Kinetic properties of NAD malic enzyme from cauliflower

The kinetic characteristics of NAD malic enzyme purified to homogeneity from cauliflower florets have been examined. Free NAD⁺ is the active form of this coenzyme. Double-reciprocal plots of data obtained by varying NAD⁺ and malate^2? at a saturating concentration of Mg²⁺ or by varying Mg²⁺ and NAD⁺ at a saturating level of malate^2? are of intersecting type. This indicates that NAD malic enzyme obeys a sequential mechanism. Analysis of these sets of data suggests that each of these substrate pairs binds randomly to the enzyme. However, each substrate binds tighter when others are already present on the enzyme. NAD malic enzyme cannot decarboxylate malate^2? in the absence of either Mg²⁺ or NAD⁺. Arrhenius plots of the NAD-linked reaction are concave downward, indicating the existence of two rate-determining steps with activation energies of 26.5 and 14.2 kcal/mol, respectively. In addition to Mg²⁺, the enzyme can also use Mn²⁺ and Co²⁺. Using Co²⁺ in place of Mg²⁺ does not change V_max or K_m,malate^2? but the K_m for metal and NAD⁺ are greatly decreased. At pH 7.0 and above, Mn²⁺ isotherms and malate^2? curves with Mn²⁺ are nonlinear and appear to be composed of two separate saturation curves. NAD malic enzyme is completely and irreversibly inactivated by N-ethylmaleimide. The enzyme is also irreversibly inactivated approximately 50% by KCNO.     

pH Effects on the Activity and Regulation of the NAD Malic Enzyme

The NAD malic enzyme shows a pH optimum of 6.7 when complexed to Mg²⁺ and NAD⁺ but shifts to 7.0 when the catalytically competent enzyme-substrate (E-S) complex forms upon binding malate⁻². This is characteristic of an induced conformational change. The slope of the V_max or V_max/K_m profiles is steeper on the alkaline side of the pH optimum. The K_m for malate increases markedly under alkaline conditions but is not greatly affected by pH values below the optimum. The loss of catalysis on the acidic side is due to protonation of a single residue, pK 5.9, most likely histidine. Photooxidation inactivation with methylene blue showed that a histidine is required for catalytic activity. The location of this residue at or near the active site is revealed by the protection against inactivation offered by malate. Three residues, excluding basic residues such as lysine (which have also been shown to be vital for catalytic activity, must be appropriately ionized for malate decarboxylation to proceed optimally. Two of these residues directly participate in the binding of substrates and are essential for the decarboxylation of malate. A pK of 7.6 was determined for the two residues required by the E-S complex to achieve an active state, this composite value representing both histidine and cysteine suggests that both have decisive roles in the operation of the enzyme. A major change in the enzyme takes place as protonation nears the pH optimum, this is recorded as a change in the enzyme's intrinsic affinity for malate (K_{m pH6.7} = 9.2 millimolar, K_{m pH7.7} = 28.3 millimolar). Similar changes in K_m have been observed for the NAD malic enzyme as it shifts from dimer to tetramer. It is most likely that the third ionizable group (probably a cysteine) revealed by the V_max/K_m profile is needed for optimal activity and is involved in the association-dissociation behavior of the enzyme.     

Carbon dioxide metabolism in leaf epidermal tissue

A number of plant species were surveyed to obtain pure leaf epidermal tissue in quantity. Commelina communis L. and Tulipa gesnariana L. (tulip) were chosen for further work. Chlorophyll a/b ratios of epidermal tissues were 2.41 and 2.45 for C. communis and tulip, respectively. Phosphoenolpyruvate carboxylase, ribulose-1,5-diphosphate carboxylase, malic enzyme, and NAD⁺ and NADP⁺ malate dehydrogenases were assayed with epidermal tissue and leaf tissue minus epidermal tissue. In both species, there was less ribulose 1,5-diphosphate than phosphoenolpyruvate carboxylase activity in epidermal tissue whether expressed on a protein or chlorophyll basis whereas the reverse was true for leaf tissue minus epidermal tissue. In both species, malic enzyme activities were higher in epidermal tissue than in the remaining leaf tissue when expressed on a protein or chlorophyll basis. In both species, NAD⁺ and NADP⁺ malate dehydrogenase activities were higher in the epidermal tissue when expressed on a chlorophyll basis; however, on a protein basis, the converse was true. Microautoradiography of C. communis epidermis and histochemical tests for keto acids suggested that CO₂ fixation occurred predominantly in the guard cells. The significance and possible location of the enzymes are discussed in relation to guard cell metabolism.     

