Sugar Transport in Immature Internodal Tissue of Sugarcane: II. Mechanism of Sucrose Transport

The mechanism by which sucrose is transported into the inner spaces of immature internodal parenchyma tissue of sugarcane (Saccharum officinarum L. var. H 49-5) was studied in short term experiments (15 to 300 seconds). Transport of sucrose, glucose, and fructose was each characterized by a V_max of 1.3 μmoles/gram fresh weight·2 hours, and each of these three sugars mutually and competitively inhibited transport of the other two. When ¹⁴C-glucose was supplied exogenously, ¹⁴C-glucose 6-phosphate and ¹⁴C-glucose were the first labeled compounds to appear in the tissue; no ¹⁴C-sucrose was detected until after 60-second incubation. After 15-second incubation in ¹⁴C-sucrose, all intracellular radioactivity was in glucose, fructose, glucose 6-phosphate, and fructose 6-phosphate; trace amounts of ¹⁴C-sucrose were found after 30 seconds and after 5 minutes, 71% of the intracellular radioactivity was in sucrose. Although it was possible that sucrose was transported intact into the inner space and then immediately hydrolyzed, it was shown that the rate of hydrolysis under these conditions was too low to account for the rate of hexose accumulation. Pretreatment of the tissue with rabbit anti-invertase antiserum eliminated sucrose transport, but had no effect on glucose transport. Since the antibodies did not penetrate the plasmalemma, it was concluded that sucrose was hydrolyzed by an invertase in the free space prior to transport. The glucose and fructose moieties, or their phosphorylated derivatives, were then transported into the inner space and sucrose was resynthesized. No evidence for the involvement of sucrose phosphate in transport was found in these experiments.     

Sucrose translocation and storage in the sugar beet

Several physiological processes were studied during sugar beet root development to determine the cellular events that are temporally correlated with sucrose storage. The prestorage stage was characterized by a marked increase in root fresh weight and a low sucrose to glucose ratio. Carbon derived from ¹⁴C-sucrose accumulation was partitioned into protein and structural carbohydrate fractions and their amino acid, organic acid, and hexose precursors. The immature root contained high soluble acid invertase activity (V_max 20 micromoles per hour per milligram protein; K_m 2 to 3 millimolar) which disappeared prior to sucrose storage. Sucrose storage was characterized by carbon derived from ¹⁴C-sucrose uptake being partitioned into the sucrose fraction with little evidence of further metabolism. The onset of storage was accompanied by the appearance of sucrose synthetase activity (V_max 12 micromoles per hour per milligram protein; K_m 7 millimolar). Neither sucrose phosphate synthetase nor alkaline invertase activities were detected during beet development. Intact sugar beet plants (containing a 100-gram beet) exported 70% of the translocate to the beet, greater than 90% of which was retained as sucrose with little subsequent conversions.     

Tissue specificity of assimilation and transport of nitrogen in the root ofZea mays L. seedlings. I. Transformations of14C- sucrose and the nitrogen metabolism enzymes in cortex and stele

An investigation has been carried out to find out in what compounds carbon is radially transported from stele to the cortex and to study sucrose metabolism in the root. These tissues were fed with¹⁴C-sucrose either directly or through the mesocotyle. In the latter case, the bulk of radioactivity, both in the stele and cortex, was concentrated in sucrose rather than in mono saccharides. This corresponds to the radial transport of carbon from stele to cortex predominantly in the form of sucrose. In the case of a direct exposure of stele and cortex,¹⁴C-sucrose was utilized for respiration, amino acid biosynthesis, and accumulation of carbon in the form of glucose. The hydrolysis of sucrose to the monosaccharides and subsequent utilization of the latter in respiration was more intensive in the stele. In the cortex, the sucrose carbon was more actively used for amino acid synthesis, owing to a high concentration of nitrate reductase, glutamate dehydrogenase and glutamine synthetase. It was concluded that the cortex is the main issue zone providing nitrogen assimilation in the root.     

Carbon metabolism of micropropagatedRosa multiflora L.

