Evidence for a Relationship between H Excretion and Auxin in Shoot Gravitropism

The role of auxin and protons in the gravitropic response of the sunflower (Helianthus annuus L. cv Sungold) hypocotyl has been investigated. No physiological asymmetry in acid-growth capacity could be detected between the upper and lower surfaces of gravistimulated hypocotyls. These data imply that neutral buffers inhibit shoot gravitropism by preventing the establishment of a lateral proton gradient along gravitropically stimulated hypocotyls. Indirect evidence that auxin is involved in the establishment and/or maintenance of such a gradient derives from the quantitative assessment of the effects of exogenous auxin, anti-auxins, and vanadate on gravicurvature. At low concentrations, exogenous auxin accelerated curvature; at high concentrations, curvature was prevented. Vanadate, an inhibitor of auxin-enhanced H⁺ secretion, α-(p-chlorophenoxy)isobutyric acid (PCIB), an anti-auxin, and 2,3,5-triiodobenzoic acid (TIBA), an auxin-transport inhibitor, prevented observable asymmetric proton excretion using a brom cresol purple agar technique and also inhibited gravicurvature. Vanadate, PCIB, and TIBA inhibition of gravicurvature could be reversed with acid treatment to the lower surface of a gravistimulated hypocotyl. Auxin treatment to the lower surface of a gravistimulated hypocotyl did not reverse vanadate-induced inhibition, but it did partially reverse PCIB- and TIBA-induced inhibition. These results indicate a close relationship between the acid-growth theory and the differential growth responses of the sunflower hypocotyl during gravitropism.     

Sequence of key events in shoot gravitropism

It has recently been shown that asymmetric acid efflux is closely correlated with the gravitropic curvature of plant shoots and roots. The research reported here addresses whether auxin (IAA) redistribution in shoots is the cause or result of asymmetric acid efflux.

When abraded sunflower (Helianthus annuus cv Mammoth) hypocotyls are submerged in 20 millimolar neutral buffer, gravicurvature is greatly retarded relative to 0.2 millimolar controls. Nevertheless, in both buffer systems there is a similar redistribution of [³H]IAA toward the lower surface of gravistimulated sunflower hypocotyls. These results suggest that graviperception initiates IAA redistribution, which in turn results in auxin-induced asymmetric H⁺ efflux across the shoot. This interpretation is reinforced by data showing the effects of removal of the epidermal layers (peeling), osmotic shock, and morphactin treatment on gravicurvature and [³H]IAA redistribution. Peeling and osmotic shock inhibit gravicurvature but not redistribution. Morphactin inhibits both processes but does not inhibit hypocotyl straight growth.

     

Acid growth effects in maize roots: Evidence for a link between auxin-economy and proton extrusion in the control of root growth

The role of proton excretion in the growth of apical segments of maize roots has been examined. Growth is stimulated by acidic buffers and inhibited by neutral buffers. Organic buffers such as 2[N-morpholino] ethane sulphonic acid (MES) — 2-amino-2-(hydroxymethyl)propane-1,3 diol (Tris) are more effective than phosphate buffers in inhibiting growth. Fusicoccin(FC)-induced growth is also inhibited by neutral buffers. The antiauxins 4-chlorophenoxyisobutyric acid (PCIB) and 2-(naphthylmethylthio) propionic acid (NMSP) promote growth and H⁺-excretion over short time periods; this growth is also inhibited by neutral buffers. We conclude that growth of maize roots requires proton extrusion and that regulation of root growth by indol-3yl-acetic acid (IAA) may be mediated by control of this proton extrusion.Abbreviations IAA indol-3yl-acetic acid - ABA abscisic acid - FC fusicoccin - PCIB 4-chlorophenoxy-isobutyric acid - MES 2(N-morpholino)ethane sulphonic acid - Tris 2-amino-2-(hydroxymethyl) propane-1,3-diol - NMSP 2-(naphthylmethylthio)propionic acid     

