Chronic response of Anabaena fertilissima Rao, C.B. on growth, metabolites and enzymatic activities by chlorophenoxy herbicide

Study was carried out to investigate the chronic response of cyanobacteria, Anabaena fertilissima to chlorophenoxy herbicide 2,4-dichlorophynoxyacetic Acid (2,4-D) ethyl ester at different concentrations 15, 30 and 60 ppm. The influence of 2,4-D on growth (pigments), release of metabolites such as carbohydrates, protein, amino acid, phenols and nitrate reductase and glutamine synthetase activities was analyzed. The test concentrations caused a concentration-dependent decrease in pigments. Depletion in carbohydrate and protein content was registered with rise in herbicide concentrations. However, phenols were found to rise with increased herbicide concentrations but amino acids were reported to decline. The inhibition of nitrate reductase and glutamine synthetase activity was also concentration-dependent and showed more sensitivity for substituted phenoxy herbicide. This study therefore suggests that decrease in metabolite content and enzyme activity can be used as a signal of herbicide toxicity in cyanobacteria.     

Mode of action of sodium sulfanilate for control of groundnut rust (Puccinia arachidis S.) and its toxicity to the host plant (Arachis hypogaea L.)

Protection of groundnut plants against leaf rust by sodium sulfanilate is reversed by both p-aminobenzoic acid and folic acid, indicating an antifungal action based on interference with folic acid biosynthesis. Folic acid is required for growth of the pathogen. However, protection may also be associated with induced disease resistence because amino acids, particularly aspartic acid and glycine, accumulated in the host plant while there was a reduction in content of threonine and proline. These conditions are possibly unfavorable for growth of the rust fungus and susceptibility of the host plant. Sodium sulfanilate causes phytotoxicity at high concentrations by reducing chlorophyll content. This phytotoxicity is reversed by addition of p-aminobenzoic acid.     

Auswirkungen des Herbizids Basta® auf die Weinrebe und den Falschen Mehltau

A field experiment was conducted in order to analyse the effects of the herbicide Basta^® with glufosinate-ammonium as the active ingredient (that inhibits specifically the enzyme glutamine-synthetase) on the grapevine plant and the infestation with Plasmopara viticola, the downy mildew pathogen. The herbicide was applied at sublethal concentrations and the toxic effects on leaves and berries based on different quality parameters were estimated. Low concentrations of glufosinate-ammonium (<?0,625?mM) did not affect the chlorophyll and amino acid concentrations in leaves. This was also the case for the content of salicylic acid and phenolic compounds. Furthermore, must parameters such as sugars (glucose and fructose), acids (tartaric acid, malic acid, total acids and volatile acids), and alcohol (ethanol and glycerine) also remained unchanged compared to the fungicide-treated or untreated control, whereas the concentrations of nitrogenous components metabolically available to yeasts increased with increasing concentrations of glufosinate-ammonium. The amount of berries harvested at the end of the experiment depended on the glufosinate-ammonium concentration applied. The harvest was highest when glufosinate-ammonium was applied as a 0.1?mM solution and differed not significantly from the fungicide-treated control, but decreased with increasing herbicide doses. However, the infestation of leaves with P. viticola was significantly reduced by the application of the herbicide, even though not each infection was eradicated due to the non-systemic mode of action of the herbicide. The particular influence of the herbicide onto this host-parasite interaction still remains unclear. Since applications of glufosinate-ammonium at low concentrations seem not to affect grapevine plants negatively, but were able to reduce the infestation with downy mildew, the specific mode of action may reveal new alternatives for the control of fungal pathogens.     

Mutations in the acetolactate synthase genes of sulfonylurea-resistant biotypes of Lindernia spp.

Acetolactate synthase (ALS) is a key enzyme in the biosynthetic pathway of branched-chain amino acids. A mutation of the ALS gene causing amino acid substitution at the position of proline in Domain A makes ALS less sensitive to sulfonylureas, which are ALS-inhibiting herbicides. We cloned partial ALS genes from four Lindernia plants, L . dubia var. dubia , L . dubia var. major , L . micrantha and L . procumbens , for which biotypes resistant to sulfonylureas have been found in paddy fields. The clones were classified into two groups in each Lindernia plant: Als1 and Als2 . Sequencing of the clones and alignment of deduced amino acid sequences with previously reported ALS of other species suggested that the cloned region contains an intron in both Als1 and Als2 . Comparison of Als1 between resistant and susceptible biotypes showed that the proline of Domain A was replaced by alanine, serine or glutamine in all resistant biotypes of Lindernia plants, while it was conserved in all susceptible biotypes. This amino acid substitution in ALS encoded by Als1 is involved in the resistant mechanism of ALS to sulfonylurea in the four Lindernia plants.     

