Starvation-induced cross protection against osmotic challenge in Escherichia coli.

Stationary-phase Escherichia coli cultures showed enhanced osmotic resistance as compared with cultures in mid-logarithmic growth or preadapted to osmotic stress. The osmotolerance that developed during starvation or osmotic adaptation required de novo protein synthesis. Of the 22 polypeptides induced during osmotic shock, five were also starvation proteins.     

Comparative Analysis of Short- and Long-Term Changes in Gene Expression Caused by Low Water Potential in Potato (Solanum tuberosum) Cell-Suspension Cultures

To dissect the cellular response to water stress and compare changes induced as a generalized response with those involved in tolerance/acclimation mechanisms, we analyzed changes in two-dimensional electrophoretic patterns of in vivo [35S]methionine-labeled polypeptides of cultured potato (Solanum tuberosum) cells after gradual and long exposure to polyethylene glycol (PEG)- mediated low water potential versus those induced in cells abruptly exposed to the same stress intensity. Protein synthesis was not inhibited by gradual stress imposition, and the expression of 17 proteins was induced in adapted cells. Some polypeptides were inducible under mild stress conditions (5% PEG) and accumulated further when cells were exposed to a higher stress intensity (10 and 20% PEG). The synthesis of another set of polypeptides was up-regulated only when more severe water-stress conditions were applied, suggesting that plant cells were able to monitor different levels of stress intensity and modulate gene expression accordingly. In contrast, in potato cells abruptly exposed to 20% PEG, protein synthesis was strongly inhibited. Nevertheless, a large set of polypeptides was identified whose expression was increased. Most of these polypeptides were not induced in adapted cells, but many of them were common to those observed in abscisic acid (ABA)-treated cells. These data, along with the finding that cellular ABA content increased in PEG-shocked cells but not in PEG-adapted cells, suggested that this hormone is mainly involved in the rapid response to stress rather than long-term adaptation. A further group of proteins included those induced after long exposure to both water stress and shock. Western blot analysis revealed that osmotin was one protein belonging to this common group. This class may represent induced proteins that accumulate specifically in response to low water potential and that are putatively involved in the maintenance of cellular homeostasis under prolonged stress.     

Salt stress adaptation of Bacillus subtilis: a physiological proteomics approach

The adaptation to osmotic stress is crucial for growth and survival of Bacillus subtilis in its natural ecosystem. Dual channel imaging and warping of 2-D protein gels were used to visualize global changes in the protein synthesis pattern of cells in response to osmotic stress (6% NaCl). Many vegetative enzymes were repressed in response to salt stress and derepressed after resumption of growth. The enzymes catalyzing the metabolic steps from glucose to 2-oxoglutarate, however, were almost constantly synthesized during salt stress despite the growth arrest. This indicates an enhanced need for the proline precursor glutamate. The synthesis of enzymes involved in sulfate assimilation and in the formation of Fe-S clusters was also induced, suggesting an enhanced need for the formation or repair of Fe-S clusters in response to salt stress. One of the most obvious changes in the protein synthesis profile can be followed by the very strong induction of the SigB regulon. Furthermore, members of the SigW regulon and of the PerR regulon, indicating oxidative stress after salt challenge, were also induced. This proteomic approach provides an overview of cell adaptation to an osmotic upshift in B. subtilis visualizing the most dramatic changes in the protein synthesis pattern.     

Survival, stress resistance, and alterations in protein expression in the marine vibrio sp. strain S14 during starvation for different individual nutrients.