The “acid growth effect” and geotropism

Summary The curvature developed by segments of sunflower hypocotyl exposed to gravitational stimulus was enhanced in buffer solutions between pH 3.4 and 4.0 in the absence of added auxin. This effect was observed both when the segments were submerged during the stimulus and when they floated near the surface of the solution. 5–10 min in a horizontal position was sufficient to induce subsequent curvature.Straight growth of the segments was also promoted in buffers of this pH range.The acid effect on curvature was insensitive to KAsO₂, HgCl₂ and cycloheximide, inhibitors which drastically reduced auxin-induced curvature. Furthermore, acid buffer, but not auxin, restored the ability of segments taken from etiolated and starved plants to respond to gravity. These results suggest that the polarisation following gravistimulus may not be resticted to the asymmetric distribution of auxin and auxin co-factors but may involve a general physiological asymmetry.     

Baroresistant buffer mixtures for biochemical analyses

Hydrostatic pressure is a useful tool in the study of varied fields such as protein aggregation, association, folding, ligand binding, and allostery. Application of pressure can have a significant effect on the pK(a) values of buffers commonly used for biochemical analysis. Consequently, cationic buffers, rather than neutral ones, are generally used to minimize pH effects; however, even with these buffers, the change in pH over 3 kbar may be consequential in highly pH-sensitive biochemical systems. Using fluorescence-based assays, we have systematically examined the effects of pressure on various buffers in the neutral pH range. We show that many commonly used cationic and Good's buffers increase in pH with pressure on the order of 0.1 to 0.3 pH units/kbar, in agreement with other published values. Carboxylates and phosphate decrease in pH to a similar extent. Buffer mixtures, composed of both cationic and carboxylate or phosphate components, are shown to be an order of magnitude less pressure sensitive than the individual component buffers. Using various relative concentrations of Tris and either phosphate, tricarballylate (1,2,3-propanetricarboxylate), or CDA (1,1-cyclohexane diacetate) at pH values between 7 and 8 yields baroresistant buffer mixtures. Buffer mixtures can be optimized for a specific pH, and a list of mixtures is presented for general laboratory use.     

Hormone-solute interactions in the lettuce hypocotyl hook

The hypocotyl hook of the lettuce (Lactuca sativa cv. Grand Rapids) seedling is stimulated to a high degree of curvature through a synergistic interaction of ethylene and gibberellic acid in the light. Presentation of various inorganic salts to the seedlings caused extensive alteration of the hormone-induced curvatures, with ammonium and sulfate being the most stimulatory of curvature, and potassium and carbonate being the most inhibitory of curvature. Experiments using organic buffers indicated that the effect was not a pH response. The abilities of various cations and anions to alter the hormonally regulated curvature is suggested as further evidence of solute alteration of hormonal effectiveness. The interpretation is offered that the solutes may be influencing hormonal effectiveness through salting-in and salting-out effects on macro-molecules such as proteins.     

Spatio-temporal kinematic analysis of shoot gravitropism in Arabidopsis thaliana

Plant shoots can bend upward against gravity, a behavior known as shoot gravitropism. The conventional quantification of shoot bending has been restricted to measurements of shoot tip angle, which cannot fully describe the spatio-temporal bending process. Recently, however, advanced imaging analyses have been developed to quantify in detail the spatio-temporal changes in inclination angle and curvature of the shoot. We used one such method (KymoRod) to analyze the gravitropism of the Arabidopsis thaliana inflorescence stem, and successfully extracted characteristics that capture when and where bending occurs. Furthermore, we implemented an elastic spring theoretical model and successfully determined best fitted parameters that may explain typical bending behaviors of the inflorescence stem. Overall, we propose a data-model combined framework to quantitatively investigate shoot gravitropism in plants.     

