Oxylipin dynamics in Medicago truncatula in response to salt and wounding stresses

Multiple stresses are becoming common challenges in modern agriculture due to environmental changes. A large set of phytochemicals collectively known as oxylipins play a key role in responses to several stresses. Understanding the fine‐tuned plant responses to multiple and simultaneous stresses could open new perspectives for developing more tolerant varieties. We carried out the molecular and biochemical profiling of genes, proteins and active compounds involved in oxylipin metabolism in response to single/combined salt and wounding stresses on Medicago truncatula. Two new members belonging to the CYP74 gene family were identified. Gene expression profiling of each of the six CYP74 members indicated a tissue‐ and time‐specific expression pattern for each member in response to single/combined salt and wounding stresses. Notably, hormonal profiling pointed to an attenuated systemic response upon combined salt and leaf wounding stresses. Combined, these results confirm the important role of jasmonates in legume adaptation to abiotic stresses and point to the existence of a complex molecular cross‐talk among signals generated by multiple stresses.     

Alterations in leaf carbohydrate metabolism in response to nitrogen stress

A series of experiments was conducted to characterize alterations in carbohydrate utilization in leaves of nitrogen stressed plants. Two-week-old, nonnodulated soybean plants (Glycine max [L.] Merrill, `Ransom'), grown previously on complete nutrient solutions with 1.0 millimolar NO₃⁻, were transferred to solutions without a nitrogen source at the beginning of a dark period. Daily changes in starch and sucrose levels of leaves were monitored over the following 5 to 8 days in three experiments. Starch accumulation increased relative to controls throughout the leaf canopy during the initial two light periods after plant exposure to N-free solutions, but not after that time as photosynthesis declined. The additional increments of carbon incorporated into starch appeared to be quantitatively similar to the amounts of carbon diverted from amino acid synthesis in the same tissues. Since additional accumulated starch was not degraded in darkness, starch levels at the beginning of light periods also were elevated. In contrast to the starch effects, leaf sucrose concentration was markedly higher than controls at the beginning of the first light period after the N-limitation was imposed. In the days which followed, diurnal turnover patterns were similar to controls. In source leaves, the activity of sucrose-P synthase did not decrease until after day 3 of the N-limitation treatment, whereas the concentration of fructose-2,6-bisphosphate was decreased on day 2. Restricted growth of sink leaves was evident with N-limited plants within 2 days, having been preceeded by a sharp decline in levels of fructose-2,6 bisphosphate on the first day of treatment. The results suggest that changes in photosynthate partitioning in source leaves of N-stressed plants resulted largely from a stable but limited capacity for sucrose formation, and that decreased sucrose utilization in sink leaves contributed to the whole-plant diversion of carbohydrate from the shoot to the root.     

Glutathione metabolism in Urtica dioica in response to cadmium based oxidative stress

To investigate the antioxidative response of glutathione metabolism in Urtica dioica L. to a cadmium induced oxidative stress, activities of glutathione reductase (GR), glutathione-S-transferase (GST), and glutathione peroxidase (GSH-Px), content of reduced (GSH) and oxidized (GSSG) glutathione, lipid peroxidation (LPO), and also accumulation of Fe, Zn, Mn, Cu besides Cd were determined in the roots, stems, and leaves of plants exposed to 0 (control), 0.045, and 0.09 mM CdCl₂ for 58 h. Whereas the Cd content continuously increased in all organs, the Fe, Zn, Mn, and Cu content decreased in dependence on the applied Cd concentration and incubation time. The Cd treatment resulted in increased GR and GST activities in all organs, however, GSH-Px activity was dependent on Cd concentration and plant organ. The GSH/GSSG ratio maintained above the control level in the stems at both Cd concentrations. The LPO was generally close to the control values in the roots and stems but it increased in the leaves especially at 0.09 mM Cd.     

Regulation of glycerol metabolism in Zygosaccharomyces rouxii in response to osmotic stress

Summary Enzyme analyses indicated that the metabolism of glycerol by Zygosaccharomyces rouxii occurred via either glycerol-3-phosphate (G3P) or dihydroxyacetone (DHA). The route via DHA is significant in osmoregulation. The specific activities of glycerol dehydrogenase (GDHG) and DHA kinase, which metabolize glycerol via DHA, increased nine- and fourfold respectively during osmotic stress [0.960 water activity (a_w) adjusted with NaCl] when compared to non-stressed conditions (0.998 a_w). Both pathways are under metabolic regulation. Glycerol kinase, mitochondrial G3P dehydrogenase and DHA kinase are induced by glycerol while the latter is also repressed by glucose. Cells treated with cycloheximide prior to osmotic upshock showed significantly lower DHA kinase and GDHG levels and lower intracellular glycerol concentrations when compared to untreated control cells. Thus protein synthesis is essential for osmotic adaptation. Offprint requests to: B. A. Prior     

