Biochemical characterization and kinetic properties of alanine aminotransferase homologues partially purified from wheat (Triticum aestivum L.)

Four homologues of alanine aminotransferase have been isolated from shoots of wheat seedlings and purified by saline precipitation, gel filtration, preparative electrophoresis and anion exchange chromatography on Protein-Pak Q 8HR column attached to HPLC. Alanine aminotransferase 1 (AlaAT1) and 2 (AlaAT2) were purified 303- and 452-fold, respectively, whereas l-glutamate: glyoxylate aminotransferase 1 (GGAT1) and 2 (GGAT2) were purified 485- and 440-fold, respectively. Consistent inhibition of AlaAT (EC 2.6.1.2) and GGAT (EC 2.6.1.4) activities by p-hydroxymercuribenzoate points on participation of cysteine residues in the enzyme activity. The molecular weight of AlaAT1 and AlaAT2 was estimated to be 65 kDa and both of them are monomers in native state. Nonsignificant differences between K_m using alanine as substrate and catalytic efficiency (k_cat/K_m) for l-alanine in reaction with 2-oxoglutarate indicate comparable kinetic constants for AlaAT1 and AlaAT2. Similar kinetic constants for l-alanine in reaction with 2-oxoglutarate and for l-glutamate in reaction with pyruvate for all four homologues suggest equally efficient reaction in both forward and reverse directions. GGAT1 and GGAT2 were able to catalyze transamination between l-glutamate and glyoxylate, l-alanine and glyoxylate and reverse reactions between glycine and 2-oxoglutarate or pyruvate. Both GGATs also consisted of a single subunit with molecular weight of about 50 kDa. The estimated K_m for GGAT1 (3.22 M) and GGAT2 (1.27 M) using l-glutamate as substrate was lower in transamination with glyoxylate than with pyruvate (9.52 and 9.09 mM, respectively). Moreover, distinctively higher values of catalytic efficiency for l-glutamate in reaction with glyoxylate than for l-glutamate in reaction with pyruvate confirm involvement of these homologues into photorespiratory metabolism.     

The development of waterlogging damage in wheat seedlings (Triticum aestivum L.)

Summary The effects of waterlogging on concentrations of gases and various solutes dissolved in the soil water were investigated in the laboratory, to determine whether the early disruption to the growth of wheat was most closely associated with depletion of dissolved oxygen, accumulation of toxins, or changes in concentrations of nutrient ions in the soil water. Waterlogging slowed shoot fresh weight accumulation, leaf extension and nodal root growth; it also caused death of the seminal root system and early senescence of the lower leaves. However, the shoot dry weight initially increased above that of the non-waterlogged controls, and thus was not a reliable indicator of the early restriction to plant growth and development. The symptoms of damage to shoots and roots were attributed to the fall in soil oxygen concentrations, rather than to any decrease in concentration of inorganic nutrients in the soil water, or to the accumulation of any other measured solutes to toxic concentrations.     

The development of waterlogging damage in wheat seedlings (Triticum aestivum L.)

Summary Decreases in the concentrations of nitrogen, phosphorus, potassium, calcium and magnesium, in the shoots of wheat seedlings soon after the start of waterlogging were mainly attributed to an inhibition of ion uptake and transport by roots in the oxygen deficient soil. There was a small net accumulation of nitrogen, phosphorus and potassium by the aerial tissues, principally the tillers rather than the main shoot. By contrast, calcium and magnesium accumulated in both tillers and main shoot. With waterlogging, nitrogen, phosphorus and potassium were translocated from the older leaves to the younger growing leaves, and in the case of nitrogen this was associated with the onset of premature senescence. Calcium and magnesium were not translocated from the older leaves, the younger leaves acquiring these cations from the waterlogged soil. The promotion of leaf senescence by waterlogging was counteracted by applications of nitrate or ammonium to the soil surface, or by spraying the shoots with solutions of urea, but the beneficial effects on shoot growth were small.The role of mineral nutrition in relation to waterlogging damage to young cereal plants is discussed.     

Non-coding small RNAs responsive to abiotic stress in wheat (Triticum aestivum L.)

