The Movement of Sugars into the Sieve Elements of Bark Strips of Willow: II. EVIDENCE FOR TWO PATHWAYS FROM THE BATHING SOLUTION

It is suggested that when ¹⁴C-labelled sucrose, or its constituenthexoses, are applied to the cambial surface of a bark strip,the sugars can move into the sieve elements by two pathways.The first is a direct one which probably involves the companioncells; in it the labelled sugars do not mix with pools of unlabelledsugars before entry into the sieve elements. Entry by this pathwayleads to activity in a wide range of compounds in the sieve-tubeexudate. The second pathway is an indirect one, involving thestorage parenchyma of the phloem, where considerable metabolicchanges take place involving the sugar applied to the strip,but the products of these changes, apart from sucrose, are unableto move into the sieve elements. These results are discussed in relation to published work onthe cytology of angiosperm phloem, and the results of otherinvestigators on the movement of sugars into plant cells.     

Demonstration of Solute Movement from the Extracambial Tissues4

When ¹⁴CO₂ was applied to the leafy shoot of a stem segment,the xylem of which was perfused with distilled water, a proportionof the activity was detected in the xylem exudate, mainly inthe form of sucrose. Experiments in which ³⁶Rb, ²²Na, or ³²P-phosphatewere applied to the cambial surface of a raised portion of barkrevealed that these solutes could also pass into the xylem exudate.With the ions, the amount which moved into the xylem vesselswas dependent upon the time of year at which the experimentswere performed.     

Ethylene-Enhanced Transport of 14C-Labeled Metabolites in Rice Seedlings in Relation to Ethylene-Stimulated Coleoptile Growth

To examine the effects of ethylene on sugar transport from endospermsto coleoptiles in rice (Oryza sativa L. cv. Sasanishiki) seedlings,the contents of free sugars in the coleoptiles of explants fedcold glucose and the distributions of ¹⁴C-activities after feedingof ¹⁴C-glucose to the scutella were determined at various timesafter ethylene application. Changes in sucrose, glucose andfructose in the cold glucose-fed explants exposed to ethylenewere similar to those in the ethylene-treated intact seedlingshaving endosperms. Ethylene enhanced the transport of ¹⁴C-labeledmetabolites from the scutella to the coleoptiles. Most of the¹⁴C accumulated in the ethylene-treated coleoptiles were presentas neutral substances in the ethanol-soluble fraction. Regardlessof the presence or absence of ethylene, the incorporation of¹⁴C into sucrose preceded that into glucose and fructose. Theglucose and fructose moieties of ¹⁴C-sucrose in the coleoptileswere almost equally labeled, and the specific activities of¹⁴C-sucrose were higher than those of ¹⁴C-glucose and ¹⁴C-fructose.These results suggested that sucrose synthesized in the scutellawas exported to the coleoptiles, and cleaved there into glucoseand fructose. Ethylene may accelerate the transport of ¹⁴C-labeledmetabolites by activating sucrose cleavage in the coleoptiles. (Received July 1, 1985; Accepted September 17, 1985)     

Action Mechanism of Ethylene in the Control of Sugar Translocation in Relation to Rice Coleoptile Growth I. Sucrose Metabolism

The fate of ¹⁴C-glucose fed through scutella of rice (Oryzasativa L. cv. Sasanishiki) seedling explants was investigatedin relation to ethylene action on sugar translocation to growingcoleoptiles and leaves. In the scutellum, sucrose, UDPglucoseand F6P were rapidly labeled, and sucrose-phosphate synthaseactivity was higher than sucrose synthase activity. Radioactivesucrose soon appeared in both coleoptiles and leaves, and increasedrapidly. Its specific activity in both tissues became almostequal to that in the scutella. The specific activities of ¹⁴C-glucosein both coleoptiles and leaves changed almost in parallel tothose of ¹⁴C-fructose. These results suggest that sucrose wassynthesized in the scutellum and exported to the coleoptileand leaf, where it was cleaved to glucose and fructose. Ethylene slightly increased the specific activities of ¹⁴C-sucrosein all tissues, but markedly increased those of ^l4C-glucoseand -fructose only in the coleoptile. We assume that the ethyleneenhancement of sucrose transport from scutellum to the coleoptileresults from the activation of sucrose unloading in the growingcoleoptile where imported sucrose is cleaved into glucose andfructose. (Received May 25, 1987; Accepted October 30, 1987)     

