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; )     

Patterns of Stomatal Behaviour, Transpiration, and CO2 Exchange in Pea Following Infection by Powdery Mildew (Erysiphe pisi)

A comparison was made of stomatal behaviour, and related phenomena,between leaves of garden pea (Pisum sativum cv. Feltham First)inoculated with powdery mildew fungus (Erysiphe pisi) and uninfectedleaves on healthy plants. Twenty four hours after inoculation,stomata opened more widely in the light in infected leaves thanin healthy leaves. Thereafter, stomatal opening was progressivelyreduced by infection and stomata failed to close completelyin the dark until, 7 d after inoculation, all movements ceasedand stomata remained partly open. Transpiration in the lightfollowed closely the pattem of stomatal opening and, after anearly increase compared with healthy controls, was progressivelyreduced by infection. Evidence is presented that transpirationfrom the fungus was less than the reduction in transpiraationfrom the leaf which was caused when development of the myceliumincreased the boundary layer resistance of the leaf. Seven daysafter inoculation, transpiration in the dark was greater frominfected leaves than from healthy leaves because of partly openstomata in the dark. Net photosynthesis in infected leaves was reduced within 24h of inoculation to a level below that found in healthy leavesand thereafter it declined progressively. The initial reductionwas due to a transient increase in photorespiration, for whenthe glycolate pathway was inhibited by a 2% O₂ concentrationthere was no difference between the (gross) photosynthetic ratesof healthy and infected leaves. Changes in photorespirationrate were confirmed from the interpretation of the CO₂ burston darkening. Reduced stomatal opening was a contributory causeof the reduction in net photosynthesis in the later stages ofinfection. Since the rate of gross photosynthesis, but not therate of photorespiration, of infected plants fell below thatof healthy plants, and infected plants had a higher rate ofrelease of CO₂ in the dark than healthy plants from the thirdday after inoculation onwards, infected plants consume an increasinglygreater proportion of their photosynthate in respiratory processesthan do healthy plants. The CO₂ compensation point of infectedplants increased at every time of sampling after inoculation.     

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     

The Response of Oxygen and Carbon Dioxide Exchanges and Root Activity to Short Term Water Stress in Soybean

The gross and net O₂ evolution together with O₂ uptake, CO₂assimilation, transpiration, shoot dark respiration, root respirationand ion uptake of a soybean plant were studied during 19 d whichincluded two periods of water stress. O₂ uptake was measuredusing ¹⁸O₂ as a tracer. Short term water stress induced immediateand lasting effects: (1) reduction of light interception bywilting, (2) limitation of the total reducing equivalent producedby the electron transport chain, (3) decrease of stomatal conductancereducing both losses of water and the entry of CO₂ for assimilation,(4) relative stimulation of O₂ uptake. The ratio of O₂ uptaketo CO₂ assimilation changed from 1.0 before stress to 1.4 forseveral days after. Root respiration was less affected by thestress than ion uptake and shoot gas exchanges. Key words: Photosynthesis, Photorespiration, Transpiration, Shoot and root respiration, Ion uptake, Water stress, Glycine max. L.     

Diurnal fluctuation of light and dark CO2 fixation in peeled and unpeeled leaves of Bryophyllum daigremontiana

Diurnal fluctuation of light and dark CO₂ fixation in peeledand unpeeled leaves of Bryophyllum daigremontiana was examined.A distinct difference in light CO₂ fixation was observed inunpeeled leaves but not in peeled ones. No measurable differencein dark CO₂ fixation was observed in either type. These resultsindicate that the leaves of CAM plants have a high capacityfor CO₂ fixation in the daytime, but it is suppressed by theclosing of the stomata. Also, the rapid depression of CO₂ uptakewhen the illumination was directed at on dark acidified leavescould be prevented by peeling off the epidermis. The net photosyntheticCO₂ uptake in peeled leaves was 77 µmoles/mg chllrophyll/hrin the 3rd leaf and 62 in the 4th leaf. (Received August 7, 1978; )     

