Regulation of the Human Plasminogen Activator Inhibitor Type 2 Gene

Background: PAI-2 (SERPINB2) is a serine protease inhibitor that is highly up-regulated in response to cellular stress. Results: The upstream transactivator region of the SERPINB2 promoter was localized to an AP-1 site that overcomes PAUSE-1 silencer activity. Conclusion: The AP-1 site binds factors that promote the derepression of the SERPINB2 promoter. Significance: These data provide molecular insight into cell-specific derepression of the PAI-2 gene during cell differentiation and cancer. Transcriptional up-regulation of the plasminogen activator inhibitor type-2 (PAI-2) gene is a major response to cellular stress. The expression of PAI-2 is induced by a variety of cytokines and growth factors that act in a cell type- and differentiation stage-dependent manner. We previously reported that the human SERPINB2 gene promoter is controlled by three major transcription regulatory domains: an inducible proximal promoter, an upstream silencer (PAUSE-1), and a distal transactivator region between −5100 and −3300, which appears to overcome inhibition mediated by the silencer. The distal transactivator region is inducible by the phorbol ester PMA, a potent activator of the protein kinase C (PKC) pathway that is a powerful inducer of PAI-2 gene expression in monocytes, macrophages, and myelomonocytic cells as well as in epidermal keratinocytes. Here we show that a 21-bp region (−4952/−4932), containing an AP-1 element, is both necessary and sufficient for PMA-induced transactivator activity in PAI-2-expressing U937 cells. This site specifically binds FosB in PAI-2-expressing U937 cells but not in HeLa cells that do not express PAI-2, and overexpression of FosB, c-Fos, or c-Jun in HeLa cells is sufficient to cause derepression of transcription from the SERPINB2 promoter. Although FosB is likely to be involved in transactivator-mediated derepression of PAI-2 transcription in macrophage-like cells, as exemplified by the U937 cell line, c-Jun may be functional in other cell types. These data suggest a model for the transcriptional control of the human PAI-2 gene and further our understanding of the molecular basis for its tissue-specific expression.

Transcriptional up-regulation of the plasminogen activator inhibitor type-2 (PAI-2) gene is a major response to cellular stress. The expression of PAI-2 is induced by a variety of cytokines and growth factors that act in a cell type-and differentiation stage-dependent manner. We previously reported that the human SERPINB2 gene promoter is controlled by three major transcription regulatory domains: an inducible proximal promoter, an upstream silencer (PAUSE-1), and a distal transactivator region between ؊5100 and ؊3300, which appears to overcome inhibition mediated by the silencer. The distal transactivator region is inducible by the phorbol ester PMA, a potent activator of the protein kinase C (PKC) pathway that is a powerful inducer of PAI-2 gene expression in monocytes, macrophages, and myelomonocytic cells as well as in epidermal keratinocytes. Here we show that a 21-bp region (؊4952/ ؊4932), containing an AP-1 element, is both necessary and sufficient for PMA-induced transactivator activity in PAI-2-expressing U937 cells. This site specifically binds FosB in PAI-2expressing U937 cells but not in HeLa cells that do not express PAI-2, and overexpression of FosB, c-Fos, or c-Jun in HeLa cells is sufficient to cause derepression of transcription from the SER-PINB2 promoter. Although FosB is likely to be involved in transactivator-mediated derepression of PAI-2 transcription in macrophage-like cells, as exemplified by the U937 cell line, c-Jun may be functional in other cell types. These data suggest a model for the transcriptional control of the human PAI-2 gene and further our understanding of the molecular basis for its tissuespecific expression.
The plasminogen activator inhibitor type 2 (PAI-2, SER-PINB2) 2 gene is transcriptionally repressed in a range of cell types but may be rapidly and robustly induced in response to certain inflammatory or cell stress stimuli. PAI-2 is a member of a large family of structurally related proteins called serine protease inhibitors (serpins), which are recognized to be key regulators of a range of biological processes such as complement activation, fibrinolysis, coagulation, cellular differentiation, tumor suppression, apoptosis, and cell motility (1)(2)(3). PAI-2 was originally characterized as an inhibitor of the urokinase type plasminogen activator (4), and intracellular PAI-2 has been associated with macrophage survival (5), monocyte (6) and keratinocyte (7) differentiation, cytoprotection (8,9), apoptosis (10), signal transduction, and modulation of immune responses (11)(12)(13)(14). Accurate control of PAI-2 gene expression is crucial, because its dysregulation is associated with inflammatory diseases such as asthma, periodontal disease, pre-eclampsia, and cancer (14 -19).
