Stomatal Responses to Light and Drought Stress in Variegated Leaves of Hedera helix

Direct and indirect mechanisms underlying the light response of stomata were studied in variegated leaves of the juvenile phase of Hedera helix L. Dose response curves of leaf conductance were measured with blue and red light in leaves kept in normal or in an inverted position. In the green portions of the leaves, the sensitivity to blue light was nearly 100 times higher than that to red light. No response to red light was observed in the white portions of the leaves up to 90 micromoles per square meter per second. Red light indirectly affected leaf conductance while blue light had a direct effect. Leaf conductance was found to be more sensitive to drought stress and showed a more persistent aftereffect in the white portions of the leaves. A differential effect of drought stress on the responses to blue and red light was also observed.     

The Responses of Stomatal Density to CO2 Partial Pressure

Experiments on a range of species of tree, shrub and herb haveshown that stomatal density and stomatal index increase as thepartial pressure of CO₂ decreases over the range from the currentlevel of 34 Pa to 22.5 Pa. Stomatal density responds to thereduced partial pressure of CO₂ in a simulation of high altitude(3000 m), when the CO₂ mole fraction is unchanged. When the partial pressure of CO₂ is increased from 35 to 70Pa stomatal density decreases slightly, with a response to unitchange in CO₂ which is about 10% of that below 34 Pa. Measurements of gas exchange on leaves which had developed indifferent CO₂ partial pressures, but at low saturation vapourpressure deficits in the range of 0.7 to 0.9 kPa, indicatedlower photosynthetic rates but higher stomatal conductancesat reduced CO₂ partial pressures. Experiments on populations of Nardus stricta originating fromaltitudes of 366 m and 810 m in Scotland, indicated geneticdifferences in the responses of stomatal density to CO₂ in pressuressimulating altitudes of sea level and 2 000 m. Plants from thehigher altitude showed greater declines in stomatal densitywhen the CO₂ partial pressure was increased. Key words: Stomata, CO₂, gas exchange, altitude, atmospheric pressure     

Stomatal Density Responses of Egyptian Olea europaea L. Leaves to CO2 Change Since 1327 BC

We have attempted to separate the effects of CO₂ and temperaturechange on stomatal density by examining ancient leaf materialof Olea europaea L. The distribution of this species is confinedto a Mediterranean type climate, so that O. europaea leavesof different ages will have formed under similar temperaturesbut different CO₂ levels over the last 3000 years. Stomataldensity measurements have been made upon leaves of O. europaeaoriginating from King Tutankhamun's tomb dating from 1327 BC,and have been compared with values obtained from Egyptian O.europaea material dating from pre-332 BC, 1818 and 1978 AD.Together, the four dates provide a record of how the plant hasresponded to increases in atmospheric CO₂ concentration duringthat time. The results demonstrate that in accordance with similarstudies examining the stomatal density response of plants overthree time scales (hundreds, thousands and tens of thousandsof years) stomatal density falls as CO₂ levels increase. Sincewe have examined a natural system with leaves developing undersimilar environmental temperatures the results confirm observationsfrom experimental studies in which plants were grown under thesame temperature but different CO₂ regimes.Copyright 1993, 1999Academic Press Olea europaea, stomatal density, atmospheric CO₂, temperature, climate change     

Stomatal Responses and the Senescence of Leaves

Guard cell responses were examined in green and senescing leavesof Victa faba using detached epidermal strips to eliminate influencesfrom the mesophyll. Stomatal opening was greater in epidermalstrips from mature leaves than from senescing leaves althoughthe latter still retained the ability to respond to CO₂ andto kinetin. It was concluded that the decline in stomatal activityduring senescence is an independent but parallel process tochanges occurring in the mesophyll. Vicia faba, leaf senescence, stomata, kinetin     

