Inhibitory activity and conformational transition of alpha 1-proteinase inhibitor variants

Identification of an alpha-1 antitrypsin variant with enhanced specificity for factor XIa by phage display, bacterial expression, and combinatorial mutagenesis

Coagulation Factor XIa (FXIa) is an emerging target for antithrombotic agent development. The M358R variant of the serpin alpha-1 antitrypsin (AAT) inhibits both FXIa and other proteases. Our aim was to enhance the specificity of AAT M358R for FXIa. We randomized two AAT M358R phage display libraries at reactive centre loop positions P13-P8 and P7-P3 and biopanned them with FXIa. A bacterial expression library randomized at P2′-P3′ was also probed. Resulting novel variants were expressed as recombinant proteins in E. coli and their kinetics of FXIa inhibition determined. The most potent FXIa-inhibitory motifs were: P13-P8, HASTGQ; P7-P3, CLEVE; and P2-P3′, PRSTE (respectively, novel residues bolded). Selectivity for FXIa over thrombin was increased up to 34-fold versus AAT M358R for these single motif variants. Combining CLEVE and PRSTE motifs in AAT-RC increased FXIa selectivity for thrombin, factors XIIa, Xa, activated protein C, and kallikrein by 279-, 143-, 63-, 58-, and 36-fold, respectively, versus AAT M358R. AAT-RC lengthened human plasma clotting times less than AAT M358R. AAT-RC rapidly and selectively inhibits FXIa and is worthy of testing in vivo. AAT specificity can be focused on one target protease by selection in phage and bacterial systems coupled with combinatorial mutagenesis.

Engineering the serpin α1 -antitrypsin: A diversity of goals and techniques

α₁ -Antitrypsin (α₁ -AT) serves as an archetypal example for the serine proteinase inhibitor (serpin) protein family and has been used as a scaffold for protein engineering for >35 years. Techniques used to engineer α₁ -AT include targeted mutagenesis, protein fusions, phage display, glycoengineering, and consensus protein design. The goals of engineering have also been diverse, ranging from understanding serpin structure-function relationships, to the design of more potent or more specific proteinase inhibitors with potential therapeutic relevance. Here we summarize the history of these protein engineering efforts, describing the techniques applied to engineer α₁ -AT, specific mutants of interest, and providing an appended catalog of the >200 α₁ -AT mutants published to date.

Cloning of six serpin genes and their responses to GCRV infection in grass carp (Ctenopharyngodon idella)

Grass carp, an economically important aquaculture fish, is very sensitive to Grass Carp Reovirus (GCRV). Haemorrhagic disease caused by GCRV infection can cause large-scale death of first-year grass carp, thereby severely restricting the intensive culture. Serpins (serine protease inhibitors) belong to the protease inhibitor gene family and are involved in numerous physiological and pathological processes, particularly coagulation and anticoagulation. Reports on grass carp serpins are scarce. Thus, we cloned six grass carp serpin genes (serpinb1, serpinc1, serpind1, serpinf1, serpinf2b and serping1) in this study. Molecular evolution showed that serpins between grass carp and zebrafish or carp are the closest relatives. SERPIN domains in these 6 serpins and reactive centre loop (RCL) along with their cleavage sites of 5 serpins (serpinb1, serpinc1, serpind1, serpinf2b and serping1) were predicted. Real-time quantitative PCR (RT-qPCR) showed that these serpins displayed tissue significance. Among them, serpinc1, serpind1, serpinf2b and serping1 had the highest expression levels in the liver. After GCRV infection, RT-qPCR showed that the liver-enriched serpins were significantly changed. Key procoagulant factor genes (kng-1, f2, f3a, f3b and f7) and anticoagulant genes (tpa, plg, thbd, proc and pros) also showed significant changes on the mRNA level. Comprehensive comparative analysis showed that the up-regulated expression of key clotting factor genes was more prominent than that of main anti-coagulation factor genes. Thus, the function of coagulation may be more dominant in grass carp during the GCRV infection, which may cause overproduction of thrombi. The serpins were involved in GCRV infection and liver-enriched serpins participate in the interaction between coagulation and anticoagulation. This study provided new insights into further research on the biological functions of grass carp serpins and clarifying the molecular mechanism of GCRV affecting the homeostasis of grass carp blood environment.

Mixture-based combinatorial libraries from small individual peptide libraries: a case study on α1-antitrypsin deficiency

The design, synthesis and screening of diversity-oriented peptide libraries using a "libraries from libraries" strategy for the development of inhibitors of α1-antitrypsin deficiency are described. The major buttress of the biochemical approach presented here is the use of well-established solid-phase split-and-mix method for the generation of mixture-based libraries. The combinatorial technique iterative deconvolution was employed for library screening. While molecular diversity is the general consideration of combinatorial libraries, exquisite design through systematic screening of small individual libraries is a prerequisite for effective library screening and can avoid potential problems in some cases. This review will also illustrate how large peptide libraries were designed, as well as how a conformation-sensitive assay was developed based on the mechanism of the conformational disease. Finally, the combinatorially selected peptide inhibitor capable of blocking abnormal protein aggregation will be characterized by biophysical, cellular and computational methods.

