Changes in the Endogenous Growth Regulators in Bulbous Iris in Bulb-forming and Nonbulb-forming Aspects

Bulblets of 3–4 g of Dutch iris (Iris hollandica) cv.Dominator stored at 20°C and then grown at 15°C developedonly three or four leaves and bulbs formed at the base of eachleaf, whereas when grown at 25°C, they continued to growvegetatively with the development of 10 true leaves and didnot form any new bulb. This demonstrated that bulb formationin bulbous plants can be controlled by environmental factors.The levels of both abscisic acid and auxin activities increasedduring growth under the bulb-forming condition whereas onlyauxin activity increased under the nonbulb-forming condition.The coexistence of both abscisic acid and auxin seems to beessential in the processes of bulb formation. (Received August 22, 1980; Accepted November 26, 1980)     

Flower Abscission in Excised Inflorescences of Three Plectranthus Cultivars

Flower abscission induced by ethylene in three Plectranthus cultivars was investigated in order to characterise response to a range of inhibitory and antagonistic compounds. Excised inflorescences were exposed to 100 ml l⁻¹ ethylene gas or placed in various concentrations of ethephon (277, 27.7, 2.77, 0.277 and 0.0277 μM). Flower abscission in Plectranthus was readily induced by applying ethylene gas and by the 277 μM dose of ethephon. Removal of the inflorescences from the ethylene treatment prevented subsequent flower abscission. This implies that ethylene treatment did not induce an autocatalytic production of ethylene. Compounds that are known to compete for the ethylene receptor (100 and 500 ppb 1-methylcyclopropene or 100 and 500 ppm 2,5-norbornadiene) did not reduce abscission in this system. Also, application of the ethylene biosynthesis inhibitor, aminooxyacetic acid at 1 mM, was ineffective at preventing ethylene-induced flower abscission. In contrast, one compound known to block protein production (100 μM cycloheximide) and a non-competitive inhibitor of ethylene action (2 mM silver thiosulfate) did prevent ethylene-induced abscission. We conclude that flower abscission in cut inflorescences of Plectranthus is very likely mediated by endogenous ethylene production, but that control of ethylene-induced flower abscission in this genus can not be readily obtained by most ethylene antagonists that are known to be effective in other systems.     

Effect of Darkness on Growth and Flowering of Chenopodium rubrum and C. murale Plants in vitro

Chenopodium rubrum, a short-day plant, and C. murale, a long-day plant, were grown in vitro in continuous darkness. Control C. rubrum plants exposed to continuous darkness for 15 d at cotyledonary phase, did not flower, while 80 % of plants flowered on the medium with 5 % glucose and 10 mg dm⁻³ GA₃. Control C. murale plants exposed to continuous darkness for 10 d at the age of 4^th pair of leaves, did not flower, while GA₃ (1 – 5 mg dm⁻³) stimulated flowering up to 65 %. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inhibitory role of gibberellins in theobroxide-induced flowering of Pharbitis nil

Theobroxide, a novel active compound isolated from a fungus, has been reported previously to induce potato tuberization and flower bud formation in Pharbitis nil under non-inductive long-day conditions. Up to date, the action mechanism of theobroxide on flower-bud induction of P. nil, however, is still unknown. In the present study, we observed a reduction of the stem length, along with the induction of flower buds, in theobroxide-treated and short-day-grown P. nil plants. Also, the results showed that flower bud formation was delayed markedly in P. nil seedlings with removal of cotyledons or exposure to night break. The suppression effect of night-break and cotyledon-removal, however, was abolished completely by spraying theobroxide. Endogenous gibberellin(1/3) contents in P. nil plants treated with theobroxide or grown under short-day conditions were relatively lower, suggesting that gibberellins probably are negatively involved in theobroxide- and short-day-induced flower-bud formation of P. nil.     

