The Spn4 gene from Drosophila melanogaster is a multipurpose defence tool directed against proteases from three different peptidase families

By alternative use of four RSL (reactive site loop) coding exon cassettes, the serpin (serine protease inhibitor) gene Spn4 from Drosophila melanogaster was proposed to enable the synthesis of multiple protease inhibitor isoforms, one of which has been shown to be a potent inhibitor of human furin. Here, we have investigated the inhibitory spectrum of all Spn4 RSL variants. The analyses indicate that the Spn4 gene encodes inhibitors that may inhibit serine proteases of the subtilase family (S8), the chymotrypsin family (S1), and the papain-like cysteine protease family (C1), most of them at high rates. Thus a cohort of different protease inhibitors is generated simply by grafting enzyme-adapted RSL sequences on to a single serpin scaffold, even though the target proteases contain different types and/or a varying order of catalytic residues and are descendents of different phylogenetic lineages. Since all of the Spn4 RSL isoforms are produced as intracellular residents and additionally as variants destined for export or associated with the secretory pathway, the Spn4 gene represents a versatile defence tool kit that may provide multiple antiproteolytic functions.     

The serpin SQN-5 is a dual mechanistic-class inhibitor of serine and cysteine proteinases

SQN-5 is a mouse serpin that is highly similar to the human serpins SCCA1 (SERPINB3) and SCCA2 (SERPINB4). Previous studies characterizing the biochemical activity of SQN-5 showed that this serpin, like SCCA2, inhibited the chymotrypsin-like enzymes mast cell chymase and cathepsin G. Using an expanded panel of papain-like cysteine proteinases, we now show that SQN-5, like SCCA1, inhibited cathepsins K, L, S, and V but not cathepsin B or H. These interactions were characterized by stoichiometries of inhibition that were nearly 1:1 and second-order rate constants of >10(4) M(-1) s(-1). Reactive site loop (RSL) cleavage analysis showed that SQN-5 employed different reactive centers to neutralize the serine and cysteine proteinases. To our knowledge, this is the first serpin that serves as a dual inhibitor of both chymotrypsin-like serine and the papain-like cysteine proteinases by employing an RSL-dependent inhibitory mechanism. The ability of serpins to inhibit both serine and/or papain-like cysteine proteinases may not be a recent event in mammalian evolution. Phylogenetic studies suggested that the SCCA and SQN genes evolved from a common ancestor approximately 250-280 million years ago. When the fact that mammals and birds diverged approximately 310 million years ago is considered, an ancestral SCCA/SQN-like serpin with dual inhibitory activity may be present in many mammalian genomes.     

Stability of mutant serpin/furin complexes: dependence on pH and regulation at the deacylation step

Furin proteolytically cleaves a wide variety of proprotein substrates mainly within the trans-Golgi network (TGN) but also at the cell membrane and in endosomal compartments where pH is more acidic. Incorporation of furin recognition sequences within the reactive site loop (RSL) of alpha(1)-antitrypsin (AT) leads to the production of furin inhibitors. In an attempt to design more stable, potent, and specific serpin-based inhibitors, we constructed a series of AT and alpha(1)-antichymotrypsin (ACT) mutants by modifying the P(7)-P(1) region of their RSLs. The biochemical properties of these variants were assessed by evaluating their propensity to establish SDS-resistant complexes with furin in a variety of conditions (pH 6.0-9.0) and by measuring their association rate constants. The effect of pH during the initial steps of complex formation was minimal, suggesting that the acylation step is not rate-limiting. The decrease in stoichiometry of inhibition (SI) values observed in AT variants at high pHs was a result of the reduced pH-dependent deacylation rate, which is rate-limiting in this mechanism and which suggests increased complex stability. Conversely, the SI values for ACT mutants had a tendency to be lower at acidic pH. Transiently transfecting HEK293 cells with these mutants abolished processing of the pro-von Willebrand factor precursor but, interestingly, only the ACT variants were secreted in the media as uncleaved forms. Our results suggest that reengineering the reactive site loops of serpins to accommodate and target furin or other serine proteases must take into account the intrinsic physicochemical properties of the serpin.     

