Effect of sugars and growth media on the dehydration of Lactobacillus delbrueckii ssp. bulgaricus

AIMS: The efficiency of trehalose, sucrose and maltose to protect Lactobacillus bulgaricus during drying has been evaluated in bacteria grown at low water activity. METHODS AND RESULTS: Bacteria were grown in MRS (control), and in MRS supplemented with sucrose (MRS-sucrose) or with polyethyleneglycol (PEG) (MRS-PEG) as low water activity media. The growth in low water activity media (MRS-sucrose and MRS-PEG) prior to drying enhanced the effectiveness of trehalose as thermoprotectant during drying. The efficiency of sucrose was improved when bacteria were grown in MRS-sucrose. On the other hand, the growth in both low water activity media did not affect the efficiency of maltose. The damage produced during dehydration has been evaluated by means of growth kinetics in milk. The preservation of bacteria dehydrated with sucrose, after growing them in MRS-sucrose, appears to be as efficient as the dehydration with trehalose. CONCLUSIONS: The growth of L. bulgaricus in low water activity media enhances the protective action of trehalose and sucrose. SIGNIFICANCE AND IMPACT OF THE THE STUDY: These results may aid the dairy industry to improve the recovery of the starters at low costs after preservation processes.     

Beneficial effect of intracellular trehalose on the membrane integrity of dried mammalian cells

Recently, there has been much interest in using trehalose and other small carbohydrates to preserve mammalian cells in the dried state as an alternative to cryopreservation. Here, we report on the successful preservation of plasma membrane integrity after drying, as a first step toward full preservation of mammalian cells. Trehalose was introduced into cells using a genetically engineered version of alpha-hemolysin, a pore-forming protein; the cells were then dried and stored for weeks at different temperatures with approximately 90% recovery of the intact plasma membrane. We show that protection of the plasma membrane by internal trehalose is dose dependent and estimate the amount of internal trehalose required for adequate protection to be approximately 10(10) molecules/cell. In addition, a minimal amount of water (approximately 15 wt%) appears to be necessary. These results show that a key component of mammalian cells can be preserved in a dried state for weeks under mild conditions (-20 degrees C and 5% relative humidity) and thereby suggest new approaches to preserving mammalian cells.     

State transitions and physicochemical aspects of cryoprotection and stabilization in freeze-drying of Lactobacillus rhamnosus GG (LGG)

Aims: The frozen and dehydrated state transitions of lactose and trehalose were determined and studied as factors affecting the stability of probiotic bacteria to understand physicochemical aspects of protection against freezing and dehydration of probiotic cultures. Methods and Results: Lactobacillus rhamnosus GG was frozen (–22 or –43°C), freeze‐dried and stored under controlled water vapour pressure (0%, 11%, 23% and 33% relative vapour pressure) conditions. Lactose, trehalose and their mixture (1 : 1) were used as protective media. These systems were confirmed to exhibit relatively similar state transition and water plasticization behaviour in freeze‐concentrated and dehydrated states as determined by differential scanning calorimetry. Ice formation and dehydrated materials were studied using cold‐stage microscopy and scanning electron microscopy. Trehalose and lactose–trehalose gave the most effective protection of cell viability as observed from colony forming units after freezing, dehydration and storage. Enhanced cell viability was observed when the freezing temperature was ?43°C. Conclusions: State transitions of protective media affect ice formation and cell viability in freeze‐drying and storage. Formation of a maximally freeze‐concentrated matrix with entrapped microbial cells is essential in freezing prior to freeze‐drying. Freeze‐drying must retain a solid amorphous state of protectant matrices. Freeze‐dried matrices contain cells entrapped in the protective matrices in the freezing process. The retention of viability during storage seems to be controlled by water plasticization of the protectant matrix and possibly interactions of water with the dehydrated cells. Highest cell viability was obtained in glassy protective media. Significance and Impact of the Study: This study shows that physicochemical properties of protective media affect the stability of dehydrated cultures. Trehalose and lactose may be used in combination, which is particularly important for the stabilization of probiotic bacteria in dairy systems.     