The Measurement of Stomatal Responses to Stimuli in Leaves and Leaf Discs

A comparison has been made of stomatal responses in intact leaves,leaf discs supplied with water via their cut edges and leafdiscs floating on water. Xanthium pennsylvanicum leaf discswatered via their cut edges appeared to be more turgid thanintact leaves; this considerably slowed down the rate of stomatalopening but it slightly increased the final steady-state stomatalopening. When the water potential of such leaf discs was loweredby pre-treatment with mannitol solutions rates of stomatal openingincreased whereas maximum steady-state openings decreased. In tobacco leaf discs floating on water the stomata in contactwith water were wider open than those in contact with normalair and they did not respond to treatment with carbon dioxide-freeair. The rate of photosynthesis was severely reduced in tobaccoleaf discs floating with the lower epidermis on water, mostprobably owing to the slow rate of diffusion of carbon dioxidein water. By floating such discs on osmotica the degree of stomatalopening was increased, however, a response to treatment withcarbon dioxide-free air was still not measurable. It is postulatedthat, on account of the relative unavailability of carbon dioxidefrom the water, the carbon dioxide concentration in the substomatalcavities of the lower surface is abnormally low, irrespectiveof whether ordinary air or carbon dioxide-free air is availableto the upper surface. A comparison between porometer readings and measurements ofsiliconerubber impressions of stomatal pores taken from insidethe porometer cup confirmed that the silicone-rubber impressionmethod of assessing stomatal responses to stimuli has severelimitations, especially at small stomatal apertures.     

Responses of Photosynthetic Electron Transport in Stomatal Guard Cells and Mesophyll Cells in Intact Leaves to Light, CO2, and Humidity

High-resolution images of the chlorophyll fluorescence parameter Fq'/Fm' from attached leaves of commelina (Commelina communis) and tradescantia (Tradescantia albiflora) were used to compare the responses of photosynthetic electron transport in stomatal guard cell chloroplasts and underlying mesophyll cells to key environmental variables. Fq'/Fm' estimates the quantum efficiency of photosystem II photochemistry and provides a relative measure of the quantum efficiency of non-cyclic photosynthetic electron transport. Over a range of light intensities, values of Fq'/Fm' were 20% to 30% lower in guard cell chloroplasts than in mesophyll cells, and there was a close linear relationship between the values for the two cell types. The responses of Fq'/Fm' of guard and mesophyll cells to changes of CO2 and O2 concentration were very similar. There were similar reductions of Fq'/Fm' of guard and mesophyll cells over a wide range of CO2 concentrations when the ambient oxygen concentration was decreased from 21% to 2%, suggesting that both cell types have similar proportions of photosynthetic electron transport used by Rubisco activity. When stomata closed after a pulse of dry air, Fq'/Fm' of both guard cell and mesophyll showed the same response; with a marked decline when ambient CO2 was low, but no change when ambient CO2 was high. This indicates that photosynthetic electron transport in guard cell chloroplasts responds to internal, not ambient, CO2 concentration.     

Stomatal Behavior and CO(2) Exchange Characteristics in Amphistomatous Leaves

The possibility that differences in stomatal conductance between upper and lower surfaces of amphistomatous leaves are adaptations to differences in CO₂ exchange characteristics for the two surfaces was investigated. The ratio of upper to lower stomatal conductance was found to change little in response to light and humidity for well-watered sunflower (Helianthus annuus L.) plants. Stressing the plants (ψ = −17 bars) and rewatering 1 day before gas exchange measurements reduced upper conductance more severely than lower in both indoor- and outdoor-grown plants, and caused small changes in conductance ratio with light and humidity. A similar pattern was found using outdoor grown sunflower and cocklebur (Xanthium strumarium L.) plants. Calculated intercellular CO₂ concentrations for upper and lower surfaces were always close to identical for a particular set of environmental conditions for both sunflower and cocklebur, indicating that no differences in CO₂ exchange characteristics exist between the two surfaces. By artificially creating a CO₂ gradient across the leaf, the resistance to CO₂ diffusion through the mesophyll was estimated and found to be so low that despite possible nonhomogeneity of the mesophyll, differences in CO₂ exchange characteristics for the two surfaces are unlikely. It is concluded that differences in conductance between upper and lower stomates are not adaptations to differences in CO₂ exchange characteristics.     

