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.     

Auxin efflux carrier activity and auxin accumulation regulate cell division and polarity in tobacco cells

Division and growth of most types of in vitro-cultured plant cells require an external source of auxin. In such cultures, the ratio of external to internal auxin concentration is crucial for the regulation of the phases of the standard growth cycle. In this report the internal concentration of auxin in suspension-cultured cells of Nicotiana tabacum L., strain VBI-0, was manipulated either (i) by increasing 10-fold the normal concentration of 1-naphthaleneacetic acid (NAA) and 2,4-dichlorophenoxyacetic acid in the external medium; or (ii) by addition 1-N-naphthylphthalamic acid (NPA; an inhibitor of auxin efflux and of auxin efflux carrier traffic). Both treatments delayed the onset of cell division for 6-7 days without loss of cell viability. In both cases, cell division activity subsequently resumed coincident with a reduction in the ability of cells to accumulate [(3)H]NAA from an external medium. Following renewed cell division, a significant proportion of the NPA-treated cells but not those grown at high auxin concentration, exhibited changes in the orientation of new cell divisions and loss of polarity. We conclude that cell division, but not cell elongation, is prevented when the internal auxin concentration rises above a critical threshold value and that the directed traffic of auxin efflux carriers to the plasma membrane may regulate the orientation of cell divisions.     

In vitro flower bud formation in tobacco: interaction of hormones

External application of auxin and cytokinin is required for the formation of flower buds on thin-layer tissue explants of Nicotiana tabacum cv Samsun. Interaction between both plant growth regulators during this regenerative process has been demonstrated with respect to speed of flower bud initiation and the number of flower buds formed. Separation in time of the hormone application during culture revealed that the cytokinin benzyladenine plays a key role in flower bud initiation whereas auxin (indoleacetic acid) stimulates in particular the differentiation of flower buds. The uptake of each hormone was proportional to the concentration supplied in the medium, and the uptake of either hormone appeared independently of the presence of the other. Metabolism studies showed the conversion of indoleacetic acid by the tissue to at least 13 metabolites after 24 h of culture. In addition, indoleacetic acid metabolism was demonstrated not to be influenced by the uptake and metabolism of benzyladenine. Taken together the results indicate that the interaction of auxin and cytokinin with respect to in vitro flower bud formation is indirect, i.e. does not take place at the level of hormone uptake or metabolism but at some step in the cascade of processes they initiate.     

Gibberellic acid-stimulated and auxin-stimulated cell growth in relation to RNA synthesis, protein synthesis and development in the wheat coleoptile

Young excised coleoptiles from dark grown wheat have their cell growth promoted by gibberellic acid (GA₃), while sections from older coleoptiles have their cell growth promoted by auxin. The GA₃ response has a much longer lag period than that of auxin. Neither GA₃ nor auxin has any effect on ¹⁴C-leucine and ¹⁴C-uridine incorporation and uptake after 1 h, indicating that the lag in growth stimulation following GA₃ application is not associated with changes in protein or RNA synthesis. Following a 6 h incubation there are small increases in ¹⁴C-leucine and ¹⁴C-uridine incorporation in response to both GA₃ and auxin, and in the case of auxin this is associated with increased uptake. Studies on protein and RNA turnover using pulse-chase experiments have shown that both GA₃ and auxin have no effect on protein and RNA stability. There are, however, developmental changes in RNA and protein synthesis that should be considered in any explanation of the mechanism of action of these hormones on cell growth. Young GA₃-sensitive tissue has high rates of RNA synthesis and low protein and RNA turnover, while auxin-sensitive tissue has low rates of RNA synthesis, slightly higher rates of RNA turnover and much higher rates of protein turnover. The evidence overall favours more effective utilisation by GA₃ and auxin of a basal control level of RNA and protein synthesis and turnover in coleoptile tissue.     

