Enhancement of Gibberellic Acid-stimulated Hypocotyl Elongation of Lettuce (Lactuca sativa L. cv. Grand Rapids) by Phlorizin and Light

The interaction of light, gibberellic acid (GA₃), and phlorizinin the growth of lettuce (Lactuca sativa L. cv. ‘GrandRapids’) hypocotyls was investigated. At all concentrationsof GA₃, phlorizin enhanced GA₃-induced growth at luminous intensitiesabove 50 ft-c (continuous light). Without GA₃, phlorizin hadno effect on hypocotyl growth in the light but it inhibitedgrowth in the dark. Both seedlings and hypocotyl sections respondedto phlorizin in the presence of GA₃. There was no iteractionbetween phlorizin and KCl. Water-growth was severly inhibitedby light. GA₃,-induced growth was slightly inhibited by light,and then only at luminous intensities above 50 ft-c. Thus, relativeto H₂O-growth, GA₃-induced growth increased with increasingluminous intensity up to 450 ft-c, where it reached saturation.It seems that a synergism may exist between light and GA₃ aswell as between phlorizin and GA₃. Lactuca sativa L, lettuce, hypocotyl elongation, gibberellic acid, phlorizin, light     

Prolongation of Embryo Sac Viability in Pear (Pyrus communis) Following Pollination or Treatment with Gibberellic Acid

Embryo sac development has been investigated in unpollinated,cross pollinated and gibberellic acid (GA₂) treated flowersof Pyrus communis L. While pollination and GA₃ treatments donot alter embryo sac development, they prolong embryo sac viability.In untreated unpollinated flowers, ovules degenerate between12 and 21 d after anthesis, while in cross pollinated and GA₃treated flowers this degeneration is postponed by about 10 d.Thus, in a cross pollinated flower this extends the period overwhich a successful fertilization can take place. This increasedperiod of viability is accompanied by an elongation of the embryosac itself. Elongation takes place two weeks prior to fertilizationin cross pollinated flowers. The extension of life span of embryo sacs following pollinationand treatment with gibberellic acid indicates that a stimulusinduced by ‘pollination’ could be mediated by GA₃Whatever its mechanism of operation, the prolongation of embryosac viability by pollination represents a selective advantage,in that the period at which the ovules are receptive to fertilizationmust be significantly extended. Embryo sac, gibberellic acid, Pyrus communis, pear, pollination     

Effects Produced on Tomato Plants, Lycopersicum esculentum, by Seed or Root Treatment with Gibberellic Acid and Indol-3yl-Acetic Acid

Growth in lengths of tomato stems and leaves was acceleratedby 5.0 µg gibberellic acid (GA₂) applied to the seed,or by 5.0, 0.5, and 0.05 µg given to the roots. Treatmentwith 5.0 µg also decreased bud number and lengthened thetime between bud appearance and fruit formation on the firsttruss by 1–8 days. Smaller amounts applied to roots shortenedthis time by 1–4 days. Indol-3yl-acetic acid at 0.5 µghad no effect, nor was simultaneous application of GA₃ and IAAto the roots more effective than GA₃, alone. Single applicationsof very small amounts of GA₃ to seeds or seedling roots thusproved capable of changing growth-rates of stems, leaves, andtrusses.The effects of treating tomatoes with GA₂ and with culturesof Azotobacter chroococcum, which contain small amounts of GA₃,and IAA, are compared.     

Abscisic Acid and Apical Dominance in Phaseolus coccineus L. The Role of Tissue Age

Abscisic acid (ABA) applied to the decapitated second internodeof runner bean plants enhanced outgrowth of lateral buds onlywhen internode stumps were no longer elongating. Applied toelongating internodes of slightly younger plants, ABA causesinhibition of bud outgrowth. Together with 10^–4 M indol-3-ylacetic acid (IAA), ABA stimulated internode elongation and interactedadditively in the inhibition of bud outgrowth. A mixture of10^–5 M ABA and 10^–6 M gibberellic acid (GA₃ ) causedsimilar effects on internode growth as IAA + ABA, but was mutuallyantagonistic in effect on growth of the lateral buds. Abscisic acid, apical dominance, gibberellic acid, indol-3yl acetic acid, Phaseolus coccineus, bean     

