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

A structure-derived snap-trap mechanism of a multispecific serpin from the dysbiotic human oral microbiome

Enduring host-microbiome relationships are based on adaptive strategies within a particular ecological niche. Tannerella forsythia is a dysbiotic member of the human oral microbiome that inhabits periodontal pockets and contributes to chronic periodontitis. To counteract endopeptidases from the host or microbial competitors, T. forsythia possesses a serpin-type proteinase inhibitor called miropin. Although serpins from animals, plants, and viruses have been widely studied, those from prokaryotes have received only limited attention. Here we show that miropin uses the serpin-type suicidal mechanism. We found that, similar to a snap trap, the protein transits from a metastable native form to a relaxed triggered or induced form after cleavage of a reactive-site target bond in an exposed reactive-center loop. The prey peptidase becomes covalently attached to the inhibitor, is dragged 75 Å apart, and is irreversibly inhibited. This coincides with a large conformational rearrangement of miropin, which inserts the segment upstream of the cleavage site as an extra β-strand in a central β-sheet. Standard serpins possess a single target bond and inhibit selected endopeptidases of particular specificity and class. In contrast, miropin uniquely blocked many serine and cysteine endopeptidases of disparate architecture and substrate specificity owing to several potential target bonds within the reactive-center loop and to plasticity in accommodating extra β-strands of variable length. Phylogenetic studies revealed a patchy distribution of bacterial serpins incompatible with a vertical descent model. This finding suggests that miropin was acquired from the host through horizontal gene transfer, perhaps facilitated by the long and intimate association of T. forsythia with the human gingiva.

Dnases in health and disease

DNA degradation is critical to healthy organism development and survival. Two nuclease families that play key roles in development and in disease are the Dnase1 and Dnase2 families. While these two families were initially characterized by biochemical function, it is now clear that multiple enzymes in each family perform similar, non-redundant roles in many different tissues. Most Dnase1 and Dnase2 family members are poorly characterized, yet their elimination can lead to a wide range of diseases, including lethal anemia, parakeratosis, cataracts and systemic lupus erythematosus. Therefore, understanding these enzyme families represents a critical field of emerging research. This review explores what is currently known about Dnase1 and Dnase2 family members, highlighting important questions about the structure and function of family members, and how their absence translates to disease.

Crystallization and diffraction analysis of the serpin IRS-2 from the hard tick Ixodes ricinus

IRS-2 from the hard tick Ixodes ricinus belongs to the serpin family of protease inhibitors. It is produced in the salivary glands of the tick and its anti-inflammatory activity suggests that it plays a role in parasite-host interaction. Recombinant IRS-2 prepared by heterologous expression in a bacterial system was crystallized using the hanging-drop vapour-diffusion method. The crystals belonged to the primitive tetragonal space group P4(3) and diffracted to 1.8 Å resolution. Mass-spectrometric and electrophoretic analyses revealed that IRS-2 was cleaved by contaminating proteases during crystallization. This processing of IRS-2 mimicked the specific cleavage of the serpin by its target protease and resulted in a more stable form (the so-called relaxed conformation), which produced well diffracting crystals. Activity profiling with specific substrates and inhibitors demonstrated traces of serine and cysteine proteases in the protein stock solution.

A tick salivary protein targets cathepsin G and chymase and inhibits host inflammation and platelet aggregation

Platelet aggregation and acute inflammation are key processes in vertebrate defense to a skin injury. Recent studies uncovered the mediation of 2 serine proteases, cathepsin G and chymase, in both mechanisms. Working with a mouse model of acute inflammation, we revealed that an exogenous salivary protein of Ixodes ricinus, the vector of Lyme disease pathogens in Europe, extensively inhibits edema formation and influx of neutrophils in the inflamed tissue. We named this tick salivary gland secreted effector as I ricinus serpin-2 (IRS-2), and we show that it primarily inhibits cathepsin G and chymase, while in higher molar excess, it affects thrombin activity as well. The inhibitory specificity was explained using the crystal structure, determined at a resolution of 1.8 Å. Moreover, we disclosed the ability of IRS-2 to inhibit cathepsin G-induced and thrombin-induced platelet aggregation. For the first time, an ectoparasite protein is shown to exhibit such pharmacological effects and target specificity. The stringent specificity and biological activities of IRS-2 combined with the knowledge of its structure can be the basis for the development of future pharmaceutical applications.

A rapid coarse residue-based computational method for x-ray solution scattering characterization of protein folds and multiple conformational states of large protein complexes

We present a coarse residue-based computational method to rapidly compute the solution scattering profile from a protein with dynamical fluctuations. The method is built upon a coarse-grained (CG) representation of the protein. This CG representation takes advantage of the intrinsic low-resolution and CG nature of solution scattering data. It allows rapid scattering determination from a large number of conformations that can be extracted from CG simulations to obtain scattering characterization of protein conformations. The method includes several important elements, effective residue structure factors derived from the Protein Data Bank, explicit treatment of water molecules in the hydration layer at the surface of the protein, and an ensemble average of scattering from a variety of appropriate conformations to account for macromolecular flexibility. This simplified method is calibrated and illustrated to accurately reproduce the experimental scattering curve of Hen egg white lysozyme. We then illustrated the applications of this CG method by computing the solution scattering patterns of several representative protein folds and multiple conformational states. The results suggest that solution scattering data, when combined with the reliable computational method that we developed, show great potential for a better structural description of multidomain complexes in different functional states, and for recognizing structural folds when sequence similarity to a protein of known structure is low.

