Influence of Giving Salicylic Acid for Different Time Periods on Flowering and Growth in the Long-Day Plant Lemna gibba G3

When the long-day plant Lemna gibba L., strain G3 is grown under continuous light on ammonium-free half-strength Hutner's medium (NH₄⁺-free 0.5 H medium) growth is excellent, but flowering is severely inhibited and often is zero. Addition of 10 micromolar salicylic acid (SA) to NH₄⁺-free 0.5 H medium quickly reverses this inhibition and leads to optimal flowering. The SA treatment also leads to a considerable reduction in the growth rate and increase in frond gibbosity. Removal of SA from the medium quickly leads to an increase in the growth rate and a large decrease in flowering. Thus, for maximal effectiveness SA must be present in the medium for the entire experiment, and the effect of SA is clearly not inductive.     

Influence of Temperature on the Flowering of Lemna perpusilla 6746 Grown under Skeleton Photoperiods

The flowering of Lemna perpusilla Torr. strain 6746 grown under 24-hour skeleton photoperiods consisting of 13- and 10.5-hour dark periods separated by 0.25-hr light pulses is strongly dependent on temperature. When plants are cultured in 50-ml Erlenmeyer flasks containing 20 ml of half-strength Hutner's medium supplemented with 1% (w/v) sucrose maximum, per cent, flowering occurs at 23 C. At temperatures above and below 23 C a marked decline in per cent flowering is seen.     

Effect of L-Pipecolic Acid on Flowering in Lemna paucicostata and Lemna gibba

L-Pipecolic acid was found to be effective in inducing floweringof Lemna paucicostata 151, 381, 441 and 6746, and of Lemna gibbaG3. When the plants were grown on half-strength Hutner's medium,L-pipecolic acid caused profuse flowering of L. paucicostata151 maintained under 9 and 10 h of light daily. In L. paucicostata441 and 6746, L-pipecolic acid had a strong flower-promotingeffect under a near critical photoperiod. In L. paucicostata381, by contrast, L-pipecolic acid had only a very small effecton flowering. In L. gibba G3 substantial promotion of floweringwas observed under continuous light. When one-twentieth-strengthHutner's medium was used as the basic medium, L-pipecolic acidstimulated flowering in all strains of Lemna examined, evenunder continuous light. When L. paucicostata 151 was grown on one-tenth-strength M mediumor one-twentieth-strength Hutner's medium, the flower-inducingactivity of L-pipecolic acid was greatly enhanced by cytokininunder continuous light. However, when this strain was grownwith 9 h of illumination daily, this synergistic effect of cytokininwas only slight. A short-term (even 1-h) treatment with L-pipecolicacid resulted in flowering, suggesting that L-pipecolic acidis involved in the induction of flowering, rather than its evocation.D-Pipecolic acid also had flower-inducing activity, but itsactivity was 50 times lower than that of the L-isomer. (Received January 23, 1992; Accepted March 9, 1992)     

Lemna paucicostata Hegelm. 6746: DEVELOPMENT OF STANDARDIZED GROWTH CONDITIONS SUITABLE FOR BIOCHEMICAL EXPERIMENTATION

Photoautotrophic and mixotrophic growth of Lemna paucicostata Hegelm. 6746 (formerly Lemna perpusilla Torr. 6746) was investigated to establish standardized conditions for biochemical studies. Optimal temperature for growth was 29 to 30 C. The medium used previously (Datko AH, Mudd SH, Giovanelli J 1977 J Biol Chem 252: 3436-3445) was modified by inclusion of NH₄Cl, decreasing macronutrient and ethylenediamine tetraacetate concentration, increasing micronutrient concentration, and inclusion of bicarbonate (for photoautotrophic growth) or 2-(N-morpholino)ethanesulfonic acid (for mixotrophic growth) buffers. Varying the sulfate concentration between 14 and 1 millimolar had no effect on growth. For photoautotrophic growth in the new medium (medium 4), the effects of CO₂ concentration, light intensity, and pH were measured. Under the optimal conditions, a multiplication rate (MR) of 300 to 315, equivalent to a doubling time of 23 to 24 hours was obtained. Addition of glutamine or asparagine did not increase this MR. For mixotrophic growth in low light, the effects of sucrose concentration and pH were determined. Under optimal conditions, MR was 210. A concentration of sucrose less than maximal for growth was chosen for the medium for experiments which will include ¹⁴C-labeling of intermediates. MR under these conditions was 184. Growth was equally good in medium 4 and in half-strength Hutner's medium when sulfate was high (0.4 to 1 millimolar), but better in medium 4 when sulfate was low (20 micromolar). Growth rates could be restored to normal in half-strength Hutner's with low sulfate by decreasing the molybdate concentration.     

