Contribution of C3 carboxylation to the circadian rhythm of carbon dioxide uptake in a Crassulacean acid metabolism plant Kalanchoë daigremontiana

During the endogenous circadian rhythm of carbon dioxide uptake in continuous light by a Crassula cean acid metabolism plant, Kalancho? daigremontiana, the two carboxylating enzymes, phosphoenolpyruvate carboxylase (PEPC) and ribulose 1,5 bisphosphate carboxylase/oxygenase (Rubisco), are active simultaneously, although, until now, only the role of PEPC in generating the rhythm has been acknowledged. According to the established model, the rhythm is primarily regulated at the PEPC activity level, modulated by periodic compartmentation of its inhibitor, malate, in the vacuole and controlled by tension/relaxation of the tonoplast. However, the circadian accumulation of malic acid (the main indicator of PEPC activity) dampened significantly within the first few periods without affecting the rhythm's amplitude. Moreover, the amount of malate accumulated during a free-running oscillation was several-fold lower than the amount expected if PEPC were the key carboxylating enzyme, based on a 1:1 stoichiometry of CO(2) and malate. Together with the observation that rates of CO(2) uptake under continuous light were higher than in darkness, the evidence shows that C(3) carboxylation greatly contributes to the generation of rhythmic CO(2) uptake in continuous light in this 'obligate' CAM plant. Because the shift from predominantly CAM to predominantly C(3) carboxylation is smooth and does not distort the trajectory of the rhythm, its control probably arises from a robust network of oscillators, perhaps also involving stomata.     

Period and phase control by temperature in the circadian rhythm of carbon dioxide fixation in illuminated leaves of Bryophyllum fedtschenkoi

The rhythm of CO₂ assimilation exhibited by leaves of Bryophyllum fedtschenkoi maintained in light and normal air occurs only at constant ambient temperatures between 10°C and 30°C. Over this range the period increases linearly with increasing temperature from the extremely low value of 15.7 h to 23.3 h, but shows a considerable degree of temperature compensation. Outside the range 10°C–30°C the rhythm is inhibited but re-starts on changing the temperature to 15°C. Prolonged exposure of leaves to high (40°C) and low (2°C) temperature inhibits the rhythm by driving the basic oscillator to fixed phase points in the cycle which differ by 180°, and which have been characterised in terms of the malate status of the leaf cells. At both temperatures loss of the circadian rhythm of CO₂ assimilation is due to the inhibition of phosphoenolpyruvate carboxylase (PEPCase) activity, but the inhibition is apparently achieved in different ways at 40°C and 2°C. High temperature appears to inhibit directly PEPCase activity, but not the activity of the enzymes responsible for the breakdown of malate, with the result that the leaf acquires a low malate status. In contrast, low temperature does not directly inhibit PEPCase activity, but does inhibit enzymes responsible for malate breakdown, so that the malate level in the leaf increases to a high value and PEPCase is eventually allosterically inhibited. The different malate status of leaves held at these two temperatures accounts for the phases of the rhythms being reversed on returning the leaves to 15°C. After exposure to high temperature, CO₂ fixation by PEPCase activity can begin immediately, whereas after exposure to low temperature, the large amount of malate accumulated in the leaves has to be decarboxylated before CO₂ fixation can begin.     

Generation of rhythmic and arrhythmic behaviour of Crassulacean acid metabolism in Kalanchoë daigremontiana under continuous light by varying the irradiance or temperature: Measurements in vivo and model simulations

