The Effect of 2-Chloro-4-ethylamino-6-isopropyl-amino-s-triazine (Atrazine) on Distribution of 14C-Compounds Following 14CO2 Fixation in Excised Kidney Bean Leaves

Excised leaves of kidney bean plants treated with various concentrationsof atrazine for different periods were allowed to fix ¹⁴CO₂CO₂ fixation was inhibited by atrazine. The ¹⁴C-labelling patternof atrazine-treated leaves resembled dark Co₂-fixation patterns.The carbon-I-carboxyl group of ¹⁴C-aspartic acid from atrazine-treatedand ‘dark’ leaves showed no significant differencesin total radioactivity. Although atrazine disrupted the photosyntheticapparatus, it seemed to have no effect on non-photosyntheticCO₂ fixation.     

THE DISTRIBUTION PATTERN OF CARBON-14 ASSIMILATED BY A SINGLE LEAF IN TOBACCO PLANT

When ¹⁴CO₂ was administered to a fully expanded leaf (12th leaf)of tobacco plant at the stage just before flower budding, about30% of ¹⁴C assimilated was translocated to other organs after3 hours. After 21 hours, 20{small tilde}30% of the radioactivitywas translocated to the roots, about 20% to upper stem, 10%to lower stem, and 10% to the 17th leaf located directly abovethe 12th leaf. The amount of ¹⁴C translocated to other leaveswas small after 31 hours. When ¹⁴CO₂ was applied to the 17th leaf, radioactivity in otherorgans was negligible. Judging from the time course of ¹⁴C-incorporation into organicsubstances, it was inferred that sucrose imported into the rootsfrom the 12th leaf was converted into compounds of cationicfraction and sugar esters. ¹⁴C imported into the 17th leaf was mostly incorporated into80% ethanol-soluble fraction, especially into sucrose. On theother hand, ¹⁴C fixed photosynthetically by the 17th leaf wasmostly recovered in starch and protein fraction after 8 hoursof ¹⁴CO₂ assimilation. ¹A part of this paper was presented at the Japanese Societyof Plant Physiologists, in April, 1965. ²Present address: Central Research Institute, Japan MonopolyCorporation, Shinagawa-ku, Tokyo.     

Effect of Temperature on Starch Degradation in Chlorella vulgaris 11h Cells

Analysis of products formed in Chlorella vulgaris 11 h cellsduring photosynthesis in air containing 3,000 ppm ¹⁴CO₂ at varioustemperatures revealed that the level of ¹⁴C-starch was maximumaround 20–24?C and decreased with further rise in temperatureuntil 40?C, while ¹⁴C-sucrose greatly increased at temperaturesabove about 28?C. Elevating the temperature from 20 to 38?Cduring photosynthetic ¹⁴CO₂ fixation resulted in a remarkabledecrease in ¹⁴C in starch and a concomitant increase in ¹⁴Cin sucrose. This conversion of starch to sucrose when shiftingthe temperature from 20 to 38?C proceeded even in the dark.Hydrolysis of sucrose by rß-fructosidase showed that,irrespective of the experimental conditions, the radioactivitiesin sucrose were equally distributed between glucose and fructose.The enhancement of starch degradation with temperature risewas more remarkable than that of the activity of ribulose bisphosphatecarboxylase from the same cells. When Chlorella cells whichhad been preloaded with ¹⁴C-starch after photosynthesis for30 min at 20?C were incubated in the dark for an additional30 min at 20?C, ¹⁴C-starch was degraded by only about 4%. However,the values after 30-min dark incubation at 28, 32, 36 and 40?Cwere increased by about 10, 19, 36 and 50%, respectively. Duringthe temperature-dependent conversion of starch to sucrose, nosignificant amount of radioactivity accumulated in free glucoseand maltose. (Received October 27, 1981; Accepted January 9, 1982)     

Pre-illumination as a Factor in the Dark Fixation of Carbon Dioxide by Leaf Disks of Kalanchoe blossfeldiana var. Feuer Blute

Dark fixation of CO₂ by leaf disks or whole leaves taken fromplants of variety ‘Feuer Blute’ was measured using¹⁴CO₂. Results indicate that dark fixation by leaf disks isindependent of photoperiodic induction of the plant, but isquantitatively related to the amount of light, over a fairlywide range, to which the leaf is exposed in the single precedinglight period.     