The novel bovine serpin endopin 2C demonstrates selective inhibition of the cysteine protease cathepsin L compared to the serine protease elastase, in cross-class inhibition

Molecular cloning revealed the unique serpin endopin 2C that demonstrates selective inhibition of cathepsin L compared to papain or elastase. Endopin 2C, thus, functions as a serpin with the property of cross-class inhibition. Endopin 2C possesses homology in primary sequence to endopin 2A and other isoforms of endopins related to alpha1-antichymotrypsin, yet endopin 2C differs in its target protease specificity. Recombinant endopin 2C showed effective inhibition of cathepsin L with a stoichiometry of inhibition (SI) of 1/1 (molar ratio of inhibitor/protease), with the second-order rate constant, k(ass), of 7.2 x 10(5) M(-1) s(-1). Less effective endopin 2C inhibition of papain and elastase occurred with k(ass) association rate constants of approximately 1 x 10(4) M(-1) s(-1) with high SI values. Endopin 2C formed SDS-stable complexes with cathepsin L, papain, and elastase that are typical of serpins. These results are among the first to demonstrate stable serpin complexes with target cysteine proteases. Interactions of endopin 2C with cathepsin L and elastase were indicated by protease cleavage of the RSL region between P1-P1' residues of Thr-Ser. The hydrophobic Phe residue in the P2 position of the RSL region is consistent with the specificity of cathepsin L for hydrophobic residues in the P2 position of its substrate cleavage site. The NH2-terminal signal sequence of endopin 2C, like that of cathepsin L, predicts their colocalization to subcellular organelles. These findings demonstrate endopin 2C as a novel serpin that possesses cross-class inhibition with selectivity for inhibition of cathepsin L.     

The novel serpin endopin 2 demonstrates cross-class inhibition of papain and elastase: localization of endopin 2 to regulated secretory vesicles of neuroendocrine chromaffin cells

This study demonstrates that endopin 2 is a unique secretory vesicle serpin that displays cross-class inhibition of cysteine and serine proteases, indicated by effective inhibition of papain and elastase, respectively. Homology of the reactive site loop (RSL) domain of endopin 2, notably at P1-P1' residues, with other serpins that inhibit cysteine and serine proteases predicted that endopin 2 may inhibit similar proteases. Recombinant N-His-tagged endopin 2 inhibited papain and elastase with second-order rate constants (k(ass)) of 1.4 x 10(6) and 1.7 x 10(5) M(-1) s(-1), respectively. Endopin 2 formed SDS-stable complexes with papain and elastase, a characteristic property of serpins. Interactions of the RSL domain of endopin 2 with papain and elastase were indicated by cleavage of endopin 2 near the predicted P1-P1' residues by these proteases. Endopin 2 did not inhibit the cysteine protease cathepsin B, or the serine proteases chymotrypsin, trypsin, plasmin, and furin. Endopin 2 in neuroendocrine chromaffin cells was colocalized with the secretory vesicle component (Met)enkephalin by confocal immunonfluorescence microscopy, and was present in isolated secretory vesicles (chromaffin granules) from chromaffin cells as a glycoprotein of 72-73 kDa. Moreover, regulated secretion of endopin 2 from chromaffin cells was induced by nicotine and KCl depolarization. Overall, these results demonstrate that the serpin endopin 2 possesses dual specificity for inhibiting both papain-like cysteine and elastase-like serine proteases. These findings demonstrate that endopin 2 inhibitory functions may occur in the regulated secretory pathway.     

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.     

Structure and properties of proprotein convertase inhibitors

This review is devoted to structure and properties of proprotein convertases (PCs), the intracellular Ca(2+)-dependent serine endoproteases of mammalia, that play the essential role in the processing of inactive protein precursors and their transforming into bioactive mature products. PCs are also implicated in development of a great variety of diseases including bacterial or viral infections and such pathologies as cancer, Alzheimer's disease, obesity and so on. Owing to these findings, PCs are considered as promising targets for design of their inhibitors and development of new potential therapeutic agents. Only several endogenous protein inhibitors are identified now for PCs: pro7B2 (Proprotein 7B2), the specific chaperon of PC2, granine-like precursor of neuroendocrine protein proSAAS, the selective ligand of PC1, and serpin Spn4A (Serine Proteinase Inhibitor) of Drosophila melanogaster that inhibits PC2 and furin. By the methods of site-directed mutagenesis, the bioengineered inhibitors of PCs were also designed. Structures and properties of protein or peptide fragments as inhibitors of PCs were also discussed. Particularly, the properties of polyarginines and small peptides containing pseudopeptide bond at the scissile site a suitable peptide substrate were described. The inhibitory activity of non-peptide compounds such as derivatives of andrographolid from Andrographis paniculata (K(i) = 2.6-200 microM against furin), certain complexes of pyridine analogs with ions of Cu2+ or Zn2+ inhibiting furin with IC50 = 5-10 microM, derivatives of 2,5-dideoxy-streptamine containing several guanidine groups (K(i) = 6-812 nM for furin) and also a number of dicoumarols (K(i) = 1-185 microM against furin) and some flavonoids (with K(i) = 5-230 microM for furin) were reflected in the article. The effects of enediynyl-amino acids derivatives or their peptides (K(i) = 40 nM against furin) were considered. Inhibition of PC2 by N-acylated bicyclic guanidines (K(i) = 3.3-10 microM) or derivatives of pyrrolidin bispyperazines (K(i) = 0.54-10 microM) are considered too. Some of synthesized derivatives may serve as lead compounds for design of the specific inhibitors for individual PCs.     

