Ethylene modification of an auxin pulse in cotton stem sections

The effect of ethylene on the basipetal movement of indole-3-acetic acid-1-¹⁴C through cotton stem sections (Gossypium hirsutum, L. var. Stoneville 213) was studied apart from processes involved in the uptake and exit of auxin by the section. Stem sections 60 mm in length were pretreated with ethylene or placed in room air (control) and pulse labeled for 20 min with IAA-1-¹⁴C. In both the ethylene treated and control sections, the IAA-1-¹⁴C taken up moved basipetally as a peak of radioactivity. Generally, the applied pulse moved down the stem sections at an average velocity of approximately 5.8 mm per hr. In some experiments, however, ethylene slightly reduced the velocity of auxin transport. Although the peak of radioactivity became broader and more dispersed during its migration through the section, it was still distinguishable after 7 hr of transport.     

A saturable site responsible for polar transport of indole-3-acetic acid in sections of maize coleoptiles

The velocity of transport and shape of a pulse of radioactive indole-3-acetic acid (IAA) applied to a section of maize (Zea mays L.) coleoptile depends strongly on the concentration of nonradioactive auxin in which the section has been incubated before, during, and after the radioactive pulse. A pulse of [³H]IAA disperses slowly in sections incubated in buffer (pH 6) alone; but when 0.5–5 M IAA is included, the pulse achieves its maximum velocity of about 2 cm h^-1. At still higher IAA concentrations in the medium, a transition occurs from a discrete, downwardly migrating pulse to a slowly advancing profile. Specificity of IAA in the latter effect is indicated by the observation that benzoic acid, which is taken up to an even greater extent than IAA, does not inhibit movement of [³H]IAA. These results fully substantiate the hypothesis that auxin transport consists of a saturable flux of auxin anions (A^-) in parallel with a nonsaturable flux of undissociated IAA (HA), with both fluxes operating down their respective concentration gradients. When the anion site saturates, the movement of [³H]IAA is nonpolar and dominated by the diffusion of HA. Saturating polar transport also results in greater cellular accumulation of auxin, indicating that the same site mediates the cellular efflux of A^-. The transport inhibitors napthylphthalamic acid and 2,3,5-triiodobenzoic acid specifically block the polar A^- component of auxin transport without affecting the nonsaturable component. The transport can be saturated at any point during its passage through the section, indicating that the carriers are distributed throughout the tissue, most likely in the plasmalemma of each cell.Abbreviations A^- auxin anion - HA undissociated auxin - IAA indole-3-acetic acid - NPA N-1-napthylphthalamic acid - TIBA 2,3,5-triiodobenzoic acid     

Movement of Indoleacetic Acid in Coleoptiles of Avena sativa L. II. Suspension of Polarity by Total Inhibition of the Basipetal Transport

Acropetal and basipetal movement of indole-3-acetic acid through coleoptiles of Avena sativa L. was studied. Sections 10-mm long were supplied with either apical or basal sources containing C(14) carboxyl-labeled indoleacetic acid (10(-5)m). Anaerobic conditions inhibit metabolically dependent movement (transport) thus reducing basipetal but not acropetal movement. Total inhibition of basipetal transport abolishes the polarity of auxin uptake and movement. The nonpolar movement that remains in anaerobic sections is free diffusion with an average diffusion coefficient of approximately 1 x 10(-4) mm(2) per second. During an 8-hour diffusion, at least the first millimeter of the section comes to equilibrium at approximately the same concentration as the donor.Acropetal movement is probably by diffusion and is accompanied by an aerobic immobilization of indoleacetic acid that increases more than proportionally to concentration. Anaerobic conditions totally prevent this immobilization and reduce acropetal uptake but not the amount of indoleacetic acid moving into the upper parts of the section; there is, therefore, no evidence for acropetal transport.Polarity of auxin movement in aerobic coleoptile sections is achieved by strict basipetal transport of auxin. The basipetal transport may intensify the polarity by recycling auxin that is moving acropetally.     

