Cloning and Molecular Modeling of Duodenase with Respect to Evolution of Substrate Specificity within Mammalian Serine Proteases That Have Lost a Conserved Active-Site Disulfide Bond

Mammalian serine proteases such as the chromosome 14 (Homo sapiens, Mus musculus) located granzymes, chymases, cathepsin G, and related enzymes including duodenase collectively represent a special group within the chymotrypsin family which we refer to here as "granases". Enzymes of this group have lost the ancient active-site disulfide bond Cys191-Cys220 (bovine chymotrypsinogen A numbering) which is strongly conserved in classic serine proteases such as pancreatic, blood coagulation, and fibrinolysis proteases and others (granzymes A, M, K and leukocyte elastases). We sequenced the cDNA encoding bovine (Bos taurus) duodenase, a granase with unusual dual trypsin-like and chymotrypsin-like specificity. The sequence revealed a 17-residue signal peptide and two-residue (GlyLys) activation peptide typical for granases. Production of the mature enzyme is apparently accompanied by further proteolytic processing of the C-terminal pentapeptide extension of duodenase. Similar C-terminal processing is known for another dual-specific granase, human cathepsin G. Using phylogenetic analysis based on 39 granases we retraced the evolution of residues 189 and 226 crucial for serine protease primary specificity. The analysis revealed that while there is no obvious link between mutability of residue 189 and the appearance of novel catalytic properties in granases, the mutability of residue 226 evidently gives rise to different specificity subgroups within this enzyme group. The architecture of the extended substrate-binding site of granases and structural basis of duodenase dual specificity based on molecular dynamic method are discussed. We conclude that the marked selectivity of granases that is crucial to their role as regulatory proteases has evolved through the fine-tuning of specificity at three levels--primary, secondary, and conformational.     

Schistosome invasion of human skin and degradation of dermal elastin are mediated by a single serine protease

Aquatic larvae (cercariae) of the trematode parasite Schistosoma mansoni rapidly penetrate human skin by degrading host proteins including elastin. Two serine proteases, one chymotrypsin-like and the second trypsin-like, have been proposed to be involved. To evaluate the relative roles of these two proteases in larval invasion, both were purified, identified by sequence, and then biochemically characterized. The trypsin-like activity was resolved into two distinct serine proteases 76% similar in predicted amino acid sequence. Southern blot analysis, genomic polymerase chain reaction, and immunolocalization demonstrated that the trypsin-like proteases are in fact not from the schistosome, but are released with larvae from the snail host Biomphalaria glabrata. Invasion inhibition assays using selective inhibitors confirmed that the chymotrypsin-like protease is the enzyme involved in skin penetration. Its ability to degrade skin elastin was confirmed, and the three sites of cleavage within elastin help define a new family of elastases.     

Partial characterization of trypsin-like protease and molecular cloning of a trypsin-like precursor cDNA in salivary glands of Lygus lineolaris

Based on substrate specificity, an alkaline pH optimum, sensitivity to selected proteinase inhibitors, and molecular analysis, we provide evidence for the presence of a trypsin-like serine proteinase in the salivary gland complex (SGC) of the tarnished plant bug, Lygus lineolaris (Palisot de Beauvois) (Heteroptera: Miridae). The predominant activity in extracts of the SGC against N(2)-benzoyl-L-arginine-p-nitroanilide (L-BApNA) was at pH 10, but a minor peak of activity also occurred at pH 5. The major BApNAase activity focused at 10.4 during preparative isoelectric focusing and was eluted with an apparent molecular weight of 23,000 from a calibrated gel filtration column. The BApNAase fraction gave a single major band when analyzed on a casein zymogram. The activity was completely suppressed by the serine protease inhibitors, phenylmethylsulfonyl fluoride (PMSF) and lima bean trypsin inhibitor. A cDNA coding for a trypsin-like protein in the salivary glands of L. lineolaris was cloned and sequenced. The 971bp cDNA contained an 873-nucleotide open reading frame encoding a 291-amino acid trypsin precursor. The encoded protein included amino acid sequence motifs that are conserved with four homologous serine proteases from other insects. Typical features of the putative trypsin-like protein from L. lineolaris included the serine protease active site (His(89), Asp(139), Ser(229)), conserved cysteine residues for disulfide bridges, the residues (Asp(223), Gly(252), Gly(262)) that determine trypsin specificity, and both zymogen signal and activation peptides. Cloning and sequencing of a trypsin-like precursor cDNA provided additional direct evidence for trypsin like enzymes in the salivary glands of L. lineolaris.     

