Production, characterization, and use of serpin antibodies

Serine protease inhibitors (serpins) constitute a still expanding superfamily of structural similar proteins, which are localized extracellularly and intracellularly. Serpins play a central role in the regulation of a wide variety of (patho) physiological processes including coagulation, fibrinolysis, inflammation, development, tumor invasion, and apoptosis. Serpins have a unique mechanism of inhibition that involves a profound change in conformational state upon interaction with their protease. This conformational change enables the production of monoclonal antibodies specific for native, complexed, and inactivated serpins. Antibodies, and assays based on these antibodies, have been helpful in elucidating the (patho) physiological function of serpins in the last decade. Serpin-specific antibodies can be used for: (1) structure-function studies such as detection of conformational changes; (2) identification of target-proteases; (3) the detection and quantification of serpin and serpin-protease complexes in bodily fluids by immunoassays such as ELISA, RIA or FACS; (4) detection of serpins in tissues by immunohistochemistry; and (5) possible therapeutical interventions. This review summarizes the techniques we have used to obtain and screen antibodies against extra- and intracellular serpins, as well as the use of these antibodies for some of the above-mentioned purposes.     

An overview of the serpin superfamily

Serpins are a broadly distributed family of protease inhibitors that use a conformational change to inhibit target enzymes. They are central in controlling many important proteolytic cascades, including the mammalian coagulation pathways. Serpins are conformationally labile and many of the disease-linked mutations of serpins result in misfolding or in pathogenic, inactive polymers.     

Serpins 2005 - fun between the beta-sheets. Meeting report based upon presentations made at the 4th International Symposium on Serpin Structure, Function and Biology (Cairns, Australia)

Serpins are the largest family of protease inhibitors and are fundamental for the control of proteolysis in multicellular eukaryotes. Most eukaryote serpins inhibit serine or cysteine proteases, however, noninhibitory members have been identified that perform diverse functions in processes such as hormone delivery and tumour metastasis. More recently inhibitory serpins have been identified in prokaryotes and unicellular eukaryotes, nevertheless, the precise molecular targets of these molecules remains to be identified. The serpin mechanism of protease inhibition is unusual and involves a major conformational rearrangement of the molecule concomitant with a distortion of the target protease. As a result of this requirement, serpins are susceptible to mutations that result in polymerization and conformational diseases such as the human serpinopathies. This review reports on recent major discoveries in the serpin field, based upon presentations made at the 4th International Symposium on Serpin Structure, Function and Biology (Cairns, Australia).     

Strand 6B deformation and residues exposure towards N-terminal end of helix B during proteinase inhibition by Serpins

Serine Protease inhibitors (Serpins) like antithrombin, antitrypsin, neuroserpin, antichymotrypsin, protein C-inhibitor and plasminogen activator inhibitor is involved in important biological functions like blood coagulation, fibrinolysis, inflammation, cell migration and complement activation. Serpins native state is metastable, which undergoes transformation to a more stable state during the process of protease inhibition. Serpins are prone to conformation defects, however little is known about the factors and mechanisms which promote its conformational change and misfolding. Helix B region in serpins is with several point mutations which result in pathological conditions due to polymerization. Helix B analysis for residue burial and cavity was undertaken to understand its role in serpin structure function. A structural overlap and an accessible surface area analysis showed the deformation of strand 6B and exposure of helix B at N-terminal end in cleaved conformation but not in the native and latent conformation of various inhibitory serpins. A cleaved polymer like conformation of antitrypsin also showed deformation of s6B and helix B exposure. Cavity analysis showed that helix B residues were part of the largest cavity in most of the serpins in the native state which increase in size during the transformation to cleaved and latent states. These data for the first time show the importance of strand 6B deformation and exposure of helix B in smooth insertion of the reactive center loop during serpin inhibition and indicate that helix B exposure due to variants may increase its polymer propensity. ABBREVIATIONS: serpin -serine protease inhibitors RCL -reactive center loop ASA -accessible surface area.     

Understanding the specificity of serpin–protease complexes through interface analysis

