Decarboxylation and transport of auxin in segments of sunflower and cabbage roots

Summary The movement of ¹⁴C from indole-3-acetic acid (IAA) ¹⁴C has been examined in 5 mm root segments of dark-grown seedlings of Helianthus annuus and Brassica oleracea. Contaminants from distilled water, phosphate buffer and the razor-blade cutter increase the decarboxylation of IAA-¹⁴C, and cutting of root segments results in an activation of IAA-destroying enzymes at the cut surfaces. When these sources of errors were eliminated the following was shown: a) Both in sunflower and cabbage there is a slight acropetal flux of ¹⁴C through the root segments into the agar receiver blocks. The amount of ¹⁴C found in the receiver blocks increases with the lenght of the transport period. b) When the root segments, after the transport period, are cut in two equal parts and these assayed separately, the amounts of ¹⁴C in the two parts indicate a greater acropetal than basipetal transport. c) The total radioactivity of the receiver blocks is in part due to IAA-¹⁴C and in part to ¹⁴CO₂, the latter being a result of enzymatic destruction of auxin. d) Addition of ferulic acid, an inhibitor of IAA oxidases, to the receiver blocks markedly inhibits the decarboxylation of IAA-¹⁴C and thus increases the amount transported. This effect is more pronounced after a 20 hr than after a 6 hr transport period.     

Transport and Accumulation of IAA-14C in Tumour-forming Nicotiana Hybrids

The polar transport of indol-3yl-acetic acid (IAA-2-¹⁴C) instem explants and decapitated shoots of tumour-prone Nicotianahybrids (2n, 3n, and 4n) was compared with that in the normal,non-tumorous parent species N. glauca and N. langsdorffii. Thetotal uptake of the auxin from donor blocks was greatest inthe hybrids and N. glauca. The velocity of the basipetal movementof IAA-¹⁴C was the same in all species tested, i.e. 8 mm/h.The transport capacity for the hormone, however, was decreasedin the three tumour-prone hybrids. Gas chromatography showedthat between 70 and 90 per cent of the transported auxin waspresent in the form of IAA, between 10 and 30 per cent in theform of indol-3yl-aldehyde (IAld). The basipetal transport exceeded the acropetal transport inyoung (third) intemodes of all plants studied, whereas in olderstem segments (tenth intenodes) the reverse was found. The polarity of auxin transport was less well expressed in thetumorous hybrids. Blocking the active transport by pre-treatment of stem cuttingswith 2,4-dinitrophenol (2,4-DNP) caused a drastic reductionin the polar IAA-¹⁴C movement; in all plants tested the auxintransport was reduced to the same low level. The accumulation of auxin at the base of cuttings was higherin N. glauca and the 2n hybrid than in N. langsdorffii, i.e.about seven times higher after 1-h and three times higher after12-h transport experiments. The release of ¹⁴C from the cuttinginto an agar receiver block, however, was markedly reduced inthe 2n hybrid, whereas in N. glauca the labelled substancesmoved more freely into the receiver blocks. Differences in the capacity for the accumulation and the releaseof IAA-¹⁴C in hybrid and N. glauca stem tissues were studiedusing decapitated greenhouse plants wounded by incision abovethe fourth internode. Accumulation of the auxin occurred onlyabove the wound-cut in hybrid plants. This observation is consistentwith the view that tumour formation on hybrid stems occurs atsites of wounding. Our data suggest an elevated auxin levelto be present during tumour initiation at these sites. These results on polar transport and accumulation of IAA-¹⁴Cin tumorous Nicotiana plants together with our previous dataon various endogenous auxins suggest that the induction of neoplasticgrowth in tobacco plants is correlated with increased auxinlevels and an accumulation of the hormone at sites of wounding.     