CO2 Assimilation and Partitioning of Carbon in Maize Plants Deprived of Orthophosphate

In order to study the effects of inorganic phosphate (P1) starvationon C₄plants, 3-week-old maize plants (Zea maysL cv. Brulouis)were grown in a growth chamber on a nutrient solution withoutP1 over 22 d During the first 2 weeks, Pi-starved plants grewas well as control plants The Pi concentration in the planttissue decreased rapidly with time, which suggests that normalbiomass production can be maintained at the expense of internalP1 In addition, photosynthetic CO2 assimilation measured 4-6h after dawn was not affected, but the concentration of glucose,sucrose, and starch in leaves was much higher than in the controls¹⁴CO₂ pulse-chase experiments earned out on the ninth day oftreatment showed that ¹⁴CO₂ assimilation was perturbed duringthis initial period, resulting in a larger flow of carbon toboth starch and sucrose At the beginning of the third week ofP1 starvation (15 d after treatment) ¹⁴C incorporation intosucrose stayed high relative to controls but this was not thecase for starch At the end of the third week of P1-deficiency,shoot growth was considerably reduced and fresh weight was onlyone-third of that of the control plants. The P1 concentrationof both the leaf and root tissues was less than 1.0 µmolg^–1 FW compared to 20-25µmol g¹ FW in the controls.Photosynthetic CO₂ assimilation was reduced and the leaf concentrationof sucrose and starch, which had begun to decrease after theend of the second week of P1 limitation, became lower than inthe controls. These results obtained on maize plants show thatphotosynthesis and carbon partitioning between sucrose and starchwere strongly affected by P1 deficiency, similar to C₃ species. Key words: CO₂ assimilation, corn, orthophosphate deficiency, starch, sucrose     

STUDIES ON THE RE-ASSIMILATION OF RESPIRATORY CO2 IN ILLUMINATED LEAVES

Experiments were performed, using rice, barley and Hydrangealeaves, to examine the re-assimilation of respiratory ¹⁴CO₂while photosynthesis is going on in an open air flow system. It was found that the leaves which had assimilated ¹⁴CO₂ beforehandevolved, when kept under photosynthesizing conditions, threeto four tenths (variable according to plant species and externalconditions) of the amount of ¹⁴CO₂ to be produced in the dark.Such an incomplete re-utilization of ¹⁴CO₂ was observed alsoin spinach leaf homogenate as well as in the leaves which hadpreviously absorbed ¹⁴C-glucose. The ¹⁴CO₂ output in rice leaves was found to be acceleratedby the light of high intensity. A possibility of light stimulationon the respiration was suggested. (Received October 7, 1961; )     

Some Effects of Yellow Rust (Puccinia striiformis) on 14Carbon Assimilation and Translocation in Wheat

A well-developed infection of Yellow Rust on a leaf of springwheat (Jufy I) caused the assimilation of ¹⁴CO₂ by that leafto decrease to 43.5 per cent of that of an uninfected leaf.Over a period of three hours translocation of ¹⁴C from an infectedleaf was only 0.87 per cent of that from a control leaf. Whencontrol plants were kept in the light for periods up to 16 hoursafter assimilating ¹⁴CO₂ translocation continued at a steadyrate, whereas there was only negligible translocation from infectedleaves after the first few hours. The retention of labelledassimilates in the infected leaf could be partly, but not completely,accounted for by a conversion of assimilates to an alcohol-insolubleform. Rust infection had no effect on the distribution patternof ¹⁴C to other leaves from one which had assimilated ¹⁴CO₂.In contrast to the marked retention of assimilate by an infectedleaf, such a leaf was unable to distort the normal distributionby attracting assimilates from the other leaves.     

