Inhibitory serpins from wheat grain with reactive centers resembling glutamine-rich repeats of prolamin storage proteins. Cloning and characterization of five major molecular forms

Genes encoding proteins of the serpin superfamily are widespread in the plant kingdom, but the properties of very few plant serpins have been studied, and physiological functions have not been elucidated. Six distinct serpins have been identified in grains of hexaploid bread wheat (Triticum aestivum L.) by partial purification and amino acid sequencing. The reactive centers of all but one of the serpins resemble the glutamine-rich repetitive sequences in prolamin storage proteins of wheat grain. Five of the serpins, classified into two protein Z subfamilies, WSZ1 and WSZ2, have been cloned, expressed in Escherichia coli, and purified. Inhibitory specificity toward 17 proteinases of mammalian, plant, and microbial origin was studied. All five serpins were suicide substrate inhibitors of chymotrypsin and cathepsin G. WSZ1a and WSZ1b inhibited at the unusual reactive center P(1)-P(1)' Gln-Gln, and WSZ2b at P(2)-P(1) Leu-Arg-one of two overlapping reactive centers. WSZ1c with P(1)-P(1)' Leu-Gln was the fastest inhibitor of chymotrypsin (k(a) = 1.3 x 10(6) m(-1) s(-1)). WSZ1a was as efficient an inhibitor of chymotrypsin as WSZ2a (k(a) approximately 10(5) m(-1) s(-1)), which has P(1)-P(1)' Leu-Ser-a reactive center common in animal serpins. WSZ2b inhibited plasmin at P(1)-P(1)' Arg-Gln (k(a) approximately 10(3) m(-1) s(-1)). None of the five serpins inhibited Bacillus subtilisin A, Fusarium trypsin, or two subtilisin-like plant serine proteinases, hordolisin from barley green malt and cucumisin D from honeydew melon. Possible functions involving interactions with endogenous or exogenous proteinases adapted to prolamin degradation are discussed.     

Alteration of serpin specificity by a protein cofactor. Vitronectin endows plasminogen activator inhibitor 1 with thrombin inhibitory properties.

Serine protease inhibitors ("serpins") are highly homologous proteins which inhibit selected "target" serine proteases by acting as a pseudo-substrate. Their specificity is primarily determined by the amino acid sequence around the carboxyl-terminally located reactive center (P1-P1'). In addition, the association rate constant between a serpin and a serine protease can be dramatically increased by non-protein cofactors, such as heparin in the case of thrombin inhibition by antithrombin III. In an attempt to alter the specificity of PAI-1 from an inhibitor of the fibrinolytic system to an inhibitor of coagulation, we replaced P1-P1' or P3 through P3' of the reactive center of PAI-1 by the corresponding residues of antithrombin III and assessed whether the mutant proteins, purified from lysates of transformed Escherichia coli cells, had acquired thrombin inhibitory properties. The experiments were performed in the presence and absence of vitronectin, a multifunctional protein which has been shown to bind PAI-1 in plasma and in the matrix of endothelial cells. The second-order rate constants for t-PA inhibition of "wild-type" PAI-1 and PAI P1-P1'ATIII, irrespective of the presence of vitronectin, were similar, whereas replacing P3-P3' resulted in a 40-fold decrease of the second-order rate constant towards t-PA, again independent of vitronectin. In the absence of vitronectin, reactivity of PAI-1 and its "antithrombin III-like" variants towards thrombin was slow; however, PAI-1 P3-P3' ATIII had a 10-fold higher k1 than wild-type PAI-1 (1.3 x 10(4) M-1 s-1 versus 1.1 x 10(3) M-1 s-1). In contrast, in the presence of vitronectin, PAI-1 and even more rapidly PAI-1 P3-P3'ATIII were found to be effective thrombin inhibitors, with k1 values of 2.2 x 10(5) M-1s-1 and 1.8 x 10(6) M-1 s-1, respectively. Thus, in the presence of vitronectin, PAI-1 P3-P3'ATIII displays a 3-fold higher k1 with thrombin than with t-PA. It is shown that vitronectin enhances, in a dose-dependent manner, the formation of sodium dodecyl sulfate-resistant complexes between PAI-1 or mutants thereof and thrombin. Therefore, vitronectin is the first protein described to function as a cofactor for serpin specificity. PAI-1 is proposed to be a versatile inhibitor which, in the presence of vitronectin, can modulate both coagulation and fibrinolysis.     

