THE EFFECT OF AUXINS ON PROTOPLASMIC STREAMING. II

1. A further study has been made of the effect of indole-3-acetic acid (auxin) on protoplasmic streaming in the epidermal cells of the Avena coleoptile. 2. The transient nature of the effect of auxin, both in accelerating and retarding streaming, is due to the temporary exhaustion of carbohydrate from the tissues. In presence of 1 per cent fructose or some other sugars the acceleration or retardation of streaming by auxin is not transient, but is maintained for at least 2 hours. 3. The retardation of streaming brought about by concentrations of auxin above 0.5 mg. per liter is due to oxygen deficiency This has been confirmed in several ways. 4. It follows that the effect of auxin is to increase the respiration of the coleoptile tissue. 5. Younger coleoptiles, 3 cm. long, are sensitive to lower concentrations of auxin than those 5 cm. long, and more readily exhibit oxygen deficiency as a result of the action of auxin. However, after decapitation their response to auxin more closely resembles that of 5 cm. coleoptiles. 6. The retardation of streaming in such coleoptiles, resulting from oxygen deficiency, is delayed by very dilute solutions of histidine. On this basis an explanation is suggested for the results of Fitting on streaming in Vallisneria leaves. 7. The mean rate of streaming in control untreated coleoptiles in pure water varies with the time of year, but not with the time of day. 8. The results support the view that auxin accelerates an oxygen-consuming process which controls the rate of protoplasmic streaming, and that the latter controls growth. The substrate for this process is probably sugar. 9. It is suggested that auxin also accelerates another oxygen-consuming process, which may withdraw oxygen from the process which controls streaming rate and hence cause retardation of the latter.     

THE EFFECT OF AUXINS ON PROTOPLASMIC STREAMING. III

1. A new method is described which gives a continuous record of the absolute rate of protoplasmic streaming in epidermal cells of the Avena coleoptile. 2. With this method a study was made of the influence of malate and iodoacetate on streaming velocity, in order to make correlations with the previously established effects of these substances on growth and respiration. 3. In the presence of optimum concentrations of indole-3-acetic acid in freshly cut sections, malate had no effect on streaming. In the presence of very low concentrations of the auxin, however, malate increased the range of response, so that the threshold of auxin sensitivity was lowered some ten times by the malate. Malate alone had no effect on streaming. 4. In coleoptile sections, soaked overnight in sugar solution or in water, the acceleration of streaming normally caused by auxin almost disappears, but the presence of malate causes large accelerations of streaming by the auxin. 5. Similarly, in sections from old coleoptiles, which no longer show acceleration of streaming by auxin, the acceleration is restored when malate is added together with the auxin. 6. Malate does not enter the cell as rapidly as does auxin, but easily detectable amounts penetrate within 30 minutes. 7. Iodoacetate in the concentration which inhibits growth (5 x 10^–5 M) completely inhibits the acceleration of streaming by auxin. In still lower concentrations iodoacetate slightly accelerates streaming. Higher concentrations, up to 2 x 10^–4 M, did not reduce the rate of streaming below that of controls without auxin. The effect of iodoacetate is therefore to inhibit the acceleration caused by auxin and not to affect the basal streaming rate. 8. It is concluded that, just as for growth and respiration, malate is necessary for the response to auxin shown by acceleration of streaming. This further strengthens the triple parallel between the effects of auxin on streaming, growth, and respiration, all of which are apparently mediated by the 4-carbon acid system.     

A DESEEDED AVENA TEST METHOD FOR SMALL AMOUNTS OF AUXIN AND AUXIN PRECURSORS

The main results presented in this article may be summarized as follows: 1. A test method with deseeded Avena seedlings for small concentrations of auxin and precursors of auxin has been described. 2. This method makes possible quantitative determinations of about ten times as low concentrations of hormone as can be obtained with the standard method, (a) Through an increase in the time of the test, so that nearly all the hormone applied can be utilized. (b) Through an increase in sensitivity of deseeded plants to unilaterally applied small concentrations of hormone. 3. The effect of deseeding in relation to curvature growth is primarily the prevention of auxin regeneration through the removal of the material for auxin synthesis, and in addition the prevention of physiological aging. 4. The mechanism of auxin synthesis in the tip of the coleoptile and the mechanism of auxin regeneration in the new physiological tip have been shown to be identical. 5. The application of the deseeded method is illustrated by determinations of auxin in primary leaves and coleoptile sections of Avena seedlings. 6. The deseeded method has been used as a test method for precursors of auxin obtainable from the coleoptile and from other sources. The method further makes possible a distinction between auxins and these substances which may become activated by the plant. 7. Evidence for the existence of a precursor of auxin in the plant is given (a) indirectly by determinations of the decrease in auxin synthesis in deseeded plants. (b) Directly by its isolation from the plant. 8. Precursors of hetero-auxin are demonstrated; their chemical nature and activation are briefly considered.     

