Metabolic Control of Anaerobic Glycolysis (Overexpression of Lactate Dehydrogenase in Transgenic Tomato Roots Supports the Davies-Roberts Hypothesis and Points to a Critical Role for Lactate Secretion

Roots of all plants examined so far have the potential for both ethanol and lactate fermentation. A short burst of lactate fermentation usually occurs when plant tissues are transferred from normoxic to anoxic conditions. According to the Davies-Roberts hypothesis, the consequent pH drop both initiates ethanol fermentation and blocks further production of lactate by inhibiting lactate dehydrogenase (LDH). However, the role of LDH in this pH control mechanism is still a matter of debate. To perturb the control system in a defined way, a barley LDH cDNA under the control of the cauliflower mosaic virus 35S promoter was introduced into tomato (Lycopersicon esculentum Mill. cv VFMT) using Agrobacterium rhizogenes. The transgenic root clones expressed up to 50 times the LDH activity of controls. The fermentative metabolism of these clones was compared using roots grown previously in normoxic conditions or roots given a 3-d hypoxic pretreatment. During the transition from normoxia to anoxia, lactate accumulation was no faster and no more extensive in transgenic roots than in controls. Similarly, during prolonged anoxia the flux of 14C from [U-14C] glucose to lactate and ethanol was not modified by the expression of the transgene. However, in both transgenic and control roots, hypoxic pretreatment increased the flux to lactate and promoted lactate export to the medium. These results show that LDH has a very low flux control coefficient for lactate fermentation, consistent with the Davies-Roberts hypothesis. Moreover, they suggest that lactate secretion exerts major control over long-term lactate glycolysis in vivo.     

Osmoprotectant β-alanine betaine synthesis in the Plumbaginaceae: S-adenosyl- l-methionine dependent N-methylation of β-alanine to its betaine is via N-methyl and N,N-dimethyl β-alanines

β -Alanine betaine is an osmoprotective compound accumulated by most members of the plant family Plumbaginaceae. Leaf and root tissues of Limonium latifolium known to accumulate β -alanine betaine readily convert supplied β -alanine to β -alanine betaine. To identify the intermediates and the enzymes involved in β -alanine betaine synthesis, radiotracer experiments using [ 14 C] formate were employed. These studies demonstrate that β -alanine betaine is synthesized from β -alanine via N -methyl and N,N- dimethyl β -alanines. A rapid and sensitive radiometric assay was developed to measure N -methyltransferase (NMT) activities by using [methyl-¹⁴C] or [methyl-³H] S -adenosyl- l -methionine (AdoMet) as the methyl donor. Leaf extracts from β -alanine betaine accumulators – Armeria maritima , L. latifolium and L. ramosissimum – had detectable NMT activities while none were found in L. perezii , a species that does not accumulate β -alanine betaine. The NMT activities were further characterized from the leaves of L. latifolium . The activities had a pH optimum of 8.0, were soluble and inhibited by S -adenosyl- l -homocysteine. Extractable activities were similar from plants grown under control and salinity stress conditions. Radiolabeling with [ 14 C] l -aspartic acid indicated that, unlike in bacteria, decarboxylation of l -aspartic acid is not the source of β -alanine in the Plumbaginaceae.     

