Protein phosphatase type-1 regulatory subunits Reg1p and Reg2p act as signal transducers in the glucose-induced inactivation of maltose permease in Saccharomyces cerevisiae

The REG1 gene encodes a regulatory subunit of the type-1 protein phosphatase (PP1) Glc7 in Saccharomyces cerevisiae, which directs the catalytic subunit to substrates involved in glucose repression. Loss of REG1 relieves glucose repression of many genes, including the MAL structural genes that encode the maltose fermentation enzymes. In this report, we explore the role of Reg1p and its homolog Reg2p in glucose-induced inactivation of maltose permease. Glucose stimulates the proteolysis of maltose permease and very rapid loss of maltose transport activity – more rapid than can be explained by loss of the permease protein alone. In a reg1Δ strain we observe a significantly reduced rate of glucose-induced proteolysis of maltose permease, and the rapid loss of maltose transport activity does not occur. Instead, surprisingly, the slow rate of proteolysis of maltose permease is accompanied by an increase in maltose transport activity. Loss of Reg2p modestly reduces the rates of both glucose-induced proteolysis of maltose permease and inactivation of maltose transport activity. Overexpression of Reg2p in a reg1Δ strain suppresses the effect on maltose permease proteolysis and partially restores the inactivation of maltose transport activity, but does not affect the insensitivity of MAL gene expression to repression by glucose observed in this strain. Thus, protein phosphatase type-1 (Glc7p-Reg1p and Glc7p-Reg2p) plays a role in transduction of the glucose signal during glucose-induced proteolysis of maltose permease, but only Glc7p-Reg1p is involved in glucose-induced inactivation of maltose transport activity and glucose repression of MAL gene expression. Overexpression of REG1 partially restores proteolysis of maltose permease in a grr1Δ strain, which lacks glucose signaling, but does not rescue rapid inactivation of maltose transport activity or sensitivity to glucose repression. A model for the role of Reg1p and Reg2p in glucose signaling pathways is discussed. We also uncovered a previously unrecognized G2/M delay in the grr1Δ but not the reg1Δ strains, and this delay is suppressed by REG1 overexpression. The G1/S delay seen in grr1Δ mutants is slightly suppressed as well, but REG1 overexpression does not suppress other grr1Δ phenotypes such as insensitivity to glucose repression. Received: 21 October 1999 / Accepted: 28 December 1999     

Regulation of glucose and maltose transport in strains ofSaccharomyces

Summary Growth of yeast cells on glucose resulted in complete inactivation of maltose transport and repression of the high affinity glucose transport system. When the cells were grown on maltose or subjected to substrate starvation, an increase in glucose and maltose transport was observed in both brewing and non-brewing yeast strains. The concentration of glucose employed in the growth medium was also observed to affect sugar transport activity. The higher the glucose concentration, the more pronounced the repressive effect. In addition, the time of growth of yeast on glucose or maltose also intermining the rate of sugar transport. These results are consistent with the repressive effect of glucose on the high affinity glucose and maltose transport systems.     

Transient responses of <Emphasis Type="Italic">Wickerhamia</Emphasis> sp. yeast continuous cultures to qualitative changes in carbon source supply: induction and catabolite repression of α-amylase synthesis

The purpose of this study was to evaluate the inductive effect of starch and maltose, and the repressive/inhibitory effect of glucose, on amy-1 gene expression and α-amylase production by Wickerhamia sp., using continuous culture under transient-state conditions at a dilution rate (D) of 0.083 h^?1. Induction and repression kinetics of α-amylase were studied by changing the medium feed from glucose to maltose or starch in the induction experiments and vice versa in the repression experiments. Expression levels of amy-1 gene were measured by RT-qPCR. Results showed that starch was a more efficient inducer of α-amylase synthesis compared to maltose, with maximum accumulation rate constants of 0.424 and 0.191 h^?1, respectively. In contrast, α-amylase synthesis in starch and maltose cultures was partially repressed by glucose as indicated by a specific activity close to basal levels and a decay constant rate (??0.065 and ??0.069 h^?1, respectively) higher than ??D. A linear dependence of the specific rate of α-amylase production on mRNA relative abundance of amy-1 gene was observed. An inhibitory effect of glucose was not observed even at a concentration of 30 g L^?1. In conclusion, the transient continuous culture is a useful tool to determine the qualitative and quantitative effects of maltose and starch on α-amylase induction and of glucose on enzyme repression, as well as to obtain a detailed understanding of the dynamic behavior of the yeast culture. Furthermore, results showed that amylaceous substrates can be very effective carbon sources for the production of α-amylase without being inhibited by glucose.     

