Internode Length in Pisum: Variation in Response to a Daylength Extension with Incandescent Light

Lines representing a range of internode length and floweringgenotypes in Pisum sativum L. were grown in 8 h of daylightfollowed by either 16 h of darkness or incandescent light. Thestem elongation response index (RI = length in 24 h ÷length in 8 h) was least in the very short internode nana types,which are grossly deficient in gibberellins (GAs), and the verylong internode slender types, which behave as if saturated withGAs. The common tall (genotype Le) and dwarf (le) types (lepartially blocks conversion of GA₂₀ to the active form, GA₁)were all markedly responsive but the peak RI (based on the mostresponsive internode) was less in tall lines (1.79 to 2.78)than in dwarf lines (2.32 to 5.01) and the peak RI tended tooccur about three to four internodes earlier in tall than indwarf lines. The cry⁸ mutation reduced the RI. (Duplicate lengthloci La and Cry are probably concerned with GA reception.) Amongle dwarf lines, genotype La cry⁸, was generally less responsivethan La Cry, La cry^c and la Cry. Data from crosses showed thaton either an le La or le la background cry⁸ segregates had alower RI than cry⁸ segregates. On an le la background, cry⁸plants were shorter than cry^c plants, cry⁸ was partially dominantto cry⁸ and segregation was clear only in long days. On an lela background, cry^c plants were shorter than cry^c plants, cry⁸was partially dominant to cry⁸ and segregation was clear inlong or short days. The very high peak RI (5.0) of the microcryptodwarfline, L57, appeared to result, in part, from a marked foreshorteningof internodes 4 to 10 in the 8 h regime. In the 24 h regimeL57 (lm) had a fairly similar growth pattern to normal (Lm)cryptodwarf types. The peak RI tended to occur at a lower internode in early thanlate flowering lines, especially among dwarf types, and genotypeswith a day neutral flowering habit (genotype sn or dne) wereless responsive than their photoperiodic counterparts (Sn Dne). White fluorescent light, given as a daylength extension, wasmuch less effective than incandescent light at stimulating stemelongation suggesting control through the phytochrome equilibrium(P_tr/P_total). Pisum sativum, garden pea, daylength extension, flowering, genotype, gibberellin, hormone receptor, incandescent light, internode length, phytochrome, stem elongation     

Internode Length in Pisum: the Response of le na Scions Grafted to Na Stocks

The recessive gene na results in peas with extremely short internodes(phenotype nana). In intact plants, na prevents expression ofthe Le/le gene pair which determine the tall/dwarf difference.na blocks a step early in the gibberellin biosynthetic pathwaywhile le prevents conversion of gibberellin A₂₀ to GA₁. Whengrafted to leafy Na stocks, le na and Le na scions become phenotypicallydwarf and tall, respectively. Hence, Na stocks provide a graft-transmissiblesubstance which promotes elongation of na scions and allowsexpression of the Le/le difference. Pisum, internode length, grafting, genotype     

Effects of Gibberellin on the Arrangement and the Cold Stability of Cortical Microtubules in Epidermal Cells of Pea Internodes

Longitudinal microtubules are predominant in epidermal cellsof the 3rd internodes of dwarf pea (Pisum sativum L. cv. LittleMarvel) seedlings. In more than 50% of the cells, cortical microtubulesare running parallel to the cell axis. GA₃ promotes elongation of the internodes and gives rise toa predominance of transverse microtubules. In more than 60%of the GA₃-treatd cells, cortical microtubules are running transverseto the cell axis. Longitudinal microtubules in the GA₃-untreated cells are resistantto low-temperature treatment, but transverse microtubules inthe GA₃-treated cells are sensitive to it. Longitudinal microtubulesare present in GA₃-treated epidermal cells with low frequency.They are resistant to low-temperature treatment. Longitudinal, oblique and transverse microtubules are presentwith almost the same frequency in epidermal cells of the 3rdinternodes of tall pea (cv. Early Alaska) seedlings. GA₃ promoteselongation of the internodes also in tall pea seedlings, butit does not alter the direction of cortical microtubules sodistinctly as it does in dwarf pea seedlings. As in dwarf pea seedlings, longitudinal microtubules are resistantto low-temperature treatment, and transverse microtubules aresensitive to it in tall pea seedlings. (Received September 19, 1986; Accepted December 26, 1986)     