The spontaneous polymerization of plasminogen activator inhibitor type-2 and Z-antitrypsin are due to different molecular aberrations

The wild-type form of plasminogen activator inhibitor type-2 (PAI-2) and the pathogenic Z-mutant of alpha(1)-antitrypsin (alpha(1)AT) are serpins that spontaneously polymerize by the loop-sheet mechanism. Compared to the consensus serpin sequence, both PAI-2 and Z-alpha(1)AT have deviations in the so-called breach region located at the top of the A beta-sheet. In the case of Z-alpha(1)AT, conformational perturbations caused by a single amino acid substitution result in polymerization in vivo and predisposes to disease. To test whether the polymerization of PAI-2 is due to aberrations in the breach region, we constructed substitution mutants of PAI-2 with conserved residues in this region. Analysis of the mutants revealed that deviations in the breach region modulate but are not the major cause of PAI-2 polymerization. Rather, PAI-2 exists in a highly polymerogenic conformation and does not require conformational rearrangements before polymerization can take place.

Identification and characterization of a novel rat ov-serpin family member, trespin

Serpins are responsible for regulating a variety of proteolytic processes through a unique irreversible suicide substrate mechanism. To discover novel genes regulated by transforming growth factor-beta1 (TGF-beta 1), we performed differential display reverse transcriptase-PCR analysis of NRP-152 rat prostatic epithelial cells and cloned a novel rat serpin that is transcriptionally down-regulated by TGF-beta and hence named trespin (TGF-beta-repressible serine proteinase inhibitor (trespin). Trespin is a 397-amino acid member of the ov-serpin clade with a calculated molecular mass of 45.2 kDa and 72% amino acid sequence homology to human bomapin; however, trespin exhibits different tissue expression, cellular localization, and proteinase specificity compared with bomapin. Trespin mRNA is expressed in many tissues, including brain, heart, kidney, liver, lung, prostate, skin, spleen, and stomach. FLAG-trespin expressed in HEK293 cells is localized predominantly in the cytoplasm and is not constitutively secreted. The presence of an arginine at the P1 position of trespin's reactive site loop suggests that trespin inhibits trypsin-like proteinases. Accordingly, in vitro transcribed and translated trespin forms detergent-stable and thermostable complexes with plasmin and elastase but not subtilisin A, trypsin, chymotrypsin, thrombin, or papain. Trespin interacts with plasmin at a near 1:1 stoichiometry, and immunopurified mammal-expressed trespin inhibits plasmin in a dose-dependent manner. These data suggest that trespin is a novel and functional member of the rat ov-serpin family.

Crystal structure of the complex of plasminogen activator inhibitor 2 with a peptide mimicking the reactive center loop

The structure of the serpin, plasminogen activator inhibitor type-2 (PAI-2), in a complex with a peptide mimicking its reactive center loop (RCL) has been determined at 1.6-A resolution. The structure shows the relaxed state serpin structure with a prominent six-stranded beta-sheet. Clear electron density is seen for all residues in the peptide. The P1 residue of the peptide binds to a well defined pocket at the base of PAI-2 that may be important in determining the specificity of protease inhibition. The stressed-to-relaxed state (S --> R) transition in PAI-2 can be modeled as the relative motion between a quasirigid core domain and a smaller segment comprising helix hF and beta-strands s1A, s2A, and s3A. A comparison of the Ramachandran plots of the stressed and relaxed state PAI-2 structures reveals the location of several hinge regions connecting these two domains. The hinge regions cluster in three locations on the structure, ensuring a cooperative S --> R transition. We hypothesize that the hinge formed by the conserved Gly(206) on beta-strand s3A in the breach region of PAI-2 effects the S --> R transition by altering its backbone torsion angles. This torsional change is due to the binding of the P14 threonine of the RCL to the open breach region of PAI-2.

Interaction between the P14 residue and strand 2 of beta-sheet B is critical for reactive center loop insertion in plasminogen activator inhibitor-2

The molecular interactions driving reactive center loop (RCL) insertion are of considerable interest in gaining a better understanding of the serpin inhibitory mechanism. Previous studies have suggested that interactions in the proximal hinge/breach region may be critical determinants of RCL insertion in serpins. In this study, conformational and functional changes in plasminogen activator inhibitor-2 (PAI-2) following incubation with a panel of synthetic RCL peptides indicated that the P14 residue is critical for RCL insertion, and hence inhibitory activity, in PAI-2. Only RCL peptides with a P14 threonine were able to induce the stressed to relaxed transition and abolish inhibitory activity in PAI-2, indicating that RCL insertion into beta-sheet A of PAI-2 is dependent upon this residue. The recently solved crystal structure of relaxed PAI-2 (PAI-2.RCL peptide complex) allowed detailed analysis of molecular interactions involving P14 related to RCL insertion. Of most interest is the rearrangement of hydrogen bonding around the breach region that accompanies the stressed to relaxed transition, in particular the formation of a side chain hydrogen bond between the threonine at P14 and an adjacent tyrosine on strand 2 of beta-sheet B in relaxed PAI-2. Structural alignment of known serpin sequences showed that this pairing (or the equivalent serine/threonine pairing) is highly conserved ( approximately 87%) in inhibitory serpins and may represent a general structural basis for serpin inhibitory activity.

