Julio Lopez-Gorge

Cysteine-153 is required for redox regulation of pea chloroplast fructose-1,6-bisphosphatase

Chloroplastic fructose‐1,6‐bisphosphatases are redox regulatory enzymes which are activated by the ferredoxin thioredoxin system via the reduction/isomerization of a critical disulfide bridge. All chloroplastic sequences contain seven cysteine residues, four of which are located in, or close to, an amino acid insertion region of approximately 17 amino acids. In order to gain more information on the nature of the regulatory site, five cysteine residues (Cys49, Cys153, Cys173, Cys178 and Cys190) have been modified individually into serine residues by site‐directed mutagenesis. While mutations C173S and C178S strongly affected the redox regulatory properties of the enzyme, the most striking effect was observed with the C153S mutant which became permanently active and redox independent. On the other hand, the C190S mutant retained most of the properties of the wild‐type enzyme (except that it could now also be partially activated by the NADPH/NTR/thioredoxin h system). Finally, the C49S mutant is essentially identical to the wild‐type enzyme. These results are discussed in the light of recent crystallographic data obtained on spinach FBPase [Villeret et al. (1995) Biochemistry 34, 4299–4306].

Thioredoxin/fructose-1,6-bisphosphatase affinity in the enzyme activation by the ferredoxin-thioredoxin system

In this work we analyze the affinity relationship between photosynthetic fructose-1,6-bisphosphatase and ferredoxin and thioredoxin from spinach leaves, two components of the proposed light-activation system of this enzyme, using affinity techniques on ferredoxin- and thioredoxin-Sepharose columns. Oxidized and reduced ferredoxin did not show enzyme affinity, whereas thioredoxin, both the oxidized and the dithiothreitol-reduced form, exhibited a strong bisphosphatase affinity at pH 7.5; this thioredoxin/enzyme affinity appears diminished at pH 8.2. When the affinity experiments were performed in the presence of 5 mM Mg2+, only 30% and 12% of the bisphosphatase remained bound to the thioredoxin-Sepharose at pH 7.5 and 8.0, respectively; these percentages were reduced to 6% when the Mg2+ concentration increased to 10 mM. These results suggest that a rise of stromal pH and Mg2+ concentration can account for a loosening of the thioredoxin/bisphosphatase linkage, which could be of physiological significance in the dark-light transition. Studies on the nature of the chemical groups responsible for the affinity have shown that the thioredoxin/bisphosphatase linkage is concerned with the existence of hydrophobic clusters. We have found no difference in the behaviour of the chloroplastic thioredoxins f and m, and the cytoplasmic ones cf and cm. These results support the existence of an in vivo thioredoxin/fructose-1,6-bisphosphatase interaction, in accordance with the light-activation mechanism by the ferredoxin-thioredoxin system.

Manganese superoxide dismutase from a higher plant. Purification of a new Mn-containing enzyme.

A manganese-containing superoxide dismutase (EC 1.15.1.1) was purified to homogeneity from a higher plant for the first time. The enzyme was isolated fromPisum sativum leaf extracts by thermal fractionation, ammonium sulfate salting out, ion-exchange and gel-filtration column chromatography, and preparative polyacrylamide gel electrophoresis. Pure manganese superoxide dismutase had a specific activity of about 3,000 U mg-1 and was purified 215-fold, with a yield of 1.2 mg enzyme per kg whole leaf. The manganese superoxide dismutase had a molecular weight of 94,000 and contained one g-atom of Mn per mol of enzyme. No iron and copper were detected. Activity reconstitution experiments with the pure enzyme ruled out the possibility of a manganese loss during the purification procedure. The stability of manganese superoxide dismutase at-20°C, 4°C, 25°C, 50°C, and 60°C was studied, and the enzyme was found more labile at high temperatures than bacterial manganese superoxide dismutases and iron superoxide dismutases from an algal and bacterial origin.

The donor side of Photosystem II as the copper-inhibitory binding site. Fluorescence and polarografic studies*

We have measured, under Cu (II) toxicity conditions, the oxygen-evolving capacity of spinach PS II particles in the Hill reactions H2O→SiMo (in the presence and absence of DCMU) and H2O→PPBQ, as well as the fluorescence induction curve of Tris-washed spinach PS II particles. Cu (II) inhibits both Hill reactions and, in the first case, the DCMU-insensitive H2O → SiMo activity. In addition, the variable fluorescence is lowered by Cu (II). We have interpreted our results in terms of a donor side inhibition close to the reaction center. The same polarographic and fluorescence measurements carried out at different pHs indicate that Cu (II) could bind to amino acid residues that can be protonated and deprotonated. In order to reverse the Cu (II) inhibition by a posterior EDTA treatment, in experiments of preincubation of PS II particles with Cu (II) in light we have demonstrated that light is essential for the damage due to Cu (II) and that this furthermore is irreversible.

