An atlas of serpin conformations

Effect of protease-activated receptor (PAR)-1, -2 and -4-activating peptides, thrombin and trypsin in rat isolated airways

Mechanisms of relaxation and contraction to protease-activated receptor- (PAR) tethered ligand peptides (SFLLRN/TFLLR, SLIGRL and GYPGKF (all C-terminally amidated) for PAR1, PAR2 and PAR4, respectively) and enzymes (thrombin and trypsin) were investigated in isolated segments of rat trachea, main and first order intrapulmonary bronchi. In airway segments previously exposed to SLIGRL, SFLLRN caused contractions that were potentiated by indomethacin, but were independent of mast cell degranulation. Contractions to TFLLR in the intrapulmonary bronchi were similarly potentiated by indomethacin. SLIGRL caused epithelium-dependent relaxations which were unaffected by N(G)-nitro-L-arginine, 1-H-oxodiazol-[1,2,4]-[4,3-a]quinoxaline-1-one or zinc-protoporphyrin-IX but were abolished by haemoglobin in all three regions of the airways. Relaxations to SLIGRL were markedly attenuated by indomethacin only in the main and intrapulmonary bronchi. GYPGKF caused epithelium-dependent relaxations in all three regions of the airway which were only significantly inhibited by indomethacin in the intrapulmonary bronchi. In general, thrombin and trypsin failed to cause any response in the airways tested. Intense PAR2-immunoreactivity was observed on airway epithelium. PAR1-immunoreactivity was faint on airway epithelium and smooth muscle, but was prevalent in mast cells. These findings indicate that PAR2 and possibly PAR4 present on rat airway epithelia mediate smooth muscle relaxation via cyclo-oxygenase-dependent and -independent mechanisms. PAR1-mediated contractions were most likely due to activation of smooth muscle receptors. The general failure of thrombin and trypsin to cause responses which may have been due to endogenous protease inhibitors, highlights the need for caution in assessing pathophysiological roles for PARs if only enzymes are used to activate PARs.

Phylogeny of the Serpin Superfamily: Implications of Patterns of Amino Acid Conservation for Structure and Function

We present a comprehensive alignment and phylogenetic analysis of the serpins, a superfamily of proteins with known members in higher animals, nematodes, insects, plants, and viruses. We analyze, compare, and classify 219 proteins representative of eight major and eight minor subfamilies, using a novel technique of consensus analysis. Patterns of sequence conservation characterize the family as a whole, with a clear relationship to the mechanism of function. Variations of these patterns within phylogenetically distinct groups can be correlated with the divergence of structure and function. The goals of this work are to provide a carefully curated alignment of serpin sequences, to describe patterns of conservation and divergence, and to derive a phylogenetic tree expressing the relationships among the members of this family. We extend earlier studies by Huber and Carrell as well as by Marshall, after whose publication the serpin family has grown functionally, taxonomically, and structurally. We used gene and protein sequence data, crystal structures, and chromosomal location where available. The results illuminate structure–function relationships in serpins, suggesting roles for conserved residues in the mechanism of conformational change. The phylogeny provides a rational evolutionary framework to classify serpins and enables identification of conserved amino acids. Patterns of conservation also provide an initial point of comparison for genes identified by the various genome projects. New homologs emerging from sequencing projects can either take their place within the current classification or, if necessary, extend it.

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

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

Conformational changes in serpins: II. The mechanism of activation of antithrombin by heparin

Antithrombin, uniquely among plasma serpins acting as proteinase inhibitors in the control of the blood coagulation cascade, circulates in a relatively inactive form. Its activation by heparin, and specifically by a pentasaccharide core of heparin, has been shown to involve release of the peptide loop containing the reactive centre from partial insertion in the A sheet of the molecule. Here we compare the structures of the circulating inactive form of antithrombin with the activated structure in complex with heparin pentasaccharide. We show that the rearrangement of the reactive centre loop that occurs upon activation is part of a widespread conformational change involving a realignment of the two major domains of the molecule. We also examine natural mutants that possess high affinity for heparin pentasaccharide, and relate the kinetics of their interaction with heparin pentasaccharide to the structural transitions occuring in the activation process.