Crystal structure of neuroserpin: a neuronal serpin involved in a conformational disease

The protease inhibitor neuroserpin regulates the development of the nervous system and its plasticity in the adult. Neuroserpins carrying the Ser53Pro or Ser56Arg mutation form polymers in neuronal cells. We describe here the structure of wild-type neuroserpin in a cleaved form. The structure provides a basis to understand the role of the mutations in the polymerization process. We propose that these mutations could delay the insertion of the reactive center loop into the central beta-sheet A, an essential step in the inhibition and possibly in the polymerization of neuroserpin.

The necrotic gene in Drosophila corresponds to one of a cluster of three serpin transcripts mapping at 43A1.2

Mutants of the necrotic (nec) gene in Drosophila melanogaster die in the late pupal stage as pharate adults, or hatch as weak, but relatively normal-looking, flies. Adults develop black melanized spots on the body and leg joints, the abdomen swells with hemolymph, and flies die within 3 or 4 days of eclosion. The TOLL-mediated immune response to fungal infections is constitutively activated in nec mutants and pleiotropic phenotypes include melanization and cellular necrosis. These changes are consistent with activation of one or more proteolytic cascades. The nec gene corresponds to Spn43Ac, one of a cluster of three putative serine proteinase inhibitors at 43A1.2, on the right arm of chromosome 2. Although serpins have been implicated in the activation of many diverse pathways, lack of an individual serpin rarely causes a detectable phenotype. Absence of Spn43Ac, however, gives a clear phenotype, which will allow a mutational analysis of critical features of the molecular structure of serpins.

An analysis of the helix-to-strand transition between peptides with identical sequence

An analysis of peptide segments with identical sequence but that differ significantly in structure was performed over non-redundant databases of protein structures. We focus on those peptides, which fold into an alpha-helix in one protein but a beta-strand in another. While the study shows that many such structurally ambivalent peptides contain amino acids with a strong helical preference collocated with amino acids with a strong strand preference, the results overwhelmingly indicate that the peptide's environment ultimately dictates its structure. Furthermore, the first naturally occurring structurally ambivalent nonapeptide from evolutionary unrelated proteins is described, highlighting the intrinsic plasticity of peptide sequences. We even find seven proteins that show structural ambivalence under different conditions. Finally, a computer algorithm has been implemented to identify regions in a given sequence where secondary structure prediction programs are likely to make serious mispredictions.

Crystal structure of viral serpin crmA provides insights into its mechanism of cysteine proteinase inhibition

CrmA is an unusual viral serpin that inhibits both cysteine and serine proteinases involved in the regulation of host inflammatory and apoptosis processes. It differs from other members of the serpin superfamily by having a reactive center loop that is one residue shorter, and by its apparent inability to form SDS-stable covalent complexes with cysteine proteinases. To obtain insight into the inhibitory mechanism of crmA, we determined the crystal structure of reactive center loop-cleaved crmA to 2.9 A resolution. The structure, which is the first of a viral serpin, suggests that crmA can inhibit cysteine proteinases by a mechanism analogous to that used by other serpins against serine proteinases. However, one striking difference from other serpins, which may be significant for in vivo function, is an additional highly charged antiparallel strand for b sheet A, whose sequence and length are unique to crmA.

Crystal structure of the apoptotic suppressor CrmA in its cleaved form

BACKGROUND

Cowpox virus expresses the serpin CrmA (cytokine response modifier A) in order to avoid inflammatory and apoptotic responses of infected host cells. The targets of CrmA are members of the caspase family of proteases that either initiate the extrinsic pathway of apoptosis (caspases 8 and 10) or trigger activation of the pro-inflammatory cytokines interleukin-1beta and interleukin-18 (caspase 1).

RESULTS

We have determined the structure of a cleaved form of CrmA to 2.26 A resolution. CrmA has the typical fold of a cleaved serpin, even though it lacks the N-terminal half of the A helix, the entire D helix, and a portion of the E helix that are present in all other known serpins. The reactive-site loop of CrmA was mutated to contain the optimal substrate recognition sequence for caspase 3; however, the mutation only marginally increased the ability of CrmA to inhibit caspase 3. Superposition of the reactive-site loop of alpha1-proteinase inhibitor on the cleaved CrmA structure provides a model for virgin CrmA that can be docked to caspase 1, but not to caspase 3.

CONCLUSIONS

CrmA exemplifies viral economy, selective pressure having resulted in a 'minimal' serpin that lacks the regions not needed for structural integrity or inhibitory activity. The docking model provides an explanation for the selectivity of CrmA. Our demonstration that engineering optimal substrate recognition sequences into the CrmA reactive-site loop fails to generate a good caspase 3 inhibitor is consistent with the docking model.

Topography of a 2.0 A structure of alpha1-antitrypsin reveals targets for rational drug design to prevent conformational disease

Members of the serpin family of serine proteinase inhibitors play important roles in the inflammatory, coagulation, fibrinolytic, and complement cascades. An inherent part of their function is the ability to undergo a structural rearrangement, the stressed (S) to relaxed (R) transition, in which an extra strand is inserted into the central A beta-sheet. In order for this transition to take place, the A sheet has to be unusually flexible. Malfunctions in this flexibility can lead to aberrant protein linkage, serpin inactivation, and diseases as diverse as cirrhosis, thrombosis, angioedema, emphysema, and dementia. The development of agents that control this conformational rearrangement requires a high resolution structure of an active serpin. We present here the topology of the archetypal serpin alpha1-antitrypsin to 2 A resolution. This structure allows us to define five cavities that are potential targets for rational drug design to develop agents that will prevent conformational transitions and ameliorate the associated disease.

