Characterization of a malate dehydrogenase in the cyanobacterium Coccochloris peniocystis

A malate dehydrogenase (MDH) was characterized from the cyanobacterium Coccochloris peniocystis. The enzyme was purified approximately 180-fold and had a molecular weight of about 90000. The enzyme had a pH optimum of pH 6.7 to 7.5; a K_m (malate) of 5.6 mM and K_ms for NAD and NADP of 24 M and 178 M, respectively, although similar V_max were obtained with either pyridine nucleotide. Enzyme activity was inhibited by ATP, citrate, oxalacetate, acetyl CoA and CoA. Enzyme assays with uniformly ¹⁴C-labelled malate caused no ¹⁴CO₂ release, indicating this MDH is not a malic enzyme. Electrophoresis and S-200 gel filtration of the partially purified enzyme indicated a single MDH was present in this preparation. A second, less abundant, MDH was present in crude extracts. The presence of MDH in this organism is consistent with the operation of a glyoxylate cycle which, in the absence of a TCA cycle, would provide organic acids required in secondary carbon metabolism. ATP inhibition of MDH may allow for light regulation of MDH activity since, in the light, oxaloacetic acid is generated by phosphoenolpyruvate carboxylase activity.Abbreviations MDH malate dehydrogenase - PEPcase phosphoenolpyruvate carboxylase - MOPS 3-[N-Morpholino] propane sulfonic acid - TRIS Tris(hydroxymethyl)-aminomethane - EDTA Disodium Ethylenadiamine Tetraacetate - MES 2[N-Morpholino]-ethane Sulfonic Acid - EPPS N-2-Hydroxyethylpiperazine Propane - MW Molecular weight - OAA Oxaloacetic acid     

Metabolite Control Overrides Circadian Regulation of Phosphoenolpyruvate Carboxylase Kinase and CO(2) Fixation in Crassulacean Acid Metabolism

Phosphoenolpyruvate carboxylase (PEPc) catalyzes the primary fixation of CO₂ in Crassulacean acid metabolism plants. Flux through the enzyme is regulated by reversible phosphorylation. PEPc kinase is controlled by changes in the level of its translatable mRNA in response to a circadian rhythm. The physiological significance of changes in the levels of PEPc-kinase-translatable mRNA and the involvement of metabolites in control of the kinase was investigated by subjecting Kalanchoë daigremontiana leaves to anaerobic conditions at night to modulate the magnitude of malate accumulation, or to a rise in temperature at night to increase the efflux of malate from vacuole to cytosol. Changes in CO₂ fixation and PEPc kinase activity reflected those in kinase mRNA. The highest rates of CO₂ fixation and levels of kinase mRNA were observed in leaves subjected to anaerobic treatment for the first half of the night and then transferred to ambient air. In leaves subjected to anaerobic treatment overnight and transferred to ambient air at the start of the day, PEPc-kinase-translatable mRNA and activity, the phosphorylation state of PEPc, and fixation of atmospheric CO₂ were significantly higher than those for control leaves for the first 3 h of the light period. A nighttime temperature increase from 19°C to 27°C led to a rapid reduction in kinase mRNA and activity; however, this was not observed in leaves in which malate accumulation had been prevented by anaerobic treatment. These data are consistent with the hypothesis that a high concentration of malate reduces both kinase mRNA and the accumulation of the kinase itself.     

Malate valves: old shuttles with new perspectives

Malate valves act as powerful systems for balancing the ATP/NAD(P)H ratio required in various subcellular compartments in plant cells. As components of malate valves, isoforms of malate dehydrogenases (MDHs) and dicarboxylate translocators catalyse the reversible interconversion of malate and oxaloacetate and their transport. Depending on the co‐enzyme specificity of the MDH isoforms, either NADH or NADPH can be transported indirectly. Arabidopsis thaliana possesses nine genes encoding MDH isoenzymes. Activities of NAD‐dependent MDHs have been detected in mitochondria, peroxisomes, cytosol and plastids. In addition, chloroplasts possess a NADP‐dependent MDH isoform. The NADP‐MDH as part of the ‘light malate valve’ plays an important role as a poising mechanism to adjust the ATP/NADPH ratio in the stroma. Its activity is strictly regulated by post‐translational redox‐modification mediated via the ferredoxin‐thioredoxin system and fine control via the NADP⁺/NADP(H) ratio, thereby maintaining redox homeostasis under changing conditions. In contrast, the plastid NAD‐MDH (‘dark malate valve’) is constitutively active and its lack leads to failure in early embryo development. While redox regulation of the main cytosolic MDH isoform has been shown, knowledge about regulation of the other two cytosolic MDHs as well as NAD‐MDH isoforms from peroxisomes and mitochondria is still lacking. Knockout mutants lacking the isoforms from chloroplasts, mitochondria and peroxisomes have been characterised, but not much is known about cytosolic NAD‐MDH isoforms and their role in planta. This review updates the current knowledge on MDH isoforms and the shuttle systems for intercompartmental dicarboxylate exchange, focusing on the various metabolic functions of these valves.     

