Critical consideration on the relationship between auxin transport and calcium transients in gravity perception of Arabidopsis seedlings

Plants regulate their growth and morphogenesis in response to gravity field, known as gravitropism. In the early process of gravitropism, changes in the gravity vector (gravistimulation) are transduced into certain intracellular signals, termed gravity perception. The plant hormone auxin is not only a crucial factor to represent gravitropism but also a potential signaling molecule for gravity perception. Another strong candidate for the signaling molecule is calcium ion of which cytoplasmic concentration ([Ca²⁺]_c) is known to increase in response to gravistimulation. However, relationship between these two factors, say which is in the first place, has been controversial. This issue is addressed here mainly based on recent progress including our latest studies. Gravistimulation by turning plants 180° induced a two-peaked [Ca²⁺]_c-increase lasting for several minutes in Arabidopsis seedlings expressing apoaequorin; only the second peak was sensitive to the gravistimulation. Peak amplitudes of the [Ca²⁺]_c-increase were attenuated by the 10 µM auxin transport inhibitor (TIBA) and vesicle trafficking inhibitor (BFA), whereas the onset time and rate of rise of the second peak were not significantly altered. This result indicates that polar auxin transport is not involved in the initial phase of the second [Ca²⁺]_c-increase. It is likely that the gravi-induced [Ca²⁺]_c-increase constitutes an upstream event of the auxin transport, but may positively be modulated by auxin since its peak amplitude is attenuated by the inhibition of auxin transport.Key words: auxin, calcium, gravity perception, gravitropism, pin-formed (PIN) protein, Arabidopsis thaliana     

Probing a Membrane Matrix Regulating Hormone Action: II. The Kinetics of Lipid-Induced Growth and Ethylene Production

Lipids which are active oleanimins, i.e., those which stimulate respiration and auxin-induced cell elongation of pea stem sections, also initiate a period of ethylene formation in them after a lag period of at least 1 hour. Production of ethylene requires auxin, is inhibited by cycloheximide and dinitrophenol applied during or before the lag period, and is greatly stimulated by lipids longer than 20 Ångstroms in length such as heptadecyl-benzene, chloro- or iodohexadecane, triolein, and vitamins E and K₁, but not by the shorter chloro- and iododecane. β-Stigmasterol at 10 to 40 μm concentrations depresses both oleanimin-induced growth and ethylene formation.     

Physical and Kinetic Properties and Regulation of the NAD Malic Enzyme Purified from Leaves of Crassula argentea

The NAD malic enzyme has been purified to near homogeneity from the leaves of Crassula argentea Thunb. The enzyme has two subunits, one of 59,000 daltons, and one of 62,000 daltons. In native gels stained for activity, the enzyme appears to exist in the dimeric, tetrameric, and predominantly the octameric forms.

The enzyme uses either Mg²⁺ or Mn²⁺ as the required divalent cation, and utilizes NADP at a rate less than 20% of that with NAD. With Mn²⁺ the K_m for malate²⁻ is lower than with Mg²⁺, but V_max is lower than with Mg²⁺. In the forward (malate-decarboxylating) direction with NAD, the kinetic parameters are essentially like those observed for the enzyme from C₃ plants. In the reverse reaction, run with Mn²⁺, the activity is 1.5% of that in the forward reaction. The equilibrium constant is 1.1 × 10⁻³ molar.

The kinetic mechanism of the reaction, at least in the forward direction, is sequential, with apparently random binding of all reaction components. Product inhibition patterns confirm this.

The enzyme displays a strong hysteretic lag, which is shortened by high enzyme concentrations, high substrate concentrations, and the presence of the product NADH.

The enzyme is activated by coenzyme A with K_a = 4 micromolar. AMP also shows competitive activation, with K_a = 24 micromolar. The activation by coenzyme A and AMP is additive, implying separate sites for their binding. Phosphoenolpyruvate activates the reaction at low (micromolar) concentrations, but higher concentrations of phosphoenolpyruvate cause deactivation. Fumarate²⁻ is a strong activator, with K_a = 0.3 millimolar. Fructose-1,6-bisphosphate activates the enzyme, but its most pronounced effect is in shortening the lag. Citrate is a competitive inhibitor of malate, with K_i = 4.9 millimolar.

