Effect of chlorsulfuron on phenylpropanoid metabolism in sunflower seedlings

The effect of the herbicide chlorsulfuron on phenylpropanoid titer and metabolism and the role of endogenous ethylene in this response was examined in light-grown sunflower (Helianthus annuus L.) seedlings. Application of chlorsulfuron to the apex resulted in large increases in both total phenolic and hydroxycinnamic acid content in hypocotyls isolated from the treated seedlings. Both of these parameters were increased within 24 h of herbicide treatment, and both reached a maximum level 3–4 days post-treatment. An increase in ethylene evolution was found to proceed in parallel with the alterations of phenolic content. The extractable activities of phenylalanine ammonia lyase,trans-cinnamic-4-hydroxylase, and soluble peroxidase were increased by chlorsulfuron treatment. Chlorsulfuron had little effect on total phenolic content when administered directly to isolated hypocotyl segments. Exogenous ethylene had no effect on the endogenous titer of phenolic compounds. Root-fed cobalt chloride (5 × 10^?4 M) inhibited chlorsulfuron-induced ethylene production by 92% and also inhibited the accumulation of phenolic materials by 56%. Exogenous ethylene was unable to reverse the inhibition caused by cobalt chloride. It was concluded that chlorsulfuron-induced increases in phenolic compounds were not mediated solely by endogenous ethylene.     

Methyl jasmonate effects on ethylene synthesis and organ-specific senescence in Helianthus annuus seedlings

Both methyl jasmonate (MJ) and ethylene have been implicated in promoting senescence, but the specific roles of each and the mechanisms by which they act are not well known. We tested the possibility that MJ and ethylene interact to promote senescence. In sunflower seedlings, the ability of MJ to affect ethylene metabolism was investigated in hypocotyls, cotyledons, and leaves. 1-aminocylcopropane-1-carboxylic acid (ACC)-dependent ethylene production was promoted to different extents depending on the organ and the age of the tissue. Newly emerged hypocotyls were sensitive to MJ, but became desensitized as the cotyledons emerged. The cotyledons increased and peaked in MJ sensitivity from emergence to the production of the primary leaves. Leaves were found to be somewhat insensitive to MJ treatment compared to cotyledons at all ages tested. In cotyledons, MJ also promoted ACC and ethylene production. However the changes in ACC, and ACC-dependent ethylene production were not directly correlated with those in ethylene production with respect to MJ concentration or tissue age. Moreover, changes in ACC-dependent ethylene production did not correlate with in vitro ACC oxidase activity. We hypothesized that MJ affects ethylene production by increasing the spatial access of ACC to ACC oxidase perhaps through increased membrane permeability. Ethylene was not involved in the MJ-induced loss of chlorophyll. But the breakdown of cell integrity and cell membranes (estimated by monitoring conductivity of the solution that bathed the cotyledons) was greatly and synergistically promoted by the combination of MJ and ethylene. Promotion of membrane breakdown by MJ and ethylene could be inhibited by treatments with ethylene inhibitors (STS or CoCl₂), and neither MJ nor ACC treatment alone could induce as much membrane breakdown as both together. We suggest that MJ and ethylene interact to accelerate some aspects of senescence in specific organs for nutrient remobilization for the benefit of the whole plant.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - MJ methyl jasmonate - STS silver thiosulphate     

