Structural basis of substrate specificity in the serine proteases

Quantitative assessment of enzyme specificity in vivo: P2 recognition by Kex2 protease defined in a genetic system

The specificity of the yeast proprotein-processing Kex2 protease was examined in vivo by using a sensitive, quantitative assay. A truncated prepro-alpha-factor gene encoding an alpha-factor precursor with a single alpha-factor repeat was constructed with restriction sites for cassette mutagenesis flanking the single Kex2 cleavage site (-SLDKR downward arrowEAEA-). All of the 19 substitutions for the Lys (P2) residue in the cleavage site were made. The wild-type and mutant precursors were expressed in a yeast strain lacking the chromosomal genes encoding Kex2 and prepro-alpha-factor. Cleavage of the 20 sites by Kex2, expressed at the wild-type level, was assessed by using a quantitative-mating assay with an effective range greater than six orders of magnitude. All substitutions for Lys at P2 decreased mating, from 2-fold for Arg to >10(6)-fold for Trp. Eviction of the Kex2-encoding plasmid indicated that cleavage of mutant sites by other cellular proteases was not a complicating factor. Mating efficiencies of strains expressing the mutant precursors correlated well with the specificity (kcat/KM) of purified Kex2 for comparable model peptide substrates, validating the in vivo approach as a quantitative method. The results support the conclusion that KM, which is heavily influenced by the nature of the P2 residue, is a major determinant of cleavage efficiency in vivo. P2 preference followed the rank order: Lys > Arg > Thr > Pro > Glu > Ile > Ser > Ala > Asn > Val > Cys > AsP > Gln > Gly > His > Met > Leu > Tyr > Phe > Trp.

New enzyme lineages by subdomain shuffling

Protein functions have evolved in part via domain recombination events. Such events, for example, recombine structurally independent functional domains and shuffle targeting, regulatory, and/or catalytic functions. Domain recombination, however, can generate new functions, as implied by the observation of catalytic sites at interfaces of distinct folding domains. If useful to an evolving organism, such initially rudimentary functions would likely acquire greater efficiency and diversity, whereas the initially distinct folding domains would likely develop into single functional domains. This represents the probable evolution of the S1 serine protease family, whose two homologous beta-barrel subdomains assemble to form the binding sites and the catalytic machinery. Among S1 family members, the contact interface and catalytic residues are highly conserved whereas surrounding surfaces are highly variable. This observation suggests a new strategy to engineer viable proteins with novel properties, by swapping folding subdomains chosen from among protein family members. Such hybrid proteins would retain properties conserved throughout the family, including folding stability as single domain proteins, while providing new surfaces amenable to directed evolution or engineering of specific new properties. We show here that recombining the N-terminal subdomain from coagulation factor X with the C-terminal subdomain from trypsin creates a potent enzyme (fXYa) with novel properties, in particular a broad substrate specificity. As shown by the 2.15-A crystal structure, plasticity at the hydrophobic subdomain interface maintains activity, while surface loops are displaced compared with the parent subdomains. fXYa thus represents a new serine proteinase lineage with hybrid fX, trypsin, and novel properties.

Sheep mast-cell proteinases-1 and -3: cDNA cloning, primary structure and molecular modelling of the enzymes and further studies on substrate specificity

Sheep mast-cell proteinase-1 (sMCP-1) is a serine proteinase expressed predominantly by mucosal mast cells, with specificity for cleavage C-terminal to basic and hydrophobic amino acid residues. A cDNA encoding sMCP-1 has been cloned using reverse transcriptase (RT)-PCR. It appears to be translated as a pre-proenzyme with a 17-amino-acid signal peptide, a basic 2-amino-acid propeptide and a 226-amino-acid catalytic domain. A second cDNA, encoding a serine proteinase 90% identical with sMCP-1, was also cloned and named sMCP-3. Molecular models were constructed for both enzymes using coordinates for the refined X-ray structures of human cathepsin G, chymase and rat mast-cell proteinase-2. The model for sMCP-1 suggests that the acidic Asp-226 side chain extends into the substrate-binding pocket, hydrogen-bonding with Ser-190 on the opposite side and bisecting the pocket. The location of an acidic moiety in this position would favour interaction with basic substrate residues and binding of aromatic residues is rationalized by interaction of the positively charged equatorial plane with Asp-226. The balance between chymotryptic and tryptic activities of sMCP-1 was found to be sensitive to salt concentration, with increasing univalent cation concentration favouring chymotryptic activity relative to the tryptic. Using a peptide substrate representing residues 36-59 of the human thrombin receptor, increasing salt concentration favoured cleavage at Phe-43 rather than at Arg-41.

Specificity of human cathepsin G

A series of tetrapeptide p-nitroanilide substrates of the general formula: suc-Ala-Ala-Pro-Aaa-p-nitroanilide was used to map the S1 binding pocket of human cathepsin G. Based on the kcat/Km parameter, the following order of preference was found: Lys=Phe>Arg=Leu>Met>Nle=Nva>Ala>Asp. Thus, the enzyme exhibits clear dual and equal trypsin- and chymotrypsin-like specificities. Particularly deleterious were beta-branched side chains of Ile and Val. The P1 substrate preferences found for cathepsin G are distinctly different from many other serine proteinases, including fiddler crab collagenase and chymotrypsin. The kcat/Km values obtained for P1 Lys, Phe, Arg and Leu substrates correlate well with those determined for analogous P1 mutants of basic pancreatic trypsin inhibitor (BPTI) obtained through recombinant techniques. To characterise the subsite specificity of the enzyme, a series of Cucurbita maxima trypsin inhibitor I (CMTI I) mutants were used comprising P2-P3' and P12' positions. All the mutants obtained were inhibitors of cathepsin G with association constants in the range: 105-109 M-1. Some of the mutations destabilised complex formation. In particular, Met8-->Arg substitution at P3', which increased association constant for chymotrypsin 46-fold, led to a 7-fold decrease of binding with cathepsin G. In addition, mutation of Ile6 at position P1' either to Val or Asp was deleterious for cathepsin G. In two cases (Ala18-->Gly (P12') and Pro4-->Thr (P2)), about a 10-fold increase in association constants was observed.