Isolation of serpin-interacting proteins in C. elegans using protein affinity purification

Caenorhabditis elegans is a useful model organism for combining multiple imaging, genetic, and biochemical methodologies to gain more insight into the biological function of specific proteins. Combining both biochemical and genetic analyses can lead to a better understanding of how a given protein may function within the context of a network of other proteins or specific pathway. Here, we describe a protocol for the biochemical isolation of serpin-interacting proteins using affinity purification and proteomic analysis. As the knowledge of in vivo serpin interacting partners in C. elegans has largely been obtained using genetic and in vitro recombinant protein studies, this protocol serves as a complementary approach to provide insight into the biological function and regulation of serpins.

Structural differences between active forms of plasminogen activator inhibitor type 1 revealed by conformationally sensitive ligands

Plasminogen activator inhibitor type 1 (PAI-1) is a serine protease inhibitor (serpin) in which the reactive center loop (RCL) spontaneously inserts into a central beta-sheet, beta-sheet A, resulting in inactive inhibitor. Available x-ray crystallographic studies of PAI-1 in an active conformation relied on the use of stabilizing mutations. Recently it has become evident that these structural models do not adequately explain the behavior of wild-type PAI-1 (wtPAI-1) in solution. To probe the structure of native wtPAI-1, we used three conformationally sensitive ligands: the physiologic cofactor, vitronectin; a monoclonal antibody, 33B8, that binds preferentially to RCL-inserted forms of PAI-1; and RCL-mimicking peptides that insert into beta-sheet A. From patterns of interaction with wtPAI-1 and the stable mutant, 14-1B, we propose a model of the native conformation of wtPAI-1 in which the bottom of the central sheet is closed, whereas the top of the beta-sheet A is open to allow partial insertion of the RCL. Because the incorporation of RCL-mimicking peptides into wtPAI-1 is accelerated by vitronectin, we further propose that vitronectin alters the conformation of the RCL to allow increased accessibility to beta-sheet A, yielding a structural hypothesis that is contradictory to the current structural model of PAI-1 in solution and its interaction with vitronectin.

Effects of Noninhibitory α-1-Antitrypsin on Primary Human Monocyte Activation in Vitro

A major function of alpha-1-antitrypsin (AAT) is the inhibition of overexpressed serine proteinases during inflammation. However, it is also known that the biological activity of AAT is affected by chemical modifications, including oxidation of the reactive-site methionine, polymerization, and cleavage by unspecific proteases, all of which will result in AAT inactivation and/or degradation. All inactive forms of AAT can be detected in tissues and fluids recovered from inflammatory sites. To test for a possible link between the inflammation-generated, noninhibitory, cleaved form of AAT and cellular processes associated with inflammation, we studied the effects of this form at varying concentrations on human monocytes in culture. We found that cleaved AAT at concentrations ranging between 1 and 10 microM in monocyte cultures over 24 h induces elevation in monocyte chemoattractant protein-1 (MCP-1) and pro-inflammatory cytokines such as TNFalpha and IL-6 and also increases production of interstitial collagenase (MMP-1) and gelatinase B (MMP-9), members of two different classes of matrix metalloproteinase. Moreover, monocytes stimulated with higher doses of cleaved AAT show an increase in cellular oxygen consumption by about 30%, while native AAT under the same experimental conditions inhibits oxygen consumption by about 50%. These results indicate that the cleaved form of AAT may play a role in monocyte recruitment and pro-inflammatory activation during inflammatory processes, and also suggest that changes in structure occurring upon AAT cleavage could alter its functional properties with potential pathological consequences.

Comparative fourier transform infrared and circular dichroism spectroscopic analysis of alpha1-proteinase inhibitor and ovalbumin in aqueous solution

Alpha1-proteinase inhibitor (alpha1Pi) and ovalbumin are both members of the serpin superfamily. They share about a 30% sequence identity and exhibit great similarity in their three-dimensional structures. However, no apparent functional relationship has been found between the two proteins. Unlike alpha1Pi, ovalbumin shows no inhibitory effect to serine proteases. To see whether or not a conformational factor(s) may contribute to the functional difference, we carried out comparative analysis of the two proteins' secondary structure, thermal stability, and H-D exchange using FT-IR and CD spectroscopy. FT-IR analysis reveals significant differences in the amide I spectral patterns of the two proteins. Upon thermal denaturation, both proteins exhibit a strong low-wavenumber beta-sheet band at 1624 cm(-1) and a weak high-wavenumber beta-sheet band at 1694 cm(-1), indicative of intermolecular aggregate formation. However, the midpoint of the thermal-induced transition of alpha1Pi (approximately 55 degrees C) is 18 degrees C lower than that of ovalbumin (approximately 73 degrees C). The thermal stability analysis provides new insight into the structural changes associated with denaturation. The result of H-D exchange explains some puzzling spectral differences between the two proteins in D2O reported previously.

