Extracellular trehalose utilization by Saccharomyces cerevisiae

Two haploid strains of Saccharomyces cerevisiae viz. MATalpha and MATa were grown in glucose and trehalose medium and growth patterns were compared. Both strains show similar growth, except for an extended lag phase in trehalose grown cells. In both trehalose grown strains increase in activities of both extracellular trehalase activities and simultaneous decrease in extracellular trehalose level was seen. This coincided with a sharp increase in extracellular glucose level and beginning of log phase of growth. Alcohol production was also observed. Secreted trehalase activity was detected, in addition to periplasmic activity. It appeared that extracellular trehalose was hydrolyzed into glucose by extracellular trehalase activity. This glucose was utilized by the cells for growth. The alcohol formation was due to the fermentation of glucose. Addition of extracellular trehalase caused reduction in the lag phase when grown in trehalose medium, supporting our hypothesis of extracellular utilization of trehalose.     

Two Distinct Pathways for Trehalose Assimilation in the Yeast Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae can synthesize trehalose and also use this disaccharide as a carbon source for growth. However, the molecular mechanism by which extracellular trehalose can be transported to the vacuole and degraded by the acid trehalase Ath1p is not clear. By using an adaptation of the assay of invertase on whole cells with NaF, we showed that more than 90% of the activity of Ath1p is extracellular, splitting of the disaccharide into glucose. We also found that Agt1p-mediated trehalose transport and the hydrolysis of the disaccharide by the cytosolic neutral trehalase Nth1p are coupled and represent a second, independent pathway, although there are several constraints on this alternative route. First, the AGT1/MAL11 gene is controlled by the MAL system, and Agt1p was active in neither non-maltose-fermenting nor maltose-inducible strains. Second, Agt1p rapidly lost activity during growth on trehalose, by a mechanism similar to the sugar-induced inactivation of the maltose permease. Finally, both pathways are highly pH sensitive and effective growth on trehalose occurred only when the medium was buffered at around pH 5.0. The catabolism of trehalose was purely oxidative, and since levels of Ath1p limit the glucose flux in the cells, batch cultures on trehalose may provide a useful alternative to glucose-limited chemostat cultures for investigation of metabolic responses in yeast.     

Biochemical characterization of neutral trehalase activity in Saccharomyces boulardii

Lyophilized cells of the non-pathogenic yeast Saccharomyces boulardii are used in many countries for the treatment of several types of diarrhoea and other gastrointestinal diseases. Although the cells must be viable, their mechanism of action is unknown. The disaccharide trehalose is a protectant against several forms of environmental stress in yeast and is involved in maintaining cell viability. There is no information on the enzymes involved in degradation of trehalose in S. boulardii. The aim of the present study was to characterize trehalase activity in this yeast. Cells of S. boulardii grown in glucose exhibited neutral trehalase activity only in the exponential phase. Acidic trehalase was not detected in glucose medium. Cells grown in trehalose exhibited acid and neutral trehalase activities at all growth stages, particularly in the exponential phase. The optimum pH and temperature values for neutral trehalase activity were determined as 6.5 and 30 °C respectively, the half-life being approximately 3 min at 45 °C. The relative molecular mass of neutral trehalase is 80 kDa and the K _m 6.4 mM (±0.6). Neutral trehalase activity at pH 6.5 was weakly inhibited by 5 mM EDTA and strongly inhibited by ATP, as well as the divalent ions Cu⁺⁺, Fe⁺⁺ and Zn⁺⁺. Enzyme activity was stimulated by Mg⁺⁺ and Ca⁺⁺ only in the absence of cAMP. The presence of cAMP with no ion additions increased activity by 40%. This revised version was published online in July 2006 with corrections to the Cover Date.     

Function and regulation of the acid and neutral trehalases of Mucor rouxii

Two different trehalose-hydrolysing activities, known as acid or non-regulatory trehalases, and neutral or regulatory trehalases, have been recognised in a number of fungal species. The true role of these apparently redundant hydrolases remained obscure for many years. However, recent evidence suggests that neutral trehalases would be specialised in the mobilisation of cytosolic trehalose, while acid trehalases would only hydrolyse extracellular trehalose. Results obtained with Mucor rouxii, a Zygomycete initially thought to posses only neutral trehalase activity, reinforced this hypothesis. M. rouxii grows efficiently in trehalose as the sole carbon source. Trehalose-grown or carbon-starved cells exhibit a high trehalase activity of optimum pH 4.5, bound to the external surface of the cell wall, in contrast with the neutral (pH 6.5) trehalase, which occurs in the cytosol. Other differences between the neutral and the acid trehalases are the temperature optimum (35°C and 45°C, respectively) and thermal stability (half-life of 2.5 min and 12 min at 45°C, respectively). The neutral trehalase, but not the acid trehalase, is activated in vitro by cAMP-dependent phosphorylation, stimulated by Ca²⁺, and inhibited by EDTA. It shows maximal activity at germination and decreases as growth proceeds. In contrast the activity of the acid trehalase is totally repressed in glucose-grown cultures and increases upon exhaustion of the carbon source, and is strongly induced by extracellular trehalose.     

