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Platelet-Activating Factor Overturns the Transcriptional Repressor Disposition of Sp1 in the Expression of MMP-9 in Human Corneal Epithelial Cells

¹From the Departments of Biochemistry and Molecular Biology and ²Ophthalmology, Neuroscience Center of Excellence, Louisiana State University Health Sciences Center, New Orleans, Louisiana.

	Abstract

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PURPOSE. Matrix metalloproteinase (MMP)-9 is induced in corneal epithelial cells stimulated with platelet-activating factor (PAF), and interferes with the normal reepithelialization of wounded cornea. Here the transcriptional regulation of MMP-9 gene expression by PAF was investigated in human corneal epithelial cells (HCECs).

METHODS. DNA-binding activity of NFB, Sp1, and AP-1 was determined in quiescent and PAF-stimulated HCECs by electrophoretic mobility shift assay (EMSA). A series of 5' deleted human MMP-9 promoter-luciferase reporter constructs was transiently transfected into HCECs, and luciferase activity was examined after stimulation with PAF. Mutagenesis and specific deletions of some elements in the MMP-9 promoter were also introduced and analyzed. Phosphorylation of Sp1 and MEK/ERK pathway proteins was examined by Western blot analysis. Activation of Sp1 and MMP-9 was also determined by ELISA and zymography, respectively, in the absence or presence of the MEK inhibitor PD98059.

RESULTS. DNA-binding activity of NFB, Sp1, and AP-1 was upregulated by PAF with a peak at 1 hour after stimulation. A region spanning –670 to –460 relative to the transcription start point was required for the induction of the MMP-9 promoter by PAF. Mutation of the –79AP-1 or –600NFB motif reduced the activity of MMP-9 promoter and the induction of gene expression by PAF. In untreated HCECs, mutation of the –558Sp1 motif upregulated gene expression, but it caused a significant decrease in the promoter activity induced by PAF. Inhibition of MEK activity eliminated the PAF-induced phosphorylation and activation of Sp1 and abolished the upregulation of MMP-9 expression and activity.

CONCLUSIONS. These findings demonstrate that collaboration between several regulatory elements is required for the induction of MMP-9 promoter activity by PAF and that PAF overturns the repressor effect of Sp1 through activation of the MEK/ERK signaling cascade.

Matrix metalloproteinases (MMPs) constitute a family of zinc-dependent endopeptidases that are involved in proteolytic degradation of extracellular matrix (ECM) components² as part of physiological or pathologic processes.^{3 4 5 6} According to their structures and substrate specificities, MMPs can be classified in four categories: collagenases (MMP-1, -8, -13); gelatinases (MMP-2, -9); stromelysins (MMP-3, -7, -10, -11, -12); and membrane-type (MT) MMPs (MT1-MMP to MT6-MMP).^{5 7} MMP-9 (also known as the 92-kDa type IV collagenase) catalyzes the cleavage of denatured collagens of all types and of native basement membrane components.^{5 8} In the cornea, MMP-9 plays a major role in cell migration⁹ because of its ability to facilitate the destruction of type IV collagen-containing basement membrane,¹⁰ which separates the epithelial and stromal layers. MMP-9 is expressed in epithelial cells migrating to resurface the wound bed after an injury^{10 11} and in the inflammatory cells infiltrating the wound.^{12 13} Overexpression of MMP-9, on the other hand, is linked to imperfect reepithelialization and impaired adhesion complex integrity.^{10 14} Overall, the architectural integrity of many tissues depends on a delicate balance between MMPs and their inhibitors. Hence, the regulation of gene transcription and tissue-specific expression of MMP-9 in normal and diseased states are being widely investigated in a search for new therapeutic targets.

Platelet-activating factor (PAF) is a potent lipid mediator of inflammatory reactions that is also implicated in cellular activation, intracellular signaling, and apoptosis.^{15 16 17 18 19 20} Reports from our laboratory show that during sustained corneal inflammation, PAF accumulates in the cornea and contributes to tissue destruction and corneal ulcer formation.^{19 20} PAF selectively upregulates gene and protein expression of MMP-1 and MMP-9 in corneal epithelial cells^{21 22} and gene expression of two members of the tissue inhibitors of metalloproteinases (TIMPs), TIMP-1 and TIMP-2, with a significant imbalance toward the elevation of MMP-9 gene expression.²³

