Modification of growth habit of Majestic potato by growth regulators applied at different times

The effect of gibberellic acid, CCC (2-chloroethyltrimethylammonium chloride) and B 9 (N-dimethylaminosuccinamic acid) was studied on growth of potato plants in pots. Growth was analysed on four occasions and changes in habit defined in terms of internode lengths, leaf areas and growth of lateral branches. Soaking seed pieces for 1 hr. in GA solution caused six internodes to elongate greatly, an effect not prevented by CCC applied when the shoot emerged from the soil. The effects on internode extension were determined by the length of the interval between GA treatment and CCC treatment. Treatment at emergence with CCC shortened all internodes and more CCC applied 4 weeks later had no effect. Late application of CCC or B9 shortened the top two lateral branches, usually very long in untreated plants. The regulators affected leaf growth differently from internode growth: usually growth regulators had less effect on leaf growth. Effects on growth depended on when the regulators were applied. Treatment with GA alone inhibited bud development at higher nodes than in untreated plants; when followed by late treatment with CCC, lateral growth at higher nodes was also less. CCC retarded development of lateral branches especially when applied early. B9 had a similar effect to CCC applied late. When regulators retarded growth of lower laterals, upper laterals often grew more than in untreated plants. Treatments did not affect the number of leaves on the main stem at first but later GA hastened senescence. GA increased the number of leaves on lateral stems, and the effect was enhanced by CCC. CCC alone increased the number of first- and second-order lateral leaves. GA lengthened and CCC shortened stolons. The effect of CCC persisted throughout the life of the plant. CCC or B 9 shortened stolons whenever applied. CCC hastened tuber initiation but slowed tuber growth. CCC at first retarded formation of lateral tubers but had no effect on the ultimate numbers of lateral and terminal tubers. The value of E (net assimilation rate) did not alter with time. CCC applied at emergence increased E, probably because it hastened tuber initiation and temporarily increased sink capacity. Although tubers formed earlier with CCC, their growth was slower and their demand for carbohydrate was also less. The increase in second-order laterals in CCC-treated plants indicates that they utilize carbohydrate that would normally go to tubers. This experiment also demonstrates that crowding leaves by shortening stems did not diminish E, possibly because another over-riding process (bigger sinks) offsets the effect of shading.     

CONTROL OF FLOWER FORMATION BY GROWTH RETARDANTS AND GIBBERELLIN IN SAMOLUS PARVIFLORUS,A LONG-DAY PLANT

The growth retardants AMO–1618 and CCC inhibited flower formation and stem elongation in Samolus parviflorus, a long-day rosette plant, under inductive conditions. The vegetative growth of the plants, as measured by leaf formation, was affected only slightly, or not affected at all. Application of gibberellic acid (GA₃) reversed completely the inhibition both of flower formation and of stem elongation caused by AMO, but relatively larger amounts of GA were required to reverse the CCC inhibition of stem elongation than that of flower formation. When applied under short-day conditions, AMO had no effect on the level of applied GA required for flower induction. When applied following long-day treatment the retardant caused some reduction of flower formation after marginal numbers of long days, but had no effect when enough long days to cause 100% flower formation were given. Other evidence indicates that the growth retardants act by inhibiting the synthesis of endogenous gibberellin. In LD plants, at least part of the action of inductive environmental conditions consists in causing an increase of gibberellin synthesis, supporting the hypothesis that relatively high GA levels are necessary for the production of the floral stimulus in this group of plants, as in long-short-day plants. The experiments with CCC indicate that stem elongation and flower formation in Samolus can be separated, and that the effect of GA on flower formation is not necessarily dependent on its effect on stem elongation.     

