Toxicity to the pea aphid Acyrthosiphon pisum of anti-chymotrypsin isoforms and fragments of Bowman-Birk protease inhibitors from pea seeds.

Aphids feed on a protein-poor diet and are insensitive to several serine protease inhibitors. However, among the Bowman-Birk family of plant trypsin inhibitors (BBI), some members display significant toxicity to the pea aphid Acyrthosiphon pisum. A BBI isoform purified from pea seeds (PsTI-2) displays an IC50 of 41 microM and a LC50 of 48 microM at 7 days. Our data show that the chymotrypsin-directed active site from these bifunctional inhibitors is responsible for this activity, and that artificial cyclic peptides bearing the Bowman-Birk anti-chymotrypsin head induce much greater toxicity and growth inhibition than their anti-trypsin counterparts. The toxic syndrome included a rapid behavioural response of aphids on diets containing the toxic peptides, with induced restlessness after only 1 h of exposure to the chymotrypsin inhibitor. Nevertheless, chymotrypsin activity was not detected in aphid guts, using two chromogenic chymotrypsin substrates, and the physiological target of the chymotrypsin inhibitor remains unknown. These data show for the first time that plant chymotrypsin inhibitors, still widely unexplored, may act as paradoxical toxicants to aphids and serve as defensive metabolites for phloem-feeding insects.

Wheat prolamine crosslinking through dityrosine formation catalyzed by peroxidases: improvement in the modification of a poorly accessible substrate by "indirect" catalysis

"Enzyme-assisted" oxidative polymerization of wheat gliadins was performed in an attempt to obtain new protein-based networks. Two plant peroxidases (soybean and horseradish) were used to induce the dimerization of tyrosine residues. The results show that tyrosines are poorly modified by these enzymes in an aqueous medium (dityrosine corresponded to 2% of the total amount of tyrosine). Two approaches were tested to overcome problems relating to accessibility to the target tyrosines: First, the efficiency of protein crosslinking via tyrosine-tyrosine aromatic ring condensation was enhanced in water when the proteins were oxidized by a fungus peroxidase (manganese-dependent peroxidase from Phanerochaete chrysosporium), which acts according to an indirect catalysis mechanism (up to 12% of the total amount of tyrosine is recovered under a dimeric form). Second, when the gliadins were dispersed in a water/dioxane (3/1) mixed solvent system, the tyrosines were more accessible on the protein surface, and similar yields were obtained with both types of peroxidase. The two types of catalysis (contact and indirect) are considered from the standpoint of the accessibility of the target residues. Enzymatic oxidations were also performed on synthetic peptides mimicking the repeatitive domains of gliadins. The results show that exposure of tyrosine to the solvent may not be sufficient to induce dityrosine formation. The mechanical properties of some films obtained from peroxidase-treated gliadins were investigated to correlate protein crosslinking with a potential application. One effect of the enzymatic treatment was to increase the tensile strength of the films. Copyright 1999 John Wiley & Sons, Inc.

Alpha-tropomyosin gene expression in Xenopus laevis: differential promoter usage during development and controlled expression by myogenic factors.

Tropomyosins (TMs) constitute a group of contractile proteins encoded by a multigene family showing distinct cell-type-specific and developmental expression patterns. In mammals and birds, the alpha-TM gene is the most complex and can produce several muscle and non-muscle isoforms. We report here the characterization of the 5' region of the Xenopus laevis alpha-TM gene and its developmental expression. The 5' region of the gene is structurally related to the avian and mammalian cognates and presents two promoters flanking a pair of alternatively spliced exons, 2a/2b, where exon 2a is a smooth-muscle-specific exon. The internal promoter is used to generate a non-muscle low molecular weight TM whilst muscle TM isoforms originate from the distal promoter. RNase protection analysis shows that the two promoters have distinct temporal programs of activation. The internal promoter is activated early in oogenesis and non-muscle transcripts are found throughout oogenesis, embryogenesis and in adult tissues. Only low molecular weight non-muscle TM-encoding mRNAs are expressed in oogenesis. The distal promoter is silent during oogenesis, and the skeletal muscle alpha-TM transcripts accumulate from stage 15 in the embryo and are expressed in adult striated muscle tissues. In situ hybridization indicates that these transcripts are expressed in both the somites and heart of the embryo. Ectopic expression of myogenic factors, but not the MEF2 myocyte-specific enhancer factor 2 factors SL1 and SL2, can induce the expression of the alpha-TM gene suggesting that the gene is a direct target for myogenic but not for MEF2 factors. The amphibian alpha-TM gene constitutes a gene marker for studying the developmental control expression of muscle genes in the different myogenic lineages.

Trypsin inhibitor polymorphism: multigene family expression and posttranslational modification.

Trypsin inhibitors from winter pea seeds (c.v. Frilene) have been purified and shown to consist of six protease inhibitors (PSTI I, II, III, IVa, IVb, and V). Based on amino acid composition, molecular mass, and N-terminal sequence, the six inhibitors are closely related to one another and belong to the Bowman-Birk family of inhibitors. To define the relations among them, molecular mass and amino acid composition of peptides obtained from digestion with trypsin were determined. The sequence and the biosynthetic mechanism of the isoform formation have been partially resolved for four major isoforms. Two isoinhibitor forms (PSTI IVa, IVb) in pea seeds are due to expression of two distinct genes; PSTI IVa has four amino acid replacements when its sequence is compared with the sequence of PSTI IVb. Two others (PSTI I, II) result from posttranslational proteolytic cleavage of nine C-terminal residues of forms PSTI IVa and IVb, respectively.

Amino acid sequence of a Bowman-Birk proteinase inhibitor from pea seeds.

Trypsin inhibitors from winter pea seeds (c.v. Frilene) have been purified by ammonium sulfate precipitation, gel filtration, and anion and cation exchange chromatography and shown to consist of six protease inhibitors (PSTI I, II, III, IVa, IVb, and V). Their molecular weights were determined by electrospray mass spectrometry as 6916, 6807, 7676, 7944, 7848 and 7844 D, respectively, and the sequences of the first 20 N-terminal amino acid residues of these six inhibitors were found to be identical. The complete amino acid sequence of PSTI IVa was determined. This protein comprises a total of 72 residues and has 14 cysteines, all involved in disulfide bridges. Comparison of the sequence of PSTI IVa with those of other leguminous Bowman-Birk type inhibitors revealed that PSTI could be classified as a group III inhibitor, closely related to Vicia faba and Vicia angustifolia inhibitors.