Isoforms of NADP-Malic Enzyme from Mesembryanthemum crystallinum L. That are Involved in C3 Photosynthesis and Crassulacean Acid Metabolism

Exposure of the facultative halophyte Mesembryanthemum crystallinumL. to salt stress induces a shift from C₃ photosynthesis toCrassulacean acid metabolism (CAM). During induction of CAM,the activity of NADP-malic enzyme (EC 1.1.1.40 [EC] ) increased asmuch as 12-fold in leaves, while the enzymatic activity in rootsfell to half of the original level. These changes in the activityof the enzyme corresponded to changes in levels of the enzymeprotein. NADP-malic enzymes extracted from leaves in the C₃and CAM modes could be distinguished by differences in electrophoreticmobility during electrophoresis on a non-denaturing polyacrylamidegel. NADP-malic enzyme extracted from roots in the C₃-mode andin the CAM mode migrated as fast as the enzyme extracted fromleaves in the CAM mode on the same gel. Although the patternof peptide fragments from NADP-malic enzyme from CAM-mode leaveswas similar to that from C₃-mode leaves, as indicated by peptidemapping, both immunoprecipitation and an enzyme-linked immunosorbentassay revealed some antigenic differences between the enzymesextracted from leaves in the C₃ and the CAM modes. These resultssuggest the existence of at least two isoforms of NADPmalicenzyme that differ in their levels of expression during inductionof CAM. (Received April 21, 1994; Accepted September 5, 1994)     

14CO2 Pulse-Chase Labelling in Clusia minor L.

Conditions and maintenance of growth were chosen so that plantsof Clusia minor L. were obtained which showed the C₃- and CAM-modes of CO₂-exchange, respectively. C. minor is known to accumulateconsiderable amounts of citric acid in addition to malic acidduring the dark-phase of CAM. ¹⁴CO₂-pulse-chase experiments were performed with these plants.Patterns of labelling during the pulse and redistribution oflabel during the chase in the C₃-mode were as expected for C₃-photosynthesis.Pulse-labelling in the CAM-mode during the last hour of thelight period, during the first part of the dark period and duringthe last hour of the dark period always led to an almost exclusiveincorporation of label into malate. Redistribution of labelfrom malate after the pulse at the end of the dark period duringthe chase in the subsequent light period followed the patternexpected for light-dependent reassimilation of CO₂ remobilizedfrom malate in CAM during the light period. During the chasesin the dark period, label was transferred from ^l4C-malate tocitrate. This suggests that during accumulation of citric acidin the dark period of CAM in C. minor, citrate is synthesizedin the mitochondria from malate or oxaloacetate after formationof malate via phosphoenolpyruvate carboxylase. The experiment also showed that no labelled compounds are exportedfrom leaves in the CAM-mode during the dark period. In plantsof the C₃-mode the roots proved to be strong sinks. Key words: Clusia minor, labelling, pulse-chase, ¹⁴CO₂     

Malate Decarboxylation by Mitochondria of the Inducible Crassulacean Acid Metabolism Plant Mesembryanthemum crystallinum

Mitochondria isolated from leaves of Mesembryanthemum crystallinumoxidized malate by both NAD malic enzyme and NAD malate dehydrogenase.Rates of malate oxidation were higher in mitochondria from plantsgrown at 400 mil NaCl in the rooting medium and performing Crassulaceanacid metabolism (CAM) than in mitochondria from plants grownat 20 mM NaCl and exhibiting C₃-photosynthetic CO₂ fixation.The mitochondria isolated from plants both in the CAM and C₃modes were tightly coupled and gave high respiratory control.At optimum pH for malate oxidation (pH 7.0), pyruvate was themajor product in mitochondria from CAM-M. crystallinum, whereasmitochondria from C₃-M. crystallinum produced predominantlyoxaloacetate. Both the extracted NAD malic enzyme in the presenceof CoA and the oxidation of malate to pyruvate by the mitochondriafrom plants in the CAM mode had a pH optimum around 7.0 withactivity declining markedly above this pH. The activity of NAD-malicenzyme, expressed on a cytochrome c oxidase activity basis,was much higher in mitochondria from the CAM mode than the C₃mode. The results indicate that mitochondria of this speciesare adapted to decarboxylate malate at high rates during CAM. ¹Current address: Lehrstuhl für Botanik II, UniversitätWurzburg, Mittlerer Dallenbergweg 64, 8700 Würzburg, WestGermany. ²Current address: KD 120, Chemical Research Division, OntarioHydro, 800 Kipling Avenue, Toronto, Ontario M8Z5S4, Canada. ³Current address: Department of Botany, Washington State University,Pullman, Washington 99164-4230, U.S.A. (Received March 13, 1986; Accepted September 18, 1986)     