木荷属和柃木属植物的嘌呤代谢及嘌呤碱合成研究

以［8-¹⁴C］标记的腺嘌呤和黄嘌呤为底物,对两种可以合成少量咖啡碱和茶叶碱的木荷属和柃木属植物（Schima mertensiana,Eurya japonica）叶片的嘌呤代谢进行了检测研究。发现木荷属和柃木属植物中嘌呤代谢相似,¹⁴C标记的腺嘌呤可以整合到嘌呤核苷酸、RNA、酰脲（包括尿囊素和尿囊酸）、二氧化碳中。经过24 h培养,在叶片吸收的放射能中,仅有6%～7%用于甲基黄嘌呤类化合物的合成（3-甲基黄嘌呤、7-甲基黄嘌呤核苷、7-甲基黄嘌呤、茶叶碱）。和其他植物一样,绝大多数¹⁴C标记的黄嘌呤整合到嘌呤的分解代谢物中（二氧化碳和酰脲）,少量的放射能分布在3-甲基黄嘌呤及茶叶碱中。根据结果可以推断木荷属和柃木属植物具有N-甲基转移酶活性,可以用来合成咖啡碱和茶叶碱,相对于茶树而言,活性不高。综上,本文对木荷属和柃木属植物的嘌呤代谢以及嘌呤碱合成进行了研究。     

Effects of dark preincubation and chloramphenicol on blue light-induced CO2 incorporation in Chlorella cells

Chlorella cells incubated in the dark longer than 12 hr showedpronounced blue light-induced ¹⁴CO₂ fixation into aspartate,glutamate, malate and fumarate (blue light effect), whereasthose kept under continuous light showed only a slight bluelight effect, if any. 2) During dark incubation of Chlorellacells, phosphoenolpyruvate carboxylase activity and the capacityfor dark ¹⁴CO₂ fixation decreased significantly, whereas ribulose-1,5-diphosphatecarboxylase activity and the capacity for photosynthetic ¹⁴CO₂fixation (measured under illumination of white light at a highlight intensity) did not decrease. 3) In cells preincubatedin the dark, intracellular levels of phosphoenolpyruvate and3-phosphoglycerate determined during illumination with bluelight were practically equal to levels determined during illuminationwith red light. 4) The blue light effect was not observed incells incubated widi chloramphenicol, indicating that blue light-inducedprotein synthesis is involved in the mechanism of the effect. (Received April 9, 1971; )     

Preparation of Radioactive Starch, Glucose and Fructose from C14O2

Radioactive starch, glucose and fructose have been preparedfrom tobacco leaves after assimilation of C¹⁴O₂. The apparatusused for photosynthesis consisted of a shallow Perspex leafchamber connected to a closed gas system, in which C¹⁴O₂ wasgenerated from BaC¹⁴O₂. Six leaves, area 14 to 18 sq. dm. whenexposed to bright sunlight with an initial CO₂ concentrationof 8 to 10 per cent., assimilated 3.35 g. of C¹⁴O₂ in 8 to 10hours. At least 80 per cent. of the C¹⁴O₂ supplied appearedin the leaves as starch and sugar and over 80 per cent. of theradioactivity was accounted for in these carbohydrates. Thespecific activity per m. atom of carbon of the isolated productswas 85 to 90 per cent. of that of the C¹⁴O₂. Small amounts ofradioactive carbon were also incorporated in the leaf proteinand in the celluose, hemicellulose and polyuronides.     