Influence of Ammonium on the Ability of Salicylic Acid to Induce Flowering in the Short-Day Plant Lemna paucicostata 6746

When the short-day plant Lemna paucicostata 6746 is grown inhalf-strength Hutner's medium, which contains 1.25 mM NH4NO3,salicylic acid does not induce flowering on daylengths of 16hr or longer. By contrast, in M (Hoagland-type medium), Pirson-Seidelor ammonium-free half-strength Hutner's media, none of whichcontain ammonium, salicylic acid is able to induce some floweringeven under continuous light. Neverthless, in each of these threemedia the effect of salicylic acid is strongly daylength dependentbecause there is a sharp drop in the flowering response to salicylicacid between the 12 and 16 hr daylengths, and the floweringresponse is nearly constant from the 16 hr daylength to continuouslight. Ammonium has the opposite effect and at 50 to 75 µMis able to overcome the salicylic acid effect completely andprevent any flowering on daylength of 16 hr or longer. (Received December 3, 1980; Accepted March 5, 1981)     

Inhibitory Effect of Carbohydrate on Flowering in Lemna perpusilla. I. Interaction of Sucrose With Calcium and Phosphate Ions

Flowering in Lemna perpusilla 6746 grown on tenth-strength Hutner's medium under short days was inhibited by 30 mM sucrose, glucose or fructose, but not by mannitol. The inhibition by sucrose does not appear to be due to sucrose-induced acidification of the medium during growth, or to trace metal contaminants of the sugar. Inhibition was partially prevented by raising either Ca²⁺ or phosphate to levels used in half-strength medium. Possible mechanisms for these effects are discussed.     

Changes in the content of endogenous auxins in apical buds ofchenopodium rubrum L. Induced with respect to the endogenous rhythm in capacity to flower

The content of endogenous auxins was examined in apical buds ofChenopodium rubrum plants induced by a photoperiodic cycle of 16h darkness and 8h light followed by a dark period of various duration so as to correspond with either maximal or minimal flowering response in the endogenous rhythm in capacity to flower initiated by the photoperiodic treatment. Apical buds of potentially generative plants contained less auxins than apical buds of plants which remained in the vegetative state. Apical buds from plants treated with kinetin (1. 10^-3 M) and therefore remaining in the vegetative state showed an auxin level comparable to that of untreated plants exhibiting minimal flowering response irrespective of the duration of the second dark period. Plants cultivated on a sucrose solution (0.6 M) during the second dark period became generative even at the normal minimum of flowering. The auxin content of the apical buds was low, similarly as in untreated plants induced for a period leading to maximal flowering response. On the other hand, apical buds from plants grown on sucrose solution during a dark period leading to the manifestation of maximal flowering response showed a relatively high auxin content comparable to that found in untreated plants which had obtained a more extended induction by three photoperiodic cycles. The results are discussed with respect to the possible role of endogenous auxins in the regulation of the changes in growth correlations occurring in the shoot apex during photoperiodic induction and in the expression of the competence to flower.     

Flowering of Cultivated Green and SAN 9789-Treated Chenopodium rubrum Plants Exposed to White,Blue, and Red Light

Green plants and plants devoid of photosynthetic pigments were compared with regard to their ability to flower under various growth conditions. Green plants of Chenopodium rubrum L. and plants treated with norflurazon SANDOZ-9789 (SAN) were grown on sucrose-containing media with or without hormones (GA₃, BA, IAA, ABA) under short-day photoperiodic or continuous illumination with white, blue, or red light. Green and SAN-treated albino plants produced flowers only under short-day conditions. The flowering of green plants was independent of the presence of sucrose and hormones in the medium as well as of the light quality. The albino plants produced flowers under white and blue light but did not flower in red light. The addition of GA₃ or BA to the medium induced flowering of albino plants exposed to red light. The functional interaction of photoreceptors in the flowering control is discussed.     