Role of the C-terminal tryptophan residue for the structure-function of the alphavirus capsid protein

The Semliki Forest virus capsid protein is a multifunctional protein which packages genomic RNA into nucleocapsid structures and binds to viral spike protein during budding. In addition, the capsid protein has an autoproteolytic activity whereby the C-terminal tryptophan is used as the substrate for cotranslational cleavage of the viral structure polyprotein. The autoproteolytic domain of the capsid protein has a chymotrypsin-like fold but has two additional short beta-strands which place the tryptophan into the active site. Here, we have substituted the C-terminal tryptophan of Semliki Forest virus capsid protein for alanine, arginine and phenylalanine and analysed the effects on different functions of the C protein such as nucleocapsid formation, spike binding and autoproteolytic activity. We found that (i) tryptophan is a better substrate for the autoproteolytic activity, (ii) the wild-type tryptophan is the only residue that allows efficient viral growth and (iii) an aromatic residue is important for correct initial folding and stability of the protein.

Engineering bidentate macromolecular inhibitors for trypsin and urokinase-type plasminogen activator

Ecotin, a dimeric serine protease inhibitor from Escherichia coli, is a novel platform for inhibitor design. An approach using the three-dimensional structure of the ecotin-trypsin complex to guide combinatiorial design efforts was taken to create potent bidentate ecotin inhibitors for trypsin and human urokinase-type plasminogen activator (uPA). The ecotin surface loop that was redesigned is composed of residues 67 to 70 (60 s loop), and binds to the target protease at a region 25 A from the enzyme active site. Two ecotin phage display libraries were constructed to exploit the binding interactions at the 60 s loop. The ecotin 60X4 library, in which residues 67 to 70 of ecotin were randomized, was panned against rat and bovine trypsin in parallel for four rounds. Panning against bovine trypsin resulted in enrichment of ecotin phage but did not yield a consensus sequence. Panning against rat trypsin resulted in enrichment as well as the ecotin consensus sequence WGFP at positions 67 to 70. The variant ecotin encoded by this sequence inhibited rat trypsin at 80 pM, a 12-fold improvement over ecotin wild-type (WT). A second generation library, ecotin M84R+60X4 including an additional methionine to arginine substitution at position 84 in the primary binding site of ecotin, was generated for panning against uPA and rat trypsin. Panning against rat trypsin resulted in enrichment but no consensus sequence. Panning against uPA resulted in enrichment as well as the different ecotin consensus sequence WGYR at positions 67 to 70. Ecotin M84R+D70R bound to uPA at 50 pM, a 56,000-fold increase in binding compared to ecotin WT. Furthermore, ecotin M84R+D70R achieved a 13,680-fold preference of specificity towards uPA versus rat trypsin. The fact that the 60 s loop of ecotin plays different roles in binding to trypsin and uPA suggests this site can be used to introduce specificity and potency for other members of the serine proteases with a chymotrypsin fold.

How the substitution of K188 of trypsin binding site by aromatic amino acids can influence the processing of beta-casein

Aspartyl 189 residue of trypsin is known to be essential for specific lysis of Arg-X and Lys-X bonds. Undertaking to modulate the catalytic properties of this protease, otherwise highly conserved K188 was replaced with aromatic amino acid residues aiming the perturbation of the electrostatics and the amplifying of hydrophobic interactions of the substrate binding site. The catalytic properties of the mutants K188F, K188Y, and K188W were measured at pH 7, 8, 9, and 10 using a pair of synthetic tetrapeptide p-nitroanilide substrates and beta-casein. The kinetic analysis reveals that all the mutants conserve the native trypsin capacity to split peptide bonds containing arginyl and lysyl residues. Surprisingly, however, depending on mutation, the optimum pH of activity changes. As demonstrated only by proteolysis of a natural substrate, all mutants cleave also peptide bonds involving asparagine and glutamine. These stuttered cleavage sites are close to the beta-casein fragments in beta-sheet according to Hydrophobic Cluster Analysis.

Elucidation of the cause for reduced activity of abnormal human plasmin containing an Ala55-Thr mutation: importance of highly conserved Ala55 in serine proteases

In serine proteases, Ala55 is highly conserved and located just behind the catalytic triad. That the activity of human plasmin is reduced by the A55T substitution indicates the importance of Ala55 in catalysis. In the present study, the 3-D model of A55T human plasmin shows that an unusual hydrogen bond between Thr55 Ogamma1 and His57 Nepsilon2 alters His57 into an inactive conformation in which His57 cannot accept a proton from Ser195 as a catalytic base. Our results demonstrate that Ala55 contributes heavily to the active conformation of His57 and ensures the proton transfer from Ser195 to His57.

Molecular mechanisms for the conversion of zymogens to active proteolytic enzymes

Proteolytic enzymes are synthesized as inactive precursors, or "zymogens," to prevent unwanted protein degradation, and to enable spatial and temporal regulation of proteolytic activity. Upon sorting or appropriate compartmentalization, zymogen conversion to the active enzyme typically involves limited proteolysis and removal of an "activation segment." The sizes of activation segments range from dipeptide units to independently folding domains comprising more than 100 residues. A common form of the activation segment is an N-terminal extension of the mature enzyme, or "prosegment," that sterically blocks the active site, and thereby prevents binding of substrates. In addition to their inhibitory role, prosegments are frequently important for the folding, stability, and/or intracellular sorting of the zymogen. The mechanisms of conversion to active enzymes are diverse in nature, ranging from enzymatic or nonenzymatic cofactors that trigger activation, to a simple change in pH that results in conversion by an autocatalytic mechanism. Recent X-ray crystallographic studies of zymogens and comparisons with their active counterparts have identified the structural changes that accompany conversion. This review will focus upon the structural basis for inhibition by activation segments, as well as the molecular events that lead to the conversion of zymogens to active enzymes.

Effect of pea and bovine trypsin inhibitors on wild-type and modified trypsins

In order to modify the catalytic properties of trypsin, lysine-188 (S1) of the substrate binding pocket was substituted by an aromatic amino acid residue (Phe, Tyr, Trp) or by a histidyl residue. Two other mutants were obtained by displacement or elimination of the negative charge of aspartic acid-189 (K188D/D189K and G187W/K188F/D189Y, respectively). The high affinity inhibitors, like PSTI II and BPTI, behaved as specific substrates of the trypsin and its mutants. Their inhibiting effect toward modified trypsins was studied. The bovine inhibitor had a higher affinity for all tested enzymes than pea inhibitor. The inhibition constants differed according to the mutations on the protease.