Summary To quantify the C-metabolism in micropropagated roses, two labeled substrates were tested:¹⁴C-sucrose and¹⁴CO₂. In the¹⁴C-sucrose experiment four parameters were followed during the culture period: the decrease of the radioactivity of the culture medium (by liquid scintillation counting), the dry matter accumulation, the radioactivity of the dry matter, and the radioactivity of the captured CO₂. These values were related to the total sucrose uptake, the total biomass increase, the biomass increase by sucrose incorporation, and the sucrose respired as CO₂. C-incorporation during photosynthesis was calculated as the difference between total biomass increase and biomass increase by sucrose incorporation. The¹⁴CO₂ experiment did not allow measurement of the net CO₂ fixation in a direct way because the ratio of¹⁴CO₂ over total CO₂ in the headspace of the container could not be kept constant over the culture period. Respiration caused a build up of the CO₂ concentration in the headspace. Indirect calculation established a comparable photosynthetic portion of CO₂ uptake for the tested variety. Presented in the Session-in-Depth Transition of Plants From Cultures to Establishment In Vivo at the 41st Annual Meeting of the Tissue Culture Association, Houston, Texas, June 10–13, 1990.     

Evidence for thiol-induced enhanced in situ translocation of 14C-sucrose from source to sink in Brassica juncea

The translocation of ¹⁴C-sucrose to the different parts of the mustard (Brassica juncea) crop has been evaluated in the context of understanding the source to sink relationship in the thiol-induced enhanced crop yield. The foliar application of thiols like TU, TGA and DTT to the plant gave maximum sucrose phosphate synthase activity, which was found to have direct correlation with the movement of sucrose. The distribution pattern of ¹⁴C-sucrose follows the path from internode and node to pod via leaf. The translocation of ¹⁴C-sucrose was found to be a light dependent process. Among the nucleotides ATP and GTP, only ATP was able to promote the translocation and GTP was ineffective. In this unique in situ tracer experiment using ¹⁴C-sucrose, we could establish that thiols are able to enhance the translocation of sucrose from source to sink.     

Evidence for thiol-induced enhanced in situ translocation of 14C-sucrose from source to sink in Brassica juncea

The translocation of ¹⁴C-sucrose to the different parts of the mustard (Brassica juncea) crop has been evaluated in the context of understanding the source to sink relationship in the thiol-induced enhanced crop yield. The foliar application of thiols like TU, TGA and DTT to the plant gave maximum sucrose phosphate synthase activity, which was found to have direct correlation with the movement of sucrose. The distribution pattern of ¹⁴C-sucrose follows the path from internode and node to pod via leaf. The translocation of ¹⁴C-sucrose was found to be a light dependent process. Among the nucleotides ATP and GTP, only ATP was able to promote the translocation and GTP was ineffective. In this unique in situ tracer experiment using ¹⁴C-sucrose, we could establish that thiols are able to enhance the translocation of sucrose from source to sink.     

14C-sucrose uptake by internode tissue

The transport and accumulation of ¹⁴C activity in decapitated, non-growing internodes of Phaseolus vulgaris L following application of ¹⁴C-sucrose or ¹⁴CO₂ is stimulated by application of auxins, cytokinins and gibberellins. The possibility that these hormone-directed effects may be mediated by stimulating the metabolism or storage of ¹⁴C-sucrose (i.e. by increasing sink demand) in the ground tissues of the stem was studied by investigations into the kinetics of ¹⁴C-sucrose uptake by thin slices of internode tissue of tomato and P. vulgaris. Sucrose uptake appears to be a carrier-mediated process, requiring active cell metabolism, and is shown to be stimulated by fusicoccin but not by indol-3yl-acetic acid (IAA). IAA only stimulates ¹⁴C-sucrose accumulation when long-distance transport is involved and it is suggested that IAA acts by stimulating the unloading of sucrose via an apoplastic pathway.     

Fructosyl Transfer between 1-Kestose and Sucrose in Wheat Leaves

The labeling pattern of the sugar moieties of 1-kestose after in vivo pulse labeling with ¹⁴CO₂ was not the same as that after in vitro labeling with ¹⁴C-sucrose. The two fructosyl residues of 1-kestose had similar specific radioactivities after in vitro synthesis, but after in vivo radiolabeling the specific radioactivity of the terminal fructosyl moiety was significantly less than the internal fructosyl moiety. Evidence is presented that the uneven specific radioactivity of in vivo radiolabeling results from enzymatic transfer of terminal fructosyl residue from 1-kestose to sucrose.     