Acid trehalase in yeasts and filamentous fungi: localization, regulation and physiological function

Yeasts and filamentous fungi are endowed with two different trehalose-hydrolysing activities, termed acid and neutral trehalases according to their optimal pH for enzymatic activity. A wealth of information already exists on fungal neutral trehalases, while data on localization, regulation and function of fungal acid trehalases have remained elusive. The gene encoding the latter enzyme has now been isolated from two yeast species and two filamentous fungi, and sequences encoding putative acid trehalase can be retrieved from available public sequences. Despite weak similarities between amino acids sequences, this type of trehalase potentially harbours either a transmembrane segment or a signal peptide at the N-terminal sequence, as deduced from domain prediction algorithms. This feature, together with the demonstration that acid trehalase from yeasts and filamentous fungi is localized at the cell surface, is consistent with its main role in the utilisation of exogenous trehalose as a carbon source. The growth on this disaccharide is in fact pretty effective in most fungi except in Saccharomyces cerevisiae. This yeast species actually exhibits a "Kluyver effect" on trehalose. Moreover, an oscillatory behaviour reminiscent of what is observed in aerobic glucose-limited continuous cultures at low dilution rate is also observed in batch growth on trehalose. Finally, the S. cerevisiae acid trehalase may also participate in the catabolism of endogenous trehalose by a mechanism that likely requires the export of the disaccharide, its extracellular hydrolysis, and the subsequent uptake of the glucose released. Based on these recent findings, we suggest to rename "acid" and "neutral" trehalases as "extracellular" and "cytosolic" trehalases, which is more adequate to describe their localization and function in the fungal cell.     

Cyclic 3',5'-adenosine monophosphate stimulates trehalose degradation in baker's yeast

The levels of cyclic 3′,5′-AMP and trehalose, as well as the specific activity of the trehalase have been investigated in cells of baker's yeast ($\text{Saccharomyces cerevisiae}$) during the lag phase preceding growth. During the first few minutes a substantial increase in the intracellular concentration of cyclic 3′,5′-AMP was observed, followed by a 6–8 fold increase in trehalase activity concomitant with the rapid degradation of trehalose. Cell free extracts prepared from resting yeast were shown to contain a cryptic trehalase, which under physiological conditions could be activated by cyclic 3′,5′-AMP to the same degree as $\text{in vivo}$. These observations suggest that in the lag phase of growth, the level of trehalose in baker's yeast is under control of a system, regulated by the level of cyclic 3′,5′-AMP.     

Saccharomyces cerevisiae strains from traditional fermentations of Brazilian cachaça: trehalose metabolism, heat and ethanol resistance

Nine indigenous cachaça Saccharomyces cerevisiae strains and one wine strain were compared for their trehalose metabolism characteristics under non-lethal (40°C) and lethal (52°C) heat shock, ethanol shock and combined heat and ethanol stresses. The yeast protection mechanism was studied through trehalose concentration, neutral trehalase activity and expression of heat shock proteins Hsp70 and Hsp104. All isolates were able to accumulate trehalose and activate neutral trehalase under stress conditions. No correlation was found between trehalose levels and neutral trehalase activity under heat or ethanol shock. However, when these stresses were combined, a positive relationship was found. After pre-treatment at 40°C for 60 min, and heat shock at 52°C for 8 min, eight strains maintained their trehalose levels and nine strains improved their resistance against lethal heat shock. Among the investigated stresses, heat treatment induced the highest level of trehalose and combined heat and ethanol stresses activated the neutral trehalase most effectively. Hsp70 and Hsp104 were expressed by all strains at 40°C and all of them survived this temperature although a decrease in cell viability was observed at 52°C. The stress imposed by more than 5% ethanol (v/v) represented the best condition to differentiate strains based on trehalose levels and neutral trehalase activity. The investigated S. cerevisiae strains exhibited different characteristics of trehalose metabolism, which could be an important tool to select strains for the cachaça fermentation process.     

