Regulation of yeast trehalase by a monocyclic, cyclic AMP-dependent phosphorylation-dephosphorylation cascade system

Look for the Scaffold: Multifaceted Regulation of Enzyme Activity by 14-3-3 Proteins

Enzyme activity is regulated by several mechanisms, including phosphorylation. Phosphorylation is a key signal transduction process in all eukaryotic cells and is thus crucial for virtually all cellular processes. In addition to its direct effect on protein structure, phosphorylation also affects protein-protein interactions, such as binding to scaffolding 14-3-3 proteins, which selectively recognize phosphorylated motifs. These interactions then modulate the catalytic activity, cellular localisation and interactions of phosphorylated enzymes through different mechanisms. The aim of this mini-review is to highlight several examples of 14-3-3 protein-dependent mechanisms of enzyme regulation previously studied in our laboratory over the past decade. More specifically, we address here the regulation of the human enzymes ubiquitin ligase Nedd4-2, procaspase-2, calcium-calmodulin dependent kinases CaMKK1/2, and death-associated protein kinase 2 (DAPK2) and yeast neutral trehalase Nth1.

D-Xylose Sensing in Saccharomyces cerevisiae: Insights from D-Glucose Signaling and Native D-Xylose Utilizers

Extension of the substrate range is among one of the metabolic engineering goals for microorganisms used in biotechnological processes because it enables the use of a wide range of raw materials as substrates. One of the most prominent examples is the engineering of baker's yeast Saccharomyces cerevisiae for the utilization of d-xylose, a five-carbon sugar found in high abundance in lignocellulosic biomass and a key substrate to achieve good process economy in chemical production from renewable and non-edible plant feedstocks. Despite many excellent engineering strategies that have allowed recombinant S. cerevisiae to ferment d-xylose to ethanol at high yields, the consumption rate of d-xylose is still significantly lower than that of its preferred sugar d-glucose. In mixed d-glucose/d-xylose cultivations, d-xylose is only utilized after d-glucose depletion, which leads to prolonged process times and added costs. Due to this limitation, the response on d-xylose in the native sugar signaling pathways has emerged as a promising next-level engineering target. Here we review the current status of the knowledge of the response of S. cerevisiae signaling pathways to d-xylose. To do this, we first summarize the response of the native sensing and signaling pathways in S. cerevisiae to d-glucose (the preferred sugar of the yeast). Using the d-glucose case as a point of reference, we then proceed to discuss the known signaling response to d-xylose in S. cerevisiae and current attempts of improving the response by signaling engineering using native targets and synthetic (non-native) regulatory circuits.

Allosteric activation of yeast enzyme neutral trehalase by calcium and 14-3-3 protein

Neutral trehalase 1 (Nth1) from Saccharomyces cerevisiae catalyzes disaccharide trehalose hydrolysis and helps yeast to survive adverse conditions, such as heat shock, starvation or oxidative stress. 14-3-3 proteins, master regulators of hundreds of partner proteins, participate in many key cellular processes. Nth1 is activated by phosphorylation followed by 14-3-3 protein (Bmh) binding. The activation mechanism is also potentiated by Ca(2+) binding within the EF-hand-like motif. This review summarizes the current knowledge about trehalases and the molecular and structural basis of Nth1 activation. The crystal structure of fully active Nth1 bound to 14-3-3 protein provided the first high-resolution view of a trehalase from a eukaryotic organism and showed 14-3-3 proteins as structural modulators and allosteric effectors of multi-domain binding partners.

Two trehalose-hydrolyzing enzymes from Crenarchaeon Sulfolobus acidocaldarius exhibit distinct activities and affinities toward trehalose

Two archaeal trehalase-like genes, Saci1250 and Saci1816, belonging to glycoside hydrolase family 15 (GH15) from the acidophilic Crenarchaeon Sulfolobus acidocaldarius were expressed in Escherichia coli. The gene products showed trehalose-hydrolyzing activities, and the names SaTreH1 and SaTreH2 were assigned to Saci1816 and Saci1250 gene products, respectively. These newly identified enzymes functioned within a narrow range of acidic pH values at elevated temperatures, which is similar to the behavior of Euryarchaeota Thermoplasma trehalases. SaTreH1 displayed high K_M and k_cat values, whereas SaTreH2 had lower K_M and k_cat values despite a high degree of identity in their primary structures. A mutation analysis indicated that two glutamic acid residues in SaTreH1, E374 and E574, may be involved in trehalase catalysis because SaTreH1 E374Q and E574Q showed greatly reduced trehalose-hydrolyzing activities. Additional mutations substituting G573 and H575 residues with serine and glutamic acid residues, respectively, to mimic the TVN1315 sequence resulted in a decrease in trehalase activity and thermal stability. Taken together, the results indicated that Crenarchaea trehalases adopt active site structures that are similar to Euryarchaeota enzymes but have distinct molecular features. The identification of these trehalases could extend our understanding of the relationships between the structure and function of GH15 trehalases as well as other family enzymes and will provide insights into archaeal trehalose metabolism.

