Influence of parenterally injected trehalose in mammals having trehalase activity at different sites]

When trehalose is injected via parenteral pathway into animals lacking kidney trehalase (rat), more than 75 per cent of this disaccharide is eliminated in urine. When the injected animals possess an active kidney trehalase (guinea-pig, rabbit), there is only a low urinary trehalose excretion. Moreover, in rabbit, a marked hyperglycaemia is observed which is due to the rapid hydrolysis of trehalose by kidney trehalase.     

Further evidence for the alternative pathway of trehalose synthesis linked to maltose utilization in Saccharomyces

Summary Yeast strains bearing a deficiency in trehalose-6-phosphate synthase activity are unable to accumulate trehalose on any carbon source unless they contain one of the MAL genes. If the gene is inducible then synthesis of trehalose occurs specifically during growth on maltose when the MAL gene is constitutive then trehalose accumulation can also be seen when cells are grown on glucose. Different systems for trehalose synthesis were suggested: one of them would require the UDPG-linked trehalose synthase whereas the second would utilize an alternative pathway. We proposed a mechanism by which the gene-product of a MAL gene would serve as a common positive regulator for the expression of the genes coding for maltose permease, -glucosidase and some component of the trehalose accumulation system. In order to elucidate this novel pathway a strain lacking UDPG-linked trehalose synthase activity and harboring a defect in maltose uptake was constructed. Excessive maltose uptake resulted in accumulation of intracellular maltose, and twice as much trehalose as in a control strain. Partial inhibition of hexokinase by xylose affected the ratio between internal maltose and trehalose and significantly reduced glycogen synthesis. Sodium fluoride also blocked glycogen synthesis but allowed for trehalose accumulation. Moreover, a mutant which lacks hexokinase I and II was unable to accumulate trehalose when grown on glucose in spite of the presence of a constitutive MAL2 gene. These results suggest that trehalose synthesis would require G-6-P formation derived from maltose. Such a deviation would allow for slowing down the glycolytic flux which, in turn, would favour efficient maltose utilization. Therefore, trehalose synthesis during growth in media containing glucose serves as an additional parameter for assessing constitutivity of MAL genes.     

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.     

Trehalase from Bradyrhizobium sp. (Lupinus) and Lupinus polyphyllus

Trehalase (THA), which hydrolyzes disaccharide trehalose into α-D -glucose, has been found in Bradyrhizobium sp. (Lupinus) and in various organs of Lupinus polyphyllus. Particularly, high THA activity was found in the lupin root nodules. The electrophoretic patterns of the native trehalase activity from the root nodules and Bradyrhizobium sp. (Lupinus) in the nondenaturating conditions were similar. The enzyme from the bradyrhizobium and lupin root nodules exhibited the optimal activity at the acidic pH and was under the effect of a high concentration of monovalent cations (NH4⁺, K⁺, Na⁺). Divalent cations, Zn²⁺ and Ca²⁺ (1 mM and 5 mM ) influenced lupin trehalase only slightly, whereas bradyrhizobial THA was inhibited by Zn²⁺ but tolerant to Ca²⁺. In addition, a little change in the THA activity from rhizobium in the presence of EDTA was observed. The enzyme from the root nodules was not affected by this chelating agent whereas trehalase activity from other organs of lupin was increased in the presence of 5 mM EDTA.     

A halotolerant Enterobacter sp. displaying ACC deaminase activity promotes rice seedling growth under salt stress