The molecular mechanisms responsible for the activation of MMP-9 promoter by PAF in corneal epithelial cells are unknown. The present study was, therefore, carried out to identify the regulatory elements in the MMP-9 promoter, the transcription factors involved, and the role of the MEK/ERK signaling pathway in PAF-induced expression and activity of MMP-9 in human corneal epithelial cells (HCECs). We identified a PAF-responding segment (PRS) spanning 670 to 460 base pairs upstream of the transcription start point of the MMP-9 gene that plays the most important role in the regulation of gene expression by PAF in HCECs. Although the transcription factors NFB and AP-1 are partially responsible for the basal and the PAF-induced activation of MMP-9 promoter, Sp1 has a divergent function with a negative regulatory effect on MMP-9 gene expression in quiescent HCECs and an enhancing role in PAF-stimulated cells. Moreover, PAF stimulates the phosphorylation of MEK1/2 and ERK1/2 and of Sp1 in HCECs, and blocking the MEK/ERK cascade resulted in the elimination of PAF-induced MMP-9 expression and activity.

	Materials and Methods

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Cell Culture
The HCEC line was kindly provided by Roger Beuerman (Department of Ophthalmology, Louisiana State University Health Sciences Center [LSUHSC], New Orleans, LA). Keratinocyte basal medium (KBM) and keratinocyte growth medium (KGM [KBM supplemented with bovine pituitary extract, recombinant human epidermal growth factor, bovine insulin, hydrocortisone, and gentamicin sulfate/amphotericin-B]) were purchased from Cambrex Bioscience Walkersville, Inc. (Walkersville, MD). HCECs were grown in KGM and subcultured twice a week. KGM was replaced with KBM for an overnight growth factor starvation of HCECs before stimulation with 100 nM methyl-carbamyl-PAF (mcPAF [1-O-alkyl-2n-methylcarbamyl-sn-glyceryl-3-phosphoryl-choline]), a nonhydrolyzable PAF analog (Cayman Chemical Co., Ann Arbor, MI), for the times specified in the experiments. LysoPAF (1-O-alkyl-sn-glycero-3-phosphocholine; Sigma, St. Louis, MO) was used as a negative control, and phorbol-12-myristate-13-acetate (PMA; Calbiochem, La Jolla, CA) was used as a positive control. In inhibition studies, HCECs were preincubated for 1 hour with KBM containing 10 µM PAF receptor antagonist LAU8080 (tetrahedral-4,7,8,10 methyl-1 (chloro-2-phenyl)6-(methoxy-4 phenyl)carbamyl-9 pyrido (4' 3'-4,5) theine (3,2,-f) triazolo-1,2,4(4,3-a) diazopine-1,4); provided by Nicolas G. Bazan, Neuroscience Center of Excellence, LSUHSC) before stimulation with mcPAF. In the MEK inhibition experiments, cells were left untreated or were preincubated for 30 minutes with 20, 30, or 40 µM PD98059 (Calbiochem) before stimulation with PAF.

Plasmid Construction
The construct containing the regulatory sequence of the human MMP-9 gene from position –2172 to +54 relative to the transcription start point cloned upstream of the luciferase reporter gene of pGL3-Basic vector (–2172/+54Luc) was kindly provided by Douglas D. Boyd (Department of Cancer Biology, MD Anderson Cancer Center, University of Texas, Houston, TX) and was used in this study with permission from Motoharu Seiki (Department of Cancer Cell Research, Institute of Medical Science, University of Tokyo, Tokyo, Japan). The constructs containing 5' deletions of MMP-9 promoter sequence and an empty vector were produced by truncating the full-length plasmid using combinations of KpnI and SmaI, PstI, XbaI, EcoRV, BamHI, PvuII, or HindIII restriction enzymes (Promega, Madison, WI). Truncation of the –670/–460 segment from the two constructs –1511/+54Luc and –1112/+54Luc was performed using a combination of XbaI and EcoRV restriction enzymes. Herpes simplex virus thymidine kinase promoter sequence (HSV-TK) was cloned into pGL3-Basic vector (Promega) to prepare a pGL3-TK construct, which was then used to clone the two major regulatory segments from MMP-9 promoter sequence—that is, basal expression segment (BES; –1112/–670) and PRS (–670/–460)—upstream of the HSV-TK promoter to prepare the BES-TK and PRS-TK constructs. Site-specific mutated constructs with point mutations at –600/–591NFB (GGAATTCCC to TTAATTCCC; mutNFB), –558/–563Sp1 (GGGCGG to GGGTTG; mutSp1), or –79/–73AP-1 (TGAGTCA to TTTGTCA; mutAP-1) consensus sequences of a plasmid containing the –670/+53 regulatory sequence of the MMP-9 gene cloned in pGL2-Basic vector were kindly provided by Derek A. Mann (Molecular Cell Biology, Division of Infection, Inflammation and Repair, University of Southampton School of Medicine, Southampton General Hospital, Southampton, UK). Luciferase reporter vectors containing the cis-acting DNA-binding element for NFB, Sp1, and AP-1 (NFB-Luc, Sp1-Luc, and AP-1-Luc, respectively) were purchased (Panomics Inc., Fremont, CA).