A kinetic mechanism for the polymerization of alpha1-antitrypsin

The mutation in the Z deficiency variant of alpha1-antitrypsin perturbs the structure of the protein to allow a unique intermolecular linkage. These loop-sheet polymers are retained within the endoplasmic reticulum of hepatocytes to form inclusions that are associated with neonatal hepatitis, juvenile cirrhosis, and hepatocellular carcinoma. The process of polymer formation has been investigated here by intrinsic tryptophan fluorescence, fluorescence polarization, circular dichroic spectra and extrinsic fluorescence with 8-anilino-1-naphthalenesulfonic acid and tetramethylrhodamine-5-iodoacetamide. These biophysical techniques have demonstrated that alpha1-antitrypsin polymerization is a two-stage process and have allowed the calculation of rates for both of these steps. The initial fast phase is unimolecular and likely to represent temperature-induced protein unfolding, while the slow phase is bimolecular and associated with loop-sheet interaction and polymer formation. The naturally occurring Z, S, and I variants and recombinant site-directed reactive loop and shutter domain mutants of alpha1-antitrypsin were used to demonstrate the close association between protein stability and rate of alpha1-antitrypsin polymerization. Taken together, these data allow us to propose a kinetic mechanism for alpha1-antitrypsin polymer formation that involves the generation of an unstable intermediate, which can form polymers or generate latent protein.

MENT, a heterochromatin protein that mediates higher order chromatin folding, is a new serpin family member

Terminal cell differentiation is correlated with the extensive sequestering of previously active genes into compact transcriptionally inert heterochromatin. In vertebrate blood cells, these changes can be traced to the accumulation of a developmentally regulated heterochromatin protein, MENT. Cryoelectron microscopy of chicken granulocyte chromatin, which is highly enriched with MENT, reveals exceptionally compact polynucleosomes, which maintain a level of higher order folding above that imposed by linker histones. The amino acid sequence of MENT reveals a close structural relationship with serpins, a large family of proteins known for their ability to undergo dramatic conformational transitions. Conservation of the "hinge region" consensus in MENT indicates that this ability is retained by the protein. MENT is distinguished from the other serpins by being a basic protein, containing several positively charged surface clusters, which are likely to be involved in ionic interactions with DNA. One of the positively charged domains bears a significant similarity to the chromatin binding region of nuclear lamina proteins and with the A.T-rich DNA-binding motif, which may account for the targeting of MENT to peripheral heterochromatin. MENT ectopically expressed in a mammalian cell line is transported into nuclei and is associated with intranuclear foci of condensed chromatin.

Topology of the stable serpin-protease complexes revealed by an autoantibody that fails to react with the monomeric conformers of antithrombin

Solving the structure of the stable complex between a serine protease inhibitor (serpin) and its target has been a long standing goal. We describe herein the characterization of a monoclonal antibody that selectively recognizes antithrombin in complex with either thrombin, factor Xa, or a synthetic peptide corresponding to residues P14 to P9 of the serpin's reactive center loop (RCL, ultimately cleaved between the P1 and P'1 residues). Accordingly, this antibody reacts with none of the monomeric conformers of antithrombin (native, latent, and RCL-cleaved) and does not recognize heparin-activated antithrombin or antithrombin bound to a non-catalytic mutant of thrombin (S195A, in which the serine of the charge stabilizing system has been swapped for alanine). The neoepitope encompasses the motif DAFHK, located in native antithrombin on strand 4 of beta-sheet A, which becomes strand 5 of beta-sheet A in the RCL-cleaved and latent conformers. The inferences on the structure of the antithrombin-protease stable complex are that either a major remodeling of antithrombin accompanies the final elaboration of the complex or that, within the complex, at the most residues P14 to P6 of the RCL are inserted into beta-sheet A. These conclusions limit drastically the possible locations of the defeated protease within the complex.

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.

Identification and characterization of a serpin with differential expression during the life cycle of the sea lamprey

We have cloned a member of the serine proteinase inhibitor gene superfamily from the sea lamprey, Petromyzon marinus. The predicted translation product contains a putative signal peptide and mRNA expression is localized mainly to the liver. Northern blot analysis indicates that the mRNA increases in the larvae and peaks in late larval life. At the onset of metamorphosis there is a approximately 10-fold drop after which it remains low. These changes correspond with levels of circulating thyroid hormone suggesting that this serpin is involved in or regulated by molecular signals that induce metamorphosis in the lamprey. Use of alignments and structural information from other serpins indicates that the lamprey serpin has the potential to be inhibitory. In addition the lamprey serpin contains methionine and serine at the P1 and P1' positions, respectively. Appropriate residues at positions important in allowing the insertion of strand s4A into beta-sheet A that occurs upon cleavage in inhibitory serpins are also found in the lamprey serpin.