Distinct physical and structural properties of the ovine uterine serpin

Experiments were performed to examine the relationship between the structure and function of ovine uterine serpin (OvUS). Limited proteolytic digestion of OvUS caused cleavage of the 55-57 kDa OvUS to a 42 kDa product nearly identical in molecular weight to a naturally-occurring breakdown product of OvUS. N-terminal amino acid sequencing and MALDI-MS revealed that, unlike other serpins, OvUS was preferentially cleaved at about 70 amino acids upstream of the putative reactive center loop. Analysis of the partially-digested protein by gel filtration chromatography suggested that the C-terminal fragment of the protein was still associated under nondenaturing conditions. Partial digestion of OvUS had no effect on the protein's secondary structure, thermal stability, ability to bind lymphocytes or pepsin, or inhibitory activity towards pepsin or mitogen-induced lymphocyte proliferation. In contrast, mild denaturation of OvUS with 0.5 M guanidine HCl increased thermal stability. Unlike for other serpins, the increase in thermal stability was lost upon removal of the denaturant. Incubation of OvUS with 100 fold molar excess of a peptide corresponding to the putative P(14)-P(2) region of the RCL for 24 h at 37 degrees C to induce binary complex formation had no effect on its secondary structure and did not alter the biological activity of the protein. Synthetic peptides corresponding to the putative P(14)-P(2) region and the P(7)-P(15') region of the RCL were not inhibitory to pepsin activity or lymphocyte proliferation. Taken together, these results indicate that the conformation of OvUS is distinct from the prototypical serpin because conditions that lead to the large-scale conformational change in other serpins such as antithrombin III and alpha(1)-antitrypsin do not cause similar changes in OvUS. Moreover, the putative RCL does not seem to contain the activity required to inhibit lymphocyte proliferation or pepsin activity.

The crystal structure of plasminogen activator inhibitor 2 at 2.0 A resolution: implications for serpin function

BACKGROUND

Plasminogen activator inhibitor 2 (PAI-2) is a member of the serpin family of protease inhibitors that function via a dramatic structural change from a native, stressed state to a relaxed form. This transition is mediated by a segment of the serpin termed the reactive centre loop (RCL); the RCL is cleaved on interaction with the protease and becomes inserted into betasheet A of the serpin. Major questions remain as to what factors facilitate this transition and how they relate to protease inhibition.

RESULTS

The crystal structure of a mutant form of human PAI-2 in the stressed state has been determined at 2.0 A resolution. The RCL is completely disordered in the structure. An examination of polar residues that are highly conserved across all serpins identifies functionally important regions. A buried polar cluster beneath betasheet A (the so-called 'shutter' region) is found to stabilise both the stressed and relaxed forms via a rearrangement of hydrogen bonds.

CONCLUSIONS

A statistical analysis of interstrand interactions indicated that the shutter region can be used to discriminate between inhibitory and non-inhibitory serpins. This analysis implied that insertion of the RCL into betasheet A up to residue P8 is important for protease inhibition and hence the structure of the complex formed between the serpin and the target protease.

Characterization of a human alpha1-antitrypsin variant that is as stable as ovalbumin

The metastability of inhibitory serpins (serine proteinase inhibitors) is thought to play a key role in the facile conformational switch and the insertion of the reactive center loop into the central beta-sheet, A-sheet, during the formation of a stable complex between a serpin and its target proteinase. We have examined the folding and inhibitory activity of a very stable variant of human alpha1-antitrypsin, a prototype inhibitory serpin. A combination of seven stabilizing single amino acid substitutions of alpha1-antitrypsin, designated Multi-7, increased the midpoint of the unfolding transition to almost that of ovalbumin, a non-inhibitory but more stable serpin. Compared with the wild-type alpha1-antitrypsin, Multi-7 retarded the opening of A-sheet significantly, as revealed by the retarded unfolding and latency conversion of the native state. Surprisingly, Multi-7 alpha1-antitrypsin could form a stable complex with a target elastase with the same kinetic parameters and the stoichiometry of inhibition as the wild type, indicating that enhanced A-sheet closure conferred by Multi-7 does not affect the complex formation. It may be that the stability increase of Multi-7 alpha1-antitrypsin is not sufficient to influence the rate of loop insertion during the complex formation.

