Probing the mechanism and improving the rate of substrate-assisted catalysis in subtilisin BPN'

Computational design of catalytic dyads and oxyanion holes for ester hydrolysis

Nucleophilic catalysis is a general strategy for accelerating ester and amide hydrolysis. In natural active sites, nucleophilic elements such as catalytic dyads and triads are usually paired with oxyanion holes for substrate activation, but it is difficult to parse out the independent contributions of these elements or to understand how they emerged in the course of evolution. Here we explore the minimal requirements for esterase activity by computationally designing artificial catalysts using catalytic dyads and oxyanion holes. We found much higher success rates using designed oxyanion holes formed by backbone NH groups rather than by side chains or bridging water molecules and obtained four active designs in different scaffolds by combining this motif with a Cys-His dyad. Following active site optimization, the most active of the variants exhibited a catalytic efficiency (k(cat)/K(M)) of 400 M(-1) s(-1) for the cleavage of a p-nitrophenyl ester. Kinetic experiments indicate that the active site cysteines are rapidly acylated as programmed by design, but the subsequent slow hydrolysis of the acyl-enzyme intermediate limits overall catalytic efficiency. Moreover, the Cys-His dyads are not properly formed in crystal structures of the designed enzymes. These results highlight the challenges that computational design must overcome to achieve high levels of activity.

Characterization and expression analysis of a trypsin-like serine protease from planarian Dugesia japonica

Trypsin-like serine proteases are involved in large number of processes, especially in digestive degradation and immune responses. Here, we identify the characterization of a trypsin-like serine protease in planarian, Djtry, which interestingly has the incompletely conserved catalytic triad (K, D, and S). Phylogenetic analysis suggests that Djtry is an ancient type of trypsin-like serine proteases. The spatial and temporal expression patterns of Djtry are shown during regenerating and embryonic development by whole-mount in situ hybridization. Djtry is found to display a tissue specific expression pattern, with a predominant expression detected in whole gut region of intact and regenerating planarian. While the tissue- and stage-specific expression patterns during the embryonic development imply the roles of Djtry involve in yolk degradation and gut formation. Quantitative real-time PCR was carried out to analyze the function of this protease in vivo after planarians were stimulated to a bacterial challenge and food. The results showed that Djtry increased after a bacterial challenge and was basically stable for food. Therefore, the trypsin-like serine protease might be involved in the innate defense reactions against bacterial infection.

[Expression and enzyme activity analysis of Djtry in planarian Dugesia japonica]

The cDNA Djtry, encoding a planarian trypsin, was identified from the cDNA library of Dugesia japonica. Multiple alignment analysis showed that the Tryps_SPc domain contained the incompletely conserved catalytic triad in which the first amino acid His was substituted by Lys. Phylogenetic analysis indicateed that Djtry protein falls at the base of other animal trypsins. The Djtry cDNA was cloned into a bacterial vector pET-28a and was transferred into E. coli BL21. The His-tagged Djtry fusion protein expression was induced by IPTG. SDS-PAGE analysis revealed that the Djtry was expressed as inclusion bodies in E. coli BL21 with the estimated molecular weight of approximately 26 kDa. Western blotting with His-tag antibody showed that the antibody was reacted with the fusion protein after refolding. Compared to bovine trypsin using BAEE as special substrate of trypsin, the enzyme activity of Djtry was measured. These results indicate that Djtry represents the archetype of animal trypsins, and this type of mutational trypsin Djtry still performs the trypsin nature with slightly weaker activity.

Phytotoxicity of sarmentine isolated from long pepper (Piper longum) fruit

Discovery of novel natural herbicides has become crucial to overcome increasing weed resistance and environmental issues. In this article, we describe the finding that a methanol extract of dry long pepper (Piper longum L.) fruits is phytotoxic to lettuce (Lactuca sativa L.) seedlings. The bioassay-guided fractionation and purification of the crude extract led to isolation of sarmentine (1), a known compound, as the active principle. Phytotoxicity of 1 was examined with a variety of seedlings of field crops and weeds. Results indicated that 1 was a contact herbicide and possessed broad-spectrum herbicidal activity. Moreover, a series of sarmentine analogues were then synthesized to study the structure-activity relationship (SAR). SAR studies suggested that phytotoxicity of sarmentine and its analogues was specific due to chemical structures, i.e., the analogues of the acid moiety of 1 were active, but the amine and its analogues were inactive; the ester analogues and amide analogues with a primary amine of 1 were also inactive. In addition, quantification of 1 from different resources of the dry P. longum fruits using liquid chromatography-mass spectrometry showed a wide variation, ranging from almost zero to 0.57%. This study suggests that 1 has potential as an active lead molecule for synthesized herbicides as well as for bioherbicides derived from natural resources.

