Tyramine oxidation by copper/TPQ amine oxidase and peroxidase from Euphorbia characias latex

Tyramine, an important plant intermediate, was found to be a substrate for two proteins, a copper amine oxidase and a peroxidase from Euphorbia characias latex. The oxidation of tyramine took place by two different mechanisms: oxidative deamination to p-hydroxyphenylacetaldehyde by the amine oxidase and formation of di-tyramine by the peroxidase. The di-tyramine was further oxidized at the two amino groups by the amino oxidase, whereas p-hydroxyphenylacetaldehyde was transformed to di-p-hydroxyphenylacetaldehyde by the peroxidase. Data obtained in this study indicate a new interesting scenario in the metabolism of tyramine.     

Purification of lipase from latex of Euphorbia characias by an extraction method with apolar solvent]

A lipase from the latex of Euphorbia characias was purified using a new method involving extraction by apolar solvent and adsorption chromatography on silica. The lipase (specific activity 1,500 IU/mg of protein) was eluted from silica complexed with a lipid. The main proteic fraction, showing a molecular weight of 38,000, was inactive when dissociated from the lipid fraction. It was necessary to reassociate the lipid and proteic fractions for 72% of the lipolytic activity to be recovered.     

Essential sulfhydryl groups in diamine oxidase from Euphorbia characias latex

Diamine oxidase from Euphorbia characias latex contains two sulfhydryl groups per mole of dimeric enzyme. The sulfhydryl groups are unreactive in the native enzyme but can be readily titrated by 4,4′-dithiodipyridine after protein denaturation, or anaerobically in the presence of the amine substrate. In the presence of both substrates (diamine and oxygen) they react sluggishly. The sulfhydryl groups show different reactivity toward various reagents, but in every case their modification inhibits catalytic activity. The insensitivity of the native enzyme to specific reagents suggests that the sulfhydryl groups are positioned in the interior of the protein and shielded from the solvent. Their reactivity in the presence of the amine substrate could be attributed to a conformational change occurring upon substrate binding or after substrate oxidation.     

Two-state irreversible thermal denaturation of Euphorbia characias latex amine oxidase

Thermal denaturation of Euphorbia latex amine oxidase (ELAO) has been studied by enzymatic activity, circular dichroism and differential scanning calorimetry. Thermal denaturation of ELAO is shown to be an irreversible process. Checking the validity of two-state it really describes satisfactorily the thermal denaturation of ELAO. Based on this model we obtain the activation energy, parameter T(*) (the absolute temperature at which the rate constant of denaturation is equal to 1 min(-1)), and total enthalpy of ELAO denaturation. HPLC experiments show that the thermal denatured enzyme conserves its dimeric state. The N(2)-->kD(2) model for thermal denaturation of ELAO is proposed: where N(2) and D(2) are the native and denatured dimer, respectively.     

Catalytic pathways of Euphorbia characias peroxidase reacting with hydrogen peroxide

The reaction of Euphorbia characias latex peroxidase (ELP) with hydrogen peroxide as the sole substrate was studied by conventional and stopped-flow spectrophotometry. The reaction mechanism occurs via three distinct pathways. In the first (pathway I), ELP shows catalase-like activity: H2O2 oxidizes the native enzyme to compound I and subsequently acts as a reducing substrate, again converting compound I to the resting ferric enzyme. In the presence of an excess of hydrogen peroxide, compound I is still formed and further reacts in two other pathways. In pathway II, compound I initiates a series of cyclic reactions leading to the formation of compound II and compound III, and then returns to the native resting state. In pathway III, the enzyme is inactivated and compound I is converted into a bleached inactive species; this reaction proceeds faster in samples illuminated with bright white light, demonstrating that at least one of the intermediates is photosensitive. Calcium ions decrease the rate of pathway I and accelerate the rate of pathways II and III. Moreover, in the presence of calcium the inactive stable verdohemochrome P670 species accumulates. Thus, Ca2+ ions seem to be the key for all catalytic pathways of Euphorbia peroxidase.     

