Inhibitory Effect of Methyl Jasmonate on Flowering and Elongation Growth in Pharbitis nil

The effect of methyl jasmonate (JA-Me) on the floral bud formation and elongation growth in the short-day plant Pharbitis nil was investigated. The placing of 4-day-old seedlings of P. nil in a solution of JA-Me for a period of 24 h before an inductive (16 h or 14 h of darkness) night led to a dramatic reduction in the number of flower buds formed by the plant. Plants treated with JA-Me also totally lost their capacity to form a generative terminal bud. JA-Me applied after photoinduction does not inhibit flowering. Gibberellic acid (GA3) partly reverses the inhibitory effect of JA-Me. Plants treated simultaneously with JA-Me and GA3 formed about 3 flower buds more than plants treated with JA-Me only. JA-Me at a concentration of 10-7 M stimulates slightly, but at higher concentrations it inhibits root growth and shoot growth. A distinct lack of correlation between the effect of JA-Me on inhibition of flowering and shoot and root growth was noted. This indicates the independent action of JA-Me in controlling both processes.     

Inhibitory Effect of Brassinosteroids on the Flowering of the Short-Day Plant Pharbitis nil

The effect of exogenous brassinosteroids (BR) on the flowering induction of Pharbitis nil was examined. Generally plants treated with brassinolide and castasterone form less number of flowers than control plants, but degree of flowering inhibition was depended on the concentration and the method of BR application as well as the length of the inductive dark period. In plants regenerated from sub-induced apices treated with brassinolide at concentration of 1 and 10 M the flower formation was inhibited completely.     

Rhythmicity of Flowering in Pharbitis nil

When young seedlings of Pharbitis nil are grown under continuous light, except for a single inductive dark period, they flower to a varying degree, depending on when this dark period is given. Plants become sensitive to this induction approximately three days after the seedlings emerge from the soil. The expression of flowering varies in a rhythmic fashion for three or more cycles, when an inductive dark period is given at progressively later times. The time between maximum expression of flowering is 24 hours or somewhat longer. It appears necessary that the inductive dark period be of sufficient duration, to only partially induce the plants to flower for this rhythm to be expressed. Under the conditions employed in this study, this duration is 12 hours. If this rhythm is endogenous, it exists at least from when the plants emerged from the soil since no environmental cues are given after that time, and it raises questions of the interpretations of data from previous studies with this organism.     

Correlation between Long-Day Flowering and Root Elongation in Pharbitis nil, Sfrain Kidachi

Long-day flowering of Pharbitis nil, dwarf strain Kidachi, at20?C was greatly influenced by the size of the culture vesseland the number of plants per vessel. The smaller the vessel,the greater the flowering response. The volume of nutrient solutionper plant was not decisive for long-day flowering. For instance,plants cultured singly in 200-ml beakers flowered, but thosecultured in 5,000-ml vessels (33?26?11.5 cm, 48 plants per vessel)did not, even though there was only about 100 ml of nutrientsolution per plant. Long-day flowering was always accompaniedby the suppression of root elongation, but not by a decreasein the dry weight of roots or shoots, or in the rate at whichthe leaf primordia appeared (plastochrone). Aeration of thenutrient solution or culture in vermiculite promoted root elongationeven in small vessels, thereby inhibiting long-day flowering.Thus the suppression of root elongation seems to be necessaryfor long-day flowering. Removal of the roots or cotyledons;however, suppressed long-day flowering even when root elongationwas inhibited by culture in small vessels. When plants werecultured at 24?C, suppression of root elongation (culture ina small vessel) did not induce long-day flowering; but, short-daytreatment induced flowering without suppressing root elongation. (Received April 19, 1982; Accepted June 24, 1982)     

Gibberellins in Relation to Growth and Flowering in Pharbitis nil Chois

Flowering can be modified by gibberellins (GAs) in Pharbitis nil Chois. in a complex fashion depending on GA type, dosage, and the timing of treatment relative to a single inductive dark period. Promotion of flowering occurs when GAs are applied 11 to 17 hours before a single inductive dark period. When applied 24 hours later the same GA dosage is inhibitory. Thus, depending on their activity and the timing of application there is an optimum dose for promotion of flowering by any GA, with an excessive dose resulting in inhibition. Those GAs highly promotory for flowering at low doses are also most effective for stem elongation (2,2-dimethyl GA₄ GA₃₂ > GA₃ > GA₅ > GA₇ > GA₄). However, the effect of GAs on stem elongation contrasts markedly with that on flowering. A 10- to 50-fold greater dose is required for maximum promotion of stem elongation, and the response is not influenced by time of application relative to the inductive dark period. These differing responses of flowering and stem elongation raise questions about the use of relatively stable, highly bioactive GAs such as GA₃ to probe the flowering response. It is proposed that the `ideal' GAs for promoting flowering may be highly bioactive but with only a short lifetime in the plant and, hence, will have little or no effect on stem elongation.     