Hormonal Relations in the Phototropic Response IV. Light-Induced Changes of Endogenous Auxins in the Coleoptile

Beside indoleacetic acid (IAA), 3 auxins were found by chromatographic resolution of acidic fractions of Avena and Zea coleoptile tips. One of these auxins, designated P, occurred at levels of activity approaching those of IAA. The other 2 auxins, termed F and M, occurred at lower levels of activity. When the auxins of the excised coleoptile tips were isolated immediately after equilateral or unilateral irradiation with blue light at first positive energies, the ratio of IAA to the other auxins increases. This rise is the result of a decrease in P and F, and probably an increase in IAA. Light did not affect materially the total auxin content. It is suggested that P and F might be associated with the basipetal transport inequalities of IAA in phototropism.

P has been partially characterized. Its R_F on chromatograms developed in ammoniacal isopropanol is about 0.65. It is converted to IAA in vitro by heat. The ultraviolet absorption spectrum of chromatographically resolved P also suggests an indolyl complex. P is not readily transported basipetally, and the slope of its relative concentration-response curve (Avena section test) is lower than that of IAA. P does not appear to be any of the chemically characterized native auxins.

     

Substituted Indoleacetic Acids Tested in Tissue Cultures

Monochloro substituted indole-3-acetic acids inhibited shoot induction in tobacco tissue cultures about as much as IAA. Dichloro substituted indole-3-acetic acids inhibited shoot formation less. Other substituted indoleacetic acids except 5-fluoro- and 5-bromoindole-3-acetic acid were less active than IAA. Callus growth was quite variable and not correlated with auxin strength measured in the Avena coleoptile test.     

Mechanism of specific inhibition of phototropism by phenylacetic Acid in corn seedling

Using geotropism as a control for phototropism, compounds similar to phenylacetic acid that photoreact with flavins and/or have auxin-like activity were examined for their ability to specifically inhibit phototropism in corn seedlings using geotropism as a control. Results using indole-3-acetic acid, napthalene-1-acetic acid, naphthalene-2-acetic acid, phenylacetic acid, and β-phenylpyruvic acid suggest that such compounds will specifically inhibit phototropism primarily because of their photoreactivity with flavins and not their auxin activity. For example, strong auxins, indole-3-acetic acid and naphthalene-1-acetic acid, affected both tropic responses at all concentrations tested whereas weak auxins, phenylacetic acid and naphthalene-2-acetic acid, exhibited specific inhibition. In addition, the in vivo concentration of phenylacetic acid required to induce specificity was well below that required to stimulate coleoptile growth. Estimates of the percentage of photoreceptor pigment inactivated by phenylacetic acid (>10%) suggest that phenylacetic acid could be used to photoaffinity label the flavoprotein involved in corn seedling phototropism.     

EFFECT OF AUXIN AND OXALIC ACID ON THE CELL WALL PROPERTY OF AVENA COLEOPTILE

In accelerating the elongation of excised Avena coleoptile cylinders,the effect of oxalic acid was found to be additive to that ofindole-3-acetic acid. Elastic and plastic extensions of the coleoptile cylinder weremeasured by using the plasmolytic method. Both indole-3-aceticacid and oxalic acid increased the elastic extension quickly,while their effect in increasing the plastic extension appeared2 hours after their application. The mechanism of auxin action is discussed in connection withthe effect of removal of calcium from the pectic substance ofthe primary cell wall. (Received November 15, 1960; )     

Studies on the Geotropism of Roots: III. EFFECTS OF GEOTROPIC STIMULATION ON GROWTH-SUBSTANCE CONCENTRATIONS IN VICIA FABA ROOT TIPS

The auxins contained in 5-mm. tips of horizontal Vicia fabaroots have been compared with those in tips of vertical rootsafter cold ethanol extraction, paper-chromatographic separation,and Avena mesocotyl bioassay. At about the time curvature commencesin horizontal roots there is a marked increase in the contentof an auxin corresponding to ‘AP(ii)’ of pea roots(Rf 0.35–0.65 in isobutanol/methanol/water). There areindications that this is not due to its release from an inactivebound state but that it is either synthesized de novo or maybe converted from another auxin corresponding to ‘AP(iii)’of pea roots (Rf 0.75–1.0). The literature dealing with the auxins of geotropically stimulatedorgans is reassessed and it is concluded that, with the exceptionof the Avena coleoptile, there is very little evidence favouringa simple transport redistribution of auxin under gravity; themajority of the data favour an effect of gravity on auxin metabolism.     