Glyphosate-induced metabolic changes in susceptible and glyphosate-resistant soybean (Glycine max L.) roots

Glyphosate (N-(phosphonomethyl)glycine) blocks the shikimate pathway, reducing the biosynthesis of aromatic amino acids, followed by the arrest interruption of protein production and a general metabolic disruption of the phenylpropanoid pathway. Glyphosate-resistance is conferred to soybean by incorporating a gene encoding a glyphosate-insensitive enzyme (CP4-EPSP synthase) that acts in the shikimate pathway. This paper evaluates the metabolic effects caused by this herbicide on the shikimate (shikimate dehydrogenase activity and shikimate content) and phenylpropanoid (phenylalanine ammonia-lyase activity, phenolic and lignin contents) pathways in BRS-133 (susceptible) and BRS-245RR (resistant) soybean (Glycine max L.) roots. In general, the results showed that in susceptible roots (1) glyphosate affects the shikimate pathway (massive shikimate accumulation and enhanced shikimate dehydrogenase activity) and the phenylpropanoid pathway (increase in PAL activity, production of benzoate derivatives and decrease of lignin) and (2) the metabolic disruption contributes to the production of p-hydroxybenzoate and vanillate, which likely originate from shikimate and/or cinnamate and their derivatives. No such changes were observed in the genetically modified soybean consistent with its resistance to glyphosate.     

In vivo biochemical changes in liver and gill of Clarias batrachus during cypermethrin exposure and following cessation of exposure

The sublethal effect of a synthetic pyrethroid, cypermethrin on total protein, amino acids, ammonia, glycogen, and enzymes like aminotransaminases (AIAT, AAT), glutamate dehydrogenase, and glycogen phosphorylases (a and ab) was studied in physiological important tissues viz; liver and gill tissues of freshwater teleost air breathing fish, Clarias batrachus. The study was conducted during exposure of 1/3 (33%) of LC₅₀ concentration and followed by cessation of exposure. Thirty-six fish were exposed to 0.07 mg/L cypermethrin for 10 days. After 10 days, 18 fish were released to freshwater and kept in the same for 10 days (recovery group). Thirty-six fish were kept in freshwater as control batch. Protein content in liver tissues decreased at the end of 1st and 5th day followed by slight increase at the end of 10th day. Gill tissue showed statistical significant decrease (P < 0.001) in protein content during exposure period of 10 days. Recovery in protein content was observed to a large extent in both the tissues. Total free amino acids were increased in liver and gill tissues throughout the treatment period, recovery response was seen after cessation of exposure. Ammonia level was decrease in both the tissues throughout the exposure period except in liver tissue at the end of 1st day of exposure. Recovery response was exhibited by both the tissues. A decreased in glycogen content of liver tissue was observed during exposure period, gill tissue also showed decrease in glycogen at the end of 1st and 5th day followed by increase at the end of 10th day of exposure period. When the fish were transferred to freshwater, recovery in glycogen content was noted. The activity level of alanine, aspartate aminotransaminase, glutamate dehydrogenase, and phosphorylases (a, ab) was increased in both the tissues, followed by recovery response after released of fish into freshwater. The present study showed that cypermethrin caused alterations in certain biochemical mechanisms of C. batrachus. This fish indicated recovery response when transferred to cypermethrin free water.     

Physiological responses of corn (Zea mays) to AC 243,997 in combination with valine,leucine, and isoleucine

Various physiological processes were measured in corn after treatment with AC 243,997. Neutral sugar levels in leaves increased 39% over the control 24 hr after application of AC 243,997. Protein synthesis, measured by [¹⁴C]leucine and [¹⁴C]cystine incorporation, and lipid synthesis were not inhibited 24 hr after application of 150 μM of AC 243,997, while respiration and RNA synthesis were inhibited 32 and 15%, respectively. DNA synthesis was severely inhibited (70–90%) by 150 μM of the herbicide 24 hr after application. The inhibition of DNA synthesis by AC 243,997 did not begin until 5 to 7 hr after application. Although protein synthesis rates were apparently unaffected by AC 243,997, the level of the soluble proteins decreased 40% while free amino acid levels increased 32% 24 hr after application of the herbicide. An exogenous supply of valine, leucine, and isoleucine to corn prevented the inhibition of growth and reversed the inhibition of DNA synthesis caused by AC 243,997. All three amino acids at a concentration of 1 mM were needed to provide maximum protection. The results support the hypothesis that AC 243,997 kills plants by interfering with the biosynthesis of valine, leucine, and isoleucine.     