Changes in NAD(P)+-dependent malic enzyme and malate dehydrogenase activities during fibroblast proliferation

A sensitive isotope exchange method was developed to assess the requirements for and compartmentation of pyruvate and oxalacetate production from malate in proliferating and nonproliferating human fibroblasts. Malatedependent pyruvate production (malic enzyme activity) in the particulate fraction containing the mitochondria was dependent on either NAD⁺ or NADP⁺. The production of pyruvate from malate in the soluble, cytosolic fraction was strictly dependent on NADP⁺. Oxalacetate production from malate (malate dehydrogenase, EC 1.1.1.37) in both the particulate and soluble fraction was strictly dependent on NAD⁺. Relative to nonproliferating cells, NAD⁺-linked malic enzyme activity was slightly reduced and the NADP⁺-linked activity was unchanged in the particulate fraction of serum-stimulated, exponentially proliferating cells. However, a reduced activity of particulate malate dehydrogenase resulted in a two-fold increase in the ratio of NAD(P)⁺-linked malic enzyme to NAD⁺-linked malate dehydrogenase activity in the particulate fraction of proliferating fibroblasts. An increase in soluble NADP⁺-dependent malic enzyme activity and a decrease in NAD⁺-linked malate dehydrogenase indictated an increase in the ratio of pyruvate-producing to oxalacetate-producing malate oxidase activity in the cytosol of proliterating cells. These coordinate changes may affect the relative amount of malate that is oxidized to oxalacetate and pyruvate in proliferating cells and, therefore, the efficient utilization of glutamine as a respiratory fuel during cell proliferation.     

Effect of bicarbonate and oxaloacetate on malate oxidation by spinach leaf mitochondria

Mitochondria isolated from spinach leaves oxidized malate by both a NAD⁺-linked malic enzyme and malate dehydrogenase. In the presence of sodium arsenite the accumulation of oxaloacetate and pyruvate during malate oxidation was strongly dependent on the malate concentration, the pH in the reaction medium and the metabolic state condition.Bicarbonate, especially at alkaline pH, inhibited the decarboxylation of malate by the NAD⁺-linked malic enzyme in vitro and in vivo. Analysis of the reaction products showed that with 15 mM bicarbonate, spinach leaf mitochondria excreted almost exclusively oxaloacetate.The inhibition by oxaloacetate of malate oxidation by spinach leaf mitochondria was strongly dependent on malate concentration, the pH in the reaction medium and on the metabolic state condition.The data were interpreted as indicating that: (a) the concentration of oxaloacetate on both sides of the inner mitochondrial membrane governed the efflux and influx of oxaloacetate; (b) the NAD⁺/NADH ratio played an important role in regulating malate oxidation in plant mitochondria; (c) both enzymes (malate dehydrogenase and NAD⁺-linked malic enzyme) were competing at the level of the pyridine nucleotide pool, and (d) the NAD⁺-linked malic enzyme provided NADH for the reversal of the reaction catalyzed by the malate dehydrogenase.     

Malic enzyme: its purification and characterization fromMucor circinelloides and occurrence in other oleaginous fungi

Malic enzyme was purified 43-fold from Mucor circinelloides. The enzyme was dependent on Mg²⁺ or Mn²⁺ for activity, was not active with Dmalate and had a pH optimum at 7.8. The apparent K_m values for malate and NADP⁺ were 488 ΜM and 41 Μm respectively. The M_r of the native enzyme was 160 kDa. Five metabolic analogues of malate: oxaloacetate, tartronic acid, 1-methylenecyclopropane trans-2,3-dicarboxyIic acid, malonic acid and glutaric acid, were found to inhibit malic enzyme activity at 10 mM. Four oleaginous fungi, Mucor circinelloides, Mortierella alpina, Mortierella elongata and Pythium ultimum, were also examined, all possessed a soluble malic enzyme, two also possessed a microsomal malic enzyme.     