Design of potent selective zinc-mediated serine protease inhibitors

Many serine proteases are targets for therapeutic intervention because they often play key roles in disease. Small molecule inhibitors of serine proteases with high affinity are especially interesting as they could be used as scaffolds from which to develop drugs selective for protease targets. One such inhibitor is bis(5-amidino-2-benzimidazolyl)methane (BABIM), standing out as the best inhibitor of trypsin (by a factor of over 100) in a series of over 60 relatively closely related analogues. By probing the structural basis of inhibition, we discovered, using crystallographic methods, a new mode of high-affinity binding in which a Zn2+ ion is tetrahedrally coordinated between two chelating nitrogens of BABIM and two active site residues, His57 and Ser 195. Zn2+, at subphysiological levels, enhances inhibition by over 10(3)-fold. The distinct Zn2+ coordination geometry implies a strong dependence of affinity on substituents. This unique structural paradigm has enabled development of potent, highly selective, Zn2+-dependent inhibitors of several therapeutically important serine proteases, using a physiologically ubiquitous metal ion.

Baculovirus-mediated expression of truncated modular fragments from the catalytic region of human complement serine protease C1s. Evidence for the involvement of both complement control protein modules in the recognition of the C4 protein substrate

C1s is the modular serine protease responsible for cleavage of C4 and C2, the protein substrates of the first component of complement. Its catalytic region (gamma-B) comprises two complement control protein (CCP) modules, a short activation peptide (ap), and a serine protease domain (SP). A baculovirus-mediated expression system was used to produce recombinant truncated fragments from this region, deleted either from the first CCP module (CCP2-ap-SP) or from both CCP modules (ap-SP). The aglycosylated fragment CCP2-ap-SPag was also expressed by using tunicamycin. The fragments were produced at yields of 0.6-3 mg/liter of culture, isolated, and characterized chemically and then tested functionally by comparison with intact C1s and its proteolytic gamma-B fragment. All recombinant fragments were expressed in a proenzyme form and cleaved by C1r to generate active enzymes expressing esterolytic activity and reactivity toward C1 inhibitor comparable to those of intact C1s. Likewise, the activated fragments gamma-B, CCP2-ap-SP, and ap-SP retained C1s ability to cleave C2 in the fluid phase. In contrast, whereas fragment gamma-B cleaved C4 as efficiently as C1s, the C4-cleaving activity of CCP2-ap-SP was greatly reduced (about 70-fold) and that of ap-SP was abolished. It is concluded that C4 cleavage involves substrate recognition sites located in both CCP modules of C1s, whereas C2 cleavage is affected mainly by the serine protease domain. Evidence is also provided that the carbohydrate moiety linked to the second CCP module of C1s has no significant effect on catalytic activity.

Engineering novel specificities for ligand-activated transcription in the nuclear hormone receptor RXR

BACKGROUND

The retinoid X receptor (RXR) activates transcription of target genes in response to its natural ligand, 9-cis retinoic acid (9cRA), and a number of RXR-specific synthetic ligands. To discover the potential for engineering nuclear receptors for activation of transcription by novel ligands, we used structure-based mutagenesis to change the ligand specificity of RXR.

RESULTS

By making substitutions at only two positions (Phe313 and Leu436) we engineered two new classes of RXR proteins that had altered ligand specificities. The first class exhibits decreased activation by 9cRA and increased activation by synthetic ligands. The second class continues to be activated by 9cRA but no longer responds to synthetic ligands. The magnitude of the change in specificity that can be accomplished is greater than 280-fold.

CONCLUSIONS

These results confirm that Phe313 and Leu436 are crucial determinants of ligand specificity for RXR and demonstrate that nuclear receptors are exceptionally promising protein scaffolds for the introduction of novel ligand specificities through structure-based protein engineering.

Linkers of secondary structures in proteins

Linkers that connect repeating secondary structures fall into conformational classes based on distance and main-chain torsion clustering. A data set of 300 unique protein chains with low pairwise sequence identity was clustered into only a few groups representing the preferred motifs. The linkers of two to eight residues for the nonredundant data set are designated H-Ln-H, H-Ln-E, E-Ln-H, E-Ln-E, where n is the length, H stands for alpha-helices, and E for beta-strands. Most of the clusters identified here corroborate earlier findings. However, 19 new clusters are identified in this paper, with many of them having seven and eight residue linkers. In our first analysis, the secondary structures flanking the linkers are both interacting and noninteracting and there is no precise angle of orientation between them. A second analysis was performed on a set of proteins with restricted orientations for the flanking elements, namely, mainly alpha class of proteins with orthogonal architecture. Two definite clusters are identified, one corresponding to linkers of orthogonal helices and the other to linkers of antiparallel helices. Loops forming binding sites or involved in catalytic activity are important determinants of the function of proteins. Although the structural conservation of the residues around the catalytic triad of serine proteases has been studied widely, there has not been a systematic analysis of the conformation of the loops that contain them. Residues of the catalytic triad reside in the linkers of beta-strands, with varying lengths of more than eight residues. Here, we analyze the structural conservation of such linkers by superposition, and observe a conserved structural feature of the linkers incorporating each of the three residues of the catalytic triad.

Converting blood coagulation factor IXa into factor Xa: dramatic increase in amidolytic activity identifies important active site determinants

The coagulation factors IXa (fIXa) and Xa (fXa) share extensive structural and functional homology; both cleave natural substrates effectively only with a cofactor at a phospholipid surface. However, the amidolytic activity of fIXa is 10(4)-fold lower than that of fXa. To identify determinants of this poor reactivity, we expressed variants of truncated fIXa (rf9a) and fXa (rf10a) in Escherichia coli. The crystal structures of fIXa and fXa revealed four characteristic active site components which were subsequently exchanged between rf9a and rf10a. Exchanging Glu219 by Gly or exchanging the 148 loop did not increase activity of rf9a, whereas corresponding mutations abolished reactivity of rf10a. Exchanging Ile213 by Val only moderately increased reactivity of rf9a. Exchanging the 99 loop, however, dramatically increased reactivity. Furthermore, combining all four mutations essentially introduced fXa properties into rf9a: the amidolytic activity was increased 130-fold with fXa substrate selectivity. The results suggest a 2-fold origin of fIXa's poor reactivity. A narrowed S3/S4 subsite disfavours interaction with substrate P3/P4 residues, while a distorted S1 subsite disfavours effective cleavage of the scissile bond. Both defects could be repaired by introducing fXa residues. Such engineered coagulation enzymes will be useful in diagnostics and in the development of therapeutics.