Ontogenetic variation in levels of gibberellin A1 in Pisum

The levels of the biologically active gibberellin (GA), GA₁, and of its precursor, GA₂₀, were monitored at several stages during ontogeny in the apical portions of isogenic tall (Le) and dwarf (le) peas (Pisum sativum L.) using deuterated internal standards and gas chromatography-selected ion monitoring. The levels of both GAs were relatively low on emergence and on impending apical arrest. At these early and late stages of development the internodes were substantially shorter than at intermediate stages, but were capable of large responses to applied GA₃. Tall plants generally contained 10–18 times more GA₁ and possessed internodes 2–3 times longer than dwarf plants. Further, dwarf plants contained 3–5 times more GA₂₀ than tall plants. No conclusive evidence for the presence of GA₃ or GA₅ could be obtained, even with the aid of [²H₂]GA₃ and [²H₂]GA₅ internal standards. If GA₃ and GA₅ were present in tall plants, their levels were less than 0.5% and 1.4% of the level of GA₁, respectively. Comparison of the effects of gene le on GA₁ levels and internode length with the effects of ontogeny on these variables shows that the ontogenetic variation in GA₁ content was sufficient to account for much of the observed variation in internode length within the wild-type. However, evidence was also obtained for substantial differences in the potential length of different internodes even when saturating levels of exogenous GA₃ were present.Abreviations GA_n gibberellin A_n We thank Noel Davies, Omar Hasan, Leigh Johnson, Katherine McPherson and Naomi Lawrence for technical help, Professor L. Mander (Australian National University, Canberra) for deuterated GA standards and the Australian Research Council for financial assistance.     

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.     

The Distribution of Gibberellins in Vegetative Tissues of Pisum sativum L. : I. Biological and Biochemical Consequences of the le Mutation

The concentrations of endogenous gibberellin (GA) 1, 5, 8, 19, 20, and 29 in the component tissues of maturing tall (Le) and dwarf (le) pea (Pisum sativum) plants have been determined. The following conclusions were drawn from the data obtained: (a) GA₂₀ and its metabolites accumulate only in the growing regions of Le and le plants; (b) the le mutation is biochemically expressed in all immature tissues of the dwarf plants; (c) the quantitative composition of the GA metabolites in the various immature tissues is variable; (d) the total GA concentration in apical buds, unexpanded leaves, and tendrils is considerably higher than in GA₁-responsive stem tissue; and (e) there is very little GA accumulation of the inactive 2β-hydroxylated GAs (GA₈ and GA₂₉) in either the mature vegetative tissues or the roots of pea plants.     

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     

Growth and Biomass Allocation, with Varying Nitrogen Availability, of Near-isogenic Pea Lines with Differing Foliage Structure

The single-gene mutation afila in pea (Pisum sativum L.) resultsin the replacement of proximal leaflets with branched tendrils,thereby reducing leaf area. This study investigated whethertheafila line could adjust biomass partitioning when exposedto varying nutrient regimes, to compensate for reduced leafarea, compared with wild-type plants. Wild-type and afila near-isogeniclines were grown in solution culture with nitrate-N added toinitially N-starved seedlings at relative addition rates (R_N)of 0.06, 0.12, 0.15 and 0.50 d^-1. The relative growth rate (R_W)of the whole plants closely matched R_Nat 0.06 and 0.12 d^-1,but higher R_Nresulted in a slightly higher growth rate. At agiven R_N, the wild-type line had lower plant nitrogen statusthan the afila line. R_Wof the roots of the afila line was lessthan R_Wof the roots of the wild-type at the three higher ratesof N supply despite a greater accumulation of N in the rootsof the afila plants. Consequently, plant nitrogen productivity(growth rate per unit nitrogen) was lower for afila. Dry matterallocation was strongly influenced by nitrogen status, but nodifferences in shoot–root dry matter allocation were foundbetween wild-type and afila with the same plant N status. Theseresults imply that decreased leaf area as a result of the single-genemutation afila affects dry matter allocation, but only accordingto its effect on the nitrogen status. Copyright 2000 Annalsof Botany Company Pisum sativum, pea, nitrogen limitation, growth, shoot–root allocation, relative growth rate, nitrogen productivity, isolines     