Inhibitory serpins from rye grain with glutamine as P1 and P2 residues in the reactive center

Six of seven serpins detected in grains of rye (Secale cereale) were purified and characterized. The amino acid sequence close to the blocked N-terminus, the reactive center loop sequence and the second order association rate constant (k(a)') for irreversible complex formation with chymotrypsin were determined for each serpin. Three of four serpins containing the unusual reactive center P2-P1' QQ/S and one with P2-P1' PQ/M were equally efficient inhibitors of chymotrypsin (k(a)' approximately 10(5) M(-1) s(-1)). One serpin with P2-P1' PY/M was a faster inhibitor (k(a)' approximately 10(6) M(-1) s(-1)). Similar but differently organized glutamine-rich reactive centers were recently found in grain serpins cloned from wheat [Ostergaard et al. (2000) J. Biol. Chem. 275, 33272] but not from barley. The prolamin storage proteins of cereal grains contain similar sequences in their glutamine-rich repeats. A possible adaption of hypervariable serpin reactive centers late in Triticeae cereal evolution as defence against insects feeding on cereal grains is discussed.     

Serpins in plants and green algae

Control of proteolysis is important for plant growth, development, responses to stress, and defence against insects and pathogens. Members of the serpin protein family are likely to play a critical role in this control through irreversible inhibition of endogenous and exogenous target proteinases. Serpins have been found in diverse species of the plant kingdom and represent a distinct clade among serpins in multicellular organisms. Serpins are also found in green algae, but the evolutionary relationship between these serpins and those of plants remains unknown. Plant serpins are potent inhibitors of mammalian serine proteinases of the chymotrypsin family in vitro but, intriguingly, plants and green algae lack endogenous members of this proteinase family, the most common targets for animal serpins. An Arabidopsis serpin with a conserved reactive centre is now known to be capable of inhibiting an endogenous cysteine proteinase. Here, knowledge of plant serpins in terms of sequence diversity, inhibitory specificity, gene expression and function is reviewed. This was advanced through a phylogenetic analysis of amino acid sequences of expressed plant serpins, delineation of plant serpin gene structures and prediction of inhibitory specificities based on identification of reactive centres. The review is intended to encourage elucidation of plant serpin functions.     

Interaction of subtilisins with serpins.

Serpins are well-characterized inhibitors of the chymotrypsin family serine proteinases. We have investigated the interaction of two serpins with members of the subtilisin family, proteinases that possess a similar catalytic mechanism to the chymotrypsins, but a totally different scaffold. We demonstrate that alpha 1 proteinase inhibitor inhibits subtilisin Carlsberg and proteinase K, and alpha 1 antichymotrypsin inhibits proteinase K, but not subtilisin Carlsberg. When inhibition occurs, the rate of formation and stability of the complexes are similar to those formed between serpins and chymotrypsin family members. However, inhibition of subtilisins is characterized by large partition ratios where more than four molecules of each serpin are required to inhibit one subtilisin molecule. The partition ratio is caused by the serpins acting as substrates or inhibitors. The ratio decreases as temperature is elevated in the range 0-45 degrees C, indicating that the serpins are more efficient inhibitors at high temperature. These aspects of the subtilisin interaction are all observed during inhibition of chymotrypsin family members by serpins, indicating that serpins accomplish inhibition of these two distinct proteinase families by the same mechanism.     

Inhibitory plant serpins with a sequence of three glutamine residues in the reactive center

Serpins appear to be ubiquitous in eukaryotes, except fungi, and are also present in some bacteria, archaea and viruses. Inhibitory serpins with a glutamine as the reactive-center P1 residue have been identified exclusively in a few plant species. Unique serpins with a reactive center sequence of three Gln residues at P3-P1 or P2-P1' were isolated from barley and wheat grain, respectively. Barley BSZ3 was an irreversible inhibitor of chymotrypsin, with a second-order association rate constant for complex formation k(a)' of the order of 10(4) M(-1) s(-1); however, only a minor fraction of the serpin molecules reacted with chymotrypsin, with the majority insensitive to cleavage in the reactive center loop. Wheat WSZ3 was cleaved specifically at P8 Thr and was not an inhibitor of chymotrypsin. These reactive-center loops may have evolved conformations that are optimal as inhibitory baits for proeinases that specifically degrade storage prolamins containing Gln-rich repetitive sequences, most likely for digestive proteinases of insect pests or fungal pathogens that infect cereals. An assembled full-length amino acid sequence of a serpin expressed in cotton boll fiber (GaZ1) included conserved regions essential for serpin-proteinase interaction, suggesting inhibitory capacity at a putative reactive center P2-P2' with a sequence of four Gln residues.     