An immunological method for quantitative determination of photosynthetic fructose-1,6-bisphosphatase in leaf crude extracts

An immunological method for quantitative determination of photosynthetic fructose-1,6-bisphosphatase in crude extracts of leaves is proposed. It is based on the ELISA technique, and offers two modifications. A non-competitive technique has a higher sensitivity and is the right option for samples of low fructose-1,6-bisphosphatase content. However, this method is not sufficiently specific when the total protein is higher than 5 μg/cm3; so, despite its lower sensitivity, in these circumstances a competitive technique is more suitable. Thus photosynthetic fructose-1,6-bisphosphatase can be measured without interferences from the gluconeogenic cytosolic enzyme of the photosynthetic cell or from a non-specific phosphatase present in the chloroplast.

Evidence for manganese(III) binding to the mangano superoxide dismutase from a higher plant (Pisum sativum L.)

Abstract Homogenous preparations of a manganese superoxide dismutase from a higher plant ( Pisum sativum L.) were studied by epr and optical spectroscopies. The visible spectrum of manganese superoxide dismutase shows a weak and broad band in the range 350–700 nm with two shoulders at about 480 and 600 nm. Reduction with dithionite brought about a considerable disappearance of the visible component of the spectrum. The epr spectra of the native and dithionite-treated enzyme did not show any signal attributable to Mn(II) that only was visible after acid hydrolysis of the protein. The lack of epr signal both in the native and reduced superoxide dismutase can be attributed to the presence of Mn(III) in the former and of Mn(II) strongly bound to the protein in the latter. The results obtained with the manganese superoxide dismutase from leaves of the higher plant Pisum sativum are consistent with the general catalytic mechanism of action postulated for superoxide dismutases from other sources studied so far.

A new procedure for the purification of spinach leaf photosynthetic fructose-1,6-bisphosphatase by affinity chromatography on mercaptoethylamine-Sepharose

A new purification procedure for spinach leaf fructose-1,6-bisphosphatase is proposed, which includes the use of affinity chromatography on mercaptoethylamine-Sepharose. A homogeneous preparation of the enzyme can be obtained in 48 hr, with a specific activity of 67 U/mg and a yield of 23%. The method may also be useful for the purification of other thioredoxin-activated chloroplast enzymes.

Construction of chimeric cytosolic fructose-1,6-bisphosphatases by insertion of a chloroplastic redox regulatory cluster.

In order to transform cytosolic fructose-1,6-bisphosphatases (FBPase)(EC 3.1.3.11) into potential reductively-modulated chloroplast-type enzymes, we have constructed four chimeric FBPases, which display structural viability as deduced by previous modelling. In the X1-type BV1 and HL1 chimera the N-half of cytosolic sugar beet (Beta vulgaris L.) and human FBPases was fused with the C-half of the pea (Pisum sativum L.) chloroplast enzyme, which carries the cysteine-rich light regulatory sequence. In the X2-type BV2 and HL2 chimera this regulatory fragment was inserted in the corresponding site of the sugar beet cytosolic and human enzymes. Like the plant cytosolic FBPases, the chimeric enzymes show a low rise of activity by dithiothreitol. Both BV1 and BV2, but not HL1 and HL2, display a negligible activation by Trxf, but neither of them by Trxm. Antibodies raised against the pea chloroplast enzyme showed a positive reaction against the four chimeric FBPases and the human enzyme, but not against the sugar beet one. The four chimera display typical kinetics of cytosolic FBPases, with Km values in the 40–140 μM range. We conclude the existence of a structural capacity of cytosolic FBPases for incorporating the redox regulatory cluster of the chloroplast enzyme. However, the ability of these chimeric FBPases for anin vitro redox regulation seems to be scarce, limiting their use from a biotechnology standpoint inin vivo regulation of sugar metabolism.ResumenCon el objetivo de transformar fructosa-1,6-bisfosfatasas (FBPasa)(EC 3.1.3.11) citosólicas en otras de características cloroplastídicas potencialmente modulables por reducción, se han construido cuatro FBPasas quiméricas, cuyo modelaje previo las define como estructuralmente viables. En las quimeras llamadas de tipo X1, BV1 y HL1, las mitades N-terminal de la FBPasa citosólica de remolacha azucarera (Beta vulgaris L.) y humana se fusionaron con la mitad C-terminal de la FBPasa cloroplastídica de guisante (Pisum sativum L.), que lleva la secuencia, rica en cisteina, responsable de la regulación por luz de la enzima. En las denominadas tipo X2, BV2 y HL2, dicho fragmento regulatorio se insertó en el lugar correspondiente de las FBPasas citosólica de remolacha y humana. Como ocurre con las FBPasas citosólicas de plantas, las cuatro enzimas quiméricas mostraron un bajo aumento de actividad por DTT. Al mismo tiempo las quimeras BV1 y BV2, pero no las HL1 y HL2, exhibieron una escasa activación por tiorredoxinaf (Trxf), mientras que ninguna de ellas por Trxm. Anticuerpos frente a la enzima cloroplastídica de guisante mostraron una reacción positiva (Western) frente a las FBPasas quiméricas y humana, pero no frente a la enzima citosólica de remolacha. Las cuatro quimeras exhibieron cinéticas características de FBPasas citosólicas, con valores de Km en el intervalo 40–140 μM. De todo ello se deduce una capacidad estructural de las FBPasas citosólicas para incorporar la secuencia de la enzima cloroplastídica responsable de la regulación por reducción. Sin embargo, la capacidad de estas FBPasas quiméricas para una regulación rédox, al menosin vitro, parece ser escasa, lo que puede limitar su uso biotecnológicopara la regulaciónin vivo del metabolismo de los azúcares en plantas.

