The roles of cell-wall acidification and proton-pump stimulation in auxin-induced growth: studies using monensin

The carboxylic ionophore, monensin, rapidly induced cell-wall acidification and a decrease in cytosolic pH when added to maize coleoptiles at low external pH and Na⁺ concentration. Elongation growth at rates equivalent to those obtained with indole-3-acetic acid was induced for about 1 h. Stimulation of the outwardly directed proton pump apparently occurred, since under the same conditions monensin induced membrane hyperpolarization of maize root rhizodermis cells. When the external pH was high (>8) and Na⁺ present, monensin treatment caused only minimal changes in membrane potential and cytosolic pH. Although the ionophore transported protons out of the cell, resulting in cell-wall acidification, no elongation growth occurred. However, under identical conditions, indole-3-acetic acid dit induce growth. The data indicates that stimulation of the outwardly directed electrogenic proton pump rather than the subsequent acidification of the cell wall is vital for the induction of elongation growth.Abbreviations CFA₂ 6-carboxyfluorescein diacetate - FA₂ fluorescein diacetate - Hepes 4-(2-hydroxyethyl-1-piperazinepropanesulfonic acid - IAA indole-3-acetic acid - Mes 2-(N-morpholino) ethanesulfonic acid - Tris 2-amino-2-(hydroxymethyl)-1,3-propanediol     

Cytochemical identification of arabinogalactan protein in the outer epidermal wall of maize coleoptiles

Artificial carbohydrate antigen (Yariv reagent), fluorescence-labeled -l-fucose-binding lectin, and -D-galactose-binding lectin were used to localize arabinogalactan protein in sections of maize (Zea mays L.) coleoptiles. All three probes bind to cell walls of vascular tissue and the outer epidermis. Intense staining is obtained at the outer and inner faces of the growth-controlling outer epidermal wall. At the inner face of this wall the auxin-inducible osmiophilic particles, hitherto observed only by electron microscope (Kutschera et al. 1987, Planta 170, 168–180), are strongly stained by all three probes and can therefore be identified as deposits of arabinogalactan protein. It is proposed that this proteoglycan acts as an epidermal wallloosening factor in auxin-mediated coleoptile growth.Abbreviation AGP arabinogalactan protein I thank Dr. R. Bergfeld for the electron micrograph of Fig. 13. This work was supported by the Deutsche Forschungsgemeinschaft.     

In-vitro auxin transport in membrane vesicles from maize coleoptiles

When membrane vesicles from maize (Zea mays L.) coleoptiles are extracted at high buffer strength, a pH-driven, saturable association of [¹⁴C] indole-3-acetic acid is found, similar to the in-vitro auxin-transport system previously described for Cucurbita hypocotyls. The phytotropins naphthylphthalamic acid and pyrenoylbenzoic acid increase net uptake, pressumably by inhibiting the auxin-efflux carrier.Abbreviations IAA indole-3-acetic acid - ION3 ionophore mixture of carbonylcyanide-3-chlorophenylhydrazone, nigericin and valinomycin - 1-NAA, 2-NAA 1-, 2-naphthaleneacetic acid - NPA 1-N-naphthylphthalamic acid - PBA 2-(1-pyrenoyl)benzoic acid     

Different properties of two types of auxin-binding sites in membranes from maize coleoptiles

Two types of auxin-binding sites (sites I and II) in membranes from maize (Zea mays L.) coleoptiles were characterized. Site I was a protein with a relative molecular mass of 21 000, and the distribution of site I protein on sucrose density gradient fractionation coincided with that of NADH-cytochrome-c reductase (EC 1.6.99.3), a marker enzyme of the endoplasmic reticulum. Immunoprecipitation and immunoblotting studies showed that the content of site I protein in maize coleoptiles was approx. 2 g·(g FW)^-1. Site II occurred in higher-density fractions and also differed immunologically from site I. Site I was present at the early developmental stage of the coleoptile and increased only twice during coleoptile growth between day 2 and 4. Site II activity was low at the early stage and increased more substantially between day 3 and 4, a period of rapid growth of the coleoptile. Both sites decreased concurrently after day 4, followed by a reduction in the growth rate of the coleoptile. Coleoptiles with the outer epidermis removed showed a lower site I activity than intact coleoptiles, indicating that site I was concentrated in the outer epidermis. Site II, in contrast, remained constant after removal of the outer epidermis. The results indicate that site I is not a precursor of site II and that the two sites are involved in different cellular functions.Abbreviations FW fresh weight - M _r relative molecular mass - 1-NAA 1-naphthaleneacetic acid - 2-NAA 2-naphthaleneacetic acid - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Physiological evidence that the primary site of auxin action in maize coleoptiles is an intracellular site

