Studies in Stomatal Behaviour: X. AN INVESTIGATION OF RESPONSES TO LOW-INTENSITY ILLUMINATION AND TEMPERATURE IN XANTHIUM PENNSYLVANICUM

Two experiments are described in which stomatal sensitivityto low-intensity white light was studied for Xanthium pennsylvanicumWall. In the first experiment a daylength extension for 7, 9, or 15hrs. was given using 10, 40, or 160 lux to shorten a basic 16-hr.night, which was also given at its full length as a tenth treatment.Measurements were made of stomatal opening ability on the morningfollowing the different treatments. With a 15-hr. extensionthere was at all intensities a significant response, shown bya reduced rate of opening in the morning. With a 9-hr. extensionusing 40 or 160 lux, opening ability was reduced, but 9 hrs.of 10 lux was insufficinet to produce a detectable effect. The7-hr. extension was ineffective at all three intensities. In the second experiment stomatal behaviour was observed during20 hrs. of either darkness or 10 lux at four temperatures (15,22, 29, and 36°C.). During 20 hrs. of darkness there wasnight opening at all temperatures, but at lower temperaturesit began sooner and lasted longer. These responses to temperaturedid not fit a simple linear relationship, there being a significantcubic term revealed by non-linear regression analysis. Thiscould be explained if the response was considered in terms ofthe magnitude of the change in temperature (from 25°C.)at the beginning of the experiment; there appeared to be sometemperature compensation over a limited range. in 10 lux, nightopening was suppressed at 29° and 36°, but at 15°it was apparently unaffected by the light; at 22° it wasnot completely suppressed by 10 lux but the time of its occurrencewas delayed. Effects of light and temperature are discussed in relation toan endogenous rhythm in darkness which was previoulsy shownto operate in Xanthium pennsylvanicum (Part IX). It is considered that to explain effects of very low intensitylight it will be necessary to recognize a ‘low intensityresponse’ by stomata, which does not operate via changesin guard-cell carbon dioxide.     

Studies in Stomatal Behaviour: IX. PHOTOPERIODIC EFFECTS ON RHYTHMIC PHENOMENA IN XANTHIUM PENNSYLVANICUM

An investigation of the effects of different day-length treatmentson stomatal behaviour in Xanthium pennsylvanicum Wall. has shownthat there are differences in long-and short-day treatmentssimilar to those first reported by Schwabe (1952) for Chrysanthemumand Kalanchoe, viz. stomatal opening towards the end of thenight in short days, but not in long days (short night precededby a period of low intensity illumination). In Xanthium therewere in addition very marked differences in rates of stomatalopening in the morning after different lengths of night. Theseeffects were not persistent, there being an immediate reversalupon a change from long- to shrot-day treatment, or vice versa. Further investigation showed that there was an endogenous rhythmaffecting the stomata in continuous darkness; rate of openingwas slow after very short nights, but became greater with extensionof the night to 14–16 hrs., this being the first ‘peak’of an ‘opening ability’ rhythm. The rhythm diedout rapidly and the second cycle was much reduced in amplitude.The period of the rhythm appeared to be approximately 24 hrs.The phase was set mainly by the time of onset of darkness, butthe duration of the pretreatment with low intensity illuminationwas also important—prolonging this was found to reudcethe time in darkness before the first peak. Each hour of lightof 1,500 lux given before darkness was found to be equivalentot approximately 0.3 hr. to darkness. The predominant effect of the length of the preceding nightwas on the slope of the opening curves rather than on the timeof onset of opening following illumination. The first peak of the opening ability rhythm was often manifestedeven in continuous darkness by a period of ‘night opening’of the stomata. The results are discussed and compared with those of other authorsand attempts are made to relate them to theories of the stomatalmechanism.     

