Biosynthesis and Metabolism of NAD in Lemna paucicostata 151

We have already reported that NiA and related compounds had plant-growth-promoting and flower-inducing activities in duckweed, Lemna paucicostata 151. These effects may be concerned with the biosynthesis and metabolism of NAD. So, for the first step, the various enzyme activities related to them were investigated in this study to obtain some fundamental information on the action mechanism of these compounds and metabolites. Extremely high enzyme activity of nicotinamidase and very high enzyme activity of N AD glycohydrolase were found. The enzyme activities of nicotinate phosphoribo- syltransferase, quinolinate phosphoribosyltransferase, and nicotinate methyltransferase were easily detected. In contrast, nicotinamide phosphoribosyltransferase and ADP-ribosyltransferase activities were very low and nicotinamide methyltransferase activity was not detectable. NiA and NAm administered to the plant were rapidly incorporated into N AD and metabolized to several compounds. Postulation of the action mechanism is discussed.     

Flowering Induced by Nitrogen Deficiency in Lemna paucicostata 151

Lemna paucicostata 151 is a weakly responsive short-day plantwhen grown in non-aseptic ten-fold diluted E medium supplementedwith 1 µM 6-benzyladenine, but it flowered even underlong-day conditions (continuous light) when grown in this mediumfor more than 14 days. On the 14th day of culture, the levelof endogenous nitrogen in the plants decreased to about 60%of that in the plants inoculated at the start of the culture.The flowering obtained under long-day conditions was suppressedby raising the concentration of nitrogen in the medium, whileit was induced more rapidly by lowering the concentration ofnitrogen in the medium. Benzyladenine did not cause floweringby itself, but it was required for the flowering that was inducedby a reduction in the level of nitrogen in the medium. Thus,the flowering observed under long-day conditions is due to nitrogendeficiency in the plants. Two inhibitors of proteases, bestatin and elastatinal, clearlyinhibited the flowering induced by nitrogen deficiency. It appears,therefore, that the induction or activation of some protease(s)is involved in the flowering that is induced by nitrogen deficiency. (Received March 19, 1991; Accepted August 16, 1991)     

Isolation and Identification of Lutein from Lemna paucicostata 381 as an Inhibitor of Benzoic Acid-induced Flowering in Lemna paucicostata 151

Efforts were made to isolate flower-inhibitory substances from extracts of the short-day plant Lemna paucicostata 381. Lemna paucicostata 151, which was used in the bioassay, exhibits poor flowering in response to the photoperiod, but flowers profusely in response to benzoic acid. Therefore, only those substances that inhibit benzoic acid-induced flowering were studied. Several fractions obtained by silica gel column chromatography exhibited flower-inhibitory activity when tested on L. paucicostata 151. After several purification steps, one of the active principles was identified as lutein by MS, UV and NMR spectroscopic analyses. Lutein and its isomer zeaxanthin inhibited benzoic acid-induced flowering in both L. paucicostata 151 and 381.     

Conversion of Lysine to L-Pipecolic Acid Induces Flowering in Lemna paucicostata 151

The natural occurrence of L-pipecolic acid and conversion oflysine to L-pipecolic acid in Lemna paucicostata 151 were demonstrateddefinitively by GC-MS. The strong flower-inducing activity ofL-pipecolic acid has already been demonstrated. Thus, the presentstudy indicates that the effect of lysine on flowering is mediatedby L-pipecolic acid. (Received June 30, 1997; Accepted August 22, 1997)     

Flower-Inducing Activity of Lysine in Lemna paucicostata 151 Cultured on Nitrogen-Deficient Medium

