Kinetic study of sunflower phospholipase Dα: interactions with micellar substrate, detergents and metals

Mixed micelles and bicontinuous microemulsions: Promising media for enzymatic reactions

Enzymes, the natural catalysts, replace catalysts of chemical origin in a wide spectrum of reactions and generally work under environment friendly conditions. Various strategies are adopted to modify catalytic activities of enzymes further, of which one is application of novel reaction medium. This work reviews applicability of novel media like mixed micelles and bicontinuous microemulsions in enzymatic reactions and points out their capability to play bigger roles in enzyme catalysis. Ionic reverse micelles reduced catalytic activities of enzymes through denaturation. Addition of nonionic surfactant to these reverse micelles led to corresponding mixed micelles and thus restored or sometimes enhanced catalytic abilities of enzymes. Mixed micelles comprising of two nonionic surfactants, bicontinuous microemulsion containing two anionic surfactants also acted as efficient reaction media for enzymes. Even a cationic/anionic/nonionic mixed micelle was found to increase activity of enzyme. Mixed micelles and bicontinuous microemulsions comprising of anionic and zwitterionic surfactants augmented enzyme catalysis. Mixed micelles and bicontinuous microemulsions containing ionic liquid and surfactant also had critical impact on enzyme catalysis. Catalytic abilities of enzymes altered significantly in substrate/surfactant and bile salt/surfactant mixed micelles. Concentrations of individual surfactant, molar ratio of surfactants, and molar ratio of water to total surfactants had notable impacts on enzyme catalysis in those media.

Expression and Purification of Recombinant Vigna unguiculata Phospholipase D in Pichia pastoris for Structural Studies

The production of pure enzymes in high quantities is a proven strategy to study the catalytic mechanism as well as the solving of structure at the atomic scale for therapeutic or industrial purposes. Phospholipase D (PLD, EC 3.1.4.4) is found in a wide majority of living organisms and has been shown to be involved in signal transduction, vesicle trafficking, and membrane metabolism processes. Located at the membrane-cytoplasm interface, plant PLDs are soluble but also bear an evident hydrophobic aspect making challenging its expression and its purification in large quantity. So far there is no high-resolution three-dimensional structure for a eukaryotic PLD. The protocols herein describe the cloning of the eukaryotic recombinant PLDα of Vigna unguiculata (cowpea) into the yeast expression system Pichia pastoris and its two-step purification process. This allowed us to purify to homogeneity hundreds of micrograms of highly pure protein to conduct in fine structural studies.

Metal ions and phosphatidylinositol 4,5-bisphosphate as interacting effectors of α-type plant phospholipase D

Plant phospholipases D (PLD) are typically characterized by a C2 domain with at least two Ca²⁺ binding sites. In vitro, the predominantly expressed α-type PLDs need 20-100 mM CaCl₂ for optimum activity, whereas the essential activator of β- or γ-type PLDs, phosphatidylinositol 4,5-bisphosphate (PIP₂), plays a secondary role. In the present paper, we have studied the interplay between PIP₂ and metal ion activation of the well-known α-type PLD from cabbage (PLDα). With mixed micelles containing phosphatidyl-p-nitrophenol as substrate, PIP₂-concentrations in the nanomolar range are able to activate the enzyme in addition to the essential Ca²⁺ activation. Mg²⁺ ions are able to replace Ca²⁺ ions but they do not activate PLDα. Rather, they abolish the activation of the enzyme by Ca²⁺ ions in the absence, but not in the presence, of PIP₂. The presence of PIP₂ causes a shift in the pH optimum of PLDα activity to the acidic range. Employing fluorescence measurements and replacing Ca²⁺ by Tb³⁺ ions, confirmed the presence of two metal ion-binding sites, in which the one of lower affinity proved crucial for PLD activation. Moreover, we have generated a homology model of the C2 domain of this enzyme, which was used for Molecular Dynamics (MD) simulations and docking studies. As is common for C2 domains, it shows two antiparallel β-sheets consisting of four β-strands each and loop regions that harbor two Ca²⁺ binding sites. Based on the findings of the MD simulation, one of the bound Ca²⁺ ions is coordinated by five amino acid residues. The second Ca²⁺ ion induces a loop movement upon its binding to three amino acid residues. Docking studies with PIP₂ reveal, in addition to the previously postulated PIP₂-binding site in the middle of the β-sheet structure, another PIP₂-binding site near the two Ca²⁺ ions, which is in accordance with the experimental interplay of PIP₂, Ca²⁺ and Mg²⁺ ions.

