Catalytic Triad Of Serine Proteases Research Articles

Charge Relay Without Proton Transfer: Coupling of Two Short Hydrogen Bonds via Imidazole in Models of Catalytic Triad of Serine Protease Active Site.

A homologous series of 20 substituted alcohol-imidazole-acetate model complexes imitating the charge relay system in Ser-His-Asp catalytic triad of serine proteases is considered quantum-chemically. We show qualitatively that the geometries of alcohol-imidazole and imidazole-acetate short hydrogen bonds are strongly coupled via the central imidazole and such complexes are capable of effectively relaying the charge from acetate to alcohol moiety upon relatively small concerted proton displacements. We hypothesize an alternative catalytic mechanism of serine proteases that does not require two complete proton transfers or hydrogen bond breakage between Ser and His residues.

PH-Dependent proteolytic activity of histidine-pendant polyacrylamides

Artificial enzymes with serine, aspartic acid, and histidine that mimic the catalytic triad of serine proteases have been studied. However, they were mainly investigated for their cleavage activity on low molecular-weight esters and amides, and there has been a lack of knowledge about their protein cleavage activity. We previously found that not only ternary polyacrylamides with serine, aspartic acid, and histidine but also homo-polyacrylamides with a single type of amino acid cleaved bovine and human serum albumins. These results suggested that the carboxy group, a common functional group in active polymers, may be involved in the expression of activity. In this study, we synthesized histidine polymers in which the carboxy group was changed to a carboxamido or amino group and investigated the relationships between structure and activity. Histidine homopolymers and histidine-acrylamide copolymers were incubated with bovine serum albumin at 37 °C for one week under different pH conditions and then analyzed by sodium dodecyl-sulfate polyacrylamide gel electrophoresis. In the case of histidine homopolymers, the carboxy-type homopolymers were active under weakly acidic to neutral conditions, while the carboxamido- and amino-type homopolymers were not active regardless of liquid properties. In the case of histidine-acrylamide copolymers, their activity was essentially the same as that of each type of histidine homopolymer, but for all types of copolymers, activity appeared under weakly basic conditions when the histidine monomer units were of a specific density. The carboxy-type copolymers with dual-mode activity showed different degradation patterns of bovine serum albumin under acidic and basic conditions. The structural features common to the active homopolymers and copolymers suggested that the carboxy group contributes to the activity under weakly acidic to neutral conditions, while the imidazole group of the histidine side chain and its density contribute to the activity under weakly basic conditions.

Immune recognition of the secreted serine protease ChpG restricts the host range of Clavibacter michiganensis from eggplant varieties.

Bacterial wilt and canker caused by Clavibacter michiganensis (Cm) inflict considerable damage in tomato‐growing regions around the world. Cm has a narrow host range and can cause disease in tomato but not in many eggplant varieties. The pathogenicity of Cm is dependent on secreted serine proteases, encoded by the chp/tomA pathogenicity island (PI), and the pCM2 plasmid. Screening combinations of PI deletion mutants and plasmid‐cured strains found that Cm‐mediated hypersensitive response (HR) in the Cm‐resistant eggplant variety Black Queen is dependent on the chp/tomA PI. Singular reintroduction of PI‐encoded serine proteases into Cm∆PI identified that the HR is elicited by the protease ChpG. Eggplant leaves infiltrated with a chpG marker exchange mutant (CmΩchpG) did not display an HR, and infiltration of purified ChpG protein elicited immune responses in eggplant but not in Cm‐susceptible tomato. Virulence assays found that while wild‐type Cm and the CmΩchpG complemented strain were nonpathogenic on eggplant, CmΩchpG caused wilt and canker symptoms. Additionally, bacterial populations in CmΩchpG‐inoculated eggplant stem tissues were c.1000‐fold higher than wild‐type and CmΩchpG‐complemented Cm strains. Pathogenicity tests conducted in multiple Cm‐resistance eggplant varieties demonstrated that immunity to Cm is dependent on ChpG in all tested varieties, indicating that ChpG‐recognition is conserved in eggplant. ChpG‐mediated avirulence interactions were disabled by alanine substitution of serine231 of the serine protease catalytic triad, suggesting that protease activity is required for immune recognition of ChpG. Our study identified ChpG as a novel avirulence protein that is recognized in resistant eggplant varieties and restricts the host range of Cm.