Auxin-dependent cell division and cell elongation. 1-Naphthaleneacetic acid and 2,4-dichlorophenoxyacetic acid activate different pathways

During exponential phase, the tobacco (Nicotiana tabacum) cell line cv Virginia Bright Italia-0 divides axially to produce linear cell files of distinct polarity. This axial division is controlled by exogenous auxin. We used exponential tobacco cv Virginia Bright Italia-0 cells to dissect early auxin signaling, with cell division and cell elongation as physiological markers. Experiments with 1-naphthaleneacetic acid (NAA) and 2,4-dichlorophenoxyacetic acid (2,4-D) demonstrated that these 2 auxin species affect cell division and cell elongation differentially; NAA stimulates cell elongation at concentrations that are much lower than those required to stimulate cell division. In contrast, 2,4-D promotes cell division but not cell elongation. Pertussis toxin, a blocker of heterotrimeric G-proteins, inhibits the stimulation of cell division by 2,4-D but does not affect cell elongation. Aluminum tetrafluoride, an activator of the G-proteins, can induce cell division at NAA concentrations that are not permissive for division and even in the absence of any exogenous auxin. The data are discussed in a model where the two different auxins activate two different pathways for the control of cell division and cell elongation.     

Maturation-related loss in rooting competence by loblolly pine stem cuttings: The role of auxin transport, metabolism and tissue sensitivity

A comparison of rooting ability of stem cuttings made from hypocotyls and epicotyls from 50-day-old seedlings of loblolly pine ( Pinus taeda L. ) reveals a dramatic decline by epicotyl cuttings, which do not root at all in 20–30 days in the presence or absence of auxin. In contrast, almost all the hypocotyls root during this time, but only in the presence of exogenously applied auxin. The failure of epicotyls to root does not appear to be due to differences in [¹⁴C]-labeled auxin uptake, transport, metabolism, or tissue distribution in the two types of cuttings. At the cellular level, initial responses to auxin, such as differentiation of the cambium into parenchyma, occur in both types of cuttings, but localized rapid cell division and root meristem organization are not observed in epicotyls. Autoradiography revealed that radioactivity from a -naphthalene acetic acid is bound in the cortex but not concentrated at sites of root meristem organization prior to the organization of the meristem in hypocotys. During the development of the epicotyl. cellular competence to form roots appears to be lost. Although this loss in competence is not associated with a concurrent loss in ability to transport auxin polarly, the latter process appears to play a key role in rooting other than to move auxin to the site of root formation. The phytotropin N-(1-naphthyl)phthalamic acid inhibits rooting if applied during the first 3 days after the cutting is made, but does not affect auxin concentration or metabolism at the rooting site.     

The effect of auxin starvation on the growth of auxin-dependent tobacco cell culture: dynamics of auxin-binding activity and endogenous free IAA content

The growth of a cell strain derived from the stem pith of tobacco(Nicotiana tabacum L., cv. Virginia Bright Italia) was investigatedin subcultures grown at various levels of synthetic auxins.Both partial and complete auxin starvation resulted in a decreaseof the frequency of cell division. For these treatments theendogenous free indole-3-acetic acid content increased substantiallyat the commencement of the exponential growth phase. The possibilitythat the receptivity of the cells to auxin changed during thegrowth cycle was examined by measuring the activity of a membrane-boundauxin-binding site. In subcultures grown in a medium with anoptimal auxin concentration the maximum auxin-binding activitywas restricted to the end of the exponential growth phase. Inthe cells cultivated in partially or completely auxin deprivedmedia the auxin-binding activity increased to varying extents.These results probably reflect mechanisms controlling both theintracellular content of free auxin and the sensitivity of thecells to exogenous auxin supply (including auxin binding) withrespect to the cell division and/or growth Key words: Nicotiana tabacum L., plant cell culture, IAA, auxin-binding site, cell division     

Histological responses of isolated leaves to hormones applied across a transverse gradient

The responses of petiolar tissue of isolated leaves of Argyreianervosa to hormones were investigated by maintaining a transversegradient of auxin and auxin antagonist or auxin and gibberellin.The auxin used was ß-indolylbutyric acid (IBA) andthe auxin antagonist applied was maleic hydrazide. Gibberellicacid was also applied simultaneously with IBA. The experimentwas designed in such a way that while the solution of one hormonewas applied internally to the petiole with a capillary tube,the external surface of the petiole came in contact with thesolution of the other hormone. Wounding was caused in the pith by inserting a capillary tube.The division of the parenchymatous cells bordering the woundwas greater and cell dimension was less when auxin was appliedinternally but cell division was restricted and cell dimensionincreased when the auxin antagonist was applied at high concentrations.Root primordia and vascular tissues were formed in the pithwhen the concentration of auxin in the vicinity was greater.But these processes were blocked when the concentration of theauxin antagonist was greater in the neighborhood. The effectof auxin and gibberellin was synergistic in inducing these processes. (Received May 23, 1980; )     

