Glycoprotein inhibitors and iodophilic polysaccharide storage in group A Streptococcus pyogenes

Inhibitors of glycoprotein synthesis in eucaryotic cells also inhibited iodophilic polysaccharide (IPS) storage in group A streptococcus pyogenes. Addition of bacitracin or amphomycin, known inhibitors of polyisoprenol phosphate metabolism or lipid-linked oligosaccharide synthesis, indicated that a key intermediate must be synthesized before IPS storage could be detected. Based on inhibitor action and energy requirements the intermediate was most likely an undecaprenol pyrophosphoryl maltosaccharide. Biosynthesis of the maltosaccharide had an ATP requirement as shown by arsenate action but IPS synthesis via amylomaltase was energy independent if the lipid-linked saccharides were preformed. Maltosaccharide acceptor site blockade with 2-deoxy-d-glucose immediately inhibited IPS storage, which demonstrated the need of acceptor glucose residues for transglycosylation activity of amylomaltase. Tunicamycin failed to inhibit IPS synthesis although it was added in lethal concentrations.     

Diversity,distribution and roles of osmoprotective compounds accumulated in halophytes under abiotic stress

Background and Aims Osmolytes are low-molecular-weight organic solutes, a broad group that encompasses a variety of compounds such as amino acids, tertiary sulphonium and quaternary ammonium compounds, sugars and polyhydric alcohols. Osmolytes are accumulated in the cytoplasm of halophytic species in order to balance the osmotic potential of the Na⁺ and Cl⁻ accumulated in the vacuole. The advantages of the accumulation of osmolytes are that they keep the main physiological functions of the cell active, the induction of their biosynthesis is controlled by environmental cues, and they can be synthesized at all developmental stages. In addition to their role in osmoregulation, osmolytes have crucial functions in protecting subcellular structures and in scavenging reactive oxygen species.Scope This review discusses the diversity of osmolytes among halophytes and their distribution within taxonomic groups, the intrinsic and extrinsic factors that influence their accumulation, and their role in osmoregulation and osmoprotection. Increasing the osmolyte content in plants is an interesting strategy to improve the growth and yield of crops upon exposure to salinity. Examples of transgenic plants as well as exogenous applications of some osmolytes are also discussed. Finally, the potential use of osmolytes in protein stabilization and solvation in biotechnology, including the pharmaceutical industry and medicine, are considered.     

Organic osmolyte channels in cell volume regulation in vertebrates

Volume-activated organic osmolyte channels are found in a variety of vertebrates and cell types and show both common and disparate features. Upon exposure to hypotonic conditions, organic compounds such as taurine are released through these channels, reducing the intracellular solute concentration and thereby restoring cell volume. Various structurally diverse membrane proteins have been proposed as the channel. Accumulating evidence suggests that some of these proteins may play a more significant role as regulators than as the channel itself. Intracellular ionic strength may also modulate the release of organic osmolytes through these channels.     

Effects of osmolytes on RNA secondary and tertiary structure stabilities and RNA-Mg2+ interactions

Osmolytes are small organic molecules accumulated by cells in response to osmotic stress. Although their effects on protein stability have been studied, there has been no systematic documentation of their influence on RNA. Here, the effects of nine osmolytes on the secondary and tertiary structure stabilities of six RNA structures of differing complexity and stability have been surveyed. Using thermal melting analysis, m-values (change in ΔG° of RNA folding per molal concentration of osmolyte) have been measured. All the osmolytes destabilize RNA secondary structure, although to different extents, probably because they favor solubilization of base surfaces. Osmolyte effects on tertiary structure, however, can be either stabilizing or destabilizing. We hypothesize that the stabilizing osmolytes have unfavorable interactions with the RNA backbone, which becomes less accessible to solvent in most tertiary structures. Finally, it was found that as a larger fraction of the negative charge of an RNA tertiary structure is neutralized by hydrated Mg²⁺, the RNA becomes less responsive to stabilizing osmolytes and may even be destabilized. The natural selection of osmolytes as protective agents must have been influenced by their effects on the stabilities of functional RNA structures, though in general, the effects of osmolytes on RNA and protein stabilities do not parallel each other. Our results also suggest that some osmolytes can be useful tools for studying intrinsically unstable RNA folds and assessing the mechanisms of Mg²⁺-induced RNA stabilization.     