Evaluation of h secretion relative to zeatin-induced growth of detached cucumber cotyledons

Cytokinins promote expansion of cotyledons detached from seedlings of more than a dozen species. The zeatin-enhanced expansion of cucumber (Cucumis sativus L. cv Marketer) cotyledons was investigated. In addition, whether acid secretion is involved in wall loosening accompanying such accelerated growth was evaluated. For cotyledons abraded with carborundum or cut into either eight or 18 pieces, we detected no zeatin-enhanced acidification of the growth medium during growth periods of 3 days. Measurements of pH values on each surface of zeatin-treated, abraded cotyledons after 3 days of growth also showed no detectable acidification caused by the hormone. Furthermore, with several buffers at pH values ranging from 5 to 8, growth of nonabraded, abraded, or cut cotyledons with or without zeatin was independent of external pH. However, experiments restricted to about 12 hours indicated that certain acidic buffers enhanced growth of cotyledons cut into 18 pieces. Lastly, concentrations of fusicoccin that caused growth promotion equal to that of zeatin initiated substantial acidification of the medium. Collectively, these data suggest that zeatin-induced expansion of detached cucumber cotyledons is independent of H⁺ secretion.     

Effect of Xyloglucan Oligosaccharides on Growth,Viscoelastic Properties,and Long-Term Extension of Pea Shoots

The growth-promoting effect of xyloglucan-derived oligosaccharides was investigated using a bioassay with entire pea (Pisum sativum L., var Alaska) shoots. After a 24-h incubation period at 25[deg]C, xyloglucan oligosaccharide (XGO) solutions with concentrations of 10-6 M notably increased the growth rate of pea shoots, whereas the same oligosaccharides at 10-7 M were less effective. To investigate the possible correlation between growth rate changes in the XGO-treated shoots and changes in the wall mechanical properties of their growing regions (third internodes), we used a short-term creep assay. The promotion of elongation by XGOs was reflected in an enhancement of the viscoelasticity of the growing regions of the shoots. To show whether this effect on wall viscoelastic properties was the cause or a consequence of their growth promotion, we tested the effect of XGOs on the long-term extension of isolated cell walls. We characterized an acid-induced extension in isolated cell walls from pea shoots that was not inhibited by preincubation in neutral buffers. Exogenously added XGOs did not alter the pattern of pea segment extension at any pH tested, indicating that XGOs have no direct effect on cell wall viscoelasticity. Finally, preincubation of pea segments in neutral buffers with XGOs enhanced their capacity to extend under acidic conditions. This finding suggests that XGOs at a neutral pH can act via transglycosylation, weakening the wall matrix and making the wall more responsive to other mechanisms of acid-induced extension as an expansin-mediated extension.     

The Effect of a Submersion Pretreatment on In Vitro Explant Growth and Shoot Regeneration from Hypocotyls of Flax (Linum Usitatissimum)

This study was carried out to determine the effect of temporary submersion of hypocotyl segments in water on in vitro explant growth and shoot regeneration on MS (Murashige and Skoog, 1962) medium supplemented with 1 mg l⁻¹ BAP (6-benzylaminopurine) and 0.02 mg l⁻¹ NAA (naphthaleneacetic acid) in three flax cultivars. It was observed that water-treated hypocotyl explants gave rise to the highest values with respect to shoot regeneration percentage, shoot number per hypocotyl, shoot length and total shoot number per Petri dish, successful rooting and plantlet establishment. This procedure may be applicable for other species cultured in vitro.     

Competence for Elicitation of H2O2 in Hypocotyls of Cucumber Is Induced by Breaching the Cuticle and Is Enhanced by Salicylic Acid

To study H2O2 production, the epidermal surfaces of hypocotyl segments from etiolated seedlings of cucumber (Cucumis sativus L.) were gently abraded. Freshly abraded segments were not constitutively competent for rapid H2O2 elicitation. This capacity developed subsequent to abrasion in a time-dependent process that was greatly enhanced in segments exhibiting an acquired resistance to penetration of their epidermal cell walls by Colletotrichum lagenarium, because of root pretreatment of the respective seedlings with 2,6-dichloroisonicotinic acid. When this compound or salicylic acid was applied to abraded segments, it also greatly enhanced the induction of competence for H2O2 elicitation. This process was fully inhibited by 5 [mu]M cycloheximide or 200 [mu]M puromycin, suggesting a requirement for translational protein synthesis. Both a crude elicitor preparation and a partially purified oligoglucan mixture from Phytophthora sojae also induced, in addition to H2O2 production, a refractory state, which explains the transient nature of H2O2 elicitation. Taken together, these results suggest that the cucumber hypocotyl epidermis becomes conditioned for competence to produce H2O2 in response to elicitors by a stimulus resulting from breaching the cuticle and/or cutting segments. This conditioning process is associated with protein synthesis and is greatly enhanced when substances able to induce systemic acquired resistance are present in the tissue.     