Metabolism of Radioactive Sugars by Tobacco leaf Disks

Destarched tobacco-leaf disks were floated on per cent. (w/v)solutions of sucrose uniformly labelled with ¹⁴C in either theglucose or fructose moiety, and on invert sugar in which onehexose only was so labelled. The experiments were carried outin an atmosphere of oxygen at 25° C. Seventy-five per cent,of the sugar lost from the external solutions was recoveredas starch, sucrose, fructose, glucose, and CO₂. With sucroseas the substrate, 30 per cent, of the material was recoveredas CO₂ and 17 per cent. each as starch, sucrose, fructose, andglucose. With invert sugar as the substrate, 30 per cent, wasagain recovered as CO₂ only 20 per cent. as the three sugarstogether, and 50 per cent. as starch. Whichever hexose was initiallylabelled and whether the sugar was supplied as sucrose or hexose,the relative specific activities of starch and sucrose in theleaf disks and of the CO₂ evolved were equal or nearly equalto that of the sugar supplied. With sucrose as the substratethe sucrose in the disks retained its asymmetry of label, andfree hexoses produced were similarly asymmetrically labelled.When invert sugar was the substrate the sucrose synthesizedwas strongly labelled in both moieties, as also were the freehexosea. It is concluded that fructose and glucose free or combinedin sucrose were equally available for starch synthesis and CO₂,formation, and that there can be no question of preferentialutilization of one or other hexose. Starch and CO₂ must arisefrom a common source in which readily formed derivatives ofthe hexoses are rapidly equilibrated. Free hexose cannot participatedirectly in either sucrose or starch synthesis. Accumulationof sugar not immediately metabolized and inversion of sucrosetake place at a site remote from the common pool. A scheme toaccommodate the results is discussed.     

Effects of Paraquat on carbon assimilation and transport by sugarcane leaves in white light and darkness

Effects of the quaternary ammonium herbicide Paraquat (1,1 -dimethyl-4,4- dipyridinium-bis-dimethyl sulfate) on ¹⁴C assimilation andtransport by sugarcane leaves were studied in white light andtotal darkness. Assimilation was almost totally repressed whenParaquat was administered prior to ¹⁴CO₂. When applied immediatelyafter ¹⁴CO₂, the subsequent transport of labeled sucrose waspartially inhibited in white light and severely inhibited indarkness. The translocation effect is tentatively attributedto a selective repression of dark transport operating in collaborationwith light-mediated transport. Transient ¹⁴C declined in sucroseand increased in hexose and raffinose among darkened and Paraquat-treatedleaves. The chemical's activity is interpreted within the contextof its known restriction of photosynthetic light reactions.A distinction is drawn between transport inhibition in darknessand published phytotoxic effects of Paraquat. ¹Present address: Rt. 2 Box 481, Pullman, Washington 99163,U.S.A. (Received November 4, 1975; )     

Starch Dissolution in Tobacco Leaves in the Light

Single attached leaves of tobacco, depleted of starch, wereallowed to assimilate a fixed amount of ¹⁴CO₂. About 50 percent. of the ¹⁴Carbon assimilated was translocated from thelamina concurrently with assimilation. Of that remaining inthe lamina 80 per cent. was incorporated into starch and sugar.Plants were then placed in air and continuous light of differentintensities as a means of controlling further starch synthesis.At about 500 f.c. there was no change in amount of starch after72 hours, but half the radioactivity was lost. At light intensitieslower than 500 f.c. percentage activity lost was greater thanthe percentage amount lost. In sunlight, where new starch synthesiswas very rapid, loss in activity from the radioactive portionwas prevented. In all circumstances activity virtually disappearedfrom both hexose and sucrose. It is concluded that starch dissolutionproceeded in light even when the amount was increasing. It isfurther suggested that the loss was mainly from outer layersof the starch grains which were replaced by newly synthesizedmaterial. Loss of sugar was by direct translocation rather thanpassage to starch, and complete replacement by new photosynthateoccurred in 24 hours.     

The Extent of Starch Turnover in Mature Pepper Leaves in the Light

The extent of starch turnover in pepper leaves in the lighthas been estimated. After leaves were labelled with ¹⁴CO₂ atconstant specific activity for 4–7 h, the irradiance wasreduced to a level which caused no net change in the starchcontent of the leaf, and the supply of ¹⁴CO₂ was removed. Therewas no significant change in specific activity of starch overthe following 6–10 h, thus there was no exchange of ¹⁴C-starchwith ¹²C-assimilates entering the chloroplasts. Starch, turnover, ¹⁴C-labelling, pepper, Capsicum annuum L.     

14CO2 Pulse-Chase Labelling in Clusia minor L.

