The Uptake of Growth Substances: VI. A COMPARATIVE STUDY OF THE FACTORS DETERMINING THE PATTERNS OF UPTAKE OF PHENOXYACETIC ACID AND 2,4,5-TRICHOLOROPHEN-OXYACETIC ACID, WEAK AND STRONG AUXINS, BY GOSSYPIUM TISSUES2

Using segments of etiolated hypocotyls of Gossypium, a comparativestudy has been made of the processes which determine the patternsof uptake of a very weak auxin, phenoxyacetic acid (POA), anda very powerful one, 2,4,5-trichlorophenoxyacetic acid (2,4,5-T). When segments are placed in solutions of POA-1-¹⁴C, a continuousincrease in the radioactivity of the tissues is accompaniedby the formation of radioactive metabolities which can be separatedfrom POA by techniques of paper chromatography. At the sametime there is a progressive increase in the amount of radio-activitywhich cannot be removed by transferring the tissues to buffer.Uptake is inhibited by low temperature, anaerobiosis, 2,4-dinitrophenol,and iodoacetate. It is concluded that the accumulation of POAinvolves its metabolic conversion to products which do not readilydiffuse out into the external medium. With 2,4,5-T-1-¹⁴C the radioactivity of the segments at firstincreases rapidly but this is followed after two hours by aphase of rapid decrease. No radioactive metoabolites can bedetected by paper chromatography and all of the ¹⁴C taken upcan be rapidly removed by transfer to buffer. The magnitudeof the decrease in radioctivity during the second phase of uptakeis balanced by a release to the medium of a matched amount ofradioactive 2,4,5-T. Uptake of 2,4,5-T is somewhat less sensitiveto temperature and anaerobiosis than uptake of POA and is bycontrast only slightly inhibited by 2,4-dinitrophenol and iodoacetate. Pretreatment of segments in buffer markedly alters the patternof uptake of 2,4,5-T but not that of POA. It reduces both theamount of 2,4,5-T initially taken up and the amount subsequentlyreleased to the medium. In addition, both net loss of radioactivityduring the course of uptake of 2,4,5-T and the reduction inthe extent of uptake following pretreatment are both arrestedby adding streptomycin, but not by the addition of pencillinor chloramphenicol. It is concluded that the uptake of 2,4,5-T involves reversibleaccumulation by a process whose efficiency decreases with time:the most likely systems are a metabolically linked mechanismfor the active transport across a membrane or reversible adsorptionon specific binding sites.     

The Uptake of Growth Substances: XI. VARIATIONS IN THE ACCUMULATION OF SUBSTITUTED PHENOXYACETIC ACIDS OF DIFFERING PHYSIOLOGICAL ACTIVITY BY SEGMENTS OF AVENA MESOCOTYL

An examination has been made of the phase of continuous accumulationof phenoxyacetic acid (POA) and the 2-, 4-, 2,4-, 2,6-, and2,4,5-chloro-derivatives, containing carbon-14 in the carboxylgroup, by segments of the Avena mesocotyl. On the basis of previousfindings to eliminate the initial transient components of uptake(Type I processes) the segments were pretreated for 13 to 18h in buffer or buffer containing the respective non-radioactivecompound. For five of the compounds the relationship between the rateof uptake and the external concentration takes the form of arectangular hyperbola, but for the sixth, 2,4,5-T, this relationshipdoes not hold. The data, except those for 2,4,5-T, have beenevaluated as linear regressions of rate of uptake against thequotient of rate over concentration. From each regression equationtwo constants have been derived: the point ‘B’ wherethe line intersects the rate axis (the theoretically maximumrate) and the slope of the regression ‘K’, whichcan alternatively be expressed as the concentration at whichthe observed rate equals half the value of ‘B’. The calculated values of B and K for POA are approximately twiceas great as the corresponding values for 2-CPA, and about 25times greater than for 4-CPA. The values for 2,4-D are closeto those for 4-CPA, and 2,6-D is intermediate between 2-CPAand 4-CPA. Although the constants for 2,4,5-T could not be calculatedprecisely, the rates of accumulation are about one-fourth ofthose measured for 2,4-D at equivalent concentrations. The uptake of radioactive 2,4-D is slightly depressed in thepresence of nonradioactive POA. Greater reductions are causedby 2-CPA or 2,6-D, and 2,4-D or 2,4,5-T are even more inhibitory.The pattern of inhibition caused by 2,4,5-T indicates competitionfor common sites of uptake, while POA appears not to be competitive.In corresponding experiments with POA, the presence of the otherregulators only caused small inhibitions and the order was different. Earlier work showed that in Avena accumulation is accompaniedby the conversion to a varying degree of the individual substitutedphenoxyacetic acids to conjugated derivatives. It is suggestedthat the variation between compounds in their rates of accumulationis in part due to differences in the stability of the conjugatedderivatives, and that the facility of conversion is a factorin determining physiological activity.     