Effect of Inversion on Growth and Movement of Indole-3-acetic Acid in Coleoptiles

The effect of a 180° displacement from the normal vertical orientation on longitudinal growth and on the acropetal and basipetal movement of ¹⁴C-IAA was investigated in Avena sativa L. and Zea mays L. coleoptile sections. Inversion inhibits growth in intact sections (apex not removed) and in decapitated sections supplied apically with donor blocks containing auxin. Under aerobic conditions, inversion inhibits basipetal auxin movement and promotes acropetal auxin movement, whereas under anaerobic conditions, it does not influence the movement of auxin in either direction. Inversion retards the basipetal movement of the peak of a 30-minute pulse of auxin in corn.

The inversion-induced inhibition of basipetal auxin movement is not explained by an effect of gravity on production, uptake, destruction, exit from sections, retention in tissue, or purely physical movement of auxin. It is concluded that inversion (a) inhibits basipetal transport, the component of auxin movement that is metabolically dependent, and as a result (b) inhibits growth and (c) promotes acropetal auxin movement.

     

Transport of the two natural auxins, indole-3-butyric acid and indole-3-acetic acid, in Arabidopsis

Polar transport of the natural auxin indole-3-acetic acid (IAA) is important in a number of plant developmental processes. However, few studies have investigated the polar transport of other endogenous auxins, such as indole-3-butyric acid (IBA), in Arabidopsis. This study details the similarities and differences between IBA and IAA transport in several tissues of Arabidopsis. In the inflorescence axis, no significant IBA movement was detected, whereas IAA is transported in a basipetal direction from the meristem tip. In young seedlings, both IBA and IAA were transported only in a basipetal direction in the hypocotyl. In roots, both auxins moved in two distinct polarities and in specific tissues. The kinetics of IBA and IAA transport appear similar, with transport rates of 8 to 10 mm per hour. In addition, IBA transport, like IAA transport, is saturable at high concentrations of auxin, suggesting that IBA transport is protein mediated. Interestingly, IAA efflux inhibitors and mutations in genes encoding putative IAA transport proteins reduce IAA transport but do not alter IBA movement, suggesting that different auxin transport protein complexes are likely to mediate IBA and IAA transport. Finally, the physiological effects of IBA and IAA on hypocotyl elongation under several light conditions were examined and analyzed in the context of the differences in IBA and IAA transport. Together, these results present a detailed picture of IBA transport and provide the basis for a better understanding of the transport of these two endogenous auxins.     

THE TIME-COURSE OF POLAR MOVEMENT OF GIBBERELLIN THROUGH ZEA ROOTS

The polarity of movement of gibberellin through sections cut from near the root tips of Zea mays L. was studied, using methods like those we previously used in roots for auxin and in petioles for auxins, cytokinins, and gibberellic acid (GA-3). One μg GA-3 was added in a donor agar block and gibberellin activity in the receiver agar at the opposite end of the section was measured directly with a modified barley endosperm bioassay. The movement of gibberellin was away from the root tip (basipetal) and thus opposite in direction to the polarity of auxin through such root sections. The time-course of basipetal movement was dissimilar to that for gibberellin or auxin movement through petiole sections. It took 14-18 hr for gibberellin activity equivalent to 6 ng GA-3 to collect in the basal receivers on roots. Apical receivers showed activity equivalent to 1.6 ng GA-3 at 14-18 hr. Less than 0.01 ng equivalent GA-3 was collected from sections to which GA-3 was not added, so the 6 and 1.6 ng were almost entirely due to the added GA-3. These general conclusions were confirmed with an experiment using ¹⁴C-GA-3. A decline in activity in receivers was found in some experiments at 18 hr, paralleling earlier results with GA-3, IAA, and adenine in petioles and IAA in roots.     

Basipetal and Acropetal Auxin Transport in Relation with Temperature

In stem sections of lentil seedlings, there is a typical polar movement of IAA labelled with ¹⁴C. The degree of polarity, expressed as the ratio of basipetal to acropetal transport, was (25°C) 7.6. A decrease (from 25° to 15°C) and an increase (from 25° to 30°C) of temperature cause a reduction of the IAA uptake by the sections and a decrease of both the basipetal and the acropetal translocation of IAA. Results suggest that the basipetal as well as the acropetal movement of auxin, are dependent of a metabolical component which is discussed.     

