Sequence, organization, chromosomal localization, and alternative splicing of the human serine protease inhibitor gene hurpin (PI13) which is upregulated in psoriasis

Hurpin (protease inhibitor 13; PI13) is the most recently identified member of the ovalbumin family of serine protease inhibitors (serpins). It is expressed in human epidermal keratinocytes and is downregulated by exposure to ultraviolet irradiation. A role for hurpin in the proliferation or differentiation of keratinocytes has been proposed because of its strong expression in proliferating cells and its deregulated expression in the lesional epidermis of psoriatic patients. Here, we report the cloning, chromosomal localization, and complete sequence of the human hurpin gene. By PCR-based screening of the GeneBridge 4 radiation hybrid panel, we mapped the gene to chromosome 18q21.3, close to a known cluster of ov-serpin genes. Using the full-length cDNA for hurpin, we identified two clones from an arrayed genomic P1 placental library that contain the entire hurpin gene. Sequencing revealed that the gene covers 12.253 kb and is comprised of eight exons and seven introns. The exon--intron boundaries are identical in position and phasing to those in other members of the 18q serpin gene cluster, and analysis of hurpin variants indicated that modified functional inhibitors, differing only in the CD interhelical loop, can be generated by differential splicing of exon 3. These data show that hurpin is a typical member of the 18q ovalbumin-serpins most closely related to the serpins squamous-cell carcinoma antigens 1 and 2.     

Human Ovalbumin Serpin Evolution: Phylogenic Analysis, Gene Organization, and Identification of New PI8-Related Genes Suggest That Two Interchromosomal and Several Intrachromosomal Duplications Generated the Gene Clusters at 18q21–q23 and 6p25

The human ovalbumin (ov) serpins are associated with tumorigenesis, inflammation, and protection from autolysis by granule proteinases. Their genes are located at 18q21 or 6p25, falling into two structurally very similar but distinct categories depending on the presence or absence of a particular exon. Analysis of ov-serpin gene structure provides an opportunity to elucidate the mechanisms contributing to the formation of the larger serpin gene superfamily. Here we have identified a new gene (PI8L1) at 6p25 that is 72% identical to the 18q21 gene PI8. FISH analysis using the 3′ untranslated region of PI8 yielded an additional signal at 18q23, separable from the known 18q21.3 signal by the t(1;18)(p32;q23) chromosomal translocation. The presence of more than one PI8-related gene was confirmed by analysis of human genomic DNA using the same probe. Cloning and analysis of PI8 showed that its intron number and phasing are identical to those of the 6p25 genes PI6, PI9, and ELANH2, and it lacks the interhelical variable loop exon found in other 18q21 genes. PCR analysis demonstrated that PI5 at 18q21 also lacks this exon, indicating that it is organized identically to the 6p25 genes. By contrast, PI10 and megsin have this exon and resemble the other 18q21 genes, PLANH2, SCCA-1, and SCCA-2, in structure. Using these data with an ov-serpin phylogenic tree we have constructed, we propose that the ov-serpin gene clusters arose via interchromosomal duplication of PI5 (or a precursor) to 6p25, followed by duplication at 6p25, and a more recent interchromosomal duplication from 6p25 to 18q to yield PI8.     

The amplified mouse squamous cell carcinoma antigen gene locus contains a serpin (Serpinb3b) that inhibits both papain-like cysteine and trypsin-like serine proteinases