Effects of Methyl Jasmonate on Anthocyanin Accumulation, Ethylene Production, and CO2 Evolution in Uncooled and Cooled Tulip Bulbs

Effects of methyl jasmonate (JA-Me) on anthocyanin accumulation, ethylene production, and CO₂ evolution in uncooled and cooled tulips (Tulipa gesneriana L. cvs. Apeldoorn and Gudoshnik) were studied. JA-Me stimulated anthocyanin accumulation in stems and leaves from uncooled and cooled bulbs of both cultivars. The highest level of anthocyanin accumulation was observed in leaves from cooled bulbs treated with 200 μL/liter JA-Me. In sprouting bulbs treated with 100 μL/liter and higher concentrations of JA-Me, the ethylene production began to increase at 3 days after treatment, being extremely greater in uncooled bulbs than in cooled ones. JA-Me also stimulated CO₂ evolution in both cultivars, depending on its concentrations. CO₂ evolution in sprouting bulbs was not affected by cooling treatment. These results suggest that anthocyanin accumulation by JA-Me in tulip leaves is not related to ethylene production stimulated by JA-Me. Received October 10, 1997; accepted November 17, 1997     

Gummosis in grape hyacinth (Muscari armeniacum) bulbs: hormonal regulation and chemical composition of gums

The purpose of this study was to investigate the hormonal regulation of gummosis in grape hyacinth (Muscari armeniacum) bulbs, focusing especially on the chemical composition of the gums. The application of ethephon (2-chloroethylphosphonic acid), an ethylene-releasing compound, at 1% and 2% (w/w) in lanolin as well as ethylene induced gummosis in the bulbs within several days. Methyl jasmonate (JA-Me, 0.1–2% in lanolin) alone had no effect on gummosis. However, simultaneous application of JA-Me and ethephon led to extreme stimulation of ethephon-induced gummosis. Ethephon-induced gummosis in the bulbs depended on the maturation stage of the bulbs, increasing from April to July, but decreasing from August to September. Regardless of the presence of JA-Me, the application of ethephon to the inflorescence axis of grape hyacinths did not induce gummosis. Gel permeation chromatography analysis revealed that gums were homogenous polysaccharides with an average molecular mass of ca. 8.3 kDa. Analysis of the sugar composition of the gums after hydrolysis revealed that the molar ratio of Rha:Ara:Gal:GalA:GlcA was 25:10:40:7:15. These results suggest that principal factors of gummosis as well as the chemical composition of gums differ between species of bulbous plants.     

Changes in free polyamines in Tulipa gesneriana flower stalks during dry-storage and after planting of bulbs

Tulip bulbs cv. Apeldoorn are dry-stored at 5°C for 12 weeks to ensure sufficient elongation of the flower stalk, when subsequently planted at higher temperatures (17–20°C). To investigate whether free polyamines are involved in this process, flower stalk internodes were analyzed during dry-storage and after planting of the bulbs.During dry-storage for 12 weeks at 5°C (cooled) and 17°C (non-cooled), the free putrescine, spermidine and spermine amounts per flower stalk increased. The putrescine amount increased at 5°C significantly more than at 17°C, whereas the opposite was found for the spermine amount. These differences developed early during dry-storage and disappeared rapidly at subsequent higher temperatures.After planting, the lower- and uppermost flower stalk internodes of the pre-cooled bulbs elongated much faster than those of the non-cooled ones. In the pre-cooled bulbs, the free polyamine amounts per internode increased with time after planting, but the time course of these changes was different. In the non-cooled bulbs, the free polyamine amounts increased to a much lesser extent or remained more or less constant.It is argued that the observed changes in the free polyamine contents are probably not required for the cold-induced extension growth of tulips cv. Apeldoorn.Abbreviations PA polyamine - Put putrescine - Spd spermidine - Spm spermine     

Ethylene perception inhibitor 1-MCP decreases oxidative damage of leaves through enhanced antioxidant defense mechanisms in soybean plants grown under high temperature stress