The Promotion of the Immobilization of Auxin in Avena Coleoptiles by Triiodobenzoie Acid

A study was made of the inhibition of auxin transport in Avena coleopliles by 2, 3, 5-triiodobenzoic acid (TIBA), using carboxyl labelled ¹⁴C indole-3-acetic acid (IAA). A transport period of 1 hour followed by an export period of 2 hours was used routinely. Treatment with TIBA resulted in increased radioactivity remaining in the coleoptile sections after the export period. This radioactivity was distributed throughout the length of the coleoptile. The increase in radioactivity was shown to be due to an increase in the amount of IAA immobilized. The action of TIBA in inhibiting auxin transport is achieved by the promotion of the immobilization of IAA.     

Gravitropic Responses of Partially Decapitated Corn Coleoptiles with and without Applied [C]Indoleacetic Acid

The curvature of corn seedling (Zea mays L. Mo17 × B73) coleoptiles which had been half-decapitated and supplied with [¹⁴C]indoleacetic acid (IAA) (3.2 micromolar, 51 milliCuries per millimole) was determined during a 3-hour period of gravitational stimulation. Curvature of such half-decapitated coleoptiles was found to be similar in rate and extent to that of intact coleoptiles responding to gravity. Gravitational stimulation was accomplished by reorienting seedlings to a horizontal position, either up or down with respect to the removed half of the coleoptile tips.

The first set of experiments involved placing aluminum foil barriers along one of the two cut surfaces to restrict the movement of IAA into tissues. The initiation and extent of curvature of these half-decapitated coleoptiles was dependent upon the orientation of the removed half-tip and the accompanying barrier. The distribution of radioactivity from [¹⁴C] IAA after 3 hours indicated that the specific lateral movement of label was also dependent upon orientation of the removed half-tip of the coleoptile. A specific movement to the lower side of approximately 14% of the total recovered radioactivity was found in coleoptiles in which the [¹⁴C]IAA was supplied across a transverse cut surface. In contrast, specific movement of only 4% was found for application across a longitudinal cut surface.

A second series of experiments was conducted using 1.0 and 3.2 micromolar [¹⁴C]IAA (51 milliCuries per millimole) supplied to half-decapitated coleoptiles without inserted barriers. The 3.2 micromolar concentration adequately replaced the removed coleoptile half-tips in terms of straight growth, but it did not result in as much curvature as shown by coleoptiles of intact seedlings. The 1 micromolar concentration was not adequate to replace the removed half-tip in straight growth, but resulted in gravitropic curvature nearly as great as that produced by the higher concentration.

The data presented here suggest that strong auxin gradients are not produced in response to gravity stimulation based on the recovered radioactivity from [¹⁴C]IAA. However, it is evident that auxin is required for the development of normal gravitropic responses. It is possible, therefore, that an important early role of this movement is not to cause a large stimulation of growth on the lower side but to decrease growth on the upper side of a gravitropically responding coleoptile.

     

The Role of Basipetal Auxin Transport in the Positional Control of Abscission Sites Induced in Impatiens sultani Stem Explants

If segments of Impatiens sultani stem are explanted and incubated,separation layers often form across them and lead to abscission.To test the suggested role of auxin concentration in controllingthe position of abscission sites, explants were labelled byapplying [¹⁴C]IAA to the shoot tip 4 h prior to explanting;transport of auxin applied in this way seems to resemble thatof endogenous auxin. During subsequent incubation of explantsfor 20 h, basipetal transport resulted in ¹⁴C accumulating justabove the base of the explants (nearly 80 % in the bottom 4mm of 24 mm explants). In internodal explants that had beenwounded at explanting by incising one side so as to sever avascular bundle, and in nodal explants with the leaf removed,the ¹⁴C also accumulated just above the wound or node to abouttwice the concentration otherwise expected; this accumulationwas probably due to basipetal transport being impeded by vasculardiscontinuity at the wound or node. Accumulation just abovethe base, or above a wound or node, resulted in gradients of¹⁴C concentration (presumably reflecting endogenous auxin concentration)decreasing in the morphologically upward direction at each ofthese three positions where abscission sites tend to occur. Impatiens sultani, abscission, auxin, IAA, node, polarized transport, positional control, separation layer, wounding     