Stomatal Responses to High Temperature in Darkness

The effect of a temperature increase from 25 to 35°C onstomatal opening in darkness (‘night opening’) onexcised, turgid leaves of Stachytarpheta indica was investigatedby microscopic examination of a baxial epidermis fixed in absoluteethanol. An appreciable degree of opening occurred towards theend of a 14-h night at 25°C, and this was substantiallyenhanced by the temperature increase to 35°C in the dark,which also promoted a marked increase in starch hydrolysis andaccumulation of potassium in the guard cells. The degree oftemperature-induced night opening was somewhat smaller thanthat of light-induced opening, and was higher in CO₂-free airthan in normal air. 2,4-dinitrophenol (DNP) was effective inarresting stomatal opening and suppressing starch hydrolysisand increase in stomatal potassium. The temperature-inducednight opening is related, to a great extent, to the enhancementby high temperature of starch hydrolysis and potassium accumulationin the guard cells, and the inhibitory effect of DNP on stomatalopening is attributed largely to its suppression of these twometabolic processes. The importance of oxidative phosphorylationas a possible source of energy for stomatal opening is brieflydiscussed.     

Flower Opening in Asiatic Lily is a Rapid Process Controlled by Dark-light Cycling

In commerce, Asiatic lilies are picked in bud, each stem holdingseveral buds. We found flower opening was rapid, taking lessthan 4 h both on the stem and for excised buds. Opening wasalso strongly synchronous. For a 12 h day-night cycle, openingbegan late in the dark period, reaching a mid-point after 11h of darkness. This was equally true of buds that were excisedwhen nearly ready to open, and those with 3–4 d of developmentto complete. Reversing day and night reversed the time of opening,and red light was as effective as white light in providing ‘day’conditions. A 15 min light break during the night did not affectthe opening. Lengthening the night (8, 12, 16 h) and shorteningthe day delayed opening from 9, to 11, to 13 h after the startof darkness, respectively. In continuous light and continuousdark, synchronicity was lost. If opening flowers were held inextended darkness, two phases of opening could be discriminated.In a ‘dark phase’, petals opened to approx. 40°,and anthers remained intact. When such flowers were returnedto light, there was a ‘light phase’, where petalsopened further, became more pigmented and began to recurve,and the anthers dehisced, these events taking only 2–3h. The net result was that flowers became fully open and anthersdehisced approx. 2 h after dawn, regardless of daylength. Copyright2000 Annals of Botany Company Asiatic lily, Lilium hybrid, flower opening, timing, endogenous rhythm, synchronicity     

Stomatal Opening in Light of Different Wavelengths: Effects of Blue Light Independent of Carbon Dioxide Concentration

Stomatal opening in Xanthium pennsylvanicum was found to besignificantly greater in blue light than in red. Experimentsin which leaves were placed in a closed system and allowed toestablish their own steady-state carbon dioxide concentrationshowed that when the CO₂ concentration was about the same asthat in red, opening was much greater in blue light. Blue lightof low intensity could cause as great an opening as red of higherintensity, even though the CO₂ concentration was much higherin blue. Stomatal opening in light is considered as involvingat least two reactions: (1) a response to the removal of CO₂by photosynthesis; (2) a response to blue light not dependenton the removal of CO₂. Blue light became increasingly effective, relative to red, asthe length of night was increased over the range 2 to 14 hours.This might, in part, explain previously observed effects ofnight length on rate of opening in light. The initial very rapid phase of closure in darkness appearedto be independent of CO₂ accumulation, for it was not preventedby flushing the intercellular spaces with air free of CO₂. Itis suggested that closure in darkness, like opening in light,should be considered as involving components both dependentupon, and independent of, CO₂ concentration.     

Environmental Factors Controlling Capitulum Opening and Closing of Dandelion, Taraxacum albidum

The capitula of Taraxacum albidum kept in darkness opened whenthe temperature rose. The higher the temperature before thechange and greater the temperature rise, the larger the openingresponse was. The opening was promoted by light. The capitulakept in darkness at 20?1?C opened after exposure to light withoutthe temperature rise. The capitula closed 8–10 h afterthe beginning of the opening under constant light and temperatureconditions. (Received November 8, 1986; Accepted March 13, 1987)     

