The solution structure of clip domains from Manduca sexta prophenoloxidase activating proteinase-2

Clip domains are structural modules found in arthropod serine proteinases and some proteolytically inactive homologues, which mediate extracellular signaling pathways of development and immunity. While little is known about their structures or functions, clip domains are proposed to be sites for interactions of proteinases with their activators, cofactors, and substrates. Here we report the solution structure of dual clip domains from Manduca sexta prophenoloxidase activating proteinase-2. Each domain adopts a new mixed alpha/beta fold (a three-stranded antiparallel beta-sheet flanked by two alpha-helices), and the architecture provides structural information on clip domains from a catalytically active proteinase for the first time. Examination of the structure in conjunction with a multiple sequence alignment of the clip domains from different groups suggests a substrate-binding site, a bacteria-interacting region, and a surface for specific interactions. In summary, our results provide insights into the structural basis of clip domain functions and this structure may represent the prototype of group-2 clip domains.     

Peptidoglycan inducible expression of a serine proteinase homologue from kuruma shrimp (Marsupenaeus japonicus)

A cDNA encoding a serine proteinase homologue of kuruma shrimp (Marsupenaeus japonicus) was cloned. The 1257 bp cDNA encodes a 339 amino acid putative peptide, with a signal sequence of 16 amino acid residues. The deduced amino acid sequence is 42-67% similar to the immune-related serine proteinases and serine proteinase homologues of arthropods. It contains catalytic triad residues in the putative catalytic domain except for one substitution of Ser by a Gly residue. The six cysteine residues that form three disulphide bridges in most serine proteinases were conserved. The M. japonicus serine proteinase homologue was mainly expressed in haemocytes, in which expression dramatically increased after 3 days feeding with peptidoglycan at 0.2 mg kg(-1) shrimp body weight per day.     

The location of inhibitory specificities in human mucus proteinase inhibitor (MPI): separate expression of the COOH-terminal domain yields an active inhibitor of three different proteinases

Human mucus proteinase inhibitor (MPI) consists of 107 amino acids arranged in two domains showing high homology to each other. This protein is an inhibitor of different serine proteinases including trypsin, chymotrypsin, leukocyte elastase and cathepsin G. On the basis of sequence comparisons it has been suggested that the first domain inhibits trypsin, whereas the second one was thought to be active against chymotrypsin and elastase. To prove the location of the different inhibitory activities gene fragments for both domains have been cloned separately and expressed in Escherichia coli. Inhibition assays with the isolated recombinant domains showed that the second domain is active against chymotrypsin, neutrophil elastase and trypsin, whereas for the first domain only a weak activity against trypsin could be detected. These results suggest that the inhibitory activities of the native molecule towards these three proteinases are all located in the second domain.     

Compensatory proteolytic responses to dietary proteinase inhibitors in the red flour beetle, Tribolium castaneum (Coleoptera: Tenebrionidae)

Increasing levels of inhibitors that target cysteine and/or serine proteinases were fed to Tribolium castaneum larvae, and the properties of digestive proteinases were compared in vitro. Cysteine proteinases were the major digestive proteinase class in control larvae, and serine proteinase activity was minor. Dietary serine proteinase inhibitors had minimal effects on either the developmental time or proteolytic activity of T. castaneum larvae. However, when larvae ingested cysteine proteinase inhibitors, there was a dramatic shift from primarily cysteine proteinases to serine proteinases in the proteinase profile of the midgut. Moreover, a combination of cysteine and serine proteinase inhibitors in the diet prevented this shift from cysteine proteinase-based digestion to serine proteinase-based digestion, and there was a corresponding substantial retardation in growth. These data suggest that the synergistic inhibitory effect of a combination of cysteine and serine proteinase inhibitors in the diet of T. castaneum larvae on midgut proteolytic activity and beetle developmental time is achieved through the prevention of the adaptive proteolytic response to overcome the activity of either type of inhibitor.     

