Seasonal Changes in the Composition and Content of Dehydrins in Winter Wheat Plants

Seasonal changes in the pattern and content of dehydrins in winter wheat (Triticum aestivum) plants grown under field and laboratory conditions were studied by one-dimensional PAGE and immunochemical methods. During hardening, plants accumulated dehydrin-like polypeptides with mol wts of 209, 196, 66, 50, and 41 kD. In winter, low-molecular-weight dehydrins with mol wts of 24, 22, 17, 15, and 12 kD were synthesized and accumulated as well. Their content dropped sharply in spring when plants became unhardened. Accumulation/disappearance of these proteins corresponded to the fluctuations in wintering plant frost tolerance before winter and in spring. It is assumed that both high- and medium-molecular-weight dehydrins are involved in plant stress responses and adaptation, whereas low-molecular-weight dehydrins are evidently involved only in the process of low-temperature adaptation.     

Accumulation of dehydrin-like proteins in the mitochondria of cereals in response to cold, freezing, drought and ABA treatment

Background

Dehydrins are known as Group II late embryogenesis abundant proteins. Their high hydrophilicity and thermostability suggest that they may be structure stabilizers with detergent and chaperone-like properties. They are localised in the nucleus, cytoplasm, and plasma membrane. We have recently found putative dehydrins in the mitochondria of some cereals in response to cold. It is not known whether dehydrin-like proteins accumulate in plant mitochondria in response to stimuli other than cold stress.

Results

We have found five putative dehydrins in the mitochondria of winter wheat, rye and maize seedlings. Two of these polypeptides had the same molecular masses in all three species (63 and 52 kD) and were thermostable. Drought, freezing, cold, and exogenous ABA treatment led to higher accumulation of dehydrin-like protein (dlp) 63 kD in the rye and wheat mitochondria. Protein 52 kD was induced by cold adaptation and ABA. Some accumulation of these proteins in the maize mitochondria was found after cold exposition only. The other three proteins appeared to be heat-sensitive and were either slightly induced or not induced at all by all treatments used.

Conclusions

We have found that, not only cold, but also drought, freezing and exogenous ABA treatment result in accumulation of the thermostable dehydrins in plant mitochondria. Most cryotolerant species such as wheat and rye accumulate more heat-stable dehydrins than cryosensitive species such as maize. It has been supposed that their function is to stabilize proteins in the membrane or in the matrix. Heat-sensitive putative dehydrins probably are not involved in the stress reaction and adaptation of plants.     

Accumulation of Dehydrins and ABA-Inducible Proteins in Wheat Seedlings during Low-Temperature Acclimation

Using one-dimensional SDS-PAGE and immunochemical methods, we detected the presence and estimated the content of dehydrins and ABA-inducible (RAB) polypeptides in etiolated seedlings of four spring and three winter wheat (Triticum aestivum L.) cultivars differing in frost hardiness. We hardened three-day-old seedlings at 4°C for nine days or grew them at 22°C for a day (control seedlings). We established that heat-stable cold-regulated (COR) polypeptides with mol wts of 209, 196, 169, 66, 50, and 41 kD, which are characteristic of hardened wheat seedlings, were homologous to polypeptides from a dehydrin family and polypeptides with mol wts of 209, 196, 66, 50, and 41 kD were immunologically related to RAB-proteins. We supposed that these COR polypeptides were involved in the prevention of local protein dehydration and denaturation during hypothermia. Analysis of the relative content of COR proteins revealed a close correlation between the cultivar frost hardiness and the concentration of these proteins. It seems evident that different accumulation of dehydrins and RAB polypeptides in different cultivars of a single species is one of the causes for different plant frost hardiness.     

