Distribution of 14C-sucrose applied to leaves at different nodes of okra (Abelmoschus esculentum) during flowering and early pod growth

The distribution pattern of ¹⁴C-sucrose from ¹⁴C-sucrose applied to vegetative okra plants and leaves 1–9 on separate plants during the green pod development stage were investigated in relation to duration and leaf position. Results indicated bi-directional transport of assimilates to both apical and basal portions of the stem. Within 48 h ¹⁴C moved to all plant parts; stem and leaves appeared to be strong sinks. In plants fed at the vegetative stage, 48 h after feeding, 66% of the fed activity was exported from the fed leaf. At the pod development stage, about 35% of the activity exported from the fed leaf was present in green pods and 65% in vegetative parts. In plants where leaf 1–9 was fed, irrespective of the position of the fed leaf, the subtending fruit was the strongest sink among the reproductive parts. Leaves and stems were the principal sinks.     

The development of Pisum sativum explant systems for studies concerning source-sink activities

Using excised fruit/shoot systems of pea ( Pisum sativum L.), the effect of the 10-day-old (post anthesis) fruit (sink) on the translocation of ¹⁴C-sucrose applied to the stipule (source) was investigated. We also examined the influence of various growth regulators on the source-sink relationships using this system. Indole-3-yl-acetic acid (100 or 200 ppm), gibberellic acid (25-100 ppm) increased ¹⁴C-sucrose translocation into the growing fruit by about 13% and 22–29%, respectively. 2-chloroethyl phosphonic acid, 6-benzyladenine and 2-methyl-4-chlorophenoxyacetic acid also increased ¹⁴C-sucrose translocation into the fruit by about 11–26%, 11–23% and 24–37%, respectively. Elevated fruit ¹⁴C-sucrose levels found in other treatments include, methyl-2-chloro-9-hydroxyfluorene-9-carboxylate (300 or 1000 ppm), 2,3,5-triiodobenzoic acid (100 and 300 ppm) and butanedioic acid mono-(2,2-dimethylhydrazide) (30-300 ppm) by about 34%, 39–52% and 7–13%, respectively.     

Evidence for two pathways of phloem loading

The minor veins of small leaf discs, punched out of mature leaves and incubated in ¹⁴C-sucrose solution, appear labeled in macro- and microautoradiographs. Discs with a labeled vein pattern and with labeled sieve tubes in microautoradiographs were found in Beta vulgaris, Vicia faba, Gomphrena globosa and Antirrhinum majus . However, in several other plant species, minor veins appeared unlabeled in macroautoradiographs when the discs were incubated in ¹⁴C-sucrose. Mesophyll cells ( Acer pseudoplatanus, Juglans regia, Fagia, sylvatica, Syringa vulgaris, Laburnum anagyroides ), bundle-sheath cells of major veins ( Salix viminalis, Robinia pseudoacacia, Commelina communis ) or epidermal layers ( Ginkgo biloba, Chlorophytum comosum ) appeared labeled. Lack of radioactivity in sieve tubes of this latter group was confirmed by microauto-radiography. Using ¹⁴C-glucose instead of ¹⁴C-sucrose, leaf discs of Beta vulgaris showed no labeled vein pattern and in microautoradiographs the sieve tubes appeared unlabeled. In view of the by-pass phloem loading, this study provides evidence for two pathways of phloem loading.     