Plant small RNAs are emerging as significant components of epigenetic processes and of gene networks involved in development and homeostasis. In this paper, to identify small RNAs in wheat, 2,076 small RNAs were identified in a small RNA library from leaf, root, and spike. These small RNAs mapped to non-coding regions the CDS region of protein-coding genes and 5' UTR and 3' UTR regions. The expression of small RNAs in seedling leaves, roots, and spikes were analyzed by northern blot, which indicates that some small RNAs were responsive to abiotic stress treatments including heat, cold, salt and dehydration.     

Silicon absorption by wheat (Triticum aestivum L.)

Although silicon (Si) is a quantitatively major inorganic constituent of higher plants the element is not considered generally essential for them. Therefore it is not included in the formulation of any of the solution cultures widely used in plant physiological research. One consequence of this state of affairs is that the absorption and transport of Si have not been investigated nearly as much as those of the elements accorded 'essential' status. In this paper we report experiments showing that Si is rapidly absorbed by wheat (Triticum aestivum L.) plants from solution cultures initially containing Si at 0.5 mM, a concentration realistic in terms of the concentrations of the element in soil solutions. Nearly mature plants (headed out) 'preloaded' with Si absorbed it at virtually the same rate as did plants grown previously in solutions to which Si had not been added. The rate of Si absorption increased by more than an order of magnitude between the 2-leaf and the 7-8 leaf stage, with little change thereafter. This revised version was published online in June 2006 with corrections to the Cover Date.     

The HPLC profile of proteins of thermoprotection-acquired wheat (Triticum aestivum L.) seedlings

A pre-treatment of 40 °Cprovided thermoprotection to wheat seedlings against 43 °C, which was otherwise a lethal temperature. Due to temperature pretreatment, the rate of protein synthesis at 45 °C increased in both plumules and radicles. The HPLC profile of plumule and radicle proteins of thermoprotection-acquired seedlings was different from the plumules and radicles of non-treated seedlings.     

Lead phytotoxicity on wheat (Triticum aestivum L.) seed germination and seedlings growth

Lead (Pb) is an environmental pollutant extremely toxic to plants and other living organisms including humans. To assess Pb phytotoxicity, experiments focusing on germination of wheat seeds were germinated in a solution containing Pb (NO(3))(2) (0.05; 0.1; 0.5; 1g/L) during 6 days. Lead accumulation in seedlings was positively correlated with the external concentrations, and negatively correlated with morphological parameters of plant growth. Lead increased lipid peroxidation, enhanced soluble protein concentrations and induced a significant accumulation of proline in roots. Esterase activity was enhanced in the presence of lead, whereas α-amylase activity was significantly inhibited. Antioxidant enzymes activities, such as, ascorbate peroxidase, peroxidase, superoxide dismutase, catalase and glutathione S-transferase were generally significantly increased in the presence of lead in a dose-dependent manner. The present results thus provide a model system to screen for natural compounds able to counteract the deleterious effects of lead.     

The wheat (Triticum aestivum L.) leaf proteome

The wheat leaf proteome was mapped and partially characterized to function as a comparative template for future wheat research. In total, 404 proteins were visualized, and 277 of these were selected for analysis based on reproducibility and relative quantity. Using a combination of protein and expressed sequence tag database searching, 142 proteins were putatively identified with an identification success rate of 51%. The identified proteins were grouped according to their functional annotations with the majority (40%) being involved in energy production, primary, or secondary metabolism. Only 8% of the protein identifications lacked ascertainable functional annotation. The 51% ratio of successful identification and the 8% unclear functional annotation rate are major improvements over most previous plant proteomic studies. This clearly indicates the advancement of the plant protein and nucleic acid sequence and annotation data available in the databases, and shows the enhanced feasibility of future wheat leaf proteome research.     