     

Responses of Avena coleoptiles to suboptimal fusicoccin: kinetics and comparisons with indoleacetic Acid

Proton excretion induced by optimal concentrations of indoleacetic acid (IAA) and fusicoccin (FC) differs not only in maximum rate of acidification but also in the lag before onset of H⁺ excretion and in sensitivity to cycloheximide. Because these differences might simply be a consequence of the difference in rate of proton excretion, FC and IAA have now been compared using oat coleoptiles (cv. Victory) under conditions where the rates of acidification are more similar, i.e. suboptimal FC versus optimal IAA. As the concentration of FC is reduced, the rate of H⁺ excretion decreases, the final equilibrium pH increases, and the lag before detectable acidification increases up to 7-fold. This enhanced lag period is not primarily a consequence of wall buffering, inasmuch as it persists when a low concentration of FC is added to sections which were already excreting H⁺ in response to IAA. An extended lag also occurs, upon reduction of FC levels, in the hyperpolarization of the membrane potential, before enhancement of O₂ uptake and before the increased rate of Rb⁺ uptake. The presence or absence of a lag is not a distinguishing feature between FC and IAA actions on H⁺ excretion and cannot be used to discriminate between their sites of action. In contrast, the insensitivity of FC-induced H⁺ excretion to cycloheximide, as compared with the nearly complete inhibition of this auxin effect by cycloheximide, persists even at dilute concentrations of FC. This seems to be a basic difference in H⁺ excretion by IAA and FC.     

Gravitropism in Higher Plant Shoots : V. Changing Sensitivity to Auxin

An alternative to the Cholodny-Went, auxin-transport hypothesis of gravitropic stem bending was proposed as early as 1958, suggesting that gravistimulation induces changes in sensitivity to auxin, accounting for differential growth and bending. To test the sensitivity hypothesis, we immersed marked, decapitated sunflower (Helianthus annuus L.) hypocotyl sections in buffered auxin solutions over a wide concentration range (0, 10⁻⁸ to 10⁻² molar IAA), photographed them at half-hour intervals, analyzed the negatives with a digitizer/computer, and evaluated surface-length changes in terms of Michaelis-Menten enzyme kinetics. Bending decreases with increasing auxin concentration; above about 10⁻⁴ molar IAA the hypocotyls bend down; increasing auxin inhibits elongation growth of lower surfaces (which is high at zero or relatively low auxin levels) but promotes upper-surface growth (which is low at low auxin levels). Thus, lower surfaces have a greater K_m sensitivity to applied auxin than upper surfaces. At optimum auxin levels (maximum growth), growth of bottom surfaces exceeds that of top surfaces, so bottom tissues have a greater V_max sensitivity. V_max sensitivity of vertical controls is slightly lower than it is for either horizontal surface; K_m sensitivity is intermediate. Clearly, gravistimulation leads to significant changes in tissue sensitivity to applied auxin. Perhaps these changes are also important in normal gravitropism.     

Inhibitory properties of endogenous subunit epsilon in the Escherichia coli F1 ATPase.

Homogeneous ? bound tightly to the purified Escherichia coli ATPase (ECF₁ from which ? had been removed and strongly inhibited its ATPase activity. ECF₁ containing ? had a lower specific activity than ECF₁ missing ?, provided that the ATPase assay was carried out at relatively high concentrations of enzyme. Antiserum specific for the ? subunit stimulated the ATPase, as did diluting the enzyme, apparently by dissociating ?. When the ATPase reaction was started by the addition of enzyme, the rate of ATP hydrolysis increased progressively during the first 3 min until a linear steady-state rate was reached. A prior incubation with ATP abolished the lag period and ADP prevented the ATP effect. ECF₁ missing ? gave a linear rate of ATP hydrolysis without a lag, unless ? was rebound to it before the assay. These results suggest that ECF₁ as purified is in an inhibited state due to the presence of the ? subunit, whose interaction with ECF₁ is governed by an equilibrium binding. ATP appears to convert ECF₁ to a form which more readily binds and releases ?.     