Multi-domain, cell-envelope proteinases of lactic acid bacteria

The multi-domain, cell-envelope proteinases encoded by the genes prtB of Lactobacillus delbrueckii subsp. bulgaricus, prtH of Lactobacillus helveticus, prtP of Lactococcus lactis, scpA of Streptococcus pyogenes and csp of Streptococcus agalactiae have been compared using multiple sequence alignment, secondary structure prediction and database homology searching methods. This comparative analysis has led to the prediction of a number of different domains in these cell-envelope proteinases, and their homology, characteristics and putative function are described. These domains include, starting from the N-terminus, a pre-pro-domain for secretion and activation, a serine protease domain (with a smaller inserted domain), two large middle domains A and B of unknown but possibly regulatory function, a helical spacer domain, a hydrophilic cell-wall spacer or attachment domain, and a cell-wall anchor domain. Not all domains are present in each cell-envelope proteinase, suggesting that these multi-domain proteins are the result of gene shuffling and domain swapping during evolution.     

Prophenoloxidase-activating proteinase-2 from hemolymph of Manduca sexta. A bacteria-inducible serine proteinase containing two clip domains

Proteolytic activation of prophenoloxidase in insects is a component of the host defense system against invading pathogens and parasites. We have purified from hemolymph of the tobacco hornworm, Manduca sexta, a new serine proteinase that cleaves prophenoloxidase. This enzyme, designated prophenoloxidase-activating proteinase-2 (PAP-2), differs from another PAP, previously isolated from integuments of the same insect (PAP-1). PAP-2 contains two clip domains at its amino terminus and a catalytic domain at its carboxyl terminus, whereas PAP-1 has only one clip domain. Purified PAP-2 cleaved prophenoloxidase at Arg(51) but yielded a product that has little phenoloxidase activity. However, in the presence of two serine proteinase homologs, active phenoloxidase was generated at a much higher level, and it formed covalently linked, high molecular weight oligomers. The serine proteinase homologs associate with a bacteria-binding lectin in M. sexta hemolymph, indicating that they may be important for ensuring that the activation of prophenoloxidase occurs only in the vicinity of invading microorganisms. PAP-2 mRNA was not detected in naive larval fat body or hemocytes, but it became abundant in these tissues after the insects were injected with bacteria.     

Phage display of a double-headed proteinase inhibitor: Analysis of the binding domains of potato proteinase inhibitor II

Potato proteinase inhibitor II (PI2) is a serine proteinase inhibitor composed of two domains that are thought to bind independently to proteinases. To determine the activities of each domain separately, various inactive and active domain combinations were constructed by substituting amino acid residues in the active domains by alanines. These derivatives were expressed as soluble protein inEscherichia coli and exposed on M13 phage as fusions to gene 3 in a phagemid system for monovalent phage display. Inactivation of both active domains by Ala residues reduced binding of phage to trypsin and chymotrypsin by 95%. Ten times more phage were bound to proteinases by domain II compared to domain I, while a point mutation (Leu⁵ Arg) altered the binding specificity of domain I of PI2 phage from chymotrypsin to trypsin. The mutants were used to show that functional PI2 phage mixed with nonfunctional PI2 phage could be enriched 323 000-fold after three rounds of panning. Thus, these results open up the possibility to use phage display for the selection of engineered PI2 derivatives with improved binding characteristics towards digestive proteinases of plants pests.The nucleotide sequence data reported will appear in the EMBL, GenBank and DDBJ Nucleotide Sequence Databases under the accession number L37519 (p303.51).     