The response of the marine Vibrio sp. strain S14 to starvation for carbon, nitrogen, or phosphorus and to simultaneous depletion of all these nutrients (multiple-nutrient starvation) was examined with respect to survival, stress resistance, quantitative and qualitative alterations in protein and RNA synthesis, and the induction of the stringent control. Of the conditions tested, carbon starvation and multiple-nutrient starvation both promoted long-term starvation resistance and a rapid induction of the stringent control, as deduced from the kinetics of RNA synthesis. Carbon- and multiple-nutrient-starved cells were also found to become increasingly resistant to heat, UV, near-UV, and CdCl2 stress. Nitrogen- and phosphorus-starved cells demonstrated a poor ability to survive in the presence of carbon and did not develop a marked resistance to the stresses examined. The carbon, nitrogen, and phosphorus starvation stimulons consisted of about 20 proteins each, while simultaneous starvation for all the nutrients elicited an increased synthesis of 42 polypeptides. Nine common proteins were found to be induced regardless of the starvation condition used and were tentatively termed general starvation proteins. It was also demonstrated that the total number of proteins induced in response to multiple-nutrient starvation was not a predictable sum of the different individual starvation stimulons. Multiple-nutrient starvation induced 14 proteins which were not detected at increased levels of expression in response to individual starvation conditions. Furthermore, four out of five phosphorus starvation-specific polypeptides were not induced during simultaneous starvation for phosphorus, nitrogen, and carbon. The results are discussed in light of the physiological alterations previously described for Vibrio sp. strain S14 cells starved for carbon, nitrogen, and phosphorus simultaneously.     

Regulation by ABA of osmotic-stress-induced changes in protein synthesis in tomato roots

Polypeptide synthesis and accumulation were examined in the roots of tomato seedlings exposed to a polyethylene glycol‐imposed water deficit stress. In these roots, the synthesis of a number of polypeptides was induced, while that of several others was enhanced or repressed. To examine the role played by abscisic acid (ABA) in co‐ordinating the accumulation of these proteins, water‐deficit‐stress‐responsive polypeptide synthesis was investigated in the roots of the ABA‐deficient mutant flacca. In the roots of this mutant, the ability to accumulate a complete set of water‐deficit‐stress‐responsive polypeptides was impaired, indicating that ABA is required for their synthesis. The role of ABA was further examined by exposing the roots of both genotypes to exogenous ABA, which, with one exception, elicited the accumulation of all water‐deficit‐stress‐responsive proteins. Polyethylene glycol‐induced polypeptide accumulation was accompanied by a 1·6‐fold increase in the level of endogenous ABA in the roots of wild‐type plants and a 5‐fold increase in the roots of flc. Thus, although the absolute level was lower than that of the wild‐type, flc has the capacity to accumulate ABA in its roots. When fluridone was used to prevent the biosynthesis of ABA, the accumulation of several water‐deficit‐stress‐responsive polypeptides was reduced further. The synthesis of polypeptides was also examined in the roots of salt‐treated seedlings. Salt altered the accumulation of several polypeptides, all of which were previously observed in water‐deficit‐stressed roots, indicating that their synthesis was the result of the osmotic component of the salt stress. However, the accumulation of these polypeptides was not impaired in flc roots, indicating that the role played by ABA in regulating their accumulation in salt‐and polyethylene glycol‐treated roots differs. As such, salt‐ and water‐deficit‐stress‐induced changes in gene expression may be effected by different mechanisms, at least at the level of polypeptide accumulation.     

Survival, stress resistance, and alterations in protein expression in the marine vibrio sp. strain S14 during starvation for different individual nutrients.

The response of the marine Vibrio sp. strain S14 to starvation for carbon, nitrogen, or phosphorus and to simultaneous depletion of all these nutrients (multiple-nutrient starvation) was examined with respect to survival, stress resistance, quantitative and qualitative alterations in protein and RNA synthesis, and the induction of the stringent control. Of the conditions tested, carbon starvation and multiple-nutrient starvation both promoted long-term starvation resistance and a rapid induction of the stringent control, as deduced from the kinetics of RNA synthesis. Carbon- and multiple-nutrient-starved cells were also found to become increasingly resistant to heat, UV, near-UV, and CdCl2 stress. Nitrogen- and phosphorus-starved cells demonstrated a poor ability to survive in the presence of carbon and did not develop a marked resistance to the stresses examined. The carbon, nitrogen, and phosphorus starvation stimulons consisted of about 20 proteins each, while simultaneous starvation for all the nutrients elicited an increased synthesis of 42 polypeptides. Nine common proteins were found to be induced regardless of the starvation condition used and were tentatively termed general starvation proteins. It was also demonstrated that the total number of proteins induced in response to multiple-nutrient starvation was not a predictable sum of the different individual starvation stimulons. Multiple-nutrient starvation induced 14 proteins which were not detected at increased levels of expression in response to individual starvation conditions. Furthermore, four out of five phosphorus starvation-specific polypeptides were not induced during simultaneous starvation for phosphorus, nitrogen, and carbon. The results are discussed in light of the physiological alterations previously described for Vibrio sp. strain S14 cells starved for carbon, nitrogen, and phosphorus simultaneously.     