Differences in metabolism between the biofilm and planktonic response to metal stress

Bacterial biofilms are known to withstand the effects of toxic metals better than planktonic cultures of the same species. This phenomenon has been attributed to many features of the sessile lifestyle not present in free-swimming populations, but the contribution of intracellular metabolism has not been previously examined. Here, we use a combined GC-MS and (1)H NMR metabolomic approach to quantify whole-cell metabolism in biofilm and planktonic cultures of the multimetal resistant bacterium Pseudomonas fluorescens exposed to copper ions. Metabolic changes in response to metal exposure were found to be significantly different in biofilms compared to planktonic cultures. Planktonic metabolism indicated an oxidative stress response that was characterized by changes to the TCA cycle, glycolysis, pyruvate and nicotinate and niacotinamide metabolism. Similar metabolic changes were not observed in biofilms, which were instead dominated by shifts in exopolysaccharide related metabolism suggesting that metal stress in biofilms induces a protective response rather than the reactive changes observed for the planktonic cells. From these results, we conclude that differential metabolic shifts play a role in biofilm-specific multimetal resistance and tolerance. An altered metabolic response to metal toxicity represents a novel addition to a growing list of biofilm-specific mechanisms to resist environmental stress.     

Rewiring of purine metabolism in response to acidosis stress in glioma stem cells

Glioma stem cells (GSCs) contribute to therapy resistance and poor outcomes for glioma patients. A significant feature of GSCs is their ability to grow in an acidic microenvironment. However, the mechanism underlying the rewiring of their metabolism in low pH remains elusive. Here, using metabolomics and metabolic flux approaches, we cultured GSCs at pH 6.8 and pH 7.4 and found that cells cultured in low pH exhibited increased de novo purine nucleotide biosynthesis activity. The overexpression of glucose-6-phosphate dehydrogenase, encoded by G6PD or H6PD, supports the metabolic dependency of GSCs on nucleotides when cultured under acidic conditions, by enhancing the pentose phosphate pathway (PPP). The high level of reduced glutathione (GSH) under acidic conditions also causes demand for the PPP to provide NADPH. Taken together, upregulation of G6PD/H6PD in the PPP plays an important role in acidic-driven purine metabolic reprogramming and confers a predilection toward glioma progression. Our findings indicate that targeting G6PD/H6PD, which are closely related to glioma patient survival, may serve as a promising therapeutic target for improved glioblastoma therapeutics. An integrated metabolomics and metabolic flux analysis, as well as considering microenvironment and cancer stem cells, provide a precise insight into understanding cancer metabolic reprogramming.     

Regulation of plants metabolism in response to salt stress: an omics approach

In recent era, some man-made and natural activities are responsible for causing salt stress that affects each component of environment. Among several components, plant is one of the essential components, and with the consequence of excess salts accumulation in the environment their metabolic activities may get affected. Plants exhibit hyper-osmotic stress and ion disturbance in the presence of excess salt accumulation. To combat this stress situation, some metabolites/or stress-responsive gene(s) and proteins are synthesized by the plants to mitigate the salt toxicity. Therefore, to reduce the impact of salt stress on yield and other physiological activities of plants it is essential to know the whole pathway through which plant’s metabolism get affected in the presence of salt. The present review is also dealing with the same objective and special focus is given to the omics tools, such as genomics, proteomics and metabolomics to discuss the different ways of tolerance mechanism in the plant system against salt toxicity.     

Energy response and fatty acid metabolism in Onychostoma macrolepis exposed to low-temperature stress

Temperature is a key environmental factor, and understanding how its fluctuations affect physiological and metabolic processes is critical for fish. The present study characterizes the energy response and fatty acid metabolism in Onychostoma macrolepis exposed to low temperature (10 °C). The results demonstrated that cold stress remarkably disrupted the energy homeostasis of O. macrolepis, then the AMP-activated protein kinase (AMPK) could strategically mobilize carbohydrates and lipids. In particular, when the O. macrolepis were faced with cold stress, the lipolysis was stimulated along with the enhanced fatty acid β-oxidation for energy, while the fatty acid synthesis was supressed in the early stage. Additionally, the fatty acid composition analysis suggested that saturated fatty acid (SFA) might accumulate while monounsaturated fatty acid (MUFA) and polyunsaturated fatty acid (PUFA) in storage lipids (mainly containing non-polar lipid, NPL) could be utilized to supply energy during cold acclimation. Altogether, this study may provide some meritorious for understanding the cold-tolerant mechanism of fish in the viewpoint of energy balance combined with fatty acid metabolism, and thus to contribute to this species rearing in fish farms in the future.     