Auxin and Ethylene-stimulated Adventitious Rooting in Relation to Tissue 9

We have previously shown that both endogenous auxin and ethylenepromote adventitious root formation in the hypocotyls of derootedsunflower (Helianthus annuus) seedlings. Experiments here showedthat promotive effects on rooting of the ethylene precursor,1-aminocyclopropane-l-carboxylic acid (ACC) and the ethylene-releasingcompound, ethephon (2-chloro-ethylphosphonic acid), dependedon the existence of cotyledons and apical bud (major sourcesof auxin) or the presence of exogenously applied indole-3-aceticacid (IAA). Ethephon, ACC, aminoethoxyvinylglycine (an inhibitorof ethylene biosynthesis), and silver thiosulphate (STS, aninhibitor of ethylene action), applied for a length of timethat significantly influenced adventitious rooting, showed noinhibitory effect on the basipetal transport of [³H]IAA. Theseregulators also had no effect on the metabolism of [³H]IAA andendogenous IAA levels measured by gas chromatography-mass spectrometry.ACC enhanced the rooting response of hypocotyls to exogenousIAA and decreased the inhibition of rooting by IAA transportinhibitor, N-1-naphthylphthalamic acid (NPA). STS reduced therooting response of hypocotyls to exogenous IAA and increasedthe inhibition of rooting by NPA. Exogenous auxins promotedethylene production in the rooting zone of the hypocotyls. Decapitationof the cuttings or application of NPA to the hypocotyl belowthe cotyledons did not alter ethylene production in the rootingzone, but greatly reduced the number of root primordia. We concludethat auxin is a primary controller of adventitious root formationin sunflower hypocotyls, while the effect of ethylene is mediatedby auxin. Key words: Auxin, ethylene, adventitious rooting, sunflower     

ACC conversion to ethylene by sunflower seeds in relation to maturation,germination and thermodormancy

Conversion of exogenous 1-aminocyclopropane-1-carboxylic acid (ACC) to ethylene was studied in sunflower (Helianthus annuus L., cv. Mirasol) seeds in relation to germinability. Ethylene production from ACC decreased during seed maturation, and non-dormant mature seeds were practically unable to synthesize ethylene until germination and growth occurred, indicating that ethylene forming enzyme (EFE) activity developed during tissue imbibition and growth. ACC conversion to ethylene was reduced by the presence of pericarp, and in young seedlings it was less in cotyledons than in growing axes.ACC conversion to ethylene by cotyledons from young seedlings was optimal at c. 30°C, and was strongly inhibited at 45°C. Pretreatment of imbibed seeds at high temperature (45°C) induced a thermodormancy and a progressive decrease in EFE activity.Abscisic acid and methyl-jasmonate, two growth regulators which inhibit seed germination and seedling growth, and cycloheximide were also shown to inhibit ACC conversion to ethylene by cotyledons of 3-day-old seedlings and by inbibed seeds.Abbreviations ABA abscisic acid - ACC 1-aminocyclopropane-1-carboxylic acid - CH cycloheximide - EFE ethylene forming enzyme - IAA indole-3-acetic acid - Me-Ja methyl-jasmonate     

Relationship between the malonylation of 1-aminocyclopropane-1-carboxylic acid and D-amino acids in mung-bean hypocotyls

In sections from hypocotyls of dark-grown mung-bean (Vigna radiata L.) seedlings, D-phenylalanine and D-methionine (D-met) inhibited the formation of 1-(malonylamino)cyclopropane-1-carboxylic acid from exogenously administered 1-aminocyclopropane-1-carboxylic acid (ACC), resulting in an increase in free ACC content and stimulation of ethylene production, whereas their L-enantiomers had little or no such effect. When the hypocotyls were administered D-Met, it was mainly metabolized to N-malonylmethionine and N-malonylmethionine sulfoxide, and this malonylation process was inhibited to a greater extent by ACC and D-amino acids (phenylalanine and serine) than by L-amino acids. These results indicate that malonylation of D-amino acids and of ACC are intimately interrelated.     

