Differential responses of the enzymes involved in proline biosynthesis and degradation in drought tolerant and sensitive cotton genotypes during drought stress and recovery

The relative water content (RWC), free proline levels and the activities of enzymes involved in proline metabolism were studied in drought tolerant (Ca/H 680) and drought sensitive (Ca/H 148) genotypes of cotton (Gossypium hirsutum L.) during induction of water stress and posterior recovery. Water stress caused a significant increase in proline levels and P5CS activity in leaves of both tolerant and sensitive genotypes, whereas the activity of P5CR increased minimally and the activity of OAT remains unchanged. The activity of PDH decreased under drought stress in both the genotypes. The leaf of tolerant genotype maintained higher RWC, photosynthetic activity and proline levels, as well as higher P5CS and P5CR activities under water stress than that of drought sensitive genotype. The drought induced proline levels and activities of P5CS and P5CR declined and tend to be equal to their respective controls, during recovery, whereas the PDH activity tends to increase. These results indicate that induction of proline levels by up regulation of P5CS and down regulation of PDH may be involved in the development of drought tolerance in cotton.     

An integrative proteome analysis of different seedling organs in tolerant and sensitive wheat cultivars under drought stress and recovery

Roots, leaves, and intermediate sections between roots and leaves (ISRL) of wheat seedlings show different physiological functions at the protein level. We performed the first integrative proteomic analysis of different tissues of the drought‐tolerant wheat cultivar Hanxuan 10 (HX‐10) and drought‐sensitive cultivar Chinese Spring (CS) during a simulated drought and recovery. Differentially expressed proteins (DEPs) in the roots (122), ISRLs (146), and leaves (163) showed significant changes in expression in response to drought stress and recovery. Numerous DEPs associated with cell defense and detoxifications were significantly regulated in roots and ISRLs, while in leaves, DEPs related to photosynthesis showed significant changes in expression. A significantly larger number of DEPs related to stress defense were upregulated in HX‐10 than in CS. Expression of six HSPs potentially related to drought tolerance was significantly upregulated under drought conditions, and these proteins were involved in a complex protein–protein interaction network. Further phosphorylation analysis showed that the phosphorylation levels of HSP60, HSP90, and HOP were upregulated in HX‐10 under drought stress. We present an overview of metabolic pathways in wheat seedlings based on abscisic acid signaling and important protein expression patterns.     

Selection of drought tolerant and sensitive genotypes from wheat DH population

Drought has significant effect on wheat production by decreasing grain yield. Phenotyping the populations is a useful tool for understanding the interactions between phenotype and genotype. 135 doubled haploid (DH) genotypes and their parental varieties Plainsman (Pl) and Cappelle Desprez (CD) were phenotyped in glasshouse under well-watered (WW) and drought-stress (DS) conditions. The response of plant height, heading time, aboveground biomass, grain yield, root dry mass harvest index (HI) under both conditions, and stress tolerance index (STI) and water consumption in WW conditions was studied. We found 20% decrease in the plant growth, 66% decrease in the aboveground biomass, and 77% decrease in the grain yield. Under WW conditions, high water consumption was not related to high yields, STI, and HI. The tolerant and the sensitive genotypes were selected. In the WW and water consumption treatment, the sensitive genotype group had better grain yield performance, but under DS, the tolerant group had higher grain yield. The average yield loss was 59% in the tolerant group compared to the WW treatment, and the sensitive yield loss was 68%. Correlation was found between the grain yield and root dry mass in the tolerant group. There was significant difference between the tolerant and sensitive groups on water consumption, as the sensitive genotypes had higher water need. We found strong positive correlation between the water consumption and the grain yield in the tolerant group. This study showed that the tolerant genotypes had improved water regulating efficiency.     

Hormonal responses to exercise during moderate cold exposure in young vs. middle-age subjects.