The Yeast Saccharomyces cerevisiae as a Model for Understanding RAS Proteins and their Role in Human Tumorigenesis

The exploitation of the yeast Saccharomyces cerevisiae as a biological model for the investigation of complex molecular processes conserved in multicellular organisms, such as humans, has allowed fundamental biological discoveries. When comparing yeast and human proteins, it is clear that both amino acid sequences and protein functions are often very well conserved. One example of the high degree of conservation between human and yeast proteins is highlighted by the members of the RAS family. Indeed, the study of the signaling pathways regulated by RAS in yeast cells led to the discovery of properties that were often found interchangeable with RAS proto-oncogenes in human pathways, and vice versa. In this work, we performed an updated critical literature review on human and yeast RAS pathways, specifically highlighting the similarities and differences between them. Moreover, we emphasized the contribution of studying yeast RAS pathways for the understanding of human RAS and how this model organism can contribute to unveil the roles of RAS oncoproteins in the regulation of mechanisms important in the tumorigenic process, like autophagy.

Free Trehalose Accumulation in Dormant Mycobacterium smegmatis Cells and Its Breakdown in Early Resuscitation Phase

Under gradual acidification of growth medium resulting in the formation of dormant Mycobacterium smegmatis, a significant accumulation of free trehalose in dormant cells was observed. According to ¹H- and ¹³C-NMR spectroscopy up to 64% of total organic substances in the dormant cell extract was represented by trehalose whilst the trehalose content in an extract of active cells taken from early stationary phase was not more than 15%. Trehalose biosynthesis during transition to the dormant state is provided by activation of genes involved in the OtsA-OtsB and TreY-TreZ pathways (according to RT-PCR). Varying the concentration of free trehalose in dormant cells by expression of MSMEG_4535 coding for trehalase we found that cell viability depends on trehalose level: cells with a high amount of trehalose survive much better than cells with a low amount. Upon resuscitation of dormant M. smegmatis, a decrease of free trehalose and an increase in glucose concentration occurred in the early period of resuscitation (after 2 h). Evidently, breakdown of trehalose by trehalase takes place at this time as a transient increase in trehalase activity was observed between 1 and 3 h of resuscitation. Activation of trehalase was not due to de novo biosynthesis but because of self-activation of the enzyme from the inactive state in dormant cells. Because, even a low concentration of ATP (2 mM) prevents self-activation of trehalase in vitro and after activation the enzyme is still sensitive to ATP we suggest that the transient character of trehalase activation in cells is due to variation in intracellular ATP concentration found in the early resuscitation period. The negative influence of the trehalase inhibitor validamycin A on the resuscitation of dormant cells proves the importance of trehalase for resuscitation. These experiments demonstrate the significance of free trehalose accumulation for the maintenance of dormant mycobacterial viability and the involvement of trehalose breakdown in early events leading to cell reactivation similar to yeast and fungal spores.

Role of the EF-hand-like motif in the 14-3-3 protein-mediated activation of yeast neutral trehalase Nth1

Trehalases hydrolyze the non-reducing disaccharide trehalose amassed by cells as a universal protectant and storage carbohydrate. Recently, it has been shown that the activity of neutral trehalase Nth1 from Saccharomyces cerevisiae is mediated by the 14-3-3 protein binding that modulates the structure of both the catalytic domain and the region containing the EF-hand-like motif, whose role in the activation of Nth1 is unclear. In this work, the structure of the Nth1·14-3-3 complex and the importance of the EF-hand-like motif were investigated using site-directed mutagenesis, hydrogen/deuterium exchange coupled to mass spectrometry, chemical cross-linking, and small angle x-ray scattering. The low resolution structural views of Nth1 alone and the Nth1·14-3-3 complex show that the 14-3-3 protein binding induces a significant structural rearrangement of the whole Nth1 molecule. The EF-hand-like motif-containing region forms a separate domain that interacts with both the 14-3-3 protein and the catalytic trehalase domain. The structural integrity of the EF-hand like motif is essential for the 14-3-3 protein-mediated activation of Nth1, and calcium binding, although not required for the activation, facilitates this process by affecting its structure. Our data suggest that the EF-hand like motif-containing domain functions as the intermediary through which the 14-3-3 protein modulates the function of the catalytic domain of Nth1.

Regulation of the yeast trehalose-synthase complex by cyclic AMP-dependent phosphorylation

BACKGROUND

Trehalose is an important protectant in several microorganisms. In Saccharomyces cerevisiae, it is synthesized by a large complex comprising the enzymes Tps1 and Tps2 and the subunits Tps3 and Tsl1, showing an intricate metabolic control.

METHODS

To investigate how the trehalose biosynthesis pathway is regulated, we analyzed Tps1 and Tps2 activities as well as trehalose and trehalose-6-phosphate (T6P) contents by mass spectrometry.

RESULTS

Tsl1 deficiency totally abolished the increase in Tps1 activity and accumulation of trehalose in response to a heat stress, whereas absence of Tps3 only reduced Tps1 activity and trehalose synthesis. In extracts of heat stressed cells, Tps1 was inhibited by T6P and by ATP. Mg(2+) in the presence of cAMP. In contrast, cAMP-dependent phosphorylation did not inhibit Tps1 in tps3 cells, which accumulated a higher proportion of T6P after stress. Tps2 activity was not induced in a tps3 mutant.