Rhythmicity in cotton seedlings

Ethylene production by detached cotyledons of cotton (Gossypium hirsutum L.) seedlings grown under cycles of 12 h darkness and 12 h light has been shown to be rhythmic, with a minimum and maximum 4 and 16 h, respectively after the start of the cycle (Rikin, Chalutz and Anderson, 1984, Plant Physiol. 75, 493–495). Treatment with silver ions stimulated the rhythmic ethylene production in both regular and inverted cycles (i.e. dark period changed to light period, and vice versa). The rate of the conversion of [3,4-¹⁴C]methionine into ethylene also followed the stimulation of rhythmic ethylene evolution by silver ions in both regular and inverted cycles, while treatment with aminoethoxyvinylglycine (AVG) decreased this stimulation. Conversion of exogenous 1-aminocyclopropane-1-carboxylic acid (ACC) into ethylene was not affected by silver ions, but was dependent upon the immediate light conditions, regardless of the time in the light-dark cycle, light decreasing and darkness increasing this process. It is concluded that silver ions stimulate the normal rhythmic ethylene production, and this stimulation is regulated at a step prior to the conversion of ACC into ethylene. The rhythmicity in other processes (cotyledon movement, phenylalanine ammonia-lyase activity, resistance to the herbicide 3-isopropyl-1H-2,1,3-benzothiadiazin-4(3H)-one 2,2-dioxide [bentazon]) was not affected by a decrease in the rhythmic changes in ethylene production by AVG or interference in ethylene action by silver ions. Thus, these rhythmic changes were not regulated by the rhythmic changes in ethylene production.Abbreviations ABA abscisic acid - ACC 1-aminocyclopropane-1-carboxylic acid - AVG aminoethyoxyvinylglycine - PAL phenylalanine ammonia-lyase     

Influence of ACC and Ethephon on cell growth in etiolated lupin hypocotyls. dependence on cell growth state

The possible implication of ethylene on the growth regulation of etiolated lupin hypocotyls was investigated. Excised hypocotyl sections from actively growing seedlings produced ethylene at a rate of 3 nmol h^-1 g^-1 min^-1. The rate of ethylene production was increased about 7 times when sections were treated with 10 mM 1-aminocyclopropane-1-carboxylic acid (ACC). Measurement of endogenous ACC showed that 95 % of total ACC (64.2 nmol g^-1 min^-1) corresponded to conjugated ACC. Treatments to intact seedlings with the ethylene precursor ACC, and the ethylene generating compound, 2-chloroethyl phosphonic acid (ethephon) during the cell elongation phase of the hypocotyl (from 7 to 21 dage), modified the cell growth of the organ. ACC (1 or 5 mM) or low concentrations of ethephon (0.66 mM) produced a transient decrease in the growth rate without modifying the final length of the hypocotyls. Higher concentrations of ethephon reduced the final length; the younger the seedlings were, the greater the reduction. Simultaneously to inhibition of cell elongation, ethephon produced stimulation of the radial expansion of cells in pith and cortex. The growth inhibition period, which lasted for 2 days after the treatments, was followed by another period in which the growth rate of treated plants surpassed that of the control. In both cases differences were observed along the hypocotyls due to the different growth status of the cells. It is suggested that the sensitivity to ethylene and the metabolism of ethylene depend on the growth status of the cells.     

An evaluation of the role of ethylene in herbicidal injury induced by picloram or clopyralid in rapeseed and sunflower plants

The role of ethylene in herbicidal injury induced by 4-amino-3,5,6-trichloropicolinic acid (picloram) or 3,6-dichloropicolinic acid (clopyralid) was investigated in sunflower (Helianthus annuus L.) and rapeseed (Brassica napus L. cv Altex). Picloram induces herbicide injury in both species, whereas clopyralid induces injury only in sunflower. Picloram applied to the third leaf of a rapeseed plant increased ethylene evolution several-fold. Clopyralid had no effect on ethylene production in rapeseed. In sunflower, both picloram and clopyralid elevated ethylene production. Ethylene biosynthesis induced by the herbicide treatment was not restricted to treated areas. When clopyralid was applied only to the lower stem and cotyledons of sunflower, the herbicide treatment resulted in an increase in the rate of ethylene production from the true leaves. Increased ethylene production preceded or coincided with the onset of morphological responses induced by a herbicide application to a susceptible species. The contrast in ethylene production by these two plant species cannot be accounted for by differences in absorption and translocation of clopyralid and picloram.