Transport of 14C-lableled indoleacetic acid in Vicia root segments

IAA transport in Vicia root segments was investigated for comparisonwith that in intact roots. Lanolin paste (1-mm-wide ring) oragar blocks (3?3?1.5mm), both containing IAA-2-¹⁴C were appliedto the surface or a cut end of the root segments, respectively;transported ¹⁴C was collected in receiver agar blocks placedon the cut end of the segments. When lanolin paste was appliedto 5-mm segments, basipetal transport of IAA predominated overacropetal transport. When agar blocks were applied to 1- and2-mm segments, the same was true; in longer segments (3 and5 mm long), however, basipetal movement occurred predominantlyat first but was surpassed by acropetal movement after 2–3hr. Among the segments tested (regions 2–4, 4–6and 8–10 mm from the tip), the most apical one showedthe distinctest predominancy of basipetal movement. The velocitiesof the acropetal and basipetal movement of the ¹⁴C were estimatedat 3–3.8 and 8–12 mm/hr, respectively. Autoradiographicstudy and the experiment in which wire was inserted longitudinallythrough the central part of the segments showed that basipetalmovement occurred mainly through the outer part of the rootsand acropetal movement mainly through the central cylinder.The present results were compatible with those obtained previouslywith intact roots. Some properties of polar movement, such asits specificity, inhibition by TIBA, and dependency on terneprature are described. (Received March 22, 1978; )     

Metabolism of [14C]Indole-3-Acetic Acid by Coleoptiles of Zea mays L.

Reverse-phase high-performance liquid chromatography was usedto analyse [¹⁴C]-labelled metabolites of indole-3-acetic acid(IAA) in coleoptile segments of Zeo mays seedlings. After incubationfor 2 h in 10^–2 mol m^–3 [2-¹⁴C]IAA, methanolic extractsof coleoptiles contained between six and ten radioactive compounds,one of which co-chromatographed with IAA. The metabolic productsin coleoptile extracts appeared to be similar to those in rootextracts, with an oxindole-3-acetic-acid-like component as theprincipal metabolite, but the rate of metabolism was slowerin coleoptile than in root segments. Decarboxylation did notappear to play a major role in the metabolism of exogenous IAAduring the short incubation periods. Moreover, external IAAconcentration had little effect on the pattern of metabolism.Coleoptile segments were also supplied with [¹⁴C]IAA from agardonor blocks placed at the apical ends, and agar receiver blockswere placed at the basal ends. After incubation for 4 h, theidentity of the single radioactive compound in the receiverblocks was shown to be IAA by both reverse-phase high-performanceliquid chromatography and gas chromatography-mass spectrometrytechniques. Key words: Zea mays, Coleoptile, High-performance liquid chromatography, Indole-3-acetic acid     

Studies on soluble RNA binding indoleacetic acid in etiolated mung bean hypocotyl sections

Nucleic acid was extracted by the SLS-phenol method from Phaseolusaureus hypocotyl treated with IAA-2-¹⁴C. Radioactivity in thenucleic acid fraction was found at the positions of sRNA andrRNA on an MAK column. IAA-¹⁴C was released from the radioactivecompound(s) in the sRNA fraction, by alkaline hydrolysis, butnot by ethanol extraction, or by dialysis to 2 M NaCl, 8 M urea,and 0.1 M EDTA. When the radioactive compound at the positionof sRNA on an MAK column was further re-chromatographed on aDEAE-cellulose column and on a BD-cellulose column, it was alwayslocalized only in a settled part of the fraction of each column.From this fraction IAA-¹⁴C was released by alkaline hydrolysis.Also, IAA-¹⁴C was released from the radioactive compound insRNA fraction, by RNase digestion, but not by pronase treatment.Results of these experiments suggest the existence of some kindsof sRNA binding IAA. The genesis of this sRNA binding IAA-¹⁴Cwas observed within 30 min after the supply of IAA-¹⁴C, andthe sRNA became saturated with IAA-¹⁴C about 2 hr after thebeginning of incubation. The behavior of sRNA binding IAA, representedby sRNA binding IAA-¹⁴C, may have a role in IAA induced growthof mung bean hypocotyl sections. (Received July 6, 1971; )     

Auxin Transport in Secondary Tissues1

Auxin transport was investigated in excised stem segments ofNicotiana tabacum L. by the agar block technique using [1-¹⁴C]indol-3yl-acetic acid (IAA). The ability of the stems to transportauxin basipetally increased as secondary development proceeded;by contrast the ability of the pith to transport auxin declinedwith age. By separation of the stem tissues it was shown thatthe great majority of auxin transport took place in cells associatedwith the internal phloem and in cells close to the cambium;in both cases similar velocities of transport were found (c.5.0 mm h^–1 at 22°C). The effects of osmotic gradientson auxin transport through the internal phloem were investigated.IAA was found by chromatography to account for practically allthe radioactivity in receiver blocks and other extracts of stemsegments. The significance of these results is discussed.     