Kazal型蛋白酶抑制剂结构与功能研究进展

蛋白酶抑制剂广泛存在于生物体内,在许多生命活动过程中发挥必不可少的作用,特别是对蛋白酶活性进行精确调控。其中Kazal型蛋白酶抑制剂是最重要的、研究最为广泛的酶抑制剂之一,该类抑制剂一般由一个或几个结构域组成,每一个结构域具有保守的序列和分子构象,同时发现该类抑制剂与蛋白酶作用的结合部位高度易变,它们大多数暴露于与溶剂接触的环上,其中P1部位是抑制作用的关键部位,抑制剂的专一性由P1部位氨基酸残基的性质决定,其它残基取代结合部位残基对抑制剂-酶的结合常数有显著的影响。Laskowski算法可直接从Kazal型丝氨酸蛋白酶抑制剂的序列推测其与6种丝氨酸蛋白酶之间的抑制常数(Ki)。目前在生物体内发现大量的Kazal型蛋白酶抑制剂,并证实其有重要的生物学功能。     

Nucleotide and protein sequences of a proteinase inhibitor from the vitelline envelope of dace (Tribolodon hakonensis) eggs

Our experimental purpose is to probe the structure(s) of the chorionic proteinase inhibitor and its cDNA sequence(s) and to develop the application of safe medicines for protection of human and other animal bodies from pathogenic microbe attacks. In this study, chorionic proteinase inhibitor protein was isolated, sequenced and used to base the design of PCR primers, which were then used to amplify DNA using RT-PCR. A cDNA clone of the protein which inhibited the activities of serine proteinases and thermolysin was obtained on the basis of mRNA extracted from ovarian tissue of dace, Tribolodon hakonensis, and the deduced amino acid sequence was determined. Chorionic proteinase inhibitor (TribSPI) peptides of about 9.0 kDa (TribSPI) and 14 kDa (TribSPI-S) were purified from vitelline envelope extracts by thermolysin-immobilized affinity-chromatography. The cloned TribSPI cDNA was 1806 bp in length, and the open reading flame (ORF) was 915 bp encoding a protein of 305 amino acid residues. The inhibitor protein had a molecular mass of 33,550 daltons and was composed of five similar domains. Each domain contained eight cysteine residues, and it's deduced amino acid sequence was only 33 approximately 34% identical to those of human and porcine antileukoproteinases (hALP and pALP, respectively). A possible binding-site for serine proteinases, Arg-Ile, was contained in three domains.     

Crystal structure of the catalytic domain of DESC1, a new member of the type II transmembrane serine proteinase family

DESC1 was identified using gene-expression analysis between squamous cell carcinoma of the head and neck and normal tissue. It belongs to the type II transmembrane multidomain serine proteinases (TTSPs), an expanding family of serine proteinases, whose members are differentially expressed in several tissues. The biological role of these proteins is currently under investigation, although in some cases their participation in specific functions has been reported. This is the case for enteropeptidase, hepsin, matriptase and corin. Some members, including DESC1, are associated with cell differentiation and have been described as tumor markers. TTSPs belong to the type II transmembrane proteins that display, in addition to a C-terminal trypsin-like serine proteinase domain, a differing set of stem domains, a transmembrane segment and a short N-terminal cytoplasmic region. Based on sequence analysis, the TTSP family is subdivided into four subfamilies: hepsin/transmembrane proteinase, serine (TMPRSS); matriptase; corin; and the human airway trypsin (HAT)/HAT-like/DESC subfamily. Members of the hepsin and matriptase subfamilies are known structurally and here we present the crystal structure of DESC1 as a first member of the HAT/HAT-like/DESC subfamily in complex with benzamidine. The proteinase domain of DESC1 exhibits a trypsin-like serine proteinase fold with a thrombin-like S1 pocket, a urokinase-type plasminogen activator-type S2 pocket, to accept small residues, and an open hydrophobic S3/S4 cavity to accept large hydrophobic residues. The deduced substrate specificity for DESC1 differs markedly from that of other structurally known TTSPs. Based on surface analysis, we propose a rigid domain association for the N-terminal SEA domain with the back site of the proteinase domain.     