Tentoxin Suppresses Stomatal Opening by Inhibiting Photophosphorylation

Tentoxin and, to a lesser extent, dihydrotentoxin (both at 10mmol m^–3) reduce stomatal opening in epidermal stripsof Commelina communis in the light but not in darkness. Thiseffect was significantly greater in normal air than in CO₂-freeair. Fusicoccin overcame the tentoxin effect. However, tentoxindid not inhibit stomatal opening in the light in epidermal stripsof Paphiopedilum harrisianum, a species which lacks guard cellchloroplasts. It is concluded that tentoxin exerts its actionon stomata not by an ionophorous effect in the plasmalemma ofguard cells but by the inhibition of photophosphorylation intheir chloroplasts. The effects of DCMU and tentoxin on guardcells are discussed in terms of their effects on chloroplastsand the extent to which energy is supplied from this organelleduring stomatal opening in the light. The results indicate thatneither photophosphorylation nor non-cyclic electron transportin guard cell chloroplasts are essential for stomatal opening. Key words: Commelina, epidermal strips, Paphiopedilum, photophosphorylation, stomata, tentoxin     

Environmental Factors Controlling Flower Opening and Closing in aPortulacaHybrid

To examine flower opening and closing of aPortulacahybrid, flowerbuds were placed in darkness for 12 h (2030–0830 h) at20 °C and then exposed to various light-temperature conditions.Flower buds exposed to light at 25, 30 or 35 °C opened within1 h, and wilted 10–14 h later. Flower buds exposed tolight at 20 °C started to open after 4 h but opened slowlyand not completely. Flower buds subjected to 25, 30 or 35 °Cin darkness also opened rapidly, but did not reach full opening.Flowers opened at 30 °C in light, and partially closed andopened repeatedly in response to cycles of a 2-h exposure to20 °C and a 2-h exposure to 30 °C at any time between1000 to 1600 h. Similar phenomena were observed when the flowersopened at 30 °C in light and then were subjected to darknessand light alternately at 30 °C, although the effect of lightwas less obvious than that of alternating temperature. Floweropening and closing were not affected by relative humidity.These results indicate that a rise in temperature is requiredfor rapid flower opening in the buds kept at 20 °C, andthat light intensifies the effect of high temperature. Exposureto light without a temperature change delayed and slowed floweropening which was never complete. The involvement of an endogenousrhythm in flower opening byPortulacais indicated. Portulacahybrid, flower opening, flower closing, temperature shift, endogenous rhythm.     

CO2 fixation in leaves of a CAM plant without lower epidermis and the effect of CO2 on their deacidification

The effects of peeling the epidermis off Bryophyllum daigremontianumleaves on CO₂ uptake in light and darkness were investigated.Light-induced CO₂ uptake in the daytime was markedly enhancedin the peeled leaves, but dark fixation of CO₂ carried out atmidnight was not. The difference in promotion of CO₂ uptakein light and darkness was due to stomatal closing in the dayand opening at night. Also, deacidification was strikingly inhibitedby CO₂ in peeled leaves. (Received February 3, 1977; )     

Responses of Stomata to IAA and Fusicoccin at the Opposite Phases of an Entrained Rhythm

The stomata of Commelma communis showed reduced opening responsesto light and low CO₂ concentrations during the night phase oftheir entrained circadian rhythm. Increased supplies of potassiumions, and treatments with indol-3-ylacetic acid and fusicoccin,failed to promote opening during the night phase to a levelequivalent to that in the day phase. The inability of fusiccocinto overcome the suppression of opening during the night phasecontrasts with its ability to counteract the closure inducedby agents such as CO₂, darkness and abscisic acid. It is concludedthat there are at least two basic mechanisms by which the turgorof guard cells can be regulated, one which is susceptible tooverriding control by fusicoccin and another which is unaffectedby fusicoccin. Several previous studies had shown a positive correlation betweenmalate in the epidermis (mainly located in guard cells) andstomatal opening. In the present experiments the aperture/malatecorrelation was broken in epidermis treated with fusicoccinduring the night phase of the rhythm. The amount of malate presentexceeded that associated with the same stomatal aperture inthe day phase. Possible explanations are (1) that fusicoccinstimulates similar proton fluxes out of the guard cells duringboth phases of the rhythm, but an unknown factor imposes a restrictionon stomatal opening during the night phase; (2) that there arelower proton fluxes in the night phase (limited, for example,by a reduced supply of ATP) but chloride availability or transportis reduced to an even greater extent so that a larger productionof malate in the guard cells is required. Key words: Stomata, IAA, Fusicoccin, Rhythms     

