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

Proteolytic cleavage of Arabidopsis thaliana phosphoenolpyruvate carboxykinase-1 modifies its allosteric regulation

Phosphoenolpyruvate carboxykinase (PEPCK) plays a crucial role in gluconeogenesis. In this work, we analyze the proteolysis of Arabidopsis thaliana PEPCK1 (AthPEPCK1) in germinating seedlings. We found that the amount of AthPEPCK1 protein peaks at 24-48 h post-imbibition. Concomitantly, we observed shorter versions of AthPEPCK1, putatively generated by metacaspase-9 (AthMC9). To study the impact of AthMC9 cleavage on the kinetic and regulatory properties of AthPEPCK1, we produced truncated mutants based on the reported AthMC9 cleavage sites. The Δ19 and Δ101 truncated mutants of AthPEPCK1 showed similar kinetic parameters and the same quaternary structure as the wild type. However, activation by malate and inhibition by glucose 6-phosphate were abolished in the Δ101 mutant. We propose that proteolysis of AthPEPCK1 in germinating seedlings operates as a mechanism to adapt the sensitivity to allosteric regulation during the sink-to-source transition.

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.

Avoiding Proteolysis during the Extraction and Purification of Active Plant Enzymes

The aim of this article is to discuss approaches to diagnose and prevent unwanted proteolysis during extraction and isolation of active enzymes from plant tissues. Enzymes are protein catalysts that require great care during sample processing in order to ensure that they remain intact and fully active. Preventing artifactual enzyme modifications ex planta is of utmost importance in order to obtain biologically relevant data. This is particularly problematic following enzyme extraction from plant tissues, which relative to microbes or animals contain relatively low protein amounts coupled with high concentrations of vacuolar proteases. Although cytoplasmic enzymes are not directly accessible to vacuolar proteases owing their physical segregation into different subcellular compartments, this compartmentation is destroyed during cell lysis. Unwanted proteolysis by endogenous proteases is an insidious problem because in many cases the enzyme of interest is only partially degraded and retains catalytic activity. This can not only lead to erroneous conclusions about an enzyme's size, subunit structure and post-translational modifications, but can also result in striking changes to its kinetic and regulatory (i.e. allosteric) properties. Furthermore, the routine addition of class-specific protease inhibitors and/or commercially available (and expensive) protease inhibitor cocktails to extraction and purification buffers does not necessarily preclude partial proteolysis of plant enzymes by endogenous proteases. When antibodies are available, plant scientists are advised to employ immunoblotting to diagnose potential in vitro proteolytic truncation of the enzymes that they wish to characterize, as well as to test the effectiveness of specific protease inhibitors in overcoming this recurrent issue.

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.

Thioredoxin-h1 reduces and reactivates the oxidized cytosolic malate dehydrogenase dimer in higher plants

Cytosolic malate dehydrogenase (cytMDH) was captured by thioredoxin affinity chromatography as a possible target protein of cytosolic thioredoxin (Yamazaki, D., Motohashi, K., Kasama, T., Hara, Y., and Hisabori, T. (2004) Plant Cell Physiol. 45, 18-27). To further dissect this interaction, we aimed to determine whether cytMDH can interact with the cytosolic thioredoxin and whether its activity is redox-regulated. We obtained the active recombinant cytMDH that could be oxidized and rendered inactive. Inactivation was reversed by incubation with low concentrations of dithiothreitol in the presence of recombinant Arabidopsis thaliana thioredoxin-h1. Inactivation of cytMDH was found to result from formation of a homodimer. By cysteine mutant analysis and peptide mapping analysis, we were able to determine that the cytMDH homodimer occurs by formation of a disulfide bond via the Cys(330) residue. Moreover, we found this bond to be efficiently reduced by the reduced form of thioredoxin-h1. These results demonstrate that the oxidized form cytMDH dimer is a preferable target protein of the reduced form thioredoxin-h1 as suggested by thioredoxin affinity chromatography.

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.

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 dimer contact area of sorghum NADP-malate dehydrogenase: role of aspartate 101 in dimer stability and catalytic activity

During thioredoxin-mediated activation of chloroplastic NADP-malate dehydrogenase, a homodimeric enzyme, the interaction between subunits is known to be loosened but maintained. A modeling of the 3D structure of the protein identified Asp-101 as being potentially involved in the association between subunits through an electrostatic interaction. Indeed, upon site-directed substitution of Asp-101 by an asparagine, the mutated enzyme behaved mainly as a monomer. The mutation strongly affected the catalytical efficiency of the enzyme. The now available 3D structure of the enzyme shows that Asp-101 is protruding at the dimer interface, interacting with Arg-268 of the neighbouring subunit.

Cloning and sequence analysis of cDNAs encoding plant cytosolic malate dehydrogenase

Here we report the first complete sequence of plant cytosolic malate dehydrogenase (EC 1.1.1.37). The phylogenetic relationships between malate dehydrogenases from different cell compartments are discussed. The constructed phylogenetic tree shows that cytosolic NAD-MDH and chloroplast NADP-MDH have evolved through gene duplication of the pre-existing nuclear gene.

