Effect of common sage plant treatment with polyamines on the contents of proline and free and conjugated polyamines under oxidative stress

Common sage (Salvia officinalis L.) plants grown in water culture to the stage of 4–5 true leaves were treated with paraquat (PQ) ( 1 ml of the solution containing 0.1 μM PQ in 0.05% Tween 80), putrescine (Put), spermidine (Spd), or Spermine (Spm) (all polyamines (PA) at the concentration of 0.5 mM in 0.05% Tween 80) or PA plus PQ for 6, 12, 24, 36, or 48 h. Under normal conditions, treatment with individual PA did not induce any changes in the content of free proline. Under oxidative stress induced by PQ, oxidation of proline and free PA by ROS resulted in their spending and demanded restoration of free PA due to hydrolysis of their insoluble conjugates. As distinct from treatment with PQ only, its combination with PA in the light was accompanied by proline accumulation. Treatment with Put plus PQ induced accumulation of intracellular Put and its soluble and insoluble conjugates. Treatments with Spd and Spm in combination with PQ resulted similarly in the increase in the levels of their intracellular soluble and insoluble conjugates. In treatments with these high-molecular PA, polyamine oxidase was activated and diaminopropan formation was observed. It seems likely that, for restoration of high-molecular PA homeostasis, their degradation by polyamine oxidase or production of insoluble conjugates is induced. Thus, the amount of free and conjugated particular PA is under strict control and is maintained at a definite level. A decrease in the content of a particular free PA induces primarily a decrease in the content of its soluble and then insoluble conjugates. The data obtained demonstrate the effects of exogenous PA on the content of intracellular proline under oxidative stress but do not allow a conclusion about direct regulation of its content by PA.     

Proline involvement in the common sage antioxidant system in the presence of NaCl and paraquat

To elucidate proline antioxidant properties in common sage (Salvia officinalis L.) plants, they were treated with paraquat (a producer of superoxide radical) and/or NaCl and also with paraquat and proline at the stage of 4–5 true leaves. The paraquat solution (1 ml containing 0.1 μmol of the agent) was applied to the leaf surface; NaCl (200 mM) and proline (the final concentration of 5 mM) were added to nutrient medium. Experimental plants were firstly kept in darkness for 12 h, then illuminated, and in 3, 6, and 12 h, leaves and roots were fixed for biochemical analyses. The results obtained are in agreement with the supposition of proline antioxidant properties. In particular, it was established that paraquat induced a slight increase in the proline level in the leaves during dark period of plant growth and also during subsequent 3 h after light switching on. This transient proline accumulation in the leaves was accompanied by its level decrease in the roots. Proline addition to the nutrient medium of paraquat-treated plants neutralized paraquat damaging action on the leaves. In the presence of paraquat, proline treatment reduced the accumulation in the roots of hydrogen peroxide and malondialdehyde, the product of membrane lipid peroxidation. It also affected indirectly the activities of superoxide dismutase (SOD) and free, covalently bound, and ionically bound peroxidases. Keeping in mind that, in the presence of paraquat, superoxide-induced changes in SOD activity in the roots were negatively correlated with the level of proline, which content was the highest during the last hours of experiments, we can conclude that proline antioxidant effects are manifested only after 12 h of stressor action, whereas antioxidant enzymes are involved in ROS scavenging during the earlier stage of damaging factor action.     

Autophagy machinery controls nitrogen remobilization at the whole-plant level under both limiting and ample nitrate conditions in Arabidopsis

? Processes allowing the recycling of organic nitrogen and export to young leaves and seeds are important determinants of plant yield, especially when plants are nitrate-limited. Because autophagy is induced during leaf ageing and in response to nitrogen starvation, its role in nitrogen remobilization was suspected. It was recently shown that autophagy participates in the trafficking of Rubisco-containing bodies to the vacuole. ? To investigate the role of autophagy in nitrogen remobilization, several autophagy-defective (atg) Arabidopsis mutants were grown under low and high nitrate supplies and labeled with at the vegetative stage in order to determine (15) N partitioning in seeds at harvest. Because atg mutants displayed earlier and more rapid leaf senescence than wild type, we investigated whether their defects in nitrogen remobilization were related to premature leaf cell death by studying the stay-green atg5.sid2 and atg5.NahG mutants. ? Results showed that nitrogen remobilization efficiency was significantly lower in all the atg mutants irrespective of biomass defects, harvest index reduction, leaf senescence phenotypes and nitrogen conditions. ? We conclude that autophagy core machinery is needed for nitrogen remobilization and seed filling.     