The role of hydrogen bond in catalytic triad of serine proteases

In order to investigate the origin of catalytic power for serine proteases, the role of the hydrogen bond in the catalytic triad was studied in the proteolysis process of the peptides chymotrypsin inhibitor 2 (CI2), MCTI-A, and a hexapeptide (SUB), respectively. We first calculated the free energy profile of the proton transfer between His and Asp residues of the catalytic triad in the enzyme-substrate state and transition state by employing QM/MM molecular dynamics simulations. The results show that a low-barrier hydrogen bond (LBHB) only forms in the transition state of the acylation of CI2, while it is a normal hydrogen bond in the acylation of MCTI-A or SUB. In addition, the change of the hydrogen bond strength is much larger in CI2 and SUB systems than in MCTI-A system, which decreases the acylation energy barrier significantly for CI2 and SUB. Clearly, a LBHB formed in the transition state region helps accelerate the acylation reaction. But to our surprise, a normal hydrogen bond can also help to decrease the energy barrier. The key to reducing the reaction barrier is the increment of hydrogen bond strength in the transition state state, whether it is a LBHB or not. Our studies cast new light on the role of the hydrogen bond in the catalytic triad, and help to understand the catalytic triad of serine proteases.

Diverse conserved domains and a positively selected site in the sugarcane streak mosaic virus P1 protein are essential for RNA silencing suppression and protein stability

AbstractRNA silencing is one of the conserved antiviral mechanisms in plants, and viruses encode RNA silencing suppressors (RSS) to overcome host RNA silencing and facilitate virus infection. Sugarcane streak mosaic virus (SCSMV; species Sugarcane streak mosaic virus, genus Poacevirus, family Potyviridae) is a major causal agent of sugarcane mosaic disease in many countries in Asia, including China. In this study, we used Agrobacterium co‐infiltration to show that the SCSMV P1 protein, rather than the helper component‐proteinase (HC‐Pro), functions as a strong RSS to suppress local RNA silencing in Nicotiana benthamiana. Mutational analysis indicated that the 15 amino acids (aa; aa 1–15) of the SCSMV P1 N‐terminus were not important for RNA silencing suppression, but rather another 15 aa domain (aa 108–122) containing a conserved motif (LFR/KNKQAYIST) was essential for efficient silencing suppression by P1. In addition to the 15 aa (aa 344–358) domain in the P1 N‐terminus, another 15 aa domain (aa 65–79) of P1, containing the LXKA motif and one conserved aa (D78), were associated with P1 protein stability. Furthermore, substituting the histidine (H263) residue in P1 with threonine (H263T) or alanine (H263A) also affected P1 protein stability. Notably, the H263 residue is both a positively selected site and part of the serine protease catalytic triad (HDS). Taken together, our data demonstrate that SCSMV P1, and not HC‐Pro, plays a functional role in suppressing RNA silencing, and also show that some conserved motifs and a positivelyselected site in the P1 protein are associated with RSS activity and protein stability.

Probing contacts of inhibitor locked in transition states in the catalytic triad of DENV2 type serine protease and its mutants by 1H, 19F and 15\u2009N NMR spectroscopy