Transient Transfection Assays
HCECs were cultured in 96-well plates (ViewPlate-96; Packard, Meriden, CT) to reach 50% to 60% confluence and were cotransfected with a transfection reagent (FuGene 6; Roche, Palo Alto, CA) at a ratio of 1 µg plasmid DNA, 50 ng pRL-TK (kindly provided by Jay D. Hunt, Department of Biochemistry and Molecular Biology, LSUHSC), and 2.5 µL FuGene 6/mL KBM at 37°C overnight. Activities of the two luciferases were then measured (Dual Glo Luciferase Assay System [Promega]; TopCount Liquid Scintillation Counter [Packard]). Data were normalized to the activity of Renilla luciferase before statistical analyses were performed for comparison of various conditions.

Electrophoretic Mobility Shift Assay
HCECs at 80% confluence were left untreated or were stimulated with 100 nM mcPAF for 0.5, 1, or 2 hours. Crude nuclear extracts were prepared (NE-PER kit; Pierce Biotechnology, Rockford, IL). Consensus oligonucleotides for NFB, Sp1, and AP-1 were obtained (Promega) and biotinylated (Biotin 3' End DNA Labeling Kit; Pierce). Binding reactions were performed for 20 minutes at room temperature with 5 µg protein in a mixture containing 2 µL buffer (Gel Shift Binding 5x Buffer; Promega), 1 µL biotinylated consensus oligonucleotide (20 fmol/µL), and nuclease-free water (Promega) up to a total volume of 9 µL. To confirm the specificity of the shifted bands, 1 µL unlabeled consensus oligonucleotide (1.75 pmol/µL) was also included in the mixture in competition tubes. DNA-protein complexes were separated from unbound oligonucleotide by electrophoresis through polyacrylamide gels for nucleic acid analysis (6% DNA Retardation Gels; Invitrogen, Carlsbad, CA), transferred to membranes (Nytran SuperCharge; Whatman-Schleicher & Schuell, Florham Park, NJ), and ultraviolet (UV) light cross-linked (GS Gene Linker UV Chamber; Bio-Rad Laboratories, Hercules, CA) before detection of shifted bands (BrightStar BioDetect Nonisotopic Detection System; Ambion, Austin, TX) and autoradiography (Chemiluminescence BioMax films; Eastman Kodak, Rochester, NY).

DNA-Binding Activity of Sp1
HCECs at 80% confluence were left untreated or were stimulated with 100 nM mcPAF for 1 hour, and nuclear extracts were prepared (Nuclear Extract Kit; Active Motif, Carlsbad, CA), to be tested for the DNA-binding activity of Sp1 (TransAm Sp1/Sp3 Activation Assay kit; Active Motif).

Western Blot Analysis
HCECs were cultured in six-well microplates (Corning, Corning, NY) to 80% to 90% and were stimulated as specified in each experiment. Cells from each well were extracted into 100 µL lysis buffer (20 mM Tris, pH 7.5; 150 mM NaCl; 10 mM EDTA; 200 µM Na₃VO₄; 10 mM NaF; 1 mM phenylmethylsulfonyl fluoride; 5 µg/mL leupeptin; 10 µg/mL aprotinin; 10% glycerol; 1% NP-40) for 8 minutes on ice and centrifuged at 21,000g for 5 minutes at 4°C. Supernatants were collected, protein concentration was determined (Bradford Protein Assay Reagent; Bio-Rad), and 10 µg protein from each sample was denatured by heating at 95°C for 7 minutes in a total volume of 25 µL, including 5 µL gel-loading buffer (62 mM Tris, pH 6.8; 6% SDS; 15% ß-mercaptoethanol; 40% glycerol; 0.025% bromophenol blue). Proteins were separated on a (8% to 16% Tris-Glycine Gel; Novex, San Diego, CA) and were transferred to a PVDF membrane (Invitrolon; Invitrogen). After incubation with blocking buffer (Odyssey; LI-COR Biosciences, Lincoln, NE), membranes were probed for 1 hour at room temperature with primary antibodies. Either polyclonal rabbit anti-Sp1 (Santa Cruz Biotechnology, Santa Cruz, CA) or monoclonal mouse anti-Sp1 (BD Biosciences PharMingen, San Diego, CA) and polyclonal rabbit anti-actin (Sigma) were used for detection of Sp1. MEK/ERK pathway proteins were detected by using anti-ERK1 (Santa Cruz), which detects ERK1 and ERK2 proteins (ERK1/2), monoclonal mouse anti-phosphorylated ERK1/2 (pERK1/2; Sigma), and rabbit anti-phosphorylated MEK1/2 (pMEK1/2; Cell Signaling, Danvers, MA). Membranes were then washed for 30 minutes with three changes of PBS–0.05% Tween 20 solution, followed by 20 minutes of incubation at room temperature with green (goat anti-rabbit; IRDye 800 [LI-COR Biosciences]) and red (Alexa Fluor 680-conjugated rabbit anti-mouse IgG; [Invitrogen]) secondary antibodies. After another washing step, as already described, specific bands were visualized by scanning (Odyssey Infrared Imaging System; LI-COR Biosciences) using both 800-nm and 700-nm channels.