Effects of abscisic acid on the contents of polyamines and proline in common bean plants under salt stress

The effects of ABA treatment on the contents of polyamines (PAs) and proline (Pro) in the glycophyte Phaseolus vulgaris L. during plant adaptation to salt stress were studied. Two-week-old common bean seedlings grown in the phytotron chamber on the Jonson nutrient medium were subjected to salinity for 6 days by one-time NaCl addition to medium up to final concentrations of 50 and 100 mM. During first three days of salinity, the root system was daily treated with ABA (1, 5, 10, or 50 μM) for 30 min. Salt stress (100 mM NaCl) elevated the level of endogenous ABA, increased the content of Pro 14-fold, reduced sharply the content of free PAs (putrescine, spermidine, spermine, and cadaverine), and the accumulation of 1,3-diaminopropan, a product of oxidation of high-molecular PAs. Common bean plant treatment with 1 μM ABA weakened the adverse effects of salt stress (100 mM NaCl), which was manifested in the maintenance of plant growth, stimulation of chlorophyll (a and b) and carotenoid accumulation, a stabilization of water and Na⁺ balance. Seedling treatment with ABA suppressed NaCl-induced Pro and intracellular ABA accumulation and restored the levels of putrescine and spermidine. The content of spermine in the leaves of plants subjected to salt stress and treated with ABA was approximately threefold higher than in control plants, whereas the content of cadaverine increased under similar conditions more than fivefold. Simultaneously, the contents of 1,3-diaminopropan and malondialdehyde as well as activity of superoxide dismutase were reduced, which indicates a weakening of oxidative stress, one of the possible causes of defensive ABA effects against salt stress. In addition, the suppression by exogenous ABA of Pro accumulation and stimulation of PA content under salt stress confirm indirectly our hypothesis that ABA is involved in the coordinated regulation of two biosynthetic pathways, Pro and PA formation, which use a common precursor, glutamate, and play an important protective role during stress in plants.     

模拟边坡条件下常见护坡植物苗期根系构型特征

植物根系对提高边坡稳定性具有重要作用。采用喷播的方式在侵蚀槽中制备模拟石质边坡,植物生长6个月后采用全根挖掘和Win-RHIZO根系分析仪扫描相结合的方法,研究了模拟边坡条件下11种常见护坡植物苗期的根系构型特征。结果表明：紫花苜蓿根系生物量最大,柠条根系生物量最小,二者主根发达,仅分布在下坡方向。沙打旺、胡枝子、紫穗槐和欧李根系生物量、总根数、总基根数、总根长、总根表面积、总根体积均较大,在上坡方向和下坡方向分布均匀,拓扑指数介于0.53—0.61之间,为叉状分枝结构,根系固土护坡能力较强,可作为边坡生态修复工程的优选植物。根系生物量与根系表面积、根体积呈现显著的线性正相关关系(R²分别为0.68和0.80),拓扑指数与根系长度、根系表面积、总根数、总基根数呈现显著的指数负相关关系(R²分别为0.82、0.68、0.87、0.86),可为植物根系构型研究提供科学依据及理论支撑。     

Proline accumulation in two bean cultivars under salt stress and the effect of polyamines and ornithine

Proline accumulation in two different bean (Phaseolus vulgaris L.) cultivars, one drought-sensitive (Canario 60) and one drought-resistant (Pinto Villa) was investigated. Both tolerated salt concentrations up to 150 mM NaCl, but the sensitive Canario 60 did not survive at 400 mM NaCl. In response to salt stress, both cvs. accumulated proline in all the analyzed tissues, the lowest contents were detected in roots. Pinto Villa accumulated higher proline concentrations than Canario 60 only at 400 mM NaCl. The addition of polyamines or ornithine increased proline content in plant tissues without stress, while they decreased it under salt stress.     