Lemna paucicostata 151, a weakly responsive short-day plant,flowers even under continuous illumination when cultured onnitrogen-free medium for more than 72 hours with subsequentculture on nitrogen-rich medium. During the nitrogen-free culture,the protease activity and protein content of the plant increasedand decreased, respectively. The plant contained a protein(s)that induced flowering of the plant when added to the medium.The level of this protein(s) also decreased during the nitrogen-freeculture. The total amount of free amino acids in plants culturedon nitrogen-free medium for 96 hours decreased to about 15%of that in plants at the start of nitrogen-free culture, butlevels of some amino acids increased. These amino acids wereexamined for their effects on flowering of plants cultured onnitrogen-deficient or nitrogen-free medium. Most of the aminoacids had no effect on flowering. However, profuse floweringwas induced when lysine was added to the medium. Lysine promotedthe flower-inductive process(es) rather than the developmentof flower buds. These results suggest that nitrogen deficiency-induced floweringof the plants is induced by lysine, which is generated froma specific protein(s) by proteolysis. (Received May 11, 1992; Accepted July 30, 1992)     

Flower-inducing effects of benzoic acid and some related compounds in Lemna paucicostata 151

Lemna paucicostata 151, collected in Bangkok, Thailand, doesnot flower under any photoperiod when cultured in M-sucrosemedium, but easily flowers when benzoic acid, salicylic acidor some other related compound is added to the medium. Benzoicacid is more effective than salicylic acid. (Received November 20, 1978; )     

Flower-Inducing Activity of Exogenous Lysine in Lemna paucicostata 151 Cultured on Nitrogen-Rich Medium

Flower-inducing activity of lysine was examined in Lemna paucicostata151, a weakly responsive short-day plant, cultured on nitrogen-richmedium under long-day conditions (continuous light). Lemna paucicostata151 was homogenized in a solution of lysine and the homogenatewas centrifuged. The supernatant (lysine-containing extract)was added to nitrogen-rich medium after passage through a membranefilter to give various concentrations of lysine in the medium.Flowering was induced in plants grown for six days on mediumthat contained lysine at concentrations above 0.25 µM.In plants grown on medium that contained 1 µM lysine,a significant flowering response was observed on the fourthday of culture. However, the flower-inducing activity of lysinedisappeared when the lysine-containing extract was added tothe medium and the medium was then autoclaved, suggesting thatthe active principle is unstable to autoclaving. Among derivativesof lysine tested, lysine hydroxamate had the highest flower-inducingactivity and lysyl lysine had almost same activity as that oflysine. When added to the medium without homogenization withplant material, lysine and lysyl lysine had flower-inducingactivity but lysine hydroxamate did not induce flowering. (Received April 26, 1993; Accepted November 8, 1993)     

Relationship between Structure and Flower-inducing Activity of Benzoic Acid Derivatives in Lemna paucicostata 151

Lemna paucicostata, strain 151, does not flower when grown in1/10 strength M medium containing 1% sucrose, but easily flowerswhen benzoic acid or its substituted derivatives are added tothe medium. The structure-activity relationship of benzoic acidderivatives are quantitatively analyzable by means of physicochemicalparameters. Aromatic substituent constants a (electronic parameter)and Vw (van der Waals volume steric parameter) delineate thevariations in the flower-inducing activity, i.e., the higherthe electron-withdrawing ability as well as the less the bulkinessof the substituents, the higher the activity. The exceptionsare the derivatives substituted with NO₂ at any position andwith OH at meta and para positions; they exhibit an activitylower than expected from their substituent parameters. 2-Hydroxybenzoicacid (salicylic acid) exhibits activity higher than the calculatedvalue, suggesting participation of the chelating effect in theflower-inducing activity besides electronic and steric effects.The molecular form responsible for the activity is suggestedto be an undissociated neutral species. (Received May 21, 1981; Accepted September 29, 1981)     

Relationship between Flower Induction by Benzoic Acid and its Metabolism in Lemna paucicostata 151