Expression of two gibberellin-regulated cDNAs during early flower development in tomato (Solanum lycopersicon). Effect of grafting and paclobutrazol

To study the role of translocation of gibberellin (GA) intermediates or bioactive GAs from other plant parts to buds during early flower development in tomato ( Solanum lycopersicon ), the effect of grafting and paclobutrazol (PAC) treatment on the expression of tgas100 and tgas118 , two GA-regulated mRNAs, was analysed. Both mRNAs accumulated in a dose-dependent fashion. Application of 0.5 ng GA₃ per bud to developmentally arrested flower buds of a GA-deficient mutant of tomato ( gib-1 ) induced tgas100 expression, while the tgas118 abundance increased. For obtaining normal flower development through anthesis in the mutant, a single GA₃ treatment was required of at least 5 ng GA₃ per bud. In wild-type flower buds, PAC decreased the abundance of tgas100 and tgas118 mRNAs either when PAC was sprayed on whole plants or directly applied to buds. When only the wild-type buds were treated with PAC, the expression profiles characteristic for untreated buds were not restored by translocation of endogenous GAs. Grafting of gib-1 scions onto wild-type donor plants did not result in normal flower development or expression profiles like in wild-type buds. We conclude that the role of GA transport in early flower development of tomato is negligible and that the GAs required for development have to be synthesized in the flower bud itself.     

THE INFLUENCE OF GROWTH STAGE ON THE RESPONSE OF RED CLOVER (TRIFOLIUM PRATENSE L.) TO GIBBERELLIC ACID

The response of seedling and first harvest year plants of red clover ( Trifolium pratense L.) to treatment with gibberellic acid (GA) at various growth stages is described.
Seedlings sprayed before the seventh leaf stage developed into single-stemmed plants; treatment with GA at the third- or fourth-tiller stage resulted in final stem numbers similar to those of controls. Emergence was earliest, and the number of heads per plant greatest where sprayings were delayed until the third- or fourth-tiller stage.
In first harvest year plants significant increases in the number of heads per stem were obtained with certain treatments, especially those which had two applications of 0.5 mg. GA per plant during the elongation of the first four internodes. This was related in all treatment groups to modifications of the branching pattern, and also to the increased incidence of multiple heading. Earlier emergence resulted from treatment at all growth stages, the effect being maximal where three well-spaced sprayings were applied during active stem extension.     

The effects of temperature and the Rht3 dwarfing gene on growth, cell extension, and gibberellin content and responsiveness in the wheat leaf

The effects of low temperature and the Rht3 dwarfing gene onthe dynamics of cell extension in leaf 2 of wheat were examinedin relation to gibberellin (GA) content and GA-responsivenessof the extension zone. Leaf 2 of wild-type (rht3) wheat closelyresembled that of the Rht3 dwarf mutant when seedlings weregrown at 10C. The maximum relative elemental growth rate (REGR)within the extension zone in both genotypes was lower at 10Cthan at 20C, but the position with respect to the leaf basewas unaffected by temperature. The size of the extension zoneand epidermal cell lengths were similar in both genotypes at10C. Growth at 20C, instead of 10C, increased the lengthof the extension zone beyond the point of maximum REGR in thewild type, but not in the Rht3 mutant. Increasing temperatureresulted in longer epidermal cells in the wild type. Treatingwild-type plants at 10C with gibberellic acid (GA₃) also increasedthe length of the extension zone, but the Rht3 mutant was GA-non-responsive.However, the concentrations of endogenous GA₁ and GA₃ remainedsimilar across the extension zone of wild-type plants grownat both temperatures, despite large differences in leaf growthrates. The period of accelerating REGR as cells enter the extensionzone, and the maximum REGR attained, are apparently not affectedby GA. It is proposed that GA functions as a stimulus for continuedcell extension by preventing cell maturation in the region beyondmaximum REGR and that low temperature increases the sensitivitythreshold for GA action. Key words: Cell extension, gibberellin, Rht3 dwarfing gene, temperature, wheat leaf     

Ectopic expression of pumpkin gibberellin oxidases alters gibberellin biosynthesis and development of transgenic Arabidopsis plants