To locate functionally the primary site of auxin action in growing cells, the pool of auxin relevant to induction of growth in maize (Zea mays L.) coleoptile sections was determined. A positive correlation was consistently noted between growth and intracellular levels of indole-3-acetic acid (IAA), i.e. growth appears to be relatively independent of the external level of IAA. N-1-Naphthylphthalamic acid (NPA), a potent inhibitor of auxin transport, was used to enhance accumulation of IAA in coleoptile cells. From the use of NPA, it is shown that: 1) increasing the accumulation of IAA in cells, while the external concentration is held constant, resulted in a concomitant increase in growth, and 2) blocking the exit of IAA from cells with NPA sustained an IAA-induced growth response in the absence of externally applied IAA. Furthermore, the absence of any alterations in auxin binding to microsomal fractions by NPA indicates that the action of NPA in causing enhancement of auxin-induced growth is based upon its inhibition of efflux of IAA from the cells. This research was supported by National Science Foundation grant No. DMB 8515925. The careful assistance of Laurie Brulport is gratefully acknowledged.     

Cooperation of epidermis and inner tissues in auxin-mediated growth of maize coleoptiles

The function of the epidermis in auxinmediated elongation growth of maize (Zea mays L.) coleoptile segments was investigated. The following results were obtained: i) In the intact organ, there is a strong tissue tension produced by the expanding force of the inner tissues which is balanced by the contracting force of the outer epidermal wall. The compression imposed by the stretched outer epidermal wall upon the inner tissues gives rise to a wall-pressure difference which can be transformed into a water-potential difference between inner tissues and external medium (water) by removal of the outer epidermal wall. ii) Peeled segments fail to respond to auxin with normal growth. The plastic extensibility of the inner-tissue cell walls (measured with a constant-load extensiometer using living segments) is not influenced by auxin (or abscisic acid) in peeled or nonpeeled segments. It is concluded that auxin induces (and abscisic acid inhibits) elongation of the intact segment by increasing (decreasing) the extensibility specifically in the outer epidermal wall. In addition, tissue tension (and therewith the pressure acting on the outer epidermal wall) is maintained at a constant level over several hours of auxin-mediated growth, indicating that the inner cells also contribute actively to organ elongation. However, this contribution does not involve an increase of cell-wall extensibility, but a continuous shifting of the potential extension threshold (i.e., the length to which the inner tissues would extend by water uptake after peeling) ahead of the actual segment length. Thus, steady growth involves the coordinated action of wall loosening in the epidermis and regeneration of tissue tension by the inner tissues. iii) Electron micrographs show the accumulation of striking osmiophilic material (particles of approx. 0.3 m diameter) specifically at the plasma membrane/cell-wall interface of the outer epidermal wall of auxin-treated segments. iv) Peeled segments fail to respond to auxin with proton excretion. This is in contrast to fusicoccin-induced proton excretion and growth which can also be readily demonstrated in the absence of the epidermis. However, peeled and nonpeeled segments show the same sensitivity to protons with regard to the induction of acid-mediated in-vivo elongation and cell-wall extensibility. The observed threshold at pH 4.5–5.0 is too low to be compatible with a second messenger function of protons also in the growth response of the inner tissues. Organ growth is described in terms of a physical model which takes into account tissue tension and extensibility of the outer epidermal wall as the decisive growth parameters. This model states that the wall pressure increment, produced by tissue tension in the outer epidermal wall, rather than the pressure acting on the inner-tissue walls, is the driving force of growth.Abbreviations and symbols E _el, E _pl elastic and plastic in-vitro cell-wall extensibility, respectively - E _tot E _el+E _pl - FC fusicoccin - IAA indole-3-acetic acid - IT inner tissue - ITW inner-tissue walls - OEW outer epidermal wall - osmotic pressure - P wall pressure - water potential     

Role of cell-wall biogenesis in the initiation of auxin-mediated growth in coleoptiles of Zea mays L.