Induction of CAM in Mesembryanthemum crystallinum Abolishes the Stomatal Response to Blue Light and Light-Dependent Zeaxanthin Formation in Guard Cell Chloroplasts

Facultative CAM plants such as Mesembryanthemum crystallinum(ice plant) possess C3 metabolism when unstressed but developCAM under water or salt stress. When ice plants shift from C3metabolism to CAM, their stomata remain closed during the dayand open at night. Recent studies have shown that the stomatalresponse of ice plants in the C3 mode depends solely on theguard cell response to blue light. Recent evidence for a possiblerole of the xanthophyll, zeaxanthin in blue light photoreceptionof guard cells led to the question of whether changes in theregulation of the xanthophyll cycle in guard cells parallelthe shift from diurnal to nocturnal stomatal opening associatedwith CAM induction. In the present study, light-dependent stomatalopening and the operation of the xanthophyll cycle were characterizedin guard cells isolated from ice plants shifting from C3 metabolismto CAM. Stomata in epidermis detached from leaves with C3 metabolismopened in response to white light and blue light, but they didnot open in response to red light. Guard cells from these leavesshowed light-dependent conversion of violaxan-thin to zeaxanthin.Induction of CAM by NaCI abolished both white light- and bluelight-stimulated stomatal opening and light-dependent zeaxanthinformation. When guard cells isolated from leaves with CAM weretreated with 100 mM ascorbate, pH 5.0 for 1 h in darkness, guardcell zeaxanthin content increased at rates equal to or higherthan those stimulated by light in guard cells from leaves inthe C3 mode. The ascorbate effect indicates that chloroplastsin guard cells from leaves with CAM retain their competenceto operate the xanthophyll cycle, but that zeaxanthin formationdoes not take place in the light. The data suggest that inhibitionof light-dependent zeaxanthin formation in guard cells mightbe one of the regulatory steps mediating the shift from diurnalto nocturnal stomatal opening typical of plants with CAM. (Received July 5, 1996; Accepted December 12, 1996)     

Flower opening and closing ofOxalis martiana

Flowers ofOxalis martiana open in the morning and close in the afternoon repeatedly for 3–5 days in May–July under natural conditions. Both in light and in darkness, the closed flowers opened in reponse to a rise in temperature (thermonasty), but not under the constant temperatures. Transfer from darkness to light along with temperature rise caused rapid flower opening, and at 20 C or higher temperatures, exposure to light caused flower opening even without changing temperature (photonasty). Therefore, the temperature of the night before opening is critical in determining whether the flower opening under natural conditions depends on thermonasty or photonasty. The opened flowers closed about 8–11 hr after the beginning of opening both under natural conditions and constant light-temperature conditions, which suggests that the time of flower closing is determined by endogenous factors. Length of the perianth increased greatly during opening and slightly during closing. Application of actionomycin D or cycloheximide inhibited both the flower opening and closing, probably by suppressing the perianth growth.     

Energy Supply for Stomatal Opening in Epidermal Strips of Commelina benghalensis

The influence of light or darkness on stomatal opening in epidermal strips of Commelina benghalensis was evaluated in the presence or absence of O₂ and/or metabolic inhibitors. Opening was restricted in nitrogen and was promoted by NADH and acids of the tricarboxylic acid cycle (succinate and α-ketoglutarate) in CO₂-free air in light as well as in darkness. The enhancement by light of stomatal opening was prevalent under nitrogen or in the presence of the respiratory inhibitors (sodium azide and oligomycin). Respiratory inhibitors decreased the opening in light or darkness under CO₂-free air but exhibited no effect under nitrogen, whereas phosphorylation uncouplers were inhibitory in light or darkness under both CO₂-free air and nitrogen. The results suggest that oxidative phosphorylation is a basic source of energy for stomatal opening, although photophosphorylation could be an energy source.     