CONCLUSION

Taken together these results suggest that Tsl1 is a decisive subunit for activity of the TPS complex since in its absence no trehalose synthesis occurred. On the other hand, Tps3 seems to be an activator of Tps2. To perform this task, Tps3 must be non-phosphorylated. To readily stop trehalose synthesis during stress recovery, Tps3 must be phosphorylated by cAMP-dependent protein kinase, decreasing Tps2 activity and, consequently, increasing the concentration of T6P which would inhibit Tps1.

GENERAL SIGNIFICANCE

A better understanding of TPS complex regulation is essential for understanding how yeast deals with stress situations and how it is able to recover when the stress is over.

In vivo phosphorylation of Ser21 and Ser83 during nutrient-induced activation of the yeast protein kinase A (PKA) target trehalase

The readdition of an essential nutrient to starved, fermenting cells of the yeast Saccharomyces cerevisiae triggers rapid activation of the protein kinase A (PKA) pathway. Trehalase is activated 5–10-fold within minutes and has been used as a convenient reporter for rapid activation of PKA in vivo. Although trehalase can be phosphorylated and activated by PKA in vitro, demonstration of phosphorylation during nutrient activation in vivo has been lacking. We now show, using phosphospecific antibodies, that glucose and nitrogen activation of trehalase in vivo is associated with phosphorylation of Ser²¹ and Ser⁸³. Unexpectedly, mutants with reduced PKA activity show constitutive phosphorylation despite reduced trehalase activation. The same phenotype was observed upon deletion of the catalytic subunits of yeast protein phosphatase 2A, suggesting that lower PKA activity causes reduced trehalase dephosphorylation. Hence, phosphorylation of trehalase in vivo is not sufficient for activation. Deletion of the inhibitor Dcs1 causes constitutive trehalase activation and phosphorylation. It also enhances binding of trehalase to the 14-3-3 proteins Bmh1 and Bmh2, suggesting that Dcs1 inhibits by preventing 14-3-3 binding. Deletion of Bmh1 and Bmh2 eliminates both trehalase activation and phosphorylation. Our results reveal that trehalase activation in vivo is associated with phosphorylation of typical PKA sites and thus establish the enzyme as a reliable read-out for nutrient activation of PKA in vivo.

Role of individual phosphorylation sites for the 14-3-3-protein-dependent activation of yeast neutral trehalase Nth1

Trehalases are important highly conserved enzymes found in a wide variety of organisms and are responsible for the hydrolysis of trehalose that serves as a carbon and energy source as well as a universal stress protectant. Emerging evidence indicates that the enzymatic activity of the neutral trehalase Nth1 in yeast is enhanced by 14-3-3 protein binding in a phosphorylation-dependent manner through an unknown mechanism. In the present study, we investigated in detail the interaction between Saccharomyces cerevisiae Nth1 and 14-3-3 protein isoforms Bmh1 and Bmh2. We determined four residues that are phosphorylated by PKA (protein kinase A) in vitro within the disordered N-terminal segment of Nth1. Sedimentation analysis and enzyme kinetics measurements show that both yeast 14-3-3 isoforms form a stable complex with phosphorylated Nth1 and significantly enhance its enzymatic activity. The 14-3-3-dependent activation of Nth1 is significantly more potent compared with Ca2+-dependent activation. Limited proteolysis confirmed that the 14-3-3 proteins interact with the N-terminal segment of Nth1 where all phosphorylation sites are located. Site-directed mutagenesis in conjunction with the enzyme activity measurements in vitro and the activation studies of mutant forms in vivo suggest that Ser60 and Ser83 are sites primarily responsible for PKA-dependent and 14-3-3-mediated activation of Nth1.

The early steps of glucose signalling in yeast

In the presence of glucose, yeast undergoes an important remodelling of its metabolism. There are changes in the concentration of intracellular metabolites and in the stability of proteins and mRNAs; modifications occur in the activity of enzymes as well as in the rate of transcription of a large number of genes, some of the genes being induced while others are repressed. Diverse combinations of input signals are required for glucose regulation of gene expression and of other cellular processes. This review focuses on the early elements in glucose signalling and discusses their relevance for the regulation of specific processes. Glucose sensing involves the plasma membrane proteins Snf3, Rgt2 and Gpr1 and the glucose-phosphorylating enzyme Hxk2, as well as other regulatory elements whose functions are still incompletely understood. The similarities and differences in the way in which yeasts and mammalian cells respond to glucose are also examined. It is shown that in Saccharomyces cerevisiae, sensing systems for other nutrients share some of the characteristics of the glucose-sensing pathways.

Transcriptional expression of bursicon and novel bursicon-regulated genes in the house fly Musca domestica

Bursicon is a neuropeptide that regulates cuticle sclerotization (hardening and tanning) via a G protein-coupled receptor. It consists of two subunits, an alpha and a beta. In the present study, we investigated the transcriptional expression and in situ localization of bursicon alpha and beta in the central nerve system of the house fly Musca domestica. Most importantly, we identified two novel bursicon-regulated genes using recombinant bursicon (rbursicon) heterodimer in a neck-ligated house fly assay. RT-PCR analysis revealed that both bursicon alpha and beta subunits were present in the central nerve system of larval and pupal stages, reached the maximal level in pharate adults, and declined sharply after adult emergence, suggesting the release of the hormone upon adult emergence. In situ localization of bursicon transcripts showed that both bursicon alpha and beta transcripts were expressed in a set of neurosecretory cells (NSCs) in the thoracic-abdominal ganglia of M. domestica. Two Drosophila melanogaster homologous genes, designated CG7985hh and CG30287hh, were up-regulated by rbursicon in a time-dependent manner and verified by real-time PCR, implying their involvement in the cuticle tanning process.