Engineering an anion-binding cavity in antichymotrypsin modulates the "spring-loaded" serpin-protease interaction

Expressed in a kinetically trapped folding state, a serpin couples the thermodynamic driving force of a massive beta-sheet rearrangement to the inhibition of a target protease. Hence, the serpin-protease interaction is the premier example of a "spring-loaded" protein-protein interaction. Amino acid substitutions in the hinge region of a serpin reactive loop can weaken the molecular spring, which converts the serpin from an inhibitor into a substrate. To probe the molecular basis of this conversion, we report the crystal structure of A349R antichymotrypsin in the reactive loop cleaved state at 2.1 A resolution. This amino acid substitution does not block the beta-sheet rearrangement despite the burial of R349 in the hydrophobic core of the cleaved serpin along with a salt-linked acetate ion. The inhibitory activity of this serpin variant is not obliterated; remarkably, its inhibitory properties are anion-dependent due to the creation of an anion-binding cavity in the cleaved serpin.

An atlas of serpin conformations

The serpins are a family of proteins that inhibit chymotrypsin-like serine proteinases, with an unusual mechanism involving a large conformational change known as the stressed-->relaxed (S-->R) transition. This article is a guide to the known serpin conformations and their biological significance.

Wild-type alpha 1-antitrypsin is in the canonical inhibitory conformation

alpha 1-Antitrypsin is the archetypal member of the serine proteinase inhibitor or serpin superfamily. Members of the family show structural homology based on a dominant A beta-sheet and a mobile reactive centre loop. Our recent crystal structure of alpha 1-antitrypsin stabilized with a point mutation showed the loop to be in a canonical inhibitory conformation in the absence of significant insertion into the A beta-sheet. It could be argued that the stabilizing mutation may induce the reactive centre loop to adopt an artificial, and unrepresentative, conformation and the finding seems to be at variance with studies assessing rates of peptide insertion into the A beta-sheet and limited proteolysis of the reactive loop. Here we present a 2.9 A structure of recombinant wild-type alpha 1-antitrypsin with no stabilizing mutations. Again, the reactive loop is in a canonical conformation in the absence of significant insertion into the A beta-sheet. A stabilizing salt bridge between P5 glutamate and arginine residues 196, 223 and 281, already identified in the mutant, provides strong evidence that this conformation is not an artefact of crystallization but represents the conformation of the circulating inhibitor in vivo. Comparison with the structure of alpha 1-antitrypsin stabilized with the Phe51Leu mutation indicates that the increased thermal stability of the mutant results from enhanced packing of aromatic residues in the hydrophobic core of the molecule. The structure of wild-type alpha 1-antitrypsin reveals a hydrophobic pocket between s2A and helices D and E that is filled on reactive loop insertion and the formation of biologically relevant loop-sheet polymers. This pocket may provide a target for rational drug design to prevent the formation of polymers and the associated plasma deficiency, liver cirrhosis and emphysema.

Effects of serpin binding on the target proteinase: global stabilization, localized increased structural flexibility, and conserved hydrogen bonding at the active site

The binding of human alpha1-proteinase inhibitor to rat trypsin was shown by NMR spectroscopy to raise the pKa' of His57 in the active site but not to disrupt the hydrogen bond between His57 and Asp102. Similar NMR results were observed for the Asp189 to serine mutant of rat trypsin, which is much more stable than wild-type trypsin against autoproteolysis as the result of mutation of the residue at the base of the specificity pocket. This mutant was used in further studies aimed at determining the extent of the conformational transition in trypsin that accompanies serpin binding and leads to disruption of the catalytic activity of the proteinase such that the inhibitor complex is trapped at the acyl enzyme intermediate stage. The stability of rat trypsin toward thermal denaturation was found to be lower in the free enzyme than in the complex with alpha1-proteinase inhibitor. This suggests that the complex contains extensive protein-protein interactions that stabilize overall folding. On the other hand, previous investigations have shown that the proteinase in serpin-proteinase complexes becomes more susceptible to limited proteolysis, suggesting that the conformational change that accompanies binding leads to the exposure of susceptible loops in the enzyme. The existence of this type of conformational change upon complex formation has been confirmed here by investigation of the rate of cleavage of disulfide linkages by added dithiothreitol. This study revealed that, despite the increased stability of trypsin in the complex, one or more of its disulfide bridges becomes much more easily reduced. We suggest that the process of complex formation with alpha1-proteinase inhibitor converts trypsin D189S into an inactive, loose structure, which serves as a "conformational trap" of the enzyme that prevents catalytic deacylation. It is also proposed that plastic region(s) of the activation domain of trypsin may play a crucial role in this inhibitor-induced structural rearrangement.

Analysis of serpin inhibitory function by mutagenesis of ovalbumin and generation of chimeric ovalbumin/PAI-2 fusion proteins

