Multiple forms of the asclepains. Cysteinyl proteases from milkweed

Studies on detection and analysis of proteases in leaf extract of medicinally important plants

ETHNO-PHARMACOLOGICAL RELEVANCE

The whole plant or the extracts obtained from them have long been used as medicine to treat various human diseases and disorders. Notably, those plants endowed with protease activity have been traditionally used as the agents for treating tumors, digestion disorders, swelling, blood coagulation, fibrinolysis and also for immune-modulation.

AIM OF THE STUDY

Proteases occupy a pivotal position in enzyme based industries. Plant proteases have been increasingly exploited for pharmaceutical, food, leather and textile processing industries. Earlier investigations have focused on the occurrence of proteases in medicinally unimportant plants. Therefore it has been aimed to study the occurrence of proteolytic enzymes from medicinally important plants establish any correlation exists between protease activity and medicinal use of individual plants.

METHODS

Crude extract were obtained from the leaves of 80 different medicinal plants. Tris-HCl buffer was used as the extraction buffer and the supernatants obtained were used for determination of total protein and protease activity using spectrophotometric methods. Qualitative screening for the presence of protease was carried out with agar diffusion method by incorporating the substrate. SDS-PAGE was used to analyse the isoforms of protease and for determination of relative molecular mass.

RESULTS

Relatively higher protease activities were observed in the extracts of leaves of Pongamia pinnata (Fabaceae), Wrightia tinctoria (Apocyanaceae) Acalypha indica (Euphorbiaceae), Adhatoda vasica (Acanthaceae) and Curcuma longa (Zingiberaceae). No correlation was found between the total protein content and protease activity in individual plant species. SDS-PAGE analysis indicated the presence of multiple forms of protease of higher molecular weight range in several plant species. We found a strong correlation between the protease activity and medicinal application of the plant CONCLUSION: The present study has unequivocally revealed that the leaves of medicinal plants could serve as excellent sources of proteases which could be exploited for various industrial, food and pharmaceutical applications.

Peptidase specificity from the substrate cleavage collection in the MEROPS database and a tool to measure cleavage site conservation

One peptidase can usually be distinguished from another biochemically by its action on proteins, peptides and synthetic substrates. Since 1996, the MEROPS database (http://merops.sanger.ac.uk) has accumulated a collection of cleavages in substrates that now amounts to 66,615 cleavages. The total number of peptidases for which at least one cleavage is known is 1700 out of a total of 2457 different peptidases. This paper describes how the cleavages are obtained from the scientific literature, how they are annotated and how cleavages in peptides and proteins are cross-referenced to entries in the UniProt protein sequence database. The specificity profiles of 556 peptidases are shown for which ten or more substrate cleavages are known. However, it has been proposed that at least 40 cleavages in disparate proteins are required for specificity analysis to be meaningful, and only 163 peptidases (6.6%) fulfil this criterion. Also described are the various displays shown on the website to aid with the understanding of peptidase specificity, which are derived from the substrate cleavage collection. These displays include a logo, distribution matrix, and tables to summarize which amino acids or groups of amino acids are acceptable (or not acceptable) in each substrate binding pocket. For each protein substrate, there is a display to show how it is processed and degraded. Also described are tools on the website to help with the assessment of the physiological relevance of cleavages in a substrate. These tools rely on the hypothesis that a cleavage site that is conserved in orthologues is likely to be physiologically relevant, and alignments of substrate protein sequences are made utilizing the UniRef50 database, in which in each entry sequences are 50% or more identical. Conservation in this case means substitutions are permitted only if the amino acid is known to occupy the same substrate binding pocket from at least one other substrate cleaved by the same peptidase.