Biochemical characterisation of the trehalase of thermophilic fungi: an enzyme with mixed properties of neutral and acid trehalase

The trehalases from some thermophilic fungi, such as Humicola grisea, Scytalidium thermophilum, or Chaetomium thermophilum, possess mixed properties in comparison with those of the two main groups of trehalases: acid and neutral trehalases. Such as acid trehalases these enzymes are highly thermostable extracellular glycoproteins, which act at acidic pH. However, these enzymes are activated by calcium or manganese, and as a result inhibited by chelators and by ATP, properties typical of neutral trehalases. Here we extended the biochemical characterisation of these enzymes, by assaying their activity at acid and neutral pH. The acid activity (25-30% of total) was assayed in McIlvaine buffer at pH 4.5. Under these conditions the enzyme was neither activated by calcium nor inhibited by EDTA or ATP. The neutral activity was estimated in MES buffer at pH 6.5, after subtracting the activity resistant to EDTA inhibition. The neutral activity was activated by calcium and inhibited by ATP. On the other hand, the acid activity was more thermostable than the neutral activity, had a higher temperature optimum, exhibited a lower K(m), and different sensitivity to several ions and other substances. Apparently, these trehalases represent a new class of trehalases. More knowledge is needed about the molecular structure of this protein and its corresponding gene, to clarify the structural and evolutionary relationship of this trehalase to the conventional trehalases.

PKA and Sch9 control a molecular switch important for the proper adaptation to nutrient availability

In the yeast Saccharomyces cerevisiae, PKA and Sch9 exert similar physiological roles in response to nutrient availability. However, their functional redundancy complicates to distinguish properly the target genes for both kinases. In this article, we analysed different phenotypic read-outs. The data unequivocally showed that both kinases act through separate signalling cascades. In addition, genome-wide expression analysis under conditions and with strains in which either PKA and/or Sch9 signalling was specifically affected, demonstrated that both kinases synergistically or oppositely regulate given gene targets. Unlike PKA, which negatively regulates stress-responsive element (STRE)- and post-diauxic shift (PDS)-driven gene expression, Sch9 appears to exert additional positive control on the Rim15-effector Gis1 to regulate PDS-driven gene expression. The data presented are consistent with a cyclic AMP (cAMP)-gating phenomenon recognized in higher eukaryotes consisting of a main gatekeeper, the protein kinase PKA, switching on or off the activities and signals transmitted through primary pathways such as, in case of yeast, the Sch9-controlled signalling route. This mechanism allows fine-tuning various nutritional responses in yeast cells, allowing them to adapt metabolism and growth appropriately.

In silico and in vivo analysis reveal a novel gene in Saccharomyces cerevisiae trehalose metabolism

Background

The ability to respond rapidly to fluctuations in environmental changes is decisive for cell survival. Under these conditions trehalose has an essential protective function and its concentration increases in response to enhanced expression of trehalose synthase genes, TPS1, TPS2, TPS3 and TSL1. Intriguingly, the NTH1 gene, which encodes neutral trehalase, is highly expressed at the same time. We have previously shown that trehalase remains in its inactive non-phosphorylated form by the action of an endogenous inhibitor. Recently, a comprehensive two-hybrid analysis revealed a 41-kDa protein encoded by the YLR270w ORF, which interacts with NTH1p.

Results

In this work we investigate the correlation of this Trehalase Associated Protein, in trehalase activity regulation. The neutral trehalase activity in the ylr270w mutant strain was about 4-fold higher than in the control strain. After in vitro activation by PKA the ylr270w mutant total trehalase activity increased 3-fold when compared to a control strain. The expression of the NTH1 gene promoter fused to the heterologous reporter lacZ gene was evaluated. The mutant strain lacking YLR270w exhibited a 2-fold increase in the NTH1-lacZ basal expression when compared to the wild type strain.

Conclusions

These results strongly indicate a central role for Ylr270p in inhibiting trehalase activity, as well as in the regulation of its expression preventing a wasteful futile cycle of synthesis-degradation of trehalose.

Evidence for a modulation of neutral trehalase activity by Ca2+ and cAMP signaling pathways in Saccharomyces cerevisiae

Saccharomyces cerevisiae neutral trehalase (encoded by NTH1) is regulated by cAMP-dependent protein kinase (PKA) and by an endogenous modulator protein. A yeast strain with knockouts of CMK1 and CMK2 genes (cmk1cmk2) and its isogenic control (CMK1CMK2) were used to investigate the role of CaM kinase II in the in vitro activation of neutral trehalase during growth on glucose. In the exponential growth phase, cmk1cmk2 cells exhibited basal trehalase activity and an activation ratio by PKA very similar to that found in CMK1CMK2 cells. At diauxie, even though both cells presented comparable basal trehalase activities, cmk1cmk2 cells showed reduced activation by PKA and lower total trehalase activity when compared to CMK1CMK2 cells. To determine if CaM kinase II regulates NTH1 expression or is involved in post-translational modulation of neutral trehalase activity, NTH1 promoter activity was evaluated using an NTH1-lacZ reporter gene. Similar beta-galactosidase activities were found for CMK1CMK2 and cmk1cmk2 cells, ruling out the role of CaM kinase II in NTH1 expression. Thus, CaM kinase II should act in concert with PKA on the activation of the cryptic form of neutral trehalase. A model for trehalase regulation by CaM kinase II is proposed whereby the target protein for Ca2+/CaM-dependent kinase II phosphorylation is not the neutral trehalase itself. The possible identity of this target protein with the recently identified trehalase-associated protein YLR270Wp is discussed.

