Inhibition of ethylene production in sunflower cell suspensions by a novel oxime ether derivative

During the incubation of undifferentiated cell suspensions of sunflower (Helianthus annuus L. cv. Spanners Allzweck) ethylene production was effectively inhibited by the novel oxime ether derivative LAB 181 508, [[(Isopropyliden)-amino]-oxy]-acetic acid-2-(methoxyl)-2-oxoethylester (PACME). The compound was most active during the first 6 days of incubation exhibiting a value of 50% inhibition at 9.5×10^?6 mol×L^?1. The pattern of changes in the internal 1-aminocyclopropanecarboxylic acid (ACC) and N-malonyl-ACC (MACC) levels paralleled the influence on ethylene formation. While the addition of ACC fully restored ethylene production, applied S-adenosyl-L-methionine (SAM) was not effective. Experiments with [¹⁴C]indole-3-acetic acid (IAA) revealed that LAB 181 508 did not affect auxin uptake into suspension cells of sunflower. The results suggest that LAB 181 508 reduces ethylene formation by inhibiting the conversion of SAM to ACC in the biosynthetic pathway. In comparison to the structurally related inhibitor of ACC synthase, aminoethoxyvinylglycine (AVG), LAB 181 508 reduced growth and viability of the suspension cells only slightly. Low phytotoxicity of LAB 181 508 combined with a less complicated chemical synthesis might offer interesting aspects for physiological research and horticultural and agricultural practice.     

Inhibition of ethylene production in sunflower cell suspensions by the plant growth retardant BAS 111..W: Possible relations to changes in polyamine and cytokinin contents

At a concentration of 10^–5 mol · L^–1 the triazole-type growth retardant BAS 111..W completely inhibited the transiently elevated ethylene production in the exponential growth phase of heterotrophic sunflower cell suspensions. This effect, which could not be restored by adding gibberellin A₃, was accompanied by transiently increased levels of 1-aminocyclopropanecarboxylic acid (ACC) in the cells, which was increasingly converted to N-malonyl-ACC. Thus, the reactions from ACC to ethylene catalyzed by the ethylene-forming enzyme appeared to be blocked by the retardant. Concomitantly, higher endogenous levels of free spermidine and particularly spermine were found over control, whereas free putrescine, the direct precursor of both polyamines, simultaneously decreased. We assume that the remaining S-adenosylmethionine from ethylene biosynthesis was increasingly incorporated into spermidine and finally spermine. A further relation appears to exist between the reduced ethylene production and enhanced levels of cytokinins in the cells. The application of both BAS 111..W and aminoethoxyvinylglycine depressed ethylene formation while immunoreactive cytokinins from isopentenyladenosine-, trans-zeatin ribo-side-, and dihydrozeatin riboside-type increased. By additional treatment with ACC, the effects could partially be reversed. On the other hand, stimulation of ethylene production by ACC alone or ethephon considerably lowered cytokinin levels.     

Ethylene production by sunflower cell suspensions : effects of plant growth retardants

From a variety of undifferentiated plant cell suspensions, 2,4-dichlorophenoxyacetic acid-dependent cells of sunflower (Helianthus annuus L. Spanners Allzweck) produced large quantities of ethylene. The maximum rate was about 1 nanomole × gram fresh weight⁻¹ × hour⁻¹ during the exponential growth phase. The action of various compounds known to interfere with ethylene formation in plant tissue was studied in sunflower cell suspensions. The influence on ethylene, 1-aminocyclopropanecarboxylic acid (ACC), and N-malonyl-ACC (MACC) levels suggested that the final steps in ethylene synthesis resemble those of other plant systems. This makes sunflower cells suitable for analyzing the effects of biologically active compounds on cellular ethylene biosynthesis. In particular, plant growth retardants of the norbornenodiazetine and triazole type inhibited ethylene production of sunflower cells. On the other hand, the ACC level was considerably elevated while that of MACC did not change significantly. It is assumed that the conversion of ACC to ethylene catalyzed by the ethylene-forming enzyme was influenced.     