The Uptake of Growth Substances: V. VARIATION IN THE UPTAKE OF A SERIES OF CHLORINATED PHENOXYACETIC ACIDS BY STEM TISSUES4GOSSYPIUM HIRSUTUM AND ITS RELATIONSHIP TO DIFFERENCES IN AUXIN ACTIVITY

When segments excised from the etiolated hypocotyls of Gossypiumhirsutum are pretreated in buffer, the subsequent uptake ofradioactive 2,4-dichlorophenoxyacetic acid (2,4-D-1-¹⁴C) isdepressed and the net loss of radioactivity which normally followsa phase of positive uptake by freshly excised segments doesnot take place. Uptake by fresh segments, in contrast with uptakeafter pretreatment, has a high Q₁₀ and is markedly depressedby both 2,4,5-trichlorophenoxyacetic acid (2,4,5-T) and 3-indolylaceticacid. On these grounds it is proposed that net loss resultsfrom the release of material accumulated by a specific mechanismwhich, with time, becomes inoperative. Additional experimentssuggest that part of the 2,4-D taken up by stem segments ofTriticum vulgare and Avena sativa is accumulated by a similarmechanism. For 1-cm segments, entry is most rapid through the cut ends,and the effects of pretreatment exert their maximal effectsin the tissue near the ends. Therefore very short segments havebeen used to compare the courses of uptake of phenoxyaceticacid (POA) and its 2-, 4-, 2,6-, 2,4- and 2,4,5- chloro- derivatives.The patterns observed are similar to those previously reportedfor 1 -cm segments, although the differences between compoundsare greater. The courses of uptake of 2,4-D and 2,4,5-T, bothterminate in a phase when there is a net loss. POA and the 2-chloro-substitutedacid (2-CPA) are both continuously accumulated. No net lossis found with either the 2,6- (2,6-D) or the 4- chloro (4-CPA)compounds but the rates of uptake progressively decrease toa low level. It is proposed that the processes which determine the patternof uptake of chlorinated phenoxyacetic acids include two typesof accumulation. With Type I accumulation the mechanisms involvedrapidly become disorganized after tissues are excised from theplant. Type 2 accumulation, on the other hand, is stable. Theavailable data indicate that Type I accumulation is peculiarto compounds with marked auxin-like properties.     

The Uptake of Growth Substances: XV. THE DIFFERENTIAL EFFECTS OF PROGRESSIVE CHLORINATION OF PHENOXYACETIC ACID ON ENTRY INTO THE EPIDERMAL AND CUT SURFACES OF STEM SEGMENTS