Effects of water stress on plant growth and root proteins in three cultivars of rice (Oryza sativa) with different levels of drought tolerance

Rice ( Oryza sativa L.) is considered a drought-sensitive crop species; however, within this species, there are considerable varietal differences in sensitivity to this environmental stress. In the present work, the effect of water stress on germination, plant growth and root proteins in three rice cultivars (Sinaloa, IR10120 and Chiapas) was analyzed. Seed germination and plant growth were found to be significantly inhibited by polyethylene glycol (PEG)-imposed water deficit in cv. Sinaloa; cvs IR10120 and Chiapas were more tolerant to water stress. Fluorographs of two-dimensional electropherograms of in vivo-labeled polypeptides were analyzed to identify changes in the root protein patterns that resulted when plants were grown in the presence of 10% PEG for 10 days. The treatment induced or increased the synthesis of eight polypeptides or groups of polypeptides in cv. Sinaloa, seven in cv, IR10120 and four in cv. Chiapas. The synthesis of several polypeptides was decreased by the PEG treatment in cv. Sinaloa and cv. IR10120. Most of these PEG-induced changes in the root protein patterns were cultivar-specific and only one 26-kDa protein with a pI of 6.0 was induced by water deficit in the two cultivars Sinaloa and IR10120.     

三唑酮提高水稻幼苗抗旱性的研究

在-0.5MPa渗透胁迫下三唑酮提高水稻(Oryza sativa L.)幼苗相对含水量,降低丙二醛(MDA)含量,提高了抗旱性。三唑酮(75mg/L)可提高渗透胁迫下水稻幼苗过氧化物酶(POD)和过氧化氢酶(CAT)活性,对超氧物歧化酶(SOD)活性影响不大。加入蛋白质合成抑制剂环己亚胺试验证明,三唑酮对POD的效应是促进酶蛋白的合成。     

Effect of Abscisic Acid, Osmoticum, and Desiccation on Synthesis of Storage Proteins during the Development of White Spruce Somatic Embryos

The effect of abscisic acid (ABA), non-permeating osmoticumand desiccation treatment on storage protein synthesis duringmaturation of somatic embryos of Picea glauca (Moench) Voss.was examined. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis(SDS-PAGE) and Western blot analysis demonstrated that someof the major crystalloid and matrix polypeptides were absentfrom somatic embryos maturing on medium containing ABA and lowosmoticum. However, treatment with polyethylene glycol-4000(PEG) in combination with ABA resulted in the synthesis of aspectrum of storage polypeptides resembling that of mature zygoticembryos. These storage proteins accumulated throughout an 8-weekculture period, resulting in a threefold higher protein contentthan somatic embryos maturing for the same time in the absenceof PEG. The structure and distribution of protein bodies incells of these osmotically treated somatic embryos was similarto that in cells of mature zygotic embryos. Treatment with 5·0-7·5%PEG prevented catabolism of the accumulated storage polypeptidesduring desiccation. The optimal culture conditions for somaticembryo maturation and storage protein deposition was 16 µMABA and 7·5% PEG for 8 weeks followed by desiccation.Analysis of mRNAs by in vitro translation and immunoprecipitationof translated products showed that the crystalloid protein mRNAprofiles of zygotic and those of somatic embryos maturing on16 µM ABA in the absence of PEG were similar. The differencesobserved in the pattern of accumulated polypeptides in thesesomatic embryos and those of mature zygotic embryos, therefore,indicates that storage-protein synthesis in response to osmoticumis in part regulated at the translational level. During regenerationof somatic embryos to plantlets the storage polypeptides wererapidly utilized in a manner similar to that in zygotic seedlings.Copyright1993, 1999 Academic Press Desiccation, osmotic stress, storage proteins, Picea, embryogenesis—somatic, mRNA (crystalloid protein)     