Oxylipin metabolism in soybean seeds containing different sets of lipoxygenase isozymes after homogenization

The oxylipin metabolism was analyzed in soybean homogenates containing different sets of lipoxygenase isozymes (L-1, -2, and -3); namely, Suzuyutaka (containing L-1, -2, and -3), Yumeyutaka (containing only L-1), Kanto102 (containing L-2), Kyushu119 (containing L-3), and Ichihime (lacking all three isozymes). The amount of oxidized fatty acids in the esterified form was higher than that in the free form with every cultivar. Kanto102 formed the highest amount of oxidized lipids, and Yumeyutaka and Ichihime formed the lowest. With Kanto102 and Kyushu119, high amounts of keto fatty acids were formed, while they were undetectable with Yumeyutaka and Ichihime. Due to the lack of lipoxygenases in Ichihime, an accumulation of free fatty acids was expected; however, their amount in Yumeyutaka was significantly lower than was expected. It is suggested that a pathway existed to form C6-volatiles through hydroperoxides in the esterified form.     

Oxylipin analysis methods

Practical guidelines for monitoring and measuring compounds such as jasmonates, ketols, ketodi(tri)enes and hydroxy-fatty acids as well as detecting the presence of novel oxylipins are presented. Additionally, a protocol for the penetrant analysis of non-enzymatic lipid oxidation is described. Each of the methods, which employ gas chromatography/mass spectrometry, can be applied without specialist knowledge or recourse to the latest analytical instrumentation. Additional information on oxylipin quantification and novel protocols for preparing oxygen isotope-labelled internal standards are provided. Four developing areas of research are identified: (i) profiling of the unbound cellular pools of oxylipins; (ii) profiling of esterified oxylipins and/or monitoring of their release from parent lipids; (iii) monitoring of non-enzymatic lipid oxidation; (iv) analysis of unstable and reactive oxylipins. The methods and protocols presented herein are designed to give technical insights into the first three areas and to provide a platform from which to enter the fourth area.     

Oxylipin profiling in pathogen-infected potato leaves

Plants respond to pathogen attack with a multicomponent defense response. Synthesis of oxylipins via the lipoxygenase (LOX) pathway appears to be an important factor for establishment of resistance in a number of pathosystems. In potato cells, pathogen-derived elicitors preferentially stimulate the 9-LOX-dependent metabolism of polyunsaturated fatty acids (PUFAs). Here we show by oxylipin profiling that potato plants react to pathogen infection with increases in the amounts of the 9-LOX-derived 9,10,11- and 9,12,13-trihydroxy derivatives of linolenic acid (LnA), the divinyl ethers colnelenic acid (CnA) and colneleic acid (CA) as well as 9-hydroxy linolenic acid. Accumulation of these compounds is faster and more pronounced during the interaction of potato with the phytopathogenic bacterium Pseudomonas syringae pv. maculicola, which does not lead to disease, compared to the infection of potato with Phytophthora infestans, the causal agent of late blight disease. Jasmonic acid (JA), a 13-LOX-derived oxylipin, accumulates in potato leaves after infiltration with P. syringae pv. maculicola, but not after infection with P. infestans.     

Oxylipin and mitochondrion probes to track yeast sexual cells

When oxylipin and mitochondrion probes, i.e., fluorescing antibodies specific for 3-hydroxy fatty acids (3-OH oxylipins) and rhodamine 123 (Rh123), were added to yeast cells, these probes accumulated mainly in the sexual cells (i.e., both associated with ascospores) and not in the vegetative cells. This suggests increased mitochondrial activity in asci, since 3-OH oxylipins are mitochondrially produced and it is known that Rh123 accumulates selectively in functional mitochondria that maintain a high transmembrane potential (Delta Psi m). This increased activity may be necessary for the production and effective release of the many spores found in single-celled asci. These results may be useful in the rapid identification of asci and in yeast sexual spore mechanics, which may find application in yeast systematics as well as hydro-, aero-, and nano-technologies.     