Inhibition of ethylene production by rhizobitoxine

Rhizobitoxine, an inhibitor of methionine biosynthesis in Salmonella typhimurium, inhibited ethylene production about 75% in light-grown sorghum seedlings and in senescent apple tissue. Ethylene production stimulated by indoleacetic acid and kinetin in sorghum was similarly inhibited. With both apple and sorghum, the inhibition could only be partially relieved by additions of methionine. A methionine analogue, α-keto-γ-methylthiobutyric acid, which has been suggested as an intermediate between methionine and ethylene, had no effect on the inhibition.     

Inhibition of ethylene production by cobaltous ion

The effect of Co²⁺ on ethylene production by mung bean (Phaseolus aureus Roxb.) and by apple tissues was studied. Co²⁺, depending on concentrations applied, effectively inhibited ethylene production by both tissues. It also strongly inhibited the ethylene production induced by IAA, kinetin, IAA plus kinetin, Ca²⁺, kinetin plus Ca²⁺, or Cu²⁺ treatments in mung bean hypocotyl segments. While Co²⁺ greatly inhibited ethylene production, it had little effect on the respiration of apple tissue, indicating that Co²⁺ does not exert its inhibitory effect as a general metabolic inhibitor. Ni²⁺, which belongs to the same group as Co²⁺ in the periodic table, also markedly curtailed both the basal and the induced ethylene production by apple and mung bean hypocotyl tissues.     

Promotion ofin vitro shoot formation from excised roots of silktree (Albizzia julibrissin) by an oxime ether derivative and other ethylene inhibitors

Summary This report describes the regeneration response of excised seedling roots of silktree (Albizzia julibrissin) to added ethylene precursors/generators (1-amino-cyclopropane-1-carboxylic acid [ACC], 2-chloroethylphosphonic acid [CEPA]), biosynthesis inhibitors (aminoethoxyvinylglycine [AVG], an oxime ether derivative [OED={[(ispropylidene)-amino]oxy}-acetic acid-2-(methoxy)-2-oxoethyl ester], CoCl² [Co⁺⁺]), and an ethylene action inhibitor (AgNO₃ [Ag⁺]). When placed on B5 medium, about 50% of the control explants formed shoot buds within 15 days. Addition of ACC or CEPA (1–10 µM) to the culture medium decreased both the percentage of cultures forming shoots and the number of shoots formed per culture. In contrast, AVG and OED (1–10 µM) increased shoot formation to almost 100% and increased the number of shoots formed per culture. Likewise, both Co⁺⁺ and Ag⁺ (1–10 µM) increased shoot regeneration, but the number of shoots produced after 30 days was less than with AVG or OED. The inhibitors of ethylene biosynthesis were partially effective in counteracting the inhibitory effect of ACC on shoot formation. These results suggest that modulation of ethylene biosynthesis and/or action can strongly influence the formation of adventitious shoots from excised roots of silktree.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - AVG aminoethoxyvinylglycine - CEPA 2-chloroethylphosphonic acid - OED oxime ether derivative     

The negligible role of carbon dioxide and ethylene in ajmalicine production by Catharanthus roseus cell suspensions

Summary Removal of gaseous metabolites in an aerated fermenter affects ajmalicine production by Catharanthus roseus negatively. Therefore, the role of CO₂ and ethylene in ajmalicine production by C. roseus was investigated in 3 l fermenters (working volume 1.8 l) with recirculation of a large part of the exhaust air. Removal of CO₂, ethylene or both from the recirculation stream did not have an effect on ajmalicine production. Inhibition of ethylene biosynthesis in shake flasks with Co²⁺, Ni²⁺ or aminooxyacetic acid did not affect ajmalicine production. However, the removal of CO₂ did enhance the amount of extracellular ajmalicine.     

Synthesis and fungicidal activities of novel benzothiophene-substituted oxime ether strobilurins

Twenty-one novel benzothiophene-substituted oxime ether strobilurins, which employed a benzothiophene group to stabilise the E-styryl group in Enoxastrobin (an unsaturated oxime strobilurin fungicide developed by Shenyang Research Institute of Chemical Industry, China) were designed and synthesised. The biological assay indicated that most compounds exhibited good or excellent fungicidal activities, especially against Colletotrichum lagenarium and Puccinia sorghi Schw. In addition, methyl 3-methoxypropenoate oxime ethers and N-methoxy-carbamic acid methyl esters exhibited good in vivo fungicidal activities against Erysiphe graminis, Colletotrichum lagenarium and Puccinia sorghi Schw. under the tested concentrations. Notably, (E,E)-methyl 3-methoxy-2-(2-((((6-chloro-1-(1H-benzo[b]thien-2-yl)ethylidene)amino)oxy)methyl)phenyl)propenoate (5E) exhibited more potent in vivo fungicidal activities against nearly all of the tested fungi at a concentration of 0.39 mg/L compared to Enoxastrobin.     