The structure of ClpP at 2.3 A resolution suggests a model for ATP-dependent proteolysis

We have determined the crystal structure of the proteolytic component of the caseinolytic Clp protease (ClpP) from E. coli at 2.3 A resolution using an ab initio phasing procedure that exploits the internal 14-fold symmetry of the oligomer. The structure of a ClpP monomer has a distinct fold that defines a fifth structural family of serine proteases but a conserved catalytic apparatus. The active protease resembles a hollow, solid-walled cylinder composed of two 7-fold symmetric rings stacked back-to-back. Its 14 proteolytic active sites are located within a central, roughly spherical chamber approximately 51 A in diameter. Access to the proteolytic chamber is controlled by two axial pores, each having a minimum diameter of approximately 10 A. From the structural features of ClpP, we suggest a model for its action in degrading proteins.

Mouse mast cell protease 9, a novel member of the chromosome 14 family of serine proteases that is selectively expressed in uterine mast cells

Mouse mast cell protease (mMCP) 1, mMCP-2, mMCP-4, and mMCP-5 are members of a family of related serine proteases whose genes reside within an approximately 850 kilobase (kb) complex on chromosome 14 that does not readily undergo crossover events. While mapping the mMCP-1 gene, we isolated a novel gene that encodes a homologous serine protease designated mMCP-9. The mMCP-9 and mMCP-1 genes are only approximately 7 kb apart on the chromosome and are oriented back to back. The proximity of the mMCP-1 and mMCP-9 genes now suggests that the low recombination frequency of the complex is due to the closeness of some of its genes. The mMCP-9 transcript and protein were observed in the jejunal submucosa of Trichinella spiralis-infected BALB/c mice. However, in normal BALB/c mice, mMCP-9 transcript and protein were found only in those mast cells that reside in the uterus. Thus, the expression of mMCP-9 differs from that of all other chymases. The observation that BALB/c mouse bone marrow-derived mast cells developed with interleukin (IL) 10 and c-kit ligand contain mMCP-9 transcript, whereas those developed with IL-3 do not, indicates that the expression of this particular chymase is regulated by the cytokine microenvironment. Comparative protein structure modeling revealed that mMCP-9 is the only known granule protease with three positively charged regions on its surface. This property may allow mMCP-9 to form multimeric complexes with serglycin proteoglycans and other negatively charged proteins inside the granule. Although mMCP-9 exhibits a >50% overall amino acid sequence identity with its homologous chymases, it has a unique substrate-binding cleft. This finding suggests that each member of the chromosome 14 family of serine proteases evolved to degrade a distinct group of proteins.

Refined X-ray crystallographic structure of the poliovirus 3C gene product

The X-ray crystallographic structure of the recombinant poliovirus 3C gene product (Mahoney strain) has been determined by single isomorphous replacement and non-crystallographic symmetry averaging and refined at 2.1 A resolution. Poliovirus 3C is comprised of two six-stranded antiparallel beta-barrel domains and is structurally similar to the chymotrypsin-like serine proteinases. The shallow active site cleft is located at the junction of the two beta-barrel domains and contains a His40, Glu71, Cys147 catalytic triad. The polypeptide loop preceding Cys147 is flexible and likely undergoes a conformational change upon substrate binding. The specificity pockets for poliovirus 3C are well-defined and modeling studies account for the known substrate specificity of this proteinase. Poliovirus 3C also participates in the formation of the viral replicative initiation complex where it specifically recognizes and binds the RNA stem-loop structure in the 5' non-translated region of its own genome. The RNA recognition site of 3C is located on the opposite side of the molecule in relation to its proteolytic active site and is centered about the conserved KFRDIR sequence of the domain linker. The recognition site is well-defined and also includes residues from the amino and carboxy-terminal helices. The two molecules in the asymmetric unit are related by an approximate 2-fold, non-crystallographic symmetry and form an intermolecular antiparallel beta-sheet at their interface.

Limited proteolysis of angiogenin by elastase is regulated by plasminogen

Human neutrophil elastase cleaves angiogenin at the Ile-29/Met-30 peptide bond to produce two major disulfide-linked fragments with apparent molecular weights of 10,000 and 4000, respectively. Elastase-cleaved angiogenin has slightly increased ribonucleolytic activity, but has lost its ability to undergo nuclear translocation in endothelial cells, a process essential for angiogenic activity. Cleavage appears to alter the cell-binding properties of angiogenin, despite the fact that it occurs some distance from the putative receptor-binding site, since the elastase-cleaved protein fails to compete with its native counterpart for nuclear translocation in endothelial cells. Plasminogen specifically accelerates elastase proteolysis of angiogenin. It does not enhance elastase activity toward ribonuclease A or the synthetic peptide substrate MeOSuc-Ala-Ala-Pro-Val-pNA. Plasminogen-accelerated inactivation of angiogenin by elastase might be a significant event in the process of angiogenin-induced angiogenesis since (i) angiogenin and plasminogen circulate in plasma at high concentrations, (ii) angiogenin, especially when bound to actin, activates tissue plasminogen activator to generate plasmin from plasminogen, and (iii) elastase cleaves plasminogen to produce angiostatin, a potent inhibitor of angiogenesis and metastasis. Interrelationships among angiogenin, plasminogen, plasminogen activators, elastase, and angiostatin may provide a sensitive regulatory system to balance angiogenesis and antiangiogenesis.

Crystal structures of bovine chymotrypsin and trypsin complexed to the inhibitor domain of Alzheimer's amyloid beta-protein precursor (APPI) and basic pancreatic trypsin inhibitor (BPTI): engineering of inhibitors with altered specificities

The crystal structures of the inhibitor domain of Alzheimer's amyloid beta-protein precursor (APPI) complexed to bovine chymotrypsin (C-APPI) and trypsin (T-APPI) and basic pancreatic trypsin inhibitor (BPTI) bound to chymotrypsin (C-BPTI) have been solved and analyzed at 2.1 A, 1.8 A, and 2.6 A resolution, respectively. APPI and BPTI belong to the Kunitz family of inhibitors, which is characterized by a distinctive tertiary fold with three conserved disulfide bonds. At the specificity-determining site of these inhibitors (P1), residue 15(I)4 is an arginine in APPI and a lysine in BPTI, residue types that are counter to the chymotryptic hydrophobic specificity. In the chymotrypsin complexes, the Arg and Lys P1 side chains of the inhibitors adopt conformations that bend away from the bottom of the binding pocket to interact productively with elements of the binding pocket other than those observed for specificity-matched P1 side chains. The stereochemistry of the nucleophilic hydroxyl of Ser 195 in chymotrypsin relative to the scissile P1 bond of the inhibitors is identical to that observed for these groups in the trypsin-APPI complex, where Arg 15(I) is an optimal side chain for tryptic specificity. To further evaluate the diversity of sequences that can be accommodated by one of these inhibitors, APPI, we used phage display to randomly mutate residues 11, 13, 15, 17, and 19, which are major binding determinants. Inhibitors variants were selected that bound to either trypsin or chymotrypsin. As expected, trypsin specificity was principally directed by having a basic side chain at P1 (position 15); however, the P1 residues that were selected for chymotrypsin binding were His and Asn, rather than the expected large hydrophobic types. This can be rationalized by modeling these hydrophilic side chains to have similar H-bonding interactions to those observed in the structures of the described complexes. The specificity, or lack thereof, for the other individual subsites is discussed in the context of the "allowed" residues determined from a phage display mutagenesis selection experiment.