NAD-dependent malate dehydrogenase and glyceraldehyde 3-phosphate dehydrogenase isoenzymes play an important role in dark metabolism of various plastid types

Chloroplasts isolated from spinach (Spinacia oleracea L.) leaves and green sweet-pepper (Capsicum annuum L. var. grossum (L.) Sendt.) fruits contain NADP-dependent malate dehydrogenase (MDH; EC 1.1.1.82) and the bispecific NAD(P)-glyceraldehyde 3-phosphate dehydrogenase (GAPDH; EC 1.2.1.13). The NADP-dependent MDH and GAPDH are activated in the light, and inactive in the dark. We found that chloroplasts possess additional NAD-dependent MDH activity which is, like the NAD-dependent GAPDH activity, not influenced by light. In heterotrophic chromoplasts from red sweet-pepper fruits, the NADP-dependent MDH and the NAD(P)-GAPDH isoenzymes disappear during the developmental transition and only NAD-specific isoforms are found. Spinach chloroplasts contain both NAD/H and NADP/H at significant concentrations. Measurements of the pyridine dinucleotide redox states, performed under dark and various light conditions, indicate that NAD(H) is not involved in electron flow in the light. To analyze the contribution of NAD(H)-dependent reactions during dark metabolism, plastids from spinach leaves or green and red sweet-pepper fruits were incubated with dihydroxyacetone phosphate (DHAP). Exogenously added DHAP was oxidized into 3-phosphoglycerate by all types of plastids only in the presence of oxaloacetate, but not with nitrite or in the absence of added electron acceptors. We conclude that the NAD-dependent activity of GAPDH is essential in the dark to produce the ATP required for starch metabolism; excess electrons produced during triose-phosphate oxidation can selectively be used by NAD-MDH to form malate. Thus NADPH produced independently in the oxidative pentose-phosphate pathway will remain available for reductive processes inside the plastids. Received: 2 July 1997 / Accepted: 20 October 1997     

Diurnal regulation of phosphoenolpyruvate carboxylase from crassula

Phosphoenolpyruvate carboxylase appears to be located in or associated with the chloroplasts of Crassula. As has been found with this enzyme in other CAM plants, a crude extract of leaves gathered during darkness and rapidly assayed for phosphoenolpyruvate carboxylase (PEPc) activity is relatively insensitive to inhibition by malate. After illumination begins, the PEPc activity becomes progressively more sensitive to malate. This enzyme also shows a diurnal change in activation by glucose-6-phosphate, with the enzyme from dark leaves more strongly activated than that from leaves in the light.

When the enzyme is partially purified in the presence of malate, the characteristic sensitivity of the day leaf enzyme is largely retained. Partial purification of the enzyme from dark leaves results in a small increase in sensitivity to malate inhibition.

Partially purified enzyme is found by polyacrylamide gel electrophoresis analysis to have two bands of PEPc activity. In enzymes from dark leaves, the slower moving band predominates, but in the light, the faster moving band is preponderant. Both of these bands are shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be composed of the same subunit of 103,000 daltons.

The enzyme partially purified from night leaves has a pH optimum of 5.6, and is relatively insensitive to malate inhibition over the range from pH 4.5 to 8. The enzyme from day leaves has a pH optimum of 6.6 and is strongly inhibited by malate at pH values below 7, but becomes insensitive at higher pH values.

Gel filtration of partially purified PEPc showed two activity peaks, one corresponding approximately to a dimer of the single subunit, and the other twice as large. The larger protein was relatively insensitive to malate inhibition, the smaller was strongly inhibited by malate.