Sucrose accumulation in developing peach fruit

Uptake of ¹⁴C-sugars and activities of sucrose metabolizing enzymes were determined in order to study the mechanism(s) of sucrose accumulation in developing peach fruit. Mesocarp of young peach fruit contained glucose and fructose but little sucrose. Starting 88 days after anthesis (DAA) the sucrose concentration increased greatly. The mechanism of sucrose accumulation was studied by measuring ¹⁴C-sucrose and ¹⁴C-glucose uptake rates at three different stages of fruit development, and by assaying weekly the activity of enzymes involved in the hydrolysis and/or synthesis of the soluble sugars. Uptake of 0.5–100 m M ¹⁴C-sucrose and ¹⁴C-glucose by mesocarp tissue slices showed a complex pattern at the first stage of fruit development (62 DAA). During the subsequent growth stages the pattern of sugar uptake changed and was approximately monophasic at the third stage of fruit development.
At 10 m M , glucose was taken up more rapidly than sucrose at the first and second stage of fruit development. Uptake was partially inhibited by the uncoupler carbonylcyanide m -chlorophenylhydrazone (CCCP) at 25 μ M. These results, together with the presence of a putative extracellular invertase, suggest an apoplastic route for sucrose uptake which is dependent, at least in part, on energy supply.
Activities of sucrose hydrolyzing enzymes (insoluble acid invertase, soluble acid invertase, neutral invertase, sucrose synthase) were high in young fruits and declined sharply with fruit development concomitantly with accumulation of sucrose. The storage of the sugar was not accompanied by a rise in synthetic activities (sucrose synthase, sucrose phosphate synthase), suggesting that sucrose could, at least in part enter the carbohydrate pool directly.     

The fate of carbon during the assimilation of carbamoyl phosphate in white spruce seedlings as revealed by [14C]-carbamoyl phosphate, [14C]-cyanate, and [14C] -bicarbonate labeling patterns

The fate of carbamoyl phosphate in white spruce seedlings revolves around the production of spontaneous degradation products, cyanate, bicarbonate, and carba-mate. When [¹⁴C]-carbamoyl phosphate and [¹⁴C]-cyanate are assimilated, urea is a common early metabolic intermediate that appears in the alcohol soluble N. By contrast, urea is not detected among the products of [¹⁴C]-bicarbonate. Carbamoyl phosphate and glutamic acid are implicated as having pivotal roles in the production of amides, arginine, and biotin. Within 2-h exposures to radioactive substrates considerably more carbon from bicarbonate was diverted into amino acids Incorporated into proteins than with carbon-nitrogen substrates. Specific activities of bound amino acid residues support the view that proteins formed from these [¹⁴C]-substrates have different rates of metabolic turnover.     

Distribution of [14C]-labeled photosynthates within intensively cultured Populus clones during the establishment year

Seasonal patterns of [¹⁴C]-labeled photosynthate distribution within two intensively cultured Populus clones with contrasting phenology ( P. tristis × P. balsamifera cv. 'Tristis no. 1'; P. × euramericana cv. Eugenei) were investigated during the establishment year. During active shoot elongation upper mature leaves exported ¹⁴C acropetally to the expanding leaves and elongating internodes, and basipetally to the stem. Little ¹⁴C was exported to lower mature leaves or lateral branches. At budset the ¹⁴C export pattern shifted dramatically in the basipetal direction, i.e., to the lower stem, hardwood cutting, and roots. The timing of budset was the primary factor determining the differences between the clones, except that in all cases Tristis exported more ¹⁴C to the roots than Eugenei. After budset lower mature leaves had a similar export pattern to upper leaves, but the quantity of ¹⁴C exported to the roots was slightly higher. The results confirm the importance of autumn foliage for root growth in poplar. Clonal differences in seasonal patterns of photosynthate distribution offer potential for the poplar breeder seeking to match a clone's growth pattern with the specific growing season of the site.     

Translocation of labelled assimilates following photosynthesis of 14CO2 by the field bean, Vicia faba

When whole plants were exposed to ¹⁴CO₂, almost the same amount of radioactivity was taken up initially by each leaf regardless of its position on the stem and of the presence of beans at that node. Thus, although developing beans are a powerful sink for assimilated carbon, they do not increase the CO₂ uptake by adjoining leaves.
The distribution of labelled assimilates 6 hours after feeding ¹⁴CO₂ to a single leaf for 1 hour varied with both the position of the treated leaf and the stage of development of the plant. Before any flowers were set most of the radioactivity from all expanded leaves moved downwards to the roots and the stem below the treated leaf (lower stem). Later, during pod-fill, the upper leaves maintained this supply to the roots and lower stem, whilst most of the carbon translocated from the lower and mid-stem leaves went to the beans. However, we found no exclusive relationship between a leaf and the supply to beans developing on the same node.
The amount of radioactivity moving out of a source leaf at a fruiting node increased over successive samplings up to 48 h; the pattern of distribution of the ¹⁴CO₂ however remained virtually unchanged.     