Induction of Glucose 6-Phosphate Transport Activity in Chloroplasts of Mesembryanthemum crystallinum by the C3-CAM Transition

To study possible changes in the transport metabolites betweenchloroplasts and cytoplasm during CAM induction of Mesembryanthemumcrystallinum, we compared substrate specificity of P1¹ translocator(s)in isolated chloroplasts from the C₃ and CAM-induced plants.The [¹⁴C]glu-cose 6-phosphate (G6P) transport activity was significantonly in the chloroplasts of CAM-mode plants and not detectablein those of C₃-mode, while a similar high rate of [³²P]P_i uptakewas observed with both types of chloroplasts. Kinetic analysisof G6P uptake in the CAM chloroplasts showed a high V_max [10.6µmol (mg Chl)^–1 h^–1] and a comparatively lowK_m value (0.41 mM); the latter was similar to K_i values of P_i,3-phosphoglycerate and phospho-enolpyruvate, 0.30, 0.34 and0.47 mM, respectively. On the other hand, [32P]Pi uptake inthe CAM chloroplasts was inhibited competitively by G6P witha K_i value (8.4 mM) 20-fold higher than the K_m value for G6Puptake, while that in C₃ chloroplasts was not inhibited at all.These results suggest that a new G6P/P_i, counterexchange mechanismis induced in the chloroplast envelope of CAM-induced M. crystallinumin addition to the ordinary type of P, translocator, that cannottransport G6P, already present in the C₃-type chloroplasts. (Received March 17, 1997; Accepted May 10, 1997)     

Properties of Leaf NAD-Malic Enzyme from the Inducible Crassulacean Acid Metabolism Species Mesembryanthemum crystallinum

NAD-malic enzyme (NAD-ME) functions to decarboxylate malatein the light in leaves of certain species displaying Crassulaceanacid metabolism (CAM). The properties of NAD-ME in desaltedextracts from the inducible CAM species, Mesembryanthemum crystallinumwere examined. The shapes of the malate saturation curve andthe activity versus pH curve at 10 mM malate were dependenton the presence of the activator CoA. The malate saturationcurve was sigmoidal in the absence of an activator and hyperbolicin the presence of CoA. The pH optimum with 10mM malate andMn²⁺ as cofactor was as low as 6.5 without an activator, andincreased to 7.2 in the presence of CoA. Fumarate activationwas synergistic with CoA above pH 7.2. The enzyme displayedhysteretic behavior under suboptimal assay conditions. Rapid extraction and desalting of the enzyme (<1.5 mim) followedimmediately by assay did not reveal any difference in the propertiesof the enzyme on a day/night basis. It is proposed that diurnalregulation of the enzyme in vivo is mediated by pH and malatelevel without a change in the oligomeric form of the enzyme.The molecular weight of the enzyme was approximately 350,000at pH 6.5 or 7.8. The enzyme obtained from M. crystallinum inthe C₃ mode was very similar to the CAM enzyme except that itdisplayed a lower V_max. ³ Current address: MSU-DOE Plant Research Lab, Michigan StateUniversity, E. Lansing, Michigan, U.S.A. 48824. (Received October 2, 1984; Accepted December 20, 1984)     

Pinitol, a Compatible Solute in Mesembryanthemum crystallinum L.?