Extraction and characterization of a natural rubber from Euphorbia characias latex

A natural rubber was identified and characterized for the first time in the latex of the perennial Mediterranean shrub Euphorbia characias. Four different methods, i.e., acetone, acetic acid, trichloroacetic acid, and Triton® X‐100, followed by successive treatments with cyclohexane/ethanol, were employed to extract the natural rubber. The rubber content was shown to be 14% (w/v) of the E. characias latex, a low content compared with that of Hevea brasiliensis (30–35%) but a similar content to other rubber producing plants. E. characias rubber showed a molecular weight of 93,000 with a M_w/M_n of 2.9. ¹H NMR, ¹³C NMR, and FTIR analysis revealed the characteristic of the cis‐1,4‐polyisoprene typical of natural rubber. These results provided novel insight into latex components and will ultimately benefit the broader understanding of E. characias latex composition. © 2012 Wiley Periodicals, Inc. Biopolymers 97: 589–594, 2012.     

Critical role of Ca2+ ions in the reaction mechanism of Euphorbia characias peroxidase

A cationic peroxidase was isolated and characterized from the latex of the perennial Mediterranean plant Euphorbia characias. The purified enzyme contained one heme prosthetic group identified as ferric iron-protoporphyrin IX. In addition, the purified peroxidase contained 1 mol of endogenous calcium per mol of enzyme; removal of this calcium ion resulted in almost complete loss of the enzyme activity. However, when excess Ca(2+) was added to the native enzyme the catalytic efficiency was enhanced by 3 orders of magnitude. The mechanism of activation was studied using a wide range of spectroscopic and analytic techniques. Analysis of the steady state by stopped-flow measurements suggests that the main effect of calcium ions is to favor the oxidation of the ferric enzyme by hydrogen peroxide to form compound I, whereas the other steps of the catalytic cycle seem to be affected to a lesser extent. UV/vis absorption spectra and CD measurements show that the heme iron is pentacoordinated high-spin in native enzyme and remains so after the binding of Ca(2+). Only minor changes in the secondary or tertiary structure of the protein could be detected by fluorescence or CD measurements in the presence of Ca(2+) ions, except for a significant perturbation of the Fe(3+) inner sphere geometry, as detected by EPR measurements. We propose that Ca(2+) binding to a low affinity site induces a reorientation of the distal histidine changing the almost inactive form of Euphorbia peroxidase to a high activity form. This is the first example of a peroxidase that responds as an on/off switch to variations in the external Ca(2+) level.     

Reversible thermal inactivation and conformational states in denaturant guanidinium of a calcium-dependent peroxidase from Euphorbia characias

The changes in the heme environment and overall structure occurring during reversible thermal inactivation and in denaturant guanidinium of Euphorbia characias latex peroxidase (ELP) were investigated in the presence and absence of calcium ions. Native active enzyme had an absorption spectrum typical of a quantum-mixed spin ferric heme protein. After 40 min at 60 degrees C ELP was fully inactivated showing the spectroscopic behavior of a pure hexacoordinate low-spin protein. The addition of Ca2+ to the thermally inactivated enzyme restored its native activity and its spectroscopic features, but did not increase the stability of the protein in guanidinium. It is concluded that, in Euphorbia peroxidase, Ca2+ ion play a key role in conferring structural stability to the heme environment and in retaining active site geometry.     

A chitinase from Euphorbia characias latex is a novel and powerful plant‐based pesticide against Drosophila suzukii