Site-specific dissection of substrate recognition by thrombin

Current approaches to enzyme specificity focus on the identification of consensus sequences from combinatorial chemistry libraries or phage display. These synthetic substrates can also be used as sensitive probes for the molecular environment of the enzyme specificity sites to determine how they contribute to recognition in the transition state. Libraries constructed to include all relevant species for a site-specific analysis contain a relatively small number of substrates and provide quantitative information on the energetics of recognition that can be exploited in studies of structure-function relations and rational drug design. We have constructed a library of substrates carrying substitutions at P1, P2, and P3 to probe the response of the specificity sites S1, S2, and S3 of thrombin. The library has been used to identify differences between the anticoagulant slow and procoagulant fast forms of thrombin and the structural origin of the effects. The results also offer new guidelines for the design of active-site inhibitors of thrombin.

The protease and the assembly protein of Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8)

A genomic clone encoding the protease (Pr) and the assembly protein (AP) of Kaposi's sarcoma-associated herpesvirus (KSHV) (also called human herpesvirus 8) has been isolated and sequenced. As with other herpesviruses, the Pr and AP coding regions are present within a single long open reading frame. The mature KSHV Pr and AP polypeptides are predicted to contain 230 and 283 residues, respectively. The amino acid sequence of KSHV Pr has 56% identity with that of herpesvirus salmiri, the most similar virus by phylogenetic comparison. Pr is expressed in infected human cells as a late viral gene product, as suggested by RNA analysis of KSHV-infected BCBL-1 cells. Expression of the Pr domain in Escherichia coli yields an enzymatically active species, as determined by cleavage of synthetic peptide substrates, while an active-site mutant of this same domain yields minimal proteolytic activity. Sequence comparisons with human cytomegalovirus (HCMV) Pr permitted the identification of the catalytic residues, Ser114, His46, and His134, based on the known structure of the HCMV enzyme. The amino acid sequences of the release site of KSHV Pr (Tyr-Leu-Lys-Ala*Ser-Leu-Ile-Pro) and the maturation site (Arg-Leu-Glu-Ala*Ser-Ser-Arg-Ser) show that the extended substrate binding pocket differs from that of other members of the family. The conservation of amino acids known to be involved in the dimer interface region of HCMV Pr suggests that KSHV Pr assembles in a similar fashion. These features of the viral protease provide opportunities to develop specific inhibitors of its enzymatic activity.

Trimeresurus stejnegeri snake venom plasminogen activator. Site-directed mutagenesis and molecular modeling

The specific plasminogen activator from Trimeresurus stejnegeri venom (TSV-PA) is a serine proteinase presenting 23% sequence identity with the proteinase domain of tissue type plasminogen activator, and 63% with batroxobin, a fibrinogen clotting enzyme from Bothrops atrox venom that does not activate plasminogen. TSV-PA contains six disulfide bonds and has been successfully overexpressed in Escherichia coli (Zhang, Y., Wisner, A., Xiong, Y. L., and Bon, C. (1995) J. Biol. Chem. 270, 10246-10255). To identify the functional domains of TSV-PA, we focused on three short peptide fragments of TSV-PA showing important sequence differences with batroxobin and other venom serine proteinases. Molecular modeling shows that these sequences are located in surface loop regions, one of which is next to the catalytic site. When these sequences were replaced in TSV-PA by the equivalent batroxobin residues none generated either fibrinogen-clotting or direct fibrinogenolytic activity. Two of the replacements had little effect in general and are not critical to the specificity of TSV-PA for plasminogen. Nevertheless, the third replacement, produced by the conversion of the sequence DDE 96a-98 to NVI, significantly increased the Km for some tripeptide chromogenic substrates and resulted in undetectable plasminogen activation, indicating the key role that the sequence plays in substrate recognition by the enzyme.

Structural determinants of specificity in the cysteine protease cruzain

The structure of cruzain, an essential protease from the parasite Trypanosoma cruzi, was determined by X-ray crystallography bound to two different covalent inhibitors. The cruzain S2 specificity pocket is able to productively bind both arginine and phenylalanine residues. The structures of cruzain bound to benzoyl-Arg-Ala-fluoromethyl ketone and benzoyl-Tyr-Ala-fluoromethyl ketone at 2.2 and 2.1 A, respectively, show a pH-dependent specificity switch. Glu 205 adjusts to restructure the S2 specificity pocket, conferring right binding to both hydrophobic and basic residues. Kinetic analysis of activated peptide substrates shows that substrates placing hydrophobic residues in the specificity pocket are cleaved at a broader pH range than hydrophilic substrates. These results demonstrate how cruzain binds both basic and hydrophobic residues and could be important for in vivo regulation of cruzain activity.

Bovine viral diarrhea virus NS3 serine proteinase: polyprotein cleavage sites, cofactor requirements, and molecular model of an enzyme essential for pestivirus replication

Members of the Flaviviridae encode a serine proteinase termed NS3 that is responsible for processing at several sites in the viral polyproteins. In this report, we show that the NS3 proteinase of the pestivirus bovine viral diarrhea virus (BVDV) (NADL strain) is required for processing at nonstructural (NS) protein sites 3/4A, 4A/4B, 4B/5A, and 5A/5B but not for cleavage at the junction between NS2 and NS3. Cleavage sites of the proteinase were determined by amino-terminal sequence analysis of the NS4A, NS4B, NS5A, and NS5B proteins. A conserved leucine residue is found at the P1 position of all four cleavage sites, followed by either serine (3/4A, 4B/5A, and 5A/5B sites) or alanine (4A/4B site) at the P1' position. Consistent with this cleavage site preference, a structural model of the pestivirus NS3 proteinase predicts a highly hydrophobic P1 specificity pocket. trans-Processing experiments implicate the 64-residue NS4A protein as an NS3 proteinase cofactor required for cleavage at the 4B/5A and 5A/5B sites. Finally, using a full-length functional BVDV cDNA clone, we demonstrate that a catalytically active NS3 serine proteinase is essential for pestivirus replication.