Revision of the theory of phototropism in plants: a new interpretation of a classical experiment

Went's classical experiment on the diffusion of auxin activity from unilaterally illuminated oat coleoptile tips (Went 1928), was repeated as precisely as possible. In agreement with Went's data with theAvena curvature assay, the agar blocks from the illuminated side of oat (Avena sativa L. cv. Victory) coleoptile tips had, on an average, 38% of the auxin activity of those from the shaded side. However, determination of the absolute amounts of indole-3-acetic acid (IAA) in the agar blocks, using a physicochemical assay following purification, showed that the IAA was evenly distributed in the blocks from the illuminated and shaded sides. In the blocks from the shaded and dark-control halves the amounts of IAA were 2.5 times higher than the auxin activity measured by theAvena curvature test, and in those from the illuminated half even 7 times higher. Chromatography of the diffusates prior to theAvena curvature test demonstrated that the amounts of two growth inhibitors, especially of the more polar one, were significantly higher in the agar blocks from the illuminated side than in those from the shaded side and the dark control. These results show that the basic experiment from which the Cholodny-Went theory was derived, does not justify this theory. The data rather indicate that phototropism is caused by the light-induced, local accumulation of growth inhibitors against a background of even auxin distribution, the diffusion of auxin being unaffected.Abbreviation IAA indole-3-acetic acid     

Investigations on the Nature of the Auxin-Wave in the Cambial Region of Pine Stems : Validation of IAA as the Auxin Component by the Avena Coleoptile Curvature Assay and by Gas Chromatography-Mass Spectrometry-Selected Ion Monitoring

The major auxin of Scots pine (Pinus silvestris L.) which is transported basipetally into agar strips from the cambial region of the stem was quantified by the Went Avena coleoptile curvature assay before and after reversed phase C₁₈ high performance liquid chromatography (HPLC), and then identified by full spectrum gas chromatography-mass spectrometry (GC-MS) as indole-3-acetic acid (IAA). The IAA was subsequently quantified by GC-MS-selected ion monitoring (SIM) using an internal standard of [¹³C]-(C₆)-IAA. The amount of IAA collected into 22-millimeter long agar strips during 10 minutes of contact with the stem cambial region was estimated by GC-MS-SIM and the Went bioassay to be 2.3 and 2.1 nanograms per strip, respectively. The GC-MS technique thus confirmed the results obtained by the Went curvature assay. The Avena curvature assay revealed the presence of at least one other, more polar (based on HPLC retention time) auxin that diffused into the agar strips with the IAA. Its bioactivity was only 5% of the IAA fraction. Its HPLC retention time was earlier than IAA-glucoside, IAA-aspartate, or IAA-glycine, but the same as IAA-inositol. No significant amounts of inhibitors or synergists of IAA activity on the Avena assay were found in extracts corresponding to one or five strips of agar. Thus, the direct bioassay of the agar strips immediately after their removal from the cambial region of P. silvestris stem sections reflects the concentration of the native IAA. For both P. silvestris and lodgepole pine (Pinus contorta) a wavelike pattern of auxin stimulation of Avena curvature was found in agar strips exposed for only 10 minutes to the basal ends of an axial series of 6-millimeter long sections from the cambial region of the stem. This wavelike pattern was subsequently confirmed for P. contorta both by Avena curvature assay and by GC-MS-SIM of HPLC fractions at the retention time of [³H]IAA. The wavelike pattern of auxin diffusing from the cambial region of Pinus has thus been determined to consist primarily of IAA and this pattern has now been quantitated using both the Went Avena curvature assay and GC-MS-SIM with [¹³C]-C₆-IAA as an internal standard.     

Selective effects of victorin on growth and the auxin response in Avena

Victorin, the pathotoxin from the host-specific pathogen, Helminthosporium victoriae, promotes the growth of coleoptile segments when given at concentrations that are high but which still show selective effects on susceptible and resistant tissue. The latent period in the growth response of both susceptible and resistant tissue is about 3.6 minutes compared to 11.0 minutes in the response of these tissues to auxin. The victorinpromoted rate of elongation of 8-millimeter segments is about 0.2 millimeter per hour in susceptible tissue and about 0.1 millimeter per hour in resistant tissue compared to about 0.4 millimeter per hour in response to auxin. At low concentrations, the toxin has no growth-promoting effect in either susceptible or resistant coleoptile segments. Over a wide range of concentrations, victorin inhibits the growth response of susceptible tissue to auxin completely while having no effect on the response of resistant tissue to auxin.     