Changes in external trehalase activity during human serum-induced dimorphic transition in Candida albicans

Yeast-like cells (blastoconidia) of Candida albicans growing exponentially on a glucose-containing medium (YPD) exhibited low external trehalase activity and stored a negligible amount of intracellular trehalose. The addition of human serum at 37 degrees C to exponential cultures promoted a high degree of germ-tube formation with no significant changes in trehalase activity or trehalose content. In contrast, stationary cells accumulated a large amount of trehalose, while external trehalase remained at a low and practically constant level. However, resting cultures were unable to enter the dimorphic program, except when they were supplemented with fresh YPD and serum together. Only under these conditions was trehalase activated and trehalose hydrolyzed. Specific inhibition of external trehalase by validoxylamine A caused a certain delay in, and a lower level of, germ-tube formation, but did not totally block the dimorphic conversion. These results suggest that external trehalase is not involved in the serum-induced morphological transition in C. albicans.

Biotechnological applications of the disaccharide trehalose

Trehalose is a disaccharide present in a variety of anhydrobiotic organisms which have the ability to promptly resume their metabolism after addition of water. It has been successfully used as a nontoxic cryoprotectant of enzymes, membranes, vaccines, animal and plant cells and organs for surgical transplants. It has been predicted that trehalose can also be used as an ingredient for dried and processed food. Therefore, the recent biotechnological applications of trehalose have imposed the standardization of methods for its production, as well as for its specific quantification.

Molecular biology of trehalose and the trehalases in the yeast Saccharomyces cerevisiae

The present state of knowledge of the role of trehalose and trehalose hydrolysis catalyzed by trehalase (EC 3.2.1.28) in the yeast Saccharomyces cerevisiae is reviewed. Trehalose is believed to function as a storage carbohydrate because its concentration is high during nutrient limitations and in resting cells. It is also believed to function as a stress metabolite because its concentration increases during certain adverse environmental conditions, such as heat and toxic chemicals. The exact way trehalose may perform the stress function is not understood, and conditions exist under which trehalose accumulation and tolerance to certain stress situations cannot be correlated. Three trehalases have been described in S. cerevisiae: 1) the cytosolic neutral trehalase encoded by the NTH1 gene, and regulated by cAMP-dependent phosphorylation process, nutrients, and temperature; 2) the vacuolar acid trehalase encoded by the ATH1 gene, and regulated by nutrients; and 3) a putative trehalase Nth1p encoded by the NTH2 gene (homolog of the NTH1 gene) and regulated by nutrients and temperature. The neutral trehalase is responsible for intracellular hydrolysis of trehalose, in contrast to the acid trehalase, which is responsible for utilization of extracellular trehalose. The role of the putative trehalase Nth2p in trehalose metabolism is not known. The NTH1 and NTH2 genes are required for recovery of cells after heat shock at 50 degrees C, consistent with their heat inducibility and sequence similarity. Other stressors, such as toxic chemicals, also induce the expression of these genes. We therefore propose that the NTH1 and NTH2 genes have stress-related function and the gene products may be called stress proteins. Whether the stress function of the trehalase genes is linked to trehalose is not clear, and possible mechanisms of stress protective function of the trehalases are discussed.

RAS2/PKA pathway activity is involved in the nitrogen regulation of L-leucine uptake in Saccharomyces cerevisiae

The aim of the present work is to study the participation of RAS2/PKA signal pathway in the nitrogen regulation of L-leucine transport in yeast cells. The study was performed on Saccharomyces cerevisiae isogenic strains with the normal RAS2 gene, the RAS2val19 mutant and the disrupted ras2::LEU2. These strains bring about different activities of the RAS2/PKA signal pathway, L-(14C)-Amino acid uptake measurements were determined in cells grown in a rich YPD medium with a mixed nitrogen source or in minimal media containing NH4+ or L-proline as the sole nitrogen source. We report herein that in all strains used, even in those grown in a minimal proline medium, the activity of the general amino acid permease (GAP1) was not detected. L-Leucine uptake in these strains is mediated by two kinetically characterized transport systems. Their KT values are of the same order as those of S1 and S2 L-leucine permeases. Mutation in the RAS2 gene alters initial velocities and Jmax values in both high and low affinity L-leucine transport systems. Activation of the RAS2/PKA signalling pathway by the RAS2val19 mutation, blocks the response to a poor nitrogen source whereas inactivation of RAS2 by gene disruption, results in an increase of the same response.