Effects of a Plant-Growth Regulator, Prohexadione, on the Biosynthesis of Gibberellins in Cell-Free Systems Derived from Immature Seeds

Inhibition of the biosynthesis of gibberellins by prohexadione,3,5-dioxo-4-propionylcyclo-hexanecarboxylic acid, was studiedwith cell-free systems derived from immature seeds of Cucur-bitamaxima, Phaseolus vulgaris and Pisum sativum. Prohexadione,at a concentration of 10–⁴ M, inhibited C-7 oxidationof GA₁₂-aldehyde, C-20 oxidation of GA₁₅, conversion of C₂₀-gib-berellinsto C₁₉-gibberellins, 3ß-hydroxylation, 2,3-dehydrogenationof GA²⁰, 2,3-epoxidation of GA₅ and 2ß-hydroxylationof GA₉ and GA₂₀. The 3ß-hydroxylase activity appearedto be more sensitive to prohexadione than were the C-20 oxygenaseand the 2ß-hydroxylase activities. The conversionof mevalonic acid to GA₁₂-aldehyde and the 13-hydroxylationof GA₁₂ were not affected by prohexadione at a concentrationof 3 ? 10^–4 M. All of the steps inhibited by prohexadioneare oxidation steps catalyzed by soluble enzymes that require2-oxoglutarate, Fe²⁺ and oxygen, and all of them occur distalto the synthesis of GA₁₂-aldehyde in the biosynthesis of gibberellins. (Received April 4, 1990; Accepted September 14, 1990)     

Comparative Potency of Nine Gibberellins

Gibberellins A₁ to A₉ have been compared, each at several doselevels, in bioassays based on extension of stems of dwarf gardenpea (Pisum sativum), dwarf bean (Phaseolus vulgaris) and Lunariaannua, of hypocotyls of cucumber (Cucumis sativus) and lettuce(Lactuca sativa), and of leaf sheaths of three dwarf mutants(d–1, d–3, d–5) of maize (Zea mays). GibberellinsA₃ (gibberellic acid) and A₇ are of high potency in most bioassays.A₈ is of negligible potency in all and is probably not a functionalhormone. The other gibberellins show a more or less marked tendencyto specificity. The plants used as bioassay material also differin the specificity of their response. Some, for example, maizedwarfs d–3 and d–5 and lettuce, respond well tomost gibberellins; others, for example, cucumber, respond onlyto a few; extreme specificity is shown by Lunaria annua which,in the unvernalized condition, responds by stem elongation onlyto gibberellin A₇. Dose/response curves of the various gibberellinsare usually parallel, but certain exceptions to this have beenfound. Possible explanations of specificity are discussed inrelation to the results obtained, and it is concluded that insufficientevidence is available to make it possible to draw any validconclusions. Current definitions of gibberellins, whether basedon chemical structure or biological activity, are unsatisfactory.     

Metabolism and Translocation of Gibberellins in Seedlings of Pharbitis nil. (I) Effect of Photoperiod on Stem Elongation and Endogenous Gibberellins in Cotyledons and Their Phloem Exudates

