Changes of antioxidants and GSH-associated enzymes in isoproturon-treated maize

The recommended field dose (RFD) of isoproturon induced significant accumulations of H₂O₂ in the leaves of 10-d-old maize seedlings throughout the following 20 d; the accumulation increased with time and also with herbicide dose. Meanwhile, low doses significantly increased ascorbic acid, glutathione and thiols while high doses caused diminutions. Superoxide dismutase (SOD; EC 1.15.1.1) activity was significantly enhanced up to the 12th d whereas ascorbate peroxidase (APX; EC 1.11.1.7) activity was significantly reduced after the fourth d onwards. Catalase (CAT; EC 1.11.1.6) and guaiacol peroxidase (GPX; EC 1.11.1.7) activities were similarly increased during the first 4 d but decreased from the 12th and the eighth d, respectively. Low doses increased SOD and GPX activities but high doses led to diminutions whereas CAT and APX were reduced by all doses. The activities of γ-glutamyl-cysteine synthethase (γ-GCS; EC 6.3.2.2) and glutathione synthethase (GSS; EC 6.3.2.3) were enhanced for 4 d; high doses caused general reductions. Isoproturon significantly reduced activities of glutathione S-transferase (GST; EC 2.5.1.18) isoforms [GST_(CDNB), GST_(ALA), or GST_(MET)] after the fourth d, however, it had no effect on GST_(ATR). Similar reductions in activities of glutathione peroxidase (GSPX; EC 1.15.1.1) and glutathione reductase (GR; EC 1.6.4.2) were detected up to the 16th and the 12th d, respectively. The activities of GST isoforms, GSPX and GR were reduced by high doses. These changes seemed to be related and might point to an oxidative stress state that exacerbated with prolonged time and/or increased isoproturon dose.     

Enzymatic response to cadmium by Impatiens glandulifera: A preliminary investigation

This paper aims to develop our understanding of the effect of cadmium (Cd) on Impatiens glandulifera, a recently identified potential Cd hyperaccumulator. Impatiens glandulifera plants were exposed to three concentrations of Cd (20, 60 and 90 mg/kg) and were sampled at two timepoints (one and seven days) to investigate the stress response of I. glandulifera to Cd. Cd can induce oxidative stress in plants, triggering overproduction of reactive oxygen species (ROS). The level of activity of catalase (CAT) and ascorbate peroxidase (APX), two crucial antioxidant enzymes responsible for detoxifying ROS, were found to increase in a concentration dependent manner. Though there was no change observed in the level of superoxide dismutase (SOD) activity, the activity of glutathione S-transferase (GST), involved in detoxifying and sequestering Cd, increased after exposure to Cd. Cd did not appear to impact the levels of proline and photosynthetic pigments, indicating the plants weren't stressed by the presence of Cd. These results suggest that the rapid response observed in enzyme activity aid the efficacious mitigation of the toxic effects of Cd, preventing significant physiological stress in I. glandulifera.     

Reactive oxygen species and antioxidants: Relationships in green cells

The imposition of oxidative stress leads to increased production of reactive oxygen species (ROS) in plant cells. Orchestrated defense processes ensue that have much in common between stresses, yet are also particular to the site of action of the stress and its concentration. Possible functional roles of these responses include, but are not restricted to, the protection of the photosynthetic machinery, the preservation of membrane integrity and the protection of DNA and proteins. Superimposed upon our understanding of cellular mechanisms for protection against abiotic stress is a newly discovered role of ROS in signalling and defense response to pathogens (J. L. Dangl, R. A. Dietrich and M. S. Richberg. 1996. Plant Cell 8: 1793–1807). Evidence to date suggests a coordinated response to ROS among different members of the superoxide dismutase (SOD) gene families. A further layer of complexity is afforded by reports of coordination of expression between ascorbate peroxidase and SOD genes. Our understanding of the signalling mechanisms that underlie these coordinated events is in its infancy. An exciting future lies ahead in which the orchestration of successful antioxidant stress responses will be gradually revealed. Current data suggest that complex regulatory mechanisms function at both the gene and protein level to coordinate antioxidant responses and that a critical role is played by organellar localization and inter-compartment coordination.     