Kinetic studies showed that malate is a mixed type inhibitor of the sensitive, day, enzyme, increasing K_m for phosphoenolpyruvate and reducing V_max. With the insensitive, night, enzyme, malate is a K type inhibitor, reducing the K_m for phosphoenolpyruvate, but having little effect on V_max. The inhibition of the insensitive enzyme by malate appears to be hysteretic, taking several minutes to be expressed during assay, probably indicating a change in the conformation or aggregation state of the enzyme.

Activation by glucose-6-phosphate is of the mixed type for the day form of the enzyme, causing both a decreased K_m for phosphoenolpyruvate and an increased V_max, but the night, or insensitive, form shows only an increase in V_max in response to glucose-6-phosphate.

     

Changes in oxidative properties of Kalanchoe blossfeldiana leaf mitochondria during development of Crassulacean acid metabolism

Kalanchoe blossfeldiana plants grown under long days (16 h light) exhibit a C₃-type photosynthetic metabolism. Switching to short days (9 h light) leads to a gradual development of Crassulacean acid metabolism (CAM). Under the latter conditions, dark CO₂ fixation produces large amounts of malate. During the first hours of the day, malate is rapidly decarboxylated into pyruvate through the action of a cytosolic NADP⁺-or a mitochondrial NAD⁺-dependent malic enzyme. Mitochondria were isolated from leaves of plants grown under long days or after treatment by an increasing number of short days. Tricarboxylic acid cycle intermediates as well as exogenous NADH and NADPH were readily oxidized by mitochondria isolated from the two types of plants. Glycine, known to be oxidized by C₃-plant mitochondria, was still oxidized after CAM establishment. The experiments showed a marked parallelism in the increase of CAM level and the increase in substrate-oxidation capacity of the isolated mitochondria, particularly the capacity to oxidize malate in the presence of cyanide. These simultaneous variations in CAM level and in mitochondrial properties indicate that the mitochondrial NAD⁺-malic enzyme could account at least for a part of the oxidation of malate. The studies of whole-leaf respiration establish that mitochondria are implicated in malate degradation in vivo. Moreover, an increase in cyanide resistance of the leaf respiration has been observed during the first daylight hours, when malate was oxidized to pyruvate by cytosolic and mitochondrial malic enzymes.Abbreviations CAM Crassulacean acid metabolism - MDH malate dehydrogenase - ME malic enzyme     

Malate valves to balance cellular energy supply

In green parts of the plant, during illumination ATP and NAD(P)H act as energy sources that are generated mainly in photosynthesis and respiration, whereas in darkness, glycolysis, respiration and the oxidative pentose-phosphate pathway (OPP) generate the required energy forms. In non-green parts, sugar oxidation in glycolysis, respiration and OPP are the only means of producing energy. For energy-consuming reactions, the delivery of NADPH, NADH, reduced ferredoxin and ATP has to take place at the required rates and in the specific compartments, since the pool sizes of these energy carriers are rather limited and, in general, they are not directly transported across biomembranes. Indirect transport of reducing equivalents can be achieved by malateoxaloacetate shuttles, involving malate dehydrogenase (MDH) for the interconversion. Isoenzymes of MDH are present in each cellular compartment. Chloroplasts contain the redox-controlled NADP-MDH that is only active in the light. In addition, a plastid NAD-MDH that is permanently active and is present in all plastid types has been found. Export of excess NAD(P)H through the malate valves will allow for the continued production of ATP (1) in photosynthesis, and (2) in oxidative phosphorylation. In the latter case, the coupled production of NADH is catalysed by the bispecific NAD(P)-GAPDH (GapAB) in chloroplasts that is active with NAD even in darkness, or by the specific plastid NAD-GAPDH (GapCp) in non-green tissues. When plants are subjected to conditions such as high light, high CO(2), NH(4) (+) nutrition, cold stress, which require changed activities of the enzymes of the malate valves, changed expression levels of the MDH isoforms can be observed. In nodules, the induction of a nodule-specific plastid NAD-MDH indicates the changed requirements for energy supply during N(2) fixation. Furthermore, the induction of glucose 6-phosphate dehydrogenase isoforms by ammonium and of ferredoxin and ferredoxin-NADP reductase by nitrate has been described. All these findings are in line with the assumption that a changed redox state caused by metabolic variability leads to the induction of enzymes involved in redox poise.     