The effects of reactive site location on the inhibitory properties of the serpin alpha(1)-antichymotrypsin

The large size of the serpin reactive site loop (RSL) suggests that the role of the RSL in protease inhibition is more complex than that of presenting the reactive site (P1 residue) to the protease. This study examines the effect on inhibition of relocating the reactive site (Leu-358) of the serpin alpha(1)-antichymotrypsin either one residue closer (P2) or further (P1') from the base of the RSL (Glu-342). alpha(1)-Antichymotrypsin variants were produced by mutation within the P4-P2' region; the sequence ITLLSA was changed to ITLSSA to relocate the reactive site to P2 (Leu-357) and to ITITLS to relocate it to P1' (Leu-359). Inhibition of the chymotrypsin-like proteases human chymase and chymotrypsin and the non-target protease human neutrophil elastase (HNE) were analyzed. The P2 variant inhibited chymase and chymotrypsin but not HNE. Relative to P1, interaction at P2 was characterized by greater complex stability, lower inhibition rate constants, and increased stoichiometry of inhibition values. In contrast, the P1' variant inhibited HNE (stoichiometry of inhibition = 4) but not chymase or chymotrypsin. However, inhibition of HNE was by interaction with Ile-357, the P2 residue. The P1' site was recognized by all proteases as a cleavage site. Covalent-complexes resistant to SDS-PAGE were observed in all inhibitory reactions, consistent with the trapping of the protease as a serpin-acyl protease complex. The complete loss in inhibitory activity associated with lengthening the Glu-342-reactive site distance by a single residue and the enhanced stability of complexes associated with shortening this distance by a single residue are compatible with the distorted-protease model of inhibition requiring full insertion of the RSL into the body of the serpin and translocation of the linked protease to the pole opposite from that of encounter.     

Sufficiency of the reactive site loop of maspin for induction of cell-matrix adhesion and inhibition of cell invasion. Conversion of ovalbumin to a maspin-like molecule

Maspin, an ov-serpin, inhibits tumor invasion and induces cell adhesion to extracellular matrix molecules. Here, we use maspin/ovalbumin chimeric proteins and the maspin reactive site loop (RSL) peptide to characterize the role of the RSL in maspin-mediated functions. Replacement of the RSL plus the C-terminal region or the RSL alone of maspin with that of ovalbumin resulted in the loss of the stimulatory effect on adhesion of corneal stromal cells to type I collagen, fibronectin, and laminin and of mammary carcinoma MDA-MB-231 cells to fibronectin. Maspin with ovalbumin as the C-terminal region retained activity, suggesting the maspin C-terminal polypeptide is not required. An R340Q mutant retained full maspin activity; however, an R340A mutant lost activity. This indicates the arginine side chain at the putative P1 site forms a hydrogen bond and not an ionic bond. The RSL peptide (P10-P5', amino acids 330-345) alone induced cell-matrix adhesion of mammary carcinoma cells and corneal stromal cells and inhibited invasion of the carcinoma cells. Substitution of the RSL of ovalbumin with that of maspin converted inactive ovalbumin into a fully active molecule. Maspin bound specifically to the surface of the mammary carcinoma cells with a kd of 367 +/- 67 nM and 32.0 +/- 2.2 x 10(6) binding sites/cell. The maspin RSL peptide inhibited binding, suggesting the RSL is involved in maspin binding to cells. Sufficiency of the maspin RSL for activity suggests the mechanism by which maspin regulates cell-matrix adhesion and tumor cell invasion does not involve the serpin mechanism of protease inhibition.     