PAI-2 gene expression is tightly regulated, and constitutive expression is highly restricted to certain cell and tissue types, specifically keratinocytes, trophoblasts, macrophages, neurons, and pre-adipocytes (20,21). PMA (phorbol 12-myristate 13-acetate) is a strong inducer of PAI-2 gene expression in many cells, including cells of the monocytic lineages. PMA, a potent tumor promoter, is a naturally derived organic compound whose endogenous analog is diacylglycerol. It is well established that a major cellular receptor for PMA and other phorbol esters is protein kinase C (PKC), a family of at least 11 serine/threonine protein kinase isoenzymes with selective tissue distributions, activators, and substrates (22,23). PMA-induced changes in gene transcription are primarily mediated through the specific binding of AP-1 complexes to the DNA sequence * This work was supported, in whole or in part, by National Institutes of Health Grant R01CA098369. This work was also supported by the National Health and Medical Research Council, Australia. □ S This article contains supplemental Figs. S1 and S2. 1  5Ј-TGA(G/C)TCA-3Ј, which has been termed the AP-1 binding site or PMA responsive element (24,25). AP-1 is a dimeric transcription factor complex composed primarily of members of the Jun and Fos protein families (26 -28). Jun family members (c-Jun, JunB, and JunD) can homo-or heterodimerize with other Jun or Fos family proteins. Fos family proteins (c-Fos, FosB, Fra-1, and Fra-2) are unable to homo-or heterodimerize with other Fos family proteins and are therefore only found as dimers with Jun partners. To define regulatory mechanisms responsible for the limited and cell-type-specific expression of PAI-2, we have characterized transcriptional regulatory promoter elements important for expression of the SERPINB2 gene (29,30). Our previous studies revealed that the SERPINB2 gene promoter was transcriptionally controlled by an inducible proximal promoter, an upstream silencer (PAUSE-1), and a more distal transactivator region. While the proximal promoter was PMA-inducible in U937 cells and constitutively active in HeLa cells, the silencer region repressed transcription in both cell types. The transactivator region was functional only in U937 cells, and hypothesized to derepress transcription in PAI-2-expressing U937 cells, but not in HeLa cells that do not express PAI-2. This transactivator region was located between 3.3 and 5.0 kb upstream of the PAI-2 transcription initiation site. In the present study, we have defined the minimal DNA region responsible for PAI-2 transactivator activity, and we have identified specific members of the activator protein-1 (AP-1) superfamily of proteins that bind to the PAI-2 transactivator region and functionally derepress the SERPINB2 promoter in both PAI-2-expressing and -nonexpressing cells. This mechanism may offer valuable insight into differential PAI-2 gene expression during cell differentiation and in certain cancers.

EXPERIMENTAL PROCEDURES
Cell Culture-Human histiocytic lymphoma U937 cells (European Collection of Cell Cultures no. 85011440) and human cervical carcinoma HeLa cells (ATCC no. CCL-2.2) were maintained in RPMI 1640 media (Invitrogen), supplemented with 2 mM L-glutamine, 10% serum supreme (BioWhittaker), 200 g/ml penicillin, 100 g/ml streptomycin, 25 mM HEPES, and 25 mM sodium bicarbonate, in 5% CO 2 and 95% humidified air atmosphere at 37°C. Bacterial lipopolysaccharide, an activator of U937 cells, was undetectable in cell cultures. Cell viability was determined by trypan blue dye exclusion. All cultures were routinely checked to exclude mycoplasma infection. Cells were stimulated with 40 ng/ml PMA for 18 h, unless otherwise indicated, prior to harvesting. U937 cells expressed a low level of PAI-2 mRNA, which was increased as early as 2 h following treatment with PMA, rising to a maximum at 10 h of more than 30-fold that of constitutive levels (supplemental Fig. S1).
