Flower-Promoting Effects of Iron and EDDHA in Lemna paucicostata 151

Lemna paucicostata 151 cultured in 1/10 strength M medium containing50 µM FeCl₃ easily flowered in response to short days,although it scarcely flowered under any photoperiod when themedium contained the standard amount of iron (2 µM FeCl₃).The flowering response was accomparied by an increase in theiron content of the plants, which was maximal at pH 5.0. Instandard M medium containing 50 µM FeCl³, this plant didnot flower even though it had a high iron content. Ethylenediamine-di (o-hydroxyphenylacetic acid) (EDDHA) inducedflowering of this strain under continuous light even in theabsence of iron and copper, and its effect was slightly loweredby the presence of iron in the medium. Thus the flower-inducingactivity of EDDHA could not be attributed to the action of ironor copper. EDTA inhibited both the iron uptake and floweringin Fe-rich medium under short-day conditions. (Received May 16, 1986; Accepted July 25, 1986)     

Some effects of salicylic acid on growth and flowering in Spirodela polyrrhiza SP20

More than 70% flowering was observed in Spirodela polyrrhizaSP₂₀ under long and short days, when fronds were grown in amedium supplemented with 5x10^–5 M salicylate (SA). Toour knowledge this is the first report of such profuse floweringof this duckweed in vitro. Besides flowering, SA also affectedthe multiplication rate, anthocyanin and chlorophyll contents,and gibbosity. Aspirin had an effect similar to that of SA. (Received April 1, 1980; )     

Floral Induction in a Photoperiodically Neutral Duckweed, Lemna paucicostata Strain LP6: Role of Chelating Agents and Iron

Lemna paucicostata, strain LP₆, does not ordinarily flower underany photoperiodic schedule, when grown in the modified Bonner-Devirianmedium supplemented with 10^–4 M EDTA and 1% sucrose (thisis a medium which is otherwise satisfactory for short day inductionof flowering of other strains of this duckweed). However, when the ferric citrate concentration in the culturemedium containing EDTA was raised 10-fold over that in the normalmedium, a low but significant flowering could be initiated inthis duckweed, irrespective of the length of the photoperiod.A similar flowering response was obtained when ferric citratewas replaced by ferrous sulphate or ferric chloride, therebyindicating that the inductive effect of higher level of ferriccitrate on flowering in strain LP₆ is due to its iron component. Some flowering in this strain could be induced even in mediumcontaining normal level of iron, provided the level of EDTA,itself, was raised to 5?10^–4 (5% flowering) or to 10^–3M (12% flowering), but replacement of EDTA by EDDHA led to trulyremarkable effects. With EDDHA, flowering could be induced at very high levels (90%)under all photoperiodic regimes tried. Floral initiation couldbe obtained even with 10^–6 M EDDHA, though the optimallevel ranged from 5?10^–6 to 10^–5 M. (Received October 4, 1985; Accepted June 26, 1986)     

Experimental control of flowering in Pistia stratiotes L.

GA₃, salicylic acid and EDDHA induced flowering in Pistia stratiotesin vitro under short days and conditions of continuous light.It has been hypothesized that EDDHA and salicylic acid bringabout the same effect on flowering in Pistia and the duckweedspecies Lemma gibba G3 whereas the effect of GA₃ on the floweringmechanism of these species is basically different. (Received March 14, 1978; )     

Specific interactions in the physiology of flowering and gibbosity of Lemna gibba G3

Fronds of Lemna gibba G3 became conspicuously gibbous when ethrel,an ethylenereleasing compound, was added to the nutrient medium.Maximal gibbosity was obtained at ethrel concentrations of 1µg/ml and higher. Unlike the chelating agent, EDDHA, whichcauses profuse flowering and markedly gibbous fronds under long-dayconditions, ethrel did not affect flowering. In the presenceof an optimal concentration of EDDHA (10 µ/ml), ethreleven significantly inhibited flowering and caused developmentof excessively gibbous fronds. Autoclaved gibberellic acid specifically negated the ethreleffect as it does that of EDDHA. Three decomposition productsof GA₃, allogibberic acid, epiallogibberic acid and gibbericacid, also nullified flowering and gibbosity in the presenceof EDDHA. A fourth decomposition product of GA₃, epigibbericacid, inhibited gibbosity but hardly affected flowering. Salicylic acid was confirmed to affect flowering and gibbosityin L. gibba G3. However, contrary to an earlier report, it didnot induce flowering under short-day conditions. (Received January 10, 1976; )     