Pyruvate metabolism in rice coleoptiles under anaerobiosis

Relative importance of ethanolic, lactate and alanine fermentation pathways was estimated in coleoptiles of rice seedlings (Oryza sativa L.) subjected to anoxic stress. The in vitro activities of alcohol dehydrogenase (ADH, EC 1.1.1.1), pyruvate decarboxylase (PDC, EC 4.1.1.1) and alanine aminotransferase (AlaAT, EC 2.6.1.2) in the coleoptiles increased in anoxia, whereas no significant increase was measured in lactate dehydrogenase (LDH, EC 1.1.1.27) activity. At 48 h, the ADH, PDC and AlaAT activities in anoxic coleoptiles were 62-, 15- and 7.6-fold greater, respectively, than those in the presence of oxygen. Ethanol and alanine in the coleoptiles accumulated rapidly under anoxia, increasing by 48 h, 57- and 5.6-fold compared with those in the presence of oxygen, respectively. However, lactate concentration did not increase and no initial burst of lactate production was detected. The relative ratio of carbon flux from pyruvate to ethanol, lactate and alanine in anoxic coleoptiles was estimated to be 92, 1 and 7% of the total carbon flux, respectively. These results suggest that the potential carbon flux from pyruvate to ethanol may be much greater than the potential flux from pyruvate to lactate and alanine in rice coleoptiles during anoxia.     

The role of nitrate reduction in the anoxic metabolism of roots II. Anoxic metabolism of tobacco roots with or without nitrate reductase activity

The effects of root anoxia on a tobacco (Nicotiana tabacum) wild type (WT) and a transformant (LNR-H) lacking root nitrate reductase were compared. LNR-H plants were visibly more sensitive to oxygen deprivation than WT, showing rapid and heavy wilting symptoms. LNR-H roots also produced substantially more ethanol and lactate than WT roots under anoxia, and their sugar and sugar-P content, as well as their ATP levels, remained higher. The fermentation rates of WT and LNR-H roots were unaffected by sugar feeding and the higher fermentation rate in the LNR-H roots was associated with a greater acidification of the cytoplasm under anoxia. From these observations it is concluded: (i) that the absence of NR activity in the LNR-H roots does not necessarily limit NADH recycling; and (ii) that nitrate reduction in the WT roots results in a more acidifying metabolism. It is the higher metabolic rate in the LNR-H roots that leads to the greater cytoplasmic acidification under anoxia despite the absence of a contribution from the metabolism of nitrate. Competition for NADH cannot explain this difference in metabolic rate, and it remains unclear why the NR-free LNR-H, and tungstate-treated WT roots, had much higher fermentation rates than WT roots. The difference in anaerobic metabolism could still be due to the presence or absence of nitrate reductase and the possibility that this could occur through the production of nitric oxide is discussed.     

Energy Metabolism in Rhizomes of Acorus calamus (L.) and in Tubers of Solanum tuberosum (L.) With Regard to their Anoxia Tolerance

Rhizomes of the marsh plant Acorus calamus (L.) and tubers of the flooding-intolerant Solanum tuberosum (L.) var. Bintje, both kept under strict anoxia, differ markedly in their fermentation properties. The fermentation capacities as measured by ADH and LDH activities and their respective product concentrations were estimated. While rhizomes of Acorus calamus, having high ADH and low LDH activities, accumulate mainly ethanol, tubers of Solanum tuberosum tend towards lactic acid fermentation. The total amount of adenine nucleotides is quite stable in Acorus calamus, whereas they show a sharp decline in S. tuberosum during the first 6h of anoxia. The adenylate energy charge of A. calamus recovers after a short initial drop (AEC > 0.8). AEC values of S. tuberosum decrease rapidly and remain at very low values (AEC ～ 0.3). Tuber tissues became soft and lost viability after about 48–72 h of anoxia at 25 °C. This might be due to tissue acidification and impaired energy metabolism, but not to the lack of energy reserves. Energy metabolism of A. calamus is well adapted to anoxia.     

Effects of oxygen level on metabolism and development of seedlings of Trapa natans and two ecologically related species

Seeds of the water plant Trapa natans L. (water chestnut) can germinate in strict anoxia. The seedlings show seminal roots growing upwards while shoot buds remain quiescent until O₂ becomes available. Trapa seedlings are highly tolerant to anoxia. The rate of ethanol fermentation was 21.2 μmol (g FW)⁻¹ h⁻¹, while production of lactate was negligible and lower than that of succinate. The seminal root of Trapa compares better to the rice coleoptile rather than to the rice root, both functionally and as to the metabolic response to anoxia. The anaerobic germination of Nuphar luteum L. and Scirpus mucronatus L. was also characterized by a limited developmental program.     