Retention of functional characteristics of glutathione-S-transferase and lactate dehydrogenase-A in fusion protein

A paradigm shift toward fusion proteins to render multiple functionalities and applications on a single platform has been incurred in enzyme based diagnosis. Herein, we report development and systematic characterizations of glutathione-S-transferase (GST) and human lactate dehydrogenase A (hLDHA) in a fusion protein (GST–hLDHA) to achieve functional activities of GST and hLDHA simultaneously. The GST-pGEX-4T-2 vector system was used for cloning and purification of hLDHA, utilizing the affinity based interaction between GST and GSH in column chromatography. Bacterially purified protein was subjected to the Western blot analysis and structural analysis by circular dichroism spectroscopy, which revealed intact structural framework of the fusion construct. Kinetic characterization of the fusion GST–hLDHA protein toward GSH and NADH, suggested retention of functional activities of GST and hLDHA in fused protein as indicated by the kinetic parameters k_m and k_cat/k_m. Further analysis of effect of temperature and pH on GST–hLDHA activity revealed maximum activity around human physiological conditions (37°C and pH 8). Preservation of the structural and functional characteristics of the fusion enzyme paves the way for potential application for the detection of NADH and GSH in conjunction as biomarkers for cancer diagnosis.     

Structural analysis of a maize gene coding for glutathione-S-transferase involved in herbicide detoxification

Summary We have used the cDNA clone encoding maize glutathione-S-transferase (GST I) to isolate a genomic DNA clone containing the complete GST I gene. Nucleotide sequence analysis of the cDNA and genomic clones has yielded a complete amino acid sequence for maize GST I and provided the exon-intron map of its gene. The mRNA homologous sequences in the maize GST I gene consist of a 107 bp 5 untranslated region, a 642 bp coding region and 340 bp of the 3 untranslated region. They are divided into three exons by two introns which interrupt the coding region. The 5 untranslated spacer contains an unusual sequence of pentamer AGAGG repeated seven times. The inbred maize line (Missouri 17) contains a single gene for GST I, whereas the hybrid line (3780A) contains two genes. Nucleotide sequence analysis of the primer extended cDNA products reveals that the 5 untranslated regions of the two genes in the hybrid 3780A are identical except for a 6 bp internal deletion (or insertion). The amino acid sequence of maize GST I shares no apparent sequence homology with the published sequences of animal GST's and represents the first published sequence of a plant GST. re]19850813 ac]19851126     

Uptake kinetics of iron-phytosiderophores in two maize genotypes differing in iron efficiency

Iron inefficiency in the maize ( Zea mays L.) mutant ysl is caused by a defect in the uptake system for Fe-phytosiderophores. To characterize this defect further, the uptake kinetics of Fe-phytosiderophores in ysl was compared to the Fe-efficient maize cultivar Alice. Short-term uptake of ⁵⁹Fe-labeled Fe-deoxymugineic acid (Fe-DMA) was measured over a concentration range of 0.03 to 300 μM. Iron uptake in Fe-deficient plants followed Michaelis-Menten kinetics up to about 30 μM and was linear at higher concentrations, indicating two kinetically distinct components in the uptake of Fe-phytosiderophores. The saturable component had similar K_m (∼ 10 μM) in both genotypes. In contrast. V_max was 5.5 μmol Fe-DMA g⁻¹ dry weight [30 min]⁻¹ in Alice, but only 0.6 μmol Fe-DMA g⁻¹ dry weight [30 min]⁻¹ in _ysl. Uptake experiments with double-labeled ⁵⁹Fe-[¹⁴C]DMA suggest that in both cultivars Fe-DMA was taken up by the roots as the intact chelate. The results indicate the existence of a high-affinity and a low-affinity uptake system mediating Fe-phytosiderophore transport across the root plasma membrane in maize. Apparently, the mutation responsible for Fe inefficiency in ysl affected high-affected uptake and led to a decrease in activity and/or number of Fe-phytosiderophore transporters.     

Changes in glutathione and phytochelatins in roots of maize seedlings exposed to cadmium

The effects of excess Cd on the contents of free cysteine, total glutathione and phytochelatin (PC) were measured in roots of intact maize seedlings. Exposure to 3 /tmM Cd for 15 min caused PCs to appe substrates for formation of longer PCs. Total glutathione levels declined with PC synthesis, free cysteine contents changed little. The reactions to excess Cd differed along the length of roots. In the 1 cm apical region a high production of PCs occurred with a moderate loss of total glutathione. In the mature region, PC content was 2.5-fold less than in apices, several unidentified thiols accumulated, and total glutathione levels declined drastically. Exposure to 0.05 μM Cd for 24 h induced PCs, the contents rose as Cd concentrations were increased. The roots produced PCs in excess of that required to chelate the Cd present, as if some PCs were compartmentalized or had not yet formed Cd-PC complexes. Phytochelatin formation was stimulated most effectively by Cd, less by Zn and Cu and negligibly by Ni. Total glutathione declined with Cd and Zn exposure, however, with excess Cu the roots contained 45% more total glutathione than did the controls.     

