[Cloning of polygalacturonase inhibitor protein genes from Solanum brevidens Fill].

New data were obtained for the Solanum brevidens Fill. nucleotide sequences coding for polygalacturonase inhibitor proteins (PGIPs), which are involved in plant defense against phytopathogenic fungi. Highly degenerate primers directed to the conserved regions of the known PGIP genes of tomato, kiwi, apple, carrot, and grape were used to clone four pgip genes and one pseudogene from the genome of S. brevidens, a species that is closely related to cultivated potato, forms no tubers, is highly resistant to phytopathogens, and is often employed in potato breeding. The sequenced part of the coding region of the new genes is 924 bp and codes for a protein of 308 amino acid residues (without the leader peptide). The genes were designated as pgipSbr1(1), pgipSbr1 (2). pgipSbr2, pgipSbr3, and pgipSbr4. The amino acid sequences of the S. brevidens PGIPs have 90.9-99.4% identity to each other and 94% identity to PGIP of Lycopersicon esculentum Mill., another member of the family Solanaceae. The amino acid residues differing between S. brevidens PGIPs were assumed to determine the selectivity of interactions with particular polyglucuronases of phytopathogenic fungi.

New subtilisin-like collagenase from leaves of common plantain.

A new subtilisin-like proteinase hydrolyzing chromogenic peptide substrate Glp-Ala-Ala-Leu-p-nitroanilide optimally at pH 8.1 was found in common plantain leaves. The protease named plantagolisin was isolated by ammonium sulfate precipitation of the leaves' extract followed by affinity chromatography on bacitracin-Sepharose and ion-exchange chromatography on Mono Q in FPLC regime. Its molecular mass is 19000 Da and pI 5.0. pH-stability range is 7-10 in the presence of 2 mM Ca(2+), temperature optimum is 40 degrees C. The substrate specificity of subtilase towards synthetic peptides and insulin B-chain is comparable with that of two other subtilisin-like serine proteinases: proteinase from leaves of the sunflower and taraxalisin. Besides, the proteinase is able to hydrolyze substrates with Pro in P(1) position. The enzyme hydrolyzes collagen. alpha and beta chains are hydrolyzed simultaneously in parallel; there are only low-molecular-mass hydrolysis products in the sample after 2 h of incubation. Pure serine proteinase was inactivated by specific serine proteinases inhibitors: diisopropylfluorophosphate, phenylmethylsulfonyl fluoride and Hg(2+). The plantagolisin N-terminal sequence ESNSEQETQTESGPGTAFL-, traced for 19 residues, revealed 37% homology with that of subtilisin from yeast Schizosaccharomyces pombe.

A new subtilisin-like proteinase from roots of the dandelion Taraxacum officinale Webb S. L.

A serine proteinase from roots of Taraxacum officinale Webb S. L. was isolated by affinity chromatography and gel-filtration on Superose 6R using FPLC. The enzyme is a 67-kD glycoprotein containing 54% carbohydrate which we have named taraxalisin. The substrate specificity of taraxalisin toward synthetic peptides and oxidized insulin B-chain is comparable with that of cucumisin from Cucumis melo and the subtilisin-like serine proteinase macluralisin from Maclura pomifera. The proteinase is inactivated by DFP and PMSF. Taraxalisin exhibits maximal activity at pH 8.0. The pH range for stability of the enzyme is narrow--6.0-9.0. The temperature optimum for the subtilisin-like activity is 40 degrees C. The N-terminal sequence of taraxalisin has 40% of its residues identical to those of subtilisin Carlsberg. Thus, the serine proteinase from dandelion roots is a member of the subtilisin family, which is evidently widespread in the plant kingdom.

Plant subtilisins.

This review presents a systematization of available data on subtilisin-like serine proteinases of plants. Enzymatic and physicochemical properties of the enzymes, their structure and processing, as well as their biological functions and origin are considered. Subtilisin-like proteinases of plants have a number of substantial differences from such typical subtilisins as subtilisin BPN or subtilisin Carlsberg. The plant subtilisins are characterized by much greater molecular mass, long inserts and C-terminal regions, and several cysteine residues, while typical subtilisins have no cysteine residues, and thiol-dependent bacterial subtilisins contain only one cysteine residue required for enzymatic activity.

Taraxalisin -- a serine proteinase from dandelion Taraxacum officinale Webb s.l.

Latex of dandelion roots contains a serine proteinase that hydrolyzes a chromogenic peptide substrate Glp-Ala-Ala-Leu-pNA optimally at pH 8.0. Maximal activity of the proteinase in the roots is attained in April, at the beginning of plant development after the winter period. The protease was isolated by ammonium sulfate precipitation of the root extract followed by affinity chromatography on a Sepharose-Ala-Ala-Leu-mrp and gel filtration on Superose 6R performed in FPLC regime. Pure serine proteinase named taraxalisin was inactivated by specific inhibitors of serine proteinases, diisopropylfluorophosphate (DFP) and phenylmethylsulfonylfluoride (PMSF). Its molecular mass is 67 kDa and pI 4.5. pH stability range is 6-9 in the presence of 2 mM Ca2+, temperature optimum is at 40 degrees C; Km=0.37+/-0.06 mM. The substrate specificity of taraxalisin towards synthetic peptides and insulin B-chain is comparable with that of two other subtilisin-like serine proteinases, cucumisin and macluralisin. The taraxalisin N-terminal sequence traced for 15 residues revealed 40% coinciding residues when aligned with that of subtilisin Carlsberg.

[Affinity sorbents with tripeptide morpholine ligands for isolation of proteases]. / Affinnye sorbenty dlia vydeleniia proteinaz, soderzhashchie v kachestve ligandov morfolidy tripeptidov.

New affine sorbents were synthesized involving tripeptide morpholides H-Ala-Ala-Leu-Mrp and H-D-Ala-Leu-Arg-Mrp as ligands that mimic substrates of subtilisin-like proteases and kallikrein, respectively. These were used for the isolation and purification of several proteases: trypsin, pepsin, alpha-chymotrypsin, thrombin, kallikrein, and termitase and were also efficient in the isolation of proteolytic enzymes from complex mixtures, such as the urine of children suffering from glomerulonephritis, hepatopancreas of Kamchatka crab, and dandelion roots. The ligands are competitive inhibitors of a number of proteases, and therefore, they were supposed to interact with the substrate binding sites in these enzymes.