Identification and Characterization of a Misfolded Monomeric Serpin Formed at Physiological Temperature

The native serpin state is kinetically trapped. However, under mildly destabilizing conditions, the conformational landscape changes, and a number of nonnative conformations with increased stability can be readily formed. The ability to undergo structural change is due to intrinsic strain within the serpin's tertiary fold, which is utilized for proteinase inhibition but renders the protein susceptible to aberrant folding and self-association. The relationship between these various conformations is poorly understood. Antichymotrypsin (ACT) is an inhibitory serpin that readily forms a number of inactive conformations, induced via either environmental stress or interaction with proteinases. Here we have used a variety of biophysical and structural techniques to characterize the relationship between some of these conformations. Incubation of ACT at physiological temperature results in the formation of a range of conformations, including both polymer and misfolded monomer. The ability to populate these nonnative states and the native conformation reflects an energy landscape that is very sensitive to the solution conditions. X-ray crystallography reveals that the misfolded monomeric conformation is in the delta conformation. Further polymerization and seeding experiments show that the delta conformation is an end point in the misfolding pathway of ACT and not an on-pathway intermediate formed during polymerization. The observation that ACT readily forms this inactive conformation at physiological temperature and pH suggests that it may have a role in both health and disease.     

Allosteric activation of antithrombin is independent of charge neutralization or reversal in the heparin binding site

We investigate the hypothesis that heparin activates antithrombin (AT) by relieving electrostatic strain within helix D. Mutation of residues K125 and R129 to either Ala or Glu abrogated heparin binding, but did not activate AT towards inhibition of factors IXa or Xa. However, substitution of residues C-terminal to helix D (R132 and K133) to Ala had minimal effect on heparin affinity but resulted in appreciable activation. We conclude that charge neutralization or reversal in the heparin binding site does not drive the activating conformational change of AT, and that the role of helix D elongation is to stabilize the activated state.     

Serpin1 of Arabidopsis thaliana is a suicide inhibitor for metacaspase 9

Metacaspases are distant relatives of animal caspases found in plants, fungi and protozoa. We demonstrated previously that two type II metacaspases of Arabidopsis thaliana, AtMC4 and AtMC9 are Arg/Lys-specific cysteine-dependent proteases. We screened a combinatorial tetrapeptide library of 130,321 substrates with AtMC9. Here, we show that AtMC9 is a strict Arg/Lys-specific protease. Based on the position-specific scoring matrix derived from the substrate library results, the tetrapeptide Val-Arg-Pro-Arg was identified as an optimized substrate. AtMC9 had a kcat/KM of 4.6x10(5) M-1 s-1 for Ac-Val-Arg-Pro-Arg-amido-4-methyl-coumarin, representing a more than 10-fold improvement over existing fluorogenic substrates. A yeast two-hybrid screen with catalytically inactive AtMC9 as bait identified a serine protease inhibitor, designated AtSerpin1, which was found to be a potent inhibitor of AtMC9 activity in vitro through cleavage of its reactive center loop and covalent binding to AtMC9. On the basis of the substrate profiling of AtMC9 and confirmation through site-directed mutagenesis, the inhibitory P4-P1 cleavage site of AtSerpin1 was determined to be Ile-Lys-Leu-Arg351. Further mutagenesis of the AtSerpin1 inhibitory cleavage site modulated AtMC9 inhibition positively or negatively. Both AtMC9 and AtSerpin1 were localized in the extracellular space, suggesting an in vivo interaction as well. To our knowledge, this is the first report of plant protease inhibition by a plant serpin.     

Structural change in β-sheet A of Z α(1)-antitrypsin is responsible for accelerated polymerization and disease

The presence of the Z mutation (Glu342Lys) is responsible for more than 95% of α₁-antitrypsin (α₁AT) deficiency cases. It leads to increased polymerization of the serpin α₁AT during its synthesis and in circulation. It has been proposed that the Z mutation results in a conformational change within the folded state of antitrypsin that enhances its polymerization. In order to localize the conformational change, we have created two single tryptophan mutants of Z α₁AT and analyzed their fluorescence properties. α₁AT contains two tryptophan residues that are located in distinct regions of the molecule: Trp194 at the top of β-sheet A and Trp238 on β-sheet B. We have replaced each tryptophan residue individually with a phenylalanine in order to study the local environment of the remaining tryptophan residue in both M and Z α₁AT. A detailed fluorescence spectroscopic analysis of each mutant was carried out, and we detected differences in the emission spectrum, the Stern-Volmer constant for potassium iodide quenching and the anisotropy of only Trp194 in Z α₁AT compared to M α₁AT. Our data reveal that the Z mutation results in a conformational change at the top of β-sheet A but does not affect the structural integrity of β-sheet B.     

