Changes in Hexokinase Activity in Echinochloa phyllopogon and Echinochloa crus-pavonis in Response to Abiotic Stress

Hexokinase (HXK; EC 2.7.1.1) regulates carbohydrate entry into glycolysis and is known to be a sensor for sugar-responsive gene expression. The effect of abiotic stresses on HXK activity was determined in seedlings of the flood-tolerant plant Echinochloa phyllopogon (Stev.) Koss and the flood-intolerant plant Echinochloa crus-pavonis (H.B.K.) Schult grown aerobically for 5 d before being subjected to anaerobic, chilling, heat, or salt stress. HXK activity was stimulated in shoots of E. phyllopogon only by anaerobic stress. HXK activity was only transiently elevated in E. crus-pavonis shoots during anaerobiosis. In roots of both species, anoxia and chilling stimulated HXK activity. Thus, HXK is not a general stress protein but is specifically induced by anoxia and chilling in E. phyllopogon and E. crus-pavonis. In both species HXK exhibited an optimum pH between 8.5 and 9.0, but the range was extended to pH 7.0 in air-grown E. phyllopogon to 6.5 in N₂-grown E. phyllopogon. At physiologically relevant pHs (6.8 and 7.3, N₂ and O₂ conditions, respectively), N₂-grown seedlings retained greater HXK activity at the lower pH. The pH response suggests that in N₂-grown seedlings HXK can function in a more acidic environment and that a specific isozyme may be important for regulating glycolytic activity during anaerobic metabolism in E. phyllopogon.     

Osmotic Stress Induces Expression of Choline Monooxygenase in Sugar Beet and Amaranth

Choline monooxygenase (CMO) catalyzes the committing step in the synthesis of glycine betaine, an osmoprotectant accumulated by many plants in response to salinity and drought. To investigate how these stresses affect CMO expression, a spinach (Spinacia oleracea L., Chenopodiaceae) probe was used to isolate CMO cDNAs from sugar beet (Beta vulgaris L., Chenopodiaceae), a salt- and drought-tolerant crop. The deduced beet CMO amino acid sequence comprised a transit peptide and a 381-residue mature peptide that was 84% identical (97% similar) to that of spinach and that showed the same consensus motif for coordinating a Rieske-type [2Fe-2S] cluster. A mononuclear Fe-binding motif was also present. When water was withheld, leaf relative water content declined to 59% and the levels of CMO mRNA, protein, and enzyme activity rose 3- to 5-fold; rewatering reversed these changes. After gradual salinization (NaCl:CaCl₂ = 5.7:1, mol/mol), CMO mRNA, protein, and enzyme levels in leaves increased 3- to 7-fold at 400 mm salt, and returned to uninduced levels when salt was removed. Beet roots also expressed CMO, most strongly when salinized. Salt-inducible CMO mRNA, protein, and enzyme activity were readily detected in leaves of Amaranthus caudatus L. (Amaranthaceae). These data show that CMO most probably has a mononuclear Fe center, is inducibly expressed in roots as well as in leaves of Chenopodiaceae, and is not unique to this family.     

拟南芥ANAC055基因突变体对高盐和渗透胁迫的响应

高盐和渗透等非生物胁迫是影响农作物产量和品质的重要因素,非生物胁迫发生时,植物通过体内各类转录因子启动胁迫应答反应,进而降低非生物胁迫对植物的损伤。本研究筛选出植物特异性转录因子ANAC055编码基因的纯合T-DNA插入突变体SALK_152738,测序分析发现T-DNA插在ANAC055基因的3'UTR区域。实时荧光定量PCR结果表明叶中ANAC055基因表达量最高;与野生型相比,突变体叶、茎和花中ANAC055基因表达量分别下降了40%、50%和70%。高盐胁迫后,野生型和突变体叶中ANAC055基因表达量分别比对照上升了320%和55.4%;而渗透胁迫时,该基因叶中的表达量分别比对照下降了47.7%和56.3%;电子表达谱分析发现该基因根中的表达可受高盐和渗透等多种非生物胁迫的诱导表达。高盐和渗透胁迫时野生型和突变体幼根的生长均受到明显抑制,但高盐胁迫对突变体根生长的抑制作用比对野生型根生长的抑制作用更大。上述分析表明拟南芥ANAC055基因可受高盐和渗透等非生物胁迫的诱导表达,并且其在拟南芥幼根的生长发育过程中具有一定的作用,本研究有助于进一步明确其在非生物胁迫过程中的作用。     