Engineering substrate preference in subtilisin: structural and kinetic analysis of a specificity mutant

Bacillus subtilisin has been a popular model protein for engineering altered substrate specificity. Although some studies have succeeded in increasing the specificity of subtilisin, they also demonstrate that high specificity is difficult to achieve solely by engineering selective substrate binding. In this paper, we analyze the structure and transient state kinetic behavior of Sbt160, a subtilisin engineered to strongly prefer substrates with phenylalanine or tyrosine at the P4 position. As in previous studies, we measure improvements in substrate affinity and overall specificity. Structural analysis of an inactive version of Sbt160 in complex with its cognate substrate reveals improved interactions at the S4 subsite with a P4 tyrosine. Comparison of transient state kinetic behavior against an optimal sequence (DFKAM) and a similar, but suboptimal, sequence (DVRAF) reveals the kinetic and thermodynamic basis for increased specificity, as well as the limitations of this approach. While highly selective substrate binding is achieved in Sbt160, several factors cause sequence specificity to fall short of that observed with natural processing subtilisins. First, for substrate sequences which are nearly optimal, the acylation reaction becomes faster than substrate dissociation. As a result, the level of discrimination among these substrates diminishes due to the coupling between substrate binding and the first chemical step (acylation). Second, although Sbt160 has 24-fold higher substrate affinity for the optimal substrate DFKAM than for DVRAF, the increased substrate binding energy is not translated into improved transition state stabilization of the acylation reaction. Finally, as interactions at subsites become stronger, the rate-determining step in peptide hydrolysis changes from acylation to product release. Thus, the release of the product becomes sluggish and leads to a low k(cat) for the reaction. This also leads to strong product inhibition of substrate turnover as the reaction progresses. The structural and kinetic analysis reveals that differences in the binding modes at subsites for substrates, transition states, and products are subtle and difficult to manipulate via straightforward protein engineering. These findings suggest several new strategies for engineering highly sequence selective enzymes.

Structure and function of fatty acid amide hydrolase

Fatty acid amide hydrolase (FAAH) is a mammalian integral membrane enzyme that degrades the fatty acid amide family of endogenous signaling lipids, which includes the endogenous cannabinoid anandamide and the sleep-inducing substance oleamide. FAAH belongs to a large and diverse class of enzymes referred to as the amidase signature (AS) family. Investigations into the structure and function of FAAH, in combination with complementary studies of other AS enzymes, have engendered provocative molecular models to explain how this enzyme integrates into cell membranes and terminates fatty acid amide signaling in vivo. These studies, as well as their biological and therapeutic implications, are the subject of this review.

Construction of a 3D model of nattokinase, a novel fibrinolytic enzyme from Bacillus natto. A novel nucleophilic catalytic mechanism for nattokinase

A three-dimensional structural model of nattokinase (NK) from Bacillus natto was constructed by homology modeling. High-resolution X-ray structures of Subtilisin BPN' (SB), Subtilisin Carlsberg (SC), Subtilisin E (SE) and Subtilisin Savinase (SS), four proteins with sequential, structural and functional homology were used as templates. Initial models of NK were built by MODELLER and analyzed by the PROCHECK programs. The best quality model was chosen for further refinement by constrained molecular dynamics simulations. The overall quality of the refined model was evaluated. The refined model NKC1 was analyzed by different protein analysis programs including PROCHECK for the evaluation of Ramachandran plot quality, PROSA for testing interaction energies and WHATIF for the calculation of packing quality. This structure was found to be satisfactory and also stable at room temperature as demonstrated by a 300ps long unconstrained molecular dynamics (MD) simulation. Further docking analysis promoted the coming of a new nucleophilic catalytic mechanism for NK, which is induced by attacking of hydroxyl rich in catalytic environment and locating of S221.