Identification of Serpin Determinants of Specificity and Selectivity for Furin Inhibition through Studies of α1PDX (α1-Protease Inhibitor Portland)-Serpin B8 and Furin Active-site Loop Chimeras

α₁-Protease inhibitor Portland (α₁PDX) is an engineered serpin family inhibitor of the proprotein convertase (PC), furin, that exhibits high specificity but limited selectivity for inhibiting furin over other PC family proteases. Here, we characterize serpin B8, a natural inhibitor of furin, together with α₁PDX-serpin B8 and furin-PC chimeras to identify determinants of serpin specificity and selectivity for furin inhibition. Replacing reactive center loop (RCL) sequences of α₁PDX with those of serpin B8 demonstrated that both the P4–P1 RXXR recognition sequence as well as the P1′–P5′ sequence are critical determinants of serpin specificity for furin. Alignments of PC catalytic domains revealed four variable active-site loops whose role in furin reactivity with serpin B8 was tested by engineering furin-PC loop chimeras. The furin(298–300) loop but not the other loops differentially affected furin reactivity with serpin B8 and α₁PDX in a manner that depended on the serpin RCL-primed sequence. Modeling of the serpin B8-furin Michaelis complex identified serpin exosites in strand 3C close to the 298–300 loop whose substitution in α₁PDX differentially affected furin reactivity depending on the furin loop and serpin RCL-primed sequences. These studies demonstrate that RCL-primed residues, strand 3C exosites, and the furin(298–300) loop are critical determinants of serpin reactivity with furin, which may be exploited in the design of specific and selective α₁PDX inhibitors of PCs.     

Serpin mechanism of hepatitis C virus nonstructural 3 (NS3) protease inhibition: induced fit as a mechanism for narrow specificity

Hepatitis C virus (HCV) nonstructural 3 (NS3) serine protease disrupts important cellular antiviral signaling pathways and plays a pivotal role in the proteolytic maturation of the HCV polyprotein precursor. This recent discovery has fostered the search for NS3 protease inhibitors. However, the enzyme's unusual induced fit behavior and peculiar molecular architecture have imposed considerable obstacles to the development of small molecule inhibitors. In this article, we demonstrate that such unique induced fit behavior and the chymotrypsin-like catalytic domain can provide the structural plasticity necessary to generate protein-based inhibitors of the NS3 protease. We took advantage of the macromolecular scaffold of a Drosophila serpin, SP6, which intrinsically supports chymotrypsin-like enzyme inhibition, to design a novel class of potent and selective inhibitors. We show that altering the SP6 reactive site loop (RSL) resulted in the development of the first effective (K(i) of 34 nm) and selective serpin, SP6(EVC/S), directed at the NS3 protease. SP6(EVC/S) operates as a suicide substrate inhibitor, and its partitioning between the complex-forming and proteolytic pathways for the NS3 protease is HCV NS4A cofactor-dependent and -specific. Once bound to the protease active site, SP6(EVC/S) partitions with equal probability to undergo proteolysis by NS3 at the C-terminal site of the engineered RSL, (P(6))Glu-Ile-(P(4))Val-Met-Thr-(P(1))Cys- downward arrow -(P(1)')Ser, or to form a covalent acyl-enzyme complex characteristic of cognate protease-serpin pairs. Our results also reveal a novel cofactor-induced serpin mechanism of enzyme inhibition that could be explored for developing effective and selective inhibitors of other important induced fit viral proteases of the Flaviviridae family such as the West Nile virus NS3 endoprotease.     

Drosophila Serpin-28D regulates hemolymph phenoloxidase activity and adult pigmentation

In insects the enzyme phenoloxidase (PO) catalyzes melanin deposition at the wound site and around parasitoid eggs. Its proenzyme prophenoloxidase (proPO) is proteolytically cleaved to active phenoloxidase by a cascade consisting of serine proteases and inhibited by serpins. The Drosophila genome encodes 29 serpins, of which only two, Serpin-27A (Spn27A) and Necrotic, have been analyzed in detail. Using a genetic approach, we demonstrate that the so far uncharacterized Serpin-28D (Spn28D, CG7219) regulates the proPO cascade in both hemolymph and tracheal compartments. spn28D is the serpin gene most strongly induced upon injury. Inactivation of spn28D causes pupal lethality and a deregulated developmental PO activation leading to extensive melanization of tissues in contact with air and pigmentation defects of the adult cuticle. Our data also show that Spn28D regulates hemolymph PO activity in both larvae and adults at a different level than Spn27A. Our data support a model in which Spn28D confines PO availability by controlling its initial release, while Spn27A is rather limiting the melanization reaction to the wound site. This study further highlights the complexity of the proPO cascade that can be differentially regulated in different tissues during development.     

