Ethylene as a possible mediator of light-induced inhibition of root growth

Eliasson, L. and Bollmark, M. 1988. Ethylene as a possible mediator of light-induced inhibition of root growth. - Physiol. Plant. 72: 605–609.
Pea seedlings ( Pisum sativum L. cv. Weibull's Marma) were used to investigate the possible role of ethylene in light-induced inhibition of root elongation. Illumination of the roots with white light inhibited root elongation by 40–50% and increased ethylene production by the roots about 4-fold. Our main approach was to use exogenous 1-aminocyclopropane-1-carboxylic acid (ACC), supplied in the growth solution, to monitor ethylene production of the roots independent of light treatment. Ethylene production of excised root tips increased with increasing ACC concentrations. The rate of ethylene production in dark-grown roots treated with 0.1 μ M ACC was similar to that caused by illumination. Low ACC concentrations (0.01–0.1 μ M ) decreased the rate of root elongation, especially in seedlings grown in the dark, and 0.1 μ M ACC inhibited elongation to about the same extent as light. In light the roots curved and grew partly plagiogravitropically. This effect was also simulated by the 0.1 μ M ACC treatment. At 1 μ M and higher concentrations, ACC inhibited root growth almost completely and caused conspicuous curvatures of the root tips both in light and darkness. Inhibitors of ethylene synthesis and action partially counteracted the inhibition of root elongation caused by light. These observations suggest that the increase in ethylene production caused by light is at least partly responsible for the decreased growth of light-exposed roots.     

Effect of apex excision and replacement by 1-naphthylacetic acid on cytokinin concentration and apical dominance in pea plants

As known from literature lateral buds from pea ( Pisum sativum ) plants are released from apical dominance when repeatedly treated with exogenous cytokinins. Little is known, however, about the endogenous role of cytokinins in this process and whether they interact with basipolar transported IAA, generally regarded as the main signal controlling apical dominance. This paper presents evidence that such an interaction exists.
The excision of the apex of pea plants resulted in the release of inhibited lateral buds from apical dominance (AD). This could be entirely prevented by applying 1-naphthylacetic acid (NAA) to the cut end of the shoot. Removal of the apex also resulted in a rapid and rather large increase in the endogenous concentrations of zeatin riboside (ZR), isopentenyladenosine (iAdo) and an as yet unidentified polar zeatin derivative in the node and internode below the point of decapitation. This accumulation of ZR and iAdo, was strongly reduced by the application of NAA. The observed increase in cytokinin concentration preceded the elongation of the lateral buds, suggesting that endogenous cytokinins play a significant role in the release of lateral buds from AD. However, the effect of NAA on the concentration of cytokinins clearly demonstrated the dominant role of the polar basipetally transported auxin in AD. The results suggest a mutual interaction between the basipolar IAA transport system and cytokinins obviously produced in the roots and transported via the xylem into the stem of the pea plants.     

Cytokinin effects on root growth and possible interactions with ethylene and indole-3-acetic acid

Etiolated pea seedlings ( Pisum sativum L. cv. Weibull's Marma) were used to investigate the effects of exogenous cytokinins on root growth. Benzylaminopurine (BAP) added to the growth solution inhibited the elongation and formation of lateral roots and stimulated swelling of the root tips. Similar effects were obtained with zeatin. The effects were obtained over a wide concentration range down to 0.01 μ M . Growth responses appeared only after treatment for several hours, and the duration of treatment had an important influence on the degree of the effects. BAP caused a moderate increase in ethylene production as measured in excised 10-mm-long root tips. Lowering ethylene production by treatment with cobalt ions counteracted both the inhibition and swelling caused by BAP. Treatment with silver ions also reversed the effect to some extent, indicating that ethylene is involved in the response of the roots to BAP. To further study the involvement of the increased ethylene production in the elongation and swelling response, the effects were compared with those obtained after application of 1-aminocyclopropane-1-carboxylic acid (ACC) in relation to the ethylene produced from this compound. This comparison showed that the increase in ethylene production caused by BAP was too low to explain the response of the roots. However, ACC treatment caused a considerable lowering of the content of indole-3-acetic acid (IAA) in the root tips, whereas BAP did not; instead, BAP increased the amount of IAA per root tip. It is concluded that cytokinins influence growth processes in roots via several mechanisms. A synergistic interaction between endogenous IAA, maintained at a high level by the cytokinin treatment, and the increased ethylene levels appears to explain most of the cytokinin effects during the first day of treatment.     