Osmolyte Allocation in Response to Tylenchulus semipenetrans Infection,Stem Girdling,and Root Pruning in Citrus

Previous studies indicated that Tylenchulus semipenetrans infection reduced concentrations of inorganic osmolytes, (Na⁺, Cl⁻, K⁺), in roots, along with leaf K⁺ in citrus. However, infection increased leaf Na⁺ and Cl⁻, along with carbohydrates in roots. Pruning of roots also increased carbohydrates in intact roots, whereas shoot pruning increased carbohydrates in shoots. Carbohydrates are translocated as reducing sugars, which collectively form organic osmolytes. Because changes in concentrations of osmolytes regulate osmotic potential in plant cells, we hypothesize that increasing concentrations of organic osmolytes in an organ displaces inorganic osmolytes. We measured the osmotic potentials of young citrus trees under nematode infection, stem girdling, and root pruning at two salinity levels. All treatments reduced leaf osmotic potentials at four sampling times. At harvest, 16 days after pruning and girdling treatments, organs with higher carbohydrates had lower inorganic osmolytes and vice versa, regardless of the treatment. Pruning simulated effects of nematode infection, whereas girdling reduced the effects of nematodes. Results suggested that high organic osmolytes in roots displace inorganic osmolytes, thereby avoiding very low osmotic potentials.     

Mitochondrial mediation of environmental osmolytes discrimination during osmoadaptation in the extremely halotolerant black yeast Hortaea werneckii

We have investigated the mitochondrial responses to hyperosmotic environments of ionic (4.5 M NaCl) and non-ionic (3.0 M sorbitol) osmolytes in the most halo/osmo-tolerant black yeast, Hortaea werneckii. Adaptation to both types of osmolytes resulted in differential expression of mitochondria-related genes. Live-cell imaging has revealed a condensation of mitochondria in hyperosmotic media that depends on osmolyte type. In the hypersaline medium, this was accompanied by increased ATP synthesis and oxidative damage protection, whereas adaptation to the non-ionic osmolyte resulted in a decrease in ATP synthesis and lipid peroxidation level in mitochondria. A proteomic study of the mitochondria revealed preferential accumulation of energy metabolism enzymes in the hypersaline medium, and accumulation of protein chaperones in the non-ionic osmolyte. The HwBmh1/14-3-3 protein, localized to mitochondria in hypersaline conditions, and not at optimal salinity, suggesting its role in differential perception of ionic and non-ionic osmolytes in H. werneckii.     

Trehalose and glycerol stabilize and renature yeast inorganic pyrophosphatase inactivated by very high temperatures

A number of naturally occurring small organic molecules, primarily involved in maintaining osmotic pressure in the cell, display chaperone-like activity, stabilizing the native conformation of proteins, and protecting them from various kinds of stress. Most of them are sugars, polyols, amino acids or methylamines. Similar to molecular chaperones, most of these compounds have no substrate specificity, but some specifically stabilize certain proteins. In the present work, the capacity of trehalose and glycerol, two well-known osmolytes, to stabilize and renature inorganic pyrophosphatase is demonstrated. Both trehalose and glycerol significantly protect pyrophosphatase against thermoinactivation achieved by incubating the enzyme at temperatures up to 95 degrees C, and allow the enzyme already inactivated in the presence of these osmolytes to renature upon incubation at low temperatures. To the best of our knowledge, there are no data on the effects of these compounds on renaturation of thermoinactivated proteins. The correlation between the recovery of enzyme activity and structural changes indicated by fluorescence spectroscopy contribute to better understanding of the protein stabilization mechanism.     

An analysis of the molecular origin of osmolyte-dependent protein stability

Protein solvation is the key determinant for isothermal, concentration-dependent effects on protein equilibria, such as folding. The required solvation information can be extracted from experimental thermodynamic data using Kirkwood-Buff theory. Here we derive and discuss general properties of proteins and osmolytes that are pertinent to their biochemical behavior. We find that hydration depends very little on osmolyte concentration and type. Strong dependencies on both osmolyte concentration and type are found for osmolyte self-solvation and protein-osmolyte solvation changes upon unfolding. However, solvation in osmolyte solutions does not involve complex concentration dependencies as found in organic molecules that are not used as osmolytes in nature. It is argued that the simple solvation behavior of naturally occurring osmolytes is a prerequisite for their usefulness in osmotic regulation in vivo.     