The clade B serpins occupy a unique niche among a larger superfamily by predominantly regulating intracellular proteolysis. In humans, there are 13 family members that map to serpin gene clusters at either 6p25 or 18q21. While most of these serpins display a unique inhibitory profile and appear to be well conserved in mammals, the clade B loci of several species show evidence of relatively recent genomic amplification events. However, it is not clear whether these serpin gene amplification events yield paralogs with functional redundancy or, through selective pressure, inhibitors with more diverse biochemical activities. A recent comparative genomic analysis of the mouse clade B cluster at 1D found nearly complete conservation of gene number, order, and orientation relative to those of 18q21 in humans. The only exception was the squamous cell carcinoma antigen (SCCA) locus. The human SCCA locus contains two genes, SERPINB3 (SCCA1) and SERPINB4 (SCCA2), whereas the mouse locus contains four serpins and three pseudogenes. At least two of these genes encoded functional, dual cross-class proteinase inhibitors. Mouse Serpinb3a was shown previously to inhibit both chymotrypsin-like serine and papain-like cysteine proteinases. We now report that mouse Serpinb3b extends the inhibitory repertoire of the mouse SCCA locus to include a second cross-class inhibitor with activity against both papain-like cysteine and trypsin-like serine proteinases. These findings confirmed that the genomic expansion of the clade B serpins in the mouse was associated with a functional diversification of inhibitory activity.     

Human ovalbumin serpin evolution: phylogenic analysis, gene organization, and identification of new PI8-related genes suggest that two interchromosomal and several intrachromosomal duplications generated the gene clusters at 18q21-q23 and 6p25

The human ovalbumin (ov) serpins are associated with tumorigenesis, inflammation, and protection from autolysis by granule proteinases. Their genes are located at 18q21 or 6p25, falling into two structurally very similar but distinct categories depending on the presence or absence of a particular exon. Analysis of ov-serpin gene structure provides an opportunity to elucidate the mechanisms contributing to the formation of the larger serpin gene superfamily. Here we have identified a new gene (PI8L1) at 6p25 that is 72% identical to the 18q21 gene PI8. FISH analysis using the 3' untranslated region of PI8 yielded an additional signal at 18q23, separable from the known 18q21.3 signal by the t(1;18)(p32;q23) chromosomal translocation. The presence of more than one PI8-related gene was confirmed by analysis of human genomic DNA using the same probe. Cloning and analysis of PI8 showed that its intron number and phasing are identical to those of the 6p25 genes PI6, PI9, and ELANH2, and it lacks the interhelical variable loop exon found in other 18q21 genes. PCR analysis demonstrated that PI5 at 18q21 also lacks this exon, indicating that it is organized identically to the 6p25 genes. By contrast, PI10 and megsin have this exon and resemble the other 18q21 genes, PLANH2, SCCA-1, and SCCA-2, in structure. Using these data with an ov-serpin phylogenic tree we have constructed, we propose that the ov-serpin gene clusters arose via interchromosomal duplication of PI5 (or a precursor) to 6p25, followed by duplication at 6p25, and a more recent interchromosomal duplication from 6p25 to 18q to yield PI8.     

Comparative genomic analysis of the clade B serpin cluster at human chromosome 18q21: amplification within the mouse squamous cell carcinoma antigen gene locus

The human clade B serpins neutralize serine or cysteine proteinases and reside predominantly within the intracellular compartment. Genomic analysis shows that the 13 human clade B serpins map to either 6p25 (n = 3) or 18q21 (n = 10). Similarly, the mouse clade B serpins map to syntenic loci at 13A3.2 and 1D, respectively. The mouse clade B cluster at 13A3.2 shows a marked expansion in the number of serpin genes (n = 15). The purpose of this study was to determine whether a similar expansion occurred at 1D. Using STS-content mapping, comparative genomic DNA sequence analysis, and cDNA cloning, we found that the mouse clade B cluster at 1D showed nearly complete conservation of gene number, order, and orientation relative to those of 18q21. The only exception was the squamous cell carcinoma antigen (SCCA) locus. The human SCCA locus contains two genes, SERPINB3 (SCCA1) and SERPINB4 (SCCA2), whereas the mouse locus contains four serpins and three pseudogenes. Based on phylogenetic analysis and predicted amino acid sequences, amplification of the mouse SCCA locus occurred after rodents and primates diverged and was associated with some diversification of proteinase inhibitory activity relative to that of humans.     

