Quantitative Effects of 2,4-Dichlorophenoxyacetic Acid on Growth of Suspension-cultured Acer pseudoplatanus Cells

Using suspension-cultured Acer pseudoplatanus cells requiring 2,4-dichlorophenoxyacetic acid for growth, the dependence of the population doubling time and the maximum increase in cell population density on the auxin concentration was studied. It appears that in the range of 2,4-dichlorophenoxyacetic acid concentration from 4 × 10⁻⁸ to 4 × 10⁻⁶ M, the rate of cell division during the logarithmic growth phase is independent of the auxin concentration, while the maximum number of cell generations obtained is limited by the initial auxin concentration. The significance of these two aspects of auxin action are discussed.     

The Involvement of Glycosidases in the Cell Wall Metabolism of Suspension-cultured Acer pseudoplatanus Cells

Several glycosidases have been isolated from suspensioncultured sycamore (Acer pseudoplatanus) cells. These include an α-galactosidase, an α-mannosidase, a β-N-acetyl-glucosaminidase, a β-glucosidase, and two β-galactosidases. The pH optimum of each of these enzymes was determined. The pH optima, together with inhibition studies, suggest that each observed glycosidase activity represents a separate enzyme. Three of these enzymes, β-glucosidase, α-galactosidase, and one of the β-galactosidases, have been shown to be associated with the cell surface. The enzyme activities associated with the cell surface were shown to possess the ability to degrade to a limited extent isolated sycamore cell walls. It was found that the activities of β-glucosidase and of one of the β-galactosidases increase as the cells go through a period of growth and decrease as cell growth ceases.     

Effect of Benzyladenine, 2,4-Dichlorophenoxyacetic Acid, and d-Glucose on myo-Inositol Metabolism in Acer pseudoplatanus L. Cells Grown in Suspension Culture

Suspension cultures of Acer pseudoplatanus L. cells grown for 15 days in medium (T. Murashige and F. Skoog. 1962. Physiol. Plant. 15: 473-497) contained 3% sucrose, 1 mg/l 6-benzylaminopurine (BA), and 0.1 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D), referred to here as normal media, removed newly added myo-inositol-2-(3)H up to 100 mg/l in 24 hours and utilized up to 20% of this cyclitol for pectin biosynthesis. When the BA content of the growth medium was raised 10-fold, uptake of myo-inositol was drastically reduced and very little was available for pectin biosynthesis. Neither cell growth as measured by packed cell volume or by dry weight, nor monomer composition of pectic polysaccharides was affected by the increased level of cytokinin. Increasing, 2,4-d 10-fold instead of BA had little or no effect on myo-inositol uptake, although it did reduce the amount of myo-inositol utilized for pectin biosynthesis. Cells grown 15 days in normal media failed to remove added myo-inositol if 3% d-glucose was included. The net result was similar to that found in cells grown in the high BA condition. If a trace amount of d-galactose-1-(14)C was supplied to cells after 15 days of growth in normal, high BA, or high 2,4-d media, there was no significant variation in uptake and utilization of label among the three growth conditions.     

Growth of Suspension-cultured Acer pseudoplatanus L. Cells in Automatic Culture Units of Large Volume

A phytostat to mass culture higher plant cells in liquid medium is described. This apparatus allowed the culture in batch, turbidostat and chemostat of 20 liters of cells. Automatic control of cell suspension growth was based on culture turbidity. Changes with time of certain cell characteristics, particularly cell respiration and phospholipid content, indicated that the test time to harvest large amounts of sycamore cells (Acer pseudoplatanus L.) in good physiological state was about 2 days before the end of the exponential phase of growth, when the cell density reached one million cells per milliliter of culture.     

Cytoplasmic pH Regulation in Acer pseudoplatanus Cells: II. Possible Mechanisms Involved in pH Regulation during Acid-Load

Qualitative and quantitative aspects of the mechanisms involved in the regulation of cytoplasmic pH during an acid-load have been studied in Acer pseudoplatanus cells. Two main processes, with about the same relative importance, account for the removal of H⁺ from the cytoplasm, namely a `metabolic consumption' of protons and the excretion of protons or proton-equivalents out of the cells. The metabolic component corresponds to a change in the equilibrium between malate synthesis and degradation leading to a 30% decrease of the malate content of the cells during the period of cytoplasmic pH regulation. Various conditions which severely inhibit the activity of the plasmalemma proton pump ATPase reduce, at most by 50%, the excretion of H⁺. This suggests that, besides the plasmalemma proton-pump, other systems are involved in the excretion of proton-equivalents. Indirect information on qualitative and quantitative features of these systems is described, which suggests the involvement of Na⁺ and HCO₃⁻ exchanges in the regulation of cytoplasmic pH of acid-loaded cells.     