Decarboxylation and Transport of Auxin in Segments of Sunflower and Cabbage Roots. II. A Chromatographic Study Using IAA-1-14C and IAA-5-3H

The polar movement of IAA has been examined in 5-mm root segments of Brassica oleracea and Helianthus annum. The movement was studied partly with IAA-1-¹⁴C and partly with IAA-5-³H. In both plants a slight acropetal flux of ¹⁴C and IAA-³H was found through the segments. The recovered radioactivity in the agar receiver blocks and in the receiver end of the segments increased as a function of time. A large portion of the applied IAA was converted on the cut surfaces and in the tissues of the segments. Chromatographic analysis indicated different destruction products when estimated by scintillation counting and by spraying with in-dole reagent (DMCA). Chromatograms run in isopropanol: ammonia: water, 8:1:1, yielded three different substances, one spot near the starting line and one near the front, neither of which has been identified. Finally there was a spot with R_f 0.4–0.6, probably representing IAA.     

Effect of kinetin on auxin uptake and distribution in normal and tumor-prone Nicotiana shoots

Stem segments of non-tumorous Nicotiana glauca and N. langsdorffiiplants and of their tumor-producing amphidiploid F₁ hybrid weretreated with 6-furfurylaminopurine (kinetin) prior to transporttests with applied labeled indoleacetic acid (IAA-2-¹⁴C). Kinetin-treatmentsincreased the uptake of IAA in non-tumorous shoots; the IAAuptake by N. langsdorffii segments was increased up to 3-fold.The auxin uptake in stem-segments of the tumor-forming hybrid,however, could not be increased significantly by kinetin. Theeven distribution of IAA-¹⁴C in segments of normal and tumorproneNicotiana shoots is stimulated by kinetin. Data are discussedin conjunction with previous results on auxin transport andtumorformation in Nicotiana. (Received August 8, 1972; )     

Auxin transport in roots

Summary The reasons underlying the initial increase and subsequent decrease in the amount of radioactivity in the receiver block at the apical end of a Zea root segment supplied with a basal donor block containing labelled IAA have been investigated.The phenomenon was observed in segments supplied with IAA-1-¹⁴C, IAA-2-¹⁴C and IAA-5-³H. An acropetal polarity in the movement of radioactivity into the receiver blocks was observed using donor blocks containing IAA-5-³H at concentrations as low as 10^-10M.The decrease in the amount of radioactivity in the receiver block begins after 6–8 h of transport at 25° C, and is unaffected by renewal of the donor block every 2 h, or the presence of 2% sucrose in the donor and receiver blocks.The net export of radioactivity into the receiver block at the apical end of the segment virtually ceases after 6–8 h of transport at 25° C, and is not prolonged by the presence of 2% sucrose in the donor and receiver blocks. At 10° C, net export of radioactivity continues for at least the first 50 h of transport, and the amount of radioactivity in a continuously applied receiver block continues to increase over this period.Receiver blocks removed from the apical end of segments after 8 h of transport and placed on planchettes show little or no decrease in the amount of radioactivity they contain as a function of time, in marked contrast to those left in contact with the segment.There is a marked, and metabolically dependent, resorption of radioactivity from the receiver block at the apical end of the segment after about 8 h of transport at 25° C; most of the resorbed radioactivity remains in the apical 2–4 mm of the segment.There is a loss of radioactive CO₂ from segments supplied with a basal donor block containing 10^-6M IAA-1-¹⁴C at 25° C, the emission beginning after 6–8 h of transport. Segments similarly supplied with 10^-6M IAA-2-¹⁴C did not begin to lose radioactive CO₂ until after about 10–12 h of transport.The ability of the segments to transport radioactivity in a polar manner declines with time after they are excised from the root, regardless of whether their cut ends are kept in the intervening period in contact with plain agar blocks, or ones containing unlabelled IAA at 10^-6M. By the 6th h after excision at 25° C no transport of radioactivity through the segments and into the receiver blocks could be detected in either the aropetal or basipetal direction.The decrease in radioactivity in the receiver block after transport periods of 6–8 h at 25° C is therefore due to (1) a cessation of net export of radioactivity into the block, and (2) the onset of a metabolically-dependent, net resorption of radioactivity. At this time substantial amounts of radioactive CO₂ begin to be evolved from segments supplied with IAA-1-¹⁴C, whereas with IAA-2-¹⁴C radioactive CO₂ is not evolved for a further 4–6 h.     