The irrigation of Mesembryanthemum crystallinum L. plants with400 mol m^–3 NaCl to induce crassulacean acid metabolism(CAM) was accompanied by the accumulation of pinitol. Pinitolconstituted 71% of the soluble carbohydrate fraction and 9.7%dry weight in the CAM form. Pinitol in the C₃ form did not exceed5% of the soluble carbohydrate fraction. Pinitol appeared metabolicallyinert: it was not readily degraded during 96 h of darkness inthe CAM form or during CAM deinduction. Preparations of CAMM. crystallinum protoplasts, vacuoles and chloroplasts showedpinitol to be chloroplastic at a concentration of about 230mol m^–3 and cytosolic at about 100 mol m^–3. No pinitolwas detected in vacuoles. CAM leaf extracts possessed a highermyo-inositol phosphate synthesising capacity than C₃ extracts,revealing greater activity in the CAM form of glucose-6-phosphatecycloaldolase, an enzyme in the pathway of pinitol synthesis. Although pinitol accumulation and CAM induction could not beseparated and appeared to be specific responses to water stress,there may not be a causal link between them. Pinitol may functionas a compatible solute in the cytosol and especially the chloroplaststo counteract the presence of high concentrations of Na⁺ andCl^– ions in the vacuole. The accumulation of pinitol,though apparently not directly related to CAM may, like CAM,be viewed as an aspect of the adaptation of the plant to a reductionin water availability. Key words: pinitol, Mesembryanthemum crystallinum L, CAM, compatible solute     

Analysis of chlorophyll a fluorescence in C3 and CAM forms of Mesembryanthemum crystallinum

Comparisons of chlorophyll a fluorescence characteristics ofC₃ and CAM forms of Mesembryanthemum crystallinum were usedto identify features of the photosynthetic mechanism associatedwith CAM. The reduction status, Q, was lower and predicted PSII activityhigher in the C₃ form than in the CAM form throughout the photoperiod.These differences were particularly pronounced during the firsthour of illumination when non-photochemical quenching attributableto the intrathylakoid proton gradient was also at its highestin the CAM form. It is argued that this high proton gradientdiminishes PSII activity and serves a protective role againstphotoinhibition at a time in the CAM cycle when both CO₂ concentrationwithin the leaf, and carbon cycle enzyme activation levels arelikely to be low. Differences in fluorescence characteristics between the C₃ andCAM forms also indicate modification of the energy transductionmechanisms of the CAM form possibly related to the increasedoverall demand for ATP in CAM photosynthesis. Total non-photochemicalquenching was higher in the CAM form than in the C₃ form. Aninverse relationship between fast and slowly-relaxing componentsof non-photochemical quenching can be interpreted in terms ofthe changing demand for ATP in the different phases of CAM. Key words: C₃/CAM photosynthesis, chlorophyll fluorescence, state transitions, cyclic photophosphorylation     

Changes in Levels of Phosphoenolpyruvate Carboxylase with Induction of Crassulacean Acid Metabolism in Mesembryanthemum crystallinum L.

Expanded leaves of Mesembryanthemum crystallinum L. performingC₃ photosynthesis were induced to perform pronounced Crassulaceanacid metabolism (CAM) by exposing the plant roots to higherNaCl concentration. Levels of phosphoenolpyruvate (PEP) carboxylaseactivity increased 10-fold during the 7-day induction period.Densitometric analysis of Coomassie-stained sodium dodecyl sulfate(SDS) polyacrylamide gradient slab gels of leaf extracts, preparedduring the course of CAM induction, revealed that at least fivebands of polypeptides increased in content (kilodalton valuesof 98, 91, 45, 41, 38). Higher levels of three additional polypeptides(kilodalton values of 102, 76, 33) became apparent after tissuehad been grown for 2 weeks at 400 mM NaCl. Of these polypeptides,that having a mass of 98 kilodaltons was identified as the subunitof PEP carboxylase by comparison with the corresponding bandfrom partially purified PEP carboxylase from the same tissue.Only a faint 98 kilodalton band was evident on SDS gels fortissue operating in the C₃ mode; staining intensity at thislocation increased with increasing NaCl-salinity in the rootingmedium until CAM was fully induced. These data provide evidencefor net synthesis of PEP carboxylase and several other proteinsduring the induction of CAM in M. crystallinum. ¹ Present address: USDA, P. O. Box 867 Airport Rd., Beckley,WV. 25801, U.S.A. ² Present address: Department of Botany, Washington State University,Pullman, Washington 99164, U.S.A. ³ Present address: Botanisches Institut der Universit?t, MittlererDallenbergweg 64, 8700 W?rzburg, W.-Germany. (Received October 27, 1981; Accepted March 15, 1982)     