Beta-alanine but not taurine can function as an organic osmolyte in preimplantation mouse embryos cultured from fertilized eggs

Early preimplantation mouse embryos are susceptible to the detrimental effects of increased osmolarity and, paradoxically, their in vitro development is significantly compromised by osmolarities near that of oviductal fluid. In vitro development can be restored, however, by several compounds that are accumulated by 1-cell embryos to act as organic osmolytes, providing intracellular osmotic support and cell volume regulation. Taurine, a substrate of the beta-amino acid transporter that functions as an organic osmolyte transporter in other cells, had been proposed to function as an organic osmolyte in mouse embryos. Here, however, we found that taurine is neither able to provide protection for in vitro embryo development against increased osmolarity nor is it accumulated to higher intracellular levels as osmolarity is increased, indicating that it cannot function as an organic osmolyte in early preimplantation embryos. In contrast, beta-alanine, the other major substrate of the beta-amino acid transporter, both protects against increased osmolarity and is accumulated to somewhat higher levels as osmolarity is increased, indicating that it is able to function as an organic osmolyte in embryos. However, we also found that beta-alanine is displaced from embryos by glycine-the most effective organic osmolyte in embryos previously identified-and beta-alanine does not increase protection above that afforded by glycine at concentrations near those in vivo. Thus, the beta-amino acid transporter is likely present in early preimplantation embryos to supply beta-amino acids such as taurine for purposes other than to serve as organic osmolytes.     

TMAO and other organic osmolytes in the muscles of amphipods (Crustacea) from shallow and deep water of Lake Baikal

Concentrations of trimethylamine oxide (TMAO) and other 'compatible' osmolytes were analyzed in the muscle tissue of Lake Baikal amphipods (Crustacea) in relation to water depth of the freshwater Lake Baikal. Using HPLC and mass spectrometry, glycerophosphoryl choline (GPC), betaine, S-methyl-cysteine, sarcosine, and taurine were detected for the first time in freshwater amphipods. These osmolytes were frequently found in the five species studied but mixtures were too complex to be quantified. The pattern of these osmolytes did not change with respect to water depth. The TMAO concentration, however, was significantly higher in the muscle tissue of amphipods living in deep water than of those living in shallow water, which supports the hypothesis that TMAO acts as a protective osmolyte at increased hydrostatic pressure. We propose that eurybathic amphipods, exposed to raised hydrostatic pressure in the extremely deep freshwater Lake Baikal, have elevated TMAO levels to counteract the adverse effect of high pressure on protein structure. The elevated intracellular osmotic pressure is balanced by upregulating the extracellular hemolymph NaCl concentration.     

Comparative effects of osmotic-, salt- and alkali stress on growth,photosynthesis, and osmotic adjustment of cotton plants

In this study, cotton seedlings were subjected to osmotic-, salt- and alkali stresses. The growth, photosynthesis, inorganic ions, and organic acids in the stressed seedlings were measured, to compare the mechanisms by which plants adapt to these stresses and attempt to probe the mechanisms by which plants adapt to high pH stress. Our results indicated that, at high stress intensity, both osmotic and alkali stresses showed a stronger injurious effect on growth and photosynthesis than salt stress. Cotton accumulated large amount of Na+ under salt and alkali stresses, but not under osmotic stress. In addition, the reductions of K⁺, NO₃ ⁻, and H₂PO₄ ⁻ under osmotic stress were much greater than those under salt stress with increasing stress intensity. The lack of inorganic ions limited water uptake and was the main reason for the higher injury from osmotic-compared to salt stress on cotton. Compared with salt- and alkali stresses, the most dramatic response to osmotic stress was the accumulation of soluble sugars as the main organic osmolytes. In addition, we found that organic acid metabolism adjustment may play different roles under different types of stress. Under alkali stress, organic acids might play an important role in maintaining ion balance of cotton; however, under osmotic stress, malate might play an important osmotic role.     