A reappraisal of nitrate inhibition of nitrogenase in A317, a nitrate reductase-deficient mutant of pea (Pisum sativum)

Symbiotic plants of Pisum sativum L. cv. Juneau and its nitrate reductase-(EC 1. 6. 6. 1)-deficient mutant, A317, were exposed to nitrate for up to 8 days and assessed for nitrate assimilation, nitrogenase activity and nodule carbohydrate status. The mutant, A317, was not impaired in its ability to absorb nitrate over up to 8 days, but was leakier with respect to nitrate reduction ability than previously realized, as 63% of the nitrate absorbed by the plant over 8 days was assimilated (in contrast to 93% in the wild type). After 2 days exposure to 5 m M nitrate, nitrogenase (EC 1.18.2.1) activity was less affected in A317 (84% of initial) than in Juneau (46% of initial): nodule starch reserves were less depleted in A317 (70% of initial) than in Juneau (26% of initial). It was concluded that nitrate reduction is a major cause of nitrate inhibition of nodule activity, and that its effect may be mediated through a decrease in the availability of carbohydrate to the nodules. Longer term (> 4 day) exposure of A317 plants to nitrate resulted in accumulation of nitrate in plant tissues, an associated necrosis of shoot tissue, a marked decrease in nodule starch content and a severe inhibition of nodule activity. This consideration of the effect of the duration of exposure to nitrate is used to resolve a discrepancy between previous reports on the sensitivity to nitrate of nitrogenase activity in nitrate reductase-deficient mutants of pea.     

Gibberellin-enhanced sugar accumulation in growing subhooks of etiolated Pisum sativum seedlings. Effects of gibberellic acid, indoleacetic acid and cycloheximide on invertase activity, sugar accumulation and growth

The possible involvement of invertase in the action of gibberellic acid (GA) on stimulating sugar accumulation in growing subhooks of Alaska pea ( Pisum sativum L. cv. Alaska) was studied. GA and indoleacetic acid (IAA) stimulated elongation growth to a similar extent. GA, in contrast to IAA, increased the amount of soluble sugars in the subhook. GA substantially increased invertase activity whereas IAA did not. These results suggest that the mode of action of GA and IAA differs, although both stimulate pea subhook growth.
Cycloheximide (CH) inhibited the effect of GA on invertase activity, accumulation of soluble sugars, and elongation growth. Good correlations were found between invertase activity, the amount of soluble sugars and growth. The results suggest that GA-induced enhancement of sugar accumulation in the subhook cells is dependent on increased invertase activity. The sugar accumulated in the subhook may be involved in growth promotion by GA.     

CO2 effects on apical dominance in Pisum sativum

Alaska pea plants (Pisum sativum L.) were grown at 0.10 vol% and 0.035 vol% CO₂ to determine the effects of high CO₂ concentration upon plant growth and apical dominance. The results showed that a 0.10 vol% CO₂ atmosphere significantly increased the rate of lateral branch, flower bud, flower and fruit development over an environment with 0.035 vol% CO₂. At plant maturity, however, there were no significant differences in the number of branches or fruits produced at the different CO₂ levels. Thus, no evidence was obtained for the loss of apical dominance at the CO₂ concentrations tested. Root dry weight was significantly greater in plants grown at 0.10 vol% CO₂ than in those grown at 0.035 vol% CO₂ and leaf dry weight was significantly lower. However, no significant differences were found in total plant dry weight production at plant maturity.     