Effect of different phenols on the nadh-oxidation catalysed by a peroxidase from lupin

Cell wall-bound peroxidase (EC 1.11.1.7) from lupin (Lupinus albus) shows a transition from oxidase to peroxidase activity when it oxidizes NADH. The oxidase phase represents a lag period in the time course of the reaction. This phase is phenol-dependent and responsible for hydrogen peroxide formation. Guaiacol, an assay substrate, and p-coumaric, ferulic and sinapic acids, precursors of the cinnamyl alcohols used in the lignification process affect both the length of lag period and the rate of the peroxidase phase of NADH oxidation. The effect of different phenols on the time course of the reaction is related to the efficacy (V_max/K_m ratio) of the enzyme when it is acting on them as a peroxidese.     

Ammonia assimilation and oxygen evolution by a reconstituted chloroplast system in the presence of 2-oxoglutarate and glutamate

(Ammonia plus 2-oxoglutarate)-dependent O₂ evolution by intact chloroplasts was enhanced three- to five fold by 2 mM L- and D-malate, attaining rates of 9–15 μmol mg^-1 Chl h^-1. Succinate and fumarate also promoted activity but D-aspartate and, in the presence of aminooxyacetate, L-aspartate inhibited the malate-promoted rate. A reconstituted chloroplast system supported (ammonia plus 2-oxoglutarate)-dependent O₂ evolution at rates of 6-11 μmol mg^-1 Chl h^-1 in the presence of MgCl₂, NADP(H), ADP plus Pi (or ATP), ferredoxin and L-glutamate. The concentrations of L-glutamate and ATP required to support 0.5 V _max were 5 mM and 0.25 mM, respectively. When the reaction was initiated with NH₄Cl, O₂ evolution was preceded by a lag phase before attaining a constant rate. The lag phase was shortened by addition of low concentrations of L-glutamine or by preincubating in the dark in the presence of glutamate, ATP and NH₄Cl. Oxygen evolution was inhibited by 2 mM azaserine and, provided it was added initially, 2 mM methionine sulphoximine. The (ammonia plus 2-oxoglutarate)-dependent O₂ evolution was attributed to the synthesis of glutamine from NH₄Cl and glutamate which reacted with 2-oxoglutarate in a reaction catalysed by ferredoxin-specific glutamate synthase using H₂O as the ultimate electron donor. The lag phase was attributed to the establishment of a steady-state pool of glutamine. L-Malate did not affect the activity of the reconstituted system.     

Studies on Auxin Protectors: XI. Inhibition of Peroxidase-Catalyzed Oxidation of Glutathione by Auxin Protectors and o-Dihydroxyphenols

Commercial horseradish peroxidase, when supplemented with dichlorophenol and either manganese or hydrogen peroxide, will rapidly oxidize glutathione. This peroxidase-catalyzed oxidation of glutathione is completely inhibited by the presence of auxin protectors. Three auxin protectors and three o-dihydroxyphenols were tested; all inhibited the oxidation. Glutathione oxidation by horseradish peroxidase in the presence of dichlorophenol and Mn is also completely inhibited by catalase, implying that the presence of Mn allows the horseradish peroxidase to reduce oxygen to H₂O₂, then to use the H₂O₂ as an electron acceptor in the oxidation of glutathione. Catalase, added 2 minutes after the glutathione oxidation had begun, completely inhibited further oxidation but did not restore any gluthathione oxidation intermediates. In contrast, the addition of auxin protectors, or o-dihydroxyphenols, not only inhibited further oxidation of gluthathione by horseradish peroxidase (+ dichlorophenol + Mn), but also caused a reappearance of glutathione as if these antioxidants reduced a glutathione oxidation intermediate. However, when gluthathione was oxidized by horseradish peroxidase in the presence of dichlorophenol and H₂O₂ (rather than Mn), then the inhibition of further oxidation by auxin protectors or o-dihydroxyphenols was preceded by a brief period of greatly accelerated oxidation. The data provide further evidence that auxin protectors are cellular redox regulators. It is proposed that the monophenol-diphenol-peroxidase system is intimately associated with the metabolic switches that determine whether a cell divides or differentiates.     