Salicylic acid and nitric oxide alleviate osmotic stress in wheat (Triticum aestivum L.) seedlings

Salicylic acid (SA) and nitric oxide (NO) are reported to alleviate the damaging effects of stress in plants rather similarly when applied at appropriate low concentrations. An experiment was therefore conducted to study the impact of SA, sodium nitroprusside (SNP; as NO donor), and methylene blue (MB; as a guanylate cyclase inhibitor) on wheat seedling performance under osmotic stress. Osmotic stress significantly reduced shoot fresh weight (SFW), chlorophyll contents (Chla, Chlb, total Chl), and membrane stability index (MSI) and also increased malondialdehyde (MDA) level, lipoxygenase (LOX) activity, and hydrogen peroxide production. Moreover, enzymatic antioxidant activities including superoxide dismutase, guaiacol peroxidase, and glutathione reductase activity were enhanced under osmotic stress. On the contrary, SA or SNP pretreatment reduced the damaging effects of osmotic stress by further enhancing the antioxidant activities that led to increased SFW, Chl, and MSI and reduced MDA level and LOX activity. However, pretreatment of plants with MB reversed or reduced the protective effects of SA and SNP suggesting that the protective effects were likely attributed to NO signaling. Therefore, NO may act as downstream of SA signaling in reduction of induced oxidative damage in wheat seedlings.     

Proteomic analysis on salicylic acid-induced salt tolerance in common wheat seedlings (Triticum aestivum L.)

The influence of salicylic acid (SA) on the salt tolerance mechanism in seedlings of common wheat (Triticum aestivum L.) was investigated using physiological measurements combined with global expression profiling (proteomics). In the present study, 0.5mM SA significantly reduced NaCl-induced growth inhibition in wheat seedlings, manifesting as increased fresh weights, dry weights, and photosynthetic pigments, but decreased lipid peroxidation. Two-week-old wheat seedlings treated with 0.5mM SA, 250mM NaCl and 250mM NaCl+0.5mM SA for 3days were used for the proteomic analyses. In total, 39 proteins differentially regulated by both salt and SA were revealed by 2D PAGE, and 38 proteins were identified by MALDI-TOF/TOF MS. The identified proteins were involved in various cellular responses and metabolic processes including signal transduction, stress defense, energy, metabolism, photosynthesis, and others of unknown function. All protein spots involved in signal transduction and the defense response were significantly upregulated by SA under salt stress, suggesting that these proteins could play a role in the SA-induced salt resistance in wheat seedlings.     

Cryopreservation of wheat (Triticum aestivum L.) egg cells by vitrification

A procedure has been developed for the cryopreservation of wheat female gametes. The procedure involves loading the cells with 25% concentrated vitrification solution consisting of 30% glycerol, 10% sucrose, 120 mM ascorbic acid (AA) and 5% propylene glycol (PG), dehydration in 80% concentrated vitrification solution, droplet vitrification and storage in liquid nitrogen, unloading and rehydration of the cells by gradual addition of isolation solution. Supplementation with AA significantly increased the proportion of viable egg cells after de- and rehydration. During the early phase of rehydration AA reduced the probability of membrane damage caused by rapid water uptake. Maintaining the temperature of the cells at 0°C during the de- and rehydration processes increased cell survival. Microscopic examination of the semi-thin sections of untreated and viable cryopreserved cells revealed that the vitrification process might cause changes in cell structure.     

Characterization of a common wheat (Triticum aestivum L.) TaSnRK2.7 gene involved in abiotic stress responses

Sucrose non-fermenting-1-related protein kinase 2 (SnRK2) plays a key role in the plant stress signalling transduction pathway via phosphorylation. Here, a SnRK2 member of common wheat, TaSnRK2.7, was cloned and characterized. Southern blot analysis suggested that the common wheat genome contains three copies of TaSnRK2.7. Subcellular localization showed the presence of TaSnRK2.7 in the cell membrane, cytoplasm, and nucleus. Expression patterns revealed that TaSnRK2.7 is expressed strongly in roots, and responds to polyethylene glycol, NaCl, and cold stress, but not to abscisic acid (ABA) application, suggesting that TaSnRK2.7 might participate in non-ABA-dependent signal transduction pathways. TaSnRK2.7 was transferred to Arabidopsis under the control of the CaMV-35S promoter. Function analysis showed that TaSnRK2.7 is involved in carbohydrate metabolism, decreasing osmotic potential, enhancing photosystem II activity, and promoting root growth. Its overexpression results in enhanced tolerance to multi-abiotic stress. Therefore, TaSnRK2.7 is a multifunctional regulatory factor in plants, and has the potential to be utilized in transgenic breeding to improve abiotic stress tolerance in crop plants.     