Inhibition of the cysteine proteinases cathepsins K and L by the serpin headpin (SERPINB13): a kinetic analysis

Headpin (SERPINB13) is a novel member of the serine proteinase inhibitor (Serpin) gene family that was originally cloned from a keratinocyte cDNA library. Western blot analysis using a headpin-specific antiserum recognized a protein with the predicted M(r) of 44kDa in lysates derived from a transformed keratinocyte cell line known to express headpin mRNA. Similarity of the reactive-site loop (RSL) domain of headpin, notably at the P1-P1(') residues, with other serpins that inhibit cysteine and serine proteinases suggests that headpin may inhibit similar proteinases. This study demonstrates that recombinant headpin indeed inhibits cathepsins K and L, but not chymotrypsin, elastase, trypsin, subtilisin A, urokinase-type plasminogen activator, plasmin, or thrombin. The second-order rate constants (k(a)) for the inhibitory reactions of rHeadpin with cathepsins K and L were 5.1+/-0.6x10(4) and 4.1+/-0.8x10(4)M(-1)s(-1), respectively. Headpin formed SDS-stable complexes with cathepsins K and L, a characteristic property of inhibitory serpins. Interactions of the RSL domain of headpin with cathepsins K and L were indicated by cleavage of headpin near the predicted P1-P1(') residues by these proteinases. These results demonstrate that the serpin headpin possesses specificity for inhibiting lysosomal cysteine proteinases.     

Identification and activity of a lower eukaryotic serine proteinase inhibitor (serpin) from Cyanea capillata: analysis of a jellyfish serpin, jellypin

Delineating the phylogenetic relationships among members of a protein family can provide a high degree of insight into the evolution of domain structure and function relationships. To identify an early metazoan member of the high molecular weight serine proteinase inhibitor (serpin) superfamily, we initiated a cDNA library screen of the cnidarian, Cyanea capillata. We identified one serpin cDNA encoding for a full-length serpin, jellypin. Phylogenetic analysis using the deduced amino acid sequence showed that jellypin was most similar to the platyhelminthe Echinococcus multiocularis serpin and the clade P serpins, suggesting that this serpin evolved approximately 1000 million years ago (MYA). Modeling of jellypin showed that it contained all the functional elements of an inhibitory serpin. In vitro biochemical analysis confirmed that jellypin was an inhibitor of the S1 clan SA family of serine proteinases. Analysis of the interactions between the human serine proteinases, chymotrypsin, cathepsin G, and elastase, showed that jellypin inhibited these enzymes in the classical serpin manner, forming a SDS stable enzyme/inhibitor complex. These data suggest that the coevolution of serpin structure and inhibitory function date back to at least early metazoan evolution, approximately 1000 MYA.     

A 2.6 A structure of a serpin polymer and implications for conformational disease.

The function of the serpins as proteinase inhibitors depends on their ability to insert the cleaved reactive centre loop as the fourth strand in the main A beta-sheet of the molecule upon proteolytic attack at the reactive centre, P1-P1'. This mechanism is vulnerable to mutations which result in inappropriate intra- or intermolecular loop insertion in the absence of cleavage. Intermolecular loop insertion is known as serpin polymerisation and results in a variety of diseases, most notably liver cirrhosis resulting from mutations of the prototypical serpin alpha1-antitrypsin. We present here the 2.6 A structure of a polymer of alpha1-antitrypsin cleaved six residues N-terminal to the reactive centre, P7-P6 (Phe352-Leu353). After self insertion of P14 to P7, intermolecular linkage is affected by insertion of the P6-P3 residues of one molecule into the partially occupied beta-sheet A of another. This results in an infinite, linear polymer which propagates in the crystal along a 2-fold screw axis. These findings provide a framework for understanding the uncleaved alpha1-antitrypsin polymer and fibrillar and amyloid deposition of proteins seen in other conformational diseases, with the ordered array of polymers in the crystal resulting from slow accretion of the cleaved serpin over the period of a year.     

