Cell-wall lectins during winter wheat cold hardening

The polypeptide composition and functional activity of cell-wall lectins from roots of winter wheat (Triticum aestivum L., cv. Mironovskaya 808) seedlings during cold hardening were studied. Several phases of lectin activity changes were observed, which indicates their involvement in the development of general adaptation syndrome of the cell. After 0.5-h low-temperature treatment, marked alterations occurred in the profile of protein elution: lectins with mol wts of 78 and 42.5 kD disappeared and new ones with mol wts of 72, 69, 37, and 34.5 kD appeared. It was established that 17.5-and 69-kD lectins and most lectins eluted with glucose were arabinogalactan proteins (AGP), which permitted a supposition that these lectins were involved in the interaction between the cell wall and cytoskeleton. After 7-day-long hardening, total protein content reduced and lectins with mol wts of 69 and 37 kD disappeared, which corresponded to reduced lectin activity by the end of hardening. A transient appearance of 37-and 69-kD lectins, which are AGP, might indicate their involvement in the triggering the development of plant-cell defense responses.     

Genetic study of glutathione accumulation during cold hardening in wheat

The effect of cold hardening on the accumulation of glutathione (GSH) and its precursors was studied in the shoots and roots of wheat (Triticum aestivum L.) cv. Cheyenne (Ch, frost-tolerant) and cv. Chinese Spring (CS, moderately frost-sensitive), in a T. spelta L. accession (Tsp, frost-sensitive) and in chro- mosome substitution lines CS (Ch 5A) and CS (Tsp 5A). The fast induction of total glutathione accumulation was detected during the first 3 d of hardening in the shoots, especially in the frost-tolerant Ch and CS (Ch 5A). This observation was corroborated by the study of de novo GSH synthesis using [³⁵S]sulfate. In Ch and CS (Ch 5A) the total cysteine, γ-glutamylcysteine (precursors of GSH), hydroxymethylglutathione and GSH contents were greater during the 51-d treatment than in the sensitive genotypes. After 35 d hardening, when the maximum frost tolerance was observed, greater ratios of reduced to oxidised hydroxymethylglutathione and glutathione were detected in Ch and CS (Ch 5A) compared to the sensitive genotypes. A correspondingly greater glutathione reductase (EC 1.6.4.2) activity was also found in Ch and CS (Ch 5A). It can be assumed that chromosome 5A of wheat has an influence on GSH accumulation and on the ratio of reduced to oxidised glutathione as part of a complex regulatory function during hardening. Consequently, GSH may contribute to the enhancement of frost tolerance in wheat. Received: 24 March 1999 / Accepted: 19 July 1999     

Effect of light on the gene expression and hormonal status of winter and spring wheat plants during cold hardening

The effect of light on gene expression and hormonal status during the development of freezing tolerance was studied in winter wheat (Triticum aestivum var. Mv Emese) and in the spring wheat variety Nadro. Ten-day-old plants (3-leaf stage) were cold hardened at 5°C for 12 days under either normal (250 μmol m(-2) s(-1) ) or low (20 μmol m(-2) s(-1) ) light conditions. Comprehensive analysis was carried out to explore the background of frost tolerance and the differences between these wheat varieties. Global genome analysis was performed, enquiring about the details of the cold signaling pathways. The expression level of a large number of genes is affected by light, and this effect may differ in different wheat genotypes. Photosynthesis-related processes probably play a key role in the enhancement of freezing tolerance; however, there are several other genes whose induction is light-dependent, so either there is cross-talk between signaling of chloroplast originating and other protective mechanisms or there are other light sensors that transduce signals to the components responsible for stress tolerance. Changes in the level of both plant hormones (indole-3-acetic acid, cytokinins, nitric oxide and ethylene precursor 1-aminocyclopropane-1-carboxylic acid) and other stress-related protective substances (proline, phenolics) were investigated during the phases of the hardening period. Hormonal levels were also affected by light and their dynamics indicate that wheat plants try to keep growing during the cold-hardening period. The data from this experiment may provide a new insight into the cross talk between cold and light signaling in wheat.     