Conditions and maintenance of growth were chosen so that plantsof Clusia minor L. were obtained which showed the C₃- and CAM-modes of CO₂-exchange, respectively. C. minor is known to accumulateconsiderable amounts of citric acid in addition to malic acidduring the dark-phase of CAM. ¹⁴CO₂-pulse-chase experiments were performed with these plants.Patterns of labelling during the pulse and redistribution oflabel during the chase in the C₃-mode were as expected for C₃-photosynthesis.Pulse-labelling in the CAM-mode during the last hour of thelight period, during the first part of the dark period and duringthe last hour of the dark period always led to an almost exclusiveincorporation of label into malate. Redistribution of labelfrom malate after the pulse at the end of the dark period duringthe chase in the subsequent light period followed the patternexpected for light-dependent reassimilation of CO₂ remobilizedfrom malate in CAM during the light period. During the chasesin the dark period, label was transferred from ^l4C-malate tocitrate. This suggests that during accumulation of citric acidin the dark period of CAM in C. minor, citrate is synthesizedin the mitochondria from malate or oxaloacetate after formationof malate via phosphoenolpyruvate carboxylase. The experiment also showed that no labelled compounds are exportedfrom leaves in the CAM-mode during the dark period. In plantsof the C₃-mode the roots proved to be strong sinks. Key words: Clusia minor, labelling, pulse-chase, ¹⁴CO₂     

Light-enhanced carbon dioxide fixation in isolated chloroplasts

Preillumination of leaves of spinach, soybean and maize in theabsence of CO₂ greatly enhanced the capacity for fixing CO₂in an immediately following dark period. Lightenhanced darkCO₂-fixation was further observed in isolated chloroplasts ofspinach and soybean. When isolated chloroplasts were illuminated,CO₂-fixing capacity in the subsequent dark period increasedrapidly at first and later more slowly attaining a stationaryvalue in about 20 min. When the light was turned off at thisstage, the capacity decreased very rapidly becoming zero inabout 10 min. The magnitude of the enhanced dark fixation andits decay in the dark were not influenced by the presence orabsence of atmospheric oxygen. In both leaves and isolated chloroplasts,no significant change in oxygen (21%) occurred in distributionpatterns of radioactivity in products fixed by photosynthetic,or light-enhanced, dark, ¹⁴CO₂-fixation. In preilluminated leaves¹⁴C was incorporated into sucrose in the subsequent dark period,indicating that the photosynthetic carbon reduction cycle isoperating in light-enhanced dark fixation in higher plants. ¹Present address: Noda Institute for Scientific Research, Noda,Chiba Prefecture (Received August 10, 1970; )     

Characterization of Photosynthetic 14Carbon Assimilation by Potamogeton lucens L.

Photosynthetic assimilation of exogenous ¹⁴CO₂ and H¹⁴CO₃^–by the aquatic angiosperm Potamogeton lucens L. is reported.Equivalent maximum rates of assimilation (1.5 µmol s^–1m^–2) were obtained in the presence of saturating levelsof ¹⁴CO₂ (1.0 mol m^–3, pH 5.3) or H¹⁴CO₃^– (1.5 molm^–3, pH, 9.2). Under subsaturating ¹⁴CO₂ levels, bothgaseous diffusion and H¹⁴CO₃^– transport were shown tooperate simultaneously, such that maximal photosynthetic rateswere established. An induction lag of approximately 3 min was observed when exogenous¹⁴CO₂ was assimilated. A longer lag of approximately 12 minwas required, however, before linear assimilation rates wereestablished when H¹⁴CO₃ acted as the carbon source. The light-activatedH¹⁴CO₃^– transport system was found to be quite labile.A brief (5 min) dark treatment returned the system to the inactivestate. Bicarbonate transport was shown to be competitively inhibitedby CO₃^2–ions. The possibility is discussed that this formof inhibition may be common to many HCO₃^– assimilators. Preliminary polar cation transport studies (from lower to upperleaf surface) indicated an almost exact one to one relationshipbetween the rates of Na⁺ influx and efflux and H¹⁴CO₃^–assimilation. The possible relationship(s) between these transportprocesses and the requirement for electrical neutrality is brieflydiscussed.     