The influence of moderate cold exposure on the hormonal responses of atrial natriuretic factor (ANF), arginine vasopressin (AVP), catecholamines, and plasma renin activity (PRA) after exhaustive exercise was studied in 9 young and 10 middle-aged subjects. Exercise tests were randomly performed in temperate (30 degrees C) and cold (10 degrees C) environments. Heart rate, oxygen consumption, and peripheral arterial blood pressure were measured at regular intervals. Blood samples were collected before and immediately after exercise at 30 or 10 degrees C. Plasma sodium and potassium concentrations as well as hemoglobin and hematocrit were measured, and the change in plasma volume was calculated. At rest and during exercise, oxygen consumption was similar during exposure to both temperate and cold temperatures. During submaximal exercise intensities, the rise in heart rate was blunted while the increase in systolic blood pressure was significantly greater at 10 than at 30 degrees C. The increases in plasma sodium and potassium concentrations after exhaustion were similar between environments, as was the decrease in plasma volume. In both groups, all plasma hormones were significantly elevated postexercise, with the AVP response similar at 10 and 30 degrees C. However, the norepinephrine and ANF responses were significantly greater while the PRA response was significantly reduced at 10 degrees C. In the middle-aged subjects the epinephrine response to exercise was higher at 10 than at 30 degrees C. The greater ANF and reduced PRA responses to exercise in the cold may have resulted from central hemodynamic changes caused by cold-induced cutaneous vasoconstriction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of oxalate oxidase and cell death in Al-sensitive and tolerant wheat roots

Several genes including oxalate oxidase (Oxo) are up-regulated in Triticum aestivum L. root tips exposed to Al. To better understand the function of Oxo during Al exposure, the protein level and enzyme activity were measured. The data indicate that both Oxo protein and activity are increased proportionally to the level of root growth inhibition (RGI). A high level of Oxo expression may result in excess H(2)O(2) production which could become toxic and induce cell death. However, the timing of H(2)O(2) production (observed after 24 h) indicates that it cannot be the primary cause of cell death first observed after 8 h. Moreover, at Al concentrations resulting in 50% RGI, we did not observe any cell death in the sensitive cultivar while a punctated pattern of death involving small groups of cells was found in the tolerant cultivar. This pattern was maintained for several days in the tolerant cultivar, suggesting the involvement of a cell death mechanism aimed at replacing epidermal cells intoxicated with Al while root growth is maintained. The accelerated epidermal cell turnover may represent a new detoxification mechanism helping to protect deeper cell layers of the meristematic and elongation zone essential for root growth.     

Metabolic responses of wheat roots to alkaline stress

Aims The aim of this study was to investigate the effects of alkaline stress on primary, secondary metabolites and metabolic pathways in the roots of wheat (Triticum aestivum). The results were used to evaluate the physiological adaptive mechanisms by which wheat tolerated alkali stress.Methods A pot experiment was carried out in the greenhouse. For each plastic pot, five wheat seeds were planted. After germination, seedlings were allowed to grow under controlled water and nutrient conditions for two months, then seedlings were exposed to alkaline stress (NaHCO₃-Na₂CO₃) for 12 days. The relative growth rate (RGR), absolute water content (AWC), metal elements, free cations and metabolites were measured.Important findings The alkaline stress caused the reduction of RGR and AWC. Alkaline stress caused a rapid increase of Na content with the concurrent decrease in K and Cl content, resulting in inhibited metal element accumulation and an ionic imbalance. In the present study, alkaline stress strongly enhanced Ca accumulation in wheat roots, suggesting that an increased Ca concentration can immediately trigger the salt overly sensitive (SOS)-Na exclusion system and reduce Na-associated injuries. Also, 70 metabolites, including organic acids, amino acids, sugars/polyols and others, behaved differently in the alkaline stress treatments according to a GC-MS analysis. The metabolic profiles of wheat were closely associated with alkaline-stress conditions. Alkaline stress caused the accumulation of organic acids, accompanied by the depletion of sugars/polyols and amino acids. Organic acids could play a central role in the regulation of intracellular pH by accumulating vacuoles to neutralize excess cations. Glycolysis and amino acid synthesis in roots were inhibited under salt stress while prolonged alkaline stress led to a progressive tricarboxylic acid (TCA) cycle. The severe negative effects of alkaline stress on sugar synthesis and storage may reflect the toxic levels of Na⁺ accumulating in plant cells in a high-pH environment, implying that the reactive oxygen species detoxification capacity was diminished by the high pH. A lack of NO₃^- in wheat roots can decrease synthase enzyme activities, limiting the synthesis of amino acids. Under salt stress, the TCA cycle and organic acid accumulation increased, but glycolysis and amino acid synthesis were inhibited in roots. Thus, energy levels and high concentrations of organic acids may be the key adaptive mechanisms by which wheat seedlings maintain their intracellular ion balance under alkaline stress.     