Effects of Ethylene and Sucrose on Translocation of Dry Matter and 14C-Sucrose in the Cut Flower of the Glasshouse Carnation (Dianthus caryophyllus) During Senescence

The translocation and distribution of dry matter were studiedin the floral and vegetative parts of the cut carnation duringsenescence. The change in dry weights of the tissues and theamount of radioactivity recovered from them after feeding with¹⁴C-sucrose were measured. Treatments with ethylene and sucrosewere used to alter the rate of senescence of the flowers. Sucrosemoved through the stem relatively unchanged but was rapidlyinverted and metabolized in the petals. During natural ageing,¹⁴C moved from the stem to the flower and the movement was enhancedby exogenous sucrose, which also reduced the loss of dry matterin the petals and promoted their growth. Treatment with ethylenecaused petals to wilt and lose dry weight, and ovaries to enlargeand increase in dry weight. The distribution of radioactivityin flowers fed with 14C-sucrose before and after ethylene treatmentsupported the observation that dry matter was translocated betweenthe flower parts. The results indicate that a change in thesource-ink relationships of the flower parts contributes tothe factors that determine the rate of flower senescence.     

RADIOAUTOGRAPHY OF CHOLESTEROL IN LUNG : An Assessment of Different Tissue Processing Techniques

30 Swiss albino mice aged 8 days were injected intraperitoneally with 0.2 ml of a solution of 4% N,N-dimethyl-formamide in 5% dextrose in water containing cholesterol-1,2-³H (~1 mCi/ml). Lung tissue was embedded in an Epon mixture after either acetone and propylene oxide dehydration, partial ethanol and Epon 812 dehydration, or the precipitation of cholesterol by digitonin succeeded by partial dehydration. The distribution of cholesterol-1,2-³H in lung parenchyma in 1µ Epon section radioautograms was compared with that in frozen section radioautograms and was found to be independent of the manner of tissue processing. Grain distribution in the tissue was essentially the same whether 16, 63, 93, or 100% radioactivity was retained in the lung. However, grain distribution in the alveolar spaces differed, presumably due to displacement of pulmonary surfactant, which contains cholesterol. Intracellular distribution of cholesterol, in electron microscope radioautograms, was the same with either 51% or 93% retention of radioactivity in the lung. Loss of radioactivity into the various processing solutions was monitored. The various processing techniques have different drawbacks.     

Long distance translocation of sucrose, serine, leucine, lysine, and carbon dioxide assimilates: I. Soybean

To determine the selectivity of movement of amino acids from source leaves to sink tissues in soybeans (Glycine max [L.] Merr. `Wells'), ¹⁴C-labeled serine, leucine, or lysine was applied to an abraded spot on a fully expanded trifoliolate leaflet, and an immature sink leaf three nodes above was monitored with a GM tube for arrival of radioactivity. Comparisons were made with ¹⁴C-sucrose and ¹⁴CO₂ assimilates. Radioactivity was detected in the sink leaf for all compounds applied to the source leaflet. A heat girdle at the source leaf petiole essentially blocked movement of applied compounds, suggesting phloem transport. Transport velocities were similar (ranged from 0.75 to 1.06 cm/min), but mass transfer rates for sucrose were much higher than those for amino acids. Hence, the quantity of amino acids entering the phloem was much smaller than that of sucrose. Extraction of source, path, and sink tissues at the conclusion of the experiments revealed that 80 to 90% of the radioactivity remained in the source leaflet. Serine was partially metabolized in the transport path, whereas lysine and leucine were not. Although serine is found in greater quantities than leucine and lysine in the source leaf and path of soybeans, applied leucine and lysine were transported at comparable velocities and in only slightly lower quantities than was applied serine. Thus, no selective barrier against entry of these amino acids into the phloem exists.     