Gibberellin A₁, (GA₁), GA₁₉, and GA₂₀ in phloem exudates andcotyledons of seedlings of Pharbitis nil cv. Violet, grown underdifferent photoperiodic conditions, were qualitatively and semi-quantitativelyanalyzed by a combination of high performance-liquid chromatography(HPLC) and radioimmunoassays (RIA). The levels of GA₁₉ and GA₂₀were higher in cotyledons from plants grown under dark treatment(DT) conditons of 16 h-light/8 h-dark for 6 days followed by8 h-light/16 h-dark for 3 days than in those grown under continuouslight (CL) for 9 days. This relationship was also observed forthe GAs in phloem exudates, although the levels were much lowerthan in the cotyledons. When GAs were applied to the cotyledons,elongation of the epicotyl was promoted more by GA₂₀ than byGA₁ or GA₁₉, especially under the CL treatment. The relativeeffect of GA₁ and GA₂₀ on the epicotyl elongation was reversedwhen these GAs were applied to epicotyls pre-treated with prohexadione,an inhibitor of 2-oxoglutarate-dependent dioxygenases. ³Present address: Frontier Research Program, The Institute ofPhysical and Chemical Research (RIKEN), 2-1 Hirosawa, Wakoshi,Saitama, 351-01 Japan ⁴Present address: Laboratory of Horticulture, Faculty of Agriculture,Nagoya University, Nagoya, 464-01 Japan     

Use of an Acylcyclohexanedione Growth Retardant, LAB 198 999, to Determine Whether Gibberellin A(20) Has Biological Activity per se in Dark-Grown Dwarf (le) Seedlings of Pisum sativum

Dwarf (le⁵⁸³⁹) seedlings of Pisum sativum respond to gibberellin A₂₀ (GA₂₀) in the dark, although the same dosage of GA₂₀ applied to light-grown le⁵⁸³⁹ seedlings elicits no growth response. The acylcyclohexanedione growth retardant, LAB 198 999, which is known to inhibit gibberellin oxidation and in particular 3β-hydroxylation such as the conversion of GA₂₀ to GA₁, also inhibits the growth response of dark-grown dwarf (le⁵⁸³⁹) seedlings to GA₂₀. Thus, the biological activity of GA₂₀ in the dark appears to be a consequence of its conversion to GA₁, even though it is known from studies with light-grown seedlings that the le mutation reduces the conversion of GA₂₀ to GA₁.     

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     

Metabolism of Gibberellins in Cell-Free Extracts of Anthers from Normal and Dwarf Rice

Cell-free extracts were prepared from anthers of normal anddwarf rice (Oryza sativa L.), and the metabolism of radioisotope-labeledgibberellins in the extracts was analyzed by HPLC and gas chromatography-massspectrometry (GC/MS). GA₁₂ was converted to GA₁₅ and GA₃₄ inthe extracts. GA₂₀ was converted to GA¹, GA₈ and GA₂₉, but GA₉was converted only to GA₃₄. The extracts of the dwarf cultivar,Waito-C (dy mutant), showed the same 3ß-hydroxylationactivity as did those of the normal cultivar, Nihonbare, indicatingthat the dy gene is not expressed in the anthers. These resultssuggest that the regulation of the biosynthesis of gibberellinsin rice is organ-specific. (Received November 9, 1989; Accepted January 10, 1990)     

Gibberellin A3 and Abscisic Acid Cause the Reorientation of Cortical Microtubules in Epicotyl Cells of the Decapitated Dwarf Pea

To determine whether or not the changes in the orientation ofmicrotubules (MTs) that are induced by GA₃ and ABA result fromchanges in the rate of epicotyl elongation caused by these hormones,we examined the effects of GA₃ and ABA on the orientation ofMTs in epidermal cells of decapitated epicotyls of the dwarfpea (Pisum sativum cv. Little Marvel), in which neither GA₃nor ABA causes changes in the rate of epicotyl elongation. Cuttings taken from GA₃-pretreated seedlings were decapitatedand treated with ABA. ABA eliminated the GA₃-induced predominanceof transverse MTs and treatment with ABA resulted in a predominanceof longitudinal MTs in the decapitated cuttings. However, ABAdid not reduce the rate of epicotyl elongation in these samples.Cuttings taken from ABA-pretreated seedlings were decapitatedand treated with GA₃. GA₃ caused the orientation of MTs to changefrom longitudinal to transverse in the decapitated cuttings.However, GA₃ had no promotive effect on elongation of theseepicotyls. The results indicate that both ABA and GA₃ have the abilityto change the orientation of MTs by mechanisms that do not involvechanges in the rate of cell elongation. (Received August 18, 1992; Accepted January 18, 1993)     