Anoxia tolerance in tobacco roots: effect of overexpression of pyruvate decarboxylase

Plant survival during flooding relies on ethanolic fermentation for energy production. The available literature indicates that the first enzyme of the ethanolic fermentation pathway, pyruvate decarboxylase (PDC), is expressed at very low levels and is likely to be rate-limiting during oxygen deprivation. The authors expressed high levels of bacterial PDC in tobacco to study the modulation of PDC activity in vivo, and assess its impact on the physiology of ethanolic fermentation and survival under oxygen stress. In contrast to leaves, wild-type normoxic roots contained considerable PDC activity, and overexpression of the bacterial PDC caused only a moderate increase in acetaldehyde and ethanol production under anoxia compared to wild-type roots. No significant lactate production could be measured at any time, making it unlikely that lactate-induced acidification (LDH/PDC pH-stat) triggers the onset of ethanol synthesis. Instead, the authors favour a model in which the flux through the pathway is regulated by substrate availability. The increased ethanolic flux in the transgenics compared to the wild-type did not enhance anoxia tolerance. On the contrary, rapid utilisation of carbohydrate reserves enhanced premature cell death in the transgenics while replenishment of carbohydrates improved survival under anoxia.     

Influence of NO3 - and NH4 + nutrition on fermentation,nitrate reductase activity and adenylate energy charge of roots of Carex pseudocyperus L. and Carex sylvatica Huds. exposed to anaerobic nutrient solutions

The adenylate energy charge, production of ethanol and lactate, and nitrate reductase activity were determined in order to study the influence of different nitrogen sources on the metabolic responses of roots of Carex pseudocyperus L. and Carex sylvatica HUDS. exposed to anaerobic nutrient solutions. Determination of adenylates was carried out by means of a modified HPLC technique. Total quantity of adenylates was higher in Carex pseudocyperus than in Carex sylvatica under all conditions. In contrast, the adenylate energy charge was only slightly different between the species and decreased more or less in relation to the applied nitrogen source under oxygen deficiency. The adenylate energy charge in roots of plants under nitrate nutrition showed a smaller decrease under anaerobic environmental conditions than plants grown with ammonium or nitrate/ammonium. Roots of nitrate-fed plants showed a lower ethanol and lactate production than ammonium/nitrate- and ammonium-fed plants. Ethanol production was higher in C. pseudocyperus, formation of lactate was lower compared to that in Carex sylvatica. The activity of enzymes involved in fermentation processes (ADH, LDH and PDC) was enhanced significantly after 24 hours of exposure to anaerobic nutrient solutions in roots of both species. The induction of these enzymes was only slightly influenced by different nitrogen supply. In vivo nitrate reductase activity increased almost 3-fold compared to the aerobic treatment in both species and overcompensated loss of NADH reoxidation capacity caused by decrease of ethanol and lactate development. Induction of in vitro nitrate reductase activity was enhanced 313% in C. pseudocyperus and 349% in C. sylvatica under anaerobic environmental conditions and nitrate supply. These results indicate that nitrate may serve as an alternative electron acceptor in anaerobic plant root metabolism and that the nitrate-supported energy charge may be due to an accelerated glycolytic flux resulting from a more effective NADH reoxidation capacity by nitrate reduction plus fermentation than by fermentation alone.Abbreviations ADH alcohol dehydrogenase - AEC adenylate energy charge - DMSO dimethyl sulfoxide - EDTA ethylen diamine tetraacetic acid - HPLC high performance liquid chromatography - LDH lactate dehydrogenase - NRA nitrate reductase activity - PCA perchloric acid - PDC pyruvate decarboxylase - PVP polyvinylpyrrolidone - PVPP polyvinylpolypyrrolidone - TCA trichloroacetic acid, Tris-tris(hydroxymethyl)aminomethane     

