Translocation of 14C-assimilates in roses

The upper shoot on decapitated rose branches ( Rosa hybrids cv. Marimba) grows faster than lower shoots on the same branch. Transport of radioactive assimilates to the upper shoot is higher than to the lower ones. Darkening of the uppermost shoot resulted in the reduction of growth and ^I4C-assimilate accumulation in the darkened shoot as well as the promotion of growth and ¹⁴C transport to the lower 2 shoots, thereby rendering dominance to the second shoot. Benzyladenine treatment to the uppermost shoot reversed the effect of darkening and restored the apical control of this shoot.     

Translocation of 14C-dieldrin from small droplets on cotton leaves

Dieldrin (HEOD) spread from dried residues formed from droplets of emulsions and crystalline suspensions applied to the upper surfaces of cotton leaves (Gossypium species). The amounts of radiolabelled insecticide reaching defined areas of leaf-surface bearing adhesive tape (Sellotape) were measured quantitatively by scintillation counting. Autoradiography supported these results in demonstrating the extent of insecticide movement in the leaf. Up to one-fifth of the applied dose spread more than 8 mm across the leaf surface within a day (lateral movement). Penetration to the lower surface (vertical movement) took place within 4 days, depending on the leaf thickness, which itself was greatly affected by the growing conditions. During this process some dieldrin formed a derivative, possibly a hydroxydieldrin, and some was sorbed at the sites of the lysigenous secretory glands within the leaf. Dieldrin spreads from a deposit (representing that left by a spray droplet) on cotton leaf in all directions to a greater extent and more rapidly than previously supposed.     

Translocation of 14C-labelled assimilates in cabbage during club root development

The effects of infection of root systems by Plasmodiophora brassicae on the translocation of ¹⁴C-labelled assimilates from the first and third leaves of cabbage seedlings were investigated. During the early phases of Plasmodium development, there were small differences in the distribution patterns of ¹⁴C-labelled assimilate between healthy and infected seedlings. At the end of growth of plasmodia and during resting spore formation, both first and third leaves exported more assimilates than corresponding leaves of healthy seedlings. When the infected roots were dissected into various regions after exposure of the fed leaves to ¹⁴CO₂, more assimilate accumulated in the club root region than in any other part.     

Interaction between K-Deficiency and Light in 14C-Sucrose Translocation in Bean Plants

The effect of K deficiency on sucrose transport was studied in bean plants from which the cotyledons had been removed soon after germination and which were subsequently grown in culture solution. Labelled sucrose wassupplied to the primary leaf. Mild Kdeficiency depressed translocation. A statistically significant interaction between the presence of K and light was observed. K deficiency had no effect on translocation if the plants had been placed in the dark before the experiment and remained in the dark during the translocationperiod. Maximum correction for differences in the specific activity of the sugar being translocated, as between control and K-deficient plants (based on sugar analyses in various plant parts), failed to abolish the K effect when the amount of sugar applied was relatively low (high specific activity). On the other hand no effect of K-deficiency was observed on translocation when the amount of applied sugar was high (low specific activity). In this case ¹⁴CO₂ fixation was greatly reduced in the controls, but not in the K-deficient plants. Significant interaction existed between added sugar and K-deficiency on ¹⁴CO₂ fixation. All results reported here can be explained on the basis of a scheme whereby K plays a rôle in reversible intermediate steps between sugar formation in the chloroplast and the entry of this photosynthesised sugar into the “translocation pool” where it mixes with exogenous sugar.     

^14CO2 Fixation and Translocation of Photoassimilates as Selection Criteria of Egyptian Taro Genotypes

The growth characterlstlcs, different physlological parameters, photosynthetic activity （^14CO2 fixation）, and the translocatlon rate of photoassimllates In different taro （Colocasia esculenta L. Schott） genotypes was studled In order to determlne the posslble use of these parameters as selectlon crlterla for dlfferent wldely used genotypes of taro （Delta No. 9, 15, 20, 21, and balady）. The results obtalned suggest that Delta No. 21 shows the most slgnlflcant increase In all parameters tested compared wlth the control （balady）, followed by Delta No. 9, 15, and 20, respectively. The results show a positive correlation between photosynthetlc actlvlty, translocatlon efflclency, and total yield. The selected clone Delta No. 21 Is recommended for cultlvatlon In the delta reglon of Egypt.     

The Effects of Benzylaminopurine on Growth and 14Carbon Translocation in Excised Mustard Cotyledons

When localized areas of blades of recently excised mustard cotyledons were fed with ¹⁴CO₂ it was found that the fixation products passed rapidly into the veins and then were translocated to the petiole. Since other cotyledons similarly treated subsequently rooted at the petiole base, this suggested that it acted as a sink for assimilates. Treatment of excised cotyledons with benzylaminopurine (BAP) resulted in the enhancement of blade growth and the suppression of root initiation and development. Quantitative determinations of labelled assimilate in both the cotyledon blade and the terminal 2 mm portion of the petiole were made. It was found that cotyledons treated with BAP at a concentration high enough to suppress completely root initiation had a higher level of radioactivity in the petiole base than the terminal segments in untreated petioles, whether expressed as specific activity or as a percentage of the total radiocarbon fixed. BAP-treated cotyledons also fixed consistently higher levels of ¹⁴CO₂, probably due to an increase in photosynthetic area. The results suggest that BAP alters the pattern of differentiation at the base of the petiole rather than the polarity of movement of assimilates to the petiole base.     