Two distinct pathways for trehalose assimilation in the yeast Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae can synthesize trehalose and also use this disaccharide as a carbon source for growth. However, the molecular mechanism by which extracellular trehalose can be transported to the vacuole and degraded by the acid trehalase Ath1p is not clear. By using an adaptation of the assay of invertase on whole cells with NaF, we showed that more than 90% of the activity of Ath1p is extracellular, splitting of the disaccharide into glucose. We also found that Agt1p-mediated trehalose transport and the hydrolysis of the disaccharide by the cytosolic neutral trehalase Nth1p are coupled and represent a second, independent pathway, although there are several constraints on this alternative route. First, the AGT1/MAL11 gene is controlled by the MAL system, and Agt1p was active in neither non-maltose-fermenting nor maltose-inducible strains. Second, Agt1p rapidly lost activity during growth on trehalose, by a mechanism similar to the sugar-induced inactivation of the maltose permease. Finally, both pathways are highly pH sensitive and effective growth on trehalose occurred only when the medium was buffered at around pH 5.0. The catabolism of trehalose was purely oxidative, and since levels of Ath1p limit the glucose flux in the cells, batch cultures on trehalose may provide a useful alternative to glucose-limited chemostat cultures for investigation of metabolic responses in yeast.     

Thermotolerance and trehalose accumulation induced by heat shock in yeast cells of Candida albicans

Candida albicans yeast cells growing exponentially on glucose are extremely sensitive to severe heat shock treatments (52.5°C for 5 min). When these cultures were subjected to a mild temperature preincubation (42°C), they became thermotolerant and displayed higher resistance to further heat stress. The intracellular content of trehalose was very low in exponential cells, but underwent a marked increase upon non-lethal heat exposure. The accumulation of trehalose is likely due to heat-induced activation of the trehalose-6-phosphate synthase complex, whereas the external trehalase remained practically unmodified. After a temperature reversion shift (from 42°C to 28°C), the pool of trehalose was rapidly mobilized without any concomitant change in trehalase activity. These results support an important role of trehalose in the mechanism of acquired thermotolerance in C. albicans and seem to exclude the external trehalase as a key enzyme in this process.     

Modulation of trehalase activity in two insect cell lines by virus infection and trehalose

Trehalase (EC 3.2.1.28), an important glycosidase involved in regulating trehalose levels and metabolic energy in insects, was measured in cell lines from fall army worm, Spodoptera frugiperda and salt marsh caterpillar, Estigmene acrea, treated with either glucose or trehalose in the presence or absence of Tipula Iridescent Virus (TIV), a cytoplasmic deoxyribovirus. In medium containing 15-35 mM trehalose, both of these cells increased their trehalase activities by 4.5 to 8x the basal levels from cells in glucose medium. Trehalase activity was rapidly reduced after cells were exposed to TIV. Maximum loss in activity (70-90%), occurring about the same time as peak viral DNA synthesis, was significantly delayed when cells were pre-incubated with 30 mM trehalose. These experiments demonstrate the potential utility of trehalase as a marker for monitoring stresses induced by viral infection and changes in nutrition.     

Trehalose metabolism in dormant and activated spores of Phycomyces blakesleeanus Burgeff

Evidence is obtained for the existence of two different localizations of trehalase (,-trehalose glucohydrolase, EC 3.2.1.28) in Phycomyces spores: one inside the cell, and one in the periplasmic region. The latter enzyme is sensitive to 0.1 mol l^-1 HCl treatment and its activity can be regulated by external pH changes. The periplasmic form of the enzyme is involved in the metabolism of added labelled trehalose. This sugar is hydrolyzed externally to glucose which is found mainly in the incubation medium and which is partly absorbed by the spores. During incubation trehalose leaks out from both dormant and activated spores and is subsequently hydrolyzed to glucose. The intracellular trehalase is probably involved in the breakdown of endogenous trehalose in spores. After heat activation the hydrolysis of endogenous trehalose is stimulated even without an important increase in activity of intracellular trehalase. Additional treatments which break dormancy of spores without a significant activation of trehalase are the following: heating of HCl-treated spores and treatment of spores with reducing substances (e.g. Na₂S₂O₄ and NaHSO₃).     

Transport of trehalose in Salmonella typhimurium.