Nodule carbohydrate metabolism and polyols involvement in the response of Medicago sativa to salt stress

Alterations of plant growth, chlorophyll fluorescence parameters, nodule carbon metabolism and polyols concentration as result of salt stress were examined in alfalfa (Medicago sativa). Plants, in symbiosis with Sinorhizobium meliloti GR4 strain, were grown under controlled conditions for 35 days (DAS) and subjected to 150 mM of NaCl stress. Plant biomass (PDW) and nitrogen fixation rate (NFR) were markedly affected by salt stress conditions; the highest reductions of PDW (50%) and NFR (40%) were registered at 84 DAS and 56 DAS, respectively. In addition, salinity affected the chlorophyll fluorescence parameters, decreased initial chlorophyll fluorescence (F₀) and increased the optimum quantum yield of PSII (F_v/F_m ratio). The enzyme activities sucrose synthase activity and phosphoenolpyruvate carboxylase, responsible for the carbon supply to the bacteroids by the formation of dicarboxylates, were drastically inhibited by salinity, mainly at 56 DAS with the beginning of flowering. The content of total soluble sugars and proline increased under salt stress, and these concentrations were higher in nodule than in leaf. This last result suggests that the nodule is an organ specially protected in order to maintain its functioning, even under stress conditions. Besides, the content of myoinositol and pinitol in leaves and nodules changed with the plant growth stage and the saline treatment. Under salinity stress, the concentrations of pinitol in nodule were higher than in leaf, which supports the central function of this molecule in the adaptive response of nodules to salt stress. The increase of pinitol synthesis in nodule of M. sativa under salt stress could be one of the adaptive features used by the plant.     