Solution structure and dynamics of a serpin reactive site loop using interleukin 1beta as a presentation scaffold

Human interleukin-1beta (IL1beta) was used as a presentation scaffold for the characterization of the reactive site loop (RSL) of the serpin alpha1-antitrypsin (A1AT), the physiological inhibitor of leukocyte elastase. A chimeric protein was generated by replacement of residues 50-53 of IL1beta, corresponding to an exposed reverse turn in IL1beta, with the 10-residue P5-P5' sequence EAIPMSIPPE from A1AT. The chimera (antitrypsin-interleukin, AT-IL) inhibits elastase specifically and also binds the IL1beta receptor. Multinuclear NMR characterization of AT-IL established that, with the exception of the inserted sequence, the structure of the IL1beta scaffold is preserved in the chimera. The structure of the inserted RSL was analyzed relative to that of the isolated 10-residue RSL peptide, which was shown to be essentially disordered in solution. The chimeric RSL was also found to be solvent exposed and conformationally mobile in comparison with the IL1beta scaffold, and there was no evidence of persisting interactions with the scaffold outside of the N- and C-terminal linkages. However, AT-IL exhibits sigificant differences in chemical shift and NOE patterns relative to the isolated RSL that are consistent with local features of non-random structure. The proximity of these features to the P1-P1' residues suggests that they may be responsible for the inhibitory activity of the chimera.     

Engineered serine protease inhibitor prevents furin-catalyzed activation of the fusion glycoprotein and production of infectious measles virus.

We have identified the major cellular endoprotease that activates the fusion (F) glycoprotein of measles virus (MV) and have engineered a serine protease inhibitor (serpin) to target the endoprotease and inhibit the production of infectious MV. The F-protein precursor of MV was not cleaved efficiently into the mature F protein in human colon carcinoma cells lacking functional furin, indicating that furin is the major enzyme responsible for activation of the MV F protein. A human serpin alpha 1-antitrypsin variant was engineered to specifically inhibit furin. When expressed from a recombinant vaccinia virus in primate cells infected by MV, the engineered serpin (alpha 1-PDX) specifically inhibited furin-catalyzed cleavage of the F-protein precursor without affecting synthesis of other MV proteins. We generated human glioma cells stably expressing alpha 1-PDX. MV infection in these cells did not result in syncytia. The infected cells produced all the MV proteins, but the F-protein precursor remained largely uncleaved. This did not prevent virus assembly. However, the released virions contained inactive F-protein precursor rather than mature F protein, and infectious-virus titers were reduced by 3 to 4 orders of magnitude. These results show that a mature F protein is not required for the assembly of MV but is crucial for virus infectivity. The engineered serpin may offer a novel molecular antiviral approach against MV.     

SPI-1-Dependent Host Range of Rabbitpox Virus and Complex Formation with Cathepsin G Is Associated with Serpin Motifs

Serpins are a superfamily of serine proteinase inhibitors which function to regulate a number of key biological processes including fibrinolysis, inflammation, and cell migration. Poxviruses are the only viruses known to encode functional serpins. While some poxvirus serpins regulate inflammation (myxoma virus SERP1 and cowpox virus [CPV] crmA/SPI-2) or apoptosis (myxoma virus SERP2 and CPV crmA/SPI-2), the function of other poxvirus serpins remains unknown. The rabbitpox virus (RPV) SPI-1 protein is 47% identical to crmA and shares all of the serpin structural motifs. However, no serpin-like activity has been demonstrated for SPI-1 to date. Earlier we showed that RPV with the SPI-1 gene deleted, unlike wild-type virus, fails to grow on A549 or PK15 cells (A. Ali, P. C. Turner, M. A. Brooks, and R. W. Moyer, Virology 202:306-314, 1994). Here we demonstrate that in the absence of a functional SPI-1 protein, infected nonpermissive cells which exhibit the morphological features of apoptosis fail to activate terminal caspases or cleave the death substrates PARP or lamin A. We show that SPI-1 forms a stable complex in vitro with cathepsin G, a member of the chymotrypsin family of serine proteinases, consistent with serpin activity. SPI-1 reactive-site loop (RSL) mutations of the critical P1 and P14 residues abolish this activity. Viruses containing the SPI-1 RSL P1 or P14 mutations also fail to grow on A549 or PK15 cells. These results suggest that the full virus host range depends on the serpin activity of SPI-1 and that in restrictive cells SPI-1 inhibits a proteinase with chymotrypsin-like activity and may function to inhibit a caspase-independent pathway of apoptosis.     