Air drying optimization of Saccharomyces cerevisiae through its water-glycerol dehydration properties

AIMS: This study describes the different stages of optimization in an original drying process for yeasts, which allows the retrieval of dried samples of Saccharomyces cerevisiae CBS 1171 with maximum viability. METHODS AND RESULTS: The process involves the addition of wheat flour to yeast pellets, followed by mixing and then air-drying in a fluidized bed dryer. The sensitivity to the osmotic stress was first studied in a water-glycerol solution and the observed results were then applied to the drying process. This study have shown that the yeast was quite resistant to osmotic stress and pointed out the existence of zones of sensitivity where viability dramatically decrease as function of final osmotic pressure and temperature of the treatment. Thus, for dehydration until low osmotic pressure (133 MPa, i.e. a(w) = 0.38) results have shown that viability was better when temperature of the treatment was less than 8 degrees C or higher than 25 degrees C. Moreover, kinetic of dehydration was found to greatly influence cells recovery. CONCLUSIONS: These observations allowed the choice of parameters of dehydration of yeasts with an original drying process which involve the mix of the yeasts with wheat flour and then drying in a fluidized bed. SIGNIFICANCE AND IMPACT OF THE STUDY: This process dried rapidly the yeasts to less than 220 MPa (aw < or = 0.2) with whole cell recovery and good fermentative capabilities.     

Osmotically induced intracellular trehalose, but not glycine betaine accumulation promotes desiccation tolerance in Escherichia coli

Trehalose considerably increased the tolerance of Escherichia coli to air drying, whether added as an excipient prior to drying or accumulated as a compatible solute in response to osmotic stress. The protective effect of exogenously added trehalose was concentration dependent, up to a threshold value of 350 mM. However, trehalose alone cannot explain the intrinsically greater desiccation tolerance of stationary compared to exponential phase E. coli cells, although their tolerance was also enhanced by exogenous or endogenously accumulated trehalose. In contrast, glycine betaine whether added as an excipient or accumulated intracellularly had no influence on desiccation tolerance. These data demonstrate that the protection provided by compatible solutes to cells subjected to desiccation differs from that during osmotic stress, due to the much greater reduction in available cell water. The protective effects of trehalose during desiccation appear to be due to its stabilising influence on membrane structure, its chemically inert nature and the propensity of trehalose solutions to form glasses upon drying, properties which are not shared by glycine betaine.     

Volume recovery, surface properties and membrane integrity of Lactobacillus delbrueckii subsp. bulgaricus dehydrated in the presence of trehalose or sucrose

AIMS: Although the practical importance of adding sugars before drying is well known, the mechanism of protection of bacteria by sugars is not clear. The response of the dehydrated micro-organisms to rehydration is analysed in terms of structural and functional changes, and correlated with their potentiality to grow in rich media. These aspects are related with the membrane integrity and the metabolic state of the rehydrated bacteria, measured by means of surface properties and permeability. To attain this objective, Lactobacillus delbrueckii subsp. bulgaricus was dehydrated in the presence and in the absence of sucrose and trehalose. The bacterial response upon rehydration was investigated by determining: (i) the lag time of the bacterial growing in rich media, (ii) the restoration of the surface properties and the cellular volume and (iii) the membrane integrity. METHODS AND RESULTS: Lactobacillus delbrueckii subsp. bulgaricus was grown in MRS at 37 degrees C overnight [De Man et al. (1960)J Appl Bacteriol 23, 130] and then dehydrated for 10, 20 and 30 min at 70 degrees C in a vacuum centrifuge. The lag time of micro-organisms was determined by optical density changes after rehydration. The surface properties were determined by measuring the zeta potential of the bacteria suspended in aqueous solution. The cellular volume recovery was measured, after stabilization in saline solution, by light scattering and by the haematocrit method [Alemohammad and Knowles (1974)J Gen Microbiol 82, 125]. Finally, the membrane integrity has been determined by using specific fluorescent probes [SYTO 9 and propidium iodide, (PI)] that bind differentially depending on the integrity of the bacterial membrane. The lag time of Lact. delbrueckii subsp bulgaricus, dehydrated by heat in the presence of sucrose or trehalose and after that rehydrated, was significantly shortened, when compared with that obtained for bacteria dried in the absence of sugars. In these conditions, trehalose and sucrose maintained the zeta potential and the cell volume close to the control (nondried) cells. However, the membrane integrity, measured with fluorescent probes, was maintained only when cells were dehydrated for 10 min in the presence of sugars. For larger times of dehydration, the membrane integrity was not preserved, even in the presence of sugars. CONCLUSIONS: When the micro-organisms are dehydrated in the absence of protectants, the membrane damage occurs with a decrease in the absolute value of the zeta potential and a decrease in the cellular volume recovered after rehydration. In contrast, when the zeta potential and the cellular volume are restored after rehydration to that corresponding to nondried cells, the micro-organisms are able to recover and grow with a reduced lag time. This can only be achieved when the dehydration is carried out in the presence of sugars. At short dehydration times, the response is associated with the preservation of the membrane integrity. However, for longer times of dehydration the zeta potential and volume recovery occurs in the presence of sugars in spite of a severe damage at membrane level. In this condition, cells are also recovered. In conclusion, to predict the ability of growing after dehydration, other bacterial structural parameters besides membrane integrity, such as zeta potential and cellular volume, should be taken into account. SIGNIFICANCE AND IMPACT OF THE STUDY: The correlation of the lag time with the surface and permeability properties is of practical importance because the correlation of these two parameters with cell viability, allow to determine the potential bacterial capacity to grow in a rich medium after the preservation procedure, without necessity of performing a kinetic curve of growth, which is certainly time-consuming.     