The flower-inducing activities in Lemna paucicostata 151 offour major metabolites of benzoic acid (N-benzoyl aspartate,benzyl 6-O-ß-D-apiofuranosyl-O-ß-D-glucopyranoside,O-benzoyl isocitrate and O-benzoyl malate) were measured, andthe effects on the uptake and metabolism of benzoic acid dueto change in the level of the benzoic acid concentration orto the addition of plant hormones were investigated. N-Benzoylaspartate had weak activity, and O-benzoyl isocitrate and malatehad fairly strong activities, while benzyl 6-O-ß-D-apiofuranosyl-ß-D-glucopyranosideshowed no activity. As the concentration of benzoic acid rose,the ratio of N-benzoyl aspartate increased and that of benzyl6-O-ß-D-apiofuranosyl-O-ß-D-glucopyranosidedecreased. GA₃ and IAA, inhibitors of flower induction by benzoicacid, seemed to promote conversion to N-benzoyl aspartate insteadof to benzyl 6-O-ß-D-apiofuranosyl-ß-D-glucopyranoside.The conversion to N-benzoyl aspartate was considered to be adetoxification process and that to benzyl 6-O-ß-D-apiofuranosyl-ß-D-glucopyranosidemay be directly related to flower induction in Lemna. (Received November 2, 1987; Accepted January 23, 1988)     

Biological Conversion of Benzoic Acid in Lemna paucicostata 151 and its Relation to Flower Induction

Benzoic acid, known to induce flowering in Lemnaceae, was shownto be converted to four major compunds in Lemna paucicostata151. These compounds were isolated and determined to be N-benzoylaspartate, benzyl 6-O-ßdD-apiofuranosyl-ß-D-glucopyranoside,O-benzoyl isocitrate and O-benzoyl malate. (Received November 2, 1987; Accepted January 23, 1988)     

The Role of Plant Hormones and Benzoic Acid in Flowering of Lemna paucicostata 151 and 381

The effects of plant hormones on flowering of Lemna paucicostata151 and 381 were investigated when exogenously applied in combinationwith benzoic acid. These strains are very sensitive to benzoicacid and flower readily on application of benzoic acid. Theflower-inducing effect of benzoic acid was strongly modifiedby plant hormones: gibberellins, indole-3-acetic acid and abscisicacid were inhibitory, while cytokinins were promotive (synergistic),suggesting that the balance between endogenous levels of benzoicacid and plant hormones contributes to the regulation of floweringin Lemna. (Received October 6, 1982; Accepted December 23, 1982)     

The S-Methylmethionine Cycle in Lemna paucicostata

The metabolism of S-methylmethionine has been studied in cultures of plants of Lemna paucicostata and of cells of carrot (Daucus carota) and soybean (Glycine max). In each system, radiolabeled S-methylmethionine was rapidly formed from labeled l-methionine, consistent with the action of S-adenosyl-l-methionine:methionine S-methyltransferase, an enzyme which was demonstrated during these studies in Lemna homogenates. In Lemna plants and carrot cells radiolabel disappeared rapidly from S-methylmethionine during chase incubations in nonradioactive media. The results of pulse-chase experiments with Lemna strongly suggest that administered radiolabeled S-methylmethionine is metabolized initially to soluble methionine, then to the variety of compounds formed from soluble methionine. An enzyme catalyzing the transfer of a methyl group from S-methylmethionine to homocysteine to form methionine was demonstrated in homogenates of Lemna. The net result of these reactions, together with the hydrolysis of S-adenosylhomocysteine to homocysteine and adenosine, is to convert S-adenosylmethionine to methionine and adenosine. A physiological advantage is postulated for this sequence in that it provides the plant with a means of sustaining the pool of soluble methionine even when overshoot occurs in the conversion of soluble methionine to S-adenosylmethionine. The facts that the pool of soluble methionine is normally very small relative to the flux into S-adenosylmethionine and that the demand for the latter compound may change very markedly under different growth conditions make it plausible that such overshoot may occur unless the rate of synthesis of S-adenosylmethionine is regulated with exquisite precision. The metabolic cost of this apparent safeguard is the consumption of ATP. This S-methylmethionine cycle may well function in plants other than Lemna, but further substantiating evidence is neeeded.     

