PHYTOCHROME CONTROLLED NYCTINASTY IN ALBIZZIA JULIBRISSIN. II. POTASSIUM FLUX AS A BASIS FOR LEAFLET MOVEMENT

Excised Albizzia leaflet pairs exposed to red (R) light close within 30–90 min after transfer to darkness. Interruption of darkness by far-red (FR) light at any time after R inhibits closure within ca. 10 min. Similarly, irradiation with R at any time after prior FR promotes closure within ca. 10 min, and the increased rate of closure is independent of the time lapse between the FR and R irradiations. Closure in the dark is inhibited by NaN₃ and DNP (5 X 10^–4 m ), by anaerobic conditions and by externally applied salts of monovalent cations, especially K; it is also temperature sensitive. Pulvinule cells are very high in K. Electron microprobe analysis of cryostated, lyophilized pulvinules reveals that during closure, K is lost from ventral cells and enters dorsal cells. FR before darkness inhibits the former but not the latter process. Thus, K flux appears to control the changes in volume of the pulvinule cells that control leaflet movement. While leaflet closure normally requires a dark period, salts of organic acids such as sodium acetate, propionate, and butyrate cause closure in the light.     

Chronobiology of Aging in Albizzia julibrissin: I. An Automated, Computerized System for Monitoring Leaflet Movement; The Rhythm in Constant Darkness

We are using leaflet movements in Albizzia julibrissin as a model system for investigating the chronobiology of aging. To monitor leaflet movements during long dark periods with adequate temporal and spatial resolution, we designed an automated, computerized photoelectric monitoring system. Each of 12 leaflet pairs was positioned in an individual light-proof container, with one leaflet immobilized. The angle of the mobile leaflet was monitored by a photosensor array using a low intensity infrared beam. Leaflet position was determined by custom-developed software, using information on the shading patterns of the sensors. Data on leaflet angle as a function of time were collected and stored on a floppy disc and then printed in numerical and graphical form.

Oscillations of young, middle-aged, and old leaflets persist during 7 d of darkness with a periodicity close to 24 h. Period length appears to be age-independent, but rhythmic wave form is age-dependent. The older the leaflet, the earlier and more completely it opens and the less completely it closes.

     

SUMMATION OF DISSIMILAR STIMULI APPLIED TO LEAFLETS OF SENSITIVE BRIER (SCHRANKIA)

1. The pinnæ of sensitive brier or Schrankia are favorable for demonstrating summation of dissimilar stimuli. 2. The demonstration was made as follows: A time of day was chosen when the closure of a single proximal leaflet did not provoke closure of the next distal leaflet. An irritating gas was applied to the pinna. A few seconds later, a single leaflet was touched; it closed, induced closure of the next distal leaflet, and inaugurated a wave of closure which proceeded until all leaflets on the same side of the mid-rib were closed.     

Endogenous Levels and Transport of 1-Aminocyclopropane-1-Carboxylic Acid in Stamens of Ipomoea nil (Convolvulaceae)

Filament and corolla growth in flowers of Ipomoea nil are inhibited by ethylene production. Anthers inhibited filament growth in vitro during younger stages of development even in the presence of the growth promoter gibberellic acid (GA₃). To test whether the anthers could be sources of 1-aminocyclopropane-1-carboxylic acid (ACC) endogenous levels of ACC and ethylene production were monitored using gas chromatography. To also test whether the filaments could be transport vectors for ACC the movement of [¹⁴C]ACC was assessed by scintillation counting from donor agarose blocks, through filament sections, and into receiver agarose blocks. While ACC levels fluctuated in anthers 87 to 21 h before anthesis, anthers contained increased levels of ACC from 15 to 6 hours before anthesis. Ethylene production also fluctuated but peak levels were shifted about 6 hours closer to anthesis than ACC levels within the anthers. Both ACC and ethylene levels in filaments showed fluctuations similar to those in the anthers. [¹⁴C]ACC movement became increasingly basipetal during development. Older stages showed greater polar [¹⁴C]ACC efflux rates, while all stages showed constant polar influx rates. Low levels of endogenous ACC were transported basipetally from the anther through the filament into agarose blocks at all stages of development. Corresponding levels of endogenous ethylene production remained constant between the various stages during ACC transport. We have evidence that stamens of I. nil have a role as source tissues and transport vectors for ACC, to stimulate corolla growth, such as corolla unfolding and senescence.     