不同生育期水分胁迫对水稻根叶渗透调节物质变化的影响

 干旱是限制水稻(Oryza sativa)作物产量的主要生态因子之一,渗透调节是作物适应干旱逆境的生理机制之一。在人为控制水分的盆栽条件下, 对水稻生长的分蘖期、幼穗分化期、抽穗期、结实期分别进行水分胁迫,研究水稻根系及叶片渗透调节物质的变化规律。结果表明, 不同生育期 干旱胁迫后叶片水势均显著下降,根系和叶片的有机渗透调节物质如可溶性糖、游离氨基酸、脯氨酸和无机渗透调节物质包括K⁺、Mg²⁺等含量 均大幅度上升,而且幼穗分化期和抽穗期这两个对水分胁迫最敏感的时期上升幅度最大,其中又以有机渗透调节物质变化最显著。不同生育期渗 透调节大小的顺序为：抽穗期>幼穗分化期>结实期>分蘖期,反映了不同生育时期渗透调节能力的差异。同时幼穗分化期和抽穗期水分胁迫结束 后再复水后根系和叶片的有机渗透调节物质含量仍长期明显高于对照,而无机离子则变化规律比较复杂,有的升高有的则降低。叶片的渗透调 节能力大于根系,无论是叶片或根系都是K⁺对渗透调节的贡献最大;其次是Ca²⁺, 6 种渗透调节物质含量大小排列顺序为K⁺ > Ca²⁺ >可溶性糖 > Mg²⁺ > 游离氨基酸 > 脯氨酸。     

Preferential Osmolyte Accumulation: a Mechanism of Osmotic Stress Adaptation in Diazotrophic Bacteria

A common cellular mechanism of osmotic-stress adaptation is the intracellular accumulation of organic solutes (osmolytes). We investigated the mechanism of osmotic adaptation in the diazotrophic bacteria Azotobacter chroococcum, Azospirillum brasilense, and Klebsiella pneumoniae, which are adversely affected by high osmotic strength (i.e., soil salinity and/or drought). We used natural-abundance ¹³C nuclear magnetic resonance spectroscopy to identify all the osmolytes accumulating in these strains during osmotic stress generated by 0.5 M NaCl. Evidence is presented for the accumulation of trehalose and glutamate in Azotobacter chroococcum ZSM4, proline and glutamate in Azospirillum brasilense SHS6, and trehalose and proline in K. pneumoniae. Glycine betaine was accumulated in all strains grown in culture media containing yeast extract as the sole nitrogen source. Alternative nitrogen sources (e.g., NH₄Cl or casamino acids) in the culture medium did not result in measurable glycine betaine accumulation. We suggest that the mechanism of osmotic adaptation in these organisms entails the accumulation of osmolytes in hyperosmotically stressed cells resulting from either enhanced uptake from the medium (of glycine betaine, proline, and glutamate) or increased net biosynthesis (of trehalose, proline, and glutamate) or both. The preferred osmolyte in Azotobacter chroococcum ZSM4 shifted from glutamate to trehalose as a consequence of a prolonged osmotic stress. Also, the dominant osmolyte in Azospirillum brasilense SHS6 shifted from glutamate to proline accumulation as the osmotic strength of the medium increased.     

Glutamine, glutamate, and alpha-glucosylglycerate are the major osmotic solutes accumulated by Erwinia chrysanthemi strain 3937

Erwinia chrysanthemi is a phytopathogenic soil enterobacterium closely related to Escherichia coli. Both species respond to hyperosmotic pressure and to external added osmoprotectants in a similar way. Unexpectedly, the pools of endogenous osmolytes show different compositions. Instead of the commonly accumulated glutamate and trehalose, E. chrysanthemi strain 3937 promotes the accumulation of glutamine and alpha-glucosylglycerate, which is a new osmolyte for enterobacteria, together with glutamine. The amounts of the three osmolytes increased with medium osmolarity and were reduced when betaine was provided in the growth medium. Both glutamine and glutamate showed a high rate of turnover, whereas glucosylglycerate stayed stable. In addition, the balance between the osmolytes depended on the osmolality of the medium. Glucosylglycerate and glutamate were the major intracellular compounds in low salt concentrations, whereas glutamine predominated at higher concentrations. Interestingly, the ammonium content of the medium also influenced the pool of osmolytes. During bacterial growth with 1 mM ammonium in stressing conditions, more glucosylglycerate accumulated by far than the other organic solutes. Glucosylglycerate synthesis has been described in some halophilic archaea and bacteria but not as a dominant osmolyte, and its role as an osmolyte in Erwinia chrysanthemi 3937 shows that nonhalophilic bacteria can also use ionic osmolytes.     

Properties of ATP-dependent protein kinase from Streptococcus pyogenes that phosphorylates a seryl residue in HPr, a phosphocarrier protein of the phosphotransferase system.

