Short-day flowering of Lemna gibba G3 induced by salicylic acid

Salicylic acid, probably as a chelating agent of the EDTA-salicylaldoximetype, can eliminate the light requirement during the inductivephase of Lemna gibba G3, and thus is able to induce short-dayflowering of this long-day plant. (Received September 4, 1975; )     

Comparison of the flowering behavior of the long-day plant Lemna gibba G3 from different laboratories

In an effort to determine the cause for the wide discrepanciesin the level of flowering response reported for the long-dayplant Lemna gibba L., strain G3, cultures of L. gibba G3 wereobtained from the laboratories of W. S. Hillman (G3-H), R. Kandeler(G3-K), Y. Oota (G3-O) and and A. Pieterse (G3-P) and comparedto the L. gibba G3 (G3-C) from this laboratory. Under continuouslight all cultures gave FL% values of 77 or above, and on a9L:15D short-day treatment, all cultures were completely vegetative.However, on daylengths of 10 to 12 hr, small but statisticallysignificant differences were obtained for the different cultures.The critical daylength curves for G3-G, which showed the shortestcritical daylength, and G3-K, which showed the longest criticaldaylength, differed by approximately one hour. Salicylic acidtreatment caused flower promotion in each culture, but statisticallysignificant differences were obtained between some of the culturesin their response to salicylic acid. It is concluded that the large discrepancies in the floweringresponses of L. gibba G3 that have been reported are due primarilyto differences in culturing methods and counting proceduresin the different laboratories. However, the results also indicatethat there may be distinct cultures of L. gibba G3 that exhibitsmall physiological and/or genetic differences that would makeprecise quantitative comparison between different laboratoriesvery difficult. (Received January 23, 1979; )     

Photoperiodic requirements for flowering of the long-day duckweed, Lemna gibba G3

The min-LD estimation by the log. flower number vs. the cultureperiod curve provides a unique method of judging whether a givenphotoperiodic schedule is a long day or not for Lemna gibbaG3. Duckweeds in M-sucrose medium are exposed to the test scheduleat 26°C on either the first or second day of a continuouslight culture. If the min-LD (48 hr for control cultures) isnot changed, the inserted schedule is considered to have functionedas a long day. If, however, the min-LD is extended by 24 hr,the inserted schedule is judged to have functioned as a shortday. Examinations using this method of orderly designed light-darkschedules disclosed two critical phases in the light requirement;the initial and terminal 1 hr portions (designated the L1- andL2-phases) of the subjective day. Thus, a given day became along or short day when both the L1- and L2-phases were illuminatedor when either or both of the two phases were darkened. Thecritical daylength (11.5 hr) was just long enough to cover boththe L1- and L2-phases and the inductive phase (L2-phase) waslocated at the end of the subjective day. (Received June 9, 1975; )     

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)     

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; )     

Induction of flowering in Lemna gibba G 3 by Fe-EDDHA

Fe-EDDHA (iron salt of ethylenediamine-di-o-hydroxyphenylaceticacid) induced profuse flowering in Lemna gibba G 3 culturedin HUTNER'S medium. The maximum number of flowering plants wasobserved in a medium supplemented with 5 ppm of this chelate. (Received April 20, 1970; )     

Uptake of uridine by a long-day duckweed, Lemna gibba G3

Uptake of uridine by a long-day duckweed, Lemna gibba G₃ wasexamined. Km and Vmax for uptake were in the range of 1 to 2x10^–5 M and of 5 to 10 x10^–8 moles/g fresh weight/2hr, respectively. Uptake rate depended on temperature, and theoptimum pH was 5.0. Uridine uptake was competitively inhibitedby some compounds structurally analogous to uridine. However,the activity of uridine kinase was not affected by these compounds,except for cytidine. Uridine uptake was inhibited by metabolicinhibitors, in which uridine taken up was left unconverted toother forms, especially in the presence of DNP. These resultssuggest that uridine was taken up into the duckweed celb bya specific transport system and immediately phosphorylated byuridine kinase. Phosphorylation of uridine was not associatedwith the uridine transport reaction. (Received November 15, 1976; )     

Chemical control of flowering in the long-day plantLemna gibba G3

Lemna gibba G3 is an ideal system for studying the chemical control of flowering in a photoperiodic plant due to its small size and aquatic growth habit which allow substances to be taken up continuously and rapidly distributed throughout the plant. Each of the known plant growth regulators has been tested onL. gibba G3 and only the gibberellins appear to be important for flowering, although they are not the limiting factor for flowering on short days. Salicylic acid (SA) and ferricyanide will both induce flowering inL. gibba G3 with ferricyanide being most effective on short days where flowering is daylength limited and SA most effective where flowering is limited by factors other than daylength. The ferricyanide action is probably due to HCN and it may act during photoperception or photoinduction. SA is most effective when reversing the inhibition caused by various parameters including copper and agar, and its effect is always strongly daylength dependent. It is postulated that SA may interact with the flowering stimulus to promote flowering and thus that SA acts at some point following photoinduction and the formation of the flowering stimulus.     