Distinguishing the specificities of closely related proteases. Role of P3 in substrate and inhibitor discrimination between tissue-type plasminogen activator and urokinase

Elucidating subtle specificity differences between closely related enzymes is a fundamental challenge for both enzymology and drug design. We have addressed this issue for two intimately related serine proteases, tissue-type plasminogen activator (t-PA) and urokinase-type plasminogen activator (u-PA), by modifying the technique of substrate phage display to create substrate subtraction libraries. Characterization of individual members of the substrate subtraction library accomplished the rapid, direct identification of small, highly selective substrates for t-PA. Comparison of the amino acid sequences of these selective substrates with the consensus sequence for optimal substrates for t-PA, derived using standard substrate phage display protocols, suggested that the P3 and P4 residues are the primary determinants of the ability of a substrate to discriminate between t-PA and u-PA. Mutagenesis of the P3 and P4 residues of plasminogen activator inhibitor type 1, the primary physiological inhibitor of both t-PA and u-PA, confirmed this prediction and indicated a predominant role for the P3 residue. Appropriate replacement of both the P3 and P4 residues enhanced the t-PA specificity of plasminogen activator inhibitor type 1 by a factor of 600, and mutation of the P3 residue alone increased this selectivity by a factor of 170. These results demonstrate that the combination of substrate phage display and substrate subtraction methods can be used to discover specificity differences between very closely related enzymes and that this information can be utilized to create highly selective inhibitors.

The structure of Staphylococcus aureus epidermolytic toxin A, an atypic serine protease, at 1.7 A resolution

BACKGROUND

Staphylococcal epidermolytic toxins A and B (ETA and ETB) are responsible for the staphylococcal scalded skin syndrome of newborn and young infants; this condition can appear just a few hours after birth. These toxins cause the disorganization and disruption of the region between the stratum spinosum and the stratum granulosum--two of the three cellular layers constituting the epidermis. The physiological substrate of ETA is not known and, consequently, its mode of action in vivo remains an unanswered question. Determination of the structure of ETA and its comparison with other serine proteases may reveal insights into ETA's catalytic mechanism.

RESULTS

The crystal structure of staphylococcal ETA has been determined by multiple isomorphous replacement and refined at 1.7 A resolution with a crystallographic R factor of 0.184. The structure of ETA reveals it to be a new and unique member of the trypsin-like serine protease family. In contrast to other serine protease folds, ETA can be characterized by ETA-specific surface loops, a lack of cysteine bridges, an oxyanion hole which is not preformed, an S1 specific pocket designed for a negatively charged amino acid and an ETA-specific specific N-terminal helix which is shown to be crucial for substrate hydrolysis.

CONCLUSIONS

Despite very low sequence homology between ETA and other trypsin-like serine proteases, the ETA crystal structure, together with biochemical data and site-directed mutagenesis studies, strongly confirms the classification of ETA in the Glu-endopeptidase family. Direct links can be made between the protease architecture of ETA and its biological activity.

Activation of pro-caspase-7 by serine proteases includes a non-canonical specificity

As a model to investigate the mechanism of caspase activation we have analysed the processing of pro-caspase-7 by serine proteases with varied specificities. The caspase-7 zymogen was rapidly activated by granzyme B and more slowly by subtilisin and cathepsin G, generating active enzymes with similar kinetic properties. Significantly, cathepsin G activated the zymogen by cleaving at a Gln-Ala bond, indicating that the canonical cleavage specificity at aspartic acid is not required for activation.

The solution structure of serine protease PB92 from Bacillus alcalophilus presents a rigid fold with a flexible substrate-binding site

BACKGROUND

Research on high-alkaline proteases, such as serine protease PB92, has been largely inspired by their industrial application as protein-degrading components of washing powders. Serine protease PB92 is a member of the subtilase family of enzymes, which has been extensively studied. These studies have included exhaustive protein engineering investigations and X-ray crystallography, in order to provide insight into the mechanism and specificity of enzyme catalysis. Distortions have been observed in the substrate-binding region of subtilisin crystal structures, due to crystal contacts. In addition, the structural variability in the substrate-binding region of subtilisins is often attributed to flexibility. It was hoped that the solution structure of this enzyme would provide further details about the conformation of this key region and give new insights into the functional properties of these enzymes.

RESULTS

The three-dimensional solution structure of the 269-residue (27 kDa) serine protease PB92 has been determined using distance and dihedral angle constraints derived from triple-resonance NMR data. The solution structure is represented by a family of 18 conformers which overlay onto the average structure with backbone and all-heavy-atom root mean square deviations (for the main body of the molecule) of 0.88 and 1.21 A, respectively. The family of structures contains a number of regions of relatively high conformational heterogeneity, including various segments that are involved in the formation of the substrate-binding site. The presence of flexibility within these segments has been established from NMR relaxation parameters and measurements of amide proton exchange rates.

CONCLUSIONS

The solution structure of the serine protease PB92 presents a well defined global fold which is rigid with the exception of a restricted number of sites. Among the limited number of residues involved in significant internal mobility are those of two pockets, termed S1 and S4, within the substrate-binding site. The presence of flexibility within the binding site supports the proposed induced fit mechanism of substrate binding.

Substrate specificity of the hepatitis C virus serine protease NS3

The substrate specificity of a purified protein encompassing the hepatitis C virus NS3 serine protease domain was investigated by introducing systematic modifications, including non-natural amino acids, into substrate peptides derived from the NS4A/NS4B cleavage site. Kinetic parameters were determined in the absence and presence of a peptide mimicking the protease co-factor NS4A (Pep4A). Based on this study we draw the following conclusions: (i) the NS3 protease domain has an absolute requirement for a small residue in the P1 position of substrates, thereby confirming previous modelling predictions. (ii) Optimization of the P1 binding site occupancy primarily influences transition state binding, whereas the occupancy of distal binding sites is a determinant for both ground state and transition state binding. (iii) Optimized contacts at distal binding sites may contribute synergistically to cleavage efficiency.

Crystal structure of varicella-zoster virus protease

Varicella-zoster virus (VZV), an alpha-herpes virus, is the causative agent of chickenpox, shingles, and postherpetic neuralgia. The three-dimensional crystal structure of the serine protease from VZV has been determined at 3.0-A resolution. The VZV protease is essential for the life cycle of the virus and is a potential target for therapeutic intervention. The structure reveals an overall fold that is similar to that recently reported for the serine protease from cytomegalovirus (CMV), a herpes virus of the beta subfamily. The VZV protease structure provides further evidence to support the finding that herpes virus proteases have a fold and active site distinct from other serine proteases. The VZV protease catalytic triad consists of a serine and two histidines. The distal histidine is proposed to properly orient the proximal histidine. The identification of an alpha-helical segment in the VZV protease that was mostly disordered in the CMV protease provides a better definition of the postulated active site cavity and reveals an elastase-like S' region. Structural differences between the VZV and CMV proteases also suggest potential differences in their oligomerization states.