Phytochrome Control of Nyetinasty in Samanea as Modified by Oxgen, Submergence, and Chemicals

Samanea saman has rapid phytochrome-regulated nyctinasty: red light preceding darkness causes pinnules to close while far-rod light allows opening- Not only the initial angle of the pinnules, but the degree of control by phytochrome depends on the “subjective time of day” at which the tissue is exposed. Excised pairs of pinnules close rapidly when submerged in water; such closure is prevented by bubbling oxygen through the water. However, if submergence closure were due solely to low oxygen levels, then nonsubmerged pinnules in a pure nitrogen atmosphere should also close. Instead, they neither close nor respond to light, but they do respond when air is readmitted, indicating that oxygen is necessary for movement rather than for photoreception. The closure of submerged pinnules remains unexplained. Attempts to detect effects of red or far-red on oxygen uptake by pulvinus tissue were unsuccessful. The following method has been used to test the effects of various inhibitors and other substances: pinnules are excised at the first hour of the day, trimmed, submerged in a sealed chamber, given far-red light, and left in darkness while oxygen is bubbled through the medium. Concentrated test solutions are injected either initially or when the red and far-red exposures are given. Thus far, the substances tested have had little or no effect on the phytochrome response.     

A circadian rhythm in oxygen uptake by samanea pulvini

The rate of O₂ uptake by excised Samanea pulvini oscillates with a circadian rhythm during 52 hours of darkness. Rates of respiration increase during pulvinar opening and decrease prior to and during closure, consistent with the concept that opening requires a greater expenditure of energy. Externally supplied sucrose, necessary for perpetuation of the leaflet movement rhythm, has a small promotive effect on the rate of respiration.     

Effect of vanadate on rhythmic leaflet movement in albizzia julibrissin

Vanadate (Na₃VO₄) selectively and reversibly affects the rhythmic movement of Albizzia julibrissin leaflets. Leaflets floated on 1 millimolar vanadate open at the same rate or more rapidly than controls, but closure is inhibited. After 6 to 24 hours incubation, the inhibition can be reversed by a 24-to 48-hour period on water or control buffer. Recovery is complete in light-dark cycles, and it is almost complete under free-running conditions (prolonged darkness). Leaflets floated on 10 millimolar vanadate do not open in darkness, but they open at a reduced rate in light. Concentrations of 100 micromolar or less are ineffective.     

The effect of light and phytochrome on 1-aminocyclopropane-1-carboxylic Acid metabolism in etiolated wheat seedling leaves

While light-grown wheat leaves produced ethylene at a low rate of <0.1 nanomoles per gram per hour and contained 1-aminocyclopropane-1-carboxylic acid (ACC) at low levels of <2.5 nanomoles per gram, etiolated wheat leaves produced ethylene at a rate of 2 nanomoles per gram per hour and accumulated concentrations of ACC at levels of 40 nanomoles per gram. Upon illumination of 8-day-old etiolated wheat seedlings with white light, the ethylene production rate increased initially, due to the activation of ethylene-forming activity, but subsequently declined to a low level (0.1 nanomoles per gram per hour) at the end of the 6-hour illumination. This light-induced decline in ethylene production rate resulted from a decline (more than 35 nanomoles per gram) in ACC level, which was accompanied by a corresponding increase in 1-(malonylamino)cyclopropane-1-carboxylic acid content. These data indicate that illumination promoted ACC malonylation, resulting in reduced ACC level and consequently reduced ethylene production. However, light did not cause any significant increase in the extractable ACC-malonyltransferase activity. The effect of continuous white light on promotion of ACC malonylation was also observed in intermittent white light or red light. A far-red light treatment following red light partially reversed the red light effect, indicating that phytochrome participates in the promotion of ACC malonylation.     