The effect of water status and season on the incorporation of 14CO2 and [14C]-acetate into resin and rubber fractions in guayule

The effects of drought stress and season on both allocation of photosynthates to stems and leaves and potential for stem rubber synthesis were studied in guayule ( Parthenium argentatum Gray USDA line 11604). Two-year-old plants grown under field conditions in the Negev desert of Israel were subjected to different irrigation regimes, and water status was assessed by measuring the relative water content (RWC). Undetached plant tips were exposed to a 1 h pulse of ¹⁴CO₂, followed by a 24 h chase. ¹⁴C fixed and translocated to different plants parts and notably ¹⁴C incorporation into rubber and resin fractions was determined. The potential of detached branch slices to incorporate [¹⁴C]-acetate into rubber was also studied. A higher percentage of fixed ¹⁴C was translocated from shoot tips in winter (28–30%) than in summer (15–18%). The percentage of [¹⁴C]-acctate incorporated into the rubber fraction by stem slices was maximal in winter (20%) and minimal in summer (3–5%) in both cases in the absence of drought stress. In summer the translocation of photosynthates into stems was inversely related to plant RWC, dropping from 18% three days after irrigation to 3% 14 days later, and the potential of stems to synthesise rubber was high under drought conditions and low in well irrigated plants.     

Characterisation of Simple In Vitro Cultures of Striga hermonthica Suitable for Metabolic Studies

Abstract: The aim of this study is to develop simplified models for standardised screenings of xenobiotics, especially targeted against mannitol production, to control the harmful parasite, S. hermonthica. Chlorophyllous protoplasts and calli were produced from the young leaves of the parasite. Best yield from protoplast isolation was obtained when leaf segments were incubated at 30 °C, in the light, under shaking in an enzyme cocktail containing 2 % cellulase Onozuka R10, 0.1 % Pectolyase and sorbitol 1 M as the osmoticum. Oxygen exchange measurements, as well as labelling experiments with ¹⁴C-bicarbonate, emphasised a significant decrease in photosynthetic capacity of protoplasts, mannitol remaining, however, a major primary product of photosynthesis. Initiation of cell cultures was unsuccessful and instability of protoplasts prevents their standardised utilisation for herbicide screening. In contrast, globular calli produced first on MS medium containing 0.5 mg L^-1 NAA, 2.5 mg L^-1 BAP and 2 % sucrose were stable for two years, after monthly subculturing on fresh medium. Sucrose substitution by mannose in the medium did not change kinetic growth and stability. Potential autotrophy was lost for calli by increasing exogenous sugar level. Biochemical analyses and labelling experiments with ¹⁴C-bicarbonate or ¹⁴C-sucrose or -mannose showed that carbon partitioning is modified in calli, in comparison with young leaves or protoplasts, sucrose or mannose accumulation being favoured in sucrose- or mannose-fed calli, respectively. However, carbon flow towards mannitol was more marked in calli growing on high mannose medium. Stability and preservation of an active mannitol biosynthetic pathway allows planning of xenobiotic assays with calli as a simplified model for Striga hermonthica.     