Evaluation of the importance of lactate for the activation of ethanolic fermentation in lettuce roots in anoxia

According to the Davies–Roberts hypothesis, plants primarily respond to oxygen limitation by a burst of lactate production and the resulting pH drop in the cytoplasm activates ethanolic fermentation. To evaluate this system in lettuce ( Lactuca sativa L.), seedlings were subjected to anoxia and in vitro activities of alcohol dehydrogenase (ADH, EC 1.1.1.1), pyruvate decarboxylase (PDC, EC 4.1.1.1) and lactate dehydrogenase (LDH, EC 1.1.1.27) and concentrations of ethanol, acetaldehyde and lactate were determined in roots of the seedlings. The in vitro activities of ADH and PDC in the roots increase in anoxia, whereas no significant increase was measured in LDH activity. At 6 h, the ADH and PDC activities in the roots kept in anoxia were 2.8- and 2.9-fold greater than those in air, respectively. Ethanol and acetaldehyde in the roots accumulated rapidly in anoxia and increased 8- and 4-fold compared with those in air by 6 h, respectively. However, lactate concentration did not increase and an initial burst of lactate production was not found. Thus, ethanol and acetaldehyde production occurred without an increase in lactate synthesis. Treatments with antimycin A and salicylhydroxamic acid, which are respiratory inhibitors, to the lettuce seedlings in the presence of oxygen increased the concentrations of ethanol and acetaldehyde but not of lactate. These results suggest that ethanolic fermentation may be activated without preceding activation of lactate fermentation and may be not regulated by oxygen concentration directly.     

Glucose metabolism and regulation of glycolysis in Lactococcus lactis strains with decreased lactate dehydrogenase activity.

The distribution of carbon flux at the pyruvate node was investigated in Lactococcus lactis under anaerobic conditions with mutant strains having decreased lactate dehydrogenase activity. Strains previously selected by random mutagenesis by H. Boumerdassi, C. Monnet, M. Desmazeaud, and G. Corrieu (Appl. Environ. Microbiol. 63, 2293-2299, 1997) were found to have single punctual mutations in the ldh gene and presented a high degree of instability. The strain L. lactis JIM 5711 in which lactate dehydrogenase activity was diminished to less than 30% of the wild type maintained homolactic metabolism. This was due to an increase in the intracellular pyruvate concentration, which ensures the maintained flux through the lactate dehydrogenase. Pyruvate metabolism was linked to the flux limitation at the level of glyceraldehyde-3-phosphate dehydrogenase, as previously postulated for the parent strain (C. Garrigues, P. Loubière, N. D. Lindley, and M. Cocaign-Bousquet (1997) J. Bacteriol. 179, 5282-5287, 1997). However, a strain (L. lactis JIM 5954) in which the ldh gene was interrupted reoriented pyruvate metabolism toward mixed metabolism (production of formate, acetate, and ethanol), though the glycolytic flux was not strongly diminished. Only limited production of acetoin occurred despite significant overflow of pyruvate. Intracellular metabolite profiles indicated that the in vivo glyceraldehyde-3-phosphate dehydrogenase activity was no longer flux limiting in the Deltaldh strain. The shift toward mixed acid fermentation was correlated with the lower intracellular trioses phosphate concentration and diminished allosteric inhibition of pyruvate formate lyase.     