Drosophila suzukii attacks on developing soft fruits have recently caused important economic losses in Europe. This study explores the effectiveness of a new control strategy against this insect pest that is based on a plant chitinase extracted from the latex of the Mediterranean spurge, Euphorbia characias. The ability of the purified Euphorbia latex chitinase (ELC) to degrade the chitin exoskeleton of D. suzukii was assessed using confocal laser scanning microscopy. ELC treatment caused reduced larval growth, higher mortality and notable degradation of external insect structures. Therefore, the chitinase may induce a double effect on the D. suzukii larvae, a direct injury on the larval bodies and an action as antifeedant. The effects of the ELC treatment were also tested on leaves of the insect's host plants, Fragaria × ananassa and Rubus idaeus, using physiological parameters (chlorophyll concentration, chlorophyll fluorescence, leaf gas exchange and water potential) and defence gene expression (FaPGIP, FaChi2_1 and FaChi2_2) as stress indicators. ELC at concentrations effective against D. suzukii did not damage the host plants. Only plant defence gene expression was somewhat enhanced during the early hours after ELC application. In conclusion, ELC, a natural product, proved to be an effective tool for use in the development of an environmentally friendly integrated management strategy against D. suzukii, a pest whose control by conventional chemical insecticides is problematic.     

Purification and properties of two lectins from the latex of the euphorbiaceous plants Hura crepitans L. (sand-box tree) and Euphorbia characias L. (Mediterranean spurge).

1. From the latex of two members of the plant family Euphorbiaceae, Hura crepitans L. (sand-box tree) and Euphorbia characias L. (Mediterranean spurge), two lectins were purified by affinity chromatography on acid-treated Sepharose 6B followed by elution with D-galactose. 2. The lectin from E. characias is a single molecular species with Mr 80 000, made up of two identical subunits with Mr 40 000, and is a glycoprotein containing 11% carbohydrate. 3. The lectin from H. creptians appears as a mixture of three isolectins with Mr 140 000, consisting of four different subunits with Mr values 37 500, 35 500, 31 000, and 29 000. 4. Both lectins have haemagglutinating activity, with no specificity for human blood groups. The haemagglutinating activity is inhibited by D-galactose and by galactose-containing oligosaccharides. 5. The lectin from H. crepitans is mitogenic to human T-, but not to B-, lymphocytes. The latex of E. characias is mitogenic to T- and, to a lesser extent, to B-, lymphocytes, but the purified E. characias lectin has no mitogenic activity. 6. The lectin from H. crepitans, but not that from E. characias, inhibits protein synthesis by a rabbit reticulocyte lysate.     

Terpenoid biosynthesis in Euphorbia latex

The latex of Euphorbia lathyris can utilize acetate, pyruvate and mevalonate for triterpene synthesis in vitro. Acetyl-CoA, hydroxymethylglutarate, hydroxymethylglutaryl-CoA and isopentenyl pyrophosphate were not effective as precursors for triterpene biosynthesis. Acetate is utilized only by the terpenoid pathway and by the tricarboxylic acid cycle; it is not used for fatty acid synthesis in this system. However, phospholipids were found to be efficient acyl donors for triterpene ester synthesis. The observed selectivity of precursor utilization as well as the observed rates for product formation indicate separate sites for triterpenol and triterpene ester synthesis and that one is not precursor for the other.     

Allosteric modulation of Euphorbia peroxidase by nickel ions

A class III peroxidase, isolated and characterized from the latex of the perennial Mediterranean shrub Euphorbia characias, contains one ferric iron-protoporphyrin IX pentacoordinated with a histidine 'proximal' ligand as heme prosthetic group. In addition, the purified peroxidase contained 1 mole of endogenous Ca(2+) per mole of enzyme, and in the presence of excess Ca(2+), the catalytic efficiency was enhanced by three orders of magnitude. The incubation of the native enzyme with Ni(2+) causes reversible inhibition, whereas, in the presence of excess Ca(2+), Ni(2+) leads to an increase of the catalytic activity of Euphorbia peroxidase. UV/visible absorption spectra show that the heme iron remains in a quantum mechanically mixed-spin state as in the native enzyme after addition of Ni(2+), and only minor changes in the secondary or tertiary structure of the protein could be detected by fluorescence or CD measurements in the presence of Ni(2+). In the presence of H(2)O(2) and in the absence of a reducing agent, Ni(2+) decreases the catalase-like activity of Euphorbia peroxidase and accelerates another pathway in which the inactive stable species accumulates with a shoulder at 619 nm. Analysis of the kinetic measurements suggests that Ni(2+) affects the H(2)O(2)-binding site and inhibits the formation of compound I. In the presence of excess Ca(2+), Ni(2+) accelerates the reduction of compound I to the native enzyme. The reported results are compatible with the hypothesis that ELP has two Ni(2+)-binding sites with opposite functional effects.     