Effect of glycosylation on the stability of alpha1-antitrypsin toward urea denaturation and thermal deactivation

The effects of glycosylation on the stability of human alpha1-antitrypsin were investigated. The transition midpoints in urea-induced equilibrium unfolding of a non-glycosylated recombinant, a yeast version of glycosylated, and human plasma alpha1-antitrypsin were 1.8 M, 2.2 M, and 2.5 M at 25 degrees C, respectively. Kinetic analyses of unfolding and refolding revealed that glycosylation retarded the unfolding without affecting the refolding rate significantly, suggesting that the stability increase is due to the stabilization of the native state as opposed to the destabilization of the unfolded state. In thermal deactivation, which is a heat-induced aggregation process, the unglycosylated recombinant alpha1-antitrypsin was deactivated most easily, which was followed in order by the yeast, and the plasma form. The results indicate that glycosylation confers the increase in stability of alpha1-antitrypsin, and that the oligomannose sugars present on the yeast form produce a less stable molecule than the complex type sugars on the plasma form. It appears that the effect of glycosylation on the enhancement of thermal resistance is exerted through the increase in conformational stability. However, a stable recombinant variant (Phe 51 --> Cys) that showed the same conformational stability as the plasma form was less resistant to thermal denaturation than the plasma alpha1-antitrypsin. The results suggest that the existence of carbohydrate moiety per se as well as the conformational stability contribute to the kinetic stability of alpha1-antitrypsin toward aggregation.

Bioengineering: alpha 1-proteinase inhibitor site-specific mutagenesis. The prospect for improving the inhibitor

alpha 1-Proteinase inhibitor (alpha 1-PI) augmentation therapy has been licensed for treatment of alpha 1-PI-deficient individuals with pulmonary emphysema. The currently available product is purified from pooled human plasma. To obtain larger amounts of protein free from possible unknown plasma contaminants, human alpha 1-PI has been produced by recombinant DNA. Since wild-type alpha 1-PI is susceptible to oxidative impairment, several alpha 1-PI variants in which the active site oxidation-sensitive residue is replaced by inert residues have been constructed. This article is aimed at reviewing the history, biological efficacy, advantages, disadvantages, and concerns linked to alpha 1-PI recombinant DNA and site-specific mutagenesis technology.

Arginine substitutions in the hinge region of antichymotrypsin affect serpin beta-sheet rearrangement

A hallmark of serpin function is the massive beta-sheet rearrangement involving the insertion of the cleaved reactive loop into beta-sheet A as strand s4A. This structural transition is required for inhibitory activity. Small hydrophobic residues at P14 and P12 positions of the reactive loop facilitate this transition, since these residues must pack in the hydrophobic core of the cleaved serpin. Despite the radical substitution of arginine at the P12 position, the crystal structure of cleaved A347R antichymotrypsin reveals full strand s4A insertion with normal beta-sheet A geometry; the R347 side chain is buried in the hydrophobic protein core. In contrast, the structure of cleaved P14 T345R antichymotrypsin reveals substantial yet incomplete strand s4A insertion, without burial of the R345 side chain.

A Spectroscopic Study of the Structures of Latent, Active and Reactive-Center-Cleaved Type-1 Plasminogen-Activator Inhibitor

Type-1 plasminogen-activator inhibitor (PAI-1) was studied by Fourier-transform infrared spectroscopy, far-ultraviolet CD spectroscopy, and fluorescence-emission spectroscopy, with the aim to obtain structural information about its active form. The spectra of latent, active and reactive-center-cleaved forms of PAI-1 produced by HT-1080 cells were different. While the cleaved and the latent forms were similar with regard to their beta-structure content, comparison of the spectra of these forms with the spectra of active PAI-1 suggested a much higher degree of unordered structure for the active form compared with the latent and reactive-center-cleaved forms than previously assumed. We discuss our results with reference to the known three-dimensional X-ray structures of latent PAI-1, of reactive-center-cleaved serpins, including reactive-center-cleaved PAI-1, and of intact serpins, and with reference to previous results on the differences in the affinity of mAbs for the different PAI-1 forms. We interpret our results in favor of a global rearrangement of secondary structure during latency transition and reactive-center cleavage in PAI-1, not only involving the reactive-center loop and parts of beta-sheets A and C, but also the "rear' side of the molecule, such as helices H and G. Thus, we suggest flexibility in serpin structural elements that were previously regarded as rigid.

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 beta-sheet secondary structure, which can take up and expel strands. Reactive site and beta-sheet polymorphism appear to be coupled in the serpins and may account for the extreme stability of serpin-proteinase complexes through the insertion of the reactive site strand into a beta-sheet. These unusual properties may have opened an adaptive pathway of proteinase regulation that was unavailable to the conformationally rigid proteinase inhibitors.