Axial and Radial Oxylipin Transport

Jasmonates are oxygenated lipids (oxylipins) that control defense gene expression in response to cell damage in plants. How mobile are these potent mediators within tissues? Exploiting a series of 13-lipoxygenase (13-lox) mutants in Arabidopsis (Arabidopsis thaliana) that displays impaired jasmonic acid (JA) synthesis in specific cell types and using JA-inducible reporters, we mapped the extent of the transport of endogenous jasmonates across the plant vegetative growth phase. In seedlings, we found that jasmonate (or JA precursors) could translocate axially from wounded shoots to unwounded roots in a LOX2-dependent manner. Grafting experiments with the wild type and JA-deficient mutants confirmed shoot-to-root oxylipin transport. Next, we used rosettes to investigate radial cell-to-cell transport of jasmonates. After finding that the LOX6 protein localized to xylem contact cells was not wound inducible, we used the lox234 triple mutant to genetically isolate LOX6 as the only JA precursor-producing LOX in the plant. When a leaf of this mutant was wounded, the JA reporter gene was expressed in distal leaves. Leaf sectioning showed that JA reporter expression extended from contact cells throughout the vascular bundle and into extravascular cells, revealing a radial movement of jasmonates. Our results add a crucial element to a growing picture of how the distal wound response is regulated in rosettes, showing that both axial (shoot-to-root) and radial (cell-to-cell) transport of oxylipins plays a major role in the wound response. The strategies developed herein provide unique tools with which to identify intercellular jasmonate transport routes.Both animals and plants produce potently active lipid-derived mediators in response to wounding. These oxylipins (oxygenated lipid derivatives) include leukotrienes and prostaglandins in animals (Funk, 2001) and jasmonates in plants (Wasternack and Hause, 2013). Although these regulators frequently show structural similarities (many are cyclopentenone and cyclopentanone lipids), they operate through different signaling pathways often involving large protein complexes. For example, prostaglandins signal in part through G protein-coupled receptor complexes (Furuyashiki and Narumiya, 2011; Kalinski, 2012), and plant jasmonate signaling operates through the Skp/Cullin/F-box CORONATINE INSENSITIVE1 complex (Browse, 2009). Many oxylipins produced in response to tissue damage in metazoans act as paracrine signals to elicit defense responses in distal undamaged cells (Funk, 2001). Similarly, it is possible that jasmonates, including the biologically active derivative jasmonoyl-Ile (JA-Ile; Fonseca et al., 2009), might be transported from cell to cell in plants. However, to date, the majority of studies on oxylipin transport in plants have used exogenous jasmonates, and it remains unclear to what extent these compounds are transported between cells and tissues when produced endogenously.Based on the fact that jasmonic acid (JA) or methyl jasmonate treatments can affect defense gene expression at a distance to the sites of their application, JA was proposed to operate as a paracrine signal capable of being transported from cell to cell in tomato (Solanum lycopersicum) leaves (Farmer et al., 1992). Similar conclusions were drawn for JA in wild tobacco (Nicotiana sylvestris; Zhang and Baldwin, 1997). Isotope-labeling experiments using exogenous jasmonates have indicated JA/JA-Ile transport away from the site of application to distal tissues and even distal organs (Zhang and Baldwin, 1997; Thorpe et al., 2007; Sato et al., 2011). Additionally, grafting experiments in tomato were consistent with long-distance transport of JA/JA precursors (Li et al., 2002; Schilmiller and Howe, 2005), although other studies did not find evidence for JA transport from wounded leaves to distal unwounded leaves (Strassner et al., 2002). Concerning Arabidopsis (Arabidopsis thaliana), Koo et al. (2009) concluded that JA-Ile accumulation detected in leaves distal to the wound site resulted mainly from de novo synthesis in undamaged leaves rather than from the transport of JA/JA-Ile from the wound site. Recently, a transporter (GLUCOSINOLATE TRANSPORTER1) capable of importing JA-Ile (but not JA) into Xenopus laevis oocytes has been described (Saito et al., 2015), further supporting the possibility that jasmonates move between cells.In addition to the transport of jasmonates, there is much evidence consistent with other wound signaling mechanisms that lead to JA synthesis and JA-mediated defense responses at various distances from wounds. That is, wound-activated signaling pathways can be classified as those working near the damage site (i.e. local responses) and those operating distal to it (Rhodes et al., 2006; Wu et al., 2007). Both these types of wound responses can be difficult to study, because several types of events (including the transport of jasmonates) may contribute to JA signaling. However, there has been some progress in understanding long-distance signaling leading to distal wound responses. These mechanisms include electrical and potentially, hydraulic signaling (for review, see Koo and Howe, 2009; Farmer et al., 2014). Membrane hyperpolarizations have been recorded in wounded plants (Zimmermann et al., 2009); however, their relationship with JA synthesis or JA responses has not yet been reported. In Arabidopsis, wounding of adult-phase rosettes stimulates the leaf-to-leaf propagation of signals that (1) can be detected with surface electrodes as cell membrane depolarizations; (2) are propagated from leaf to leaf in a mechanism that requires several clade 3 GLUTAMATE RECEPTOR-LIKE (GLR) genes, including GLR3.3 and GLR3.6; and (3) can induce JA and JA-Ile accumulation in distal unwounded sites (Mousavi et al., 2013). However, even when electrical signals were compromised in both the wounded and distal leaves of a glr3.3 glr3.6 double mutant, JA responses were affected only in the distal leaf; local responses in the damaged leaf itself were similar to the wild type (Mousavi et al., 2013). Therefore, certain clade 3 GLRs operate in rosette-stage plants to extend the range of the wound response, and even if these genes are mutated, wounded rosette leaves still produce jasmonates. In summary, both jasmonates made near wounds and jasmonates made far from wounds in response to distal signals might be subject to transport within the plant.This study focused on the mobility of endogenous jasmonates produced in response to wounding. Here, we ask: how mobile are endogenous jasmonates generated in aboveground tissues in response to wounding? Our analysis was conducted throughout the vegetative phase and included different tissues that ranged from embryonic leaves (cotyledons) and roots to expanded rosette leaves. We investigated whether a glr3.3 glr3.6 double mutant that reduces leaf-to-leaf signal propagation in the adult phase (Mousavi et al., 2013) could also reduce cotyledon-to-root wound signaling in seedlings. Results from these electrophysiology experiments then led us to investigate whether JA (or JA precursors) can translocate from wounded cotyledons to roots. To do this, we used two approaches. One was based on mutants in 13-LIPOXYGENASEs (13-LOXs) that are necessary for an early step in the synthesis of the JA precursor oxophytodienoic acid. All four 13-LOXs in Arabidopsis (LOX2, LOX3, LOX4, and LOX6) are known to contribute to JA synthesis in vivo (Chauvin et al., 2013). First, LOX2 is responsible for the synthesis of a large pool of JA in wounded leaves (Bell et al., 1995), and it also produces precursors for the synthesis of arabidopside defense-related metabolites (Glauser et al., 2009). Second, LOX3 and LOX4 act together to produce the JA required for full male fertility (Caldelari et al., 2011). Third, LOX6 produces jasmonates in roots that are first separated from aerial tissues and then wounded (Grebner et al., 2013). We tested the impact of mutations in the different 13-LOXs on root JA signaling after cotyledon wounding. This was followed by grafting experiments between the wild type and the JA-deficient mutant allene oxide synthase (aos; Park et al., 2002) to test whether JA (or JA precursors) could translocate axially from wounded shoots into undamaged roots.In addition to its role in wounded roots (Grebner et al., 2013), LOX6 has been implicated in long-distance wound signaling in the adult-phase rosette, where it is necessary for most of the rapid distal expression of the JA-responsive gene JASMONATE ZIM-DOMAIN10 (JAZ10) when another leaf is wounded (Chauvin et al., 2013). This and the fact that the LOX6 promoter is active principally in xylem contact cells (Chauvin et al., 2013) provided us with the opportunity to investigate oxylipin transport within leaves. We confirmed the cellular localization of the LOX6 polypeptide with a LOX6-GUS fusion protein. We then used a lox234 triple mutant expressing a JAZ10 reporter to test whether jasmonates could be exported from xylem contact cells. These experiments led to unique insights into the transport of jasmonates across different leaf cell layers.     