Molecular basis for resistance to tribenuron in shepherd’s purse (Capsella bursa-pastoris (L.) Medik.)

Capsella bursa-pastoris, a winter annual weed in the mustard family, can not be controlled by tribenuron after the herbicide has been continuously used for several years. The resistant biotype Lz-R was the generation of a population collected from Liangzhu, a place where tribenuron had been used for more than 15 consecutive years. To confirm and characterize the resistance of C. bursa-pastoris to tribenuron, whole-plant bioassays were conducted in the greenhouse. The results of whole-plant bioassays revealed that Lz-R was highly resistant to tribenuron with the resistance index (GR₅₀ Lz-R)/(GR₅₀ Lz-S) up to 236.6. To investigate the molecular basis of resistance in C. bursa-pastoris, the acetolactate synthase (ALS) genes were sequenced and compared between susceptible and resistant biotypes. Analysis of the nucleotide and deduced amino acid sequences between the biotypes indicated that one substitution had occurred in Domain A, cytosine by thymine (CCT to TCT) at position 197, that led to a change of the amino acid proline in the susceptible to serine in the Lz-R.     

Effects of the aglycone of ascaulitoxin on amino acid metabolism in Lemna paucicostata

Ascaulitoxin and its aglycone (2,4,7-triamino-5-hydroxyoctanoic acid, CAS 212268-55-8) are potent phytotoxins produced by Ascochyta caulina, a plant pathogen being developed for biocontrol of weeds. The mode of action of this non-protein amino acid was studied on Lemna paucicostata. Ascaulitoxin is a potent growth inhibitor, with an I₅₀ for growth of less than 1 μM, almost completely inhibiting growth at about 3 μM. Its action is slow, starting with growth inhibition, followed by darker green fronds, and then chlorosis and death. Most amino acids, including non-toxic non-protein amino acids, reversed the effect of the toxin when supplemented in the same medium. Supplemental sucrose slightly increased the activity. d-Amino acids were equally good inhibitors of ascaulitoxin activity, indicating the amino acid effects may not be due to inhibition of amino acid synthesis. Oxaloacetate, the immediate precursor of aspartate, also reversed the activity. LC-MS did not detect interaction of the compound with lysine, an amino acid that strongly reversed the effect of the phytotoxin. Metabolite profiling revealed that the toxin caused distinct changes in amino acids. Reduction in alanine, paralleled by enhanced levels of the branched chain amino acids valine, leucine and isoleucine and nearly unchanged levels of pyruvate, might indicate that the conversion of pyruvate to alanine is affected by ascaulitoxin aglycone. In addition, reduced levels of glutamate/glutamine and aspartate/asparagine might suggest that synthesis and interconversion reactions of these amino group donors are affected. However, neither alanine aminotransferase nor alanine: glyoxylate aminotransferase were inhibited by the toxin in vitro. Our observations might be explained by three hypotheses: (1) the toxin inhibits one or more aminotransferases not examined, (2) ascaulitoxin aglycone affects amino acid transporters, (3) ascaulitoxin aglycone is a protoxin that is converted in vivo to an aminotransferase inhibitor.     