Treatment with aminoethoxyvinylglycine (AVG) before picloram or clopyralid application prevented an increase in ethylene production. Pretreatment with AVG also delayed the development of morphological changes induced by picloram or clopyralid. It appears that enhanced ethylene biosynthesis after application of picloram or clopyralid to the susceptible plant species was a factor involved in resulting morphological changes.

     

Uniconazole inhibits stress-induced ethylene in wheat and soybean seedlings

Previous studies have shown that uniconazole inhibits ethylene synthesis and protects plants from various stresses. The present research was conducted to delineate the mechanism of ethylene inhibition by uniconazole [(E)-(p-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)-1-penten-3-ol]. Following heat stress of 48°C for 3 h, the shoots of the control wheat seedlings became desiccated, and the seedlings lost 23% of their fresh mass 8 h after stress. The control soybean seedlings had epinastic unifoliate leaves 5 h after foliar application (4.4 g.a.i./ha) of the herbicide triclopyr [(3,5,6-trichloro-2-pyridinyl)oxyacetic acid]. Soil drench applications of uniconazole, a potent member of the triazole family, reduced these symptoms associated with heat and herbicide stress in wheat (5.0 mg/L) and soybean (0.4 mg/L) seedlings, respectively.Basal ethylene production was inhibited 32 and 48% by uniconazole in the wheat and acotyledonous soybean seedlings, respectively. Following a 48°C heat stress, 1-aminocyclopropane-1-carboxylic acid (ACC) levels increased 40% in both the control and uniconazole-treated wheat seedlings. After triclopyr application, ACC levels increased 400% in both the control and uniconazoletreated soybean seedlings. The increased ACC levels, following stress, were accompanied by increased ethylene production from the control, but not from the uniconazole-treated wheat and acotyledonous soybean seedlings. Uniconazole treatment did not significantly change the basal or stress-induced N-malonyl-1-aminocyclopropane-1-carboxylic acid (MACC) levels compared to controls. These results suggest that uniconazole inhibits ethylene synthesis by interfering with the conversion of ACC to ethylene in wheat and acotyledonous soybean seedlings. Ethylene production and ACC conversion were not inhibited by uniconazole in excised soybean cotyledons. These results indicate that different ethylene-forming enzyme (EFE) systems operate in the soybean acotyledonous seedling and cotyledon, and the system in the former is inhibited by uniconazole.     

Uniconazole inhibits stress-induced ethylene in wheat and soybean seedlings

Previous studies have shown that uniconazole inhibits ethylene synthesis and protects plants from various stresses. The present research was conducted to delineate the mechanism of ethylene inhibition by uniconazole [(E)-(p-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)-1-penten-3-ol]. Following heat stress of 48°C for 3 h, the shoots of the control wheat seedlings became desiccated, and the seedlings lost 23% of their fresh mass 8 h after stress. The control soybean seedlings had epinastic unifoliate leaves 5 h after foliar application (4.4 g.a.i./ha) of the herbicide triclopyr [(3,5,6-trichloro-2-pyridinyl)oxyacetic acid]. Soil drench applications of uniconazole, a potent member of the triazole family, reduced these symptoms associated with heat and herbicide stress in wheat (5.0 mg/L) and soybean (0.4 mg/L) seedlings, respectively. Basal ethylene production was inhibited 32 and 48% by uniconazole in the wheat and acotyledonous soybean seedlings, respectively. Following a 48°C heat stress, 1-aminocyclopropane-1-carboxylic acid (ACC) levels increased 40% in both the control and uniconazole-treated wheat seedlings. After triclopyr application, ACC levels increased 400% in both the control and uniconazoletreated soybean seedlings. The increased ACC levels, following stress, were accompanied by increased ethylene production from the control, but not from the uniconazole-treated wheat and acotyledonous soybean seedlings. Uniconazole treatment did not significantly change the basal or stress-induced N-malonyl-1-aminocyclopropane-1-carboxylic acid (MACC) levels compared to controls. These results suggest that uniconazole inhibits ethylene synthesis by interfering with the conversion of ACC to ethylene in wheat and acotyledonous soybean seedlings. Ethylene production and ACC conversion were not inhibited by uniconazole in excised soybean cotyledons. These results indicate that different ethylene-forming enzyme (EFE) systems operate in the soybean acotyledonous seedling and cotyledon, and the system in the former is inhibited by uniconazole.     