Plant pyruvate dehydrogenase complex: analysis of the kinetic properties and metabolite regulation

The pyruvate dehydrogenase complex was isolated from the mitochondria of broccoli florets and shown to be similar in its reaction mechanism to the complexes from other sources. Three families of parallel lines were obtained for the initial velocity patterns, indicating a multisite ping-pong mechanism. The apparent K_m values obtained were 321 ± 18, 148 ± 13, and 7.2 ± 0.51 μm for pyruvate, NAD⁺, and CoA, respectively. Product inhibition studies using acetyl-CoA and NADH yielded results which were in agreement with those predicted by the multisite ping-pong mechanism. Acetyl-CoA and NADH were found to be competitive inhibitors versus CoA and NAD⁺, respectively. All other substrate-product combinations showed uncompetitive inhibition patterns, except for acetyl-CoA versus NAD⁺. Among various metabolites tested, only hydroxypyruvate (K_i = 0.11 mM) and glyoxylate (K_i = 3.27 mM) were found to be capable of inhibiting the broccoli enzyme to a significant degree. Initial velocity patterns using Mg²⁺? or Ca²⁺-thiamine pyrophosphate and pyruvate as the variable substrate were found to be consistent with an equilibrium ordered mechanism where Mg? or Ca-thiamine pyrophosphate bind first, with dissociation constants of 33.8 and 3 μm, respectively. The Mg- or Ca-thiamine pyrophosphate complexes also dissociated rapidly from the enzyme complex.     

Photosynthetic CO(2) Fixation Products and Activities of Enzymes Related to Photosynthesis in Bermudagrass and Other Plants

After a 5-second exposure of illuminated bermudagrass (Cynodon dactylon L. var. `Coastal') leaves to ¹⁴CO₂, 84% of the incorporated ¹⁴C was recovered as aspartate and malate. After transfer from ¹⁴CO₂-air to ¹²CO₂-air under continuous illumination, total radioactivity decreased in aspartate, increased in 3-phosphoglyceric acid and alanine, and remained relatively constant in malate. Carbon atom 1 of alanine was labeled predominantly, which was interpreted to indicate that alanine was derived from 3-phosphoglyceric acid. The activity of phosphoenolpyruvate carboxylase, alkaline pyrophosphatase, adenylate kinase, pyruvate-phosphate dikinase, and malic enzyme in bermudagrass leaf extracts was distinctly higher than those in fescue (Festuca arundinacea Schreb.), a reductive pentose phosphate cycle plant. Assays of malic enzyme activity indicated that the decarboxylation of malate was favored. Both malic enzyme and NADP⁺-specific malic dehydrogenase activity were low in bermudagrass compared to sugarcane (Saccharum officinarum L.). The activities of NAD⁺-specific malic dehydrogenase and acidic pyrophosphatase in leaf extracts were similar among the plant species examined, irrespective of the predominant cycle of photosynthesis. Ribulose-1, 5-diphosphate carboxylase in C₄-dicarboxylic acid cycle plant leaf extracts was about 60%, on a chlorophyll basis, of that in reductive pentose phosphate cycle plants.     

