Limited proteolysis of inactive tetrameric chloroplast NADP-malate dehydrogenase produces active dimers

Redox regulation of NADP-malate dehydrogenase is vital for land plants under fluctuating light environment

Many enzymes involved in photosynthesis possess highly conserved cysteine residues that serve as redox switches in chloroplasts. These redox switches function to activate or deactivate enzymes during light-dark transitions and have the function of fine-tuning their activities according to the intensity of light. Accordingly, many studies on chloroplast redox regulation have been conducted under the hypothesis that "fine regulation of the activities of these enzymes is crucial for efficient photosynthesis." However, the impact of the regulatory system on plant metabolism is still unclear. To test this hypothesis, we here studied the impact of the ablation of a redox switch in chloroplast NADP-malate dehydrogenase (MDH). By genome editing, we generated a mutant plant whose MDH lacks one of its redox switches and is active even in dark conditions. Although NADPH consumption by MDH in the dark is expected to be harmful to plant growth, the mutant line did not show any phenotypic differences under standard long-day conditions. In contrast, the mutant line showed severe growth retardation under short-day or fluctuating light conditions. These results indicate that thiol-switch redox regulation of MDH activity is crucial for maintaining NADPH homeostasis in chloroplasts under these conditions.

Malate Circulation: Linking Chloroplast Metabolism to Mitochondrial ROS

In photosynthetic cells, chloroplasts and mitochondria are the sites of the core redox reactions underpinning energy metabolism. Such reactions generate reactive oxygen species (ROS) when oxygen is partially reduced. ROS signaling leads to responses by cells which enable them to adjust to changes in redox status. Recent studies in Arabidopsis thaliana reveal that chloroplast NADH can be used to generate malate which is exported to the mitochondrion where its oxidation regenerates NADH. Oxidation of this NADH produces mitochondrial ROS (mROS) which can activate signaling systems to modulate energy metabolism, and in certain cases can lead to programmed cell death (PCD). We propose the term 'malate circulation' to describe such redistribution of reducing equivalents to mediate energy homeostasis in the cell.

Flexibility in the Energy Balancing Network of Photosynthesis Enables Safe Operation under Changing Environmental Conditions

Given their ability to harness chemical energy from the sun and generate the organic compounds necessary for life, photosynthetic organisms have the unique capacity to act simultaneously as their own power and manufacturing plant. This dual capacity presents many unique challenges, chiefly that energy supply must be perfectly balanced with energy demand to prevent photodamage and allow for optimal growth. From this perspective, we discuss the energy balancing network using recent studies and a quantitative framework for calculating metabolic ATP and NAD(P)H demand using measured leaf gas exchange and assumptions of metabolic demand. We focus on exploring how the energy balancing network itself is structured to allow safe and flexible energy supply. We discuss when the energy balancing network appears to operate optimally and when it favors high capacity instead. We also present the hypothesis that the energy balancing network itself can adapt over longer time scales to a given metabolic demand and how metabolism itself may participate in this energy balancing.

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.

L-Malate dehydrogenase activity in the reductive arm of the incomplete citric acid cycle of Nitrosomonas europaea