The role of conformational change in serpin structure and function

Serpins are members of a family of structurally related protein inhibitors of serine proteinases, with molecular masses between 40 and 100kDa. In contrast to other, simpler, proteinase inhibitors, they may interact with proteinases as inhibitors, as substrates, or as both. They undergo conformational interconversions upon complex formation with proteinase, upon binding of some members to heparin, upon proteolytic cleavage at the reactive center, and under mild denaturing conditions. These conformational changes appear to be critical in determining the properties of the serpin. The structures and stabilities of these various forms may differ significantly. Although the detailed structural changes required for inhibition of proteinase have yet to be worked out, it is clear that the serpin does undergo a major conformational change. This is in contrast to other, simpler, families of protein inhibitors of serine proteinases, which bind in a substrate-like or product-like manner. Proteolytic cleavage of the serpin can result in a much more stable protein with new biological properties such as chemo-attractant behaviour. These structural transformations in serpins provide opportunities for regulation of the activity and properties of the inhibitor and are likely be important in vivo, where serpins are involved in blood coagulation, fibrinolysis, complement activation and inflammation.     

Introduction of alpha-hydroxymethyamino acid residues in substrate specificity P1 position of trypsin inhibitor SFTI-1 from sunflower seeds retains its activity

In many complexes formed by serine proteinases and their inhibitors, the hydroxyl group provided by water molecule or by the inhibitor Ser residue is located close to the inhibitor P1-P1' reactive site. In order to investigate the role of this group, we synthesized analogues of trypsin inhibitor SFTI-1 isolated from the seeds of sunflower modified in P1 by alpha-hydroxymethylserine (HmSer) and both enantiomers of alpha-hydroxymethylvaline (HmVal). All the synthesized analogues inhibited bovine beta-trypsin and human leukocyte elastase. SFTI-1 analogues with HmVal and HmSer appear to be potent inhibitors of bovine beta-trypsin, whereas [Val5]SFTI-1 is practically inactive. Also trypsin inhibitory activity of [Ser5]SFTI-1 is significantly lower. Since the electrostatic interaction between protonated epsilon-NH2 group of the inhibitor P1 position and beta-carboxylate of trypsin Asp189 is the main driving force for interaction of both molecules, the results obtained are very interesting. We believe that these SFTI-1 analogues belong to a novel class of serine proteinase inhibitors.     

An elastase inhibitor from equine leukocyte cytosol belongs to the serpin superfamily. Further characterization and amino acid sequence of the reactive center

Horse leukocyte elastase inhibitor rapidly forms stable, equimolar complexes with both human leukocyte elastase and cathepsin G, porcine pancreatic elastase, and bovine alpha-chymotrypsin. Formation of the inhibitor-pancreatic elastase complex results in peptide bond cleavage at the reactive site of the inhibitor so that a small peptide fragment representing the carboxyl-terminal sequence of the inhibitor is released. Sequence analysis of both this peptide, as well as that of an overlapping peptide obtained by enzymatic inactivation of native inhibitor with either Staphylococcus aureus metalloproteinase, Pseudomonas aeruginosa elastase, or cathepsin B, yields data which indicate that the reactive site encompasses a P1-P1' Ala-Met sequence. However, unlike the human endothelial plasminogen activator inhibitor, which also has a Met residue in the P1' position, oxidation of the horse inhibitor only slightly reduces its association rate constant with either of the elastolytic enzymes tested or with chymotrypsin. Comparison of the amino acid sequence at or near the reactive site of the horse inhibitor (P2-P18') with members of the serpin superfamily of proteinase inhibitors indicates that it not only belongs in this class but also represents the first example of a functionally active intracellular serpin.     

The interaction between some serine proteinases and horse leucocyte inhibitor

Horse blood leucocyte cytosol exhibits a broad inhibitory activity against serine proteinases. The purified inhibitor was exposed to investigated enzymes (trypsin, chymotrypsin, elastases and serine proteinase from S. aureus) for variable time and the products were analyzed by gradient polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. The molar ratio I:E, association rate constants k on and inhibition constants Ki for the enzymes and inhibitor were determined. The examined elastases form stable, stoichiometric complexes with the inhibitor (Ki less than 10(-10) M), and do not undergo proteolytic degradation during 30 min incubation at 20 degrees C even at the 2-fold molar excess of the proteinases. The reactions with elastases are extremely rapid (k on greater than 10(7) M-1 s-1) and are completed within one second whereas similar reactions with chymotrypsin and trypsin are much slower (k on = 3 X 10(5) M-1 s-5 and 5 X 10(2) M-1 s-1, respectively). Serine proteinase from S. aureus neither react nor inactivates the investigated inhibitor. The complexes of the inhibitor with trypsin and chymotrypsin are digested even at a molar ratio I:E = 2:1. All these observations point out that the inhibitor from horse leucocyte cytosol is a specific and effective inhibitor of elastases.     