Lactic Acid efflux as a mechanism of hypoxic acclimation of maize root tips to anoxia

Hypoxic pretreatment (3 kPa oxygen) of maize (Zea mays L.) root tips improved their survival time in a subsequent anoxic incubation from 10 h to more than 3 d, provided that glucose was added to the medium to sustain metabolism. The glycolytic flux (lactate + ethanol) was the same in both pretreated and untreated root tips during the 1st h after transfer to anoxia. It was only after 2 h that it declined sharply in untreated tips, but was sustained in pretreated ones. Right after the transition from normoxia to anoxia of untreated root tips, the only fermentative product detected was lactic acid, which accumulated in a 7:1 proportion after 30 min in tissue and medium, respectively. It took 10 min before ethanol could be detected and 20 min for it to be produced at its maximum rate at the expense of lactate production, which slowed down. In contrast, in hypoxically pretreated root tips, ethanol was produced at a maximum rate right after the transfer to anoxia. Concurrently, low amounts of lactic acid were produced that accumulated in a 1:1 proportion after 30 min in tissue and medium, respectively. This large efflux of lactic acid could account for the higher cytoplasmic pH values always found in pretreated tissues. The presence of cycloheximide during pretreatment abolished this difference, suggesting that the greater efficiency of lactate efflux was linked to protein synthesis. The role of lactate in cytosolic pH regulation and in sensitivity to anoxia is discussed.     

Effects of anaerobiosis on carbohydrate oxidation by roots of Pisum sativum

The aim of this work was to discover the effects of anaerobiosis on the breakdown of sugars by the apical 6 mm of the roots of 5-day-old seedlings of Pisum sativum. Estimates of the maximum catalytic activities of alcohol dehydrogenase, lactate dehydrogenase, phosphoenolpyruvate carboxylase and NADP-specific malic enzyme showed them to be comparable to that of phosphofructokinase. Metabolism of sucrose-[U-¹⁴C] by excised apices was restricted by anoxia mainly to conversion to ethanol, CO₂ alanine and glycolytic intermediates. Measurements of metabolites over a period of 240 min after transfer of excised apices to nitrogen showed a marked and continual accumulation of ethanol, a smaller continual accumulation of alanine, a small initial rise in lactate and no detectable accumulation of malate or pyruvate. The rates of CO₂ production, of accumulation of ethanol and alanine, and of the labelling of these compounds by sucrose-[¹⁴C] declined markedly during the first 240 min of anaerobiosis. The conclusion is that under anaerobic conditions carbohydrate metabolism in the pea root apex is largely restricted to alcoholic fermentation, and, to a lesser degree, to alanine production.     

Biosystematic study of the genus Limonium (Plumbaginaceae) in the Aegean area, Greece. EO. Limonium on the islands Kithira and Antikithira and the surrounding islets

The genus Limonium is represented on Kithira, Antikithira and the surrounding islets by the following nine species: L. aphroditae and L. cythereum , recently described from Kithira; L. runemarkii and L. ocymifolium , endemic to Greece; L. graecum and L. sieberi , distributed in E Mediterranean; L. virgatum, L. sinuatum and L. echioides , having a wider Mediterranean distribution. For L. runemarkii , considered so far as endemic to SE Ewia, a new extended distribution range is given from Ewia to NW Kriti, through Peloponnisos and Kithira, showing the phytogeographic relationship of these areas. Moreover, the treatment of L. pigadiense as synonym of L. ocymifolium is proposed. Key and diagnostic characters for the species studied are given, while their affinities to related Aegean and Mediterranean Limonium taxa are discussed. Data on the cytology and breeding system are given. The following chromosome numbers were found: 2n=3x=27 for L. aphroditae and L. virgatum , 2n=6x=52 for L. cythereum , 2n=6x=51 for L. sieberi (firstly reported), 2n=5x=43 for L. runemarkii (firstly reported), L. ocymifolium and L. graecum , 2n=2x=16 for L. sinuatum and 2n=2x=18 for L. echoides. Concerning pollen-stigma combination, L. aphroditae, L. ocymifolium and L. virgatum are monomorphic with the self-incompatible combination B, while L. cythereum and L. runemarkii are also monomorphic with the self-incompatible combination A. According to these data the above species can be considered as apomictic. The facultative apomictic L. graecum was found monomorphic with the combination A, while L. sieberi , has the combination A or B within different populations. The autogamous species L. echioides has the self-compatible combination C, while the allogamous L. sinuatum is dimorphic having both combinations A and B in each population.     