Basipetally polarised transport of [3H]gibberellin A1 and [14C]gibberellin A3, and acropetal polarity of [14C]indole-3-acetic acid transport,in stelar tissues of Phaseolus coccineus roots

Summary Movement of both [³H]GA₁ and [¹⁴C]GA₃ through root segments from P. coccineus seedlings was basipetally polarised. The basipetal/acropetal ratio of radioactivity from [³H]GA₁ in agar receiver blocks was 9.2 for apical, elongating segments, and 4.0 for more basal, non-elongating segments. Polarity of gibberellin transport was restricted to the stele, and absent from cortical tissues. Transport of [¹⁴C]IAA through root segments to agar receivers was preferentially acropetal, particularly so in the stele. Despite the existence of basipetal polarity of gibberellin transport in the root, [³H]GA₁ injected into cotyledons moved into and acropetally along the seedling root.     

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.     

Auxin Transport in Roots: V. EFFECTS OF TEMPERATURE ON THE MOVEMENT OF IAA IN ZEA ROOTS

The effects of temperature on the polar movement of IAA through6-mm and 12-mm segments of Zea mays roots have been investigatedover the range from 1 to 50°C. At all temperatures an acropetal polar movement of IAA predominated,although at low temperatures and at 50°C the 6-mm segmentsshowed a transient basipetal polarity, before the persistentacropetal polarity developed. At 1°C the differences betweenacropetal and basipetal movement of IAA were less distinct thanat the other temperatures. There is, however, a marked metabolically-dependentacropetal movement of IAA through the tissues at 1°C, becausewhen the segments were deprived of oxygen the acropetal movementwas severely reduced while the basipetal movement was reducedto a smaller extent. At 1°C and at 5°C there was alwaysa persistent basipetal polarity of IAA movement through 6-mmand 12-mm segments under anaerobic conditions. The velocity of acropetal movement (mm h^–1) was the samethrough the 6-mm and the 12-mm segments and was markedly affectedby temperature. It increased from 1°C to a maximum valueof 8 mm h^–1 at 31°C and then decreased again at 40and 50°C. The velocity of basipetal movement could be assessedonly at 1 and 5°C at which temperatures it was greater thanthe velocity of acropetal movement, and virtually independentof segment length. The acropetal flux of IAA (cpm h^–1) was much less through12-mm segments than through 6-mm segments. For both lengthsof segment, however, the flux showed a complex relationshipwith ambient temperature, increasing from 1°C to a maximumat 10–15°C, declining to a minimum value at 31°Cand then rising again at 40 and 50°C. The basipetal fluxof IAA could be astimated only at 1 and 5°C at which itwas very much smaller than the acropetal flux. The amount of IAA in the receiver blocks increased linearlywith time at the lower temperatures. At temperatures withinthe range 15°C to about 31°C, however, the amount ofIAA in the receiver blocks began to decline if the transportperiods exceeded a certain length. The time at which this declinein the IAA in the receiver block began was related to the ambienttemperature. Chromatographic analysis indicated one radioactive substancein receiver blocks at the apical end of segments supplied withIAA-1-¹⁴C at the basal end after transport periods of 6 h at25°C, and 72 h at 5°C. The Rf of this substance wasclosely similar to that of the radioactive IAA supplied in thedonor blocks.     

Translocation of Indole-3-acetic Acid-1'-C and Tryptophan-1-C in Seedlings of Phaseolus coccineus L. and Zea mays L

Indole-3-acetic acid-1′-¹⁴C (IAA-¹⁴C) and tryptophan-1-¹⁴C injected in small amounts into cotyledons of Phaseolus coccineus L. seedlings were found to be translocated acropetally into the epicotyls and young shoots. Similarly IAA-¹⁴C was translocated acropetally into coleoptiles of Zea mays following injection into the endosperms. Labeled metabolites of the injected compounds were also extractable from shoot tissue. However, evidence that IAA-¹⁴C itself was translocated acropetally was obtained by collection in agar blocks applied to cut surfaces of coleoptiles of injected seedlings. The acropetal translocation in Phaseolus was shown not to occur in the transpiration stream but in living tissue. Cotyledons of Phaseolus coccineus and Phaseolus vulgaris contain extensive vascular tissue.     