Inhibition of ethylene production by osmotic shock. Further evidence for membrane control of ethylene production

Effects of osmotic shock applied to mung bean hypocotyl segmentswere examined to see if auxin-induced ethylene production isregulated by membrane activity. Uptake of -aminoisobutyric acidwas significantly inhibited by osmotic shock. While cold shockalone also inhibited the uptake, cold osmotic shock was mosteffective. Auxin-induced ethylene production by the osmoticallyshocked tissue was similarly inhibited. Shock treatment of auxin-pretreatedtissue also suppressed the subsequent ethylene production. Oxygenuptake was not affected by the shock treatment. Sorbitol andsucrose used as osmotic substance were as effective as mannitol.The results suggest that ethylene production is controlled bymembrane activity. (Received July 18, 1977; )     

Inhibition of P-selectin-mediated cell adhesion by a sulfated derivative of sialic acid

P-selectin, a carbohydrate-binding cell adhesion molecule expressed on activated endothelial cells and platelets, plays a key role in the recruitment of leukocytes to inflammatory and hemorrhagic sites. It simultaneously recognizes a sialic acid-containing carbohydrate chain and the sulfated tyrosine residues of a specific counter-receptor expressed on the leukocyte surface. We examined the inhibitory effects of a synthetic sulfated derivative of sialic acid (NMSO3) on P-selectin-mediated cell adhesion and found the following: (1) P-selectin/IgG chimera bound to immobilized NMSO3. (2) The binding of P-selectin/IgG chimera to purified P-selectin glycoprotein ligand-1 was inhibited by soluble NMSO3. (3) The adhesion of HL60 cells to P-selectin-expressing CHO cells was inhibited by NMSO3. (4) NMSO3 inhibited P-selectin-induced tumor necrosis factor-alpha production in monocytes and activated platelet-induced generation of reactive oxygen species in neutrophils. In conclusion, NMSO3 acts as a specific inhibitor for P-selectin-mediated cell adhesion and for adhesion-dependent leukocyte activation.     

Inhibition of ethylene production in fruit slices by a rhizobitoxine analog and free radical scavengers

The rhizobitoxine analog, L-2-amino-4-(2-aminoethoxy)-trans-3-butenoic acid (Ro), which effectively inhibits ethylene production in apple (Malus domestica Borkh.) and other tissues at concentrations at about 68 micromolar, inhibited ethylene production by about 50 to 70% in green tomato (Lycopersicon esculentum Mill.) fruit slices but only by about 15% in pink and ripe tomato tissue slices. Ethylene production in climacteric-rise and postclimacteric avocado slices was likewise relatively insensitive to 68 micromolar Ro. At 340 micromolar Ro, inhibition of ethylene production increased up to 50% in pink tomato slices, whereas 680 micromolar Ro was required to inhibit ethylene production by 30% in avocado slices. Incorporation of ¹⁴C from [¹⁴C]methionine into ethylene in green and pink tomato tissues was inhibited by Ro to about the same extent as inhibition of total ethylene production. Results thus far are inconclusive as to the mechanism of Ro resistance in tomato and avocado tissues. At 1 millimolar, free radical scavengers such as benzoate, propyl gallate, nordihydroguaiaretic acid, and to a lesser extent, eugenol, inhibited ethylene production in both Ro-sensitive (green tomato and apple) tissues and Ro-resistant (pink tomato and avocado) tissues. Therefore, free radical steps are suggested in the ethylene-forming systems.     