Effect of trehalose on survival of Bradyrhizobium japonicum during desiccation

AIMS: A major reason for the ineffectiveness of legume inoculants in the field is the rapid death of rhizobia because of desiccation. The major purpose of this study was to identify conditions under which alpha,alpha-trehalose would improve survival of Bradyrhizobium japonicum during desiccation. METHODS AND RESULTS: Trehalose was added to cultures just prior to desiccation or was supplied to bacteria during the 6-day growth period. A wide variety of trehalose concentrations was tested. Trehalose added to cultures at the time of desiccation improved survival slightly, but trehalose loading during growth was much more effective in protection against desiccation. Growth of bacteria with 3 mmol l-1 trehalose increased trehalose concentration in cells by about threefold and increased survival of cells placed on soya bean [Glycine max (L.) Merr.] seeds by two- to four-fold after 2 or 24 h. Average of overall results indicate that growth of bacteria with trehalose in the medium resulted in a 294% increase in survival after 24 h of desiccation. The concentration of trehalose in cells was very highly correlated with survival of bacteria. When trehalose-loaded cells were suspended in buffer or water, 60-85% of cellular trehalose was lost in about 1 h and, in spite of these losses, survival during desiccation was not reduced. CONCLUSIONS: Accumulation of trehalose in the cytoplasm is critical to the survival of B. japonicum during desiccation. Increasing the periplasmic concentration of trehalose is also beneficial but is not so critical as the concentration of trehalose in the cytoplasm. Because B. japonicum cannot utilize trehalose as a carbon source, cells can be loaded with trehalose by providing the disaccharide during the growth period. SIGNIFICANCE AND IMPACT OF THE STUDY: Although it may not be practical to use trehalose as a carbon source in inoculant production, it may be possible to engineer greater trehalose accumulation in rhizobia. Trehalose concentration in cells should be a useful predictor of survival during desiccation.     

Dehydrating phospholipid vesicles measured in real-time using ATR Fourier transform infrared spectroscopy

According to the water replacement hypothesis, trehalose stabilizes dry membranes by preventing the decrease in spacing between adjacent phopspholipid headgroups during dehydration. Alternatively, the water-entrapment hypothesis postulates that in the dried state sugars trap residual water at the biomolecule sugar interface. In this study, Fourier transform infrared spectroscopy with an attenuated total reflection accessory was used to investigate the influence of trehalose on the dehydration kinetics and residual water content of egg phosphatidylcholine liposomes in real time under controlled relative humidity conditions. In the absence of trehalose, the lipids displayed a transition to a more ordered gel phase upon drying. The membrane conformational disorder in the dried state was found to decrease with decreasing relative humidity. Even at a relative humidity as high as 94% the conformational disorder of the lipid acyl chains decreased after evaporation of the bulk water. The presence of trehalose affects the rate of water removal from the system and the lipid phase behavior. The rate of water removal is decreased and the residual water content is higher, as compared to drying in the absence of trehalose. During drying, the level of hydrogen bonding to the head groups remains constant. In addition, the conformational disorder of the lipid acyl chains in the dried state more closely resembles that of the lipids in the fully hydrated state. We conclude that water entrapment rather than water replacement explains the effect of trehalose on lipid phase behavior of phosphatidylcholine lipid bilayers during the initial phase of drying.     