Bud Dormancy in the Kiwi Fruit, Actinidia chinensis Planch

A study of lateral bud dormancy in Actinidia chinensis has shownthat true dormancy can be induced, especially in short daysat warm and constant temperatures This dormancy can be brokenquantitatively by chilling but temperatures as high as 10 °Care effective The dormancy appears to be due to an inhibitor(possibly ABA), apparently stored in the special bud cover aspecial structure in Kiwi fruit which may represent fused stipulesRemoval of the cover also admits oxygen and light, both of whichhave promoting effects on bud break Application of ABA enhancesdormancy (as do crude extracts tentatively identified as ABA)while GA₃ application enhances dormancy before chilling andpromotes bud break only after chilling Actinidia chinensis, Kiwi fruit, dormancy, abscissic acid, gibberellic acid, chilling     

Long-Day Induced Bud Break in Salix pentandra Is Associated with Transiently Elevated Levels of GA1 and Gradual Increase in Indole-3-Acetic Acid

Initiation of dormancy in woody species is induced by a shortphotoperiod. In the early stages of dormancy development, growthcan be initiated by long days. To study the possible involvementof gibberellins and indole-3-acetic acid in bud break in Salixpentandra, effects on levels of these plant hormones of transferof seedlings in an early stage of dormancy to a growth-inductivelong photoperiod was investigated. The bud break and initiationof growth correlated with a rapid transient increase in GA₁in defined zones of shoot tips to levels twice of that in continuouslyelongating long day-grown control seedlings, followed by a rapiddecrease to levels similar to in these control plants. Also,the contents of GA₅₃, GA₁₉, GA₂₀, GA₈ increased upon transferfrom short to long days. Levels of indole-3-acetic acid showeda gradual decline under short days, and increased graduallyupon transfer to long days up to a level of continuously elongatingplants. The present data suggest an interaction between gibberellinand indole-3-acetic acid in the photoperiodic control of dormancydevelopment and bud break in S. pentandra. (Received October 14, 1996; Accepted February 18, 1997)     

The role of gibberellins in the growth of floral organs of Mirabilis jalapa

Evidence that the anther is a source of GAs which may be a mainfactor limiting the growth of floral organs of Mirabilis jalapais presented. GAs in floral tubes at different developmentalstages were surveyed using TLC followed by bioassay with ‘Tan-ginbozu’dwarf rice seedlings. The amount of GA_s in the floral tube increasedrapidly after the calyx became visible above the bract 8 daysbefore anthesis, reached a maximum 5 days before anthesis, thendeclined markedly thereafter. The stamen had relatively largeamounts of GAs and mainly accounted for the change of GA_s duringthe flower development. The GA content in the anther was 3 timesas much as that in the filament. Exogenously supplied GA3 promotedelongation of sections in excised flower organs. Extracts ofanthers also showed definite growth promotion of style sections.Removal of the anthers greatly reduced the final length of thefloral tube. (Received December 7, 1974; )     

The Effect of Gibberellins on Growth and Flowering of Fragaria and Duchesnea

In a series of experiments petiole lengths were increased, steminternode elongation induced, runner formation promoted, andflower initiation inhibited both in the perpetual-fruiting andthe seasonal-fruiting varieties of strawberry by applicationsof gibberellic acid. Runners were induced to form in Fragariavesca semper-florcns var. Baron Solemacher, which does not normallyrunner. Thus the physiological processes which lead to the morphologicaldifferences between perpetual and seasonal fruiting types wereoverruled by treatment with gibberellic acid. Gibberellins A₁, A₄, A₇, and A₉, like gibberellic acid (A₃),induced elongation of petioles (a normal photoperiodic response),elongation of internodes on the main stem, and inhibition offlower formation in Baron Solemacher (responses not inducedby photoperiod). When applied to the cut stump of a debladed petiole, gibberellicacid inhibited flower formation at the growing apex of the stem,thus substituting for the leaf blade, which in long photoperiodsinhibited flower formation. A morphological study suggested that in Duchesnea indica, arelated genus, flower initiation is not regulated by environmentalcircumstances, but is the inevitable consequence of growth.Although promoting increase in petiole length and in elongationof lateral growths as in strawberry, gibberellic acid did notinhibit flower initiation in this species, except in so faras it caused a retardation in the growth of certain axillarybuds, so that a lower proportion of them reached the stage offlower initiation within the duration of the experiment. These results are discussed in relation to the hypothesis thatflower formation is regulated by an inhibitory hormone in seasonal-fruitingstrawberries.     