Polypeptide Composition of Envelope Membranes Isolated from Chloroplasts of C3, C4, and CAM Plants

Chloroplast envelopes were isolated from chloroplasts purifiedfrom Spinacea oleracea L. (C₃), Panicum miliaceum L. (NAD-malicenzyme-type C₁), Digitaria sanguinalis (L.) Scop. (NADP-malicenzyme-type C₄), Kalanchoe daigremontiana Hamet et Perrier (constitutiveCAM), and from Mesembryanthemum crystallinum L. (inducible CAM)performing either C₃ photosynthesis or Crassulacean acid metabolism(CAM). For each species, methods were developed to isolate chloroplastenvelopes free of thylakoid contamination. The polypeptidesof ribulose bisphosphate (RuBP) carboxylase which has been consistentlyreported in envelope preparations of spinach were not foundin envelope preparations of C₄ mesophyll chloroplasts. Silverstaining of envelope polypeptides resolved electrophoreticallyon sodium dodecylsulfate polyacrylamide gradient slab gels produceda more complex profile than did Coomassie staining which haspreviously been used with C₃ envelope preparations, even thoughsilver reacted poorly with polypeptides corresponding to thesubunits of RuBP carboxylase. All of the plants examined possesseda major polypeptide of 27 to 29 kilodaltons (kD) which was previouslysuggested to be the phosphate translocator in spinach. WithC₃ M. crystallinum, the 29 kD polypeptide stained most intensely.After induction of CAM, a 32 kD polypeptide also stained intensely,giving a profile similar to that obtained with the constitutiveCAM species. A 32 kD polypeptide was also prominent in C₄ envelopepreparations, suggesting that a 32 kD polypeptide may be a translocatorprotein which is required in Crassulacean acid metabolism andC4 photosynthesis, but not in C₃ photosynthesis. (Received April 25, 1983; Accepted July 9, 1983)     

Induction of Light Dependent Pyruvate Transport into Chloroplasts of Mesembryanthemum crystallinum by Salt Stress

Mode of photosynthesis in Mesembryanthemum crystallinum changesfrom C₃ to Crassulacean acid metabolism (CAM) when the plantswere stressed with high salinity. [¹⁴C]Pyruvate uptake for 30s into intact chloroplasts isolated from leaves of the CAM modeof M. crystallinum was enhanced more than 5-fold in the lightcompared with that in the dark. The stromal concentration ofpyruvate in the light reached to more than 2.5 times of themedium. In contrast, little or no pyruvate uptake occurred inchloroplasts from C₃ leaves in either light or dark condition.The initial uptake rate (10 s incubation at 4°C) into theCAM chloroplasts in the light was about 3-fold higher than therate in the dark. K_m and V_max of the initial uptake in the lightwere 0.54 mM and 8.5 µmol (mg Chl)^–1 h^–1 respectively.These suggest that pyruvate was actively incorporated into theCAM chloroplasts against its concentration gradient across theenvelope in the light. When hydroponically grown M. crystallinumwere stressed by 350 mM NaCl, the capacity of chloroplasts forpyruvate uptake was induced in 6 d corresponding to the inductionof the activities of PEP-carboxylase and NAD(P)⁺-malic enzymesin response to salt stress. (Received October 12, 1995; Accepted January 19, 1996)     

Enzymatic Properties of Phosphoenolpyruvate Carboxylase of Purified Chloroplasts from CAM-Performing Kalanchoe blossfeldiana Poelln. Plants

A phosphoenolpyruvate carboxylase (PEPC) (EC 4.1.1.3 [EC] ) activitywas associated with, the Percoll purified chloroplasts fromKalanchoe blossfeldiana leaves performing crassulacean acidmetabolism (CAM) (plants grown under short-day conditions).Very little PEPC activity was detected in the chloroplasts whenthe plants were grown under long days, performing a C₃-typephotosynthetic metabolism. The PEPC activity measured in thechloroplasts from CAM-plants was very sensitive to such effectorsas glucose-6-phosphate (G-6-P) and malate: the initial activityof PEPC in the presence of 1.2 mM PEP was 400% activated by10 mM G-6-P and was 25% inhibited by 1 mM malate. These resultsshow that the PEPC in the chloroplasts has the enzymatic characteristicsdescribed by Brulfert and Queiroz [(1982) Planta 154: 339] forPEPC extracted from CAM-performing K. blossfeldiana leaves. (Received November 1, 1985; Accepted April 25, 1986)     