The comparative patterns of entry into segments with sealedand open ends, excised from etiolated internodes of Pisum sativum,have been examined for phenoxyacetic acid (POA) and its 2-,4-, 2,4-, 2,6-, 3,5-, 2,4,5- and 2,4, 6-chloro derivatives,each containing ¹⁴C in the carboxyl group. Sealing the ends greatly depresses the level of entry, on averagean eight-fold reduction at 9 h. Likewise, the interrelationsbetween the degree of chlorination and uptake potential aredisparate. For segments with exposed cut surfaces the finalcontent is maximal for POA and the 2-chloro compound and minimalfor the 3,5-dichloro derivative (3,5-D) with an eight-fold difference.With sealed ends this difference is reduced to two-fold butwhile 3,5-D accumulates least uptake is now highest for POAand 2,4-D. There are also changes in the order with time. Initially,2,4,5-T penetrates fastest into sealed segments but for segmentswith open ends entry is most rapid for the 4- and 2,4,6-chloroderivatives. Additions of streptomycin and cetyltrimethylammoniumbromide(CTAB) induce differential changes in the patterns of uptake.Where uptake is promoted the enhancement is not restricted toactive auxins. Sealing the ends may alter the nature of theresponse. The likely physico-chemical and metabolic processes concernedin the two routes of entry are discussed and the results comparedwith previous divergent findings on the relationship betweenchemical structure and uptake by Lemna minor and penetrationinto leaves of Phaseolus vulgaris.     

Studies on the Growth in Culture of Plant Cells: XX. UTILIZATION OF 2,4-DICHLOROPHENOXYACETIC ACID BY STEADY-STATE CELL CULTURES OF ACER PSEUDOPLATANUS L

Omission of 2,4-dichlorophenoxyacetic acid (2,4-D) from batchcultures of sycamore produced an immediate reduction in ratesof cell division and eventually in rates of biomass accumulation.The sequential responses of a chemostat and of turbidostat culturessubjected to gradual withdrawal of 2,4-P were: (i) a transientincrease in biomass accumulation, (ii) increased accumulationof p-coumaric acid, flavonoids, and lignin, (iii) increasedcell aggregation, (iv) reduced rates of cell division, and (v)death. During stepwise reduction of 2,4-D supplied to turbidostatcultures, rates of 2,4-D uptake were reduced when the spentmedium concentration fell to 3?5–1?0 ? 10^–7 M. Underthese conditions the 2,4-D concentration in soluble and insolublecell fractions declined. The growth responses were correlatedwith the spent-medium 2,4-D concentration but not with its concentrationin the intracellular fractions.     

Growth Substance Interactions during Uptake by Mesocotyl Segments of Zea mays L.

The effects of various growth substances on the ‘metabolic’uptake of indol-3yl-acetic acid (IAA) by Zea mesocotyl segmentswas investigated using methods of fluorescence spectroscopyand radioactivity assay. 2, 4-Dichlorophenoxyacetic acid (2,4-D) and -(I-naphthylmethylthio)propionic acid (NMSP) exertedno discernible effects on IAA uptake, whereas N-I-naphthylphthalmicacid (NPA) stimulated uptake to some degree. Low concentrationsof 2,3,5-tri-iodobenzoic acid (TIBA) promoted the uptake oflow IAA concentrations, while higher concentrations were decidedlyinhibitory. 2,4-Dinitrophenol (DNP), ioxynil, and bromoxynilalso induced marked inhibition presumably by preventing oxidativephosphorylation. The uptake interactions between these compoundswere examined in relation to concentration and time. In no casewas there evidence of competitive interaction. The inhibitoryeffects of TIBA on IAA uptake were considerably greater thanthose of DNP. SH-enzyme protectors such as BAL and cysteinedid not relieve these inhibitions. The absorption of TIBA-¹³¹Iwas completely unaffected by any concentration of IAA tested.Chromatographic and radio-autographic analysis revealed no detectableproducts of IAA-I-¹⁴C metabolism or degradation in maize mesocotyltissue during the 6-h experimental period and this was not alteredby TIBA treatment. Respiratory decarboxylation of IAA-I-¹⁴Cwas found to be negligible and unaffected by TIBA.     

The Uptake of Growth Substances: III. INFLUENCE OF INDOLEACETIC ACID AND OTHER AUXINS ON THE UPTAKE OF 2,4-DICHLOROPHENOXY-ACETIC ACID BY CHLORELLA