Photobiology of phytochrome-mediated growth responses in sections of stem tissue from etiolated oats and corn

The far-red reversibility of the phytochrome-controlled stimulation of elongation of coleoptile sections by low fluence red light has been characterized in subapical coleoptile sections from dark-grown Avena sativa L., cv Lodi seedlings. The fluence dependence of the far-red reversal was the same whether or not the very low fluence response is also expressed. The capacity of far-red light to reverse the red light-induced response began to decline if the far-red light was given more than 90 minutes after the red irradiation. Escape was complete if the far red irradiation was given more than 240 minutes after the red irradiation. Sections consisting of both mesocotyl and coleoptile tissue from dark-grown Avena seedlings were found to have physiological regulation of the very low fluence response by indole 3-acetic acid and low external pH similar to that seen for sections consisting entirely of coleoptile tissue. The fluence-dependence of the red light-induced inhibition of mesocotyl elongation was studied in mesocotyl sections from dark grown Zea mays L. hybrid T-929 seedlings. Ten micromolar indole 3-acetic acid stimulates the control elongation of the sections, while at the same time increasing the sensitivity of the tissue for the light-induced inhibition of growth by a factor of 100.     

Auxin Transport in Zea mays Coleoptiles II. Influence of Light on the Transport of Indoleacetic Acid-2-C

The effect of bilateral irradiation with white light (1000 Meter Candle Sec) on the basipetal transport of auxin has been investigated. Illumination of either the intact shoot or the excised coleoptile tip of the Zea seedling, decreased the amount of diffusible auxin obtained from the tip, and decreased Avena curvature response to unilaterally applied indoleacetic acid. Irradiation of the intact Zea seedling did not affect the absorption of ¹⁴C-labeled indoleacetic acid from an agar block subsequently placed on the decapitated coleoptile. However, light caused a significant decrease in the amount of labeled auxin basipetally transported, without affecting materially the velocity of that transport. These and other observations are interpreted as support for the hypothesis that the primary hormonal phenomenon in first-positive phototropism is a light-induced impairment in the basipetal transport of auxin.     

Polar auxin transport and auxin-induced elongation in the absence of cytoplasmic streaming

Summary When cytoplasmie streaming in oat and maize coleoptile cells is completely inhibited by cytochalasin B (CB), polar transport of auxin (indole-3-acetic acid) continues at a slightly reduced rate. Therefore, cytoplasmic streaming is not required for polar transport. Auxin induces elongation in CB-inhibited coleoptile and pea stem segments, but elongation rate is reduced about 40% by CB. Therefore, stimulation of cytoplasmic streaming cannot be the means by which auxin promotes cell elongation, but streaming may be beneficial to elongation growth although not essential to it. A more severe inhibition of elongation develops after several hours in CB. With coleoptiles this could be due to inhibition of sugar uptake; in pea tissue it may be due to permeability changes and cytoplasmic degeneration. CB does not disorganize or disorient microfilament bundles when it inhibits streaming in maize, but appears instead to cause hypercondensation of microfilament material.     

EFFECT OF YEAST SEXUAL HORMONES ON ELONGATION OF AVENA COLEOPTILE

Effect of yeast (Saccharomyces cerevisiae) sexual hormones on the elongation of etiolated Avena coleoptile segments was studied. The elongation was promoted by a hormone excreted by cells of mating type a, but not by α hormone excreted by cells of α type. The effect of the former was as great as that of 5 mg/1 indole-3-acetic acid in the first hour of application. The optimal concentration of a hormone was 10 units/ml. Its growth promoting effect was greatly inhibited by an antiauxin, 2,4,6-trichlorophenoxyacetic acid. a Hormone increased cell wall extensibility just as auxin does. Testosterone, β-estradiol, progesterone and ergosterol showed very little effect on the elongation of coleoptile segments.     

New methods to analyse auxin-induced growth II: The swelling reaction of protoplasts – a model system for the analysis of auxin signal transduction?