Aluminum-Induced Changes in Cell-Wall Glycoproteins in the Root Tips of Al-Tolerant and Al-Sensitive Wheat Lines

To investigate wheat (Triticum aestivumL.) responses to Al stress, KCl- and SDS-extracted glycoproteins (covalently bound proteins isolated by cell-wall digestion by cellulysine–pectolase mixture) and extensins (hydroxyproline-containing glycoproteins, HRGPs) were isolated from cell-wall preparations purified from the root apices of Al-sensitive and Al-tolerant near-isogenic lines ES8 and ET8. Under Al stress conditions, two lines differed mostly in their extensins. The untreated plants of two lines were low in covalently bound extensins, although the content of this protein fraction in ES8 was higher than in ET8. When the seedlings were treated with Al, the extensin content increased in both wheat lines and especially in the Al-tolerant ET8 plants. Using two-dimensional electrophoresis, the authors demonstrated the accumulation of polypeptides with mol wts of 22.2 kD (pI 5.5–6.5), 24.5 kD (pI 5.8–6.0), and 33.1 kD (pI 5.25) and polypeptides of 22.2 kD (pI 6.8–7.6) and 40.5 kD (pI 7.6) in the extensin fraction from the cell walls of the Al-sensitive plants. The regulation of cell responses to Al stress may involve extensin expression.     

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.     

Identification and characterization of dehydrins in horse chestnut recalcitrant seeds

The fraction of heat-stable dehydrins cytosolic proteins from mature recalcitrant seeds of horse chestnut (Aesculus hippocastanum L.) was studied in the period of their dormancy and germination in order to identify and characterize stress-induced dehydrin-like polypeptides. In our experiments, in tissues of dormant seeds, dehydrin was identifies by immunoblotting as a single bright band with a mol wt of about 50 kD. Low-molecular-weight heat-stable proteins with mol wts of 25 kD and below 16 kD, which were abundant in this fraction, did not cross-react with the antibody. Dehydrin was detected in all parts of the embryo: in the cells of axial organs, cotyledon storage parenchyma, and petioles of cotyledonary leaves. This indicates the absence of tissue-specificity in distribution of these proteins in the horse chestnut seeds. Dehydrins were detected among heat-stable proteins during the entire period of stratification and also radicle emersion. During radicle emergence, not only the fraction of heat-stable proteins was reduced but also the proportion of dehydrins in it decreased. In vitro germination of axes excised at different terms of stratification also resulted in dehydrin disappearance. When growth of excised axes was retarded by treatments with ABA, cycloheximide, or α-amanitin, dehydrins did not disappeared from the fraction of heat-stable proteins. When excised axes were germinated in vitro in the presence of compounds, which did not affect their growth or stimulated it (dehydrozeatin, glucose), this resulted in dehydrin disappearance. This means that dehydrin metabolism is closely related to the process of germination. Dehydrin in the horse chestnut seeds could cross-react with the antibody against ubiquitin, which can indicate the involvement of ubiquitination in the process of dehydrin degradation during germination via the proteasome system. The analysis of total proteins of the homogenate from horse chestnut seeds revealed, along with a 50-kD heat-stable dehydrin, one more component with a mol wt of 80 kD, which was located in the fraction of heat-sensitive proteins and was named as a dehydrin-like protein. It was demonstrated that dehydrins in horse chestnut seeds represented only a very small fraction of heat-stable cytosolic proteins. The role and function of major heat-stable proteins in horse chestnut seeds are yet to be studied.     

Dehydrins associated with the development of frost resistance of Asian white birch

Seasonal changes in the content of dehydrins in Asian white birch (Betula platyphylla Sukacz.) growing under extreme cold conditions of Eastern Siberia (Central Yakutia) were studied for the first time by SDS-PAGE and immunoblotting. Several polypeptides, including putative storage proteins, which content was higher in winter than in other periods, were observed. Intraspecies polymorphism of dehydrins was detected during plant dormancy. The two groups of dehydrins were found: dehydrins with mol wts of 56-73 kD, which were present year-round, and dehydrins with mol wts of 15–21 kD, evidently related to the development of frost resistance because they were absent in summer but present in large amounts in winter. Under low winter temperatures, the highest level of dehydrins coincided with the lowest content of water in buds, which was accompanied by increased plant frost resistance to the highest values.     