Probing serpin reactive-loop conformations by proteolytic cleavage

Several crystal structures of intact members of the serine proteinase inhibitor (or serpin) superfamily have recently been solved but the relationship of their reactive-loop conformations to those of circulating forms remains unclear. Here we examine reactive-loop conformational changes of anti-trypsin and anti-thrombin by using limited proteolysis and binary complex formation with synthetic homologous reactive-loop peptides. Proteolysis at the P10-P9, P8-P7 and P7-P6 of anti-trypsin was distorted by binary complex formation. The P1'-P2' bond in anti-thrombin was more accessible to proteolysis after binary complex formation, whereas cleavage at the P4-P3 bond was variably altered by synthetic peptide insertion. The proteolytic accessibility of the reactive-site P1-P1' bond of anti-trypsin and anti-thrombin binary complexes was identical with that of the native form and no cleavage was observed in the hinge region (P15-P10) of either protein, whether native or as binary complexes. these results fit with the proposal that the hydrophobic reactive loop of serpins adopts a modified helical conformation in the circulation, with the hinge region being partly incorporated into the A beta-pleated sheet. This loop can be displaced by peptides and induced to adopt a new conformation similar to the three-turn helix of ovalbumin. Both the native and binary complexed forms of anti-thrombin showed a greatly increased proteolytic sensitivity in the presence of heparin, indicating that heparin either induces a conformational change in the local structure of the helical reactive loop or facilitates the approximation of enzyme and inhibitor.

Divining the serpin inhibition mechanism: a suicide substrate 'springe'?

The most important of diverse serpin functions is serine-protease inhibition. In contrast to the 'standard-mechanism' inhibitors, inhibitory serpins use a mechanism that involves unusual flexibility, and cofactor and receptor interactions. The principal feature is a refolding step, during which a disordered or helical strand is inserted into the center of a beta sheet. This transition, which is essential for inhibition, can be induced by heating, proteolytic cleavage of the serpin, or complexation with the proteinase target; analogous transitions can be induced by peptide complexation or aggregation. Although it is difficult to determine the details of this mechanism, information derived from crystal structures and other experiments has stimulated drug design efforts with wide-ranging potential applications.

The acid stabilization of plasminogen activator inhibitor-1 depends on protonation of a single group that affects loop insertion into beta-sheet A

The serpin plasminogen activator inhibitor-1 (PAI-1) spontaneously adopts an inactive or latent conformation by inserting the N-terminal part of the reactive center loop as strand 4 into the major beta-sheet (sheet A). To examine factors that may regulate reactive loop insertion in PAI-1, we determined the inactivation rate of the inhibitor in the pH range 4.5-13. Below pH 9, inactivation led primarily to latent PAI-1, and one predominant effect of pH on the corresponding rate constant could be observed. Protonation of a group exhibiting a pKa of 7.6 (25 degrees C, ionic strength = 0.15 M) reduced the rate of formation of latent PAI-1 by a factor of 35, from 0.17 h-1 at pH 9 to about 0.005 h-1 below pH 6. The ionization with a pKa 7.6 was found to have no effect on the rate by which PAI-1 inhibits trypsin and is therefore unlikely to change the flexibility of the loop or the orientation of the reactive center. The peptides Ac-TEASSSTA and Ac-TVASSSTA (cf. P14-P7 in the reactive loop of PAI-1) formed stable complexes with PAI-1 and converted the inhibitor to a substrate for tissue type plasminogen activator. We found that peptide binding and formation of latent PAI-1 are mutually exclusive events, similarly affected by the pKa 7.6 ionization. This is direct evidence that external peptides can substitute for strand 4 in beta-sheet A of PAI-1 and that the pKa 7.6 ionization regulates insertion of complementary, internal or external, strands into this position. A model that accounts for the observed pH effects is presented, and the identity of the ionizing group is discussed based on the structure of latent PAI-1. The group is tentatively identified as His-143 in helix F, located on top of sheet A.

Production of chicken ovalbumin in Escherichia coli

For better understanding of the structure-function relationship in serine proteinase inhibitors, a protein engineering approach for converting non-inhibitory chicken ovalbumin (Ova) to the inhibitory form would be a highly useful model system. A prerequisite expression system for the Ova-encoding gene (Ova) was established in this study. The Ova gene was expressed in Escherichia coli with high yield using the T7 phage promoter; the amount of the recombinant Ova (re-Ova) was 29.4% of cellular proteins. SDS-PAGE and Western blotting analysis revealed that re-Ova immunoreacting with the egg ovalbumin antibody is not glycosylated. The re-Ova was purified by anion exchange chromatography into homogeneity, as evaluated by SDS-PAGE. Amino-acid and N-terminal sequence analyses confirmed that the purified product had the correct sequence designed for Ova production. As for secondary structure, re-Ova showed a far-UV circular dichroism spectrum indistinguishable from natural egg Ova. Furthermore, the proteolytic fragmentation pattern that should reflect protein conformation was exactly the same for the natural egg and re-Ova. Using the proteolytic fragments, the identity of the internal sequences for the natural and re- proteins was confirmed.