A method for monitoring the time course of auxin-induced volume changesby protoplasts at a high temporal resolution was developed for Zeamays coleoptile protoplasts. Auxins, like indole-3-acetic acid(IAA), induce a rapid change in volume. Immediately after addition ofthis auxin, a transient shrinkage was observed, followed by a long-termswelling response. This reaction occurred in the same time window as thetypical auxin growth response of intact coleoptiles. Active auxins, like1-naphthalene acetic acid (1-NAA) and 4-chloroindole-3-acetic acid(4-Cl-IAA), caused similar volume changes, whereas the inactive analogue2-naphthalene acetic acid (2-NAA) had no effect. The phytotoxinfusicoccin (FC) induced a rapid swelling response. We conclude that thissingle cell system is very adequate to analyse mechanisms of auxinsignal transduction.     

Organogenesis in leafy spurge (Euphorbia esula L.)

Summary All parts of leafy spurge seedlings can be regenerated when isolated and placed onto B5 medium. One-centimeter isolated hypocotyl segments were tested successfully for their usefulness as a bioassay system by comparing the response of auxins, herbicides, and cytokinins. Indole-3-acetic acid (IAA) was the most effective auxin to stimulate root formation. IAA was effective whether the hypocotyl segments remained on the same medium up to 60 days, or the segments were transferred to basal media after 2 or 5 days (pulse treatment). Pulse treatments with the other auxins resulted in stimulation of root formation; continuous or 5-day pulses of higher concentrations of indole-3-butyric acid,α-naphthaleneacetic acid and especially 2,4-dichlorophenoxyacetic acid and picloram formed excessive callus instead of roots. Picloram did not stimulate root formation, whether the treatment was continuous or pulse-treated. No roots formed with continuous picloram at 0.1 mg/liter or greater, but transfer to basal media did result in root and shoot formation at about 50% of the number formed on the controls. Lesser picloram concentrations had no effect. Shoots formed readily on untreated (control) segments, but continuous treatment with all three cytokinins, kinetin, zeatin, and zeatin riboside, increased the numbers of shoots about equally. Root formation was inhibited by the cytokinins at the higher concentrations (0.1 to 0.2 mg/liter). With the exception of a 5-day pulse of 0.04 mg/liter IAA, the auxins did not stimulate shoot formation, but generally inhibited shoot formation, even in pulse-treated cultures.     

Auxin-induced hydrogen-ion secretion in Avena coleoptiles and its implications

Summary The dose response curve for hydrogen-ion-induced extension growth in Avena coleoptile segments has been reinvestigated. The previously published optimum (pH 3.0) is in error by about two orders of magnitude. The correct optimum is around pH 5.0. This discrepancy is thought to be due to the impermeable nature of the cuticle to hydrogen ions. In the present study the cuticular barrier to H⁺ entry was circumvented by using coleoptile segments from which the epidermis with cuticle were physically removed. Using such peeled coleoptile sections, it was also found that auxin can rapidly (20–30 min) initiate H⁺ secretion and that the magnitude of auxin-induced secretion is sufficient to initiate considerable cell-extension growth. Furthermore, it is shown that the secretion response is specific for active auxins, and inhibited by agents which inhibit auxin-induced growth (dinitrophenol, abscisic acid, cycloheximide, valinomycin and others). These results make it very likely that H⁺ secretion is responsible, at least in part, for the initiation of auxin-induced cell wall loosening and extension growth.     

Effects of Mechanical Stimulation on Avena Coleoptile Segment Elongation in a High Resolution, Continuous Growth-recording System

The effects of an abrasive mechanical stimulation of the inner epidermal surfaces of excised Avena coleoptile segments were examined in relation to growth in the presence and absence of exogenously supplied indole-3-acetic acid. Mechanical stimulation of this nature, provided immediately following excision, was found to elicit a small, transient increase in endogenous growth rate which contributed to a larger initial rapid growth response (previously referred to as a tactile response). These results, contrary to the earlier reports, suggest that the inner epidermal mechanical or tactile stimulation does not account for the entire initial rapid growth response. Preliminary experiments indicate that an alternative form of mechanical stimulation (segment excision) may contribute to that portion of initial rapid growth which is not attributable to inner epidermal abrasion.

Following its initial growth-enhancing effect, inner epidermal stimulation had either no effect or in some cases appeared inhibitory to endogenous growth. Growth in response to exogenous auxin was appreciably inhibited by this form of mechanical stimulation.

     

Studies on growth regulators. I. Improved Avena coleoptile elongation test for auxin

A modified procedure is presented for the bioassay of auxin using Avena coleoptile segments. The modifications introduced result in a substantial improvement of the commonly used coleoptile elongation tests.