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 Sodium and Calcium on the Translocation of 14C-sucrose in Excised Cotton Roots

The effect of sodium and calcium on the translocation of ¹⁴C-sucrose in excised cotton roots (Gossypium birsutum) was studied. The roots were allowed to elongate in a modified Guinn's medium that was very low in calcium (6.25 × 10^?2 mM) and sodium (8.70 × 10^?3 mM). After a period of six days the roots were transferred to 20 × 100 mm Petri dishes that contained 10 × 40 mm Petri dishes as center wells. The roots were draped over the edge of the center well and extended into the outer dish. The outer Petri dish and its center well contained the same solution except that sucrose was supplied only in the center well. The sucrose used was spiked with uniformally labeled ¹⁴C-sucrose. Four treatments were started which varied in their Na and Ca content. Three and six day harvests were taken and the amount of ¹⁴C that had moved from the distal (in the center well) to the apical root section (in the outer dish) was determined. Increasing substrate Na or Ca caused an increase in ¹⁴C-sucrose translocation and the effects of both ions were additive by the final harvest. These results were found to be independent of treatment effects on growth and respiration of the excised roots. These data support the conclusion that Na may partially substitute for Ca in carbohydrate translocation. Thus, roots supplied the Low Ca-High Na and High Ca-Low Na treatments had equal translocation rates over a six day period. The highest translocation rate was obtained with the High Ca-High Na treatment. Data from the High Ca-High Na treatment on two successive three day periods indicate that Na may have a role in translocation other than that associated with substitution for Ca, or maintenance of tissue hydration.     

Tracer studies of gas circulation in Nuphar: 18O2 and 14CO2 transport

The objective of this study was to investigate the behaviour of different legumes against salinity and water stress, thus trying to discover simultaneous adaptations to both stresses. The nitrogen fixation, transpiration, predawn leaf water potential, and stomatal response of Medicago sativa L. (cvs. Tierra de Campos and Aragon), Trifolium repens L. (cv. Aberystwyth S-184) and T. brachycalycinum Katzn. et Morley (= T. subterraneum L. cv. Clare) were compared at three levels of stress (0.05, 0.3 and 0.5 MPa of either NaCl or polyethylene glycol 6000) in nutrient solution. The plants were stressed for three days and then returned to control nutrient solution. The changes in the parameters analyzed were dependent on the proportion of stress treatments and the nature of the species, always being greater in plants from PEG than from NaCl solutions. Transfer of lucerne and subclover plants from NaCl at 0.05 MPa to a non-saline medium resulted in an increase of nitrogen fixation above the level of the non-salinized control plants, especially significant in lucerne. Analysis of possible inorganic impurities in commercial PEG suggest that such type of impurities are not responsible for the toxic effects reported. Plant damage resulting from PEG treatment was apparently due to penetrations of PEG (as determined qualitatively by using the tetraiodinebismuthic acid technique) or low-molecular organic impurities into the plant. – The results are discussed as part of the adaptation of the different species to salinity and water stress. The best performance was given by "Tierra de Campos".     

Production of [14C]Acetylcholine and [14C]Carbon Dioxide from [U–14C]Glucose in Tissue Prisms from Aging Rat Brain

Abstract: Production of [¹⁴C]acetylcholine and ¹⁴CO₂ was examined by using tissue prisms from neocortex, hippocampus, and striatum from rats aged approximately 5 months, 13 months, and 27 months. [¹⁴C]Acetylcholine synthesis in the striatum showed highly significant decreases with age for measurements in the presence of both 5 m m - and 31 m m -K⁺, contrasting with the lack of significant change in ¹⁴CO₂ production in this region. The neocortex and hippocampus showed only small changes, especially when comparison was made between 13-month and senescent animals. Measurements of the release of [¹⁴C]acetylcholine and influence of atropine on this release confirmed the relative stability with age of the cholinergic system in the neocortex.     

Distribution of Soluble 14C-Labelled Assimilates as Related to Distribution of 14C-Benzyladenine in Shoot Tips of Hedera helix

The relationship between benzyladenine and assimilate distributions in shoot tips of English Ivy (Hedera helix L.) was studied. Exogenous applications of benzyladenine resulted in small amounts of the hormone moving to the apical meristem. The large part of the recovered benzyladenine was found in the young leaves of the shoot tip. Benzyladenine increased the amount of ¹⁴C-labelled assimilates in the shoot tip, but the distribution pattern of those assimilates within the tip was like that of the untreated control.     