pH-Dependence of Extension Growth in Avena Coleoptiles and Its Implications for the Mechanism of Auxin Action

The pH-dependence of acid-induced growth in excised segments of Avena sativa coleoptiles has been reinvestigated in the pH range 3 to 7. In contrast to previous reports (e.g. DL Rayle [1973] Planta 114: 63-73), only acidic buffers with a pH below 5.0 induce an extension response. A pH of 3.5 to 4.0 is required to mimic auxin-mediated growth. Very similar pH-response curves are obtained with both intact (abraded) and peeled coleoptiles. These results agree with the recent finding of a similarly low sensitivity to protons in maize coleoptiles. It is shown that the apparently much higher sensitivity to protons previously reported for peeled Avena coleoptiles is due to incubating the tissue in buffer of pH 6.8 between peeling and measuring the effect of acidic buffers. Neutral pH reversibly inhibits the spontaneous extension burst originating on release from tissue tension after removing the epidermis. Reversal of this inhibition can be achieved by buffers of pH 5.0 to 6.0 (or distilled water), thereby simulating an acid-induced growth response in this pH range. It is concluded that true acid-induced wall-loosening generally does not take place above pH 5.0 and that a pH considerably below 4.0 is required in order to stimulate growth to an extent comparable to that obtained in response to auxin. The “acid-growth theory,” which requires an acid-mediated loosening of the cell wall in the pH range 5 to 6, this pH being established by auxin-induced proton excretion, can therefore also not be substantiated in Avena.     

Role of xyloglucan breakdown in epidermal cell walls for auxininduced elongation of azuki bean epicotyl segments

Auxin-induced elongation of epicotyl segments of azuki bean ( Vigna angularis Ohwi et Ohashi cv. Takara) was suppressed by a fucose-binding lectin from Tetragonolobus purpureas Moench and by polyclonal antibodies raised against xyloglucan heptasaccharide (Xyl₃Glc₄) when the cuticle present in the outer surface of epicotyls was abraded. In contrast, elongation of non-abraded segments was not influenced by the lectin or the antibodies. Epicotyl segments, from which the epidermal and the outer cortical cells had been removed, elongated rapidly for 2 h and than only slowly. Auxin slightly stimulated elongation of the inner tissue segments in the phase of slow growth. Neither in the presence nor in the absence of auxin did the lectin or the antibodies affect elongation of the inner tissue segments. The split portions of outer surface-abraded epicotyl segments incubated in buffer extended outward, and auxininhibited this outward bending. The lectin and the antibodies reversed the effect of auxin on bending. The fucose-binding lectin pretreated with fucose or the immunoglobulin fraction obtained from preimmune serum exhibited little or no inhibitory effect on auxin-induced elongation of abraded or split segments. These results support the view that a breakdown of xyloglucans in the epidermal cell walls plays an essential role in auxin-induced elongation in dicotyledons.     

Transgenic tobacco over-expressing a homeobox gene shows a developmental interaction between leaf morphogenesis and phyllotaxy.

The tobacco gene, NTH1, encodes a polypeptide of 326 amino acids and is a member of the class1 KN1-type family of homeobox genes. Expression of NTH1 has mainly been observed in vegetative and reproductive shoot apices, not observed in roots or expanded leaves. Over-expression of NTH1 in transgenic plants caused abnormal leaf morphology, consisting of wrinkling and curvature. Interestingly, the direction of leaf curvature tended to be conserved among almost all of the leaves in any given transformant. In transgenic plants exhibiting clockwise or anticlockwise phyllotaxy, leaves curved to the right or left, respectively, when looking from the shoot apex toward the base. Micro-surgical experiments demonstrated that the presence of the shoot apex is necessary for the development of leaf curvature, indicating that the order of formation of leaves on the stem (the generative spiral) affects leaf development. We found a correlation between the severity of leaf curvature and the value of the plastochron ratio, a parameter of phyllotaxy. Transformants with more severe phenotypes had larger plastochron ratios. From these findings, we discuss the possibility that an increase in the plastochron ratio, caused by over-expression of NTH1 in the shoot apex, may be involved in leaf curvature.     