Truncation of the N- and C-terminal regions of the human 11beta-hydroxysteroid dehydrogenase type 2 enzyme and effects on solubility and bidirectional enzyme activity

The 11beta-hydroxysteroid dehydrogenase type II enzyme (11betaHSD2) endows specificity on the mineralocorticoid receptor by metabolising glucocorticoids. Sequence comparisons with other microsomal proteins showed the strongly preferred topology of a lumenal pentapeptide followed by three transmembrane helices with residues beyond Ala73 on the cytoplasmic side of the membrane, suggesting that 11betaHSD2 is anchored to the endoplasmic reticulum by the N-terminal region. However, deletion of the N-terminus (11betaHSD2 deltaN) and expression of the construct in mammalian cells showed that the enzyme remained bound to the microsomal fraction, indicating that other regions are also involved in membrane anchoring. Crosslinking studies and nonreducing SDS-PAGE demonstrated that 11betaHSD2 is a non-covalently linked dimer. Deletion of the non-conserved C-terminal region (11betaHSD2 deltaC) resulted in an enzyme with a Km of 215 nM for cortisol in whole cell assays, while 11betaHSD2 and 11betaHSD2 deltaN displayed a Km of 62 and 74 nM, respectively. In homogenates 11betaHSD2 and 11betaHSD2 deltaC displayed maximal activity at 140 mM NaCl or KCl, but showed a marked decrease in enzyme activity with increasing salt. 11BetaHSD2 was more stable than 11betaHSD2 deltaC in the presence of NaSCN, suggesting that the C-terminal region plays a role in enzyme stability. There was no detectable activity in homogenates containing 11betaHSD2 deltaN, while 11betaHSD2 deltaC and 11betaHSD2 displayed a Km of 135 and 46 nM, respectively. Although 11betaHSD2 is conventionally considered a unidirectional dehydrogenase all constructs converted 11-dehydrodexamethasone to dexamethasone in whole cell assays, providing an explanation for the potency of the synthetic glucocorticoid in the face of a powerful inactivator of natural glucocorticoids.

An internal cysteine is involved in the thioredoxin-dependent activation of sorghum leaf NADP-malate dehydrogenase

The chloroplastic NADP-malate dehydrogenase is activated by thiol/disulfide interchange with reduced thioredoxins. Previous experiments showed that four cysteines located in specific N- and carboxyl-terminal extensions were implicated in this process, leading to a model where no internal cysteine was involved in activation. In the present study, the role of the conserved four internal cysteines was investigated. Surprisingly, the mutation of cysteine 207 into alanine yielded a protein with accelerated activation time course, whereas the mutations of the three other internal cysteines into alanines yielded proteins with unchanged activation kinetics. These results suggested that cysteine 207 might be linked in a disulfide bridge with one of the four external cysteines, most probably with one of the two amino-terminal cysteines whose mutation similarly accelerates the activation rate. To investigate this possibility, mutant malate dehydrogenases (MDHs) where a single amino-terminal cysteine was mutated in combination with the mutation of both carboxyl-terminal cysteines were produced and purified. The C29S/C365A/C377A mutant MDH still needed activation by reduced thioredoxin, while the C24S/C365A/C377A mutant MDH exhibited a thioredoxin-insensitive spontaneous activity, leading to the hypothesis that a Cys24-Cys207 disulfide bridge might be formed during the activation process. Indeed, an NADP-MDH where the cysteines 29, 207, 365, and 377 are mutated yielded a permanently active enzyme very similar to the previously created permanently active C24S/C29S/C365A/C377A mutant. A two-step activation model involving a thioredoxin-mediated disulfide isomerization at the amino terminus is proposed.

Kinetic evidence for protein complexes between thioredoxin and NADP-malate dehydrogenase and presence of a thioredoxin binding site at the N-terminus of the enzyme

The kinetics of activation of NADP-malate dehydrogenase (MDH; EC 1.1.1.82) from soybean and spinach leaves by the chloroplast thioredoxins isolated from the same plants, by the corresponding storage forms of the soybean chloroplast thioredoxins from soybean seeds, and by the bacterial Escherichia coli thioredoxin have been studied. The Hill equation has been applied to evaluate the saturation kinetics. The observed variable thioredoxin saturation characteristics (Vmax 0.37-14.5 mumol NADPH min-1 mg enzyme-1; K0.5 0.15-1.33 microM; Hill coefficient h 0.90-3.04) indicate that the activation of NADP-MDH depends strongly on the individual thioredoxin used. Thus, thioredoxin action is not solely due to simple reductive activation of the NADP-MDH. Specific thioredoxin complex formation between thioredoxin and NADP-MDH must be included into the mechanism of the activation process. To study the regulatory consequences of the specific thioredoxin/NADP-MDH complexes we investigated the saturation kinetics of the substrates NADPH and oxaloacetate in presence of different concentrations of each individual thioredoxin species. The kinetic characteristics of the substrates (S0.5, Vmax, and Hill coefficients h) varied individually in response to the different thioredoxin species substantiating our model of thioredoxin/ NADP-MDH complex formation. Aminopeptidase-K-truncated pea NADP-MDH has been used to demonstrate that the N-terminal 37 amino residues are involved in providing a specific thioredoxin binding site. The fact that the versatile light-dependent regulation of numerous enzyme activities by only two thioredoxin species in chloroplasts cannot be accomplished without the formation of thioredoxin/target enzyme complexes is discussed in detail.