BackgroundDetailed structural knowledge of enzyme-inhibitor complexes trapped in intermediate state is the key for a fundamental understanding of reaction mechanisms taking place in enzymes and is indispensable as a structure-guided drug design tool. Solution state NMR uniquely allows the study of active sites of enzymes in equilibrium between different tautomeric forms. In this study 1H, 19F and 15 N NMR spectroscopy has been used to probe the interaction contacts of inhibitors locked in transition states of the catalytic triad of a serine protease. It was demonstrated on the serotype II Dengue virus NS2B:NS3pro serine protease and its mutants, H51N and S135A, in complex with high-affinity ligands containing trifluoromethyl ketone (tfk) and boronic groups in the C-terminal of tetra-peptides.ResultsMonitoring 19F resonances, shows that only one of the two isomers of the tfk tetra-peptide binds with NS2B:NS3pro and that access to the bulk of the active site is limited. Moreover, there were no bound water found in proximity of the active site for any of the ligands manifesting in a favorable condition for formation of low barrier hydrogen bonds (LBHB) in the catalytic triad. Based on this data we were able to identify a locked conformation of the protein active site. The data also indicates that the different parts of the binding site most likely act independently of each other.ConclusionsOur reported findings increases the knowledge of the detailed function of the catalytic triad in serine proteases and could facilitate the development of rational structure based inhibitors that can selectively target the NS3 protease of Dengue type II (DENV2) virus. In addition the results shows the usefulness of probing active sites using 19F NMR spectroscopy.

Identification and characterization of the gene encoding an extracellular protease from haloarchaeon Halococcus salifodinae

Extracellular proteases from haloarchaea (halolysins) can resist high salt conditions. In this study, the gene encoding a halolysin from Halococcus salifodinae was identified. The hlyA gene encoded an active halolysin with the classical Asp-His-Ser catalytic triad of serine proteases. Site-directed mutagenesis showed that the three cysteine residues in the catalytic domain were important for the extracellular proteolytic activity and displayed an additive effect on the activity. Truncation mutants of the C-terminal extension (CTE) domain displayed very low or almost no extracellular protease activity towards milk and small peptide substrates, indicating its importance for the function of HlyA. CTE can be functionally interchangeable among halolysins. Additionally, the HlyA expressing strain as a starter culture for fish sauce fermentation significantly increased the peptide release and total free amino acid content in fish sauce. This study enriches our knowledge of the key amino acid residues and domains of halolysins, and provides an opportunity for applications of halolysins in fish sauce fermentation.

Direct NMR Observation and pKaDetermination of the Asp102Side Chain in a Serine Protease

The pK(a) value of aspartic acid in the catalytic triad of serine proteases has been a pivotal element in essentially every mechanism proposed for these enzymes over the past 40 years, but has, until now, eluded direct determination. Here, we have used the multinuclear 3D-NMR pulse programs HCACO and HCCH-TOCSY to directly identify and study the side-chain resonances of the aspartate and glutamate residues in uniformly (13)C-labeled α-lytic protease. Resonances from four of the six residues were detected and assigned, including that of Asp(102), which is notably the weakest of the four. pH titrations have shown all of the carboxylate (13)C signals to have unusually low pK(a) values: 2.0, 3.2, and 1.7 for Glu(129), Glu(174), and Glu(229), respectively, and an upper limit of 1.5 for Asp(102). The multiple H-bonds to Asp(102), long known from X-ray crystal studies, probably account for its unusually low pK(a) value through preferential stabilization of its anionic form. These H-bonds probably also contribute to the weakness of the NMR resonances of Asp(102) by restricting its mobility. The Asp(102)(13)C(γ) atom responds to the ionization of His(57) in the resting enzyme and to the inhibitor-derived oxyanion in a chloromethyl ketone complex, observations that strongly support the assignment. The low pK(a) value of Asp(102) would appear to be incompatible with mechanisms involving strong Asp(102)-His(57) H-bonds or high pK(a) values, but is compatible with mechanisms involving normal Asp(102)-His(57) H-bonds and moving His(57) imidazole rings, such as the reaction-driven ring flip.

Evolutionary Analysis of Novel Serine Proteases in the Venom Gland Transcriptome of Bitis gabonica rhinoceros