Cathepsin B stability,but not activity,is affected in cysteine:cystine redox buffers

In order to test the hypothesis that the lysosomal cysteine protease cathepsin B may be redox regulated in vivo, cathepsin B activity and stability were measured in cysteine- and/or cystine-containing buffers. Cathepsin B activity in cysteine-containing buffers was similar at pH 6.0 and pH 7.0, over all thiol concentrations tested. In contrast, the stability of the enzyme was greater at pH 6.0 than at pH 7.0. This suggests that the enzyme's operational pH in vivo may be < pH 7.0. The activity of the enzyme was depressed in glutathione-containing buffers. When assessed in cysteine:cystine redox buffers (pH 6.0-7.0) cathepsin B was active over a broad redox potential range, suggesting that cathepsin B activity may not be redox regulated. However, at pH 7.0, the stability of cathepsin B decreased with increasing reduction potential and ambient cystine concentration. This suggests that the stability of the enzyme at neutral pH is dependent on redox potential, and on the presence of oxidising agents.     

Roots of Pisum sativum L. exhibit hydrotropism in response to a water potential gradient in vermiculite

In the present study, root hydrotropism in an agravitropic mutant of Pisum sativum L. grown in vermiculite with a steep water potential gradient was examined. When wet and dry vermiculite were placed side by side, water diffused from the wet (-0.04 MPa) to the dry (-1.2 MPa) and a steep water potential gradient became apparent in the dry vermiculite close to the boundary between the two. The extent and location of the gradient remained stable between the fourth and sixth day after filling a box with vermiculite, and the steepest gradient (approx. 0.02 MPa mm-1) was found in the initially dry vermiculite between 60 and 80 mm from the boundary. When seedlings with 25-35 mm long roots were planted in the initially dry vermiculite near where the gradient had been established, each of the main roots elongated toward the wet vermiculite, i.e. toward the high water potential. Control roots elongated without curvature in both the wet and the dry vermiculite, in which no water potential gradient was detectable. These results show that pea roots respond to the water potential gradient around them and elongate towards the higher water potential. Therefore, positive hydrotropism occurs in vermiculite just as it does in air. Hydrotropism in soil may be significant when a steep water potential gradient is apparent, such as when drip irrigation is applied.     

Ethylene-induced lateral expansion in etiolated pea stems : the role of Acid secretion

Ethylene-induced inhibition of elongation and promotion of lateral expansion in the stems of etiolated pea (Pisum sativum L. var Alaska) seedlings is not associated with any alteration of auxin-stimulated proton extrusion. Indeed, lateral expansion in response to ethylene apparently requires an acidified wall since it is prevented by strong neutral buffers and by the ATPase inhibitor orthovanadate. Ethylene treatment reduces the capacity of live and frozen-thawed sections to extend in the longitudinal direction in response to acid. The effect of ethylene on lateral acid growth capacity is more complicated. Ethylene-treated internodes do not exhibit acid-induced lateral expansion. Ethylene-treated segments which have been frozen-thawed do show an enhanced capacity to extend in the transverse direction at acid pH, but only when the inner tissues have been removed by coring. We conclude that two of the factors which control the directionality of expansion during ethylene treatment are a decrease in the sensitivity of the walls to acid longitudinally and an increase in the sensitivity of the outer cortical parenchyma walls to acid in the transverse direction.     