We have studied trehalose uptake in Salmonella typhimurium and the possible involvement of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) in this process. Two transport systems could recognize and transport trehalose, the mannose PTS and the galactose permease. Uptake of trehalose via the latter system required that it be expressed constitutively (due to a galR or galC mutation). Introduction of a ptsM mutation, resulting in a defective IIMan/IIIMan system, in S. typhimurium strains that grew on trehalose abolished growth on trehalose. A ptsG mutation, eliminating IIGlc of the glucose PTS, had no effect. In contrast, a crr mutation that resulted in the absence of IIIGlc of the glucose PTS prevented growth on trehalose. The inability of crr and also cya mutants to grow on trehalose was due to lowered intracellular cyclic AMP synthesis, since addition of extracellular cyclic AMP restored growth. Subsequent trehalose metabolism could be via a trehalose phosphate hydrolase, if trehalose phosphate was formed via the PTS, or trehalase. Trehalose-grown cells contained trehalase activity, but we could not detect phosphoenolpyruvate-dependent phosphorylation of trehalose in toluenized cells.     

Glucose and fructose consumption in a phosphoglucoseisomeraseless mutant in Saccharomyces cerevisiae

Saccharomyces cerevisiae with a practically complete absence of phosphoglucoseisomerase activity when grown in fructose or glucose minimal medium showed different consumption of fructose and glucose during different periods of the culture. At the beginning of growth, cells had a great quantity of glucose available relative to their requirements and a large quantity of trehalose accumulated from ¹⁴C-glucose in comparison with the wild type strain. A second phase arises when the concentration of glucose in the medium was practically absent and the cells obtain glucose by mobilisation of stored glucose containing compounds. It is very likely that at this moment a balance rate between glucose 6-phosphate formation and consumption occurs. Finally cells reach conditions of glucose starvation and fructose consumption increases in this last stage. The different consumption of fructose throughout different periods of cell growth most probably indicates a strict regulation at the level of sugar uptake.Non Standard Abbreviation pgi phosphoglucoseisomerase     

Identification of an integral membrane 80 kDa protein of Saccharomyces cerevisiae induced in response to dehydration

Using SDS-PAGE gels we observed the induced synthesis of a protein with a molecular mass of 80 kDa when cells of strains of Saccharomyces cerevisiae were subjected to dehydration. Physiological analysis showed that this protein is not present during growth on glucose but was found in derepressed cells from stationary phase. Furthermore, its synthesis was induced when cells were grown on medium containing α-methyl-glucoside as carbon source. However, the 80 kDa protein was not found in cells of mutants unable to transport trehalose. This protein was localized in the cytoplasmic membrane and showed trehalose-binding activity, determined by its partial purification on a trehalose–Sepharose 6B affinity column. The possible involvement of the 80 kDa protein with the trehalose transport system is discussed.     

Trehalose and glycogen accumulation is related to the duration of the G1 phase of Saccharomyces cerevisiae

Several factors may control trehalose and glycogen synthesis, like the glucose flux, the growth rate, the intracellular glucose-6-phosphate level and the glucose concentration in the medium. Here, the possible relation of these putative inducers to reserve carbohydrate accumulation was studied under well-defined growth conditions in nitrogen-limited continuous cultures. We showed that the amounts of accumulated trehalose and glycogen were regulated by the growth rate imposed on the culture, whereas other implicated inducers did not exhibit a correlation with reserve carbohydrate accumulation. Trehalose accumulation was induced at a dilution rate (D)相似文献   

Regulation of energy metabolism in Saccharomyces cerevisiae. Relationships between catabolite repression, trehalose synthesis, and mitochondrial development.

Changes in trehalose accumulation and in cytochromes during diauxic growth in glucose medium were examined in a normal Saccharomyces cerevisiae strain. While no appreciable disaccharide accumulation occurred during most of the logarithmic phase, a rapid synthesis took place during the final stages. The intrinsic capacity of cells to accumulate trehalose was also determined under nonproliferating conditions, in glucose medium lacking a nitrogen source. Cells harvested at an early growth stage had a much lower trehalose accumulation capacity than cells taken after glucose was exhausted from the culture medium. A high trehalose accumulation capacity could also be obtained at any growth stage by using maltose or galactose as carbon source. Since cells grown under various conditions exhibit a correlated change in cytochrome development and in trehalose accumulation capacity, it was concluded that the level of glucose repression determines the concentration and/or state of activation of the trehalose synthetase-trehalase complex. Independent control of trehalose accumulation capacity and mitochondrial biogenesis by the level of glucose repression was shown in two ways: by demonstrating derepression of trehalose accumulation without development of cytochromes a and c in microaerobic cells, and by showing repression-dependent changes in a cytoplasmic respiration-deficient (ρ^?) mutant, which lacked functional mitochondria. Therefore, the capacity of a cell to accumulate trehalose is not regulated solely by the supply of ATP generated by oxidative phosphorylation.     