Regulatory properties of malic enzyme in the oleaginous yeast, Yarrowia lipolytica, and its non-involvement in lipid accumulation

Malic enzyme (EC 1.1.1.40) converts l-malate to pyruvate and CO₂ providing NADPH for metabolism especially for lipid biosynthesis in oleaginous microorganisms. However, its role in the oleaginous yeast, Yarrowia lipolytica, is unclear. We have cloned the malic enzyme gene (YALI0E18634g) from Y. lipolytica into pET28a, expressed it in Escherichia coli and purified the recombinant protein (YlME). YlME used NAD⁺ as the primary cofactor. K_m values for NAD⁺ and NADP⁺ were 0.63 and 3.9 mM, respectively. Citrate, isocitrate and α-ketoglutaric acid (>5 mM) were inhibitory while succinate (5–15 mM) increased NADP⁺- but not NAD⁺-dependent activity. To determine if fatty acid biosynthesis could be increased in Y. lipolytica by providing additional NADPH from an NADP⁺-dependent malic enzyme, the malic enzyme gene (mce2) from an oleaginous fungus, Mortierella alpina, was expressed in Y. lipolytica. No significant changes occurred in lipid content or fatty acid profiles suggesting that malic enzyme is not the main source of NADPH for lipid accumulation in Y. lipolytica.     

Kinetic and Structural Properties of NADP-Malic Enzyme from Sugarcane Leaves

Oligomeric structure and kinetic properties of NADP-malic enzyme, purified from sugarcane (Saccharam officinarum L.) leaves, were determined at either pH 7.0 and 8.0. Size exclusion chromatography showed the existence of an equilibrium between the dimeric and the tetrameric forms. At pH 7.0 the enzyme was found preferentially as a 125 kilodalton homodimer, whereas the tetramer was the major form found at pH 8.0. Although free forms of l-malate, NADP⁺, and Mg²⁺ were determined as the true substrates and cofactors for the enzyme at the two conditions, the kinetic properties of the malic enzyme were quite different depending on pH. Higher affinity for l-malate (K_m = 58 micromolar), but also inhibition by high substrate (K_i = 4.95 millimolar) were observed at pH 7.0. l-Malate saturation isotherms at pH 8.0 followed hyperbolic kinetics (K_m = 120 micromolar). At both pH conditions, activity response to NADP⁺ exhibited Michaelis-Menten behavior with K_m values of 7.1 and 4.6 micromolar at pH 7.0 and 8.0, respectively. Negative cooperativity detected in the binding of Mg²⁺ suggested the presence of at least two Mg²⁺ - binding sites with different affinity. The K_a values for Mg²⁺ obtained at pH 7.0 (9 and 750 micromolar) were significantly higher than those calculated at pH 8.0 (1 and 84 micromolar). The results suggest that changes in pH and Mg²⁺ levels could be important for the physiological regulation of NADP-malic enzyme.     

Occurrence of Two Pathways for Malate Oxidation in Bacteroids Isolated from Sesbania rostrata Stem Nodules during C(2)H(2) Reduction

Malate oxidation supported C₂H₂ reduction by bacteroids isolated from Sesbania rostrata stem nodules. Optimal activity reached 7.5 nanomoles per minute per milligram of dry weight and was in the same order of magnitude as that observed with succinate but always required a lower O₂ tension. Malate dehydrogenase (EC 1.1.1.37), purified 66-fold from bacteroids, actively oxidized malate (K_m = 0.19 millimolar). Malic enzyme (EC 1.1.1.39) from Sesbania bacteroids had a lower affinity for malate (K_m = 2.32 millimolar). Both enzymes exclusively required NAD⁺ as cofactor and required an alkaline pH for optimal activity. 2-Oxoglutarate and oxalate, inhibiting malate dehydrogenase and malic enzyme, respectively, were used to specifically block each malate oxidation pathway in bacteroids. The predominance of malate dehydrogenase activity to support bacteroid N₂ fixation was demonstrated. The inhibition of O₂ consumption by 2-oxoglutarate confirmed the importance of the malate dehydrogenase pathway in malate oxidation. It is proposed that the utilization of malate, with regard to O₂, is important in a general strategy of this legume to maintain N₂ fixation under O₂ limited conditions.     