Immature pumpkin (Cucurbita maxima) seeds contain gibberellin (GA) oxidases with unique catalytic properties resulting in GAs of unknown function for plant growth and development. Overexpression of pumpkin GA 7-oxidase (CmGA7ox) in Arabidopsis (Arabidopsis thaliana) resulted in seedlings with elongated roots, taller plants that flower earlier with only a little increase in bioactive GA4 levels compared to control plants. In the same way, overexpression of the pumpkin GA 3-oxidase1 (CmGA3ox1) resulted in a GA overdose phenotype with increased levels of endogenous GA4. This indicates that, in Arabidopsis, 7-oxidation and 3-oxidation are rate-limiting steps in GA plant hormone biosynthesis that control plant development. With an opposite effect, overexpression of pumpkin seed-specific GA 20-oxidase1 (CmGA20ox1) in Arabidopsis resulted in dwarfed plants that flower late with reduced levels of GA4 and increased levels of physiological inactive GA17 and GA25 and unexpected GA34 levels. Severe dwarfed plants were obtained by overexpression of the pumpkin GA 2-oxidase1 (CmGA2ox1) in Arabidopsis. This dramatic change in phenotype was accompanied by a considerable decrease in the levels of bioactive GA4 and an increase in the corresponding inactivation product GA34 in comparison to control plants. In this study, we demonstrate the potential of four pumpkin GA oxidase-encoding genes to modulate the GA plant hormone pool and alter plant stature and development.     

Effects of fruit load,shading, and 9,10-ketol-octadecadienoic acid (KODA) application on <Emphasis Type="Italic">MdTFL1</Emphasis> and <Emphasis Type="Italic">MdFT1</Emphasis> genes in apple buds

The effects of fruit load, shading, and 9, 10-ketol-octadecadienoic acid (KODA) application on the expression of MdTFL1 and MdFT1 genes were investigated in apples (Malus domestica Borkh.). The expression of MdTFL1 in apical buds from 21 to 63 days after full bloom (DAFB) in plants subjected to heavy crop treatment (HCT) was higher than that in plants subjected to flower thinning treatment (FTT). In contrast, the expression of MdFT1 did not show a clear difference between HCT and FTT. The shading treatment increased the expression of MdTFL1 at 35, 49, and 80 DAFB. However, MdFT1 did not show a clear difference between shading and non-shading treatments. KODA application decreased the expression of MdTFL1 at 49 DAFB, but it did not have a clear effect on the expression of MdFT1 from 21 to 91 DAFB. KODA application did not influence endogenous gibberellic acid (GA) concentrations in apical buds. These results show that KODA may be related to flower bud formation through its influence on MdTFL1. The relationship between KODA and GA with regard to the flower bud formation of apples was also discussed.     

喷施烯效唑对苹果顶芽激素水平和花芽分化的影响

用烯效唑(uniconazol,S3307)1 g/L喷洒“红富士“苹果树降低了顶芽IAA、GA1,3,4,7含量,提高了ZR、ABA含量,从而提高了ZR/IAA、ZR/GA1,3,4,7、ABA/IAA和ABA/GA1,3,4,7比值.烯效唑处理增加了花芽形成百分率,加速了花芽分化的进程,缩短了花芽形成的延续时期,但对花芽生理孕育临界时期长短没有影响.烯效唑处理对花芽的节位数没有影响,但使叶芽节位数增加了1节.     