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.

Engineering a domain-locking disulfide into a bacterial malate dehydrogenase produces a redox-sensitive enzyme

Light-dependent reduction of cystine disulfide bonds results in activation of several of the enzymes of photosynthetic carbon metabolism within the chloroplast. We have modeled the tertiary structure of four of these light-activated enzymes, namely NADP-linked malate dehydrogenase, glyceraldehyde-3-P dehydrogenase, fructosebisphosphatase, and sedoheptulosebisphosphatase, and identified cysteines in each enzyme that be expected to form inactivating disulfide bonds (Li, D., F. J. Stevens, M. Schiffer, and L. E. Anderson, 1994. Biophys. J. 67:29-35). We have now converted two residues in the Escherichia coli NAD-linked malate dehydrogenase to cysteines and produced a redox-sensitive enzyme. Oxidation of domain-locking cysteine residues in the mutant enzyme clearly mimics dark inactivation of the redox-sensitive chloroplast dehydrogenase. This result is completely consistent with our proposed mechanism.

Purification, and phosphorylation in vivo and in vitro, of phosphoenolpyruvate carboxykinase from cucumber cotyledons

Phosphoenolpyruvate carboxykinase (PEPCK) with a subunit molecular mass of 74 kDa has been purified 450-fold to homogeneity from the cotyledons of cucumber (Cucumis sativus L.). This is the first purification of the native form of the enzyme from any plant tissue. Incubation of the purified enzyme with [gamma-32P]ATP and either phosphoenolpyruvate-carboxylase kinase or mammalian cAMP-dependent protein kinase led to labelling of the enzyme in a part of the molecule separate from the active site. This was reversed by incubation with protein phosphatase 2A. Cotyledons of cucumber seedlings were also supplied with 32Pi. Homogenates of such cotyledons contained a heavily labelled polypeptide which was confirmed as PEPCK by immunoprecipitation. Labelling of PEPCK by 32Pi in darkened cotyledons was reversed by illumination.

Redox equilibria between the regulatory thiols of light/dark-modulated chloroplast enzymes and dithiothreitol: fine-tuning by metabolites

Three light/dark-modulated chloroplast enzymes, namely NADP-dependent malate dehydrogenase (EC 1.1.1.82), D-fructose 1,6-bisphosphatase (EC 3.1.3.11), and phosphoribulokinase (EC 2.7.1.19) were purified to apparent homogeneity from spinach leaves. Equilibrium constants for the covalent modification of the regulatory disulfide bonds of these enzymes in dithiothreitol (DTT)-redox buffer were determined according to a previously published method in the literature (Clancey and Gilbert (1987) J. Biol. Chem. 262, 13545-13549). The thiol/disulfide-redox potential (Kox) was defined as the ratio of reduced to oxidized dithiothreitol at which 50% of the maximal enzyme activity was observed after equilibrium had been established. All Kox values were very high, comparable to those of extracellular disulfide containing proteins: 0.23 +/- 0.02 for NADP-malate dehydrogenase, 0.59 +/- 0.17 for phosphoribulokinase, and 0.70 +/- 0.16 for D-fructose 1,6-bisphosphatase. The equilibrium constants for the reactions between these enzymes and the redox buffers were also determined in the presence of various concentrations of specific metabolites known to influence the rates of reduction and oxidation. Increasing concentrations of D-fructose 1,6-bisphosphate in the presence of Ca2+ shift the equilibrium constant between D-fructose 1,6-bisphosphatase and the DTT-redox buffer to much lower values. A decreasing NADPH/(NADP + NADPH) ratio increases the Kox of NADP-malate dehydrogenase in the redox buffer to very high values. For PRK, low concentrations of ATP result in a slight decrease of the Kox that is not further affected by higher ATP concentrations. The differences of the equilibrium constants of NADP-malate dehydrogenase and D-fructose 1,6-bisphosphatase as dependent upon the NADPH/(NADP + NADPH) ratio and the concentration of D-fructose 1,6-bisphosphate, respectively, reflect a mechanism of feed-back and feed-forward regulation by the product NADP and the substrate D-fructose 1,6-bisphosphate, respectively. Thus the actual activation state of these two key enzymes of chloroplast metabolism are determined in an independent manner. The relatively small effect of the ATP concentration upon the redox potential of phosphoribulokinase indicates that fine-regulation at this step might be achieved on another level (e.g., catalysis or aggregation state).

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.