Malate Oxidation in Plant Mitochondria via Malic Enzyme and the Cyanide-insensitive Electron Transport Pathway

Malate oxidation in plant mitochondria proceeds through the activities of two enzymes: a malate dehydrogenase and a NAD⁺-dependent malic enzyme. In cauliflower, mitochondria malate oxidation via malate dehydrogenase is rotenone- and cyanide-sensitive. Addition of exogenous NAD⁺ stimulates the oxidation of malate via malic enzyme and generates an electron flux that is both rotenone- and cyanide-insensitive. The same effects of exogenous NAD⁺ are also observed with highly cyanide-sensitive mitochondria from white potato tubers or with mitochondria from spinach leaves. Both enzymes are located in the matrix, but some experimental data also suggest that part of malate dehydrogenase activity is also present outside the matrix compartment (adsorbed cytosolic malate dehydrogenase?). It is concluded that malic enzyme and a specific pool of NAD⁺/NADH are connected to the cyanide-insensitive alternative pathway by a specific rotenone-insensitive NADH dehydrogenase located on the inner face of the inner membrane. Similarly, malate dehydrogenase and another specific pool of NAD⁺/NADH are connected to the cyanide- (and antimycin-) sensitive pathway by a rotenone-sensitive NADH dehydrogenase located on the inner face of the inner membrane. A general scheme of electron transport in plant mitochondria for the oxidation of malate and NADH can be given, assuming that different pools of ubiquinone act as a branch point between various dehydrogenases, the cyanide-sensitive cytochrome pathway and the cyanide-insensitive alternative pathway.     

Metabolic regulation of malic enzyme activity from Paracoccus denitrificans by glyoxylate and acetylCoA.

$\text{Paracoccus denitrificans}$ contains both NAD⁺- and NADP⁺-linked malic enzyme activities when grown on malate/nitrate. The enzyme is inactive in the absence of NH₄⁺. AcetylCoA inhibits both activities competitively with respect to L-malate. Glyoxylate (0.5 mM) causes 60% inhibition of the NADP⁺-linked activity but has little effect on the NAD⁺-linked activity. Citrate, aspartate, AMP, ADP, and ATP, at 0.5mM, have little effect on either of the two activities. The results are discussed with regards to the control of malic enzyme activity within the cell.     

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     

Pyridine nucleotide transhydrogenases of parasitic helminths.

Mitochondria from the parasitic helminth, Hymenolepis diminuta, catalyzed both NADPH:NAD⁺ and NADH:NADP⁺ transhydrogenase reactions which were demonstrable employing the appropriate acetylpyridine nucleotide derivative as the hydride ion acceptor. Thionicotinamide NAD⁺ would not serve as the oxidant in the former reaction. Under the assay conditions employed, neither reaction was energy linked, and the NADPH:NAD⁺ system was approximately five times more active than the NADH:NADP⁺ system. The NADH:NADP⁺ reaction was inhibited by phosphate and imidazole buffers, EDTA, and adenyl nucleotides, while the NADPH:NAD⁺ reaction was inhibited only slightly by imidazole and unaffected by EDTA and adenyl nucleotides. Enzyme coupling techniques revealed that both transhydrogenase systems functioned when the appropriate physiological pyridine nucleotide was the hydride ion acceptor. An NADH:NAD⁺ transhydrogenase system, which was unaffected by EDTA, or adenyl nucleotides, also was demonstrable in the mitochondria of H. diminuta. Saturation kinetics indicated that the NADH:NAD⁺ reaction was the product of an independent enzyme system. Mitochondria derived from another parasitic helminth, Ascaris lumbricoides, catalyzed only a single transhydrogenase reaction, i.e., the NADH:NAD⁺ activity. Transhydrogenase systems from both parasites were essentially membrane bound and localized on the inner mitochondrial membrane. Physiologically, the NADPH:NAD⁺ transhydrogenase of H. diminuta may serve to couple the intramitochondrial metabolism of malate (via an NADP linked “malic” enzyme) to the anaerobic NADH-dependent ATP-generating fumarate reductase system. In A. lumbricoides, where the intramitochondrial metabolism of malate depends on an NAD-linked “malic” enzyme which is localized primarily in the intermembrane space, the NADH:NAD⁺ transhydrogenase activity may serve physiologically in the translocation of hydride ions across the inner membrane to the anaerobic energy-generating fumarate reductase system.     