Subtilases: the superfamily of subtilisin-like serine proteases

Subtilases are members of the clan (or superfamily) of subtilisin-like serine proteases. Over 200 subtilases are presently known, more than 170 of which with their complete amino acid sequence. In this update of our previous overview (Siezen RJ, de Vos WM, Leunissen JAM, Dijkstra BW, 1991, Protein Eng 4:719-731), details of more than 100 new subtilases discovered in the past five years are summarized, and amino acid sequences of their catalytic domains are compared in a multiple sequence alignment. Based on sequence homology, a subdivision into six families is proposed. Highly conserved residues of the catalytic domain are identified, as are large or unusual deletions and insertions. Predictions have been updated for Ca(2+)-binding sites, disulfide bonds, and substrate specificity, based on both sequence alignment and three-dimensional homology modeling.

The refined crystal structure of the 3C gene product from hepatitis A virus: specific proteinase activity and RNA recognition

The virally encoded 3C proteinases of picornaviruses process the polyprotein produced by the translation of polycistronic viral mRNA. The X-ray crystallographic structure of a catalytically active mutant of the hepatitis A virus (HAV) 3C proteinase (C24S) has been determined. Crystals of this mutant of HAV 3C are triclinic with unit cell dimensions a = 53.6 A, b = 53.5 A, c = 53.2 A, alpha = 99.1 degrees, beta = 129.0 degrees, and gamma = 103.3 degrees. There are two molecules of HAV 3C in the unit cell of this crystal form. The structure has been refined to an R factor of 0.211 (Rfree = 0.265) at 2.0-A resolution. Both molecules fold into the characteristic two-domain structure of the chymotrypsin-like serine proteinases. The active-site and substrate-binding regions are located in a surface groove between the two beta-barrel domains. The catalytic Cys 172 S(gamma) and His 44 N(epsilon2) are separated by 3.9 A; the oxyanion hole adopts the same conformation as that seen in the serine proteinases. The side chain of Asp 84, the residue expected to form the third member of the catalytic triad, is pointed away from the side chain of His 44 and is locked in an ion pair interaction with the epsilon-amino group of Lys 202. A water molecule is hydrogen bonded to His 44 N(delta1). The side-chain phenolic hydroxyl group of Tyr 143 is close to this water and to His 44 N(delta1) and may be negatively charged. The glutamine specificity for P1 residues of substrate cleavage sites is attributed to the presence of a highly conserved His 191 in the S1 pocket. A very unusual environment of two water molecules and a buried glutamate contribute to the imidazole tautomer believed to be important in the P1 specificity. HAV 3C proteinase has the conserved RNA recognition sequence KFRDI located in the interdomain connection loop on the side of the molecule diametrically opposite the proteolytic site. This segment of polypeptide is located between the N- and C-terminal helices, and its conformation results in the formation of a well-defined surface with a strongly charged electrostatic potential. Presumably, this surface of HAV 3C participates in the recognition of the 5' and 3' nontranslated regions of the RNA genome during viral replication.

Rational engineering of activity and specificity in a serine protease

The discovery of the Na(+)-dependent allosteric regulation in serine proteases makes it possible to control catalytic activity and specificity in this class of enzymes in a way never considered before. We demonstrate that rational site-directed mutagenesis of residues controlling Na+ binding can profoundly after the properties of a serine protease. By suppressing Na+ binding to thrombin, we shift the balance between procoagulant and anticoagulant activities of the enzyme. Those mutants, compared to wild-type, have reduced specificity toward fibrinogen, but enhanced or slightly reduced specificity toward protein C. Because this engineering strategy targets a fundamental regulatory mechanism, it is amenable of extension to other enzymes of biological and pharmacological importance.

Sheep mast cell proteinase-1: characterization as a member of a new class of dual-specific ruminant chymases

Sheep mast cell proteinase 1 (SMCP-1), which is abundantly expressed in gastrointestinal but not skin mast cells, was isolated and its substrate specificity was investigated. Peptide substrates, including angiotensin I, substance P, bradykinin and oxidized insulin B chain were hydrolysed at P1 Phe, Leu or Tyr residues, conforming to the known chymotrypsin-like properties of the enzyme. However, SMCP-1 was found to hydrolyse some chromogenic substrates with P1 Lys and Arg residues. The enzyme also demonstrated trypsin-like activity against protein substrates, cleaving BSA at Lys114-Leu115, Lys238-Val239, Lys260-Tyr261 and Lys376-His377. Bovine fibrinogen beta-chain was cleaved at Lys28-Lys29. To ensure homogeneity of the enzyme, the ratio of chymotrypsin-like to trypsin-like activity was observed; it was found to be constant during purification and between different preparations of SMCP-1. Treatment of SMCP-1 with a range of inhibitors decreased chymotrypsin-like and trypsin-like activities by similar extents, supporting the assertion that both activities are the property of a single enzyme. In terms of activity, and by N-terminal amino acid sequencing, SMCP-1 strongly resembles the similarly dual-specific bovine duodenal proteinase, duodenase. It is proposed that SMCP-1 and duodenase represent a new class of ruminant chymases with unusual dual specificities.

The role of disulfide bond C191-C220 in trypsin and chymotrypsin

Serine proteases of the chymotrypsin family contain three conserved disulfide bonds: C42-C58, C168-C182, and C191-C220. C191-C220 connects the loops around the substrate binding pocket. Using site directed mutagenesis, cysteines of this disulfide bridge were replaced by alanines in trypsin, in chymotrypsin, and in Tr-->Ch-[S1+L1+L2+Y172W], a mutant trypsin with high chymotrypsin like activity. The functional role of this "active site" disulfide was assessed by comparing the catalytic properties of wild-type and mutant enzymes. Its removal from all three proteases caused a decrease in kcat/KM of two to three orders of magnitude, mainly as a consequence of a dramatic increase in KM. The pH dependence of the activity also changed: the rather wide pH optimum, characteristic of the wild-type enzymes (especially trypsin), narrowed since the pKa in the alkaline region shifted downwards. Results show that C191-C220 is necessary for the high activity of both trypsin and chymotrypsin. By contrast, elimination of this disulfide bridge greatly decreased the specificity of trypsin and of Tr-->Ch-[S1+L1+L2+Y172W], but had no significant change on that of chymotrypsin.