Autotoxicity of wheat (Triticum aestivum L.) as determined by laboratory bioassays

Wheat varietal autotoxicity and varietal allelopathy were assessed based on plant extract and root exudate bioassays under laboratory conditions. Aqueous extract of wheat differed in varietal autotoxicity and varietal allelopathy, inhibiting wheat germination by 2–21%, radicle growth by 15–30%, and coleoptile growth by 5–20%, depending on the combination of the receiver and donor. Extracts of cv Triller or cv Currawong were more allelopathic to other wheat varieties than cv Batavia and cv Federation. Triller extract was more autotoxic than Federation. Assessment of root exudates by the equal-compartment-agar-method further identified the significant differences in varietal autotoxicity and varietal allelopathy of root exudates between wheat varieties, with root exudates of Triller or Batavia showing stronger autotoxic or allelopathic effects than Currawong or Federation. The varietal autotoxicity and allelopathy of root exudates also showed a characteristic radial inhibitory pattern in the agar growth medium. These results suggest that careful selection of suitable wheat varieties is necessary in a continuous cropping system in order to minimize the negative impacts of varietal allelopathy and varietal autotoxicity. Factors affecting autotoxicity in the field and strategies in autotoxicity management are discussed. Resposible Editor: Philippe Hinsinger     

Accelerated production of transgenic wheat (Triticum aestivum L.) plants

We have developed a method for the accelerated production of fertile transgenic wheat (Triticum aestivum L.) that yields rooted plants ready for transfer to soil in 8–9 weeks (56–66 days) after the initiation of cultures. This was made possible by improvements in the procedures used for culture, bombardment, and selection. Cultured immature embryos were given a 4–6 h pre-and 16 h post-bombardment osmotic treatment. The most consistent and satisfactory results were obtained with 30 g of gold particles/bombardment. No clear correlation was found between the frequencies of transient expression and stable transformation. The highest rates of regeneration and transformation were obtained when callus formation after bombardment was limited to two weeks in the dark, with or without selection, followed by selection during regeneration under light. Selection with bialaphos, and not phosphinothricin, yielded more vigorously growing transformed plantlets. The elongation of dark green plantlets in the presence of 4–5 mg/l bialaphos was found to be reliable for identifying transformed plants. Eighty independent transgenic wheat lines were produced in this study. Under optimum conditions, 32 transformed wheat plants were obtained from 2100 immature embryos in 56–66 days, making it possible to obtain R3 homozygous plants in less than a year.     

Agrobacterium-mediated In-planta transformation of bread wheat (Triticum aestivum L.)

Journal of Plant Biochemistry and Biotechnology - Agrobacterium-mediated in-planta transformation method allows efficient plant transformation without tissue culture. In the present study, a tissue...     

Biotic and abiotic stress responses through calcium-dependent protein kinase (CDPK) signaling in wheat (Triticum aestivum L.)