Potassium Flux and Leaf Movement in Samanea saman : II. Phytochrome Controlled Movement

Phytochrome, a membrane-localized biliprotein whose conformation is shifted reversibly by brief red or far-red light treatments, interacts with the rhythmic oscillator to regulate leaflet movement and potassium flux in pulvinal motor cells of Samanea. Darkened pinnae exposed briefly to red light (high P_fr level) have less potassium in motor cells in the extensor region, more potassium in motor cells in the flexor region, and smaller angles than those exposed to far-red light (low P_fr level). Increase in temperature from 24° to 37° increases the differential effect of the light treatments during opening (the energetic phase) but not during closure, implying that phytochrome controls an energetic process. It seems likely that phytochrome interacts with rhythmically controlled potassium pumps in flexor and extensor cells. During nyctinastic closure of white-illuminated pinnae, exposure to far-red light before darkening results in larger angles than does exposure to red. As in rhythmic opening, the angles of all pinnae and the differential effect of the light treatments increases with increasing temperature.     

Accumulation of 1-(malonylamino)cyclopropane-1-carboxylic acid in ethylene-synthesizing tobacco leaves

During the hypersensitive reaction of Samsun NN tobacco to tobacco mosaic virus (TMV) the inoculated leaves synthesize large quantities of ethylene. At the same time, 1-(malonylamino)cyclopropane-1-carboxylic acid (MACC), a conjugate of the ethylene precursor 1-aminocyclopropane-1-carboxylic acid (ACC) accumulates. Smaller amounts of MACC are formed concomitant with ethylene synthesis during the normal development of tobacco leaves. The conjugate appears neither to be hydrolysed to liberate ACC, nor to be transported to other plant parts. Its accumulation thus reflects the history of the operation of the pathway of ethylene synthesis in the leaf. In floating leaf discs exogenously applied ACC was converted only slowly to both ethylene and MACC. More ethylene and less MACC were produced in darkness than in light, suggesting that environmental conditions may influence the ratio at which ACC in converted to either ethylene or MACC.     

Stimulation of lettuce seed germination by ethylene

Ethylene increased the germination of freshly imbibed lettuce (Lactuca sativa L. var. Grand Rapids) seeds. Seeds receiving either red or far-red light or darkness all showed a positive response to the gas. However, ethylene was apparently without effect on dormant seeds, those which failed to germinate after an initial red or far-red treatment. Carbon dioxide, which often acts as a competitive inhibitor of ethylene, failed to clearly reverse ethylene-enhanced seed germination. While light doubled ethylene production from the lettuce seeds, its effect was not mediated by the phytochrome system since both red and far-red light had a similar effect.     

Xylem Transport of 1-Aminocyclopropane-1-carboxylic Acid, an Ethylene Precursor, in Waterlogged Tomato Plants

Waterlogging is known to cause an increase in ethylene synthesis in the shoot which results in petiole epinasty. Evidence has suggested that a signal is synthesized in the anaerobic roots and transported to the shoot where it stimulates ethylene synthesis. Experimental data are presented showing that 1-aminocyclopropane-1-carboxylic acid (ACC), the immediate precursor of ethylene, serves as the signal. Xylem sap was collected from detopped tomato plants (Lycopersicon esculentum Mill. cv. VFN8). ACC in the sap was quantitated by a sensitive and specific assay, and its tentative chemical identity verified by paper chromatography. ACC levels in both roots and xylem sap increased markedly in response to waterlogging or root anaerobiosis. The appearance of ACC in the xylem sap of flooded plants preceded both the increase in ethylene production and epinastic growth, which were closely correlated. Plants flooded and then drained showed a rapid, simultaneous drop in ACC flux and ethylene synthesis rate. ACC supplied through the cut stem of tomato shoots at concentrations comparable to those found in xylem sap caused epinasty and increased ethylene production. These data indicate that ACC is synthesized in the anaerobic root and transported to the shoot where it is readily converted to ethylene.     

Evidence for phytochrome involvement in light-mediated stomatal movement in Phaseolus vulgaris L.