Comparative studies of sucrose and mannitol utilization in celery (Apium graveolens)

Utilization of sucrose and mannitol, the major forms of translocatable assimilate in celery ( Apium graveolens L. cv. Giant Pascal), was investigated in intact plants, excised leaves and leaf discs by estimating the soluble carbohydrate pools, starch levels and oxidation of [¹⁴C]-sucrose or mannitol in the light and after extended dark treatments. In detached mature fully-expanded leaves, mannitol pools remained constant, while sucrose decreased during a 48 h dark treatment. In attached leaves on plants trimmed to a single compound leaf, however, mannitol levels decreased after a dark treatment. In leaf discs floated on bathing solutions containing [¹⁴C]-sucrose or [¹⁴C]-mannitol, oxidation of mannitol was restricted to young leaf tissues, whereas sucrose was metabolized to CO₂ regardless of leaf age. Uptake of labelled mannitol, however, was greater than that of sucrose in the light in leaves of every age. Although both mannitol and sucrose are translocated out of leaf tissues, leaf age differences indicate that, unlike sucrose, mannitol utilization is restricted to active sink tissues. The results suggest different roles for mannitol and sucrose with mannitol representing a more rigorously sequestered transport carbohydrate.     

14C-Metabolism in cultured cotyledon explants of radiata pine

Excised cotyledons of radiata pine ( Pinus radiata D. Don), cultured under shootforming (plus cytokinin) and elongating (minus cytokinin) conditions, were incubated in ¹⁴C-glucose, ¹⁴C-acetate or ¹⁴C-bicarbonate at different stages of growth and differentiation. ¹⁴CO₂ was produced when the cotyledons were fed ¹⁴C-glucose and ¹⁴C-acetate (no measurement was made for ¹⁴C-bicarbonate feeding). Label from these precursors was incorporated into ethanol-soluble and -insoluble fractions. The largest percentage of radioactivity was associated with the ethanol-soluble portion, which was further fractionated into lipids, amino acids, organic acids and sugars. The amount of label and the pattern of labelling associated with each of the above classes of metabolites varied with time in culture and morphogenetic behaviour of the cotyledons. In general, there was a tendency towards a high rate of incorporation of label in elongating cotyledons during the period of rapid elongation. On the other hand, a high rate of incorporation of label in shoot-forming cotyledons coincided with the period of meristematic tissue formation. The data obtained support the hypothesis that organized development in vitro involves a shift in metabolism, which precedes and is coincident with the initiation of the process.     

Incorporation of 15N and 14C of methionine into the mugineic acid family of phytosiderophores in iron-deficient barley roots

The role of methionine as a precursor in mugineic acid (MA) biosynthesis was studied by feeding ¹⁵N-ammonium sulfate, ¹⁴C-amino acids, and [1-¹⁴C, ¹⁵N]-methionine to iron-deficient barley roots ( Hordeum vulgare L. cv. Minorimugi), grown hydroponically. The incorporation of isotopes into amino acids was also examined. Methionine appears to be the most efficient precursor of the mugineic acid family (MAs) of phytosiderophores; homoserine was also incorporated into the MAs, but other amino acids such as glutamate, alanine, and γ-amino butyric acid did not act as precursors of MAs. Carbon-14 and ¹⁵N of methionine were incorporated into MAs. This specific incorporation of ¹⁴C and ¹⁵N indicated that the nitrogen atoms of MAs were derived from two molecules of methionine. It is suggested that deoxymugineic acid (DMA) is probably the first phytosiderophore to be synthesized on the biosynthetic pathway of MAs.     

The role of abscisic acid in the ripening of grapes

Ripening in grapes ( Vitis vinifera L. cv. Thompson seedless) was accompanied by an increase in the levels of sucrose, glucose and fructose and a decrease in the levels of acids. The activity of glucose-6-phosphatase and fructose-l–6-bisphospbatase was lower in sweet grapes as compared to sour ones. Abscisic acid (10⁻⁶ M) stimulated the gluconeogenic process in sour grapes. The levels of some gluconeogenic enzymes were also elevated in its presence. Cyclohexitnide (0.036–1.8 mM) nullified the abscisic acid effect, suggesting that this effect involves de novo protein synthesis. The incorporation of [¹⁴C]-leucine into proteins was enhanced about 80% by abscisic acid, confirming that abscisic acid promoted protein synthesis. Again, cycloheximide blocked the hormone mediated increase in the incorporation of radioactivity into proteins. The results indicate that one of the factors for sourness in certain mature ripe grapes may be that abscisic acid is not available.     