Purification, sequencing and characterization of phospholipase D from Indian mustard seeds

Phospholipase D (PLD; E.C. 3.1.4.4) is widespread in plants where it fulfills diverse functions in growth and in the response to stresses. The enzyme occurs in multiple forms that differ in their biochemical properties. In the present paper PLD from medicinally relevant Indian mustard seeds was purified by Ca(2+)-mediated hydrophobic interaction and anion exchange chromatography to electrophoretic homogeneity. Based on mass-spectrometric sequence analysis of tryptic protein fragments, oligonucleotide primers for cloning genomic DNA fragments that encoded the enzyme were designed and used to derive the complete amino acid sequence of this PLD. The sequence data, as well as the molecular properties (molecular mass of 92.0 kDa, pI 5.39, maximum activity at pH 5.5-6.0 and Ca(2+) ion concentrations ⩾60 mM), allowed the assignment of this enzyme to the class of α-type PLDs. The apparent kinetic parameters Vmax and Km, determined for the hydrolysis of phosphatidylcholine (PC) in an aqueous mixed-micellar system were 356±15 μmol min(-1) mg(-1) and 1.84±0.17 mM, respectively. Phosphate analogs such as NaAlF4 and Na3VO4 displayed strong inhibition of the enzyme. Phosphatidylinositol 4,5-bisphosphate had a strong activating effect at 2-10 mM CaCl2. PLD was inactivated at temperatures >45 °C. The enzyme exhibited the highest activity toward PC followed by phosphatidylethanolamine and phosphatidylglycerol. PCs with short-chain fatty acids were better substrates than PCs with long fatty acid chains. Lyso-PC was not accepted as substrate.

Identification of a new phospholipase D in Carica papaya latex

Phospholipase D (PLD) is a lipolytic enzyme involved in signal transduction, vesicle trafficking and membrane metabolism. It catalyzes the hydrolysis and transphosphatidylation of glycerophospholipids at the terminal phosphodiester bond. The presence of a PLD in the latex of Carica papaya (CpPLD1) was demonstrated by transphosphatidylation of phosphatidylcholine (PtdCho) in the presence of 2% ethanol. Although the protein could not be purified to homogeneity due to its presence in high molecular mass aggregates, a protein band was separated by SDS-PAGE after SDS/chloroform-methanol/TCA-acetone extraction of the latex insoluble fraction. This material was digested with trypsin and the amino acid sequences of the tryptic peptides were determined by micro-LC/ESI/MS/MS. These sequences were used to identify a partial cDNA (723 bp) from expressed sequence tags (ESTs) of C. papaya. Based upon EST sequences, a full-length gene was identified in the genome of C. papaya, with an open reading frame of 2424 bp encoding a protein of 808 amino acid residues, with a theoretical molecular mass of 92.05 kDa. From sequence analysis, CpPLD1 was identified as a PLD belonging to the plant phosphatidylcholine phosphatidohydrolase family.

The substrate specificities of sunflower and soybean phospholipases D using transphosphatidylation reaction

BACKGROUND

Phospholipase D (PLD) belongs to a lipolytic enzyme subclass which catalyzes the hydrolysis and transesterification of glycerophospholipids at the terminal phosphodiester bond.

RESULTS

In this work, we have studied the substrate specificity of PLDs from germinating sunflower seeds and cultured-soybean cells, using their capacity of transphosphatidylation. In the presence of a nucleophilic acceptor, such as [¹⁴C]ethanol, PLD catalyzes the production of phosphatidyl-[¹⁴C]-ethanol. The resulting product is easily identified since it is well separated from the other lipids by thin-layer chromatography. The main advantage of this assay is that the phospholipid used as substrate does not need to be radiolabelled and thus allow us a large choice of polar heads and fatty acids. In vitro, we observed that sunflower and soybean cell PLD show the following decreasing order of specificity: phosphatidylcholine, phosphatidylethanolamine and phosphatidylglycerol; while phosphatidylserine and phosphatidylinositol are utilized much less efficiently.

CONCLUSIONS

The substrate specificity is modulated by the fatty acid composition of the phosphatidylcholine used as well as by the presence of other charged phospholipids.