Induction and enhancement of stress proteins in a trichloroethylene-degrading methanotrophic bacterium, Methylocystis sp. M

The responses of the trichloroethylene-degrading bacterium Methylocystis sp. M to six different water-pollutants, carbon starvation, and temperature-shock (heat and cold) were examined using 2-dimensional gel electrophoresis. Twenty-eight polypeptides were induced, and these stress-induced proteins were classified into three groups. Some of the chemically induced proteins were the same as those induced by carbon starvation and temperature-shock. Two of the polypeptides were induced by trichloroethylene. Trichloroethylene-stress protein synthesis required 1-2 h at a concentration of trichloroethylene that had no effect on growth. Furthermore, 25 stress-enhanced polypeptides were observed, and one of these was enhanced by trichloroethylene. Based on these results, we discuss applications of chemical-stress induction of proteins to establish effective bioremediation and bioassay by methanotrophs.     

UV-inducible proteins and UV-induced cross-protection against acid,ethanol, H2O2 or heat treatments in Lactococcus lactis subsp. lactis

The relationship between UV-irradiation-induced tolerance to different environmental stresses and change in protein synthesis was examined in Lactococcus lactis subsp lactis IL1403. The results showed that preirradiation of cultures of L. lactis subsp. lactis with UV_254nm light led to increased tolerance of usually lethal challenges to acid (pH 4.0), ethanol (20%, v/v), H₂O₂ (15 mM), or heat (52° C). This suggests that there is an overlapping regulation between the UV-induced pathway and the other stress responses. Whole-cell protein extracts from UV-treated (100 J/m²) and untreated cultures were compared using two-dimensional polyacrylamide gel electrophoresis. At least 14 polypeptides were induced in response to damage after UV irradiation, which indicated an SOS-like response in this species. The RecA protein, however, seemed not to be significantly induced in Lactococcus lactis subsp. lactis IL1403. Some of the UV-induced polypeptides overlaped with stress proteins induced by the other treatments.     

Inducibility of the response of yeast cells to peroxide stress.

Exponential phase cells of the yeast, Saccharomyces cerevisiae when treated with a non-lethal concentration of hydrogen peroxide (H2O2; 0.2mM) for 60 min adapted to become resistant to the lethal effects of a higher dose of H2O2 (2mM). From studies using cycloheximide to inhibit protein synthesis it appears that protein synthesis is required for maximal induction of resistance but that some degree of protection from the lethal effects of peroxide can be acquired in the absence of protein synthesis. Treatment of cells with 50 micrograms cycloheximide ml-1 alone lead to them acquiring some protection from peroxide. Cells subjected to heat shock became more resistant to 2mM-H2O2; however, peroxide pretreatment did not confer thermotolerance. L-[35S]Methionine labelling of cells subjected to 0.2 mM-H2O2 stress showed that synthesis of at least ten polypeptides was induced by peroxide treatment. Some of these were also induced in cells subjected to heat shock (23 to 37 degrees C shift) but the synthesis of at least four polypeptides (45, 39.5, 38 and 24 kDa) was unique to peroxide-stressed cells. Resistance to peroxide was also inducible in an isogenic petite and an isogenic strain with a mutation in the HAP1 gene, indicating that the adaptive response does not require functional mitochondria.     

Salinity-stress-induced proteins in two nitrogen-fixing Anabaena strains differentially tolerant to salt.

