Partial characterization of the crude proteolytic extracts of five Asclepiadaceae species namely Araujia hortorum Fourn., Asclepias curassavica L., Funastrum clausum (Jacq.) Schlechter, Morrenia brachystephana Griseb. and Morrenia odorata (Hook. et Arn.) Lindley, and a comparison of these results and those from other Asclepiadaceae species are reported. Additionally, the crude extract from M. brachystephana was submitted to further purification and characterization. The crude enzyme showed high proteolytic activity when assayed on casein in the presence of 12 mM cysteine but was strongly inhibited by very low concentrations of sodium iodoacetate (0.01 mM) and mercuric chloride (0.1 mM) suggesting that the enzyme belongs to the cysteinyl‐proteases type. Fractioned acetone precipitation followed by cation exchange chromatography allowed the separation of two basic ( pI > 9.3) proteolytically active fractions, both homogeneous by sodium dodecyl sulphate–polyacrylamide gel electrophoresis and with similar molecular masses (25.5 and 26 kDa).Copyright © 1998 John Wiley & Sons, Ltd.
An outstanding parameter in cheese making is the type of coagulant, which greatly influences the characteristics of the final products. Proteolysis is the most important set of biochemical changes during ripening of most cheeses, and is carried out, in different magnitude, by proteolytic agents originated in milk, rennet (or rennet substitute), and starter and non-starter micro-organisms (Silva & Malcata, 2000). The demand for alternative sources of milk coagulants, to replace the expensive and limited natural rennet supplies, has increased (Esteves et al. 2001). All commercial enzymes employed as milk coagulant are aspartic proteinases, which are most active at acidic pH and preferentially cleave peptide bonds between residues with hydrophobic side-chains (Silva & Malcata, 1999). Because of the presence of aspartic proteinases, aqueous crude extracts from flowers of Cynara cardunculus (Veríssimo et al. 1995, 1996), Cynara humilis, and/or Cynara scolymus are traditionally employed in the Iberian Peninsula as vegetable rennet for cheesemaking (Reis et al. 2000). Milk clotting activity was also proved in flowers of Centaurea calcitrapa and Onopordum turcicum (Tamer, 1993; Domingos et al. 1998). All these species are included within the Asteraceae family and furthermore in the same tribe: Cardueae Cass.= Cynareae Less. (Ariza Espinar & Delucchi, 1998). When a potential rennet substitute is studied, it is particularly important to evaluate adequately the degradation patterns of the caseins because of their effects on yield, consistency, and flavour of the final cheese (Fox, 1989). It is important to guarantee a well-balanced breakdown of curd proteins (caseins) in order to avoid formation of undesired attributes in cheese such as low viscosity and high bitterness (Visser, 1993). One of the most frequently used methods to monitor proteolytic processes on caseins is urea-polyacrylamide gel electrophoresis. On the other hand, tricine-SDS polyacrylamide gel electrophoresis improves the separation, identification and quantification of casein hydrolysates because it allows the visualization of large and small peptides (Pardo & Natalucci, 2001), with the additional advantage of allowing the estimation of molecular masses. Both methods are then suitable to characterize the performance of vegetable rennet in different ways. This preliminary study had the following objectives: the partial characterization of (i) the aspartic proteolytic activity present in flowers of Silybum marianum (L.) Gaertn. (Asteraceae); and (ii) the hydrolytic profile of bovine caseins.
In this work we report the isolation, purification and characterization of a new protease from latex of Asclepias curassavica L. Crude extract (CE) was obtained by gathering latex on 0.1 M citric-phosphate buffer with EDTA and cysteine with subsequent ultracentrifugation. Proteolytic assays were made on casein or azocasein as substrates. Caseinolytic activity was completely inhibited by E-64. Stability at different temperatures, optimum pH and ionic strength were evaluated by measuring the residual caseinolytic activity at different times after the incubation. CE showed the highest caseinolytic activity at pH 8.5 in the presence of 12 mM cysteine. CE was purified by cation exchange chromatography (FPLC). Two active fractions, homogeneous by SDS-PAGE, were isolated. The major purified protease (asclepain cI) showed a molecular mass of 23.2 kDa by mass spectrometry and a pI higher than 9.3. The N-terminal sequence showed a high similarity with those of other plant cysteine proteinases. When assayed on N-alpha-CBZ-aminoacid-p-nitrophenyl esters, the enzyme showed higher preference for the glutamine derivative. Determinations of kinetic parameter (km and Kcat) were performed with PFLNA.
A new protease (araujiain h I) was purified to mass spectroscopy homogeneity from the latex of Araujia hortorum Fourn. (Asclepiadaceae) fruits by ultracentrifugation and ion exchange chromatography. The enzyme has a molecular mass of 24,031 (mass spectrometry) and an iso-electric point higher than 9.3. The optimum pH range for casein hydrolysis was 8.0-9.5. The enzyme showed remarkable caseinolytic activity at high temperatures, although its thermal stability decayed rapidly. The proteinase was activated by thiol compounds and inhibited by common thiol-blocking reagents, particularly E-64 and HgCl2, suggesting the enzyme belongs to the cysteine protease family. The concentration of active sites as determined by titration with E-64 was 3.3 microM. When assayed on N-alpha-CBZ-amino acid-p-nitrophenyl esters, the enzyme showed higher preference for the glutamine derivative, followed by those of alanine, asparagine, glycine, and leucine, in decreasing order. Partial homology (36-48%) with other plant cysteine proteinases was observed in an internal fragment obtained by Protease V8 treatment.
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