Agricultural productivity is proven to be hampered by the synthesis of reactive oxygen species (ROS) and production of stress-induced ethylene under salinity stress. One-aminocyclopropane-1-carboxylic acid (ACC) is the direct precursor of ethylene synthesized by plants. Bacteria possessing ACC deaminase activity can use ACC as a nitrogen source preventing ethylene production. Several salt-tolerant bacterial strains displaying ACC deaminase activity were isolated from rice fields, and their plant growth-promoting (PGP) properties were determined. Among them, strain P23, identified as an Enterobacter sp. based on phenotypic characteristics, matrix-assisted laser desorption ionization-time of flight mass spectrometry data and the 16S rDNA sequence, was selected as the best-performing isolate for several PGP traits, including phosphate solubilization, IAA production, siderophore production, HCN production, etc. Enterobacter sp. P23 was shown to promote rice seedling growth under salt stress, and this effect was correlated with a decrease in antioxidant enzymes and stress-induced ethylene. Isolation of an acdS mutant strain enabled concluding that the reduction in stress-induced ethylene content after inoculation of strain P23 was linked to ACC deaminase activity.     

Characterization of maltose and maltotriose transport in the acarbose-producing bacterium Actinoplanes sp

Acarbose, a pseudomaltotetraose, is produced by strains of the genus Actinoplanes. The compound is an inhibitor of alpha-glucosidases and is used in the treatment of patients suffering from type II diabetes. The benefits of acarbose for the producer are not known; however, a role as carbophor has been proposed. Acarbose synthesis is induced in the presence of maltose and maltotriose. We have investigated the transport activities for these sugars in Actinoplanes sp. strain SN 223/29 grown on different carbon sources, including acarbose. Under the conditions used, Actinoplanes sp. utilized acarbose as sole source of carbon and energy, although growth ceased after 24 h, possibly due to the accumulation of a toxic degradation product in the cytosol. Maltose transport was observed in cells grown on each of the substrates tested except glucose. Maltose transport of acarbose-grown cells was inhibited by sucrose and trehalose and, to a lesser extent, by maltodextrins but not by acarbose. In contrast, in maltose/maltotriose-grown cells maltose uptake was inhibited by acarbose. Maltotriose uptake in these cells was less inhibited by maltose but was more sensitive to acarbose than in acarbose-grown cells. The Km and Vmax values of maltose uptake are in the range of those reported for binding protein-dependent sugar ATP-binding cassette (ABC) transport systems. A maltose-binding protein that does not bind acarbose was isolated from cells grown on either acarbose, glycerol or maltose. These results suggest that an acarbose-insensitive maltose/sucrose/trehalose transporter that also accepts maltodextrins operates in acarbose-grown cells while a maltodextrin transporter that accepts maltose/sucrose/trehalose and is moderately sensitive to acarbose is found in cells grown in maltose/maltotriose-containing media.     

Analysis of genome sequence and trehalose lipid production peculiarities of the thermotolerant Gordonia strain

Gordoniae are one of the most promising hydrocarbon-oxidizing actinobacteria. Here we present the genome sequence analysis of thermotolerant strain Gordonia sp. 1D isolated from oil-refinery soil. It is capable of alkane consumption and biosurfactant production at temperatures of up to 50°C. Gordonia sp. 1D demonstrates maximum biosurfactant production when grown on hexadecane, and at 40°C it was slightly higher than at 27°C: 35 and 39 mN/m, respectively. For the first time, it was experimentally confirmed that the carbohydrate component of extracellular biosurfactants produced by strain 1D is trehalose. In addition, genes for the production of trehalose lipid biosurfactants were identified. The genetic determinants for two different pathways for trehalose synthesis were found. The strain carries genes otsA and otsB involved in de novo trehalose biosynthesis. Moreover, the genes treY and treZ responsible for trehalose biosynthesis from maltooligosaccharides and starch or glycogen were identified.     

Constitutive nitrate- and nitrite reductase activities of Rhizobium in relation to denitrification

Nitrate reductase (NR) activity of R. meliloti SU 47 grown in yeast extract mannitol (YM) medium not containing any nitrate was highest during early stationary phase of growth. The strain did not express nitrite reductase (NiR) activity under this condition. In this medium stationary phase cells of some strains of rhizobia expressed nitrite reductase activity and produced gas from nitrate or nitrite in Durham tubes under anaerobic condition in 72 hrs. The strain SU 47, although, did not produce any gas in 72 hrs, did so and expressed NiR activity when grown for 8 days under anaerobic condition. The data indicated a positive correlation between gas production and NiR activity.     