Inhibitory mechanism of a cross-class serpin,the squamous cell carcinoma antigen 1

The squamous cell carcinoma antigen (SCCA) 1 and its homologous molecule, SCCA2, belong to the ovalbumin-serpin family. Although SCCA2 inhibits serine proteinases such as cathepsin G and mast cell chymase, SCCA1 targets cysteine proteinases such as cathepsin S, K, L, and papain. SCCA1 is therefore called a cross-class serpin. The inhibitory mechanism of the standard serpins is well characterized; those use a suicide substrate-like inhibitory mechanism during which an acyl-enzyme intermediate by a covalent bond is formed, and this complex is stable against hydrolysis. However, the inhibitory mechanism of cross-class serpins remains unresolved. In this article, we analyzed the inhibitory mechanism of SCCA1 on a cysteine proteinase, papain. SCCA1 interacted with papain at its reactive site loop, which was then cleaved, as the standard serpins. However, gel-filtration analyses showed that SCCA1 did not form a covalent complex with papain, in contrast to other serpins. Interaction with SCCA1 severely impaired the proteinase activity of papain, probably by inducing conformational change. The decreased, but still existing, proteinase activity of papain was completely inhibited by SCCA1 according to the suicide substrate-like inhibitory mechanism; however, papain recovered its proteinase activity with the compromised level, when all of intact SCCA1 was cleaved. These results suggest that the inhibitory mechanism of SCCA1 is unique among the serpin superfamily in that SCCA1 performs its inhibitory activity in two ways, contributing the suicide substrate-like mechanism without formation of a covalent complex and causing irreversible impairment of the catalytic activity of a proteinase.     

The expanding superfamily of serpins: searching for the real targets

The serpin superfamily of proteins has expanded rapidly in recent years as represented by the ovalbumin-type serpin subfamily. PCR methods have been used to identify new ovalbumin-type serpins, including leupin or SCCA-2, a close relative of SCCA. Although in vitro inhibition of proteases by these serpins has been shown, and we have evidence that leupin can protect cells against apoptosis, the exact role of these serpins is not well understood. Finding relevant targets is a major challenge in serpin biology, and we have investigated the yeast-2-hybrid trap for identification of new interactions. Preliminary studies suggest that serpins are at the upper limit for bait size, but this technique may be useful for identifying interactions where full-length serpin protein is not required.     

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.     

SERPINB12 is a novel member of the human ov-serpin family that is widely expressed and inhibits trypsin-like serine proteinases

Members of the human serpin family regulate a diverse array of serine and cysteine proteinases associated with essential biological processes such as fibrinolysis, coagulation, inflammation, cell mobility, cellular differentiation, and apoptosis. Most serpins are secreted and attain physiologic concentrations in the blood and extracellular fluids. However, a subset of the serpin superfamily, the ov-serpins, also resides intracellularly. Using high throughput genomic sequence, we identified a novel member of the human ov-serpin gene family, SERPINB12. The gene mapped to the ov-serpin cluster at 18q21 and resided between SERPINB5 (maspin) and SERPINB13 (headpin). The presence of SERPINB12 in silico was confirmed by cDNA cloning. Expression studies showed that SERPINB12 was expressed in many tissues, including brain, bone marrow, lymph node, heart, lung, liver, pancreas, testis, ovary, and intestines. Based on the presence of Arg and Ser at the reactive center of the RSL, SERPINB12 appeared to be an inhibitor of trypsin-like serine proteinases. This hypothesis was confirmed because recombinant SERPINB12 inhibited human trypsin and plasmin but not thrombin, coagulation factor Xa, or urokinase-type plasminogen activator. The second-order rate constants for the inhibitory reactions were 2.5 +/- 1.6 x 10(5) and 1.6 +/- 0.2 x 10(4) M(-1) S(-1), respectively. These data show that SERPINB12 encodes for a new functional member of the human ov-serpin family.     