The involvement of cell-wall polymer synthesis in auxin-mediated elongation of coleoptile segments from Zea mays L. was investigated with particular regard to the growth-limiting outer epidermis. There was no effect of indole acetic acid (IAA) on the incorporation of labeled glucose into the major polysaccharide wall fractions (cellulose, hemicellulose) within the first 2 h of IAA-induced growth. 2,6-Dichlorobenzonitrile inhibited cellulose synthesis strongly but had no effect on IAA-induced segment elongation even after a pretreatment period of 24 h, indicating that the growth response is independent of the apposition of new cellulose microfibrils at the epidermal cell wall. The incorporation of labeled leucine into total and cell-wall protein of the epidermis was promoted by IAA during the first 30 min of IAA-induced growth. Inhibition of IAA-induced growth by protein and RNA-synthesis inhibitors (cycloheximide, cordycepin) was accompanied by an inhibition of leucine incorporation into the epidermal cell wall during the first 30 min of induced growth but had no effect on the concomitant incorporation of monosaccharide precursors into the cellulose or hemicellulose fractions of this wall. It is concluded that at least one of the epidermal cell-wall proteins fulfills the criteria for a growth-limiting protein induced by IAA at the onset of the growth response. In contrast, the synthesis of the polysaccharide wall fractions cellulose and hemicellulose, as well as their transport and integration into the growing epidermal wall, appears to be independent of growth-limiting protein and these processes are therefore no part of the mechanism of growth control by IAA.Abbreviations CHI cycloheximide - COR cordycepin - DCB 2,6-dichlorobenzonitrile - GLP growth-limiting protein(s) - IAA indole-3-acetic acid     

Auxin-induced changes in the population of translatable messenger RNA in elongating maize coleoptile sections

In-vitro translation products of polyadenylated RNA from untreated and indole-3-acetic acid (IAA)-treated elongating sections of maize (Zea mays L.) coleoptiles were analyzed by twodimensional polyacrylamide gel electrophoresis. Treatment with IAA results in an increased amount of at least four in-vitro translation products. The amounts of two of these translation products are increased within 10 min of IAA treatment.Abbreviation IAA indole-3-acetic acid     

Action of red light on indole-3-acetic-acid status and growth in coleoptiles of etiolated maize seedlings

Brief irradiation of intact etiolated seedlings of maize (Zea mays L.) with red light (R; 30 W cm^-2, 10 min) reduces the amounts of diffusible and free (solvent-extractable) indole-3-acetic acid (IAA) obtainable from excised coleoptile tips. The effect is transient, the lowest level (30% of the dark control) occurring at about 3 h after irradiation. The free-IAA content of the whole coleoptile and the diffusible-IAA yield from the base of the same organ are similarly reduced, whereas the conjugated-IAA content of the coleoptile is not affected. These results support the view that R inhibits the production of IAA at the coleoptile tip. It is further shown that R inhibits biosynthesis of [³H]IAA from [³H]tryptophan supplied to the coleoptile tip. The shapes of the fluence-response curves obtained for the reduction of the diffusible-IAA yield by R and far-red light (FR) indicate the participation of two photoreactive systems. One has thresholds at 10^-3 W s cm² of R, five orders of magnitude less than the minimum required for the appearance of spectrophotometrically measurable far-red-absorbing form of phytochrome (Pfr) in vivo, and 10^-1 W s cm^-2 of FR; its response is linear to the logarithm of fluence exceeding five orders of magnitude. The other system is seen above 10² W s cm^-2 as an increase in the slope of the fluenceresponse curve; its response is FR reversible and related to the Pfr level of total photoreversible phytochrome. Both systems inhibit biosynthesis of IAA from tryptophan. Elongation of the coleoptile is stimulated by R; the stimulation is most apparent in the apical region, and is saturated with a fluence at which bo detectable pfr is formed. Farred light can also saturate this response. Since the endogenous IAA concentration in the coleoptile appears not to be in the inhibitory range, it is concluded that the stimulation of coleoptile elongation is not the result of changes in free-IAA levels.Abbreviations FR far-red light - IAA indole-3-acetic acid - Pfr phytochrome in the far-red-absorbing form - Pr phytochrome in the red-absorbing form - R red light     

Effect of auxin and abscisic acid on cell wall extensibility in maize coleoptiles