Construction of hPAI-2 Reporter Gene Plasmids-An 8.8-kb genomic fragment containing 5 kb of the SERPINB2 promoter as well as the first exon and first intron of the human SERPINB2 gene has been described (31). The nucleotide sequence of the first 2 kb of the human SERPINB2 promoter (32) (GenBank TM accession number M22469) and the sequence of the most distal 1.6 kb of this genomic fragment (31) (GenBank TM accession number L19065) have been reported. We report the sequence of the interim 1.4 kb, which has been deposited in GenBank TM with accession number AF071400. With the available complete sequence of the human PAI-2 promoter region, chloramphenicol acetyltransferase (CAT) reporter plasmids described previously (29,31) were renamed to reflect the position of the deletions in the deletion constructs described previously. These included pCAT-4952 (pNatCAT), pCAT-3306 (pCAT5Ј-3.3), and pCAT-1977 (pCAT5Ј-1.9), which contain the human SER-PINB2 gene 5Ј-flanking sequence from Ϫ4952, Ϫ3306, and Ϫ1977 nucleotides, respectively, to the 3Ј-end of the first intron (ϩ3729).
pCAT-1977ϩ330 and pCAT-1977ϩ330R contain the 330-bp transactivator region Ϫ4952/Ϫ4623 cloned into the HindIII site immediately upstream of nucleotide Ϫ1977 of pCAT-1977 in the wild-type and reverse orientation, respectively. The Ϫ4952/Ϫ4623 region was cloned from pCAT-4952 by a PCR approach using the sense primer BS5ЈCAT (5Ј-ACC-GGGAAGCTTGAATTCATGACTCACAGTGTT-3Ј) and the antisense primer BShPt6 (5Ј-AAGCATAAGCTTAGGCCAC-CGGGAGG-3Ј). Both primers contain a HindIII restriction site (underlined) that enable digestion of the PCR product with HindIII and subsequent cloning into the HindIII site of pCAT-1977.
CAT Reporter Gene Assays-Cells (1 ϫ 10 7 HeLa and 3 ϫ 10 7 U937) were transfected with 20 g of plasmid reporter DNA in a total volume of 250 l by electroporation (0.25 kV and 960 microfarads). For co-transfection experiments, 20 g of reporter plasmid and 5 g of expression plasmid were used. Transfected cells were transferred to 10 ml of media and incubated 16 -18 h prior to harvesting. CAT assays were performed using 50 g of whole cell lysate essentially as described previously (29). Acetylation of [ 14 C]chloramphenicol was detected using a PhosphorImager (Molecular Dynamics), and signals were quantitated using ImageQuant version 4.2a (Molecular Dynamics). CAT activity was expressed as the percentage conversion of [ 14 C]chloramphenicol per microgram of whole cell lysate and normalized to the value of the positive control plasmid, pCAT-Control (Promega), to allow comparison of the results of independent experiments. Protein concentration was determined by using the Bradford assay (Bio-Rad).
Northern Blot Analysis-Total RNA for Northern analysis and RT-PCR was prepared using TRIzol reagent (Invitrogen). Gel electrophoresis was performed using denaturing 1.2% agarose gels, and RNA transfer was to Hybond N membranes (Amersham Biosciences). cDNA probes were radiolabeled with [␥-32 P]dCTP (Amersham Biosciences) using a Megaprime DNA labeling system (Amersham Biosciences). Membranes were hybridized in the presence of probe at 65°C and washed to a final stringency of 0.5ϫ SSC/0.1% SDS at 65°C before exposure to Kodak XK-1 film.
RT-PCR-RT-PCR was performed using Superscript TM II reverse transcriptase (Invitrogen) for first strand cDNA synthesis followed by PCR amplification with AmpliTaq TM DNA polymerase. For first strand cDNA synthesis, 5 g of total RNA and 500 ng of oligo(dT) (Invitrogen), in a volume of 12 l, were first incubated together at 70°C for 10 min then chilled on ice. Quantitative PCR-RNeasy Mini Kit (Qiagen) was used to isolate total RNA from PMA-treated HeLa cells that were transiently transfected with Jun and Fos family pCMV expression plasmids (Lipofectamine, Invitrogen). For first-strand cDNA synthesis, 1 g of total RNA was used as a template with random primers and TaqMan® reverse transcription reagents (Applied Biosystems). For quantitative PCR, inventoried Taq-Man® Gene Expression 20ϫ primers for SERPINB2 and ␤-actin were used, and the assay was performed according to the manufacturer's instructions (Applied Biosystems).