Effects of temperature shifts on the metabolism of trehalose in Neurospora crassa wild type and a trehalase-deficient (tre) mutant. Evidence against the participation of periplasmic trehalase in the catabolism of intracellular trehalose

The effects of temperature shifts on the metabolism of trehalose in Neurospora crassa were studied in conidiospore germlings of a wild type strain, and of a mutant (tre), deficient in the activity of periplasmic trehalase. When the temperature of the medium was raised from 30 degrees C to 45 degrees C both strains accumulated trehalose, either in media supplemented with glucose or with glycerol as carbon sources. The profiles of glycolysis metabolites suggested that at 45 degrees C glycolysis was inhibited at the level of the phosphofructokinase-1 reaction, while that of fructose-1,6-bisphosphatase was active, thus explaining how the flux of carbon from glucose or glycerol was channeled to trehalose synthesis at that temperature. This assumption was also supported by the changes in levels of fructose-2,6-bisphosphate, which dropped during the incubation at 45 degrees C. The opposite phenomena were observed when the cultures were reincubated at 30 degrees C and glycolysis was strongly activated. Surprisingly, the intracellular pool of trehalose of the mutant decreased after reincubation at 30 degrees C at the same rate observed for the wild type (about 25.0 nmol/min per mg protein) despite its low trehalase activity (about 5.0 nmol/min per mg protein). Labeling experiments using [U-14C]-glucose demonstrated that both the wild type and the mutant metabolized internally the trehalose pool, without detectable leakage of glucose or trehalose into the external medium. Cells submitted to heat shock in glycerol-supplemented medium and resuspended at 30 degrees in the absence of an exogenous carbon source and in the presence of the glycolysis inhibitor 2-deoxyglucose accumulated high levels of free intracellular glucose, indicating that trehalose was hydrolysed internally. This suggested the existence of a cytosolic regulatory trehalase in Neurospora crassa, but all efforts to detect such activity in cell extracts have been unsuccessful so far. Altogether, these results argued against the participation of the periplasmic trehalase of N. crassa in the catabolism of intracellular trehalose. They are also conflictant with the enzyme/substrate decompartmentation hypothesis, earlier suggested as a way of explaining the mobilization of endogenous trehalose reserves accumulated in fungal spores (reviewed in Thevelein 1984, Microbiol. Rev. 48, 42-59).

Comparative study of two trehalase activities from Fusarium oxysporum var. lini

Acid and neutral trehalase activities (optimum pH of 4.6 and 6.8, respectively) from Fusarium oxysporum var. lini were studied separately through partial isolation by ammonium sulfate precipitation followed by ion-exchange chromatography on DEAE-Sephacel for neutral enzyme, or using some of their differential properties. Acid activity was unaffected by 1 mM of Ca2+, Mg2+, Mn2+, Ba2+, or EDTA. Contrarily, the neutral enzyme was activated by Ca2+ with an apparent Ka of 0.15 mM; was inhibited by EDTA, Zn2+, Hg2+, or Mg(2+)-ATP; and showed an increase in activity by the raise of buffer ionic strength or by the addition of 100 mM KCl. Acid and neutral enzymes have, respectively, an apparent optimum temperature of 45 and 30 degrees C, an apparent Km for trehalose of 0.43 and 8.45 mM, and an apparent M(r) of 160,000 and 100,000 (by glycerol gradient ultracentrifugation). Acid trehalase was specifically inhibited by acetate buffer and more stable at 50 degrees C than the neutral enzyme. Neutral enzyme exhibited a pI of 6.2 by isoelectric focusing. Contrary to neutral trehalases from other fungi, the enzyme from Fusarium oxysporum var. lini was not activated in crude extract by treatment with Mg(2+)-ATP in the presence of cAMP and not inactivated by alkaline phosphatase from Escherichia coli.

Differential changes in the activity of cytosolic and vacuolar trehalases along the growth cycle of Saccharomyces cerevisiae

Saccharomyces cerevisiae cells contain two intracellular and soluble trehalases with distinct subcellular location (cytosol and vacuoles, respectively). Both enzymes showed an opposite pattern of activity along the growth cycle. Activity of the cytosolic trehalase was high in cells growing exponentially on fermentable sugars (glucose, mannose or galactose) and sharply decayed as the cultures enter stationary phase coinciding with the beginning of trehalose biosynthesis. By contrast, vacuolar trehalase was only detectable in glucose-grown resting cells or in cultures growing on respiratory substrates (glycerol or ethanol). This enzyme was partially derepressed in the mutant hex2, which is deficient in glucose repression. Addition of fresh YPD medium to stationary-phase cultures induced the sudden reactivation of cytosolic trehalase with the concomitant slower inactivation of vacuolar trehalase. However, addition of glucose or various nitrogen sources alone had only a minor effect on both activities. The presence of cycloheximide had no effect on cytosolic trehalase, whereas completely blocked the appearance of vacuolar trehalase suggesting the requirement of protein synthesis 'de novo'.

The interaction of Saccharomyces cerevisiae trehalase with membranes

Plasma membranes isolated from cells of Saccharomyces cerevisiae previously submitted to a heat-shock showed a 10-fold increase in membrane-bound trehalase activity. Trehalase was purified to a high specific activity and was shown to be inhibited by glucose 6-phosphate and by the addition of a neutral phospholipid-like surfactant. Purified trehalase binds spontaneously to egg phosphatidylcholine small unilamellar vesicles, when in its active, phosphorylated form. When the enzyme was treated with alkaline phosphatase no binding was observed. The significance of this reversible binding for the control of trehalose metabolism in yeast cells is still unknown.