Mass spectrometric determination of the inorganic carbon species assimilated by photoautotrophic cells of Euphorbia characias L

The chemical forms of inorganic carbon, CO2 or HCO3-, incorporated during photosynthesis in photoautotrophic Euphorbia characias cell suspension cultures were determined in experiments using 13CO2 and a mass spectrometry technique. From the equations of the CO2 hydration reaction, a kinetic model was first developed, and the effect of photosynthesis on the external CO2 concentration was simulated. It was predicted from this model that CO2 and HCO3- uptakes could be differentiated by recording only the CO2 variation rate in the external medium, successively in absence then in presence of an exogenous carbonic anhydrase activity. The results obtained with either CO2-grown or air-grown photoautotrophic cells were in good agreement with the model and demonstrated that CO2 was the sole species taken up during photosynthesis. In addition no accumulation of inorganic carbon within the cells was observed in the light. Similarly, in dark, CO2 was the only species released by respiration in the external medium.     

Oxygen exchange during growth of photomixotrophic cell suspensions of Euphorbia characias L.

Growth of photomixotrophic cell culture of Euphorbia characias L. is described; oxygen exchange rates were measured along this growth cycle using a mass-spectrometric technique. During the exponential and mid-stationary phases, photosynthesis was strongly increasing, the major part of oxygen uptake in the light was due to mitochondrial respiration. In the late stationary phase, gross photosynthesis was decreasing; this could not be explained by an alteration of Rubisco because photorespiratory process could be observed; in addition the Mehler reaction must be called upon to explain whole oxygen uptake in the light.     

Activity and Structural Changes of Euphorbia characias Peroxidase in the Presence of Trifluoroethanol

Activity assays, conformational changes and transitional switches between secondary structures of a peroxidase from Euphorbia characias were studied in the presence of trifluoroethanol and in the presence or absence of calcium ions. The addition of trifluoroethanol up to 10–20% first induced a drastic decrease of α-helix content followed by an increase of tryptophan fluorescence emission intensity, a progressive re-induction of the formation of α-helical elements concomitant with loss of enzyme activity. In the presence of calcium ions, the fluorescence of the enzyme almost remained unchanged in the trifluoroethanol concentration range 5–20%. Further increase in trifluoroethanol concentration led to a protein structure characterized by a progressive re-induction of α-helical elements, a remarkable increase of the tryptophan fluorescence and a loss of enzyme activity. These results indicate that calcium ions in Euphorbia peroxidase play an essential role in maintaining the hydrophobic interactions on the protein structure preserving enzymatic activity.     

Structure and nucleotide sequence of Euphorbia characias copper/TPQ-containing amine oxidase gene

A cDNA encoding for a copper containing amine oxidase has been isolated and sequenced from young leaves of Euphorbia characias, a perennial mediterranean shrub. A single long open reading frame of 2068 pb encodes a protein composed of 653 amino acids with a molecular mass of about 74 kDa. A putative 24-aminoacid signal peptide precedes the sequence of the mature protein, with characteristics of a secretion signal peptide. Alignments of Euphorbia amine oxidase cDNA nucleotide sequence with that of amine oxidase from the seedlings of the pulses lentil, pea, and chickpea reveal several conserved regions, especially in the C-terminus, with a homology 90%–97%. The near 5 region shows several insertions, deletions, and different nucleotide sequence with ca. 60% homology. The enzyme contains 1%–2% carbohydrate deduced by deglycosylation experiments. Five cysteine residues are present in the deduced aminoacid sequence with a single disulfide bridge as judged by titration with cysteine reagents.