Some effects of enhanced UV-B irradiation on the growth and composition of plants

Barley (Hordeum vulgare), corn (Zea mays), bean (Phaseolus vulgaris), and radish (Raphanus sativus) seedlings were continuously irradiated under a lighting device for 5–10 d at an increased ultraviolet (UV)-B fluence rate. In their growth parameters, composition, and leaf surface, these four species responded differently to the increased UV-B exposure. Bean seedlings suffered the most serious effects, radish and barley less, and corn was hardly influenced at all. In all plant species, the fresh weight, the leaf area, the amounts of chlorophylls, carotenoids and the galactolipids of the chloroplasts were reduced. The lipid content of the corn and bean seedlings also diminished. But all the irradiated plants showed a rise in their protein content compared to the control plants. The content of flavonoids increased in barley and radish seedlings by about 50%. The effects on growth parameters and composition were more extensive with increasing UV-B fluence rates, at least as shown in the case of barley seedlings. The fresh weights fell proportionally with the chlorophylls and carotenoids. In contrast, the flavonoid content of barley leaves rose parallel to the increasing UV-B fluence rates and reached 180% of the value in the control plants with the highest UV-B fluence rate. Scorching appeared regularly in the form of bronze leaf discoloration at the highest UV-B fluence rates. Scanning electron micrographs of the leaf surface of UV-B irradiated plants showed deformed epidermal structures.Abbreviations MGDG monogalactosyldiglyceride - DGDG digalactosyldiglyceride - SL sulfoquinovosyldiglyceride - PG phosphatidylglycerol - PC phosphatidylcholine - PE phosphatidylethanolamine - PI phosphatidylinositol - LA leaf are - FW fresh weight - DW dry weight - SEM scanning electron microscopy - C total carotenoids - Chl total chlorophyll     

Effect of ABA on the contents of proline, polyamines, and cytokinins in the common ice plants under salt stress

The effects of ABA treatment on the contents of proline, polyamines (PA), and cytokinins (CK) in the facultative halophyte the common ice plant (Mesembryanthemum crystallinum L.) subjected to salt stress were studied. Plants grown in the phytotron chamber on Jonson nutrient medium for 6 weeks were subjected to 6-day-long salinity by a single NaCl adding to medium. During first three days of salinity, half plants of each treatment were placed for 30 min on nutrient medium containing 0, 100, or 300 mM NaCl plus ABA in the final concentration of 1 μM. Salinity reduced biomass accumulation and water and chlorophyll contents in plants. This was accompanied by the increase in the levels of MDA, proline, and sodium ions. ABA treatment of salt-stressed plants favored biomass accumulation and photosynthetic pigment protection, reduced the intensity of oxidative stress and the level of NaCl-induced proline accumulation. ABA treatment increased the contents of putrescine (Put) and spermidine (Spd) in the leaves and roots of control plants (not subjected to salt stress), reduced the losses of Put in the leaves and roots and Spd in the roots in the presence of 100 mM NaCl, and suppressed cadaverine (Cad) accumulation in the roots in the presence of 300 mM NaCl. In the presence of NaCl, ABA reduced the contents of zeatin and zeatin riboside and increased the level of zeatin-O-glucoside in the roots and isopentenyladenosine and isopentenyladenine in the leaves. Thus, ABA protective action under salinity can be realized through the weakening of oxidative stress (a decrease in MDA content) and the regulation of PA, proline, and CK metabolism, which has a great significance in plant adaptation to injurious factors.     