The autotrophic nitrifying bacterium Nitrosomonas europaea does not synthesize 2-oxoglutarate (α-ketoglutarate) dehydrogenase under aerobic conditions and so has an incomplete citric acid cycle. L-malate (S-malate) dehydrogenase (MDH) from N. europaea was predicted to show similarity to the NADP(+)-dependent enzymes from chloroplasts and was separated from the NAD(+)-dependent proteins from most other bacteria or mitochondria. MDH activity in a soluble fraction from N. europaea ATCC 19718 was measured spectrophotometrically and exhibited simple Michaelis-Menten kinetics. In the reductive direction, activity with NADH increased from pH 6.0 to 8.5 but activity with NADPH was consistently lower and decreased with pH. At pH 7.0, the K m for oxaloacetate was 20 μM; the K m for NADH was 22 μM but that for NADPH was at least 10 times higher. In the oxidative direction, activity with NAD(+) increased with pH but there was very little activity with NADP(+). At pH 7.0, the K m for L-malate was 5 mM and the K m for NAD(+) was 24 μM. The reductive activity was quite insensitive to inhibition by L-malate but the oxidative activity was very sensitive to oxaloacetate. MDH activity was not strongly activated or inhibited by glycolytic or citric acid cycle metabolites, adenine nucleotides, NaCl concentrations, or most metal ions, but increased with temperature up to about 55 °C. The reductive activity was consistently 10-20 times higher than the oxidative activity. These results indicate that the L-malate dehydrogenase in N. europaea is similar to other NAD(+)-dependent MDHs (EC 1.1.1.37) but physiologically adapted for its role in a reductive biosynthetic sequence.

Light-modulated NADP-malate dehydrogenases from mossfern and green algae: insights into evolution of the enzyme's regulation

Chloroplast NADP-dependent malate dehydrogenase is one of the best-studied light-regulated enzymes. In C3 plants, NADP-MDH is a part of the 'malate valve' that controls the export of reducing equivalents in the form of malate to the cytosol. NADP-MDH is completely inactive in the dark and is activated in the light with reduced thioredoxin. Compared with its permanently active NAD-linked counterparts, NADP-MDH exhibits N- and C-terminal sequence extensions, each bearing one regulatory disulphide. Upon reduction of the C-terminal disulphide, the enzyme active site becomes accessible for the substrate. Reduction of the N-terminal disulphide promotes a conformational change advantageous for catalysis. To trace the evolutionary development of this intricate regulation mechanism, we isolated cDNA clones for NADP-MDH from the mossfern Selaginella and from two unicellular green algae. While the NADP-MDH sequence from Selaginella demonstrates the classic cysteine pattern of the higher plant enzyme, the sequences from the green algae are devoid of the N-terminal regulatory disulphide. Phylogenetic analysis of new sequences and of those available in the databases led to the conclusion that the chloroplast NADP-MDH and the cytosolic NAD-dependent form arose via duplication of an ancestral eubacterial gene, which preceded the separation of plant and animal lineages. Redox-sensitive NADP-MDH activity was detected only in the 'green' plant lineage starting from the primitive prasinophytic algae but not in cyanobacteria, Cyanophora paradoxa, red algae and diatoms. The latter organisms therefore appear to utilize mechanisms other than the light-regulated 'malate valve' to remove from plastids excessive electrons produced by photosynthesis.

The autoinhibition of sorghum NADP malate dehydrogenase is mediated by a C-terminal negative charge

The chloroplastic NADP malate dehydrogenase is completely inactive in its oxidized form and is activated by thiol/disulfide interchange with reduced thioredoxin. To elucidate the molecular mechanism underlying the absence of activity of the oxidized enzyme, we used site-directed mutagenesis to delete or substitute the two most C-terminal residues (C-terminal Val, penultimate Glu, both bearing negative charges). We also combined these mutations with the elimination of one or both of the possible regulatory N-terminal disulfides by mutating the corresponding cysteines. Proteins mutated at the C-terminal residues had no activity in the oxidized form but were partially inhibited when pretreated with the histidine-specific reagent diethyl pyrocarbonate before activation, showing that the active site was partially accessible. Proteins missing both N-terminal regulatory disulfides reached almost full activity without activation upon elimination of the negative charge of the penultimate Glu. These results strongly support a model where the C-terminal extension is docked into the active site through a negatively charged residue, acting as an internal inhibitor. They show also that the reduction of both N-terminal bridges is necessary to release the C-terminal extension from the active site. This is the first report for a thiol-activated enzyme of a regulatory mechanism resembling the well known intrasteric inhibition of protein kinases.