Leaves of Kalanchoë daigremontiana Hamet et Perr. at a photon flux density (PFD) above 220 mol·m^–2s^–1 (400–700 nm) or at leaf temperatures above 27.0 °C showed a rapid loss of rhythmicity, and a more or less pronounced damping-out of the endogenous circadian rhythm of CO₂ exchange under continuous illumination. This rhythm was reinitiated after reduction of the PFD by 90–120 mol·m^–2·s^–1 or reduction of leaf temperature by 3.5–11.0 °C under otherwise unchanged external conditions. The reduction in the magnitude of the external control parameter of the Crassulacean acid metabolism (CAM) rhythm (i.e. PFD or leaf temperature) set the phase of the new rhythm. The maxima of CO₂ uptake occurred about 5, 28, 51, 75 h after the reduction. Simulations with a CAM model under comparable conditions showed a similar behaviour. The influence of temperature on the endogenous CAM rhythm observed in K. daigremontiana in vivo could be simulated by incorporating into the model temperature-dependent switch modes for passive efflux of malate from the vacuole to the cytoplasm. Thus, the model indicates that tonoplast function plays an important role in regulation of the endogenous CAM rhythm in K. daigremontiana.Abbreviations CAM Crassulacean acid metabolism - PAR photosynthetically active radiation - PFD photon flux density This work was supported by a grant to F.B. and U.L. from Teilprojekt B5 in the Sonderforschungsbereich 199 of the Deutsche Forschungsgemeinschaft (Bonn, Germany) and by a grant to T. E. E. G. from the Sudienstiftung des deutschen Volkes (Bonn, Germany). Erika Ball is thanked for processing of time-course data for the analysis of Fourier spectra.     

Plasticity of crassulacean acid metabolism at subtropical latitudes: a pineapple case study

Plants with the crassulacean acid metabolism (CAM) express high‐metabolic plasticity, to adjust to environmental stresses. This article hypothesizes that irradiance and nocturnal temperatures are the major limitations for CAM at higher latitudes such as the Azores (37°45'N). Circadian CAM expression in Ananas comosus L. Merr. (pineapple) was assessed by the diurnal pattern of leaf carbon fixation into l ‐malate at the solstices and equinoxes, and confirmed by determining maximal phosphoenolpyruvate carboxylase (PEPC) activity in plant material. Metabolic adjustments to environmental conditions were confirmed by gas exchange measurements, and integrated with environmental data to determine CAM's limiting factors: light and temperature. CAM plasticity was observed at the equinoxes, under similar photoperiods, but different environmental conditions. In spring, CAM expression was similar between vegetative and flowering plants, while in autumn, flowering (before anthesis) and fructifying (with fully developed fruit before ripening) plants accumulated more l ‐malate. Below 100 µmol m^?2 s^?1, CAM phase I was extended, reducing CAM phase III during the day. Carbon fixation inhibition may occur by two major pathways: nocturnal temperature (<15°C) inhibiting PEPC activity and l ‐malate accumulation; and low irradiance influencing the interplay between CAM phase I and III, affecting carboxylation and decarboxylation. Both have important consequences for plant development in autumn and winter. Observations were confirmed by flowering time prediction using environmental data, emphasizing that CAM expression had a strong seasonal regulation due to a complex network response to light and temperature, allowing pineapple to survive in environments not suitable for high productivity.     

Conditionality of circadian rhythmicity: Synergistic action of light and temperature

Summary With cells which have been grown at 20°C, the circadian rhythm of bioluminescence inGonyaulax polyedra disappears at a critical temperature, which is about 12°C. The transition from the rhythmic to the arrhythmic state is very sharp with temperature: the two states are separated by only 1–2°C. Following a return to a higher temperature (20°C) under otherwise constant conditions, the rhythm resumes with its new phase defined by the time of the cool to warm transition. Loss of rhythmicity also occurs in constant bright light, with a similar resumption and phase determination upon transfer to darkness. The experiments described here show that the effects of light and low temperature are additive: rhythmicity is lost under combined low temperature and light intensity treatments which are ineffective individually.Abbreviations CT circadian time - ft-c footcandle - LD 12:12 12 h light/12 h dark cycle NIH Predoctoral Trainee in Biophysics, 2 T01 GM00782-16.     