Chromosomal Assignment of Human Nuclear Envelope Protein Genes LMNA, LMNB1, and LBR by Fluorescencein SituHybridization

We have used fluorescencein situhybridization to establish precise chromosomal localizations for three human genes encoding four different nuclear envelope proteins. Lamin A/C (LMN1, HGMW-approved symbol LMNA) mapped to 1q21.2–q21.3, with a most probable gene assignment to 1q21.3; lamin B receptor (LBR) was localized to 1q42.1; and lamin B1 (LMNB1) was mapped to the interface of bands 5q23.3–q31.1. Assignments were determined by direct placement of signals relative to high-resolution DAPI or G-bands. Comparison of these results of band positions predicted from fractional length measurements to signal placement indicated that more accurate predictions are made using Francke idiograms and that measurement strategy avoids variance due to polymorphic chromosome segments.     

A serpin in the cellulosome of the anaerobic fungus Piromyces sp. strain E2

A gene encoding a novel component of the cellulolytic complex (cellulosome) of the anaerobic fungus Piromyces sp. strain E2 was identified. The encoded 538 amino acid protein, named celpin, consists of a signal peptide, a positively charged domain of unknown function followed by two fungal dockerins, typical for components of the extracellular fungal cellulosome. The C-terminal end consists of a 380 amino acid serine proteinase inhibitor (or serpin) domain homologue, sharing 30 % identity and 50 % similarity to vertebrate and bacterial serpins. Detailed protein sequence analysis of the serpin domain revealed that it contained all features of a functional serpin. It possesses the conserved amino acids present in more than 70 % of known serpins, and it contained the consensus of inhibiting serpins. Because of the confined space of the fungal cellulosome inside plant tissue and the auto-proteolysis of plant material in the rumen, the fungal serpin is presumably involved in protection of the cellulosome against plant proteinases. The celpin protein of Piromyces sp. strain E2 is the first non-structural, non-hydrolytic fungal cellulosome component. Furthermore, the celpin protein of Piromyces sp. strain E2 is the first representative of a serine proteinase inhibitor of the fungal kingdom.     

Sequence organization and matrix attachment regions of the human serine protease inhibitor gene cluster at 14q32.1

The human serine protease inhibitor (serpin) gene cluster at 14q32.1 is a useful model system for studying the regulation of gene activity and chromatin structure. We demonstrated previously that the six known serpin genes in this region were organized into two subclusters of three genes each that occupied ~370 kb of DNA. To more fully understand the genomic organization of this region, we annotated a 1-Mb sequence contig from data from the Genoscope sequencing consortium ( ). We report that 11 different serpin genes reside within the 14q32.1 cluster, including two novel 1-antiproteinase-like gene sequences, a kallistatin-like sequence, and two recently identified serpins that had not been mapped previously to 14q32.1. The genomic regions proximal and distal to the serpin cluster contain a variety of unrelated gene sequences of diverse function. To gain insight into the chromatin organization of the region, sequences with putative nuclear matrix-binding potential were identified by using the MAR-Wiz algorithm, and these MAR-Wiz candidate sequences were tested for nuclear matrix-binding activity in vitro. Several differences between the MAR-Wiz predictions and the results of biochemical tests were observed. The genomic organization of the serpin gene cluster is discussed. These authors (Stephanie J. Namciu and Richard D. Friedman) contributed equally to this work.     

Physical mapping of four serpin genes: alpha 1-antitrypsin, alpha 1-antichymotrypsin, corticosteroid-binding globulin, and protein C inhibitor, within a 280-kb region on chromosome I4q32.1.

Alpha 1-antitrypsin (alpha 1AT; protease inhibitor [PI] locus), alpha 1-antichymotrypsin (alpha 1ACT; AACT locus), corticosteroid-binding globulin (CBG; CBG locus), and protein C inhibitor (PCI; PCI locus) are members of the serine protease inhibitor (serpin) superfamily. A noncoding PI-like (PIL) gene has been located 12 kb 3' of the PI gene. The PI, PIL, and AACT loci have been localized to 14q32.1, the CBG locus has been localized to 14q31-14q32.1, and PCI has been mapped to chromosome 14. Genetic linkage analysis suggests tight linkage between PI and AACT. We have used pulsed-field gel electrophoresis to generate a physical map linking these five serpin genes. The order of the genetic loci is AACT/PCI-PI-PIL-CBG, with a maximum distance of about 220 kb between the AACT/PCI and PI genes. These genes form a PI cluster at 14q32.1, similar to that of the homologous genes on murine chromosome l2. The close proximity of these genes has implications for disease-association studies.     