Differential response to paraquat induced oxidative stress in two rice cultivars on antioxidants and chlorophyll a fluorescence

The responses of antioxidative system and photosystem II photochemistry of rice (Oryza sativa L.) to paraquat induced oxidative stress were investigated in a chilling-tolerant cultivar Xiangnuo no. 1, and a chilling-susceptible cultivar, IR-50. Electrolyte leakage and malondialdehyde (MDA) content of Xiangnuo no. 1 were little affected by paraquat, but they increased in IR-50. After paraquat treatment, superoxide dismutase (SOD) activity remained high in Xiangnuo no. 1, while it declined in IR-50. Activities of catalase (CAT), ascorbate peroxidase (APX) and glutathione reductase (GR) declined with oxidative stress in both cultivars, but Xiangnuo no. 1 had higher GR activity than IR-50. Under paraquat induced oxidative stress, ascorbic acid (AsA) and reduced glutathione (GSH) concentrations remained high in Xiangnuo no. 1, but decreased in IR-50. The results indicated that higher activities of SOD and GR and higher contents of AsA and GSH in Xiangnuo no. 1 under paraquat induced oxidative stress were associated with its tolerance to paraquat, while paraquat induced damage to IR-50 was related to decreased activities of SOD, APX and GR and contents of AsA and GSH. F _v/F _m, Φ _PSII, and qP remained high in Xiangnuo no. 1, while they decreased greatly in IR-50 under paraquat induced oxidative stress.     

Yield of tomato and maize in response to foliar and root applications of triacontanol

Triacontanol applied to tomato plants as a foliar spray caused a significant increase in total yield and yield per plant. When triacontantol was added to the growth medium, only a temporary increase in yield and number of fruits was observed. The yield of maize was unaffected by triacontanol, either applied to the leaves or to the growth substrate. These results support an earlier observation that a reduction in photorespiration is involved in the regulatory function of triacontanol, since only the yield of tomato, a C₃ plant, was increased. The application method was an important factor in it's effectiveness.     

Changes in the photosynthetic light response curve during leaf development of field grown maize with implications for modelling canopy photosynthesis

Changes in the photosynthetic light-response curve during leaf development were determined for the fourth leaf of maize crops sown on 23 April and 10 June. Temperatures were unusually mild during late spring/early summer and neither crop experienced chilling damage. The concept of thermal time was used to take into account the effects of different temperature regimes on developmental stage, thereby enabling photosynthetic light-response data to be combined for both crops to describe the general response. Large variations in the upper asymptote (A_sat) and convexity () of the light-response curve occurred during leaf development, but the maximum quantum yield of CO₂ assimilation remained relatively constant throughout. Dark respiration rates showed a small but significant decrease with leaf age and generally ranged between 5 and 10% of A_sat. A simple mathematical model was developed to assess the sensitivity of daily leaf photosynthesis (A_L) to reductions in the A_sat, and the initial slope () of the light-response curve at different stages of leaf development. On bright sunny days, and at all developmental stages, A_L was ca. twice as sensitive to reductions in A_sat than to reductions in and . In overcast conditions, however, all three parameters contributed significantly to reductions in leaf photosynthesis, although the contribution of was greatest during early leaf growth, while older leaves were most sensitive to depressions in A_sat. The implications of these results for modelling the sensitivity of canopy photosynthesis to chill-induced photoinhibition of the light-response curve are discussed.     

Auxin transport in maize roots in response to localized nitrate supply

Background and Aims

Roots typically respond to localized nitrate by enhancing lateral-root growth. Polar auxin transport has important roles in lateral-root formation and growth; however, it is a matter of debate whether or how auxin plays a role in the localized response of lateral roots to nitrate.

Methods

Treating maize (Zea mays) in a split-root system, auxin levels were quantified directly and polar transport was assayed by the movement of [³H]IAA. The effects of exogenous auxin and polar auxin transport inhibitors were also examined.

Key Results

Auxin levels in roots decreased more in the nitrate-fed compartment than in the nitrate-free compartment and nitrate treatment appeared to inhibit shoot-to-root auxin transport. However, exogenous application of IAA only partially reduced the stimulatory effect of localized nitrate, and auxin level in the roots was similarly reduced by local applications of ammonium that did not stimulate lateral-root growth.

Conclusions

It is concluded that local applications of nitrate reduced shoot-to-root auxin transport and decreased auxin concentration in roots to a level more suitable for lateral-root growth. However, alteration of root auxin level alone is not sufficient to stimulate lateral-root growth.     

