Gravistimulus Direction, Ethylene Production and Shoot Elongation in the Release of Apical Dominance in Pharbitis nil

Prasad, T. K. and Cline, M. G. 1985. Gravistimulus direction,ethylene production and shoot elongation in the release of apicaldominance in Pharbitis nil.—. exp. Bot. 36: 1969–1975.Release of apical dominance can be induced in Pharbitis nilby the inversion of the upper shoot. This promotion of outgrowthof the highest lateral bud adjacent to the bend of the stemappears to be mediated by ethylene inhibition of growth of theinverted main shoot. In the present investigation the existenceof a direct correlation between ethylene evolution and the directionof gravistimulus is demonstrated as well as an inverse correlationbetween ethylene production by the inverted upper shoot andits elongation. An inverse correlation also exists between elongationof the inverted upper shoot and the outgrowth of the highestlateral bud if the lower portion of the shoot (below the bend)is oriented in an upright position. The latent period for shoot–inversioninduction of ethylene production is about 2 h. These resultssupport the hypothesis of indirect ethylene control of apicaldominance release by retardation of elongation of the invertedshoot. Key words: Shoot inversion, gravistimulus, ethylene, latent period, bud outgrowth, pharbitis nil     

Apical Dominance Control in Ipomoea nil: The Influence of the Shoot Apex, Leaves and Stem

The outgrowth of lateral buds is known to be controlled by theupper shoot tissues, which include the apex, the young leavesand the upper stem. An analysis of the influence of these plantparts on axillary bud elongation in Ipomoea nil was carriedout by various treatments on these specific tissues. A restriction of elongation in the main shoot due to eitherdecapitation or shoot inversion resulted in the release of apicaldominance A non-linear type of compensating growth relationshipwas observed between the 13 cm apical growing region of thestem and the lateral buds. It was determined by decapitation,defoliation and AgNO₃ treatments that both the 13 cm stem-growthregion and the young leaves (1–5 cm in length) had a muchgreater inhibitory influence on the outgrowth of specified lateralbuds than did the stem apex (consisting of the terminal 0.5cm of the shoot). The specified lateral buds which were analyzedfor outgrowth were located a number of nodes below the shootapex. The intervening nodes were debudded. Although the importanceof young leaves in the control of apical dominance has beenpreviously recognized, the most significant result from thepresent study with Ipomoea was the strong influence of the 13cm apical growth region of the stem on the out growth of thelateral buds. Apical dominance, Ipomoea nil L., Pharbitis nil, growth region, lateral bud outgrowth, decapitation, defoliation, shoot inversion     

Does Auxin Play a Role in the Release of Apical Dominance by Shoot Inversion in Ipomoea nil?

According to the auxin-inhibition hypothesis of apical dominance,apically produced auxin moves down the stem and inhibits axillarybud outgrowth, either directly or indirectly. This hypothesishas been examined further by monitoring changes in basipetalauxin transport and endogenous auxin concentration in Ipomoeanil caused by shoot inversion, a stimulus that releases apicaldominance. The results indicate that inversion reduces auxintransport in the main stem. In upright shoots of intact plants,a 16-h pretreatment with [³H]IAA 4 cm below the apex resultsin downward movement of label and accumulation in nodes, especiallythe cotyledonary node. Label does not accumulate in the lateralbuds. GC-MS determinations of endogenous free auxin level inthe fourth node, where a lateral bud grows out following inversionof the upper part of the shoot, show no changes at 3 and 8 hafter inversion, the range of times for inversion-induced budrelease, or at 24 h, when bud outgrowth is continuing. However,inversion did cause a just-detectable decrease (approx. 10%)in the IAA level of the shoot's elongation region. Althoughauxin transport in segments of the main stem is partially inhibitedby inversion over a period shorter than the latent time of budrelease, thus providing a means for the expected depletion ofauxin in the fourth node, no depletion could be detected there.These results suggest that either a decrease in IAA level inthe main stem is not causal of bud release or that the decreasedIAA pool responsible for bud release is compartmented and cannotbe measured in whole-tissue extracts.Copyright 1993, 1999 AcademicPress Apical dominance, auxin content, auxin transport, axillary bud release, GC-MS, Ipomoea nil, Pharbitis nil, shoot inversion     

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.     