Production of plant proteases in vivo and in vitro--a review

In the latest two decades, the interest received by plant proteases has increased significantly. Plant enzymes such as proteases are widely used in medicine and the food industry. Some proteases, like papain, bromelain and ficin are used in various processes such as brewing, meat softening, milk-clotting, cancer treatment, digestion and viral disorders. These enzymes can be obtained from their natural source or through in vitro cultures, in order to ensure a continuous source of plant enzymes. The focus of this review will be the production of plant proteases both in vivo and in vitro, with particular emphasis on the different types of commercially important plant proteases that have been isolated and characterized from naturally grown plants. In vitro approaches for the production of these proteases is also explored, focusing on the techniques that do not involve genetic transformation of the plants and the attempts that have been made in order to enhance the yield of the desired proteases.

Biochemical analysis of a papain-like protease isolated from the latex of Asclepias curassavica L

Most of the species belonging to Asclepiadaceae family usually secrete an endogenous milk-like fluid in a network of laticifer cells in which sub-cellular organelles intensively synthesize proteins and secondary metabolites. A new papain-like endopeptidase (asclepain c-II) has been isolated and characterized from the latex extracted from petioles of Asclepias curassavica L. (Asclepiadaceae). Asclepain c-II was the minor proteolytic component in the latex, but showed higher specific activity than asclepain c-I, the main active fraction previously studied. Both enzymes displayed quite distinct biochemical characteristics, confirming that they are different enzymes. Crude extract was purified by cation exchange chromatography (FPLC). Two active fractions, homogeneous by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and mass spectrometry, were isolated. Asclepain c-II displayed a molecular mass of 23,590 Da, a pI higher than 9.3, maximum proteolytic activity at pH 9.4-10.2, and showed poor thermostability. The activity of asclepain c-II is inhibited by cysteine proteases inhibitors like E-64, but not by any other protease inhibitors such as 1,10-phenantroline, phenylmethanesulfonyl fluoride, and pepstatine. The Nterminal sequence (LPSFVDWRQKGVVFPIRNQGQCGSCWTFSA) showed a high similarity with those of other plant cysteine proteinases. When assayed on N-alpha-CBZ-amino acid-p-nitrophenyl esters, the enzyme exhibited higher preference for the glutamine derivative. Determinations of kinetic parameters were performed with N-alpha-CBZ-L-Gln-p-nitrophenyl ester as substrate: K(m)=0.1634 mM, k(cat)=121.48 s(-1), and k(cat)/K(m)=7.4 x 10(5) s(-1)/mM.

Philibertain g I, the Most Basic Cysteine Endopeptidase Purified from the Latex of Philibertia gilliesii Hook. et Arn. (Apocynaceae)

A new papain-like cysteine peptidase isolated from latex of Philibertia gilliesii Hook. et Arn., Apocynaceae (formerly Asclepiadaceae) has been purified and characterized. The enzyme, named philibertain g I, is the most basic component present in latex extracts and was purified by acetone fractionation followed by cation exchange chromatography (SP-Sepharose HR) using FPLC system. Homogeneity was confirmed by SDS-PAGE and mass spectroscopy (MS). Molecular mass of the enzyme was 23,530 Da (MALDI-TOF MS), its isoelectric point was >10.25, and maximum proteolytic activity (casein) was achieved at pH 7-8. The new protease was inhibited by E-64 a cysteine peptidases inhibitor. Km was 0.15 mM, using PFLNA as substrate. The N-terminal sequence of philibertain g I (LPASVDWRKEGAVLPIRHQGQCG) was compared with those of twenty plant proteases. Philibertain g I showed the higher degree of identity (73%) with caricain, one of the Carica papaya endopepetidases.

Purification and characterization of a new plant endopeptidase isolated from latex of Asclepias fruticosa L. (Asclepiadaceae)

Asclepias fruticosa L. is a small shrub containing latex with proteolytic activity. The crude extract (latex diluted 1:250 and ultracentrifuged) contained 276 microg of protein/mL and the proteolytic activity reached 1.2 caseinolytic U/mL. This enzyme preparation was very stable even after 2 hours at 45 degrees C, but was quickly inactivated after 5 minutes at 80 degrees C. Chromatographic purification was achieved by FPLC using a cation exchanger (SP-Sepharose FF). Thus, a unique proteolitically active fraction could be isolated, being homogeneous by bidimensional electrophoresis and mass spectrometry (Mr = 23,652). The optimum pH range was achieved at 8.5-10.5. The enzyme activity was completely inhibited by specific cysteine peptidases inhibitors. Isoelectric focusing followed by zymogram showed the enzyme had a pI greater than 9.3. The N-terminus sequence (LPDSVDWREKGVVFPIRNQGK) shows a great deal of similarity to those of the other cysteine endopeptidases isolated from latices of Asclepiadaceae even when a high degree of homology could be observed with other plant cysteine endopeptidases.