Stomatal Responses of Variegated Leaves to CO2 Enrichment

The responses of stomatal density and stomatal index of fivespecies of ornamental plants with variegated leaves grown attwo mole fractions of atmospheric CO₂ (350 and 700 µmolmol^-1) were measured. The use of variegated leaves allowed anypotential effects of mesophyll photosynthetic capacity to beuncoupled from the responses of stomatal density to changesin atmospheric CO₂ concentration. There was a decrease in stomataldensity and stomatal index with CO₂ enrichment on both white(unpigmented) and green (pigmented) leaf areas. A similar responseof stomatal density and index was also observed on areas ofleaves with pigmentation other than green indicating that anydifferences in metabolic processes associated with colouredleaves are not influencing the responses of stomatal densityto CO₂ concentrations. Therefore the carboxylation capacityof mesophyll tissue has no direct influence on stomatal densityand index responses as suggested previously (Friend and Woodward1990 Advances in Ecological Research 20: 59-124), instead theresponses were related to leaf structure. The stomatal characteristics(density and index) of homobaric variegated leaves showed agreater sensitivity to CO₂ on green portions, whereas heterobaricleaves showed a greater sensitivity on white areas. These resultsprovide evidence that leaf structure may play an important rolein determining the magnitude of stomatal density and index responsesto CO₂ concentrations.Copyright 1995, 1999 Academic Press Leaf structure, photosynthesis, stomatal conductance, CO₂, stomatal density, stomatal index     

Diurnal changes in malate-decarboxylation activity in the leaves of a CAM plant, Bryophyllum daigremontianum

Bryophyllum diagremontianum plants grown under light-dark regimeswere exposed to one more cycle of the regime or to continuousdarkness for 24 hr. Photosynthetic O₂ evolution by leaf segmentsfrom these plants was investigated in the presence of 15 mMNaHCO₃ (CO₂-dependent O₂ evolution) or in the absence of CO₂(malate-dependent O₂ evolution). The malate-dependent O₂ evolutionserved as an index of the activity of malate decarboxylation.Malate content was respectively 67, 64 and 85 µmoles/g.fwin leaves measured at 7 hr 30 min in light and 6 hr 26 min inthe dark from plants under the light-dark regime (light 12 hr/dark12 hr) and those measured at 6 hr 26 min in the dark from plantsunder the continuous dark regime. The malate- and CO₂-dependentphotosynthetic O₂ evolutions in the same leaves were 9.7 and22, 0.2 and 17, and 16 and 26 µmoles/g.fw.hr, respectively.Thus, the diurnal change in capacity for malate-dependent O₂evolution was relieved by continuous dark treatment. These results suggest that the diurnal change in malate decarboxylationin this crassulacean acid metabolism plant does not occur byan endogenous rhythm. This further indicates lack of an endogenousrhythm for the influx-efflux of malate across the vacuole andin malate decarboxylation enzyme activity. (Received August 1, 1979; )     

Effects of dark preincubation and chloramphenicol on blue light-induced CO2 incorporation in Chlorella cells

Chlorella cells incubated in the dark longer than 12 hr showedpronounced blue light-induced ¹⁴CO₂ fixation into aspartate,glutamate, malate and fumarate (blue light effect), whereasthose kept under continuous light showed only a slight bluelight effect, if any. 2) During dark incubation of Chlorellacells, phosphoenolpyruvate carboxylase activity and the capacityfor dark ¹⁴CO₂ fixation decreased significantly, whereas ribulose-1,5-diphosphatecarboxylase activity and the capacity for photosynthetic ¹⁴CO₂fixation (measured under illumination of white light at a highlight intensity) did not decrease. 3) In cells preincubatedin the dark, intracellular levels of phosphoenolpyruvate and3-phosphoglycerate determined during illumination with bluelight were practically equal to levels determined during illuminationwith red light. 4) The blue light effect was not observed incells incubated widi chloramphenicol, indicating that blue light-inducedprotein synthesis is involved in the mechanism of the effect. (Received April 9, 1971; )     

Physiological and Anatomical Effects of Growth Temperature on Phaseolus vulgaris L. Cultivars