The Influence of Nicotinic Acid and Plant Hormones on Flowering in Lemna

Nicotinic acid induces flowering in Lemna paucicostata 151 and381 and Lemna gibba G3 when they are grown in one tenth-strengthM medium under continuous light. For L. paucicostata 151 and381, the simultaneous addition of IAA, GA₃ or ABA to the mediumleads to an inhibition of the flower-inducing effect of nicotinicacid, while zeatin leads to a further stimulation of floweringabove that obtained by nicotinic acid alone. By contrast, inL. gibba G3 all four plant hormones inhibit the nicotinic acid-inducedstimulation of flowering. The effect of nicotinic acid on flowering in all three plantsis strongly daylength dependent when the plants are grown inhalf-strength Hutner's medium. Thus, nicotinic acid causes floweringin L. gibba G3 on continuous light but not on 9L:15D or 10L:14Dregimes. In L. paucicostata 381 nicotinic acid has a small effecton 12L:12D regime, a large effect on a 13L:11D regime and noeffect with daylengths longer than 14 hours, and in L. paucicostata151 nicotinic acid is only effective on daylengths shorter thanabout 11 hours. However, in L. paucicostata 151 and 381 treatmentwith both nicotinic acid and zeatin results in flowering undercontinuous light on half-strength Hutner's medium. Nicotinic acid is present in different Lemna but its concentrationdoes not appear to be influenced by changes in daylength. Thus,flowering clearly cannot be controlled by nicotinic acid actingalone, but the results of this study indicate that nicotinicacid could interact with other factors, possibly including oneor more of the known plant hormones, to influence the floweringprocess in Lemna. (Received August 28, 1985; Accepted October 29, 1985)     

Uptake and Metabolism of [C]Salicylic Acid in Lemna gibba G3

When the long-day plant Lemna gibba L., strain G3 is grown under continuous light on ammonium-free half-strength Hutner's medium (NH₄⁺-free 0.5 H medium) there is virtually no flowering, but addition of 10 micromolar salicylic acid (SA) to the medium results in substantial flowering. Using this system, the uptake and metabolism of [¹⁴C]SA in L. gibba G3 has been examined. SA uptake is rapid and linear for at least the first 24 hours. After 30 minutes, nearly 90% of the radioactivity in the plants is present as free SA. Part of this is rapidly converted to one or more bound forms of SA that appear either in the acidic butanol fraction or in the aqueous residue, and after 12 hours an equilibrium is reached between the free and bound forms of SA. When plants receive SA for 6 days and then are switched to control medium, both the free and bound SA remain nearly constant for at least 5 days. However, there is virtually no transfer of SA from mother fronds to daughter fronds, indicating that the SA is apparently sequestered within the cell. Cell fractionation studies show that nearly 95% of the SA remains in the supernatant even after a 2-hour centrifugation at 300,000 g. Thus, it is unlikely that SA is confined within a specific organelle, but rather is probably secreted into the vacuole.     

Factors Affecting the Water-sensitive Phase of Flowering in the Short Day Plant Lemna perpusilla

The flowering of Lemna perpusilla strain 6746 is inhibited by daily transfers to water for short periods during a sensitive phase. Supplementing the water with Ca(NO₃)₂ partially reverses the inhibition of flowering while MgSO₄ increases the inhibition. The inhibition by MgSO₄ is overcome by low concentrations of Ca(NO₃)₂. Flower-promoting activity was detected in water and in MgSO₄ solutions that had been incubated with plants under dark but not light conditions. The prevention of this effect by light appears to be photosynthetic rather than to depend on phytochrome. The activity is destroyed by autoclaving but not by brief boiling. This loss of a flower-promoting material may explain the inhibiting effect on flowering by transfers to water.     

Inhibition of flowering in the long-day plant Lemna gibba G3 by Hutner's medium and its reversal by salicylic acid

Flowering in the long-day plant Lemna gibba L., strain G3 ispoor or absent in Hutner's medium even under continuous light,an effect generally ascribed to the ammonium content of themedium. However, flowering is also inhibited in ammonium-freemodifications of Hutner's medium, particularly in the presenceof sucrose, but is restored to high levels by the presence of10 µu salicylic acid. These results link two of the leastunderstood chemical effects in Lemnaceae flowering, and theyprovide a system in which large effects of salicylic acid canbe readily obtained. ²Present address: Lab. of Applied Bot., Fac. of Agric, KyotoUniv., Kyoto 606, Japan. (Received January 27, 1979; )     

Inhibitory Effect of Carbohydrate on Flowering in Lemna perpusilla: II. Reversal by Glycine and l-Aspartate. Correlation with Reduced Levels of beta-Carotene and Chlorophyll

Flowering of Lemna perpusilla strain 6746 grown on 0.1 strength Hutner's medium in short days was inhibited by sucrose, glucose, fructose, and mannose, but not by various other sugars or metabolic intermediates. Only those sugars that inhibited flowering supported heterotrophic growth. Experiments with a single inductive long night indicated that an early stage in flowering was the sugar-sensitive process. Inhibition of flowering by carbohydrates was accompanied by reduced levels of chlorophyll and β-carotene. The inhibitory effects of carbohydrates on flowering were partially reversed by iminodiacetate, glycine, and l-aspartate but not by d-aspartate, ethylenediaminetetraacetate, acetate, δ-aminolevulinic acid, or mevalonic acid. The possibility is discussed that carbohydrate repression of flowering and of chloroplast pigments resulted from inadequate levels of amino acids.     