H662 is the linchpin of ATP hydrolysis in the nucleotide-binding domain of the ABC transporter HlyB

The ABC transporter HlyB is a central element of the HlyA secretion machinery, a paradigm of Type I secretion. Here, we describe the crystal structure of the HlyB-NBD (nucleotide-binding domain) with H662 replaced by Ala in complex with ATP/Mg2+. The dimer shows a composite architecture, in which two intact ATP molecules are bound at the interface of the Walker A motif and the C-loop, provided by the two monomers. ATPase measurements confirm that H662 is essential for activity. Based on these data, we propose a model in which E631 and H662, highly conserved among ABC transporters, form a catalytic dyad. Here, H662 acts as a 'linchpin', holding together all required parts of a complicated network of interactions between ATP, water molecules, Mg2+, and amino acids both in cis and trans, necessary for intermonomer communication. Based on biochemical experiments, we discuss the hypothesis that substrate-assisted catalysis, rather than general base catalysis might operate in ABC-ATPases.

Tyrosine 547 Constitutes an Essential Part of the Catalytic Mechanism of Dipeptidyl Peptidase IV

Human dipeptidyl peptidase IV (DPP-IV) is a ubiquitously expressed type II transmembrane serine protease. It cleaves the penultimate positioned prolyl bonds at the N terminus of physiologically important peptides such as the incretin hormones glucagon-like peptide 1 and glucose-dependent insulinotropic peptide. In this study, we have characterized different active site mutants. The Y547F mutant as well as the catalytic triad mutants S630A, D708A, and H740L showed less than 1% wild type activity. X-ray crystal structure analysis of the Y547F mutant revealed no overall changes compared with wild type apoDPP-IV, except the ablation of the hydroxyl group of Tyr(547) and a water molecule positioned in close proximity to Tyr(547). To elucidate further the reaction mechanism, we determined the crystal structure of DPP-IV in complex with diisopropyl fluorophosphate, mimicking the tetrahedral intermediate. The kinetic and structural findings of the tyrosine residue are discussed in relation to the catalytic mechanism of DPP-IV and to the inhibitory mechanism of the 2-cyanopyrrolidine class of potent DPP-IV inhibitors, proposing an explanation for the specificity of this class of inhibitors for the S9b family among serine proteases.

Evidence for distinct roles in catalysis for residues of the serine-serine-lysine catalytic triad of fatty acid amide hydrolase

Fatty acid amide hydrolase (FAAH) is a mammalian amidase signature enzyme that inactivates neuromodulatory fatty acid amides, including the endogenous cannabinoid anandamide and the sleep-inducing substance oleamide. The recent determination of the three-dimensional structures of FAAH and two distantly related bacterial amidase signature enzymes indicates that these enzymes employ an unusual serine-serine-lysine triad for catalysis (Ser-241/Ser-217/Lys-142 in FAAH). Mutagenesis of each of the triad residues in FAAH has been shown to severely reduce amidase activity; however, how these residues contribute, both individually and in cooperation, to catalysis remains unclear. Here, through a combination of site-directed mutagenesis, enzyme kinetics, and chemical labeling experiments, we provide evidence that each FAAH triad residue plays a distinct role in catalysis. In particular, the mutation of Lys-142 to alanine indicates that this residue functions as both a base involved in the activation of the Ser-241 nucleophile and an acid that participates in the protonation of the substrate leaving group. This latter property appears to support the unusual ability of FAAH to hydrolyze amides and esters at equivalent rates. Interestingly, although structural evidence indicates that the impact of Lys-142 on catalysis probably occurs through the bridging Ser-217, the mutation of this latter residue to alanine impaired catalytic activity but left the amide/ester hydrolysis ratios of FAAH intact. Collectively, these findings suggest that FAAH possesses a specialized active site structure dedicated to a mechanism for competitive amide and ester hydrolysis where nucleophile attack and leaving group protonation occur in a coordinated manner dependent on Lys-142.

PvuII-endonuclease induces structural alterations at the scissile phosphate group of its cognate DNA

We investigated the PvuII endonuclease with its cognate DNA by means of molecular dynamics simulations. Comparing the complexed DNA with a reference simulation of free DNA, we saw structural changes at the scissile phosphodiester bond. At this GpC step, the enzyme induces the highest twist and axial rise, inclination is increased and the minor groove widened. The distance between the scissile phosphate group and the phosphate group of the following thymine base is shortened significantly, indicating a substrate-assisted catalysis. A feasible reason for this vicinity is the catalytically important amino acid residue lysine 70, which bridges the free oxygen atoms of the successive phosphate groups. Due to this geometry, a compact reaction pocket is formed where a water molecule can be held, thus bringing the reaction partners for hydrolysis into contact. The O1-P-O2 angle of the scissile nucleotide is decreased, probably due to a complexation of the negative oxygen atoms through protein and solvent contacts.