Dim-Red-Light-Induced Increase in Polar Auxin Transport in Cucumber Seedlings : I. Development of Altered Capacity, Velocity, and Response to Inhibitors

We have developed and characterized a system to analyze light effects on auxin transport independent of photosynthetic effects. Polar transport of [³H]indole-3-acetic acid through hypocotyl segments from etiolated cucumber (Cucumis sativus L.) seedlings was increased in seedlings grown in dim-red light (DRL) (0.5 μmol m⁻² s⁻¹) relative to seedlings grown in darkness. Both transport velocity and transport intensity (export rate) were increased by at least a factor of 2. Tissue formed in DRL completely acquired the higher transport capacity within 50 h, but tissue already differentiated in darkness acquired only a partial increase in transport capacity within 50 h of DRL, indicating a developmental window for light induction of commitment to changes in auxin transport. This light-induced change probably manifests itself by alteration of function of the auxin efflux carrier, as revealed using specific transport inhibitors. Relative to dark controls, DRL-grown seedlings were differentially less sensitive to two inhibitors of polar auxin transport, N-(naphth-1-yl) phthalamic acid and 2,3,5-triiodobenzoic acid. On the basis of these data, we propose that the auxin efflux carrier is a key target of light regulation during photomorphogenesis.     

Cloning and Characterization of AtRGP1 : A Reversibly Autoglycosylated Arabidopsis Protein Implicated in Cell Wall Biosynthesis

A reversibly glycosylated polypeptide from pea (Pisum sativum) is thought to have a role in the biosynthesis of hemicellulosic polysaccharides. We have investigated this hypothesis by isolating a cDNA clone encoding a homolog of Arabidopsis thaliana, Reversibly Glycosylated Polypeptide-1 (AtRGP1), and preparing antibodies against the protein encoded by this gene. Polyclonal antibodies detect homologs in both dicot and monocot species. The patterns of expression and intracellular localization of the protein were examined. AtRGP1 protein and RNA concentration are highest in roots and suspension-cultured cells. Localization of the protein shows it to be mostly soluble but also peripherally associated with membranes. We confirmed that AtRGP1 produced in Escherichia coli could be reversibly glycosylated using UDP-glucose and UDP-galactose as substrates. Possible sites for UDP-sugar binding and glycosylation are discussed. Our results are consistent with a role for this reversibly glycosylated polypeptide in cell wall biosynthesis, although its precise role is still unknown.The primary cell wall of dicot plants is laid down by young cells prior to the cessation of elongation and secondary wall deposition. Making up to 90% of the cell''s dry weight, the extracellular matrix is important for many processes, including morphogenesis, growth, disease resistance, recognition, signaling, digestibility, nutrition, and decay. The composition of the cell wall has been extensively described (Bacic et al., 1988; Levy and Staehelin, 1992; Zablackis et al., 1995), and yet many questions remain unanswered regarding the synthesis and interaction of these components to provide cells with a functional wall (Carpita and Gibeaut, 1993; Carpita et al., 1996).Heteropolysaccharide biosynthesis can be divided into four steps: (a) chain or backbone initiation, (b) elongation, (c) side-chain addition, and (d) termination and extracellular deposition (Waldron and Brett, 1985). The similarity between various polysaccharide backbones leads to the prediction that the synthesizing machinery would be conserved between them. For example, the backbone of xyloglucan polymers, β-1,4 glucan, can be synthesized independently of or concurrently with side-chain addition (Campbell et al., 1988; White et al., 1993), and this polymer and the chains that make up cellulose are identical. The later addition of side chains to xyloglucan are catalyzed by specific transferases (Kleene and Berger, 1993) such as xylosyltransferase (Campbell et al., 1988), galactosyltransferase, and fucosyltransferase (Faïk et al., 1997), all of which are localized to the Golgi compartment (Brummell et al., 1990; Driouich et al., 1993; Staehelin and Moore, 1995).The enzymes involved in wall biosynthesis have been recalcitrant to isolation (Carpita et al., 1996; Albersheim et al., 1997). Only recently has the first gene encoding putative cellulose biosynthetic enzymes, celA, been isolated from cotton (Gossypium hirsutum) and rice (Oryza sativa; Pear et al., 1996).During studies of polysaccharide synthesis in pea (Pisum sativum) Golgi membranes, Dhugga et al. (1991) identified a 41-kD protein doublet that they suggested was involved in polysaccharide synthesis. The authors showed that this protein could be glycosylated by radiolabeled UDP-Glc but that this labeling could be reversibly competed with by unlabeled UDP-Glc, UDP-Xyl, and UDP-Gal, the sugars that make up xyloglucan (Hayashi, 1989). The 41-kD protein was named PsRGP1 (P. sativum Reversibly Glycosylated Polypeptide-1; Dhugga et al., 1997). Furthermore, the conditions that stimulate or inhibit Golgi-localized β-glucan synthase activity are the same conditions that stimulate or inhibit the glycosylation of PsRGP1 (Dhugga et al., 1991). To address the role of this protein in polysaccharide synthesis, the authors purified the polypeptides and obtained the sequences from tryptic peptides (Dhugga and Ray, 1994). Antibodies raised against PsRGP1 showed that it is soluble and localized to the plasma membrane (Dhugga et al., 1991) and Golgi compartment (Dhugga et al., 1997). In addition to its Golgi localization, the steady-state glycosylation of PsRGP1 is approximately 10:7:3 (UDP-Glc:-Xyl:-Gal), which is similar to the typical sugar composition of xyloglucan (1.0:0.75:0.25; Dhugga et al., 1997).We were interested in studying various aspects of cell wall metabolism, including the synthesis of polysaccharides and their delivery to the cell wall. Studies in pea have shown that a 41-kD protein may be involved in cell wall polysaccharide synthesis, possibly that of xyloglucan (Dhugga et al., 1997). Here we report the characterization of AtRGP1 (Arabidopsis thaliana Reversibly Glycosylated Polypeptide-1), a soluble protein that can also be found weakly associated with membrane fractions, most likely the Golgi fraction. The reversible nature of the glycosylation of this Arabidopsis homolog by the substrates used to make polysaccharides (nucleotide sugars) suggests a possible role for AtRGP1 in polysaccharide biosynthesis.     