When 2,4-dichlorophenoxyacetic acid, labelled with ¹⁴C, is accumulatedby Chlorella pyrenoidosa, an appreciable fraction, which increaseswith time, is held within the cell in a form which is not removedwhen the cells are placed in a solution containing the unlabelledcompound. The accumulation of this fraction is dependent uponthe supply of metabolic energy since it is affected by temperature,light, and the addition of inhibitors or citrate to the externalmedium. The uptake of this metabolically accumulated 2,4-D follows apattern which indicates that a single enzymic reaction is apredominant component of the uptake process. In the presenceof the other auxins, including indoleacetic acid, 2,4,5-trichlorophenoxyaceticacid and 4-chlorophenoxyacetic acid, the uptake of 2,4-D isdepressed and the changes suggest that there is competitionat the site of this reaction. The nature of the competitionis seemingly of the type where each compound serves as a substratefor the enzyme. It may be significant that the extent to which the individualauxins compete with 2,4-D is in the same order as their generaleffectiveness as growth regulators for other species.     

The Uptake of Growth Substances: XIII. DIFFERENTIAL UPTAKE OF INDOL-3YL-ACETIC ACID THROUGH THE EPIDERMAL AND CUT SURFACES OF ETIOLATED STEM SEGMENTS

The patterns of uptake of indol-3yl-acetic acid (IAA-2-¹⁴C)by etiolated stem segments of varying lengths have been examined,employing tissues excised from (a) the first and third internodesof Pisum sativum, (b) the top and base of the hypocotyl of Gossypiumhirsutum, and (c) the mesocotyl of Avena sativa. For all species,concentrations (10^–5–10^–3 M) and times upto 24 h, there is a steady accumulation of radioactivity inthe segments. For equal volumes of tissue uptake is inverselycorrelated with segment length but for extending tissues theinitial enhanced extension growth is independent of length;that is there is no direct linkage between the rate of extensionand auxin content. Comparisons between segments with free andsealed ends established that over 24 h some 57–73 percent of the IAA enters via the cut surfaces. Initially, thepercentage is greater; expressed as a rate per unit of surfacethe differences between cut and epidermal surfaces can reach28-fold. The rate of entry through the epidermal surface islinearly proportional to the external concentration but thisdoes not hold for cut surfaces. The addition of streptomycin,synthalin, cetyltrimethylammoniumbromide (CTAB), and chitosanto the external medium does not promote uptake of IAA by Pisumsegments; indeed synthalin is markedly inhibitory. With Gossypiumsynthalin causes little inhibition. Larger depressive effectswere induced for entry via the cut surfaces. On entry the IAAis rapidly metabolized and the rate of conversion is higherfor segments with sealed ends. These findings are discussedin relation to (a) differences in the mechanisms determiningthe uptake of IAA and other auxins, (b) cell extension and thedistribution of auxin in the tissues.     

Studies on Foliar Penetration: I. FACTORS CONTROLLING THE ENTRY OF 2, 4 - DICHLOROPHENOXYACETIC ACID

A technique, using leaf disks, has been developed to study thepenetration of isotopically labelled compounds into leaves underconditions where there is no appreciable change in the concentrationof the external solution and no subsequent translocation. Inthis preliminary survey, the leaves of Phaseolus vulgaris andColeus Blumei were employed to investigate the entry of 2,4-dichlorophenoxyaceticacid (2,4-D), labelled in the carboxyl group with ¹⁴C. Over3 days there is no loss of ¹⁴C to the atmosphere from treatedleaves of Phaseolus. The rate of penetration is enhanced when(a) the leaves are young, (b) the water status is lowered, (c)the temperature is raised (Q₁₀=2.3–2.8), and (d) a surface-activeagent is added to the external solution. Penetration is alsofavoured by a decrease in the pH, the relation indicating thatboth ions and molecules enter. Penetration is greater in thelight and prior illumination of the tissues positively affectsthe subsequent rate in the light, but not in the dark. In boththe light and the dark considerably more 2,4-D penetrates theabaxial surface of Phaseolus leaves. For Coleus an even greaterdifference between surfaces is found in the light but not inthe dark. For both species in the light the rates of entry intoboth surfaces are proportional to their respective stomataldensities. The simultaneous addition of indoleacetic acid tothe external solution caused more 2,4-D to enter Phaseolus leaves,but the addition of triiodobenzoic acid restricts entry. Therate of penetration remains constant over 24 hours and between0.1 and 200 mg./l. the rate is linearly related to concentration.Subsequent to entry, the 2,4-D is in a form which does not diffusefrom the tissue into buffer or exchange with unlabelled 2,4-D.Moreover, no outward movement takes place from treated tissuewhich has been frozen and thawed. These findings are discussedin relation to previous work on foliar penetration. It is concludedthat at least with Phaseolus penetration largely takes placethrough the guard cells and/or accessory cells.     