Carbon Dioxide and Flowering in Pharbitis nil Choisy

The effects of photoperiod on floral and vegetative development of Pharbitis nil were modified by atmospheric CO₂ concentrations maintained during plant growth. Short day (SD) photoperiods caused rapid flowering in Pharbitis plants growing in 0.03 or 0.1% CO₂, while plants in long day (LD) conditions remained vegetative. At 1 or 5% CO₂, however, flower buds were developed under both the SD and LD photoperiods. Flowering was earliest in the plants exposed to SD at low CO₂ concentrations which formed floral buds at stem node 3 or 4. At high CO₂ concentrations, floral buds did not form until stem node 6 or 7. Both high CO₂ concentrations and LD photoperiods tended to enhance stem elongation and leaf formation.     

Jasmonates Inhibit Flowering in Short-Day Plant Pharbitis nil

The role of jasmonates in the photoperiodic flower induction of short-day plant Pharbitis nil was investigated. The plants were grown in a special cycle: 72 h of darkness, 24 h of white light with lowered intensity, 24-h long inductive night, 14 days of continuous light. At 4 h of inductive night the cotyledons of non-induced plants contained about two times the amount of endogenous jasmonates (JA/JA-Me) compared to those induced. A 15-min long pulse of far red light (FR) applied at the end of a 24-h long white light phase inhibited flowering of P. nil. The concentration of jasmonates at 2 and 4 h of inductive night in the cotyledons of the plants treated with FR was similar. Red light (R) could reverse the effect of FR. R light applied after FR light decreased the content of jasmonates by about 50%. Methyl jasmonate (JA-Me) applied to cotyledons, shoot apices and cotyledon petioles of P. nil inhibited the formation of flower buds during the first half of a 24-h long inductive or 14-h long subinductive night. Application of JA-Me to the cotyledons was the most effective. None of the plants treated with JA-Me on the cotyledons in the middle of the inductive night formed terminal flower buds. The aspirin, ibuprofen and phenidone, jasmonates biosynthesis inhibitors partially reversed the effect of FR, stimulating the formation of axillary and terminal flower buds. Thus, the results obtained suggests that phytochrome system control both the photoperiodic flower induction and jasmonates metabolism. Jasmonates inhibit flowering in P. nil.     

Effect of Plant Growth Regulators on Flower-Opening of Pharbitis nil

Flower buds of Pharbitis nil (due to open the next morning)cut from plants in the field before noon open very slowly bothin darkness and at a low temperature (20°C), unlike thebuds cut in the evening. On cool cloudy days, even the budscut in the evening open very slowly. Addition of sucrose, mineralnutrients or plant growth regulators other than ABA to the waterin which the cut buds were placed did not promote flower-openingunder such conditions, but addition of ABA (10–100 µM)greatly promoted it. IAA (100 µM) given alone or in combinationwith ABA suppressed floweropening completely. Mature flowerbuds placed in an ABA solution opened even under continuouslight at 25°C just as those kept in darkness without ABA;flower-opening occurred about 12 h after the application ofABA. ABA given to the buds in darkness at 25°C and thatgiven in continuous light at 20°C also advanced the timeof flower-opening. The action mechanism of ABA is discussed. ¹ This paper is dedicated to the memory of Dr. Joji Ashida,the first president of the Japanese Society of Plant Physiologist. (Received October 28, 1982; Accepted January 7, 1983)     