Floral Induction in Wolffia microscopica by Salicylic Acid and Related Compounds under Non-inductive Long Days

Flowering in Wolffia microscopica, a short-day plant, couldbe induced with salicylic acid (SA), under long days. Aspirin,benzoic acid and salicylaldoxime were also effective for inductionof flowering in this duckweed. Amonsgt these, SA is the mosteffective compound, as it could induce flowering even at 10^–7M. Flowering was further enhanced when Wolffia fronds were subjectedto short days, in the presence of SA. However, SA neither showedany effect on flowering ofW. microscopica in the absence ofEDTA in the nutrient medium, nor could it, by itself, supporteven the vegetative growth. The probable mechanism of actionof SA has also been discussed. It appears that the effect cannotbe due simply to chelation of metal ions and perhaps the salicylmoiety itself exerts a specific effect. (Received March 15, 1983; Accepted May 6, 1983)     

Gibberellin-EDDHA interaction in flowering and gibbosity of Lemna gibba G3

The effect of gibberellic acid (GA₃), in the presence of EDDHA,on the flowering and gibbosity of Lemna gibba G3 was studied.At 10 ppm and at higher concentrations of GA₃ the EDDHA-effect,i.e. profuse flowering and conspicuously gibbous fronds, wascompletely nullified. (Received July 15, 1974; )     

The Role of Benzoic Acid and Plant Hormones in Flowering of Lemna gibba G3

The level of benzoic acid was measured in Lemna gibba G3 grownon M and E media under inductive and non-inductive daylengths.Benzoic acid was slightly higher in plants grown on M mediumbut there was no difference in the benzoic acid levels in floweringand vegetative plants. When L. gibba G3 was grown under continuouslight on 1/10 M medium or 1/2 H medium there was virtually noflowering, but addition of benzoic acid to either medium ledto a substantial flowering response. In both cases this floweringresponse was inhibited by the plant hormones IAA, GA₃, ABA andzeatin, with IAA and GA₃ being the least inhibitory and ABAbeing the most inhibitory. This same pattern of inhibition wasseen when L. gibba G3 was grown on M medium under continuouslight, conditions that lead to photoinduction of flowering.These results leave open the possibility that endogenous benzoicacid may interact with other factors to influence the floweringresponse in L. gibba G3. (Received November 13, 1984; Accepted February 27, 1985)     

Interaction of naphthol with EDDHA/salicylic acid in flowering and gibbosity of Lemna gibba G3

Flowering and gibbosity in Lemna gibba G3, as enhanced or inducedby optimal concentrations of salicylic acid or EDDHA, was specificallyinhibited by 10 µg/ml and higher concentrations of ß-naphthol.These effects of ß-naphthol are similar to those ofbreakdown products of GA_s. (Received March 20, 1978; )     

Effects of some SH-inhibitors and EDTA on flowering in Lemna perpusilla 6746

Lemna perpusilla 6746, a short-day duckweed, flowered undercontinuous illumination on M-sucrose medium containing CuSO₄,AgNO₃ and HgCl₂, which are SH-inhibitors. The optimum concentrationsof CuSO₄, AgNO₃ and HgCl₂ were 5, 1 and 20 µM, respectively.Other metal ions tested were ineffective, but at least two otherSHinhibitors, potassium ferricyanide and iodoacetamide, alsoinduced long-day flowering at the concentrations of 0.1-1 µM. Adding 50 µM EDTA to the medium prevented the effect ofcupric ion, but not that of other SH-inhibitors. EDTA at 200µM induced some long-day flowering when added to a mediumwith no SH-inhibitors. It also permitted some flowering whenadded together with cupric ion, and accelerated flowering inthe presence of the other SHinhibitors listed above. EDTA andSH-inhibitor effects appeared to be additive. (Received May 25, 1973; )     

