The structure of the C/E-1 inhibitor confirms that inhibitors from Ascaris suum belong to a novel family of proteinase inhibitors. It also provides conclusive evidence for the correct disulfide bridge connections. The C/E-1 inhibitor probably acts by a common inhibitory mechanism proposed for other substrate-like protein inhibitors of serine proteinases. The unusual molecular scaffolding presents a challenge to current folding algorithms. Proteins like the C/E-1 inhibitor may provide a valuable model system to study how the primary sequence of a protein dictates its three-dimensional structure.
The major pepsin inhibitor from Ascaris suum was isolated by affinity chromatography and chromatofocusing. Its amino acid sequence was determined by automated Edman degradation of peptide fragments. Peptides were produced by chemical and enzymatic cleavage of pyridylethylated protein and were purified by reverse-phase high-performance liquid chromatography. The inhibitor consists of 149 residues with the following sequence: QFLFSMSTGP10FICTVKDNQV20FVANLPWTML30EGDDIQVGKE40 FAARVEDCTN50VKHDMAPTCT60KPPPFCGPQD70MKMFNFVGCS80VLGNKLFIDQ90KYVRDLTAK D100 HAEVQTFREK110IAAFEEQQEN120QPPSSGMPHG130AVPAGGLSPP140PPPSFCTVQ149. It has a molecular weight of 16,396. All cysteines are engaged as disulfide bonds: Cys(13)-Cys(59), Cys(48)-Cys(66), and Cys(79)-Cys(146). The protein is probably composed of two domains connected by a short hydrophobic region. This is the first aspartyl protease inhibitor of animal origin that has been sequenced. The sequence has no significant homology with any other known protein.
The solution conformation of the Ascaris trypsin inhibitor, a member of a novel class of proteinase inhibitors, has been investigated by nuclear magnetic resonance spectroscopy. Complete sequence-specific assignments of the 1H NMR spectrum have been obtained by using a number of two-dimensional techniques for identifying through-bond and through-space (less than 5-A) connectivities. Elements of regular secondary structure have been identified on the basis of a qualitative interpretation of the nuclear Overhauser enhancement, coupling constant, and amide exchange data. These are two beta-sheet regions. One double-stranded antiparallel beta-sheet comprises residues 11-14 (strand 1) and 37-39 (strand 2). The other triple-stranded sheet is formed by two antiparallel strands comprising residues 45-49 (strand 4) and 53-57 (strand 5) connected by a turn (residues 50-52), and a small strand consisting of residues 20-22 (strand 3) that is parallel to strand 4.
The three-dimensional structures of pepsin inhibitor-3 (PI-3) from Ascaris suum and of the complex between PI-3 and porcine pepsin at 1. 75 A and 2.45 A resolution, respectively, have revealed the mechanism of aspartic protease inhibition by this unique inhibitor. PI-3 has a new fold consisting of two domains, each comprising an antiparallel beta-sheet flanked by an alpha-helix. In the enzyme-inhibitor complex, the N-terminal beta-strand of PI-3 pairs with one strand of the 'active site flap' (residues 70-82) of pepsin, thus forming an eight-stranded beta-sheet that spans the two proteins. PI-3 has a novel mode of inhibition, using its N-terminal residues to occupy and therefore block the first three binding pockets in pepsin for substrate residues C-terminal to the scissile bond (S1'-S3'). The molecular structure of the pepsin-PI-3 complex suggests new avenues for the rational design of proteinaceous aspartic proteinase inhibitors.
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