Auxin transport and the regulation of petiole abscission in cotton (Gossypium hirsutum L.): A comparison of indol-3yl-acetic acid and phenylacetic acid

Distal applications of indol-3yl-acetic acid (IAA) to debladed cotyledonary petioles of cotton (Gossypium hirsutum L.) seedlings greatly delayed petiole abscission, but similar applications of phenylacetic acid (PAA) slightly accelerated abscission compared with untreated controls. Both compounds prevented abscission for at least 91 h when applied directly to the abscission zone at the base of the petiole. The contrasting effects of distal IAA and PAA on abscission were correlated with their polar transport behaviour-[1-¹⁴C]IAA underwent typical polar (basipetal) transport through isolated 30 mm petiole segments, but only a weak diffusive movement of [1-¹⁴C]PAA occurred.Removal of the shoot tip substantially delayed abscission of subtending debladed cotyledonary petioles. The promotive effect of the shoot tip on petiole abscission could be replaced in decapitated shoots by applications of either IAA or PAA to the cut surface of the stem. Following the application of [1-¹⁴C]IAA or [1-¹⁴C]PAA to the cut surface of decapitated shoots, only IAA was transported basipetally through the stem. Proximal applications of either compound stimulated the acropetal transport of [¹⁴C]sucrose applied to a subtending intact cotyledonary leaf and caused label to accumulate at the shoot tip. However, PAA was considerably less active than IAA in this response.It is concluded that whilst the inhibition of petiole abscission by distal auxin is mediated by effects of auxin in cells of the abscission zone itself, the promotion of abscission by the shoot tip (or by proximal exogenous auxin) is a remote effect which does not require basipetal auxin transport to the abscission zone. Possible mechanisms to explain this indirect effect of proximal auxin on abscission are discussed.     

Polarity of Thiamine Movement through Tomato Petioles

Thiamine-¹⁴C moved through petiolar sections of Lycopersicon esculentum Mill. var. Michigan State Forcing with striking similarity in kinetics to auxins and gibberellic acid moving through similar sections of other green plants. Thiamine moved with strong basipetal polarity, at a velocity of 3 to 5 mm per hour, and emerged unchanged into the basal receiver agar block, judging by chromatography. This lends support to the hypothesis that polar movement is a property of several classes of plant hormones, rather than being restricted to the auxins (as previously believed).     

MOVEMENT OF IAA IN SECTIONS FROM SPIDER FLOWER (CLEOME HASSLERIANA) STAMEN FILAMENTS

Movement of IAA in spider flower (Cleome hassleriana Chod.) stamen filaments was studied by placing 2-mm sections horizontally between donor agar blocks containing ¹⁴C-labeled IAA and plain agar receiver blocks and measuring radioactivity in the donor and receiver blocks and filament sections by scintillation counting after the desired transport time. Movement was strictly polar and basipetal at all stages of floral development, except in open flowers just before stamen abscission when the amounts moving acropetally and basipetally were equal. The amount of IAA moved depended upon the stage of development. As buds aged more IAA was moved, until the buds opened and the stamen filaments reached maximum elongation; then the amount of IAA moving basipetally dropped drastically. There was an insignificant amount of acropetal IAA movement except just before stamen abscission. This change in IAA movement is not due to a change in filament diameter. In time-course studies the amount of IAA moved basipetally increased with time up to 5 hr and then declined slightly. The amount of radioactivity retained by sections increased until 8 hr. The amount of IAA moved in tip sections was less than that in mid or base sections; however, this can be partially explained by differences in uptake area of these sections. The relationship of these results to the hypothesis that changes in IAA movement are important in the control of stamen filament elongation and abscission is discussed.     