The citrate ion increases the conformational stability of alpha(1)-antitrypsin

Sodium citrate has previously been shown to convert native alpha(1)-antitrypsin into the inactive latent state and cause alpha(1)-antitrypsin to polymerize via the C-sheet pathway instead of the more common A-sheet pathway. In order to begin to understand these dramatic effects, we have examined the influence of low concentrations of sodium citrate upon the structure, stability and function of alpha(1)-antitrypsin. In 0.5 M citrate, the midpoint of guanidine hydrochloride-induced unfolding was increased by 1.8 M and the rate of heat inactivation was decreased approximately 30-fold compared with Tris or phosphate buffer. alpha(1)-Antitrypsin was fully active in the presence of a range of citrate concentrations (0. 1-0.5 M), forming a stable 1:1 complex with chymotrypsin. The association rate constant between alpha(1)-antitrypsin and chymotrypsin was decreased with increasing citrate concentration. Fluorescence and circular dichroism spectroscopy demonstrated no significant changes in the tertiary structure due to the presence of citrate. However, the insertion rate of exogenous reactive-center loop peptide increased with increasing citrate concentration, indicating some structural changes in the A beta-sheet region. Taken together, these data suggest that in the presence of 0.5 M citrate alpha(1)-antitrypsin adopts a highly stable but active conformation.

Mutations on the hinge region of leukocyte elastase inhibitor determine the loss of inhibitory function

Leukocyte elastase inhibitor (LEI) is a cytosolic component of lung macrophages and blood leukocytes that inhibits neutrophil elastase. LEI is a member of the serpin superfamily, these proteins, mostly protease inhibitors, are thought to undergo a conformational change upon complex formation with proteinase that involves partial insertion of the hinge region of the reactive centre loop into a beta-sheet of the inhibitor. In this work three mutations were produced in the hinge region of elastase inhibitor that abolish the inhibition activity of LEI and transform the protein in a substrate of the elastase. This result demonstrates that the inhibitory mechanism of serpin is common to LEI.

Structural basis of the endoproteinase-protein inhibitor interaction

Proteolytic enzymes are potentially hazardous to their protein environment, so that their activity must be carefully controlled. Living organisms use protein inhibitors as a major tool to regulate the proteolytic activity of proteinases. Most of the inhibitors for which 3D structures are available are directed towards serine proteinases, interacting with the active sites in a 'canonical' i.e. substrate-like manner via an exposed reactive site loop of conserved conformation. More recently, some non-canonically binding serine proteinase inhibitors directed against coagulation factors, in particular thrombin, a few cysteine proteinase inhibitors inhibitory towards papain-like proteinases, and three zinc endopeptidase inhibitors directed against metzincins and thermolysin have been characterised in the free and complexed state, displaying novel mechanisms of inhibition with their target proteinases. These different interaction modes are presented and briefly discussed with respect to the different strategies applied by nature.

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.

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.

Separate cis-acting DNA elements control cell type- and tissue-specific expression of collagen binding molecular chaperone HSP47

HSP47 is a collagen-binding heat shock protein and is assumed to act as a molecular chaperone in the biosynthesis and secretion of procollagen. As the synthesis of HSP47 is closely correlated with that of collagen in various cell lines and tissues, we performed a promoter/reporter assay using HSP47-producing and nonproducing cells. 280 base pairs (bp(s)) of upstream promoter were shown to be necessary for the basal expression but not to be enough for the cell type-specific expression. When the first and the second introns were introduced downstream of this 280-bp region, marked up-regulation of the reporter activity was observed in HSP47-producing cells but not in nonproducing cells. This was confirmed in transgenic mice by staining the lacZ gene product under the control of the 280-bp upstream promoter and the introns. Staining was observed in skin, chondrocytes, precursor of bone, and other HSP47/collagen-producing tissues. A putative Sp1-binding site at -210 bp in the promoter, to which Sp3 and an unidentified protein bind, was shown to be responsible for this up-regulation when combined with the introns. However no difference in the binding to this probe was observed between HSP47-producing and nonproducing cells. The responsible region for cell type-specific up-regulation was found to be located in a 500-bp segment in the first intron. On electrophoresis mobility shift assay using this 500-bp probe, specific DNA-protein complexes were only observed in HSP47-producing cell extracts. These results suggest that two separate elements are necessary for the cell type-specific expression of the hsp47 gene; one is a putative Sp1-binding site at -210 bp necessary for basal expression, and the other is a 500-bp region within the first intron, required for cell type-specific expression.