SCCA2 inhibits TNF-mediated apoptosis in transfected HeLa cells. The reactive centre loop sequence is essential for this function and TNF-induced cathepsin G is a candidate target.

The squamous cell carcinoma antigens, SCCA1 and SCCA2, are members of the serine protease inhibitors (serpin) superfamily and are transcribed by two tandomly arrayed genes. A number of serpins are known to inhibit apoptosis in mammalian cells. In this study we demonstrate the ability of SCCA2 to inhibit tumor necrosis factor-alpha (TNF alpha)-induced apoptosis. HeLa cells stably transfected with SCCA2 cDNA had increased percentage cell survival and reduced DNA fragmentation. We investigated if the reactive centre loop (RCL) was necessary to allow SCCA2 to inhibit TNF alpha-mediated apoptosis. The RCL amino acids (E353Q, L354G, S355A), flanking the predicted cleavage site, were mutated and the resulting SCCA2 lost both the ability to inhibit cathepsin G and to protect stably transfected cells from TNF alpha-induced apoptosis. The presence of SCCA2 caused a decrease in the activation of caspase-3 upon induction with TNF alpha but no direct inhibition of caspases by SCCA2 has been found. Expression of cathepsin G was found to be induced in HeLa cells following treatment with TNF alpha. This protease has recently been shown to have a role in apoptosis through cleavage of substrates, so maybe the relevant target for SCCA2 in this system.     

Co-expression of the squamous cell carcinoma antigens 1 and 2 in normal adult human tissues and squamous cell carcinomas.

Squamous cell carcinoma antigen (SCCA) serves as a serological marker for advanced squamous cell carcinomas (SCCs) and as an indicator of therapeutic response. Recent molecular studies show that the SCCA is transcribed by two almost identical tandemly arrayed genes, SCCA1 and SCCA2. These genes are members of the high molecular weight serine proteinase inhibitor (serpin) superfamily. Although SCCA1 and SCCA2 are 92% identical at the amino acid level, they have distinct biochemical properties. Paradoxically, SCCA1 is an inhibitor of papain-like cysteine proteinases, such as cathepsins L, S, and K, whereas SCCA2 inhibits chymotrypsin-like serine proteinases, cathepsin G, and mast cell chymase. Using a new set of discriminatory monoclonal antibodies (MAbs) and polymerase chain reaction (PCR) assay, we showed that SCCA1 and SCCA2 were co-expressed in the suprabasal layers of the stratified squamous epithelium of the tongue, tonsil, esophagus, uterine cervix and vagina, Hassall's corpuscles of the thymus, and some areas of the skin. SCCA1 and SCCA2 also were detected in the pseudo-stratified columnar epithelium of the conducting airways. Examination of squamous cell carcinomas of the lung and head and neck showed that SCCA1 and SCCA2 were co-expressed in moderately and well-differentiated tumors. Moreover, there was no differential expression between these SCCA "isoforms" in normal or malignant tissues. In contrast to previous studies, these data indicated that the expression of SCCA1 and SCCA2 was not restricted to the squamous epithelium and that these serpins may coordinately regulate cysteine and serine proteinase activity in both normal and transformed tissues.     