Studies on Translocation of Metabolites in the Xylem of Grapevine Shoots

Fluid extracted from grapevine shoots by suction contained upto 0.2 per cent (w/v) of sugar. The total sugar concentrationand the relative concentrations of sucrose, glucose, and fructosechanged along the length of a shoot. Whereas sucrose is absentfrom or present only in traces in fluid bleeding from cut stumps,it was found to be a major constituent in fluid extracted fromsections of wood by suction. ¹⁴C-glucose administered to thewood of an excised shoot moved up in the transpiration stream,moved laterally, into the bark, and was partly converted tosucrose and fructose. When ¹⁴CO₂ was supplied to a leaf of anintact vine, radioactive sugars were found in the fluid afterwardsextracted from the wood by suction. When a ring of bark wasremoved from the stem at a point above the ¹⁴CO₂-treated leafmost of the ¹⁴C in the bark, wood, and extracted fluid belowthe ring was in the form of sugar but ¹⁴C in tissues above thering was mainly in organic acids and amino acids. It is suggestedthat a barrier within the wood prevents diffusion of sugarsinto the transpiration stream, and that the fluid extractedfrom the wood by suction cannot be regarded as ascending sapsince it contains considerable amounts of non-moving material.     

The Transport of Sugars in Developing Fruits of Satsuma Mandarin

Transport of sugars to the juice sacs of developing satsumamandarin (Citrus unshui Marc) has been studied in attached fruitsand in isolated fruit pieces. ¹⁴CO₂ fed to the leaves resultedin [¹⁴C]sugar accumulation in the juice sacs, mainly as [¹⁴C]sucrose.Uptake of sucrose and glucose by the excised fruit pieces proceededlinearly with time. Sucrose uptake was linearly related to sucroseconcentration over the range 25–300 mM, with no indicationof saturation. This uptake was insensitive to pH (5, 7 or 9),Ca²⁺(3 mM), PCMBS (2.5 mM), DNP (1 mM) or vanadate (0.1 mM)but was slightly reduced by erythrosin (21 % by 0–1 mM;27 % by 1 mM). No competitive effect of glucose (up to 100 mM)was detectable on sucrose uptake from 100 mM solution. Mostof the [¹⁴C]sucrose uptake observed was reversible, althoughconsiderable hydrolysis and metabolic conversion were evidenced.A vanadate-sensitive ATPase was demonstrated by EM localizationon the plasma membrane of the juice sac cells. These resultsare interpreted in relation to the accumulation of assimilatesby the developing fruit. Transport: sugar, satsuma mandarin, juice sacs     

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.     

Import of Sucrose and its Partitioning in the Synthesis of Galactomannan and Raffinose-oligosaccharides in the Developing Guar (Cyamopsis tetragonolobus) Seed

Import of sucrose and its transformation to galactomannan andraffinose-oligosaccharides have been studied in the developingguar seed. The amount of galactomannan gradually increased withthe ageing of the seed. During the entire period of pod development,sucrose constituted the major portion of the free sugars inthe seed (both endosperm and cotyledons) as well as in the podwall. Besides myo-inositol, the free sugars detected in thedeveloping endosperm and cotyledons were glucose, fructose,raffinose and stachyose. Some compounds, possibly glycosides(RG values higher than that of fructose), were also detectedin the endosperm. In the later stages of seed development, therelative proportion of raffinose in the free sugars increased,reaching 50% of the total free sugars in 77-d-old cotyledons.With pod maturity, the activities of soluble acid and boundacid invertases in the pod wall increased manifold with a concomitantdecline in the non-reducing sugar content. These enzymes seemto be involved in the mobilization of sucrose from this fruitingstructure into the seed. An increased synthesis of raffinose-oligosaccharidesboth in the endosperm and cotyledons was associated with highactivities of soluble acid invertase (pH 4.8) and sucrose-UDPglucosyl transferase in these tissues. Feeding uniformly labelled¹⁴C-sugars to the detached intact pods as well as to the isolatedendosperm and cotyledons resulted in labelling of all endogenousfree sugars and galactomannan. The uptake and incorporationinto galactomannan of ¹⁴C was stimulated by Co²⁺, Mn²⁺ and Mg²⁺.Except for mannose, a major proportion of the ¹⁴C from glucose,fructose and sucrose appeared in sucrose in both endosperm andcotyledons indicating a fast reconstitution of sucrose in situ.Based on the present results, a possible mode of transformationof sucrose to galactomannan and raffinose-oligosaccharides hasbeen proposed. Key words: Sucrose, galactomannan, raffinose-oligosaccharides, invertase, sucrose-UDP glucosyl transferase, ¹⁴C-incorporation, guar seed     