Heat stress effects on sink activity of developing maize kernels grown in vitro

The objective of this study was to determine the effect of short-term (4 days) and long-term (8 days) heat stress (35°C) on sink activity of maize (Zea mays L.) kernels. Beginning at 3 days after pollination (DAP) kernels were grown in vitro at 25°C and 24 h later were transferred to 35°C for either 4 or 8 days. Each treatment had a control that was maintained continously at 25°C. Two experiments were designed to examine the uptake and distribution of ¹⁴C among hexoses, sucrose and starch in the pedicel placento-chalazal (pedicel/p-c). endosperm, and pericarp tissues of kernels exposed to heat stress for 4 or 8 days. Kernels cultured in vitro were placed in ¹⁴C-sucrose medium either during the period of heat stress (experiment 1; 5 to 13 DAP) or immediately following heat-stress treatments (experiment 2; 10 to 22 DAP). In both experiments no significant effect of heat stress was observed on the total radioactivity accumulated in the kernels until about 17 DAP, after which heat-stressed kernels accumulated less ¹⁴C than the control. During the linear fill period, the endosperm of kernels exposed to heat stress accumulated more radioactivity associated with hexoses and sucrose and less radioactivity incorporated into starch, as compared to the control. Kernels heat stressed for 4 days showed a partial recovery in starch synthesis by 21 DAP, but to levels of only 65% of that of the control. Kernels heat stressed for 8 days did not recover. When ¹⁴C-sucrose was supplied during the heat stress period (5–13 DAP). kernels from all treatments accumulated more hexoses that sucrose in the pedicel/p-c. However, during the period following heat stress (10–22 DAP), pedicel/p-c accumulated sucrose, but only in kernels exposed to long-term heat stress. Soluble invertase activity was inhibited by both short-term and long-term heat stress, whereas the activity of insoluble invertase was affected only by long-term heat stress. These results support the hypothesis that the disruption of kernel growth and more particularly endosperm starch biosynthesis, in response to heat stress, is mainly associated with changes in carbon utilization and partitioning between the different nonstructural carbohydrates within the endosperm rather than with a limitation in carbon supply to the kernel. Therefore, the effect on sink activity does not seem to be attributable to a thermal disruption of kernel uptake of sugars, but rather it is a consequence of heat perturbation of other physiological processes such as endosperm sugar metabolism and starch biosynthesis.     

SUCROSE-INDOLE-3-ACETIC ACID INTERACTIONS ON ROOT REGENERATION BY PINUS LAMBERTIANA EMBRYO CUTTINGS

Interactions affecting root formation by IAA and sucrose, supplied to Pinus lambertiana embryo cuttings through their cotyledons, were explored. The sucrose optimum for rooting and dry weight increase is approximately 8 %. Osmotic substitutes for sucrose, applied alone or concomitantly with sucrose, were unable to duplicate its effects on regeneration. One μM IAA increased the number of roots per cutting with all sucrose concentrations. However, with suboptimal sucrose concentrations it only increased the total number of cuttings forming roots. Because IAA accumulates at the site of root formation, the possibility that it mobilizes sucrose or its derivatives to the site of root formation was explored. No evidence was found for hormone-directed transport of sucrose in this system. IAA had no effect on either the basal accumulation or transport of label derived from U-¹⁴C-sucrose.     

Evidence for Phloem loading from the apoplast: chemical modification of membrane sulfhydryl groups

The water-soluble, sulfhydryl-specific, chemical modifier p-chloromercuribenzenesulfonic acid reversibly inhibited the accumulation of exogenously supplied ¹⁴C-sucrose into leaf discs of Beta vulgaris. P-Chloromercuribenzenesulfonic acid treatment did not inhibit photosynthesis or respiration or induce membrane leakage to sucrose, indicating that the site of inhibition was the plasmalemma. The active loading of sucrose and ¹⁴CO₂-derived assimilates into the phloem and their translocation from the source leaf were inhibited by the nonpermeant modifier. Several nonpermeant sulfhydryl group modifiers also inhibited sucrose accumulation into leaf discs while two amino-reactive reagents had no effect. The results indicate that sugars are actively accumulated into the phloem from the apoplast and that membrane sulfhydryl groups may be involved.     