Ovalbumin is a non-inhibitory serpin which lacks the ability to undergo the S --> R transition or conformational change. Amino acid residues in the hinge region (P11 to P14) of ovalbumin and other non-inhibitory serpins differ from the concensus sequence of this region of inhibitory serpins, and have been proposed to be responsible for lack of inhibitory properties, particularly the P14 charged residue. Site directed mutagenesis using PCR overlap extension was performed on these residues in ovalbumin to create a mutant with three amino acid changes, R340T, V342A and V343A. However analysis of the mutant recombinant ovalbumin with the consensus residues failed to show inhibitory activity or decreased stability, indicating that the hinge region alone is not responsible for lack of inhibition. A series of three fusion proteins were then constructed by replacing varying C-terminal regions of ovalbumin with the corresponding region of the inhibitory ov-serpin PAI-2 in order to further analyse serpin inhibitory function. Fusion proteins F1 and F2 contained approximately 16% and 35% PAI-2, respectively. This resulted in the replacing of structural features such as the reactive site loop, hinge region and beta sheet strands 5A and 6A. However both fusion proteins showed no inhibitory activity with the PAI-2 target protease urokinase (uPA) and no decrease in stability as analysed by transverse urea gradient (TUG) gels. The third chimeric fusion protein constructed (F3) contained 64% PAI-2 and did demonstrate inhibition of uPA, SDS-PAGE stable complex formation with uPA and increased instability on TUG gels. Structural differences between the inactive F2 and active F3 include the replacement of helix F and beta sheet strand 3A of ovalbumin with those of PAI-2, suggesting that these features may have a key role in serpin beta-sheet opening and inhibitory function.

Importance of the release of strand 1C to the polymerization mechanism of inhibitory serpins

Serpin polymerization is the underlying cause of several diseases, including thromboembolism, emphysema, liver cirrhosis, and angioedema. Understanding the structure of the polymers and the mechanism of polymerization is necessary to support rational design of therapeutic agents. Here we show that polymerization of antithrombin is sensitive to the addition of synthetic peptides that interact with the structure. A 12-m34 peptide (homologous to P14-P3 of antithrombin reactive loop), representing the entire length of s4A, prevented polymerization totally. A 6-mer peptide (homologous to P14-P9 of antithrombin) not only allowed polymerization to occur, but induced it. This effect could be blocked by the addition of a 5-mer peptide with s1C sequence of antithrombin or by an unrelated peptide representing residues 26-31 of cholecystokinin. The s1C or cholecystokinin peptide alone was unable to form a complex with native antithrombin. Moreover, an active antitrypsin double mutant, Pro 361-->Cys, Ser 283-->Cys, was engineered for the purpose of forming a disulfide bond between s1C and s2C to prevent movement of s1C. This mutant was resistant to polymerization if the disulfide bridge was intact, but, under reducing conditions, it regained the potential to polymerize. We have also modeled long-chain serpin polymers with acceptable stereochemistry using two previously proposed loop-A-sheet and loop-C-sheet polymerization mechanisms and have shown both to be sterically feasible, as are "mixed" linear polymers. We therefore conclude that the release of strand 1C must be an element of the mechanism of serpin polymerization.

Pepsin-inhibitory activity of the uterine serpins

Among the major products secreted by the uteri of cattle, sheep, and pigs during pregnancy are glycoproteins with amino acid sequences that place them in the serpin (serine proteinase inhibitor) superfamily of proteins. The inferred amino acid sequences for bovine uterine serpin (boUS-1) and ovine uterine serpin (ovUS-1) exhibit about 72% sequence identity to each other but only about 50% and 56% identity, respectively, to two distinct porcine uterine serpins (poUS-1 and poUS-2). Despite these differences in primary structure, the uterine serpins possess well-conserved reactive center loop regions that contain several motifs present in the propeptide regions of pepsinogens. One such motif, VVVK, aligns with the first 4 amino acids of the aspartic proteinase inhibitor pepstatin. Although no inhibitory activity toward any serine proteinase has been found, at least one of the uterine serpins, ovUS-1, can bind specifically to immobilized pepsin A and can weakly inhibit the proteolytic activities of pepsin A and C (but not cathepsins D and E). OvUS-1 is the first specific inhibitor of aspartic proteinases to be identified in vertebrates and provides another example of a serpin with "crossover" activity. The pregnancy-associated glycoproteins (PAGs), which are secreted by the trophoblast layer of the placentas of ungulate species and are inactive members of the aspartic proteinase family, can also bind ovUS-1 and may be the natural target partners for the uterine serpins.

Serpin alpha 1proteinase inhibitor probed by intrinsic tryptophan fluorescence spectroscopy

Various conformational forms of the archetypal serpin human alpha 1proteinase inhibitor (alpha 1PI), including ordered polymers, active and inactive monomers, and heterogeneous aggregates, have been produced by refolding from mild denaturing conditions. These forms presumably originate by different folding pathways during renaturation, under the influence of the A and C sheets of the molecule. Because alpha 1PI contains only two Trp residues, at positions 194 and 238, it is amenable to fluorescence quenching resolved spectra and red-edge excitation measurements of the Trp environment. Thus, it is possible to define the conformation of the various forms based on the observed fluorescent properties of each of the Trp residues measured under a range of conditions. We show that denaturation in GuHCl, or thermal denaturation in Tris, followed by renaturation, leads to the formation of polymers that contain solvent-exposed Trp 238, which we interpret as ordered head-to-tail polymers (A-sheet polymers). However, thermal denaturation in citrate leads to shorter polymers where some of the Trp 238 residues are not solvent accessible, which we interpret as polymers capped by head-to-head interactions via the C sheet. The latter treatment also generates monomers thought to represent a latent form, but in which the environment of Trp 238 is occluded by ionized groups. These data indicate that the folding pathway of alpha 1PI, and presumably other serpins, is sensitive to solvent composition that affects the affinity of the reactive site loop for the A sheet or the C sheet.