Properties of chloroplast membrane-bound ferredoxin--NADP + reductase during cold hardening of wheat. No indication of qualitative membrane changes during cold hardening

Kinetic parameters of the chloroplastbound ferredoxin-NADP⁺ reductase from two varieties of wheat (Triticum aestivum), hardy Kharkov 22 MC (winter wheat) and less hardy Rescue (spring wheat), were followed during induction of frost hardiness as a means of examining possible changes in chloroplast membranes during hardening. No changes were found in the Michaelis constants for NADPH and 2,6-dichlorophenol indophenol, inhibition constants for p-chloromercuriphenylsulfonate, and activation energy values of the enzyme in either variety. The data suggest that no qualitative changes occurred in the properties of wheat chloroplast membranes related to ferredoxin-NADP⁺ reductase during cold hardening.     

Antioxidant function of alternative oxidase in mitochondria of winter wheat during cold hardening

The activity of alternative oxidase (AOX) and generation of reactive oxygen species (ROS) in mitochondria of winter wheat Triticum aestivum L. isolated from seedlings subjected to one (7-day exposure to 2–3°C) and two (7-day exposure to 2–3°C and 2-day exposure to −2°C) phases of a cold hardening has been studied. The antioxidant role of AOX in the first phase of the cold hardening has been determined using inhibitors of respiratory chain. Exposure to low temperature was shown to lead to inhibition of cytochrome pathway in mitochondria, increase of ROS production, and switching of the electron transport to the alternative pathway. Decrease in succinate- and antimycin A-induced ROS generation was found during two phases of cold hardening. This fact may point out to functioning of uncoupling proteins under these conditions. Thus, antioxidant function of AOX during the first phase of cold hardening may be an important component of the cold adaptation mechanism in winter crops. The data suggest that ROS and free fatty acids may be signal molecules regulating the activity of two energy-dissipation systems (AOX and uncoupling proteins).     

Regulation of a wheat actin-depolymerizing factor during cold acclimation

We have previously shown that the wheat (Triticum aestivum) TaADF gene expression level is correlated with the plants capacity to tolerate freezing. Sequence analysis revealed that this gene encodes a protein homologous to members of the actin-depolymerizing factor (ADF)/cofilin family. We report here on the characterization of the recombinant TaADF protein. Assays for ADF activity showed that TaADF is capable of sequestering actin, preventing nucleotide exchange, and inducing actin depolymerization. In vitro phosphorylation studies showed that TaADF is a substrate for a wheat 52-kD kinase. The activity of this kinase is modulated by low temperature during the acclimation period. Western-blot analyses revealed that TaADF is expressed only in cold-acclimated Gramineae species and that the accumulation level is much higher in the freezing-tolerant wheat cultivars compared with the less tolerant ones. This accumulation was found to be regulated by a factor(s) encoded by a gene(s) located on chromosome 5A, the chromosome most often found to be associated with cold hardiness. The induction of an active ADF during cold acclimation and the correlation with an increased freezing tolerance suggest that the protein may be required for the cytoskeletal rearrangements that may occur upon low temperature exposure. These remodelings might be important for the enhancement of freezing tolerance.     

Changes in the level of MACC during cold hardening and dehardening in winter wheat

Changes in the level of 1-(malonylamino)-cyclopropane-1-carboxylic acid (MACC) were determined in 6 winter wheat cultivars during cold hardening at 4°C. The cultivars differed by one degree of frost resistance within the range of degree II to VII of the COMECON scale. The time-course of changes in MACC level showed a similar pattern in all 6 cultivars; i.e. increase till day 6, no changes for the next 10 days, and then a steady decrease till the end of the hardening period. There was little difference between the final and the initial levels. The increase of MACC level, expressed as per cent of the original level, was not directly correlated with either the degree of frost resistance of the actual percentage of survival. In some cultivars. mean errors exceeded the difference in MACC accumulation between cultivars closest on the resistance scale.
The fate of MACC during the second half of hardening and after transfer of plants to 25°C was studied in cultivars Bezostaya and San Pastore. During the second half of the hardening period the level of MACC decreased in the leaves of both cultivars, but increased significantly in the roots. Within two days of transfer of the hardened plants to 25°C, the MACC level in leaves increased again, while that in the roots decreased. This finding, together with the preliminary evidence of very low MACC metabolism, strongly suggest that MACC accumulates in roots during the hardening period and when transferred to 25°C, it moves from roots to leaves.     