Effects of a Plant Growth Regulator, Prohexadione Calcium (BX-112), on the Elongation of Rice Shoots Caused by Exogenously Applied Gibberellins and Helminthosporol, Part II

Prohexadione calcium (BX-112) is a novel plant growth regulatorthat inhibits the late stages of the biosynthesis of gibberellinsin plants. Fourteen kinds of gjbberellin, helminthosporol and'helminthosporic acid were applied simultaneously with BX-112to rice seedlings (Oryza sativa L. ), and their growth-promotingactivities in terms of shoot elongation were examined. The growth-promotingactivities of GA₁, GA₄, GA₁₈, GA₂₂, GA₂₃, GA₃₈, helminthosporoland helminthosporic acid were not inhibited by BX-112, but thoseof GA₅, GA₉, GA₁₅, GA₁₉, GA₂₀, GA₃₁, GA₄₄ and GA₅₃ were inhibited.These results suggest that 3ß-hydroxylation is animportant and necessary step in the biosynthesis of gibberellinsthat promote shoot elongation in rice seedlings. The weak promotionof shoot elongation by GA₂₂ in the presence of BX-112 suggeststhat the effect of a hydroxyl group at C-18 of GA₂₂ might beable to mimic the effect of the 3ß-hydroxyl groupof GA₁. Helminthosporol and helminthosporic acid may promotethe shoot elongation of rice by mimicking physiologically activegibberellins and not by stimulating their biosynthesis. ¹Part I is the previous paper by Nakayama et al. (1990a) ³Present address: Frontier Research Program RIKEN, Wako-shi,Saitama, 351-01 Japan. (Received June 26, 1991; Accepted September 4, 1991)     

Quantal Response of Seed Germination in Seven Genera of Cruciferae to White Light of Varying Photon Flux Density and Photoperiod

The response of the germination of seeds of Barbarea vema (Mill.)Aschers, Brassica chinensis L., Brassica juncea (L.) Czern.& Coss., Brassica oleracea L. var. gongylodes L., Camelinasaliva (L.) Crantz, Eruca saliva Mill., Lepidium sativum L.,Nasturtium officinale R. Br., and Rorippa palustris (L.) Besserto white fluorescent light of different photon flux densitiesapplied for different daily durations in a diurnal alternatingtemperature regime of 20 °C/30 °C (16 h/8 h) was quantifiedby linear relations between probit percentage germination andthe logarithm of photon dose, the product of photon flux densityand duration. The low energy reaction, in which increasing dosepromotes germination, was detected in all the seed populationsbut in Barbarea vema and Brassica Juncea the lowest photon doseapplied (10^–5–2 and 10^{–5 7} mol m^–2 d^–1,respectively) was sufficient to saturate the response. Comparisons,where possible, between photoperiods demonstrated reciprocity,i.e. germination was proportional to photon dose irrespectiveof photoperiod, for the low energy reaction in Brassica oleracea(1 min d^–1 to 1 h d^–1), Camelina saliva (1 min d^–1to 8 h d^–1), Eruca saliva (1 min d^–1 to 24 h d^–1),Lepidium sativum (I min d^–1 to 8 h d^–1) and Rorippapalustris (1 min d^–1 to 8 h d^–1), but not in Brassicachinensis and Nasturtium officinale. The high irradiance reaction,in which increasing dose inhibits germination, was detectedin Barbarea vema, Brassica chinensis, Brassica juncea, Brassicaoleracea, and Camelina saliva. The minimum dose at which inhibitionwas detected was lO^–0–3 mol m^–2 d^–1.These results are discussed in the context of devising optimallight regimes for laboratory tests intended to maximize germination The response of germination to photon dose was also quantifiedwith 3 x 10^–4 M GA₂, co-applied (Brassica chinensis, Camelinasaliva, and Lepidium sativum) and with 2 x 10^–2 M potassiumnitrate co-applied (Brassica chinensis). In the latter casepotassium nitrate had no effect in the dark and inhibited germinationin the light, but GA₂, promoted germination substantially inall three species. Variation amongst seeds in the minimum photondose required to stimulate germination was not affected by co-applicationof GA₂, in Brassica chinensis and Camelina saliva, whereas seedsof Lepidium salivum showed a narrower distribution of sensitivitiesto the low energy reaction in the presence of GA₂ Barbarea vema (Mill.) Aschers, Brassica chinensis L., Brassica juncea (L.) Czern. & Coss., Brassica oleracea L. var. gongylodes L., Camelina saliva (L.) Crantz, Eruca saliva Mill., Lepidium satiaum L., Nasturtium officinale R. Br., Rorippa palustris (L.) Besser, Cruciferae, light, gibberellic acid, seed germination, seed dormancy     