Ethylene is a stress hormone involved in early senescence and abscission of vegetative and reproductive organs under stress conditions. Ethylene perception inhibitors can minimize the impact of ethylene-mediated stress. The effects of high temperature (HT) stress during flowering on ethylene production rate in leaf, flower and pod and the effects of ethylene inhibitor on ethylene production rate, oxidative damage and physiology of soybean are not understood. We hypothesize that HT stress induces ethylene production, which causes premature leaf senescence and flower and pod abscission, and that application of the ethylene perception inhibitor 1-Methyl cyclopropene (1-MCP) can minimize HT stress induced ethylene response in soybean. The objectives of this study were to (1) determine whether ethylene is produced in HT stress; (2) quantify the effects of HT stress and 1-MCP application on oxidative injury; and (3) evaluate the efficacy of 1-MCP at minimizing HT-stress-induced leaf senescence and flower abscission. Soybean plants were exposed to HT (38/28 °C) or optimum temperature (OT; 28/18 °C) for 14 d at flowering stage (R2). Plants at each temperature were treated with 1-MCP (1 μg L⁻¹) gas for 5 h or left untreated (control). High temperature stress increased rate of ethylene production in leaves, flowers and pods, production of reactive oxygen species (ROS), membrane damage, and total soluble carbohydrate content in leaves and decreased photosynthetic rate, sucrose content, F_v/F_m ratio and antioxidant enzyme activities compared with OT. Foliar spray of 1-MCP decreased rate of ethylene production and ROS and leaf senescence traits but enhanced antioxidant enzyme activities (e.g. superoxide dismutase and catalase). In conclusion, HT stress increased ethylene production rates, caused oxidative damage, decreased antioxidant enzyme activity, caused premature leaf senescence, increased flower abscission and decreased pod set percentage. Application of 1-MCP lowered ethylene and ROS production, enhanced antioxidant enzyme activity, increased membrane stability, delayed leaf senescence, decreased flower abscission and increased pod set percentage. The beneficial effects of 1-MCP were greater under HT stress compared to OT in terms of decreased ethylene production, decreased ROS production, increased antioxidant protection, decreased flower abscission and increased pod set percentage.     

The Effect of Pollination and Ethylene on the Colour Change of the Banner Spot of Lupinus albifrons (Bentham) Flowers

In Lupinus albifrons flowers the banner spot of the standardis initially coloured white or pale yellow. Two to three daysafter reaching the stage of full flower opening, this bannerspot develops a pinkish blush and is deep magenta after a further24 h. The development of this pigmentation is accelerated byexposure to ethylene in a concentration- and time-dependentmanner. Flowers with a pinkish banner spot produced the greatestamounts of ethylene and production was much lower in flowerswhich had either completed the colour change or in which thebanner spot colour remained unchanged. Treatments such as stigmaremoval or pollination increased the rate of ethylene production.Dissection of the flowers showed that while the banner spotis changing colour there is no change in the rate of productionof ethylene from the standard, i.e. from the banner spot orsurrounding tissue. The major sites of production at this timeare the keel and pistil. Isolated flowers withered within 2 d of removal from the plantand therefore did not show any change in the colour of the bannerspot unless exposed to ethylene. The increase in banner spotpigment was about fourfold when isolated floweres were exposedto ethylene (0·24 µl 1^–1): however, the increasewas less than twofold when isolated standards were exposed toethylene (0·27 µl I^–1). Application of silverthiosulphate (STS) to intact isolated flowers, as a 1 h pulseprior to ethylene exposure, partially prevented the pigmentaccumulation, whilst a continuous supply of STS reduced theethylene-induced colour change by approx. 50% Low concentrationsof cycloheximide (CHI) (0·01 mg ml^–1) reduced theaccumulation of pigment in the banner spot of ethylene-treatedflowers, and higher concentrations (1·0 mg ml^–1)completely prevented the ethylene-induced colour change. Ethylene, flower senescence, Lupinus albifrons, pollination     

Inhibition of flower bud abscission and ethylene evolution by light and silver thiosulphate in Lilium

The ethylene evolution from 3 cm-long flower buds of Lilium X 'Enchantment' increased when the plants were placed in darkness. Also shortening the daily light period led to an increase in ethylene evolution from the buds. Dark-enhanced ethylene evolution could only be evoked in flower buds between 2 and 3.5 cm long. Flower bud abscission induced by dakrness could be prevented by injecting silver thiosulphate into the flower buds, or by using plants grown from bulbs previously immersed in a silver thiosulphate solution. It is suggested that light-controlled flower bud abscission in Lilium X 'Enchantment' is mediated by ethylene, and that an increase in ethylene evolution in darkness is a consequence of the influence of light on ethylene action rather than a direct influence on ethylene biosynthesis.     