Modeling of serpin-protease complexes: antithrombin-thrombin, alpha 1-antitrypsin (358Met-->Arg)-thrombin, alpha 1-antitrypsin (358Met-->Arg)-trypsin, and antitrypsin-elastase

Based on the most recent available crystal structures and biochemical studies of protease complexes of normal and mutant serine protease inhibitors (serpins), we have built models of the complexes: alpha 1-antitrypsin + human neutrophil elastase; alpha 1-antitrypsin Pittsburgh (358Met-->Arg) (Scott et al., J. Clin. Invest. 77:631-634, 1986) + tyrpsin; alpha 1-antitrypsin Pittsburgh (358Met-->Arg) + thrombin; and antithrombin + thrombin. All serpin sequences correspond to human molecules. The models show correct stereochemistry and no steric clashes between protease and inhibitor. The main structural differences in the serpins from the parent structures are: (1) the reactive center loop is inserted into the A-sheet as far as P12; (2) strand s1C is removed from the C-sheet; and (3) the C-terminus has changed conformation and interacts with the protease. In the absence of an X-ray structure determination of a serpin-protease complex, the demonstration that insertion of the reactive center loop into the A-sheet as far as P12 is stereochemically feasible provides structures of a protease-bound conformation of intact serpins with which to rationalize the properties of mutants, guide the design of experiments, and form a basis for further modeling studies, such as the investigation of the interaction of heparin with serpin-protease complexes.

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.

Is the binding of beta-amyloid protein to antichymotrypsin in Alzheimer plaques mediated by a beta-strand insertion?

A growing body of experimental evidence demonstrates that the serpin antichymotrypsin plays a regulatory role in Alzheimer plaque physiology by interacting with the 42 residue beta-amyloid protein, and we have used molecular modeling and energy minimization techniques to study this interaction. Based on the unique plasticity of beta-sheet elements in antichymotrypsin (as well as other serpins), we conclude that the interaction of the two proteins is mediated by insertion of the N-terminus of beta-amyloid into beta-sheet C of antichymotrypsin as a pseudo-strand s1C. This beta-strand insertion requires the displacement of native antichymotrypsin strand s1C, which is known to occur partially or completely at different stages of serpin function. Thus, the association of the two proteins in vivo may be facilitated by a particular functional state of the serpin, e.g., the native or protease-complexed state.

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.

Significance of secondary structure predictions on the reactive center loop region of serpins: a model for the folding of serpins into a metastable state

To address how serpins might fold so as to adopt the mechanistically required metastable conformation we have compared the predicted secondary structures of the reactive center loops (RCLs) of a large number of serpins with those of the equivalent regions of other non-serpin protein proteinase inhibitors. Whereas the RCLs of non-serpin inhibitors are predicted to be loop or beta-strand, those of inhibitory serpins are strongly predicted to be alpha-helical. However, non-inhibitory serpins, which also adopt the metastable conformation, show no consistent preference for alpha-helix. We propose that the RCL primary structure plays little role in promoting the metastable serpin conformation. Instead we hypothesize that preference for the metastable state results from the incorporation of part of the RCL into beta-sheet C, which as a consequence precludes incorporation of the RCL into beta-sheet A to give the most stable conformation. Consequently the RCL must be exposed and by default will adopt the most stable conformation in this particular context, which is likely to be an alpha-helix irrespective of the primary structure. Thus the observed correlation between inhibitory properties in serpins and prediction of alpha-helix in the RCL may instead reflect a need for alanine residues between positions P12 and P9 for functioning as an inhibitor rather than a structural or mechanistic requirement for alpha-helix.

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.

alpha 1-Antitrypsin Mmalton (Phe52-deleted) forms loop-sheet polymers in vivo. Evidence for the C sheet mechanism of polymerization

The Z (Glu342-->Lys) and Siiyama (Ser53-->Phe) deficiency variants of alpha 1-antitrypsin result in the retention of protein in the endoplasmic reticulum of the hepatocyte by loop-sheet polymerization in which the reactive center loop of one molecule is inserted into a beta-pleated sheet of a second. We show here that antitrypsin Mmalton (Phe52-deleted), which is associated with the same liver inclusions, is also retained at an endoglycosidase H-sensitive stage of processing in the Xenopus oocyte and spontaneously forms polymers in vivo. These polymers, obtained from the plasma of an Mmalton/QO (null) bolton heterozygote, were much shorter than other antitrypsin polymers and contained a reactive center loop-cleaved species. Monomeric mutant antitrypsin was also isolated from the plasma. The monomeric component had a normal unfolding transition on transverse urea gradient gel electrophoresis and formed polymers in vitro more readily than M, but less readily than Z, antitrypsin. The A beta-sheet accommodated a reactive center loop peptide much less readily than Z antitrypsin, which in turn was less receptive than native M antitrypsin. The nonreceptive conformation of the A sheet in antitrypsin Mmalton had little effect on kinetic parameters, the formation of SDS-stable complexes, the S to R transition, and the formation of the latent conformation. Comparison of the results with similar findings of short chain polymers associated with the antithrombin variant Rouen VI (Bruce, D., Perry, D., Borg, J.-Y., Carrell, R. W., and Wardell, M. R. (1994) J. Clin. Invest. 94, 2265-2274) suggests that polymerization is more complicated than the mechanism proposed earlier. The Z, Siiyama, and Mmalton mutations favor a conformational change in the antitrypsin molecule to an intermediate between the native and latent forms. This would involve a partial overinsertion of the reactive loop into the A sheet with displacement of strand 1C and consequent loop-C sheet polymerization.