C-terminal truncation of spinach chloroplast NAD(P)-dependent glyceraldehyde-3-phosphate dehydrogenase prevents inactivation and reaggregation

Chloroplast NAD(P)-dependent glyceraldehyde-3-phosphate dehydrogenase (NAD(P)-GAPDH; EC 1.2.1.13) consists of two types of subunits: GapA and GapB, which are rather similar, except that GapB carries an unique C-terminal sequence extension. Here, we report evidence that this sequence extension might be responsible for aggregation and dark inactivation of the enzyme in vivo. Recently, it had been demonstrated that upon limited proteolysis of the purified 600 kDa enzyme, using the Staphylococcus aureus V8 endoproteinase (Zapponi et al. (1993) Biol. Chem. Hoppe-Seyler 374, 395-402), the C-terminus of GapB can be removed, giving rise to the 150 kDa form. Based on these findings, we analyzed the changed catalytic properties of the enzyme after proteolysis and its ability to reaggregate. The time-course of proteolysis is paralleled by a strong increase in enzyme activity and the appearance of the tetrameric enzyme form, the increase of apparent activity preceding disaggregation. The proteolyzed enzyme is characterized by its increased affinity towards the substrate 1,3-bisphosphoglycerate and thus resembles the fully activated intact enzyme. In contrast to the effector-mediated activation of the intact enzyme, both proteolytic activation and the resulting disaggregation of the high-molecular-weight form cannot be reversed, even by incubation with NAD.

Cysteines of chloroplast NADP-malate dehydrogenase form mixed disulfides

Chloroplast NADP-malate dehydrogenase (NADP-MDH) from pea and from spinach was N-terminally truncated by limited proteolysis with Staphylococcus aureus protease V8. The resulting monomeric enzymes lacking, respectively, the 37 and 38 N-terminal amino acids were inactive. Reduction and addition of low concentrations of guanidine-HCl (50-100 mM) resulted in a highly active enzyme of 850 units per mg protein. Equilibration of the truncated enzyme with various glutathione (GSH) redox buffers and assaying its activity in the presence of guanidine-HCl was used to establish the existence of protein-GSH mixed disulfides. This finding was further confirmed using incorporation of radioactively labelled thiol. The possible function of such cysteine modifications under oxidative stress and their regeneration by the thioredoxin system in the light is discussed.

Mechanism of light modulation: identification of potential redox-sensitive cysteines distal to catalytic site in light-activated chloroplast enzymes

Light-dependent reduction of target disulfides on certain chloroplast enzymes results in a change in activity. We have modeled the tertiary structure of four of these enzymes, namely NADP-linked glyceraldehyde-3-P dehydrogenase, NADP-linked malate dehydrogenase, sedoheptulose bisphosphatase, and fructose bisphosphatase. Models are based on x-ray crystal structures from non-plant species. Each of these enzymes consists of two domains connected by a hinge. Modeling suggests that oxidation of two crucial cysteines to cystine would restrict motion around the hinge in the two dehydrogenases and influence the conformation of the active site. The cysteine residues in the two phosphatases are located in a region known to be sensitive to allosteric modifiers and to be involved in mediating structural changes in mammalian and microbial fructose bisphosphatases. Apparently, the same region is involved in covalent modification of phosphatase activity in the chloroplast.

Cloning, site-specific mutagenesis, expression and characterization of full-length chloroplast NADP-malate dehydrogenase from Pisum sativum