GIBBERELLIN-INDUCED INHIBITION OF FLORAL INITIATION IN FUCHSIA

The ‘Lord Byron’ cultivar of Fuchsia hybrida is a long day plant for which GA acts as an inhibitor of flower initiation. At the dosages required to inhibit initiation (0.025 μg per plant) GA also promotes increased stem elongation but causes no other departures from normal development. Similar tests with auxins, antiauxins, kinins, and other substances showed no effect on flower initiation at dosages equivalent to that for GA. At 10- to 100-fold greater dosages, auxins, kinins, and anti-auxins inhibit not only flower initiation but also vegetative development. Thus the effect of GA on flower initiation appears to be unique, although other hormonal substances, such as abscisin, have not been tested. GA-induced inhibition is directly proportional to the dosage applied and inversely to the strength of long day induction (as measured by the number of long days). GA is most effective when applied to the terminal bud rather than to the mature leaves, suggesting that it is active at the site of flower initiation rather than in the leaves. If it is applied after translocation of the floral stimuli from the leaves, GA does not prevent flower initiation. Regardless of the dose applied, GA is less effective if applied later rather than earlier during LD induction. The inhibitory effect persists for several days. For example, an 0.85 μg dosage causes an 8–10-day delay in initiation; lower dosages have reduced effects. GA inhibits flower initiation but has no effect upon flower development. The rate of bud development is the same in GA-treated and control plants. Apparently no more than one to two axillary buds immediately below the apical meristem are receptive to long day-induced floral stimuli from the leaves. Regardless of the daylength conditions axillary buds more basal do not initiate flowers but develop into branch axes. The effect of a long day treatment persists for a very short time, perhaps no longer than the inhibition caused by minimal GA dosage. Thus flower initiation continues for a very short time following the end of long day induction. The significance of these findings is discussed in relation to the many reports of GA-induced inhibition as well as promotion of flower initiation. In particular, the discussion concerns the nation that flower initiation in fuchsia may be controlled by a gibberellin-like transmissible inhibitor.     

Interrelations of Flowering and Vegetative Growth in Callistephus chinensis (var. Queen of the Market)

In a study of the effect of photoperiod upon the growth andflowering of Calistephus chinensis (var. Queen of the Market)it has been shown that a one-hour night break of low intensityred light given to plants growing in eight hours daylight canhave a number of morphogenetic effects. In the young plant, such a treatment increased the total areaof the leaf surface and the area per unit weight of leaf material,i.e. the specific leaf area. This effect enabled the treatedplants to make greater use of the incident light, for afternine weeks they were at least 25 per cent heavier than comparableplants which had not had the benefit of the night-break treatment.This treatment also caused flower induction and concomitantstem extension, but transfer back into eight-hour days afteran inductive period accelerated further flower development andrestricted stem extension of both the main axis and the laterals.If flower development was delayed by continuing night breaksor by delaying the onset of induction then more flowers wereeventually formed, but in the very prolific treatments flowersize was reduced. The experiment also indicated that the partition of availabledry weight between leaves, stems, and roots followed a definitepattern dependent only upon total plant dry weight. The diversionof dry weight into flowers was strongly accelerated by transferinto eight-hour days after induction but the remaining dry matterstill appeared to be distributed between the vegetative partsalong the general pattern determined by total vegetative weight. Finally the experiment showed that a wide range of plant formsbearing varying amounts of flowers could be obtained by appropriatetransfers between treatments.     

Gibberellins and stem growth in Arabidopsis thaliana. Effects of photoperiod on expression of the GA4 and GA5 loci.

Arabidopsis thaliana (L.) Heynh. is a quantitative long-day (LD) rosette plant in which stem growth is mediated by gibberellins (CAs). Application of GAs to plants in short-day (SD) conditions resulted in rapid stem elongation and flower formation, with GA4 and GA9 being equally effective, and GA1 showing lower activity. The effects of photoperiod on the levels of endogenous GAs were measured by combined gas chromatography-mass spectrometry with selected ion monitoring. When plants were transferred from SD to LD conditions there was a slight decrease in the level of GA53 and an increase in the levels of C19-GAs, GA9, GA20, GA1, and GA8, indicating that GA 20-oxidase activity is stimulated in LD conditions. Expression of GA5, which encodes GA 20-oxidase, was highest in elongating stems and was correlated with the rate of stem elongation. By contrast, GA4, which encodes 3 beta-hydroxylase, showed low expression in stems and its expression was not correlated with the rate of stem elongation. We conclude that stem elongation in LD conditions is at least in part due to increased expression of GA5, whereas expression of GA4 is not under photoperiodic control.     