Auxin transport in roots

Summary The net uptake and movement of radioactivity by 12-mm root segments of Zea mays have been studied as a function of time at 5, 15 and 25° C. Segments were supplied with an agar donor block containing 1 M IAA-1-¹⁴C or IAA-2-¹⁴C continuously or for a limited period of time (pulse-labelling). In the latter case the original donor block was replaced either by a plain agar block or by one containing 1 M unlabelled IAA. Receiver blocks were placed at the other end of the segments.The net uptake of radioactivity from the donor block at 15° C was greater at the basal end than at the apical end of the segment. At 5 and 15° C, the net uptake from a basal donor was virtually linear with time but at 25° C the rate of net accumulation decreased after about 10 h. Decarboxylation of IAA undoubtedly occurred at 15 and 25° C when the concentration in the tissue attained a high value.An acropetally polarised movement of radioactivity into the receiver blocks occurred regardless of whether the results were based on the actual amounts of radioactivity in the receiver block, or on the amounts in the receiver block expressed as a percentage of the net total radioactivity accumulated from the donor block. Only one radioactive substance was present in the receiver block and it ran to the same R_f as IAA in the isopropanol: ammonium: water solvent system.The amounts of radioactivity moving into that part of the root segment at least 6 mm distant from the end in contact with either an apical or a basal donor block were assessed. An acropetal polarity in the movement of radioactivity was observed on the basis of the actual amounts of radioactivity in these distal parts of the segments, but no such polarity was evident when the amounts of radioactivity were expressed as a percentage of the net total accumulated from the donor block. At least 3 radioactive substances were present in the tissue in addition to the substance running to the same R_f as IAA. The distribution of radioactivity in the segment cannot therefore be used to assess the distribution of IAA.Acropetal movement of radioactivity into an apical receiver block is not dependent upon the continued uptake of IAA at the basal end of the segment. No distinct pulses of radioactivity were detected moving through the root segments.Only a small part of the radioactivity in the root segment appears to be located in the polar transport system, while the bulk is not. The polarity found in the movement of the bulk radioactivity within the segment seems to be related to the polarity in IAA uptake from the donor blocks.     

Auxin transport in roots

Summary Light promotes the net acropetal movement of ¹⁴C through 6-mm subapical segments of dark-grown roots of Zea mays supplied at their basal ends with 1 M IAA-1-¹⁴C in agar blocks. This promotion occurs only when the segments are irradiated during the transport period, and both red and blue light appear to be as effective as white light at the radiant flux densities used in this investigation. The promotion is not found if the segments are pretreated with light and then returned to darkness before the trasport of IAA-1-¹⁴C is determined. The very slight basipetal movement of ¹⁴C through the segments supplied with an apical source of IAA-1-¹⁴C is unaffected by light.Only one radioactive substance is found in the apical receiver blocks. This substance has an R_f virtually identical to those of the stock solution of IAA incorporated into the donor block and of unlabelled IAA. The movement of radioactivity into the receiver blocks through, the illuminated segments therefore appears to reflect the movement of IAA. Light thus increases the acropetal movement of IAA through the Zea root segment.The primary roots of Zea mays var. Giant Horse Tooth seedlings grown in total darkness do not exhibit a positive geotropic response. When the seed is orientated with the embryo uppermost the radicle grows out horizontally. On exposure to light, however, the roots bend down. This reaction appears about 3–9 hours after the onset of illumination, and white, red and blue light appear to be equally effective at the flux densities employed in this study. Green light in the spectral band between 510–530 nm did not appear to induce this positive geotropic responsiveness.     

The Lateral Transport of 2, 4-Dichlorophenoxyacetic Acid in Horizontal Hypocotyl Segments of Helianthus annuus

The longitudinal and lateral transport of 2, 4-D-[1-¹⁴C] hasbeen studied in 6-mm horizontally disposed segments of the hypocotylof Helianthun annuus. The technique involved the asymmetricapplication of the auxin in agar donor blocks to either theupper or lower halves of the cut surface of the segments andthe measurement of ¹⁴C accumulating with time in split receiverblocks on the upper and lower halves of the cut surfaces atthe opposite ends. A highly significant effect of gravity inducinga polar migration of 2, 4-D to the lower side has been establishedand represents, under optimal conditions, about 10 per centof the total 2, 4-D in transit. This lateral polar movementshows a tendency to saturate at higher donor concentrations(5 mg/1) and is affected by temperature in precisely the sameway as the basipetal longitudinal transport. The optimal flux(intensity of transport) occurs at about 35 °C or slightlyabove, and above 40 °C both transport systems are seriouslyimpaired. There is some evidence that gravity increases thevelocity of 2, 4-D transport in the lowermost tissues of thehorizontal hypocotyl but does not affect the transport intensity.     