Woody plants of Yakutia and low-temperature stress

Physiological and biochemical features of woody plants (Pinus sylvestris L. and Betula platyphylla Sukacz.) during transition from vegetative to frost-resistant state under conditions of extremely severe climate of Yakutia were studied. In P. sylvestris such transition was accompanied by a decrease in the content of chlorophylls long before first frosts and by an increase in the proportion of Xanth and simultaneous decrease in the content of β-carotene in needles during the first and second phases of hardening. In the period of preparation to dormancy, overwintering organs of both P. sylvestris (needles) and B. platyphylla (buds) accumulated the two groups of major dehydrins, with low mol wts of 15–21 kD and middle mol wts of 66–141 kD. Simultaneously, low temperature led to a great increase in the content of polyunsaturated fatty acids (FAs) in lipids of P. sylvestris needles and B. platyphylla buds, primarily linoleic acid and also eicosenoic FAs differing in the extent of desaturation. Observed qualitative and quantitative changes in pigments, total proteins, dehydrins, and FAs during autumn hardening of P. sylvestris and B. platyphylla plants presume their important role in the development of resistance of these tree species to low-temperature stress (down to −60°C) in the cryolithic zone of Yakutia.     

The relationship between the differences in frost resistance of Arabidopsis and Thellungiella and heat shock proteins and dehydrins

Plants of extremophile Thellungiella (Thellungiella salsuginea (Pall.) OE Schulz) withstood freezing at ?15°C for 2 h without hardening, whereas plants of Arabidopsis (Arabidopsis thaliana (L.) Heinh.) were damaged at ?10°C and died at ?15°C under these conditions. The content of heat shock proteins (HSPs) HSP101, HSP60 and constitutive HSC70 was significantly higher in unhardened Thellungiella plants than in unhardened Arabidopsis plants. The spectrum of dehydrins (DHNs) in unhardened Thellungiella plants was more diverse and their total content was higher than in unhardened Arabidopsis plants. Frost resistance of Arabidopsis increased after hardening (4°C, 7 days), and there was an increase in the content of HSP101 and HSP60, as well as in the content of the DHN with a mol wt of 70 kD. Thellungiella plants survived after hardening at ?18°C, and the increase in the content of HSP101, HSP70, and HSP60 was significantly less pronounced than in Arabidopsis. At the same time, the content of DHNs in Thellungiella increased significantly during the hardening primarily because of the appearance of two DHNs (mol wts of 42 and 45 kD). It is assumed that an increased content of HSPs and DHNs and their greater diversity can be one of the factors of Thellungiella resistance to low temperatures as compared to Arabidopsis.     

Lectin activity and composition in the wheat cell walls under the effects of low temperature and inhibitors of calcium signaling pathway

In the roots of winter wheat (Triticum aestivum L., cv. Mironovskaya 808) seedlings, the effects of neomycin (100 μM), an inhibitor of phospholipase C, and dilthiazem (250 μM), a blocker of calcium channels on lectin activity and composition at low-temperature treatment (2–3°C) were studied. Hypothermia induced the appearance of two peaks of cell wall-bound lectin activity, e.g., in 0.5 and 6 h. Under these conditions, the inhibitors suppressed lectin activity. In 0.5 h of hypothermia, substantial changes in total profile of proteins were observed: lectins with mol wts of 85, 78, and 54 kD disappeared, and novel lectins with mol wts of 110, 105, 70, 50, and 34.5 kD appeared. In the presence of dilthiazem, the set of lectin proteins remained similar to that in unhardened plants, and the increase in the lectin content and activity was observed only after 3-h exposure to low temperature. This indicates that blocking dilthiazem-sensitive calcium channels slowed plant response to stress and did not permitt the cell to start rapidly the development of defense mechanisms. The important role of lectins with mol wts of 110 and 60 kD in the formation of freeze tolerance is supposed because these lectins did not appear in the presence of dilthiazem.     

