Effects of abscisic acid on flowering in Pharbitis nil

Under continuous light, flowering of Pharbitis seedlings wasnot induced by abscisic acid (ABA) treatment. Under short daytreatment, flowering was slightly enhanced by ABA at 0.2 and0.4 mg/liter. Stem elongation was considerably inhibited by25 and 50 mg/liter of ABA irrespective of day length. (Received October 21, 1972; )     

Gibberellin-enhanced elongation of inverted Pharbitis nil shoot prevents the release of apical dominance

Ethylene evolution resulting from the gravity stress of shoot inversion appears to induce the release of apical dominance in Pharbitis nil (L.) by inhibiting elongation of the inverted shoot. It has been previously demonstrated that this shoot inversion release of apical dominance can be prevented by promoting elongation in the inverted shoot via interference with ethylene synthesis or action. In the present study it was shown that apical dominance release can also be prevented by promoting elongation of the inverted shoot via treatment with gibberellic acid (GA₃). A synergistic effect was observed when AgNO₃, the ethylene action inhibitor, was applied with GA₃. Both GA₃ and AgNO₃ increased ethylene production in the inverted shoot. These results are consistent with the view that it is ethylene-induced inhibition of elongation and not any direct effect of ethylene per se which is responsible for the outgrowth of the highest lateral bud.     

Effects of Light and Temperature on Flower-opening of Pharbitis nil

Flower buds of Pharbitis nil cut from plants growing in thefield opened rapidly when kept in darkness for 8 hr followedby continuous light at 20–25°C, but those kept indarkness for 4 hr opened promptly oniy when the temperatureduring the following light period was kept at 23°C or lower.Buds exposed to continuous light at 25°C did not open, butthose exposed to continuous light at 23°C opened slowly.At a lower temperature, the buds opened rapidly even in continuouslight. When the buds were placed in darkness at 25°C at13:30, 17:30 and 21:30 (artificial light from 17:30 to 21:30),they opened about 10 hr after the onset of darkness regardlessof the time of the onset of darkness, but when the buds werekept at 20°C in light from 13:30, 17:30 and 21:30, theyopened at 3:30–5:30 regardless of the time of transferto the lower temperature. The biological clock which controlsthe time of flower-opening is suggested to be easily reset bya light-off signal, but not by a shift from a normal to lowertemperature (20°C). At the lower temperature, the time offlower-opening probably is determined by the time of the latestpreceding light-off (or light-on) signal. ¹Dedicated to Professor Dr. Erwin Biinning on the occasion ofhis 75th birthday. (Received October 23, 1980; Accepted December 15, 1980)     

Appearance of peroxidase isozymes in floral‐initiated shoot apices of Pharbitis nil

A novel biochemical assay system for detecting the early stage of flowering is reported. Peroxidase isozymes in shoot apices of Pharbitis nil plants that had been exposed to flower‐inducing or non‐inducing conditions were analyzed by isoelectric focusing in polyacrylamide gels and activity staining for peroxidase. Several isozymes with pH 8.5–8.8 appeared for the first time 7 days after the beginning of short‐day treatment, but not after nightbreak (non‐inducing) treatment. When shoot tips were cultured in vitro, these same isozymes also appeared after short‐day treatment but not after night‐break treatment. The extent of the appearance of these isozymes was reduced by exposure to high or low temperature during the inductive dark period and removal of cotyledons after the inductive dark period. Such treatments also reduced the extent of flowering. The appearance of an isozyme with pH 8.5 was more closely correlated with flowering than that of the other isozymes. From these results, the appearance of this peroxidase isozyme in shoot apices is discussed as a biochemical marker of flowering in intact plants and in cultured shoot tips.     

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.     