Immunoprecipitation
Whole cell extract (200 µg) was mixed with anti-Sp1 antibody (4 µg; Santa Cruz Biotechnology) for 2 hours followed by overnight incubation with 25 µL protein A/G PLUS-agarose at 4°C. Beads were pelleted at 1000g for 5 minutes at 4°C and were washed 3 times with lysis buffer before denaturation of proteins and immunoblotting of supernatants, as described in Western Blot Analysis, using polyclonal rabbit anti-Sp1 (Santa Cruz) and either anti-phosphoserine or anti-phosphothreonine mouse monoclonal antibody (Sigma).

Zymography
HCECs were cultured to 70% to 80% confluence and were stimulated as described in each experiment. Conditioned media were collected and centrifuged to remove debris and dead cells, and 10 µL of each supernatant was mixed with an equal volume of zymogram sample buffer (Bio-Rad) and separated (10% Zymogram (Gelatin) Gel; Invitrogen) for 2 hours. The gel was then incubated for 2 hours in renaturing buffer (Zymogram; Invitrogen) and overnight in developing buffer (Zymogram; Invitrogen) before it was stained with 1% Coomassie brilliant blue (Sigma) in distilled water/methanol/acetic acid (4.5:4.5:1) for 30 minutes and washed with distilled water. Gels were examined (Odyssey Infrared Imaging System; LI-COR) using the 700-nm channel.

Statistical Analysis
Comparison between various conditions was tested by analysis of variance (ANOVA); P < 0.05 was considered statistically significant. All experiments were performed at least three times.

	Results

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Activation of NFB, Sp1, and AP-1 in HCECs Stimulated with PAF
MMP-9 is encoded by a 7.7-kb pair gene with 13 exons, the transcription of which yields a 2.5-kb mRNA^{24 25} and is regulated primarily by 670 bp of regulatory sequence, which includes the binding sites for NFB, AP-1, and Sp1.²⁵ We investigated the effect of PAF on the level of DNA-binding activity of these transcription factors in HCECs. After treatment of the cells with mcPAF for 0.5, 1, or 2 hours, nuclear extracts were collected, and the DNA-binding activity of the transcription factors NFB, Sp1, and AP-1 was determined by electrophoretic mobility shift assay (EMSA). Nuclear extract from untreated cells was used as a control for the basal level of transcription factor activities. PAF induced an upregulation of NFB, Sp1, and AP-1 DNA-binding activity, with a peak at 1 hour after stimulation (Fig. 1A) . To confirm the specificity of the shifted bands, EMSA was performed in the presence of unlabeled oligonucleotides that competed out the shifted bands for each transcription factor (Fig. 1B) .

View larger version (86K): [in this window] [in a new window]   FIGURE 1. DNA-binding activity of NFB, Sp1, and AP-1 in HCECs stimulated with PAF. (A) After overnight growth factor starvation, cultures of HCECs were left untreated (lane 1) or were stimulated with 100 nM mcPAF for 0.5, 1, or 2 hours (lanes 2–4, respectively), and the nuclear extracts were subjected to EMSA. (B) EMSA was carried out with the use of biotinylated oligonucleotide (B/O) in the absence (–) or presence (+) of unlabeled oligonucleotide (U/O) to compete out the specific shifted bands (arrows) in nuclear extracts of HCECs stimulated for 1 hour with 100 nM mcPAF.