Polymorphism of Thermostable Proteins in Soft Wheat Seedlings during Low-Temperature Acclimation

The accumulation of thermostable stress proteins during hardening was studied in etiolated seedlings of spring (cvs. Rollo, Drott, Angara-86, and Tyumenskaya-80) and winter (moderately frost-resistant cv. Bezostaya-1 and highly frost-resistant cvs. Irkutskaya ozimaya and Zalarinka) wheat using one-dimensional SDS-PAGE. Hardening was performed at 4°C for nine days. Seedling tolerance to low subzero temperatures was estimated from electrolyte leakage and seedling survival after freezing. Hardening of all wheat genotypes tested resulted in the accumulation of thermostable cold-regulated (COR) polypeptides with mol wts of 209, 196, 169, 66, 50, and 41 kD. A densitometric analysis demonstrated a close correlation between the cultivar frost tolerance and the relative content of COR proteins, which evidently indicated the protective functions of the latter. These results led us to suggest that the level of specific protective agents, thermostable high-molecular-weight COR polypeptides in particular, determines the degree of plant frost resistance within a particular plant species.     

Interactions of intrinsically disordered Thellungiella salsuginea dehydrins TsDHN-1 and TsDHN-2 with membranes - synergistic effects of lipid composition and temperature on secondary structure

Dehydrins are intrinsically disordered (unstructured) proteins that are expressed in plants experiencing stressful conditions such as drought or low temperature. Dehydrins are typically found in the cytosol and nucleus, but also associate with chloroplasts, mitochondria, and the plasma membrane. Although their role is not completely understood, it has been suggested that they stabilize proteins or membrane structures during environmental stress, the latter association mediated by formation of amphipathic α-helices by conserved regions called the K-segments. Thellungiella salsuginea is a crucifer that thrives in the Canadian sub-Arctic (Yukon Territory) where it grows on saline-rich soils and experiences periods of both extreme cold and drought. We have cloned and expressed in Escherichia coli two dehydrins from this plant, denoted TsDHN-1 (acidic) and TsDHN-2 (basic). Here, we show using transmission-Fourier transform infrared (FTIR) spectroscopy that ordered secondary structure is induced and stabilized in these proteins by association with large unilamellar vesicles emulating the lipid compositions of plant plasma and organellar membranes. Moreover, this induced folding is enhanced at low temperatures, lending credence to the hypothesis that dehydrins stabilize plant outer and organellar membranes in conditions of cold.     

The effect of hypothermia on the content of 310 kD stress protein in seedlings of winter rye and wheat

The effect of hypothermia on the content of 310 kD stress protein in seedlings of winter rye and wheat was studied by rocket-immunoelectrophoresis and radioactive label. The 1-h low-temperature stress was found to result in an increase in the content of this protein at both above- and below-zero temperatures. It was found that the increase in the relative content of the protein with mol. wt 310 kD, under the effect of short-term low-temperature stress, occurs due to induction of its synthesis. It has been found that during cold hardening of winter wheat the content of this protein decreases up to 64% compared to the control during the first day of hardening but starts to rise by the third day and reaches 179% by the seventh day, which is well correlated with the increase in cold resistance of winter wheat plants during cold hardening.     

Localization of Proteins Immunologically Related to Subunits of Stress 310-kD Protein in Winter Wheat Mitochondria

We studied the localization of polypeptides immunochemically related to subunits of cold-shock 310-kD protein from winter rye (Secale cerealeL.) in mitochondria and submitochondrial structures of winter wheat (Triticum aestivumL.) seedlings. Polypeptides were separated by SDS-PAGE and probed with the antibody against 310-kD protein from rye seedlings. Wheat mitochondria contained the following polypeptides cross-reacting with this antibody: 66, 60, 55, and 23 kD in the inner membrane; 60 and 58 kD in the outer membrane; and 66 and 55 kD in the matrix.     

