND RESULTS: Bacteria in liquid cultures were applied to seeds, and the number of survivors was quantified after 2, 24, 48, or 96 h. Addition of yeast extract to a defined medium increased on-seed survival 50- to 80-fold. Addition of 40 mmol l(-1) of NaCl to the medium doubled or tripled the accumulation of trehalose in cells and increased survival several fold, and the addition of both salt and trehalose had an additive effect. There was a threefold difference among strains in survival, and survival of the various strains was significantly correlated with differences in the accumulation of trehalose. The correlation between trehalose accumulation by bacteria and survival was also highly significant in other experiments. Studies in controlled humidity environments showed 100-fold or more differences in survival. CONCLUSIONS: The consistently significant correlation of trehalose content of cells with survival on seed suggests that trehalose is an important component of the survival mechanisms. When some of the factors (salt and trehalose in the medium plus humidity control) were studied in combination, several 100-fold increases in survival of bacteria on seeds were recorded. SIGNIFICANCE AND IMPACT OF THE STUDY: It is possible by manipulation of several parameters--strain selection, salt and trehalose content of the medium, control of relative humidity--to achieve substantial improvements in survival of Bradyrhizobium on soya bean seeds.     

Controlling the membrane fluidity of yeasts during coupled thermal and osmotic treatments

Yeasts are often exposed to variations in osmotic pressure in their natural environments or in their substrates when used in fermentation industries. Such changes may lead to cell death or activity loss. Previous work by our team has allowed us to relate the mortality of cells exposed to a combination of thermal and osmotic treatments to leakage of cellular components through an unstable membrane when lipid phase transition occurs. In this study, yeast viability was measured after numerous osmotic and thermal treatments. In addition, the fluidity of yeast membranes was assessed according to a(w) and temperature by means of 1,6-diphenyl-1,3,5-hexatriene (DPH) anisotropy measurement. The results show that there is a negative correlation between the overall fluidity variation undergone by membranes during treatments and yeast survival. Using a diagram of membrane fluidity according to a(w) and temperature, we defined dehydration and rehydration methods that minimize fluidity fluctuations, permitting significantly increased yeast survival. Thus, such membrane fluidity diagram should be a potential tool for controlling membrane state during dehydration and rehydration and improve yeast survival. Overall fluidity measurements should now be completed by accurate structural analysis of membranes to better understand the plasma membrane changes occurring during dehydration and rehydration.     

Levels of Glycogen and Trehalose in Mycobacterium smegmatis and the Purification and Properties of the Glycogen Synthetase

The levels of glycogen, free trehalose, and lipid-bound trehalose were compared in Mycobacterium smegmatis grown under various conditions of nitrogen limitation. In a mineral salts medium supplemented with yeast extract and containing fructose as the carbon source, the accumulation of glycogen increased dramatically as the NH(4)Cl content of the medium was lowered. However, levels of free trehalose remained relatively constant. Cells were grown in low nitrogen medium and were then shifted to medium containing high nitrogen. Under these conditions, there was a rapid accumulation of glycogen in low nitrogen, and this glycogen was rapidly depleted when cells were placed in high nitrogen medium. Again the concentration of free trehalose remained fairly constant. However, when cells were grown in low nitrogen medium with [(14)C]fructose and then transferred to high nitrogen medium with unlabeled fructose, the specific radioactivity (counts per minute per micromole) of the free trehalose fell immediately, indicating that it was being synthesized and turned over continually. On the other hand, the specific radioactivity of the glycogen and bound trehalose declined much more slowly, suggesting that these two compounds were not turning over as rapidly or were being synthesized at a much slower rate. Experiments on the incorporation of [(14)C]fructose into glycogen and trehalose indicated that cells in high nitrogen medium synthesized much less glycogen than those in low nitrogen. However, synthesis of both free trehalose and bound trehalose was the same in both cases. The specific enzymatic activities of the glycogen synthetase and the trehalose phosphate synthetase varied somewhat from one growth condition to another, but there was no correlation between enzymatic activity and the amount of glycogen or trehalose, suggesting that changes in glycogen levels were not due to increased synthetic capacity. The glycogen synthetase was purified about 35-fold and its properties were examined. This enzyme was specific for adenosine diphosphate glucose as the glucosyl donor.     