Seed Development,Oil Accumulation and Fatty Acid Composition of Drought Stressed Rapeseed Plants Affected by Salicylic Acid and Putrescine

Two field experiments were carried out in 2017 and 2018 to evaluate the impacts of salicylic acid (1?mM SA) and putrescine (1?mM Put) on leaf osmolytes, seed reserve and oil accumulation and fatty acid composition of rapeseed (Brassica napus L.) under different watering levels (irrigations after 70 and 150?mm evaporation as normal irrigation and severe drought stress, and 70?→?90?→?110?→?130?→?150 and 70?→?100?→?130→150 as gradual and moderately gradual water deficits, respectively). The experiments were laid out as split plot on the bases of randomized complete block design in three replications. Water stress increased the contents of glycine betaine, proline, soluble sugars, and proteins. Application of SA and Put further enhanced the contents of glycine betaine and soluble sugars, while reduced proline content of leaves. Seed filling duration, seeds per plant, plant biomass and seed yield were decreased with increasing irrigation intervals. Exogenous SA and Put enhanced all of these parameters under different irrigation intervals. Oil accumulation in seeds was diminished as water stress severed. The gradual water deficit considerably reduced the impacts of drought stress on yield related traits and oil content per seed, due to stress acclimation of plants. Oil content of seeds was augmented by SA and Put treatments through prolonging seed filling duration, particularly under limited irrigations. Percentages of palmitic acid and stearic acid (saturated fatty acids) were not affected by water limitation. However, unsaturated fatty acids of linoleic and linolenic acids were reduced, and oleic acid was enhanced due to water shortage. Unsaturation index was improved by SA and Put treatments under severe water stress as a result of decreasing oleic acid and increasing linoleic and linolenic acids contents. The SA spray was the best treatment for improving rapeseed seed and oil production under normal and stressful conditions.

     

Phytotoxicity of Roundup Ultra 360 SL in aquatic ecosystems: Biochemical evaluation with duckweed (Lemna minor L.) as a model plant

Glyphosate-based herbicides (e.g. Roundup Ultra 360 SL) are extensively used in aquatic environment. Although glyphosate is more environmental favorable than many other herbicides, it may be exceptionally dangerous for aquatic ecosystems through high water solubility. Thus, the aim of the work was quantification of influence of Roundup Ultra 360 SL (containing isopropylamine salt of glyphosate as an active ingredient) on biomass and chlorophyll content within duckweed (Lemna minor L.). Moreover, changes in polyamine content and activity of such antioxidative enzymes as catalase (CAT) and ascorbate peroxidase (APX) were assayed in order to determine the biochemical mechanisms of L. minor response to the herbicide treatment. Obtained results showed that phytotoxicity of the herbicide was connected with decrease in chlorophyll-a, b and a+b content, and reduction of biomass growth. Roundup, similarly to some abiotic and biotic stressors, caused over-accumulation of putrescine, spermidine and total polyamines (PAs) within duckweed tissues. In addition an increase in CAT and APX activities suggested that stress generated by the herbicide treatment was at least partially connected with oxidative burst. Intensity of the duckweed responses to the herbicide was dependent on the applied herbicide level and/or duration of treatment.     

萝卜对芜菁花叶病毒的抗性和其叶内游离氨基酸含量的关系

 以6份抗感芜菁花叶病毒病的萝卜品种为材料,探讨了萝卜在不同叶龄期的抗病性以及不同品种的抗病性和叶内游离氨基酸含量的关系,分析了萝卜在幼苗期的抗病性和接种芜菁花叶病毒后20天时病叶和对照叶游离氨基酸含量比值的相关性,调查了接种芜菁花叶病毒后抗感病萝卜品种叶内游离氨基酸含量的变化情况。结果表明:抗病品种叶内含有较高的蛋氨酸,感病品种的含量较低;子叶期后,萝卜叶内天冬氨酸、蛋氨酸、脯氨酸及总游离氨基酸含量的迅速提高和抗病性的迅速增強呈平行关系;接种芜菁花叶病毒后,病叶蛋氨酸、酪氨酸含量和健叶差异不明显,其它各种氨基酸含量均有不同程度的上升。文中还对氨基酸作为抗性鉴定标准及鉴定的适宜时间进行了讨论。     

Inhibition of Methionine Biosynthesis in Botrytis cinerea by the Anilinopyrimidine Fungicide Pyrimethanil

When mycelium of Botrytis cinerea was treated with low concentrations of the anilinopyrimidine fungicide pyrimethanil the total amount of free amino acids increased. Qualitative variations were also induced: alanine, glutamine, lysine, glycine, histidine, asparagine, arginine, threonine and moreover, α-aminobutyrate and β-alanine were accumulated; cyst(e)ine, valine, leucine and citrulline were reduced. When mycelium of B. cinerea was incubated with Na₂[³⁵S]O₄, pyrimethanil at 1·5 μM induced a decrease of [³⁵S]methionine and simultaneously an increase of [³⁵S]cystathionine. These data indicate that the anilinopyrimidine fungicide pyrimethanil inhibits the biosynthesis of methionine and suggest that the primary target could be the cystathionine β-lyase. © 1997 SCI.     