Activity-based protein profiling reveals active serine proteases that drive malignancy of human ovarian clear cell carcinoma

Ovarian clear cell carcinoma (OCCC) is an understudied poor prognosis subtype of ovarian cancer lacking in effective targeted therapies. Efforts to define molecular drivers of OCCC malignancy may lead to new therapeutic targets and approaches. Among potential targets are secreted proteases, enzymes which in many cancers serve as key drivers of malignant progression. Here, we found that inhibitors of trypsin-like serine proteases suppressed malignant phenotypes of OCCC cell lines. To identify the proteases responsible for malignancy in OCCC, we employed activity-based protein profiling to directly analyze enzyme activity. We developed an activity-based probe featuring an arginine diphenylphosphonate warhead to detect active serine proteases of trypsin-like specificity and a biotin handle to facilitate affinity purification of labeled proteases. Using this probe, we identified active trypsin-like serine proteases within the complex proteomes secreted by OCCC cell lines, including two proteases in common, tissue plasminogen activator and urokinase-type plasminogen activator. Further interrogation of these proteases showed that both were involved in cancer cell invasion and proliferation of OCCC cells and were also detected in in vivo models of OCCC. We conclude the detection of tissue plasminogen activator and urokinase-type plasminogen activator as catalytically active proteases and significant drivers of the malignant phenotype may point to these enzymes as targets for new therapeutic strategies in OCCC. Our activity-based probe and profiling methodology will also serve as a valuable tool for detection of active trypsin-like serine proteases in models of other cancers and other diseases.     

Biochemical and molecular characterization of serine proteases from larvae of Chrysomya bezziana, the Old World Screwworm fly

The diversity of serine proteases secreted from Chrysomya bezziana larvae was investigated biochemically and by PCR and sequence analysis. Cation-exchange chromatography of purified larval serine proteases resolved four trypsin-like activities and three chymotrypsin-like activities as discerned by kinetic studies with benzoyl-Arg-p-nitroanilide and succinyl-Ala-Ala-Pro-Phe-p-nitroanilide. Amino-terminal sequencing of the three most abundant fractions gave two sequences, which were homologous to other Dipteran trypsins and chymotrypsins. Analysis of products generated by PCR of cDNA from whole larvae using specific primers based on the amino-terminal sequences and generic serine protease primers identified 22 different sequences, while phylogenetic analysis of the deduced amino acid sequences differentiated two trypsin-like and four chymotrypsin-like families. Phylogenetic comparisons with Dipteran and mammalian serine protease sequences showed that all the Chrysomya bezziana sequences clustered with Dipteran sequences. The Chrysomya bezziana chymotrypsin-like sequences segregated within a Dipteran cluster of chymotrypsin sequences, but were well dispersed amongst these sequences. The largest Chrysomya bezziana serine protease family, the trypB family, clustered tightly as a group, and was closely related to a Lucilia cuprina trypsin but distinct from Drosophila melanogaster alpha and beta trypsins. The trypB family contains ten highly homologous sequences and probably represents an example of concerted evolution of a trypsin gene in Chrysomya bezziana.     

Identification and structural analysis of four serine proteases in a monotreme, the platypus, Ornithorhynchus anatinus

To study the emergence of the major subfamilies of serine proteases during vertebrate evolution, we present here the primary structure of four serine proteases expressed in the spleen of a monotreme, the platypus, Ornithorhynchus anatinus. Partial cDNA clones for four serine proteases were isolated by a PCR-based strategy. This strategy is based on the high level of sequence identity between various members of the large gene family of trypsin-related serine proteases, over two highly conserved regions, those of the histidine and the serine of the catalytic triad. The partial cDNA clones were used to isolate full-length or almost full-length cDNA clones for three of these proteases from a platypus spleen cDNA library. By phylogenetic analysis, these three clones were identified as being the platypus homologues of human coagulation factor X, neutrophil elastase, and a protease distantly related to the T-cell granzymes. The remaining partial clone was found to represent a close homologue of human complement factor D (adipsin). The isolation of these four clones shows that several of the major subfamilies of serine proteases had evolved as separate subfamilies long before the radiation of the major mammalian lineages of today, the monotremes, the marsupials, and the placental mammals. Upon comparison of the corresponding proteases of monotremes and eutherian mammals, the coagulation and complement proteases were shown to display a higher degree of conservation compared to the hematopoietic proteases N-elastase and the T-cell granzymes. This latter finding indicates a higher evolutionary pressure to maintain specific functions in the complement and coagulation enzymes compared to many of the hematopoietic serine proteases.     