Salinity altered the protein synthesis patterns in two cyanobacterial strains: Anabaena torulosa, a salt-tolerant brackish water strain, and Anabaena sp. strain L-31, a salt-sensitive freshwater strain. The cyanobacterial response to salinity was very rapid, varied with time, and was found to be correlated with the external salt (NaCl) concentration during stress. Salinity induced three prominent types of modification. First, the synthesis of several proteins was inhibited, especially in the salt-sensitive strain; second, the synthesis of certain proteins was significantly enhanced; and third, synthesis of a specific set of proteins was induced de novo by salinity stress. Proteins which were selectively synthesized or induced de novo during salt stress, tentatively called the salt-stress proteins, were confined to an isoelectric pI range of 5.8 to 7.5 and were distributed in a molecular mass range of 12 to 155 kilodaltons. These salt-stress proteins were unique to each Anabaena strain, and their expression was apparently regulated coordinately during exposure to salt stress. In Anabaena sp. strain L-31, most of the salt-stress-induced proteins were transient in nature and were located mainly in the cytoplasm. In A. torulosa, salt-stress-induced proteins were evenly distributed in the membrane and cytoplasmic fractions and were persistent, being synthesized at high rates throughout the period of salinity stress. These initial studies reveal that salinity-induced modification of protein synthesis, as has been demonstrated in higher plant species, also occurs in cyanobacteria and that at least some of the proteins preferentially synthesized during salt stress may be important to cyanobacterial osmotic adaptation.     

Understanding Saline and Osmotic Tolerance of Populus euphratica Suspended Cells

Tolerance of Populus euphratica suspended cells to ionic and osmotic stresses implemented respectively by NaCl and PEG (6000) was characterized by monitoring cell growth, morphological features, ion compartmentation and polypeptide patterns. The cells grew and proliferated when submitted to stresses of 137 mM NaCl or 250 g l⁻¹ PEG, and survived at 308 mM of NaCl, showing tolerance to saline and particularly osmotic stress. They were resistant to plasmolysis and had dense cytoplasms, large nuclei and nucleoli, and evident cytoplasmic strands under high saline and osmotic stress. The sequestration of Cl⁻ into the vacuoles was observed in the cells stressed with 137 and 223 mM NaCl. The cellular protein profile was modified by high salt and osmotic stress and showed 28 kDa polypeptides up-regulated by both NaCl and PEG, and 66 and 25 kDa polypeptides up-regulated only by high NaCl stress. The salt tolerance of P. euphratica cells might be related to their capacity of adapting to higher osmotic stress by maintaining cell integrity, sequestrating Cl⁻ into vacuoles and modulating polypeptides that reflect cellular metabolic adaptations.     

Hsp70 and a 54 kDa protein (Osp54) are induced in salmon (Salmo salar) in response to hyperosmotic stress.

Hsp70 and a 54 kDa osmotic stress protein (osp54) were induced in isolated tissues of anadromous Atlantic salmon (Salmo salar) upon exposure to hyperosmotic conditions. Incubation of branchial lamellae, hepatic tissue, and erythrocytes in medium supplemented with 200-600 mM NaCl dramatically reduced protein synthesis. Although general protein synthesis remained depressed following transfer of tissues from 450 mM supplemental NaCl to iso-osmotic medium, hsp70 was prominently induced in branchial lamellae and hepatic tissue. Accumulation of hsp70 mRNA and a decrease in actin mRNA suggest preferential upregulation of the hsp70 gene. Induction of osp54 was observed in branchial lamellae and erythrocytes, but not in hepatic tissue, during exposure to 75-125 mM supplemental NaCl. Use of glycerol in place of NaCl to create hyperosmotic conditions stimulated induction of hsp70 in branchial lamellae. Substitution with mannitol resulted in induction of osp54 in both branchial lamellae and erythrocytes. The solute-specific and temporal patterns of response suggest that hsp70 and osp54 might function in concert to restore osmotic homeostasis and renature proteins destabilized or denatured during the early stages of osmotic shock.     