Serpins such as antithrombin, heparin cofactor II, plasminogen activator inhibitor, antitrypsin, antichymotrypsin, and neuroserpin are involved in important biological processes by inhibiting specific serine proteases. Initially, the protease recognizes the mobile reactive loop of the serpin eliciting conformational changes, where the cleaved loop together with the protease inserts into β-sheet A, translocating the protease to the opposite side of inhibitor leading to its inactivation. Serpin interaction with proteases is governed mainly by the reactive center loop residues (RCL). However, in some inhibitory serpins, exosite residues apart from RCL have been shown to confer protease specificity. Further, this forms the basis of multi-specificity of some serpins, but the residues and their dimension at interface in serpin-protease complexes remain elusive. Here, we present a comprehensive structural analysis of the serpin-protease interfaces using bio COmplexes COntact MAPS (COCOMAPS), PRotein Interface Conservation and Energetics (PRICE), and ProFace programs. We have carried out interface, burial, and evolutionary analysis of different serpin-protease complexes. Among the studied complexes, non-inhibitory serpins exhibit larger interface region with greater number of residue involvement as compared to the inhibitory serpins. On comparing the multi-specific serpins (antithrombin and antitrypsin), a difference in the interface area and residue number was observed, suggestive of a differential mechanism of action of these serpins in regulating their different target proteases. Further, detailed study of these multi-specific serpins listed few essential residues (common in all the complexes) and certain specificity (unique to each complex) determining residues at their interfaces. Structural mapping of interface residues suggested that individual patches with evolutionary conserved residues in specific serpins determine their specificity towards a particular protease.     

A novel Drosophila serpin that inhibits serine proteases

Serpins define a large protein family in which most members function as serine protease inhibitors. Here we report the results of a search for serpins in Drosophila melanogaster that are potentially required for oogenesis or embryogenesis. We cloned and sequenced ovarian cDNAs that encode six distinct proteins having extensive sequence similarity to mammalian serpins, including residues important in the serpin inhibition mechanism. One of these new serpins in recombinant form inactivates, and complexes with, trypsin-like proteases in vitro. To our knowledge, these results represent the first evidence for a serpin in Drosophila that functions as a serine protease inhibitor.     

The role of conformational change in serpin structure and function

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

How serpins change their fold for better and for worse

The serpins differ from the many other families of serine protease inhibitors in that they undergo a profound change in topology in order to entrap their target protease in an irreversible complex. The solving of the structure of this complex has now provided a video depiction of the changes involved. Cleavage of the exposed reactive centre of the serpin triggers an opening of the five-stranded A-sheet of the molecule, with insertion of the cleaved reactive loop as an additional strand in the centre of the sheet. The drastic displacement of the acyl-linked protease grossly disrupts its active site and gives an overall loss of 40% of ordered structure. This ability to provide effectively irreversible inhibition explains the selection of the serpins to control the proteolytic cascades of higher organisms. The conformational mechanism provides another advantage in its potential to modulate activity. Sequential crystallographic structures now provide clear depictions of the way antithrombin is activated on binding to the heparans of the microcirculation, and how evolution has utilized this mobile mechanism for subtle variations in activity. The complexity of these modulatory mechanisms is exemplified by heparin cofactor II, where the change in fold is seen to trigger multiple allosteric effects. The downside of the mobile mechanism of the serpins is their vulnerability to aberrant intermolecular beta-linkages, resulting in various disorders from cirrhosis to thrombosis. These provide a well defined structural prototype for the new entity of the conformational diseases, including the common dementias, as confirmed by the recent identification of the familial neuroserpin dementias.     

Role of serine protease inhibitors in insect‐host‐pathogen interactions

Serine protease inhibitors (serpins), evolutionary old, structurally conserved molecules, are a superfamily of proteins found in almost all living organisms. Serpins are relatively large, typically 350–500 amino acids in length, with three β‐sheets and seven to nine α‐helices folding into a conserved tertiary structure with a reactive center loop. Serpins perform various physiological functions in insects, including development, digestion, host‐pathogen interactions, and innate immune response. In insects, the innate immune system is characterized as the first and major defense system against the invasion of microorganisms. Serine protease cascades play a critical role in the initiation of innate immune responses, such as melanization and the production of antimicrobial peptides, and are strictly and precisely regulated by serpins. Herein, we provide a microreview on the role of serpins in the insect‐host‐pathogen interactions, emphasizing their role in immune responses, particularly in diamondback moth (Plutella xylostella), highlighting the important discoveries and also the gaps that remain to be explored in future studies.     

Tip of another iceberg: Drosophila serpins

Serpins are serine protease inhibitors with a conserved structure that have been identified in nearly all species and act as suicide substrates by binding covalently to their target proteases. Serpins regulate various physiological processes and defence mechanisms. In humans, several serpin mutations are linked to diseases. The genome of Drosophila melanogaster encodes 29 serpins and even more serine proteases. To date, three serpins have been investigated in detail. Spn27A controls the Toll pathway during early development and is involved in defence reactions in adult flies. SPN42DaA is an inhibitor of furin, a subtilisin-like convertase that is required for pro-protein maturation. Spn43Ac controls the Toll pathway during the immune response. In each case, Drosophila genetics has shed new light on the function of these serine protease inhibitors.     

