Raymond Chollet

Regulatory phosphorylation of C4 PEP carboxylase

PEP carboxylase is of paramount importance in plant metabolism, and is one of only a few enzymes known to undergo regulatory phosphorylation in the living plant. In illuminated leaves of C 4 species, a complex light-signal transduction cascade occurs, which possibly involves cross-talk between the two neighboring photosynthetic cell types. This process upregulates the activity of a Ca 2+ -independent, substrate-specific protein-Ser/Thr kinase, and thereby increases the phosphorylation state of the photosynthesis-related, C 4 PEP carboxylase isoform. This reversible covalent modification is superimposed on the opposing regulation of PEP carboxylase by carboxylic acids and phosphorylated metabolites, and is critical for the coordination and functioning of C 4 photosynthesis. The general occurrence of PEP carboxylase-kinase and the conserved N-terminal phosphorylation domain of the various plant PEP carboxylase isoforms support the hypothesis that similar regulatory mechanisms are functional in the diverse physiological contexts involving this enzyme.

Phosphoenolpyruvate carboxylase : structure, regulation and evolution

Abstract Plant phosphoenolpyruvate carboxylase (EC 4.1.1.31; PEPC) is encoded by a small multigene family in which the expression of each member is controlled individually by exogenous (light, environmental) and/or endogenous (hormonal and developmental) stimuli. The involvement of putative trans-actig factors and consensus cis-elements of promoters in the specific transcriptional regulation of the PEPC genes is discussed. At the post-translational level, the regulatory strategy of the plant enzyme is mainly to offset the negative effect of the feedback inhibitor, L-malate, the end-product of the oxaloacetate reduction. All plant PEPC-forms are under positive and negative allosteric control by metabolite effectors and possess a consensus phosphorylation site containing a target serine residue near their N-terminus (e.g. Ser8 in C4 PEPC from sorghum). In C4 and Crassulacean acid metabolism (CAM) plants, a complex signal-transduction chain activates a Ca2+-independent protein-serine kinase responsible for regulatory phosphorylation of PEPC. A more thorough understanding of the functional and regulatory properties of the bacterial and C4 enzymes has emerged by exploiting recombinant proteins and site-directed mutagenesis. In these newly opened areas, PEPC offers one of the best characterized paradigms of plant signaling. Finally, some emerging ideas on the evolution and phylogenetic relationships of the various PEPC isoforms are presented.

In Vivo Regulation of Wheat-Leaf Phosphoenolpyruvate Carboxylase by Reversible Phosphorylation

Regulation of C3 phosphoenolpyruvate carboxylase (PEPC) and its protein-serine/threonine kinase (PEPC-PK) was studied in wheat (Triticum aestivum) leaves that were excised from low-N-grown seedlings and subsequently illuminated and/or supplied with 40 mM KNO3. The apparent phosphorylation status of PEPC was assessed by its sensitivity to L-malate inhibition at suboptimal assay conditions, and the activity state of PEPC-PK was determined by the in vitro 32P labeling of purified maize dephospho-PEPC by [[gamma]-32P]ATP/Mg. Illumination ([plus or minus]NO3-) for 1 h led to about a 4.5-fold increase in the 50% inhibition constant for L-malate, which was reversed by placing the illuminated detached leaves in darkness (minus NO3-). A 1 -h exposure of excised leaves to light, KNO3, or both resulted in relative PEPC-PK activities of 205, 119, and 659%, respectively, of the dark/0 mM KNO3 control tissue. In contrast, almost no activity was observed when a recombinant sorghum phosphorylation-site mutant (S8D) form of PEPC was used as protein substrate in PEPC-PK assays of the light plus KNO3 leaf extracts. In vivo labeling of wheat-leaf PEPC by feeding 32P-labeled orthophosphate showed that PEPC from light plus KNO3 tissue was substantially more phosphorylated than the enzyme in the dark minus-nitrate immunoprecipitates. Immunoblot analysis indicated that no changes in relative PEPC-protein amount occurred within 1 h for any of the treatments. Thus, C3 PEPC activity in these detached wheat leaves appears to be regulated by phosphorylation of a serine residue near the proteins N terminus by a Ca2+ -independent protein kinase in response to a complex interaction in vivo between light and N.