Theobroxide induces tubers in potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.) and flower buds in morning glory (<Emphasis Type="Italic">Pharbitis nil</Emphasis>) under non-inductive high temperatures

Induction of some plant organs including tubers and flower buds begins with sensing environmental cues, such as photoperiod and temperature in the leaves. Theobroxide has been shown to induce potato tuberization and flower-bud formation in morning glory under non-inductive photoperiodic conditions, stimulating the activity of lipoxygenase (LOX) and the synthesis of jasmonic acid (JA). In the present study, the ability of theobroxide to overcome the inhibitory effect of unfavorable high temperature on the induction of tubers in potato and flower buds in morning glory was examined. Both tuber induction and flower-bud formation under non-inductive high temperatures were promoted by the application of theobroxide at a high concentration. However, although theobroxide treatment resulted in an increase in fresh weight during potato tuber growth at 30°C, morning glory plants treated with theobroxide at 35°C failed to bloom, implying that theobroxide may assist only in flower-bud formation.     

Effects of anaerobiosis on ethylene production, respiration and flowering in iris bulbs

Ethylene production of iris bulbs (Iris hollandica cv. Ideal) was very low. When stored at 30°C, production was 12–20 pmol C₂H₄ (kg fresh weight)^?1 h^?1. Higher temperatures (35°C, 40°C) enhanced the ethylene production; a treatment with 40°C for ca 7 days caused a 3 times higher ethylene production than at 30°. During anaerobic storage (in 100% N₂) ethylene production was equal to that of control bulbs. When after a 7 day period of anaerobiosis the N₂ was replaced by air, a burstlike ethylene production was observed. Twenty-four h after the replacement, ethylene production was equal to control values again. The effects of this production of ethylene on mitochondrial respiration and flowering were investigated. When mitochondria were isolated immediately after the anaerobic treatment (before the enhanced ethylene production) alternative pathway capacity was not detectable, a situation also occurring in control bulbs. When mitochondria were isolated 24 h after the end of the anaerobiosis (after the ethylene burst) uninhibited respiration did not change significantly, but a capacity of the alternative pathway was observed. The increase in alternative pathway capacity after anaerobiosis was partly inhibited by 2,5-norbornadiene (NBD), an ethylene antagonist. Fermentation occurred during anaerobiosis: ethanol concentrations increased during the treatment and decreased when air was supplied. When bulbs were exposed to ethanol vapour the alternative pathway was induced but only when very high ethanol levels in the bulbs were reached. The amount of ethanol accumulated in the bulbs during a 7 day anaerobic treatment was far too low to explain the observed induction of alternative pathway capacity. Flowering percentages were enhanced after a 24 h treatment with ethylene and after a 7 day anaerobic treatment. NBD significantly inhibited the effect of exogenous ethylene and of anaerobiosis on flowering. Ethanol was not able to induce flowering. The burst-like production of ethylene after anaerobiosis probably is responsible for the effects on respiration and flowering.     

转反义LeETR2基因番茄的表型

转反义LeETR2基因番茄植株的表型与普通番茄有所不同。用乙烯25μL／L处理,转基因番茄能够表现出正常的“三重反应”,但根的伸长和根毛形成受到显著抑制。同时,转基因番茄植株对乙烯处理的偏上生长反应敏感度不及普通番茄,叶柄和花柄的脱落被延迟。这几方面的表型特点并不完全一致,我们推测LeETR2在番茄发育的不同阶段可能发挥不同的功能。     

Formation of onion bulblets in vitro and viability during medium-term storage

 The influences of light conditions, sucrose and ethylene on in vitro formation and storability of onion (Allium cepa L.) bulblets were studied in various accessions. Light, sucrose and ethylene influenced bulb formation. Storability was primarily enhanced by a high sucrose concentration (100 g/l) in the culture medium. The bulbing process was characterised by changes in bulbing ratio, leaf length, number of leaves and leaf development time. The viability of bulbs after 1 year of in vitro storage at low temperatures was determined by their growth reaction in subsequent subcultures, growth after transfer into the greenhouse and tetrazolium staining. Sufficient sprouting of bulblets previously stored at –1  °C demonstrated the possibility of storing them in a low-temperature, slow-growth culture. Received: 8 June 2000 / Revision received: 5 October 2000 / Accepted: 5 October 2000     