Effects of permeant buffers on the initiation of photosynchronous phosphorylation and postillumination phosphorylation in chloroplasts

Under canonical chemiosmotic formulations, the development of a delocalized transmembrane proton gradient should precede and, in the absence of a membrane potential, should account for all the capacity of an energy transducing system to synthesize ATP. Furthermore, any agents, such as permeant proton-absorbing buffers, that slow down the kinetics of the development of this gradient should, consequently, delay ATP synthesis. We have studied the very early (0 through 1000 ms) steps of photosynthetic ATP synthesis utilizing real-time, rapid flow-quench techniques. We have investigated the effect(s) that permeant buffers exert on this process where these buffers show no uncoupling effects, and the transmembrane potential has been collapsed by valinomycin and K+. Experimentally this system was dissected into two ATP synthesizing components, as follows: synthesis of ATP strictly concomitant with light influx and unaffected by the addition of permeant buffers. We refer to this as photosynchronous phosphorylation and synthesis of ATP monitored after the light was extinguished and which was greatly diminished by the addition of proton-absorbing permeant buffers, thus exhibiting the characteristics of conventional postillumination phosphorylation, and we suggest that it represents part of capacitance phosphorylation. The potential for capacitance phosphorylation initiates very rapidly under light and gradually builds up to steady-state level, and it is governed by canonical chemiosmotic principles. We estimate that its contribution to overall ATP yield is minimal during the first few cycles of the system and that it increases gradually towards steady state when it contributes to the majority of ATP synthesized. Neither a delocalized transmembrane proton gradient nor a strictly localized intramembrane proton pathway can account for these observations so we have proposed that a gating mechanism exists which delivers intramembrane protons initially directly to the ATP synthetase complex but subsequently to the lumen as well, and thus, allows the lumen to act as a capacitor during the steady state. This study can reconcile the findings of Ort et al. (Ort, D. R., Dilley, R. A., and Good, N. E. (1976) Biochim. Biophys. Acta 449, 108-124) with the contrasting findings of Vinkler et al. (Vinkler, C., Avron, M., and Boyer, P. D. (1980) J. Biol. Chem. 255, 2263-2266) through the opposite effects which osmotic strength and KCl concentration exert on the two ATP synthetic phases (during and after illumination) of the rapid flash technique used in those studies.(ABSTRACT TRUNCATED AT 400 WORDS)     

An analysis of the changes in growth rate occurring during the initial stages of geocurvature in shoots

Abstract A detailed study of the changes in growth rate on the two sides of a shoot prior to, and following geostimulation has been undertaken. Data from etiolated Zea seedlings, and cucumber hypocotyls, and from light grown sunflower hypocotyls are presented. In all cases, the differential growth which brings about geocurvature begins simultaneously along the length of the organ. This is contrary to previous reports in the literature which suggested that curvature begins first at the tip of an organ and progresses basipetally. The feature which is common to all species investigated is that growth of the upper side of the shoot ceases following geostimulation. In some cases there is also a marked acceleration in growth rate on the lower side of the shoot (sunflower) but other species show no such acceleration of growth (cucumber). It has been assumed for many years that the major factor causing upward curvature was an acceleration of growth on the lower side of the organ. The data presented here show that the cessation of growth on the upper side is a major, and in some cases the only factor bringing about geocurvature. The data are discussed in relation to the mechanisms which might control geotropic curvature.     

THE FATE OF THE DWARF SHOOT APEX IN BRISTLECONE PINE (PINUS LONGAEVA)

The fate of the pine dwarf shoot (DS) apex after needle initiation has been controversial. Dwarf shoot primordia of Pinus longaeva were examined to determine the developmental basis for DS with and without interfoliar buds. Interfoliar buds are microscopic buds derived from the original terminal apex of the DS. In October, all the DS primordia are similar in size and appearance. However, as the needles elongate in the following June the apices of more proximal DS decrease in size, such that by July there is a clear diminishing size gradient of apical domes in going from the most distal to the most proximal positions. The distal DSs start to form bud scales in July and have fully formed interfoliar buds by mid-August. In contrast, those DS apices lacking protective bud scales at needle maturity become suberized and can never proliferate into long shoots. The distal placement of interfoliar buds may be due to a group effect, where each developing DS inhibits the more proximal DSs in the long shoot terminal bud.