The relationship between red and far-red light on flowering of the long-day plant, Lemna gibba

Lemna gibba, a long-day duckweed, can be induced to flower whenthe 10 hr white photoperiod is extended with red or far-redlight. The 10 hr red photoperiod is also effective in inducingflowering when followed by a far-red extension, but a red extensionis ineffective. When 2 hr of far-red light are given immediately after the 10hr red photoperiod, the following red as well as the far-redextension can induce flowering, indicating that the 2 hr far-redlight plays an important role as a starting factor for induction.This red or far-red extension is effectively replaced by a redbreak given at a proper time in the darkness which follows the2 hr far-red light as the starting factor. The effect of thered break in not cancelled by subsequent exposure to far-red,which synergistically promotes flowering. However, a red break given immediately after a proper periodof far-red extension further promotes flowering. The phase sensitiveto the red break coincides with that sensitive to the red breakgiven in darkness. The effect of the red break is reversed bysubsequent exposure to far-red, contrary to the effect of thered break in darkness. Using these results, relation between red and far-red lighton flowering in L. gibba is discussed. (Received July 17, 1971; )     

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; )     

Reversal of the dark inhibition of flowering in a long-day duckweed, Lemna gibba G3, by thymidine and related nucleosides

Effects of several nucleosides on flowering in Lemna gibba G3inhibited by darkness inserted just before an inductive lightperiod were investigated. Thymidine and deoxyuridine could reversethe inhibition, but deoxycytidine, cytidine, uridine, thymineand deoxyribose could not. Since interruption of die darknesswith a brief light period was effective similarly to additionof thymidine and deoxyuridine, the light-stimulated step inthymidine biosynthesis is probably the reaction of deoxyuridinesynthesis. Furthermore, maintenance of thymidine content isprobably required for the progress of floral induction. (Received March 29, 1973; )     

Induction of flowering in Lemna gibba G3 under short-day conditions

In the presence of the chelating agent EDDHA, long-day duckweedLemna gibba G3 was induced to flower under a short-day scheduleof 9 hr of light and 15 hr of darkness in a 24-hr cycle. Weconcluded that EDDHA creates effects very similar to those ofsalicylic acid. When EDDHA or salicylic acid was added to thenutrient medium in combination with BA, flowering was inducedeven under conditions of 8 hr of light and 16 hr of darkness.Under a photoperiod of 9 hr, BA markedly enhanced the effectof EDDHA as well as salicylic acid. On the other hand, BA alonewas ineffective as far as flowering was concerned. By quantitativeinteractions, BA seems to complement the modifying effect ofEDDHA or salicylic acid on flowering in this duckweed strain. (Received June 25, 1976; )     

Removal of the sugar inhibition of flowering in Lemna gibba G3 by catecholamines

DL-Epinephrine (10^–8–10^–7 M), DL-norepinephrine(10⁶ M) and DL-isoproterenol (10^–8–10^–6 M)alleviated floral inhibition due to 1% of sucrose, in Lemnagibba G3. The induction period extended by sucrose was curtailedby epinephrine, frond multiplication enhanced by the sugar beingleft unaltered. The pattern of action of catecholamines appearedto be very similar to that of cAMP. DL-Epinephrine, however,was ineffective in the presence of 10^–7 M DL-propranololwhich affected neither flower nor frond production by itself.Quabain and nicotinic acid also nullified the epinephrine actionon duckweed flowering. These and other relevant findings supportthe hypothesis that the cAMP-adenyl cyclase system participatesin the processes of flower induction in this long-day plant. (Received August 21, 1973; )     

Endogenous light-on rhythm in respiration of a long-day duckweed, Lemna gibba G3

1. The rate of O₂-uptake of Lemna gibba G₃ changed with a dampeddiurnal rhythm under continuous illumination given after shortdays. The rhythm was started by a light-on stimulus with a 6hr lag period and is thought to be under the control of a biologicalclock. 2. The 6 hr lag period was replaceable with a 6 hr dark periodinterrupted twice (at 0 and 3 hr) by a brief illumination withred light. The effect of red light was removed by immediateexposure to far-red light. This effect of far-red was reversedby subsequent red light. The 6 hr lag may involve a phytochrome-mediatedreaction which may be preparatory to the induction of this rhythm. (Received December 13, 1969; )     

Spectral dependence of the critical photoperiod in the long-day duckweed, Lemna gibba G3