Cloning and characterization of trypsin- and chymotrypsin-like proteases from the midgut of the sand fly vector Phlebotomus papatasi

Trypsin and chymotrypsin serine proteases are the main digestive proteases in Diptera midguts and are also involved in many aspects of the vector-parasite relationship. In sand flies, these proteases have been shown to be a potential barrier to Leishmania growth and development within the midgut. Here we describe the sequence and partial characterization of six Phlebotomus papatasi midgut serine proteases: two chymotrypsin-like (Ppchym1 and Ppchym2) and four trypsin-like (Pptryp1-Pptryp4). All six enzymes show structural features typical to each type, including the histidine, aspartic acid, and serine (H/D/S) catalytic triad, six conserved cysteine residues, and other amino acid residues involved in substrate specificity. They also show a high degree of homology (40-60% identical residues) with their counterparts from other insect vectors, such as Anopheles gambiae and Aedes aegypti. The mRNA expression profiles of these six proteases vary considerably: two trypsin-like proteases (Pptryp1 and Pptryp2) are downregulated and one (Pptryp4) upregulated upon blood feeding. The two chymotrypsin-like enzymes display expression behavior similar to that of the early and late trypsins from Ae. aegypti.     

Rat mast cell protease 4 is a beta-chymase with unusually stringent substrate recognition profile

Activated mast cells release a variety of potent inflammatory mediators including histamine, cytokines, proteoglycans, and serine proteases. The serine proteases belong to either the chymase (chymotrypsin-like substrate specificity) or tryptase (trypsin-like specificity) family. In this report we have investigated the substrate specificity of a recently identified mast cell protease, rat mast cell protease-4 (rMCP-4). Based on structural homology, rMCP-4 is predicted to belong to the chymase family, although rMCP-4 has previously not been characterized at the protein level. rMCP-4 was expressed with an N-terminal His tag followed by an enterokinase site substituting for the native activation peptide. The enterokinase-cleaved fusion protein was labeled by diisopropyl fluorophosphate, demonstrating that it is an active serine protease. Moreover, rMCP-4 hydrolyzed MeO-Suc-Arg-Ala-Tyr-pNA, thus verifying that this protease belongs to the chymase family. rMCP-4 bound to heparin, and the enzymatic activity toward MeO-Suc-Arg-Ala-Tyr-pNA was strongly enhanced in the presence of heparin. Detailed analysis of the substrate specificity was performed using peptide phage display technique. After six rounds of amplification a consensus sequence, Leu-Val-Trp-Phe-Arg-Gly, was obtained. The corresponding peptide was synthesized, and rMCP-4 was shown to cleave only the Phe-Arg bond in this peptide. This demonstrates that rMCP-4 displays a striking preference for bulky/aromatic amino acid residues in both the P1 and P2 positions.     

Graspases--a special group of serine proteases of the chymotrypsin family that has lost a conserved active site disulfide bond

In this report we propose a new approach to classification of serine proteases of the chymotrypsin family. Comparative structure–function analysis has revealed two main groups of proteases: a group of trypsin-like enzymes and graspases (granule-associated proteases). The most important structural peculiarity of graspases is the absence of conservative active site disulfide bond Cys191–Cys220. The residue at position 226 in the S1-subsite of graspases is responsible for substrate specificity, whereas the residue crucial for specificity in classical serine proteases is located at position 189. We distinguish three types of graspases on the base of their substrate specificity: 1) chymozymes prefer uncharged substrates and contain an uncharged residue at position 226; 2) duozymes possess dual trypsin-like and chymotrypsin-like specificity and contain Asp or Glu at 226; 3) aspartases hydrolyze Asp-containing substrates and contain Arg residue at 226. The correctness of the proposed classification was confirmed by phylogenic analysis.     