PAI-2 Transactivator Activity Localizes to the Ϫ4952/Ϫ4623
(330 bp) Region of the Human PAI-2 Promoter-The constitutive and PMA-inducible transactivator activity of the SER-PINB2 promoter is present within a 1.6-kb region (Ϫ3306 to Ϫ4952) upstream of the PAI-2 transcription initiation site (29). To localize this transactivator activity, a series of CAT reporter plasmids was constructed from pCAT-4952 with progressively greater 5Ј-deletions to Ϫ3306 (Fig. 1A). U937 cells were transiently transfected with these reporter plasmids, and CAT activity was measured in the presence or absence of 40 ng/ml PMA. As shown in Fig. 1B, constitutive and PMA-inducible CAT activity was abolished upon deletion of the PAI-2 promoter to position Ϫ4622 in U937 cells. Furthermore, deletion beyond nucleotide Ϫ4622 resulted in neither additional loss nor significant restoration of PAI-2 promoter-directed CAT activity. In contrast, no significant constitutive nor PMA-inducible PAI-2 promoter-directed CAT activity was seen with any of the CAT reporter constructs in HeLa cells (Fig. 1B). Together these results demonstrate that the cell-type-specific activity of the human PAI-2 transactivator is located within a 330-bp region between nucleotides Ϫ4952 and Ϫ4623 of the human PAI-2 promoter.
The 330-bp Region (Ϫ4952/Ϫ4623) of the Human PAI-2 Promoter Is Sufficient for PAI-2 Transactivator Activity-To investigate whether the 330-bp region (Ϫ4952 to Ϫ4623) of the human SERPINB2 transactivator contained the one or more necessary cis-elements for mediating PAI-2 transactivator activity, this region was inserted immediately upstream of nucleotide Ϫ1977 in pCAT-1977 in both the wild-type and reverse orientations, denoted as pCAT-1977ϩ330 and pCAT-1977ϩ330R, respectively (Fig. 1A). pCAT-1977 contains the PAUSE-1 silencer element, which effectively silences transcription from the SERPINB2 promoter in both U937 and HeLa cells (29,30). Transient transfection experiments in U937 cells demonstrated that the 330-bp transactivator region, when positioned immediately upstream of nucleotide Ϫ1977 in the wildtype orientation, effectively reproduced the transactivator activity detected with pCAT-4952 (Fig. 1C), thereby derepressing silencer activity in pCAT-1977. In contrast, inversion of the 330-bp transactivator was found to greatly reduce transactiva-

PAI-2 Gene Regulation
tor activity (Fig. 1C). Taken together, these results indicated that the 330-bp region of the human SERPINB2 promoter (Ϫ4952/Ϫ4623) contains the necessary cis-element(s) required for transactivator function and that this activity is orientationdependent. Moreover, the data further indicate that the activity of the 330-bp region can occur independently of nucleotides Ϫ4622 to Ϫ1978.
PAI-2 Transactivator Function Is Dependent on an AP-1 Site at Ϫ4945/Ϫ4939-Analysis of the nucleotide sequence of the 330-bp transactivator region revealed several potential candidates for mediating transactivator function (Fig. 2A). These include an AP-1 site, an AP-2 site, and an NF-B motif, each of which are recognized binding sites for transcription factors transducing PMA-induced cell signaling (24,36,37). To investigate whether these cis-elements may play a role in transactivator function, each element was mutated in pCAT-4952 by single nucleotide substitution to disrupt transcription factorbinding activity, generating pCAT-4952mAP-1, pCAT-4952mAP-2, and pCAT-4952mNF-B (Fig. 2B). Transient transfection of U937 cells shows that, although mutation of either the AP-2 or NF-B site had no effect on PMA-inducible PAI-2 transactivator function, mutation of the AP-1 site at Ϫ4945/Ϫ4939 reduced pCAT-4952-directed CAT activity to the level observed for pCAT-4622 (Fig. 2C). This result demonstrates that PAI-2 transactivator function is dependent on an intact AP-1 site at Ϫ4945/Ϫ4939 and is possibly mediated by one or more members of the AP-1 transcription factor family.