Low glyphosate rates do not affect Citrus limonia (L.) Osbeck seedlings

BACKGROUND: Glyphosate is used to control weeds in citrus orchards, and accidental spraying or wind drift onto the seedlings may cause growth arrest owing to metabolism disturbance. Two experiments were carried out to investigate the effect of non‐lethal rates (0, 180, 360 and 720 g AI ha^?1) of glyphosate on four‐month‐old ‘Cravo’ lime, Citrus limonia (L.) Osbeck, seedlings. Photosynthesis and the concentrations of shikimic acid, total free amino acids and phenolic acids were evaluated. RESULTS: Only transitory effects were observed in the contents of shikimate and total free amino acids. No visual effects were observed. CONCLUSION: The present study showed that glyphosate at non‐lethal rates, which is very usual when accidental spraying or wind drift occurs in citrus orchard, did not cause severe metabolic damage in ‘Cravo’ lime seedlings. Copyright © 2009 Society of Chemical Industry     

Response of leaf acetolactate synthase from different leaf positions and seedling ages to sulfonylurea herbicide

Responses of acetolactate synthase (ALS) from grass and broadleaf weed to sulfonylurea (SU) herbicide were compared in relation to the leaf position in a seedling and seedling age. The responses of Echinochloa crus-galli (L.) P. Beauv. and Eclipta prostrata L., dominant grass and broadleaf weed in paddy fields in Korea, respectively, to azimsulfuron were examined. In this study, in vivo ALS assay was used to verify the responsibility of selected weed species at different leaf stages to SU-herbicides. The data from in vivo ALS assay could be used for discriminating the degree of tolerance between weeds showed different susceptibility. In E. crus-galli and E. prostrata there was no apparent relationship between the chlorophyll concentrations and herbicide concentrations treated on leaves. Both in E. crus-galli and E. prostrata, the free amino acid concentrations, however, were increased as herbicide concentration increased in the younger leaves. The free amino acid concentrations were generally higher in older leaves than young leaves and were significantly increased concomitantly with increasing herbicide concentration. The ALS activity was decreased rapidly with higher azimsulfuron rates in old but not senescent leaves compared to juvenile leaves. Generally, ALS activity was less sensitive at the early leaf stage than late leaf stage. The activity of ALS in E. prostrata was highly responsive to application time and more susceptible to the herbicide as compared to E. crus-galli. The highest levels of acetoin were observed in the uppermost and youngest leaf in all species tested.     

Effect of herbicide clomazone on photosynthetic processes in primary barley (Hordeum vulgare L.) leaves

The effect of pre-emergently applied herbicide clomazone on the photosynthetic apparatus of primary barley leaves (Hordeum vulgare L.) was studied. Clomazone application caused a reduction in chlorophyll (a+b) and carotenoid levels that was accompanied by a decline in the content of light harvesting complexes as judged from the increasing chlorophyll a/b ratio. The pigment reduction also resulted in changes in 77 K chlorophyll fluorescence emission spectra indicating lower chlorophyll (Chl) fluorescence reabsorption and absence of the long-wavelength emission forms of photosystem I. The maximal photochemical yield of photosystem II (PSII) and the reoxidation kinetics of the primary quinone acceptor Q_A⁻ were not significantly influenced by clomazone. A higher initial slope of Chl fluorescence rise in the Chl fluorescence induction kinetic indicated an increased delivery of excitations to PSII. Simultaneously, analysis of the Chl fluorescence quenching revealed that clomazone reduced function of the electron transport chain behind PSII. The decrease in the saturation rates of CO₂ assimilation paralleled the decrease of the Chl content and has been suggested to be caused by a suppressed number of the electron transport chains in the thylakoid membranes or by their decreased functionality. The obtained results are discussed in view of physiological similarity of the clomazone effect with changes of photosynthetic apparatus during photoadaptation.     