Histological responses of isolated leaves to hormones applied across a transverse gradient

The responses of petiolar tissue of isolated leaves of Argyreianervosa to hormones were investigated by maintaining a transversegradient of auxin and auxin antagonist or auxin and gibberellin.The auxin used was ß-indolylbutyric acid (IBA) andthe auxin antagonist applied was maleic hydrazide. Gibberellicacid was also applied simultaneously with IBA. The experimentwas designed in such a way that while the solution of one hormonewas applied internally to the petiole with a capillary tube,the external surface of the petiole came in contact with thesolution of the other hormone. Wounding was caused in the pith by inserting a capillary tube.The division of the parenchymatous cells bordering the woundwas greater and cell dimension was less when auxin was appliedinternally but cell division was restricted and cell dimensionincreased when the auxin antagonist was applied at high concentrations.Root primordia and vascular tissues were formed in the pithwhen the concentration of auxin in the vicinity was greater.But these processes were blocked when the concentration of theauxin antagonist was greater in the neighborhood. The effectof auxin and gibberellin was synergistic in inducing these processes. (Received May 23, 1980; )     

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.     

Hormone and seed-specific regulation of pea fruit growth

Growth of young pea (Pisum sativum) fruit (pericarp) requires developing seeds or, in the absence of seeds, treatment with gibberellin (GA) or auxin (4-chloroindole-3-acetic acid). This study examined the role of seeds and hormones in the regulation of cell division and elongation in early pea fruit development. Profiling histone H2A and gamma-tonoplast intrinsic protein (TIP) gene expression during early fruit development identified the relative contributions of cell division and elongation to fruit growth, whereas histological studies identified specific zones of cell division and elongation in exocarp, mesocarp, and endocarp tissues. Molecular and histological studies showed that maximal cell division was from -2 to 2 d after anthesis (DAA) and elongation from 2 to 5 DAA in pea pericarp. Maximal increase in pericarp gamma-TIP message level preceded the maximal rate of fruit growth and, in general, gamma-TIP mRNA level was useful as a qualitative marker for expanding tissue, but not as a quantitative marker for cell expansion. Seed removal resulted in rapid decreases in pericarp growth and in gamma-TIP and histone H2A message levels. In general, GA and 4-chloroindole-3-acetic acid maintained these processes in deseeded pericarp similarly to pericarps with seeds, and both hormones were required to obtain mesocarp cell sizes equivalent to intact fruit. However, GA treatment to deseeded pericarps resulted in elevated levels of gamma-TIP mRNA (6 and 7 DAA) when pericarp growth and cell enlargement were minimal. Our data support the theory that cell division and elongation are developmentally regulated during early pea fruit growth and are maintained by the hormonal interaction of GA and auxin.     

Early embryo development in Fucus distichus is auxin sensitive

Auxin and polar auxin transport have been implicated in controlling embryo development in land plants. The goal of these studies was to determine if auxin and auxin transport are also important during the earliest stages of development in embryos of the brown alga Fucus distichus. Indole-3-acetic acid (IAA) was identified in F. distichus embryos and mature tissues by gas chromatography-mass spectroscopy. F. distichus embryos accumulate [(3)H]IAA and an inhibitor of IAA efflux, naphthylphthalamic acid (NPA), elevates IAA accumulation, suggesting the presence of an auxin efflux protein complex similar to that found in land plants. F. distichus embryos normally develop with a single unbranched rhizoid, but growth on IAA leads to formation of multiple rhizoids and growth on NPA leads to formation of embryos with branched rhizoids, at concentrations that are active in auxin accumulation assays. The effects of IAA and NPA are complete before 6 h after fertilization (AF), which is before rhizoid germination and cell division. The maximal effects of IAA and NPA are between 3.5 and 5 h AF and 4 and 5.5 h AF, respectively. Although, the location of the planes of cell division was significantly altered in NPA- and IAA-treated embryos, these abnormal divisions occurred after abnormal rhizoid initiation and branching was observed. The results of this study suggest that auxin acts in the formation of apical basal patterns in F. distichus embryo development.     