Interaction of Osmotic Stress, Temperature, and Abscisic Acid in the Regulation of Gene Expression in Arabidopsis

The impact of simultaneous environmental stresses on plants and how they respond to combined stresses compared with single stresses is largely unclear. By using a transgene (RD29A-LUC) consisting of the firefly luciferase coding sequence (LUC) driven by the stress-responsive RD29A promoter, we investigated the interactive effects of temperature, osmotic stress, and the phytohormone abscisic acid (ABA) in the regulation of gene expression in Arabidopsis seedlings. Results indicated that both positive and negative interactions exist among the studied stress factors in regulating gene expression. At a normal growth temperature (22°C), osmotic stress and ABA act synergistically to induce the transgene expression. Low temperature inhibits the response to osmotic stress or to combined treatment of osmotic stress and ABA, whereas low temperature and ABA treatments are additive in inducing transgene expression. Although high temperature alone does not activate the transgene, it significantly amplifies the effects of ABA and osmotic stress. The effect of multiple stresses in the regulation of RD29A-LUC expression in signal transduction mutants was also studied. The results are discussed in the context of cold and osmotic stress signal transduction pathways.     

Short-Lived and Phosphorylated Proteins Contribute to Carrier-Mediated Efflux, but Not to Influx, of Auxin in Suspension-Cultured Tobacco Cells