Nocturnal Accumulation of Acid in Leaves of Wall Pennywort (Umbilicus rupestris) Following Exposure to Water Stress

Physiological responses to water stress (drought) have beeninvestigated in Umbilicus rupestris (wall pennywort) by comparingcontrol (well-watered) and draughted plants with respect to(i) diurnal fluctuations in the acid content of the leaves,(ii) CO₂ exchange patterns and (iii) stomatal conductance. Controlplants show no diurnal fluctuations in acid content, whereasafter 6 d of drought a clear CAM-type pattern (nocturnal acidificationfollowed by deacidification in the light) is observed. In controlplants, the CO₂ exchange pattern over a 24 h period is of atypical C-3 ‘square-wave’ type, with extensive CO₂uptake in the light and CO₂ output in the dark. In droughtedplants the day-time CO₂ uptake is confined to a morning ‘burst’,whilst night-time CO₂ output is markedly reduced. There is howeverno net noctural uptake of CO₂. In control plants, stomatal conductanceis high during the day (especially in the first half of theday) falling to a low level at the onset of darkness, and thenrising slowly through the remainder of the night. In droughtedplants, stomatal conductance is very low, except that thereis morning ‘burst’ of high conductance and a periodduring the night when conductance is higher than in controlplants. These results are discussed in relation to the response of U.rupestris to drought both in laboratory and in field conditions. Umbilicus rupestris, wall pennywort, CO₂ exchange, Crassulacean acid metabolism, drought, stomatal conductance, water stress     

Photosynthesis affects following night leaf conductance in Vicia faba

Night-time stomatal opening in C₃ plants may result in significant water loss when no carbon gain is possible. The objective of this study was to determine if endogenous patterns of night-time stomatal opening, as reflected in leaf conductance, in Vicia faba are affected by photosynthetic conditions the previous day. Reducing photosynthesis with low light or low CO₂ resulted in reduced night-time stomatal opening the following night, irrespective of the effects on daytime stomatal conductance. Likewise, increasing photosynthesis with enriched CO₂ levels resulted in increased night-time stomatal opening the following night. Reduced night-time stomatal opening was not the result of an inability to regulate stomatal aperture as leaves with reduced night-time stomatal opening were capable of greater night-time opening when exposed to low CO₂. After acclimating plants to long or short days, it was found that night-time leaf conductance was greater in plants acclimated to short days, and associated with greater leaf starch and nitrate accumulation, both of which may affect night-time guard cell osmotic potential. Direct measurement of guard cell contents during endogenous night-time stomatal opening will help identify the mechanism of the effect of daytime photosynthesis on subsequent night-time stomatal regulation.     

ENDOGENOUS RHYTHM IN OPENING AND ODOR OF FLOWERS OF CESTRUM NOCTURNUM

Overland , Lillian . (Missouri Botanical Garden, St. Louis.) Endogenous rhythm in opening and odor of flowers of Cestrum nocturnum. Amer. Jour. Bot. 47(5): 378—382. Illus. 1960.–The opening and closing of flowers of Cestrum nocturnum have been found to occur in a cyclic manner both in constant light and constant darkness at constant temperature. The strong odor, which in nature occurs at night and was previously believed to be a direct result of darkness, has been shown to exist as an endogenous rhythm, occurring under constant conditions of temperature and light, as well as in darkness. Although in nature the odor cycle is so synchronized by the environment as to have a period of roughly 24 hr., in constant conditions temperature affects the cycle by lengthening it at low temperature and reducing it at high temperature. The cycle may be disrupted by shifting between extreme temperatures, but it is not destroyed. The controlling mechanism for odor production seems to be located in the tips of the corolla and the cycle exists independently in the excised tips.     