Flower-inducing Effect of Benzoic and Salicylic Acids in Various Strains of Lemna paucicostata and L. minor

The flower-inducing activities of benzoic and salicylic acidsadded to the medium differ with the species (Lemna paucicostataand L. minor), and even with the strains used. The type andpH of the medium used, full or 1/10 strength M medium at pH3.8, 4.4 or 5.1, or 1/2 or 1/20 strength NH₄⁺-free Hutner'smedium at pH 5.0, 6.0 or 7.0, also modify their activity. L.paucicostata, strain 151 is the most sensitive of the strainsused to both benzoic and salicylic acids followed by strain381. Such dramatic flowering responses were not obtained withthe other strains, but even strain 321, reportedly insensitiveto benzoic acid, could be induced to flower by adding benzoicacid to a modification of the medium. Benzoic acid is more effectivethan salicylic acid for all strains of L. paucicostata, butthe contrary is true for two L. minor strains tested. A higherpercentage of flowering is obtained in L. paucicostata in 1/2strength NH₄⁺-free Huter'sn medium than in M medium, exceptfor strain 151. When diluted, both media enhance flowering inall L. paucicostata strains. Generally, a lower concentrationof benzoic acid or salicylic acid is enough to induce floweringwhen the pH of the medium is lower. (Received March 30, 1981; Accepted May 16, 1981)     

Obligate Requirement of Salicylic Acid for Short-Day Induction of Flowering in a New Duckweed, Wolffiella hyalina 7378

Wolffiella hyalina 7378, a member of the Lemnaceae, does notflower in the basal media of Bonner-Devirian, Hoagland, Hutner(1/2 strength), M medium of Hillman or Pirson-Seidel under eitherlong or short day photoperiodic regimes. Well-known chelatingagents, such as EDTA, EDDHA and 8-hydroxyquinoline, which havebeen shown to significantly influence flowering in other membersof the Lemnaceae, also do not show any effect in this strain.It is, however, noteworthy that W. hyalina 7378 flowers profuselyunder a short-day photoperiodic schedule of 8 h light and 16h darkness provided that 10^–5 M salicylic acid is supplementedto modified Bonner and Devirian medium. The critical daylengthof W. hyalina 7378 is 13 h. Further, at least two inductivephotocycles are required for initiation of flowering. As tothe mechanism of SA action, it appears that SA effect on floweringis hormonal in nature rather than due to chelation of metalions. (Received August 25, 1986; Accepted January 9, 1987)     

Inhibition of Flowering in the Long-Day Plant Lemna gibba G3 by Hutner's Medium and its Reversal by Medium Modification

The long-day plant Lemna gibba G3 flowers normally in E medium(Hoagland-type medium plus 30 µM EDTA) but in 0.5 H mediumthere is no flowering. Ammonium is present in 0.5 H medium andis known to inhibit flowering in L. gibba G3, but even in NH₄⁺-free0.5 H medium there is virtually no flowering under continuouslight. Increasing the phosphate concentration of the NH₄⁺-free0.5 H medium from 1.15 ITIM to 12 or 16 mM results in substantialflowering. Decreasing the EDTA concentration from 850 µIMto 250 µM, or raising the nitrate concentration from 4mM to 12 mM, results in only a small increase in flowering.If the decrease in EDTA and increase in nitrate are combinedwith the increase in phosphate, however, the flowering responseis nearly as good as that obtained using E medium. Thus, withthese three changes the inhibitory effect of NH₄⁺free 0.5 Hmedium for flowering in L. gibba G3 is almost completely reversed In the above studies flowering was not limited by daylength.When plants were grown on E medium under an 11 hour daylengthwhere flowering is limited by daylength, decreasing the phosphateconcentration in the medium reduced flowering, but increasingthe phosphate concentration in the medium did not stimulateflowering. Thus, when flowering is limited by daylength, highphosphate will not cause flowering, but a certain level of phosphateappears to be necessary for the expression of photoinductionunder long days. (Received January 14, 1986; Accepted June 24, 1986)     

Effects of some metabolic inhibitors on flowering of Lemna gibba G3, a long-day duckweed