Photolytic Decarboxylation of Carboxyl-14C-labelled Indol-3yl-acetic Acid in Leaves of the Apple Tree

The nature and rate of degradation of carboxyl-¹⁴C-labelledindol-3y1-acetic acid (IAA-[l-¹⁴C]) were studied in apple leaves.The labelled auxin was applied to the cut surface of the growingshoot after the apical part had been removed. The respiratoryCO₂ absorbed by chromatographic paper as Na₂CO₃ then freed byphosphoric acid was quantitatively measured by an internal gascounter. It was found that the concentration of ¹⁴CO₂ evolvedby leaves was 77 times higher in daylight than in darkness.The ratio of ¹⁴CO₂/CO₂ obtained from respiration from the uppersurface of leaf blades was two and seven times higher than thatfrom the lower surface after 15 and 30 h of daylight, respectively.No such differences were noticed in darkness. Similarly, thetotal radioactivity of leaf tissues tripled in daylight, presumablybecause of photosynthetic incorporation of radioactive CO₂ evolvedduring decomposition of LAA. These facts demonstrate the photolyticcharacter of auxin decarboxylation in apple leaves. Prolongeddarkness seemed to provoke a large metabolite withdrawal fromleaves and, to some extent, to protect auxin against decarboxylation.     

Dynamics of Carbon Photosynthetically Assimilated in Nodulated Soya Bean Plants under Steady-state Conditions 1. Development and Application of 13CO2 Assimilation System at a Constant 13C Abundance

A long-term, steady-state ¹³CO₂ assimilation system at a constantCO₂ concentration with a constant ¹³C abundance was designedand applied to quantitative investigations on the allocationof photoassimilated carbon in nodulated soya bean (Glycine maxL.) plants. The CO₂ concentration in the assimilation chamberand its ¹³C abundance were maintained constant with relativevariances of less than ±0.5 per cent during an 8-h assimilationperiod. At the termination of 8-h ¹³CO₂ assimilation by plantsat early flowering stage, the currently assimilated carbon relativeto total tissue carbon (measured by the degree of isotopic saturation)were for young leaves (including flower buds), 13.9 per cent;mature leaves, 15.7 per cent; stems+petioles, 5.9 per cent;roots, 5.4 per cent and nodules, 6.9 per cent, 48 h after theend of the ¹³CO₂ assimilation period, they were 12.3, 7.5, 7.4,6.8 and 6.1 per cent, respectively. The treatment with a highconcentration of nitrate in the nutrient media significantlydecreased the allocation of ¹³C into nodules. Experiments on¹³CO₂ assimilation by plants at the pod-filling stage were alsoconducted. Labelling by ¹³C was weaker than at the early floweringstage, but an intense accumulation of ¹³C into reproductiveorgans was observed. Glycine max L., nodulated soya bean plants, ¹³CO₂ assimilation, carbon dynamics     

Ammonia Induces Starch Degradation in Chlorella Cells

When ammonia was added to cells of Chlorella which had fixed¹⁴CO₂ photo synthetically, ¹⁴C which had been incorporated intostarch was greatly decreased. A similar effect was observedwhen potassium nitrate and sodium nitrite were added. The ammonia-induceddecrease in ¹⁴C-starch was observed in all species of Chlorellatested. With cells of C. vulgaris 11h, most of the radioactivityin starch was recovered in sucrose, indicating that ammoniainduces the conversion of starch into sucrose. The percent of¹⁴C recovered in sucrose differed from species to species andpractically no recovery in sucrose was observed in C. pyrenoidosa.In most species tested, the enhancing effects of blue lightand ammonia on O₂ uptake as well as the ammonia effect on starchdegradation were greater in cells which had been starved inphosphate medium in the dark than in non-starved cells. In contrast,the enhancing effect of ammonia on dark CO₂ fixation was muchgreater in non-starved cells. C. pyrenoidosa was unique in thatblue light did not show any effect on its O₂ uptake. (Received August 15, 1984; Accepted November 16, 1984)