Rubisco and some chaperone protein responses to water stress and rewatering at early seedling growth of drought sensitive and tolerant wheat varieties

Four wheat varieties differing in their drought tolerance were subjected to severe but recoverable water stress at seedling stage. Growth parameters, leaf water deficit (WD) and electrolyte leakage (EL) were used to evaluate the stress intensity and the extent of recovery. The physiological response of the varieties was quite similar under severe drought. Leaf protein patterns and levels of some individual proteins relevant to ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) maintenance were studied in control, stressed and recovering plants by electrophoresis and immunoblotting. The bands representing Rubisco large subunit (RLS), N- and C-terminus of RLS, Rubisco activase (RA) and Rubisco binding protein (RBP, cpn 60), as well as the chaperone and proteolytic subunits of the Clp protease complex were identified using polyclonal antibodies. Under drought conditions RLS, Clp proteases and especially RBP were enhanced, whereas the RA band was only slightly affected. The drought tolerant varieties had higher RBP content in the controls and drought treated plants. Its concentration could be a potential marker for drought tolerance.     

Several lanthanides activate malate efflux from roots of aluminium‐tolerant wheat

Many elements of the lanthanide series exist as trivalent cations in solution below pH 6. The present study was carried out to investigate whether lanthanides could stimulate malate efflux from wheat (Triticum aestivum L.) roots, as has been found for trivalent aluminium (Al) cations. Excised root apices treated with 100 µm of each of seven different lanthanide elements (lanthanum, praseodymium, europium, gadolinium, terbium, erbium, and ytterbium) stimulated malate efflux, with five‐ to fifty‐fold more malate being released from an Al‐tolerant wheat line than from a near‐isogenic Al‐sensitive line. As erbium stimulated the greatest malate efflux of the lanthanides tested, this response was characterized further. The characteristics of the erbium‐activated efflux were similar to the Al‐activated efflux described previously suggesting that both of these ions activate the same transport mechanism. The capacity for erbium‐activated malate efflux cosegregated with Al tolerance in wheat seedlings derived from a cross between Al‐sensitive and Al‐tolerant near‐isogenic lines. This is the first study to identify cations, other than Al, which can activate malate release from wheat roots. It also provides additional evidence that malate efflux from root apices is the primary mechanism for Al tolerance in wheat.     

Glycerol hyperhydration: physiological responses during cold-air exposure.

Hypohydration occurs during cold-air exposure (CAE) through combined effects of reduced fluid intake and increased fluid losses. Because hypohydration is associated with reduced physical performance, strategies for maintaining hydration during CAE are important. Glycerol ingestion (GI) can induce hyperhydration in hot and temperate environments, resulting in greater fluid retention compared with water (WI) alone, but it is not effective during cold-water immersion. Water immersion induces a greater natriuresis and diuresis than cold exposure; therefore, whether GI might be effective for hyperhydration during CAE remains unknown. This study examined physiological responses, i.e., thermoregulatory, cardiovascular, renal, vascular fluid, and fluid-regulating hormonal responses, to GI in seven men during 4 h CAE (15 degrees C, 30% relative humidity). Subjects completed three separate, double-blind, and counterbalanced trials including WI (37 ml water/l total body water), GI (37 ml water/l total body water plus 1.5 g glycerol/l total body water), and no fluid. Fluids were ingested 30 min before CAE. Thermoregulatory responses to cold were similar during each trial. Urine flow rates were higher (P = 0.0001) with WI (peak 11.8 ml/min, SD 1.9) than GI (5.0 ml/min, SD 1.8), and fluid retention was greater (P = 0.0001) with GI (34%, SD 7) than WI (18%, SD 5) at the end of CAE. Differences in urine flow rate and fluid retention were the result of a greater free water clearance with WI. These data indicate glycerol can be an effective hyperhydrating agent during CAE.     

