Laminin Reduces Expression of the Human {alpha}6 Integrin Subunit Gene by Altering the Level of the Transcription Factors Sp1 and Sp3

doi:10.1167/iovs.07-0016

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Laminin Reduces Expression of the Human ${alpha}$ 6 Integrin Subunit Gene by Altering the Level of the Transcription Factors Sp1 and Sp3

Manon Gaudreault,¹ Fran $ç$ ois Vigneault,¹ Steeve Leclerc,¹ and Sylvain L. Guérin¹^,2

^¹From the Oncology and Molecular Endocrinology Research Center and the ^²Unit of Ophthalmology, CHUL, Centre Hospitalier Universitaire de Québec and Laval University, Québec, QC, Canada.

Abstract

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Abstract
Materials and Methods
Results
Discussion
References

PURPOSE. Damage to the corneal epithelium results in the massivesecretion of fibronectin (FN) shortly after corneal injury,which is later replaced by the secretion of laminin (LM). Lamininis recognized by receptors ( ${alpha}$ 6ß1 and ${alpha}$ 6ß4)that belong to the integrin family. The authors characterizedthe regulatory influence exerted by laminin on the Sp1/Sp3-mediated ${alpha}$ 6 gene promoter function.

METHODS. Recombinant plasmids bearing the CAT reporter gene,fused to various segments from the ${alpha}$ 6 promoter, were transfectedinto rabbit corneal epithelial cells (RCECs) grown on untreatedor on LM-coated culture plates or into Sp1-deficient DrosophilaSchneider cells. Expression and DNA binding of Sp1/Sp3 was monitoredwith the use of Western blot and electrophoretic mobility shiftassays (EMSAs), respectively. DNA target sites for Sp1/Sp3 inthe ${alpha}$ 6 gene promoter were identified in vitro by DNAse I footprinting.Binding of Sp1 and of a few other transcription factors wasalso examined in vivo by chromatin immunoprecipitation (ChIP)assays. Expression of the ${alpha}$ 6 mRNA in RCECs grown on LM-coatedculture plates was also assessed by Northern blot and RT-PCRanalyses.

RESULTS. Transfection experiments provided evidence that bothSp1 and Sp3 positively influence ${alpha}$ 6 promoter activity in Sp1/Sp3-deficientSL2 Schneider cells. Two GC-rich target sites for Sp1/Sp3 (aproximal and a distal site) were identified in the ${alpha}$ 6 promoterby DNAse I footprinting. Binding of Sp1/Sp3 was further validatedin vivo by ChIP. Transfections conducted into RCECs grown onLM-coated culture plates resulted in repression of the activitydirected by the ${alpha}$ 6 promoter. This LM-mediated negative regulatoryinfluence also translated into a similar reduction in the expressionof the endogenous ${alpha}$ 6 mRNA as revealed by both RT-PCR and Northernblot analyses. Most of all, results from EMSA and Western blotanalyses suggested that the LM-mediated repression of the ${alpha}$ 6promoter activity results in part from the proteolytic cleavageof Sp1/Sp3.

CONCLUSIONS. Unlike FN, which functions as an activator of ${alpha}$ 5gene transcription, LM repressed transcription, directed bythe ${alpha}$ 6 gene promoter, by altering the nuclear levels of Sp1 andSp3. Reappearance of LM in the basement membrane after repairof the corneal damage is therefore expected to substantiallycontribute to the final steps of this process by influencingthe degree to which genes that encode protein products requestedfor cell adhesion and migration, such as integrin genes, areexpressed during corneal wound healing.

