Metabolism of gamma-aminobutyric acid during cold acclimation and freezing and its relationship to frost tolerance in barley and wheat

Amino acid homeostasis was investigated in frost-resistant barley seedlings under either cold- or freezing-stress conditions. Total free amino acid content varied only slightly, but a substantial conversion of glutamate to gamma-aminobutyric acid (GABA) was found that was proportional to the severity of the stress. Cold acclimation caused a significant increase in amino acid pools, and induced the expression of the GABA-shunt genes. As a consequence, GABA accumulated to a higher extent during the subsequent exposure to lower temperature. A different picture was obtained with a frost-sensitive genotype, in which glutamate decarboxylation occurred during the stress as well, but the activation of the GABA shunt seemed not to take place, and free glutamate was almost depleted. Analogous results were found in frost-resistant and frost-sensitive wheat cultivars. Feeding non-hardened plants with exogenous glutamate resulted in increased GABA accumulation under low temperature. The possibility that glutamate decarboxylation and GABA metabolism would play a role in frost tolerance is discussed.     

High expression level of a gene coding for a chloroplastic amino acid selective channel protein is correlated to cold acclimation in cereals

A cold-regulated gene (cor tmc-ap3) coding for a putative chloroplastic amino acid selective channel protein was isolated from cold-treated barley leaves combining the differential display and the 5-RACE techniques. Cor tmc-ap3 is expressed at low level under normal growing temperature, and its expression is strongly enhanced after cold treatment. A positive correlation between the expression of cor tmc-ap3 and frost tolerance was found both among barley cultivars and among cereal species. The COR TMC-AP3 protein was expressed in vitro, purified and used to raise a polyclonal antibody. Western analysis showed that the cor tmc-ap3 gene product is localized to the chloroplastic outer envelope fraction, supporting its putative function. The frost-resistant winter cultivar Onice accumulated COR TMC-AP3 more rapidly and at a higher level than the frost-susceptible spring cultivar Gitane. After 28 days of cold acclimation the winter cultivar had about 2-fold more protein than the spring genotype. All these results suggest that an increased amount of a chloroplastic amino acid selective channel protein could be required for cold acclimation in cereals. Hypotheses about the role of COR TMC-AP3 during the hardening process are discussed.     

The role of ABA in freezing tolerance and cold acclimation in barley

The role of ABA in freezing resistance in nonacclimated and cold‐acclimated barley ( Hordeum vulgare L.) was studied. Eleven nonacclimated cultivars differed in their LT₅₀, ranging from −10.8 to −4.8°C. Sugars, free proline, soluble proteins and ABA were analyzed in nonacclimated cultivars and during cold acclimation of one cultivar. There was an inverse correlation between LT₅₀ and both ABA and sucrose contents. Exogenous ABA caused a decrease in the freezing point of leaf tissue in the cultivar with the lowest level of endogenous ABA, but not in the cultivar with the highest level, suggesting that ABA in the latter may be near the optimum endogenous level to induce freezing tolerance. Plants of cv. Aramir treated with ABA or allowed to acclimate to cold temperature increased their soluble sugar content to a similar level. The LT₅₀ of leaves of cold‐acclimated cv. Aramir decreased from −5.8 to −11.4°C, with biphasic kinetics, accumulating proline and soluble sugars with similar kinetics. The biphasic profile observed during cold acclimation could be a direct consequence of cryoprotectant accumulation kinetics. ABA and soluble protein accumulation showed a single step profile, associated mainly with the second phase of the LT₅₀ decrease. Thus, a significant increase in endogenous ABA is part of the response of barley to low temperature and may be required as a signal for the second phase of cold acclimation. Endogenous ABA contents in the nonacclimated state may determine constitutive freezing tolerance.     

