Changes in adenine nucleotides and energy charge in isolated winter wheat cells during low temperature stress

Adenylate energy charge (AEC) and adenine nucleotide levels of isolated winter wheat (Triticum aestivum L. cv Kharkov 22 MC) cells exposed to various low temperature stresses were determined. During ice encasement at −1°C, nucleotide levels decreased gradually in approximate relation to a decline in cell viability. AEC values remained high even after 5 weeks of icing when cell viability was severely reduced. When isolated cell suspensions were exposed to various cooling and freezing regimes ranging from −10 to −30°C, cell damage was dependent on the minimum temperature imposed and the duration of exposure to the freezing stress. The levels of all three adenine nucleotides declined with increasing severity of the imposed stress, but AEC values remained high even at −30°C when nearly all of the cells were killed. The addition of 10 millimolar Ca²⁺ to cell suspensions enhanced survival during low temperature stresses, but did not influence nucleotide levels other than through its effect on cell viability. These results indicate that impairment of the ion transport system during the early stages of ice encasement prior to a detectable decline in cell viability cannot be attributed to changes in the adenylate energy charge system of the cell.     

Membrane properties of isolated mudpuppy taste cells

The voltage-dependent currents of isolated Necturus lingual cells were studied using the whole-cell configuration of the patch-clamp technique. Nongustatory surface epithelial cells had only passive membrane properties. Small, spherical cells resembling basal cells responded to depolarizing voltage steps with predominantly outward K+ currents. Taste receptor cells generated both outward and inward currents in response to depolarizing voltage steps. Outward K+ currents activated at approximately 0 mV and increased almost linearly with increasing depolarization. The K+ current did not inactivate and was partially Ca++ dependent. One inward current activated at -40 mV, reached a peak at -20 mV, and rapidly inactivated. This transient inward current was blocked by tetrodotoxin (TTX), which indicates that it is an Na+ current. The other inward current activated at 0 mV, peaked at 30 mV, and slowly inactivated. This more sustained inward current had the kinetic and pharmacological properties of a slow Ca++ current. In addition, most taste cells had inwardly rectifying K+ currents. Sour taste stimuli (weak acids) decreased outward K+ currents and slightly reduced inward currents; bitter taste stimuli (quinine) reduced inward currents to a greater extent than outward currents. It is concluded that sour and bitter taste stimuli produce depolarizing receptor potentials, at least in part, by reducing the voltage-dependent K+ conductance.     

Effect of low temperature and calcium on survival and membrane properties of isolated winter wheat cells

Isolated cells obtained by enzymic digestion of young primary leaves of cold-hardened, dark-grown Kharkov winter wheat (Triticum aestivum L.) were exposed to various low temperature stresses. The initial uptake of ⁸⁶Rb was generally decreased by increasing concentrations of Ca²⁺, but after longer periods of incubation, the inhibiting effect of high Ca²⁺ levels diminished. Viability of isolated cells suspended in water declined rapidly when ice encased at −1°C, while in the presence of 10 millimolar Ca²⁺ viability declined only gradually over a 5-week period. Ice encasement markedly reduced ⁸⁶Rb uptake prior to a significant decline in cell viability or increased ion efflux. Cell damage increased progressively when the icing temperature was reduced from −1 to −2 and −3°C, but the presence of Ca²⁺ in the suspending medium reduced injury. Cell viability and ion uptake were reduced to a greater extent following slow cooling than after rapid cooling to subfreezing temperatures ranging from −10 to −30°C. The results from this study support the view that an early change in cellular properties due to prolonged ice encasement at −1°C involves the ion transport system, whereas cooling to lower subfreezing temperatures for only a few hours results in more general membrane damage, including loss of semipermeability of the plasma membrane.     

Studies on the respiratory properties of mitochondria isolated from developing winter wheat seedlings

Mitochondria isolated from shoots of 2 days, light- and dark-grown winter wheat (Triticum aestivum L. cv. Rideau) seedlings oxidize alpha-ketoglutarate and l-malate with good respiratory control and ADP: O ratios. The efficiency of oxidative phosphorylation, and respiratory control are both reduced significantly when succinate or NADH is employed as substrate. Respiratory control values and ADP: O ratios show a general decline in mitochondria from seedlings of increasing age, whether grown in light or dark. In light-grown seedlings, the decrease in respiratory control with aging is due principally to a decrease in the rate of state 3 respiration, while in dark-grown material, the decrease appears to be due mainly to an increased rate of state 4 respiration. In both light- and dark-grown seedlings, oxygen consumption during state 3 respiration is severely inhibited by oligomycin. During state 4 respiration, 2,4-dinitrophenol stimulates oxygen uptake to a level approximately two-thirds the normal ADP-stimulated rate.     