View larger version (18K): [in this window] [in a new window]   FIGURE 2. Human MMP-9 promoter activity in HCECs stimulated by PAF. (A) Cultures of HCECs were cotransfected with pRL-TK and one of the various 5'-deleted MMP-9 promoter constructs containing firefly luciferase as the reporter gene. Transiently transfected cells were left untreated or were stimulated with 100 nM mcPAF overnight, and promoter activity was tested. Significant differences (P < 0.05) between PAF-stimulated and untreated conditions. Significant differences (P < 0.05) between the empty vector and any of the other constructs in untreated conditions. Values are the averages (±SEM) of 5 independent experiments. (B) Key segments in the human MMP-9 promoter sequence. Transcriptional regulation of the MMP-9 gene in quiescent HCECs is mainly controlled by the BES located at –1112 to –670 relative to the transcription starting point. PRS that is largely responsible for the elevated activation of human MMP-9 promoter sequence in response to PAF stimulation is located immediately downstream of the BES and spans –670 to –460 relative to the transcription starting point.

View larger version (11K): [in this window] [in a new window]   FIGURE 3. Truncation of PRS abolished the upregulation of MMP-9 gene transcription by PAF. Cultures of HCECs were cotransfected with pRL-TK and one of the various 5'-deleted MMP-9 promoter constructs, two of which were also truncated to remove PRS. Transiently transfected HCECs were left untreated or were stimulated with 100 nM mcPAF overnight, and promoter activity was tested. In the untreated conditions, significant differences were found between any two constructs (P < 0.05) but not between –670/+54Luc and –460/+54Luc constructs (NS, not significant). Significant differences between PAF-stimulated and untreated conditions. Values are the averages (±SEM) of three independent experiments.

View larger version (16K): [in this window] [in a new window]   FIGURE 4. PRS conferred PAF-inducible activity to the HSV-TK promoter. Cultures of HCECs were cotransfected with pRL-TK and pGL3-Basic, pGL3-TK, or pGL3-TK with BES or PRS of the MMP-9 promoter sequence cloned upstream of the HSV-TK promoter, as indicated in the figure. Transiently transfected HCECs were left untreated or were stimulated overnight with 100 nM lysoPAF or 100 nM mcPAF in the absence or presence of 10 µM PAF receptor antagonist LAU8080, and promoter activity was tested. In the untreated conditions, significant differences were found between any two constructs (P < 0.05). Significant differences between PAF-stimulated and untreated conditions (P < 0.05). Values are the averages (±SEM) of three independent experiments.

View larger version (22K): [in this window] [in a new window]   FIGURE 5. Site-directed mutations in the MMP-9 promoter sequence. (A) Cultures of HCECs were cotransfected with pRL-TK and empty vector (pGL2-Basic), wild-type (w/t), or mutant MMP-9 promoter constructs. (B) After overnight culture of transiently transfected cells, the promoter activity was tested. Significant differences between pGL2-Basic and any of the MMP-9 promoter constructs (P < 0.05). Significant differences between the wild-type and any of the mutant constructs (P < 0.05). Values are the averages (±SEM) of four independent experiments. (C) Transiently transfected cells were left untreated or were stimulated overnight with 100 nM mcPAF in the absence or presence of 10 µM PAF receptor antagonist LAU8080 or with 50 nM PMA as a positive control. Significant differences between PAF- or PMA-stimulated and untreated conditions (P < 0.05). Significant differences between the wild-type and any of the mutant constructs (P < 0.05). Values are the averages (±SEM) of four independent experiments.

View larger version (30K): [in this window] [in a new window]   FIGURE 6. Activation of the MEK/ERK pathway in HCECs stimulated with PAF. (A) HCECs were left untreated (U) or were stimulated with 100 nM mcPAF for the times specified. Whole cell extracts were subjected to Western blot analysis. Images were captured using the 800-nm (top) or the 700-nm (middle) channel on an infrared imaging system and were merged together (bottom). (B) Bands for 3-minute stimulation in (A) are shown at a higher magnification for details. (C) HCECs were left untreated or were stimulated with 100 nM mcPAF for 24 hours in the absence or presence of 20 µM PD98059. Whole cell extracts were subjected to Western blot analysis, and images were captured as described in (A). In the merged captures, orange represents the binding of both antibodies to the same band, indicating that these are phosphorylated ERK1/2 proteins. (D) Cultures of HCECs were transiently transfected with luciferase reporter vectors containing the cis-acting DNA-binding element for NFB, Sp1, or AP-1 before they were stimulated with 100 nM mcPAF in the absence or presence of 40 µM PD98059 (PD). Luciferase activity was determined and is indicated by the dashed line in untreated cells. (E) Cultures of HCECs were left untreated or were stimulated with 100 nM mcPAF in the absence or the presence of 20 µM PD98059 for 1 hour, and the nuclear extracts were collected and tested for the DNA-binding activity of Sp1. Significant differences (P < 0.05) between PAF-stimulated or PD98059-treated and untreated conditions. Values are the averages (±SEM) of three independent experiments.