Ethanol inhibition of Saccharomyces and Candida enzymes

Summary Ethanol inhibition of several hydrolases (sucrase, maltase, trehalase, melezitase and cellobiase) has been measured in both highly ethanol-tolerant Saccharomyces strains (R) and in Candida strains less tolerant to ethanol (S). Cells were either grown in the presence of ethanol and the activities of the enzymes measured without preincubation in this alcohol (in situ inhibition assay), or the culture was grown in the absence of ethanol and the activities of the enzymes were determined after preincubation and in the presence of this compound (in vitro inhibition assay). Ethanol inhibition (Ki values) of sucrase, maltase, trehalase, and melezitase was quite different for these different enzymes in the same strain (R or S), but similar for the same enzyme in different strains (R and S). The Ki values for cellobiase, which is absent from the R strain, were higher when induced than at the basal level and higher in in vitro assays than in in situ assays. This suggests that the inhibition observed in situ is mainly the result of an inhibition of other proteins related to cellobiase (i.e., those involved in its synthesis) but not a direct inactivation of the enzyme by ethanol. Accordingly, when hybrids between Saccharomyces (R) and Candida (S) strains were constructed by protoplast fusion, and cellobiase was measured in the parental Candida strain and some of the hybrids, there was an increase in the Ki values in the in situ assays from 2.25% ethanol in Candida to 5.5% in some of the hybrids.     

Molecular diversity of peanut‐nodulating rhizobia in soils of Argentina

RSα sequencing is a valuable tool for identification of bacterial strains, and for evaluating the genetic structure of indigenous rhizobial populations. The purpose of this study was to evaluate, qualitatively, the presence or absence of RSα fragment in peanut‐nodulating strains isolated from plants grown at four sites in central Argentina. RSα fragment was found in only three of 26 indigenous strains, and in one of three inoculant strains analyzed. In contrast to results from studies of other symbiotic nitrogen‐fixing bacteria, such as soybean‐nodulating strains, no correlation was found between generation time and presence of RSα sequence. Phylogenetic analysis of the 16S rRNA gene sequence grouped peanut‐nodulating strains into two clusters, Bradyrhizobium japonicum vs. B. elkanii, and showed divergence among strains positive for RSα sequence. Our results confirm the genetic diversity previously reported for various peanut‐nodulating rhizobial strains, and indicate that the RSα fragment is not applicable as a marker or tool for competition assays at the field or ecological level. (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Identification of Candida glabrata by a 30-second trehalase test

Rapid (30-s) trehalase tests done with material from colonies of 482 yeasts suspended in a drop of trehalose solution on a commercially supplied glucose test strip were positive for 225 (99.1%) of 227 Candida glabrata isolates grown on either of two differential media, Candida ID medium or CandiSelect medium. The test was positive for only 3 (1.2%) and 12 (4.7%) of 255 isolates of other medically important yeast species grown on the same two media, respectively. A rapid maltase test done with a subset of 255 yeast isolates was negative for all but 1 of 64 trehalase-positive C. glabrata isolates, raising the specificity of the rapid testing for C. glabrata to 98.4 to 100%, depending on the isolation medium used. Rapid trehalase and maltase tests done independently in two laboratories with 217 yeast isolates showed sensitivities of 96.0 to 98.0% and specificities of 98.2 to 99.4% for identification of C. glabrata from colonies grown on Candida ID medium. The specificity was much lower because of frequent false-positive trehalose test results when the source of colonies was Sabouraud agar formulated with 4% glucose. We conclude that direct recognition of C. albicans as blue colonies on Candida ID isolation medium coupled with the performance of the 30-s trehalase and maltase tests for C. glabrata among the white colonies on this medium will allow the rapid presumptive identification of the two yeast species most commonly encountered in clinical samples.     