Daily Changes in CO(2) and Water Vapor Exchange, Chlorophyll Fluorescence, and Leaf Water Relations in the Halophyte Mesembryanthemum crystallinum during the Induction of Crassulacean Acid Metabolism in Response to High NaCl Salinity

Simultaneous measurements of net CO₂ exchange, water vapor exchange, and leaf water relations were performed in Mesembryanthemum crystallinum during the development of crassulacean acid metabolism (CAM) in response to high NaCl salinity in the rooting medium. Determinations of chlorophyll a fluorescence were used to estimate relative changes in electron transport rate. Alterations in leaf mass per unit area, which—on a short-term basis—largely reflect changes in water content, were recorded continuously with a beta-gauge. Turgor pressure of mesophyll cells was determined with a pressure probe. As reported previously (K Winter, DJ von Willert [1972] Z Pflanzenphysiol 67: 166-170), recently expanded leaves of plants grown under nonsaline conditions showed gas-exchange characteristics of a C₃ plant. Although these plants were not exposed to any particular stress treatment, water content and turgor pressure regularly decreased toward the end of the 12 hour light periods and recovered during the following 12 hours of darkness. When the NaCl concentration of the rooting medium was raised to 400 millimolar, in increments of 100 millimolar given at the onset of the photoperiods for 4 consecutive days, leaf water content and turgor pressure decreased by as much as 30 and 60%, respectively, during the course of the photoperiods. These transient decreases probably triggered the induction of the biochemical machinery which is required for CAM to operate. After several days at 400 millimolar NaCl, when leaves showed features typical of CAM, overall turgor pressure and leaf mass per unit area had increased above the levels before onset of the salt treatment, and diurnal alterations in leaf water content were reduced. Net carbon gain during photoperiods and average intercellular CO₂ partial pressures at which net CO₂ uptake occurred, progressively decreased upon salinization. Reversible diurnal depressions in leaf conductance and net CO₂ uptake, with minima recorded in the middle of the photoperiods, preceded the occurrence of nocturnal net CO₂ uptake. During these reductions, intercellular CO₂ partial pressure and rates of photosynthetic electron transport decreased. With advancing age, leaves of plants grown under nonsaline conditions exhibited progressively greater diurnal reductions in turgor pressure and developed a low degree of CAM activity.     

The Influence of Nitrogen, Light and Water Stress on CO2 Exchange and Organic Acid Accumulation in the Tropical C3-CAM Tree, Clusia minor

The carbon balance and changes in leaf structure in Clusia minorL., were investigated in controlled conditions with regardto nitrogen supply and responses to low and high photosyntheticallyactive radiation (PAR). Nitrogen deficiency and high PAR ledto the production of smaller leaves with higher specific leafdry weight (SLDW) and higher leaf water content, but with lowerchlorophyll content. Nitrogen and PAR levels at growth alsoaffected CO₂ exchange and leaf area. In – N conditions,total daily net CO₂ uptake and leaf area accumulation were slightlyless for high-PAR-grown plants. In contrast, high-PAR-grownplants supplied with nitrogen showed about a 4-fold higher totaldaily CO₂ uptake and about twice the total leaf area of low-PAR-grownplants. Although total daily net CO₂ uptake of +N plants wasonly slightly higher than –N plants under the low PARlevel, –N plants produced almost three times more leafarea but with lower SLDW. Under well-watered conditions, low-PAR-grownplants showed only CO₂ evolution during the night and malicacid levels decreased. However, there was considerable night-timeaccumulation of titratable protons due to day/night changesin citric acid levels. High-PAR-grown plants showed net CO₂uptake, malate and citrate accumulation during the dark period.However, most of the CO₂ fixed at night probably came from respiratoryCO₂. Positive night-time CO₂ exchange was readily observed forlow-PAR-grown plants when they were transferred to high PARconditions or when they were submitted to water stress. In plantsgrown in high and low PAR, CAM leads to a substantial increasein daily water use efficiency for water-stressed plants, althoughtotal net CO₂ uptake decreased.     