Changes in zinc ligation promote remodeling of the active site in the zinc hydrolase superfamily

The zinc hydrolase superfamily is a group of divergently related proteins that are predominantly enzymes with a zinc-based catalytic mechanism. The common structural scaffold of the superfamily consists of an eight-stranded beta-sheet flanked by six alpha-helices. Previous analyses, while acknowledging the likely divergent origins of leucine aminopeptidase, carboxypeptidase A and the co-catalytic enzymes of the metallopeptidase H clan based on their structural scaffolds, have failed to find any homology between the active sites in leucine aminopeptidase and the metallopeptidase H clan enzymes. Here we show that these two groups of co-catalytic enzymes have overlapping dizinc centers where one of the two zinc atoms is conserved in each group. Carboxypeptidase A and leucine aminopeptidase, on the other hand, no longer share any homologous zinc-binding sites. At least three catalytic zinc-binding sites have existed in the structural scaffold over the period of history defined by available structures. Comparison of enzyme-inhibitor complexes show that major remodeling of the substrate-binding site has occurred in association with each change in zinc ligation in the binding site. These changes involve re-registration and re-orientation of the substrate. Some residues important to the catalytic mechanism are not conserved amongst members. We discuss how molecules acting in trans may have facilitated the mutation of catalytically important residues in the active site in this group.

Construction of high-complexity combinatorial phage display peptide libraries

Random peptide libraries displayed on the surface of filamentous bacteriophage are widely used as tools for the discovery of ligands for biologically relevant macromolecules, including antibodies, enzymes, and cell surface receptors. Phage display results in linkage of an affinity-selectable function (the displayed peptide) to the DNA encoding that function, allowing selection of individual binding clones by iterative cycles of in vitro panning and in vivo amplification. Critical to the success of a panning experiment is the complexity of the library: the greater the diversity of clones within the library, the more likely the library contains sequences that will bind a given target with useful affinity. A method for construction of high-complexity (> or = 10(9) independent clones) random peptide libraries is presented. The key steps are highly efficient binary ligation under conditions where the vector is relatively dilute, with only a modest molar excess of insert, followed by efficient electrotransformation into Escherichia coli. Library design strategies and a protocol for rapid sequence characterization are also presented.

Protein engineering of subtilisin

The serine protease subtilisin is an important industrial enzyme as well as a model for understanding the enormous rate enhancements affected by enzymes. For these reasons along with the timely cloning of the gene, ease of expression and purification and availability of atomic resolution structures, subtilisin became a model system for protein engineering studies in the 1980s. Fifteen years later, mutations in well over 50% of the 275 amino acids of subtilisin have been reported in the scientific literature. Most subtilisin engineering has involved catalytic amino acids, substrate binding regions and stabilizing mutations. Stability has been the property of subtilisin which has been most amenable to enhancement, yet perhaps least understood. This review will give a brief overview of the subtilisin engineering field, critically review what has been learned about subtilisin stability from protein engineering experiments and conclude with some speculation about the prospects for future subtilisin engineering.

Substrate-assisted catalysis: molecular basis and biological significance

Substrate-assisted catalysis (SAC) is the process by which a functional group in a substrate contributes to catalysis by an enzyme. SAC has been demonstrated for representatives of three major enzyme classes: serine proteases, GTPases, and type II restriction endonucleases, as well as lysozyme and hexose-1-phosphate uridylyltransferase. Moreover, structure-based predictions of SAC have been made for many additional enzymes. Examples of SAC include both naturally occurring enzymes such as type II restriction endonucleases as well as engineered enzymes including serine proteases. In the latter case, a functional group from a substrate can substitute for a catalytic residue replaced by site-directed mutagenesis. From a protein engineering perspective, SAC provides a strategy for drastically changing enzyme substrate specificity or even the reaction catalyzed. From a biological viewpoint, SAC contributes significantly to the activity of some enzymes and may represent a functional intermediate in the evolution of catalysis. This review focuses on advances in engineering enzyme specificity and activity by SAC, together with the biological significance of this phenomenon.