Storage Organ Development in Radish (Raphanus sativus L.). 2. Effects of Growth Promoters on Cambial Activity in Cultured Roots, Decapitated Seedlings and Intact Plants

The radish varieties Cherry Belle and Long White Icicle wereused to investigate the role of the shoot and the effects ofsynthetic growth promoters in controlling cambial activity inthe seedling axis. Development was compared in excised roots, roots with hypocotylsattached and intact seedlings cultured aseptically on a nutrientmedium. No cambial divisions were seen in isolated radicleswhich had been cultured for ten days following excision butretention of hypocotyl tissue or the entire shoot resulted incambial activity and the production of secondary vascular tissues.Enriching the culture medium by raising the sucrose conantrationto 8% and including 10^–5 M indol-3yl acetic acid (IAA)5 x 10^–6 M 6-benzylaminopurine (BA) and 5 x 10^–4Minositol enhanced root thickening, increasing stele and xylemdiameters in roots cultured both with and without attached shoottissues. The effects of shoot tissues and enrichment of themedium were additive. The effects of auxin, cytokinin and gibberellin (gibberellicacid, GA²) were also studied on daxpitated seedlings. BA wasmuch more effective in inducing cell divisions in the hypocotylthan either IAA or GA supplied separately but a mixture of IAA+GAalso produced clearly defined arcs of cambial tissue. Littlesecondary tissue had been produced after seven days' treatment,and stelar enlargement was due to the development of a cambialzone and cell expansion in the primary tissues. Only minor differencesin response were observed between the two varieties. No stimulation of storage organ development occurred when auxin,cytokinin or inositol was inwrporated into the inorganic culturesolution in which plants of Cherry Belle were grown. Rnphanus sarivus, radish, storage organ, cambial activity, growth promoters, indol-3-ylacetic acid, 6-benzylaminopurine, gibberellic acid     

The Effects of Leaf Age and Senescence on the Distribution of Carbon in Lolium temulentum

Assimilate distribution in leaves of Lolium temulentum was establishedby root absorption of [¹⁴C]sucrose and after exposure to ¹⁴CO₂.Age determined the amount of carbon assimilated, with more labelbeing incorporated during expansion than at maturity. Duringsenescence ¹⁴C assimilation was much lower. Ethanol-solubleextracts from various tissues of root-labelled plants containedmost of the radioactivity chiefly in basic and acidic compounds.The neutral fraction was composed predominantly of sucrose. Sucrose was comparably labelled in leaves from plants fed equalamounts of either [¹⁴C]sucrose, glucose, or fructose and onlytraces of labelled monosaccharides appeared in extracts. Radioactive sucrose was translocated rapidly from mature leaveswhereas, in the expanding leaf, carbon incorporation was directedtowards growth and the greater proportion of label present atligule formation was in ethanol-insoluble material. Induced senescence, of a mature leaf fed during expansion, produceda rapid loss from the pool of insoluble ¹⁴C. This was accompaniedby a reduction in the contents of chlorophyll and soluble proteinand an accumulation of amino acids. The onset of senescencecaused changes in leaf sugar levels which were correlated withincreased rates of respiration.     