Expression and characterization of recombinant Manduca sexta serpin- 1B and site-directed mutants that change its inhibitory selectivity

Hemolymph of Manduca sexta contains a number of serine proteinase inhibitors from the serpin superfamily. During formation of a stable complex between a serpin and a serine proteinase, the enzyme cleaves a specific peptide bond in an exposed loop (the reactive-site region) at the surface of the serpin. The amino acid residue on the amino-terminal side of this scissile bond, the P₁ residue, is important in defining the selectivity of a serpin for inhibiting different types of serine proteinases. M. sexta serpin-1B, with alanine at the position predicted from sequence alignments to be the P₁ residue, was previously named alaserpin. This alanyl residue was changed by site-directed mutagenesis to lysine (A343K) and phenylalanine (A343F). The serpin-1B cDNA and its mutants were inserted into an expression vector, H6pQE-60, and the serpin proteins were expressed in Escherichia coli. Affinity-purified recombinant serpins selectively inhibited mammalian serine proteinases: serpin-1B inhibited elastase; serpin-1B(A343K) inhibited trypsin, plasmin, and thrombin; serpin-1B(A343F) inhibited chymotrypsin as well as trypsin. All three serpins inhibited human cathepsin G. This insect serpin and its site-directed mutants associated with mammalian serine proteinases at rates similar to those reported for mammalian serpins. Serpin-1B and its mutants formed SDS-stable complexes with the enzymes they inhibited. The scissile bond was determined to be between residues 343 and 344 in wild-type serpin-1B and in serpin-1B with mutations at residue 343. These results demonstrate that the P₁ alanine residue defines the primary selectivity of serpin-1B for elastase-like enzymes, and that this selectivity can be altered by mutations at this position.     

Analysis of the plasma elimination kinetics and conformational stabilities of native, proteinase-complexed, and reactive site cleaved serpins: comparison of alpha 1-proteinase inhibitor, alpha 1-antichymotrypsin, antithrombin III, alpha 2-antiplasmin, angiotensinogen, and ovalbumin.

Proteinase inhibitors of the serpin superfamily may exist in one of three distinct conformations: the native form, a fully active protein with the reactive site loop intact; the proteolytically modified form in which inhibitory capacity is abolished; and the proteinase-complexed form, a stable equimolar complex between the inhibitor and a target proteinase. Here, the specificity and kinetics of the plasma elimination of different serpin conformations are compared. Proteinase-complexed serpins were rapidly cleared from the circulation. However, the native and modified forms were not cleared rapidly, indicating that the receptor-mediated pathways which recognize the complexes fail to recognize the native and modified forms. This result suggests that significant structural differences exist between modified and proteinase-complexed serpins. The structural differences were probed by using transverse urea gradient gel electrophoresis, a technique that allows comparisons of the conformational stabilities of proteins. With the exception of the noninhibitory serpins ovalbumin and angiotensinogen, the modified and proteinase-complexed serpins were both stabilized thermodynamically compared to the native forms. In addition, the proteinase component of the serpin-proteinase complex was usually thermodynamically stabilized. These data are used to compare the conformations of serpin-proteinase complexes with those of native and modified serpins; they are discussed in terms of a model whereby serpins inhibit proteinases in a manner similar to that described for other types of protein inhibitors of serine proteinases.     

Functional diversification during evolution of the murine alpha(1)-proteinase inhibitor family: role of the hypervariable reactive center loop

Alpha(1)-proteinase inhibitor (alpha(1)-PI) is a member of the serpin superfamily of serine proteinase inhibitors that are involved in the regulation of a number of proteolytic processes. Alpha(1)-PI, like most serpins, functions by covalent binding to, and inhibition of, target proteinases. The interaction between alpha(1)-PI and its target is directed by the so-called reactive center loop (RCL), an approximately 20 residue domain that extends out from the body of the alpha(1)-PI polypeptide and determines the inhibitor's specificity. Mice express at least seven closely related alpha(1)-PI isoforms, encoded by a family of genes clustered at the Spi1 locus on chromosome 12. The amino acid sequence of the RCL region is hypervariable among alpha(1)-PIs, a phenomenon that has been attributed to high rates of evolution driven by positive Darwinian selection. This suggests that the various isoforms are functionally diverse. To test this notion, we have compared the proteinase specificities of individual alpha(1)-PIs from each of the two mouse species. As predicted from the positive Darwinian selection hypothesis, the various alpha(1)-PIs differ in their ability to form covalent complexes with serine proteinases, such as elastase, trypsin, chymotrypsin, and cathepsin G. In addition, they differ in their binding ability to proteinases in crude snake venoms. Importantly, the RCL region of the alpha(1)-PI polypeptide is the primary determinant of isoform-specific differences in proteinase recognition, indicating that hypervariability within this region drives the functional diversification of alpha(1)-PIs during evolution. The possible physiological benefits of alpha(1)-PI diversity are discussed.     