POLAR TRANSPORT OF GROWTH-REGULATORS IN PITH AND VASCULAR TISSUES OF COLEUS STEMS

Movement of IAA-C¹⁴ and 2,4-D-C¹⁴ through cylinders of known size and histology was compared using liquid scintillation counting. Both auxins showed strongly polar movement, even through pith parenchyma cut from Coleus internode #5, the youngest internode to have ceased elongation. The polar movement was correlated with sizable elongation of the excised cylinders. Velocities of basipetal movement for a given auxin, as determined by the intercept method, showed small or negligible differences between pith and “corner” cylinders. (Corner cylinders comprised mostly vascular tissue, plus some cortical, pith, and epidermal cells.) For IAA, basipetal velocities ranged from 2.1 to 3.3 mm per hr; for 2,4-D, they were 0.6–0.8. For both auxins there was much more net loss into corner than into pith cylinders, a difference associated with the fact that corner cylinders showed 10 times as many cells in transection. More 2,4-D moved basipetally through corner than through pith cylinders and the reverse was true of IAA. By chromatographic evidence, all the radioactivity in the basal receiving blocks was still associated with the auxin molecules.     

Cell wall pH and auxin transport velocity

According to the chemiosmotic polar diffusion hypothesis, auxin pulse velocity and basal secretion should increase with decreasing cell wall pH. Experiments were designed to test this prediction. Avena coleoptile sections were preincubated in either fusicoccin (FC), cycloheximide, pH 4.0, or pH 8.0 buffer and subsequently their polar transport capacities were determined. Relative to controls, FC enhanced auxin (IAA) uptake while CHI and pH 8.0 buffer reduced IAA uptake. Nevertheless, FC reduced IAA pulse velocity while cycloheximide increased velocity. Additional experiments showed that delivery of auxin to receivers is enhanced by increased receiver pH. This phenomenon was overcome by a pretreatment of the tissue with IAA. Our data suggest that while acidic wall pH values facilitate cellular IAA uptake, they do not enhance pulse velocity or basal secretion. These findings are inconsistent with the chemiosmotic hypothesis for auxin transport.     

Indoleacetic-acid-enhanced chloride uptake into coleoptile cells

Summary The enhancement by indoleacetic acid (IAA) of ³⁶Cl^- uptake into Avena coleoptile sections was used to study the effects of a hormone on a membrane-controlled phenomenon. Compared to sections in phosphate buffer only, Cl^- content of the cells increases 15 min after addition of IAA; the promotion is seen only with growth-active auxins and is saturated at 3 M IAA. The percent enhancement by IAA is the same over a wide range of Cl^- concentrations. The hormone effect is not observed at ice-bath temperature and is not correlated with growth or water movement into the cells. IAA does not influence the movement of Cl^- in the section. While auxin must be present within the tissue in order to maintain the enhancement, there is no relationship between the total amount of auxin and the accelerated Cl^- uptake that results. A polarity in the auxin effect is implied since only apical applications of IAA promote Cl^- uptake.     

Transport and Degradation of Auxin in Relation to Geotropism in Roots of Phaseolus vulgaris

The movement of auxin in Phaseolus vulgaris roots has been examined after injection of IAA^?3H into the basal root/hypocotyl region of intact, dark-grown seedlings. Only a portion of the applied IAA^?3H was transported unchanged to the root tip. The major part of the chromatographed, labelled compounds translocated to the roots was indole-3-acetylaspartic acid (IAAsp) and an unidentified compound running near the front in isopropanol, ammonia, water. The velocity of the auxin transport (7.2 mm per hour) was calculated from scintillation countings of methanol extracts from serial sections of the root. An accumulation of radioactive compounds in the extreme root tip, was observed 5 h after the injection of IAA. The influence of exogenous IAA on the geotropical behaviour of the bean seedling roots was examined. Pretreated roots were stimulated for 5 min in the horizontal position and then rotated parallel to the horizontal axis of the klinostat for 60 or 90 min. The resulting geotropic curvature of IAA-injected and control roots showed significantly different patterns of development. When the stimulation was started 5 h after application of the auxin, the geotropic curvature became larger in roots of the injected plants than in the controls. If, however, the translocation period was extended to 20 h the geotropic curvature was significantly smaller in the roots of the injected plants. The auxin injection did not significally affect the rate of root elongation. The change in geotropical behaviour of the roots is interpreted as a result of the influence of the conversion products of the applied IAA on the geotropical responsiveness.     