Stomatal Responses of Woody Seedlings to Flooding in Relation to Nutrient Status in Leaves

Ten-week-old woody seedlings of Gmelina arborea Roxb., Tectonagrandis L. (De Wild. & Th. Dur.) Merrill, and Nauclea diderrichiif., were subjected to 10 weeks flooding and a 5-week-long post-floodingperiod. Flooding induced the development of hypertrophied lenticels,adventitious roots, and root aerenchyma in Gmelina and Tectona,while it did not in Nauclea. All three species responded toflooding by first closing their stomata and reopening at differenttimes during the flooding period. The time and extent of reopeningwere earliest and greatest in Gmelina, followed by Tectona,and latest and smallest in Nauclea. Differences in stomatalconductance at the end of the flooding period paralleled theconcentrations of ethanol in roots and inorganic nutrients inleaves. After flooding was discontinued, stomatal conductanceincreased in Gmelina, but did not in the other species. Leafwater potentials and transpiration rates of flooded Gmelinaand Tectona plants were higher at week 8 than at week 2 whilethe reverse was the case in Nauclea. It is argued that whilepersistently small stomatal apertures during the post-floodingperiod in Nauclea may be a strategy to slow down the movementof accumulated toxic substances from the soil, the higher leafwater potential and transpiration in Gmelina and Tectona atweek 8 than at week 2 may represent recovery of shoot waterrelations resulting from adventitious roots development. Key words: Flooding, stomatal conductance, transpiration, adventitious roots, ethanol     

Responses of Photosynthetic Rate and Stomatal Conductance to Water Stress in Soybean Leaves

Responses of photosynthetic rate and stomatal conductance to water stress as weI1 as the relationship between photosynthetic rate and stomatal conductance were investigated with soybean cultivars “Ludou No. 4” and “7605”. The former was a high yield cultivars widely used in Shandong province, and the latter was a small grain soybean line bred by Shandong Academy of Agricultural science. Soil water stress decreased leaf apparent photosynthetic rate and stomatal conductance of two soybean cultivars, and “Ludou No. 4” decreased more than “7605”. At the same value of water potential, photosynthetic rate and stomatal conductance of “7605” were higher than those of “Ludou No,4”,but the rate of stomatal closure for “7605” was higher than “Ludou No. 4”. Decreasing of stomatal conductance caused rising of leaf temperature of two soybean cultivars, and the rising of “7605” was more rapid than “Ludou No. 4”, but at the same treatment of water stress, leaf temperature of “Ludou No. 4” was higher than “7605”. Leaf water use efficiecy (WUE) of two soybean cultivars were decreased under water stress, and the rate of decreasing in “Ludou No.4” was more rapid than in “7605”. These results showed that “7605” was more resistant to water:stress than “Ludou No. 4”.     

Direct Observation of Reversible and Irreversible Stomatal Responses of Attached Sunflower Leaves to SO(2)

The effects of SO₂ on stomatal aperture of attached sunflower leaves were observed with a remote-control light microscope system that permitted continuous observation of stomatal responses over periods of several hours. The relationship between actual stomatal aperture and stomatal conductance, measured with a porometer, also was examined on leaves before and after exposure to SO₂.

A distinction between uninjured and injured regions was clearly visible on leaves after exposure to 1.5 microliters per liter SO₂ for less than an hour. During the exposure, the mean value of apertures for many stomata, which indicates stomatal conductance and transpiration rate, tended to decrease simultaneously in the uninjured and injured regions. However, the rate of decrease in the injured region was slower than that in the uninjured region because of a transient opening induced by water-soaking in the injured region. The transient opening was less common in stomata near veins and veinlets.

There was a good correlation between pore width and stomatal conductance measured with a porometer before exposure to SO₂. This correlation continued in leaves exposed to SO₂ until visible, irreversible injury occurred, but then it disappeared.

The results of these experiments indicate the necessity of continuous observation of individual stomata under the microscope to understand the effects of air pollutants such as SO₂ on stomatal behavior.

     

Stomatal Responses to CO(2) in Paphiopedilum and Phragmipedium: Role of the Guard Cell Chloroplast

A role of the guard cell chloroplasts in the CO₂ response of stomata was investigated through a comparison of the leaf gas exchange characteristics of two closely related orchids: Paphiopedilum harrisianum, which lacks guard cell chloroplasts and Phragmipedium longifolium, which has chlorophyllous guard cells. Leaves of both species had an apparent quantum yield for assimilation of about 0.05, with photosynthesis saturating at 0.300 to 0.400 millimoles per square meter per second. CO₂ curves were obtained by measuring steady-state assimilation and stomatal conductance under 0.180 or 0.053 millimoles per square meter per second white light, or darkness, at 0 to 400 microliters per liter ambient CO₂. The response of assimilation to changes in CO₂ was similar in the two species, but the response of conductance was consistently weaker in Paphiopedilum than in Phragmipedium. The data suggest involvement of guard cell chloroplasts in the stomatal response to CO₂ and in the coupling of assimilation and conductance in the intact leaf.     