Yama/CPP32 beta, a mammalian homolog of CED-3, is a CrmA-inhibitable protease that cleaves the death substrate poly(ADP-ribose) polymerase

Although the mechanism of mammalian apoptosis has not been elucidated, a protease of the CED-3/ICE family is anticipated to be a component of the death machinery. Several lines of evidence predict that this protease cleaves the death substrate poly(ADP-ribose) polymerase (PARP) to a specific 85 kDa form observed during apoptosis, is inhibitable by the CrmA protein, and is distinct from ICE. We cloned a ced-3/ICE-related gene, designated Yama, that encodes a protein identical to CPP32 beta. Purified Yama was a zymogen that, when activated, cleaved PARP to generate the 85 kDa apoptotic fragment. Cleavage of PARP by Yama was inhibited by CrmA but not by an inactive point mutant of CrmA. Furthermore, CrmA blocked cleavage of PARP in cells undergoing apoptosis. We propose that Yama may represent an effector component of the mammalian cell death pathway and suggest that CrmA blocks apoptosis by inhibiting Yama.

A thermostable mutation located at the hydrophobic core of alpha 1-antitrypsin suppresses the folding defect of the Z-type variant

A thermostable mutation, F51L, at the hydrophobic core of human alpha 1-antitrypsin (alpha 1AT) increased the conformational stability of the molecule by decreasing the unfolding rate significantly without altering the refolding rate. The mutation specifically influenced the transition between the native state and a compact intermediate, which retained approximately 70% of the far-UV CD signal, but which had most of the fluorescence signal already dequenched. The mutant alpha 1AT protein was more resistant than the wild-type protein to the insertion of the tetradecapeptide mimicking the sequence of the reactive center loop, indicating that the mutation increases the closing of the central beta-sheet, the A-sheet, in the native state. The F51L mutation enhanced the folding efficiency of the Z-type (E342K) genetic variation, which causes aggregation of the molecule in the liver. It has been shown previously that the aggregation of the Z protein occurs via loop-sheet polymerization, in which the reactive center loop of one molecule is inserted into the opening of the A-sheet of another molecule. Our results strongly suggest that the hydrophobic core of alpha 1AT regulates the opening-closing of the A-sheet and that certain genetic variations that cause opening of the A-sheet can be corrected by inserting an additional stable mutation into the hydrophobic core.

Mutations which impede loop/sheet polymerization enhance the secretion of human alpha 1-antitrypsin deficiency variants

alpha 1-Antitrypsin plasma deficiency variants which form hepatic inclusion bodies within the endoplasmic pathway include the common Z variant (Glu342-->Lys) and the rarer alpha 1-antitrypsin Siiyama (Ser53-->Phe). It has been proposed that retention of both abnormal proteins is accompanied by a common mechanism of loop-sheet polymerization with the insertion of the reactive center loop of one molecule into a beta-pleated sheet of another. We have compared the biosynthesis, glycosylation, and secretion of normal, Z and Siiyama variants of alpha 1-antitrypsin using Xenopus oocytes. Siiyama and Z alpha 1-antitrypsin both duplicated the secretory defect seen in hepatocytes that results in decreased plasma alpha 1-antitrypsin levels. Digestion with endoglycosidase H localized both variants to a pre-Golgi compartment. The mutation Phe51-->Leu abolished completely the intracellular blockage of Siiyama alpha 1-antitrypsin and reduced significantly the retention of Z alpha 1-antitrypsin. The secretory properties of M and Z alpha 1-antitrypsin variants containing amino acid substitutions designed to decrease loop mobility and sheet insertion were investigated. A reduction in intracellular levels of Z alpha 1-antitrypsin was achieved with the replacement of P11/12 alanines by valines. Thus a decrease in Z and Siiyama alpha 1-antitrypsin retention was observed with mutations which either closed the A sheet or decreased loop mobility at the loop hinge region.

Conformational changes in serpins and the mechanism of alpha 1-antitrypsin deficiency

alpha 1-Antitrypsin is a member of the serine proteinase inhibitor, serpin, family of protease inhibitors, which have their reactive centers situated on a mobile peptide loop. This reactive loop can adopt varied conformations and perturbations of molecular structure to allow the pathological linking of the loop of one molecule to a beta-pleated sheet of another. This linkage has been shown to be the cause of the polymerization and aggregation within the hepatocyte of the common Z mutant of antitrypsin. The occurrence of loop-sheet polymerization has been confirmed with other deficiency variants of antitrypsin that accumulate in the liver (Mmalton, Siiyama) and also shown to occur in pathological mutants of C1-inhibitor and antithrombin. Deductive evidence indicates that the loop is inserted into the A-sheet of the next molecule, but recent structural findings raise the possibility of insertion into the C-sheet. This detail of loop-sheet polymerization is important for the design of strategies to interfere with insertion and hence lesson the accumulation of Z antitrypsin that is responsible for associated liver damage.