Auxin Transport in Tendril Segments of Passiflora caerulea

The movement of auxin through tendril segments of Passiflora caerulca L. has been investigated using IAA-2-¹⁴C. It has been shown that (1) flux of IAA through the segments is strongly polarized basipetally: (2) the amount of ¹⁴C recovered in the basal receiver blocks increases linearly within a transport period of 6 h; (3) velocity of basipetal transport is 14.5 mm h^?1; (4) at least 70% of the radioactivity in the receiver blocks is confined to the IAA molecule: approximately 55% of ¹⁴C from methanolic extracts of the segments is IAA: (5) at low temperatures (2–4°C) the basipetal transport is abolished; (6) white light promotes basipetal transport, and this effect is abolished in a CO₂-free atmosphere; (7) no difference could be detected in ¹⁴C content between dorsal and ventral halves of tendril segments nor among individual dorsal and ventral receiver blocks.     

Auxin-promoted Transport of Metabolites in Stems of Phaseolus vulgaris L.: SOME CHARACTERISTICS OF THE EXPERIMENTAL TRANSPORT SYSTEMS

Indol-3yl-acetic acid (IAA) applied to sterns of Phaseolus vulgarisseedlings, decapitated above primary leaves, enhanced the mobilizationof ¹⁴C-metabolites to the treated stumps and this effect wasapparent within 3–6 h of applying the hormone. More than90 per cent of the total ¹⁴C-activity transported to the stumpswas detected in the alcohol-soluble extracts. In all treatments,less than 5 per cent of the ¹⁴C-photosynthate exported fromthe primary leaves was translocated upwards. Accumulation of¹⁴C-activity was also increased when the IAA was applied laterallyto intact internodes. This effect was obtained when ¹⁴C wassupplied either above or below the point of hormone application.By selective heat girdling, it was shown that the auxin affected¹⁴C transport when either the root ‘sink’ was removedor transpiratory flow of water through the treated internodewas maintained. Decapitated stems treated with plain lanolinfor 3 d were found to retain their responsiveness to auxin interms of enhanced metabolite transport. Heat-girdling experimentsand estimates of ¹⁴C transport velocity suggested that mostof the ¹⁴C movement was restricted to the phloem of treatedstumps. Similar effects of IAA on a transport in excised stemsegments of Phaseolus vulgaris were observed.     

Effect of {alpha}-Tomatine on the Response of Wheat Coleoptile Segments to Exogenous Indole-3-acetic Acid

A concentration of 10^–5 M tomatine had no effect on leakagefrom, or elongation of, wheat coleoptile segments, but consistentlyreduced IAA-enhanced extension growth by c. 50 per cent. Therewas no evidence of chemical interaction between the alkaloidand the auxin in solution, and IAA action was not affected bypre-treatment for up to 3 h with 10^–5 M tomatine. Studieswith [2-¹⁴C]IAA revealed that 10^–5 M tomatine did notinhibit uptake of auxin into segments. The effect of pre-treatingsegments for up to 3 h with IAA could be virtually nullifiedby 10^–5 M tomatine, as could also IAA-induced changesin properties of coleoptile cell walls. Results are discussedin relation to the ability of tomatine to disrupt membrane functionand to current hypotheses implicating membranes in the primaryaction of auxin.     

Transport and Metabolism of Kinetin-8-14C in the Mesocotyl and Coleoptile of Zea mays L.

The movement and metabolism of kinetin-8-¹⁴C in the mesocotyland coleoptile of Zea mays have been investigated. The segments (10 mm) of coleoptile with and without an apexwere used. The presence of apex decreases the quantity of countswhich move basipetally in the segments. The quantity transported acropetally in the segments (apex incontact with receiver blocks) was about three times higher thanthat transported basipetally (apex in contact with donor blocks). Using 10 mm coleoptile segments excised I mm below the apex,there was no appreciable difference between acropetal and basipetalmovement. The transport of kinetin in the mesocotyl was studied with andwithout vascular tissue. The quantity transported in segmentswithout vascular tissue was always lower than in the segmentswith vascular tissue. The presence of the node between the coleoptile and mesocotyldoes not disturb the movement of kinetin in the basipetal position(node in contact with donor blocks). Thin layer chromatography of plant extracts after a 48-hourtransport period revealed several radioactive substances whichappeared to be adenine with R_f 0.5 and other components appearedat R_f 0.6.