Red Light-Regulated Growth : I. Changes in the Abundance of Indoleacetic Acid and a 22-Kilodalton Auxin-Binding Protein in the Maize Mesocotyl

We examined the changes in the levels of indoleacetic acid (IAA), IAA esters, and a 22-kilodalton subunit auxin-binding protein (ABP1) in apical mesocotyl tissue of maize (Zea mays L.) during continuous red light (R) irradiation. These changes were compared with the kinetics of R-induced growth inhibition in the same tissue. Upon the onset of continuous irradiation, growth decreased in a continuous manner following a brief lag period. The decrease in growth continued for 5 hours, then remained constant at 25% of the dark rate. The abundance of ABP1 and the level of free IAA both decreased in the mesocotyl. Only the kinetics of the decrease in IAA within the apical mesocotyl correlated with the initial change in growth, although growth continued to decrease even after IAA content reached its final level, 50% of the dark control. This decrease in IAA within the mesocotyl probably occurs primarily by a change in its transport within the shoot since auxin applied as a pulse moved basipetally in R-irradiated tissue at the same rate but with half the area as dark control tissue. In situ localization of auxin in etiolated maize shoots revealed that R-irradiated shoots contained less auxin in the epidermis than the dark controls. Irradiated mesocotyl grew 50% less than the dark controls even when incubated in an optimal level of auxin. However, irradiated and dark tissue contained essentially the same amount of radioactivity after incubation in [¹⁴C]IAA indicating that the light treatment does not affect the uptake into the tissue through the cut end, although it is possible that a small subset of cells within the mesocotyl is affected. These observations support the hypothesis that R causes a decrease in the level of auxin in epidermal cells of the mesocotyl, consequently constraining the growth of the entire mesocotyl.     

The role of auxin in growth of the plumular hook section of etiolated pea seedling

Externally applied GA greatly promoted elongation of the plumularhook section of the etiolated Alaska pea seedling, but IAA hadno such effect when given either alone or with GA. PCIB inhibitedelongation of the plumular hook section both in the presenceand absence of applied GA. The PCIB effect in the absence ofGA was partially overcome by IAA, but not completely. On theother hand, the PCIB effect in the presence of GA was completelyovercome by IAA. No antagonic response was, however, obtainedbetween GA and PCIB. CCC also retarded elongation of the sectionand this inhibition was completely overcome by GA, but not byIAA. There was little difference in the amount of endogenous auxindetectable in GA treated and untreated sections. These resultssuggest that auxin is necessary for the growth of both GA treatedand untreated plumular hook sections and that auxin and gibberellinact differently on the growth of the section. (Received April 24, 1968; )     

Auxin Transport in Roots: VI. MOVEMENT OF IAA THROUGH DIFFERENT ZONES OF ZEA ROOTS

The movement of IAA through 6-mm segments excised 1 mm, 7 mm,and 13 mm behind the apex of the primary root of Zea mays seedlingshas been investigated at temperatures between 10 and 25°C. In all segments, and at all temperatures, the movement of IAAwas polarized acropetally, more IAA being found in apical receiverblocks than in basal ones after transport periods of up to 24h. The amounts of IAA which moved acropetally through a segmentdecreased as the segment was taken at an increasing distancebehind the root apex. Similarly, at least after transport periodsof 8 h, more IAA moved basipetally through the apical segmentthan through the basal ones. At 10°C the velocity of acropetal movement was similar inall three segments, but the acropetbut the acropetal flux wasgreatest in the apical segment and smallest in the most basalone. The same situation appears to exist at the other temperatures. The flux and velocity of the acropetal movement of IAA througha 6-mm segment taken 7 mm behind the apex of the root were similarto those previously reported for the acropetal movement througha 12-mm segment excised 1 mm behind the apex. The smaller amountsof IAA which move acropetally through longer root segments aretherefore attributable to a limitation of the flux in the mostbasal regions of the segment.