Role of MEK/ERK Pathway in the Phosphorylation of Sp1 by PAF
The involvement of MEK/ERK signaling pathway in the phosphorylation of Sp1 in PAF-stimulated HCECs was examined by Western blotting. Sp1 phosphorylation was upregulated in HCEC stimulated with PAF for 24 hours (Fig. 7A) . This was more prominent when the intensity of the bands was normalized to the actin band. To confirm the phosphorylation status of Sp1, extracts of HCECs stimulated with PAF were immunoprecipitated with Sp1 antibody and tested for the expression of Sp1 (green) and either phosphorylated threonine (Fig. 7B , top; pThr) or phosphorylated serine (Fig. 7B , bottom; pSer) residues. As indicated in Figure 7B , the lower band corresponds to the nonphosphorylated form and the higher band is positive for both pThr and pSer. Stimulation of HCECs by PAF in the presence of PD98059, however, did not cause the phosphorylation of Sp1 (Fig. 7A) .

View larger version (30K): [in this window] [in a new window]   FIGURE 7. PAF induced the phosphorylation of Sp1 and the upregulation of MMP-9 expression and activity in HCECs. (A) HCECs were left untreated or were stimulated with 100 nM mcPAF for 24 hours in the absence or presence of 20 µM PD98059. Whole cell extracts were subjected to Western blot analysis. Images were captured using the 700-nm (top) or 800-nm (bottom) channel on an infrared imaging system. (B) HCECs were stimulated with 100 nM mcPAF for 24 hours. Whole cell extract was subjected to immunoprecipitation with anti-Sp1 antibody, and membranes were immunoblotted for Sp1 and either phosphothreonine (top) or phosphoserine (bottom). Images were captured using the 800-nm (left) or 700-nm (middle) channel on an infrared imaging system and merged together (right). In the merged captures, orange represents the binding of both antibodies to the same band, indicating that these are phosphorylated Sp1. (C) HCECs were left untreated or were stimulated overnight with 100 nM mcPAF in the absence or presence of 20 µM PD98059. Whole cell extracts were subjected to Western blotting, and conditioned media were subjected to zymography, to detect the expression level and the activity of MMP-9. Images were captured on 800 nm channel (WB) and 700 nm channel (Zym) on an infrared imaging system. Bands on the zymography gels from three independent experiments were measured for the intensity of reactions, and the averages (±SEM) were graphed to indicate the significant differences (*) between PAF-stimulated or PD98059-treated and untreated conditions (P < 0.05).

	Discussion

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Although our previous studies have shown that PAF strongly induces the gene and protein expression of MMP-9 and two of its inhibitors, TIMP-1 and TIMP-2, with an imbalance in favor of MMP-9,^{21 22 23} the regulatory mechanism of such induction is unknown. With the use of HCECs, we found that PAF stimulates the DNA-binding activity of NFB, Sp1, and AP-1 in the cells. Activation of these transcription factors is known to be involved in the expression of MMP-9 by other stimulants,^{25 26 28 29 30 31 32 33} indicating that an orchestrated collaboration of various transcription factors may be responsible for the upregulation of MMP-9 promoter activity.

To uncover the significance of their role in the expression profile of MMP-9 in HCECs, we studied the contribution of various segments of the regulatory sequence of the human MMP-9 gene by implementing sequential deletions at the 5' end of a construct spanning –2172 to +54 bp relative to the transcriptional start site of the MMP-9 gene. We found that the basal expression of the gene was predominantly regulated by a segment spanning –1112 to –670 bp upstream of the transcription start site, which we designated BES. The elements participating in the PAF-induced expression of the MMP-9 gene in HCECs were, however, primarily accumulated in a region positioned immediately downstream of the BES, from –670 to –460, which was designated PRS. We further confirmed our findings by performing truncation studies in which the PRS was cut out from two of the constructs carrying the 5'-deleted MMP-9 promoter sequence, which resulted in the elimination of PAF-induced activation of the promoter. We also carried out fusion studies by the insertion of PRS or BES upstream of the promoter sequence of thymidine kinase and found that PAF enhanced the promoter activity of HSV-TK adjoined by the PRS and not the BES. These findings demonstrate that PRS has the capacity to enhance the activity of various promoter sequences in PAF-stimulated cells, and they signified the undisputable contribution of the elements integrated in the PRS of the MMP-9 regulatory sequence in the gene expression induced by PAF in HCECs.