Light/dark regulation of maize leaf phosphoenolpyruvate carboxylase by in vivo phosphorylation☆

Phosphoenolpyruvate carboxylase (PEPCase) from light- and dark-adapted maize leaves was rapidly purified in the presence of L-malate and glycerol to apparent electrophoretic homogeneity by ammonium sulfate fractionation, hydroxylapatite chromatography, and fast-protein liquid chromatography on Mono Q. The resulting preparations were totally devoid of pyruvate, orthophosphate dikinase protein based on immunoblot analysis. Throughout the purification, both forms of PEPCase retained their different enzymatic properties. The specific activity of the light enzyme was consistently about twice that of the dark form when assayed at suboptimal (but physiological) pH (pH 7.0-7.3), and the former was also less sensitive to feedback inhibition by L-malate than that from darkened leaves under various conditions. Covalently bound phosphate and high-performance liquid chromatography-based phosphoamino acid analyses showed that both forms of purified PEPCase were phosphorylated exclusively on serine residues, but the degree of phosphorylation was about 50% greater in the light enzyme. Notably, incubation of purified PEPCase in vitro with exogenous alkaline phosphatase led to an increase in malate sensitivity and a decrease in specific activity of the light form enzyme to levels observed with the dark form, which was essentially not affected by phosphatase treatment. These results with the purified enzyme from light- and dark-adapted maize leaves indicate that the light-induced changes in activity and malate sensitivity of C4 PEPCase are related, at least in part, to the degree of covalent seryl phosphorylation of the protein in vivo.

PROTEIN TURNOVER AS A COMPONENT IN THE LIGHT/DARK REGULATION OF PHOSPHOENOLPYRUVATE CARBOXYLASE PROTEIN-SERINE KINASE ACTIVITY IN C4 PLANTS

Maize leaf phosphoenolpyruvate carboxylase [PEPC; orthophosphate:oxaloacetate carboxy-lyase (phosphorylating), EC 4.1.1.31] protein-serine kinase (PEPC-PK) phosphorylates serine-15 of its target enzyme, thus leading to an increase in catalytic activity and a concomitant decrease in malate sensitivity of this cytoplasmic C4 photosynthesis enzyme in the light. We have recently demonstrated that the PEPC-PK activity in maize leaves is slowly, but strikingly, increased in the light and decreased in darkness. In this report, we provide evidence that cycloheximide, an inhibitor of cytoplasmic protein synthesis, when fed to detached leaves of C4 monocots (maize, sorghum) and dicots (Portulaca oleracea) in the dark or light, completely prevents the in vivo light activation of PEPC-PK activity regardless of whether the protein kinase activity is assessed in vivo or in vitro. In contrast, chloramphenicol, an inhibitor of protein synthesis in chloroplasts, has no effect on the light activation of maize PEPC-PK. Similarly, treatment with cycloheximide did not influence the light activation of other photosynthesis-related enzymes in maize, including cytoplasmic sucrose-phosphate synthase and chloroplast stromal NADPH-malate dehydrogenase and pyruvate, Pi dikinase. These and related results, in which detached maize leaves were treated simultaneously with cycloheximide and microcystin-LR, a potent in vivo and in vitro inhibitor of the PEPC type 2A protein phosphatase, indicate that short-term protein turnover of the PEPC-PK itself or some other essential component(s) (e.g., a putative protein that modifies this kinase activity) is one of the primary levels in the complex and unique regulatory cascade effecting the reversible light activation/seryl phosphorylation of PEPC in the mesophyll cytoplasm of C4 plants.