Phosphoenolpyruvate Carboxylase During Development of Crassulacean Acid Metabolism and During a Diurnal Cycle in Mesembryanthemum Crystallinum

Crassulacean acid metabolism (CAM) in Mesembryanthemum crystallinumwas induced by transfer of plants from 100 to 400 mM NaCl. Diurnalmalate fluctuations developed slowly; maximum rates of net malatesynthesis in the dark were reached only on the 10th day afterNaCl was increased to 400 mM. In contrast, phosphoenolpyruvatecarboxylase (PEPC) activity, assayed at optimum pH of 8–0,had nearly reached its maximum on the 5th day after plants weretransferred to 400 mM NaCl. Characteristics of PEPC changedduring the first 12 d of exposure of plants to 400 mM NaCl.There were increases in the ratio of PEPC activity at pH 7 0/PEPCactivity at pH 8.0, and decreases in the Km for PEP measuredat pH 7.0, and possibly in the degree of malate inhibition.All further measurements were made once CAM was well established.In vivo rates of malate synthesis were 14–18 times smallerthan PEPC activity at 2 mM PEP, both processes being measuredat 15 °C. It is suggested that the high PEPC levels favourrapid, preferential flow of carbon to malate, by maintainingvery low PEP levels in the cytoplasm. PEPC changed in characteristicsduring the diurnal cycle. During the first few minutes afterisolation, extracts made during the first hours of the day,when malate was consumed, showed very low PEPC activity at pH7.0 but high activity at pH 8.0. The activity of PEPC at pH7.0 rose gradually during storage of the extracts at 0 °C,usually reaching the activity at pH 8.0 after about 30–50min. In contrast, extracts obtained during the first hours ofthe night, when malate was synthesized, showed high PEPC activityat both pH 7.0 and 8–0 within 30–50 s after extraction.The results indicate that PEPC of M. crystallinum, performingdistinct CAM, may exist in two states. One state would favourrapid malate synthesis and transport to the vacuoles and wouldfunction during the night. The second state, with little activitybelow pH 7.5, would occur during the day, thus preventing complicationsof continued synthesis of malate while it is converted to carbohydrates.     

Dramatic difference in the responses of phosphoenolpyruvate carboxylase to temperature in leaves of C3 and C4 plants

Temperature caused phenomenal modulation of phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31) in leaf discs of Amaranthus hypochondriacus (NAD-ME type C(4) species), compared to the pattern in Pisum sativum (a C(3) plant). The optimal incubation temperature for PEPC in A. hypochondriacus (C(4)) was 45 degrees C compared to 30 degrees C in P. sativum (C(3)). A. hypochondriacus (C(4)) lost nearly 70% of PEPC activity on exposure to a low temperature of 15 degrees C, compared to only about a 35% loss in the case of P. sativum (C(3)). Thus, the C(4) enzyme was less sensitive to supra-optimal temperature and more sensitive to sub-optimal temperature than that of the C(3) species. As the temperature was raised from 15 degrees C to 50 degrees C, there was a sharp decrease in malate sensitivity of PEPC. The extent of such a decrease in C(4) plants (45%) was more than that in C(3) species (30%). The maintenance of high enzyme activity at warm temperatures, together with a sharp decrease in the malate sensitivity of PEPC was also noticed in other C(4) plants. The temperature-induced changes in PEPC of both A. hypochondriacus (C(4)) and P. sativum (C(3)) were reversible to a large extent. There was no difference in the extent of phosphorylation of PEPC in leaves of A. hypochondriacus on exposure to varying temperatures, unlike the marked increase in the phosphorylation of enzyme on illumination of the leaves. These results demonstrate that (i) there are marked differences in the temperature sensitivity of PEPC in C(3) and C(4) plants, (ii) the temperature induced changes are reversible, and (iii) these changes are not related to the phosphorylation state of the enzyme. The inclusion of PEG-6000, during the assay, dampened the modulation by temperature of malate sensitivity of PEPC in A. hypochondriacus. It is suggested that the variation in temperature may cause significant conformational changes in C(4)-PEPC.     