Equilibrium constants under physiological conditions for the reactions of the nonphosphorylated pathway of L-serine biosynthesis

The observed equilibrium constants (K_obs) for the reactions of d-2-phosphoglycerate phosphatase, d-2-Phosphoglycerate^3? + H₂O → d-glycerate^? + HPO₄^2?; d-glycerate dehydrogenase (EC 1.1.1.29), d-Glycerate^? + NAD⁺ → NADH + hydroxypyruvate^? + H⁺; and l-serine:pyruvate aminotransferase (EC 2.6.1.51), Hydroxypyruvate^? + l-H · alanine^± → pyruvate^? + l-H · serine^±; have been determined, directly and indirectly, at 38 °C and under conditions of physiological ionic strength (0.25 m) and physiological ranges of pH and magnesium concentrations. From these observed constants and the acid dissociation and metal-binding constants of the substrates, an ionic equilibrium constant (K) also has been calculated for each reaction. The value of K for the d-2-phosphoglycerate phosphatase reaction is 4.00 × 10³m [ΔG⁰ = ?21.4 kJ/mol (?5.12 kcal/mol)]([H₂0] = 1). Values of K_obs for this reaction at 38 °C, [K⁺] = 0.2 m, I = 0.25 M, and pH 7.0 include 3.39 × 10³m (free [Mg²⁺] = 0), 3.23 × 10³m (free [Mg²⁺] = 10^?3m), and 2.32 × 10³m (free [Mg²⁺] = 10^?2m). The value of K for the d-glycerate dehydrogenase reaction has been determined to be 4.36 ± 0.13 × 10^?13m (38 °C, I = 0.25 M) [ΔG⁰ = 73.6 kJ/mol (17.6 kcal/mol)]. This constant is relatively insensitive to free magnesium concentrations but is affected by changes in temperature [ΔH⁰ = 46.9 kJ/mol (11.2 kcal/mol)]. The value of K for the serine:pyruvate aminotransferase reaction is 5.41 ± 0.11 [ΔG⁰ = ?4.37 kJ/mol (?1.04 kcal/mol)] at 38 °C (I = 0.25 M) and shows a small temperature effect [ΔH⁰ = 16.3 kJ/ mol (3.9 kcal/mol)]. The constant showed no significant effect of ionic strength (0.06–1.0 m) and a response to the hydrogen ion concentration only above pH 8.5. The value of K_obs is 5.50 ± 0.11 at pH 7.0 (38 °C, [K⁺] = 0.2 m, [Mg²⁺] = 0, I = 0.25 M). The results have also allowed the value of K for the d-glycerate kinase reaction (EC 2.7.1.31), d-Glycerate^? + ATP^4? → d-2-phosphoglycerate^3? + ADP^3? + H⁺, to be calculated to be 32.5 m (38 °C, I = 0.25 M). Values for K_obs for this reaction under these conditions and at pH 7.0 include 236 (free [Mg²⁺] = 0) and 50.8 (free [Mg²⁺] = 10^?3m).     

NAD+ -dependent malic enzyme of Rhizobium meliloti is required for symbiotic nitrogen fixation

DEAE-cellulose chromatography of extracts of free-living Rhizobium meliloti cells revealed separate NAD⁺-dependent and NADP⁺-dependent malic enzyme activities. The NAD⁺ malic enzyme exhibited more activity with NAD⁺ as cofactor, but also showed some activity with NADP⁺. The NADP⁺ malic enzyme only showed activity when NADP⁺ was supplied as cofactor. Three independent transposon-induced mutants of R. meliloti which lacked NADP⁺ malic enzyme activity (dme) but retained NADP⁺ malic enzyme activity were isolated. In an otherwise wild-type background, the dme mutations did not alter the carbon utilization phenotype; however, nodules induced by these mutants failed to fix N₂. Structurally, these nodules appeared to develop like wild-type nodules up to the stage where N₂-fixation would normally begin. These results support the proposal that NAD⁺ malic enzyme, together with pyruvate dehydrogenase, functions in the generation of acetyl-CoA required for TCA cycle function in N₂-fixing bacteroids which metabolize C₄-dicarboxylic acids supplied by the plant.     