Inhibition of auxin-induced ethylene production by salicylic acid in mung bean hypocotyls

Salicylic acid (SA), a common plant phenolic compound, influences diverse physiological and biochemical processes in plants. To gain insight into the mode of interaction between auxin, ethylene, and SA, the effect of SA on auxininduced ethylene production in mung bean hypocotyls was investigated. Auxin markedly induced ethylene production, while SA inhibited the auxin-induced ethylene synthesis in a dose-dependent manner. At 1 mM of SA, auxininduced ethylene production decreased more than 60% in hypocotyls. Results showed that the accumulation of ACC was not affected by SA during the entire period of auxin treatment, indicating that the inhibition of auxin-induced ethylene production by SA was not due to the decrease in ACC synthase activity, the rate-limiting step for ethylene biosynthesis. By contrast, SA effectively reduced not only the basal level of ACC oxidase activity but also the wound-and ethylene-induced ACC oxidase activity, the last step of ethylene production, in a dose-dependent manner. Northern and immuno blot analyses indicate that SA does not exert any inhibitory effect on the ACC oxidase gene expression, whereas it effectively inhibits both the in vivo and in vitro ACC oxidase enzyme activity, thereby abolishing auxin-induced ethylene production in mung bean hypocotyl tissue. It appears that SA inhibits ACC oxidase enzyme activity through the reversible interaction with Fe²⁺, an essential cofactor of this enzyme. These results are consistent with the notion that ethylene production is controlled by an intimate regulatory interaction between auxin and SA in mung bean hypocotyl tissue.     

Effects of novel oxime ether derivatives of aminooxyacetic acid on ethylene formation in leaves of oilseed rape and barley and on carnation flower senescence

New derivatives of aminooxyacetic acid were tested for their ability to inhibit ethylene formation in higher plants. Treatments with {[(isopropylidene)-aminojoxy}-acetic acid-2-(methoxy)-2-oxoethyl ester, {[(isopropylidene)-aminojoxy}-acetic acid-2-(hexyloxy)-2-oxoethyl ester or {[(cyclohexylidene)-amino]oxy}-acetic acid-2-(isopropyloxy)-2-oxoethyl ester reduced ethylene evolution by leaf discs of oilseed rape and drought-stressed barley leaves. The new compounds delayed senescence of cut carnation flowers. The endogenous levels of 1-aminocyclopropane-1-carboxylic acid (ACC) and its N-malonyl conjugate were also reduced in the leaf discs of oilseed rape. This suggests that a step in the biosynthesis of ethylene, prior to the formation of ACC, is inhibited by these new compounds. A lag phase in response suggests that these compounds have to be activated most likely by the production of metabolites with a free aminooxy group.     

Inhibition of infectious Rous sarcoma virus production by rifamycin derivative.

A new rifamycin derivative, rifazone-82 (R-82), an inhibitor of viral RNA-dependent DNA polymerase, is selectively toxic to transformed chicken cells in culture. R-82 has now been shown to possess antiviral activity as well. The relatively nontoxic properties of R-82 to nontransformed cells have permitted the execution of experiments examining the effect of a rifamycin derivative on virus reproduction. Addition of low concentrations of R-82 (15 mug/ml) to cultures soon after Rous sarcoma virus infection prevents the spread of infection thoroughout the culture. This inhibition is not dependent on concomitant cellular transformation as identical results were obtained with cells infected with a transformation-defective Rous sarcoma virus. Addition of R-82 to cultures in which all the cells are infected does not substantially affect the yield of physical particles as measured by RNA-dependent DNA polymerase activity and by (3H) uridine incorporation into viral RNA. However, the infectivity of the progeny virus, as measured by focus-forming ability, is decrreased 95 to 99% by R-82 treatment.     