Plastic and elastic in-vitro extensibilities (E _pland E _el ) of cell walls from growing maize (Zea mays L.) coleoptile segments were measured by stretching frozen-thawed tissue, pre-extended to its in-vivo length, at constant force (creep test) in a custom-buildt extensiometer, equipped with a linear-displacement transducer. The indole-3-acetic acid (IAA)-induced change of E _pl (E _pl ) is strictly correlated with the growth rate for a period of 3–4 h. Subsequently, E _plremains constant while the growth rate is slowing down. Since this discrepancy can be accounted for by a growth-dependent reduction of osmotic pressure, it is concluded that E _plrepresents quantitatively the relative increase of in-vivo extensibility (cell wall loosening) involved in IAA-mediated cell growth over a much longer time. On the other side it is argued that the growth rate may not be strictly correlated with wall extensibility during long-term growth. Abscisic acid (ABA) inhibits segment growth induced by auxin, fusicoccin, or exogenous acid, and this effect can be quantitatively attributed to an ABA-mediated reduction of cell wall extensibility as determined by the E _plmeasurement. Both, IAA and ABA have no effect on total protein synthesis, RNA synthesis, and amount of osmotic solutes. Fusicoccin-induced proton excretion is only slightly inhibited by ABA. In contrast to ABA, growth inhibition by cycloheximide (CHI) is always much larger than the concomitant reduction of E _pl , indicating that a further growth parameter is also involved in the inhibition of cell growth by CHI. E _el is not affected by either IAA, ABA, or CHI. It is concluded that E _pl as determined by the applied method, represents a relative measure of the actual in-vivo extensibility of the growing cell wall at the very moment when the tissue is killed, rather than an average extensibility accumulated over some immediate-past period of time as suggested by Cleland (1984, Planta 160, 514–520). Hence, we further draw the conclusion that IAA and ABA control of cell growth can entirely be attributed to a modulation of cell wall extensibility by these hormones in maize coleoptiles.Abbreviations ABA ±abscisic acid - CHI cycloheximide - E _el , E_pl elastic and plastic in vitro extensibilities, respectively (E _el+E_pl=E_tot>) - FC fusicoccin - IAA indole-3-acetic acid     

Auxin causes oscillations of cytosolic free calcium and pH inZea mays coleoptiles

In epidermal cells of maize (Zea mays L.) coleoptiles, cytosolic pH (pH_c), cytosolic free calcium, membrane potential and changes thereof were monitored continuously and simultaneously (pH_c/, _m, Ca²⁺/ _m) using double-barrelled ion-sensitive microelectrodes. In the resting cells the cytosolic pH was 7.3–7.5 and the concentration of free calcium was 119±24 nM. One-micromolar indole-3-acetic acid (IAA), added to the external medium at pH 6.0 triggered oscillations in _m, pH_c and free calcium with a period of 20 to 30 min. Acidification of the cytosolic pH increased the cytosolic free calcium. The _m oscillations are attributed to changes in activity of the H⁺-extrusion pump at the plasmalemma, triggered off by pH and controlled by pH regulation (pH oscillation). The origin of the pH_c and Ca²⁺ changes remains unclear, but is possibly caused by auxin-receptor-induced lipid breakdown and subsequent second-messenger formation. It is suggested that the observed cytosolic pH and Ca²⁺ changes are intrinsically interrelated, and it is concluded that this onset of regulatory processes through the phytohormone IAA is indicative of calcium and protons mediating early auxin action in maize coleoptiles. It is further concluded that the double-barrelled ion-sensitive microelectrode is an invaluable tool for investigating in-vivo hormone action in plant tissues.Abbreviations and symbols FC fusicoccin - IAA indole-3-acetic acid - Mes 2-(N-morpholino)ethanesulfonic acid - pH_c cytosolic pH - Tris 2-amino-2-(hydroxymethyl)-1,3-propanediol - _m membrane potential difference (mV)     

Auxin binding in roots: A comparison between maize roots and coleoptiles

Auxin binding onto membrane fractions of primary roots of maize seedlings has been demonstrated using naphth-1yl-acetic acid (NAA) and indol-3yl-acetic acid (IAA) as ligands. This binding is compared with the already well characterized interaction between auxins and coleoptile membranes. The results indicate that while kinetic parameters are of the same order for root and coleoptile binding, a number of differences occur with respect to location in cells and relative affinity. The possible significance of the existence of such binding sites in root cells is discussed in relation to auxin action.Abbreviations 4-Cl-PA 4-chlorophenoxyacetic acid - EDTA ethylene diamine tetracetic acid - IAA indol-3yl-acetic acid - MCPA 2-methyl-4-chlorophenoxyacetic acid - NAA naphth-1yl-acetic acid - 2-NAA naphth-2yl-acetic acid - Tris 2-amino-2-(hydroxymethyl) propane-1,3 diol - TIBA 2,3,5 triiodobenzoic acid - NPA naphthylphthalamic acid - PCIB 4-chlorophenoxyisobutyric acid - PCPP 4-chlorophenoxyisopropionic acid - 2,4-D 2,4-dichlorophenoxyacetic acid     