PRS consists of consensus sequences for NFB at –600 and Sp1 at –558,²⁵ indicating a possible role for these transcription factors in the upregulation of MMP-9 gene expression in HCECs stimulated with PAF. It has been reported that the mutation or deletion of –600NFB, –558Sp1, or –79AP-1 motifs reduced or abolished the ability of tumor necrosis factor- to stimulate the MMP-9 promoter in OST osteosarcoma and HepG2 hepatoma cells.²⁵ Moreover, activation of the MMP-9 promoter by v-src in HT 1080 fibrosarcoma cells was attributed to a binding site for AP-1 (–79) and an Sp1-binding GT box at –52.²⁶ We therefore extended our investigation by using the wild-type and mutant constructs of MMP-9 promoter sequence, with the –600NFB, –558Sp1, or –79AP-1 site knocked down by site-directed mutagenesis. We found that though –600NFB site was partially involved in basal and PAF-induced expression of the MMP-9 gene, the –558Sp1 site is a negative regulator in the expression of MMP-9 in quiescent HCECs but contributes to the upregulation of gene expression in cells stimulated with PAF. We also showed that mutation of the –79AP-1 site did not entirely abolish basal expression of the MMP-9 gene and had only a diminishing effect on PAF-induced expression. In a previous study, the proximal –79AP-1 site was identified as an essential element for TPA- and TNF-induced promoter activity. It was also shown that the –79AP-1 motif is indispensable but insufficient for induction of the gene by TPA or TNF-, which also requires the two upstream binding sites for NFB (–600) and Sp-1 (–558).²⁵ We found that the proximal –79AP-1 site is not essential for the response of HCECs to PMA, whereas it is a crucial element for the PAF-induced activity of the MMP-9 promoter. We also found that though the –79AP-1 site contributes to the induction of MMP-9 promoter activity by PAF, the NFB (–600) and Sp1 (–558) binding sites were also essential and played a major role in the elevated activity of the MMP-9 promoter in PAF-stimulated HCECs. Removal of the NFB (–600) and Sp1 (–558) motifs by deletion or truncation of the PRS abolished the upregulation of MMP-9 promoter activity by PAF, indicating the collaborative and synergistic role of the two transcription factors as the most important element in the PAF-induced expression of MMP-9 in HCECs.

Among other regulatory elements reported to be involved in the activation of the MMP-9 promoter, Pax6 was shown to bind directly to a motif that is not located within the PRS and to interact with a consensus sequence within the PRS that also contains the Sp1 motif.³⁴ The possibility of collaboration between Pax6 and Sp1 in the activation of the MMP-9 promoter by PAF must be further investigated. AP-2 shares two motifs located within the PRS with other transcription factors, NFB (–470) and NFB and Sp1 (–482). Further studies on these two consensus sequences are required to identify the possible collaboration between AP-2 and Sp1 or NFB with regard to activation of the MMP-9 promoter by PAF.

Although the inducing effect of PAF on the expression of the MMP-9 gene in HCECs is regulated by more than one element, we report, for the first time, that a negative regulatory element (Sp1-binding site at –558) has an important role in the upregulation of MMP-9. Previous studies suggest that Sp1 can act as either a transcription activator or a repressor.^{35 36 37 38 39 40 41 42 43 44} These contradictory findings indicate that Sp1 and the Sp1-like transcription factors may exert a bipolar function, depending on the type and intensity of stimulation.^{36 43 45} The ultimate course of action taken by the Sp1-like family largely depends on the promoter to which they bind and on their interactions with coregulators.^{41 42 44 46 47 48 49 50 51 52} It has been shown that the zinc finger DNA-binding domain (ZFDBD) and inhibitory domain (ID) of Sp1 are involved in protein-protein interactions with corepressors^{53 54 55} and that they play an important role in the transcriptional regulation of Sp1-dependent genes.⁵⁶ These interactions are apparently regulated by the MEK/ERK signaling pathway, and the activation of MEK was shown to reduce the association between the corepressor/s and Sp1 bound to the regulatory sequence of the gene, resulting in an enhanced transcriptional activity of Sp1.⁵⁶ It has also been reported that the activation of ERK1/2 increases the DNA-binding activity of Sp1.⁵⁷ Furthermore, recombinant ERK2 stimulates and dephosphorylation reduces the DNA-binding activity of Sp1,⁵⁸ indicating that the activity of Sp1 entails its phosphorylation.