Lack of correlation between trehalase activation and trehalose-6 phosphate synthase deactivation in cAMP-altered mutants of Saccharomyces cerevisiae

The rise in cAMP level that follows the addition of glucose or 2,4-dinitrophenol (DNP) to stationary-phase cells of Saccharomyces cerevisiae was accompanied by a marked activation of trehalase (3-fold increase) and a concomitant deactivation of trehalose-6 phosphate synthase (50% of the basal levels). In glucose-grown exponential cells, which are deficient in glucose-induced cAMP signalling, the addition of glucose also prompted a decrease in trehalose-6 phosphate synthase, but had no effect on trehalase activity. Mutants defective in the RAS-adenylate cyclase pathway (ras1 ras2 bcy1 strain), as well as mutants containing greatly reduced protein kinase activity either cAMP-dependent (tpkw1 BCY1 strains) or cAMP-independent (tpk1w1 bcy1 strains), were unable to show glucose- or DNP-induced trehalase activation but still displayed a clear decrease in trehalose-6 phosphate synthase activity upon addition of these compounds. These data suggest that the activity of trehalose-6 phosphate synthase, as opposed to that of trehalase, is not controlled by the cAMP signalling pathway "in vivo". Trehalose-6 phosphate synthase was competitively inhibited by glucose (Ki = 15 mM) and resulted unaffected by ATP in assays performed "in vitro".

Analysis of glucose repression in Saccharomyces cerevisiae by pulsing glucose to a galactose-limited continuous culture

In this study, glucose repression in Saccharomyces cerevisiae was analysed under defined physiological conditions, at both the molecular and physiological levels, by pulsing glucose to a galactose-limited continuous culture. During this pulse of glucose, the galactose feed was kept constant. Directly after the glucose pulse, carbon dioxide production increased while oxygen consumption remained constant, demonstrating that the surplus of glucose had been consumed by means of fermentation. The direct accumulation of galactose in the medium after the glucose pulse indicated that the consumption of galactose had been stopped instantaneously. Galactose uptake experiments revealed that the galactose transporter was still present but apparently was incapable of galactose uptake, which could be due to inhibition of the galactose transporter by glucose. The total concentration of cAMP increased from 5 nmol g-1 at t = 0 to 25 nmol g-1 at t = 1.5 min. After 2 min the concentration of cAMP gradually decreased again to the normal level. Within 2 min after the addition of glucose, the transcription of the GAL genes and SUC2 was inhibited. In addition, the transcription of the HXK1 gene, encoding hexokinase isoenzyme 1, was also inhibited, which demonstrates that the HXK1 gene is regulated at the transcriptional level comparable with invertase.

Trehalose levels and survival ratio of freeze-tolerant versus freeze-sensitive yeasts

Five freeze-tolerant yeast strains suitable for frozen dough were compared with ordinary commercial bakers' yeast. Kluyveromyces thermotolerans FRI 501 cells showed high survival ability after freezing when their resting cells were fermented for 0 to 180 min in modified liquid medium, and they grew to log and stationary phases. Among the freeze-tolerant strains of Saccharomyces cerevisiae, FRI 413 and FRI 869 showed higher surviving and trehalose-accumulating abilities than other S. cerevisiae strains, but were affected by a prolonged prefermentation period and by growth phases. The freeze tolerance of the yeasts was, to some extent, associated with the basal amount of intracellular trehalose after rapid degradation at the onset of the prefermentation period. In the freeze-sensitive yeasts, the degree of hydrolysis of trehalose may thus be affected by the kind of saccharide, unlike in freeze-tolerant yeasts.

The ras oncogene--an important regulatory element in lower eucaryotic organisms

The ras proto-oncogene in mammalian cells encodes a 21-kilodalton guanosine triphosphate (GTP)-binding protein. This gene is frequently activated in human cancer. As one approach toward understanding the mechanisms of cellular transformation by ras, the function of this gene in lower eucaryotic organisms has been studied. In the yeast Saccharomyces cerevisiae, the RAS gene products serve as essential function by regulating cyclic adenosine monophosphate metabolism. Stimulation of adenylyl cyclase is dependent not only on RAS protein complexed to GTP, but also on the CDC25 and IRA gene products, which appear to control the RAS GTP-guanosine diphosphate cycle. Although analysis of RAS biochemistry in S. cerevisiae has identified mechanisms central to RAS action, RAS regulation of adenylyl cyclase appears to be strictly limited to this particular organism. In Schizosaccharomyces pombe, Dictyostelium discoideum, and Drosophila melanogaster, ras-encoded proteins are not involved with regulation of adenylyl cyclase, similar to what is observed in mammalian cells. However, the ras gene product in these other lower eucaryotes is clearly required for appropriate responses to extracellular signals such as mating factors and chemoattractants and for normal growth and development of the organism. The identification of other GTP-binding proteins in S. cerevisiae with distinct yet essential functions underscores the fundamental importance of G-protein regulatory processes in normal cell physiology.