Flowering of Lemna gibba G₃, a long-day duckweed, was inhibitedby adding CuSO₄, AgNO₃, HgCl₂, Na₂WO₄ or iodoacetamide to themedium at the concentrations inducing long-day flowering inLemna paucicostata 6746, a short-day duckweed. This suggeststhat these metabolic inhibitors affected the photoperiodic sensitivityrather than directly affecting flower initiation. Ferricyanidepromoted flowering in both of these short-day and long-day duckweeds. (Received July 7, 1977; )     

Flowering of the long-day plant, Lemna gibba, under short-day schedules composed of red and far-red light

Flowering in Lemna gibba, a long-day duckweed, can be inducedunder a short-day condition when the photoperiodic regimes areR₇FR₃ (7 hr red followed by 3 hr far-red), R₅FR₅ and R₃FR₇.This indicates the necessity of a proper balance between redand far-red effects for flowering. The flowering induced bythese regimes is inhibited by a brief exposure to red givenat the start of darkness and this inhibition is reversed bysubsequent exposure to far-red. Thus, the red/far-red reversibleeffect is found only at the beginning of darkness for floweringof L. gibba. However, flowering of L. gibba is promoted by a red light breakgiven near the middle of a 14 hr dark period. The promotiveeffect is not reversed by subsequent exposure to far-red, i.e.,the effect of the red break converts from inhibition to promotionas when given later in the dark period, which suggests the involvementof a timing mechanism. (Received July 21, 1973; )     

Influence of nutrients on the development of gibbosity in fronds of the duckweed Lemna gibba L.

The duckweeds Lemna gibba L. and Lemna minor L. only grew wellin undisturbed culture under axenic conditions in low lightintensity when provided with a suitable energy source such asglucose. In media containing N0₃-N gibbosity (a convex ventralsurface) was induced in the presence of the chelating agentethylene-diamine-di-o-hydroxyphenylacetic acid (EDDHA). In nutrientsolutions containing NO₃-N as the only N source, but withoutEDDHA, L. gibba occasionally exhibited gibbosity in culturesolutions of 40 cm³ volumes. More fronds were induced to exhibitgibbosity when the volume of the culture medium was increasedfrom 40 cm³ to 200 cm³. Gibbosity was never induced in L. minor,neither was it induced in L. gibba in media containing NH₄-N,even in the presence of NO₃-N. There was no direct correlationbetween the occurrence of gibbosity and frond growth rate, butgibbosity occurred only when there was good frond growth. In the absence of a sugar, frond growth was enhanced by bubblingair through the culture solution in the light. Increasing theCO₂ concentration in the air up to 1% enhanced growth and inducedgibbosity. Carbon dioxide did not induce gibbosity in mediacontaining NH₄-N. Key words: Ammonium-N, carbon dioxide, gibbosity, Lemna, nitrate-N     

Flowering and Endogenous Levels of Plant Hormones in Lemna Species

The occurrence and endogenous level of various plant hormoneswere measured for the short-day plants Lemna paucicostata 151and 381 and the long-day plant Lemna gibba G3 to determine whetherany of them are involved in the photoperiodic control of flowering.ABA, IAA, GA₁, GA₂₉, GA₃₄, GA₅₃, trans- and cis-zeatin, trans-and cis-ribosyl zeatin, N⁶-(²-isopentenyl) adenine and N⁶-(²-isopentenyl)adenosine were definitely detected in each species, while GA₄was only detected in L. gibba G3 and GA₂₀ was only detectedin L. paucicostata 151. The endogenous levels of ABA and IAAwere in the range of 1–7 ng/g fr wt and were not significantlydifferent in vegetative and flowering plants. The endogenousgibberellin levels were generally higher in Lemna grown underlong-day rather than short-day conditions. The endogenous cytokininlevels were almost the same in both flowering and vegetativeplants of L. paucicostata 151 and 381. In L. gibba G3, however,the level of cis-ribosyl zeatin, N⁶-(²-isopentenyl) adenineand N⁶-(²-sopentenyl) adenosine were higher in vegetative thanin flowering plants. These results indicate that there is not necessarily a directrelation between endogenous plant hormone levels and flowering,and that the chemical basis for the photoperiodic control offlowering cannot be explained solely by changes in hormone levels.The possibility remains, however, that one or more of the planthormones has some influence of secondary importance on the floweringprocess in Lemna. (Received January 29, 1986; Accepted July 12, 1986)     