Comparison of the effects of white light and the growth retardant paclobutrazol on the ethylene production in bean hypocotyls

At a concentration of 17 µmol·L^–1, paclobutrazol (PP), a triazole plant growth retardant, effectively reduced the elongation and increased the thickness of hypocotyls in 6-day-old Phaseolus vulgaris L. cv. Juliska seedlings, both in the light and in the dark. PP treatment did not increase the cell number in transverse sections of hypocotyls. The diameter of hypocotyls was uniform from the zone of intensive elongation along the whole hypocotyl in etiolated plants, but those grown in the light exhibited an additional lateral expansion at the base. Ethylene evolution was not reduced by PP in etiolated hypocotyls, and did not differ significantly in the elongating apical and fully grown basal zones. PP reduced the ethylene release by the growing zones in green hypocotyls, but not in the basal parts, which resulted in an increasing ethylene gradient towards the hypocotyl base. The level of 1-aminocyclopropane-1-carboxylic acid (ACC), the immediate precursor of ethylene, was much higher in retardant-treated hypocotyls than in the controls, which was due in part to the reduced malonylation. The swelling of the hypocotyl bases could be eliminated by inhibitors of ethylene biosynthesis or action, or could be induced by 10 µmol·L^–1ACC in control plants in the light. None of these treatments had a significant effect on the lateral expansion of hypocotyls in etiolated seedlings. PP treatment induced a similar effect to that of white light in etiolated seedlings, and amplified the effect of light in green plants with respect to the ACC distribution, and consequently, the ethylene production in the hypocotyls of 6-day-old bean seedlings. It can be concluded that the lateral expansion of hypocotyl bases in PP-treated green plants is controlled by ethylene.     

Ethylene-Mediated Regulation of Gibberellin Content and Growth in Helianthus annuus L

Elongation of hypocotyls of sunflower can be promoted by gibberellins (GAs) and inhibited by ethylene. The role of these hormones in regulating elongation was investigated by measuring changes in both endogenous GAs and in the metabolism of exogenous [³H]- and [²H₂]GA₂₀ in the hypocotyis of sunflower (Helianthus annuus L. cv Delgren 131) seedlings exposed to ethylene. The major biologically active GAs identified by gas chromatography-mass spectrometry were GA₁, GA₁₉, GA₂₀, and GA₄₄. In hypocotyls of seedlings exposed to ethylene, the concentration of GA₁, known to be directly active in regulating shoot elongation in a number of species, was reduced. Ethylene treatment reduced the metabolism of [³H]GA₂₀ and less [²H₂]GA₁ was found in the hypocotyls of those seedlings exposed to the higher ethylene concentrations. However, it is not known if the effect of ethylene on GA₂₀ metabolism was direct or indirect. In seedlings treated with exogenous GA₁ or GA₃, the hypocotyls elongated faster than those of controls, but the GA treatment only partially overcame the inhibitory effect of ethylene on elongation. We conclude that GA content is a factor which may limit elongation in hypocotyls of sunflower, and that while exposure to ethylene results in reduced concentration of GA₁ this is not sufficient per se to account for the inhibition of elongation caused by ethylene.     

Some Morphogenic Differences between Monoecious and Gynoecious Cucumber Seedlings as Related to Ethylene Production

Exposure of gibberellic acid-treated seedlings of a monoecious cucumber cultivar `Chipper' (Cucumis sativus L.) to ethylene caused thickening of the hypocotyl, inhibited longitudinal growth, and had no effect on fresh weight. Downward curvature of cotyledons was increased by the presence of ethylene. A gynoecious breeding line, `Gy 3,' had thicker hypocotyls and displayed its cotyledons in a more downward position than `Chipper'. Excised hypocotyls of the gynoecious seedlings produced three times as much ethylene as did the monoecious Chipper hypocotyls. Thus, ethylene may play a role in the regulation of cucumber seedling morphology.     