Shoot inversion-induced ethylene in pharbitis nil induces the release of apical dominance by restricting shoot elongation

Shoot inversion induces outgrowth of the highest lateral bud (HLB) adjacent to the bend in the stem in Pharbitis nil. In order to determine whether or not ethylene produced by shoot inversion plays a direct role in promoting or inhibiting bud outgrowth, comparisons were made of endogenous levels of ethylene in the HLB and HLB node of plants with and without inverted shoots. That no changes were found suggests that the control of apical dominance does not involve the direct action of ethylene. This conclusion is further supported by evidence that the direct application of ethylene inhibitors or ethrel to inactive or induced lateral buds has no significant effect on bud outgrowth. The hypothesis that ethylene evolved during shoot inversion indirectly promotes the outgrowth of the highest lateral bud (HLB) by restricting terminal bud (TB) growth is found to be supported by the following observations: (1) the restriction of TB growth appears to occur before the beginning of HLB outgrowth; (2) the treatment of the inverted portion of the shoot with AgNO₃, an inhibitor of ethylene action, dramatically eliminates both the restriction of TB growth and the promotion of HLB outgrowth which usually accompany shoot inversion; and (3) the treatment of the upper shoot of an upright plant with ethrel mimics shoot inversion by retarding upper shoot growth and inducing outgrowth of the lateral bud basipetal to the treated region.     

Isolation and identification of lateral bud growth inhibitor,indole-3-aldehyde,involved in apical dominance of pea seedlings

A lateral bud growth inhibitor was isolated from etiolated pea seedlings and identified as indole-3-aldehyde. The indole-3-aldehyde content was significantly higher in the diffusates from explants with apical bud and indole-3-acetic acid treated decapitated explants, in which apical dominance is maintained, than in those from decapitated ones releasing apical dominance. When the indole-3-aldehyde was applied to the cut surface of etiolated decapitated plants or directly to the lateral buds, it inhibited outgrowth of the latter. These results suggest that indole-3-aldehyde plays an important role as a lateral bud growth inhibitor in apical dominance of pea seedlings.     

A reappraisal of the role of abscisic acid and its interaction with auxin in apical dominance

BACKGROUND AND AIMS: Evidence from pea rms1, Arabidopsis max4 and petunia dad1 mutant studies suggest an unidentified carotenoid-derived/plastid-produced branching inhibitor which moves acropetally from the roots to the shoots and interacts with auxin in the control of apical dominance. Since the plant hormone, abscisic acid (ABA), known to inhibit some growth processes, is also carotenoid derived/plastid produced, and because there has been indirect evidence for its involvement with branching, a re-examination of the role of ABA in apical dominance is timely. Even though it has been determined that ABA probably is not the second messenger for auxin in apical dominance and is not the above-mentioned unidentified branching inhibitor, the similarity of their derivation suggests possible relationships and/or interactions. METHODS: The classic Thimann-Skoog auxin replacement test for apical dominance with auxin [0.5 % naphthalene acetic acid (NAA)] applied both apically and basally was combined in similar treatments with 1 % ABA in Ipomoea nil (Japanese Morning Glory), Solanum lycopersicum (Better Boy tomato) and Helianthus annuus (Mammoth Grey-striped Sunflower). KEY RESULTS: Auxin, apically applied to the cut stem surface of decapitated shoots, strongly restored apical dominance in all three species, whereas the similar treatment with ABA did not. However, when ABA was applied basally, i.e. below the lateral bud of interest, there was a significant moderate repression of its outgrowth in Ipomoea and Solanum. There was also some additive repression when apical auxin and basal ABA treatments were combined in Ipomoea. CONCLUSION: The finding that basally applied ABA is able partially to restore apical dominance via acropetal transport up the shoot suggests possible interactions between ABA, auxin and the unidentified carotenoid-derived branching inhibitor that justify further investigation.     