Changes in the metabolism of the proteoglycans from sheep articular cartilage in response to mechanical stress

The effect of altered mechanical stress on the metabolism of sheep articular cartilage has been investigated. A simple experimental model involving the immobilisation of a single sheep foreleg was used to study the effect of increased or decreased functional demand on the chemical composition of, and the incorporation of labelled acetate into, the proteoglycans of sheep articular cartilage. By immobilisation of one of the sheep forelegs, mechanical stress is removed from that particular joint, while increased stress is placed on the other foreleg. The load distribution about the two hind legs remains essentially the same. After a 4-week immobilisation period there was a significant increase in the hexuronic acid content of the cartilage from the loadbearing ankle joint, and a corresponding decrease in the hexuronic acid content of the non-loadbearing joint cartilage. Hexosamine analyses of the cartilage from each joint showed that the major chemical occurred in the chondroitin sulphate fraction. From analyses of the extracted and isolated proteoglycans from each experimental joint it was evident that there was a significant decrease in the molecular weight of the proteoglycan from the non-loadbearing joint. In vitro studies showed increased incorporation of labelled acetate into the chondroitin sulphate fraction from the loadbearing joint but a corresponding decreased incorporation into the non-loadbearing immobilised joint cartilage. These results suggest that the changes observed in the chemical composition of the cartilage from the loadbearing and non-loadbearing joints may be accounted for in part by changes in the biosynthesis of the cartilage proteoglycan in response to altered functional demand.     

Intracellular glycerol in Dunaliella is depleted by intracellular metabolism in response to hypoosmotic stress by dilution

Abstract When Dunaliella tertiolecta cells are subjected to a dilution stress (hypoosmotic shock) the intracellular glycerol is metabolised biochemically, but it does not leak into the medium. However, Dunaliella cells have a certain 'threshold' to withstanding a hypoosmotic shock beyond which cell damage occurs and then glycerol is leaked into the medium. Both in the light or the dark, the glycerol metabolism was inhibited by micromolar concentration of carbonylcyanide m - chlorophenyl - hydrazone (CCCP) suggesting that the required ATP for the glycerol dissimilation is dependent upon an energized membrane, and most of which can be supplied through the oxidative phosphorylation.     

Trehalose metabolism in root nodules of the model legume Lotus japonicus in response to salt stress

In wheat ( Triticum aestivum L), the leaves particularly flag leaves have been considered to be the key organs contributing to higher yields, whereas awns have been considered subsidiary organs. Compared with extensive investigations on the assimilation contribution of leaves, the photosynthetic characteristics of awns have not been well studied. In this study, we investigated the ultrastructure of chloroplasts, oxygen evolution, and phosphoenolpyruvate carboxylase [phosphoenolpyruvate carboxylase (PEPCase) EC 4.1.1.31)] activity in both flag leaves and awns during the ontogenesis of wheat. Transmission electron microscope observations showed initial increases in the sizes of grana and the degree of granum stacks from the florescence-emergence stage both in flag leaves and in awns, followed by the breakdown of membrane systems after the milk-development stage. The results of oxygen evolution assays revealed that in both organs, the rate of photosynthesis increased in the first few stages and then decreased, but the decrease occurred much earlier in flag leaves than in awns. A PEPCase activity assay demonstrated that the activity of PEPCase was much higher in awns than in flag leaves throughout ontogeny; the value was particularly high at the late stages of grain filling. Our results suggest that awns play a dominant role in contributing to large grains and a high grain yield in awned wheat cultivars, particularly during the grain-filling stages.