Transport of sugars across the cytoplasmic membranes of gram-positive bacteria appears to be regulated by the action of a metabolite-activated, ATP-dependent protein kinase that phosphorylates a seryl residue in the phosphocarrier protein of the phosphotransferase system, HPr. We have developed a quantitative assay for measuring the activity of this enzyme from Streptococcus pyogenes. The product of the in vitro protein kinase-catalyzed reaction was shown to be phosphoseryl-HPr by several independent criteria (rates of hydrolysis in the presence of various agents, detection of serine-phosphate in acid hydrolysates, immunological assay, and electrophoretic migration rates). HPrs isolated from four different gram-positive bacteria (S. pyogenes, Streptococcus faecalis, Staphylococcus aureus, and Bacillus subtilis) were shown to be phosphorylated by the kinase from S. pyogenes. In contrast, Escherichia coli HPr was not a substrate of this enzyme. The soluble kinase released from the particulate fraction of the cells with high salt in the presence of a protease inhibitor was shown to have an approximate molecular weight of 60,000 as estimated by gel filtration. Its activity was dependent on divalent cations, with Mg2+ and Mn2+ being most active. EDTA, Pi, and high concentrations of salt were strongly inhibitory. The enzyme was optimally active at pH 7.0, exhibited high affinity for its substrates, and was dependent on the presence of one of several metabolites. Of these compounds, fructose 1-6-diphosphate was most active, with gluconate 6-phosphate, 2-phosphoglycerate, 2,3-diphosphoglycerate, phosphoenolpyruvate, and pyruvate exhibiting moderate to low stimulatory activities. Other compounds tested, including a variety of sugar phosphates, pyridine nucleotides, and other metabolites were without effect. The ATP-dependent phosphorylation of HPr on the seryl residue was strongly inhibited by phosphoenolpyruvate-dependent phosphorylation of the active histidyl residue of this protein. Treatment of the kinase with diethyl pyrocarbonate strongly inhibited the ATP-dependent phosphorylation activity, although the sulfhydryl reagents N-ethylmaleimide, p-chloromercuribenzoate, and iodoacetate were without effect. These results serve to characterize the HPr (serine) kinase, which apparently regulates the rates of carbohydrate transport in streptococcal cells via the phosphotransferase system. A primary role of this kinase in the control of cellular inducer levels and carbohydrate metabolic rates is proposed.     

Synthesis of organic osmolytes and salt tolerance mechanisms in Paspalum vaginatum

Synthesis of organic compounds in response to salinity stress and their contribution to organic osmotic adjustment were investigated in seashore paspalum (Paspalum vaginatum Swartz). Nine genotypes exhibiting the widest range of salt tolerance were grown in sea-salt amended nutrient solution in a greenhouse. Salinity ranges were 1.1 (EC_w0, control) to 49.7 dS m⁻¹ (EC_w50) based on electrical conductivity of the solution (EC_w). Organic osmolytes most important within seashore paspalum under salinity stress were proline, Gly-betaine, and trigonelline in terms of explaining intraspecific salt tolerance differences and, therefore, should be the focus of biotechnology approaches to enhance these traits. While these osmolytes differed in accumulation with increasing salinity and absolute concentrations among salt tolerant and intolerant genotypes, the magnitude of responses was not sufficiently large to suggest use for salt screening as physiological/biochemical markers. Fructose concentration increased with salinity, especially for salt sensitive ecotypes, and may have potential as a marker. Glucose, sucrose, and myo-inositol tended to increase with salinity, but changes did not relate to intraspecific salt tolerance, while mannitol and sorbitol were not affected by salinity. Proline demonstrated a 20.8-fold increase averaged across genotypes from EC_w0 to EC_w50 salinity. Proline was the primary organic osmolyte for osmotic adjustment accounting for an average of 9.3% to total solute potential (Ψ_s) at EC_w50 and 56% of the organic solute contribution to Ψ_s. In the salt tolerant genotype, SI 93-2, proline and Gly-betaine exhibited greater absolute concentration and accumulation rate relative to the least salt tolerant, Adalayd. The intraspecific role of Gly-betaine did not relate to osmotic adjustment differences, suggesting another role perhaps in protection of the thylakoid membrane.     