Effects of Exogenous Amino Acids on Iron Uptake in Relation to their Effects on Photoperiodic Flowering in Lemna paucicostata 6746

The flowering of Lemna paucicostata 6746 grown on 14-h photoperiodwas enhanced by the addition of high concentrations of ironto the medium, which also increased the endogenous iron concentration.The addition of asparagine, aspartate, glutamate, -alanine,glycine or serine to the medium also increased the endogenousiron level, resulting in the promotion of flowering. In contrast,the addition of cysteine, cystine, glutamine, arginine, threonineor phenylalanine lowered the endogenous iron level, resultingin the inhibition of flowering. Glycine and asparagine added to the medium during an inductive96-h dark period did not promote iron uptake and had no effecton flowering, but when added during the subsequent 120-h lightperiod, they promoted both iron uptake and flowering response.The increase in the endogenous iron level seems to favor floraldevelopment rather than induction of photoperiodic floweringof Lemna paucicostata 6746. (Received September 8, 1986; Accepted March 31, 1987)     

Lysine Reverses the Inhibition of Flowering by Elastatinal, a Protease Inhibitor, in Lemna paucicostata 151

The flowering of Lemna paucicostata 151 that is normally inducedby nitrogen-free culture was suppressed by the application ofeither of two protease inhibitors, namely, elastatinal and bestatin,to the medium. These protease inhibitors prevented the flower-inductiveprocess(es) rather than the development of flower buds, suppressingof the degradation of some proteins. The amount of free lysinein plants increased during nitrogen-free culture and lysinehad a flower-inducing effect on the plant. However, levels ofendogenous lysine did not increase when elastatinal was presentin the medium. The suppressive effect of elastatinal on flowerinduction was almost completely reversed by simultaneous applicationof lysine to the medium while the suppressive effect of bestatinwas only partially reversed by lysine. These results suggestthat induction of flowering by nitrogen deficiency is due toendogenous free lysine and that elastatinal suppresses the proteolyticprocesses by which free lysine is generated from protein(s)during nitrogen-free culture. (Received August 7, 1992; Accepted February 9, 1993)     

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)     

Synthesis of Ethanolamine and Its Regulation in Lemna paucicostata

The metabolism of ethanolamine and its derivatives in Lemna paucicostata has been investigated, with emphasis on the path-way for synthesis of phosphoethanolamine, a precursor of phosphatidylcholine in higher plants. In experiments involving labeling of intact plants with radioactive serine, ambiguities of interpretation due to entry of radioactivity into methyl groups of methylated ethanolamine derivatives were mitigated by pregrowth of plants with methionine. Difficulties due to labeling of diacylglyceryl moieties of phospholipids were avoided by acid hydrolysis of crucial samples and determination of radioactivity in isolated serine or ethanolamine moieties. The results obtained from such experiments are most readily reconciled with the biosynthetic sequence: serine → ethanolamine → phosphoethanolamine → phosphatidylethanolamine. A possible alternative is: serine → phosphatidylserine → phosphatidylethanolamine → ethanolamine → phosphoethanolamine. Cell-free extracts of L. paucicostata were shown to produce CO₂ from the carbon originating as C-1 of serine at a rate sufficient to satisfy the demand for ethanolamine moieties. A number of experiments produced no support for a hypothetical role for phosphoserine in phosphoethanolamine formation. Uptake of exogenous ethanolamine commensurately down-regulates the synthesis of ethanolamine moieties (considered as a whole, and regardless of their state of derivatization at the time of their formation). In agreement with previous observations, uptake of exogenous choline down-regulates the methylation of phosphoethanolamine, without being accompanied by secondary accumulation of a marked excess of ethanolamine derivatives.     