Chloroplast NADP-dependent malate dehydrogenase is regulated by a dithiol redox reaction. The assignment of the groups involved, requires the primary structure of the enzyme to be known. Using the polymerase chain reaction and the cDNA library of Pisum sativum, the sequence of the enzyme and its targeting signal was determined. The gene was cloned in Escherichia coli JM83 and expressed in E. coli JM83 and E. coli B at high yield. The determination of the physical properties of the gene product proves the recombinant protein to be indistinguishable from the enzyme purified from the plant. This holds true, in spite of the fact that the plant enzyme lacks 11 N-terminal residues. The lengths of the complete polypeptide chain of the recombinant enzyme and its transit peptide are 388 and 53 residues, respectively. The comparison of the sequences of the mature enzyme with those of known chloroplast NADP-MDH shows 83-95% identity, but with mitochondrial or bacterial MDH only approximately 20%. Reduction of the (inactive) oxidized enzyme with dithiothreitol allows mimicking of the in vivo activation. The reaction follows a consecutive second-order-kinetics mechanism. Guanidinium chloride (GdmCl) at concentrations below 0.4 M leads to a significant activation of the oxidized form of the enzyme. At [GdmCl] = 0.4-0.46 M, both oxidized and reduced NADP-MDH show highly cooperative changes in the hydrodynamic and spectral properties, indicating the synchronous breakdown of the quaternary, tertiary and secondary structures. Site-directed mutations C23A and C28A do not quench the regulatory properties of the enzyme; additional substitution of alanine for Cys206 and Cys376 renders the enzyme equally active in both the reduced and the oxidized state. Therefore, one can consider these residues, either alone or in combination with Cys23 and Cys28, as responsible for enzyme activation.

Effects of N-terminal truncations upon chloroplast NADP-malate dehydrogenases from pea and spinach

Using the purification procedure of Fickenscher and Scheibe (Biochim. Biophys. Acta 749 (1983), 249-254) and a modification of the method, we produced a series of NADP-MDH forms from spinach and pea-leaf extracts that were characterized by a stepwise shortening of the N-terminal sequences. Limited proteolysis of the enzymes resulted in the generation of even shorter forms. Immunoprecipitation of the NADP-MDH from crude extracts revealed that the sequences of the intact enzymes from pea, spinach and maize started at a position (Ser) identical with that established for the Sorghum enzyme (Crétin, C., et al. (1990) Eur. J. Biochem. 192, 299-303). Spinach NADP-MDH isolated by conventional methods was shown to represent the intact form. Thus, the kinetic, regulatory and structural properties of the various truncated forms could be compared with those of an intact form. Removal of 5 or 11 amino acids, as occurred during isolation of the pea NADP-MDH, was without any significant effect. The enzymes were all dimeric and still exhibited the characteristic redox-regulatory properties. However, removal of 31 and 37 amino acids using aminopeptidase K resulted in the formation of active monomers characterized by only slightly lowered affinities towards the substrates, a shift of their pH optimum from 8 to 7, the loss of oxaloacetate inhibition and an increased maximal velocity. Although these forms lacked most or all of the N-terminal extra-peptide, including the 2 cysteines involved in redox-modification, they were still sensitive to the redox-potential. However, the low concentration of thiol required for immediate and complete restoration of any lost activity (40 mM beta-mercaptoethanol) suggested that this reaction might not be relevant for redox-regulation in vivo.

Limited proteolysis of NADP-malate dehydrogenase from pea chloroplast by aminopeptidase K yields monomers. Evidence of proteolytic degradation of NADP-malate dehydrogenase during purification from pea

NADP-malate dehydrogenase (L-malate: NADP oxidoreductase, EC 1.1.1.82) from leaves of Pisum sativum has been purified to homogeneity, as judged by polyacrylamide gel electrophoresis. In the crude leaf extract and in the absence of protease inhibitors in the isolation medium, the N-terminus of NADP-MDH was found to be highly susceptible to proteolysis. Evidence of proteolysis during purification includes observations of reduced subunit size on SDS-PAGE and reduced specific activity. Experiments were carried out to investigate the function of the N-terminal amino acid sequence extension of NADP-MDH. Limited proteolysis of highly active (600 units/mg protein) NADP-MDH using aminopeptidase K yielded catalytically active monomers of 34.7 kDa. The results support the conclusions that the N-terminal region is located at the surface of the protein, and that for maintenance of the native NADP-MDH dimer an N-terminal amino acid sequence is important.