Hardening, abscisic acid, proline and freezing resistance in two winter wheat varieties

Two varieties of winter wheat ( Triticum aestivum L.) differing in freezing resistance ("Holme" from Sweden, freezing resistant, and "Amandus" from Germany, less freezing resistant) were hardened for five weeks by gradually reducing the day/night temperature from 20°C/15°C during the first week to 2° C/0° C during the fifth week and the photoperiod from 15 to 9 h. This treatment increased the freezing resistance of both varieties in comparison to unhardened control plants. Hardening caused an increase in osmolarity of cell sap and in the levels of proline and abscisic acid (ABA). Increase in osmolarity preceded the increase in ABA level, and proline levels increased later than ABA levels. Holme had higher values of osmolarity as well as higher levels of ABA and proline. but the differences between the two varieties were significant only for proline. Since the pressure potential remained constant or increased slightly during the hardening period, it is suggested that the accumulation of ABA is due to the hardening process and not to simple water stress caused by cold-induced inhibition of water uptake by the root.
Spraying hardened plants with 10⁻⁴ M ABA 24 h before a freezing test increased freezing resistance in both varieties, but did not obliterate the differences in freezing resistance between the two varieties. Spraying hardened plants with an aqueous proline solution (10%, w/v) was without effect on freezing resistance. It is concluded that the hardening procedure causes an accumulation of ABA in winter wheat leaves and that ABA is involved in the chain of events leading to freezing resistance.     

Profiling the Changes of Molecular Species in Membrane Lipids during Cold acclimation in Winter and Spring Cultivars of Rapeseed (Brassica napus)

The changes of molecular species in membrane lipids during cold acclimation (CA) in winter and spring cultivars of rapeseed (Brassica napus) were profiled with ESI MS/MS based lipidomics. The membrane fluidity, the critical properties for plants to tolerate freeing injuring, was examined with double bond index (DBI) and carbon number of the fatty acid of the glycrolipid. The results indicated that the molecular composition of membrane lipids in the two cultivars under both normal growth condition and CA were similar to that of Arabidopsis reported previously and that DBI in spring cultivar accumulation subtly more than that in winter cultivar. The results suggested that CA of rapeseeds needs more than 3 days and that spring cultivar were more sensitive to CA, which was confirmed by the CA induced proline accumulation.     

Abscisic acid in developing grains of wheat and barley genotypes differing in grain weight

Two genetically related wheat lines growing in cabinets were given different temperatures during grain filling, and abscisic acid (ABA) was measured in whole grains by gas chromatography with an electron-capture detector. Three genetically related barley lines grown in the field were assayed for ABA content in endosperm and embryo fractions separately by radiommunoassay.Maximum grain growth rate and final weight per grain of the two wheat lines differed by 50–60% at low temperature and 30–40% at high temperature. During grain development two peaks in ABA level were observed at low temperature but only one at high temperature. At times when differences in grain growth rate between genotypes and between temperature treatments were large, the corresponding differences in ABA concentration were small. In barley, one line (Iabo 14) had 30% heavier grains than the other two (Onice and Opale). Endosperm ABA concentrations showed no clear differences between genotypes until grain filling was nearly complete. Embryo ABA levels were up to 10-times greater than those in the endosperm, with Opale having significantly less ABA in the embryo than the other two cultivars.Our experiments did not provide evidence for a causal relationship between ABA levels during grain filling and grain growth rate or final weight.Abbreviations ABA Abscisic acid - DAA days after anthesis - DW dry weight - FW fresh weight     

Regulation of salicylic acid, jasmonic acid and fatty acids in cucumber (Cucumis sativus L.) by spermidine promotes plant growth against salt stress

Phytohormones and fatty acids play a significant role in developmental stages of plant growth and defense against biotic and abiotic stresses. The purpose of this study was to determine the spermidine (Spd)-induced phytohormones and fatty acids changes involve the acclimation of cucumber plants against salt stress. Plants exposed to salt stress had significant reduction in their growth. Exogenously applied Spd increased the shoot length and protein content in salt-stressed plants. The accumulation of total phenol and malondialdehyde was higher in salt-affected plants than in their controls and these detrimental effects were mitigated by Spd treatment. Moreover, salt stress caused a significant increase in salicylic acid (SA) and jasmonic acid (JA); while Spd treatment ameliorated these salt stress effects by reducing SA and JA content. The marked accumulation of total free fatty acid was observed in salt-stressed plants, while the application of Spd to salt-stressed plants reduced the total free fatty acid content. In addition, Spd inhibited the stearic acid, linoleic acid and linolenic acid in salt-stressed plants. The results of current study suggest that exogenous application of Spd-induced phytohormones and fatty acids changes would be a reason for increasing the acclimation of cucumber plants under salt stress condition.     