Elastase substrate specificity tailored through substrate-assisted catalysis and phage display

The catalytic histidine of human neutrophil elastase was replaced with alanine (H57A) to determine if a substrate histidine could substitute for the missing catalytic group-'substrate-assisted catalysis'. H57A and wild-type elastase were recovered directly from Pichia pastoris following expression from a synthetic gene lacking the elastase pro sequence, thereby obviating the need for zymogen activation. Potential histidine-containing substrates for H57A elastase were identified from a phage library of randomized sequences. One such sequence, REHVVY, was cleaved by H57A elastase with a catalytic efficiency, k(cat)/K(M), of 2800 s(-1) M(-1), that is within 160-fold of wild-type elastase. In contrast, wild-type but not H57A elastase cleaved the related non-histidine containing sequence, REAVVY. Ten different histidine-containing linkers were cleaved by H57A elastase. In addition to the requirement for a P2 histidine, significant preferences were observed at other subsites including valine or threonine at P1, and methionine or arginine at P4. A designed sequence, MEHVVY, containing the preferred residues identified at each subsite proved to be a more favorable substrate than any of the phage-derived sequences. Extension of substrate-assisted catalysis to elastase suggests that this engineering strategy may be widely applicable to other serine proteases thereby creating a family of highly specific histidine-dependant proteases.

Substrate-Assisted Catalysis in Sialic Acid Aldolase

Sialic acid aldolase catalyses the reversible aldol condensation of pyruvate and N-acetylmannosamine with an apparent lack of stereospecificity. Consistent with this, modeling of Schiff base and enamine intermediates in the active site of this enzyme yields two conformations, corresponding to si- and re-face attack in the aldol condensation reaction. The acceptor-aldehyde group is found on different sides of the enamine in the two conformations, but with the remainder of the substrate having very similar geometries in the protein. No histidine residue previously speculated to function as a general base in the mechanism is found near the enzyme active site. In the absence of functionally active groups in the active site, the carboxylate of the substrate is proposed to function as the general acid/base. Molecular orbital calculations indicate that the barrier to aldol cleavage via this mechanism in the gas phase of the related system, 4-hydroxy-2-methyiminopentanoic acid, is 74 kJ mol(-)(1).

Crystallization and preliminary X-ray analysis of a 1:1 complex between a designed monomeric interferon-gamma and its soluble receptor

A variant of human interferon-gamma (IFN-gamma) has been created in which the two chains of the homodimeric cytokine were linked N- to C-terminus by an eight residue polypeptide linker. The sequence of this linker was derived from a loop in bira bifunctional protein, and was determined from a structural database search. This "single-chain" variant was used to create an IFN-gamma molecule that binds only a single copy of the alpha-chain receptor, rather than the 2 alpha-chain receptor: 1 IFN-gamma binding stoichiometry observed for the native hormone. Crystals have been grown of a 1:1 complex between this single-chain molecule and the extracellular domain of its alpha-chain receptor. These crystals diffract beyond 2.0 A, significantly better than the 2.9 A observed for the native 2:1 complex. Density calculations suggest these crystals contain two complexes in the asymmetric unit; a self-rotation function confirms this conclusion.

Rescue of a mutant G-protein by substrate-assisted catalysis

Signaling by guanine-nucleotide-binding proteins (G-proteins) occurs when they are charged with GTP, while hydrolysis of the bound nucleotide turns the signaling off. Despite a wealth of biochemical and structural information, the mechanism of GTP hydrolysis by G-proteins remains controversial. We have employed substrate-assisted catalysis as a novel approach to study catalysis by G-proteins. In these studies, we have used diaminobenzophenone-phosphonoamidate-GTP, a unique GTP analog bearing the functional groups that are missing in the GTPase-deficient [Leu227]G(s alpha) mutant. This mutant, found in various human tumors, fails to hydrolyze GTP for an extended period. In contrast, the GTP analog is hydrolyzed by this mutant and by the wild-type enzyme at the same rate. On the other hand, modification of G(s alpha) by cholera toxin, which catalyses ADP-ribosylation of Arg201 of G(s alpha), decreased the rates of hydrolysis of both GTP and its analog by 95%. These results attest to the specificity of the GTP analog as a unique substrate for the [Leu227]G(s alpha) mutant and to the essential role of Gln227 in GTP hydrolysis. Furthermore, the finding that the GTP analog was hydrolyzed at the same rate as GTP by the wild-type enzyme, favors a model in which formation of a pentavalent transition state intermediate, presumably stabilized by the catalytic glutamine, is not the rate-limiting step of the GTPase reaction.

On the failure of de novo-designed peptides as biocatalysts

While the elegance and efficiency of enzymatic catalysis have long tempted chemists and biochemists with reductionist leanings to try to mimic the functions of natural enzymes in much smaller peptides, such efforts have only rarely produced catalysts with biologically interesting properties. However, the advent of genetic engineering and hybridoma technology and the discovery of catalytic RNA have led to new and very promising alternative means of biocatalyst development. Synthetic chemists have also had some success in creating nonpeptide catalysts with certain enzyme-like characteristics, although their rates and specificities are generally much poorer than those exhibited by the best novel biocatalysts based on natural structures. A comparison of the various approaches from theoretical and practical viewpoints is presented. It is suggested that, given our current level of understanding, the most fruitful methods may incorporate both iterative selection strategies and rationally chosen small perturbations, superimposed on frameworks designed by nature.