Sterol methyltransferase 1 controls the level of cholesterol in plants

The side chain in plant sterols can have either a methyl or ethyl addition at carbon 24 that is absent in cholesterol. The ethyl addition is the product of two sequential methyl additions. Arabidopsis contains three genes-sterol methyltransferase 1 (SMT1), SMT2, and SMT3-homologous to yeast ERG6, which is known to encode an S-adenosylmethionine-dependent C-24 SMT that catalyzes a single methyl addition. The SMT1 polypeptide is the most similar of these Arabidopsis homologs to yeast Erg6p. Moreover, expression of Arabidopsis SMT1 in erg6 restores SMT activity to the yeast mutant. The smt1 plants have pleiotropic defects: poor growth and fertility, sensitivity of the root to calcium, and a loss of proper embryo morphogenesis. smt1 has an altered sterol content: it accumulates cholesterol and has less C-24 alkylated sterols content. Escherichia coli extracts, obtained from a strain expressing the Arabidopsis SMT1 protein, can perform both the methyl and ethyl additions to appropriate sterol substrates, although with different kinetics. The fact that smt1 null mutants still produce alkylated sterols and that SMT1 can catalyze both alkylation steps shows that there is considerable overlap in the substrate specificity of enzymes in sterol biosynthesis. The availability of the SMT1 gene and mutant should permit the manipulation of phytosterol composition, which will help elucidate the role of sterols in animal nutrition.     

Occurrence of ethanol in pea plants in the course of growth under normal and anaerobic conditions

1. At a so-called natural anaerobiosis during the first 48 hours of germination the concentration of ethanol in pea tissues increases (according to the cultivation conditions) up to 40 μmol per gram fresh weight.
2. In a nitrogen atmosphere the content of ethanol in pea seedlings increases as well, and after a 90 hour incubation in N₂ it can reach even 100 μmol ethanol per gram fresh weight. In older plants the content increases the most markedly in cotyledons, but considerable amounts were revealed also in stems and roots. Its increase in vegetative organs of plants cultivated both in light and darkness is more or less identical. Ethylalcohol can be formed by the vegetative organs themselves, as proved by the increase of this metabolite in plants deprived of reserve organs; in addition, however, it is evidently transported into them from reserve parts. Ethanol formed under anaerobiosis is catabolyzed after transferring plants to the air.

     

Proliferation kinetics of mouse tongue epithelium under normal conditions and following single dose irradiation

Epithelial proliferation in the ventral surface of mouse tongue follows a pronounced circadian rhythm with a peak in mitotic activity at 10.00 a.m., preceded by a wave of DNA synthesis 8 h earlier. Nearly all cells (85%) pass through G2 and mitosis immediately after the S-phase; they subsequently divide again, usually after 2 or 3 days, indicating cohorts of cells with different G1-duration. The fraction of all nucleated cells comprised in one daily proliferation wave is about 20%, indicating a turnover time of the nucleated cell compartment of about 5 days. Cytotoxic injury by a single radiation dose of 20 Gy causes a steep decrease in cell counts, leading to complete denudation after 9–13 days. The difference between the latent period before ulceration and the tissue turnover time is explained by a marked proliferative activity of the doomed cells. The mitotic index increases steeply after day 1 to three times the control level, but most mitotic figures display gross abnormalities such as multipolar spindles or chromosome clumping. As a consequence cells with abnormal or multiple nuclei appear in the basal layers 3 days post irradiation and subsequently migrate to the upper layers. After denudation the epithelium rapidly becomes restored, with a phase of transient hyperplasia on days 13–14. Normal architecture is regained by day 15. Over the whole healing period the mitotic index remains at a high level, with most of the mitoses appearing histologically normal.     

Interactive effects of UV-B irradiation and triadimefon on nodulation and nitrogen metabolism in Vigna radiata plants

Supply of aqueous solution of triadimefon (20 mg dm⁻³) to unstressed green gram plants increased the contents of soluble proteins, amino acids, nitrate and nitrite, and the activity of nitrate reductase in the leaves and nitrate reductase in nodules. The nitrogenase activity in nodules and roots was also increased. Number and fresh mass of nodules and their nitrate and nitrite contents were also higher than those of the controls. In contrast, the UV-B stress (12.2 kJ m⁻² d⁻¹) suppressed nodulation and nitrogen metabolism in leaves and roots compared to plants under natural UV-B (10 kJ m⁻² d⁻¹). Triadimefon-treated plants did not show such severe inhibitions after exposure to elevated UV-B. Thus triadimefon increased their tolerance to UV-B stress.     