Two Phaseolus vulgaris L. cultivars were grown at 20/15, 25/20,and 30/25 °C day/night temperatures in growth chambers witha 16 h thermoperiod corresponding to the photoperiod. When thefirst trifoliolate leaf was fully expanded rates of CO₂ exchange(CER) were measured at 27 °C and saturating light usinginfrared gas analysis. Stomatal (r_s) and mesophyll resistances,CO₂ compensation points, activities of the enzymes ribulosebisphosphate carboxylase (RuBPCase), glycolate oxidase (GAO),malate dehydrogenase (MDH), and fructose-1, 6 diphosphate (FDP),chlorophyll content, Hill activities, and leaf anatomy at boththe light and electron microscope level were also investigatedin these leaves. Rates of CO₂ exchange in the light, transpiration rate, andchlorophyll content increased with increasing growth temperaturewhile leaf thickness, specific leaf weight, RuBPCase activity,compensation point, and stomatal resistance decreased. Mesophyllresistance also decreased when calculated assuming zero chloroplastCO₂ concentration (rm, o), but not when calculated assuminga chloroplast CO₂ concentration equal to the CO₂ compensationconcentration (rm, g). Average leaf size was maximal in 25/20°C plants while dark respiration, MDH activity, stomataldensity, and starch were minimal. The activities of GAO andFDP and Hill activity were not affected by temperature pretreatment.     

Photosynthesis and Diffusion Conductance of the Valencia Orange Fruit under Field Conditions

CO₂ uptake and diffusion conductance of Valencia orange fruits(Citrus sinensis L. Osbeck) were measured in the field duringthe growing season of 1977/78 to ascertain if, as in the leaf,stomata control photosynthesis and transpiration under changingenvironmental conditions. Measurements were made on 15 yearold trees grown in a sandy loam soil and receiving either adry or a wet treatment. Fruit diffusive conductance was measuredwith a modified water vapour diffusion conductance meter andgross photosynthesis was measured with a ¹⁴CO₂ uptake meter.Photosynthetically active radiation (PAR) was measured witha quantum sensor. Fruits exposed to light assimilated CO₂ ata rate which was 25–50% of that assimilated by leaves.The uptake was dependent on fruit size, PAR, chlorophyll content,and on diffusive conductance of the fruit epidermis. Epidermalconductance showed a diurnal trend which was similar in shapeto that of the leaf except in the late afternoon. Cuticularconductance of the fruit was calculated and ranged between 0.22and 0.30 mm s^–1. It was speculated that the CO₂ uptakeby the fruit could support the growth of flavedo cell layerswhen exposed to light. Dry soil caused an increase in the ¹⁴CO₂uptake by fruit possibly caused by the increased potential areaof the stomatal opening per unit of fruit surface area.     

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     

Comparison of Palaeobotanical Observations with Experimental Data on the Leaf Anatomy of Durmast Oak [Quercus petraea(Fagaceae)] in Response to Environmental Change

To test whether stomatal density measurements on oak leaf remainsare reliable tools for assessing palaeoatmospheric carbon dioxideconcentration [CO₂], under changing Late Miocene palaeoenvironmentalconditions, young seedings of oak (Quercus petraea,Liebl.) weregrown at elevatedvs.ambient atmospheric [CO₂] and at high humiditycombined with an increased air temperature. The leaf anatomyof the young oaks was compared with that of fossil leaves ofthe same species. In the experiments, stomatal density and stomatalindex were significantly decreased at elevated [CO₂] in comparisonto ambient [CO₂]. Elevated [CO₂] induced leaf cell expansionand reduced the intercellular air space by 35%. Leaf cell sizeor length were also stimulated at high air humidity and temperature.Regardless of a temperate or subtropical palaeoclimate, leafcell size in fossil oak was not enhanced, since neither epidermalcell density nor length of the stomatal apparatus changed. Theabsence of these effects may be attributed to the phenologicalresponse of trees to climatic changes that balanced temporalchanges in environmental variables to maintain leaf growth underoptimal and stable conditions.Quercus petraea,which evolvedunder recurring depletions in the palaeoatmospheric [CO₂], maypossess sufficient phenotypic plasticity to alter stomatal frequencyin hypostomatous leaves allowing high maximum stomatal conductanceand high assimilation rates during these phases of low [CO₂].Copyright1998 Annals of Botany Company Atmospheric CO₂, high humidity, elevated temperature,Quercus petraea,durmast oak, Late Miocene, palaeoclimates, leaf anatomy, stomatal density, stomatal index     