The corneal epithelium is made up of five to seven layers ofregularly arranged squamous epithelial cells. On corneal injury,the damaged cells should be replaced rapidly to maintain propervisual acuity, a process that is ensured by the centripetalmigration of stem cell-derived transient amplifying cells fromthe corneal limbus.¹ ² The early events of the wounding processare chiefly characterized by the disassembling of the hemidesmosomesin the epithelial cells 50 to 70 µm from the wound edge³ and the massive secretion of fibronectin (FN), which peaksas late as 3 to 12 hours after corneal damage and whose expressionis transitory in the basal membrane as it starts disappearing1 week later.⁴ ⁵ It is thought that the newly synthesized FNserves as a temporary matrix for the attachment and migrationof the basal epithelial cells that border the injured area.⁶ It is produced by subepithelial stromal cells in superficialwounds that alter the epithelium or by stromal cells and cornealepithelial cells in more important wounds that also involvethe basal membrane and the stroma.⁷ As FN staining progressivelydiminishes, the secretion of laminin (LM), a major componentof the basal membrane (BM), increases to reach maximal expression1 week after corneal damage.⁴ LM-1 (recently reclassified asLM-111⁸ ), LM-5 (recently reclassified as LM-332⁸ ), and LM-10(recently reclassified as LM-511⁸ ) are the major LM isoformsin the corneal BM.⁹ ¹⁰ The primary function of FN and LM isin cell-matrix attachment, but many additional biological activities,including the promotion of cell migration, wound repair, andmediated cell-signaling events, have been demonstrated.⁹ ¹¹ The BM has many functions that help maintain the normal multilayerstructure in the corneal epithelium. Interaction of its basiccomponents, collagen and LM, with their corresponding transmembraneintegrin receptors, control cell shape, gene expression, cellmigration and proliferation, and programmed cell death.

Integrins are widely expressed, glycosylated, heterodimerictransmembrane adhesion receptors made up of noncovalently bound ${alpha}$ - and ß-subunits that link the extracellular matrix(ECM) to the cell’s cytoskeleton. They mediate bidirectionaltransfer of information through diverse signal transductionpathways (for reviews, see Plow et al.¹² and van der Flierand Sonnenberg¹³ ). In a recent survey of the human genome,24 ${alpha}$ - and 9 ß-integrin subunits have been identified,¹⁴ which implies 6 novel ${alpha}$ - and 1 novel ß-subunits relativeto the previously recognized 18 ${alpha}$ - and 8 ß-subunitsreported to form 24 different heterodimers.¹² ¹⁵ ¹⁶ ¹⁷ However,the existence of these new integrin subunits remains to be firmlyestablished. The ${alpha}$ 6ß1 and the ${alpha}$ 6ß4 integrinsrecognize LM as their ligand.¹⁸ ¹⁹ The integrin ${alpha}$ 6ß4is a component of the hemidesmosomes (HDs) and is thereforelocated to the basal side of the basal epithelial cells.²⁰ ²¹²² ²³ HDs are specialized junctional complexes that contributeto the attachment of epithelial cells to the BM²⁴ and are implicatedin signal transduction through ${alpha}$ 6ß4.²⁵ The patternof integrins expressed by the basal cells of the corneal epitheliumis considerably altered as the leading edge progresses towardthe wounded corneal surface.⁴ ²⁰ ²⁶ ²⁷ A few studies reporteddynamic changes in the distribution of the ${alpha}$ 6 subunit duringcorneal wound healing in vivo.²⁰ ²⁸ In response to wounding,HDs are disassembled, and the expression of ${alpha}$ 6²² and ß4²⁷ increases during migration of the epithelial cells in vivo.Stepp et al.²⁷ suggested that the increased ß4 expressionmust play a role in cell-cell or cell-substrate adhesion mechanismsthat are required during the corneal wounding or in the preparationof cells for the restratification process.

Although FN deposition can be observed as early as 3 hours afterdamage to the corneal epithelium, no staining of LM occurs beneaththe leading edge of migrating epithelial cells until 24 hoursafter the injury.²⁹ Interestingly, FN has been shown to influencethe transcriptional activity not only of the ${alpha}$ 5 subunit gene³⁰ but also that of the LM binding ${alpha}$ 6 integrin subunit ²² in invitro cultures of rabbit corneal epithelial cells (RCECs). Theseresults suggest that while corneal epithelial cells start migratingover the newly synthesized temporary FN matrix, expression ofthe ${alpha}$ 5 and ${alpha}$ 6 integrin subunit genes is turned on, ensuring earlyexpression of the ${alpha}$ 6 subunit well before LM accumulates beneaththe leading edge. As a consequence, the signal transductionpathway activated on binding of the ${alpha}$ 6ß1 and ${alpha}$ 6ß4integrins to their ligand LM might trigger regulatory signalsdistinct from those resulting from the binding of FN to the ${alpha}$ 5ß1 integrin. Activation of the MAPK pathway throughthe binding of FN to its ${alpha}$ 5ß1 integrin was recentlyreported to result in the transcriptional activation of the ${alpha}$ 5 gene through a modification in the phosphorylation state ofSp1.³⁰ Both the promoter and the 5'-flanking region of thehuman ${alpha}$ 6 subunit gene have recently been cloned.³¹ ³² ³³ Althoughmultiple target sites for Sp1 were identified along the ${alpha}$ 6 proximalpromoter sequence by DNAse I footprinting,³² only the mostproximal Sp1 site (position –48 to –43) was assessedfor its regulatory influence through site-directed mutagenesis.³¹ In addition, all ${alpha}$ 6 promoter transfection experiments conductedto date were performed in cancer cell lines of various origins.Nontransformed primary cultured cells are much closer to theirin vivo counterparts than are transformed cells or cell lines;consequently, they are attractive as a source of cellular materialfor gene expression studies³⁴ ³⁵ ³⁶ (also see Gaudreault etal.³⁷ ). Considering that cancer cell lines and nontransformedprimary cultured cells of similar tissue origin often behavedifferently, regulatory elements with negligible regulatoryinfluence in transformed cells may be required for gene transcriptionin nontransformed cells.