Changes during aerobic exposure of wheat silages

Aerobic stability is an important characteristic of silages because they are exposed to air during storage and feedout. The objective of the current study was to investigate changes that occur in wheat silages during aerobic exposure. Silages of whole crop wheat harvested at the flowering, milk and dough stages of maturity were prepared in 1.5 L anaerobic glass jars. Three months after ensiling, silages were subjected to a 7-day aerobic stability test. The silages of wheat harvested at the flowering stage were the most stable upon aerobic exposure, but had the largest fermentation losses. Silages of milk-stage wheat were unstable upon aerobic exposure, and had large amounts of CO₂ and heating, large yeast populations, decreased amounts of fermentation products and decreased dry matter (DM) and neutral detergent fiber (NDF) digestibility (from 667 to 572 g/kg DM and from 597 to 558 g/kg DM, following 7-day aerobic exposure, respectively). Silages of dough-stage wheat had relatively low fermentation losses and were quite stable for at least 4 days of aerobic exposure. Silage samples from the center of commercial bunker silos, and from areas adjacent to the walls of the silos, were judged to be of good quality. Samples from the shoulders of bunker silos were spoiled with higher pH (P<0.05), higher ash content and lower DM and NDF digestibility compared with samples from the center of the silos and areas near the walls (6.8 vs. 4.0, 19.0 vs. 7.8, 477 g/kg DM vs. 634 g/kg DM and 230 g/kg DM vs. 487 g/kg DM, respectively).     

Nitrogen nutrition influences some biochemical responses to iron deficiency in tolerant and sensitive genotypes of Vitis

The effects of nitrogen source on iron deficiency responses were investigated in two Vitis genotypes, one tolerant to limestone chlorosis Cabernet Sauvignon (Vitis vinifera cv.) and the other susceptible Gloire de Montpellier (Vitis riparia cv.). Plants were grown with or without Fe(III)-EDTA, and with NO₃⁻ alone or a mixture of NO₃⁻ and NH₄⁺. Changes in pH of the nutrient solution and root ferric chelate reductase (FC-R) activity were monitored over one week. We carried out quantitative metabolic profiling (¹H-NMR) and determined the activity of enzymes involved in organic acid metabolism in root tips. In iron free-solutions, with NO₃⁻ as the sole nitrogen source, the typical Fe-deficiency response reactions as acidification of the growth medium and enhanced FC-R activity in the roots were observed only in the tolerant genotype. Under the same nutritional conditions, organic acid accumulation (mainly citrate and malate) was found for both genotypes. In the presence of NH4⁺, the sensitive genotype displayed some decrease in pH of the growth medium and an increase in FC-R activity. For both genotypes, the presence of NH₄⁺ ions decreased significantly the organic acid content of roots. Both Vitis genotypes were able to take up NH₄⁺ from the nutrient solution, regardless of their sensitivity to iron deficiency. The presence of N-NH₄⁺ modified typical Fe stress responses in tolerant and sensitive Vitis genotypes.     

Aluminium and calcium transport interactions in intact roots and root plasmalemma vesicles from aluminium-sensitive and tolerant wheat cultivars

Recent research from our laboratory indicates that aluminium (Al) and calcium (Ca) transport interactions may play an important role in the mechanisms of Al phytotoxicity. In this study, we investigated the effects of Al on Ca²⁺ transport in intact roots of winter wheat (Triticum aestivum L.) cultivars (Al-tolerant Atlas 66 and Al-sensitive Scout 66). We used both a vibrating Ca²⁺-microelectrode technique and ⁴⁵Ca²⁺ to monitor Ca²⁺ influx in intact roots. Root apical Ca²⁺ uptake was immediately inhibited, when roots were exposed to Al levels that ultimately decreased root growth in Al-sensitive Scout 66. The Al-tolerant cultivar was able to resist this Al inhibition of Ca²⁺ uptake, and to resist Al inhibition of ⁴⁵Ca²⁺ translocation from roots to shoots. We also studied Ca²⁺ transport in right-side out plasmalemma vesicles isolated from roots of Al-sensitive and tolerant wheat cultivars. Calcium influx into the vesicles was mediated by a voltage-gated Ca²⁺ channel. Aluminium blocks the Ca²⁺ channel equally well in the plasmalemma vesicles isolated from Al-sensitive and Al-tolerant wheat roots. The results indicate that the differential response observed in intact roots is not due to differences in Ca²⁺ channels. The Al-tolerant wheat cultivar may have an ability to reduce Al³⁺ activity in the rhizosphere, thus reducing the Al-inhibition of Ca²⁺ influx.     