Antigenic Relationships between Chloroplast and Cytosolic Fructose-1,6-Bisphosphatases

Cytosolic fructose-1,6-biphosphatases (FBPase, EC 3.1.3.11) from pea (Pisum sativum L. cv Lincoln) and spinach (Spinacia oleracea L. cv Winter Giant) did not cross-react by double immunodiffusion and western blotting with either of the antisera raised against the chloroplast enzyme of both species; similarly, pea and spinach chloroplast FBPases did not react with the spinach cytosolic FBPase antiserum. On the other hand, spinach and pea chloroplast FBPases showed strong cross-reactions against the antisera to chloroplast FBPases, in the same way that the pea and spinach cytosolic enzymes displayed good cross-reactions against the antiserum to spinach cytosolic FBPase. Crude extracts from spinach and pea leaves, as well as the corresponding purified chloroplast enzymes, showed by western blotting only one band (44 and 43 kD, respectively) in reaction with either of the antisera against the chloroplast enzymes. A unique fraction of molecular mass 38 kD appeared when either of the crude extracts or the purified spinach cytosolic FBPase were analyzed against the spinach cytosolic FBPase antiserum. These molecular sizes are in accordance with those reported for the subunits of the photosynthetic and gluconeogenic FBPases. Chloroplast and cytosolic FBPases underwent increasing inactivation when increasing concentrations of chloroplast or cytosolic anti-FBPase immunoglobulin G (IgG), respectively, were added to the reaction mixture. However, inactivations were not observed when the photosynthetic enzyme was incubated with the IgG to cytosolic FBPase, or vice versa. Quantitative results obtained by enzyme-linked immunosorbent assays (ELISA) showed 77% common antigenic determinants between the two chloroplast enzymes when tested against the spinach photosynthetic FBPase antiserum, which shifted to 64% when assayed against the pea antiserum. In contrast, common antigenic determinants between the spinach cytosolic FBPase and the two chloroplast enzymes were less than 10% when the ELISA test was carried out with either of the photosynthetic FBPase antisera, and only 5% when the assay was performed with the antiserum to the spinach cytosolic FBPase. These results were supported by sequencing data: the deduced amino acid sequence of a chloroplast FBPase clone isolated from a pea cDNA library indicated a 39,253 molecular weight protein, with a homology of 85% with the spinach chloroplast FBPase but only 48.5% with the cytosolic enzyme from spinach.

Spinach Leaf Photosynthetic Fructose-1.6-bisphosphatase: Biosynthetic Characteristics

Fructose-1.6-bisphosphatase (FBPase; EC 3.1.3.11) is a key enzyme in the regulation of Calvin cycle, and it has been profusely studied from structural and regulatory points of view. Many authors have demonstrated that its activity rise after the dark-light transition is due, in addition to an increase in the stromal pH and Mg2+ concentration, to a light activation by reduction of essential -S-S- groups of the enzyme molecule. However, little attention has been paid to the possible existence of a second regulatory mechanism by light of FBPase activity, by way of a photoregulated induction of the enzyme synthesis, such it has been found for the NADP+-malate dehydrogenase (NADP+-MD)(Vidal, Gadal,1981), the 32–34 kilodalton polypeptide which shields the B acceptor of Phot.II (Steinback “et al”, 1981), and for the assembly of ribulose-1.5-bisphosphate carboxylase (Bloom “et al”, 1983).