Induction of Crassulacean Acid Metabolism in the Facultative Halophyte Mesembryanthemum crystallinum by Abscisic Acid

The facultative halophyte, Mesembryanthemum crystallinum, shifts its mode of carbon assimilation from the C₃ pathway to Crassulacean acid metabolism (CAM) in response to water stress. In this study, exogenously applied abscisic acid (ABA), at micromolar concentrations, could partially substitute for water stress in induction of CAM in this species. ABA at concentrations of 5 to 10 micromolar, when applied to leaves or to the roots in hydroponic culture or in soil, induced the expression of CAM within days (as indicated by the nocturnal accumulation of total titratable acidity and malate). After applying ABA there was also an increase in phosphoenolpyruvate carboxylase and NADP-malic enzyme activities. The degree and time course of induction by ABA were comparable to those induced by salt and water stress. Electrophoretic analyses of leaf soluble protein indicate that the increases in phosphoenolpyruvate carboxylase activity during the induction by ABA, salt, and water stress are due to an increase in the quantity of the enzyme protein. ABA may be a factor in the stress-induced expression of CAM in M. crystallinum, serving as a functional link between stress and biochemical adaptation.     

The participation of phytochrome in the signal transduction pathway of salt stress responses in Mesembryanthemum crystallinum L.

Continuous irradiation of Mesembryanthemum crystallinum plantswith light of equal amounts of photosynthetically active radiation,but widely different red:far red ratios was used to intervenein phytochrome-mediated signal transduction pathways in thepresence and absence of salt stress. Light with a low ratioof red:far red (in contrast to light with a high ratio of red:farred), caused induction of PEP carboxylase activity, accumulationof the CAM isoform of PEP carboxylase, and the accumulationof malate anion. Taking these as indicators of CAM inductionit is concluded that phytochrome can participate in the signaltransduction pathway leading to CAM in M. crystallinum. A lowratio of red: far red light acted synergystically with saltstress in the induction of these CAM indicators. The simplestinterpretation of this interaction is that the phytochrome-mediatedeffects and salt stress effects acted on the same signal transductionpathway. The accumulation of pinitol was also increased by light witha low ratio of red:far red, consistent with the existence ofa stress syndrome in M. crystallinum which utilizes a commontransduction pathway. A low ratio of red:far red light induced a strong shade avoidanceresponse and, compared to light with a high red:far red ratio,modified chlorophyll content and betacyanin pigment complement. Plants grown in light with a low ratio of red:far red floweredearlier than plants grown in light with a high red:far red ratio. It is concluded that phytochrome can participate in the signaltransduction pathway leading to the induction of both CAM andthe processes which result in pinitol accumulation and pigmentationin M. crystallinum, as well as in the mediation of shade avoidanceand flowering responses. Key words: Mesembryanthemum crystallinum, CAM, phytochrome, signal transduction, drought stress     

Effect of Potassium Deficiency on C3 and C4 Cereals

C₄ cereals (Zea maya L. and Sorghum bicolor L. Moench) and C₃cereals (Triticum aestivum L. and Hordeum vulgare L) were grownin nutrient solutions with constant, interrupted, or absentpotassium supply. The lack of potassium retarded shoot growthand depressed the chlorophyll accumulation in all species ina similar way. After the renewal of potassium, the differencesin the compensation for growth retardation were not correlatedwith the photosynthetic system, but with the recovery of chlorophyllaccumulation in younger leaves. As important for the compensationof shoot growth retardation was a slower senescence of old leavescompared to plants with a constant potassium supply. This wasshown by the chlorophyll content and PEP carboxylase activity.In contrast to C₃ cereals, the C₄ cereals did not react withhigher chlorophyll contents to the same extent after the renewalof the postassium supply. The PEP carboxylase activity, however,was immediately raised higher than in control leaves. Chlorophylland PEP carboxylase activity increased simultaneously only inless aged leaves.     