Physiological Analysis of Flower Formation in Wedgwood Iris

A series of experiments is described in which buds and scalesof iris bulbs were implanted in nutrient media and subjectedto varying temperature treatments, in an attempt to analysethe effect of different endogenous growth factors and of gibberellicacid on flower formation. In isolated scales incubated at 13°C for one to three weeks much of a heat-stable flower-inducingcompound and a small quantity of a second growth factor is produced.At 25.5° C no such substances are formed. It is shown thatat different times during a prolonged lowtemperature treatmentof iris bulbs, different growth factors are formed which activatesuccessive stages in the differentiation of the flower primordium.At 25.5° C the production and activity of the factor responsiblefor the transition to the reproductive stage are inhibited.Probably not inhibited at this temperature are differentiationprocesses in the reproductive primordium controlled by otherfactors with gibberellin-like characters.     

Environmental Factors Controlling Flower Opening and Closing in aPortulacaHybrid

To examine flower opening and closing of aPortulacahybrid, flowerbuds were placed in darkness for 12 h (2030–0830 h) at20 °C and then exposed to various light-temperature conditions.Flower buds exposed to light at 25, 30 or 35 °C opened within1 h, and wilted 10–14 h later. Flower buds exposed tolight at 20 °C started to open after 4 h but opened slowlyand not completely. Flower buds subjected to 25, 30 or 35 °Cin darkness also opened rapidly, but did not reach full opening.Flowers opened at 30 °C in light, and partially closed andopened repeatedly in response to cycles of a 2-h exposure to20 °C and a 2-h exposure to 30 °C at any time between1000 to 1600 h. Similar phenomena were observed when the flowersopened at 30 °C in light and then were subjected to darknessand light alternately at 30 °C, although the effect of lightwas less obvious than that of alternating temperature. Floweropening and closing were not affected by relative humidity.These results indicate that a rise in temperature is requiredfor rapid flower opening in the buds kept at 20 °C, andthat light intensifies the effect of high temperature. Exposureto light without a temperature change delayed and slowed floweropening which was never complete. The involvement of an endogenousrhythm in flower opening byPortulacais indicated. Portulacahybrid, flower opening, flower closing, temperature shift, endogenous rhythm.     

Effects of Ethylene on Photosynthesis and Partitioning in Tomato, Lycopersicon esculentum Mill

The extended period of ethylene release from ethephon (2-chloroethylphosphonicacid) after application to intact tomato plants has provideda model system in which the effects of ethylene on photosyntheticmetabolism and carbon partitioning has been studied. Ethylenerelease from leaf tissue after ethephon treatment was 10 timesgreater than that from untreated control leaves. The specificactivity of 14C2H4 released from [14C] ethephon remained constantover several days demonstrating that the ethylene was derivedfrom the applied ethephon. The ethephon-treated plants exhibitedextreme epinasty of the leaves and 24 h after application theflower buds in the first visible cluster had abscised, leafexpansion at the apex had ceased and developing adventitiousroots were visible on the lower stem. Rates of steady-state photosynthesis, respiration, photorespirationand transpiration were the same in treated and control leaves24 h after ethephon application. Both treated and control leavespartitioned similar proportions of newly-fixed 14C from 14CO²into neutral (46.4%), acidic (14.0%), basic (5.0%) and insoluble(34.0%) leaf fractions under steady-state conditions. The speedof 11C-assimilate movement in the stems of control plants (3.62±0.42cm min-1 towards the apex and 4.03±0.15 cm min-1 towardsthe roots) was more rapid than in the ethephon-treated plants(2.90±0.31 cm min-1 upwards and 2.59±0.22 cm min-1downwards). Furthermore, in the control plants 20.0±5.4%of the 14C exported to the plant from the source leaf was transportedtowards the developing flower cluster and young leaves. Twenty-fourhours after ethephon application only 6.5 ±1.7% of theexported 14C was translocated towards the shoot. Contrary tosome reports ethylene did not affect steady-state gas exchangeprocesses while carbon partitioning was significantly alteredindicating that ethylene effects on photosynthetic carbon metabolismare indirect and not due to direct effects on photosyntheticprocesses per se. Key words: Ethylene, photosynthesis, partitioning     