Derepression of a baker's yeast strain for maltose utilization is associated with severe deregulation of HXT gene expression

Aims: We undertook to improve an industrial Saccharomyces cerevisiae strain by derepressing it for maltose utilization in the presence of high glucose concentrations. Methods and Results: A mutant was obtained from an industrial S. cerevisiae strain following random UV mutagenesis and selection on maltose/5‐thioglucose medium. The mutant acquired the ability to utilize glucose simultaneously with maltose and possibly also sucrose and galactose. Aerobic sugar metabolism was still largely fermentative, but an enhanced respirative metabolism resulted in a 31% higher biomass yield on glucose. Kinetic characterization of glucose transport in the mutant revealed the predominance of the high‐affinity component. Northern blot analysis showed that the mutant strain expresses only the HXT6/7 gene irrespective of the glucose concentration in the medium, indicating a severe deregulation in the induction/repression pathways modulating HXT gene expression. Interestingly, maltose‐grown cells of the mutant display inverse diauxy in a glucose/maltose mixture, preferring maltose to glucose. Conclusion: In the mutant here reported, the glucose transport step seems to be uncoupled from downstream regulation, because it seems to be unable to sense abundant glucose, via both repression and induction pathways. Significance and Impact of the Study: We report here the isolation of a S. cerevisiae mutant with a novel derepressed phenotype, potentially interesting for the industrial fermentation of mixed sugar substrates.     

Utilisation of maltose and glucose by lactobacilli isolated from sourdough

Abstract The utilisation of glucose and maltose was investigated with Lactobacillus strains isolated from sourdough starters. These preparations have been in continuous use for a long period to produce sourdough from rye, wheat and sorghum. The major metabolic products formed by resting cells from glucose or maltose were lactate, ethanol and acetate. Upon fermentation of maltose, resting cells of Lactobacillus sanfrancisco, L. reuteri, L. fermentum and Lactobacillus ep. released up to 13.8 mM glucose after 8 h. The ratio of released glucose per mol of utilised maltose was up to 1:1. Glucose formation was high when starved cells of L. sanfrancisco and Lactobacillus sp. were used. This is consistent with maltose utilisation via maltose phosphorylase which phosphorylates maltose without the expenditure of ATP and thus allows the cell to waste glucose in the presence of abundant maltose. The glucose formed may be utilised by the lactobacilli or other microorganisms, e.g. yeasts. However, the release of glucose into the medium by sourdough lactobacilli prevents competitors from utilising the abundant maltose by glucose repression. In strains of L. sanfrancisco , maltose utilisation was very effective and not subject to glucose repression. Therefore, they overgrow other microorganisms sharing this habitat. Wild isolates of L. sanfrancisco were initially unable to grow on glucose. Upon growth on maltose such strains required adaptation times of up to 150 h to grow on glucose. After subsequent transfer of glucose-grown cells to fresh medium the strains resumed growth both on glucose or maltose. They readily lost their ability to grow on glucose upon exposure to maltose. L. sanfrancisco exhibited biphasic growth characteristics on media containing glucose, maltose or both carbon sources. Evidence is provided that biphasic growth and metabolite formation are dependent on the redox potential.     

Alleviation of glucose repression of maltose metabolism by MIG1 disruption in Saccharomyces cerevisiae.

The MIG1 gene was disrupted in a haploid laboratory strain (B224) and in an industrial polyploid strain (DGI 342) of Saccharomyces cerevisiae. The alleviation of glucose repression of the expression of MAL genes and alleviation of glucose control of maltose metabolism were investigated in batch cultivations on glucose-maltose mixtures. In the MIG1-disrupted haploid strain, glucose repression was partly alleviated; i.e., maltose metabolism was initiated at higher glucose concentrations than in the corresponding wild-type strain. In contrast, the polyploid delta mig1 strain exhibited an even more stringent glucose control of maltose metabolism than the corresponding wild-type strain, which could be explained by a more rigid catabolite inactivation of maltose permease, affecting the uptake of maltose. Growth on the glucose-sucrose mixture showed that the polypoid delta mig1 strain was relieved of glucose repression of the SUC genes. The disruption of MIG1 was shown to bring about pleiotropic effects, manifested in changes in the pattern of secreted metabolites and in the specific growth rate.     