Betaine status in wheat in relation to nitrogen stress and to transient salinity stress

Summary Glycine betaine is readily accumulated in wheat (Triticum aestivum cv. Inia) shoots during periods of salinity stress. The ability of the plant to utilize betaine as a source of nitrogen remains unresolved. We, therefore, conducted solution culture experiments in a greenhouse to test the hypothesis that betaine is degraded in wheat shoots under conditions of severe nitrogen deficiency. Betaine concentrations increased in continuously salt stressed plants for only 17 days after salinity was imposed. After this period, concentrations (dry weight basis) decreased steadily until plants died 32 days later. Decreases in betaine concentration were also observed in treatments where salinity stress was removed. The rate of decrease in concentration was greatest in the N-free treatment. These decreases in betaine concentration were the result of dilution by plant growth. Betaine contents (mol shoot^–1) remained unchanged after removal of substrate nitrate. Therefore our results support the hypothesis that betaine is a stable end product of metabolism.     

Physiological and metabolic responses of winter wheat to prolonged freezing stress

Survival and cold hardiness declined gradually when cold-hardened Fredrick winter wheat (Triticum aestivum L.) was maintained at −6°C for several weeks. Moisture content of crown and root tissue did not change significantly during this period. Uptake of O₂ and accumulation of ⁸⁶Rb by root tissue declined abruptly upon exposure to −6°C, whereas a concomitant negative effect of freezing on these metabolic processes was not observed in crown tissue. Electron spin resonance spectroscopic analysis of microsomal membrane preparations from crown tissue revealed no evidence of gross changes in the physical properties of the bulk lipids even when seedlings were killed. The results provide biochemical evidence that seedling damage due to prolonged exposure to a mild freezing stress is due to disruption of key metabolic process in the root while cells within the crown remain viable.     

Changes in the photosynthetic efficiency of winter wheat in response to abiotic stress

The assessment of heat and drought tolerance is of primary importance in breeding programmes designed to improve heat and drought tolerance in cereals. Three winter wheat varieties grown in controlled growth chambers were exposed to heat (H) and drought (D) stress singly and in combination (H+D). The combined effects of H and D stress were much more severe than those of individual treatments for both physiological and yield parameters during grain filling. The chlorophyll content, effective quantum yield of PSII, net assimilation rate, transpiration, stomatal conductance and intercellular CO₂ concentration were greatly reduced by H, D and their interaction. Grain yield decreased to a greater extent (48.3%) in Plainsman V, averaged over the stress treatments, than in Mv Magma (67.8%) and Fatima 2 (53.7%). The least decline was found in grain number, except in Plainsman V. Mv Magma tolerated heat stress better than Fatima 2. In terms of photosynthetic activity, Plainsman V showed better drought tolerance than Mv Magma. The results showed that changes in physiological properties during stress treatment are not always associated with changes in yield parameters, so a combination of methods may be needed to give a more precise picture of the stress tolerance of wheat varieties.     

Thermal stress evaluation of suspension cell cultures in winter wheat

Summary The objectives of this study were to compare thermotolerance in whole plants vs. suspension cell cultures of winter wheat, and to evaluate the synthesis of heat shock proteins in relation to genotypic differences in thermotolerance in suspension cells. Whole plant genetic differences in the development of heat tolerance were identified for three wheat genotypes (ND 7532, KS 75210 and TAM 101). Suspension cell cultures of these genotypes were used to evaluatein vitro response to heat stress. Viability tests by triphenyl tetrazolium chloride (TTC) and by fluorescein diacetate (FD) were utilized to determine the relationship of cellular response to heat stress (37°C/24 h, 50°C/1h). KS 75210 and ND 7532 are relatively heat susceptible. TAM 101 is heat tolerant. Both tests at the cellular level were similar to the whole plant response. Thus, cellular selection for enhancing heat tolerance seems feasible. Heat shock protein (HSP) synthesis of two genotypes, ND 7532 and TAM 101 were determined for suspension cultured cells. In suspension cultures, HSPs of molecular weight 16 and 17 kD were found to be synthesized at higher levels in the heat tolerant genotype (TAM 101) than the susceptible genotype (ND 7532), both at 34° and 37°C treatments for 2 hours and 5 hours. HSP 22 kD was synthesized more at 34°C for TAM 101 than ND 7532, but not at 37°C; whereas, HSP 33 kD was synthesized at 37°C at similar abundance for both genotypes, but not at 34°C.These results indicated that there is a differential expression of HSP genes in wheat suspension cells at different temperature stress durations and between heat tolerant and heat susceptible genotypes. It appears that the levels of synthesis of HSPs 16 and 17 kD are correlated with genotypic differences in thermal tolerance at the cellular level in two genotypes of wheat.     