A 21-bp Region (Ϫ4952/Ϫ4932) Containing the Consensus AP-1 Site, Is Sufficient for Transactivator Function-To determine whether the AP-1 site was sufficient for transactivator function, a 21-bp region (Ϫ4952/Ϫ4932), containing the consensus AP-1 site, was inserted immediately upstream of pCAT-1977 in the wild-type orientation (pCAT-1977ϩAP-1) (Fig.  2D). Reporter gene analysis shows that the AP-1 site effectively derepressed silencing of pCAT-1977 in U937 cells, comparable with the transactivator activity detected using pCAT-4952 (Fig.  2E). These data demonstrate that the AP-1 site in the 21-bp region between Ϫ4952 and Ϫ4932 is sufficient to reproduce PAI-2 transactivator activity.

The 21-bp Transactivator Region (Ϫ4952/Ϫ4932) Is Bound by Nuclear Factors in Both U937 and HeLa
Cells-To investigate nuclear protein binding to the 21-bp AP-1 site (Ϫ4952/ Ϫ4932), EMSAs were performed with nuclear extracts from both untreated and PMA-treated U937 and HeLa cells (Fig. 3). A single DNA-protein complex was detected with the 21-bp (Ϫ4952/Ϫ4932) transactivator probe, the mobility of which was shifted relative to that of the unbound or free probe. Although the intensity of this complex was approximately the same with both untreated and PMA-treated HeLa nuclear extracts, it was consistently observed to increase with PMA treatment with U937 nuclear extracts. The specificity of this interaction was investigated using a 100-fold molar excess of unlabeled competitor oligonucleotides (Fig. 3). Although the unlabeled wild-type 21-bp double-stranded oligonucleotide (Ϫ4952/Ϫ4932) successfully competed for nuclear extract binding to the radiolabeled 21-bp probe, neither a mutated AP-1 oligonucleotide nor a control oligonucleotide containing a GAS element (nonspecific oligonucleotide) competed for binding. These data confirmed that nuclear proteins from both U937 and HeLa cells specifically bound to the human SER-PINB2 promoter Ϫ4952/Ϫ4932 region in vitro and, furthermore, that a consensus AP-1 cis-element is required for binding of these nuclear proteins. These data indicate that human PAI-2 transactivator function might involve one or more members of the AP-1 transcription factor family.
The Human PAI-2 Transactivator Binds Multiple Jun and Fos Family Proteins-To identify the specific transcription factors involved in the 21-bp (Ϫ4952/Ϫ4932) transactivator binding complex, EMSA supershift assays were performed using antibodies specific for each Jun and Fos family member. As shown in Fig. 4, both U937 and HeLa nuclear extracts contained multiple Jun and Fos family proteins, which bound the 21-bp (Ϫ4952/Ϫ4932) double-stranded oligonucleotide in vitro. JunB, JunD, c-Fos, Fra-1, and Fra-2, present in nuclear extracts from both U937 and HeLa cells, each bound the 21-bp transactivator probe prior to treatment of the cells with PMA, with increased binding observed for JunB, c-Fos, and Fra-1 following PMA treatment. In contrast, neither U937 nor HeLa nuclear extracts showed detectable c-Jun-binding activity before or after treatment with PMA. Significantly, PMA-inducible binding of the 21-bp transactivator probe by FosB was detected in U937 nuclear extracts but was absent in HeLa nuclear extracts. Immunoblot analysis showed that U937 and HeLa cells both expressed constitutive c-Jun and FosB (data not shown). The absence of c-Jun in the EMSA supershift assays was somewhat surprising, given that c-Jun previously has been shown to be induced in both U937 and HeLa cells by PMA treatment (38,39) and has been shown to bind a doublestranded oligonucleotide containing an AP-1 site by EMSA supershift assay (40). Because induction of c-Jun may be a transient event (41), EMSA supershift assays were performed using nuclear extracts prepared at various times following PMA treatment of both U937 and HeLa cells. Although recombinant c-Jun was demonstrated to be capable of binding to the 21-bp transactivator probe, no c-Jun bound with nuclear extracts prepared from either U937 or HeLa cells treated for up to 4 h with PMA (supplemental Fig. S2).
These data demonstrate that the 21-bp region of the SER-PINB2 transactivator binds multiple Jun and Fos family members present in both U937 and HeLa cells. Although most of the bound Jun and Fos family-binding proteins are common to both PAI-2-expressing U937 cells and PAI-2-non-expressing HeLa cells, FosB bound the transactivator only in U937 cells and not HeLa cells.