The activity and malate inhibition/stimulation of phosphoenolpyruvate-carboxylase in crassulacean-acid-metabolism plants in their natural environment

The effect of environmental conditions, temperature, relative humidity, and light, together with the regulation of PEPC (phosphoenolpyruvate-carboxylase) activity by malate and pH on CAM (crassulacean acid metabolism), was studied in members of the Mesembryanthemaceae in their natural environment, the southern Namib desert. It was found that during a 24 h period the characteristics of PEPC change. Before sunrise the activity is higher when measured at pH 7 than 8. With bright sunlight the activity measured at pH 7 drops to 20% of its pre-sunrise value, the activity only recovers gradually after malate disappearance and stays constant throughout the night. When measured at pH 8, PEPC shows an opposite behavior, i.e., activity increases in bright sunlight and declines as the pH 7 activity increases. A day-night oscillation in the capacity of malate to stimulate or inhibit PEPC was found. During the day malate inhibits about 90% of the PEPC activity at both pH 7 and 8. After sunset there is a sudden decrease in this inhibition and, at pH 8, malate stimulates the activity by 50%. At pH 7 the stimulation was less.Both stomatal conductance and malate formation were found to increase only when the relative humidity at night rose to 80%. Changes in the properties of the PEPC coincided with the exposure to bright sunlight and changes in leaf temperature. The importance of these metabolic and environmental controls on the regulation of CAM in the Mesembryanthemaceae will be discussed.Abbreviations CAM crassulacean acid metabolism - PEP phosphoenolpyruvate - PEPC PEP-carboxylase     

Exogenous Abscisic Acid Mimics Cold Acclimation for Cacti Differing in Freezing Tolerance

The responses to low temperature were determined for two species of cacti sensitive to freezing, Ferocactus viridescens and Opuntia ficus-indica, and a cold hardy species, Opuntia fragilis. Fourteen days after shifting the plants from day/night air temperatures of 30/20[deg]C to 10/0[deg]C, the chlorenchyma water content decreased only for O. fragilis. This temperature shift caused the freezing tolerance (measured by vital stain uptake) of chlorenchyma cells to be enhanced only by about 2.0[deg]C for F. viridescens and O. ficus-indica but by 14.6[deg]C for O. fragilis. Also, maintenance of high water content by injection of water into plants at 10/0[deg]C reversed the acclimation. The endogenous abscisic acid (ABA) concentration was below 0.4 pmol g-1 fresh weight at 30/20[deg]C, but after 14 d at 10/0[deg]C it increased to 84 pmol g-1 fresh weight for O. ficus-indica and to 49 pmol g-1 fresh weight for O. fragilis. Four days after plants were sprayed with 7.5 x 10-5 M ABA at 30/20[deg]C, freezing tolerance was enhanced by 0.5[deg]C for F. viridescens, 4.1[deg]C for O. ficus-indica, and 23.4[deg]C for O. fragilis. Moreover, the time course for the change in freezing tolerance over 14 d was similar for plants shifted to low temperatures as for plants treated with exogenous ABA at moderate temperatures. Decreases in plant water content and increases in ABA concentration may be important for low-temperature acclimation by cacti, especially O. fragilis, which is widely distributed in Canada and the United States.     

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)     

Requirements for activation of the signal-transduction network that leads to regulatory phosphorylation of leaf guard-cell phosphoenolpyruvate carboxylase during fusicoccin-stimulated stomatal opening

Leaves regulate gas exchange through control of stomata in the epidermis. Stomatal aperture increases when the flanking guard cells accumulate K+ or other osmolytes. K+ accumulation is stoichiometric with H+ extrusion, which is compensated for by phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31)-mediated malate synthesis. Plant PEPCs are regulated allosterically and by phosphorylation. Aspects of the signal-transduction network that control the PEPC phosphorylation state in guard cells are reported here. Guard cells were preloaded with [32P]orthophosphate (32Pi); then stomata were incubated with fusicoccin (FC), which activates the guard-cell plasma membrane H+-ATPase. [32P]PEPC was assessed by immunoprecipitation, electrophoresis, immunoblotting, and autoradiography. In -FC controls, stomatal size, guard-cell malate, and [32P]PEPC were low; maximum values for these parameters were observed in the presence of FC after a 90-min incubation and persisted for an additional 90 min. This high steady-state phosphorylation status resulted from continuous phosphorylation and dephosphorylation, even after the malate-accumulation phase. PEPC phosphorylation was diminished by approximately 80% when K+ uptake was associated with Cl- uptake and was essentially abolished when stomatal opening was sucrose--rather than K+--dependent. Finally, alkalinization by NH4+ in the presence of K+ did not cause PEPC phosphorylation (as it does in C4 plants). As discussed, a role for cytoplasmic protons cannot be completely excluded by this result. In summary, activation of the plasma membrane H+-ATPase was essential, but not sufficient, to cause phosphorylation of guard-cell PEPC. Network components downstream of the H+-ATPase influence the phosphorylation state of this PEPC isoform.     