pH-Dependent accumulation of indoleacetic acid by corn coleoptile sections

The uptake of auxin by 1-mm slices of corn (Zea mays L.) coleoptiles, a tissue known to transport auxin polarly, depends on the pH of the medium. Short-term uptake of indole-3-acetic acid (IAA) in coleoptiles increases with decreasing pH of the buffer as would be expected if the undissociated weak acid, IAA·H, were more permeable than the auxin anion, IAA^-, and IAA^- accumulates in the tissues because of the higher pH of the cytoplasm. Although uptake of [³H]IAA is reduced in neutral buffers, it is greater than expected if it were limited to just the extracellular space of the tissue. The radioactivity accumulated by the tissue can be quantitatively extracted by organic solvents and identified as IAA by thin-layer chromatography. The tissue radioactivity is freely mobile and can efflux from the tissue. Thus these cells in pH 5 buffer are able to retain an average internal concentration of mobile IAA that is at least several times greater than the external concentration. A prominent feature of auxin uptake from acidic buffers is enhanced accumulation at high auxin concentration. This indicates that, in addition to fluxes of IAA·H, a saturable site is involved in auxin uptake. Whenever the auxin-anion gradient is directed outward, saturating the efflux of auxin anions increases accumulation. Furthermore, the observed slowing of short-term uptake of radioactive IAA by increasing concentrations of IAA or K⁺ indicates either an activation of the presumptive auxin leak or saturation of another carrier-mediated uptake system such as a symport of auxin anions with protons. By contrast in neutral buffers, effects of concentration on uptake rates disappear. This implies that at neutral pH the anion leak is decreased and influx depends on the symport.     

In-vivo measurement of cell-wall extensibility in maize coleoptiles: Effects of auxin and abscisic acid

Plastic and elastic in-vivo extensibilities (E_pl and E_el, respectively) of cell walls of growing maize (Zea mays L.) coleoptile segments were measured by stretching living tissue at constant force (creep test) in an extensiometer. The linear displacement transducer used as a measuring device permits the determination of load-induced extensions in the range of 0–1% of the segment's length, leading to a minimal disturbance of the hydraulic parameters of the tissue and allowing the measurement of unidirectional cell-wall creep at virtually unchanged turgor and metabolic activity. A rein-vestigation of the time-course of indole-3-acetic acid-promoted and abscisic acid-inhibited wall loo-sening revealed that the in-vivo creep test yields results very similar to those obtained previously with the in-vitro creep test [Kutschera and Schopfer, 1986, Planta 167, 527–535]. The hormones affect elongation rate and E_pl in a closely correlated manner both in step-up as well as step-down growth changes whereas E_el remains unaltered. It is argued that both hormones influence growth by modifying E_pl of the outer epidermis and that this effect can be quantitatively measured, in relative units, by either the in-vivo or the in-vitro creep test.Abbreviations ABA ±abscisic acid - E_el, E_pl elastic and plastic in-vivo cell-wall extensibility, respectively - E_tot E_el+E_pl - IAA indole-3-acetic acid; m, cell-wall yielding coefficient     

Role of protein and RNA synthesis in the initiation of auxin-mediated growth in coleoptiles of Zea mays L.

The kinetics of inhibition by protein- and RNA-synthesis inhibitors (cycloheximide and cordycepin, respectively) of indole-3-acetic acid (IAA)-induced elongation growth were investigated using abraded coleoptile segments of Zea mays L. Removal of the cuticle — a diffusion barrier for solutes — by mechanical abrasion of the outer epidermal cell wall increased the effectiveness of inhibitors tremendously. In an attempt to elucidate the role of growth-limiting protein(s) (GLP) in the growth mechanism the following results were obtained. The elongation induced by IAA was completely inhibited when cycloheximide (10 mol·l^-1) was applied to abraded coleoptile segments as shortly as 10 min before the onset of the growth response (=5 min after administration of IAA). However, when cycloheximide was applied after 60 min of IAA treatment (when a steady-state growth rate is reached), the time required for complete cessation of growth was much longer (about 40 min). Cycloheximide inhibited the incorporation of [³H]leucine into protein within about 5 min. Cordycepin (400 mol·l^-1) prevented IAA-induced growth when applied as shortly as 25 min before the onset of the growth response (=10 min before administration of IAA) but required more than 60 min for a full inhibition of steady-state growth. The incorporation of [³H]adenosine into RNA was inhibited by cordycepin within 10 min. It is concluded that, contrary to previous investigations with nonabraded organ segments, the initiation of growth by IAA depends directly on the synthesis of GLP. Moreover, the apparent lifetime of GLP is at least four times longer than the time required by cycloheximide to inhibit the initiation of growth by IAA. This is interpreted to mean that GLP is not present before IAA starts to act but is synthesized as a consequence of IAA action starting a few minutes before the initiation of growth. Interpreting the kinetics of growth inhibition by cordycepin in a similar way, we further conclude that GLP synthesis is mediated by IAA-induced synthesis of the corresponding mRNA which starts about 10 min before the onset of GLP synthesis. Inhibition by cycloheximide and cordycepin of IAA-induced growth cannot be alleviated by acidifying the cell wall to pH 4-5, indicating that these inhibitors do not act on growth via an inhibition of auxin-mediated proton excretion.Abbreviations CHI cycloheximide - COR cordycepin - GLP growth-dimiting protein(s) - IAA indole-3-acetic acid - mRNA_GLP mRNA coding for GLP     