Galactose inhibition of auxin-induced cell elongation in oat coleoptile segments

Auxin-induced cell elongation in oat coleoptile segments was inhibited by galactose; removal of galactose restored growth. Galactose did not appear to affect the following factors which modify cell elongation: auxin uptake, auxin metabolism, osmotic concentration of cell sap, uptake of tritium-labeled water, auxin-induced wall loosening as measured by a decrease in the minimum stress-relaxation time and auxininduced glucan degradation. Galactose markedly prevented incorporation of [¹⁴C]-glucose into cellulosic and non-cellulosic fractions of the cell wall. It was concluded that galactose inhibited auxin-induced long-term elongation of oat coleoptile segments by interfering with cell wall synthesis.     

Influence of indole-3-acetic acid on adventitious root primordia of brittle willow

Summary Removal of the stem apex and certain leaves and axillary buds of brittle willows (Salix fragilis) was employed to limit the supply of endogenous auxin to adventitious root primordia during their formation, which occurs at predetermined sites. Limiting endogenous auxin by this surgical treatment resulted in reduced primordium initiation and, to a lesser degree, primordium growth in cell number. Root primordium cells in surgically treated plants differentiated into mature parenchyma after losing their meristematic character. Application of indole-3-acetic acid (IAA) to surgically treated plants partially overcame the effects of the surgical tretament, increasing root primordium initiation and growth by cell division. When IAA-2-¹⁴C was applied to surgically treated plants, label was detected in root primordium cells by means of autoradiography. Root primordium cells took up more label during the earliest stage of initiation than during a later stage of growth. The data indicate that the initiation of these primordia is more dependent on a supply of auxin than is their subsequent development. Further, the auxin apparently acts directly in the cells which initiate primordia.This investigation was supported in part by Public Health Service Research Grant No. UI 00110-07 (now 5R01 FD 00074-09) from the National Center for Urban and Industrial Health. Paper No. 7138, Min nesota Agricultural Experiment Station.     

Hexose uptake and control of fibroblast proliferation

The role of glucose uptake in control of cell growth was studied by experimentally varying the rate of glucose uptake and examining the subsequent effect on initiation and cessation of cell proliferation. The rate of glucose uptake was varied by adjusting the concentration of glucose in the culture medium. This permitted analysis of two changes in rate of glucose uptake which are closely related to the regulation of cell growth: (1) the rapid increase in glucose uptake that can be detected within several minutes after mitogenic stimulation of quiescent fibroblasts and (2) the decrease in glucose uptake which accompanies growth to a quiescent state. Quiescent cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to fresh serum-containing medium with either the normal amount of glucose or a reduced level that lowered the rate of glucose uptake below the rate characteristic of quiescent control cells. The subsequent increases in cell number were equal in both media, demonstrating that the increase in glucose uptake, commonly observed after mitogenic stimulation, was not necessary for initiation of cell division. Measurements of intracellular D-glucose pools after serum stimulation of quiescent cells revealed that the increase in glucose uptake was not accompanied by a detectable change in the intracellular concentration of glucose. Nonconfluent growing cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to low glucose media, lowering the rate of glucose uptake below levels observed for quiescent cells. This did not affect rates of DNA synthesis or cell division over a several-day period. Thus, the decrease in glucose uptake, which usually occurs at about the same time as the decrease in DNA synthesis as cells grow to quiescence, does not cause the decline in cell proliferation. Experiments indicated that there was no set temporal relationship between the decline in glucose uptake and DNA synthesis as cells grew to quiescence. The sequence was variable and probably depended on the cell type as well as culture conditions. Measurements of intracellular D-glucose pools in secondary chick embryo cells demonstrated that the internal concentration of glucose in these cells did not significantly vary during growth to quiescence. Taken together, our results show that these fluctuations in the rate of glucose uptake do not lead to detectable changes in the intracellular concentration of glucose and that they do not control cell proliferation rates under usual culture conditions.     