冬油菜和春油菜在冷驯过程中膜脂分子的变化

研究了冬油菜和春油菜两种油菜品种在4℃冷驯3天后11类151种膜脂分子的变化,计算了其中膜脂的相对含量、双键指数和碳链长度值。结果发现油菜膜脂的膜脂分子组成模式及其冷驯诱导的膜脂分子组成变化与前期实验中的拟南芥情况非常相似,冷驯3天诱导的膜脂分子组成变化较小,但是膜脂的双键指数略有升高,春油菜双键指数和冷驯积累的脯氨酸含量都比冬油菜多。上述结果说明,油菜的冷驯需要更多的时间,春油菜对冷驯比较敏感。     

Possible correlation between high temperature-induced floret sterility and endogenous levels of IAA,GAs and ABA in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

In order to explore the possible physiological mechanism of high temperature induced sterility in rice, we examined the floret sterility and endogenous plant growth regulator contents in pollens of two hybrid rice cultivars Shanyou63 and Teyou559 that are tolerant and susceptible to high temperature, respectively. Indexes of floret sterility, pollen activity, and variation of endogenous indole-3-acetic acid (IAA), gibberellic acids (GAs), abscisic acid (ABA), free proline and soluble proteins in anthers were measured. We found that during the course of high temperature treatment, both cultivars exhibited a marked decrease in pollen activity, pollen germination and floret fertility; however, the high temperature tolerant Shanyou63 showed a much slower rate of decrease than the high temperature susceptible Teyou559. In addition, anthers of both cultivars displayed a decrease in the contents of IAA, GAs, free proline and soluble proteins but an increase in the ABA content. Yet compared to Teyou559, Shanyou63 retained significantly higher levels of free praline and GAs and a lower level of ABA, along with higher pollen vigour and pollen germination rate even after prolonged high temperature treatment. Our study suggests a possible correlation between pollen viability/floret sterility and high temperature-caused changes in IAA, GAs, ABA, free proline and soluble protein contents. The severity in these changes may reflect the variation of rice cultivars in their heat stress sensitivities for floret development.     

Efficiency of cold hardiness induction by desiccation stress in four winter cereals

A number of defined desiccation treatments without low temperature exposure were able to induce freezing tolerance in 20 cultivars of winter cereals. A maximal degree of freezing tolerance was induced in epicotyls at 24°C in 24 hours at 40% relative humidity in rye and wheat, 7 days at 54% RH in barley, and 4 days at 70% RH in oats. Freezing tolerance was not correlated to water content of the plants after desiccation treatment but was related to the genetic capacity of the cultivars to frost harden. Levels of freezing tolerance induced by desiccation were similar to those induced by cold acclimation in rye and wheat, but considerably less in barley and oats. This is associated with a more rapid desiccation injury in barley and oats, precluding the completion of the hardening process.     

The content of some amino acids in young apple shoots in relation to frost resistance

In the years 1963–1965 the content of proline, asparagine, glutamic and γ-aminobutyric acids in young apple (Malus cultivars) shoots was studied. Two groups of apple varieties differing in frost resistance were included into experiments: the Yellow Transparent and Oberländer Himbeerapfel varieties as frost-resistant ones and-the Ontario and Reinette du Canada varieties as sensitive to frost. In the course of experiment γ-aminobutyric acid showed a relatively balanced level but glutamic acid, asparagine and especially proline were found in greater amount in the frost-resistant varieties. According to the results of this experiment the amount of proline—along with many other factors—can be considered as one of the indicators of the length of winter dormancy and also of the frost resistance of apple-trees at the beginning of the winter period.     