Observations made with primary leaves of Phaseolus vulgaris L. demonstrated that phytochrome modulates light-induced stomatal movement. Removal of the far-red-absorbing form of the pigment (Pfr) with far-red (FR) radiation decreased the time required by the stomata to reach maximal opening following a dark-to-light transition; this effect of FR was fully reversible with red. Removal of Pfr with FR also decreased the time required to reach maximal closure following a light-to-dark transition, and the rate of closure was dependent on the final irradiation treatment before darkness. No evidence was found for phytochrome involvement in determining stomatal aperture under constant conditions of either darkness of light.Abbreviations and symbols Chl chlorophyll - D darkness - FR far-red - phytochrome photostationary state - Pfr, Pr FR- and R-absorbing forms of phytochrome, respectively - R red     

Ethylene production and metabolism of 1-aminocyclopropane-1-carboxylic acid in a long-day plant,Chenopodium murale L., as influenced by photoperiodic flower induction

Chenopodium murale plants, induced to flower by 5 days of continuous light, produced 43% more ethylene than vegetative plants kept under short days (16 h darkness, 8 h light). The 1-aminocyclopropane-1-carboxylic acid (ACC)-induced ethylene production, using saturating ACC concentration (10 mol·m⁻³) was also 55% higher in induced plants. Their ACC and N-malonyl-ACC (MACC) levels were also higher, the former increasing by 56% in both shoots and roots, the latter by 288% and 108% in shoots and roots, respectively. Administration of labeled [2,3-¹⁴C]ACC produced a very similar relative content of ACC and MACC in both treatments. The only process influenced by flower induction was ACC conversion to ethylene. Induced plants converted 66% more ACC than the vegetative ones. The effects of photoperiod on ethylene formation and metabolism in a long-day plant (LDP)C. murale and a short-day plant (SDP)C. rubrum are compared. Ethylene formation seems to be under photoperiodic control in both species, but its role in flower induction remains obscure.     

Inhibition of darkness-induced stomatal closure by ethylene involves a removal of hydrogen peroxide from guard cells of <Emphasis Type="Italic">Vicia faba</Emphasis>

Ethylene regulates many aspects of plant growth and development; however, its effect on the behavior of the stomata is still largely obscure. Here, the association between ethylene inhibition of darkness-induced stomatal closure and hydrogen peroxide (H₂O₂) levels in Vicia faba guard cells was studied. Like ascorbic acid (ASA), the most important reducing substrate for H₂O₂ removal, catalase (CAT), one of H₂O₂-scavenging enzymes, and diphenylene iodonium (DPI), an inhibitor of the H₂O₂-generating enzyme NADPH-oxidase, both ethylene-releasing compound 2-chloroethylene phosphonic acid (ethephon, ETH) and 1-aminocyclopropane-1-carboxylic acid (ACC), the immediate precursor of ethylene, were found to inhibit stomatal closure by darkness and to reduce H₂O₂ levels in guard cells, indicating that ethylene-caused inhibition of darkness-induced stomatal closure involves reduction in the H₂O₂ level in guard cells. Additionally, similar to ASA and CAT, ACC/ETH not only suppressed H₂O₂-induced stomatal closure and H₂O₂ level in guard cells treated with exogenous H₂O₂ in the light, but also reopened the stomata, which had been closed by darkness, and reduced H₂O₂ level that had been generated by darkness, showing that ethylene causes H₂O₂ removal from guard cells. However, the above-mentioned effect of ACC/ETH was dissimilar from that of DPI, which not only was incapable to reduce H₂O₂ level induced by exogenous H₂O₂ but also could not abolish H₂O₂ that had been generated by darkness. Thus, we suggest that ethylene probably induces H₂O₂ removal and reduces H₂O₂ level in guard cells and finally inhibits stomatal closure induced by darkness. Furthermore, the mechanism of H₂O₂ removal caused by ethylene was also discussed.     

Does light inhibit ethylene production in leaves?

The effect of light on the rate of ethylene production was monitored using two different techniques—leaf segments incubated in closed flasks versus intact plants in a flow-through open system. Three different plants were used, viz sunflower (Helianthus annuus), tomato (Lycopersicon esculentum), and soybean (Glycine max). Experiments were conducted both in the presence and absence of 1-aminocyclopropane-1-carboxylic acid (ACC).