Effects of Low Irradiance Stress on Gibberellin Levels in Pea Seedlings

Using gas chromatography-selected ion monitoring with internalstandards we analyzed endogenous levels of GA₁, GA₈, GA₁₉, GA₂₀,GA₂₉, GA₄₄ and GA₅₃ in shoots of pea cv. Alaska grown underdifferent levels of irradiance: high irradiance, 386±70µmolm^-2s^-1, control (100%); medium (50%); low (10%); darkness (0%).The average plant heights for medium and low irradiance anddark grown plants were 157%, 275%, and 460% of the control plants,respectively. Plants grown in medium and low irradiance developedthe same numbers of internodes as control plants but plantsin darkness developed fewer internodes and exhibited suppressedleaf expansion. The endogenous levels of GA₁ GA₈ and GA₂₉ werehigher in medium and low irradiance grown plants than thoseof the high irradiance control. In particular, the GA₂₀ levelof low irradiance plants was markedly higher (7.6-fold) thanthat of control plants. In dark-grown plants GA₁, and GA₈ levelsalso slightly increased but GA₂₀ and GA₂₉ levels decreased andthe levels of GA₁₉, GA₄₄ and GA₅₃ did not change. Feeding ofGA₁, and a GA biosynthesis inhibitor (uniconazole) to plantsgrown at reduced irradiance and in darkness suggests that theresponsiveness of plants to GA₁, also increased at low irradianceand in darkness. In conclusion, plants increase both GA₁, andGA₂₀ biosynthesis or altered catabolism and GA₁, responsivenessunder low irradiance stress ¹Present address: Dept. of Plant Physiol., Warsaw AgriculturalUniversity, Rakowiecka 26-30, 02-528 Warsaw, Poland     

Metabolism and Translocation of Gibberellins in the Seedlings of Pharbitis nil (II). Photoperiodic Effects on Metabolism and Translocation of Gibberellins Applied to Cotyledons

We investigated the metabolism and translocation of two gibberellins(GAs), [³H]GA₂₀ and [³H]GA₁, which were applied at low concentrationto the cotyledons of Pharbitis nil (cv. Violet). Seedlings weregrown under three different photoperiodic conditions: continuouslight (CL-CL), continous light followed by short day conditions(CL-DT) and long day conditions followed by short day conditions(DT-DT). Translocation of the applied [³H]GAs from cotyledonsto hypocotyls was promoted by DT for all GAs examined. Whilethe conversion of the translocated [³H]GA₁ to [³H]GA₈ and itsconjugates was rapid in hypocotyl, the conversion of translocated[³H]GA₂₀ to [³H]GA₂₉ was slow. Radioactivity in epicotyls wasdetected much more rapidly on application of [³H]GA₂₀ than of[³H]GA₁, [³H]GA₈ and [³H]GA₂₉ and their conjugates. The conversionof [³H]GA₂₀ to [³H]GA₁ in the epicotyl was more rapid underCL-CL conditions. This result in consistent with the higherlevel of endogenous GA₁ existing in epicotyls under CL-DT thanDT-DT conditions. However, when [³H]GA₁ was applied to the cotyledon,only small amounts of [³H]GA₈ and its conjugates were detectedin the epicotyl regardless of the photoperiodic conditions.This result may suggest that the translocation and metabolismof [³H]GA₂₀ from cotyledons to epicotyl was faster under CL-CLthan DT-DT conditions and may correlate with the increased epicotylelongation of GA₂₀ treated plants under CL-DT than DT-DT conditions. (Received June 28, 1995; Accepted November 2, 1995)