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)     

Silica Deposition in Some C3 and C4 Species of Grasses, Sedges and Composites in the USA

We report new information on silica deposition in 15 plant species,including nine grasses, two sedges and four composites. Thesilica depositional patterns found in seven of the grass speciesindicate that they are C₄ plants. However the festucoid grassCortaderia selloana is a C₃ plant with long leaf trichomes andoval silica structures in the leaves. In contrast the panicoidC₄ grasses Chasmathium latifolium, Chasmathium sessiflorum,Imperata cylindrica, Panicum repens, Panicum commutatum andSetaria magna, all produce dumb-bell-shaped silica structuresin the leaves. The chloridoid grasses Spartina patens and Spartinacynosuroides have saddle-shaped structures and no dumb-bellor oval shaped ones. The sedges Rhynchospora plumosa and Scirpuscyperinus were found to have oval phytoliths and may be C₃ plants.Our examination of these and other grasses strongly suggeststhat C₄ grasses tend to produce the same type of silica cells.Grasses and sedges with C₃ type photosynthesis tend to produceoval silica structures. The composite Grindelia squarrosa andsunflowers Helianthus angustifolia, Helianthus atrorubens andHelianthus tuberosus absorb relatively small amounts of siliconand larger amounts of calcium, where both elements deposit inleaf trichomes. We found no clear indicator for the C₃ sunflowersor C₄ types in the Asteraceae. Helianthus tuberosus leaves havemany trichomes on the adaxial surface. These trichomes havea higher concentration of silica than the surrounding leaf surface.Helianthus tuberosus leaves had much higher ash and silica contentsthan those of Helianthus angustifolia and Helianthus atrorubens.The composite Grindelia squarrosa has a usual deposition ofsilica in the basal cells around the guard cells. Silica depositionoften reflects the surface features of a leaf. An exceptionis Scripus cyperinus where the silica structures are deep inthe tissue and do not reflect the surface configurations. Theinforescence of Setaria magna had a 14.64 silica content. Thetufts of white, silky hairs characteristic of Imperata cylindricainflorescence have no silica. C₃ and C₄ plants, silica and ash content, scanning electron microscopy, energy-dispersive X-ray analysis, silicon distribution, spectra of elements in plants, trichomes, silica fibres, phytoliths     

Evidence that the induction of crassulacean acid metabolism by water stress in Mesembryanthemum crystallinum (L.) involves root signalling

The aim of this study was to investigate whether the root system of Mesembryanthemum crystallinum (L.) plays a role in triggering the induction of crassulacean acid metabolism (CAM) during water stress. Depriving well-irrigated plants of water, by allowing the soil surrounding the roots to dry, caused increased daily losses in leaf relative water content (RVVC) and mesophyll cell turgor pressure. The RWC of the roots also declined. Subsequently plants exhibited physiological characteristics of CAM photosynthesis (i.e. diurnal fluctuations in leaf titratable acidity and nocturnal net CO₂ fixation). When the root system of plants was divided equally between two soil compartments and one half deprived of water, plants exhibited physiological characteristics of CAM without prior changes in leaf RWC content or mesophyll cell turgor pressure. Only the RWC of the water-stressed portion of the roots was reduced. These data suggest that in water-stressed plants daily changes in leaf water relations greater than those observed in well-irrigated plants, are not essential to trigger CAM expression. It is probable that a reduction in soil water availability can be perceived by the roots of M. crystallinum and that this information is conveyed to the leaves triggering the transition from C₃ to CAM photosynthesis.     

Chlorophyll Fluorescence and Organic Acid Oscillations during Transition from CAM to C3-photosynthesis inClusia minor L. (Clusiaceae)

In species of Clusia, switching from C₃-photosynthesis (C₃-PS)to crassulacean acid metabolism (CAM) may be a means of optimizingwater use, plant carbon balance and photon utilization duringperiods of stress. We ask whether, in perennial species of Clusia,the switch from CAM back to C₃-PS is also of ecophysiologicalsignificance. Our objective was to investigate the performanceof C. minor L. during a short-term shift from CAM to C₃-PS.During the transition from CAM to C₃-PS, nocturnal malate andcitrate accumulation decreased whereas CO₂uptake increased duringthe daytime. However, after 7 d, marked nocturnal accumulationof citrate and 24 h CO₂uptake occurred. In contrast to C₃-likephotosynthesis, a pronounced reduction in the effective quantumyield of photosystem II,