BackgroundSerine proteases are major components of viper venom and target various stages of the blood coagulation system in victims and prey. A better understanding of the diversity of serine proteases and other enzymes present in snake venom will help to understand how the complexity of snake venom has evolved and will aid the development of novel therapeutics for treating snake bites.Methodology and Principal FindingsFour serine protease-encoding genes from the venom gland transcriptome of Bitis gabonica rhinoceros were amplified and sequenced. Mass spectrometry suggests the four enzymes corresponding to these genes are present in the venom of B. g. rhinoceros. Two of the enzymes, rhinocerases 2 and 3 have substitutions to two of the serine protease catalytic triad residues and are thus unlikely to be catalytically active, though they may have evolved other toxic functions. The other two enzymes, rhinocerases 4 and 5, have classical serine protease catalytic triad residues and thus are likely to be catalytically active, however they have glycine rather than the more typical aspartic acid at the base of the primary specificity pocket (position 189). Based on a detailed analysis of these sequences we suggest that alternative splicing together with individual amino acid mutations may have been involved in their evolution. Changes within amino acid segments which were previously proposed to undergo accelerated change in venom serine proteases have also been observed.Conclusions and SignificanceOur study provides further insight into the diversity of serine protease isoforms present within snake venom and discusses their possible functions and how they may have evolved. These multiple serine protease isoforms with different substrate specificities may enhance the envenomation effects and help the snake to adapt to new habitats and diets. Our findings have potential for helping the future development of improved therapeutics for snake bites.

Mechanistic role of NS4A and substrate in the activation of HCV NS3 protease

Hepatitis C virus (HCV) NS3 protease is the key enzyme for its maturation. Three hypotheses have been advanced in the literature to demonstrate the mechanism of the activation of the HCV NS3 protease. A virus-encoded protein NS4A and substrate are proposed to be involved in the activation of the HCV NS3 protease. However, the three hypotheses are not completely consistent with one another. Multiple molecular dynamics simulations were performed on various NS3 protease systems: free NS3 protease, NS3/4A, NS3/inhibitor, and NS3/4A/inhibitor complexes, to further unravel the mechanism of the activation of the NS3 protease. Simulation results suggest that the binding of NS4A induces a classic serine protease conformation of the catalytic triad of the NS3 protease. NS4A rearranges the secondary structure of both the N-terminus and catalytic site of the NS3 protease, reduces the mobility of the global structure of the NS3 protease, especially the catalytic site, and provides a rigid and tight structure, except for the S1 pocket, for the binding and hydrolysis of substrates. The binding of substrate also contributes to the activation of the NS3 protease by an induced-fit of the classic serine protease catalytic triad. However, the global structure of the NS3 protease is still loose and highly flexible without stable secondary structural elements, such as helix α0 at the N-terminus and helix α1 and β-sheet E1-F1 at the catalytic site. The structure of the NS3 protease without NS4A is not suitable for the binding and hydrolysis of substrates.

Exclusive expression of a membrane-bound Spink3-interacting serine protease-like protein TESPL in mouse testis

We identified a testis-specific protease-like protein tentatively named TESPL and a pancreatic trypsinogen Prss2 from the clones of a yeast two-hybrid screen against a mouse testicular cDNA library using the trypsin inhibitor Spink3 from male accessory sexual glands as bait. The enzymatic motifs and the cysteine patterns in serine proteases are highly conserved in these two proteins. Based on the phylogenetic analysis, Prss2 duplicated recently and TESPL underwent distant evolution without gene duplication from the progenitor of trypsin-like and chymotrypsin-like proteases. We found that TESPL transcription was restricted to the testis and that the level of transcription was positively correlated with animal maturation. In contrast, Prss2 was constitutively expressed in many tissues including testis. Alignment of the cDNA-deduced sequences of serine proteases showed the replacement of an essential serine residue in the catalytic triad of serine proteases by a proline residue in TESPL, which was demonstrated to be a membrane-bound protein devoid of proteolytic activity. The immunohistochemical staining patterns of seminiferous tubules in the testis revealed TESPL mainly on postmeiotic cells such as spermatids and spermatozoa. On the mouse sperm from caudal epididymis, TESPL was localized mainly on the plasma membrane overlaying the acrosomal region. Further, orthology group for mouse TESPL was identified in the conserved gene family of eutherian testis serine protease 5.