Optimization of preservation conditions of As (III) bioreporter bacteria

Long-term preservation of bioreporter bacteria is essential for the functioning of cell-based detection devices, particularly when field application, e.g., in developing countries, is intended. We varied the culture conditions (i.e., the NaCl content of the medium), storage protection media, and preservation methods (vacuum drying vs. encapsulation gels remaining hydrated) in order to achieve optimal preservation of the activity of As (III) bioreporter bacteria during up to 12 weeks of storage at 4°C. The presence of 2% sodium chloride during the cultivation improved the response intensity of some bioreporters upon reconstitution, particularly of those that had been dried and stored in the presence of sucrose or trehalose and 10% gelatin. The most satisfying, stable response to arsenite after 12 weeks storage was obtained with cells that had been dried in the presence of 34% trehalose and 1.5% polyvinylpyrrolidone. Amendments of peptone, meat extract, sodium ascorbate, and sodium glutamate preserved the bioreporter activity only for the first 2 weeks, but not during long-term storage. Only short-term stability was also achieved when bioreporter bacteria were encapsulated in gels remaining hydrated during storage.     

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.     

A role for microwave processing in the dry preservation of mammalian cells

Dry preservation involves removing water from samples so that degradative biochemical processes are slowed and extended storage is possible. Recently this approach has been explored as a method for preserving living mammalian cells. The current work explores the use of microwave processing to enhance evaporation rates and to improve drying uniformity, thereby overcoming some of the challenges in this field. Mouse macrophage cells (J774) were pre-incubated in full complement media containing 50 mM trehalose, for 18-h, to allow for endocytosis of trehalose. Droplets of experimental and control (no intracellular trehalose) cell suspensions were placed on coverslips in a microwave cavity. Water was evaporated using intermittent microwave heating (600 W, 30 s intervals). Samples were dried to various moisture levels, rehydrated, and then survival was assessed after a 45-min recovery period using Calcein-AM/PI fluorescence and Trypan Blue exclusion assays. The metabolic activity of dried cells (4.3 gH(2)O/gdw) was assessed after rehydration using a resazurin reduction assay. Apoptosis levels were also measured. Post- rehydration survival correlated with the final moisture content achieved, consistent with other drying methods. Intracellular trehalose provided protection against injury associated with moisture loss. Metabolic assays revealed normal growth in surviving cells, and these survival levels were consistent with results from apoptosis assays (P > 0.05). Brightfield and fluorescence images of microwave-dried samples revealed a uniform distribution of cells within the dried matrix and profilometry analysis demonstrated that solids were uniformly distributed throughout the sample. Microwave-processing successfully facilitated rapid and uniform dehydration of cell-based samples.     

Dependence of trehalose protective action on the initial phase state of dipalmitoylphosphatidylcholine bilayers

Dipalmitoylphosphatidylcholine (DPPC) bilayers hydrated in the presence of trehalose were equilibrated at various temperatures (4, 20, and 60 degrees C) corresponding to the crystalline Lc, gel L beta', and liquid-crystalline L alpha phases, respectively, and then desiccated at these temperatures or freeze-dried at -80 degrees C to ca. DPPC dihydrate. The thermotropic behavior of the resulting DPPC/trehalose mixtures was investigated by differential scanning calorimetry and found to be dependent not only on the trehalose concentration but also on the phase state of the hydrated bilayers prior to their drying. Trehalose was most effective when the desiccation was carried out from the L alpha phase at 60 degrees C. In this case, one trehalose molecule per two DPPC molecules was sufficient to depress the melting temperature from values typical of DPPC dihydrate to 45 degrees C. Trehalose's influence decreased when dried from the L beta' phase and was significantly less pronounced when dried from the Lc phase. These data show that trehalose's protective influence depends on the initial phase state of the lipid bilayer and reaches its maximum in the liquid-crystalline state. The possible role of this effect in anhydrobiosis is pointed out.     