Deletion of Various Carboxy-Terminal Domains of Lactococcus lactis SK11 Proteinase: Effects on Activity, Specificity, and Stability of the Truncated Enzyme

The Lactococcus lactis SK11 cell envelope proteinase is an extracellular, multidomain protein of nearly 2,000 residues consisting of an N-terminal serine protease domain, followed by various other domains of largely unknown function. Using a strategy of deletion mutagenesis, we have analyzed the function of several C-terminal domains of the SK11 proteinase which are absent in cell envelope proteinases of other lactic acid bacteria. The various deletion mutants were functionally expressed in L. lactis and analyzed for enzyme stability, activity, (auto)processing, and specificity toward several substrates. C-terminal deletions of first the cell envelope W (wall) and AN (anchor) domains and then the H (helix) domain leads to fully active, secreted proteinases of unaltered specificity. Gradually increasing the C-terminal deletion into the so-called B domain leads to increasing instability and autoproteolysis and progressively less proteolytic activity. However, the mutant with the largest deletion (838 residues) from the C terminus and lacking the entire B domain still retains proteolytic activity. All truncated enzymes show unaltered proteolytic specificity toward various substrates. This suggests that the main role played by these domains is providing stability or protection from autoproteolysis (B domain), spacing away from the cell (H domain), and anchoring to the cell envelope (W and AN domains). In addition, this study allowed us to more precisely map the main C-terminal autoprocessing site of the SK11 proteinase and the epitope for binding of group IV monoclonal antibodies.     

Hepatitis C virus NS3 serine proteinase: trans-cleavage requirements and processing kinetics.

The hepatitis C virus H strain (HCV-H) polyprotein is cleaved to produce at least 10 distinct products, in the order of NH2-C-E1-E2-p7-NS2-NS3-NS4A-NS4B-NS5A-NS5B -COOH. An HCV-encoded serine proteinase activity in NS3 is required for cleavage at four sites in the nonstructural region (3/4A, 4A/4B, 4B/5A, and 5A/5B). In this report, the HCV-H serine proteinase domain (the N-terminal 181 residues of NS3) was tested for its ability to mediate trans-processing at these four sites. By using an NS3-5B substrate with an inactivated serine proteinase domain, trans-cleavage was observed at all sites except for the 3/4A site. Deletion of the inactive proteinase domain led to efficient trans-processing at the 3/4A site. Smaller NS4A-4B and NS5A-5B substrates were processed efficiently in trans; however, cleavage of an NS4B-5A substrate occurred only when the serine proteinase domain was coexpressed with NS4A. Only the N-terminal 35 amino acids of NS4A were required for this activity. Thus, while NS4A appears to be absolutely required for trans-cleavage at the 4B/5A site, it is not an essential cofactor for serine proteinase activity. To begin to examine the conservation (or divergence) of serine proteinase-substrate interactions during HCV evolution, we demonstrated that similar trans-processing occurred when the proteinase domains and substrates were derived from two different HCV subtypes. These results are encouraging for the development of broadly effective HCV serine proteinase inhibitors as antiviral agents. Finally, the kinetics of processing in the nonstructural region was examined by pulse-chase analysis. NS3-containing precursors were absent, indicating that the 2/3 and 3/4A cleavages occur rapidly. In contrast, processing of the NS4A-5B region appeared to involve multiple pathways, and significant quantities of various polyprotein intermediates were observed. NS5B, the putative RNA polymerase, was found to be significantly less stable than the other mature cleavage products. This instability appeared to be an inherent property of NS5B and did not depend on expression of other viral polypeptides, including the HCV-encoded proteinases.     

Crystal structure of the beta-chain of human hepatocyte growth factor-like/macrophage stimulating protein