Complementary action of Gibberellic acid and auxins in Pea internode extension

Gibberellic acid (GA) induced extension of green pea-stem sectionsin light only if an auxin was also present. Of the auxins tested3-indolylacetic acid, 2-methyl-4-chloro-phenoxyacetic acid,2: 4-dichloro-phenoxyacetic acid and I-naphthylacetic acid wereeffective in increasing extension of sections and in elicit-inga response to GA. Excised internodes from plants pre-treatedwith GA extended appreciably faster in vitro than those fromuntreated plants only if an auxin was supplied in the incubationmedium. This and other evidence suggests that in the intactplant GA elicits a growth-response only in the presence of auxin.By comparing growth-rates of excised internodes in vitro andof intact internodes in vivo under comparable conditions, usinguntreated plants and plants pre-treated with GA, evidence hasbeen obtained that in untreated plants growth-rate is somehowlimited to a level below that made potentially possible by theendogenous auxin supply; treatment with GA appears to releasethe plant from this state of inhibition. Growth of intact peainternodes is considered to be regulated by a three-factor system,consisting of auxin, an inhibitory system, and a hormone withphysiological properties similar to those of GA.     

Involvement of abscisic acid in the regulation of sex expression in the cucumber

The interaction between abscisic acid (ABA), gibberellin (GA)and ethephon on sex determination in cucumber (Cucumis sativusL.) flowers was examined. ABA promoted the female tendency ofgynoecious plants, but did not change the sex expression ofmonoecious ones. When ABA was applied together with GA₄₊₇ thepromoting activity of the GA on male flower formation in thegynoecious line was reduced. ABA also inhibited tendril appearanceand internode length, characteristic of GA treatments. A combinedABA and ethephon treatment resulted in a synergistic activityinhibiting growth and increasing the period of female flowerappearance in the monoecious line. It is suggested that ABAparticipates in the sex regulation of the cucumber by inhibitingGA activity. (Received March 8, 1974; )     

光皮树花芽分化过程中内源激素含量变化的研究

以4年生光皮树嫁接苗为材料,采用酶联免疫吸附法（ELISA）测定同龄开花光皮树与不开花光皮树叶内4种内源激素生长素（IAA）、赤霉素（GA3）、玉米核苷素（ZR）、脱落酸（ABA）含量的动态变化,研究成花过程中叶片内源激素含量的变化与成花的关系。研究结果表明：在芽分化时期开花光皮树和未开花光皮树叶内4种内源激素含量动态变化存在显著差异。有花芽分化的光皮树保持相对较低和稳定IAA、GA3含量,ABA含量高且变化幅度较大,ZR含量相对较低,但随着花的形成含量逐渐升高;而在相同的生长季内,无花光皮树IAA、GA3含量先升高后降低,ABA含量先逐渐升高,然后下降,而ZR含量呈现出先逐渐升高然后降低,再升高再下降的变化趋势。因此,4种内源激素含量的动态变化影响光皮树的成花过程。     

The Effects of Nutrient Factors on the Response of Peas to Gibberellic Acid

The extent to which gibberellic acid (GA) stimulated internodeextension and depressed leaf growth was found to be greatestwhen nutrient supplies were low. Node of first flower was independentlyaffected by GA (increased) and by nutrient (decreased). Developingflowers varied in their sensitivity to GA, aborting when givenGA at about four plastochrons of age.     