The Effect of Addition of Sucrose on the Energy Status and the Trans-Root Electrical Potential Difference of Excised Maize Roots

We present the results of our attempt to determine the metabolicstatus of excised maize roots (Zea mays L. cv. ZP SC704) andits effect on the trans-root electrical potential difference(TRP). Besides the electrical potential difference, we measuredoxygen consumption, sugar content and ¹⁴C-sucrose uptake anddistribution by supplying the cut end of root with sucrose.Our experiments show that sucrose added to the cut end of excisedroots was taken up by them, increasing the sugar content andmetabolic activity of such roots. These sugar-supplemented rootsexhibited approximately 60% higher internal sugar content andrespiratory rates, and 30% higher magnitudes of TRP, comparedto sugar-depleted roots. By optimizing the ionic composition(pH, K⁺, Ca²⁺) and sucrose concentration of the upper solutionfor sucrose uptake and translocation, maintenance of energeticstatus and transport functions of the excised root, closer tothat existing in situ, was ensured. (Received July 4, 1994; Accepted October 17, 1994)     

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.     

Transport of [1-14C]-indole-3-acetic acid in Abies balsamea shoots ringed with Ethrel

The terminal (1-year-old) shoot of dormant, 2-year-old Abies balsamea (L.) Mill. seedlings was ringed with 0 or 10 mg Ethrel g^-1 lanolin. After 5 weeks of culture under environmental conditions favorable for growth, some of the treated shoots were harvested to measure tracheid number by microscopy and ethylene evolution by gas chromatography-flame ionization detection. The remaining shoots were used to measure basipetal IAA transport in the cambial region by decapitating the shoot apex, applying a pulse of [1-¹⁴C]-IAA to the cut surface, and monitoring the subsequent distribution of radioactivity. Ringing with 10 mg Ethrel g^-1 lanolin, compared with lanolin alone, stimulated cambial region ethylene evolution about 26-fold at, and 3-fold above and below the ringing site, but promoted tracheid production at the ringing site only. Ethrel ringing also increased the velocity, after 26 h transport, at which the front of the [1-¹⁴C]-IAA pulse moved below the ringing site. After 72 h of [1-¹⁴C]-IAA transport, when only immobilized radioactivity was present, the amount of radioactivity recovered in shoots ringed with 10 mg Ethrel g^-1 lanolin was higher than with lanolin alone at the ringing site but lower below it. No difference was observed above the ringing site. The distribution of radioactivity was the same in shoots ringed with lanolin alone and in unringed shoots. The results support the hypothesis that an abnormally high cambial region concentration of ethylene derived from Ethrel ringing inhibits the capacity of basipetal IAA transport at the ringing site, resulting in a local accumulation of IAA that stimulates tracheid production.     

Effects of Carbon Dioxide on Metabolism by the Glycollate Pathway in Leaves

When solutions of [¹⁴C]glycollate, glycine, serine, glycerate,or glucose were supplied to segments of wheat leaves throughtheir cut bases in the light, most of the ¹⁴C was incorporatedinto sucrose in air but in CO₂-free air less sucrose was made.The synthesis of sucrose was decreased because metabolism ofserine was partly blocked. Sucrose synthesis from glucose andglycerate in CO₂-free air was decreased but to a smaller extent;relatively more CO₂ was evolved and serine accumulated. Theeffects of DCMU and light of different wavelengths on metabolismby leaves of L-[U-¹⁴C]serine confirmed that simultaneous photosyntheticassimilation of carbon was necessary for the conversion of serineto sucrose. Of various products of photosynthesis fed exogenouslyto the leaves -keto acids were the most effective in promotingphotosynthesis of sucrose and release of ¹⁴CO₂ from ¹⁴C-labelledserine. This suggests that in CO₂-free air the metabolism ofserine may be limited by a shortage of -keto acid acceptorsfor the amino group. In CO₂-free air added glucose stimulatedproduction of CO₂ and sucrose from D-[U-¹⁴C]- glycerate andno competitive effects were evident even though glucose is convertedrapidly to sucrose under these conditions. In addition to asupply of keto acid, photosynthesis may also provide substratesthat can be degraded and provide energy in the cytoplasm forthe conversion of glycerate to sugar and phosphates and sucrose.     