Genotype differences in the metabolism of proline and polyamines under moderate drought in tomato plants

Water stress is one of the most important factors limiting the growth and productivity of crops. The implication of compatible osmolytes such as proline and polyamines in osmotic adjustment has been widely described in numerous plants species under stress conditions. In the present study, we investigated the response of five cherry tomato cultivars (Solanum lycopersicum L.) subjected to moderate water stress in order to shed light on the involvement of proline and polyamine metabolism in the mechanisms of tolerance to moderate water stress. Our results indicate that the most water stress‐resistant cultivar (Zarina) had increased degradation of proline associated with increased polyamine synthesis, with a higher concentration of spermidine and spermine under stress conditions. In contrast, Josefina, the cultivar most sensitive to water stress, showed a proline accumulation associated with increased synthesis after being subjected to stress. In turn, in this cultivar, no rise in polyamine synthesis was detected. Therefore, all the data appear to indicate that polyamine metabolism is more involved in the tolerance response to moderate water stress.     

Proliferation kinetics of mouse tongue epithelium under normal conditions and following single dose irradiation.

Epithelial proliferation in the ventral surface of mouse tongue follows a pronounced circadian rhythm with a peak in mitotic activity at 10.00 a.m., preceded by a wave of DNA synthesis 8 h earlier. Nearly all cells (85%) pass through G2 and mitosis immediately after the S-phase; they subsequently divide again, usually after 2 or 3 days, indicating cohorts of cells with different G1-duration. The fraction of all nucleated cells comprised in one daily proliferation wave is about 20%, indicating a turnover time of the nucleated cell compartment of about 5 days. Cytotoxic injury by a single radiation dose of 20 Gy causes a steep decrease in cell counts, leading to complete denudation after 9-13 days. The difference between the latent period before ulceration and the tissue turnover time is explained by a marked proliferative activity of the doomed cells. The mitotic index increases steeply after day 1 to three times the control level, but most mitotic figures display gross abnormalities such as multipolar spindles or chromosome clumping. As a consequence cells with abnormal or multiple nuclei appear in the basal layers 3 days post irradiation and subsequently migrate to the upper layers. After denudation the epithelium rapidly becomes restored, with a phase of transient hyperplasia on days 13-14. Normal architecture is regained by day 15. Over the whole healing period the mitotic index remains at a high level, with most of the mitoses appearing histologically normal.     

Ethylene reduces gas exchange and growth of lettuce plants under hypobaric and normal atmospheric conditions

Elevated levels of ethylene occur in controlled environment agriculture and in spaceflight environments, leading to adverse plant growth and sterility. The objectives of this research were to characterize the influence of ethylene on carbon dioxide (CO₂) assimilation (C_A), dark period respiration (DPR) and growth of lettuce ( Lactuca sativa L. cv. Buttercrunch) under ambient and low total pressure conditions. Lettuce plants were grown under variable total gas pressures of 25 kPa (hypobaric) and 101 kPa (ambient) pressure. Endogenously produced ethylene accumulated and reduced C_A, DPR and plant growth of ambient and hypobaric plants. There was a negative linear correlation between increasing ethylene concentrations [from 0 to around 1000 nmol mol⁻¹ (ppb)] on C_A, DPR and growth of ambient and hypobaric plants. Declines in C_A and DPR occurred with both exogenous and endogenous ethylene treatments. C_A was more sensitive to increasing ethylene concentration than DPR. There was a direct, negative effect of increasing ethylene concentration reducing gas exchange as well as an indirect ethylene effect on leaf epinasty, which reduced light capture and C_A. While the C_A was comparable, there was a lower DPR in hypobaric than ambient pressure plants – independent of ethylene and under non-limiting CO₂ levels (100 Pa pCO₂, nearly three-fold that in normal air). This research shows that lettuce can be grown under hypobaria (≅25% of normal earth ambient total pressure); however, hypobaria caused no significant reduction of endogenous ethylene production.