The Uptake of Growth Substances: VII. THE ACCUMULATION OF CHLORINATED BENZOIC ACIDS BY STEM TISSUES2

The courses of uptake of benzoic acid (BA) and its 2-chloro-(2-CBA), 2,4-dichloro- (2,4-DCBA), 2,5-dichloro- (2,5-DCBA),and 2,3,6-trichloro- (2,3,6-TCBA) derivatives, all containing¹⁴C in the carboxyl group, have been investigated, employingstem segments of Pisum sativum, Gossypium hirsutum, and Avenasativa. From comparisons of the rates of accumulation by segmetns ofdifferent length it is conclueded that for each compound uptakeproceeds largely or wholly via the cut surfaces. The initial uptake of BA and 2-CBA by segments of Pisum is depressedas the pH of the solution is raised from 4 to 6.5, but the fallis less rapid than the decrease in the proportion of undissociatedmolecules. For all three species, BA and 2-CBA, which induced no extensiongrowth, were accumulated at a more or less constant rate. Bycontrast, the course of uptake of 2,3,6-TCBA, a powerful auxin,exhibited marked deviations from a linear pattern, especiallyin Avena where uptake became negative between four and six hours.This loss of radioactivity from the tissues was due to the netegress of 2,3,6-TCBA itself into the external solution. In Avenathe two dichloro-benzoic acids (2,4-DCBA and 2,5-DCBA) haveintermediate trens: net accumulation declined almost to zerobut subsequently recovered and proceeded at a rapid rate. These findings are discussed in relation to prior studies ofthe uptake of substituted phenoxyacetic acids and the conceptsof Type 1 and Type 2 accumulation. It is proposed that accumulationof BA and 2-CBA is largely governed by a stable Type 2 processwhile the initial uptake of the powerful auxins, 2,3,6-TCBAand 2,5-DCBA proceeds via an unstable system, similar or identicalto Type 1 accumulation.     

The Effects of 2,4-Dichlorophenoxyacetic Acid on Ion Uptake by Maize Roots

The effects of the synthetic auxin and herbicide 2,4-dichlorophenoxyaceticacid (2,4-D) on K^$ and Cl^– uptake and H^$ release by youngexcised maize roots has been studied. Brief exposure to 2,4-D(0.01 mmol dm^–3) at pH 3.5 causes a large depolarizationof the electrical potential across the root plasma membranesand converts K^$ uptake to K^$ leakage into the bathing solution.These results can be explained by the increased H^$ permeabilityof the membranes induced by the weak acid 2,4-D. The depolarizationresults in a less favourable electrochemical potential gradientfor K^$ uptake across these membranes. These effects are notrelated to the auxin properties of 2,4-D as the nonauxin 3,5-dichlorophenoxyaceticacid (3,5-D) gives rise to similar effects. The relative depolarizationsinduced by a range of weak acids appear to be unrelated to theiroil/water partition coefficients. In contrast, on bathing the roots for longer periods in solutions(pH > 5) containing 2,4-D (0.01 mmol dm^–3) K^$ and Cl^–uptake and H^$ release are inhibited. These effects are not shownwith 3,5-D suggesting an auxin-linked action for 2,4-D. Alsothe electrical potential across the plasma membranes is onlyslightly depolarized so that a change in the electrochemicalpotential gradient cannot be invoked to explain the loweredion fluxes. The evidence is consistent with the removal of anenergy supply to a metabolically linked K^–/H^– exchangemechanism in the plasma membranes. It is likely that both modes of action would operate to lowerion uptake under soil-grown conditions, the former becomingmore manifest in acidic soils.     