pH-responsive polymers for trehalose loading and desiccation protection of human red blood cells

PP-50, a synthetic pH-responsive biopolymer, is here shown to increase the permeability of the phospholipid bilayer to trehalose, a disaccharide accumulated in desiccation tolerant organisms across all kingdoms. Uptake of 251 ± 6 mm intracellular trehalose facilitated an increase in the membrane integrity of vacuum dried cells by a factor of 9 ± 1 and reduced extent of hemoglobin oxidation in dried cells from 66 ± 1% to 23 ± 3%. To elucidate the mechanism of PP-50 mediated trehalose delivery, permeability studies were conducted using molecules ranging in size from sucrose to 10 kDa poly(ethylene glycol). It was shown that the logarithm of relative diffusant membrane permeability decreased linearly with diffusant molecular volume, suggesting transport via non-Stokesian diffusion. Consistent with this conclusion, topographic atomic force micrographs reported membrane thinning proximate to PP-50 adsorption on the erythrocyte membrane, a phenomenon associated with increased incidence of phospholipid hydrocarbon chain bending.     

Characterization and regulation of the trehalose synthesis pathway and its importance in the pathogenicity of Cryptococcus neoformans

The disaccharide trehalose has been found to play diverse roles, from energy source to stress protectant, and this sugar is found in organisms as diverse as bacteria, fungi, plants, and invertebrates but not in mammals. Recent studies in the pathobiology of Cryptococcus neoformans identified the presence of a functioning trehalose pathway during infection and suggested its importance for C. neoformans survival in the host. Therefore, in C. neoformans we created null mutants of the trehalose-6-phosphate (T6P) synthase (TPS1), trehalose-6-phophate phosphatase (TPS2), and neutral trehalase (NTH1) genes. We found that both TPS1 and TPS2 are required for high-temperature (37 degrees C) growth and glycolysis but that the block at TPS2 results in the apparent toxic accumulation of T6P, which makes this enzyme a fungicidal target. Sorbitol suppresses the growth defect in the tps1 and tps2 mutants at 37 degrees C, which supports the hypothesis that these sugars (trehalose and sorbitol) act primarily as stress protectants for proteins and membranes during exposure to high temperatures in C. neoformans. The essential nature of this pathway for disease was confirmed when a tps1 mutant strain was found to be avirulent in both rabbits and mice. Furthermore, in the system of the invertebrate C. elegans, in which high in vivo temperature is no longer an environmental factor, attenuation in virulence was still noted with the tps1 mutant, and this supports the hypothesis that the trehalose pathway in C. neoformans is involved in more host survival mechanisms than simply high-temperature stresses and glycolysis. These studies in C. neoformans and previous studies in other pathogenic fungi support the view of the trehalose pathway as a selective fungicidal target for use in antifungal development.     

Hydrogen peroxide excretion by oral streptococci and effect of lactoperoxidase-thiocyanate-hydrogen peroxide

Approved type strains of Streptococcus sanguis, S. mitis, S. mutans, and S. salivarius were grown under aerobic and anaerobic conditions. The rate of hydrogen peroxide excretion, oxygen uptake, and acid production from glucose by washed-cell suspensions of these strains were studied, and the levels of enzymes in cell-free extracts which reduced oxygen, hydrogen peroxide, or hypothiocyanite (OSCN-) in the presence of NADH or NADPH were assayed. The effects of lactoperoxidase-thiocyanate-hydrogen peroxide on the rate of acid production and oxygen uptake by intact cells, the activity of glycolytic enzymes in cell-free extracts, and the levels of intracellular glycolytic intermediates were also studied. All strains consumed oxygen in the presence of glucose. S. sanguis, S. mitis, and anaerobically grown S. mutans excreted hydrogen peroxide. There was higher NADH oxidase and NADH peroxidase activity in aerobically grown cells than in anaerobically grown cells. NADPH oxidase activity was low in all species. Acid production, oxygen uptake, and, consequently, hydrogen peroxide excretion were inhibited in all the strains by lactoperoxidase-thiocyanate-hydrogen peroxide. S. sanguis and S. mitis had a higher capacity than S. mutans and S. salivarius to recover from this inhibition. Higher activity in the former strains of an NADH-OSCN oxidoreductase, which converted OSCN- into thiocyanate, explained this difference. The change in levels of intracellular glycolytic intermediates after inhibition of glycolysis by OSCN- and the actual activity of glycolytic enzymes in cell-free extracts in the presence of OSCN- indicated that the primary target of OSCN- in the glycolytic pathway was glyceraldehyde 3-phosphate dehydrogenase.     