Influence of cobalt on soybean hypocotyl growth and its ethylene evolution

Development of dark-grown “Clark” soybean (Glycine max [L.] Merr.) seedlings is abnormal at 25 C but normal at 20 and 30 C. At 25 C, hypocotyls swell and fail to elongate normally; lateral root formation and seedling ethylene evolution are enhanced.

Co²⁺ promoted hypocotyl elongation of etiolated “Clark” soybean seedlings by 28% when grown at 25 C. The same growth-promoting concentration reduced hypocotyl thickness and primary root elongation by 28 and 43%, respectively. Co²⁺ inhibited ethylene production both of intact seedlings and of apical 1-centimeter hypocotyl segments with attached epicotyls and cotyledons by 65 and 60%, respectively. These results suggest that Co²⁺ exerts its effects on the hypocotyl growth by inhibiting ethylene production, and also confirm our previous conclusion that abnormal ethylene production at 25 C is responsible for the inhibition of hypocotyl elongation and for its swelling.

     

Effects of Mecoprop (an Auxin Analogue) on Ethylene Evolution and Epinasty in Two Biotypes of Stellaria media

Petiolar epinasty and the production of ethylene (ethene) werestudied in chickweed biotypes, Stellaria media, treated withthe herbicide and auxin analogue (RS)-2-(4-chloro-o-tolyloxy)propionicacid, potassium salt, common name mecoprop. This compound causedsevere epinasty and stimulated the production of ethylene fromshoot explants. However, when intact plants were treated withethylene, the leaves became only slightly epinastic. The ethyleneprecursor, 1-aminocyclopropane-I-carboxylic acid (ACC), at concentrationswhich stimulated the release of ethylene, was equally ineffectivein causing epinasty. Furthermore, 2, 5-norbornadiene, a specific,competitive inhibitor of ethylene action, only partly alleviatedmecoprop-induced epinasty. The responses observed in chickweedwere compared with those produced in tomato plants. ACC inducedepinasty in tomato within 2 h and these symptoms were completelyinhibited by norbornadiene. However, as in chickweed, the inhibitorgave only partial reversal of mecoprop-induced epinasty, implyingthat the epinastic response caused by the herbicide was notattributable to ethylene alone. We therefore suggest that mecoprop-inducedepinasty is a result of the combined ethylene-stimulating andgrowth-promoting properties of the herbicide. Mecoprop-stimulated ethylene evolution was initially significantlygreater in a herbicide-resistant, compared with a more susceptiblebiotype of chickweed. The significance of this finding is discussedin relation to the mechanism of mecoprop resistance in chickweed. Epinasty, ethylene, (RS)-2-(4-chloro-o-tolyloxy)propionic acid, mecoprop, herbicide resistance, chickweed, Stellaria media L., tomato, Lycopersicon esculentum L.     

Narrow-band light regulation of ethylene and gibberellin levels in hydroponically-grown <Emphasis Type="Italic">Helianthus annuus</Emphasis> hypocotyls and roots