Major proteinase movement upon stable serpin-proteinase complex formation

To determine whether formation of the stable complex between a serpin and a target proteinase involves a major translocation of the proteinase from its initial position in the noncovalent Michaelis complex, we have used fluorescence resonance energy transfer to measure the separation between fluorescein attached to a single cysteine on the serpin and tetramethylrhodamine conjugated to the proteinase. The interfluorophore separation was determined for the noncovalent Michaelis-like complex formed between alpha 1-proteinase inhibitor (Pittsburgh variant) and anhydrotrypsin and for the stable complex between the same serpin and trypsin. A difference in separation between the two fluorophores of approximately 21 A was found for the two types of complex. This demonstrates a major movement of the proteinase in going from the initial noncovalent encounter complex to the kinetically stable complex. The change in interfluorophore separation is most readily understood in terms of movement of the proteinase from the reactive center end of the serpin toward the distal end, as the covalently attached reactive center loop inserts into beta-sheet A of the serpin.

Identification of a hydrophobic exosite on tissue type plasminogen activator that modulates specificity for plasminogen

A wide variety of important biological processes, including both the formation and dissolution of blood clots, depend on specific cleavage of individual target proteins by serine proteases. For example, tissue type plasminogen activator (t-PA), a trypsin-like enzyme that catalyzes the rate-limiting step of the endogenous fibrinolytic cascade, has only one known substrate in vivo, a single peptide bond (Arg561-Val562) in the proenzyme plasminogen. We have previously suggested that the specificity of t-PA for plasminogen is mediated in part by direct protein-protein interactions between the protease domain of t-PA and plasminogen that are distinct from those occurring within t-PA's active site. We demonstrate in this study that residues 420-423 of t-PA, which form a fully solvent-exposed, hydrophobic region of a surface loop mapping near one edge of the active site of t-PA, form, or are essential for the integrity of, an important, secondary site of interaction between t-PA and plasminogen that significantly modulates the rate of plasminogen activation in the absence, but not the presence, of fibrin. Identification of this secondary site of interaction between t-PA and plasminogen provides new insight into molecular details of the evolution of stringent substrate specificity by t-PA and suggests a novel strategy to enhance the fibrin dependence of plasminogen activation by t-PA. While the activity of wild type t-PA is stimulated by fibrin by a factor of approximately 650, the activity of two variants characterized in this study, t-PA/R275E,P422G and t-PA/R275E,P422E, is stimulated by a factor of approximately 39,000 or 61,000, respectively. It is therefore possible that, compared with wild type t-PA, the two variants would display enhanced "clot selectivity" in vivo due to reduced activity in the circulation but full activity at a site of fibrin deposition.

Nonenzymatic anticoagulant activity of the mutant serine protease Ser360Ala-activated protein C mediated by factor Va

The human plasma serine protease, activated protein C (APC), primarily exerts its anticoagulant function by proteolytic inactivation of the blood coagulation cofactors Va and VIIIa. A recombinant active site Ser 360 to Ala mutation of protein C was prepared, and the mutant protein was expressed in human 293 kidney cells and purified. The activation peptide of the mutant protein C zymogen was cleaved by a snake venom activator, Protac C, but the "activated" S360A APC did not have amidolytic activity. However, it did exhibit significant anticoagulant activity both in clotting assays and in a purified protein assay system that measured prothrombinase activity. The S360A APC was compared to plasma-derived and wild-type recombinant APC. The anticoagulant activity of the mutant, but not native APC, was resistant to diisopropyl fluorophosphate, whereas all APCs were inhibited by monoclonal antibodies against APC. In contrast to native APC, S360A APC was not inactivated by serine protease inhibitors in plasma and did not bind to the highly reactive mutant protease inhibitor M358R alpha 1 antitrypsin. Since plasma serpins provide the major mechanism for inactivating APC in vivo, this suggests that S360A APC would have a long half-life in vivo, with potential therapeutic advantages. S360A APC rapidly inhibited factor Va in a nonenzymatic manner since it apparently did not proteolyze factor Va. These data suggest that native APC may exhibit rapid nonenzymatic anticoagulant activity followed by enzymatic irreversible proteolysis of factor Va. The results of clotting assays and prothrombinase assays showed that S360A APC could not inhibit the variant Gln 506-FVa compared with normal Arg 506-FVa, suggesting that the active site of S360A APC binds to FVa at or near Arg 506.

Catalytic hydroxyl/amine dyads within serine proteases

The 'catalytic triad' mechanism, which involves a serine, histidine and aspartic acid, has become synonymous with serine proteases. However, recently, mechanistically novel serine proteases have been discovered. These proteases use hydroxyl/epsilon-amine or hydroxyl/alpha-amine 'catalytic dyads' as their reactive centers.

Exploration of requirements for peptidomimetic immune recognition. Antigenic and immunogenic properties of reduced peptide bond pseudopeptide analogues of a histone hexapeptide

We present a detailed analysis of the antigenic and immunogenic properties of a series of very stable peptidomimetics of a model hexapeptide corresponding to the C-terminal residues 130-135 of histone H3. Five pseudopeptide analogues of the natural sequence IRGERA were synthesized by systematically replacing, in each analogue, one peptide bond at a time by a reduced peptide bond Psi(CH2-NH). Three important features of the resulting analogues were examined. First, the analogues were tested in a biosensor system for their ability to bind monoclonal antibodies generated against the parent natural peptide, and their kinetic rate constants were measured. The results show that reduced peptide bond analogues can very efficiently mimic the parent peptide. The position of reduced bonds which were deleterious for the binding was found to depend on the antibody tested, and one monoclonal antibody recognized all five analogues. The equilibrium affinity constant toward reduced peptide bond analogues of four antibodies of IgG1 isotype induced against the parent hexapeptide was higher (up to 670 times) with certain analogues than toward the homologous peptide. Second, immunogenic properties of the five analogues were studied, and it was found that polyclonal antibodies induced against analogues in which Psi(CH2-NH) bonds were introduced between residues 130-131, 131-132, and 132-133 (R1-R2, R2-R3, and R3-R4) cross-reacted strongly with the cognate protein H3. Third, we tested the protease resistance of analogues. Altogether, the results provide a strong support for the potent applicability of reduced peptide bond pseudopeptides as components of synthetic vaccines and open a new field for the development of immunomodulatory agents.