Flowering and dwarfism induced by DNA demethylation in Pharbitis nil

Flowering and dwarfism induced by 5‐azacytidine and zebularine, which both cause DNA demethylation, were studied in a short‐day (SD) plant Pharbitis nil (synonym Ipomoea nil), var. Violet whose photoinduced flowering state does not last for a long period of time. The DNA demethylating reagents induced flowering under non‐inductive long‐day (LD) conditions. The flower‐inducing effect of 5‐azacytidine did not last for a long period of time, and the plants reverted to vegetative growth. The progeny of the plants that were induced to flower by DNA demethylation did not flower under the non‐inductive photoperiodic conditions. These results suggest that the flowering‐related genes were activated by DNA demethylation and then remethylated again in the progeny. The DNA demethylation also induced dwarfism. The dwarfism did not last for a long period of time, was not heritable and was overcome by gibberellin A₃ but not by t‐zeatin or kinetin. The change in the genome‐wide methylation state was examined by methylation‐sensitive amplified fragment length polymorphism (MS‐AFLP) analysis. The analysis detected many more polymorphic fragments between the DNA samples isolated from the cotyledons treated with SD than from the cotyledons under LD conditions, indicating that the DNA methylation state was altered by photoperiodic conditions. Seven LD‐specific fragments were extracted from the gel of the MS‐AFLP and were sequenced. One of these fragments was highly homologous with the genes encoding ribosomal proteins.     

The Effect of Various Lipids on Flowering of Pharbitis nil in in vitro Culture

The effect of applied arachidonic acid, prostaglandin (PGE₁) and various sterols and combinations of arachidonic acid + sterols, on flowering of Pharbitis nil were ascertained by using a tissue culture technique. It was found that arachidonic acid, PGE₁ stigmasterol, testosterone, cholesterol, stigmasterol + arachidonic acid, -sitosterol + arachidonic acid and cholesterol + arachidonic acid all caused earlier flowering. Four inhibitors of prostaglandin biosynthesis (gentisic acid, acetylsalicylic acid, salicylic acid and oleic acid), inhibited flowering completely. The results confirm that the compounds tested could possibly play a role in the flowering of P. nil.     

Dihydrokaempferol Glucoside from Cotyledons Promotes Flowering in Pharbitis nil

An extract of cotyledons of Pharbitis nil, which had been exposedto short-day conditions, was tested for flower-promoting activityin a shoot-tip assay system in vitro. The crude extract hadno flower-promoting activity, however, after partitioning ofthe crude extract with dichloromethane, the resulting aqueousfraction had flower-promoting activity. This activity was separatedinto two fractions by column chromatography on Toyopearl HW-40.One active fraction was identified as dihydrokaempferol-7-O-rß-D-glucoside(DHK-glc). This compound exhibited flower-promoting activityat the extremely low concentration of 4.4x10^-9. (Received April 25, 1995; Accepted August 11, 1995)     

Effects of Aminooxyacetic Acid and Its Derivatives on Flowering in Pharbitis nil

Aminooxyacetic acid (AOA) inhibited photoperiodically inducedflowering in Pharbitis nil. The application of AOA to the plumulejust after an inductive period was the most effective in inhibitingflowering. A correlation between inhibition of flowering andinhibition of glutamic-oxalacetic transaminase activity wasobserved with fifteen aminooxy derivatives. (Received April 18, 1992; Accepted June 25, 1992)     

The Inhibition of Flowering by Non-Induced Cotyledons of Pharbitis nil

Inhibitory effects on flowering of a non-induced cotyledon havebeen examined in Pharbitis nil seedlings. The photoperiodicinduction of one cotyledon was accomplished by wrapping it inaluminium foil for 13 to 15 h while the seedling remained inthe light. The presence of the other cotyledon in the lightblocked this inductive stimulus. The timing of its inhibitoryeffect suggested that its action was to block the expressionof the inductive stimulus, presumably at the shoot apex. Byvarying the area of the non-induced cotyledon parallel inhibitoryeffects were shown on export of stimulus and of ¹⁴C-labelledassimilate to the apex from the induced cotyledon. Thus, partof the inhibition was by interference with assimilate/stimulusco-transport in the phloem. However, an additional inhibitoryeffect was also evident and for this second component therewas no relationship between assimilate and stimulus transport.This latter inhibition was generated by brief light interruptionsof darkness given to one cotyledon only whilst the other waswrapped. The control treatment, removal of the unwrapped cotyledon,did not alter flowering compared to seedlings with intact, darkenedcotyledons. Thus, these studies show that the brief night interruptionsacted to trigger a photoperiodically sensitive inhibitor notto block induction. The implications of these findings are discussedin relation to models of time measurement in the photoperiodiccontrol of flowering. (Received March 20, 1989; Accepted November 16, 1989)     