The Effects of Daylength and Treatment with Gibberellic Acid on Spikelet Initiation and Development in Clipper Barley

The effects of photoperiod, light quality and a single applicationof gibberellic acid (GA₃) on the development of the main-stemapex in Clipper barley are reported. In 16 and 24 h days spikeletinitiation was rapid but extended over a short period whereasin 8 h photoperiods both spikelet initiation and developmentwere slower but occurred for a much longer time. Initiationalways stopped when the anther primordia were clearly visiblein the most advanced spikelet. Daylength extensions with lowintensity incandescent light were most effective when they followedrather than preceeded the 8 h period of high light intensity.Plants grown in 8 h high intensity followed by 8 h low intensitylight initiated spikelets almost as rapidly as those grown in16 h high intensity light. Thus, the effects of daylength onspikelet production were primarily mediated through photoperiodicallycontrolled processes rather than through photosynthesis andassimilate supply. The effects of applied GA₃ were long livedand greatest in short days where the rates of both spikeletinitiation and development were promoted. The parallels betweenthe effects of long days and GA₃ treatment are discussed togetherwith possible reasons for the cessation of initiation and thelong duration of the GA₃ effect. daylength, gibberellic acid, spikelet initiation, Hordeum vulgare L., barley, main-stem apex, primordia     

Effects of Abscisic Acid on the Growth Pattern of the Shoot Apical Meristem and on Flowering in Chenopodium rubrum L.

Abscisic acid (ABA) at 1 x 10^–4 M or 3 x 10^–4 Mwas applied to the apical buds of Chenopodium rubrum plantsexposed to different photoperiodic treatments and showing differentpatterns of floral differentiation. Stimulation of growth inwidth of the apical meristem of the shoot and/or inhibitionof growth in length was obtained under all photoperiodic treatments.This change of growth pattern was followed by different effectson flowering. In non-induced plants grown under continuous light ABA stimulatedpericlinal divisions in the peripheral zone and the initiationof leaves as well as the growth in width of bud primordia. Inplants induced by two short days reduced growth of the meristemcoincided with ABA application. Longitudinal growth of the meristemwas inhibited in this case and only a temporary stimulationof inflorescence formation took place. In plants induced ata very early stage, ABA exerted a strong inhibitory effect onflowering. A permanent and reproducible stimulatory effect onflowering was obtained in plants induced by three sub-criticalphotoperiodic cycles if ABA was applied to apices released fromapical dominance. In this case formation of lateral organs andinternodes was promoted by ABA and was followed by stimulatedinflorescence formation. Gibberellic acid (GA2) at 1x 10^–4M or 3 x 10^–4 M brought about a similar effect on floweringas ABA, although the primary growth effect was different, i.e.GA₂ stimulated longitudinal growth. The effects of ABA and GA₂ on floral differentiation have beencompared with earlier results obtained from auxin and kinetinapplications. These growth hormones are believed to regulateflowering by changing cellular growth within the shoot apex.Depending on the actual state of the meristem identical growthresponses may result in different patterns of organogenesisand even in opposite effects on flowering. Shoot apex, flowering, photoperiodic induction, abscisic acid, gibberellic acid, Chenopodium rubrum L.     

Dwarfism Caused by Floral-Bud Removal in Petunia and its Reversal by Gibberellin

The effect of floral-bud removal at different stages of developmenton the plant height and on the total number of buds of Petuniawas studied. Continuous removal of all the floral buds 2 d beforeanthesis caused a marked decrease in plant height and also increasedthe total number of floral buds formed thereafter. At otherstages of floral bud development, bud removal had a lesser effecton both phenomena. Moreover, the plants did not respond to budremoval at anthesis. GA₃ at 25 ppm applied to plants from which the buds had beenremoved, promoted stem elongation. The most pronounced effectwas on plants from which the buds were removed 2 d before anthesis,but it had no effect on plants from which the buds were removedat anthesis stage. The possible involvement of endogenous growth hormones in theresponse of Petunia plants to floral-bud removal and to applicationof GA₃ is discussed. Bud removal, bud number, dwarfness, GA₃, Petunia, plant height     

Interaction between Hormones, Light, and Nutrition on Extension of Lateral Buds in Phaseolus vulgaris L.

Gibberellic acid (GA₃), kinetin, and indol-3yl-acetic acid (IAA)contained in lanolin were applied in various combinations andconcentrations to decapitated stems and petioles and to budsof Phaseolus vulgaris L. GA₃ applied alone usually promotedgrowth of main stems and laterals but this was by no means consistentand occasionally it acted in the opposite way. IAA applied alonereduced lateral bud extension slightly, but not consistently;however, when applied with GA₃ or GA₃ plus kinetin, it oftenmarkedly inhibited the promotion caused by these compounds.On occasions, however, GA₃ and IAA acted synergistically topromote and sometimes to inhibit lateral shoot growth. Kinetinalone showed few significant effects on lateral shoot growthbut applied with GA₃ it often dramatically increased GA₃-inducedgrowth of main stems and laterals. The diversity of these results,which parallels that found in the literature, was shown to bepartly dependent on the point of hormone application and ageof the plant or bud, on concentration of hormone and on lightintensity or nutrition. However, no meaningful relationshipswere found and it is concluded that growth of laterals and mainstems is dependent on a hormone balance which can be criticallymodified by a wide range of internal and external factors thenature of which is still to be determined.     