Both hypocotyl and root growth of sunflower (Helianthus annuus) were examined in response to a range of narrow-band width light treatments. Changes in two growth-regulating hormones, ethylene and gibberellins (GAs) were followed in an attempt to better understand the interaction of light and hormonal signaling in the growth of these two important plant organs. Hydroponically-grown 6-day-old sunflower seedlings had significantly elongated hypocotyls and primary roots when grown under far-red (FR) light produced by light emitting diodes (LEDs), compared to narrow-band red (R) and blue (B) light. However, hypocotyl and primary root lengths of seedlings given FR light were still shorter than was seen for dark-grown seedlings. Light treatment in general (compared to dark) increased lateral root formation and FR light induced massive lateral root formation, relative to treatment with R or B light. Levels of ethylene evolution (roots and hypocotyls) and concentrations of endogenous GAs (hypocotyls) were assessed from both 6-day-old sunflower plants either grown in the dark, or treated with FR, R or B light. Both R and B light had similar effects on hypocotyl and root growth as well as on ethylene and on hypocotyl GA levels. Dark treatment resulted in the highest ethylene levels, whereas FR treatment significantly reduced ethylene evolution for both hypocotyls and roots. R- and B-light treatments elevated ethylene evolution relative to FR light. Endogenous GA₅₃ and GA₁₉ levels in hypocotyls were significantly higher and GA₄₄, GA₂₀ and GA₁ levels significantly lower, for dark and FR light treatments compared to R and B light-treatments. The patterns seen for changes in GA concentrations indicate FR-, R- and B-light-mediated effects [differences] in the metabolism of the early C₂₀ GAs, GA₅₃ → GA₄₄ → GA_19. Surprisingly, GA₂₀, GA₁ and GA₈ levels in hypocotyls were very much reduced by treatment of the plants with FR light, relative to B and R-light treatments, e.g. the increased hypocotyl elongation induced by FR light was correlated with reduced levels of all three of the downstream C₁₉ GAs. The best explanation, albeit speculative, is that a more rapid metabolism, i.e. GA₂₀ → GA₁ → GA₈ → GA₈ conjugates occurs under FR light. Although this study provided no evidence that elevated ethylene evolution by roots or hypocotyls of sunflower is controlling growth via endogenous GA biosynthesis, there are differences between soil-grown and hydroponically-grown sunflower seedlings with regard to trends seen for hypocotyl GA concentrations and both root and hypocotyl ethylene evolution in response to narrow band width R and FR light signaling.     

Effect of paraquat on ethylene biosynthesis by intact green Phaseolus vulgaris seedlings

Ethylene production by intact green bean ( Phaseolus vulgaris L. cv. Limburgse vroege) seedlings was investigated in white light and in darkness. In white light both endogenous and 1-aminocyclopropane-1-carboxylic acid (ACC)-induced ethylene production were stimulated. A decrease in the 1-(malonylamino)cyclopropane-1-carboxylic acid (M-ACC) level and a slight increase in the free ACC concentration could be observed in light. The total amount of endogenous ACC was not changed by light. We related the effect of light to the effect of paraquat on ethylene biosynthesis. Paraquat caused a strong increase of endogenous ethylene production in light. However, the conversion of exogenously applied ACC in light was not influenced by the paraquat treatment, although the presence of the herbicide in the chloroplasts was evident through the inhibition of net photosynthesis. In light, paraquat increased the total ACC content. This was due to an enlargement of the free ACC pool. The effects of white light and paraquat on ethylene biosynthesis can be differentiated from one another: white light exerts its influence on the conversion of ACC to ethylene; it also seems to inhibit the malonylation and may act on the formation of ACC itself. Paraquat influences only ACC synthesis.     

Regulation of Auxin-induced Ethylene Production in Mung Bean Hypocotyls: Role of 1-Aminocyclopropane-1-Carboxylic Acid

Ethylene production in mung bean hypocotyls was greatly increased by treatment with 1-aminocyclopropane-1-carboxylic acid (ACC), which was utilized as the ethylene precursor. Unlike auxin-stimulated ethylene production, ACC-dependent ethylene production was not inhibited by aminoethoxyvinylglycine, which is known to inhibit the conversion of S-adenosylmethionine to ACC. While the conversion of methionine to ethylene requires induction by auxin, the conversion of methionine to S-adenosylmethionine and the conversion of ACC to ethylene do not. It is proposed that the conversion of S-adenosylmethionine to ACC is the rate-limiting step in the biosynthesis of ethylene, and that auxin stimulates ethylene production by inducing the synthesis of the enzyme involved in this reaction.