New insights into activation and substrate recognition of polyhydroxyalkanoate synthase from Ralstonia eutropha

The polyhydroxyalkanoate synthase of Ralstonia eutropha (PhaC_Re) shows a lag time for the start of its polymerization reaction, which complicates kinetic analysis of PhaC_Re. In this study, we found that the lag can be virtually eliminated by addition of 50 mg/L TritonX-100 detergent into the reaction mixture, as well as addition of 2.5 g/L Hecameg detergent as previously reported by Gerngross and Martin (Proc Natl Sci USA 92: 6279–6283, 1995). TritonX-100 is an effective lag eliminator working at much lower concentration than Hecameg. Kinetic analysis of PhaC_Re was conducted in the presence of TritonX-100, and PhaC_Re obeyed Michaelis–Menten kinetics for (R)-3-hydroxybutyryl-CoA substrate. In inhibitory assays using various compounds such as adenosine derivatives and CoA derivatives, CoA free acid showed competitive inhibition but other compounds including 3′-dephospho CoA had no inhibitory effect. Furthermore, PhaC_Re showed a considerably reduced reaction rate for 3′-dephospho (R)-3-hydroxybutyryl CoA substrate and did not follow typical Michaelis–Menten kinetics. These results suggest that the 3′-phosphate group of CoA plays a critical role in substrate recognition by PhaC_Re.     

Pattern of antioxidant enzyme activities and hydrogen peroxide content during developmental stages of rhizogenesis from hypocotyl explants of Mesembryanthemum crystallinum L.

Key message

H ₂ O ₂ is necessary to elicit rhizogenic action of auxin. Activities of specific catalase and manganese superoxide dismutase forms mark roots development.

Abstract

Hypocotyl explants of Mesembryanthemum crystallinum regenerated roots on medium containing 2,4-dichlorophenoxyacetic acid. Explants became competent to respond to the rhizogenic action of auxin on day 3 of culture, when hydrogen peroxide content in cultured tissue was the highest. l-Ascorbic acid added to the medium at 5 μM lowered the H₂O₂ level, inhibited rhizogenesis and induced non-regenerative callus, suggesting that certain level of H₂O₂ is required to promote root initiation. Coincident with the onset of rhizogenic determination, meristemoids formed at the periphery of the hypocotyl stele and the activity of the manganese form of superoxide dismutase, MnSOD-2 was induced. Once induced, MnSOD-2 activity was maintained through the post-determination phase of rooting, involving root growth. MnSOD-2 activity was not found in non-rhizogenic explants maintained in the presence of AA. Analyses of the maximum photochemical efficiency of photosystem II and the oxygen uptake rate revealed that the explants were metabolically arrested during the predetermination stage of rhizogenesis. Respiratory and photosynthetic rates were high during root elongation and maturation. Changes in catalase and peroxidase activities correlated with fluctuations of endogenous H₂O₂ content throughout rhizogenic culture. Expression of a specific CAT-2 form accompanied the post-determination stage of rooting and a high rate of carbohydrate metabolism during root growth. On the other hand, the occurrence of MnSOD-2 activity did not depend on the metabolic status of explants. The expression of MnSOD-2 activity throughout root development seems to relate it specifically to root metabolism and indicates it as a molecular marker of rhizogenesis in M. crystallinum.     

Effect of Plasmid pSa and of Auxin on Attachment of Agrobacterium tumefaciens to Carrot Cells

When the plasmid pSa is introduced into Agrobacterium tumefaciens, its presence results in the suppression of bacterial virulence. A. tumefaciens(pSa) cells are virulent on Bryophyllum diagremontiana only when inoculated with auxin. A. tumefaciens(pSa) cells also bind to plant cells only in the presence of auxin. The effect of auxin is on the bacteria rather than on the plant cells, since the bacteria require auxin to bind to heat-killed carrot cells. Bacteria containing pSa and grown in the absence of auxin showed a lag in binding to carrot cells in auxin-containing medium. This lag was not seen during the binding of wild-type strains. Tetracycline inhibited the binding of A. tumefaciens(pSa) in auxin-containing medium, suggesting that bacterial protein synthesis is required for the auxin effect. No difference was seen in the size or ability to inhibit bacterial binding of lipopolysaccharides from bacteria containing or lacking pSa and grown with or without auxin. A. tumefaciens(pSa) cells grown in the absence of auxin lacked surface polypeptide(s) found in bacteria grown in the presence of auxin and in the wild-type bacteria, which do not contain pSa. Thus, the presence of certain polypeptides appears to be associated with the ability of the bacteria to bind to plant cells.     