Atmospheric CO2 enrichment and drought stress modify root exudation of barley

Rising CO₂ concentrations associated with drought stress is likely to influence not only aboveground growth, but also belowground plant processes. Little is known about root exudation being influenced by elements of climate change. Therefore, this study wanted to clarify whether barley root exudation responds to drought and CO₂ enrichment and whether this reaction differs between an old and a recently released malting barley cultivar. Barley plants were grown in pots filled with sand in controlled climate chambers at ambient (380 ppm) or elevated (550 ppm) atmospheric [CO₂] and a normal or reduced water supply. Root exudation patterns were examined at the stem elongation growth stage and when the inflorescences emerged. At both dates, root exudates were analyzed for different compounds such as total free amino acids, proline, potassium, and some phytohormones. Elevated [CO₂] decreased the concentrations in root exudates of some compounds such as total free amino acids, proline, and abscisic acid. Moreover, reduced water supply increased proline, potassium, electric conductivity, and hormone concentrations. In general, the modern cultivar showed higher concentrations of proline and abscisic acid than the old one, but the cultivars responded differentially under elevated CO₂. Plant developmental stage had also an impact on the root exudation patterns of barley. Generally, we observed significant effects of CO₂ enrichment, watering levels, and, to a lesser extent, cultivar on root exudation. However, we did not find any mitigation of the adverse effects of drought by elevated CO₂. Understanding the multitude of relationships within the rhizosphere is an important aspect that has to be taken into consideration in the context of crop performance and carbon balance under conditions of climate change.     

Effect of auxin physiological analogues on rapeseed (Brassica napus) cold hardening, seed yield and quality

The effect of the auxin physiological analogues analogues 1-[2-chloroethoxycarbonylmethyl]-4-naphthalenesulfonic acid calcium salt (TA-12) and 1-[2-dimethylaminoethoxicarbonylmethyl]naphthalene chlormethylate (TA-14) TA-14 on different winter rapeseed cultivars were studied with regard to their autumnal growth, cold hardening, accumulation of the stress-protective metabolites proline and saccharide in plant organs: apical bud and root collum, winter survival and productivity formation. The test cultivars were the very early ‘Libea’ medium-resistant to wintering, the medium-early ‘Sunday’ resistant to wintering, the medium–early ‘Valesca’ less than medium resistant to wintering, and the early ‘Hornet’ (hybrid) tolerant to stress growth conditions. During the period of cold hardening in natural field conditions, the test compounds TA-12 (2 mM) and TA-14 (4 mM), applied to different winter rapeseed cultivars at the 4th–5th leaf stage, stimulate accumulation proline and saccharides (sucrose and glucose) in the root collum and apical bud tissues, influence plants acclimation to cold, overwintering and productivity formation. Compounds TA-12 and especially TA-14 produced a stable effect on seed and crude fat yield in cvs. ‘Hornet’, ‘Sunday’ and ‘Libea’. The genotypic peculiarities of a cultivar and the meteorological conditions of the plant vegetation period were the factors that mostly determined fatty acid content in seed oil.     

Oryzalin-Induced Changes in Water Status and Cytoskeleton Proteins of Winter Wheat Seedlings upon Cold Acclimation and ABA Treatment

The effect of oryzalin (a specific inhibitor of tubulin polymerization in plant cells) on water retention by the leaves and roots of winter wheat (Triticum aestivum L.) seedlings was studied. The cultivars differing in their frost resistance were compared after their acclimation to low temperature (3°C for 3 or 7 days) and after treatment with ABA. In control untreated plants, oryzalin reduced the water-retaining capacity (WRC) of leaves and roots. Both hardening and ABA lowered the effect of the inhibitor on WRC in leaves, whereas their effects on water retention by roots were opposite, i.e., hardening weakened and ABA intensified the effect of oryzalin. Oryzalin-induced reduction of WRC decreased in the following sequence of cultivars: weakly frost resistant moderately frost resistant highly frost resistant. It was more pronounced in the leaves than in the roots, the latter being characterized by the lower WRC and lower frost resistance. After three-day-long hardening of plants, an additive effect of hypothermia and ABA on oryzalin-induced decrease in WRC of leaves and the lack of such effect in the roots were observed. The immunochemical analysis of the composition and content of cytoskeletal proteins with Western blotting showed that in the leaves the actin/tubulin ratio was higher than in the roots. The treatment of nonacclimated plants with ABA lowered the content of - and -tubulins and actin in roots but did not affect the level of actin in leaves. Hardening negated the effects of ABA on cytoskeletal proteins. Oryzalin produced the greatest inhibitory effect on WRC and an increase in frost resistance in ABA-treated plants in the experiments with leaves of the weakly frost resistant cultivar before and after hardening. Organ- and cultivar-specific and ABA-mediated dependence of WRC on cytoskeletal proteins and microtubules and microfilaments formed by them is supposed to result from their effect on the state of intracellular water and water permeability of the plasma membrane. In the course of cold acclimation of plants and upon their treatment with ABA, this dependence was more distinctly expressed in leaves than in roots, and especially in the plants of the weakly frost resistant cultivar.     