Phosphate transport in potato cuttings: Effect of gibberellic acid and abscisic acid

Apical cuttings of Solanum tuberosum L. cv. Sirtema were used al different stages of development to study long-distance transport of phosphate. The effects of two hormones, gibberellic acid (GA₃) and abscisic acid (ABA), on this process were also investigated. Before tuberization, phosphate (³²P) supplied to a single leaf was transported preferentially in the young and growing parts of the plant: apical bud, young leaves and roots. After tuberization, the tuber became the principal site of phosphate accumulation. GA³ treatment (10⁻⁴ M) of the tuber as well as of the leaves led to reduced transport of ³²P into the tuber. By contrast, treatment of the tuber with ABA (10⁻⁴M) did not change the ³²P distribution within the plant, while foliar spray with ABA greatly increased the transport into the tuber. The opposite effects of the two hormones on phosphate accumulation by tubers are discussed with regard to their opposite effects on the tuberization process.     

BIOCHEMICAL AND PHYSIOLOGICAL ASPECTS OF LEAF DEVELOPMENT IN COCOA (THEOBROMA CACAO)

The dormant phase of the flush cycle of leaf growth in cocoa is known to be correlated with high abscisic acid (ABA) levels in the mature leaves of the new flush (NF) and previous flush (PF) leaves. Defoliation of either the NF leaves or PF leaves of cocoa seedlings reduced the length of the dormant phase of the flush cycle, thus showing that the mature leaves were a source of growth inhibitors which could affect shoot apical activity. The application of ABA to the NF and PF leaves led to an extension of the dormant phase, whereas application of zeatin or gibberellic acid decreased it. The distribution of [¹⁴C]ABA following its application to NF and PF leaves at different stages throughout the growth cycle showed that [¹⁴C] ABA was accumulated by the bud in relatively larger amounts during the final stages of bud dormancy (I-1 and I-2) than in the earlier stage (F-2). The results suggest that internal competition for nutrients may be responsible for the inhibition of growth at the F-2 stage but that ABA translocated from the mature leaves causes the buds to remain dormant during the subsequent stages of I-1 and I-2.     

Translocation of photoassimilate from leaves of two popyploid genotypes of tall fescue differing in photosynthetic rates

The photosynthetic rate of a decaploid genotype (1-16-2) of tall fescue ( Festuca arundinacea Schreb.) is about twice that of a common hexaploid genotype (V6-802) (Plant Physiol. 72: 16–21, 1983). Translocation of photosynthate out of the leaves is a possible means of regulating carbon assimilation. To evaluate this possibility, we have examined a) translocation velocity, b) time course of translocation from leaves, c) photoassimilate partitioning pattern into whole plants in pulse and chase experiments, and d) interveinal distances between two ploidy genotypes. Most of the ¹⁴C accumulated in sucrose, and the labelled carbon moved down the leaf blades at similar velocities (6 to 10 cm h⁻¹) in both genotypes. Recent ¹⁴C assimilate was rapidly translocated from the fed area of the leaf blade. For example, the decaploid and the common hexaploid had translocated 40 and 26% of the ¹⁴C, respectively, at 6 h, and 79 and 49% of the ¹⁴C, respectively, at 24 h. Partitioning of ¹⁴C among plant organs was considerably different between the genotypes after a 24 h chase. For example, out of the total ¹⁴C recovered from the whole plant, the decaploid had retained 40% in the labelled leaf with 10, 33 and 29% in other leaves, stem bases and roots, respectively; whereas the hexaploid had retained 91% in the labelled leaf with 4, 3 and 2% in other leaves, stem bases and roots, respectively. However, the higher rate of translocation was correlated with greater interveinal distances in the decaploid genotype. These results suggested that the higher translocation percentage in the decaploid than the hexaploid genotype was due to greater sink activity.     