Defense responses of soybean roots during exposure to cadmium, excess of nitrogen supply and combinations of these stressors

Heavy metal pollution is a serious environmental problem in agricultural soils since the uptake of heavy metals by plants represents an entry point into the food chain and is influenced by the form and amount of nitrogen (N) fertilization. Here we studied the defense responses in soybean roots exposed to ions of cadmium (applied as 50?mg?l^?1 Cd²⁺) when combined with an excessive dose of N in form of NH₄NO₃. Our data indicate that despite of stunted root growth, several stress symptoms typically observed upon cadmium treatment, e.g. peroxidation of lipid membranes or activation of chitinase isoforms, become suppressed at highly excessive N. At the same time, other defense mechanisms such as catalases and proline accumulation were elevated. Most importantly, the interplay of ongoing responses resulted in a decreased uptake of the metal into the root tissue. This report points to the complexity of plant defense responses under conditions of heavy metal pollution combined with intensive fertilization in agriculture.     

Metabolic response of roots to osmotic stress in sensitive and tolerant cereals--qualitative in vivo [31P] nuclear magnetic resonance study.

High resolution [31P] nuclear magnetic resonance (NMR) spectroscopy was used to investigate the changes in phosphate metabolism and intracellular pH in intact root segments of relatively osmotic stress sensitive species maize (Zea mays L) and insensitive species pearl millet (Pennisetron americanum (L) Leeke) exposed to hyper osmotic shock. The results were used to understand the adaptive mechanism of the two species. The hyper osmotic shock resulted in large build-up of phosphocholine and decrease in glucose 6-phosphate (G-6P) and UDPG levels in both the crops. The osmotic shock produced a large vacuolar alkalinization and decrease in pH across tonoplast membrane in maize roots. However, the roots of pearl millet were able to adapt to the stress and maintained pH gradient across tonoplast with marginal vacuolar alkalinization. This may be attributed to the sustained activity of primary tonoplast pumps and increased activity of H+-ATPase that normally maintain pH gradient across tonoplast.     

Cadmium tolerant and sensitive wheat lines: their differences in pollutant accumulation,cell damage,and autophagy

Cadmium (Cd) is a major abiotic stressor that affects plant growth and reduces the productivity of field crops. Here, we examined the ultrastructural, physiological, and molecular changes in three wheat cultivars [Sumai 3, Jingdong 8 (JD 8), and Nannong 9918 (9918)] in response to different concentrations of Cd (0, 10, 50, and 100 μM) in 1/4 Hoagland nutrient solution. The results showed that JD 8 contained the lowest shoot Cd content and the highest root Cd content among the three cultivars at higher Cd concentrations and so JD 8 was proposed to be a relatively Cd-tolerant cultivar. Next, the stress responses of JD 8 and 9918 were compared. Cadmium reduced root growth and size and number of the leaves, inhibited root hair development, and promoted leaf cell death. The result of trypan blue staining showed that the dead leaf cells induced by Cd stress gradually emerged in the xylem, supporting the hypothesis that cell death could restrict Cd transport. The Cd-induced deterioration of the leaf ultrastructure led to the complete disorganization of the chloroplasts, which had lower amounts of transitory starch and an increased number of osmiophilic granules compared to those in the untreated controls. Autophagy-related genes and autophagy in the leaves were induced by Cd stress. At the same concentration and Cd treatment time, the Cd-tolerant genotype JD 8 exhibited less toxic symptoms compared to the Cd-sensitive genotype 9918. The results of this study provide insights into the ultrastructural and physiological damages induced by Cd stress, which may help in selecting Cd-tolerant wheat cultivars.     