The Role of Gravity in Apical Dominance : Effects of Clinostating on Shoot Inversion-Induced Ethylene Production, Shoot Elongation, and Lateral Bud Growth

Shoot inversion-induced release of apical dominance in Pharbitis nil is inhibited by rotating the plant at 0.42 revolutions per minute in a vertical plane perpendicular to the axis of rotation of a horizontal clinostat. Clinostating prevented lateral bud outgrowth, apparently by negating the restriction of the shoot elongation via reduction of ethylene production in the inverted shoot. Radial stem expansion was also decreased. Data from experiments with intact tissue and isolated segments indicated that shoot-inversion stimulates ethylene production by increasing the activity of 1-aminocyclopropane-1-carboxylic acid synthase. The results support the hypothesis that shoot inversion-induced release of apical dominance in Pharbitis nil is due to gravity stress and is mediated by ethylene-induced retardation of the elongation of the inverted shoot.     

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 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     

Flowering Response in Relation to C and N Contents of Pharbitis nil Plants Cultured in Nitrogen-Poor Media

Flowering of seedlings of Pharbitis nil, strains Violet andTendan, cultured in modified White's medium, was promoted bymedium dilution, the critical dark period being shortened byabout 15 min. Dilution of the N source alone was enough to causethe medium-dilution effect. Dilution of the culture medium duringthe day before and on the day of exposure to the dark-period(a total of two days) caused the maximum dilution effect. TheC and N contents of the cotyledons and of the shoot apices changedrapidly in response to medium dilution. In 1/2-strength White'smedium with 1/1,000 strength NO₃^– which was most effectivefor flower promotion, the C-N ratio was highest. In 1/2-strengthmodified White's medium, in which flowering was lowest withthe longest critical dark period, the C-N ratio was lowest.Thus, there is a close relation between flowering response andthe C-N ratio in cotyledons or shoot apices of Pharbitis nil. (Received September 14, 1984; Accepted January 26, 1985)     

Shoot inversion-induced ethylene production: a general phenomenon?

Shoot inversion induction of ethylene production was found in inverted shoots of corn, peas, soybean, sunflower, tomato, andPharbitis nil. The increases in ethylene production were found to range from two- to threefold in soybean to eightfold in corn and sunflower. The occurrence of peaks of ethylene production ranged from 16 h following shoot inversion in corn to 72 h inPharbitis. That the enhanced ethylene production was due to activation of 1-aminocyclopropane-1-carboxylic acid (ACC) synthase is supported by the finding of increased ACC content in inverted shoots of all species tested. Shoot inversion inhibition of elongation was found in inverted shoots of pea, soybean, sunflower, tomato, andPharbitis nil. This inhibition is thought to be mediated via increased ethylene production in the inverted shoots. That shoot inversion induction of ethylene is not a persistent effect is supported by the finding that ethylene synthesis could be terminated by reorientation of shoots to the upright position and could be reinitiated by the subsequent inversion of the shoots. The effects of shoot inversion on the enhancement of ethylene production and on the inhibition of elongation of the inverted shoot appear to be general phenomena.     

Floral initiation under continuous light in Pharbitis nil, a typical short-day plant

Seedling-cuttings of Pharbitis nil, a typical short-day plant,initiated floral buds under continuous light of 2200–2400lux at 24–26?C. When cultured under poor-nutritional conditions,the node bearing the first floral bud was as low as the 4thone. A close relation between floral initiation under continuouslight and retarded vegetative growth was observed. (Received September 28, 1973; )     

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.     