Effect of plant density on the uptake and distribution of 14C in the field bean, Vicia faba

Whole bean plants, ev. Cockfield, grown in pots crowded or well-spaced (50 or 10 plants m², respectively) were treated with ¹⁴CO₂ at the pod-fill stage (25 modes) and the radioactivity in each leaf was determined after 30 min. With spaced plants the uptake was greatest in the mid-stem leaves and was proportional to leaf area. In contrast, 70% of the total assimilation took place in the upper six leaves of crowded plants and there was a steady decrease down the stem.
When ¹⁴CO₂ was fed to single leaves of similar crowded plants the resultant distribution of labelled assimilates varied with the position of the treated leaf. After 6 h, 67% of the ¹⁴C fixed by a mid-stem leaf (node 13) was recovered from the beans, whereas 76% of that from an upper leaf (node 23) had accumulated along the stem. Due to the shading of mid-stem leaves at the higher planting densities, seed yield becomes increasingly dependent upon re-distribution of assimilates from stem to beans.     

An apparatus for pulse and pulse-chase experiments with 14CO2 on attached leaves with known, steady-state rates of photosynthesis

Abstract. An apparatus is described to carry out pulse and pulse-chase experiments with ¹⁴CO₂ on intact, attached leaves with known, steady-state rates of photosynthesis under defined conditions of temperature, vapour pressure deficit and photon flux density. Data are presented which show that the pattern of distribution of ¹⁴C between compounds in extracts of such leaves is a true reflection of the pathways of photosynthetic carbon metabolism in the leaf during steady-state photosynthesis.     

Mammalian cerebral metabolism and amino acid neurotransmission during hibernation

This report demonstrates that during the torpor phase of hibernation, hamsters utilize ¹⁴C and ¹³C glucose in torpor-specific brain metabolic pathways. Microdialysis of ¹⁴C glucose into the striatum rapidly induced a steady state labeling of extracellular fluid (ECF) lactate and labeling of tissue GABA, glutamate, glutamine, and alanine in ipsilateral and contralateral striata. The same tissue metabolites were labeled in cortex, hypothalamus, and brainstem after microdialysis of ¹⁴C lactate into the lateral ventricle. Serine, aspartate, glycine, taurine, tyrosine, and methionine were not synthesized from glucose or lactate during torpor. ECF levels of amino and organic acids were low and unchanging during torpor and increased late during arousal to cenothermia. Labeled intracellular ¹⁴C GABA and glutamate were not communicated to the striatal ECF or ventricular space during torpor. ¹³C NMR demonstrated rapid formation of lactate and functional tricarboxylic acid cycles in GABAergic and glutamatergic neurons, and enrichment of glutamine and alanine after i.v. ¹³C glucose. Large changes in tissue levels of amino acids occur prior to or during entrance into torpor but not during torpor. It is proposed that cerebral intracellular dehydration, the enlargement of ECF and the biochemistries associated with brain water homeostasis may have a role in regulating hibernation.     

Pathway and regulation of phosphate translocation to the pods of soybean explants

We investigated the degree to which developing fruit compete directly with leaves for mineral nutrients, e.g. phosphate coming up from the roots. When soybean ( Glycine max (L.) Merrill cv. Anoka) explants cut at mid-late podfill were given a 15-min pulse of ³²Pi via the cut stem and then transferred to distilled water, 75% of the ³²P accumulated in the leaves and 21% in stem and petiole during the first hour. The amount of ³²P entering the seeds was low (1%) initially, but thereafter increased to 30% in 48 h. An accumulation of ³²P in the seed coats preceded its entry into the embryos. Disruption (with hot steam) of the phloem between the leaf and the pods after pulse labelling indicated that more than 80% of the ³²Pi pulse moved to the leaf before redistribution to the pods. Increasing "sink" size by adjusting the pod load from 1 to 2–3 did not increase the ³²P accumulated by the pods proportionally. Conversely, excision of the seeds after pulse labelling did not prevent translocation of ³²P out of the leaves. These results suggest that the rate of transport of phosphate to the pods at mid-late podfill is controlled primarily by factors in the leaves. The results are consistent with the observation that the relative size of the sink (pod load) does not regulate leaf senescence.