藤本月季“安吉拉”花芽分化形态结构及内源激素变化研究

以藤本月季“安吉拉”为试验材料,通过石蜡切片、体视显微镜观察及内源激素的测定,研究花芽分化过程的形态结构及内源激素的变化,为花期调控、景观品质的提升及相关育种工作提供基础数据。藤本月季“安吉拉”花芽各部分分化顺序由外向内进行,分为5个时期,共历时30 d,首先是生长锥呈圆锥状突起的形态分化期;扁平生长锥周围出现5个突起,即为萼片原基分化期;萼片原基的内方分化出成轮状的多个花瓣原基,即为花瓣原基分化期;花瓣原基基部从上向下分化出多轮雄蕊原基,即为雄蕊原基分化期;扁平的生长锥顶端突起形成多个雌蕊原基,为雌蕊原基分化期。随花芽分化进程脱落酸(ABA)、细胞分裂素(CTK)浓度变化规律相似,均呈先升高再下降趋势,萼片原基分化期其浓度均显著高于其他时期;生长素(IAA)浓度呈逐渐上升的趋势;赤霉素(GA)浓度呈逐渐下降趋势。随花芽分化进程IAA/GA和IAA/ABA比值呈逐渐上升趋势,CTK/GA和(ABA+CTK)/GA比值在萼片原基分化期显著高于形态分化期。内源激素测定结果表明:ABA、CTK浓度在萼片原基分化期显著升高与花芽分化诱导有关,较低的IAA浓度以及GA浓度的降低有利于藤本月季“安吉拉”的花芽分化;萼片原基分化期CTK/GA和(ABA+CTK)/GA比值升高可能与花芽分化诱导有关,高水平的IAA/ABA和IAA/GA比值可能与花器官原基的进一步发育相关。     

Floral initiation in strawberry: Spectral evidence for the regulation of flowering by long-day inhibition

Summary Floral initiation in strawberry cv. Cambridge Favourite, a facultative short-day plant, was inhibited by a daylength extension with red light (R) during the second half of a 16-hour night but not during the first half, and by far-red light (FR) in the first half but not during the second. Mixed R plus FR light was inhibitory to flowering at both times. This change in sensitivity to R and FR light in the evening and morning resembles the pattern for flower induction in long-day plants but differs from the pattern for flower inhibition in several other short-day plants, examples of which are given. These experiments afford further support for the hypothesis that the control of flower initiation in strawberry depends on the production of a flower inhibitor by leaves exposed to long photoperiods.Abbreviations R red - FR far-red - SD short day - LD long day - SDP short-day plant - LDP long-day plant     

Expression of gibberellin 2-oxidase 4 from Arabidopsis under the control of a senescence-associated promoter results in a dominant semi-dwarf plant with normal flowering

Gibberellin (GA), a plant hormone, is involved in many aspects of plant growth and development both in vegetative and reproductive phases. GA2-oxidase plays a key role in the GA catabolic pathway to reduce bioactive GAs. We produced transgenic Arabidopsis plants expressing GA2-oxidase 4 (AtGA2ox4) under the control of a senescenceassociated promoter (SEN1). As we hypothesized, transgenic plants (SEN1::AtGA2ox4) exhibited a dominant semi-dwarf phenotype with a decrease of bioactive GAs (e.g., GA4 and GA1) up to two-fold compared to control plants. Application of bioactive GA3 resulted in increased shoot length, indicating that the GA signaling pathway functions normally in the SEN1::AtGA2ox4 plants. Expressions of other members of GA2-oxidase family, such as AtGA2ox1, AtGA2ox3, AtGA2ox6, and AtGA2ox8, were decreased slightly in the flower and silique tissues while GA biosynthetic genes (e.g., AtGA20ox1, AtGA20ox2 and AtGA3ox1) were not significantly changed in the SEN::AtGA2ox4 plants. Using proteome profiling (2-D PAGE followed by MALDI-TOF/MS), we identified 29 protein spots that were increased in the SEN1::AtGA2ox4 plants, but were decreased to wild-type levels by GA3 treatment. The majority were found to be involved in photosynthesis and carbon/energy metabolism. Unlike the previous constitutive over-expression of GA2-oxidases, which frequently led to floral deformity and/or loss of fertility, the SEN1::AtGA2ox4 plants retained normal floral morphology and seed production. Accordingly, the expressions of FT and CO genes remained unchanged in the SEN1::AtGA2ox4 plants. Taken together, our results suggest that the dominant dwarf trait carried by SEN1::AtGA2ox4 plants can be used as an efficient dwarfing tool in plant biotechnological applications.