Structural basis for serpin inhibitor activity

The mechanism of formation and the structures of serpin-inhibitor complexes are not completely understood, despite detailed knowledge of the structures of a number of cleaved and uncleaved inhibitor, noninhibitor, and latent serpins. It has been proposed from comparison of inhibitor and noninhibitor serpins in the cleaved and uncleaved forms that insertion of strand s4A into preexisting beta-sheet A is a requirement for serpin inhibitor activity. We have investigated the role of this strand in formation of serpin-proteinase complexes and in serpin inhibitor activity through homology modeling of wild type inhibitor, mutant substrate, and latent serpins, and of putative serpin-proteinase complexes. These models explain the high stability of the complexes and provide an understanding of substrate behavior in serpins with point mutations in s4A and of latency in plasminogen activator inhibitor I.

Inhibitory mechanism of serpins. Interaction of thrombin with antithrombin and protease nexin 1

The mechanism for the inhibition of thrombin by the serpins antithrombin and protease nexin 1 has been investigated using several kinetic techniques at pH 7.9 and 37 degrees C with an ionic strength of 0.3 M. Rapid kinetic studies demonstrated that a two-step mechanism for the formation of the stable thrombin-serpin complex applied to both serpins. The inhibition constant for the initial thrombin-antithrombin complex was 265 microM, and the rate constant for the conversion of this complex to the final one was 3.9 s-1; the corresponding values for PN1 were 3.4 microM and 6.0 s-1. By using slow-binding kinetics, it was possible to obtain estimates of the second-order rate constants for the formation of the stable thrombin-serpin complexes (1.2 x 10(4) and 1.5 x 10(6) M-1 s-1 for antithrombin and protease nexin 1, respectively) and the dissociation constants for these complexes (< 1 nM for both serpins). The influence of viscosity on the reactions indicated that the rate of interaction of both serpins with thrombin was diffusion-controlled. Moreover, the results indicated that the initial complex reacted more rapidly to form the stable complex than it dissociated to free enzyme and inhibitor; i.e., the behavior of the serpins was analogous to that of "sticky" substrates. By using the results from slow-binding, viscosity, and rapid kinetic studies, it was possible to set values for all of the rate constants for the interactions of antithrombin and protease nexin 1 with thrombin.(ABSTRACT TRUNCATED AT 250 WORDS)

Preparation and characterization of latent alpha 1-antitrypsin

Members of the serine proteinase inhibitor or serpin superfamily have a common molecular architecture based on a dominant five-membered A beta-pleated sheet and a mobile reactive center loop. The reactive center loop has been shown to adopt a range of conformations from the three turn alpha-helix of ovalbumin to the cleaved or latent inhibitor in which the reactive center loop is fully inserted into the A sheet of the molecule. While the cleaved state can be achieved in all inhibitory serpins only plasminogen activator inhibitor-1 and, more recently, antithrombin have been shown to adopt the latent conformation. We show here that the archetypal serpin, alpha 1-antitrypsin, can also be induced to adopt the latent conformation by heating at high temperatures in 0.7 M citrate for 12 h. The resulting species elutes at a lower sodium chloride concentration on an anion-exchange column and has a more cathodal electrophoretic mobility on non-denaturing polyacrylamide gel electrophoresis and isoelectric focusing than native M antitrypsin. Latent antitrypsin is inactive as an inhibitor of bovine alpha-chymotrypsin, is stable to unfolding with 8 M urea, and is more resistant to heat-induced loop-sheet polymerization than native but less resistant than cleaved antitrypsin. The reactive center loop of latent antitrypsin is inaccessible to proteolytic cleavage, and its occupancy of the A sheet prevents the molecule accepting an exogenous reactive center loop peptide. The activity of latent antitrypsin may be increased from < 1% to approximately 35% by refolding from 6 M guanidinium chloride.

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.

Biological implications of a 3 A structure of dimeric antithrombin

BACKGROUND

Antithrombin, a member of the serpin family of inhibitors, controls coagulation in human plasma by forming complexes with thrombin and other coagulation proteases in a process greatly accelerated by heparin. The structures of several serpins have been determined but not in their active conformations. We have determined the structure of intact antithrombin in order to study its mechanism of activation, particularly with respect to heparin, and the dysfunctions of this mechanism that predispose individuals to thrombotic disease.

RESULTS

The crystal structure of a dimer of one active and one inactive molecule of antithrombin has been determined at 3 A. The first molecule has its reactive-centre loop in a predicted active conformation compatible with initial entry of two residues into the main beta-sheet of the molecule. The inactive molecule has a totally incorporated loop as in latent plasminogen activator inhibitor-1. The two molecules are linked by the reactive loop of the active molecule which has replaced a strand from another beta-sheet in the latent molecule.

CONCLUSION

The structure, together with identified mutations affecting its heparin affinity, allows the placement of the heparin-binding site on the molecule. The conformation of the two forms of antithrombin demonstrates the extraordinary mobility of the reactive loop in the serpins and provides insights into the folding of the loop required for inhibitory activity together with the potential modification of this by heparin. The mechanism of dimerization is relevant to the polymerization that is observed in diseases associated with variant serpins.