葡萄幼苗高温锻炼过程中与水杨酸相关的信号转导的初步研究

对无性繁殖的‘京秀’葡萄（Vitis vinifera cv.Jingxiu）幼苗高温锻炼12 h或外施水杨酸（SA）后12 h发现,两种处理引起葡萄内源ABA含量的变化趋势相似,即在处理后1 h急剧升高,然后又迅速下降,并保持这种低水平到处理结束, 而脂氧合酶（LOX）活性并没有表现出和ABA相似的变化趋势。高温锻炼期间,葡萄叶片内自由态SA含量与ABA变化趋势相似,表现出一种典型的化学信号分子特征。而SA合成的限速酶苯丙氨酸解氨酶（PAL）也表现出和前两者相似的变化趋势。推测SA单独或通过ABA诱导葡萄抗热性。     

Quantification of free and conjugated abscisic acid in five genotypes of barley (Hordeum vulgare L.) under water stress conditions

The goal of the present study was to obtain new insights into the mechanisms underlying drought stress adaptations in barley plants. For this purpose we evaluated changes in endogenous abscisic acid (ABA) and its glucose ester conjugate (ABAGE), as well as changes in proline content, water relations and growth parameters of five barley genotypes with different drought resistance characteristics. Different responses among the five genotypes studied (Ardahoui, Pakistan, Rihane, Manel ad Roho) led to changes in their pattern of growth and development under drought conditions. Water stress induced a reduction in relative water content, as well as an increase in proline content and endogenous ABA concentrations in all tested genotypes. The lack of water led to a 2-fold increase in proline content for var. Rihane and to a 5-fold increase in endogenous ABA for cv. Ardhaoui. Also, increases in endogenous ABAGE in all genotypes except for cv. Ardhaoui were observed. Our results show that changes in ABA and ABAGE correlated with variations in proline content and growth parameters of these genotypes which present different mechanisms to cope with water stress. We also suggest that new regulatory mechanisms implying ABA mobilization can be of great importance in adaptation of barley to drought.     

The change of chlorophyll fluorescence parameters in winter barley during recovery after freezing shock and as affected by cold acclimation and irradiance

The change of chlorophyll fluorescence parameters in froze leaves of 3 leaf-age seedlings were examined using two winter barley cultivars (Chumai 1 and Mo 103) differing in cold tolerance to investigate physiological response to low temperature as affected by cold acclimation (under 3/1 degrees C, day/night for 5 days before freezing treatment) and irradiation size (high irradiance: 380+/-25 micromol m(-2)s(-1) and low irradiance: 60+/-25 micromol m(-2)s(-1)) during recovery. The results showed that non-lethal freezing shock (exposed to -8 degrees C for 18 h) did not obviously affect maximum quantum efficiency in photosystem II (PSII), but dramatically increased non-photochemical quenching and reduced effective quantum yield in PSII. Cold acclimation significantly improved stability of photosynthetic function of leaves after freezing stress through buffering excessive energy and alleviating photoinhibition during recovery, indicating it increased recovery ability of barley plants from freezing injury. High irradiance was quite harmful to the stability of PSII in barley plants during recovery from freezing injury. The electron transport rate of PSII varied with cold-acclimation, irradiance and genotype. Cold acclimation caused significant increase in electron transport rate of PSII for relatively tolerant cultivar Mo 103, but not for relatively sensitive cultivar Chumai 1. It can be concluded that some chlorophyll fluorescence parameters during recovery from freezing shock may be used as the indicators in identification and evaluation of cold tolerance in barley.     