Familial encephalopathy with neuroserpin inclusion bodies

We report on a new familial neurodegenerative disease with associated dementia that has presented clinically in the fifth decade, in both genders, and in each of several generations of a large family from New York State-a pattern of inheritance consistent with an autosomal dominant mode of transmission. A key pathological finding is the presence of neuronal inclusion bodies distributed throughout the gray matter of the cerebral cortex and in certain subcortical nuclei. These inclusions are distinct from any described previously and henceforth are identified as Collins bodies. The Collins bodies can be isolated by simple biochemical procedures and have a surprisingly simple composition; neuroserpin (a serine protease inhibitor) is their predominant component. An affinity-purified antibody against neuroserpin specifically labels the Collins bodies, confirming their chemical composition. Therefore, we propose a new disease entity-familial encephalopathy with neuroserpin inclusion bodies (FENIB). The conclusion that FENIB is a previously unrecognized neurodegenerative disease is supported by finding Collins bodies in a small kindred from Oregon with familial dementia who are unrelated to the New York family. The autosomal dominant inheritance strongly suggests that FENIB is caused by mutations in the neuroserpin gene, resulting in intracellular accumulation of the mutant protein.

Characterization of the thyroxine-binding site of thyroxine-binding globulin by site-directed mutagenesis

The principal transport protein for T4 in human blood, thyroxine-binding globulin (TBG), binds T4 with an exceptionally high affinity (Ka = 10(10) M(-1)). Its homology to the superfamily of the serpins has recently been used in the design of chimeric proteins, providing experimental evidence that an eight-stranded beta-barrel domain encompasses the ligand-binding site. We have now characterized the T4 binding site by site-directed mutagenesis. Sequence alignment of TBG from several species revealed a phylogenetically highly conserved stretch of amino acids comprising strands 2B and 3B of the beta-barrel motif. Mutations within this region (Val228Glu, Cys234Trp, Thr235Trp, Thr235Gln, Lys253Ala, and Lys253Asp), designed to impose steric hindrance or restriction of its mobility, had no significant influence on T4 binding. However, binding affinity was 20-fold reduced by introduction of an N-linked glycosylation site at the turn between strands 2B and 3B (Leu246Thr) without compromising the proper folding of this mutant as assessed by immunological methods. In most other serpins, this glycosylation site is highly conserved and has been shown to be crucial for cortisol binding of corticosteroid-binding globulin, the only other member of the serpins with a transport function. The ligand-binding site could thus be located to a highly aromatic environment deep within the beta-barrel. The importance of the binding site's aromatic character was investigated by exchanging phenylalanines with alanines. Indeed, these experiments revealed that substitution of Phe249 in the middle of strand 3B completely abolished T4 binding, while the substitution of several other phenylalanines had no effect.

Three-state unfolding and self-association of maspin, a tumor-suppressing serpin

Maspin is a tumor suppressor protein expressed by normal human mammary epithelium but not by many breast tumor cell lines. Recombinant human maspin (rMaspin) inhibits tumor cell motility, invasion, and metastasis and thus has potential value as an anti-cancer therapeutic. Maspin is a member of the serpin family and, although the molecular mechanism by which maspin acts is unknown, recent work suggests that tissue plasminogen activator is a potential target. A puzzling observation in previous cell culture studies was loss of rMaspin activity at higher protein concentrations. One hypothesis to explain these results is self-association of rMaspin at the higher concentrations, which would be consistent with the tendency of serpins to form noncovalent polymers. This hypothesis is addressed by examining the relationship between rMaspin stability and self-association. Urea denaturation of rMaspin at pH 7 and 25 degrees C and at protein concentrations ranging from 0.01 to 0.2 mg/ml has been monitored by circular dichroism and intrinsic tryptophan fluorescence. Denaturation profiles show a protein concentration dependence and indicate the presence of at least one unfolding intermediate. The results suggest that destabilization of native monomeric rMaspin leads to partial unfolding and formation of an intermediate which can self-associate.

Vaccinia virus serpin-1 deletion mutant exhibits a host range defect characterized by low levels of intermediate and late mRNAs

Orthopoxviruses encode three serpin homologs-SPI-1, SPI-2 and SPI-3-of which SPI-2 has been well characterized as an inhibitor of ICE-like proteases. A rabbitpox virus SPI-1 deletion mutant exhibited a host range restriction in human lung A549 and pig kidney 15 cell lines that was attributed to apoptosis. Here we report that replication of a vaccinia virus SPI-1 deletion mutant (DeltaSPI-1) was restricted in primary human keratinocytes as well as A549 cells. Although chromatin condensation was detected in some A549 cells, other morphological or biochemical signs of apoptosis including DNA fragmentation, cleavage of poly(ADP-ribose)polymerase or nuclear mitotic apparatus protein, or caspase 3 activation were not found. Moreover, DeltaSPI-1 protected A549 cells from apoptosis induced by tumor necrosis factor, whereas the corresponding DeltaSPI-2 mutant did not. Further studies indicated undiminished amounts of vaccinia virus early mRNA and replicated DNA in the absence of the SPI-1 product. However, there were reduced amounts of viral intermediate and late mRNAs, viral late proteins, cleaved core proteins, and virus particles. These data suggested that apoptosis is not the determining factor in the host range restriction of DeltaSPI-1 and that the SPI-1 gene product is needed to allow efficient expression of intermediate and late genes in A549 cells.