Ethylene biosynthesis in Regnellidium diphyllum and Marsilea quadrifolia

The pathway of ethylene biosynthesis was examined in two lower plants, the semi-aquatic ferns Regnellidium diphyllum Lindm. and Marsilea quadrifolia L. As a positive control for the ethylene-biosynthetic pathway of higher plants, leaves of Arabidopsis thaliana (L.) Heynh. were included in each experiment. Ethylene production by Regnellidium and Marsilea was not increased by treatment of leaflets with 1-aminocyclopropane-1-carboxylic acid (ACC), the precursor of ethylene in higher plants. Similarly, ethylene production was not inhibited by application of aminoethoxyvinylglycine and -aminoisobutyric acid, inhibitors of the ethylene biosynthetic enzymes ACC synthase and ACC oxidase, respectively. However, ACC was present in both ferns, as was ACC synthase. Compared to leaves of Arabidopsis, leaflets of Regnellidium and Marsilea incorporated little [¹⁴C]ACC and [¹⁴C]methionine into [¹⁴C]ethylene. From these data, it appears that the formation of ethylene in both ferns occurs mainly, if not only, via an ACC-independent route, even though the capacity to synthesize ACC is present in these lower plants.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - AdoMet S-adenosyl-l-methionine - AIB -aminoisobutyric acid - AVG aminoethoxyvinylglycine This research was supported by the U.S. Department of Energy through grant No. DE-FG02-91ER20021 and, in part, by a fellowship of the National Engineering and Research Council of Canada to Jacqueline Chernys.     

Nitrate reductase activity in nodules of pea inoculated with hydrogenase positive and hydrogenase negative strains of Rhizobium leguminosarum

The nitrate reductase (NR, EC 1.6.6.1) activity in root nodules formed by hydrogenase positive (Hup⁺) and hydrogenase negative (Hup⁻) Rhizobium leguminosarum strains was examined in symbioses with the pea cultivar Alaska ( Pisum sativum L.), Rates of activity were determined by the in vivo assay in nodules from plants that were only N₂-dependent or grown in the presence of 2 m M KNO₃. The rates varied widely among strains, regardless of the Hup phenotype of the R. leguminosarum strain used for inoculation, but the overall results indicated that nodules formed by Hup⁻ strains accumulated more nitrite in the incubation medium than did those with Hup⁻ phenotypes. Total plant dry weight and reduced nitrogen content of pea plants grown in the presence of 2 m M KNO₃ and inoculated with single Hup⁺ and Hup⁻ R. leguminosarum strains were statistically different among some strains. These observations suggest that the possible advantages derived from the presence of the Hup system on whole plant growth may be counteracted by the higher rates of NR activity in the Hup⁻ strains in the R. leguminosarum -pea symbiosis.     

Characteristics of nitrate uptake into seedlings of pea (Pisum sativum L. cv. Feltham First). Changes in net NO−3 uptake following inoculation with Rhizobium and growth in low nitrate concentrations

Abstract Nitrate uptake into intact pea seedlings (Pisum sativum L. cv. Feltham First) grown in hydroponic culture has been investigated. Following inoculation with Rhizobium leguminosarum a twofold increase in net nitrate uptake was observed. Changes in morphological characteristics following inoculation were found to decrease the effective area available for absorption. There was a two-fold decrease in net nitrate uptake into intact seedlings grown in the presence of N compared with N free media. In the former case net nitrate uptake appeared to stall at regular intervals. In both cases only the initial rates of nitrate uptake were found to be responsive to the external nitrate concentration. The results are discussed in terms of current models for the regulation of NO^?₃ uptake by higher plants.     

Ethylene formation in plant mitochondria. Dependence on the transport of 1-aminocyclopropane-1-carboxylic acid across the membrane