Biologically active peptides and enzymatic approaches to their production

This review briefly surveys various classes of biologically active and flavor peptides that have been isolated and characterized in recent years, and analyzes emerging trends and advances in biotechnological methods for their production.

Homologous expression and purification of mutants of an essential protein by reverse epitope-tagging

Purification of mutant enzymes is a prime requirement of biophysical and biochemical studies. Our investigations on the essential Escherichia coli enzyme glutaminyl-tRNA synthetase demand mutant enzymes free of any wild-type protein contamination. However, as it is not possible to express noncomplementing mutant enzymes in an E. coli glnS-deletion strain, we developed a novel strategy to address these problems. Instead of following the common tactic of epitope-tagging the mutant protein of interest on an extrachromosomal genetic element, we fused a reporter epitope to the 5' end of the chromosomal glnS-gene copy: this is referred to as 'reverse epitope-tagging.' The corresponding strain, E. coli HAPPY101, displays a normal phenotype, and glutaminyl-tRNA synthetase is exclusively present as an epitope-tagged form in cell-free extracts. Here we report the use of E. coli HAPPY101 to express and purify a number of mutant glutaminyl-tRNA synthetases independently of their enzymatic activity. In this process, epitope-tagged wild-type protein is readily separated from mutant enzymes by conventional chromatographic methods. In addition, the absence of wild-type can be monitored by immunodetection using a monoclonal antibody specific for the epitope. The strategy described here for expression and purification of an essential enzyme is not restricted to glutaminyl-tRNA synthetase and should be applicable to any essential enzyme that retains sufficient activity to sustain growth following reverse epitope-tagging.

Depletion and replacement of protein metal ligands

Recently, site-directed mutagenesis has been applied to protein-derived metal ligands in a way that permits the replacement in trans of protein ligands. The chemical diversity of ligands available using this method far exceeds that attainable using standard mutagenesis. Non-conservative ligand replacement can yield novel metalloproteins with altered ligand-binding, enzymatic activities, and spectroscopic properties. Conservative ligand substitution, or 'ligand detachment', allows the structural and functional effects of the covalent linkage between the ligand and the protein to be evaluated; this linkage is often proposed to play a critical role in modulating the structure and reactivity of the metal center. Furthermore, this method can be exploited to study the details of molecular recognition at the structural, thermodynamic, and dynamic levels.

Structural basis of substrate specificity in the serine proteases

Structure-based mutational analysis of serine protease specificity has produced a large database of information useful in addressing biological function and in establishing a basis for targeted design efforts. Critical issues examined include the function of water molecules in providing strength and specificity of binding, the extent to which binding subsites are interdependent, and the roles of polypeptide chain flexibility and distal structural elements in contributing to specificity profiles. The studies also provide a foundation for exploring why specificity modification can be either straightforward or complex, depending on the particular system.

Generation of soluble interleukin-1 receptor from an immunoadhesin by specific cleavage

The extracellular portion of the interleukin-1 receptor (IL-1R) is sufficient for high-affinity binding to IL-1; however, the structural basis for binding of the receptor to IL-1 is not known. To produce individual domains of IL-1 receptor for structural studies, we constructed a molecular fusion of IL-1 receptor with immunoglobulin G heavy chain that contains a protease specific sequence joining the two portions of the molecule (IL-1R-G-IgG). We introduced the hexapeptide sequence AAHY:TL (where ":" denotes the scissile bond) at the junction of the IL-1R and IgG regions, for specific cleavage by an H64A variant of subtilisin BPN' (Genenase I), an endoprotease that cleaves selectively at this sequence (Carter et al., (1989) Proteins 6, 240-248). Plasmid DNA encoding the fusion protein was used to transfect human embryonic kidney 293 cells transiently, and secreted IL-1R-G-IgG was purified from cell supernatants by protein A chromatography. The IL-1 receptor's extracellular region was then generated by enzymatic cleavage with Genenase I which was immobilized on controlled-pore glass. Incubation of IL-1R-G-IgG with immobilized Genenase I resulted in specific cleavage at the target site, as confirmed by SDS-PAGE, immunoblotting and direct sequencing of the newly generated termini. The resulting soluble IL-1R was separated from the immunoglobulin Fc cleavage product by re-chromatography on protein A. The purified, soluble IL-1R retained quantitatively the ability to bind to its ligand, IL-1 beta. This approach offers a generic means by which the extracellular region of a given type I transmembrane receptor can be expressed as an immunoadhesin, released enzymatically and then easily purified for crystallographic or ligand binding studies.