Auxin is transported across the plasma membrane of plant cells by diffusion and by two carriers operating in opposite directions, the influx and efflux carriers. Both carriers most likely play an important role in controlling auxin concentration and distribution in plants but little is known regarding their regulation. We describe the influence of modifications of the transmembrane pH gradient and the effect of agents interfering with protein synthesis, protein traffic, and protein phosphorylation on the activity of the auxin carriers in suspension-cultured tobacco (Nicotiana tabacum L.) cells. Carrier-mediated influx and efflux were monitored independently by measuring the accumulation of [¹⁴C]2,4-dichlorophenoxyacetic acid and [³H]naphthylacetic acid, respectively. The activity of the influx carrier decreased on increasing external pH and on decreasing internal pH, whereas that of the efflux carrier was only impaired on internal acidification. The efflux carrier activity was inhibited by cycloheximide, brefeldin A, and the protein kinase inhibitors staurosporine and K252a, as shown by the increased capability of treated cells to accumulate [³H]naphthylacetic acid. Kinetics and reversibility of the effect of brefeldin A were consistent with one or several components of the efflux system being turned over at the plasma membrane with a half-time of less than 10 min. Inhibition of efflux by protein kinase inhibitors suggested that protein phosphorylation was essential to sustain the activity of the efflux carrier. On the contrary, the pharmacological agents used in this study failed to inhibit [¹⁴C]2,4-dichlorophenoxyacetic acid accumulation, suggesting that rapidly turned-over proteins or proteins activated by phosphorylation are not essential to carrier-mediated auxin influx. Our data support the idea that the efflux carrier in plants constitutes a complex system regulated at multiple levels, in marked contrast with the influx carrier. Physiological implications of the kinetic features of this regulation are discussed.     

A Quantitative Study of the Hog1 MAPK Response to Fluctuating Osmotic Stress in Saccharomyces cerevisiae

Background

Yeast cells live in a highly fluctuating environment with respect to temperature, nutrients, and especially osmolarity. The Hog1 mitogen-activated protein kinase (MAPK) pathway is crucial for the adaption of yeast cells to external osmotic changes.

Methodology/Principal Findings

To better understand the osmo-adaption mechanism in the budding yeast Saccharomyces cerevisiae, we have developed a mathematical model and quantitatively investigated the Hog1 response to osmotic stress. The model agrees well with various experimental data for the Hog1 response to different types of osmotic changes. Kinetic analyses of the model indicate that budding yeast cells have evolved to protect themselves economically: while they show almost no response to fast pulse-like changes of osmolarity, they respond periodically and are well-adapted to osmotic changes with a certain frequency. To quantify the signal transduction efficiency of the osmo-adaption network, we introduced a measure of the signal response gain, which is defined as the ratio of output change integral to input (signal) change integral. Model simulations indicate that the Hog1 response gain shows bell-shaped response curves with respect to the duration of a single osmotic pulse and to the frequency of periodic square osmotic pulses, while for up-staircase (ramp) osmotic changes, the gain depends on the slope.

Conclusions/Significance

The model analyses suggest that budding yeast cells have selectively evolved to be optimized to some specific types of osmotic changes. In addition, our work implies that the signaling output can be dynamically controlled by fine-tuning the signal input profiles.     

Differential Response to Root-Knot Nematodes in Prunus Species and Correlative Genetic Implications

Responses of 17 Prunus rootstocks or accessions (11 from the subgenus Amygdalus and 6 from the subgenus Prunophora) were evaluated against 11 isolates of Meloidogyne spp. including one M. arenaria, four M. incognita, four M. javanica, one M. hispanica, and an unclassified population from Florida. Characterization of plant response to root-knot nematodes was based on a gall index rating. Numbers of females and juveniles plus eggs in the roots were determined for 10 of the rootstocks evaluated against one M. arenaria, one M. incognita, one M. javanica, and the Florida isolate. These 10 rootstocks plus Nemaguard and Nemared were retested by growing three different rootstock genotypes together in containers of soil infested individually with each of the above four isolates. Garfi and Garrigues almonds, GF.305 and Rutgers Red Leaf peaches, and the peach-almond GF.677 were susceptible to all isolates. Differences in resistance were detected among the other rootstocks of the subgenus Amygdalus. The peach-almond GF.557 and Summergrand peach were resistant to M. arenaria and M. incognita but susceptible to M. javanica and the Florida isolate. Nemaguard, Nemared, and its two hybrids G x N no. 15 and G x N no. 22 were resistant to all but the Florida isolate. In the subgenus Prunophora, Myrobalan plums P.1079, P.2175, P.2980, and P.2984; Marianna plum 29C; and P. insititia plum AD.101 were resistant to all isolates. Thus, two different genetic systems of RKN resistance were found in the subgenus Amygdalus: one system acting against M. arenaria and M. incognita, and another system also acting against M. javanica. Prunophora rootstocks bear a complete genetic system for resistance also acting against the Florida isolate. The hypotheses on the relationships between these systems and the corresponding putative genes of resistance are presented.