Stimulation of the Alternative Pathway by Succinate and Malate

Stimulation of the cyanide-resistant oxidation of exogenous NADH in potato (Solanum tuberosum L. cv Bintje) tuber callus mitochondria was obtained with succinate, malate, and pyruvate. Half-maximal stimulation was observed at a succinate or malate concentration of 3 to 4 mM, which is considerably higher than that found for pyruvate (0.128 mM). No effect of succinate or malate addition was found when duroquinone was the electron acceptor. Duroquinol oxidation via the alternative pathway was poor and not stimulated by organic acids. Under stimulating conditions, no swelling or contraction of the mitochondria could be observed. Conversely, variation of the osmolarity did not affect the extent of stimulation. However, the assay temperature had a significant effect: no stimulation occurred at temperatures below 16 to 20[deg]C. Membrane fluidity measurements showed a phase transition at about 17[deg]C. Ubiquinone reduction levels were not significantly higher in the presence of succinate and malate, but the kinetics of the alternative oxidase were changed in a way comparable to that found for stimulation by pyruvate. At low temperatures the alternative oxidase displayed "activated" kinetics, and a role for membrane fluidity in the stimulation of the alternative pathway by carboxylic acids is suggested.     

The Effect of Irradiance on Carboxylating/Decarboxylating Enzymes and Fumarase Activities in Mesembryanthemum crystallinum L. Exposed to Salinity Stress

Abstract: In Mesembryanthemum crystallinum plants, treated for 9 days with 0.4 M NaCl at low light intensities (80 - 90 or 95 - 100 μE m^-2 s^-1; λ = 400 - 700 nm), no day/night malate level differences (Δmalate) were detected. At high light (385 - 400 μE m^-2 s^-1) strong stimulation of PEPC activity, accompanied by a Δmalate of 11.3 mM, demonstrated the presence of CAM metabolism. This indicates that, to evolve day/night differences in malate concentration, high light is required. Salt treatment at low light induces and increases the activity of NAD- and NADP-malic enzymes by as much as 3.7- and 3.9-fold, while at high light these values reach 6.4- and 17.7-fold, respectively. The induction of activity of both malic enzymes and PEPC (phospo enol pyruvate carboxylase) take place before Δmalate is detectable. An increase in SOD (superoxide dismutase) was observed in plants cultivated at high light in both control and salt-treated plants. However, in salt-treated plants this effect was more pronounced. Carboxylating and decarboxylating enzymes seem to be induced by a combination of different signals, i.e., salt and light intensity. Plants performing CAM, after the decrease of activity of both the decarboxylating enzymes at the beginning of the light period, showed an increase in these enzymes in darkness when the malate pool reaches higher levels. In CAM plants the activity of fumarase (Krebs cycle) is much lower than that in C₃ plants. The role of mitochondria in CAM plants is discussed.     

Dawn signal as a rhythmical timer for the seasonal adaptive variation of CAM: a model

Abstract Photoperiodism, known to control the level of CAM in different types of CAM plants (e.g. Kalanchoe blossfeldiana, Bryophyllum daigremontianum), would act as a reliable timer for seasonal coherent adaptation. Two different endogenous rhythms (malic enzyme activity, PEP carboxylase capacity) appear to be separately coupled to dawn and dusk, respectively, thus achieving time-compartmentation of CAM; this feature suggests involvement of an ‘internal coincidence’ type of clock mechanism. Persistence in continuous darkness of the rhythm of malic enzyme activity (measured by label incorporation into pyruvate or by CO₂ output) establishes its endogenous character and shows that light is not necessary for malate decarboxylation. The role of the dawn signal would be to entrain the CAM system, i.e. to phase the endogenous rhythm of malic enzyme activity correctly to local time. The possibility of an effect of the phase of the PEP carboxylase rhythm on the phase of the decarboxylation rhythm is ruled out by the presence of the intermediary malate storage step. Phase responses to red and to far-red show that phytochrome is involved in rephasing the rhythm of malic enzyme activity. The relative position of dusk affords a ‘measurement’ of the season by the CAM system entrained by dawn. According to the dusk-dawn interval, the level of PEP carboxylase capacity (amount of active enzyme) is modified, resulting in changes of CAM level (high activity under short days).     