Somatic embryogenesis in tulip (<Emphasis Type="Italic">Tulipa gesneriana</Emphasis> L.) flower stem cultures

In the present study, the procedures for induction of somatic embryogenesis (SE) in an in vitro culture of the tulip have been developed. SE was initiated on flower stem explants isolated from “Apeldoorn” bulbs during their low-temperature treatment. Bulbs had not been chilled or had been chilled for 12 or 24 weeks at 5°C. The explants were cultured with exogenous auxins 2,4-dichlorophenoxyacetic acid (2,4-D), 4-amino-3,5,6-trichloropicolinic acid (Picloram), α-naphthaleneacetic acid (NAA) at 1–100 μM and cytokinins: benzyladenine (BA) and zeatin (ZEA) at 0.5–50 μM. Increase in auxin concentrations caused an intensive enlargement of the explant parenchyma, which changed into homogenous colorless callus. On the same media, vein bundles developed into yellowish, nodular callus. Picloram was more efficient in inducing the formation of embryogenic nodular callus than 2,4-D, whereas the latter stimulated formation of colorless callus. The base of the lower part of the flower stem isolated from bulbs chilled for 12 weeks proved to be the best explant for callus formation. The highest number of somatic embryos was produced on medium with 25 μM Picloram and 0.5 μM BA. Development of adventitious roots was noticed in the presence of 2,4-D. Globular embryos developed into torpedo stage embryos under the influence of BA (5 μM) and NAA (0.5 μM). Morphological and anatomical data describing development of callus and somatic embryos are presented.     

Ethylene production and metabolism of 1-aminocyclopropane-1-carboxylic acid in a long-day plant,Chenopodium murale L., as influenced by photoperiodic flower induction

Chenopodium murale plants, induced to flower by 5 days of continuous light, produced 43% more ethylene than vegetative plants kept under short days (16 h darkness, 8 h light). The 1-aminocyclopropane-1-carboxylic acid (ACC)-induced ethylene production, using saturating ACC concentration (10 mol·m⁻³) was also 55% higher in induced plants. Their ACC and N-malonyl-ACC (MACC) levels were also higher, the former increasing by 56% in both shoots and roots, the latter by 288% and 108% in shoots and roots, respectively. Administration of labeled [2,3-¹⁴C]ACC produced a very similar relative content of ACC and MACC in both treatments. The only process influenced by flower induction was ACC conversion to ethylene. Induced plants converted 66% more ACC than the vegetative ones. The effects of photoperiod on ethylene formation and metabolism in a long-day plant (LDP)C. murale and a short-day plant (SDP)C. rubrum are compared. Ethylene formation seems to be under photoperiodic control in both species, but its role in flower induction remains obscure.     

The Role of Cotyledons in Flower Initiation of Pharbitis nil at Low Temperatures

Seedlings of Pharbitis nil, Strains Violet, Tendan and Kidachi,initiated floral buds under Continuous light when exposed totemperatures lower than 15, 15 and 21?C, respectively, throughoutthe experimental period, or to 13–14?C for a minimum durationof 10, 8 and 4 days, respectively. Cotyledons were necessaryfor floral initiation when the seedlings at the start of coldtreatment were 8 days old (10 days old for Kidachi) or younger,although neither cotyledons nor foliage leaves were necessarywhen the plants were older. When the cotyledons in young seedlingswere removed immediately after exposure to cold temperature(13–14?C) for 14 (Violet), 12 (Tendan) or 8 (Kidachi)days (cold treatment begun when the cotyledons had just unfolded),only a few plants initiated floral buds under continuous light.However, when the cotyledons were left attached for 2 more daysat 23?C, the plants produced as many flower buds as those withintact cotyledons, suggesting that cotyledons exposed to coldtemperature produce a floral stimulus which can be translocatedto buds even after the end of the cold treatment. (Received October 14, 1981; Accepted January 20, 1982)