Cloning, sequencing and functional expression of cytosolic malate dehydrogenase from Taenia solium: Purification and characterization of the recombinant enzyme

We report herein the complete coding sequence of a Taenia solium cytosolic malate dehydrogenase (TscMDH). The cDNA fragment, identified from the T. solium genome project database, encodes a protein of 332 amino acid residues with an estimated molecular weight of 36517 Da. For recombinant expression, the full length coding sequence was cloned into pET23a. After successful expression and enzyme purification, isoelectrofocusing gel electrophoresis allowed to confirm the calculated pI value at 8.1, as deduced from the amino acid sequence. The recombinant protein (r-TscMDH) showed MDH activity of 409 U/mg in the reduction of oxaloacetate, with neither lactate dehydrogenase activity nor NADPH selectivity. Optimum pH for enzyme activity was 7.6 for oxaloacetate reduction and 9.6 for malate oxidation. K_cat values for oxaloacetate, malate, NAD, and NADH were 665, 47, 385, and 962 s⁻¹, respectively. Additionally, a partial characterization of TsMDH gene structure after analysis of a 1.56 Kb genomic contig assembly is also reported.     

Isolation and biochemical characterization of grape malic enzyme

Malic enzyme (ME=L-malate: NADP oxidoreductase; E.C. 1.1.1.40) was extracted by Triton X-100-induced resolubilization of enzyme proteins which denaturize spontaneously upon homogenization of grape berry material. The purification procedure included fractionating with (NH₄)₂SO₄, preparative IEF, and Sephadex G-100 chromatography. ME was identified by TLC of the radioactive product after supplementing the assay mixture with [¹⁴C]malate. Cofactor dependence, pH-optimum and affinities for substrates and cosubstrates were determined. Enzymic pI was found to be 5.8, the Hill coefficients range from 1 to 3. In malate decarboxylating direction at pH 7.4, grape ME displayed positive cooperativity toward the substrate, the curve approaching normal Michaelis-Menten-kinetics at pH 7.0. Substituting Mn²⁺ for Mg²⁺ not only increased maximal turnover rates, but also enzymic affinity for malate. These features were considered indicative of the regulatory properties of the enzyme. Their relevance for grape malate metabolism and fruit ripening is discussed.Abbreviations EDTA ethylenediaminetetraacetic acid - IFF isoelectric focusing - MDH malate dehydrogenase - ME malic enzyme - OAA oxaloacetic acid - PAG polyacrylamide gel - TCA trichloroacetic acid - TLC thin layer chromatography     

Effects of temperature and photosynthetic inhibitors on light activation of C4-phosphoenolpyruvate carboxylase

Phosphoenolpyruvate carboxylase from leaves of the C₄ plant Setaria verticillata (L.) Beauv. is activated by light; day levels of activity are reached after 30 minutes of illumination. Photoactivation is prevented by inhibitors of photosynthetic electron flow or of photophosphorylation and by D,L-glyceraldehyde, which inhibits the reductive pentose phosphate pathway.Although the extractable activity in the dark is not affected by temperature the photoactivation is prevented when both illumination and extraction are done under low temperature (5 C). High temperature (30 C) during either illumination or extraction is needed for activation. Once the enzyme is photoactivated at 30 C, a transfer of the leaves to 5 C does not abolish the extra activity.The results suggest that both unimpaired electron flow and photophosphorylation are prerequisites for the activation of phosphoenolpyruvate carboxylase. Low temperature apparently suppresses either the transport to the cytoplasm of a photosynthetic intermediate or the activating reaction itself. The inclusion of phosphoenolpyruvate in the extraction medium increases the night activity.On the basis of the available information, it is suggested that phosphoenolpyruvate could be the activator in vivo. In that case, the activation of phosphoenolpyruvate carboxylase would depend on internal CO₂ level and prior photoactivation of both pyruvate, orthophosphate, dikinase and NADP malate dehydrogenase.Abbreviations PEPCase phosphoenolpyruvate carboxylase - PEP phosphoenolpyruvate - PAR photosynthetically active radiation - CCCP carbonyl cyanide m-chlorophenylhydrazone - DCMU 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea - DSPD disalicylidenpropanediamine - MV methylviologen - ME malic enzyme - MDH malate dehydrogenase - PPDK pyruvate, Pi dikinase - CAM Crassulacean Acid Metabolism     

Mitochondrial malic enzyme (ME2) in pancreatic islets of the human, rat and mouse and clonal insulinoma cells: Simple enzyme assay for mitochondrial malic enzyme 2