Characterization of sugar transport in 2-deoxy-d-glucose resistant mutants of yeast

Summary A number of 2-deoxy-d-glucose (2-DOG) resistant mutants exhibiting resistance to glucose repression were isolated from variousSaccharomyces yeast strains. Most of the mutants isolated were observed to have improved maltose uptake ability in the presence of glucose. Fermentation studies indicated that maltose was taken up at a faster rate and glucose taken up at a slower rate in the mutant strains compared to the parental strains, when these sugars were fermented together. When these sugars were fermented separately, only the 2-DOG resistant mutant obtained fromSaccharomyces cerevisiae strain 1190 exhibited alterations in glucose and maltose uptake compared to the parental strain. Kinetic analysis of sugar transport employing radiolabelled glucose and maltose indicated that both glucose and maltose were transported with higher rates in the mutant strain. These results suggested that the high affinity glucose transport system was regulated by glucose repression in the parental strain but was derepressed in the mutant.     

An evaluation of D-glucosamine as a gratuitous catabolite repressor of Saccharomyces carlsbergensis.

Summary Glucose represses mitochondrial biogenesis and the fermentation of maltose, galactose and sucrose in yeast. We have analyzed the effect of D-glucosamine on these function, in order to determine if it can produce a similar repression. It was found that glucosamine represses the respiration rate (QO₂) but more rapidly than glucose and to a final level slightly higher than in glucose-treated cells. Derepression of the respiration rate following either glucose or glucosamine repression was similar. A two hour lag was followed by a linear increase in QO₂ to the derepressed level. Both glucose and glucosamine repressed the level of cytochrome oxidase to the same level. Glucosamine was also found to repress maltose and galactose fermentation but not sucrose fermentation. The derepression of maltase synthesis was inhibited by glucosamine. The constitutive synthesis of maltase was repressed by the addition of glucosamine. Glucosamine was judged to produce a repressed state similar to glucose repression in many respects.     

Repression and inactivation by glucose of the maltose transport system of Candida utilis

Summary The maltose utilization system of Candida utilis was affected by glucose through two different mechanisms: catabolite repression and inactivation. Maltose permease was under the control of both, whereas -glucosidase was only repressed.In glucose-maltose continuous culture, both sugars were consumed simultaneously at glucose steady-state concentrations in the fermentor below 100 mg/l, corresponding to dilution rates lower than 0.4 h^-1. At higher dilution rates, and consequently higher glucose concentrations, repression increased steeply, being complete when glucose concentration reached 170 mg/l.Glucose induced inactivation of maltose permease, in maltose-growing and resting cells, by decreasing V _max, without changing maltose affinity for its transport system. The inactivation process apparently required the entrance of the inactivator into the cell and its subsequent phosphorylation because: 1) The specific inactivation rate showed a dependence on glucose similar to that of glucose transport and 2) only rapidly phosphorylated glucose analogues could mimic the inactivation effect.     

Regulation of maltose metabolism in stationary phase cultures of an asporogenous mutant of Bacillus licheniformis

An asporogenous strain of Bacillus licheniformis accumulated maltose by an energy dependent transport mechanism during an extended stationary phase. Maltose transport was sensitive to the effects of the uncoupler tetrachlorosalicylanide (TCS), and was also inhibited by glucose. Maltose stimulated synthesis of a p -nitrophenyl-α- D -glucoside-hydrolysing enzyme ( p NPGase) in log phase and in stationary phase cells. In the presence of glucose this induction was inhibited. Glucose was used preferentially to maltose in stationary phase cells. The uptake of maltose from the medium, and the synthesis of p NPGase, were immediately and completely inhibited in the presence of glucose. These results are consistent with a mechanism of inducer exclusion mediating the repressive effect of glucose upon p NPGase synthesis in stationary phase cells. Catabolite repression of α-amylase synthesis by glucose was also demonstrated in late stationary phase mutant cells.     