Substrate specificity of human cathepsin D using internally quenched fluorescent peptides derived from reactive site loop of kallistatin

Kallistatin, a serpin that specifically inhibits human tissue kallikrein, was demonstrated to be cleaved at the Phe-Phe bond in its reactive site loop (RSL) by cathepsin D. Internally quenched fluorescent peptides containing the amino acid sequence of kallistatin RSL were highly susceptible to hydrolysis by cathepsin D. Surprisingly, these peptides were efficiently hydrolyzed at Phe-Phe bond, despite having Lys and Ser at P2 and P2' positions, respectively, which was reported to be very unfavorable for substrates for cathepsin D. Due to the importance of cathepsin D in several physiological and pathological processes, we took the peptide containing kallistatin RSL sequence, Abz-Ala-Ile-Lys-Phe-Phe-Ser-Arg-Gln-EDDnp, as a reference substrate for a systematic specificity study of S3 to S3' protease subsites (EDDnp=N-[2,4-dinitrophenyl]-ethylenediamine and Abz=ortho-amino benzoic acid). We present in this paper some internally quenched fluorescent peptides that were efficient substrates for cathepsin D. They essentially differ from other previously described substrates by their higher kcat/Km values due, mainly, to low Km values, such as the substrate Abz-Ala-Ile-Ala-Phe-Phe-Ser-Arg-Gln-EDDnp (Km=0.27 microM, kcat=16.25 s(-1), kcat/Km=60185 microM(-1) x s(-1)).     

Multiple domains of endopin 2A for serpin cross-class inhibition of papain

The serpin endopin 2A inhibits the cysteine protease papain in cross-class inhibition. This study demonstrates the novel finding that both the non-RSL NH(2)-domain and the RSL domain with P1-P1' residues participate in endopin 2A inhibition. Production of a chimeric mutant of endopin 2A with replacement of its NH(2)-domain with that of endopin 1 resulted in less effective inhibition of papain, indicated by its lower k(ass) association rate constant compared to wild-type endopin 2A. This chimeric mutant formed complexes with papain, but at lower levels compared to that with wild-type endopin 2A. Papain degradation of a portion of the chimeric mutant suggested a role for the NH(2)-domain in regulating relative amounts of endopin 2A that enter the substrate pathway compared to the serpin inhibitory pathway. Furthermore, site-directed mutagenesis demonstrated that the RSL domain with intact P1-P1' residues was necessary for inhibition. These findings indicate that the NH(2)-domain and the RSL region both participate in endopin 2A inhibition of papain.     

SERPINB11 is a new noninhibitory intracellular serpin. Common single nucleotide polymorphisms in the scaffold impair conformational change

SERPINB11, the last of 13 human clade B serpins to be described, gave rise to seven different isoforms. One cDNA contained a premature termination codon, two contained splice variants, and four contained full-length open reading frames punctuated by eight single nucleotide polymorphisms (SNPs). The SNPs encoded amino acid variants located within the serpin scaffold but not the reactive site loop (RSL). Although the mouse orthologue, Serpinb11, could inhibit trypsin-like peptidases, SERPINB11 showed no inhibitory activity. To determine whether the human RSL targeted a different class of peptidases or the serpin scaffold was unable to support inhibitory activity, we synthesized chimeric human and mouse proteins, in which the RSLs had been swapped. The human RSL served as a trypsin inhibitor when supported by mouse scaffold sequences. Conversely, the mouse RSL on the human scaffold showed no inhibitory activity. These findings suggested that variant residues in the SERPINB11 scaffold impaired serpin function. SDS-PAGE analysis supported this notion as RSL-cleaved SERPINB11 was unable to undergo the stressed-to-relaxed transition typical of inhibitory type serpins. Mutagenesis studies supported this hypothesis, since the reversion of amino acid sequences in helices D and I to those conserved in other clade B serpins partially restored the ability of SERPINB11 to form covalent complexes with trypsin. Taken together, these findings suggested that SERPINB11 SNPs encoded amino acids in the scaffold that impaired RSL mobility, and HapMap data showed that the majority of genomes in different human populations harbored these noninhibitory SERPINB11 alleles. Like several other serpin superfamily members, SERPINB11 has lost inhibitory activity and may have evolved a noninhibitory function.