Effect of thidiazuron, a cytokinin-active urea derivative, in cytokinin-dependent ethylene production systems

Cytokinins are known to stimulate ethylene production in mungbean hypocotyls synergistically with indoleacetic acid (IAA), in mungbean hypocotyls synergistically with Ca²⁺, and in wilted wheat leaves. Thidiazuron, a substituted urea compound, mimicked the effect of benzyladenine (BA) in all three systems. In the Ca²⁺ + cytokinin system and the IAA + cytokinin systems of mungbean hypocotyls, thiadiazuron was slightly more active than BA at equimolar concentration. In mungbean hypocotyls exogenously applied IAA was rapidly conjugated into IAA asparate, and this conjugation process was effectively inhibited by thidiazuron, as by cytokinins. In the wilted wheat leaves system, 10 micromolar thidiazuron exerted stress ethylene production equal to that exerted by 1 millimolar BA, indicating that thidiazuron is more active than BA by two orders. The structure-activity relationship of thidiazuron and its thiadiazolylurea analogs in stimulating Ca²⁺-dependent ethylene production in mungbean hypocotyls was found to agree well with the structure-activity relationship of these derivatives in promoting the growth of callus tissues. These results indicate that thidiazuron and its derivatives are highly active to mimic the adenine-type cytokinin responses in promoting ethylene production and that the structure-activity relationship in promoting the growth of callus and in promoting ethylene production is similar.     

Effect of carbon dioxide and light on ethylene production in intact sunflower plants

High CO₂ concentration (0.5%) increased the rate of ethylene production, measured in a continuous flow system, in intact sunflower (Helianthus annuus L.) plants. However, the rate of ethylene production subsided to near control levels after approximately 24 hours. The effect of high CO₂ could only be observed in light. Although high CO₂ concentration had no effect on the rate of ethylene production in darkness, prolonged exposure (approximately 16 hours) of plants to high CO₂ in the dark prevented the increase in ethylene production when the plants were exposed to light and high CO₂.     

Effects of carbon dioxide on ethylene production and action in intact sunflower plants

A continuous flow system was used to study the interactions between carbon dioxide and ethylene in intact sunflower (Helianthus annuus L.) plants. An increase in the concentration of carbon dioxide above the ambient level (0.033%) in the atmosphere surrounding the plants increased the rate of ethylene production, and a decrease in carbon dioxide concentration resulted in a decrease in the rate of ethylene production. The change in the rate of ethylene production was evident within the first 15 minutes of the carbon dioxide treatment. Continuous treatment with carbon dioxide was required to maintain increased rate of ethylene production. The rate of carbon dioxide fixation increased in response to high carbon dioxide treatment up to 1.0%. Further increases in carbon dioxide concentration had no additional effect on carbon dioxide fixation. Carbon dioxide concentrations higher than 0.11% induced hyponasty of the leaves whereas treatment with 1 microliter per liter ethylene induced epinasty of the leaves.     

Metabolism of 5-hydroxyicosatetraenoate by human neutrophils: production of a novel omega-oxidized derivative

Human neutrophils incorporated 5-hydroxy-E,Z,Z,Z-6,8,11,14-eicosatetraenoic acid (5-HETE) into cellular triglyceride and phospholipid. They also metabolized 5-HETE into a novel, extracellularly released derivative, 5,20-dihydroxy-E,Z,Z,Z-6,8,11,14-eicosatetraenoic acid (5,20-diHETE). 5,20-diHETE formation predominated at higher substrate concentrations and longer incubation intervals. In the absence of added 5-HETE, 1 X 10(8) neutrophils stimulated with 20 microM ionophore A23187 produced up to 243 ng of 5,20-diHETE, indicating that both endogenously formed and exogenously added substrate could be oxidized at carbon 20. 5,20-diHETE was about 10- to 100-fold weaker than 5-HETE in enhancing human neutrophil degranulation responses to platelet-activating factor. omega-Oxidation appears to be a general enzymatic mechanism for inactivation of arachidonic acid metabolites.     

Enhancement of vitamin E production in sunflower cell cultures

The most biologically active component of vitamin E, -tocopherol, is synthesized in its most effective stereoisomeric form only by photosynthetic organisms. Using sunflower cell cultures, a suitable in vitro production system of natural -tocopherol was established. The most efficient medium was found to be MS basal medium with naphthaleneacetic acid and 6-benzylaminopurine with the addition of casaminoacids and myo-inositol. Culture feeding experiments using biosynthetic precursors showed that -tocopherol production improved by 30% when homogentisic acid was used. Interestingly, time-course experiments with sunflower suspension cultures showed a possible increase of 78% in -tocopherol production when using cultures of longer subculture intervals. Compared to the starting plant tissue, an overall 100% increase of -tocopherol was reached by these sunflower cell cultures.