Kinetic properties of IAA oxidase from mung bean cotyledons

A crude enzyme preparation from mung bean cotyledons was separated into peroxidative and non-peroxidative IAA oxidase on a DEAE-cellulose column. Both fractions differed in their pH optima, K_m and V_max. The K_m and V_max of non-peroxidative IAA oxidase were higher than those of peroxidative IAA oxidase. Peroxidative IAA oxidase showed a linear increase in absorption at 247 and 254 nm after a short lag of 2–3 min. The addition of catalytic amounts of hydrogen peroxide eliminated the lag period and also enhanced the rate of IAA degradation. The non-peroxidative IAA oxidase fraction, however, did not exhibit any significant increase in absorption at 247 and 254 nm and showed a lag period of 5 min which was not affected by hydrogen peroxide. Instead, addition of the same catalytic amount of hydrogen peroxide inhibited the rate of IAA degradation. The peroxidative IAA oxidase fraction exhibited the reaction kinetics characteristic of peroxidase-catalysed IAA degradation. The rate of IAA oxidation by purified non-peroxidative IAA oxidase was very low. The slow rate of catalysis shown by non-peroxidative IAA oxidase appears to be due to the presence of inhibitor(s).     

Adaptation of the Cyanobacterium Anabaena variabilis to Low CO(2) Concentration in Their Environment

The rate of adaptation of high CO₂ (5% v/v CO₂ in air)-grown Anabaena to a low level of CO₂ (0.05% v/v in air) was determined as a function of O₂ concentration. Exposure of cells to low (2.6%) O₂ concentration resulted in an extended lag in the adaptation to low CO₂ concentration. The rate of adaptation following the lag was not affected by the concentration of O₂. The length of the lag period is markedly affected by the O₂/CO₂ concentration ratio, indicating that the signal for adaptation to low CO₂ may be related to the relative rate of ribulose-1,5-bisphosphate carboxylase/oxygenase activities, rather than to CO₂ concentration proper. This suggestion is supported by the observed accumulation of phosphoglycolate following transfer of cells from high to low CO₂ concentration.     

Fatty acids and lysophospholipids as potential second messengers in auxin action. Rapid activation of phospholipase A2 activity by auxin in suspension-cultured parsley and soybean cells

Activation of cytosolic phospholipase A₂ is a typical signal transduction reaction in animal cells and occurs in plants in response to auxin, elicitors and wounding. Exogenously added fluorescent bis-BODIPY-phosphatidylcholine was taken up and hydrolysed by a cellular phospholipase A₂. Rapid activation of a phospholipase A₂ by auxin in suspension-cultured parsley ( Petrosilenum crispum L.) and soybean ( Glycine max L.) cells was shown by detection and quantification of fluorescent reaction products of phospholipase A₂. Hormone-triggered fluorescent fatty acid accumulation could be detected as early as 5 min. Auxins at 2 μM or higher concentrations activated phospholipase A₂ and fluorescent fatty acids accumulated 1.1- to threefold after 90–120 min, depending on the auxin concentration. Fluorescent lysolipid did not accumulate up to 150 μM auxin. Known inhibitors of phospholipase A₂ inhibited hormone-dependent fluorescent fatty acid accumulation in cell cultures and, previously, elongation growth in etiolated zucchini hypocotyl segments ( Scherer & Arnold (1997 ) Planta 202, 462–469). When lipids were labeled by [¹⁴C]-choline and [¹⁴C]-ethanolamine the corresponding lysophospholipids could be quantified in cell extracts. Radioactive lysophospholipids accumulated as rapidly as 1–2 min after auxin treatment but only at concentrations well above 100 μM auxin. We hypothesize that phospholipase A₂ activation is an early intermediate step between receptor and downstream responses. We hypothesize that fatty acid(s) could be second messengers in several auxin functions, especially in cell elongation. Lysophospholipids seem to be indicators or second messengers for stress caused by high auxin concentrations or may have different auxin-linked functions and are also known to accumulate during elicitor action.     

A fluorometric method for the kinetic assay of indole-3-acetic acid oxidase.