The mitochondrial fraction isolated from plumular hooks of etiolated pea seedlings ( Pisum sativum L. cv. Kelvedon Wonder) displayed a ten-fold higher rate of ethylene formation from 1-aminocyclopropane-1-carboxylic acid [ACC; 3.2 nmol C₂H₄ (mg protein ⁻¹)h⁻¹], than the tissue from which it was isolated. When the ionophores valinomycin or nigericin were added, a 60- to 70-fold increase in activity in intact mitochondria over the activity in plumular hooks was obtained for ethylene formation under the same conditions, and a 20-fold increase was obtained upon addition of gramicidin. The addition of ionophores did not affect the rate of ethylene formation in submitochondrial particles (55% inside-out as determined by cytochrome oxidase latency) which already exhibited a 2–3-fold higher specific activity than intact mitochondria. Low concentrations of the detergents cholate and deoxycholate increased mitochondrial ethylene formation activity and had no effect on the rate of the reaction in submitochondrial particles. These results support the suggestion that ACC conversion to ethylene is associated with the inner side of the inner mitochondrial membrane and that transport across the intact mitochondrial membrane is rate-limiting in the reaction.     

Ascorbic acid effect on the onset of cell proliferation in pea root

The ability of ascorbic acid to induce cell proliferation of non-cycling cells was investigated in quiescent embryo root of Pisum sativum L. cv. Lincoln, as well as in the active plantlet root meristem, where a minor portion of the cells is non-proliferating. Quiescent embryo cells speeded up the G₀–G₁ transition during germination in the presence of ascorbic acid. In addition, proliferating cells present in the root tip of 3-day-old plantlets, arrested at the G₁/S boundary by hydroxyurea, resumed the cycle earlier than the control, when treated with ascorbic acid. In contrast, ascorbic acid was unable to induce the proliferation of non-cycling cells present in the active meristem. Therefore, these data suggest that the ability of ascorbic acid lo induce cell proliferation depends on the physiological status of the cell. In particular the data indicate that ascorbic acid is involved in cell proliferation as a factor necessary to enable already competent cells to progress through the cell cycle phases, but not as a factor able to induce non-competent cells to overcome proliferation arrest.     

镉引起小麦苗逆境乙烯的产生及其和镉的吸收分布的关系

溶液培养小麦幼苗转移至含Cd~(2 )的营养液中,根系乙烯产生较快地增加,约在12h达高峰,然后下降;ACC含量亦呈先升后降的趋势。未和Cd~(2 )溶液直接接触的地上部乙烯亦增加,至36h达高峰,此后急剧下降,而ACG和 MAGC含量持续上升。地上部乙烯的增加,主要是由通过根系运往地上部的镉直接作用的结果,不是根部合成ACG运往地上部后再产生的。电镜观察表明,地上部乙烯产生和ACC含量变化的时间进程,可以与镉进入叶细胞内的部位及其对细胞膜和细胞器的影响相联系。     

Effects of cadmium on the uptake,distribution and assimilation of nitrate in Pisum sativum

The net uptake, distribution and assimilation of NO ₃ ^– were studied in pea plants subjected to either long-term continuous Cd treatment for 10 d (10 or 50 M Cd) or short-term treatment (72 h) with 50 M Cd. In the latter treatment, the effects of transferring the plants to a Cd-free nutrient solution for a 'recovery period' of 96 h were also studied. All these treatments were compared with 'controls', plants which received no Cd. In both experiments, the reduction in fresh weight was associated with a decrease in the content (%) of shoot and root water and in transpiration rate as Cd concentration increased. The concentration of ₃ ^– in the shoots and sap decreased dramatically and net ₃ ^– uptake was severely inhibited, effects associated with a loss of shoot nitrate reductase (NR) activity. In the short-term Cd treatment, net ₃ ^– uptake was almost completely inhibited after 24 h, but recovered after the transfer of plants to a Cd-free nutrient solution. Similarly, a dramatic decrease in the shoot NR activity was observed. The uptake, distribution and tissue partitioning of K was also studied, which is considered to be the major counterion of ₃ ^– . Potassium uptake was similarly affected by Cd, as inferred from the ratio ₃ ^– /K uptake, which was ca. 10. The ratio K/ ₃ ^– tissue content increased in the shoot concomitantly to Cd in both long-term and short-term metal supply. These parameters showed a tendency of K similar to that observed for ₃ ^– , although its relative tissue distribution was not affected by Cd.     