TEMPORAL COMPARTMENTATION IN LEMNA PAUCICOSTATA: PHOTOPERIODISM,RESPIRATION, NITROGEN NUTRITION AND HETEROTROPHIC GROWTH OF DIFFERENT STRAINS

In previous work with strain 6746 of Lemna paucicostata Hegelm. in heterotrophic culture, changes in the light schedule affected certain features of the daily respiratory pattern, on some but not all nitrogen sources, in a manner parallelling their effects on timing in the photoperiodic flowering response. Seeking further guidance on which metabolic processes should be investigated to understand this relationship, twelve additional strains were compared with 6746 in regard to 1) heterotrophic flowering under short-day skeleton photoperiods, and 2) daily respiratory patterns under 0.25 hr daily of dim red light. Heterotrophic flowering occurred in eight strains; among these, several differed sharply from 6746 in the character of their respiratory patterns and the probable relation of those patterns to photoperiodic timing. For example, in 6746, the second daily peak on NO₃, NH₄ and probably on glutamine reflects photoperiodic timing; the patterns on N-deficient, aspartate and glutamate media do not. In strains 6609 and 381, in contrast, glutamate also elicits a second peak probably reflective of photoperiodic timing; in strain 421, neither the NO₃ nor NH₄ patterns resemble those reflecting photoperiodic timing in 6746. Other strain differences in flowering, respiratory patterns and heterotrophic growth provide useful material for studying phytochrome action, N assimilation and respiration, and they confirm the view that strain identity may be crucial in biochemical investigations on Lemnaceae. These results also reinforce the concept that the “temporal compartmentation” of systems entrained to light/dark cycles can provide important insights, and should be more widely used, in work on regulation of plant metabolism.     

In vitro flowering of Fortunella hindsii (Champ.)

Branch internodes of mature plants and stem internodes of seedlings of Fortunella hindsii flowered in vitro on half-strength MT (Murashige and Tucker 1969) basal medium supplemented with benzyladenine, adenine, 6---dimethylallylaminopurine and kinetin. The highest percentage of flowering was achieved with explants originating from branch internodes of flowering plants close to the apex on half-strength MT basal medium containing 5% sucrose and 0.01 mg 1^–1 BA in light. Exposure to darkness for more than 3 weeks followed by re-exposure to light reduced flowering. Flowering required a 4-day exposure to BA, but shoot formation could be initiated even without exposure to BA. First branch internode segments on MT basal medium containing 5% sucrose were prolific in flower (85%) production. The sucrose treatment affected the flower bud size distribution. There were about 13 flower buds per culture in the largest size category (>5 mm).     

Dark induction of nitrate reductase in the halophilic alga Dunaliella salina

The effect of nitrogen starvation on the NO₃-dependent induction of nitrate reductase (NR) and nitrite reductases (NIR) has been investigated in the halophilic alga Dunaliella salina. When D. salina cells previously grown in a medium with NH ₄ ⁺ as the only nitrogen source (NH ₄ ⁺ -cells) were transferred into NO ₃ ^? medium, NR was induced in the light. In contrast, when cells previously grown in N-free medium were transferred into a medium containing NO ₃ ^? , NR was induced in light or in darkness. Nitrate-dependent NR induction, in darkness, in D. salina cells previously grown at a photon flux density of 500 umol · m^?2 s^?1 was observed after 4 h preculture in N-free medium, whilst in cells grown at 100 umol · m^?2 s^?1 NR induction was observed after 7–8 h. An inhibitor of mRNA synthesis (6-methylpurine) did not inhibit NO ₃ ^? -induced NR synthesis when the cells, previously grown in NH ₄ ⁺ medium, were transferred into NO ₃ ^? medium (at time 0 h) after 4-h-N starvation. However, when 6-methylpurine was added simultaneously with the transfer of the cells from NH ₄ ⁺ to NO ₃ ^? medium (at time 0 h), NO ₃ ^? induced NR synthesis was completely inhibited. The activity of NIR decreased in N-starved cells and the addition of NO ₃ ^? to those cells greatly stimulated NIR activity in the light. The ability to induce NR in darkness was observed when glutamine synthetase activity reached its maximal level during N starvation. Although cells grown in NO ₃ ^? medium exhibited high NR activity, only 0.33% of the total NR was found in intact chloroplasts. We suggest that the ability, to induce NR in darkness is dependent on the level of N starvation, and that NR in D. salina is located in the cytosol. Light seems to play an indirect regulatory role on NO ₃ ^? uptake and NR induction due to the expression of NR and NO ₃ ^? -transporter mRNAs.     