Energy metabolism in wheat roots during modification of cell surface

A study was made of dynamics of wheat production, intensity of respiration and changes in bioelectric characteristics of exised roots. Response reactions of two wheat varieties were compared in the process of adaptive reactions. The varieties differed in bioelectric characteristics of root cells in intact seedlings grown in CaCl2 and EDTA containing media. Different changes of membrane characteristics of root cells were observed: in soft wheat MP and Rin increased, but in hard wheat these decreased after a 5 h incubation of excised root. The rate of heat production was at the same level in both wheat varieties, but oxygen absorption of the root cells was lower in hard wheat compared with soft wheat. The rate of respiration of excised roots was stable in EDTA-containing medium. The obtained data allow to discuss more in detail the role of Ca(2+)-ions in the regulation of cell functions under formation of adaptive processes as the tissue level.     

The response of sensitive and tolerant clones of Populus tremuloides to dynamic ozone exposure under controlled environmental conditions

Both sensitive and tolerant clones of aspen ( Populus tremuloides ) were exposed to ozone using four different exposure regimes under controlled environmental conditions. Based on data on ambient ozone from 10 cities in the USA, three treatments of 4-wk exposure to the same SUM06 (an accumulation of hourly O₃ concentrations greater than 0.06 ml l⁻¹) were constructed. The regimes allowed us to investigate: (a) the importance of long (3 wk, treatment 1) versus short (1 wk, treatment 2) duration of regimes with high peaks; (b) the effect of treatments with variable peak occurrence (treatments 1 and 2) versus uniform peak occurrence (treatment 3) during the exposure period. Nonfumigated control plants were maintained at ozone concentrations <10 nl l⁻¹. Bifacial black necrosis, a typical symptom of ozone injury on aspen leaves, occurred on both clones after 2 wk exposure. Up to 60% of the leaves on the sensitive clone were injured, with an average of 6% of total leaf area injured. In the tolerant clone only 10% of the leaves were injured, with less than 1% of the total leaf area symptomatic. The severity of injury was consistently greatest in treatment 2, followed by treatments 1 and 3, respectively. The interval between peak exposures was less important than the occurrence of peaks versus a stable maximum concentration. Premature leaf abscission occurred in the sensitive clone. Measures of gas exchange demonstrated reduced photosynthesis under ozone fumigation, but exposure regime was not a significant factor. Concentrations of two antioxidants, ascorbic acid and glutathione, were almost always greater in the resistant than in the sensitive clone, but the differences were not statistically significant. The levels of these antioxidants in aspen leaves did not change with ozone fumigation or leaf age.     

Antioxidant responses to water deficit by drought‐tolerant and ‐sensitive sugarcane varieties

Water deficit is the major yield‐limiting factor of crop plants. The exposure of plants to this abiotic stress can result in oxidative damage due to the overproduction of reactive oxygen species. The aim of this work was to study the antioxidant‐stress response of drought‐tolerant (SP83‐2847 and SP83‐5073) and drought‐sensitive (SP90‐3414 and SP90‐1638) sugarcane varieties to water‐deficit stress, which was imposed by withholding irrigation for 3, 10 and 20 days. The drought‐sensitive varieties exhibited the lowest leaf relative water content and highest lipid peroxidation, hydrogen peroxide (H₂O₂) and proline contents during the progression of the drought‐stress condition. The antioxidant enzymes superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX), guaiacol peroxidase (GPOX) and glutathione reductase (GR) activities changed according to variety and stress intensity. SP83‐2847 exhibited higher CAT and APX activities than the other varieties in the early stage of drought, while the activities of GPOX and GR were the highest in the other varieties at the end of the drought‐stress period. A Cu/Zn SOD isoenzyme was absent at the end of drought period from the SP90‐3414‐sensitive variety. The results indicate that lipid peroxidation and early accumulation of proline may be good biochemical markers of drought sensitivity in sugarcane.