The results obtained indicate that, in all three species studied, light strongly inhibits ethylene production when cut leaf segments are incubated in the presence of ACC in closed flasks. When ethylene measurements are made with ACC-sprayed intact plants using a continuous flow system, the effect of light on ethylene production is only marginal. In leaf segments of sunflower and soybean incubated only in distilled H₂O in closed flasks, light promotes ethylene production. In tomato, there is no difference between the rate of ethylene production between light and darkness under such conditions. When measurements are made with intact plants in a continuous flow system, the rate of ethylene production is almost identical in light and darkness, in the three plants studied.

It is concluded that the effect of light on cut leaf segments incubated in the presence of ACC in closed flasks can be attributed to the techniques used for these measurements. Light has little effect on ethylene production by intact plants in an open system.

     

Protein Synthesis during Endogenous Rhythmic Leaflet Movement in Albizzia

A rhythm was found in protein synthesis accompanying rhythmic leaflet opening and closing in the dark in the plant Albizzia. More protein was synthesized during the opening of the leaflets than during the closing. Furthermore, an inhibitor of protein synthesis, cycloheximide, prevented rhythmic opening of leaflets but had no effect on rhythmic closing. It is suggested that protein synthesis is involved in the movement across membranes of K⁺ ions that cause turgor changes and leaflet movement.     

Three positive regulators of leaf senescence in Arabidopsis, ORE1, ORE3 and ORE9, play roles in crosstalk among multiple hormone-mediated senescence pathways

Leaf senescence is a developmentally programmed event, but the initiation and progression of leaf senescence are affected by a range of plant hormones including abscisic acid (ABA), ethylene and methyl jasmonate (MeJA). To investigate plant hormone crosstalk during leaf senescence, hormone-induced senescence phenotypes were analyzed in three leaf senescence mutants [ore1 (oresara1), ore3 and ore9] showing delayed senescence phenotypes in age-dependent and dark-induced senescence. The ore mutants exhibited delayed leaf senescence phenotypes following treatment with ABA, ACC (aminocyclo-propane-1-carboxylic acid) or MeJA. After each hormone treatment, the photochemical efficiency of photosystem II and chlorophyll content were significantly higher in the ore mutant leaves than in the wild-type leaves. The expression of CAB2 and SEN4 in the wild-type was rapidly altered following each hormone treatment. However, the decrease in CAB2 expression and the induction of SEN4 expression in the mutants were less affected by ABA, ACC or MeJA treatment. It is suggested that ORE1, ORE3 and ORE9 are required for the proper progression of leaf senescence mediated by ABA, ethylene and MeJA. This implies that ORE1, ORE3 and ORE9 may be linked to the crosstalk among senescence pathways induced by ABA, ethylene and MeJA, as well as age and darkness.     

Circadian Ethylene Synthesis in <Emphasis Type="Italic">Sorghum bicolor</Emphasis>: Expression and Control of the System at the Whole Plant Level

Ethylene production by sorghum is rhythmic and the amplitude of the rhythm is increased both by dim, far-red enriched light and in mutant plants deficient in phytochrome B. The mechanisms involved in controlling ethylene production were examined in detail by measuring the rate of ethylene production among organs and tissues, examining the organ-specific levels of ACC (1-aminocyclopropane-1-carboxylic acid, the ethylene precursor) and investigating the contribution of the roots to shoot ethylene production. The results demonstrate that the expanding leaves were the major source of ethylene under dim, far-red enriched light and in the phytochrome B mutant. Enhanced ethylene production by the expanding leaf appeared to be the result of targeted delivery of ACC to this tissue. Root ACC levels were much higher than those in the shoot but roots converted much less of this endogenous ACC to ethylene. Applying ACC to the roots had only a marginal effect on their ethylene production, but greatly increased that of the shoots. Decapitated shoots continued to produce ethylene in a rhythmic pattern but the amplitude decreased with time compared to intact plants. The results collectively suggest that some, but not all, of the shoot ethylene rhythm depends on the transport of ACC from the roots to the shoots.