The Uptake of Growth Substances: VIII. ACCUMULATION OF CHLORINATED BENZOIC ACIDS BY AVENA SEGMENTS: A POSSIBLE MECHANISM FOR THE TRANSIENT PHASE OF ACCUMULATION

If segments from the mesocotyls of Avena sativa are first keptin buffer then the initial rates of uptake of radioactive 2,3,6-trichlorobenzoicacid (2,3,6-TCBA) and 2,4- and 2,5-dichlorobenzoic acids (2,4-DCBAand 2,5-DCBA) are less than those of freshly excised segments.No such effect of pretreatment is found for benzoic acid orfor 2-chlorobenzoic acid (2-CBA). Uptake of 2,3,6-TCBA normallybecomes negative between two and six hours after excision, andthis phase of net loss is prevented by the addition of streptomycin,which also offsets the decline in the rates of uptake of 2,5-DCBAand 2,4-DCBA. In contrast, streptomycin inhibits accumulationof 2-CBA. From a comparison of these results with similar andprior findings for substituted phenoxyacetic acids, it is concludedthat the initial uptake of 2,3,6-TCBA, 2,5-DCBA, and 2,4-DCBAis governed by an unstable accumulatory system (Type 1), whosebreakdown can result either in a phase of net loss during thecourse of uptake, or in a decline in uptake following pretreatment. Net loss of 2,3,6-TCBA is also prevented by synthalin (decamethylenediguanidine dihydrochloride), cetyl trimethyl ammonium bromide(CTAB) and by 2,3,5-triiodobenzoic acid (TIBA). During pretreatment,the presence of streptomycin, synthalin or TIBA prevents a fallin the subsequent uptake of 2,3,6-TCBA, while the addition ofCTAB causes a dramatic increase in uptake. We have proposed for Type 1 accumulation a biochemical mechanismcapable of accounting for the unstable nature of the accumulationand for the protective action of the compounds with cationicnitrogen groups, such as streptomycin, synthalin, and CTAB.     

Studies on Foliar Penetration: IV. MECHANISMS CONTROLLING THE RATE OF PENETRATION OF 2,4-DICHLOROPHENOXYACETIC ACID (2,4-D) INTO LEAVES OF PHASEOLUS VULGARIS

The effects of a wide range of metabolic inhibitors on the penetrationof 2,4-dichlorophenoxyacetic acid (2,4-D) into the leaf disksof Phaseolus vulgaris have been studied. While recognizing thelack of specificity of most inhibitors, compounds were chosenwhich are known to affect respiration, phosphorylation, photosynthesis,membrane permeability, protein synthesis, and the binding capacityof membrane systems. They were: fluoride, azide, arsenite, iodoacetate,arsenate, 2,4-dinitrophenol (DNP), 3-(3,4-dichlorophenyl), -I,I-dimethylurea (DCMU), phenylmercuric chloride, octenylsuccinicacid, decenylsuccinic acid, dimethyl sulphoxide, actinomycin-D,chloramphenicol, streptomycin, 5-fluorouracil, cycloheximide,and cetyltrimethylammoniumbromide (CTAB).At sub-toxic levelsall compounds had little or no influence on penetration in darknesssave for iodoacetate and decenylsuccinic acid, which causedsome enhanced entry at 10^-4M and 10^-3M respectively, and CTABwhich promoted penetration at concentrations known tolower thesurface tension of water.The much greater rate of penetrationof 2,4-D into disks exposed to bright light (16 000 lx) is unaffectedby fluoride, azide, DNP, octenylsuccinic acid, decenylsuccinicacid, dimethyl sulphoxide, or actinomycin-D. It is, however,progressively inhibited by increasing concentrations of arsenite,iodoacetate, arsenate, streptomycin, and 5-fluorouracil. Chloramphenicol,cycloheximide, and CTAB lower the rate of penetration at intermediateconcentrations but at high concentrations the affect is reversed.The most active inhibitors of light-induced penetration areDCMU and phenylmercuric chloride, compounds which block theproduction of ATP.These results are discussed in relation tomechanisms of transport, in particular the structureand stabilityof barriers likely to impede penetration.     

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.     