Enterotoxin A synthesis in Staphylococcus aureus: inhibition by glycerol and maltose

Studies indicated that prior growth of Staphylococcus aureus 196E on glycerol or maltose led to cells with repressed ability to produce staphylococcal enterotoxin A (SEA). A PTS- mutant (196E-MA) lacking the phosphoenolpyruvate phosphotransferase system (PTS), derived from strain 196E, showed considerably less repression of SEA synthesis when cells were grown in glycerol or maltose. Since SEA synthesis is not repressed in the PTS- mutant, repression of toxin synthesis by glycerol, maltose or glucose in S. aureus 196E appears to be related to the presence of a functional PTS irrespective of whether the carbohydrate requires the PTS for cell entry. With lactose as an inducer, glucose, glycerol, maltose or 2-deoxyglucose repressed the synthesis of beta-galactosidase in S. aureus 196E. It is postulated that these compounds repress enzyme synthesis by an inducer exclusion mechanism involving phosphorylated sugar intermediates. However, inducer exclusion probably does not explain the mechanism of repression of SEA synthesis by carbohydrates.     

Effects of the principal nutrients on lovastatin production by Monascus pilosus

Lovastatin production is dependent on the substrates provided. We investigated how several carbon and nitrogen sources in the medium affect lovastatin production by Monascus pilosus. M. pilosus required a suitable concentration of organic nitrogen peptone for high lovastatin production. As sole carbon source with peptone, although glucose strongly repressed lovastatin production, maltose was responsible for high production. Interestingly, glycerol combined with maltose enhanced lovastatin production, up to 444 mg/l in the most effective case. Moreover, an isolated mutant, in which glucose repression might be relieved, easily produced the highest level of lovastatin, 725 mg/l on glucose-glycerol-peptone medium. These observations indicate that lovastatin production by M. pilosus is regulated by strict glucose repression and that an appropriate release from this repression by optimizing medium composition and/or by a mutation(s) is required for high lovastatin production.     

Maltose fermentation and leavening ability of baker's yeast

Summary Baker's yeasts with completely differenta-glucoside permease,a-glucosidase and maltose fermentation activities may still be almost equivalent in their leavening ability.A repression of the maltose uptake system of yeast occurs in a medium that besides maltose contains glucose or fructose. Hardly any maltose is utilized until the concentration of monosaccharide falls below 0.2% and a derepression of the maltose uptake system starts. It is almost conceivable that the repression also takes place in dough, as the hexose content of wheat flour is high enough to repress the maltose uptake system. The activities of the maltose fermenting system do not influence the leavening ability of the yeast as measured for the first hour of proofing, although maltose is the predominant sugar present.     

Kinetics of alpha-amylase synthesis from Bacillus amyloliquefaciens

The microbial production of alpha-amylase from Bacillus amyloliquefaciens was investigated. The microorganism was grown using media containing glucose or maltose at 37 degrees C and under aerobic conditions in a 16-L fermentor. The alpha-amylase synthesis from maltose was not found to be inducible but was found to be subject to catabolite repression. The maltose uptake rate was observed to be the rate-limiting step compared to the conversion rate of maltose to glucose by intracellular alpha-glucosidase. The alpha-amylase activity achieved with maltose as a substrate was higher than that achieved with glucose. A slower growth rate and a higher cell density were obtained with maltose. The enzyme production pattern depended upon the nutrient composition of the medium.     

Modelling the growth kinetics of <Emphasis Type="Italic">Kocuria marina</Emphasis> DAGII as a function of single and binary substrate during batch production of β-Cryptoxanthin

In the present investigation, growth kinetics of Kocuria marina DAGII during batch production of β-Cryptoxanthin (β-CRX) was studied by considering the effect of glucose and maltose as a single and binary substrate. The importance of mixed substrate over single substrate has been emphasised in the present study. Different mathematical models namely, the Logistic model for cell growth, the Logistic mass balance equation for substrate consumption and the Luedeking–Piret model for β-CRX production were successfully implemented. Model-based analyses for the single substrate experiments suggested that the concentrations of glucose and maltose higher than 7.5 and 10.0 g/L, respectively, inhibited the growth and β-CRX production by K. marina DAGII. The Han and Levenspiel model and the Luong product inhibition model accurately described the cell growth in glucose and maltose substrate systems with a R ² value of 0.9989 and 0.9998, respectively. The effect of glucose and maltose as binary substrate was further investigated. The binary substrate kinetics was well described using the sum-kinetics with interaction parameters model. The results of production kinetics revealed that the presence of binary substrate in the cultivation medium increased the biomass and β-CRX yield significantly. This study is a first time detailed investigation on kinetic behaviours of K. marina DAGII during β-CRX production. The parameters obtained in the study might be helpful for developing strategies for commercial production of β-CRX by K. marina DAGII.     