Photosynthetic Carbon Reduction and Carbon Oxidation Cycles are the Main Electron Sinks for Photosystem II Activity During a Mild Drought

Stomatal closure can explain the inhibition of net CO₂ uptakeby a leaf subjected to a mild drought: the photosynthetic apparatusappears resistant to lack of water. Changes in both the watercontent of leaves maintained in a constant environment and theambient CO₂ molar fraction during measurements on well-hydratedleaves lead to similar effects on net CO₂ uptake and whole chainelectron transport as estimated by leaf chlorophyll fluorescencemeasurements. In particular, it is shown that photosystem II(PSII) functioning and its regulation are not qualitativelychanged during desiccation and that the variations in PSII photochemistrycan simply be understood by changes in substrate availabilityin this condition. Moreover, an analysis of the literature showsthat when inhibition of net CO₂ uptake by C₃ leaves under drought(Phaseolus vulgaris L., Helianthus annus L. and Solanum tuberosumL.) was lower than 80 %, elevated CO₂ completely restored thephotosynthetic capacity. The CO₂ molar fraction in the chloroplastsdeclines as stomata close in drying leaves. As a consequence,in C₃ plants, ribulose-1,5-bisphosphate oxygenation increasesand becomes the main sink for photosynthetic electrons. Dependingon the prevailing photon flux density, the O₂ uptake throughphotorespiratory activity can entirely replace carbon dioxideas an electron acceptor, or not. The rate of the Mehler reactionremains low and unchanged during desiccation. However, droughtcould also involve CO₂-sensitive modification of the photosyntheticmetabolism depending on plant growth conditions and possiblyalso on plant species.     

Development of Lipid Synthesis from CO2 in Avena Leaves during Greening of Etiolated Seedlings

The development of the lipid synthesizing system in Avena leafsections was examined in connection with carbon fixation duringthe greening of etiolated seedlings under light. During theinitial 2 h illumination there was a low level of CO₂ fixationby PEP carboxylation, but its products, malate and citrate,did not serve as a carbon source for lipid synthesis, althoughlipid synthesis from acetate had already been established. Withthe initiation of Calvin cycle activity after the initial 2h illumination, lipid synthesis began, with CO₂ fixed by RuBPcarboxylation serving exclusively as the carbon source. Fattyacid synthesis in the leaves during the initial 3 h illumination,unlike the fatty acid synthesis thereafter, was insensitiveto thiolactomycin, an inhibitor of type II fatty acid synthetasecontained in the plastids, and was not dependent on light, incontrast to light-dependent activity in greened leaves. The distribution of ¹⁴C incorporated into lipid molecules fromNaH¹⁴CO₃ showed an equal ratio of ¹⁴C in fatty acid, glyceroland choline moieties of labeled phosphatidylcholine, but a denserradioactivity in the galactose moiety than in the residual moietyof mono- and di-galactosyldiacylglycerols. This suggests a regulatedsupply of glycerol, choline and fatty acid moieties for phosphatidylcholinesynthesis, and an excess supply of galactose to diacylglycerolmoiety for galactosyldiacylglycerol synthesis in Avena leaves. (Received October 31, 1984; Accepted January 25, 1985)     

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     

Elevated carbon dioxide affects the patterning of subsidiary cells in Tradescantia stomatal complexes