Commercial baker's yeast stability as affected by intracellular content of trehalose, dehydration procedure and the physical properties of external matrices

The effects of vacuum-drying and freeze- drying on the cell viability of a commercial baker's yeast, Saccharomyces cerevisiae, strain with different endogenous contents of trehalose were analyzed. An osmotolerant Zygosaccharomyces rouxii strain was used for comparative purposes. Higher viability values were observed in cells after vacuum-drying than after freeze-drying. Internal concentrations of trehalose in the range 10–20% protected cells in both dehydration processes. Endogenous trehalose concentrations did not affect the water sorption isotherm nor the T _g values. The effect of external matrices of trehalose and maltodextrin was also studied. The addition of external trehalose improved the survival of S. cerevisiae cells containing 5% internal trehalose during dehydration. Maltodextrin (1.8 kDa) failed to protect vacuum-dried samples at 40 °C. The major reduction in the viability during the freeze-drying process of the sensitive yeast cells studied was attributed to the freezing step. The suggested protective mechanisms for each particular system are vitrification and the specific interactions of trehalose with membranes and/or proteins. The failure of maltodextrins to protect cells was attributed to the fact that none of the suggested mechanisms of protection could operate in these systems. Received: 6 December 1999 / Received revision: 8 May 2000 / Accepted: 19 May 2000     

A dual role for intracellular trehalose in the resistance of yeast cells to water stress.

It is well known that yeast cells survive environmental stresses such as desiccation and freezing and there is evidence that these phenomena may be related to the presence of trehalose in the cells. However, the molecular mechanism by which trehalose might exert an influence on cell functions remains unknown. In this report, thermogravimetry and differential thermal analysis were used to estimate the amount of bound water in yeast cells. It is shown that when the trehalose content is greater than 2-3% of the cell dry weight, the amount of bound water is drastically decreased and the viability of the dried cells is increased. This implies that a major portion of the bound water is replaced by trehalose. In addition, measurements of the NMR spin-lattice relaxation time of the intracellular water protons show that trehalose acts as a water-structuring agent in hydrated yeast cells. This dual role is essential for high resistance to water stress in yeast cells.     

Effects of ice-seeding temperature and intracellular trehalose contents on survival of frozen Saccharomyces cerevisiae cells

Freezing tolerance is an important characteristic for baker’s yeast, Saccharomyces cerevisiae, as it is used to make frozen dough. The ability of yeast cells to survive freezing is thought to depend on various factors. The purpose of this work was to study the viability of yeast cells during the freezing process. We examined factors potentially affecting their survival, including the growth phase, ice-seeding temperature, intracellular trehalose content, freezing period, and duration of supercooling. The results showed that the ice-seeding temperature significantly affected cell viability. In the stationary phase, trehalose accumulation did not affect the viability of yeast cells after brief freezing, although it did significantly affect the viability after prolonged freezing. In the log phase, the ice-seeding temperature was more important for cell survival than the presence of trehalose during prolonged freezing. The importance of increasing the extracellular ice-seeding temperature was verified by comparing frozen yeast survival rates in a freezing test with ice-seeding temperatures of −5 °C and −15 °C. We also found that the cell survival rates began to increase at 3 h of supercooling. The yeast cells may adapt to subzero temperatures and/or acquire tolerance to freezing stress during the supercooling.     

Physiological manipulation and formulation of the biocontrol yeast Pichia anomala for control of Penicillium verrucosum and ochratoxin A contamination of moist grain

The major hurdle in the production of commercial biocontrol agents (BCAs) has been the lack of production of appropriate formulations. Of particular importance is the conservation of viability and ecological competence after application. With this in mind studies were conducted to develop formulations of P. anomala which would have these attributes. Cells were grown in molasses-based medium modified with proline to different water availability levels (0.98 and 0.96) which significantly increased (up to 50%) the content of trehalose and arabitol in the yeast cells during liquid broth fermentation. The use of isotonic solutions for harvesting the yeast cells further increased the endogenous content of these compatible solutes as well as glycerol. Fluidised bed drying of cells at 30–80°C was carried out for 10 and 20 min and showed that viability was significantly decreased at 70–80°C. A temperature of 50°C for 20 min was found to be best for viability (70%) and moisture content of <10%. Several additives for conservation of viability showed that cotton seed flour+skimmed milk was the best treatment when dried at 50°C. The biocontrol efficacy of formulated P. anomala cells was tested in laboratory scale studies and this showed that they inhibited growth of Penicillium verrucosum and reduce ochratoxin A production in moist wheat grain under some combinations of water availability. Physiologically modified formulated yeast cells with increased levels of trehalose and arabitol gave similar efficacy as fresh cells. This suggests that ecophysiological manipulation of such BCAs can result in improved ecological competence of such formulations and effective biocontrol.     