Molecular cloning of cDNA for matriptase, a matrix-degrading serine protease with trypsin-like activity.

A major protease from human breast cancer cells was previously detected by gelatin zymography and proposed to play a role in breast cancer invasion and metastasis. To structurally characterize the enzyme, we isolated a cDNA encoding the protease. Analysis of the cDNA reveals three sequence motifs: a carboxyl-terminal region with similarity to the trypsin-like serine proteases, four tandem cysteine-rich repeats homologous to the low density lipoprotein receptor, and two copies of tandem repeats originally found in the complement subcomponents C1r and C1s. By comparison with other serine proteases, the active-site triad was identified as His-484, Asp-539, and Ser-633. The protease contains a characteristic Arg-Val-Val-Gly-Gly motif that may serve as a proteolytic activation site. The bottom of the substrate specificity pocket was identified to be Asp-627 by comparison with other trypsin-like serine proteases. In addition, this protease exhibits trypsin-like activity as defined by cleavage of synthetic substrates with Arg or Lys as the P1 site. Thus, the protease is a mosaic protein with broad spectrum cleavage activity and two potential regulatory modules. Given its ability to degrade extracellular matrix and its trypsin-like activity, the name matriptase is proposed for the protease.     

Functional and Structural Characterization of Vibrio cholerae Extracellular Serine Protease B,VesB

The chymotrypsin subfamily A of serine proteases consists primarily of eukaryotic proteases, including only a few proteases of bacterial origin. VesB, a newly identified serine protease that is secreted by the type II secretion system in Vibrio cholerae, belongs to this subfamily. VesB is likely produced as a zymogen because sequence alignment with trypsinogen identified a putative cleavage site for activation and a catalytic triad, His-Asp-Ser. Using synthetic peptides, VesB efficiently cleaved a trypsin substrate, but not chymotrypsin and elastase substrates. The reversible serine protease inhibitor, benzamidine, inhibited VesB and served as an immobilized ligand for VesB affinity purification, further indicating its relationship with trypsin-like enzymes. Consistent with this family of serine proteases, N-terminal sequencing implied that the propeptide is removed in the secreted form of VesB. Separate mutagenesis of the activation site and catalytic serine rendered VesB inactive, confirming the importance of these features for activity, but not for secretion. Similar to trypsin but, in contrast to thrombin and other coagulation factors, Na⁺ did not stimulate the activity of VesB, despite containing the Tyr²⁵⁰ signature. The crystal structure of catalytically inactive pro-VesB revealed that the protease domain is structurally similar to trypsinogen. The C-terminal domain of VesB was found to adopt an immunoglobulin (Ig)-fold that is structurally homologous to Ig-folds of other extracellular Vibrio proteins. Possible roles of the Ig-fold domain in stability, substrate specificity, cell surface association, and type II secretion of VesB, the first bacterial multidomain trypsin-like protease with known structure, are discussed.     

Molecular cloning of dog mast cell tryptase and a related protease: structural evidence of a unique mode of serine protease activation

Mast cell tryptase is a secretory granule associated serine protease with trypsin-like specificity released extracellularly during mast cell degranulation. To determine the full primary structure of the catalytic domain and precursor forms of tryptase and to gain insight into its mode of activation, we cloned cDNAs coding for the complete amino acid sequence of dog mast cell tryptase and a second, possibly related, serine protease. Using RNA from dog mastocytoma cells, we constructed a cDNA library in lambda gt 10. Screening of the library with an oligonucleotide probe based on the N-terminal sequence of tryptase purified from the same cell source allowed us to isolate and sequence overlapping clones coding for dog mast cell tryptase. The tryptase sequence includes the essential residues of the catalytic triad and an aspartic acid at the base of the putative substrate binding pocket that confers P1 Arg and Lys specificity on tryptic serine proteases. The apparent N-terminal signal/activation peptide terminates in a glycine. A glycine in this position has not been observed previously in serine proteases and suggests a novel mode of activation. Additional screening of the library with a trypsinogen cDNA led to the isolation and sequencing of a full-length clone apparently coding for the complete sequence of a second tryptic serine protease (DMP) which is only 53.4% identical with the dog tryptase sequence but which contains an apparent signal/activation peptide also terminating in a glycine. Thus, the proteases encoded by these cloned cDNAs may share a common mode of activation from N-terminally extended precursors.     