Dynamic Organization of Microtubules in Guard Cells of Viciafaba L. with Diurnal Cycle

Stomatal movement is regulated by changes in the volume of guardcells, thought to be mainly controlled by an osmo-regulatorysystem. In the present study, we examined the additional involvementof cytoskeletal events in the regulation of stomatal movement.Microtubules (MTs) in guard cells of Viciafaba L., grown undersunlight, were observed during the day and night by immunofluorescencemicroscopy. Cortical MTs began to be organized in a radial arrayat dawn and increased in numbers in the morning following theincrease in the stomatal aperture size. Thereafter, MTs becamelocalized near the nucleus and began to be destroyed from theevening to midnight, following the decrease in stomatal aperturesize. These diurnal changes in MT organization were observedeven two days after transfer from natural light condition tototal darkness, and were accompanied by corresponding changesin stomatal aperture. The increase in stomatal aperture sizein the early morning was inhibited by 50 µM propyzaraide,which destroys cortical MTs in guard cells, whereas the decreasein aperture size in the evening was suppressed by 10 µMtax-ol, which stabilizes cortical MTs. These results suggestthat radially-organized cortical MTs of guard cells may controldiurnal stomatal movement. (Received September 3, 1997; Accepted November 5, 1997)     

The Effect of Temperature on the Production and Abscission of Flowers and Pods in Snap Bean (Phaseolus vulgaris L.)

The effect of temperature on production and abscission of flowerbuds, flowers and pods was studied in a determinate snap-beancultivar (cv. Tenderette). Under moderate temperature (e.g.27/17 °C) the onset of pod development was associated withcessation of flower bud production and with enhanced abscissionof flower buds. Raising night temperature from 17 °C to27 °C strongly reduced pod production, mature pod size andseeds per pod, while an increase in day temperature from 22°C to 32 °C had smaller and less consistent effects.Pod production under high night temperature was not constrainedby flower production since 27 °C at night promoted branchingand flower bud appearance. Under 32/27 °C day/night temperaturethe large reduction in pod set was due to enhanced abscissionof flower buds, flowers and young pods (< 3 cm). Flowershad the highest relative abscission followed by young pods andflower buds. Therefore, the onset of anthesis and of pod developmentwere the plant stages most sensitive to night temperature. Podslarger than 3 cm did not abscise but usually aborted and shrivelledunder high night temperature. The effects of 32/27 °C werenot due to transient water stresses and were observed even undercontinuous irrigation and mist-spraying. High temperature, flower production, pod set, seed set, abscission, snap bean, Phaseolus vulgaris L., cv. Tenderette     

Suppression of the stomatal opening by morphactins in isolated epidermal strips

The effects of three morphactins, chlorflurenol, flurenol andEMD 7301 W, were examined on the stomatal aperture using isolatedepidermal strips of Commelina benghalensis. Morphactins produced,a striking decrease in the stomatal opening in light but hadno effect on stomatal closure in darkness. Various catalystsand inhibitors of photophosphorylation had no influence on themorphactin-induced stomatal closure. The stimulatory effectsof ATP, pyruvate and KC1 on stomatal opening were suppressedby the morphactins. The cytokinin, benzyladenine stimulatedthe stomatal opening even in the presence of a morphactin. Theinfluence of morphactins on the stomatal aperture closely resembledthe effect of abscisic acid. ¹Present address: Central Plantation Crops Research Institute,Regional Station, Vittal 574243, Karnataka, India. (Received September 16, 1975; )     

Characterization of a wilty sunflower (Helianthus annuus L.) mutant: I. Abscisic acid content, light-dark changes in the stomatal conductance and genetic analysis

The present study was conducted to characterize geneticallyand physiologically a spontaneous mutation in sunflower whichconfers a wilty phenotype. The wilting condition of the mutantis due to abnormal stomatal behaviour. The mutant stomata resistclosure in darkness. This abnormality is associated with lowlevels of endogenous abscisic acid (ABA). By artificially elevatingthe ABA content of the mutant plants by spray treatments with10^– and 10^– M solutions it proved possible to effecta phenotypic reversion of the mutant. It has, therefore, beenproposed that the primary effect of this spontaneous mutationis to reduce the level of ABA. The genetic analysis has shownthat the willy phenotype is due to recessive nuclear mutationat a single locus. Key words: ABA, Helianthus annuus L, stomatal conductance, wilty mutant