Changing Responses of Stomata to Abscisic Acid and CO2 as Leaves and Plants Age

Willmer, C. M., Wilson, A. B. and Jones, H. G. 1988. Changingresponses of stomata to abscisic acid and CO₂ as leaves andplants age.—J. exp. Bot. 39: 401–410. Stomatal conductances were measured in ageing leaves of Commelinacommunis L. as plants developed; stomatal responses to CO₂ andabscisic acid (ABA) in epidermal strips of C. communis takenfrom ageing leaves of developing plants and in epidermal stripsfrom the same-aged leaves (the first fully-expanded leaf) ofdeveloping plants were also monitored. Stomatal behaviour wascorrelated with parallel measurements of photosynthesis andleaf ABA concentrations. Stomatal conductance in intact leavesdecreased from a maximum of 0-9 cm s^{– 1} at full leaf expansionto zero about 30 d later when leaves were very senescent. Conductancesdeclined more slowly with age in unshaded leaves. Photosynthesisof leaf slices also declined with age from a maximum at fullleaf expansion until about 30 d later when no O₂ exchange wasdetectable. Exogenously applied ABA (0.1 mol m^{– 3}) didnot affect respiration or photosynthesis. In epidermal stripstaken from ageing leaves the widest stomatal apertures occurredabout 10 d after full leaf expansion (just before floweringbegan) and then decreased with age; this decrease was less dramaticin unshaded leaves. The inhibitory effects of ABA on stomatalopening in epidermal strips decreased as leaves aged and wasgreater in the presence of CO₂ than in its absence. When leaveswere almost fully-senescent stomata were still able to open.At this stage, guard cells remained healthy-looking with greenchloroplasts while mesophyll cells were senescing and theirchloroplasts were yellow. Similar data were obtained for stomatain epidermal strips taken from the same-aged leaves of ageingplants. The inhibitory effects of ABA on stomatal opening alsodecreased with plant age. In ageing leaves both free and conjugated ABA concentrationsremained low before increasing dramatically about 30 d afterfull leaf expansion when senescence was well advanced. Concentrationsof free and conjugated ABA remained similar to each other atall times. It is concluded that the restriction of stomatal movements inintact leaves as the leaves and plants age is due mainly toa fall in photosynthetic capacity of the leaves which affectsintracellular CO₂ levels rather than to an inherent inabilityof the stomata to function normally. Since stomatal aperturein epidermal strips declines with plant and leaf age and stomatabecome less responsive to ABA (while endogenous leaf ABA levelsremain fairly constant until leaf senescence) it is suggestedthat some signal, other than ABA, is transmitted from the leafor other parts of the plant to the stomata and influences theirbehaviour. Key words: Abscisic acid, CO₂, Commelina, leaf age, senescence, stomatal sensitivity     

Stomatal Responses to Two Herbicidal Auxins

The effects of 1-naphthylacetic acid (NAA) and 2-naphthoxyaceticacid (NOXA) on stomatal opening on illumination of excised,turgid leaves of Stachytarpheta indica were investigated bymicroscopic examination of abaxial epidermises fixed in absoluteethanol. Both chemicals were effective in restricting, but notcompletely preventing, stomatal opening and suppressing starchhydrolysis and potassium accumulation in the guard cells. Therepressive effects were only partly reversed by CO₂-free air.It is concluded that NAA and NOXA do not greatly affect passiveopening mediated by changes in the leaf water balance, but partlysupress photoactive opening by arresting starch hydrolysis andpotassium accumulation in the guard cells and partly by disturbingthe intercellular CO₂ concentration. A possible link betweenstarch hydrolysis and potassium accumulation in the guard cellsis briefly mentioned.     