Characteristics of Nectar Secretion by the Extrafloral Nectaries of Ricinus communis

The characteristics of nectar secretion by excised extrafloralnectaries of Ricinus have been examined. Secreted nectar wasfound to contain three sugars: sucrose, glucose and fructose,with glucose and fructose occurring in a 1: 1 ratio. All threesugars supported secretion when used in the culture medium andthe yield of nectar sugar was found to be concentration-dependent.Other sugar sources failed to support secretion. Experimentsusing ¹⁴C-sugars and ¹⁴CO₂ fed to intact plants allowed themovement of sugars through the nectary to be examined. Sucrosesynthesis occurs when excised glands are fed glucose and thisoccurs very early in the transport through the nectary. Themain sugar transported was sucrose, with little hydrolysis occurringuntil the final step of secretion. There was no evidence thatsucrose hydrolysis occurs either by invertase in the nectaror by a microbial flora. Inhibitors of respiration were foundto inhibit secretion as did anaerobiosis. Temperature also hada marked effect, with a temperature coefficient of 1.8. However,secretion of sucrose was not affected by anaerobic conditions,low temperatures or inhibitors of respiration as markedly asthat of glucose and fructose. Electron microscopy revealed the presence of a thickened andheavily stained wall at the inner border of the secretory epidermallayer. This wall contained numerous plasmodesmata at a frequencyof 14 per µm² and may represent an apoplastic barrier.Light microscope cytochemistry revealed that acid phosphataseis primarily located in the nectiferous tissue, while ATPaseis concentrated in the epidermis. The possibility that the nectarycontains two pathways for sucrose secretion, both apoplasticand symplastic, is discussed. Key words: Invertase, nectary, plasmodesmata, Ricinus communis, sucrose     

Does Apoplastic Sucrose Induce the Ability for Sucrose Loading in Developing Leaves of Sugarbeet?

Dark-grown sugarbeet (Beta vulgaris L.) leaves were used toinvestigate a possible role of apoplastic sucrose in the inductionand development of the putative phloem-located sucrose carrierin relation to minor vein loading and export capacity. Unlabeledsucrose was introduced to the leaf apoplast after which veinaccumulation of [¹⁴C]sucrose was determined by autoradiogra-phy.Western blotting was used to detect the putative carrier. Anaffinity purified antibody against the sucrose binding proteinof soybean did not cross-react with the protein in a plasmalemma-enrichedfraction from sugarbeet leaves. Challenging the apoplast ofleaf discs with buffer plus sucrose for 6 h (induction) resultedin decreased [¹⁴C]sucrose uptake. When induction treatmentswere conducted with detached intact leaves in the dark, sucroseand glucose, but not buffer alone enhanced [¹⁴C]sucrose uptake.Detached leaves induced under laboratory light conditions for24 h showed enhanced [¹⁴C]sucrose uptake even in the absenceof any sugar introduced to the apoplast (buffer only). The datasuggested that in the etiolated tissue, sucrose was not a directand specific inducer of its putative carrier; instead sugarsmay have provided the energy for vein loading. Furthermore,the data suggested a role for light in the development of theputative sucrose carrier and vein accumulation of sucrose intransitional leaves of sugarbeet. The role of light may alsobe related to tissue energy level. ¹Contribution No. D-15192-1-91 from the New Jersey AgriculturalExperiment Station. This work was funded in part by the BeetSugar Development Foundation and Rutgers University ResearchCouncil and was submitted as partial fulfillment for M.S. degreeby Lynne H. Pitcher. (Received February 19, 1991; Accepted May 13, 1991)     

Carbon dioxide assimilation and photosystem II deficiency in bundle sheath strands isolated from C4 plants