Morphological and physiological changes in roots of various wheat genotypes as related to cytoskeleton disruption

A depolymerizing effect of anti-microtubule drug oryzalin on the roots of three winter wheat (Triticum aestivum L.) cultivars contrasting in their frost-resistance was studied. The influence of plant cold acclimation (3°C, 7 days) and ABA treatment (30 μM) on oryzalin action was evaluated. Plant growing in the presence of 10 μM oryzalin under optimum temperature of 23°C resulted in the root-length decrease by 19–24% and root-apex swelling. All cells, especially in the root cortex, changed their radial dimensions. The cells acquired a rounded or irregular shape and increased in size. This indicates the loss of correct cell growth polarity. Most pronounced changes in the root apex diameter and most severe linear growth suppression were observed in the cultivar of moderate frost-resistance. The roots of this cultivar contained the highest amounts of actin and tubulins, as was evident from the immunoblot analysis. The effect of oryzalin on root growth and apex swelling was correlated with the content of actin in the roots of different wheat cultivars. Cold acclimation and exogenous ABA reduced (or prevented) oryzalin action on roots in a cultivar-specific manner. The conclusion was made that the bulk of the cytoskeletal net determined the efficiency of the cytoskeletal control of plant growth and morphogenesis. During autumn and winter periods, this is important for a better adaptation to temperature fluctuations of moderately frost-resistant plants, which are characterized by a high ecological plasticity.     

Activities of photosystem II and antioxidant enzymes in chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L<Emphasis Type="Italic">.</Emphasis>) cultivars exposed to chilling temperatures

This study was carried out to determine the effect of chilling on both cold-acclimated and non-acclimated chickpea (Cicer arietinum L.) cultivars (Gökçe and Can?tez 87). Chickpea seedlings grown in soil culture for 12 days were subjected to chilling temperatures (2 and 4°C for 12 days) after maintaining in cold-acclimation (10°C, 7 days) or non-acclimation (25°C, 7 days) periods. The lowest values of growth parameters were obtained with cold-acclimated plants, whereas non-acclimated plants exhibited the lowest water content values, especially at 2°C. There was no effect of cold-acclimation period on chlorophyll fluorescence parameters. Plants subjected to chilling temperatures after cold-acclimation were more tolerant with respect to chlorophyll fluorescence parameters, and Gökçe had better photosystem II (PSII) photochemical activity. In the chilling treatments, total chlorophyll (a + b) content reduced, especially at 2°C, while anthocyanin and flavonoid contents increased to a greater extent in Gökçe and carotenoid content of the cultivars did not change. Malondialdehyde (MDA) content was higher for Can?tez 87, mostly at 2°C, while proline accumulation was greater for Gökçe. The cold-acclimation period led to a remarkable increase in antioxidant enzyme activities of both cultivars. The superoxide dismutase (SOD) activity was much higher in Gökçe for both chilling temperatures and the ascorbate peroxidase (APX) activity increased only in the cold-acclimated 4°C treatments. Similarly, with APX activity, the glutathione reductase (GR) and peroxidase (POD) activities of cultivars were higher in cold-acclimated plants at both the chilling temperatures, mostly in Gökçe. The results of this study indicate that cold-acclimation increased the cultivars ability to withstand the chilling temperatures. The lower MDA content and higher antioxidant and photochemical activities in Gökçe indicated an enhanced chilling tolerance capacity of this cultivar to protect the plant from oxidative damage.     

Does abscisic acid influence proline accumulation in stressed leaves?

Root treatments of barley (Hordeum distichum L.) plants with 10^-7 to 10^-4 M abscisic acid (ABA) caused an increase in proline content, especially at higher concentrations, within 2–3 h. Even 3 h after the removal of ABA from the medium the plants continued to accumulate proline. The higher the concentration of the ABA, the higher was the proline level at 6 h. When the highest ABA concentration, 10^-4 M, was tested with polyethylene glycol (PEG) (-5.0 bars) in the medium, the ABA treatment resulted in a higher proline content than in control plants. The treatments PEG alone and PEG + ABA resulted in heavy accumulation of proline, especially, 3 h after releasing the plants from the stress. The proline content in PEG+ABA-treated plants was always higher than plants treated with PGE or ABA alone. In peas (Pisum sativum L. cv Alaska) the same trend occurred although to a lesser degree. These findings indicate an influence of ABA on proline accumulation in water-stressed plants.Abbreviations ABA abscisic acid - PEG polyethylene glycol - RWC relative water content