Caspase inhibition by baculovirus P35 requires interaction between the reactive site loop and the beta-sheet core

Baculovirus P35 is a universal substrate-inhibitor of the death caspases. Stoichiometric inhibition by P35 is correlated with cleavage of its reactive site loop (RSL) and formation of a stable P35.caspase complex through a novel but undefined mechanism. The P35 crystal structure predicts that the RSL associates with the beta-sheet core of P35 positioning the caspase cleavage site at the loop's apex. Here we demonstrate that proper interaction between the RSL and the beta-sheet core is critical for caspase inhibition, but not cleavage. Disruption of RSL interaction with the beta-sheet by substituting hydrophobic residues of the RSL's transverse helix alpha1 with destabilizing charged residues caused loss of caspase inhibition, without affecting P35 cleavage. Restabilization of the helix/sheet interaction by charge compensation from within the beta-sheet partially restored anti-caspase potency. Mutational effects on P35 helix/sheet interactions were confirmed by measuring intermolecular helix/sheet association with the yeast two-hybrid system. Moreover, the identification of P35 oligomers in baculovirus-infected cells suggested that similar P35 interactions occur in vivo. These findings indicate that P35's anti-caspase potency depends on a distinct conformation of the RSL which is required for events that promote stable, post-cleavage interactions and inhibition of the target caspase.

Predicting conformational switches in proteins

We describe a new computational technique to predict conformationally switching elements in proteins from their amino acid sequences. The method, called ASP (Ambivalent Structure Predictor), analyzes results from a secondary structure prediction algorithm to identify regions of conformational ambivalence. ASP identifies ambivalent regions in 16 test protein sequences for which function involves substantial backbone rearrangements. In the test set, all sites previously described as conformational switches are correctly predicted to be structurally ambivalent regions. No such regions are predicted in three negative control protein sequences. ASP may be useful as a guide for experimental studies on protein function and motion in the absence of detailed three-dimensional structural data.

Engineering of conformations of plasminogen activator inhibitor-1. A crucial role of beta-strand 5A residues in the transition of active form to latent and substrate forms

The serpin (serine proteinase inhibitor) family is of general protein chemical interest because of its ability to undergo large conformational changes, in which the surface-exposed reactive centre loop (RCL) is inserted as strand 4 in the large central beta-sheet A. Loop insertion is an integral part of the inhibitory mechanism and also takes place at conversion of serpins to the latent state, occurring spontaneously only in plasminogen activator inhibitor-1 (PAI-1). We have investigated the importance of beta-strand 5A residues for the activity and latency transition of PAI-1. An approximately fourfold increase in the rate of latency transition resulted from His-substitution of Gln324 (position 334 in the alpha(1)-proteinase inhibitor template numbering), which interacts with the underlying alpha-helix B. The side chains of Gln321 and Lys325 (template residues 331 and 335, respectively) form hydrogen bonds to the peptide backbone of a loop connecting alpha-helix F and beta-strand 3A. While substitution with Ala of Glu321 had only minor effects on the properties of PAI-1, substitution with Ala of Lys325 led to stabilization of the inhibitory activity at incubation conditions leading to conversion of wild-type PAI-1 to a substrate form, and to an anomalous reaction towards a monoclonal antibody, which induced a delay in the latency transition of the mutant, but not wild-type PAI-1. We conclude that the anchoring of beta-strand 5A plays a crucial role in loop insertion. These findings provide new information about the mechanism of an important example of protein conformational changes.