Expression of rat liver glutathione-S-transferase GSTA5 in cell lines provides increased resistance to alkylating agents and toxic aldehydes

The glutathione-S-transferases (GST) are a major contributor to the eukaryotic cell's defences against chemical and oxidative stress. However, the role of individual GST isoenzymes in conferring resistance to xenobiotics has not been fully determined. We have examined the effect of the rat GSTA5 isoenzyme in the detoxication of alkylating agents and aldehydes by constructing a cell line in which it is stably expressed. The hamster fibroblast cell line V79 was transfected with a construct expressing GSTA5 from the CMV promoter. A stable clone (V79-GSTA5) was isolated after selecting for the neomycin phosphotransferase gene present on the introduced DNA. The cell line showed significantly increased levels of resistance towards the alkylating agents chorambucil and melphalan. Levels of resistance were 4-6-fold greater in V79-GSTA5 cells than in control cells. Increased levels of resistance were also observed towards the lipid peroxidation product acrolein (IC(50)=80 microM compared with 17 microM in control cells). The V79-GSTA5 cells also showed a 4-fold increase in resistance to trans, trans muconaldehyde (IC(50)=4 micro compared with l microM for control cells). GSTA5 did not protect against 4-hydroxynonenal, but it did provide greater levels of protection to hydrogen peroxide, with an IC(50) of 380 microM in V79-GSTA5 compared with 180 microM in control cells. In contrast, V79-GSTA5 cells were more sensitive to methyl glyoxal, suggesting that a methyl glyoxal-glutathione conjugate is more toxic that the parental compound. These data contribute towards the evaluation of the role of GSTA5 in the detoxication of these compounds.     

外源茉莉酸处理地下部对玉米化学防御反应影响的时间和浓度效应

在“高油115”玉米幼苗地下部施用4种不同浓度（10、50、100、200 μmol·L^-1）的茉莉酸3～48 h后,采用生化成分分析和基因表达分析方法,检测了处理部位（根系）和非处理部位（叶片）中防御物质及防御相关基因的表达,以探讨茉莉酸诱导玉米地下部对化学防御反应影响的时间和浓度效应.结果表明：茉莉酸处理玉米地下部对处理部位（根系）和非处理部位（叶片）化学防御反应的影响均与茉莉酸作用的时间和浓度相关.茉莉酸处理玉米地下部后,在3～12 h内就能直接诱导处理部位（根系）Bx9、PAL、PR-2a、MPI和FPS基因的表达,使得根中的丁布含量增加而总酚含量下降,其中100 μmol·L^-1茉莉酸处理浓度产生的诱导作用最强,其次是50 μmol·L^-1,再次是10 μmol·L^-1;后期诱导作用则逐渐减弱.另外,茉莉酸处理玉米地下部还能间接影响到非处理部位（叶片）的化学防御反应,50 μmol·L^-1茉莉酸在处理后3 h就能系统诱导叶片中Bx9和FPS基因的表达,使叶片的丁布含量增加;在6～24 h内则使叶片Bx9、PAL、PR-1、MPI和TPS基因表达量增加,丁布和总酚含量降低.可见,对于大部分检测指标来说,茉莉酸处理玉米地下部对地上部的间接诱导作用不如对地下部的直接诱导作用强,根系启动防御反应的时间较叶片早,同时,随着处理浓度的增加,茉莉酸对根系和叶片防御反应的诱导作用有增强趋势.     

Anomalous kinetics of sucrose uptake in maize scutellum slices1

Abstract The kinetics of sucrose uptake into maize scutellum slices showed that the uptake mechanism had a saturable component with a Km of l.5mol m^?3 sucrose. Nevertheless, uptake rate was constant (zero order) over extended periods of time until the bathing solution was nearly depleted of sucrose. It is concluded that these anomalous uptake kinetics reflect sucrose influx across the plasmalemma because of the following results: (a) Efflux of sucrose into buffer was negligible compared with uptake rate, (b) When slices were incubated in fructose, sucrose was synthesized and there was a net release of sucrose to the bathing solution until a steady-state was reached when influx and efflux were equal in magnitude. After the steady-state was reached, efflux of sucrose from the slices was nearly the same in magnitude as the estimated rate of uptake that would have occurred from bathing solutions initially containing the steady-state sucrose concentration, (c) Exchange of sucrose between bathing solution and slices was negligible compared with uptake rate, (d) Pretreatment of slices with uranyl nitrate abolished sucrose uptake, but uptake rate was re-established in these slices after treatment with HCl (pH 2). Uptake rate was set by the initial sucrose concentration of the bathing solution, and was not influenced by the level of endogenous sucrose or by the rate at which the sucrose concentration of the bathing solution declined. Abrupt increases in sucrose concentration during the uptake period increased the rate of uptake only if the concentration was increased above that at the start of the uptake period. Following abrupt decreases in sucrose concentration, there was a lag of about 30 min before uptake rate decreased greatly. If slices were washed and replaced in a fresh sucrose solution during the uptake period, a new uptake rate was set to correspond to the new initial sucrose concentration. It is suggested that the sucrose carrier has a transport site with a relatively low Km (much below 1.5mol m^?3) and that the measured Km (1.5mol m^?3) is that of a site that binds sucrose and thereby controls the rate of uptake. The low Km suggested for the transport site would explain the zero order kinetics but a model of the uptake mechanism that includes the control site cannot, as yet, be constructed from the data.