Inactivation of photosystems I and II in response to osmotic stress in Synechococcus. Contribution of water channels

The effects of osmotic stress due to sorbitol on the photosynthetic machinery were investigated in the cyanobacterium Synechococcus R-2. Incubation of cells in 1.0 M sorbitol inactivated photosystems I and II and decreased the intracellular solute space by 50%. These effects of sorbitol were reversible: Photosynthetic activity and cytoplasmic volume returned to the original values after removal of the osmotic stress. A blocker of water channels prevented the osmotic-stress-induced inactivation and shrinkage of the intracellular space. It also prevented the recovery of photosynthetic activity and cytoplasmic volume when applied just before release from osmotic stress. Inhibition of protein synthesis by lincomycin had no significant effects on the inactivation and recovery processes, an observation that suggests that protein synthesis was not involved in these processes. Our results suggest that osmotic stress decreased the amount of water in the cytoplasm via the efflux of water through water channels (aquaporins), with resultant increases in intracellular concentrations of ions and a decrease in photosynthetic activity.     

Water Uptake and Protein Synthesis in Germinating Wheat Embryos under the Osmotic Stress of Polyethylene Glycol

The effect of osmotic stress on wheat-seed germination was testedby imbibition in aqueous polyethylene glycol solutions at differentconcentrations. The experiments were designed to allow blockingand the subsequent recovery of germination by 12 h or 24 h pre-imbibitionof seeds in osmoticum, followed by transfer to water. Seedswere alternatively presoaked in water for 12 or 24 h, then transferredto polyethylene-glycol solutions to study the induced blockingof germination. Water content and [³H]leucine incorporationinto embryo tissues (as a measure of in vivo protein synthesis)were determined over a 48-h imbibition period. A close relationshipwas established overall between hydration status and proteinsynthesis rate. Osmotic stress seems to have a strong influenceupon the quantitative synthesis of proteins, suggesting thatthis biochemical activity is associated with the regulationof the germination process. Triticum durum, embryo, osmotic stress, water uptake, protein synthesis     

盐胁迫下苜蓿中盐蛋白的诱导产生

盐胁迫下苜蓿叶片中蛋白质的合成受到抑制,而其离体叶绿体中蛋白质合成增强,ABA阻碍了后者的蛋白质合成。NaCl胁迫下,“松江”和“肇东”两品种的根和叶中均无新多肽出现。在盐敏感的“松江”品种离体叶绿体中,NaGl诱导70,65,60和43kD4种多肽产生,ABA诱导60和17kD两种多肽产生;在较抗盐的“肇东”品种离体叶绿体中,NaGl诱导83,80kD和43kD3种多肽产生,但100mmol/L NaCl并不诱导83kD多肽出现,ABA无明显作用。两品种的43kD多肽和肇东品种的80kD多肽都存在于类囊体膜上,而松江品种的60kD多肽则存在于叶绿体间质中。     

Proteomic analysis of rice leaves shows the different regulations to osmotic stress and stress signals

Following the idea of partial root-zone drying(PRD)in crop cultivation,the morphological and physiological responses to partial root osmotic stress(PROS)and whole root osmotic stress(WROS)were investigated in rice.WROS caused stress symptoms like leaf rolling and membrane leakage.PROS stimulated stress signals,but did not cause severe leaf damage.By proteomic analysis,a total of 58 proteins showed differential expression after one or both treatments,and functional classification of these proteins suggests that stress signals regulate photosynthesis,carbohydrate and energy metabolism.Two other proteins(anthranilate synthase and submergence-induced nickel-binding protein)were upregulated only in the PROS plants,indicating their important roles in stress resistance.Additionally,more enzymes were involved in stress defense,redox homeostasis,lignin and ethylene synthesis in WROS leaves,suggesting a more comprehensive regulatory mechanism induced by osmotic stress.This study provides new insights into the complex molecular networks within plant leaves involved in the adaptation to osmotic stress and stress signals.