Pathways of carbohydrate fermentation in the roots of marsh plants

We did this work to discover the pathways of carbohydrate fermentation in unaerated roots of three species of flood-tolerant plants, Ranunculus sceleratus, Glyceria maxima, and Senecio aquaticus. The experiments were done with the apical 1–2 cm of the roots and the results for the three species were similar. The maximum catalytic activities of alcohol dehydrogenase, lactate dehydrogenase, phosphoenolpyruvate carboxylase, NADP-dependent malic enzyme, and phosphofructokinase were appreciable and roughly comparable. Reduced aeration of the roots led to 1.5 to 5-fold increases in the maximum catalytic activities of alcohol dehydrogenase, small increases in those of lactate dehydrogenase in two species, and no increase in those of phosphoenolpyruvate carboxylase and phosphofructokinase. Phosphoenolpyruvate carboxykinase could not be detected. Metabolism of [U-¹⁴C]sucrose under anaerobic conditions by excised roots, grown without aeration, led to appreciable labelling of ethanol and alanine, slight but significant labelling of lactate, and minimal labelling of malate and related organic acids. Incubation of similar excised roots under anaerobic conditions for 4 h caused marked accumulation of ethanol, smaller accumulation of lactate, and no detectable accumulation of malate. We conclude that in all three species fermentation of carbohydrate results in the accumulation of predominant amounts of ethanol, smaller amounts of lactate, no significant quantities of malate, and probably appreciable amounts of alanine. Crawford's metabolic theory of flooding tolerance is held to be incompatible with these results.Abbreviations MES 2-(N-morpholino)ethanesulphonic acid - MOPS 2-(N-morpholino)propanesulphonic acid     

Stimulation of alanine amino transferase (AlaAT) gene expression and alanine accumulation in embryo axis of the model legume Medicago truncatula contribute to anoxia stress tolerance

The efficiency of ethanolic fermentation in anoxia tolerance under sugar-limiting conditions, as in the field is still matter of debate. Due to higher rates of glycolysis and ethanol fermentation, faster depletion of sugar stores leads to decreased survival. In the present work the hypothesis that alanine amino transferase ( AlaAT ) fermentation be involved in anoxia tolerance was explored in Medicago truncatula during germination and seedling establishment. Expression of AlaAT and two low oxygen-responsive genes, alcohol dehydrogenase ( ADH ) and lactate dehydrogenase ( LDH ) were determined by real time quantitative RT-PCR and AlaAT activity was determined by ¹⁵N-Glutamate labelling coupled to amino acids analysis by gas chromatography–mass spectrometry and HPLC. Under anoxia not only ADH and LDH levels of expression increased but also AlaAT expression increased substantially. In parallel in vivo AlaAT activity increased and resulted in an increase in alanine synthesis that accumulated as the major amino acid instead of asparigine. These findings support the hypothesis that AlaAT expression and alanine accumulation contribute efficiently to anoxia tolerance. By competing with ethanolic fermentation for pyruvate, under sugar-limiting conditions alanine synthesis saves C3 skeletons avoiding a shortage in carbon availability and limits accumulation of acetaldehyde, a toxic compound. On another hand, increase in alanine was accompanied by an increase in γ-amino butyric acid, both amino acids may intervene in cytosolic pH regulation. Finally the role of alanine in anoxia tolerance was strengthened by the fact that when alanine synthesis was impaired germination and seedling development failed under anoxia.     