Nitrogen stress in wheat — Its measurement and relation to leaf nitrogen

Summary The intensity of nitrogen deficiency in the young wheat plant was measured over a range of 1 to 83 per cent of nitrogen stress. Within these limits of tress relative growth rate of tops fell from 11 to 2 per cent per day.Symptoms of nitrogen deficiency appeared when the stress was greater than 40 per cent.Nitrogen stress in the variety Gabo is calibrated in terms of the concentrations of total nitrogen, soluble nitrogen and free ninhydrin nitrogen of the youngest fully expanded leaf.     

Role of silicon in enhancing resistance to freezing stress in two contrasting winter wheat cultivars

The main objective of this study was to elucidate the roles of silicon (Si) in enhancing tolerance to freezing stress (?5 °C) in two contrasting wheat (Triticum aestivum L.) cultivars: i.e. cv. Yangmai No. 5, a freezing-susceptible cultivar and cv. Linmai No. 2, a freezing-tolerant cultivar. Shoot dry weight of the freezing-susceptible wheat was significantly lower under freezing stress than in controls, but increased significantly with Si amendment. The freezing treatment did not affect shoot dry weight of the freezing-tolerant cultivar. The leaf water content was considerably decreased by freezing stress in the freezing-susceptible cultivar, but was significantly increased by Si amendment. In contrast, freezing treatment did not significantly reduce leaf water content in the freezing-tolerant cultivar and Si played no role in water retention in this cultivar. The concentrations of H₂O₂ and free proline along with malondialdehyde (MDA) were progressively enhanced by freezing stress in the two wheat cultivars used, but were significantly suppressed by amendment with Si. The major antioxidant enzyme activities and non-enzymatic antioxidants (i.e. glutathione and ascorbic acid) in the leaves of freezing-stressed plants were decreased, but were stimulated significantly by the exogenous Si. The possible mechanisms for Si-enhanced freezing stress may be attributed to the higher antioxidant defense activity and lower lipid peroxidation through water retention in leaf tissues.     

甘肃省冬小麦生长发育对暖冬现象的响应

运用甘肃省天水、西峰两地1951-2005年的气温资料及天水、西峰农业气象试验站1981-2003年冬小麦物候观测资料,分析探讨了甘肃冬小麦种植区50多年的冬季气温变暖趋势及冬小麦生长发育过程对气候变暖的响应．结果表明：冬季气温升高对冬小麦生长发育产生了较大影响．在最近20多年,冬小麦越冬死亡率下降到2％以下,越冬天数减少了7～8d,整个生育期缩短8～10d,返青一开花期天数延长7d,这有利于冬小麦生产及气候资源的利用-同时,冬季气温升高及降水减少也使冬小麦产量稳定性变差,麦田病、虫危害发生率增加,给冬小麦的安全生产增加了不确定因素．     

The mechanical behavior of isolated Avena coleoptile walls subjected to constant stress: properties and relation to cell elongation

In order to assess the role of the mechanical properties of the wall in auxin-induced cell elongation, a study has been made of the ability of isolated Avena coleoptile walls to extend (creep) when subjected to a constant applied stress. Creep occurs as a viscoelastic extension which has the following characteristics: the extension is proportional to log time and is partly reversible, and the extension rate has a Q₁₀ of about 1.05 and is markedly greater in auxin-pretreated walls. In nonconditioned walls the extension rate is proportional to applied stress, but pre-extension causes the appearance of an apparent yield strain. The similarity of creep and instantaneous plastic deformation in response to temperature or to pretreatment with auxin or KCN suggests that the instantaneous deformation is simply the viscoelastic extension which occurs at very short times. A comparison of these viscoelastic properties with the properties of auxin-induced cell elongation indicates that cell elongation requires more than just a physical extension of the wall. It is suggested that elongation occurs as a series of extension steps, each of which involves a viscoelastic extension preceded or accompanied by an auxin-dependent biochemical change in the wall properties.     