Cytoplasmic pH Regulation in Acer pseudoplatanus Cells: I. A P NMR Description of Acid-Load Effects

Modifications of cytoplasmic pH in Acer pseudoplatanus L. cells cultivated in suspension have been induced by acid-loads and studied by using ³¹P nuclear magnetic resonance spectroscopy. The initial drop of cytoplasmic pH, observed in the first minutes of exposure to weak lipophilic acids, was followed by a slow recovery to reach a plateau phase with a pH value lower than the initial one. Conversely, removal of the acid led to a sharp increase of cytoplasmic pH with in most cases an overshoot toward more alkaline values than the initial one and a subsequent decrease to more acidic values. This shows that A. pseudoplatanus cells powerfully regulate their cytoplasmic pH both on the acid side of their normal pH, during the acid-load, and on the alkaline side, after removal of acid. Similar results were obtained with different types of acid-loads, i.e. treatments with propionic or benzoic acid or bubbling with CO₂-enriched air. This indicates that the occurrence of pH regulation does not depend upon the method used to acid-load the cells. The time courses of cytoplasmic pH observed for A. pseudoplatanus and also Catharanthus roseus cells are similar to those recorded for animal cells but different from those described for other plant materials for which no recovery phase was observed. This can be explained by different balances between the initial rate of proton influx brought in by the acids, and the capacity of proton consumption by the regulatory mechanisms. The existence of the recovery phase offers a unique possibility to study the regulation of the cytoplasmic pH of plant cells, as it has been done in animal systems.     

Metabolism of 2,4-Dichlorophenoxyacetic Acid (2,4-D) in Soybean Root Callus : EVIDENCE FOR THE CONVERSION OF 2,4-D AMINO ACID CONJUGATES TO FREE 2,4-D

An auxin-requiring soybean root callus metabolized [1-¹⁴C]-2,4-dichlorophenoxyacetic acid (2,4-D) to diethyl ether-soluble amino acid conjugates and water-soluble metabolites. The uptake in tissue varied with incubation time, concentration, and amount of tissue. Uptake was essentially complete (80%) after a 24-hour incubation and the percentage of free 2,4-D in the tissue fell to its lowest point at this time. At later times, the percentage of free 2,4-D increased and the percentage of amino acid conjugates decreased, whereas the percentage of water-soluble metabolites increased only slightly. Similar trends were seen if the tissue was incubated for 24 hours in radioactive 2,4-D, followed by incubation in media without 2,4-D for 24 hours. Inclusion of nonlabeled 2,4-D during the 24-hour chase period did not reduce amino acid conjugate disappearance but did reduce the percentage of free [1-¹⁴C]2,4-D. Thus, an external supply of 2,4-D does not directly prevent amino acid conjugate metabolism in this tissue. It is concluded that 2,4-D amino acid conjugates were actively metabolized by this tissue to free 2,4-D and water-soluble metabolites.     

The Effect of Growth Hormones on Cell Division and Expansion in Liquid Suspension Cultures of Acer pseudoplatanus

The effects on cell division and cell size of indole-3-aceticacid (IAA), gibberellic acid (GA), and kinetin were studiedin liquid suspension cultures of cambial cells derived fromAcer pseudoplatanus. It was shown that all three hormones promotecell division and that the effects of both GA and kinetin areadditive to those of IAA, but the effects of GA and kinetintogether are not additive. Treatment with IAA resulted in anincrease of mean cell size (indicating that cell expansion ispromoted), but after GA or kinetin treatment the mean cell sizewas smaller, indicating that little cell expansion had takenplace after each division. The results are discussed in relationto previous work on the effects of hormones in the intact cambiumand to current theories on the interactions of growth hormones.     

2,4-D Resistance in a Tobacco Cell Culture Variant II. Effects of 2,4-D on Nucleic Acid and Protein Synthesis and Cell Respiration