Human Neuroserpin: Structure and Time-Dependent Inhibition

Human neuroserpin (hNS) is a protein serine protease inhibitor expressed mainly in the nervous system, where it plays key roles in neural development and plasticity by primarily targeting tissue plasminogen activator (tPA). Four hNS mutations are associated to a form of autosomal dominant dementia, known as familial encephalopathy with neuroserpin inclusion bodies. The medical interest in and the lack of structural information on hNS prompted us to study the crystal structure of native and cleaved hNS, reported here at 3.15 and 1.85 Å resolution, respectively. In the light of the three-dimensional structures, we focus on the hNS reactive centre loop in its intact and cleaved conformations relative to the current serpin polymerization models and discuss the protein sites hosting neurodegenerative mutations. On the basis of homologous serpin structures, we suggest the location of a protein surface site that may stabilize the hNS native (metastable) form. In parallel, we present the results of kinetic studies on hNS inhibition of tPA. Our data analysis stresses the instability of the hNS-tPA complex with a dissociation half-life of minutes compared to a half-life of weeks observed for other serpin-cognate protease complexes.     

Inhibition of heat- and chemical-induced aggregation of various proteins reveals chaperone-like activity of the acute-phase component and serine protease inhibitor human α1-antitrypsin

In vitro chaperone-like activity of the serpin family member and plasma acute-phase component human α₁-antitrypsin (AAT) has been shown for the first time. Results of light-scattering experiments demonstrated that AAT efficiently inhibits both heat- and chemical-induced aggregation of various test proteins including alcohol dehydrogenase, aldolase, carbonic anhydrase, catalase, citrate synthase, enolase, glutathione S-transferase, l-lactate dehydrogenase, and β_L-crystallin. The results suggest that the unique metastable serpin architecture enables dual function, protease inhibiton as well as chaperone activity and highlight the serpin superfamily as a possible source of additional intra- and extracellular chaperones (e.g. α₁-antichymotrypsin). The present finding is surprising in the light of the well-known role of mutated forms of AAT and other serpins in the pathogenesis of diseases called serpinopathies that featured with aberrant conformational transitions and consequent self-aggregation of serpin proteins.     

Refolding and Polymerization Pathways of Neuroserpin

Neuroserpin is a member of the serpin superfamily, and its mutants are retained within the endoplasmic reticulum of neurons as ordered polymers in association with dementia. It has been proposed that neuroserpin polymers are formed by a conformational change in the folded protein. However, an alternative model whereby polymers are formed during protein folding rather than from the folded protein has recently been proposed. We investigated the refolding and polymerization pathways of wild-type neuroserpin (WT) and of the pathogenic mutants S49P and H338R. Upon refolding, denatured WT immediately formed an initial refolding intermediate I_IN and then underwent further refolding to the native form through a late refolding intermediate, I_R. The late-onset mutant S49P was also able to refold to the native form through I_IN and I_R, but the final refolding step proceeded at a slower rate and with a lower refolding yield as compared with WT. The early-onset mutant H338R formed I_R through the same pathway as S49P, but the protein could not attain the native state and remained as I_R. The I_Rs of the mutants had a long lifespan at 4 °C and thus were purified and characterized. Strikingly, when incubated under physiological conditions, I_R formed ordered polymers with essentially the same properties as the polymers formed from the native protein. The results show that the mutants have a greater tendency to form polymers during protein folding than to form polymers from the folded protein. Our finding provides insights into biochemical approaches to treating serpinopathies by targeting a polymerogenic folding intermediate.     

Kinetic Instability of the Serpin Z α1-Antitrypsin Promotes Aggregation

The serpinopathies encompass a large number of diseases caused by inappropriate conformational change and self-association (polymerization) of a serpin (serine proteinase inhibitor) molecule. The most common serpinopathy is α₁-antitrypsin (α₁AT) deficiency, which is associated with an increased risk for liver cirrhosis, hepatocellular carcinoma and early-onset emphysema. The Z variant of α₁AT, which accounts for 95% of all cases of α₁AT deficiency, polymerizes during synthesis and after secretion. Here, we show using intrinsic and extrinsic fluorescence probes that Z α₁AT exists in a non-native conformation. We examined the thermodynamic stability by transverse urea gradient gel electrophoresis, thermal denaturation and equilibrium guanidine hydrochloride unfolding and found that, despite structural differences between the two proteins, wild-type α₁AT and Z α₁AT display similar unfolding pathways and thermodynamic stabilities. Far-UV circular dichroism and bis-ANS (4,4′-dianilino-1,1′-binaphthyl-5,5′-disulfonic acid, dipotassium salt) fluorescence suggest that the intermediate ensembles formed during unfolding of wild-type α₁AT and Z α₁AT are characterized by similar structural features. Kinetic analysis of the unfolding transition showed that Z α₁AT unfolds at least 1.5-fold faster than the wild type. The biological implications of these data are discussed.