Growth and flowering of Lemna paucicostata I. General aspects and role of chelating agents in flowering

Lemna paucicostata HEGELM. is normally a short-day plant andflowers only in the presence of a chelating agent (EDTA or EDDHA)in the medium. The plant can be induced to flower even by asingle long night treatment; the flowering percentage, however,increases with further inductive cycles. The length of the criticaldark period depends upon the chelating agent employed in themedium. It is between 10 and 12 hr in the medium containingEDTA and about 8 hr in the EDDHA-supplemented medium. Red lightinterruption in the middle of the dark period—even fora minute—is inhibitory for flowering. Attempts to identify the metal ion(s) chelated reveal that thechelating agents affect flowering by facilitating iron uptake.This is also supported by the fact that the requirement of achelating agent for flowering can be overcome with an excessof iron in the medium. Interestingly, provision of EDDHA andexcess of ferric citrate, together, can bring about floweringeven under long days. ¹Originally HEGELMAIER (1) designated L. paucicostata as a separatespecies; however, THOMPSON (2) and DAUBS (3) have treated itsynonymous to L. perpusilla. More recently, based on physiologicaland chemotaxonomic studies, the distinctiveness of L. paucicostatafrom L. perpusilla has been favoured (4, 5). (Received September 8, 1969; )     

Phase Shifting Effects in the Photoperiodic Rhythm of Flowering in Dark-Grown Seedlings of Pharbitis nil Choisy

Dark-grown seedlings of Pharbitis nil Choisy received an initialsaturating fluence of red (R) light (R₁), followed at intervalsby further R pulses (R₂ and R₃). R₂ was given at different timesafter R₁. R₂ was used to scan the subsequent 72 h period. The initial exposure to R (R₁) initiated a circadian rhythmin the flowering response to the scanning R exposure (R₂). Thephase of the rhythm was shifted by the second exposure to R(R₂) and the sensitivity of the phase-shifting response variedwith the time of giving the R₂ pulse. The direct response toR₂ (i.e., the magnitude of flowering produced in the absenceof a scanning R₂ exposure) also varied in sensitivity. WhenR² was given 4h after R₁, the phase-shift was achieved by anexposure of 20 s (sufficient to establish 20–25% Pfr/P)but more than 80 s was required to saturate the direct floweringresponse at this time. When given 16 h after R₁, 80 s of R₂(sufficient to establish 55% Pfr/P) was required for the phase-shift,whereas the maximum promotion of flowering was produced by only5 s R. These differences in fluence-response relationships indicatethat the direct flowering response to a dark interruption withR and the effect of such an interruption to phase-shift theunderlying rhythm are distinct processes. (Received April 30, 1986; Accepted November 11, 1986)     

Flowering responses of Lemna perpusilla and L. gibba in relation to nitrate concentration in the culture medium

Flowering responses of Lemna perpusilla strain 6746, a short-dayplant, and L. gibba strain G3, a long-day plant, to nitrateconcentration in Hoagland's type medium with or without EDTA,were compared. Maximum flowering of L. perpusilla under SD occurredat higher nitrate concentrations than did colony proliferation.Even under CL, L. perpusilla grown at sub-optimal nitrate concentrationsfor colony proliferation, flowered irrespective of the presenceof EDTA which reduces flowering. Unlike L. perpusilla, L. gibba failed to flower under SD atany nitrate concentration whether or not EDTA was added. UnderCL, however, L. gibba flowered at almost any nitrate concentrationwith or without EDTA. Double optima for nitrate concentrationwas exhibited in the presence of EDTA; optimal concentrationfor colony proliferation came between the two optima for flowering. We concluded that the nitrogen level of the medium is importantin regulating flowering of duckweeds, and that the effect ofEDTA, if any, may primarily be on colony proliferation and onlysecondarily or antagonistically on flowering. ¹ Present address: Institute for Agricultural Research, TohokuUniversity, Sendai 980, Japan. (Received September 25, 1971; )