The influence of elevated CO₂ concentration (670 ppm) on thestructure, distribution, and patterning of stomata in Tradescantialeaves was studied by making comparisons with plants grown atambient CO₂. Extra subsidiary cells, beyond the normal complementof four per stoma, were associated with nearly half the stomatalcomplexes on leaves grown in elevated CO₂. The extra cells sharedcharacteristics, such as pigmentation and expansion, with thetypical subsidiary cells. The position and shape of the extrasubsidiary cells in face view differed in the green and purplevarieties of Tradescantia. Substomatal cavities of complexeswith extra subsidiary cells appeared larger than those foundin control leaves. Stomatal frequency expressed on the basisof leaf area did not differ from the control. Stomatal frequencybased on cell counts (stomatal index) was greater in leavesgrown in CO₂-enriched air when all subsidiary cells were countedas part of the stomatal complex. This difference was eliminatedwhen subsidiary cells were included in the count of epidermalcells, thereby evaluating the frequency of guard cell pairs.The extra subsidiary cells were, therefore, recruited from theepidermal cell population during development. Stomatal frequencyin plants grown at elevated temperature (29 C) was not significantlydifferent from that of the control (24 C). The linear aggregationsof stomata were similar in plants grown in ambient and elevatedCO₂. Since enriched CO₂ had no effect on the structure or patterningof guard cells, but resulted in the formation of additionalsubsidiary cells, it is likely that separate and independentevents pattern the two cell types. Plants grown at enrichedCO₂ levels had significantly greater internode lengths, butleaf area and the time interval between the appearance of successiveleaves were similar to that of control plants. Porometric measurementsrevealed that stomatal conductance of plants grown under elevatedCO₂ was lower than that of control leaves and those grown atelevated temperature. Tradescantia was capable of regulatingstomatal conductance in response to elevated CO₂ without changingthe relative number of stomata present on the leaf. Key words: Elevated CO₂, stomata, subsidiary cells, patterning     

Root Water Uptake, Leaf Water Storage and Gas Exchange of a Desert Succulent: Implications for Root System Redundancy

A technique used for hydroponics was adapted to measure instantaneousroot water uptake from the soil for a leaf succulent CAM species,Agave deserti. Comparisons were made to previously modelledwater fluxes for A. deserti and to Encelia farinosa, a non-succulentC₃species. Net CO₂uptake and transpiration forA. deserti underwell-watered conditions occurred primarily at night whereasroot water uptake was relatively constant over 24 h. Leaf thicknessdecreased when transpiration commenced and then increased whenrecharge from the stem and soil occurred, consistent with previousmodels. A drought of 90 d eliminated net CO₂uptake and transpirationand reduced the water content of leaves by 62%. Rewetting theentire root system for 7 d led to a full recovery of leaf waterstorage but only 56% of maximal net CO₂uptake. Root water uptakewas maximal immediately after rewetting, which replenished rootwater content, and decreased to a steady rate by 14 d. Whenonly the distal 50% of the root system was rewetted, the timefor net CO₂uptake and leaf water storage to recover increased,but by 30 d gas exchange and leaf water storage were similarto 100% rewetting. Rewetting 10 or 20% of the root system resultedin much less water uptake; these plants did not recover leafwater storage or gas exchange by 30 d after rewetting. A redundancyin the root system of A. deserti apparently exists for dailywater uptake requirements under wet conditions but the entireroot system is required for rapid recovery from drought.Copyright1999 Annals of Botany Company Agave deserti Engelm., desert, drought, gas exchange, rewetting, roots, succulent, water uptake.     

Simultaneous CO2- and 16O2/18O2-gas exchange and fluorescence measurements indicate differences in light energy dissipation between the wild type and the phytochrome-deficient aurea mutant of tomato during water stress