Osmotic Effects on Membrane Permeability in a Marine Bacterium

When cells of Alteromonas haloplanktis 214 (ATCC 19855) were preloaded with α-[¹⁴C]aminoisobutyric acid or the K⁺ in the cells was labeled with ⁴²K by incubation in a buffered salt solution containing 0.05 M MgSO₄, 0.01 M KCl, and 0.3 M NaCl, the cells retained their radioactivity when resuspended in the same salt solution. When NaCl was omitted from the solution, 80 to 90% of the radioactivity was lost from the cells. Cells suspended at intermediate concentrations of NaCl also lost radioactivity. New steady-state levels of the intracellular solutes were established within 15 s of suspending the cells; the percentage of radioactivity retained at each level decreased proportionately as the osmolality of the NaCl in the suspending solution decreased. With minor variations in effectiveness, MgCl₂, LiCl, and sucrose could substitute for NaCl on an equiosmolal basis for the retention of radioactivity by the cells. KCl, RbCl, and CsCl were appreciably less effective as replacements for NaCl, particularly when their osmolalities in the suspending solutions were low. The amount of α-[¹⁴C]aminoisobutyric acid taken up by the cells at the steady-state level increased to a maximum as the NaCl concentration in the suspending medium increased to 0.3 M. At suboptimal levels of NaCl, either LiCl or sucrose could substitute for NaCl in increasing the steady-state levels. The results obtained indicate that the porosity of the cytoplasmic membrane of this organism is determined by the difference between the osmotic pressure of the cytoplasm and the suspending medium. The lesser effectiveness of K⁺, Rb⁺, and Cs⁺ than Na⁺, Li, or Mg²⁺ in permitting the retention of solutes by the cells is attributed to the greater penetrability of the hydrated ions of the former group through the dilated pores of a stretched cytoplasmic membrane.     

The Uptake of Surcrose and its Conversion to Starch in Detached Ears of Wheat

Detached ears of wheat were cultured on solutions of ¹⁴C-sucroseand the distribution of carbon-14 in the ear was followed. Within 8 h radioactive sucrose was found in all the tissuesof the cultured ear, and considerable amounts of carbon-14 hadaccumulated in other ethanol-soluble compounds. Carbon-14 accumulatedrapidly in the starch deposited in the endosperm, but littlewas found in the starch of the pericarp, or in other materialinsoluble in ethanol in the vegetative organs. During 48 h the specific radioactivity of the sucrose in theendosperm increased in a hyperbolic pattern and was equal tothat of the starch produced. Carbon-14 in the glucose and fructoseaccumulated more slowly and in a Linear fashion. Experiments with sucrose containing carbon-14 in both moietiesequally, or in the fructosyl moiety exclusively, confirmed thatboth moieties are converted into starch and at about the samerate. As sucrose in endosperm provided with asymmetric sucroseretained a considerable degree of asymmetry, it seems as thoughinversion is not a necessary step in the transport of sucroseinto the grain. In ears provided with ¹⁴C-sucrose at 30 mg ml^–1 the rateof accumulation of ¹⁴C-sucrose in the culm, rachis, and floralorgans was about 0.6 times the value at 50 mg ml^–1. However,in the sucrose of the endosperm, and in the starch depositedthere, the rates of accumulation of carbon-14 from both levelswere identical. This finding supports the concept that the transportof sucrose is limited during the final stages of its passageinto the grain.     

Metabolism of C-arachidonate in rat isolated lung

Metabolism of ¹⁴C-arachidonate was investigated in rat isolated lungs perfused via the pulmonary circulation with Krebs solution. Only 10% of the radioactivity derived from an infusion of ¹⁴C-arachidonate through the pulmonary circulation of rat isolated lungs appeared in the effluent by 10 minutes. At 10 min, the major component of effluent radioactivity and 20–40% of that retained in lung was unchanged arachidonate. Between 10 and 20 min of perfusion, a further small amount of radioactivity was lost in lung effluent and at 20 min the retained radioactivity showed a decrease in the proportion present as free arachidonate. Between 20 and 60 min, there was no further loss of radioactivity in effluent and no further change in the distribution in lung. Addition of albumin to the Krebs solution perfusate during the infusion of ¹⁴C-arachidonate increased effluent radioactivity to 80%, but albumin added after 10 min only caused the efflux of a small amount of radioactivity (10%). Treatment of labelled lung at 20 min with the calcium ionophore A23187 released biologically active metabolites of arachidonate but very little radioactivity. Metabolism of arachidonate, either during the infusion or after retention in lung, in rat lung was closer to that in human lung than to that in guinea-pig lung.     