NADH reoxidation does not control glycolytic flux during exposure of respiring Saccharomyces cerevisiae cultures to glucose excess

Introduction of the Lactobacillus casei lactate dehydrogenase (LDH) gene into Saccharomyces cerevisiae under the control of the TPI1 promoter yielded high LDH levels in batch and chemostat cultures. LDH expression did not affect the dilution rate above which respiro-fermentative metabolism occurred (Dc) in aerobic, glucose-limited chemostats. Above Dc, the LDH-expressing strain produced both ethanol and lactate, but its overall fermentation rate was the same as in wild-type cultures. Exposure of respiring, LDH-expressing cultures to glucose excess triggered simultaneous ethanol and lactate production. However, the specific glucose consumption rate was not affected, indicating that NADH reoxidation does not control glycolytic flux under these conditions.     

Metabolic Acclimation to Anoxia Induced by Low (2-4 kPa Partial Pressure) Oxygen Pretreatment (Hypoxia) in Root Tips of Zea mays

Young intact plants of maize (Zea mays L. cv INRA 508) were exposed to 2 to 4 kilopascals partial pressure oxygen (hypoxic pretreatment) for 18 hours before excision of the 5 millimeter root apex and treatment with strictly anaerobic conditions (anoxia). Hypoxic acclimation gave rise to larger amounts of ATP, to larger ATP/ADP and adenylate energy charge ratios, and to higher rates of ethanol production when excised root tips were subsequently made anaerobic, compared with root tips transferred directly from aerobic to anaerobic media. Improved energy metabolism following hypoxic pretreatment was associated with increased activity of alcohol dehydrogenase (ADH), and induction of ADH-2 isozymes. Roots of Adh1⁻ mutant plants lacked constitutive ADH and only slowly produced ethanol when made anaerobic. Those that were hypoxically pretreated acclimated to anoxia with induction of ADH2 and a higher energy metabolism, and a rate of ethanol production comparable to that of nonmutants. All these responses were insensitive to the presence or absence of NO₃⁻. Additionally, the rate of ethanol production was about 50 times greater than the rate of reduction of NO₃⁻ to NO₂⁻. These results indicate that nitrate reductase does not compete effectively with ADH for NADH, or contribute to energy metabolism during anaerobic respiration in this tissue through nitrate reduction. Unacclimated root tips of wild type and Adhl⁻ mutants appeared not to survive more than 8 to 9 hours in strict anoxia; when hypoxically pretreated they tolerated periods under anoxia in excess of 22 hours.     

A reassessment of the function of the so-called compatible solutes in the halophytic plumbaginaceae Limonium latifolium

The compatible solute hypothesis posits that maintaining osmotic equilibrium under conditions of high salinity requires synthesis of organic compounds, uptake of potassium ions, and partial exclusion of NaCl. To assess whether osmotic adaptation in Limonium latifolium proceeds according to this hypothesis, a comprehensive analysis of solute accumulation during NaCl treatments was conducted. Determination of prevailing inorganic ions and establishment of the metabolic profiles for low M(r) organic substances revealed that contrary to the mentioned hypothesis the major contributors to osmolarity were constituted by inorganic solutes. Independent of salinity, only 25% of this osmolarity resulted from organic solutes such as Suc and hexoses. Proline (Pro), beta-alanine betaine, and choline-O-sulfate were minor contributors to osmolarity. Compatible inositols also occurred, especially chiro-inositol, characterized for the first time in this species, to our knowledge. Principal component analysis showed that only a limited number of metabolic reconfigurations occurred in response to dynamic changes in salinity. Under such conditions only sugars, chiro-inositol, and Pro behave as active osmobalancers. Analysis of metabolic profiles during acclimatization to either mild salinity or nonsaline conditions showed that organic solute accumulation is predominantly controlled by constitutive developmental programs, some of which might be slightly modulated by salinity. Osmolarity provided under such conditions can be sufficient to maintain turgor in salinized seedlings. Compartmental analysis of Pro and beta-alanine betaine in leaf tissues demonstrated that these solutes, mainly located in vacuoles under nonsaline conditions, could be partly directed to the cytosol in response to salinization. Thus they did not conform with the predictions of the compatible solute hypothesis.