Abscisic acid-induced secretory proteins in suspension-cultured cells of winter wheat

In suspension-cultured cells of winter wheat (Triticum aestivum L. cv. Chihokukomugi), the accumulation of soluble secretory proteins in the culture medium was promoted by ABA treatment in comparison with non-treated cells. The total amount of secretory proteins in ABA-treated cells was 1.7-fold higher than that in non-treated cells. The analysis of two-dimensional electrophoresis revealed that at least twelve secretory proteins were induced by ABA, and these were named WAS (wheat ABA-induced secretory) proteins 1 to 12. N-terminal amino acid sequence analysis of WAS proteins revealed the sequences of WAS-2 and WAS-3. Homology searches showed that WAS-2 had 55% identity with the N-terminus of the wheat chemically induced gene (WCI-5 gene) product. WAS-3 was also shown to have 93% identity with the N-terminus of the barley protein R, a typical member of thaumatin-like proteins (TLPs). Immunoblot analysis also suggested that WAS-3 was related to protein R. These results suggest that exogenous ABA induces some basic secretory proteins that are related to the plant defense system in wheat.     

Electromechanical effects of menadione on isolated rat heart in relation to oxidative stress

Although Ca2+ overloading has been observed in hepatocytes and in the isolated liver treated with 0.2 mM menadione, it has not been determined if menadione has similar effects on cardiac tissue and, if so, whether Ca2+ overloading leads to cardiac contracture, and if such an event results from plasma membrane peroxidation initiated by oxidative stress. The present study reveals that when the isolated heart is perfused with 0.2 mM menadione for 30 min, it shows Ca2+ overloading, which can not be reversed even after 30 min of drug-free perfusion. The time courses of glutathione, ethane, and LDH release from the hearts do not show a parallel pattern of abnormality between 30 and 60 min, indicating that contractile failure precedes the development of lipid peroxidation or plasma membrane disintegration. The evidence that the plasma membrane of menadione-treated rat cardiac tissue remains intact is supported by the observation that the resting membrane potential of the atrium remains virtually unchanged during the 30 min of drug exposure and then gradually falls (-67 +/- 3.1 vs. -76 +/- 2 mv) only during the last 10 min of the drug washout. Interestingly, even after the atria are treated with menadione for 30 min and followed by washout of 30 min, and have shown calcium overloading, as evidenced by contracture, they are still capable of generating action potentials in response to electrical field stimulation.     

Membrane potentials of vallisneria leaf cells and their relation to photosynthesis

A study has been made of the effects of the inhibitors carbonylcyanide m-chlorophenylhydrazone (CCCP), 3-(3,4-dichlorophenyl)-1,1-dimethyl urea (DCMU), and of anoxia on the light-sensitive membrane potential of Vallisneria leaf cells. The present results are compared with the known effects of these inhibitors on ion transport and photosynthesis (Prins 1974 Ph.D thesis). The membrane potential is composed of a diffusion potential plus an electrogenic component. The electrogenic potential is about −13 millivolts in the dark and −80 millivolts in the light. The inhibitory effect of DCMU and CCCP on the electrogenic mechanisms strongly depends on the light intensity used, the inhibition being less at a higher light intensity. This is of significance in view of the often conflicting results obtained with these inhibitors. With ion transport in Vallisneria the electrogenic pump derives its energy from phosphorylation; however, the process which causes the initial light-induced hyperpolarization and the process that keeps the membrane potential at a steady hyperpolarized state in the light have different energy requirements. The action of photosystem I alone is sufficient to induce the initial hyperpolarization. For continuous operation in the light the activity of photosystem II also is needed.     

Productivity of a doubled haploid winter wheat population under heat stress

Breeding of new winter wheat cultivars with good heat tolerance requires better understanding of the genetic background of heat tolerance. In the present work the effect of heat stress on the 6^th day after heading was investigated in a doubled haploid (DH) population arising from a cross between heat-sensitive (Plainsman V) and heat-tolerant (Mv Magma) cultivars. Averaged over the population, heat stress was found to result in a significant reduction in biomass, grain yield and grain number per plant, and in thousand-kernel weight (TKW) and harvest index. High temperature had the greatest effect on the grain yield, with a drop of 36.2% compared with the control. This could be attributed jointly to significant reductions in the TKW of the main ear and in the grain number of the side tillers. The relationship between the yield parameters was confirmed by the positive correlations obtained for the lines in the population. The diverse levels of heat tolerance in the different lines were confirmed by the significant differences in the reduction in the chlorophyll content (SPAD index) of the flag-leaves and in yield parameters. The changes in yield components in stress condition, however, can be still the most effective tools for heat stress evaluation.     

Observations on the number of cereal aphids on the soil in relation to aphid density in winter wheat

The numbers of cereal aphids on the soil surface was assessed by soil samples and by counting the numbers captured in pitfall traps. A relationship was found by both methods between the density of aphids on the plants and the numbers of aphids on the soil. This relationship indicated that a higher proportion of the aphid population was on the soil surface at the lower densities on the plant. Reasons for this relationship are suggested and discussed.