Factors Influencing the Distribution of Growth Between Stem and Axillary Buds in Decapitated Bean Plants

Phaseolus multiflorus plants at three stages of developmentwere decapitated either immediately below the apical bud orlower down at a point 1 cm above the insertion of the primaryleaves. Growth regulators in lanolin were applied to the cutstem surface. IAA always inhibited axillary bud elongation anddry-matter accumulation, and enhanced internode dry weight butnot elongation. GA₃ applied below the apical bud greatly increasedinternode elongation and dry weight, but simultaneously reducedbud elongation and dry-weight increase. Application of GA₃ 1cm above the buds had no effect on bud elongation in the youngestplants, but enhanced their elongation in the two older groups.IAA always antagonized GA₃-enhancement of internode extensiongrowth, whereas its effects on GA₃-enhanced dry-matter accumulationdepended on the stage of internode development. Bud elongationwas greater in plants treated with GA₃+IAA than in plants treatedonly with IAA, except in the youngest plants decapitated immediatelybelow the apical bud, where GA₃ caused a slight increase inIAA-induced bud inhibition. GA₃ increased inhibition of buddry weight by IAA in the two youngest groups of plants, butslightly reduced it in the oldest plants. No simple compensatorygrowth relationship existed between internode and buds. It wasconcluded that, (1) auxin appears to be the principal growthhormone concerned in correlative inhibition, and (2) availabilityof gibberellin to internode and buds is of importance as a modifyingfactor in auxin-regulated apical dominance by virtue of itslocal effects on growth in the internode and in the buds.     

Physiological Controls on the Production of Cleistogamous and Chasmogamous Flowers in Lamium amplexicaule L

Plants of Lamium amplexicaule, grown under short-day field conditionsin Northern California produce predominantly closed flowers.Under long-day field conditions, plants may produce up to 50per cent open flowers, the same total number of flowers beingproduced under each daylength regime. A 20 ml drop of GA₃ or GA₇ (100µM) was applied to themain shoot apex of plants growing under short-day conditions,and all subsequently produced flowers opened. CCC, an inhibitorof gibberellin synthesis, was applied (0.06 per cent) to thesoil of seedlings grown under long-day conditions. The CCC-treatedplants were dwarfed and bore only closed flowers. With GA₇ appliedexogenously to the CCC-treated shoots, inhibition was released,resulting in elongated internodes and open flower production.The timing of flower production and internodal extension inLamium amplexicaule are positively correlated. When floral primordiawere removed from main shoots, the average internode lengthsdecreased. The number of nodes produced in treated plants wasincreased as a result of flower removal. Exogenous GA₇ (10 µM)applied to the nodes from which flowers were removed resultedin internodal extension but had no effect on node number. Twoprocesses that may contribute to the control of the productionof open and closed flowers in Lamium amplexicaule are: (1) anincreasing anther sac size from lower to upper node flowersthat may exert control locally, via GN production, on corollaexpansion, and (2) a photoperiodic control. Lamium amplexicaule L, henbit, cleistogamy, chasmogamy, gibberellins, gibberellic acid (GA₃), (2 chloroethyl) trimethylammonium chloride (cycocel)     

Comparative Effects of lndole-3-acetic acid, Abscisic acid, Gibberellic acid and 6-Benzylaminopurine on the Dark- and Light-induced Pulvinar Movements in Cassia fasciculata Michx

Effects of plant hormones were examined on the dark- and light-inducedmovements of Cassia fasciculata. Indole-3-acetic acid (IAA),gibberellic acid (GA₃) and 6-benzylaminopurine (6-BAP) inhibitedthe scotonastic movement whereas abscisic acid (ABA) enhancedit. After brief treatments (5 to 30 min), the ABA effect wasinhibitory rather than promotional. Hormonal treatment in theacidic range gave the best physiological response for ABA, butthe greatest efficiency of IAA, GA₃ and 6-BAP was obtained withpH values close to neutrality. Three to 5 h were needed beforeexpression of the physiological effect triggered by GA₃ and6-BAP, while 5 min treatments were sufficient for IAA and ABA.Light-induced movements were largely enhanced by IAA and slightlyby GA₃ but inhibited by 6-BAP and ABA. The results are discussedin relation to the ionic changes in the pulvinar motor cells,regulating leaflet movements. Key words: Abscisic acid, auxins, cytokinins, gibberellic acid, pulvinar movements     

The Effect of Gibberellic Acid on Starch Breakdown in Sprouting Tubers of Solanum tuberosum L.