Some Characteristics of Protein Kinases in Lemna paucicostata

The three protein kinases of Lemna paucicostata that are separableby DEAE-Sephacel chromatography have been designated PI, PIIand PIII [Kato et al. (1983) Plant & Cell Physiol. 24: 841].The optimum pH for the PI and PII enzymes was 7.5 and for thePHI enzyme 7.0. The activities of these enzymes were stimulatedby divalent cations, the maximum stimulation being producedby 5 nw Mg^{2 $} for PI, by 3 mM Co^{2 $} for PII and by 1 mM Mn^2$ for PIII. The cytokinins; benzyladenine, kinetin and zeatin,inhibited the activity of the PIII enzyme. The molecular weightsof the PI and PII enzymes did not change after incubation withcAMP even though their activities were regulated by this compound. (Received October 17, 1983; )     

Flower-inducing Activity of Vitamin K in Lemna paucicostata

Vitamins K₁ K₃ and K₅ induced flowering in Lemna paucicostata151, a short-day plant, cultured in 1/10 strength M medium (1/10M medium) under continuous light, and their activity was greatlyintensified by simultaneous application of benzyladenine. Themost active of these was vitamin K₅ L. paucicostata 6746 ismore sensitive to vitamin K₅ than strain 151, but the effectof vitamin K₅ on strain 6746 was not intensified by benzyladenine.The flower-inducing activity of vitamin K₅ was intensified bythe addition of benzoic acid in both strains and by the additionof copper or ferricyanide in Strain 6746, when these chemicalswere added at such low concentrations that they would scarcelyinduce flowering. In strain 6746, vitamin K₅ added to 1/10 M had little effecton flowering under a subcritical photoperiod, while it clearlyinduced flowering under continuous light. In this strain, vitaminK₅ added to full strength M medium, in which this plant wasmore sensitive to short photoperiods than in 1/10 M medium,did not induce flowering even under continuous light, and wasrather inhibitory under short photoperiods. (Received August 14, 1984; Accepted October 16, 1984)     

Flower-Inducing Activity of Lysine in Lemna paucicostata 6746

Flowering of Lemna paucicostata 6746, a typical short-day plant,was induced by culture for 96 or 120 h in nitrogen-free mediumunder continuous illumination. To examine the effects of lysine,we homogenized entire plants of L. paucicostata 151 in a solutionof lysine and the supernatant obtained after centrifugationof the homogenate was added to the medium to give various concentrationsof lysine in the medium. Flowering of strain 6746 in nitrogen-freeor nitrogen-deficient culture medium was effectively promotedby the addition of a lysine-containing supernatant to the medium.The suppressive effect of elastatinal, a protease inhibitor,on the induction of flowering was almost completely reversedby the simultaneous application of a lysine-containing supernatantto the medium. During nitrogen-free culture, the level of endogenousfree lysine, expressed on the basis of the amount of total freeamino acids, increased. Lysine-containing supernatants alsoinduced flowering of plants in nitrogen-rich medium under continuousillumination. These findings suggest that endogenous lysineis involved in the induction of flowering in L. paucicostata6746 on nitrogen-free or nitrogen-deficient medium, as it isin the induction of flowering in L. paucicostata 151 (Received July 29, 1996; Accepted November 18, 1996)     

Aspartokinase of Lemna paucicostata Hegelm. 6746

A sensitive and specific method was developed for assay of aspartokinase (EC 2.7.2.4) in crude extracts of Lemna paucicostata. Lysine inhibited approximately 93%, and threonine approximately 6%; together, these amino acids inhibited 99%. Inhibition by lysine was synergistically increased by S-adenosylmethionine, which by itself had no effect on activity. Essentially complete inhibition of threonine-resistant activity was obtained with lysine, and of lysine-resistant activity with threonine. Inhibition by lysine and threonine was additive, with no indication of concerted inhibition. Aspartate concentration had no effect on the relative proportions of lysine- and threonine-sensitive activities. Aspartokinase activity was in large excess of that reported by other workers, the maximum capacity (V_max) far exceeding the in vivo requirements. Estimations of rates of aspartokinase in vivo suggest that the step catalyzed by this enzyme may not be the overall `rate-limiting' one for entry of 4-carbon units into the aspartate family of amino acids, and that feedback inhibition of this enzyme by lysine and threonine may not be a major factor in regulating flux through this step.