Structural Insight into the Activation Mechanism of Human Pancreatic Prophospholipase A2

Pancreatic phospholipase A2 (phospholipase A2 group 1B, G1B) belongs to the superfamily of secreted phospholipase A2 (PLA2) enzymes. G1B has been proposed to be a potential target for diseases such as hypertension, obesity, and diabetes. Human pancreatic prophospholipase A2 (pro-hG1B) is activated by cleavage of the first seven-residue propeptide (phospholipase A2 propeptide, PROP). However, questions still remain on the mode of action for pro-hG1B. In this work, we expressed pro-hG1B in Pichia pastoris and determined the crystal structure at 1.55-A resolution. The x-ray structure demonstrates that pro-hG1B forms a trimer. In addition, PROP occupies the catalytic cavity and can be self-cleaved at 37 degrees C. A new membrane-bound surface and activation mechanism are proposed based on the trimeric model of pro-hG1B. We also propose a new autoproteolytic mechanism for pro-hG1B by the reaction triad Asp49-Arg0-Ser(-2) that is similar to the serine protease catalytic triad.

Theoretical studies of the proton transfer behaviors in molecular complexes analogous to catalytic triad of serine protease: Toward understanding the existence and significance of the low-barrier hydrogen-bond in enzymatic catalysis

A representative acetate-(5-methylimidazole)-methanol system has been employed as a model of catalytic triad in serine protease to validate the formation processes of low-barrier H-bonds (LBHB) at the B3LYP/6-311++G** level of theory, and variable H-bonding characters from conventional ones to LBHBs have been represented along with the proceedings of proton transfer. Solvent effect is an important factor in modulation of the existence of an LBHB, where an LBHB (or a conventional H-bond) in the gas phase can be changed into a non-LBHB (an LBHB) upon solvation. The origin of the additional stabilization energy arising from the LBHB may be attributed to the H-bonding energy difference before and after proton transfer because the shared proton can freely move between the proton donor and proton acceptor. Most importantly, the order of magnitude of the stabilization energy depends on the studied systems. Furthermore, the nonexistence of LBHBs in the catalytic triad of serine proteases has been verified in a more sophisticated model treated using the ONIOM method. As a result, only the single proton transfer mechanism in the catalytic triad has been confirmed and the origin of the powerful catalytic efficiency of serine proteases should be attributed to other factors rather than the LBHB.

Streptococcus agalactiae CspA Is a Serine Protease That Inactivates Chemokines

Streptococcus agalactiae (group B Streptococcus [GBS]) remains a leading cause of invasive infections in neonates and has emerged as a pathogen of the immunocompromised and elderly populations. The virulence mechanisms of GBS are relatively understudied and are still poorly understood. Previous evidence indicated that the GBS cspA gene is necessary for full virulence and the cleavage of fibrinogen. The predicted cspA product displays homology to members of the extracellular cell envelope protease family. CXC chemokines, many of which can recruit neutrophils to sites of infection, are important signaling peptides of the immune system. In this study, we purified CspA and demonstrated that it readily cleaved the CXC chemokines GRO-alpha, GRO-beta, GRO-gamma, neutrophil-activating peptide 2 (NAP-2), and granulocyte chemotactic protein 2 (GCP-2) but did not cleave interleukin-8. CspA did not cleave a panel of other test substrates, suggesting that it possesses a certain degree of specificity. CXC chemokines also underwent cleavage by whole GBS cells in a cspA-dependent manner. CspA abolished the abilities of three representative CXC chemokines, GRO-gamma, NAP-2, and GCP-2, to attract and activate neutrophils. Genetic and biochemical evidence indicated that CspA is a serine protease with S575 at its active site. D180 was also implicated as part of the signature serine protease catalytic triad, and both S575 and D180 were required for both N-terminal and C-terminal autocatalytic processing of CspA.