Evidence for the Existence of Granzyme-Like Serine Proteases in Teleost Cytotoxic Cells

Granzymes are granule-associated serine proteases, which are important effector molecules in NK cell and CTL functions. The granzyme family poses a perplexing problem in phylogenetics due to the lack of nonmammalian sequence information. We now report the identification of a cDNA that codes for a granzyme homologue, channel catfish granzyme-1 (CFGR-1), from nonspecific cytotoxic cells (NCC) of a teleost. NCC are the first identified and extensively studied cytotoxic cell population in teleosts. Ictalurus punctatus (channel catfish) granzyme cDNA encodes a protein with ~50% similarity to granzymes A and K. Highly conserved catalytic triad residues of serine proteases and other motifs common to granzymes were also identified. Conserved amino acid sequences, structure–function data available for the serine protease family, and the crystal structure of human granzyme K supported a model of CFGR-1. It suggested an Arg/Lys primary substrate specificity that is shared with granzymes A and K. Furthermore, CFGR-1 has the four conserved disulfide bonds of granzymes A, K, and M. Phylogenetic analysis suggested that this molecule is a member of the granzyme family. Expression of CFGR-1 in NCC was confirmed by RT-PCR analysis. Presence of a granzyme-like molecule that might play an important role in the effector functions of NCC indicates that cell-mediated immunity with granule exocytosis and Fas pathways have been conserved for more than 300 million years.     

Analysis and prediction of functional sub-types from protein sequence alignments

The increasing number and diversity of protein sequence families requires new methods to define and predict details regarding function. Here, we present a method for analysis and prediction of functional sub-types from multiple protein sequence alignments. Given an alignment and set of proteins grouped into sub-types according to some definition of function, such as enzymatic specificity, the method identifies positions that are indicative of functional differences by comparison of sub-type specific sequence profiles, and analysis of positional entropy in the alignment. Alignment positions with significantly high positional relative entropy correlate with those known to be involved in defining sub-types for nucleotidyl cyclases, protein kinases, lactate/malate dehydrogenases and trypsin-like serine proteases. We highlight new positions for these proteins that suggest additional experiments to elucidate the basis of specificity. The method is also able to predict sub-type for unclassified sequences. We assess several variations on a prediction method, and compare them to simple sequence comparisons. For assessment, we remove close homologues to the sequence for which a prediction is to be made (by a sequence identity above a threshold). This simulates situations where a protein is known to belong to a protein family, but is not a close relative of another protein of known sub-type. Considering the four families above, and a sequence identity threshold of 30 %, our best method gives an accuracy of 96 % compared to 80 % obtained for sequence similarity and 74 % for BLAST. We describe the derivation of a set of sub-type groupings derived from an automated parsing of alignments from PFAM and the SWISSPROT database, and use this to perform a large-scale assessment. The best method gives an average accuracy of 94 % compared to 68 % for sequence similarity and 79 % for BLAST. We discuss implications for experimental design, genome annotation and the prediction of protein function and protein intra-residue distances.     

7S Nerve growth factor alpha and gamma subunits are closely related proteins

The polypeptide composition and partial amino acid sequence of the 7S nerve growth factor (NGF) alpha subunit have been determined. Residues in 76 unique positions corresponding to 35% of the molecule were identified. The sequence shows that the NGF alpha subunit is closely related to the NGF gamma subunit and thus a member of the same protein family as the serine proteases. This finding is unexpected since the NGF alpha subunit is devoid of detectable protease activity. However, the NGF alpha subunit differs in one important respect from the NGF gamma subunit and related serine proteases. The highly conserved amino-terminal activation cleavage structure, common to most serine proteases, has been deleted, and an uncleaved activation peptide remains attached to the amino terminus of the mature NGF alpha subunit. It is suggested that this feature is causally related to the apparent lack of proteolytic activity.     