Effects of propanil on growth and cell constituents of Nostoc calcicola

The rice field herbicide, propanil, was toxic to the nitrogen-fixing cyanobacterium Nostoc calcicola. A decrease in growth was observed with the increasing concentrations of propanil, 30 μg/ml being lethal. Since toxicity of the herbicide could be reversed by exogeneous supplementation of assimilable organic carbon glucose, it is suggested that carbon fixation was sensitive to the herbicide. The herbicide inhibited heterocyst differentiation and nitrogen fixation. There was a rapid decrease in total protein, nucleic acids (DNA, RNA), and carbohydrate content accompanied by a loss of photosynthetic pigments. The phycocyanin: chlorophyll a ratio showed positive correlation with increased dosages of the herbicide, suggesting the inhibition of chlorophyll a.     

The possible role of quinate in the mode of action of glyphosate and acetolactate synthase inhibitors

BACKGROUND: The herbicide glyphosate inhibits the biosynthesis of aromatic amino acids by blocking the shikimate pathway. Imazethapyr and chlorsulfuron are two herbicides that act by inhibiting branched‐chain amino acid biosynthesis. These herbicides stimulate secondary metabolism derived from the aromatic amino acids. The aim of this study was to test if they cause any cross‐effect in the amino acid content and if they have similar effects on the shikimate pathway. RESULTS: The herbicides inhibiting two different amino acid biosynthesis pathways showed a common pattern in general content of free amino acids. There was a general increase in total free amino acid content, with a transient decrease in the proportion of amino acids whose pathways were specifically inhibited. Afterwards, an increase in these inhibited amino acids was detected; this was probably related to proteolysis. All herbicides caused quinate accumulation. Exogenous application of quinate arrested growth, decreased net photosynthesis and stomatal conductance and was ultimately lethal, similarly to glyphosate and imazethapyr. CONCLUSIONS: Quinate accumulation was a common effect of the two different classes of herbicide. Moreover, exogenous quinate application had phytotoxic effects, showing that this plant metabolite can trigger the toxic effects of the herbicides. This ability to mimic the herbicide effects suggests a possible link between the mode of action of these herbicides and the potential role of quinate as a natural herbicide. Copyright © 2009 Society of Chemical Industry     

Action de l'atrazine, du chlortoluron et du MCPA sur les teneurs en pyruvate, oxalacétate, cétoglutarate, glutamate et glutamine dans les feuilles et les racines de concombre (Cucumis sativus)

Action of atrazine, chlortoluron and MCPA on the pyrovate, oxalacetate, cetoglutarate, glutamate and glutamine content in the leaves and roots of cucumber (Cucumis sativus) Lethal rates of atrazine, chlortoluron and MCPA were administered to 17-day old cucumber seedlings growing in a nutrient solution. The ketonic acid, glutamate and glutamine composition of the leaves and roots was determined after intervals of 1–4 days. Two days after application of photosynthesis-inhibiting herbicides, the ketoglutarate, oxaloacetate, pyruvate, glutamate and glutamine content of the leaves was 11–20%; 30–54%; 43–50%; 101–112% and 49–65% respectively, compared with the controls. After 4 days it was 16–22%; 31–56%; 26–42%; 71–75% and 180–205%. In the roots, the glutamate decreased in the same proportion as the ketoglutarate while the glutamine increased the first 2 days and decreased on the fourth day. The MCPA treatment did not modify the cetoglutarate concentration in the leaves but increased it from 300 to 800% in the roots. Simultaneous analysis of ketoglutarate and glutamate can be used to identify the nature of a herbicide treatment.     

The phenylurea cytokinin 4PU-30 protects maize plants against glyphosate action

The effects of the phenylurea cytokinin 4PU-30 and the herbicide glyphosate, applied alone and in combination on young maize plants were investigated. The influence of the compounds on the changes of growth, chlorophyll content, levels of hydrogen peroxide, and some stress markers, the activities of peroxidase, catalase, and glutathione-S-transferase, as well as glutathione amount were measured 3, 6, and 10 days after the treatment. The application of glyphosate increased the levels of lipid peroxidation, glutathione, and free proline content, ion fluxes, and the activity of catalase, guaiacol peroxidase, and glutathione-S-transferase, i.e., along with the inhibition of its target enzyme the herbicide induced also an oxidative stress. We found that the phenylurea cytokinin 4PU-30 alleviated in some extent the detrimental effects due to the glyphosate action. Moreover, we speculated that the cytokinin renders its protective action by induction of “hardiness” in the antioxidant defense systems in maize plants similarly to the effects observed after the application of some herbicide safeners.