Somatic Embryogenesis and Plant Regeneration from Cultured Leaf Explants of Zea mays

Young leaf segments of Zea mays L. seedlings were cultured onMurashige and Skoog's basal nutrient medium supplemented with2 mg l^–1 2, 4-D and sub-cultured on medium containing8 mg l^–1 2,4-D. Two types of callus tissues appeared—embryogenicand non-embryogenic. The embryogenic callus tissue producednumerous somatic embryos which on transfer to media containinglow amounts of 2,4-D or ABA produced plantlets. Callus tissuesexhibited embryogenic potential for more than 1 year. Zea mays L. cv. Ageti-76, Zea mays L. cv. N-L-D-Comp., maize, leaf, callus, somatic embryogenesis, regeneration     

Metabolism of 2,4-Dichlorophenoxyacetic Acid (2,4-D) in Soybean Root Callus : EVIDENCE FOR THE CONVERSION OF 2,4-D AMINO ACID CONJUGATES TO FREE 2,4-D

An auxin-requiring soybean root callus metabolized [1-¹⁴C]-2,4-dichlorophenoxyacetic acid (2,4-D) to diethyl ether-soluble amino acid conjugates and water-soluble metabolites. The uptake in tissue varied with incubation time, concentration, and amount of tissue. Uptake was essentially complete (80%) after a 24-hour incubation and the percentage of free 2,4-D in the tissue fell to its lowest point at this time. At later times, the percentage of free 2,4-D increased and the percentage of amino acid conjugates decreased, whereas the percentage of water-soluble metabolites increased only slightly. Similar trends were seen if the tissue was incubated for 24 hours in radioactive 2,4-D, followed by incubation in media without 2,4-D for 24 hours. Inclusion of nonlabeled 2,4-D during the 24-hour chase period did not reduce amino acid conjugate disappearance but did reduce the percentage of free [1-¹⁴C]2,4-D. Thus, an external supply of 2,4-D does not directly prevent amino acid conjugate metabolism in this tissue. It is concluded that 2,4-D amino acid conjugates were actively metabolized by this tissue to free 2,4-D and water-soluble metabolites.     

Effect of Xyloglucan Nonasaccharide on Cell Elongation Induced by 2,4-Dichlorophenoxyacetic Acid and Indole-3-acetic Acid

Xyloglucan nonasaccharide (XG9) is recognized as an inhibitorof 2,4-D-induced long-term growth of segments of pea stems.In the presence of 10^–5 M 2,4-D, inhibition by 10^–9M XG9 of elongation of third internode segments of pea seedlingswas detected within 2 h after the start of incubation, in someexperiments. Analysis by double-reciprocal (Lineweaver-Burk)plots of elongation in the presence of various concentrationsof 2,4-D, with or without XG9, gave parallel lines, indicatingthat XG9 inhibited 2,4-D-induced elongation in an uncompetitivemanner. XG9 did not influence the 2,4-D-induced cell wall loosening.Thus, XG9 does not fulfill the proposed definition of an "antiauxin". XG9 at 10^–11 to 10^–6 M did not influence IAA-inducedelongation of segments from pea third internodes, azuki beanepicotyls, cucumber hypocotyls, or oat coleoptiles. Inhibitionof IAA-induced elongation by XG9 was not observed even whenthe segments from pea or azuki bean were abraded. Furthermore,fucosyl-lactose at 10^–11 to 10^–4 M did not affectthe IAA-induced elongation of segments of pea internodes orof azuki bean epicotyls. XG9 may be incapable of inhibitingthe IAA-induced cell elongation (especially in oat) or, alternatively,the endogenous levels of XG9 may be so high that exogenouslyapplied XG9 has no inhibitory effect on IAA-induced elongation. (Received February 28, 1991; Accepted May 25, 1991)     

Studies on Foliar Penetration: VI. FACTORS CONTROLLING THE PENETRATION OF 4-AMINO-3,5,6-TRI-CHLOROPICOLINIC ACID (PICLORAM) INTO THE LEAVES OF PHASEOLUS VULGARIS