Despite interest in malic enzyme(ME)s in insulin cells, mitochondrial malic enzyme (ME2) has only been studied with estimates of mRNA or with mRNA knockdown. Because an mRNA’s level does not necessarily reflect the level of its cognate enzyme, we designed a simple spectrophotometric enzyme assay to measure ME2 activity of insulin cells by utilizing the distinct kinetic properties of ME2. Mitochondrial ME2 uses either NAD or NADP as a cofactor, has a high K_m for malate and is allosterically activated by fumarate and inhibited by ATP. Cytosolic ME (ME1) and the other mitochondrial ME (ME3) use only NADP as a cofactor and have lower K_ms for malate. The assay easily showed for the first time that substantial ME2 activity is present in pancreatic islets of humans, rats and mice and INS-1 832/13 cells. ME2’s presence was confirmed with immunoblotting. There was no evidence that ME3 is present in these tissues.     

Malate Dehydrogenases in Guard Cells of Pisum sativum

Guard cell protoplasts of Pisum sativum show considerable NADP-dependent malate dehydrogenase (MDH) activity in darkness which can be enhanced severalfold by illumination or treatment with dithiothreitol (DTT). The question arose whether guard cells possess an NADP-MDH different from that present in the chloroplasts of the mesophyll (which is inactive in darkness or in the absence of DTT). MDH activities were determined in extracts of isolated protoplasts from mesophyll and epidermis, and in mechanically prepared epidermal pieces (with guard cells as the only living cells and no interference from proteases originating from the cell wall digesting enzymes). Guard cells possessed NAD-dependent MDHs of high activity and incomplete exclusion of NADP as a coenzyme. This NADP-dependent activity of the NAD-MDH(s) could not be stimulated by DTT or, inferentially, by light. The DTT- (and light-) dependent NADP-MDH represented 0.05% of the total protein of the guard cells and had a specific activity of 0.1 unit per milligram protein; both values are in the same range as the corresponding ones of the mesophyll cells. Agreement was also found in the extent of light activation, in subunit molecular weight, immunological cross-reactions, and in the behavior on an ion exchange column. The activity of the chloroplastic NADP-MDH in guard cells barely suffices to meet the malate requirement for stomatal opening in the light. It is therefore likely that NAD-MDHs residing in other compartments of the guard cells supplement the activity of the chloroplastic NADP-MDH particularly during stomatal opening in darkness.     

Coimmobilization of malate dehydrogenase and formate dehydrogenase in polyethyleneglycol(#4000)diacrylate gel by droplet gel-entrapping method

A new immobilization technique suitable for coupled enzymes requiring cofactors was established. This is a droplet gel-entrapping method in which many small droplets including the enzymes are fixed in the gel. The first emulsion was prepared by mixing of a solution containing thermostable malate dehydrogenase (MDH) and formate dehydrogenase (FDH) with benzene containing a surfactant. The first emulsion was added to a solution containing polyethyleneglycol(#4000)diacrylate and N,N'-methylenebisacrylamide to prepare the second emulsion (w/o/w). After the second emulsion was gelled by addition of potassium persulfate and 3-dimethylaminopropionitrile, the benzene was removed. The expressed MDH and FDH activities of the MDH-FDH immobilized gel were 7.1 and 13.9% of the initial activities, respectively. The K(m) values of the gel were 0.60mM for formate and 1.5muM for NAD, respectively. The K(m) for formate and NAD were found to be extremely low. By using the column packed with 30 g gel having the MDH activity of 41.7 units and the FDH activity of 11.1 units, 13.8mM oxalacetate was completely converted to malate at 30 degrees C. The malate production rate was not affected by the concentration of more than 50mM formate, more than 2mM oxalacetate, and more than 0.1 mM NAD, respectively. Long-term malate production was demonstrated at 30 degrees C by passing the substrate solution containing the two substrates and NAD through the column. The maximum conversion ratio (7.8%) was obtained at the fifth day, and 83% of maximum productivity was maintained even after 3 weeks. The expressed FDH activity at the fifth day was calculated to be 20.5% of the initial activity.     