Differential expression of putative floral genes in Pharbitis nil shoot apices cultured on glucose compared with sucrose

If, following an inductive treatment of 2 d of continuous darkness, shoot apices of Pharbitis nil are cultured 1 d later on White's medium supplemented with 2% sucrose, they cannot form carpels, but they can if they are cultured on 2% glucose. It was hypothesized that the differential effect of these sugars was because of differential expression of carpel-specific genes. Partial cDNA homologues to the Arabidopsis genes, LEAFY (PnLFY), AGAMOUS (PnAG1/2), and CRABS CLAWS (PnCRC1/2) were cloned. PnLFY was expressed in the shoot apex 1 d following the start of induction and remained higher than in non-induced apices for a further 6 d before exhibiting a major peak of expression on day 7. Peaks of expression of PnAG1 and PnAG2 spanned days 7-11, coinciding with the appearance of stamens and then carpels. The Pharbitis 'PnCRC2' showed greatest homology to Arabidopsis YABBY2 (PnYABBY). Its expression peaked on day 8 when the carpels first appeared. 'PnCRC1' showed greatest homology to Arabidopsis FILAMENTOUS (PnFIL). Its expression was approximately the same in inductive and non-inductive treatments. Apart from PnFIL these partial cDNAs could be used as markers to test the hypothesis concerning differential effects of sucrose and glucose. Cultured shoot apices from induced plants were sampled at weekly intervals. All four genes were expressed more strongly in the glucose compared with the sucrose treatment, most notably at day 17. A more intensive sampling (days 15-19) indicated that PnLFY and PnYABBY exhibited much higher expression on glucose compared with sucrose, most notably on days 15-16 and days 18-19.     

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)     

Gibberellins in Immature Seeds of Pharbitis nil

Two new gibberellins, gibberellins A₂₆ and A₂₇ were isolated from immature seeds of Japanese morning-glory (Pharbitis nil) and their structures were elucidated as I and IX.     

Physical Basis of Flower-opening in Pharbitis nil

Flower buds of Pharbitis nil cut from plants growing in thefield open rapidly when subjected to darkness (20–25°C)or low temperature (20°C) in light. Petals of the buds arethe sites of photo- and thermo-perception; flower-opening iscaused mainly by the epinasty of petal midribs. ¹Dedicated to Professor Dr. Erwin Bunning on the occasion ofhis 75th birthday. (Received October 23, 1980; Accepted December 15, 1980)     

Gravistimulus direction, ethylene production and shoot elongation in the release of apical dominance in Pharbitis nil

Release of apical dominance can be induced in Pharbitis nil by the inversion of the upper shoot. This promotion of outgrowth of the highest lateral bud adjacent to the bend of the stem appears to be mediated by ethylene inhibition of growth of the inverted main shoot. In the present investigation the existence of a direct correlation between ethylene evolution and the direction of gravistimulus is demonstrated as well as an inverse correlation between ethylene production by the inverted upper shoot and its elongation. An inverse correlation also exists between elongation of the inverted upper shoot and the outgrowth of the highest lateral bud if the lower portion of the shoot (below the bend) is oriented in an upright position. The patent period for shoot-inversion induction of ethylene production is about 2 h. These results support the hypothesis of indirect ethylene control of apical dominance release by retardation of elongation of the inverted shoot.     

Phytochrome in Norflurazon-treated seedlings of Pharbitis nil

The properties of phytochrome have been measured by dual-wavelength spectropho-tometry in the cotyledons of the short-day plant Pharbitis nil Choisy cv. Violet, where it is known to play a role in flower induction. In plants de-etiolated by a single white light period (4 h or longer), destruction of the far-red absorbing form of phytochrome (P_fr) was twice as rapid as after 10 min red light. A small fraction of P_fr was stable. After de-etiolation by a period of white light (6 h or longer) the rapid decrease of P_fr during the first 30 min was accompanied by a rapid increase of the red absorbing form of phytochrome (P_fr). This rapid increase of P_fr is probably due to dark reversion. Long term synthesis of phytochrome was inhibited by the presence of P_fr. Phytochrome synthesised in darkness showed the etiolated-plant type characteristics and underwent rapid destruction upon photoconversion to P_fr. The stable P_fr identified here is possibly that pool of phytochrome associated with the long term promotive process in flower induction, and the rapidly reverting P_fr is that pool associated with the night break inhibition of flowering.     