Differential expression of wheat genes during cold acclimation

Overwintering crops such as winter wheat display significant increase in freezing tolerance during a period of cold acclimation (CA). To gain better understanding of molecular mechanisms of CA, it is important to unravel functions and regulations of CA-associated genes. Differential screening of a cDNA library constructed from cold acclimated crown tissue of winter wheat identified three novel CA-associated cDNA clones. Nucleotide sequence analysis showed that the clones encode a high mobility globular protein (HMGB1), a glycine-rich RNA-binding protein (TaGRP2), and a LEA D-11 dehydrin (DHN14). Accumulation of the three mRNAs during 14 days of CA was differentially regulated. In response to drought, and ABA, DHN14 mRNA rapidly accumulated while HMGB1 and TaGRP2 mRNA levels remained unchanged. The possible functions of each of these genes in cold acclimation are discussed.     

Differential expression of wheat genes during cold acclimation

Overwintering crops such as winter wheat display a significant increase in freezing tolerance during periods of cold acclimation (CA). To gain a better understanding of the molecular mechanisms of CA, it is important to unravel the functions and regulations of CA-associated genes. Differential screening of a cDNA library constructed from cold acclimated crown tissue of winter wheat identified three novel CA-associated cDNA clones. Nucleotide sequence analysis showed that the clones encode a high mobility globular protein (HMGB1), a glycine-rich RNA-binding protein (TaGRP2), and a LEAD-11 dehydrin (DHN14). Accumulation of the three mRNAs during 14 days of CA was differentially regulated. In response to drought, and ABA, DHN14 mRNA rapidly accumulated while HMGB1 and TaGRP2 mRNA levels remained unchanged. The possible functions of each of these genes in cold acclimation are discussed. The text was submitted by the authors in English.     

Changes in the fatty acid unsaturation after hardening in wheat chromosome substitution lines with different cold tolerance

Two wheat (Triticum aestivum L.) varieties, Cheyenne (Ch, winter wheat with excellent frost tolerance) and Chinese Spring (CS, spring wheat with weak frost tolerance), and chromosome substitution lines (CS/Ch 5A, CS/Ch 5D, CS/Ch 7A) created from Cheyenne and Chinese Spring were used to study the effect of chromosome substitutions on the membrane lipid composition in the leaves and crowns before and after cold hardening. The percentage of fatty acid unsaturation in phosphatidylethanolamine was greater in the crown of hardened Cheyenne than in Chinese Spring. The value of CS/Ch 5A was similar to Cheyenne and that of CS/Ch 5D to Chinese Spring, while the value of CS/Ch 7A was in between those of Cheyenne and Chinese Spring. A smaller difference was found between the unsaturation level in the phosphatidylcholine from Cheyenne and Chinese Spring after hardening, while the value obtained for the substitution line CS/Ch 7A was similar to Cheyenne. The percentage decrease in thetrans-Δ³-hexadecenoic acid content was found to be correlated with the frost tolerance of the wheat genotypes.     

Gene expression during cold and heat shock in wheat

Translatable messenger RNAs expression was compared in cold- and heat-stressed winter wheat (Triticum aestivum L. 'Fredrick' and 'Norstar') and spring wheat (T. aestivum L. 'Glenlea'). Polyadenylated RNA isolated from the crown and leaf tissues was translated in a wheat germ cell free system and the acidic and basic in vitro products were resolved by two-dimensional SDS-PAGE and autoradiography. The results showed that low temperature stress rapidly induced two groups of mRNAs. The first group was transient in nature and consists of 18 mRNAs that reached their highest levels of induction after 24 h of low temperature exposure and then decreased to undetectable levels. The second group consists of 53 mRNAs that were also induced or increased rapidly, but maintained their levels of expression during the 4 weeks required to induce freezing tolerance. Among those, at least 34 were expressed at higher levels in the freezing tolerant winter wheat compared with the less tolerant spring wheat. This suggests a possible relation between the expression of these mRNAs and the capacity of each genotype to develop freezing tolerance. In the case of heat shock, 50 mRNAs were induced or increased after 3 h at 40 degrees C. Among these, the expression of only six mRNAs was altered in a similar manner in the three genotypes by both treatments. The remaining mRNAs code for typical heat shock proteins which are different from those induced by low temperature. None of these mRNAs has been associated with the development of freezing tolerance. These results suggest that heat and cold stress are controlled by different genetic systems.     