The CO₂-, H₂O- and ¹⁶O₂/¹⁸O₂ isotopic-gas exchange and the fluorescencequenching by attached leaves of the wild-type and of the phytochrome-deficienttomato aurea mutant was compared in relation to water stressand the photon fluence rate. The chlorophyll content of aurealeaves was reduced and the ultra-structure of the chloroplastswas altered. Nevertheless, the maximum rate of net CO₂ uptakein air by the yellow-green leaves of the aurea mutant was similarto that by the dark-green wild-type leaves. However, less O₂was produced by the leaves of the aurea mutant than by leavesof the wild-type. This result indicates a reduced rate of photosyntheticelectron flux in aurea mutant leaves. No difference in bothphotochemical and non-photochemical fluorescence quenching wasfound between wild-type and aurea mutant leaves. Water stresswas correlated with a reversible decrease in the rates of bothnet CO₂ uptake and transpiration by wild-type and aurea mutantleaves. The rate of gross ¹⁶O₂ evolution by both wild-type andaurea mutant leaves was fairly unaffected by water stress. Thisresult shows that in both wild-type and aurea leaves, the photochemicalprocesses are highly resistant to water stress. The rate ofgross ¹⁸O₂ uptake by wild-type leaves increased during waterstress when the photon fluence rate was high. Under the sameconditions, the rate of gross ¹⁸O₂ uptake by ^aurea mutant leavesremained unchanged. The physiological significane of this differencewith respect to the (presumed) importance of oxygen reductionin photoprotection is discussed. Key words: Water stress, gas exchange, fluorescence quenching, Lycopersicon esculentum, mutant (tomato, aurea), energy dissipation     

Stomatal Density and Index of Fossil Plants Track Atmospheric Carbon Dioxide in the Palaeozoic

It has been demonstrated that the leaves of a range of foresttree species have responded to the rising concentration of atmosphericCO₂ over the last 200 years by a decrease in both stomatal densityand stomatal index. This response has also been demonstratedexperimentally by growing plants under elevated CO₂ concentrations.Investigation of Quaternary fossil leaves has shown a correspondingstomatal response to changing CO₂ concentrations through a glacial-interglacialcycle, as revealed by ice core data. Tertiary leaves show asimilar pattern of stomatal density change, using palynologicalevidence of palaeo-temperature as a proxy measure of CO₂ concentration.The present work extends this approach into the Palaeozoic fossilplant record. The stomatal density and index of Early Devonian,Carboniferous and Early Permian plants has been investigated,to test for any relationship that they may show with the changesin atmospheric CO₂ concentration, derived from physical evidence,over that period. Observed changes in the stomatal data givesupport to the suggestion from physical evidence, that atmosphericCO₂ concentrations fell from an Early Devonian high of 10-12times its present value, to one comparable to that of the presentday by the end of the Carboniferous. These results suggest thatstomatal density of fossil leaves has potential value for assessingchanges in atmospheric CO₂ concentration through geologicaltime.Copyright 1995, 1999 Academic Press Aglaophyton major, Sawdonia ornata, Swillingtonia denticulata, Lebachia frondosa, Juncus effusus, Psilotum nudum, Araucaria heterophylla, stomatal density, stomatal index, Palaeozoic CO₂     

Effects of Different Nitrogen Sources and Concentrations on CAM Photosynthesis in Kalanchoe blossfeldiana

When Kalanchoë blossfeldiana Poelln. cv. Hikan plants werecultured in solutions containing 0.2, 1.0, 5.0 or 10 mM of nitrateor ammonium under a long-day photoperiod, some criteria of CAM(Crassulacean acid metabolism) photosynthesis (diurnal changesof CO₂ uptake, titratable acidity and malate content in leaves)were examined. The plants absorbed 90 to 100% of CO₂ duringthe light phase regardless of the supplied nitrogen. Nitrate-grownplants absorbed about 10% of CO₂ during the dark phase regardlessof the supplied concentration, whereas in ammonium-grown plantsthe nocturnal CO₂ uptake occurred at 0.2 mM, at which the plantsdepleted nitrogen and no uptake was observed at the higher concentrations.Changes of nocturnal increase in titratable acidity and malatecontent almost corresponded with the changes in the amount ofnocturnal CO₂ uptake. Also K. daigremontiana plants suppliedwith 10 mM of ammonium had a less CAM-like pattern of diurnalCO₂ uptake than the plants supplied with 10 mM of nitrate. Theseresults suggest that a sufficient supply of ammonium depressesCAM photosynthesis.