Maltose and maltotriose can be formed endogenously in Escherichia coli from glucose and glucose-1-phosphate independently of enzymes of the maltose system.

The maltose system in Escherichia coli consists of cell envelope-associated proteins and enzymes that catalyze the uptake and utilization of maltose and alpha,1-4-linked maltodextrins. The presence of these sugars in the growth medium induces the maltose system (exogenous induction), even though only maltotriose has been identified in vitro as an inducer (O. Raibaud and E. Richet, J. Bacteriol., 169:3059-3061, 1987). Induction is dependent on MalT, the positive regulator protein of the system. In the presence of exogenous glucose, the maltose system is normally repressed because of catabolite repression and inducer exclusion brought about by the phosphotransferase-mediated vectorial phosphorylation of glucose. In contrast, the increase of free, unphosphorylated glucose in the cell induces the maltose system. A ptsG ptsM glk mutant which cannot grow on glucose can accumulate [14C]glucose via galactose permeases. In this strain, internal glucose is polymerized to maltose, maltotriose, and maltodextrins in which only the reducing glucose residue is labeled. This polymerization does not require maltose enzymes, since it still occurs in malT mutants. Formation of maltodextrins from external glucose as well as induction of the maltose system is absent in a mutant lacking phosphoglucomutase, and induction by external glucose could be regained by the addition of glucose-1-phosphate entering the cells via a constitutive glucose phosphate transport system. malQ mutants, which lack amylomaltase, are constitutive for the expression of the maltose genes. This constitutive nature is due to the formation of maltose and maltodextrins from the degradation of glycogen.     

Construction of industrial baker's yeast strains able to assimilate maltose under catabolite repression conditions

Spore progeny from an industrial baker's yeast strain were mutagenized with UV and mutants resistant to 2-deoxyglucose isolated. One of these mutants (10a12–13) showed high levels of maltase (-glucosidase) and external invertase, and assimilated maltose when growing under catabolite repression conditions. This mutant was not allelic to any of the catabolite repression mutants tested cat4, cat80, cid1, cyc8, hex2, hxk2 and tup1. Mutant 10a12–13 was crossed with appropriate strains to construct hybrids that were also able to assimilate maltose in the presence of glucose. These hybrids may be useful in fermentation processes where both glucose and maltose are present.     

Parallel changes in catabolite repression of haem biosynthesis and cytochromes in repression-resistant mutants of Saccharomyces cerevisiae

Effects of three mutant genes, CAT1-2d, cat2-1 and hex2-3, on catabolite repression of mitochondrial cytochromes and the first two enzymes of haem biosynthesis were compared. The CAT1-2d mutation gave no resistance to glucose, whereas cat2-1 endowed both cytochromes and 5-aminolaevulinate dehydratase with resistance, but did not alter the effect of glucose on 5-aminolaevulinate synthase. The hex2-3 mutation caused repression resistance of cytochromes and of the two haem biosynthetic enzymes. hex2-3 strains also accumulated intracellular 5-aminolaevulinate. Co-inheritance of the latter traits, sensitivity to maltose inhibition and ability to grow on raffinose in the presence of 2-deoxyglucose, demonstrated that the pleiotropic phenotype is a function of the single gene hex2-3. Revertants which grew on maltose regained sensitivity to deoxyglucose and exhibited normal sensitivity of cytochromes and haem biosynthesis enzymes to repression. Addition of the hex1-18 mutation, which renders cytochromes resistant to repression, to a cat2-1 strain did not produce the same effect on 5-aminolaevulinate synthase as hex2-3. It is concluded that repression patterns of haem and cytochrome biosynthesis are substantially affected by hex2-3 and cat2-1 but not by CAT1-2d.