Transient Transfection of HeLa Cells with FosB or c-Jun Derepresses Transcriptional Silencing of the Human PAI-2 Promoter-
To investigate whether the absence of detectable nuclear FosB or c-Jun binding to the 21-bp transactivator region reflected a functional consequence for human PAI-2 promoter activity in HeLa cells, HeLa cells were transiently co-transfected with expression vectors for FosB and c-Jun, as well as each of the other Jun and Fos MARCH 23, 2012 • VOLUME 287 • NUMBER 13 family members, together with the CAT reporter vector pCAT-4952. As shown in Fig. 5A, transient overexpression of JunB, JunD, c-Fos, Fra-1, or Fra-2 had no effect on PAI-2 promoter-directed CAT activity. However, transient overexpression of FosB or c-Jun increased PAI-2 promoter-directed CAT activity ϳ10-fold and 35-fold, respectively, in HeLa cells. Mutation of the transactivator AP-1 site resulted in a 6-and 2-fold decrease in CAT activity following transient overexpression of c-Jun and FosB, respectively (Fig. 5B), indicating that the increase in CAT activity is dependent on a functional AP-1 site. Transient overexpression of both FosB and c-Jun together, however, had an antagonistic effect on promoter activity when compared with overexpression of either factor alone, with PAI-2 promoter-directed CAT activity increasing only slightly more than 2-fold with this combination (Fig. 1A). Thus overexpression of either FosB or c-Jun, two AP-1 constituent factors that did not bind to the 21-bp SERPINB2 transactivator region in either untreated or PMA-treated HeLa cells by EMSA supershift assay, resulted in a functional derepression of the nor- . The ؊4952/؊4932 AP-1 region is a site for nuclear binding factors from both U937 and HeLa cells. EMSA analysis of nuclear extracts prepared from U937 or HeLa cells cultured in the presence or absence of PMA for 4 h. A 21-bp 32 P-labeled double-stranded Ϫ4952/Ϫ4932 oligonucleotide was used as a probe. Cold competition reactions were performed using a 100-fold molar excess of the following unlabeled specific double-stranded oligonucleotides: AP-1, the Ϫ4952/Ϫ4932 region containing the distal AP-1 consensus sequence; mAP-1, the Ϫ4952/Ϫ4932 region containing a mutant AP-1 site; and GAS, a GAS region containing an unrelated oligonucleotide from the Ϫ4870/Ϫ4852 region of the human PAI-2 promoter.  (Fig. 6). These data provide evidence that overexpression of FosB or c-Jun may be sufficient to cause derepression and transactivation of the endogenously silenced SERPINB2 gene, although clearly additional factors are required for full induction of PAI-2 gene expression.

DISCUSSION
Transcriptional derepression is an important mechanism for the accurate control of gene expression. Here we have shown that a distal AP-1 site is both necessary and sufficient for transactivator function in both PAI-2-expressing and -non-expressing cells. Our studies indicated that the AP-1 site mediated PAI-2 promoter activity in a location-independent and orientation-dependent manner. Supershift assays revealed that the The SERPINB2 promoter contains several AP-1 or AP-1-like consensus sequences, however, their presence does not automatically imply functionality in a given gene promoter. The SERPINB2 promoter contains a consensus AP-1 site between nucleotides Ϫ1568 and Ϫ1562, yet this site has not been implicated in either constitutive or PMA-stimulated PAI-2 gene expression (29). In contrast, two AP-1-like sites in the proximal SERPINB2 promoter have been found to contribute to both constitutive and PMA-stimulated transcription of PAI-2 (42). Because various Jun and Fos family members differ in their transactivation potential (26), differences in promoter-bound AP-1 complexes may be involved in cell-type-specific differences in gene transcription. The data presented here suggest that this is the case for the PAI-2 transactivator AP-1 site and its differential action in derepressing transcription from the SER-PINB2 promoter in U937 and HeLa cells. FosB, presumably exerting its effect on the PAI-2 transactivator AP-1 site as a JunB-FosB or JunD-FosB dimer, appears to be the mechanism by which U937 cells derepress transcriptional silencing of the SERPINB2 promoter. Alternatively, c-Jun may possibly be the most important Jun family member mediating derepression of the SERPINB2 gene in HeLa cells.