Trehalase activity in genetically diabetic mice (serum, kidney, and liver).

Trehalase activity was determined in serum, liver, and kidney in alloxan treated Swiss mice and in homozygous (Ob/Ob, Db/Db) and heterozygous (Ob/+, Db/m+) diabetic mice. Both alloxan and genetic diabetic mice exhibited a large increase in serum and liver trehalase activity with no change in kidney trehalase activity. The heterozygotes (Ob/+, Db/m+) showed only a slight increase of enzyme activity. Further quantitative differences were noticed between the genetic and alloxan diabetic animals. The liver enzyme activity increased from 10- to more than 20-fold in the liver of the homozygous Ob/Ob and Db/Db strains and only 3-fold (not significant compared to controls) in the alloxan treated animals. The above results suggest a regulatory relationship between the genes coding for trehalase and the enzymes of glucose metabolism activity involved in the development of the metabolic anomalies of diabetes. The structural gene for trehalase may well have survived elimination of selective pressure during phylogenesis and remained part of a co-regulated group of glucose metabolising enzymes. This could explain its sensitivity to mutations affecting glucose metabolism and its sensitivity to insulin directed regulatory mechanisms.     

Biosynthese des Makrolid-Antibioticums A 6599 durch Streptomyces hygroscopicus JA 6599 und Aktivität des NADP-abhängigen Stoffwechsels

The activities of some NADP-specific enzymes and of corresponding metabolic pathways were studied in mycelium extracts of Streptomyces hygroscopicus JA 6599 strains producing different yields of the macrolide antibiotic A 6599. Isocitrate dehydrogenase (EC 1.1.1.40) was the most active NADP-specific enzyme in a higher producing (B) and in a low producing strain (A) grown on complex or synthetic media. Glucose catabolism via hexosomonophosphate pathway as also NADP-specific decarboxylation of malic acid may contribute to NADPH-regeneration less than isocitrate oxidation. In strain B increased activities of glucose-6-phosphate dehydrogenase (EC 1.1.1.49) and of some tricarboxylic acid cycle enzymes were found but in the low producing strain A NADP-specific glutamate dehydrogenase (EC 1.4.1.4) was more active. The results point to the importance of NADPH-production in the biosynthesis of secondary metabolite A 6599 and may indicate also a competition for this coenzyme between antibiotic biosynthesis and formation of glutamic acid. The discussions regarding the connection of tricarboxylic acid cycle activity and NADPH-regeneration are supported from studies of effector influence on metabolism and antibiotic production.     

Comparative effect of fenitrothion treatment on intracellular protease activities in insecticide-resistant and susceptible strains of Musca domestica L

In order to further elucidate the biochemical mechanisms responsible for insecticide resistance in insects, we have determined changes in the activity levels of a comprehensive range of proteolytic enzymes (cytoplasmic and lysosomal proteinases and peptidases, which play a key role in normal cell functioning) in fenitrothion-resistant (571ab) and susceptible (Cooper) strains of Musca domestica following in vivo exposure to the insecticide fenitrothion. Untreated insects of the resistant strain had significantly higher levels (20-100%) of activity for many protease types compared to the susceptible strain (whole body analysis). Exposure to fenitrothion resulted in further activity increases for most proteases at some point during the subsequent 24 h period in resistant strain insects; susceptible strain insects were also capable of similar increases in protease activities. We therefore suggest that it must be the combination of intrinsically higher protease levels (prior to pesticide exposure), together with the capacity to further increase protease activities following insecticide exposure, which is important in the mechanism by which proteases may confer survival advantages in insecticide resistant insects. We further speculate that this mechanism may involve increased supply of precursor amino acids from proteolytic degradation products to the intracellular pool, prior to de novo synthesis of detoxifying enzymes following insecticide exposure.     