Hepatocyte growth factor like/macrophage stimulating protein (HGFl/MSP) and hepatocyte growth factor/scatter factor (HGF/SF) define a distinct family of vertebrate-specific growth factors structurally related to the blood proteinase precursor plasminogen and with important roles in development and cancer. Although the two proteins share a similar domain structure and mechanism of activation, there are differences between HGFl/MSP and HGF/SF in terms of the contribution of individual domains to receptor binding. Here we present a crystal structure of the 30 kDa beta-chain of human HGFl/MSP, a serine proteinase homology domain containing the high-affinity binding site for the RON receptor. The structure describes at 1.85 Angstrom resolution the region of the domain corresponding to the receptor binding site recently defined in the HGF/SF beta-chain, namely the central cleft harboring the three residues corresponding to the catalytic ones of active proteinases (numbers in brackets define the sequence position according to the standard chymotrypsinogen numbering system) [Gln522 (c57), Gln568 (c102) and Tyr661 (c195)] and an adjacent loop flanking the S1 specificity pocket and containing residues Asn682 (c217) and Arg683 (c218) previously shown to be essential for binding of HGFl/MSP to the RON receptor. The study confirms the concept that the serine proteinase homology domains of HGFl/MSP and HGF/SF bind their receptors in an 'enzyme-substrate' mode, reflecting the common evolutionary origin of the plasminogen-related growth factors and the proteinases of the clotting and fibrinolytic pathways. However, analysis of the intermolecular interactions in the crystal lattice of beta-chain HGFl/MSP fails to show the same contacts seen in the HGF/SF structures and does not support a conserved mode of dimerization of the serine proteinase homology domains of HGFl/MSP and HGF/SF responsible for receptor activation.     

Deletion of various carboxy-terminal domains of Lactococcus lactis SK11 proteinase: effects on activity, specificity, and stability of the truncated enzyme

The Lactococcus lactis SK11 cell envelope proteinase is an extracellular, multidomain protein of nearly 2,000 residues consisting of an N-terminal serine protease domain, followed by various other domains of largely unknown function. Using a strategy of deletion mutagenesis, we have analyzed the function of several C-terminal domains of the SK11 proteinase which are absent in cell envelope proteinases of other lactic acid bacteria. The various deletion mutants were functionally expressed in L. lactis and analyzed for enzyme stability, activity, (auto)processing, and specificity toward several substrates. C-terminal deletions of first the cell envelope W (wall) and AN (anchor) domains and then the H (helix) domain leads to fully active, secreted proteinases of unaltered specificity. Gradually increasing the C-terminal deletion into the so-called B domain leads to increasing instability and autoproteolysis and progressively less proteolytic activity. However, the mutant with the largest deletion (838 residues) from the C terminus and lacking the entire B domain still retains proteolytic activity. All truncated enzymes show unaltered proteolytic specificity toward various substrates. This suggests that the main role played by these domains is providing stability or protection from autoproteolysis (B domain), spacing away from the cell (H domain), and anchoring to the cell envelope (W and AN domains). In addition, this study allowed us to more precisely map the main C-terminal autoprocessing site of the SK11 proteinase and the epitope for binding of group IV monoclonal antibodies.     

Prophenoloxidase-activating proteinase-3 (PAP-3) from Manduca sexta hemolymph: a clip-domain serine proteinase regulated by serpin-1J and serine proteinase homologs

Phenoloxidase (PO) is a key enzyme implicated in several defense mechanisms in insects and crustaceans. It is converted from prophenoloxidase (proPO) through limited proteolysis by prophenoloxidase-activating proteinase (PAP). We previously isolated PAP-1 from integument and PAP-2 from hemolymph of the tobacco hornworm, Manduca sexta. Here, we report the purification, characterization, and regulation of PAP-3 from the hemolymph. Similar to M. sexta PAP-2, PAP-3 consists of two amino-terminal clip domains followed by a carboxyl-terminal catalytic domain, whereas PAP-1 contains only one clip domain at its amino-terminus. Purified PAP-3 cleaved proPO at Arg51 and generated a low level of PO activity. However, the enzyme efficiently activated proPO when M. sexta serine proteinase homolog-1 and -2 were present. These proteinase-like proteins associate with immulectin-2, a pattern-recognition receptor for lipopolysaccharide. M. sexta PAP-3 was inhibited by recombinant serpin-1J, which formed an SDS-stable complex with the enzyme. PAP-3 mRNA was detected at a low level in the fat body or hemocytes of naive larvae, but was elevated in insects that had been challenged with bacteria. These data, along with our previous results on PAP-1 and PAP-2, indicate that proPO activation by PAPs is a tightly regulated process. Individual PAPs could play different roles during immune responses and developmental processes.