Modelling NADH turnover in plant mitochondria

NADH is central to the functioning of mitochondrial respiration. It is produced by enzymes in, or associated with, the tricarboxylic acid cycle in the matrix, and it is oxidized by two respiratory chain enzymes in the inner membrane, the rotenone-sensitive complex I and the rotenone-insensitive internal NADH dehydrogenase (ND_in). A simplified kinetic model for NADH turnover in the matrix of plant mitochondria is presented. Only the two main NADH-producing enzymes, NAD-malate dehydrogenase [EC 1.1.1.37] (MDH) and NAD-malic enzyme [EC 1.1.1.39] (ME), are considered. This model reproduces the complex behaviour of malate oxidation by isolated mitochondria in response to additions of ADP (state 3/state 4), NAD⁺ and/or rotenone, as well as to changes in pH. It is found that MDH always operates at or close to equilibrium. Changes in the activity of complex I, ND_in, or ME are predicted to cause clear changes in the pattern of malate oxidation. In general, the model predicts high sensitivity to changes in the ME activity. In contrast, MDH activity can be reduced 100-fold without detectable changes in malate oxidation. It is demonstrated that it is not the high activity, but the equilibrium properties of MDH that are important for the redox-buffering function of MDH in the mitochondrial matrix. Binding of NAD⁺ and NADH in the matrix reduces the concentrations of free NAD⁺ and NADH, depending on the concentration of binding sites and the binding strength. On the basis of the modelling results it is estimated that a significant proportion of the mitochondrial NAD is bound.     

Oxidations of various substrates and effects of the inhibitors on purified mitochondria isolated from <Emphasis Type="Italic">Kalanchoë pinnata</Emphasis>

Kalanchoë pinnata mitochondria readily oxidized succinate, malate, NADH, and NADPH at high rates and coupling. The highest respiration rates usually were observed in the presence of succinate. The high rate of malate oxidation was observed at pH 6.8 with thiamine pyrophosphate where both malic enzyme (ME) and pyruvate dehydrogenase were activated. In CAM phase III of K. pinnata mitochondria, both ME and malate dehydrogenase (MDH) simultaneously contributed to metabolism of malate. However, ME played a main function: malate was oxidized via ME to produce pyruvate and CO₂ rather than via MDH to produce oxalacetate (OAA). Cooperative oxidation of two or three substrates was accompanied with the dramatic increase in the total respiration rates. Our results showed that the alternative (Alt) pathway was more active in malate oxidation at pH 6.8 with CoA and NAD⁺ where ME operated and was stimulated, indicating that both ME and Alt pathway were related to malate decarboxylation during the light. In K. pinnata mitochondria, NADH and NADPH oxidations were more sensitive with KCN than that with succinate and malate oxidations, suggesting that these oxidations were engaged to cytochrome pathway rather than to Alt pathway and these capacities would be desirable to supply enough energy for cytosol pyruvate orthophosphate dikinase activity.     

Respiratory properties and malate metabolism in Percoll-purified mitochondria isolated from pineapple, Ananas comosus (L.) Merr. cv. smooth cayenne

An investigation was made of the respiratory properties and the role of the mitochondria isolated from one phosphoenolpyruvate carboxykinase (PCK)-CAM plant Ananas comosus (pineapple) in malate metabolism during CAM phase III. Pineapple mitochondria showed very high malate dehydrogenase (MDH), and low malic enzyme (ME) and glutamate-oxaloacetate transaminase (GOT) activities. The mitochondria readily oxidized succinate and NADH with high rates and coupling, while they only oxidized NADPH in the presence of Ca(2+). Pineapple mitochondria oxidized malate with low rates under most assay conditions, despite increasing malate concentrations, optimizing pH, providing cofactors such as coenzyme A, thiamine pyrophosphate, and NAD(+), and supplying individually external glutamate or GOT. However, providing glutamate and GOT simultaneously strongly increased the rates of malate oxidation. The OAA easily permeated the mitochondrial membranes to import into or export out of pineapple mitochondria during malate oxidation, but the mitochondria did not consume external Asp or alpha-KG. These results suggest that OAA played a significant role in the mitochondrial malate metabolism of pineapple, in which malate was mainly oxidized by active mMDH to produce OAA which could be exported outside the mitochondria via a malate-OAA shuttle. Cytosolic GOT then consumed OAA by transamination in the presence of glutamate, leading to a large increase in respiration rates. The malate-OAA shuttle might operate as a supporting system for decarboxylation in phase III of PCK-CAM pineapple. This shuttle system may be important in pineapple to provide a source of energy and substrate OAA for cytosolic PCK activity during the day when cytosolic OAA and ATP was limited for the overall decarboxylation process.     