Recombination between gtfB and gtfC Is Required for Survival of a dTDP-Rhamnose Synthesis-Deficient Mutant of Streptococcus mutans in the Presence of Sucrose

The rml genes are involved in dTDP-rhamnose synthesis in Streptococcus mutans. A gene fusion between gtfB and gtfC, which both encode extracellular water-insoluble glucan-synthesizing enzymes, accompanied by inactivation of the rml genes was observed for cells grown in the presence of sucrose. The survival rates of rml mutants isolated in the absence of sucrose were drastically reduced in the presence of sucrose. The rates were consistent with the frequency of spontaneous gene fusions between gtfB and gtfC, suggesting that the spontaneous recombinant organisms were selected in the presence of sucrose. The rml mutants with a gtfB-gtfC fusion gene had markedly reduced water-insoluble glucan synthetic activity and lost the ability to colonize glass surfaces in the presence of sucrose. These results suggest that the rml mutants of S. mutans, which are defective in dTDP-rhamnose synthesis, can survive only in the absence of water-insoluble glucan synthesis.     

Metabolism and physiological behaviour of Leuconostoc mesenteroides subsp. mesenteroides growing on raffinose

The α-galactosidase activities of 11 strains of Leuconostoc mesenteroides subsp. mesenteroides grown on glucose, lactose or raffinose were determined. The inductive effects of lactose and raffinose differed depending on the strain. In four of the strains, α-galactosidase activity of cells grown on lactose was higher than that of cells grown on raffinose, while the reverse was true for one other strain. The study of two strains exhibiting a different behaviour was extended to all raffinose-component sugars: melibiose, sucrose, glucose, galactose and fructose. The apparent fermentation yields with raffinose-component sugars complied with heterofermentation theory, except for sucrose, where there was a 40% deficit in fermentation products. Raffinose hydrolysis enzymes (α-galactosidase and β-fructosidase) underwent a catabolic repression by glucose. Growth on raffinose was considerably stimulated if the inoculum was first grown on melibiose or raffinose (induction of α-galactosidase).     

Trehalose hydrolysis is not required for human serum-induced dimorphic transition in Candida albicans: evidence from a tps1/tps1 mutant deficient in trehalose synthesis

Exponential yeast-like cells of a Candida albicans wild-type strain exhibited strong capacity for germ tube formation in a glucose-containing medium (YPD) after induction with human serum at 37 degrees C, whereas the isogenic double disruptant tps1/tps1 mutant, which is deficient in trehalose synthesis, failed to produce germ tubes. In a medium without glucose (YP), the morphological transition fraction was roughly equivalent in both strains. Substitution of glucose by galactose or glycerol increased the number of wild-type proliferating cells able to enter the dimorphic program with no noticeable change in their trehalose content, while stationary cells, which accumulate a large amount of trehalose, did not form germ tubes. When fresh medium was added, a high proportion of these resting cells recovered their ability to carry out dimorphic transition. The tps1/tps1 mutant followed the same pattern of hyphae formation, despite the fact that it was unable to accumulate trehalose either during dimorphism induction or after several stress challenges. Furthermore, trehalose-6-phosphate synthase activity was barely detectable in the mutant. These results strongly suggest that serum-induced dimorphic transition does not require trehalose mobilization; they also support the idea that TPS1 is the only activity involved in trehalose biosynthesis in C. albicans.