Responses to CO2 Enrichment by Two Genotypes of Arabidopsis thaliana Differing in their Sensitivity to Nutrient Availability

The responses of two genotypes of Arabidopsis thaliana, whichdiffer in their sensitivities to nutrients to present and predictedfuture CO₂ concentration were determined under rich vs. poornutrient regimes on the basis of both single traits and thewhole plant. Based on individual traits, the two genotypes respondedsimilarly to CO₂ enrichment for all the traits measured exceptfor rate of increase in crown diameter, for which a decreasewas observed in the less nutrient-sensitive genotype grown atincreased CO₂. Based on the overall response of the whole plant,by analysing groups of plant traits using multivariate analysis,the two genotypes differed substantially from one another andboth responded more strongly to nutrient availability than toCO₂ concentration, especially for traits measured at harvestthat related to reproductive fitness. The less nutrient-sensitivegenotype also showed a weaker overall response to CO₂, and thepattern of the overall response was strikingly similar at differentnutrient supply. In contrast, the more nutrient-sensitive genotyperesponded more strongly to CO₂ than the less nutrient-sensitivegenotype, and responded differently to CO₂ at low vs. high nutrientavailability.Copyright 1995, 1999 Academic Press Plasticity, CO₂ enrichment, nutrient status, nutrient x CO₂ interaction, Arabidopsis thaliana, canonical analysis     

Influence of CO2 on Stomatal Numbers

From nine different plant species grown at 1500 cm³ m^-3 CO₂ five responded with a significant increase in stomatal numbers per mm² as compared with plants grown under normal air conditions. Within a collection of twelve french bean cultivars remarkable cultivar differences with regard to the CO₂ enhancement effect on stomatal numbers was found.     

The Influence of Prior Water Stress and Abscisic Acid Foliar Spraying on Stomatal Responses to CO2, IAA, ABA, and Calcium in Leaves of Solanum melongena

The influence of a water stress or foliar ABA spraying pretreatmenton stomatal responses to water loss, exogenous ABA, IAA, Ca²⁺,and CO₂ were studied using excised leaves of Solanum melongena.Both pretreatments increased stomatal sensitivity of water loss,in the presence and absence of CO₂, but decreased stomatal sensitivityto exogenous ABA. CO₂ greatly reduced the effect of exogenouslyapplied ABA. IAA decreased leaf diffusion resistance for controland ABA sprayed leaves, but did not influence the LDR of previouslywater-stressed leaves. CA²⁺ did not influence LDR of any leavesof any treatments. Key words: Water stress, stomatal response, pretreatments     

Drawing the future: Stomatal response to CO2 levels

Gas exchange between the plant and the atmosphere is regulated by controlling both the stomatal density and the aperture of the stomatal pore. Environmental factors such as light, the level of atmospheric CO₂ and hormones regulate stomatal development and/or function. Because atmospheric CO₂ levels have been rising since the Industrial Revolution, and it is predicted that they will continue doing so in the future, an understanding of the CO₂ signalling mechanisms in the stomatal responses will help to know how plants were in the past and will allow predicting how they will respond to climate change in the near future. This article covers the recent knowledge of the CO₂ signalling mechanisms that regulate both stomatal function and development.Key words: Arabidopsis, CO₂, development, epidermis, gas exchange, leaf, patterning, stoma     

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.     

Stomatal responses to light and CO2 in greening wheat leaves

The development of two types of stomatal transpiration, oneinduced by light (light-induced stomatal transpiration) andthe other induced by CO₂-free air in the dark (CO₂-sensitivestomatal transpiration), in greening leaves of wheat (Triticumaestivum L.) was studied in respect to the development of CO₂uptake and chlorophyll formation. Light-induced stomatal transpirationwas not observed at all in etiolated leaves and was generatedafter 3 hr of illumination for greening, when the activity ofCO₂ uptake was generated. CO₂-sensitive stomatal transpirationwas low in etiolated leaves and started to increase at the sametime during greening as the start of CO₂ uptake. The activitiesof both light-induced and CO₂-sensitive stomatal transpirationincreased as the activity of CO₂ uptake and the chlorophyllcontent increased. Pre-illumination of etiolated leaves for1 min followed by 4 hr of dark incubation eliminated the lagfor the development of the two types of stomatal transpirationand CO₂ uptake. (Received September 4, 1978; )