EFFECT OF COPPER ON GROWTH,SILICIC ACID UPTAKE AND SOLUBLE POOLS OF SILICIC ACID IN THE MARINE DIATOM,THALASSIOSIRA WEISFLOGII (BACILLARIOPHYCEAE)1

The toxicity of Cu to Thalassiosira weissflogii (Grunow) was investigated, focusing on the internal soluble pool of silicic acid. Silicic acid uptake and growth rates were found to be functions of both the cupric ion activity and the concentration of silicic acid in the growth medium. The soluble pool of Si per cell depended on the balance between the uptake rate and the division rate. The soluble pool in non-dividing cultures reflected simply the uptake rate (and inhibition by copper of the uptake rate), but in dividing cultures the soluble pools had complex patterns with time depending on uptake rates and timing of division. Intracellular soluble pools of silicic acid are a good indicator for the relative inhibition of uptake and growth processes.     

Auxin-Induced Expansion Growth of Cells and Protoplasts of Yeast

Using an auxin-responsive mutant of Sacchairomyces ellipsodeus, expansion growth of cells caused by auxin was studied especially in comparison with that of protoplasts.

• 1 Indole-3-acetic acid induced detectable cell expansion growth in 3 hours in a buffered simple solution where no cell division occurred.
• 2 The auxin-induced expansion growth was inhibited by an antiauxin, trans-cinnamic acid.
• 3 Actinomycin D, chloramphenicol and cycloheximide inhibited the auxin-induced cell expansion growth.
• 4 Protoplasts did not expand in response to auxin under the condition where intact cells did.
• 5 The stability of protoplasts was not changed by the low auxin concentration (20 mg/1) which induced cell expansion.
• 6 High concentrations (100–1000 mg/1) of auxin caused protoplasts to burst even under an osmotically stable condition.

     

Investigations on the Mechanism of the Brassinosteroid Response: I. Indole-3-acetic Acid Metabolism and Transport

A brassinosteroid treatment of light-grown first internode sections of Phaseolus vulgaris results in an increased bending response following unilateral indole-3-acetic acid (IAA) application. Reverse isotope dilution analysis shows that this increased response is not due to an increase in the concentration of applied IAA in the tissue or a change in the amount of IAA conjugated. Treatment with the brassinosteroid also does not affect the rate of IAA transport as measured using the agar block method. These results indicate that even though brassinosteroid potentiates auxin action, it does not have a direct effect on IAA uptake, metabolism, or cell to cell transport.     

The influence of growth regulating substances on the development of enhanced metabolic rates in thin slices of beetroot storage tissue

Freshly cut disks of beetroot tissue develop high rates of respiration, uptake of phosphate and activity of the enzyme invertase after having been washed for 18 hours in 0.01 m potassium maleate.Incubation of the disks in solutions of indole-3-acetic acid or kinetin completely prevented the development of the higher activities in all 3 systems assayed, while incubation in gibberellic acid had no inhibitory effect. Using a series of synthetic plant growth regulating compounds it was possible to establish that there was no correlation between the activity of the compound as an auxin and the ability of the compound to prevent the development of the enhanced rates of metabolism.     

An Auxin Gradient and Maximum in the Arabidopsis Root Apex Shown by High-Resolution Cell-Specific Analysis of IAA Distribution and Synthesis

Local concentration gradients of the plant growth regulator auxin (indole-3-acetic acid [IAA]) are thought to instruct the positioning of organ primordia and stem cell niches and to direct cell division, expansion, and differentiation. High-resolution measurements of endogenous IAA concentrations in support of the gradient hypothesis are required to substantiate this hypothesis. Here, we introduce fluorescence-activated cell sorting of green fluorescent protein–marked cell types combined with highly sensitive mass spectrometry methods as a novel means for analyses of IAA distribution and metabolism at cellular resolution. Our results reveal the presence of IAA concentration gradients within the Arabidopsis thaliana root tip with a distinct maximum in the organizing quiescent center of the root apex. We also demonstrate that the root apex provides an important source of IAA and that cells of all types display a high synthesis capacity, suggesting a substantial contribution of local biosynthesis to auxin homeostasis in the root tip. Our results indicate that local biosynthesis and polar transport combine to produce auxin gradients and maxima in the root tip.