RNA Binding by Plant Serpins in vitro

Biochemistry (Moscow) - Serpins constitute a large family of protease inhibitors with regulatory functions found in all living organisms. Most plant serpins have not been functionally...     

The conformational dynamics of a metastable serpin studied by hydrogen exchange and mass spectrometry

Serpins are a class of protease inhibitors that initially fold to a metastable structure and subsequently undergo a large conformational change to a stable structure when they inhibit their target proteases. How serpins are able to achieve this remarkable conformational rearrangement is still not understood. To address the question of how the dynamic properties of the metastable form may facilitate the conformational change, hydrogen/deuterium exchange and mass spectrometry were employed to probe the conformational dynamics of the serpin human alpha(1)-antitrypsin (alpha(1)AT). It was found that the F helix, which in the crystal structure appears to physically block the conformational change, is highly dynamic in the metastable form. In particular, the C-terminal half of the F helix appears to spend a substantial fraction of time in a partially unfolded state. In contrast, beta-strands 3A and 5A, which must separate to accommodate insertion of the reactive center loop (RCL), are not conformationally flexible in the metastable state but are rigid and stable. The conformational lability required for loop insertion must therefore be triggered during the inhibition reaction. Beta-strand 1C, which anchors the distal end of the RCL and thus prevents transition to the so-called latent form, is also stable, consistent with the observation that alpha(1)AT does not spontaneously adopt the latent form. A surprising degree of flexibility is seen in beta-strand 6A, and it is speculated that this flexibility may deter the formation of edge-edge polymers.     

Serpins and other covalent protease inhibitors

Serpins are irreversible covalent 'suicide' protease inhibitors. In the past two years, important advances in the structural biology of serpins have been forthcoming with the crystal structures of a covalent complex between trypsin and alpha1-antitrypsin, and of a Michaelis encounter complex between trypsin S195A and serpin 1B from Manduca sexta. These structures have helped elucidate many aspects of the mechanism of action of serpins. Also, the crystal structure of the cysteine protease caspase-8 in complex with the inhibitor p35 has revealed a new family of suicide protease inhibitors.     

The high resolution crystal structure of a native thermostable serpin reveals the complex mechanism underpinning the stressed to relaxed transition

Serpins fold into a native metastable state and utilize a complex conformational change to inhibit target proteases. An undesirable result of this conformational flexibility is that most inhibitory serpins are heat sensitive, forming inactive polymers at elevated temperatures. However, the prokaryote serpin, thermopin, from Thermobifida fusca is able to function in a heated environment. We have determined the 1.8 A x-ray crystal structure of thermopin in the native, inhibitory conformation. A structural comparison with the previously determined 1.5 A structure of cleaved thermopin provides detailed insight into the complex mechanism of conformational change in serpins. Flexibility in the shutter region and electrostatic interactions at the top of the A beta-sheet (the breach) involving the C-terminal tail, a unique structural feature of thermopin, are postulated to be important for controlling inhibitory activity and triggering conformational change, respectively, in the native state. Here we have discussed the structural basis of how this serpin reconciles the thermodynamic instability necessary for function with the stability required to withstand elevated temperatures.     

Correlation of serpin-protease expression by comparative analysis of real-time PCR profiling data

Imbalanced protease activity has long been recognized in the progression of disease states such as cancer and inflammation. Serpins, the largest family of endogenous protease inhibitors, target a wide variety of serine and cysteine proteases and play a role in a number of physiological and pathological states. The expression profiles of 20 serpins and 105 serine and cysteine proteases were determined across a panel of normal and diseased human tissues. In general, expression of serpins was highly restricted in both normal and diseased tissues, suggesting defined physiological roles for these protease inhibitors. A high correlation in expression for a particular serpin-protease pair in healthy tissues was often predictive of a biological interaction. The most striking finding was the dramatic change observed in the regulation of expression between proteases and their cognate inhibitors in diseased tissues. The loss of regulated serpin-protease matched expression may underlie the imbalanced protease activity observed in pathological states.     

Aeropin from the extremophile Pyrobaculum aerophilum bypasses the serpin misfolding trap

Serpins are metastable proteinase inhibitors. Serpin metastability drives both a large conformational change that is utilized during proteinase inhibition and confers an inherent structural flexibility that renders serpins susceptible to aggregation under certain conditions. These include point mutations (the basis of a number of important human genetic diseases), small changes in pH, and an increase in temperature. Many studies of serpins from mesophilic organisms have highlighted an inverse relationship: mutations that confer a marked increase in serpin stability compromise inhibitory activity. Here we present the first biophysical characterization of a metastable serpin from a hyperthermophilic organism. Aeropin, from the archaeon Pyrobaculum aerophilum, is both highly stable and an efficient proteinase inhibitor. We also demonstrate that because of high kinetic barriers, aeropin does not readily form the partially unfolded precursor to serpin aggregation. We conclude that stability and activity are not mutually exclusive properties in the context of the serpin fold, and propose that the increased stability of aeropin is caused by an unfolding pathway that minimizes the formation of an aggregation-prone intermediate ensemble, thereby enabling aeropin to bypass the misfolding fate observed with other serpins.     