Malate dehydrogenase isoenzymes: cellular locations and role in the flow of metabolites between the cytoplasm and cell organelles

Malate dehydrogenases belong to the most active enzymes in glyoxysomes, mitochondria, peroxisomes, chloroplasts and the cytosol. In this review, the properties and the role of the isoenzymes in different compartments of the cell are compared, with emphasis on molecular biological aspects. Structure and function of malate dehydrogenase isoenzymes from plants, mammalian cells and ascomycetes (yeast, Neurospora) are considered. Significant information on evolutionary aspects and characterisation of functional domains of the enzymes emanates from bacterial malate and lactate dehydrogenases modified by protein engineering. The review endeavours to give up-to-date information on the biogenesis and intracellular targeting of malate dehydrogenase isoenzymes as well as enzymes cooperating with them in the flow of metabolites of a given pathway and organelle.

A prediction of the three-dimensional structure of maize NADP(+)-dependent malate dehydrogenase which explains aspects of light-dependent regulation unique to plant enzymes

A model has been built for the plant NADP-malate dehydrogenase from Zea mays, a key enzyme in photosynthesis, which undergoes light-dependent regulation. The model was based on sequence and presumed structural homology to the known three-dimensional structure of mammalian porcine cytosolic NAD-malate dehydrogenase. A cystine-loop present in an extended C-terminal region of plant NADP-malate dehydrogenases was modelled using molecular mechanics and computer graphical methods, based on the assumption that a disulphide bridge exists in the inactive form of the enzyme between Cys351 and Cys363. The predicted conformation of the intact C-terminal cystine-loop suggests that the extended polypeptide will bind in the active centre and inhibit enzyme activity. Another ionizable cysteine residue in the active site is predicted to control the charge of the catalytic His215 and might be responsible for the uniquely tight binding of the positively charged nicotinamide ring of NADP+ in this and other C4 and C3 plant NADP-malate dehydrogenases.

Properties of recombinant NADP-malate dehydrogenases from Sorghum vulgare leaves expressed in Escherichia coli cells

In this study, a cDNA clone coding for sorghum leaf NADP-malate dehydrogenase [Crétin, C., Luchetta, P., Joly, C., Decottignies, P., Lepiniec, L., Gadal, P., Sallantin, M., Huet, J. C. & Pernollet, J. C. (1990) Eur. J. Biochem. 192, 299-303] was used either in the full-length form or in a shorter form deprived of the 5' end coding for the transit peptide. Both cDNA fragments were cloned into the expression vector pKK233-2 and the resulting constructions were used to transform E. coli cells. The bacterial cells which do not contain any NADP-dependent malate dehydrogenase before transformation were able to express the protein after transformation and induction, as detected both by activity measurements and by immunoblot. The recombinant proteins could be purified to homogeneity and their biochemical characteristics studied. They were identical to those of the enzyme isolated from corn or sorghum leaves, including the well known redox regulatory properties. The NADP-malate dehydrogenases derived from both constructions had a similar subunit size and the analysis of their N-terminal sequences revealed that E. coli cells were able to recognize the processing signal of the precursor polypeptide and to mature and assemble the protein in a manner similar to higher plants.

Primary structure and analysis of the location of the regulatory disulfide bond of pea chloroplast NADP-malate dehydrogenase