Serpins in Unicellular Eukarya, Archaea, and Bacteria: Sequence Analysis and Evolution

Most serpins irreversibly inactivate specific serine proteinases of the chymotrypsin family. Inhibitory serpins are unusual proteins in that their native structure is metastable, and rapid conversion to a relaxed state is required to trap target enzymes in a covalent complex. The evolutionary origin of the serpin fold is unresolved, and while serpins in animals are known to be involved in the regulation of a remarkable diversity of metabolic processes, the physiological functions of homologues from other phyla are unknown. Addressing these questions, here we analyze serpin genes identified in unicellular eukaryotes: the green alga Chlamydomonas reinhardtii, the dinoflagellate Alexandrium tamarense, and the human pathogens Entamoeba spp., Eimera tenella, Toxoplasma gondii, and Giardia lamblia. We compare these sequences to others, particularly those in the complete genome sequences of Archaea, where serpins were found in only 4 of 13 genera, and Bacteria, in only 9 of 56 genera. The serpins from unicellular organisms appear to be phylogenetically distinct from all of the clades of higher eukaryotic serpins. Most of the sequences from unicellular organisms have the characteristics of inhibitory serpins, and where multiple serpin genes are found in one genome, variability is displayed in the region of the reactive-center loop important for specificity. All the unicellular eukaryotic serpins have large hydrophobic or positively charged residues at the putative P₁ position. In contrast, none of the prokaryotic serpins has a residue of these types at the predicted P₁ position, but many have smaller, neutral residues. Serpin evolution is discussed.[Reviewing Editor: Dr. Peer Bork]     

An additional locus (PI4) in the protease inhibitor (PI) gene cluster of pigs

A further α-protease inhibitor system, PI4, was detected in porcine sera using either 2D agarose gel, pH 5.0-PAGE, pH 9.0, or ID PAGE followed by immunoblotting with rabbit anti-porcine PI2 or PI3 antisera. PI4 inhibited chymotrypsin, but not trypsin. Seven allelic variants of PI4 were described. By haplotyping of a-protease inhibitor systems in 52 complete families it was shown that PI4 locus belongs to the PI gene cluster. The probable order of the PI loci was: PI1, PO1A, PI2, PI4, PI3.     

Kinetics and physiologic relevance of the inactivation of alpha 1-proteinase inhibitor, alpha 1-antichymotrypsin, and antithrombin III by matrix metalloproteinases-1 (tissue collagenase), -2 (72-kDa gelatinase/type IV collagenase), and -3 (stromelysin).

Serpins encompass a superfamily of proteinase inhibitors that regulate many of the serine proteinases involved in inflammation and hemostasis. In vitro, many serpins are catalytically inactivated by proteinases that they do not inhibit, leading to the concept of proteolytic down-regulation of serpin inhibitory capacity. The extent to which down-regulation of serpin activity occurs in vivo is debated, since little is known of the rates at which the process occurs. To address this debate, we have measured the rates of inactivation of three serpins, alpha 1-proteinase inhibitor (alpha 1PI), alpha 1-antichymotrypsin (alpha 1ACT), and antithrombin III (ATIII), by three human matrix metalloproteinases (MMPs-1, -2, and -3) thought to be involved in tissue destruction and repair. Our object was to establish a working kinetic model which can be used to predict whether serpin inactivation by these proteinases is likely to occur in vivo. We determined the rates of inactivation of these three serpins by each of the MMPs and compared these to rates of inhibition of the MMPs by an endogenous inhibitor, alpha 2-macroglobulin. An equation designed to predict the extent of substrate hydrolyzed by an enzyme in the presence of an enzyme inhibitor gave the following predictions of the inactivation in vivo: (i) ATIII is unlikely to be inactivated by the MMPs. (ii) MMP-2 (72-kDa gelatinase/type IV collagenase) is unlikely to inactivate any of the three serpins. (iii) MMP-1 (tissue collagenase) will inactivate alpha 1PI and alpha 1ACT only when its concentration saturates that of its controlling inhibitors. (iv) MMP-3 (stromelysin) may inactivate small amounts of alpha 1PI and more significant amounts of alpha 1ACT, even in the presence of its controlling inhibitors. Any physiologic or pathologic inactivation of these serpins by these MMPs that occurs in vivo will probably be due to MMP-3, and will likely only take place in tissues and inflammatory loci where the concentration of MMP inhibitors is depressed.