Characterization of heat‐labile uracil‐DNA glycosylase from Psychrobacter sp. HJ147 and its application to the polymerase chain reaction

Abstract

An affinity matrix containing the antimalarial drug target Plm II (plasmepsin II) as ligand was generated. This enzyme belongs to the family of Plasmodium (malarial parasite) aspartic proteinases, known as Plms (plasmepsins). The procedure established to obtain the support has two steps: the immobilization of the recombinant proenzyme of Plm II to NHS (N-hydroxysuccinimide)-activated Sepharose and the activation of the immobilized enzyme by incubation at pH 4.4 and 37 degrees C. The coupling reaction resulted in a high percentage immobilization (95.5%), and the matrices obtained had an average of 4.3 mg of protein/ml of gel. The activated matrices, but not the inactive ones, were able to hydrolyse two different chromogenic peptide substrates and haemoglobin. This ability was completely blocked by the addition of the general aspartic-proteinase inhibitor, pepstatin A, to the reaction mixture. The matrices were useful in the affinity purification of the Plm II inhibitory activity detected in marine invertebrates, such as Xestospongia muta (giant barrel sponge) and the gorgonian (sea-fan coral) Plexaura homomalla (black sea rod), with increases of 10.2- and 5.9-fold in the specific inhibitory activity respectively. The preliminary K(i) values obtained, 46.4 nM (X. muta) and 1.9 nM (P. homomalla), and the concave shapes of the inhibition curves reveal that molecules are reversible tight-binding inhibitors of Plm II. These results validated the use of the affinity matrix for the purification of Plm II inhibitors from complex mixtures and established the presence of Plm II inhibitors in some marine invertebrates.