The treatment of potato tubers with 150 µmol dm^–3gibberellic acid (GA₃) stimulated starch breakdown and hexoseaccumulation in tuber tissues and the transfer of dry matterto stems. These effects could not be accounted for by enhancedactivities of starch phosphorylase, amylase and acid invertase.Indeed enzyme activities either declined or remained relativelyconstant as starch degradation and hexose accumulation proceeded.Changes in the rate of starch depletion were related to changesin sink strength and sink type, the onset of tuber initiationin controls causing the rate of starch degradation to exceedthat in GA₃-treated tissues, in which tuberization was inhibited. Solanum tuberosum L., gibberellic acid, starch breakdown     

Gibberellins and the Early Disease Syndrome of Aspermy Virus in Tomato (Lycopersicon esculentum Mill.)

A quantitative examination of the development of the diseasesyndrome created by as permyvirus in tomato (Lycopersicon esculentumMill., cultivar Potentate) revealed an early reduction in subapicalmitotic activity which led to the development of smaller internodes.Later symptoms were associated with necrosis of young axillarybuds and the failure of a new vegetative apex to develop onceflower initiation had begun in the primary apical bud. Application of gibberellic acid (GA₃) to the growing point tendedto reverse virus-induced stunting by increasing cell expansionbut the response was less than that in healthy plants. Thiswas due to a reduction in the number of mitoses associated withvirus infection. No consistent difference was found betweenthe endogenous gibberellin levels of healthy and infected plants.It is suggested that the most important single factor in earlysymptom development is a virus-induced reduction in cell divisionwhich cannot be overcome by applying GA₃.     

Effects of Plant Growth Regulators on Grain-filling and Yield of Rice

Effects of three phytohormones (IAA₁, GA₃ and kinetin) on grain-fillingand the pattern of ³²P translocation from individual leavesto grains were studied at intervals of 7 days during the progressof reproductive development of rice (Oryza saliva L. cv. Jaya).The plants were sprayed with 100 µg ml^–1 aqueoussolutions of the hormones at 100 days, when the plants wereentering the reproductive stage. Kinetin produced a pronouncedeffect on grain-filling as well as on ³²P mobilization fromindividual leaf to grains and increased yield, possibly by increasingleaf longevity. GA₃ and IAA also increased the grain-fillingand ³²P mobilization significantly over control but the effectswere less marked than those of kinetin. Oryza sativa L., rice, grain yield, translocation, growth regulators, gibberellic acid, indol-3-yl acetic acid, kinetin     

Retardation of Leaf Senescence by Ascorbic Acid

Leaf discs of Solatium melongena were floated on various concentrationsof ascorbic acid (AA), gibberellic acid (GA₃), and kinetin inorder to study their effect on senescence. AA was highly effectivein retarding senescence as shown by the arrest of the fall inlevels of chlorophyll, DNA, RNA, and proteins. AA was effectiveat a lower concentration than that of GA₃ or kinetin.     

Inhibition of Gibberellic Acid-Induced Elongation-Growth of Pea Epicotyls by Xyloglucan Oligosaccharides

The biological activity of a cell wall-derived xyloglucan nonasaccharide(XG9) was investigated using a bioassay with entire pea epicotyls(Pisum sativum cv. Progress). The xyloglucan fragment was foundto inhibit gibberellic acid-induced elongation of etiolatedpea epicotyls with maximum inhibition at concentrations rangingfrom 10^–11 to 10^–9M. Growth of etiolated epicotylsin the absence of exogenously applied GA₃ was also inhibitedby XG9 in the same concentration range. A cell wall-derivedheptasaccharide (XG7) lacking the fucosyl-galactosyl-side chainshowed no inhibitory effect in the pea epicotyl bioassay withand without exogenous GA₃. Furthermore, the biological activityof a synthetic pentasaccharide (XG5), containing the fucosylgalactosyl-sidechain which is necessary for the biological activity was investigatedin the same bioassay. Compared to XG9 the pentasaccharide hada similar inhibitory activity on GA₃-promoted elongation aswell as on the endogenous growth in the absence of exogenouslyapplied GA₃, but did not exhibit a distinct concentration optimum. Key words: Elongation-growth, gibberellic acid (GA₃), oligosaccharides, pea, XG9