Thrombin inhibition by serpins disrupts exosite II

Thrombin uses three principal sites, the active site, exosite I, and exosite II, for recognition of its many cofactors and substrates. It is synthesized in the zymogen form, prothrombin, and its activation at the end of the blood coagulation cascade results in the formation of the active site and exosite I and the exposure of exosite II. The physiological inhibitors of thrombin are all serpins, whose mechanism involves significant conformational change in both serpin and protease. It has been shown that the formation of the thrombin-serpin final complex disorders the active site and exosite I of thrombin, but exosite II is thought to remain functional. It has also been hypothesized that thrombin contains a receptor-binding site that is exposed upon final complex formation. The position of this cryptic site may depend on the regions of thrombin unfolded by serpin complexation. Here we investigate the conformation of thrombin in its final complex with serpins and find that in addition to exosite I, exosite II is also disordered, as reflected by a loss of affinity for the γ'-peptide of fibrinogen and for heparin and by susceptibility to limited proteolysis. This disordering of exosite II occurs for all tested natural thrombin-inhibiting serpins. Our data suggest a novel framework for understanding serpin function, especially with respect to thrombin inhibition, where serpins functionally "rezymogenize" proteases to ensure complete loss of activity and cofactor binding.     

Serpins Flex Their Muscle: I. PUTTING THE CLAMPS ON PROTEOLYSIS IN DIVERSE BIOLOGICAL SYSTEMS*

Serpins compose the largest superfamily of peptidase inhibitors and are well known as regulators of hemostasis and thrombolysis. Studies using model organisms, from plants to vertebrates, now show that serpins and their unique inhibitory mechanism and conformational flexibility are exploited to control proteolysis in molecular pathways associated with cell survival, development, and host defense. In addition, an increasing number of non-inhibitory serpins are emerging as important elements within a diversity of biological systems by serving as chaperones, hormone transporters, or anti-angiogenic factors.     

Conformational changes in serpins: I. The native and cleaved conformations of alpha(1)-antitrypsin

The serpins (SERine Proteinase INhibitors) are a family of proteins with important physiological roles, including but not limited to the inhibition of chymotrypsin-like serine proteinases. The inhibitory mechan- ism involves a large conformational change known as the S-->R (stressed-->relaxed) transition. The largest structural differences occur in a region around the scissile bond called the reactive centre loop: In the native (S) state, the reactive centre is exposed, and is free to interact with proteinases. In inhibitory serpins, in the cleaved (R) state the reactive centre loop forms an additional strand within the beta-sheet. The latent state is an uncleaved state in which the intact reactive centre loop is integrated into the A sheet as in the cleaved form, to give an alternative R state.The serpin structures illustrate detailed control of conformation within a single protein. Serpins are also an unusual family of proteins in which homologues have native states with different folding topologies. Determination of the structures of inhibitory serpins in multiple conformational states permits a detailed analysis of the mechanism of the S-->R transition, and of the way in which a single sequence can form two stabilised states of different topology.Here we compare the conformations of alpha(1)-antitrypsin in native and cleaved states. Many protein conformational changes involve relative motions of large rigid subunits. We determine the rigid subunits of alpha(1)-antitrypsin and analyse the changes in their relative position and orientation. Knowing that the conformational change is initiated by cleavage at the reactive centre, we describe a mechanism of the S-->R transition as a logical sequence of mechanical effects, even though the transition likely proceeds in a concerted manner.     

The structure of a Michaelis serpin-protease complex.

Serine protease inhibitors (serpins) regulate the activities of circulating proteases. Serpins inhibit proteases by acylating the serine hydroxyl at their active sites. Before deacylation and complete proteolysis of the serpin can occur, massive conformational changes are triggered in the serpin while maintaining the covalent linkage between the protease and serpin. Here we report the structure of a serpin-trypsin Michaelis complex, which we visualized by using the S195A trypsin mutant to prevent covalent complex formation. This encounter complex reveals a more extensive interaction surface than that present in small inhibitor-protease complexes and is a template for modeling other serpin-protease pairs. Mutations of several serpin residues at the interface reduced the inhibitory activity of the serpin. The serine residue C-terminal to the scissile peptide bond is found in a closer than usual interaction with His 57 at the active site of trypsin.