Effect of nitrate on nitrogen fixation and nodule carbohydrate and organic acid concentrations in pea mutants deficient in nitrate reductase

Nitrate inhibits symbiotic N₂ fixation and a number of hypotheses concerned with NO₃⁻ assimilation have been suggested to explain this inhibition. These hypotheses were tested using a pea ( Pisum sativum L. cv. Juneau) with normal nitrate reductase NR; (EC 1,6,6,4) activity and two mutants of cv. Juneau, A317 and A334, with impaired NR activity. The plants were inoculated with three strains of Rhizobium leguminosarum and grown for 3 weeks in N-free medium, followed by 1 week in medium supplemented with 0, 5 or 10 m M KNO₃ before harvesting. NO₃ was taken up at comparable rates by the parent and the mutants and accumulated in leaf and stem tissue of the latter. Acetylene reduction rates were inhibited similarly in both the parent and mutants in the presence of KNO₃ but there were differences among rhizobial strains. Starch concentration of the nodules decreased by 46% in the presence of KNO₃ and there were differences among rhizobial strains but not among pea genotypes. Malate and succinate accumulated in nodules in the presence of KNO₃. These data are not consistent with the photosynthate deprivation hypothesis as a primary mechanism for NO₃ inhibition of N₂ fixation since NO₃ affected the nodule carbohydrate composition of all three pea genotypes in a similar manner. The lack of correlation between NR activity and NO₃ inhibition of N₂ fixation suggests that NO₃ assimilation may be only indirectly involved in the inhibition phenomenon.     

In vivo formation of 1-malonylaminocyclopropane-1-carboxylic acid and its relationship to ethylene production in cocklebur seed segments: A tracer study with 1-amino-2-ethylcyclopropane-1-carboxylic acid

The in vivo formation of 1-malonylaminocyclopropane-1-carboxylic acid (malonyl-ACC) and its relationship to ethylene production in the axial tissue of cocklebur (Xanthium pennsylvanicum) seeds were investigated using the stereoisomers of the 2-ethyl derivative of ACC (AEC), as tracers of ACC. Of the four AEC isomers, the (1R, 2S)-isomer was converted most effectively to a malonyl conjugate as well as to 1-butene. Malonyl-AEC, once formed, was not decomposed, supporting the view that malonyl-ACC does not liberate free ACC for ethylene production in this tissue. d-Phenylalanine inhibited the formation of malonyl-AEC and, at the same time, promoted the evolution of 1-butene, whereas l-phenylalanine did not. Possibly, the d-amino-acid-stimulated ethylene production in cocklebur seed tissues is due to an increase in the amount of ACC available for ethylene production which results from the decrease of ACC malonylation in the tissues treated with d-amino acid. 2-Aminoisobutyric acid, a competitive inhibitor of ACC-ethylene conversion, did not affect the malonylation of AEC.     

Interaction of 4-chloroindole-3-acetic acid and gibberellins in early pea fruit development

In pea, normal pod (pericarp) growth requires the presence of seeds; and in the absence of seeds, gibberellins (GAs) and/or auxins can stimulate pericarp growth. To further characterize the function of naturally occurring pea GAs and the auxin, 4-chloroindole-3-acetic acid (4-Cl-IAA), on pea fruit development, profiles of the biological activities of GA3, GA1, and 4-Cl-IAA on pericarp growth were determined separately and in combination on pollinated deseeded ovaries (split-pericarp assay) and nonpollinated ovaries. Nonpollinated ovaries (pericarps) responded differently to exogenous GAs and 4-Cl-IAA than pollinated deseeded pericarps. In nonpollinated pericarps, both GA3 and 4-Cl-IAA stimulated pericarp growth, but GA3 was significantly more active in stimulating all measured parameters of pericarp growth than 4-Cl-IAA. 4-Cl-IAA, GA1, and GA3 were observed to stimulate pericarp growth similarly in pollinated deseeded pericarps. In addition, the synergistic effect of simultaneous application of 4-Cl-IAA and GAs on pollinated deseeded pericarp growth supports the hypothesis that GAs and 4-Cl-IAA are involved in the growth and development of pollinated ovaries.