Regulatory seryl-phosphorylation of C4 phosphoenolpyruvate carboxylase by a soluble protein kinase from maize leaves

A reconstituted system composed of purified phosphoenolpyruvate carboxylase (PEP-Case) and a soluble protein kinase (PK) from green maize leaves was developed to critically assess the effects of in vitro protein phosphorylation on the catalytic and regulatory (malate sensitivity) properties of the target enzyme. The PK was partially purified from light-adapted leaf tissue by ammonium sulfate fractionation (0-60% saturation fraction) of a crude extract and blue dextran-agarose affinity chromatography. The resulting preparation was free of PEPCase. This partially purified protein kinase activated PEPCase from dark-adapted green maize leaves in an ATP-, Mg2+-, time-, and temperature-dependent fashion. Concomitant with these changes in PEPCase activity was a marked decrease in the target enzymes sensitivity to feedback inhibition by L-malate. The PK-mediated incorporation of 32P from [gamma-32P]ATP into the protein substrate was directly correlated with these changes in PEPCase activity and malate sensitivity. The maximal molar 32P-incorporation value was about 0.25 per 100-kDa PEPCase subunit (i.e., 1 per holoenzyme). Phosphoamino acid analysis of the 32P-labeled target enzyme by two-dimensional thin-layer electrophoresis revealed the exclusive presence of phosphoserine. These in vitro results, together with our recent studies on the light-induced changes in phosphorylation status of green maize leaf PEPCase in vivo (J. A. Jiao and R. Chollet (1988) Arch. Biochem. Biophys. 261, 409-417), collectively provide the first unequivocal evidence that the seryl-phosphorylation of the dark-form enzyme by a soluble protein kinase is responsible for the changes in catalytic activity and malate sensitivity of C4 PEPCase observed in vivo during dark/light transitions of the parent leaf tissue.

Seryl-phosphorylation of soybean nodule sucrose synthase (nodulin-100) by a Ca2+-dependent protein kinase

Sucrose synthase (SS; EC 2.4.1.13) was radiolabeled in situ by incubating detached soybean nodules with 32Pi. Phosphoamino acid analysis indicated that SS was phosphorylated on a serine residue(s). In‐vitro phosphorylation of purified nodule SS by desalted nodule extracts was Ca2+‐dependent. This SS‐kinase was partially purified (∼2200‐fold) from nodules harvested from illuminated plants. The molecular mass of the SS‐kinase was about 55 000 on a Superdex 75 size‐exclusion column or in a denaturing autophosphorylation gel. With either purified nodule SS or Syntide 2 as substrate, exogenous calmodulin and phosphatidylserine showed little or no effect on the in‐vitro activity of this partially purified protein kinase. However, its activity was inhibited by W‐7. The purified nodule SS‐kinase (or CDPK) phosphorylated nodule PEP carboxylase (PEPC; EC 4.1.1.31) in the presence of Ca2+. In contrast, a partially purified nodule PEPC‐kinase preparation was incapable of phosphorylating nodule SS. Unlike nodule PEPC [Zhang et al. (1995) Plant Physiol. 108, 1561–1568], the phosphorylation state of SS is not likely modulated in planta by photosynthate supply from the shoots.

In Vivo Regulatory Phosphorylation of Soybean Nodule Phosphoenolpyruvate Carboxylase.