Formation of the covalent chymotrypsin.antichymotrypsin complex involves no large-scale movement of the enzyme

alpha(1)-Antichymotrypsin is a member of the serine proteinase inhibitor, or serpin, family that typically forms very long-lived, enzymatically inactive 1:1 complexes (denoted E*I*) with its target proteinases. Serpins share a conserved tertiary structure, in which an exposed region of amino acid residues (called the reactive center loop or RCL) acts as bait for a target proteinase. Within E*I*, the two proteins are linked covalently as a result of nucleophilic attack by Ser(195) of the serine proteinase on the P1 residue within the RCL of the serpin. This species is formally similar to the acyl enzyme species normally seen as an intermediate in serpin proteinase catalysis. However, its subsequent hydrolysis is extremely slow as a result of structural changes within the enzyme leading to distortion of the active site. There is at present an ongoing debate concerning the structure of the E*I* complex; in particular, as to whether the enzyme, bound to P1, maintains its original position at the top of the serpin molecule or instead translocates across the entire length of the serpin, with concomitant insertion of RCL residues P1-P14 within beta-sheet A and a large separation of the enzyme and RCL residue P1'. We report time-resolved fluorescence energy transfer and rapid mixing/quench studies that support the former model. Our results indicate that the distance between residue P1' in alpha(1)-antichymotrypsin and the amino terminus of chymotrypsin actually decreases on conversion of the encounter complex E.I to E*I*. These results led us to formulate a comprehensive mechanism that accounted both for our results and for those of others supporting the two different E*I* structures. In this mechanism, partial insertion of the RCL, with no large perturbation of the P1' enzyme distance, is followed by covalent acyl enzyme formation. Full insertion can subsequently take place, in a reversible fashion, with the position of equilibrium between the partially and fully inserted complexes depending on the particular serpin-proteinase pair under consideration.     

The structural puzzle of how serpin serine proteinase inhibitors work

Serine proteinase cleavage of proteins is essential to a wide variety of biological processes and is primarily regulated by protein inhibitors. Many inhibitors are conformationally rigid simulations of optimal serine proteinase substrates, which makes them highly efficient competitive inhibitors of target proteinases. In contrast, members of the serpin family of serine proteinase inhibitors display extensive flexibility and polymorphism, particularly in their reactive site segments and in β-sheet secondary structure, which can take up and expel strands. Reactive site and β-sheet polymorphism appear to be coupled in the serpins and may account for the extreme stability of serpinproteinase complexes through the insertion of the reactive site strand into a β-sheet. These unusual properties may have opened an adaptive pathway of proteinase regulation that was unavailable to the conformationally rigid proteinase inhibitors.     

Loop-inserted and thermostabilized structure of P1-P1' cleaved ovalbumin mutant R339T.

Ovalbumin is a member of a superfamily of serine proteinase inhibitors, known as the serpins. It is, however, non-inhibitory towards serine proteinases, and lacks the loop insertion mechanism common to the serpins due to unknown structural factors. Mutant ovalbumin, R339T, in which the P14 hinge residue is replaced, was produced and analyzed for its thermostability and three-dimensional structure. Differential scanning calorimetry revealed that the mutant ovalbumin, but not the wild-type protein, undergoes a marked thermostabilization (DeltaT(m)=15.8 degrees C) following the P1-P1' cleavage. Furthermore, the crystal structure, solved at 2.3 A resolution, clearly proved that the P1-P1' cleaved form assumes the fully loop-inserted conformation as seen in serpin that possess inhibitory activity. We therefore conclude that ovalbumin acquires the structural transition mechanism into the loop-inserted, thermostabilized form by the single hinge mutation. The mutant protein does not, however, possess inhibitory activity. The solved structure displays the occurrence of specific interactions that may prevent the smooth motion, relative to sheet A, of helices E and F and of the loop that follows helix F. These observations provide crucial insights into the question why R339T is still non-inhibitory.