Proteolytically cleaved mutant antithrombin-Hamilton has high stability to denaturation characteristic of wild type inhibitor serpins

The serpin family of proteins consists primarily of proteinase inhibitors which form tight complexes with target proteinases. Inhibitor serpins are cleaved by proteinase and undergo a large conformational change in which the polypeptide segment terminating at the target reactive site, at which cleavage takes place, inserts itself as an additional strand, s4A, in the center of a preexisting beta-sheet. This change in conformation increases the stability towards denaturation of the cleaved serpin relative to the native uncleaved form. Mutant serpins with single amino acid changes in the s4A strand have been identified, and in most cases these are proteinase substrates but not inhibitors. We have measured the stability to denaturation of one of these non-inhibitor substrate mutants, antithrombin-Hamilton, which has an Ala-->Thr change at position P12 in strand s4A. We find that it undergoes the transformation to the more stable form which is observed for inhibitor serpins, from which we conclude that the Ala-->Thr change in antithrombin-Hamilton does not prevent insertion of s4A into beta-sheet A in the cleaved form.

Structural aspects of serpin inhibition

The essential roles of proteins of the serpin family in many physiological processes, along with new discoveries of their unique folding properties, have attracted intense interest in recent years. Many serpins display unusual mobile behavior attributed to rearrangements of alpha-helical or beta-sheet domains, whereby large scale transitions accompany a variety of functions, including inactivation. This unusual behavior was first recognized with the X-ray structure of modified alpha 1-proteinase inhibitor. Subsequent experiments, including new X-ray structures, have revealed a surprising variety of conformations which are functionally important but only partially understood. We review here experimental evidence for conformations relevant to the serpin inhibitory mechanism.

Crystal structure of an uncleaved serpin reveals the conformation of an inhibitory reactive loop

The three-dimensional structure of an uncleaved serpin, a variant of human antichymotrypsin engineered to be an inhibitor of human neutrophil elastase, has been determined by X-ray crystallographic methods and is currently being refined at 2.5 A resolution. It contains an intact reactive loop in a distorted helical conformation. A comparison of the current model with that of its cleaved counterpart suggests that the conformational 'stress' of the serpin in its uncleaved and uncomplexed state may not be confined solely to the reactive loop or beta-sheet A. It is intriguing that strand s4A is not pre-inserted into beta-sheet A of the native serpin, and this has profound implications for the mechanism of serpin function.

Expression of alpha 1-proteinase inhibitor in Escherichia coli: effects of single amino acid substitutions in the active site loop on aggregate formation

Overproduction of eukaryotic proteins in microorganisms often leads to the formation of insoluble protein aggregates which accumulate as intracellular inclusion bodies. alpha 1-Proteinase inhibitor (alpha 1-PI) when produced as a cytoplasmic protein in Escherichia coli (E. coli) forms inclusion bodies containing the majority of the inhibitor in an inactive form. Several variants of alpha 1-PI with single amino acid substitutions within their active site loop (amino acids 345-358) were produced in a bioreactor showing that substitution of Met351 with Glu resulted in significantly reduced aggregate formation compared to the other variants and to wild-type protein. In addition, this variant proved to be fully functional as a proteinase inhibitor. Based on these findings and on results of previous structural studies a mechanism for aggregate formation during expression of alpha 1-PI is suggested.

Regulation of the activity of glyceraldehyde 3-phosphate dehydrogenase by glutathione and H2O2

The activity lost during storage of a solution of muscle glyceraldehyde 3-phosphate dehydrogenase was rapidly restored on adding a thiol compound, but not arsenite or azide. On treatment with H2O2, the enzyme was partially inactivated and complete loss of activity occurred in the presence of glutathione. Samples of the enzyme pretreated with glutathione followed by removal of the thiol compound by filtration on a Sephadex column showed both full activity and its complete loss on adding H2O2, in the absence of added glutathione. Most of the activity was restored when the H2O2-inactivated enzyme was incubated with glutathione (25 mM) or dithiothreitol (5 mM) whereas arsenite or azide were partly effective and ascorbate was ineffective. The need for incubation for a long time with a strong reducing agent for restoration of activity suggests that the oxidized group (disulfide or sulfenate) must be in a masked state in the H2O2-inactivated enzyme. Analysis by SDS-PAGE gave evidence for the formation of a small quantity of glutathione-reversible disulfide-form of the enzyme. Circular dichroic spectra indicated a decrease in alpha-helical content in the inactivated form of the enzyme. The evidence suggest that glutathione and H2O2 can regulate the active state of this enzyme.

Interconversions between active, inert and substrate forms of denatured/refolded type-1 plasminogen activator inhibitor

The latent form of type-1 plasminogen activator inhibitor (PAI-1) acquires inhibitory activity by denaturation followed by refolding. We show here that the reactions of denatured/refolded PAI-1 with plasminogen activators are affected by low concentrations of SDS, which may remain after using SDS for denaturation. Without SDS, the active fraction of denatured/refolded PAI-1 comprised around 60%. Increasing SDS concentrations led to conversions to an inert form without inhibitory activity; then to a substrate form, that is being cleaved proteolytically in the reactive centre by the activators without complex formation, and finally to a second inert form. The first two conversions were associated with changes of the reactivity with monoclonal antibodies and of the thermal stability, respectively. Our results define clearly different interconvertible forms of denatured/refolded PAI-1, distinguish these from the latent and the reactive-centre-cleaved forms, and provide conditions for reproducibly producing reactive-centre-cleaved PAI-1 and PAI-1/activator complexes.