The identification of FosB as the mediator of PAI-2 transactivator function explains the orientation dependence observed for PAI-2 transactivator activity (Fig. 1A). Because FosB must form a heterodimer with a Jun partner to bind DNA, and Jun-Fos heterodimers bind DNA in a preferred orientation (43,44), Jun-FosB binding to the transactivator AP-1 site is likely to be unidirectional. Reversing the transactivator sequence will reverse the orientation of the bound Jun-FosB AP-1 factor, an action that is likely to impair its ability to interact with other DNA-bound factors in the SERPINB2 promoter and thus its activity.
The observation that c-Jun was a strong transactivator of PAI-2 promoter reporter gene expression in HeLa cells, but not in U937 cells, was a surprising finding. However its explanation may lie with the AP-1 dimer preference of the transactivator AP-1 site, the presence of detectable FosB binding in U937 cells but not HeLa cells, and the probability of successful competition for binding to the transactivator AP-1 site by c-Jun in HeLa cells versus U937 cells. Thus, although recombinant c-Jun bound to the transactivator AP-1 site in the absence of nuclear extracts, the absence of c-Jun in transactivator AP-1 complexes formed with both HeLa and U937 nuclear extracts may indicate that this site has greater affinity for AP-1 complexes that do not contain c-Jun. Furthermore, the presence of detectable FosB in transactivator AP-1 complexes formed with U937 nuclear extracts suggests that this factor binds readily as a JunB-FosB or JunD-FosB heterodimer rather than as a c-Jun-FosB heterodimer, an observation made previously with the Bal-17 B cell line (45). Thus given the possible preference of the PAI-2 transactivator AP-1 site for AP-1 complexes not containing c-Jun and the added competition for binding to this site by FosB in U937 cells and not HeLa cells, transient transfection with c-Jun may produce sufficient c-Jun to successfully compete for transactivator AP-1 site binding in HeLa cells. This hypothesis is supported by our evidence showing that transient overexpression of c-Jun in HeLa cells induces the highest endogenous PAI-2 mRNA expression, when compared with overexpression of any other Jun or Fos family member.
The observation that both FosB and c-Jun can derepress transcription from the SERPINB2 promoter may have general significance for PAI-2-expressing cells. Although the expression pattern of Jun and Fos family proteins in the placenta is yet to be suitably examined, an immunostaining analysis of human skin (46) suggests that it might. In this study, FosB was demonstrated to be expressed in both the basal and spinous layers of the epidermis and disappeared in the granular layer. Although staining was localized to both the nuclei and cytoplasm in the basal layer, the intensity of nuclear staining increased in cells of the spinous layers, suggesting nuclear translocation of FosB in these cells. In contrast immunostaining for c-Jun showed that it occurred in a sharply defined band confined to the granular layer of the epidermis in both a nuclear and cytoplasmic distribution. In comparison, PAI-2 expression in the epidermis is low in the basal keratinocyte layer, increases through the spinous layers, and is highest in the granular layers before the transition to cornified dead squames (47). With this non-overlapping and possibly complementary pattern of FosB and c-Jun expression, it is tempting to speculate that the coordinate expression of these two factors in turn may be responsible for the observed expression of PAI-2 in the epidermis. Although expression of FosB by keratinocytes of the basal and spinous layers of the epidermis may result in low to moderate levels of PAI-2 expression in these cell layers, the switch to c-Jun expression by keratinocytes of the granular layers may lead to increased PAI-2 expression in this layer.
With the large body of evidence implicating alterations in PAI-2 expression to a host of inflammatory diseases, it is important that the precise mechanisms for its expression, repression, and derepression be elucidated. With respect to cancer in particular, PAI-2 has been implicated as both a positive and negative prognostic indicator of tumor progression by microarray analysis as well as several in vivo studies (19,21). Clinically, tumor-associated PAI-2 expression is associated with favorable patient prognosis in several cancers, namely breast, ovarian, squamous cell carcinoma, and pancreatic cancer (19,48,49). On the other hand, PAI-2 expression is associated with poor prognosis in endometrial and colorectal cancers (50,51). Our present findings make an important contribution to an evolving model for the transcriptional control of the human PAI-2 gene and toward understanding the molecular basis for its tissue specific expression.