Vacuolar malate uptake is mediated by an anion-selective inward rectifier

Electrophysiological studies using the patch‐clamp technique were performed on isolated vacuoles from leaf mesophyll cells of the crassulacean acid metabolism (CAM) plant Kalanchoë daigremontiana to characterize the malate transport system responsible for nocturnal malic acid accumulation. In the presence of malate on both sides of the membrane, the current–voltage relations of the tonoplast were dominated by a strongly inward‐rectifying anion‐selective channel that was active at cytoplasmic‐side negative voltages. Rectification of the macroscopic conductance was reflected in the voltage‐dependent gating of a 3‐pS malate‐selective ion channel, which showed a half‐maximal open probability at ?43 mV. Also, the time‐averaged unitary currents following a step to a negative voltage corresponded to the time‐dependent kinetics of the macroscopic currents, suggesting that the activity of this channel underlies the anion‐selective inward rectifier. The inward rectifier showed saturation kinetics with respect to malate (apparent K_m of 2.5 mm malate^2? activity), a selectivity sequence of fumarate^2? > malate^2? > Cl^? > maleate^2– ≈ citrate^3–, and greater activity at higher pH values (with an apparent pK of 7.1 and maximum activity at around pH 8.0). All these properties were in close agreement with the characteristics of malate transport observed in isolated tonoplast vesicles. Further, 100 µm niflumate reversibly blocked the activity of the 3‐pS channel and inhibited both macroscopic currents and malate transport into tonoplast vesicles to the same extent. The macroscopic current densities recorded at physiological voltages and the estimated channel density of 0.2 µm^?2 are sufficient to account for the observed rates of nocturnal malic acid accumulation in this CAM plant, suggesting that the 3‐pS, inward‐rectifying, anion‐selective channel represents the principal pathway for malate influx into the vacuole.     

Physical and Kinetic Properties and Regulation of the NAD Malic Enzyme Purified from Leaves of Crassula argentea

The NAD malic enzyme has been purified to near homogeneity from the leaves of Crassula argentea Thunb. The enzyme has two subunits, one of 59,000 daltons, and one of 62,000 daltons. In native gels stained for activity, the enzyme appears to exist in the dimeric, tetrameric, and predominantly the octameric forms.

The enzyme uses either Mg²⁺ or Mn²⁺ as the required divalent cation, and utilizes NADP at a rate less than 20% of that with NAD. With Mn²⁺ the K_m for malate²⁻ is lower than with Mg²⁺, but V_max is lower than with Mg²⁺. In the forward (malate-decarboxylating) direction with NAD, the kinetic parameters are essentially like those observed for the enzyme from C₃ plants. In the reverse reaction, run with Mn²⁺, the activity is 1.5% of that in the forward reaction. The equilibrium constant is 1.1 × 10⁻³ molar.

The kinetic mechanism of the reaction, at least in the forward direction, is sequential, with apparently random binding of all reaction components. Product inhibition patterns confirm this.

The enzyme displays a strong hysteretic lag, which is shortened by high enzyme concentrations, high substrate concentrations, and the presence of the product NADH.

The enzyme is activated by coenzyme A with K_a = 4 micromolar. AMP also shows competitive activation, with K_a = 24 micromolar. The activation by coenzyme A and AMP is additive, implying separate sites for their binding. Phosphoenolpyruvate activates the reaction at low (micromolar) concentrations, but higher concentrations of phosphoenolpyruvate cause deactivation. Fumarate²⁻ is a strong activator, with K_a = 0.3 millimolar. Fructose-1,6-bisphosphate activates the enzyme, but its most pronounced effect is in shortening the lag. Citrate is a competitive inhibitor of malate, with K_i = 4.9 millimolar.