Incubation of corn coleoptiles with auxin enhances in-vitro fusicoccin binding

Binding of fusicoccin (FC) to microsomal preparations of corn (Zea mays L.) coleoptiles is enhanced after incubation of the tissue with indole-3-acetic acid (IAA). Treatment of the kinetic data according to Scatchard shows that the enhancement is a consequence of an increase in the number of high-affinity FC-binding sites without changes of their K_D. The minimal effective concentration of IAA is 10^-7 M; above 10^-5 M the effect declines. The stimulation is insensitive to protein-synthesis inhibitors (cycloheximide and puromycin). The same effect is observed with the synthetic auxins 2,4-dichlorophenoxyacetic acid and naphtalene-1-acetic acid while it is abolished by the auxin antagonists naphtalene-2-acetic acid and p-chlorophenoxyisobutyric acid. Since the above effect is only observed with intact tissue and not after incubation of IAA with microsomal preparations, a direct interaction of IAA with the FC-binding sites is ruled out and an alternative mechanism must be sought.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - FC fusicoccin - [³H]FC ³H-labeled dihydrofusicoccin - IAA indole-3-acetic acid - 1-NAA naphtalene-1-acetic acid - 2-NAA naphtalene-2-acetic acid - PCIB p-chlorophenoxyisobutyric acid     

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     

Kinetics of amyloplast sedimentation in gravistimulated maize coleoptiles

Inner mesophyll cells from coleoptiles of Zea mays L. cv. Merit were fixed after varying periods of gravistimulation. A statistically significant amount (17–21%) of amyloplast sedimentation occurred in these cells after 30 s of gravistimulation. The presentation time is approx. 40 s or less. The accumulation of amyloplasts near the new lower wall shows a linear relationship to the logarithm of the gravistimulation time (r=0.92 or higher). The intercept of this line with the baseline value of amyloplasts in vertical coleoptiles indicates that the number of amyloplasts on the new lower wall begins increasing 11–15 s after the onset of gravistimulation. Direct observations of living cells confirm that many amyloplasts sediment within less than 15–30 s. These rapid kinetics are consistent with the classical statolith hypothesis of graviperception involving the sedimentation of amyloplasts to the vicinity of the new lower wall.     

Interaction of gravi- and phototropic stimulation in the response of maize (Zea mays L.) coleoptiles

The influence of gravitropic stimulation upon blue-light-induced first positive phototropism for stimulations in the same (light source and center of gravity opposite to each other) and in opposing directions was investigated in maize cole-optiles by measuring fluence-response patterns. As a result of gravitropic counterstimulation, phototropic bending was transient with maximum curvature occurring 100 min after stimulation. On a horizontal clinostat, however, the seedlings curved for 20 h. Gravistimulation in the opposite direction acted additively upon blue-light curvature. Gravistimulation in the same direction as phototropic stimulation produced a complex behaviour deviating from simple additivity. This pattern can be explained by a gravitropically mediated sensitization of the phototropic reaction, an optimal dependence of differential growth on the sum of photo-and gravistimulation, and blue-light-induced inhibition of gravitropic curvature at high fluences. These findings indicate that several steps of photo-and gravitransduction are separate. Preirradiation with red light desensitized the system independently of applied gravity-treatment, indicating that the site of red-light interaction is common to both transduction chains.Abbreviations BL blue light - G⁺ stimulation by light and gravity in the same direction (i.e. light source and center of gravity opposite to each other) - G^- stimulation by light and gravity in opposing directions