Conservation of intramembrane proteolytic activity and substrate specificity in prokaryotic and eukaryotic rhomboids

Rhomboid is an intramembrane serine protease responsible for the proteolytic activation of Drosophila epidermal growth factor receptor (EGFR) ligands. Although nothing is known about the function of the approximately 100 currently known rhomboid genes conserved throughout evolution, a recent analysis suggests that a Rhomboid from the pathogenic bacterium Providencia stuartii is involved in the production of a quorum-sensing factor. This suggests that an intercellular signaling mechanism may have been conserved between prokaryotes and metazoans. However, the function of prokaryotic Rhomboids is unknown. We have examined the ability of eight prokaryotic Rhomboids to cleave the three Drosophila EGFR ligands. Despite their striking sequence divergence, Rhomboids from one Gram-positive and four Gram-negative species, including Providencia, specifically cleaved Drosophila substrates, but not similar proteins such as Transforming Growth Factor alpha (TGFalpha) and Delta. Although the sequence similarity between these divergent Rhomboids is very limited, all contain the putative serine catalytic triad residues, and their specific mutation abolished protease activity. Therefore, despite low overall homology, the Rhomboids are a family of ancient, functionally conserved intramembrane serine proteases, some of which also have conserved substrate specificity. Moreover, a function for Rhomboids in activating intercellular signaling appears to have evolved early.     

Two new extracellular serine proteases from Streptomyces fradiae.

1. Two new extracellular serine proteases have been purified to homogeneity from Streptomyces fradiae. 2. On amino acid sequencing, striking homology is observed between the first enzyme and Streptomyces griseus Protease A, and the second enzyme and S. griseus trypsin. 3. The sequence information shows for the first time that structurally and enzymatically related serine proteases are extracellularly expressed by different Streptomycetes. 4. Differential keratinolytic substrate specificity among these two microbes are probable due to a difference in disulfide reduction capacity.     

Cysteine proteases of positive strand RNA viruses and chymotrypsin-like serine proteases. A distinct protein superfamily with a common structural fold

Evidence is presented, based on sequence comparison and secondary structure prediction, of structural and evolutionary relationship between chymotrypsin-like serine proteases, cysteine proteases of positive strand RNA viruses (3C proteases of picornaviruses and related enzymes of como-, nepo- and potyviruses) and putative serine protease of a sobemovirus. These observations lead to re-identification of principal catalytic residues of viral proteases. Instead of the pair of Cys and His, both located in the C-terminal part of 3C proteases, a triad of conserved His, Asp(Glu) and Cys(Ser) has been identified, the first two residues resident in the N-terminal, and Cys in the C-terminal beta-barrel domain. These residues are suggested to form a charge-transfer system similar to that formed by the catalytic triad of chymotrypsin-like proteases. Based on the structural analogy with chymotrypsin-like proteases, the His residue previously implicated in catalysis, together with two partially conserved Gly residues, is predicted to constitute part of the substrate-binding pocket of 3C proteases. A partially conserved ThrLys/Arg dipeptide located in the loop preceding the catalytic Cys is suggested to confer the primary cleavage specificity of 3C toward Glx/Gly(Ser) sites. These observations provide the first example of relatedness between proteases belonging, by definition, to different classes.     

Characterization of the molecular features and expression patterns of two serine proteases in Hermetia illucens (Diptera: Stratiomyidae) larvae

To investigate the molecular scavenging capabilities of the larvae of Hermetia illucens, two serine proteases (SPs) were cloned and characterized. Multiple sequence alignments and phylogenetic tree analysis of the deduced amino acid sequences of Hi-SP1 and Hi-SP2 were suggested that Hi-SP1 may be a chymotrypsin- and Hi-SP2 may be a trypsin-like protease. Hi-SP1 and Hi-SP2 3-D homology models revealed that a catalytic triad, three disulfide bonds, and a substrate-binding pocket were highly conserved, as would be expected of a SP. E. coli expressed Hi-SP1 and Hi-SP2 showed chymotrypsin or trypsin activities, respectively. Hi-SP2 mRNAs were consistently expressed during larval development. In contrast, the expression of Hi-SP1 mRNA fluctuated between feeding and molting stages and disappeared at the pupal stages. These expression pattern differences suggest that Hi-SP1 may be a larval specific chymotrypsin-like protease involved with food digestion, while Hi-SP2 may be a trypsin-like protease with diverse functions at different stages.