Transport of Kinetin-814C in Petioles

Several differences in the translocation pattern of radioactive kinetin in plant petioles were determined. Radioactivity from kinetin-8-¹⁴C (Kn*) moved from donor agar blocks through petioles of bean and cocklebur but not of cotton. There was no difference in basipetal or acropetal movement of radioactivity from Kn* in cocklebnr petioles, but there was in bean petioles. In bean petioles this movement was preferentially basipetal, but it was influenced by the age of the petiole and by the presence of added indoleactic acid. The combination treatment accelerated the basipetal movement of radioactivity from Kn* in young bean petioles and not in old ones. All data is based on radioactivity translocated into receiver agar blocks which were assayed individually in a liquid scintillation spectrometer. The results show that plant species, direction of transport, age of tissue, and presence of IAA can all influence the translocation of Kn* in petioles.     

14C Translocation pathways in honeylocust and green ash: Woody plants with complex leaf forms

Long-distance transport in plants requires precise knowledge of vascular pathways, and these pathways differ among species. This study examines the ¹⁴C translocation pathways in honeylocust (Gleditsia triacanthos L.) and green ash (Fraxinus pennsylvanica Marsh.), species with compound leaves, and compares them with those of cottonwood (Populus deltoides Bartr. ex Marsh.), a species with simple leaves. The stem vasculature of honeylocust conforms to a 2/5 helical phyllotaxy and that of green ash to a decussate phyllotaxy. The plastochron is relatively long in both species – 2.5+ days in honeylocust and 4.5+ days in green ash. Consequently, the transition from upward to downward translocation from mature source leaves is abrupt and occurs close to the apex. Export of ¹⁴C from localized treatment positions within a leaf was found to vary both quantitatively and spatially. To determine export patterns, ¹⁴CO₂ was administered to either individual leaflets of once-pinnate or pinnae of bipinnate leaves of honeylocust, and to either individual veins of simple or leaflets of compound leaves of green ash. Transections of either the petiole or rachis base were then examined for ¹⁴C by micro-autoradiography. In all cases, as treatment positions advanced acropetally in the leaves, the bundles translocating ¹⁴C were situated more dorsally in the basal petiole and rachis vasculatures. ¹⁴C was confined to the right side of the vasculature when structures on the right side of a leaf were treated. Compound leaves of both species mature acropetally. Thus, mature basal pinnae of honeylocust and basal leaflets of green ash translocate acropetally to younger leaf parts that are still rapidly expanding. All translocation pathways, both in the stem and leaf, conformed with vascular organization previously determined by anatomical analyses.     

Metabolism of [14C]ss-glucose and [14C]-acetate by lettuce embryos during early germination

The metabolism of ['⁴C]-labelled glucose and acetate has been investigated during the early germination - before radicle emergence - of lettuce ( Lactuca sativa L., cv. Val d'Orge) embryos. Similar amounts of radioactivity from both substrates were evolved as C., or incorporated into organic acids, amino acids and proteins. A large part of the [¹⁴C]-glucose was also incorporated into sucrose and polysaecharides, and a small part into the glycerol moiety of lipids. Acetate was massively incorporated into lipids, and only slightly into neutral compounds. These results show that both glucose and acetate can be utilized as respiratory substrates during early germination of lettuce embryos. Various biosynthetic pathways leading to amino acids, proteins, polysaecharides and lipids are active during this period.     

Alterations in the Production of 14CO2 and [14C]Acetylcholine from [U-14C]Glucose in Brain Subregions Following Transient Forebrain Ischemia in the Rat

Abstract: The production of ¹⁴CO₂ and [¹⁴C]acetylcholine from [U-¹⁴C]glucose was determined in vitro using tissue prisms prepared from the dorsolateral striatum (a region developing extensive neuronal loss following ischemia) and the paramedian neocortex (an ischemia-resistant region) following 30 min of forebrain ischemia and recirculation up to 24 h. Measurements were determined under basal conditions (5 mMK⁺) and following K⁺ depolarization (31 mM K⁺). The production of ¹⁴CO₂ by the dorsolateral striatum was significantly reduced following 30 min of ischemia for measurements in either 5 or 31 mM K⁺ but recovered toward preischemic control values during the first hour of recirculation. Further recirculation resulted in ¹⁴CO₂ production again being reduced relative to control values but with larger differences (20–27% reductions) detectable under depolarized conditions at recirculation times up to 6 h. Samples from the paramedian neocortex showed no significant changes from control values at all time points examined. [¹⁴C]Acetylcholine synthesis, a marker of cholinergic terminals that is sensitive to changes in glucose metabolism in these structures, was again significantly reduced only in the dorsolateral striatum. However, even in this tissue, only small (nonstatistically significant) differences were seen during the first 6 h of recirculation, a finding suggesting that changes in glucose oxidation during this period were not uniform within all tissue components. The results of this study provide evidence that in a region susceptible to ischemic damage there were specific changes during early recirculation in the metabolic response to depolarization. This apparent inability to respond appropriately to an increased need for energy production could contribute to the further deterioration of cell function in vivo and ultimately to the death of some cells.