Two new cysteine endopeptidases obtained from the latex of Araujia hortorum fruits

Two new endopeptidases were purified to homogeneity from the latex of Araujia hortorum fruits by a simple purification procedure involving ultracentrifugation and ion exchange chromatography. Molecular weights of araujiain h II and araujiain h III were 23,718 and 23546 (mass spectrometry), respectively. The isoelectric point of araujiain h II was 8.9, whereas araujiain h III had a pI higher than 9.3. Maximum proteolytic activity on caseine was reached at pH 8.0-9.0 for both endopeptidases, which were irreversibly inhibited by iodoacetate and E-64, suggesting they belong to the cysteine protease family. Esterolytic activity was determined on N-alpha-CBZ-amino acid-p-nitrophenyl esters, and the highest kcat/Km values for the both enzymes were obtained with the glutamine derivative. The N-terminal sequences of araujiain h II and araujiain h III showed a high degree of homology with other plant cysteine endopeptidases.

Isolation and characterization of a cysteine protease from the latex of Araujia hortorum fruits

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.

Purification of ginger proteases by DEAE-Sepharose and isoelectric focusing

Ginger proteases in ginger rhizome (Zingiber officinale roscoe) were extracted from the ginger acetone powder and purified on DEAE-Sepharose and Sephadex G-75 columns. Before the purification, excess p-chloromercuribenzoate was added to the enzymes to prevent their autodigestion. The mercuribenzoate-proteases were further purified and fractionated by isoelectric focusing in Ampholine of pH 3-10 or pH 4-6. The proteases were fractionated into three components by the isoelectric focusing, having pI value of 4.5, 4.6 and 4.8 respectively. All these proteases had a molecular mass of 29,000 as measured by SDS-polyacrylamide gel electrophoresis and by TSK G2000SW XL gel chromatography. The Ampholine in the purified enzymes can quickly be removed by the gel chromatography of TSK G2000SW. Some divalent metal ions, such as Hg2+, Cu2+, Cd2+, and Zn2+, strongly inhibited these purified enzymes.

Comparative studies on calotropins DI and DII from the latex of Calotropis gigantea

Autodigestion of two cysteine proteinases, calotropins DI and DII isolated from the latex of Calotropis gigantea, has been studied at pH 7.5 and 37 degrees C in the presence of an activating agent. Calotropin DI is more susceptible to autodigestion than calotropin DII. During autodigestion no interconversion of one calotropin to another has occurred, as verified by polyacrylamide gel electrophoresis in the presence and absence of sodium dodecyl sulfate. Immunologically, both calotropins are closely related, but they differ from papain and ficin. Both calotropins have blocked N-terminal amino acid residues. Their C-terminal amino acid sequences, determined by treatment with carboxypeptidase Y, are -(Pro, Ala)-Ala-Val-Tyr for calotropin DI and -(Ala, Val)-Ala-Pro-Tyr for calotropin DII. The tryptic peptide maps of their reduced and S-carboxymethylated derivatives suggest that both calotropins share a high proportion of common regions in their amino acid sequences. Calotropins DI and DII are two distinct proteinases, and they do not appear to be produced by autodigestion of a single precursor. Although they are inert to the common synthetic substrates of papain and ficin, their specificities toward oxidized insulin B chain are comparable to those of papain and ficin.

Homologies of the N-terminal sequences of asclepains and papain

Sequences to residue 21 have been determined for the two asclepains, cysteinyl proteases isolated from milkweed (Asclepias syriaca L.). These were compared with the sequence for papain, and extensive homology was found.