Nitrate reductase and glutamine synthetase activities in relation to growth and nitrogen assimilation in red oak and red ash seedlings: effects of N-forms,N concentration and light intensity

The effects of growing seedlings of red oak (Quercus rubra) and red ash (Fraxinus pennsylvanica) with Hoagland solutions containing five N-regimes, differing in the N-forms (NH₄, NO₃) and concentrations (High and Low), in relation to light intensity were investigated by the utilization of enzymatic markers of the N assimilation pathway, nitrate reductase (NR) and glutamine synthetase (GS). Red oak and red ash showed different patterns of N-assimilation. Red oak seedlings assimilated NO₃ in low amounts in their roots and leaves, whereas red ash seedlings assimilated high amounts of NO₃, mostly in the leaves. A significant amount of constitutive NR activity was found in red oak seedlings supplied with NH₄ N-regime. This could be characteristic of a species adapted to soils that are poor in nitrogen. Root GS activity was lower in red oak seedlings than in red ash seedlings, indicating that the rate of NH₄ assimilation differed in these two hardwood species. Low irradiance reduced growth of both hardwood species, but greatly affected the specific leaf area of red ash and reduced NO₃ assimilation (when data are expressed per leaf area). Both species reacted similarly to N-regimes in terms of relative growth rate.     

C4 isoform of NADP-malate dehydrogenase. cDNA cloning and expression in leaves of C4, C3, and C3-C4 intermediate species of Flaveria.

In C4 plants of the NADP-malic enzyme type, an abundant, mesophyll cell-localized NADP-malate dehydrogenase (MDH) acts to convert oxaloacetate, the initial product of carbon fixation, to malate before it is shuttled to the bundle sheath. Since NADP-MDH has different but important roles in leaves of C3 and C4 plants, we have cloned and characterized a nearly full-length cDNA encoding NADP-MDH from Flaveria trinervia (C4) to permit comparative structure/expression studies within the genus flaveria. The dicot genus Flaveria includes C3-C4 intermediate species, as well as C3 and C4 species. We show that the previously noted differences in NADP-MDH activity levels among C3, C4, and C3-C4 Flaveria species are in part due to interspecific differences in mRNA accumulation. We also show that the NADP-MDH gene appears to be present as a single copy among different Flaveria species, suggesting that a pre-existing gene has been reregulated during the evolution from C3 to C4 plants to accommodate the abundance and localization requirements of the C4 cycle.     

Effect of drought stress on net CO2 uptake by Zea leaves

The net CO₂ assimilation by leaves of maize (Zea mays L. cv. Adonis) plants subjected to slow or rapid dehydration decreased without changes in the total extractable activities of phosphoenolpyruvate carboxylase (PEPC), malate dehydrogenase (MDH) and malic enzyme (ME). The phosphorylation state of PEPC extracted from leaves after 2–3 h of exposure to light was not affected by water deficit, either. Moreover, when plants which had been slowly dehydrated to a leaf relative water content of about 60% were rehydrated, the net CO₂ assimilation by leaves increased very rapidly without any changes in the activities of MDH, ME and PEPC or phosphorylation state of PEPC. The net CO₂-dependent O₂ evolution of a non-wilted leaf measured with an oxygen electrode decreased as CO₂ concentration increased and was totally inhibited when the CO₂ concentration was about 10%. Nevertheless, high CO₂ concentrations (5–10%) counteracted most of the inhibitory effect of water deficit that developed during a slow dehydration but only counteracted a little of the inhibitory effect that developed during a rapid dehydration. In contrast to what could be observed during a rapidly developing water deficit, inhibition of leaf photosynthesis by cis-abscisic acid could be alleviated by high CO₂ concentrations. These results indicate that the inhibition of leaf net CO₂ uptake brought about by water deficit is mainly due to stomatal closure when a maize plant is dehydrated slowly while it is mainly due to inhibition of non-stomatal processes when a plant is rapidly dehydrated. The photosynthetic apparatus of maize leaves appears to be as resistant to drought as that of C₃ plants. The non-stomatal inhibition observed in rapidly dehydrated leaves might be the result of either a down-regulation of the photosynthetic enzymes by changes in metabolite pool sizes or restricted plasmodesmatal transport between mesophyll and bundle-sheath cells.