Cytokinin/Auxin Control of Apical Dominance in Ipomoea nil

Although the concept of apical dominance control by the ratioof cytokinin to auxin is not new, recent experimentation withtransgenic plants has given this concept renewed attention.In the present study, it has been demonstrated that cytokinintreatments can partially reverse the inhibitory effect of auxinon lateral bud outgrowth in intact shoots of Ipomoea nil. Althoughless conclusive, this also appeared to occur in buds of isolatednodes. Auxin inhibited lateral bud outgrowth when applied eitherto the top of the stump of the decapitated shoot or directlyto the bud itself. However, the fact that cytokinin promotiveeffects on bud outgrowth are known to occur when cytokinin isapplied directly to the bud suggests different transport tissuesand/or sites of action for the two hormones. Cytokinin antagonistswere shown in some experiments to have a synergistic effectwith benzyladenine on the promotion of bud outgrowth. If theratio of cytokinin to auxin does control apical dominance, thenthe next critical question is how do these hormones interactin this correlative process? The hypothesis that shoot-derivedauxin inhibits lateral bud outgrowth indirectly by depletingcytokinin content in the shoots via inhibition of its productionin the roots was not supported in the present study which demonstratedthat the repressibility of lateral bud outgrowth by auxin treatmentsat various positions on the shoot was not correlated with proximityto the roots but rather with proximity to the buds. Resultsalso suggested that auxin in subtending mature leaves as wellas that in the shoot apex and adjacent small leaves may contributeto the apical dominance of a shoot. (Received September 24, 1996; Accepted March 16, 1997)     

Peroxidase isozymes and their indoleacetate oxidase activity in the Japanese morning glory, Pharbitis nil

Distributions of peroxidase isozymes in various organs of theJapanese morning glory (Pharbitis nil CHOISY) are described.Most peroxidase isozymes had indoleacetate oxidase activity. (Received December 29, 1969; )     

Interaction between L-Pipecolic Acid and Water Extracts of Various Plant Species in Floral Induction of Lemna paucicostata

The flower-inducing activity of L-pipecolic acid was synergisticallyenhanced by simultaneous application of the water extracts ofLemna paucicostata and Pharbitis nil, but suppressed by thewater extracts of all other plants we examined. Simultaneousapplication of the water extract of Lemna enhanced the flower-inducingactivity of all plant water extracts. (Received June 6, 1990; Accepted July 7, 1990)     

Inhibition of photoperiodic floral induction in Pharbitis nil by ethylene

Application of ethylene at 100 ppm or higher completely inhibitedflowering in Pharbitis nil when made during an inductive darkperiod. Exposing plants to ethylene before or after the inductivedark period produced only slight or almost no inhibition. Ethylenewas effective when it was applied only to a cotyledon, but wasineffective when applied only to a receptor bud. Ethylene hadno effect on translocation of the floral stimulus. Ethylene-treatedcotyledon did not transfer any flower inhibiting entity. Thus,ethylene is considered to inhibit the induction process(es)in cotyledons. Except for an initial temporary cotyledon epinasty, ethylenetreatment had no effect on the subsequent growth and vigor ofplants. This temporary cotyledon epinasty disappeared withinthe next 24 hr. (Received May 4, 1972; )     

Correlative Inhibition of Lateral Bud Growth in Phaseolus vulgaris L. Effect of Application of Indol-3yl-Acetic Acid to Decapitated Plants

In view of the variation in the ability of indol-3yl-aceticacid (IAA) to prevent lateral bud growth on decapitated plantsvarious factors which might influence the response have beeninvestigated in Phaseolus vulgaris L. The effectiveness of IAAapplied in lanolin varied from experiment to experiment. Factorsthat altered the response included the time of year, the concentrationand quantity of IAA, the age of the plant, the type of lanolinand the region of application. In many instances IAA, at a concentrationbelieved to mimic the auxin relations of the intact plant, cancompletely replace the main shoot with respect to the correlativeinhibition of lateral bud growth. The evidence for the involvementof IAA as the primary determinant in apical dominance in P.vulgaris is summarized.     

Sensitivity to Humidity and Temperature in Darkness of the Photoinduction of S-Adenosyl-L-Methionine Decarboxylase Activity in Leaves of Pharbitis nil

The activity of S-adenosyl-L-methionine decarboxylase (SAMD)in leaves of Pharbitis nil increased maximally at "lights-on"after growth in darkness for 16 h at 21 to 25°C and 30%to 40% relative humidity. Under other condition, less SAMD activitywas induced. The photoinduction of SAMD was also observed inleaves of many other plant species. (Received December 14, 1994; Accepted April 6, 1995)     

Floral initiation of Pharbitis nil, a short-day plant, under continuous high-intensity light

Pharbitis nil, a short-day plant, initiated floral buds undercontinuous illumination at 23°C, provided that the lightintensity was kept at 16,000 lux or above. Stem elongation ofthe plants was strongly inhibited but leaves developed normallyunder this condition. (Received November 26, 1971; )     

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.     

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)