An anhydrous polymorphic form of trehalose

An anhydrous polymorphic form of alpha,alpha-trehalose was prepared from trehalose dihydrate by two different drying methods: (1) heating under vacuum; and (2) heating in hot air. Preparation of this anhydrous form by vacuum heating showed good reproducibility. This form was characterized by X-ray powder diffraction analysis and differential scanning calorimetry. This anhydrous form was converted to an amorphous phase at 127 degrees C and was found to be hygroscopic. At 43% relative humidity at 25 degrees C, this form rapidly reverted to dihydrate, while the amorphous phase remained unchanged. When an amorphous phase coexisted with this form, the rate of water adsorption to the amorphous phase was slower than that to the amorphous phase alone. These properties of this anhydrous form of alpha,alpha-trehalose may explain the effects of trehalose in dehydration tolerance of plants and insects in the desert.     

Preservation of freeze-dried liposomes by trehalose

One of the practical difficulties with the frequently proposed use of liposomes for delivery of water-soluble substances to cells in whole organisms is that liposomes are relatively unstable during storage. We have studied the ability of trehalose, a carbohydrate commonly found at high concentrations in organisms capable of surviving dehydration, to stabilize dry liposomes. With trehalose both inside and outside the bilayer, almost 100% of trapped solute was retained in rehydrated vesicles previously freeze-dried with 1.8 g trehalose/g dry phospholipid. Trehalose is very effective at inhibiting fusion between liposomes during drying, as assessed by freeze-fracture and resonance energy transfer between fluorescent probes incorporated into the bilayer. However, inhibition of fusion alone does not account for the preservation of the dry liposomes, since the concentration of trehalose required to prevent leakage is more than 10-fold that required to prevent fusion. We provide evidence that stabilization of the dry liposomes requires depression of transition temperature and consequent maintenance of the constituent lipids in the dry liposomes in a liquid crystalline phase.     

Identification of trehalose as a compatible solute in different species of acidophilic bacteria

The major industrial heap bioleaching processes are located in desert regions (mainly Chile and Australia) where fresh water is scarce and the use of resources with low water activity becomes an attractive alternative. However, in spite of the importance of the microbial populations involved in these processes, little is known about their response or adaptation to osmotic stress. In order to investigate the response to osmotic stress in these microorganisms, six species of acidophilic bacteria were grown at elevated osmotic strength in liquid media, and the compatible solutes synthesised were identified using ion chromatography and MALDI-TOF mass spectrometry. Trehalose was identified as one of, or the sole, compatible solute in all species and strains, apart from Acidithiobacillus thiooxidans where glucose and proline levels increased at elevated osmotic potentials. Several other potential compatible solutes were tentatively identified by MALDITOF analysis. The same compatible solutes were produced by these bacteria regardless of the salt used to produce the osmotic stress. The results correlate with data from sequenced genomes which confirm that many chemolithotrophic and heterotrophic acidophiles possess genes for trehalose synthesis. This is the first report to identify and quantify compatible solutes in acidophilic bacteria that have important roles in biomining technologies.     

Effect of trehalose as an additive to dimethyl sulfoxide solutions on ice formation,cellular viability,and metabolism

Cryopreservation is the only established method for long-term preservation of cells and cellular material. This technique involves preservation of cells and cellular components in the presence of cryoprotective agents (CPAs) at liquid nitrogen temperatures (−196 °C). The organic solvent dimethyl sulfoxide (Me₂SO) is one of the most commonly utilized CPAs and has been used with various levels of success depending on the type of cells. In recent years, to improve cryogenic outcomes, the non-reducing disaccharide trehalose has been used as an additive to Me₂SO-based freezing solutions. Trehalose is a naturally occurring non-toxic compound found in bacteria, fungi, plants, and invertebrates which has been shown to provide cellular protection during water-limited states. The mechanism by which trehalose improves cryopreservation outcomes remains not fully understood. Raman microspectroscopy is a powerful tool to provide valuable insight into the nature of interactions among water, trehalose, and Me₂SO during cryopreservation. We found that the addition of trehalose to Me₂SO based CPA solutions dramatically reduces the area per ice crystals while increasing the number of ice crystals formed when cooled to −40 or −80 °C. Differences in ice-formation patterns were found to have a direct impact on cellular viability. Despite the osmotic stress caused by addition of 100 mM trehalose, improvement in cellular viability was observed. However, the substantial increase in osmotic pressure caused by trehalose concentrations above 100 mM may offset the beneficial effects of changing the morphology of the ice crystals achieved by addition of this sugar.     