Molecular cloning of the neutral trehalase gene from Kluyveromyces lactis and the distinction between neutral and acid trehalases

We cloned the Kluyveromyces lactis KlNTH1 gene, which encodes neutral trehalase. It showed 65.2% and 68.5% identity at nucleotide and amino acid sequence level, respectively, with the Saccharomyces cerevisiae NTH1 gene. Multiple alignment of the predicted trehalase protein sequences from yeasts, bacteria, insects, and mammals revealed two major domains of conservation. Only the yeast trehalases displayed in an N-terminal extension two consensus sites for cAMP-dependent protein phosphorylation and a putative Ca²⁺-binding sequence. Gene disruption of the KlNTH1 gene abolished neutral trehalase activity and clearly revealed a trehalase activity with an acid pH optimum. It also resulted in a high constitutive trehalose level. Expression of the KlNTH1 gene in an S. cerevisiae nth1Δ mutant resulted in rapid activation of the heterologous trehalase upon addition of glucose to cells growing on a nonfermentable carbon source and upon addition of a nitrogen source to cells starved for nitrogen in a glucose-containing medium. In K. lactis, the same responses were observed except that rapid activation by glucose was observed only in early-exponential-phase cells. Inactivation of K. lactis neutral trehalase by alkaline phosphatase and activation by cAMP in cell extracts are consistent with control of the enzyme by cAMP-dependent protein phosphorylation. Received: 19 March 1996 / Accepted: 15 October 1996     

α-Glucose-1-phosphate formation by a novel trehalose phosphorylase from Flammulina velutipes

A novel type of trehalose phosphorylase was found in a basidiomycete. Flammulina velutipes . The enzyme catalyzes both the reversible phosphorolysis of trehalose to form α-glucose 1-phosphate and glucose and also the synthesis of trehalose. Comparison of the specific activity of trehalose phosphorylase with that of trehalase suggested that the function of the former enzyme was more important in the fruit-bodies of this fungus.     

高温对家蚕三品系血淋巴中糖水平的影响（英文）

家蚕Bombyx mori的两个二化性品系热耐受型NB4D2和热敏感型CSR2均适合于温带气候,而多化性的PM（Pure Mysore) 品系适合于热带气候,将这3种品系5龄幼虫分别置于32℃和36℃的高温下,观察高温对其5龄幼虫至蛹期血淋巴中糖含量及海藻糖酶活性的影响。结果表明： PM幼虫和蛹的死亡率均小于NB4D2和CSR2。在蜕皮期间血淋巴海藻糖水平较高,而葡萄糖水平及海藻糖酶活性较低。32℃和36℃的高温下,幼虫蜕皮期间血淋巴中糖含量及海藻糖酶活性仅在其各自的水平上表现为小幅度的增加。蜕皮后幼虫血淋巴中海藻糖含量显著下降,而葡萄糖含量和海藻糖酶活性显著上升。在较高温度下,蜕皮后幼虫血淋巴中海藻糖含量下降幅度更大,而葡萄糖含量及海藻糖酶活性上升水平也更加显著。25±1℃下取食幼虫血淋巴中葡萄糖含量显著下降,海藻糖含量显著上升;3℃和36℃下PM 和NB4D2取食幼虫血淋巴葡萄糖和海藻糖含量以及海藻糖酶活性增加,而CSR2均减少或降低。吐丝幼虫血淋巴中葡萄糖含量及海藻糖酶活性显著下降,海藻糖小幅度下降。而在较高温度下,耐热型PM 和NB4D2吐丝家蚕血淋巴糖含量含量和海藻糖酶活性明显增加,而热敏感型CSR2的则明显下降。这3种品系蛹发育期的血淋巴糖含量及海藻糖酶活性均下降。在两较高温度下,PM蛹期血淋巴糖和海藻糖酶活性增加,而NB4D2 36℃时增加幅度小于32℃时。对于CSR2,32℃时观察到其血淋巴葡萄糖含量增加,但当环境温度增加到36℃时其血淋巴葡萄糖含量降至正常水平下。然而,当CSR2的蛹置于32℃和36℃时血淋巴海藻糖含量及其酶活性下降,且36℃时下降幅度更大。因此,桑蚕对高温的适应取决于家蚕的品系及发育阶段,并可通过其血淋巴糖及海藻糖酶活性水平进行验证。