Endonuclease activities in the coleoptile and the first leaf of developing etiolated wheat seedlings

DNase activity in coleoptiles and the first leaf apices of winter wheat (Triticum aestivum L., cv. Mironovskaya 808) etiolated seedlings was found to increase significantly during seedling growth, peaking on the eighth day of plant development. The maximum of DNase activity was coincident with apoptotic internucleosomal DNA fragmentation in these organs. Wheat endonucleases are capable of hydrolyzing both singleand double-stranded DNA of various origins. The leaf and coleoptiles were found to exhibit nuclease activities that hydrolyzed the lambda phage DNA with N⁶-methyladenine and 5-methylcytosine more actively compared to the hydrolysis of similar unmethylated DNAs. Thus, the endonucleases of wheat seedlings are sensitive to the methylation status of their substrate DNAs. The leaves and coleoptiles exhibited both Ca²⁺/Mg²⁺- and Zn²⁺-dependent nuclease activities that underwent differential changes during development and senescence of seedling organs. EDTA at a concentration of 50 mM fully inhibited the total DNase activity. Electrophoretic heterogeneity was observed for DNase activities operating simultaneously in the coleoptile and the first leaf at different stages of seedling development. Proteins exhibiting DNase activity (16–80 kD mol wt) were revealed in the first leaf and the coleoptile; these proteins were mostly nucleases with the pH optimum around 7.0. Some endonucleases (mol wts of 36, 39, and 28 kD) were present in both organs of the seedling. Some other DNases (mol wts of 16, 56, and about 80 kD) were found in the coleoptile; these DNases hydrolyzed DNA in the nucleus at terminal stages of apoptosis. Different suites of DNase activities were revealed in the nucleus and the cytoplasm, the nuclear DNase activities being more diverse than the cytoplasmic ones. Thus, the cellular (organspecific) and subcellular heterogeneity in composition and activities of DNases has been revealed in wheat plants. These DNases undergo specific changes during seedling development, serving at various stages of programmed cell death in seedling tissues.     

Effect of Ca<Superscript>2+</Superscript> and cAMP on protein phosphorylation in mitochondria of maize seedlings

The effect of common intracellular signals (Ca²⁺ and cAMP) on the activity of protein phosphorylation in mitochondria was investigated in coleoptiles of maize (Zea mays L.). Treatment of isolated mitochondria with 2 mM CaCl₂ brought about an increase in the level of phosphorylation of proteins with mol ws of 74, 60, and 33 kD but considerably reduced phosphorylation of the protein with a mol wt of 51.5 kD. In the presence of Ca²⁺, phosphorylation of polypeptides with mol wts of 59 and 66 kD was also detected. cAMP considerably reduced phosphorylation of essentially all the investigated proteins in isolated mitochondria, which could be explained by activation of their dephosphorylation. Phosphorylation of mitochondrial proteins involves a polypeptide of about 94 kD showing kinase activity, which may be proper protein kinase or one of the subunits of a compound structure. In maize mitochondria, PP1A phosphatases were found. A hypothesis was advanced that redox-dependent phosphorylation/dephosphorylation of mitochondrial proteins plays an important role in mitochondrial signaling in higher plants.     

Accumulation pattern of dehydrins during sugarcane (var. SP80.3280) somatic embryogenesis

The objective of the present study was to determine dehydrin protein levels in sugarcane var. SP80-3280 during somatic embryogenesis. Dehydrins from embryogenic and non-embryogenic cell cultures were analyzed using western blot and in situ immunolocalization microscopy. Both techniques employ antibodies raised against a highly conserved lysine-rich 15-amino acid sequence termed the K-domain, which is extensively used to recognize proteins immunologically related to the dehydrin family. In embryogenic cultures, western blot analysis of the heat-stable protein fraction revealed eleven major bands ranging from 52 to 17?kDa. They were already visible on the first days, gradually increasing until reaching peak values around day 14, when organogenesis begins, to later decrease in concurrence with the appearance of green plantlets (around day 28). These fluctuations indicate that this pattern of accumulation is under developmental control. Dehydrins were mainly immunolocalized in the nuclei. A phosphatase treatment of protein extracts caused a mobility shift of the 52, 49, and 43?kDa dehydrin bands suggesting a putative modulation mechanism based on protein phosphorylation. In sugarcane embryogenic cultures, presence of dehydrins is a novel finding. Dehydrins were absent in non-embryogenic cultures. The novel findings regarding accumulation, nuclear localization, and phosphorylation of dehydrins provide a starting point for further research on the role of these proteins in the induction and/or maintenance of embryogenesis. Key message The novel findings regarding accumulation, nuclear localization, and phosphorylation of dehydrins provide a starting point for further research on the role of these proteins in the induction and/or maintenance of embryogenesis.     