Ammonia toxicity under hyponatremic conditions in astrocytes: de novo synthesis of amino acids for the osmoregulatory response

This study investigates how the metabolic activity and de novo synthesis of amino acids from glucose correlate with changes in intracellular organic osmolytes involved in astrocytic volume regulation during hyperammonemia and hyponatremia. Multinuclear (1H-, 31P-, 13C-) NMR spectra were recorded to quantify water-soluble metabolites, the cellular energy state, as well as the incorporation of [1-(13)C]glucose into amino acids of primary astrocyte cultures. Myo-inositol levels were strongly decreased already at 3h after treatment with NH4Cl; other intracellular osmolytes, such as hypotaurine and choline-containing compounds were also decreased, along with a concomitant increase of both the total concentration and the amount of newly synthesized glutamine, alanine, and glutathione. During ammonia stress, the decrease of organic osmolytes compensated in part for increased intracellular osmolarity caused by amino acid synthesis. Hypotonic conditions alone also lowered the content of organic osmolytes including cellular amino acids, but much less than in hyperammonemia. This was due to impaired mitochondrial metabolic activity via the Krebs cycle, which also enhanced ammonia-induced ATP decrease. However, the changes in the sum of organic osmolytes were not significantly different after ammonia-treatment in hypoosmotic compared to anisoosmotic media, suggesting that the decrease of cellular organic osmolytes may not adequately compensate for the increased intracellular osmolarity caused by amino acids under hyponatremia. Therefore, the ammonia-induced release of osmolytes is an early process in response to increased intracellular osmolarity evoked by increased glutamine and alanine as a consequence of stimulated metabolic activity. The imperfect correlation of changes in astrocytic glutamine, other organic osmolytes, and the cellular energy state under hyperammonemic stress in isoosmotic and hypoosmotic media, however, point to additional mechanisms contributing to astrocyte dysfunction in hyperammonemic states, which are independent from glutamine formation.     

Structural basis of Streptococcus pyogenes immunity to its NAD+ glycohydrolase toxin

The virulence of Gram-positive bacteria is enhanced by toxins like the Streptococcus pyogenes β-NAD(+) glycohydrolase known as SPN. SPN-producing strains of S. pyogenes additionally express the protein immunity factor for SPN (IFS), which forms an inhibitory complex with SPN. We have determined crystal structures of the SPN-IFS complex and IFS alone, revealing that SPN is structurally related to ADP-ribosyl transferases but lacks the canonical binding site for protein substrates. SPN is instead a highly efficient glycohydrolase with the potential to deplete cellular levels of β-NAD(+). The protective effect of IFS involves an extensive interaction with the SPN active site that blocks access to β-NAD(+). The conformation of IFS changes upon binding to SPN, with repacking of an extended C-terminal α helix into a compact shape. IFS is an attractive target for the development of novel bacteriocidal compounds functioning by blocking the bacterium's self-immunity to the SPN toxin.     

中度嗜盐菌相容性溶质机制的研究进展

生活在高盐环境中的中度嗜盐菌不仅能抗衡外界的高渗透压胁迫,而且还能迅速适应短时间内的渗透冲击。为适应该环境,中度嗜盐菌依赖于一种被称为相容性溶质的物质,以执行渗透保护功能。这类物质属于极性的、易溶的和低分子量的有机化合物,其中包括糖类、氨基酸类、甜菜碱类和四氢嘧啶类等。中度嗜盐菌主要采用相容性溶质机制来适应盐环境。在此,就中度嗜盐菌的盐适应机理、相容性溶质的种类和特点,以及其作用的分子机制进行了阐述和讨论。     

Glutamine, Glutamate, and α-Glucosylglycerate Are the Major Osmotic Solutes Accumulated by Erwinia chrysanthemi Strain 3937

Erwinia chrysanthemi is a phytopathogenic soil enterobacterium closely related to Escherichia coli. Both species respond to hyperosmotic pressure and to external added osmoprotectants in a similar way. Unexpectedly, the pools of endogenous osmolytes show different compositions. Instead of the commonly accumulated glutamate and trehalose, E. chrysanthemi strain 3937 promotes the accumulation of glutamine and α-glucosylglycerate, which is a new osmolyte for enterobacteria, together with glutamine. The amounts of the three osmolytes increased with medium osmolarity and were reduced when betaine was provided in the growth medium. Both glutamine and glutamate showed a high rate of turnover, whereas glucosylglycerate stayed stable. In addition, the balance between the osmolytes depended on the osmolality of the medium. Glucosylglycerate and glutamate were the major intracellular compounds in low salt concentrations, whereas glutamine predominated at higher concentrations. Interestingly, the ammonium content of the medium also influenced the pool of osmolytes. During bacterial growth with 1 mM ammonium in stressing conditions, more glucosylglycerate accumulated by far than the other organic solutes. Glucosylglycerate synthesis has been described in some halophilic archaea and bacteria but not as a dominant osmolyte, and its role as an osmolyte in Erwinia chrysanthemi 3937 shows that nonhalophilic bacteria can also use ionic osmolytes.