Engineering proteins to facilitate bioprocessing

Genetic engineering is now being applied to aid the purification of recombinant proteins. The addition of specifically designed tags or the modification of sequences within the target-gene product has enabled the development of novel strategies for downstream processing that can be employed for efficient recovery of both native or modified proteins. This article discusses novel trends in genetic engineering that aid the bioprocessing of recombinant proteins.

Structural basis for type I and type II deficiencies of antithrombotic plasma protein C: patterns revealed by three-dimensional molecular modelling of mutations of the protease domain

Familial deficiency of protein C is associated with inherited thrombophilia. To explore how specific missense mutations might cause observed clinical phenotypes, know protein C missense mutations were mapped onto three-dimensional homology models of the protein C protease domain, and the implications for domain folding and structure were evaluated. Most Type I missense mutations either replaced internal hydrophobic residues (I201T, L223F, A259V, A267T, A346T, A346V, G376D) or nearby interacting residues (I403M, T298M, Q184H), thus disrupting the packing of internal hydrophobic side chains, or changed hydrophilic residues, thus disrupting ion pairs (N256D, R178W). Mutations (P168L, R169W) at the activation site destabilized the region containing the activation peptide structure. Most Type II mutations involved solvent-exposed residues and were clustered either in a positively charged region (R147W, R157Q, R229Q, R352W) or were located in or near the active site region (S252N, D359N, G381S, G391S, H211Q). The cluster of arginines 147, 157, 229, and 352 may identify a functionally important exosite. Identification of the spatial relationships of natural mutations in the protein C model is helpful for understanding manifestations of protein C deficiency and for identification of novel, functionally important molecular features and exosites.

Variants of subtilisin BPN' with altered specificity profiles

A strategy for increasing the size of the S4 binding pocket was used to improve the specificity of subtilisin BPN' toward substrates with large hydrophobic P4 side chains. This approach involves single and double amino acid replacements at positions 104, 107, and 126. Previously, alteration of I107 to glycine has been found to increase the specificity of subtilisin toward leucine, isoleucine, and phenylalanine as P4 residues by up to 214-fold. Replacement of Y104 by alanine also yields a similar improvement in specificity. However, this subtilisin variant favors isoleucine and phenylalanine over leucine. When L126 was replaced by valine, alanine, and glycine, respectively, only the L126A subtilisin variant, which possesses a 28-fold-increased catalytic efficiency for isoleucine compared with all other substrates tested, showed a significantly improved specificity profile. As inferred from the double-mutant enzymes I107G/L126V, I107G/L126A, and I107G/Y104A, none of the effects of the single amino acid replacements on the kinetic parameters are additive. The I107G/L126V mutant subtilisin has the largest improvement in P4 substrate specificity reported so far: kcat/KM is increased 340-fold for leucine compared to alanine. By contrast, the specificity profile of the I107G/Y104A mutant enzyme is impaired in comparison with that of the corresponding single mutants. Therefore, the design of high-specificity subtilisin variants through the combination of single amino acid replacements in the S4 pocket appears to be nontrivial due to the interference of the introduced structural changes.

Converting tissue plasminogen activator to a zymogen: a regulatory triad of Asp-His-Ser

Unlike most serine proteases of the chymotrypsin family, tissue-type plasminogen activator (tPA) is secreted from cells as an active, single-chain enzyme with a catalytic efficiency only slightly lower than that of the proteolytically cleaved form. A zymogenic mutant of tPA has been engineered that displays a reduction in catalytic efficiency by a factor of 141 in the single-chain form while retaining full activity in the cleaved form. The residues introduced in the mutant, serine 292 and histidine 305, are proposed to form a hydrogen-bonded network with aspartate 477, similar to the aspartate 194-histidine 40-serine 32 network found to stabilize the zymogen chymotrypsinogen.