The evaluation of the factors controlling the penetration of4-amino-3,5,6-trichloropicounic acid (picloram), containing¹⁴C in the carboxyl group, into leaves of Phaseolus vulgarisis complicated by the ability of the leaf tissue to decarboxylatethe compound rapidly. The degradation system becomes fully activatedonly after some hours following treatment with picloram whilethe capacity for decarboxylation declines with the age of theleaf. When allowance for decarboxylation is made, the pattern of penetrationfor picloram resembles in particular that of 2,2-dichloropropionicacid (dalapon). At the abaxial surface penetration continuesover 24 h at a fairly constant rate but in light, which enhancespenetration, a ‘surge’occurs between the secondand sixth hour. Raising the external concentration promotespenetration and in light entry is directly proportional to concentrationup to at least 2.5 x 10^–l M. The response to varying lightintensity resembles that of dalapon rather than 2,4-D. Evenlow intensities promote penetration; the effect is maximal atabout 10 000 lx at the abaxial surface but continues at leastup to 20 000 lx at the adaxial surface. Penetration is retarded at 4°C but the decarboxylation systemremains functional. In light, but not in darkness, penetrationis strikingly reduced by 3-(3,4-dichlorophenyl)-l,l-dimethylurea(DCMU). Raising the external pH from 4.2 to 7.2 retards entry. It is concluded that the factors which determine the penetrationof picloram into Phaseolus leaves also control the entry ofa wide range of organic compounds and inorganic ions.     

Vessel element formation in cultured carrot-root phloem slices

The effects of light, auxin and cytokinin on vessel elementformation in phloem slices of carrot root were examined. When slices of carrot cultivars, ‘Nakamura-senko-futo’and ‘Yamada-hyakunichisenk6- naga’, preculturedin the dark on modified Murashige and Skoog's medium for twodays were cultured on a medium containing 5x10^–6 M 2,4-Din the dark, no vessel element formation occurred. When preculturedslices were cultured in the light with 5x10^–6M 2,4-D,vessel element formation was remarkable. But when 5x10^–7Mkinetin, benzyladenine or zeatin was added, vessel elementswere readily formed even in the dark. When slices were cultured in the light, a cytokinin-like substance(s)that causes vessel element formation was produced in the slices,then was released to the medium. The substance(s) was fairlystable to heat. In slices of carrot cultivars, kuroda-gosun, ‘Kintoki’and ‘Kokubu-senk6-6naga’, a different result forvessel element formation was obtained. When slices of thesecultivars were cultured on a medium containing 5x10^–6M2,4-D in the dark, vessel element formation was remarkable.It seemed, therefore, that these cultivars contain enough ofa cytokinin-like substance(s) to form vessel elements. In fact,vessel element forming activity was found in the alcohol extractof carrot root phloem from these cultivars. (Received June 8, 1971; )     

The movement of 2,4-dichlorophenoxy acetic acid in root segments of Pisum sativum L.

Summary An acropetal polarisation of the movement of 2,4-dichlorophenoxy acetic acid (2,4-D) through subapical segments of Pisum seedling primary roots has been monitored throughout a 60 h transport period in darkness at 25° C using [1-¹⁴C]2,4-D and [2-¹⁴C]2,4-D. Uptake of 2,4-D does not proceed at a constant rate; periods in which the amount of ¹⁴C in the root segments and receiver blocks increases rapidly are followed by periods in which the amount of radioactivity remains relatively constant or declines slightly. These oscillations do not appear to be related to the time of day at which the experiments are begun or ended. Immobilisation and degradation of 2,4-D during transport in the segments seems to be low. Replacement of [1-¹⁴C]2,4-D donor blocks after 25 h by blocks containing unlabelled 2,4-D results in continued transport of the compound into receiver blocks, with only small amounts of ¹⁴C remaining in the root tissues. Radioactivity is also exported from the segments into the blocks used to replace the donor blocks, with larger amounts being exported into the blocks applied to the apical ends than into those applied to the basal ends of the segments. This radioactivity may be taken-up again by the segments but more ¹⁴C is exported into these blocks towards the end of the experiments. The possibility of regular oscillations in uptake and movement of 2,4-D in Pisum root segments is discussed.