In this report we provide evidence that cytosolic phosphoenolpyruvate carboxylase (PEPC) in soybean (Glycine max L.) root nodules is regulated in vivo by a seryl-phosphorylation cycle, as with the C4, Crassulacean acid metabolism, and C3 leaf isoforms. Pretreatment of parent plants by stem girdling for 5 or 14 h caused a significant decrease in the apparent phosphorylation state of nodule PEPC, as indicated by the 50% inhibition constant (L-malate) and specific activity values assayed at suboptimal conditions, whereas short-term darkness alone was without effect. However, extended (26 h) darkness led to the formation of a relatively dephosphorylated nodule PEPC, an effect that was reversed by illuminating the darkened plants for 3 h. This reversal of the apparent phosphorylation state in the light was prevented by concomitant stem girdling. In contrast, the optimal activity of nodule PEPC and its protein level showed little or no change in all pretreated plants. These results suggest that the phosphorylation state of PEPC in soybean root nodules is possibly modulated by photosynthate transported recently from the shoots. In situ [32P]orthophosphate labeling, immunoprecipitation, and phosphoamino acid analyses confirmed directly that PEPC in detached intact soybean nodules is phosphorylated on a serine residue(s).

Phosphoenolpyruvate Carboxylase Kinase in Tobacco Leaves Is Activated by Light in a Similar but Not Identical Way as in Maize

We have previously reported the partial purification of a Ca2+- independent phosphoenolpyruvate carboxylase (PEPC) protein-serine/threonine kinase (PEPC-PK) from illuminated leaves of N-sufficient tobacco (Nicotiana tabacum L.) plants (Y.-H. Wang, R. Chollet [1993] FEBS Lett 328: 215–218). We now report that this C3 PEPC-kinase is reversibly light activated in vivo in a time-dependent manner. As the kinase becomes light activated, the activity and L-malate sensitivity of its target protein increases and decreases, respectively. The light activation of tobacco PEPC-PK is prevented by pretreatment of detached leaves with various photosynthesis and cytosolic protein-synthesis inhibitors. Similarly, specific inhibitors of glutamine synthetase block the light activation of tobacco leaf PEPC-kinase under both photorespiratory and nonphotorespiratory conditions. This striking effect is partially and specifically reversed by exogenous glutamine, whereas it has no apparent effect on the light activation of the maize (Zea mays L.) leaf kinase. Using an in situ “activity-gel” phosphorylation assay, we have identified two major Ca2+-independent PEPC-kinase catalytic polypeptides in illuminated tobacco leaves that have the same molecular masses (approximately 30 and 37 kD) as found in illuminated maize leaves. Collectively, these results indicate that the phosphorylation of PEPC in N-sufficient leaves of tobacco (C3) and maize (C4) is regulated through similar but not identical light-signal transduction pathways.

C3-C4 intermediate species in the genus Flaveria: leaf anatomy, ultrastructure, and the effect of O2 on the CO2 compensation concentration

Leaf anatomical, ultrastructural, and CO2-exchange analyses of three closely related species of Flaveria indicate that they are C3−C4 intermediate plants. The leaf mesophyll of F. floridana J.R. Johnston, F. linearis Lag., and F. chloraefolia A. Gray is typical of that in dicotyledonous C3 plants, but the bundle sheath cells contain granal, starch-containing chloroplasts. In F. floridana and F. chloraefolia, the chloroplasts and numerous associated mitochondria are arranged largely centripetally, as in the closely related C4 species, F. brownii A.M. Powell. In F. linearis, fewer mitochondria are present and the chloroplasts are more evenly distributed throughout the bundle sheath cytosol. There is no correlation between the bundle sheath ultrastructure and CO2 compensation concentration. (Γ) values of these C3−C4 intermediate Flaveria species. At 21% O2 and 25°C, Γ for F. chloraefolia, F. linearis, and F. floridana is 23–26, 14–19, and 8–10 μl CO2 l-1, respectively. The O2 dependence of Γ is the greatest for F. chloraefolia and F. linearis (similar to that for C3−C4 intermediate Panicum and Moricandia species) and the least for F. floridana, whose O2 response is identical to that for F. brownii from 1.5 to 21% O2, but greater at higher pO2. The variation in leaf anatomy, bundle sheath ultrastructure, and O2 dependence of Γ among these Flaveria species may indicate an active evolution in the pathway of photosynthetic carbon metabolism within this genus.