Breaching the conformational integrity of the catalytic triad of the serine protease plasmin: localized disruption of a side chain of His-603 strongly inhibits the amidolytic activity of human plasmin

Site-directed mutagenesis has been used to construct a cDNA that encodes a recombinant variant human plasminogen (hPg) containing a Pro-611-->Ile mutation (MrhPg). The mutein was expressed in recombinant baculovirus-infected Spodoptera frugiperda cells (IPLB-SF-21AE), and purified. After activation of this zymogen to its corresponding form of the serine protease plasmin (MrhPm), this latter enzyme was essentially inactive toward an amide plasmin substrate, most likely from alteration of the spatial relationships of the active-site His-603 to its partners of the catalytic triad, Asp-646 and Ser-741. Partial amidolytic activity of MrhPm was restored as a consequence of imidazole addition to the assay medium, due to an increase in the catalytic constant kcat of the enzyme. The serine protease inhibitor, diisopropylphosphofluoridate, when preincubated with MrhPm, did not inhibit restoration of its amidolytic activity with imidazole, whereas diisopropylphosphofluoridate did inhibit the amidolytic activity of MrhPm in the presence of imidazole. This result implies that His-603 directly influences the nucleophilic character of Ser-741. When imidazole as pretreated with alpha-N-tosyl-L-lysine chloromethyl ketone, the ability of this imidazole solution to restore amidolytic activity to MrhPm was eliminated, suggesting that N alpha-(p-tosyl)lysine chloromethyl ketone directs into the binding pocket a derivatized form of imidazole, which is ineffective as an His-603 substitute. These results indicate that the conformational reorientation of His-603 results in a malfunctional catalytic triad in the serine protease MrhPm, thus leading to an inactive enzyme despite the presence of all three essential amino acids of the catalytic triad. Addition of extramolecular imidazole restores a portion of the amidolytic activity of this mutant enzyme. These data also argue for an enzyme mechanism in which the active-center His-603 residue directly influences the nucleophilicity of the active-site Ser 741 residue.

Substrate phage: selection of protease substrates by monovalent phage display

A method is described here for identifying good protease substrates among approximately 10(7) possible sequences. A library of fusion proteins was constructed containing an amino-terminal domain used to bind to an affinity support, followed by a randomized protease substrate sequence and the carboxyl-terminal domain of M13 gene III. Each fusion protein was displayed as a single copy on filamentous phagemid particles (substrate phage). Phage were then bound to an affinity support and treated with the protease of interest. Phage with good protease substrates were released, whereas phage with substrates that resisted proteolysis remained bound. After several rounds of binding, proteolysis, and phagemid propagation, sensitive and resistant substrate sequences were identified for two different proteases, a variant of subtilisin and factor Xa. The technique may also be useful for studying the sequence specificity of a variety of posttranslational modifications.

Engineering a novel specificity in subtilisin BPN'

The specificity of subtilisin BPN' toward substrates with large hydrophobic P4 residues has been improved by single amino acid replacements at positions 104 and 107. Mutations were designed to (i) increase the size of the P4 binding pocket by replacing Ile107, which is at the bottom of the S4 pocket, by Val, Ala, and Gly and (ii) lose the hydrogen bond between Tyr104 and Ser130 at the entrance of the P4 binding pocket by changing Tyr104 to Phe and thus reduce interactions between small P4 side chains and residue 104. All mutant subtilisins, except for I107V, have increased specificity for residues with large side chains at P4 compared with wild type. Using the conventional definition of specificity as the competition of different substrates for the same enzyme, the I107G mutant subtilisin has one of the largest improvements in substrate specificity reported for subtilisin so far; kcat/KM is increased > 200-fold for Phe compared with Ala as the P4 residue. Further, the activity of I107G toward its specific substrate is comparable to that of the wild-type enzyme. Surprisingly, much of the increase in specificity on mutation of Ile107-->Gly appears to result from a lesion that is transmitted through the structure and effects catalysis. The value of kcat/KM for the small substrate acetyltyrosine ethyl ester, which binds to the S1 pocket, drops by 93% on mutation of Ile107-->Gly. The lesion in subtilisin I107G is complemented, however, on binding of longer substrates that have a large hydrophobic P4 amino acid side chain that can bind in the S4 pocket.

New recombinant DNA methodology for protein engineering

Over the past year considerable progress has been made in the application of recombinant DNA technology to protein engineering. A number of new methods for gene synthesis and mutagenesis have been reported that simplify the construction of novel coding sequences. The polymerase chain reaction plays an increasingly important role in these methods. Amino acid diversity has been extended by the incorporation of unnatural amino acids via coupled in vitro transcription-translation methods. Novel random mutagenesis strategies have been developed that substitute amino acids with a desired chemical character at a given position, thereby generating a sophisticated library of protein variants.