The effects of 2,4-D on nucleic acid and protein synthesis andcell respiration were compared between a 2,4-D-resistant variantand its wild-type cell lines of tobacco (Nicotiana tabacum L.).The variant continued cell division and growth in the presenceof 100 µM 2,4-D which was strongly inhibitory to the wild-typecell lines. Among the macromolecular syntheses studied, DNAsynthesis was the most sensitive and protein synthesis was theleast sensitive to inhibitory concentrations of 2,4-D. The variantdisplayed threefold higher resistance to 2,4-D than the wild-typecell line based on the 50% inhibitory concentrations of 2,4-Don DNA synthesis. No significant differences which could explainthe 2,4-D resistance were found between the variant and thewild-type cell lines in 2,4-D concentrations required to inhibitRNA and protein synthesis. The effect of 2,4-D on cell respirationwas detectable without a noticeable lag. The resistance of thevariant based on the effect on cell respiration also was apparentimmediately after 2,4-D addition. According to the 50% inhibitoryconcentrations of 2,4-D on cell respiration, the variant showeda level of resistance similar to that estimated by DNA synthesis.These results indicate that the resistance of the variant isdue to a modification which reduces the cellular sensitivityto phyto-toxic concentrations of 2,4-D with respect to, at least,DNA synthesis and respiration. (Received August 6, 1985; Accepted November 27, 1985)     

2,4-D和NAA在拟南芥细胞分裂和伸长中的作用分析

以拟南芥悬浮细胞体系为实验材料,研究了人工合成生长素NAA和2,4-D外源处理对细胞形态、细胞鲜重、细胞分裂指数等指标的影响.结果表明:2μmol/L 2,4-D可有效促进细胞分裂但不影响细胞伸长;同样浓度的NAA主要诱导细胞的伸长;细胞伸长和细胞分裂是2个不相偶联的过程;在2,4-D所诱导的细胞分裂过程中异三聚体G-蛋白α-亚基GPA1强表达.     

The Effects of 2,4-Dichlorophenoxyacetic Acid on Ion Uptake by Maize Roots

The effects of the synthetic auxin and herbicide 2,4-dichlorophenoxyaceticacid (2,4-D) on K^$ and Cl^– uptake and H^$ release by youngexcised maize roots has been studied. Brief exposure to 2,4-D(0.01 mmol dm^–3) at pH 3.5 causes a large depolarizationof the electrical potential across the root plasma membranesand converts K^$ uptake to K^$ leakage into the bathing solution.These results can be explained by the increased H^$ permeabilityof the membranes induced by the weak acid 2,4-D. The depolarizationresults in a less favourable electrochemical potential gradientfor K^$ uptake across these membranes. These effects are notrelated to the auxin properties of 2,4-D as the nonauxin 3,5-dichlorophenoxyaceticacid (3,5-D) gives rise to similar effects. The relative depolarizationsinduced by a range of weak acids appear to be unrelated to theiroil/water partition coefficients. In contrast, on bathing the roots for longer periods in solutions(pH > 5) containing 2,4-D (0.01 mmol dm^–3) K^$ and Cl^–uptake and H^$ release are inhibited. These effects are not shownwith 3,5-D suggesting an auxin-linked action for 2,4-D. Alsothe electrical potential across the plasma membranes is onlyslightly depolarized so that a change in the electrochemicalpotential gradient cannot be invoked to explain the loweredion fluxes. The evidence is consistent with the removal of anenergy supply to a metabolically linked K^–/H^– exchangemechanism in the plasma membranes. It is likely that both modes of action would operate to lowerion uptake under soil-grown conditions, the former becomingmore manifest in acidic soils.     

Effect of Xyloglucan Nonasaccharide on Cell Elongation Induced by 2,4-Dichlorophenoxyacetic Acid and Indole-3-acetic Acid

Xyloglucan nonasaccharide (XG9) is recognized as an inhibitorof 2,4-D-induced long-term growth of segments of pea stems.In the presence of 10^–5 M 2,4-D, inhibition by 10^–9M XG9 of elongation of third internode segments of pea seedlingswas detected within 2 h after the start of incubation, in someexperiments. Analysis by double-reciprocal (Lineweaver-Burk)plots of elongation in the presence of various concentrationsof 2,4-D, with or without XG9, gave parallel lines, indicatingthat XG9 inhibited 2,4-D-induced elongation in an uncompetitivemanner. XG9 did not influence the 2,4-D-induced cell wall loosening.Thus, XG9 does not fulfill the proposed definition of an "antiauxin". XG9 at 10^–11 to 10^–6 M did not influence IAA-inducedelongation of segments from pea third internodes, azuki beanepicotyls, cucumber hypocotyls, or oat coleoptiles. Inhibitionof IAA-induced elongation by XG9 was not observed even whenthe segments from pea or azuki bean were abraded. Furthermore,fucosyl-lactose at 10^–11 to 10^–4 M did not affectthe IAA-induced elongation of segments of pea internodes orof azuki bean epicotyls. XG9 may be incapable of inhibitingthe IAA-induced cell elongation (especially in oat) or, alternatively,the endogenous levels of XG9 may be so high that exogenouslyapplied XG9 has no inhibitory effect on IAA-induced elongation. (Received February 28, 1991; Accepted May 25, 1991)