Subcellular localization of dehydrins in wheat plant seedlings subjected to low-temperature adaptation

Subcellular localization of dehydrins (dhn) in stem cell tissues of winter wheat seedlings (Triticulum aestivum L., cult. Irkutskaya ozimaya) was studied by immunoelectron microscopy. It was found that cold hardening at 4°C for 7 days resulted in a duplication of the dhn quantity in the cells as compared with control conditions (22°C). The maximum increase of the dhn content was observed in rough endoplasmic reticulum, mitochondria, cell walls, and intercellular spaces (3.8-, 3.0- and 2.8-fold, respectively); minimum increase was found in chloroplasts (1.4-fold). In the membrane compartments (mitochondria, rough endoplasmic reticulum, chloroplasts) low-temperature stress caused an increase of dhn quantity not only near membranes but also in the intermembrane space. A significant accumulation of dhn (2.5-fold) in the nucleus under low- temperature was found. We conclude that cold hardening of the plant induces accumulation and translocation of dhn to the regions of inter- and intracellular compartments that most require protection during the low-temperature stress.     

DNA-Binding Proteins and Structural Characteristics of Chloroplast Nucleoids

A comparative analysis of proteins from chloroplast nucleoids was performed in two higher-plant species (Pisum sativumL. andArabidopsis thalianaL.) and a green alga Chlamydomonas reinhardtiiDang. In the nucleoids of the higher plants and the alga, 26–27 proteins were detected with their mol wts ranging from 10 to more than 94 kD. In all the species tested, the distribution of nucleoid proteins by their mol wts was similar, especially between the predominant proteins with mol wts of 10 to 40 kD. Six DNA-binding proteins (12–18 kD) were detected in nucleoids fromCh. reinhardtiichloroplasts after in vivocovalent cross-linking between chloroplast DNA and proteins. Under an electron miscroscope, some regular structures resembling nucleosome-like particles of bacterial cells were revealed.     

Activity of Lectin-Like Proteins of the Cell Walls and the Outer Organelle Membranes as Related to Endogenous Ligands in Cold-Adapted Seedlings of Winter Wheat

The hemagglutinating activity (HA) of lectin-like components in the cell walls and the outer organelle membranes was studied in freezing-tolerant winter wheat (Triticum aestivum L., cv. Mironovskaya 808) plants in the course of hardening at 2°C, in parallel with the effects of endogenous ligands from the soluble fraction on HA. Low hardening temperature divergently changed HA of the lectin-like components in the cell walls, the outer membranes of nuclei, plastids, and mitochondria, and the microsomal membranes: HA increased in the cell walls, nuclei, and plastids and decreased in the mitochondria and microsomal membranes. Under hardening conditions, with plant growth slowed down, HA of the lectin-like proteins from the outer organelle membranes was inhibited in the presence of the soluble fraction components (soluble ligands); such inhibition was not observed in the case of actively growing nonhardened seedlings. The authors put forward a hypothesis that the lectin-like proteins from both peripheral (cell walls) and intracellular (outer organelle membranes) compartments are essential for developing freezing tolerance. HA of the cell walls and the outer membranes of nuclei and plastids enhanced by hardening manifested positive correlation with freezing tolerance and negative correlation with the growth rate. In contrast, HA of the outer membranes of mitochondria and microsomes was positively related to plant growth and negatively, to freezing tolerance. As negative and positive effectors of membrane-dependent processes, the lectin-like components of the outer organelle membranes seem to control membrane functional activities in the course of cold adaptation.