Trehalose accumulation from soluble starch by Saccharomycopsis fibuligera sdu

Trehalose accumulation from starch by Saccharomycopsis fibuligera sdu was examined in 300-ml shaken flask culture and Biostat B(2) 2-1 fermentation. In the 300-ml flask, 16.5% (w/w) trehalose accumulated in the yeast cells (cell dry weight) was observed with 100-ml medium shaken at 200 rpm for 50 h at 30 degrees C. We found that 1.0% soluble starch in the medium was most suitable for trehalose accumulation by this yeast strain. In the Biostat B(2) 2-1 fermentor, 18.0% (w/w) trehalose accumulated in the yeast cells (cell dry weight) was observed within 48 h of fermentation when agitation speed was 200 rpm. The trehalose obtained from the yeast cells was identical to standard trehalose from Sigma based on the analysis results of High-Performance Exchange Anionic Chromatography (HPEAC).     

Effect of intracellular trehalose in Cryptococcus laurentii and exogenous lyoprotectants on its viability and biocontrol efficacy on Penicillium expansum in apple fruit

AIMS: To improve viability and biocontrol efficacy of Cryptococcus laurentii after freeze drying and in subsequent storage. METHODS AND RESULTS: Viability of C. laurentii was improved after freeze drying and in subsequent storage at 4 or 25 degrees C by using skimmed milk (SM) and sugars (glucose, galactose, sucrose and trehalose) as protectants. Sugars and SM mixed together showed better protection than when they were used separately. Citric acid used as carbon source could induce accumulation of intracellular trehalose in the yeast. The yeast cells with high trehalose level (HT cells) had higher viability than those with low trehalose level (LT cells) after freeze drying and storage for 90 days. After storage for 90 days at 4 degrees C, the HT cells plus SM and sugars as protectant showed a similar biocontrol effect against blue mould rot in apple fruit caused by Penicillium expansum as fresh cells. CONCLUSIONS: Increasing intracellular trehalose content of C. laurentii and adding exogenous protectant (sugars + SM) could improve its viability and maintain its biocontrol efficacy. SIGNIFICANCE AND IMPACT OF THE STUDY: The results have a potential value for commercial application of C. laurentii.     

克鲁氏假丝酵母在高渗环境中海藻糖和胞内甘油积累的研究

Brown[1]在1976年提出了相容溶质(Compatible solutes)的概念,尽管有关它们功能的确切机制尚不是非常清楚,但是通常它们被认为是具有渗透调节作用和对细胞中生物活性物质具保护功能的物质.海藻糖和甘油在这方面所表现出的特殊功能已被国内外广泛关注[2].Brown[3]和Crowe[4]还分别报道了甘油和海藻糖在保护胞内可溶性酶和细胞膜稳定性方面的功能.Crowe[5]在研究几种不同碳水化合物对动物肌细胞的保护功能时发现,海藻糖和甘油都在不同程度上表现出这种特性.关于酵母细胞在加盐培养基中的生长代谢情况Kuniho Nakata[6]和Sukesh [7]分别进行了报道,发现酵母细胞内有海藻糖的积累,并且海藻糖的量与细胞对外界不利环境的耐受性有密切关系.     

The Structure of Destruxin B,a Toxic Metabolite of Oospora destructor

The viability of freeze-dried Lactobacillus bulgaricus B-1 was affected by rehydration temperature, and maximum recovery of the viable cells was obtained when they were rehydrated at 20 to 25°C. Cellular ribonucleotides leaked out from the freeze-dried cells during rehydration, but there was no correlation between the viability of cells and the amount of leaked substances. Rehydration of the freeze-dried cells in the presence of RNase caused marked loss of viability. These results suggest that the cell surface was damaged by freeze-drying and its selective permeability was lost to some extent.     

Action of trehalose on the preservation of Lactobacillus delbrueckii ssp. bulgaricus by heat and osmotic dehydration

AIM: This work determines the efficiency of trehalose on the preservation by heat or osmotic drying of a strain of Lactobacillus delbrueckii ssp. bulgaricus. Cell recovery at different trehalose concentrations during drying correlated with the surface properties and osmotic response of cells after rehydration. METHODS AND RESULTS: Bacteria were dried in the presence of glycerol, trehalose, sucrose at 70 degrees C and at 20 degrees C. Trehalose attenuates the loss of viability at 0.25 m. At this concentration, the osmotic response and zeta potential of the bacteria were comparable with the nondried ones. CONCLUSIONS: Trehalose diminishes significantly the damage produced by dehydration both when the bacteria are dried by heating or subjected to osmotic dehydration. This effect appears related to the preservation of the permeability to water and the surface potential of the bacteria. SIGNIFICANCE AND IMPACT OF THE STUDY: Dehydration occurring during heating or during osmosis appears to have similar effects. As dehydration-induced damage is in correlation with osmotic response recovery and is hindered or buffered by the presence of trehalose, it may be related to water eliminated from biological structures involved in water permeation.