Gibberellins in Immature Seeds of Pharbitis nil

A new gibberellin, gibberellin A₂₀ (GA₂₀), was isolated from immature seeds of morning-glory (Pharbitis nil). Its structure was established as 4aα, 7α-dihydroxy-1β-methyl-8-methylenegibbane-1α, 10β-dicarboxylic acid-1→4a lactone (I) on the basis of its physicochemical analysis as well as chemical evidences. GA₂₀ shows marked growth promoting activities on dwarf maize d₂ and d₅ but weak activities on d₁, rice seedling and dwarf pea.     

Calcium and photoperiodic flower induction in Pharbitis nil

The relationship between phytochrome-mediated induction of flowering, Ca²⁺ transport and metabolism in Pharbitis nil Chois cv. Violet seedlings has been investigated. Ethyleneglycol-bis-(β-aminoethylether)-N,N,N', N'-tetraacetic acid (EGTA), a specific Ca⁺ chelator, caused a 30–40% inhibition of flowering in Pharbitis subjected to complete photoperiodic induction. It was most effective when applied during the light period preceding along inductive dark period. The agonist of calcium channels. Bay K-8644, did not affect flowering, while Nifedipine, Verapamil and La³⁺ (antagonists of calcium channels) only slightly inhibited this process. A similar small effect has been found when the plants were treated with Li⁺ (inhibitor of the membrane phospholipids pathway), and with chlorpromazine (a camodulin inhibitor). Except for EGTA, the effect of the other substances did not depend on the timing of their application. The results of the present study suggest that the effect of all the substances applied was not specific, and flowering is not directly dependent on transport and intracellular metabolism of Ca²⁺.     

牵牛全草的化学成分研究

从牵牛全草(Pharbitis nilChoisy)乙酸乙酯提取物中分离得到十个化合物。据理化性质和光谱分析鉴定其结构为:顺式阿魏酸酰对羟基苯乙胺(1),对羟基桂皮酸酰对羟基苯乙胺(2),阿魏酸酰对羟基苯乙胺(3),顺式对羟基桂皮酸酰对羟基苯乙胺(4),桂皮酸酰对羟基苯乙胺(5),对羟基苯乙胺(6),7-羟基香豆素(7),6-甲氧基-7-羟基香豆素(8),尿嘧啶(9),β-谷甾醇葡萄糖苷(10)。化合物1～9均为首次从该植物中得到。     

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.     

Effect of gravity on apical dominance in Pharbitis nil.

When the upper part of main shoot of morning glory (Pharbitis nil) is gently bent down, lateral bud on the bending region is released from apical dominance and starts to elongate. But, clinorotating the bending shoots prevents the release of the lateral bud from apical dominance. These results suggest that gravity affects apical dominance in morning glory. Here we verified the gravity-regulated apical dominance by using a weeping morning glory defective in gravitropic response due to abnormal differentiation of endodermis. That is, bending main shoot of the weeping morning glory hardly caused the lateral bud to elongate. In addition, decapitation of apical bud released the lateral bud from apical dominance, and exogenous auxin applied to the cut surface of the decapitated stem was inhibitory to the outgrowth of the lateral bud in the wild type. However, the effect of auxin was much less in the weeping morning glory. Thus, apical dominance of the weeping morning glory was weaker and less influenced by gravity than that of the wild type, which could occur due to abnormal differentiation of endodermis required for graviperception.     

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)     

Effects of Moonlight on Flower Induction in Pharbitis nil, Using a Single Dark Period

Flowering of Pharbitis nil plants was slightly inhibited byexposure to the light of the full moon for 8 or more hours witha single dark period of 16, 14 or 13 h. It is suggested thatin the natural environment moonlight may have at most only aslight delaying effect on the time of flower induction in short-dayplants. Flowering, moonlight, night-break, Pharbitis nil, photoperiodism, short day plants