Modularity of serpins. A bifunctional chimera possessing alpha1-proteinase inhibitor and thyroxine-binding globulin properties

An exciting application of protein engineering is the creation of proteins with novel functions by the retrofitting of native proteins. Such attempts might be facilitated by the idea of a mosaic architecture of proteins out of structural units. Even though numerous theoretical concepts deal with the delineation of structural "modules," their potential in the design of proteins has not yet been sufficiently exploited. To address this question we used a gain of function approach by designing modular chimeric molecules out of two structurally homologous but functionally diverse members of the superfamily of serine-proteinase inhibitors, alpha1-proteinase inhibitor and thyroxine-binding globulin. Substitution of two of four alpha1-proteinase inhibitor modules (Lys222 to Leu288 and Pro362 to Lys394, respectively), identified by alpha-backbone distance analysis, with their thyroxine-binding globulin homologues resulted in a bifunctional chimera with inhibition of human leukocyte elastase and high affinity thyroxine binding. To our knowledge, this is the first report on a bifunctional chimera engineered from modules of homologous globular proteins. Our results demonstrate how a modular concept can facilitate the design of new functional proteins by swapping structural units chosen from members of a protein superfamily.

Crystal structure of baculovirus P35: role of a novel reactive site loop in apoptotic caspase inhibition

The aspartate-specific caspases are critical protease effectors of programmed cell death and consequently represent important targets for apoptotic intervention. Baculovirus P35 is a potent substrate inhibitor of metazoan caspases, a property that accounts for its unique effectiveness in preventing apoptosis in phylogenetically diverse organisms. Here we report the 2.2 A resolution crystal structure of P35, the first structure of a protein inhibitor of the death caspases. The P35 monomer possesses a solvent-exposed loop that projects from the protein's main beta-sheet core and positions the requisite aspartate cleavage site at the loop's apex. Distortion or destabilization of this reactive site loop by site-directed mutagenesis converted P35 to an efficient substrate which, unlike wild-type P35, failed to interact stably with the target caspase or block protease activity. Thus, cleavage alone is insufficient for caspase inhibition. These data are consistent with a new model wherein the P35 reactive site loop participates in a unique multi-step mechanism in which the spatial orientation of the loop with respect to the P35 core determines post-cleavage association and stoichiometric inhibition of target caspases.

Protein movement during complex-formation between tissue plasminogen activator and plasminogen activator inhibitor-1

Plasminogen activator inhibitor-1 (PAI-1) rapidly inactivates tissue plasminogen activator (tPA). After initial binding and cleavage of the reactive-centre loop of PAI-1, this complex is believed to undergo a major rearrangement. Using surface plasmon resonance and SDS-PAGE, we have studied the influence of a panel of monoclonal antibodies on the reaction leading to the final covalent complex. On the basis of these data, we suggest the mechanisms for the action of different classes of inhibitory antibodies. We propose that the antibodies which convert PAI-1 into a substrate for tPA do this by means of preventing the conversion of the initial PAI-1/tPA complex into the final complex by sterical intervention. Moreover, the localisation of the binding epitopes on free PAI-1, as well as on the PAI-1/tPA complex, suggests that tPA in the final complex cannot be located near helices E and F, as has previously been proposed.

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.

Regulation of pro-apoptotic leucocyte granule serine proteinases by intracellular serpins

Caspase activation and apoptosis can be initiated by the introduction of serine proteinases into the cytoplasm of a cell. Cytotoxic lymphocytes have evolved at least one serine proteinase with specific pro-apoptotic activity (granzyme B), as well as the mechanisms to deliver it into a target cell, and recent evidence suggests that other leucocyte granule proteinases may also have the capacity to kill if released into the interior of cells. For example, the monocyte/granulocyte proteinase cathepsin G can activate caspases in vitro, and will induce apoptosis if its entry into cells is mediated by a bacterial pore-forming protein. The potent pro-apoptotic activity of granzyme B and cathepsin G suggests that cells producing these (or other) proteinases would be at risk from self-induced death if the systems involved in packaging, degranulation or targeting fail and allow proteinases to enter the host cell cytoplasm. The purpose of the present review is to describe recent work on a group of intracellular serine proteinase inhibitors (serpins) which may function in leucocytes to prevent autolysis induced by the granule serine proteinases.