Purified pea chloroplast NADP-malate dehydrogenase (S)-malate: NADP+ oxidoreductase, EC 1.1.1.82) was digested with trypsin and the resulting peptides were separated by HPLC and sequenced. Together with the information from earlier work (Fickenscher, K. et al. (1987) Eur. J. Biochem. 168, 653-658) the total sequence is not known to an extent of 78%. Comparison with the sequence of the corn NADP-malate dehydrogenase deduced from its cDNA (Metzler, M.C. et al. (1989) Plant Mol. Biol. 12, 713-722) showed 84% agreement; however, the 11 N-terminal residues exhibit only 27% similarity. The N- and C-terminal extrapeptides of the pea NADP-malate dehydrogenase when aligned with non-regulatory NAD-malate dehydrogenases from bacteria or mammals consist of 30 and 17 amino acids, respectively. Since all cysteine-containing peptides were sequenced, the number of eight cysteines per subunit of the pea enzyme was established. The native, oxidized enzyme is characterized by an extremely slow reactivity of two thiols. Titration of the thiols of the denatured, oxidized enzyme both with DTNB and with pCMB resulted in six thiols not involved in disulfide formation. Therefore, one disulfide bridge must be present per 38.9 kDa subunit. Analysis of disulfide bonds by urea gel electrophoresis confirmed this finding. Using digestion products of NADP-malate dehydrogenase with aminopeptidase K, the location of the single disulfide bridge was established to be on the N-terminal arm (Cys-12 and Cys-17) of the polypeptide chain.

Oligomeric enzymes in the C4 pathway of photosynthesis

This review deals with the factors controlling the aggregation-state of several enzymes involved in C4 photosynthesis, namely phosphoenolpyruvate carboxylase, NAD-and NADP-malic enzyme, NADP-malic dehydrogenase and pyruvate, phosphate dikinase and its regulatory protein. All of these enzymes are oligomeric and have been shown to undergo changes in their quaternary structure in vitro under different conditions. The activity changes linked to variations in aggregation-state are discussed in terms of their putative physiological role in the regulation of C4 metabolism.

Structural and catalytic properties of oxidized and reduced chloroplast NADP-malate dehydrogenase upon denaturation and renaturation

Chloroplast NADP-dependent malate dehydrogenase exists in two interconvertible forms: the inactive disulfide-containing form and the active dithiol form. No major difference in secondary structure or conformation was found between the oxidized and the reduced enzyme as determined by circular dichroism and intrinsic protein fluorescence. The guanidine/HCl-dependent unfolding of the enzyme is characterized by two transition midpoints: those of the reduced enzyme are lower by about 0.2 M guanidine/HCl compared to the oxidized enzyme. As shown by analytical ultracentrifugation, there was no effect of guanidine/HCl concentrations up to 0.25 M on the quaternary structure of the enzyme in its oxidized and reduced forms: both sedimentation coefficient (S20,w = 4.9 +/- 0.1 S) and sedimentation equilibrium (75 +/- 3 kDa) yield the dimer. In the oxidized state the enzyme undergoes guanidine-dependent dissociation to the monomer with a midpoint of transition at 0.5 M. The kinetics of unfolding were found to be significantly faster for the reduced than for the oxidized enzyme. Renaturation and reactivation of reduced enzyme was more rapid and occurred with higher yields (100%) than for the oxidized enzyme (60-80% yield). Furthermore, the effect of denaturants on catalytic activity, and reductive activation of the oxidized form, were studied. Both increase in protein fluorescence and a stimulatory effect on the activities at low guanidine/HCl concentrations were observed for the oxidized and the reduced form of the enzyme. Denaturants increase the rate of reductive activation of NADP-malate dehydrogenase.

Maize NADP-malate dehydrogenase: cDNA cloning, sequence, and mRNA characterization

We report here the isolation, characterization and nucleotide sequence of clones encoding the maize chloroplastic NADP-malate dehydrogenase (NADP-MDH) which functions in the C4 cycle of photosynthesis. A nearly full-length NADP-MDH cDNA clone was isolated using antibodies against the purified protein. This clone hybridizes to a 1600 base mRNA that is eight times more abundant in light-grown maize leaves than in etiolated leaves. Transcription in leaves begins 230 bp upstream of the predicted start of translation, as shown by primer extension experiments. The encoded amino acid sequence predicts that NADP-MDH is synthesized as a preprotein of 432 amino acids (46 865 Da) which is processed into a mature protein of 375 amino acids (40 934 Da) with removal of a 57 amino acid transit peptide (5 931 Da). We identify regions of similarity between the maize NADP-MDH and other MDH polypeptides.