A player of many parts: the spotlight falls on thrombin's structure

The wealth of structural information now available for thrombin, its precursors, its substrates, and its inhibitors allows a rationalization of its many roles. alpha-thrombin is a rather rigid molecule, binding to its target molecules with little conformational change. Comparison of alpha-thrombin with related trypsin-like serine proteinases reveals an unusually deep and narrow active site cleft, formed by loop insertions characteristic of thrombin. This canyon structure is one of the prime causes for the narrow specificity of thrombin. The observed modularity of thrombin allows a diversity in this specificity; its "mix-and-match" nature is exemplified by its interactions with macromolecules (Fig. 20). The apposition of the active site to a hydrophobic pocket (the apolar binding site) on one side and a basic patch (the fibrinogen recognition exosite) on the other allows for a fine tuning of enzymatic activity, as seen for fibrinogen. Thrombin receptor appears to use the same sites, but in a different way. Protein C seems only able to interact with thrombin if the recognition exosite is occupied by thrombomodulin. These two sites are also optimally used by hirudin, allowing the very tight binding observed; thrombin inhibition is effected by blocking access to the active site. On the other hand, antithrombin III makes little use of the recognition exosite; instead, its interactions are tightened with the help of heparin, which binds to a second basic site (the heparin binding site). Thrombin's modularity is a result of the conjunction of amino acid residues of like properties, such as charge or hydrophobicity. The charge distribution plays a role, not only in the binding of oppositely charged moieties of interacting molecules, but also in selection and preorientation of them. Nonproteolytic cellular properties are attributed to 1) the rigid insertion loop at Tyr60A, and 2) a partially inaccessible RGD sequence. The former can interact with cells in the native form; the latter would appear to be presented only in an (at least partially) unfolded state. The membrane binding properties of prothrombin can be understood from the ordered arrangement of calcium ions on binding to the Gla domain. Kringle F2 binds to thrombin at the heparin binding site through charge complementarity; a conformational change appears to occur on binding. The observed rigidity of the thrombin molecule in its complexes makes thrombin ideal for structure based drug design. Thrombin can be inhibited either at the active site or at the fibrinogen recognition exosite, or both.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence for the extent of insertion of the active site loop of intact alpha 1 proteinase inhibitor in beta-sheet A

The extent of insertion of beta-strand s4A into sheet A in intact serpin alpha 1-proteinase inhibitor (alpha 1PI has been probed by peptide annealing experiments [Schulze et al. (1990) Eur. J. Biochem. 194, 51-56]. Twelve synthetic peptides of systematically varied length corresponding in sequence to the unprimed (N-terminal) side of the active site loop were complexed with alpha 1PI. The complexes were then characterized by circular dichroism spectroscopy and tested for inhibitory activity. Four peptides formed complexes which retained inhibitory activity, one of which was nearly as effective as the native protein. Comparison with the three dimensional structures of cleaved alpha 1PI [Löbermann et al. (1984) J. Mol. Biol. 177, 531-556] and plakalbumin [Wright et al. (1990) J. Mol. Biol. 213, 513-528] supports a model in which alpha 1PI requires the insertion of a single residue, Thr345, into sheet A for activity.

Crystal structure of cleaved equine leucocyte elastase inhibitor determined at 1.95 A resolution

The crystal structure of active-site cleaved equine leucocyte elastase inhibitor, a member of the serpin superfamily, has been solved and refined to a crystallographic R-factor of 17.6% at 1.95 A resolution. Despite being an intracellular inhibitor with rather low sequence homology of 30% to human alpha 1-antichymotrypsin and alpha 1-proteinase inhibitor, the three-dimensional structures are very similar, with deviations only at the sites of insertions and few mobile secondary structure elements. The better resolution in comparison with the structures of other cleaved serpins allows a more precise description of the so-called R-state of the serpins.

Natural protein proteinase inhibitors and their interaction with proteinases

The substrate-like 'canonical' inhibition by the 'small' serine proteinase inhibitors and the product-like inhibition by the carboxypeptidase inhibitor have provided the only atomic models of protein inhibitor--proteinase interactions for about 15 years. The recently published structures of cystatin/stefin--papain complexes and of hirudin--thrombin complexes reveal novel non-substrate-like interactions. In addition, the structure of pro-carboxypeptidase shows a model of inactivation which bears resemblance to proteinase/protein inhibitor systems. Considerable progress in understanding the transition between native and cleaved states of the serpins has also been made by several recent structural studies.