Inhibition of apoptosis and clonogenic survival of cells expressing crmA variants: optimal caspase substrates are not necessarily optimal inhibitors

To study the role of various caspases during apoptosis, we have designed a series of caspase inhibitors based on the cowpox virus cytokine response modifier A (crmA) protein. Wild-type crmA inhibits caspases 1 and 8 and thereby protects cells from apoptosis triggered by ligation of CD95 or tumour necrosis factor (TNF) receptors, but it does not protect against death mediated by other caspases. By replacing the tetrapeptide pseudosubstrate region of crmA (LVAD) with tetrapeptides that are optimal substrates for the different families of caspases, or with the four residues from the cleavage site of the baculovirus protein p35 (DQMD), we have generated a family of caspase inhibitors that show altered ability to protect against cell death. Although DEVD is the optimal substrate for caspase 3, crmA DEVD was degraded rapidly and was a weaker inhibitor than crmA DQMD, which was not degraded. Unlike wild-type crmA and crmA DEVD, crmA DQMD was able to inhibit apoptosis caused by direct activation of caspase 3 and protected lymphoid cells from death induced by radiation and dexamethasone. Significantly, the protected cells were capable of sustained growth.

The structure of active serpin 1K from Manduca sexta

BACKGROUND

The reactive center loops (RCL) of serpins undergo large conformational changes triggered by the interaction with their target protease. Available crystallographic data suggest that the serpin RCL is polymorphic, but the relevance of the observed conformations to the competent active structure and the conformational changes that occur on binding target protease has remained obscure. New high-resolution data on an active serpin, serpin 1K from the moth hornworm Manduca sexta, provide insights into how active serpins are stabilized and how conformational changes are induced by protease binding.

RESULTS

The 2.1 A structure shows that the RCL of serpin 1K, like that of active alpha1-antitrypsin, is canonical, complimentary and ready to bind to the target protease between P3 and P3 (where P refers to standard protease nomenclature),. In the hinge region (P17-P13), however, the RCL of serpin 1K, like ovalbumin and alpha1-antichymotrypsin, forms tight interactions that stabilize the five-stranded closed form of betasheet A. These interactions are not present in, and are not compatible with, the observed structure of active alpha1-antitrypsin.

CONCLUSIONS

Serpin 1K may represent the best resting conformation for serpins - canonical near P1, but stabilized in the closed conformation of betasheet A. By comparison with other active serpins, especially alpha1-antitrypsin, a model is proposed in which interaction with the target protease near P1 leads to conformational changes in betasheet A of the serpin.

Conformational changes and disease--serpins, prions and Alzheimer's

Some of the most perplexing disorders in medicine are each now known to arise from the conformational instability of an underlying protein. The consequence is a continuum of pathologies with typically a change in fold leading to ordered aggregation and tissue deposition. The serpins provide a structural prototype for these pathologies and give a perspective on the assessment of current proposals as to the conformational basis of both Alzheimer's disease and the transmissible prion encephalopathies.

Alpha 1-antitrypsin polymerisation can occur by both loop A and C sheet mechanisms

A number of disease states are attributable to alpha1-antitrypsin polymerisation within the endoplasmic reticulum of hepatocytes and subsequent plasma deficiency. Two distinct mechanisms describing the process of alpha1-antitrypsin polymerisation have been proposed, the loop A-sheet and C-sheet mechanisms. We report fluorescence studies using alpha1-antitrypsin covalently modified with pyrene maleimide. These results in conjunction with detailed molecular modelling studies, show that alpha1-antitrypsin is capable of undergoing both loop A-sheet and loop C-sheet mechanisms of polymerisation, depending upon the in vitro buffer conditions.

Deconvolution of the fluorescence emission spectrum of human antithrombin and identification of the tryptophan residues that are responsive to heparin binding

Heparin causes an allosterically transmitted conformational change in the reactive center loop of antithrombin and a 40% enhancement of tryptophan fluorescence. We have expressed four human antithrombins containing single Trp --> Phe mutations and determined that the fluorescence of antithrombin is a linear combination of the four tryptophans. The contributions to the spectrum of native antithrombin at 340 nm were 8% for Trp-49, 10% for Trp-189, 19% for Trp-225, and 63% for Trp-307. Trp-225 and Trp-307 accounted for the majority of the heparin-induced fluorescence enhancement, contributing 37 and 36%, respectively. Trp-49 and Trp-225 underwent spectral shifts of 15 nm to blue and 5 nm to red, respectively, in the antithrombin-heparin complex. The blue shift for Trp-49 is consistent with partial burial by contact with heparin, whereas the red shift for Trp-225 and large enhancement probably result from increased solvent access upon heparin-induced displacement of the contact residue Ser-380. The enhancement for Trp-307 may result from the heparin-induced movement of helix H seen in the crystal structure. The time-resolved fluorescence properties of individual tryptophans of wild-type antithrombin were also determined using the four variants and showed that Trp-225 and Trp-307 experienced the largest change in lifetime upon heparin binding, providing support for the steady-state fluorescence deconvolution.