Flowering Response of Pharbitis nil to Agents Affecting Cytoplasmic pH

Permeant weak acids and auxins have been shown to reduce the cytosplasmic pH in several systems. Lactic, citric, formic, butyric, salicylic, parahydroxybenzoic, propionic acid, and sodium propionate inhibited the flowering response of Pharbitis nil seedlings when applied immediately before an inductive dark period. The acidic auxins IAA, indolebutyric, and α-naphtaleneacetic acid, as well as the nonacidic auxin α-naphtaleneaceteamid, also inhibited the flowering response. Inhibition was generally more pronounced with a 12-hour than with a 16-hour dark period. Salicylic acid and sodium propionate shifted the response curve of the dark period by about 2 hours. Salicyclic acid, sodium propionate, and indolebutyric acid were inhibitory when applied during the first few hours of the dark period. The permeant weak bases NH₄Cl, procaine, and trisodium citrate enhanced the flowering response. NH₄Cl reduced the length of the critical dark period. The inhibition of flowering by acids and auxins as well as the promotion of flowering by bases was obtained even when only the cotyledons had been treated. The inhibition of floral induction by auxins may not be dependent on their effect on the cytoplasmic pH.     

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.     

Flowering of Pharbitis nil is controlled by an endogenous semidian rhythm

Abstract Flowering of Pharbitis nil after an inductive dark period is greatly influenced by far-red (FR) irradiation during the preceding light period. The response to FR is rhythmic in otherwise constant conditions, and the period of the oscillation is approximately 12 h (i.e. semidian). The rhythm also appears to operate under daily light-dark cycles. The expression of this novel rhythm depends on the time from the beginning of FR pretreatment to the onset of the inductive dark period. The cotyledons are the site of response to both the pretreatment and inductive darkness, and both these conditions must be perceived by the same cotyledon.     

Flowering response of Ipomoea batatas scions grafted onto Pharbitis nil stocks

Young seedlings of Ipomoea batatas (L.) Lam. cv. Big One did not form floral buds, but were induced to flower when grafted onto Pharbitis nil Chois. cv. Violet with its cotyledons exposed to a 16 h dark period (SD). Four SD were required to induce flowering in I. batatas scions when the grafted plants were first grown under an 8 h dark period (LD) for 18 days and then exposed to SD. Transmission of the flowering stimulus across the graft union required 4 days. It was also slow in the graft combination of P. nil and P. nil , but increased greatly when the graft union was established more completely. These results suggest that the flowering stimulus of P. nil may move symplastically and its life may be between 4 and 6 days. Although the leaves of I. batatas inhibited flowering, the flowering response of P. nil grafted onto I. batatas suggested that the involvement of a transmissible flowering-inhibitor was unlikely.     

Effect of High-intensity Light Given Prior to Low-temperature Treatment on the Long-day Flowering of Pharbitis nil

Pharbitis nil, strain Violet which had been exposed to high-intensitylight (18,000 lux at 23?C) for 7 days followed by a low-temperaturetreatment (13–14?C) for 7 days initiated flower buds evenunder continuous light, but plants given these treatments inreverse order failed to bud. Three days of high-intensity lightat 23?C was most effective in promoting the flower-inducingeffect of the subsequent low-temperature period. Six days oflow temperature following the 3-day high-intensity light periodinduced near-maximum flowering response. DCMU (5?10^–6M) given during the high-intensity light period inhibited flowering,but when given during or after the low-temperature period itwas ineffective. DCMU at the same concentration given before,during or after an inductive 16-hr dark period at 26?C did notinhibit flowering. Sucrose, ATP, NADPH and some other reducingagents tested did not nullify the DCMU effect nor substitutefor the effect of high-intensity light. But, the high-intensitylight effect could be substituted, at least partly, by 5-chlorosalicylicacid, 3,4-dichlorobenzoic acid and some other benzoic acid derivatives,which are highly effective in inducing long-day flowering inthe short-day plant, Lemna paucicostata. (Received October 20, 1981; Accepted February 3, 1982)     

Timing of Growth Inhibition following Shoot Inversion in Pharbitis nil

Shoot inversion in Pharbitis nil results in the enhancement of ethylene production and in the inhibition of elongation in the growth zone of the inverted shoot. The initial increase in ethylene production previously was detected within 2 to 2.75 hours after inversion. In the present study, the initial inhibition of shoot elongation was detected within 1.5 to 4 hours with a weighted mean of 2.4 hours. Ethylene treatment of upright shoots inhibited elongation in 1.5 hours. A cause and effect relationship between shoot inversion-enhanced ethylene production and inhibition of elongation cannot be excluded.