Reinvestigation of a Selenopeptide with Purportedly High Glutathione Peroxidase Activity

A 15-amino acid long selenopeptide (15SeP) was recently reported to possess nearly the same catalytic activity as glutathione peroxidase (Gpx) for the reduction of hydrogen peroxide by glutathione (Sun, Y., Li, T. Y., Chen, H., Zhang, K., Zheng, K. Y., Mu, Y., Yan, G. L., Li, W., Shen, J. C., and Luo, G. M. (2004) J. Biol. Chem. 279, 37235-37240). Such a finding is startling considering the high efficiency of the natural enzyme and the modest catalytic properties of most short peptides. As 15SeP had been subjected only to limited chemical characterization, we prepared it by a new route involving selenocysteine-mediated native chemical ligation. High resolution matrix-assisted laser desorption ionization mass spectrometry confirmed the identity of the reaction product, whereas circular dichroism spectroscopy showed that 15SeP assumes a random coil conformation in solution. Although low levels of peroxidase activity were detectable under standard assay conditions, the peptide is >5 orders of magnitude less active than native Gpx. Our observations are incompatible with claims ascribing remarkable catalytic properties to 15SeP and suggest that the efficiency of Gpx derives from its well defined three-dimensional structure.

The Burkholderia pseudomallei serine protease MprA is autoproteolytically activated to produce a highly stable enzyme

Burkholderia pseudomallei, a tropical pathogen and the causative agent of melioidosis, is known to secrete a serine metalloprotease (MprA) into the internal milieu of the infectious host. This protein has been shown to cause extensive damage to mammalian physiological proteins and its role in the pathogenesis of melioidosis is still under investigation. Previously, we have reported on the epitope mapping of B. pseudomallei protease that revealed a consensus peptide sequence of serine–methionine–alanine (SMA). The serine within this motif is involved in the serine protease catalytic triad and the SMA domain of the B. pseudomallei serine protease could be a major immunodominant domain. We undertook to further characterize the mprA gene and protein to gain deeper insight into the role and mechanism of this protein. Preliminary analysis showed that the crude lysate of expressed recombinant protease was able to hydrolyze gelatin, azocasein and skimmed milk. Further biochemical characterization demonstrated that the expressed protein maintained good proteolytic activity over a wide pH range of 5–11, is stable from 4 °C up to 68 °C and partially digested immunoglobulins A and G, transferrin and myosin. The proteolytic activity was strongly inhibited by phenylmethylsulfonyl fluoride. From our in vitro experimental evidence, we propose a proenzyme processing mechanism similar to that of subtilisin to produce the mature active protease.

Genetic characterization and expression of the novel fungal protease, EPg222 active in dry-cured meat products

EPg222 protease is a novel extracellular enzyme produced by Penicillium chrysogenum (Pg222) isolated from dry-cured hams that has the potential for use over a broad range of applications in industries that produce dry-cured meat products. The gene encoding EPg222 protease has been identified. Peptide sequences of EPg222 were obtained by de novo sequencing of tryptic peptides using mass spectrometry. The corresponding gene was amplified by PCR using degenerated primers based on a combination of conserved serine protease-encoding sequences and reverse translation of the peptide sequences. EPg222 is encoded as a gene of 1,361 bp interrupted by two introns. The deduced amino acid sequence indicated that the enzyme is synthesized as a preproenzyme with a putative signal sequence of 19 amino acids (aa), a prosequence of 96 aa and a mature protein of 283 aa. A cDNA encoding EPg222 has been cloned and expressed as a functionally active enzyme in Pichia pastoris. The recombinant enzyme exhibits similar activities to the native enzyme against a wide range of protein substrates including muscle myofibrillar protein. The mature sequence contains conserved aa residues characteristic of those forming the catalytic triad of serine proteases (Asp42, His76 and Ser228) but notably the food enzyme exhibits specific aa substitutions in the immunoglobulin-E recognition regions that have been identified in protein homologues that are allergenic.