Age-specific changes of acidity, phosphoenolpyruvate carboxylase, ribulose-1,5-bisphosphate carboxylase/oxygenase, abscisic acid and leaf water potential in Mesembryanthemum nodiflorum

Age-induced changes in 1) nocturnal and diurnal acidity fluctuations that coincide with the ongoing environmental conditions, 2) the build up of abscisic acid (ABA) in plant roots and leaves during sunrise, midday, and sunset in all growing stages, 3) the changes in phosphoenolpyruvate carboxylase (PEPC) and ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) activities as key enzymes of the photosynthetic pathways of C3 and CAM, 4) leaf water potential (ψ1), and 5) Km and Vmax for PEPC to express its activity and affinity, were studied in Mesembryanthemum nodiflorum during transition from C3 to CAM mode of CO2 fixation. The acidity during sunset in mature stage was higher than in earlier stages and reflected the impact of environmental conditions on physiological and metabolic changes. Moreover, the higher acidity during sunrise and sunset was observed during the senescence than the mature stage; this might be due to CO2 release and oxygen intake during senescence induced ethylene formation that lead to increased malic acid formation. The ABA concentration was high in M. nodiflorum leaves, but stomatal closure was insensitive to elevated ABA concentrations recorded. Vmax of PEPC, Km, and the affinity of PEPC during later stages indicated the ability of PEPC to fix CO2 taking up at night in CAM cycle of M. nodiflorum. Less affinity during sunrise indicated inhibitory effect of malate on PEPC during the release of CO2. The second peak of PEPC activity before sunset caused CO2 fixation. The RuBPCO was inactive at night. Slight increase in ABA during sunset, and night drop in air temperature and increase in relative humidity reduced markedly transpiration rate without decreasing ψ1. This revised version was published online in July 2006 with corrections to the Cover Date.     

Protein Synthesis and Breakdown during Heat Shock of Cultured Pear (Pyrus communis L.) Cells

Cultured pear (Pyrus communis L. cv Passe Crassane) cells were subjected to temperatures of 39, 42, and 45[deg]C. Heat-shock protein (hsp) synthesis was greater at 30[deg]C than at temperatures above 40[deg]C and continued for up to 8 h. Both cellular uptake of radiolabeled methionine and total protein synthesis were progressively lower as the temperature was increased. Polysome levels decreased immediately when cells were placed at 39 or 42[deg]C, although at 39[deg]C the levels began to recover after 1 h. In cells from both temperatures, reassembly occurred after transfer of cells to 25[deg]C Four heat-shock-related mRNAs[mdash]hsp17, hsp70, and those of two ubiquitin genes[mdash]all showed greatest abundance at 39[deg]C and decreased at higher temperatures. Protein degradation increased with time at 42 and 45[deg]C, but at 39[deg]C it increased for the first 2 h and then decreased. In the presence of cycloheximide, which prevented hsp synthesis, protein degradation at 39[deg]C was as great as that at 45[deg]C in the absence of cycloheximide. The data suggest that hsps may have a role in protecting proteins from degradation at the permissive temperature of 39[deg]C. At temperatures high enough to inhibit hsp synthesis, protein degradation was enhanced. Although ubiquitin may play a role in specific protein degradation, it does not appear to be involved in increased protein degradation occurring above 40[deg]C.     