Effects of diurnal and bidiurnal photoperiodic treatments on mitosis in Pharbitis

Abstract

Photoperiodic effect on mitotic activity of buds from dwarf Pharbitis has been analyzed. No significant differences in mitotic activity were found in plants grown under long days or diurnal (24 h) light break photoperiodic treatments. Differences in both mitotic activity and flowering were seen in plants subjected to diurnal short days, bidiurnal (48 h) short days, or bidiurnal short days with light breaks. An elevation of mitotic activity occurs in plants grown in bidiurnal photoperiodic treatments compared to diurnal treatments. The differences in mitotic activity of buds, both vegetative and floral, seem to indicate that both phytochrome and light effect on an endogenous rhythm influence meristematic activity. Also, the extended dark period of a bidiurnal short day enhances both mitosis and flowering.     

Further studies on the flowering ofLemna paucicostata in Japan

Flowering behavior of 22 strains ofLemna paucicostata collected in Japan by Yukawa and Takimoto (1976) was re-examined. The critical dark periods of the short-day strains (N-1 and N-2 types) were shorter than those determined by Yukawa and Takimoto except for that of one strain. Particularly in strains 391, 381 and 321, the differences were as large as 2.25, 1.75 and 1.5 hr, respectively. Such differences were found to be due at least partly to the difference in night temperature; 25 C for the light and 23 C for the dark periods in the present experiment, and 25 C throughout the light and dark periods in the previous experiment. The S type strains did not flower under our experimental conditions (fluorescent light of 6,000 lux at 25 C) at any photoperiod tested, but flowered as a quantitative long-day plant under natural daylight or high-intensity light (12,000 lux). Addition of sucrose or ammonium ion to the medium suppressed the flowering of these strains under high-intensity light. Addition of benzoic acid (1–5 μM) to 0.5 strength NH₄ ⁺-free Hutner's medium caused daylength-independent flowering in some N-1 type strains and in all N-2 type strains tested. S type strains cultured under fluorescent light of 6,000 lux also flowered rapidly in response to benzoic acid.     

Effects of Ferrous and Phosphate Ions on Flowering in Lemna paucicostata 6746 in Diluted Hutner's Medium

In Lemna paucicostata 6746, P₂ (flower induction period) incontinuous darkness was largely extended by dilution of 1/2H1S medium (Hutner's medium supplemented with 1% sucrose) to1/10 strength. The dilution of 1/2 H1S medium to 1/10 strengthremoved completely the extension of P₁ (pre-flower inductionperiod) and P₂ due to a red light pulse given at the 7th h ofthe dark period, which was observed in 1/2 H1S medium. When iron and phosphate ions were added to 1/10 H1S medium upto the same concentration as in 1/2 H1S medium, the extensionof P₂ was removed completely. The red light pulse-induced extensionof P₁ was observed in 1/10 H1S medium only when iron ions wereadded. It is suggested that iron (Fe^{$ $}) and phosphate ionsare important in determining the rate of photoperiodic flowerinduction in L. paucicostata 6746. (Received December 23, 1983; Accepted June 6, 1984)     

Floral Induction in a Photoperiodically Insensitive Duckweed, Lemna paucicostata LP6 : Role of Glutamate, Aspartate, and Other Amino Acids and Amides

The effects of 20 amino acids and two amides were studied on the flowering of a photoperiodically insensitive duckweed, Lemna paucicostata LP6. Alanine, asparagine, aspartate, cystine, glutamate, glutamine, glycine, lysine, methionine, proline, serine, and threonine induced flowering under a photoperiodic regime of 16 hours light and 8 hours darkness. Among these, glutamate and aspartate were found to be the most effective for flower induction. These acids could initiate flowering even at 5 × 10⁻⁷ molar level, though maximal flowering (about 80%) was obtained at 10⁻⁵ molar. Change in the photoperiodic schedule or the pH of the nutrient medium did not influence glutamate- or aspartate-induced flowering. The low concentrations at which glutamate and aspartate are effective suggests that they may have a regulatory role rather than simply acting as metabolites.