ERK1/2 has also been shown to directly phosphorylate Sp1 on threonines 453 and 739 in vitro and in vivo.⁵⁹ We found that MEK1/2 and ERK1/2 were rapidly phosphorylated after PAF stimulation. ERK2 activation was more prominent after 24 hours of stimulation with PAF and was accompanied by threonine and serine phosphorylation of Sp1 that could be eliminated by MEK inhibition. The DNA-binding and transcriptional activity of Sp1 were also upregulated by PAF and were abolished by blocking of the activation of the MEK/ERK pathway. This correlates with elimination of the PAF-induced upregulation of MMP-9 protein expression and gelatinase activity. Our findings indicate that PAF regulates the expression and enzymatic activity of MMP-9 by activation of the MEK/ERK pathway and phosphorylation of Sp1, resulting in the increased DNA-binding and transcriptional activity of Sp1. Our data also show that though an orchestrated collaboration of NFB, Sp1, and AP-1 is required for the optimal upregulation of MMP-9 gene expression by PAF, Sp1 plays a pivotal role by changing its repressor disposition to an inducer element. It may, therefore, be postulated that PAF could disengage the repressor elements from Sp1 (Fig. 8A) , enhance the cross talk between the coactivators and Sp1 (Fig. 8B) , or use a combination of the two effects (Fig. 8C) through activation of the MEK/ERK pathway. These effects overrule the repressor effect of Sp1 that, in unstimulated HCECs, plays a balancing role in the expression of MMP-9. Moreover, Sp1-like proteins, including a class of Krüppel-like factors (KLFs), have recently been identified by the presence of zinc-binding domain structures highly similar to the ZFDBD of Sp1^{35 60 61 62} and were described, along with Sp1-Sp6, as the Sp1-like/KLF (Sp/KLF) family.³⁶ Some members of the Sp/KLF family have been reported to function as repressor proteins that bind the same consensus sequence as Sp1 and that prevent proper activation of the promoter sequence by Sp1.^{36 45} Therefore, it is possible that activation of the MEK/ERK pathway by PAF turns down the DNA-binding activity of a repressor protein, which in turn allows a more compelling interaction between Sp1 and its consensus sequence, resulting in the upregulation of transcriptional activity of an otherwise repressed promoter (Fig. 8D) . Further studies are required to determine which of these mechanisms are activated by PAF. Overall, our results support the conclusion that PAF stimulation transposes the suppression effect of Sp1 transcription complex to an activating function through MEK/ERK signaling and increased phosphorylation of Sp1. Activation of Sp1, along with an increase in the DNA-binding activity of other transcription factors (NFB and AP-1), leads to upregulation in the expression and enzymatic activity of MMP-9 in HCECs stimulated with PAF. Further studies on the pathways involved in the overturn of Sp1 from a repressor to an inducer in corneal epithelial cells may reveal the corresponding corepressors, coactivators, or both that may be targeted for therapeutic approaches in the regulation of inflammatory responses by PAF.

View larger version (29K): [in this window] [in a new window]   FIGURE 8. Models of postulated mechanisms for PAF-induced overturn of the Sp1-mediated transcriptional repression of MMP-9 gene expression. Phosphorylation of the MEK/ERK cascade in PAF-stimulated HCECs may lead to modifications in the interactions between Sp1 and its repressors, activators, or both or to changes in the DNA-binding activity of repressor members of the Sp/KLF family. One or more of the following alterations may be an underlying mechanism of PAF-induced upregulation of transcriptional activity of MMP-9 promoter. Phosphorylation of Sp1 (A) weakens the interactions between the transcription factor and its corepressors, resulting in the removal of binding hindrance, transcriptional interruption, or both. Alternatively, phosphorylation of Sp1 (B) may promote the interactions between Sp1 and its coactivators, which leads to enhanced DNA-binding or transcriptional activity of Sp1. A third possibility is that the phosphorylation of Sp1 (C) may turn down the connections between Sp1 and its corepressors on one hand and may improve the interactions between Sp1 and its coactivators on the other hand, the result of which will be an increased DNA-binding or transcriptional activity of Sp1. Another alternative mechanism is that phosphorylation of a repressor member of the Sp/KLF family (D) weakens its DNA-binding activity and allows Sp1 to compete out the repressor protein and to make a stronger interaction with its consensus sequence, which in turn upregulates the transcriptional activity of MMP-9 promoter.

	Acknowledgements

 
The authors thank Joelle Finley for maintaining the HCEC cultures and Azucena Kakazu for technical support.

	Footnotes

 
Supported by United States Public Health Science Grant RO1 EY04928 from the National Eye Institute, National Institutes of Health (HEPB).

Submitted for publication August 24, 2006; revised November 17, 2006; accepted March 6, 2007.

Disclosure: F. Taheri, None; H.E.P. Bazan, None

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Haydee E. P. Bazan, Department of Ophthalmology, Neuroscience Center of Excellence, Louisiana State University Health Sciences Center, 2020 Gravier Street, Suite D, New Orleans, LA 70112-2223; hbazan1{at}lsuhsc.edu.

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