Calcium-dependent protein kinases (CDPKs) sense the calcium concentration changes in plant cells and play important roles in signaling pathways for disease resistance and various stress responses as indicated by emerging evidences. Among the 20 wheat CDPK genes studied, 10 were found to respond to drought, salinity and ABA treatments. Consistent with previous observations, one CDPK gene was shown to respond to multiple abiotic stresses in wheat suggesting that CDPKs could be converging points for multiple signaling pathways. Among the 12 wheat CDPK genes that were responsive to Blumeria graminis tritici (Bgt) infection or the treatment of hydrogen peroxide (H₂O₂), eight also responded to abiotic stresses, suggesting a cross-talk between biotic and abiotic stress signaling pathways. Phylogenetic analysis indicated that some of these genes were closely related to CDPKs from other species, whose functions have been partially studied, suggesting similar functions wheat CDPK genes. Combining the up-to-date knowledge of CDPK functions and our observations, a model was developed to project the possible roles of wheat CDPK genes in the signaling of biotic and abiotic stress responses.Key words: CDPK, calcium, kinase, stress response, disease resistance, signal transduction, wheatSessile plants have developed sophisticated signaling pathways to deal with dramatic environmental changes that may affect their normal growth, such as pathogen attack, drought, and cold. Calcium is a universal secondary messenger that responds to these stimuli. The fluctuation in cytosolic Ca²⁺ levels can be sensed by calcium-dependent protein kinases (CDPKs), which will modify the phosphorylation status of substrate proteins.^1–3 Accumulating evidence indicate that CDPKs mediate biotic and abiotic stress signaling pathways.^4–7 For example, overexpression of the rice CDPK gene OsCDPK7 provides cold, salt, and drought tolerance for the transgenic rice plants, demonstrating the potential of CDPK engineering to generate stress tolerance enhanced crops.^8,9In wheat, 10 out of 14 CDPK genes appeared to respond to abiotic stresses including drought, NaCl, as well as ABA stimulus (Fig. 1A).¹⁰ Five CDPKs (TaCPK4, 6, 9, 10 and 18) were particularly interesting since they could respond to at least two of the three treatments, among which the expression level of TaCPK9 was enhanced under all three treatments suggesting that TaCPK9 is the point where multiple signaling pathways cross. In wheat, TaCPK4 responded to both ABA treatment and NaCl stress (Fig. 1A). Interestingly, its best Arabidopsis homologs AtCPK4 and AtCPK11, as suggested by a Neighbor-Joining phylogenetic analysis (Fig. 1B), have been postulated as two important positive regulators in CDPK/calcium-mediated ABA signaling pathways.¹¹ Such a correlation strongly supports the idea that TaCPK4 is a good candidate in wheat for ABA signaling. Figure 1A also shows that one wheat CDPK gene could respond to multiple abiotic stresses suggesting that CDPKs are converging points for multiple signaling pathways. On the other hand, multiple CDPKs were involved in single stress response. It is however not clear how these CDPKs are organized in one signaling pathway.Open in a separate windowFigure 1The roles of wheat CDPKs in abiotic and biotic stress responses. (A) One CDPK gene responded to multiple abiotic stresses and multiple CDPKs were required for single stress response. (B) Phylogenetic relationship of wheat CDPKs with functionally studied CDPKs from barley (HvCPKs), Arabidopsis (AtCPKs), and potato (StCDPKs) that are known to be involved in ABA signaling, oxidative burst regulation and defense to powdery mildew pathogenesis. (C) A model depicting CDPK-mediated signaling pathways under biotic and abiotic treatments in wheat (see text for details). Dotted lines with a question mark indicate unknown intermediate steps.Regarding the roles of CDPKs in defense reactions, 12 TaCPKs were found to be responsive to either Blumeria graminis tritici (Bgt) infection or H₂O₂ treatment. The response to H₂O₂ was investigated because cytosolic calcium influx and reactive oxygen species, such as H₂O₂ are known to be implicated in both plant innate immunity and abiotic stresses.^12–17 Among these CDPK genes, five responded to both treatments (Group II) whereas the ones that responded to Bgt infection (Group I) or H₂O₂ treatment (Group III) were four and three respectively. The differential expression patterns suggest different functional modes of these CDPK genes. Involvement of CDPK genes in plant defense response has been shown in multiple species.^5,7 Recently, two barley CDPK paralogs (HvCDPK3 and HvCDPK4) were found to play antagonistic roles during the early phase of powdery mildew pathogenesis.⁵ The close similarity between wheat CDPK genes (TaCPK2 and TaCPK5, Fig. 1B) with these two barley genes may suggest their potential roles in wheat powdery mildew resistance. Surprisingly, we did not detect the responsiveness of TaCPK5 to wheat Bgt infection, indicating the divergence of CDPK functions in these two members of Triticeae family. Recently, one potato (Solanum tuberosum) CDPK gene StCDPK5 has been shown to be directly involved in regulating oxidative burst via phosphorylation of the NADPH oxidase StRBOHB.¹⁸ In light of the close relationship of TaCPK2 with HvCDPK5 and StCDPK5 (Fig. 1B), we speculate that TaCPK2 could be associated with both biotic and abiotic stress response signaling pathways and therefore play multiple roles in wheat.A model was proposed in Figure 1C regarding the positions of wheat CDPK genes in signaling pathways for biotic and abiotic responses. The hypothesis depicted four different roles of wheat CDPK genes: (1) Group I genes that respond only to Bgt infection may, like potato StCDPK5, render defense response through an oxidase like NADPH oxidase that generates increased amount of H₂O₂;¹⁸ (2) At one aspect, Group II genes may participate in defense response in a manner similar to Group I genes; (3) On the other hand, since Group II genes also respond to H₂O₂ treatment directly, an auto-regulation circuit was proposed, which eventually joins the oxidase pathway; (4) Group III CDPK genes and some remaining CDPK genes are considered to be mainly involved in abiotic stress responses. The model positioned CDPKs both upstream and downstream of H₂O₂, presenting a complicated wiring of the signaling pathway network involving wheat CDPKs. Future biochemical, genetic, and transgenic analyses may help elucidate the genuineness of such a rather early model for the functions of wheat CDPK genes.     