Crystal structure of a glycosylated Fab from an IgM cryoglobulin with properties of a natural proteolytic antibody

The 2.6 A (1 A=0.1 nm) resolution structure has been determined for the glycosylated Fab (fragment antigen binding) of an IgM (Yvo) obtained from a subject with Waldenström's macroglobulinaemia. Dynamic light scattering was used to estimate the gel point and monitor the formation of an ordered hydroscopic gel of Yvo IgM upon cooling. If a cryoglobulin forms gels in peripheral tissues and organs, the associated swelling and damage to microvasculature can result in considerable morbidity and mortality. The three-dimensional structure of the branched N-linked oligosaccharide associated with the CH1 domain (first constant domain of heavy chain) is reported. The carbohydrate may act to shield part of the lateral surface of the CH1 domain and crowd the junction between the CH1 and CH2 domains, thereby limiting the segmental flexibility of the Fab arms in intact Yvo IgM, especially at low temperatures. Recently, Yvo IgM was shown to have the properties of a naturally occurring proteolytic antibody [Paul, Karle, Planque, Taguchi, Salas, Nishiyama, Handy, Hunter, Edmundson and Hanson (2004) J. Biol. Chem. 279, 39611-39619; Planque, Bangale, Song, Karle, Taguchi, Poindexter, Bick, Edmundson, Nishiyama and Paul (2004) J. Biol Chem. 279, 14024-14032]. The Yvo protein displayed the ability to cleave, by a nucleophilic mechanism, the amide bonds of a variety of serine protease substrates and the gp120 coat protein of HIV. An atypical serine, arginine and glutamate motif is located in the middle of the Yvo antigen-binding site and displays an overall geometry that mimics the classical serine, histidine and aspartate catalytic triad of serine proteases. Our present findings indicate that pre-existing or natural antibodies can utilize at least one novel strategy for the cleavage of peptide bonds.

Purification and molecular characterization of glutamyl endopeptidase from zein-utilizing Bacillus pumilus strain MS-1

In this study, we report the purification and characterization of the extracellular protease BPP-B from the zein-utilizing Bacillus pumilus strain MS-1. The purified BPP-B exhibited glutamyl endopeptidase activity. The Optimum pHs for the cleavage of casein and Suc-Ala-Ala-Pro-Glu-pNA were 11.0 and 8.0, respectively. The bppB gene encoded a 303-amino-acid pre-pro form of BPP-B, and mature BPP-B contained 215-amino-acid residues. BPP-B had three V8 serine protease family signatures (amino acid residues 96-113, 120-137, and 211-224), a serine protease (trypsin or chymotrypsin) family signature (amino acid residues 120-136), and the catalytic triad of serine proteases (His135, Asp186 and Ser259). These results indicate that BPP-B is a glutamyl endopeptidase belonging to peptidase family S2B. This is the first report on a glutamyl endopeptidase from a Bacillus pumilus strain. Although we have recently reported a subtilisin-like protease (BPP-A) playing a major part in zein degradation by Bacillus pumilus strain MS-1, it is possible that BPP-B is also involved in the further digestion of zein.

Human Polyserase-2, a Novel Enzyme with Three Tandem Serine Protease Domains in a Single Polypeptide Chain

We have cloned a human cDNA encoding a new serine protease that has been called polyserase-2 (polyserine protease-2) because it is the second identified human enzyme with several tandem serine protease domains in its amino acid sequence. The first serine protease domain contains all characteristic features of these enzymes, whereas the second and third domains lack one residue of the catalytic triad of serine proteases and are predicted to be catalytically inactive. This complex domain organization is also present in the sequences of mouse and rat polyserase-2 and resembles that of polyserase-1, which also contains three serine protease domains in its amino acid sequence. However, polyserase-2 lacks additional domains present in polyserase-1, including a type II transmembrane motif and a low-density lipoprotein receptor A module. Enzymatic analysis demonstrated that both full-length polyserase-2 and its first serine protease domain hydrolyzed synthetic peptides used for assaying serine proteases. Nevertheless, the activity of the isolated domain was greater than that of the entire protein, suggesting that the two catalytically inactive serine protease domains of polyserase-2 may modulate the activity of the first domain. Northern blot analysis showed that polyserase-2 is expressed in fetal kidney; adult skeletal muscle, liver, placenta, prostate, and heart; and tumor cell lines derived from lung and colon adenocarcinomas. Finally, analysis of post-translational processing mechanisms of polyserase-2 revealed that, contrary to those affecting to the membrane-bound polyserase-1, this novel polyprotein is a secreted enzyme whose three protease domains remain as an integral part of a single polypeptide chain.