The activities of Hill reaction and photosynthetic ¹⁴CO₂ fixationin bundle sheath strands enzymatically isolated from millet(Panicum miliaceum) were 3–15 times as high as those observedin corn (Zea mays). In both preparations, 3-phosphoglyceratewas the initial ¹⁴CO₂ fixation product and the radioactivitywas incorporated into sucrose and insoluble compounds (glucose-polymers)during the later period. After 20 sec of photosynthetic ¹⁴CO₂fixation, the percent of ¹⁴C incorporated into sugar phosphatesin millet was about 3 times as high as that in corn, while incorn, the percent of ¹⁴C in 3-phosphoglycerate was higher thanthat observed in millet throughout the experimental period.When ¹⁴C-phosphoglycerate was added to the isolated bundle sheathstrands, the rates of transfer of the radioactivity to dihydroxyacetonephosphate and sugar diphosphates in millet were significantlyhigher than those in corn. These results indicate that in thebundle sheath strands isolated from corn in which photosystemII activity is deficient, the reductive pentose cycle is impairedat the reduction step of 3-phosphoglycerate to glyceraldehydephosphate due to the limited supply of NADPH through the photoelectrontransport system. In contrast, the bundle sheath strands isolatedfrom millet which have adequate photosystem II activity cancarry out normal photosynthetic CO₂ fixation. (Received January 23, 1975; )     

The Distribution of 14C-labelled Assimilates in Young Apple Trees as Influenced by Doses of Supplementary Nitrogen: II. Soluble Carbohydrates and Amino Acids

Methanol extracts of young MM.104 apple trees fed ¹⁴CO₂ viaa single leaf were fractionated to compare ¹⁴C activity in totalsoluble sugar and amino acid components. ¹⁴C activity in aminoacids increased after the supply of ammonium nitrate to thesoil in plants where ¹⁴C labelled carbohydrates were presentin the roots. Estimates of specific carbon activity gave lowervalues for the amino acid carbon than the general value fortotal soluble carbohydrates. The fractionation of subsequentmethanol extracts of MM.104 roots has shown that sucrose hadlower specific activity than other components. Although thelevels of activity would accord with sucrose being a substratefor amino acid synthesis, an alternative explanation for theobserved results involving a cyclical system for transferringnitrogen is postulated.     

Unsaponifiable Lipid Biosynthesis in the Seedling of Euphorbia lathyris L.: A Bypass via Alcoholic Fermentation

[1-¹⁴C]-ethanol supplied to the cotyledons of 9-d-old Euphorbialathyris seedlings was rapidly incorporated into unsaponifiablelipids, particularly into sterols, latex triterpenols and intothe triterpene ketones of the epicuticular wax. The [¹⁴C]-triterpenoidproduction from ethanol was hardly affected by sucrose in theexternal medium when sucrose uptake rates were low, but whenthe uptake rate was higher the [¹⁴C]-triterpenoid productionfrom [¹⁴C]-ethanol was greatly reduced. This observation isconsistent with the proposition that at high sucrose uptakerates, some sucrose is converted into ethanol, so that the incorporationof [¹⁴C]-ethanol into triterpenoids is reduced by competitionwith endogenously formed ethanol. A calculation based on theputative daily ethanol production in the cotyledons and thedaily triterpenoid production of seedlings indicates that about10 % of the triterpenoid synthesis in vivo may be from ethanol. Ethanol, Euphorbia lathyris, fermentation, seedling, triterpenoid biosynthesis     

Epicormic Bud Development in Quercus robur L. Studies of Endogenous IAA, ABA, IAA Polar Transport and Water Potential in Cambial Tissues10

Seasonal measurements of IAA,³ made using GC-MS, ⁴ indicatedthat in Q. robur the spring initiation of cambial activity andonset of visible bud outgrowth in the canopy is preceded byan increase in cambial region IAA. The effects of notch-girdlescut into the bole indicated that IAA in the cambial region laterwas present in separate physiological pools, with only the polar-transportedfraction affecting epicormic bud outgrowth. The stage in thespring when the epicormic buds grew out coincided with an increaseboth in cambial region IAA and in the capacity of cambial explantsfor IAA polar transport. Thus the stimulus needed by the epicormicbuds to overcome inhibition by polar-transported IAA appearedto be self-generated. The observed effects of exogenous hormoneson epicormic bud outgrowth from stem explants indicated thatthis stimulus might be cytokinin. The seasonal changes detectedin cambial region ABA³ were consistent with a role for stress-inducedABA in the induction of epicormic bud dormancy after canopydevelopment during the summer. No consistent effects of standthinning on cambial region IAA, ABA, water potentials or watercontents were detected, although polar transport of exogenousIAA by cambial region explants removed in the spring was reducedby thinning. Key words: Epicormic buds, cambium, hormones