Metabolism of 14C-arachidonate in rat isolated lung

Metabolism of ¹⁴C-arachidonate was investigated in rat isolated lungs perfused via the pulmonary circulation with Krebs solution. Only 10% of the radioactivity derived from an infusion of ¹⁴C-arachidonate through the pulmonary circulation of rat isolated lungs appeared in the effluent by 10 minutes. At 10 min, the major component of effluent radioactivity and 20–40% of that retained in lung was unchanged arachidonate. Between 10 and 20 min of perfusion, a further small amount of radioactivity was lost in lung effluent and at 20 min the retained radioactivity showed a decrease in the proportion present as free arachidonate. Between 20 and 60 min, there was no further loss of radioactivity in effluent and no further change in the distribution in lung. Addition of albumin to the Krebs solution perfusate during the infusion of ¹⁴C-arachidonate increased effluent radioactivity to 80%, but albumin added after 10 min only caused the efflux of a small amount of radioactivity (10%). Treatment of labelled lung at 20 min with the calcium ionophore A23187 released biologically active metabolites of arachidonate but very little radioactivity. Metabolism of arachidonate, either during the infusion or after retention in lung, in rat lung was closer to that in human lung than to that in guinea-pig lung.     

The translocation of photosynthetic products from mesophyll into midrib in tobacco plant III. The transformation of translocated 14C-sugars in the veins

¹⁴C-U-sugars were introduced into tobacco plants through themesophyll, the veins of the first order of branching, and themidrib, and ¹⁴C-compounds in the veins and the midrib whichtranslocated towards the base of the midrib were traced duringthe period of 120 min after the ¹⁴C-sugar introductions. 1) When ¹⁴C-U-sucrose was introduced into the leaf, no matterwhat the means of feeding was, most of the ¹⁴C which translocatedbasipetally in the veins and the midrib was found in the formof sucrose. 2) When ¹⁴C-U-glucose or ¹⁴C-U-fructose was administered tothe leaf dirough the cut vein of the first order of branching,most of the ¹⁴C which translocated basipetally in the veinsand the midrib was found in the form of sucrose. 3) ¹⁴C-U-glucose or ¹⁴C-U-fructose injected into the vascularbundles of the midrib was translocated basipetally, as such,10 and 30 min after injection; and at 30 min, the amount ofthe ¹⁴C-sucrose in the midrib attained 9–22% of the 80%ethanol-soluble ¹⁴C in the midrib. 4) When ¹⁴C-U-glucose or ¹⁴C-U-fructose was supplied to themesophyll, the radioactivities of these hexoses were predominantin the first and second veins soon after application, then decreasingwith a concomitant increase in the radioactivity of the ¹⁴C-sucrose. From these results, it was inferred that in the veins of thefirst and second order of branching, glucose and fructose whichmoved from the mesophyll did not translocate as such, but wereutilized for the synthesis of sucrose available for translocationvia the midrib to the stem. ¹A part of this paper was presented at the Crop Science Societyof Japan, in April, 1969 (Received December 8, 1969; )     

The Role of Phloem Transport in the Translocation of Sucrose Along the Stem of Carnation Cut Flowers

The pathway and distribution of ¹⁴C-sugars in flower parts havebeen examined to find out in which tissue sugars are translocatedin the stem of the cut carnation; ¹⁴C-sucrose or ¹⁴C-glucosewas supplied at the base of the cut stem from a feeding solutionand the localization and chemical nature of the carbon-14 recoveredfrom flower parts were investigated. By reducing the rate oftranspiration it was found that the uptake of feeding solutionwas also reduced, but the distribution of absorbed ¹⁴C-sucrosein the flower parts was different from that which would be expectedif sucrose moved exclusively in the transpiration stream. Autoradiographsdemonstrated that ¹⁴C absorbed from the feeding solution as¹⁴C-sucrose appeared in both xylem and phloem but predominantlyin the latter; girdling failed to stop the translocation ofthe absorbed ¹⁴C-sucrose. Results of experiments with ¹⁴C-sucroseand ¹⁴C-glucose showed that sucrose was the mobile sugar andthat glucose was converted to sucrose before it was translocated.It was concluded that the translocation of sucrose absorbedfrom the feeding solution takes place both in xylem and phloemand is regulated by a mechanism involving the loading and translocationof sucrose in the phloem.