Trehalose maintains phase separation in an air-dried binary lipid mixture

Mixing and thermal behavior of hydrated and air-dried mixtures of 1,2-dilauroyl-sn-glycero-3-phosphocholine (DLPC) and 1,2-distearoyl-d70-sn-glycero-3-phosphocholine (DSPCd-70) in the absence and presence of trehalose were investigated by Fourier transform infrared spectroscopy. Mixtures of DLPC:DSPCd-70 (1:1) that were air-dried at 25 degrees C show multiple phase transitions and mixed phases in the dry state. After annealing at high temperatures, however, only one transition is seen during cooling scans. When dried in the presence of trehalose, the DLPC component shows two phase transitions at -22 degrees C and 75 degrees C and is not fully solidified at -22 degrees C. The DSPCd-70 component, however, shows a single phase transition at 78 degrees C. The temperatures of these transitions are dramatically reduced after annealing at high temperatures with trehalose. The data suggest that the sugar has a fluidizing effect on the DLPC component during drying and that this effect becomes stronger for both components with heating. Examination of infrared bands arising from the lipid phosphate and sugar hydroxyl groups suggests that the strong effect of trehalose results from direct interactions between lipid headgroups and the sugar and that these interactions become stronger after heating. The findings are discussed in terms of the protective effect of trehalose on dry membranes.     

A study of the effect of sorbitol on osmotic tolerance during partial desiccation of bovine sperm

The goal of the study was to improve the partial desiccation survival of bovine sperm by decreasing the dehydration induced osmotic injury. The protective role of sorbitol, a polyol, was investigated by (i) studying the osmotic behavior of sperm in hypertonic Tyrode’s buffer in the presence of sorbitol and trehalose, (ii) studying the effect of sorbitol and trehalose on sperm motility following partial dehydration. The osmotic behavior studies included the assessment of motility and volumetric responses in the presence of the additives. For the drying experiments, motility was assayed after drying the samples to different end water content followed by immediate rehydration. Compared to the effect of “intracellular + extracellular” trehalose alone, results showed a much improved motility in the presence of sorbitol and trehalose. While the drying results suggest an enhanced osmotolerance in the presence of sorbitol, the study of motility under hypertonic conditions combined with the sperm volume excursion experiments suggest that sorbitol imparts the enhancement by permeating into the cell cytoplasm.     

Influence of trehalose on the molecular chaperone activity of p26, a small heat shock/alpha-crystallin protein

Encysted embryos of the primitive crustacean Artemia franciscana are among the most resistant of all multicellular eukaryotes to environmental stress, in part due to massive amounts of a small heat shock/alpha-crystallin protein (p26) that acts as a molecular chaperone. These embryos also contain very large amounts of the disaccharide trehalose, well known for its ability to protect macromolecules and membranes against damage due to water removal and temperature extremes. Therefore, we looked for potential interactions between trehalose and p26 in the protection of a model substrate, citrate synthase (CS), against heat denaturation and aggregation and in the restoration of activity after heating in vitro. Both trehalose and p26 decreased the aggregation and irreversible inactivation of CS at 43 degrees C. At approximate physiological concentrations (0.4 M), trehalose did not interfere with the ability of p26 to assist in the reactivation of CS after heating, but higher concentrations (0.8 M) were inhibitory. We also showed that CS and p26 interact physically during heating and that trehalose interferes with complex formation and disrupts CS-p26 complexes that form at high temperatures. We suggest from these results that trehalose may act as a "release factor," freeing folding intermediates of CS that p26 can chaperone to the native state. Trehalose and p26 can act synergistically in vitro, during and after thermal stress, suggesting that these interactions also occur in vivo.