The oxidation of IAA by peroxidase (1) and by more specific oxidases (2) leads to the formation of products which may have physiological activity (3, 4). The colorimetric estimation of IAA oxidation products involving reaction with p-dimethylaminocinnamaldehyde (DMACA) is reported to be more sensitive than other end point determinations such as the Salkowski and Ehrlich procedures which monitor the disappearance of IAA (5). These methods are end point procedures and, as such, are awkward and time consuming and present difficulties in obtaining kinetic data and measuring lag times. IAA oxidation has also been monitored by measuring ¹⁴CO₂ released from [1-¹⁴C] IAA (6) and uv spectral shifts during oxidation of IAA were reported by Meudt (3). The present paper reports a new procedure for the assay of horseradish peroxidase catalyzed oxidation of IAA. The assay procedure is based on the continuous measurement of a fluorescent product of the reaction.     

Boron and calcium sites involved in indole-3-acetic Acid transport in sunflower hypocotyl segments

Sunflower (Helianthus annuus L. cv Russian Mammoth) hypocotyl segments deficient in either B or Ca exhibited a higher rate of potassium leakage, compared to nondeficient segments. Potassium leakage, used here as an indication of membrane integrity, was completely reversed by the addition of H₃BO₃ or Ca(NO₃)₂ to the incubation medium of the B-deficient or Ca-deficient hypocotyl segments, respectively. This role of B and Ca in membrane integrity, which may be important in the entry and exit of auxin in cells, is identified as the first site of action for each of these two essential elements in the basipetal secretion of auxin. A second site for B is postulated because auxin transport was not restored, even when K⁺ leakage has been completely reversed to the nondeficient level, when B-deficient hypocotyls were incubated in B solution. This lack of reversibility of auxin transport implied that the incubation for 2 h in B solution was not enough to restore the auxin transport process. However, since the transfer of B-deficient seedlings to B solutions prevented further deterioration of auxin transport, these observations suggest that: (a) either an intact seedling, or a longer period of incubation of the hypocotyl in B solution, is required for the synthesis or maintenance of the functional second site for B; (b) B is probably essential in the synthesis of a ligand, which may or may not be needed to bind B, but which is essential in the basipetal transport of auxin. The second site for Ca in auxin transport, is indicated by the complete reversal of its inhibition in Ca-deficient hypocotyl, when incubated in Ca solution. The second site for Ca is thought to be directly involved in the secretion of auxin, in which Ca probably plays the role of a second messenger, as in stimulus-response coupling. The two sites for Ca can be distinguished from each other by their cation specificity. The requirement for Ca in the first site can be substituted by other divalent cations, while the second site is highly specific for Ca.     

Gravitropism in Higher Plant Shoots : VI. Changing Sensitivity to Auxin in Gravistimulated Soybean Hypocotyls

Although the Cholodny-Went model of auxin redistribution has been used to explain the transduction phase of gravitropism for over 60 years, problems are apparent, especially with dicot stems. An alternative to an auxin gradient is a physiological gradient in which lower tissues of a horizontal stem become more sensitive than upper tissues to auxin already present. Changes in tissue sensitivity to auxin were tested by immersing marked Glycine max Merrill (soybean) hypocotyl sections in buffered auxin solutions (0, 10⁻⁸ to 10⁻² molar indoleacetic acid) and observing bending and growth of upper and lower surfaces. The two surfaces of horizontal hypocotyl sections responded differently to the same applied auxin stimulus; hypocotyls bent up (lower half grew more) in buffer alone or in low auxin levels, but bent down (upper half grew more) in high auxin. Dose-response curves were evaluated with Michaelis-Menten kinetics, with auxin-receptor binding analogous to enzyme-substrate binding. V_max for the lower half was usually greater than that for the upper half, which could indicate more binding sites in the lower half. K_m of the upper half was always greater than that of the lower half (unmeasurably low), which could indicate that upper-half binding sites had a much lower affinity for auxin than lower-half sites. Dose-response curves were also obtained for sections `scrubbed' (cuticle abraded) on top or bottom before immersion in auxin, and `gravitropic memory' experiments of L. Brauner and A. Hagar (1958 Planta 51: 115-147) were duplicated. [1-¹⁴C]Indoleacetic acid penetration was equal into the two halves, and endogenous plus exogenously supplied (not radiolabeled) free auxin in the two halves (by gas chromatography-selected ion monitoring-mass spectrometry) was also equal. Thus, differential growth occurred without free auxin redistribution, contrary to Cholodny-Went but in agreement with a sensitivity model.