Spectral dependence of the light sensitive L1- and L2-phasesof the critical photoperiod of Lemna gibba G3 was examined bythe min-LD method for wavelengths ranging from ca. 420 to 800nm. The L1-phase had a sharp peak of sensitivity at 650–680nm and a gentle slope of sensitivity ascending from 500 nm towardshorter wavelengths. The L2-phase showed remarkable sensitivityaround 750 nm and in the blue-violet regions (500 nm). Red/far-redphotoreversibility was confirmed for the LI-phase, but not forthe L2-phase. The properties of the light receptors involvedare discussed briefly. ¹Present address: National Institute for Basic Biology, Myodaiji,Okazaki 444, Japan. (Received May 14, 1979; )     

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; )     

Effect of light on the metabolism of thymidine in the long-day duckweed, Lemna gibba G3

Metabolism patterns of exogenous thymidine as disclosed by ECTEOLAcellulose column chromatography, were examined with a long-dayduckweed, Lemna gibba G3, under dark and light conditions. Whenthymidine-6-³H was applied, the pattern of thymidine metabolismin the light was not very different from that in the dark. However,when thymidine (methyl-³H) was used, incorporation of radioactivityinto two major ( and ß) and one minor components ofboth B and D fractions separated by column chromatography, wasstrikingly stimulated by the light, through photosynthetic activity.Component a of fraction B was tentatively concluded to be ß-ureidoisobutyricacid by paper chromatography. As the radioactivity from thymidine-6-³Hwas hardly recovered in the a component of fraction D, the partof the thymidine molecule incorporated into this component wasnot the pyrimidine ring, but a methyl residue. (Received March 29, 1973; )     

On the rhythm of sensitivity to light interruption in a long-day duckweed, Lemna gibba G 3

1. The rhythm of sensitivity to light interruption in a long-dayduckweed, Lemna gibba G 3, was examined. The rhythm was circadianand was suggested to be under the control of a physiologicalclock. Light given in the trough between the first and secondpeaks reset the rhythm. Five to 7 cycles of non-circadian photoperiodicregimes given entrained the rhythm to external periodicity,and this entrained rhythm persisted even after the plants weretransferred to continuous darkness. 2. It was suggested that the induction period is not determinedby the physiological clock disclosed here, but by a periodicalternation of dark-sensitivity, or by a periodic change inactivity of SS (system sensitive to IPEF, induction period extendingfactor,) as postulated previously. (Received November 28, 1967; )     

Diurnal change of light-dependent uridine incorporation into RNA in a long-day duckweed, Lemna gibba G3

Light-dependent incorporation during subjective day and nightof radioactive uridine into RNA of a long-day duckweed, Lemmagibba G3, was examined. When the dark treatment was startedfrom the subjective night phase, the activity of uridine incorporationdropped approximately by half only after the very subjectivenight phase had passed or with the commencement of the subsequentsubjective day phase. However, when the dark treatment was startedfrom the subjective day phase, the incorporating activity promptlybegan to decrease and the inhibition increased with the lengthof the dark period until a final steady level (also at ca. 50%of the initial level) was reached after 24 hr of darkness. Thesetwo phases of different light sensitivities recurred daily undercontrol of the physiological clock and the rhythm was resetby a light-on signal. The lowered incorporating activity dueto the darkened day phase was recovered completely by a 12-hror even 15-min white light period perturbing the succeedingnight phase. That the incorporation of uridine in every RNAspecies, especially in chloroplast ribosomal RNA, was loweredby dark treatment of the day and night phases, was disclosedby MAK column chromatography and acrylamide gel electrophoresis. (Received August 21, 1974; )     

Maintenance of high Pfr-level in the dark period in relation to flowering in Lemna gibba G3

The relative Pfr-level in a long-day duckweed, Lemna gibba G3,was estimated by the null response method. The null % R value(% R in a R/FR-mixture that provides a null flowering response.This value was assumed to indicate the endogenous Pfr-levelof the duckweed.) remained high during the initial hours ofthe 15 hr nyctoperiod then decreased rapidly, if a 12 or 33hr photoperiod preceded the nyctoperiod. The null % R valuedropped immediately after the start of the 15 hr nyctoperiodsubsequent to a 1 or 24 hr photoperiod. Thus, the duration ofthe maintenance of a high Pfr-level changed rhythmically dependingon the length of the preceding photoperiod. Nyctoperiods ofup to 9 hr following a 12 hr photoperiod hardly affected flowering,but nyctoperiods given after a 24 hr photoperiod suppressedflowering in proportion to the length of the period. The Pfr-levelin the nyctoperiod, therefore, seems to be important for flowering,and phytochrome change, as a function of the length of photoperiod,may serve as a photoperiodic timer. Although floral responseto interruption with R or FR changed with the application period,the difference in response between R-treated and FR-treatedplants was relatively constant during a 15 hr nyctoperiod combinedwith a photoperiod of any length other than 1 hr. Apparently,the floral response to the R or FR pulse was regulated by ashift in the Pfr-level caused by the light pulse. (Received April 2, 1979; )