An engineered phosphoenolpyruvate carboxylase redirects carbon and nitrogen flow in transgenic potato plants

Phosphoenolpyruvate carboxylase (PEPC) plays a central role in the anaplerotic provision of carbon skeletons for amino acid biosynthesis in leaves of C3 plants. Furthermore, in both C4 and CAM plants photosynthetic isoforms are pivotal for the fixation of atmospheric CO2. Potato PEPC was mutated either by modifications of the N-terminal phosphorylation site or by an exchange of an internal cDNA segment for the homologous sequence of PEPC from the C4 plant Flaveria trinervia. Both modifications resulted in enzymes with lowered sensitivity to malate inhibition and an increased affinity for PEP. These effects were enhanced by a combination of both mutated sequences and pulse labelling with 14CO2 in vivo revealed clearly increased fixation into malate for this genotype. Activity levels correlated well with protein levels of the mutated PEPC. Constitutive overexpression of PEPC carrying both N-terminal and internal modifications strongly diminished plant growth and tuber yield. Metabolite analysis showed that carbon flow was re-directed from soluble sugars and starch to organic acids (malate) and amino acids, which increased four-fold compared with the wild type. The effects on leaf metabolism indicate that the engineered enzyme provides an optimised starting point for the installation of a C4-like photosynthetic pathway in C3 plants.     

The appearance of a new molecular species of phosphoenolpyruvate carboxylase (PEPC) and the rapid induction of CAM in Sedum telephium L.

Abstract. When detached leaves of Sedum telephium are incubated in the absence of water, a rapid switch from C₃ photosynthesis to CAM (as indicated by the onset of day-to-night fluctuations in titratable acidity. ΔH⁺) occurs within the first dark period. The C₃-CAM switch in intact plants occurs within 3 5d. Extractable activity of phospho enol pyruvate carboxylase (PEPC) increases five-fold in intact plants during CAM induction; however, during rapid CAM induction in detached leaves, there is only a very small increase in PEPC activity. Fractionation by anion exchange chromatography of crude extracts from leaves of intact plants subjected to water deficit shows that CAM induction is associated with the appearance of a molecular species of PEPC termed PEPC I. PEPC I is barely detectable in well-watered plants which are not performing CAM. The major form in these plants is termed PEPC II. In leaves from intact plants, there is a significant positive correlation between PEPC I activity and ΔH⁺ during a period of increasing water deficit. PEPC I exhibits day to night fluctuations in malate sensitivity, being less sensitive during the dark period. In contrast, PEPC II is more sensitive to inhibition by malate and has no day to night fluctuation in sensitivity. In detached leaves deprived of water, a small increase in PEPC I capacity is detected at the end of the first dark period (20 h after the start of treatment). The results suggest that PEPC I is required for attainment of maximum nocturnal malic acid synthesis. There is a significant correlation between leaf water status (relative water content), ΔH⁺, total PEPC and PEPC I activity suggesting that the internal water status of the plant may be a trigger for CAM induction. Abscisic acid applied to detached leaves does not cause nocturnal acidification.     

Purification and characterization of an NAD-dependent malate dehydrogenase from leaves of the crassulacean acid metabolism plant Aptenia cordifolia

An NAD-malate dehydrogenase (NAD-MDH, EC 1.1.1.37) was purified and characterized from leaves of Aptenia cordifolia L. f. (Schwant). This plant performs crassulacean acid metabolism (CAM), as indicated by: (a) elevated levels of phosphoenolpyruvate carboxylase (PEPC) and NAD(P) malic enzyme; (b) regulation of PEPC compatible with its function during the night; (c) characteristic day/night changes in titratable acidity; and (d) gas exchange profile consistent with that shown by CAM plants. These features remained unchanged by water availability or salt stress, suggesting constitutive CAM. The purified MDH showed a subunit molecular mass of 39.4 kDa, a native mass of 83 kDa (dimer) and a pI of 5.8. It cross-reacted with antibodies against cytosolic malate dehydrogenase (cMDH) from pineapple. Maximum activities for oxaloacetate (OAA) reduction or malate oxidation were observed at pH 7.0 and between pH 7.2 and 8.4, respectively. The enzyme was inhibited by excess OAA, in a pH-dependent manner. A discontinuity was observed in Arrhenius plots at 33 °C, with an activation energy twice as high below this temperature. Although immunologically related, some physical and kinetic dissimilarities between the A. cordifolia and pineapple enzymes suggest that diverse CAM metabolic subtypes may require different MDH isozymes to carry out OAA reduction.