Non-invasive monitoring of the light-induced cyclic photosynthetic electron flow during cold hardening in wheat leaves

The effect of irradiance during low temperature hardening was studied in a winter wheat variety. Ten-day-old winter wheat plants were cold-hardened at 5 degrees C for 11 days under light (250 micromol m(-2) S(-1)) or dark (20 micromol m(-2) s(-1)) conditions. The effectiveness of hardening was significantly lower in the dark, in spite of a slight decrease in the Fv/Fm chlorophyll fluorescence induction parameter, indicating the occurrence of photoinhibition during the hardening period in the light. Hardening in the light caused a downshift in the far-red induced AG (afterglow) thermoluminescence band. The faster dark re-reduction of P700+, monitored by 820-nm absorbance, could also be observed in these plants. These results suggest that the induction of cyclic photosynthetic electron flow may also contribute to the advantage of frost hardening under light conditions in wheat plants.     

The alpha-tubulin gene family in wheat (Triticum aestivum L.) and differential gene expression during cold acclimation.

The alpha-tubulins and beta-tubulins are the major constituents of microtubules, which have been recognized as important structural elements in cell growth and morphogenesis, and, recently, for their role in regulation and signal transduction. We have identified 15 full-length cDNAs for the members of the alpha-tubulin gene family in hexaploid bread wheat (Triticum aestivum L.). The genes were clustered into 5 homeologous groups of 3 genes. Representatives of the 5 homeologous groups were mapped to different chromosome arms, and the genome of origin was determined for each gene. Changes in mRNA levels were observed for the paralogous members of the gene family during cold acclimation. Three members of the family had initial decreases in mRNA levels in response to cold treatment, which were followed by increases, each with a different pattern of reinduction. One gene-family member showed increased mRNA for up to 14 d during cold acclimation and had decreased levels after 36 d of cold treatment; a fifth paralogous member of the gene family had slowly declining mRNA levels up to 36 d. Subtle differences in the level of gene expression among homeologs and large differences among paralogs were detected by comparing the relative abundance of wheat alpha-tubulin expressed sequence tags (ESTs) in public databases.     

Location of a gene regulating cold-induced carbohydrate production on chromosome 5A of wheat

 Major changes in osmotic potential during cold acclimation are due to changes in sugar concentration, and there is a good correlation between sugar content and frost tolerance. The objective of the present study was to localize a gene(s) responsible for carbohydrate accumulation during cold acclimation on chromosome 5A of wheat using recombinant lines developed from the cross between the substitution lines Chinese Spring (Cheyenne 5A) and CS(Triticum spelta 5A). Previously, major genes influencing frost resistance (Fr1) and vernalization requirement (Vrn1) had been localized on the long arm of that chromosome. The T. spelta 5A chromosome carrying the Fr1 (frost-sensitive) allele for frost tolerance and the Vrn1 (spring-habit) allele for vernalization requirement did not have a major effect on the sucrose and fructan contents in the Chinese Spring background. On the other hand, the presence of Cheyenne alleles for vernalization requirement, vrn1, and frost tolerance, fr1, significantly increased sugar concentrations. A recombinant line thought to exhibit recombination between the Vrn1 and Fr1 loci suggested that the gene regulating sucrose accumulation was closely associated with, or else represented a pleiotropic effect of, Vrn1, but was separable from the Fr1 locus. Received: 3 March 1997 / Accepted: 7 March 1997