Cyclic AMP controls the plasma membrane H+-ATPase activity from Saccharomyces cerevisiae

The thermosensitive G1-arrested cdc35-10 mutant from Saccharomyces cerevisiae, defective in adenylate cyclase activity, was shifted to restrictive temperature. After 1 h incubation at this temperature, the plasma membrane H+-ATPase activity of cdc35-10 was reduced to 50%, whereas that in mitochondria doubled. Similar data were obtained with cdc25, another thermosensitive G1-arrested mutant modified in the cAMP pathway. In contrast, the ATPase activities of the G1-arrested mutant cdc19, defective in pyruvate kinase, were not affected after 2 h incubation at restrictive temperature. In the double mutants cdc35-10 cas1 and cdc25 cas1, addition of extracellular cAMP prevented the modifications of ATPase activities observed in the single mutants cdc35-10 and cdc25. These data indicate that cAMP acts as a positive effector on the H+-ATPase activity of plasma membranes and as a negative effector on that of mitochondria.

Comparative studies between the glucose-induced phosphorylation signal and the heat shock response in mutants of Saccharomyces cerevisiae

Addition of glucose to derepressed yeast cells, as well as a heat shock treatment, trigger the phosphorylation of trehalase and of trehalose-6-phosphate synthase. In the present paper, evidence is provided for the requirement of the RAS protein in the transduction of the glucose signal. On the other hand, a heat shock at 52 degrees C for 2 min was able to produce a significant phosphorylating effect even in mutant strains deficient in the GTP binding protein. Moreover, it was shown that this treatment does not affect exclusively the cAMP-dependent protein kinase. The use of a series of mutant strains confirmed that low levels of cAMP favor thermotolerance; the role of trehalose in yeast viability is also discussed.

Substrate specificity of the phosphorylated fructose-1,6-bisphosphatase dephosphorylating protein phosphatase from Saccharomyces cerevisiae

Enzymatic dephosphorylation of the phosphorylated forms of five different yeast enzymes has been studied: fructose-1,6-bisphosphatase, glycogen phosphorylase, neutral trehalase, NAD-glutamate dehydrogenase and 6-phosphofructo-2-kinase. Phosphorylated fructose-1,6-bisphosphatase and phosphorylated 6-phosphofructo-2-kinase were present in extracts of starved yeast cells which had been incubated for 10 min with glucose. Phosphorylated glycogen phosphorylase, neutral trehalase and NAD-glutamate dehydrogenase were obtained by incubation of yeast extract with ATP, cyclic AMP and Mg2+. After incubation with commercially available preparations of alkaline phosphatase, all five phosphorylated enzymes studied showed the changes in catalytic activity that would be expected as a consequence of dephosphorylation. The recently purified yeast enzyme which dephosphorylates phosphorylated fructose-1,6-bisophosphatase (Horn and Holzer (1987) however, was found to be active only with the phosphorylated fructose-1,6-bisphosphatase, but not with the other four phosphorylated enzymes studied. By contrast, a crude extract from yeast showed dephosphorylating activity towards all five substrates. Substrate specificity with the five phosphorylated enzymes studied of different phosphoprotein phosphatases from yeast prepared by others is discussed.

Differential location of regulatory and nonregulatory trehalases in Candida utilis cells

The isolation of vacuoles by density gradient centrifugation of protoplast lysates from Candida utilis cells showed a high specific activity for nonregulatory trehalase in vacuoles whereas the regulatory trehalase activatable by phosphorylation behaves as a cytoplasmic enzyme. The vacuolar trehalase is a glycoprotein that can be precipitated by Con A-Sepharose. Treatment of this enzyme with endo H reduced its reactivity with the lectin without loss of enzyme activity and decreased its apparent molecular weight by gel filtration.

Characterization of low- and high-affinity glucose transports in the yeast Kluyveromyces marxianus

Glucose transport in the yeast Kluyveromyces marxianus proceeds by two functionally and presumably structurally distinct transporters depending on the carbon source of the culture medium. In lactose-grown cells, glucose was taken up through a high-affinity H+-sugar symporter (Km = 0.09 mM), whereas a low-affinity transporter (Km = 3.5 mM) was utilized in glucose-grown cells. The two transporters exhibited different substrate specificities. Galactose was demonstrated to be a selective substrate of the H+-glucose symporter (Km = 0.14 mM) and did not significantly enter glucose-grown cells. Fructose was a preferential substrate of the low-affinity carrier (Km = 3.5 mM), but it entered lactose-grown cells through a high-affinity H+-fructose symporter distinct from the H+-glucose one. Other putative substrates of the two glucose transporters were identified by competition experiments. 2-Deoxyglucose recognized both carriers with a similar affinity, while the non-phosphorylatable analogues 6-deoxyglucose, 3-O-methylglucose and D-fucose exhibited a 10-30 fold preference for the high-affinity transporter.

Cyclic AMP controls the switch between division cycle and resting state programs in response to ammonium availability in Saccharomyces cerevisiae

We have identified a mutation called rcal (for rescue by cAMP) which allows adenylate cyclase-deficient mutants to divide in the presence of cAMP. We took advantage of this rcal mutation to study the effect of externally added cAMP on the onset of the resting state when cells are starved for ammonium. We measured the resistance of the cells to zymolyase treatment as a parameter of the resting state. We observed that the onset of the resting state is reversibly blocked by cAMP. This inhibitory effect of cAMP is discussed together with the cAMP control of the start. This leads us to propose a model in which the cAMP level, controlled by the availability of nutrients, should trigger the choice between the entry of the cell into the resting state and the initiation of a new division cycle.