Control of tissue culture response in wheat (Triticum aestivum L.)

Summary The ability of immature embryos of wheat (Triticum aestivum L.) to respond to tissue culture has been shown to involve the group 2 chromosomes. The available group 2 ditelosomic and nullisomic-tetrasomic lines of Chinese Spring wheat were used to determine the chromosome arm location and chromosome dosage effect associated with the expression of tissue culture response (TCR). Significant differences were found between the aneuploid lines and the euploid control for the expression of both regenerable callus formation and callus growth rate. A model is proposed suggesting that a major TCR gene is located on 2DL and that 2AL and 2BS possess minor TCR genes. Furthermore, a major regulatory gene controlling the expression of TCR genes may be located on chromosome 2BL.     

Identification of three Wx proteins in wheat (Triticum aestivum L.)

Nullisomic analysis of waxy (Wx) protein of hexaploid wheat (Triticum aestivum L.) cv. “Chinese Spring” using two-dimensional polyacrylamide gel electrophoresis revealed that threeWx loci,Wx-A1, Wx-B1, andWx-D1, located on chromosome arms 7AS, 4AL, and 7DS, produce three distinct Wx subunit groups, subunit group-A (SGA), SGB, and SGD, respectively. SGA has a higher molecular weight and a more basic isoelectric point (pI) than the other two. SGB and SGD have the same molecular weight but a slightly different pI range. Owing to the detection of these three subunit groups, we were able to identify the expression of three waxy genes in wheat endosperm and to find two types of mutants among Japanese wheat cultivars, one lacking SGA and the others SGB. These results suggest the possibility of breeding a waxy wheat.     

Influence of minerals on cytoplasmic streaming in root hairs of intact wheat seedlings (Triticum aestivum L.)

The calcium dependency of the cytoplasmic streaming of wheat root hairs was demonstrated by adding the Ca-Ionophore A 23187. Within three minutes the streaming velocity was decreased dramactically. The influence of ammonium on the cytoplasmic streaming is highly pH-dependent. While at a pH of 9.0 an inhibitory effect was observed even at low ammonium concentrations (0.5 mM) no effect could be measured at a pH of 6.5. Nitrate, independently of medium pH had no effect on the cytoplasmic streaming. The same is true for aluminium. It is suggested that at pH 9 ammonium permiates the plasmalemma as NH₃. Due to higher cytoplasmic pH ( 7.5), NH₃ is protonated leading to an increase in cytoplasmic pH. Ammonium may displace sorbed calcium leading to an increase in the free cytoplasmic calcium responsible for the cessation of the streaming. Alternative explanations are discussed.Abbreviations HEPES N-2-Hydroxyethylpiperazine-N-2-ethanesulfonic acid