The purpose of this study was to investigate in more detailthe role exerted by the positive transcription factors Sp1 andSp3 on the transcriptional activity directed by the ${alpha}$ 6 promoterin primary cultured and established tissue-cultured cells andto evaluate whether LM may alter the regulatory influence mediatedby these nuclear proteins. DNAse I footprinting analyses identifiedtwo specific target sites for Sp1 (a proximal and a distal site)along the ${alpha}$ 6 promoter sequence. Binding of Sp1 to the ${alpha}$ 6 promoterwas also demonstrated in vivo through ChIP assays. Site-directedmutational analyses provided evidence that different cells useeither Sp1 target site, proximal or distal, with varying efficiency.Most of all, the activity directed by the ${alpha}$ 6 promoter was foundto be downregulated when RCECs were grown on LM-coated cultureplates. The reduced ${alpha}$ 6 promoter activity was shown to rely, atleast in part, on a reduced level of expression of Sp1 and Sp3in corneal epithelial cells (RCECs and HCECs) when they aregrown on LM.

Materials and Methods

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Abstract
Materials and Methods
Results
Discussion
References

All experiments were conducted in voluntary compliance withthe ARVO Statement for the Use of Animals in Ophthalmic andVision Research, and all procedures were approved by the LavalUniversity Animal Care and Use Committee.

Cell Culture and Media
HCECs were isolated from the limbal area of normal eyes froma 44-year-old donor and were obtained through the Eye Bank fromthe CHUL Research Center in accordance with a procedure we previouslydescribed.³⁷ ³⁸ RCECs were obtained from the central area offreshly dissected rabbit corneas and were grown into SHEM medium(fetal bovine serum, 15% wt/vol), as recently described.³⁹ Human skin keratinocytes (HSKs) were obtained from normal newbornforeskin specimens from a 17-day-old donor and were culturedwith a feeder layer, as recently described.⁴⁰ Human skin fibroblasts(HSFs) were isolated from skin biopsy specimens of healthy maledonors and underwent primary culture in Dulbecco modified Eaglemedium (DMEM, Gibco BRL, Burlington, ON, Canada) supplementedwith 10% fetal bovine serum (FBS; Gibco BRL). Human epithelioidcarcinoma HeLa (ATCC CCL 2) cells were grown in DMEM supplementedwith 10% fetal bovine serum (FBS). Human colon adenocarcinomaCaco2/15, a derivative of the Caco2 cell line (ATCC HTB-37;Rockville, MD) characterized by Beaulieu and Quaroni,⁴¹ wasgrown in DMEM high glucose, 10% FBS, HEPES 20 mM, and glutamine10 mM. ARPE-19 cells were purchased from the ATCC (CRL-2302)(Manassas, VA) and grown in DMEM/F12 growth medium (CanadianLife Technologies, Burlington, ON, Canada) with 3 mM glutamine(Sigma, Oakville, ON, Canada) and supplemented with 10% fetalbovine serum (Hyclone, Logan, UT). SL2 Drosophila Schneidercells (ATCC CRL-1963) were cultured at 28°C without CO₂in Schneider insect medium (Sigma) supplemented with 10% FBSand 20 µg/mL gentamicin. All cells were grown under 5%CO₂ at 37°C, and gentamicin was added to all media at afinal concentration of 15 µg/mL.

Flow Cytometric Analysis
RCECs, HeLa, HSFs, HSKs, and ARPE-19 cells were grown as describedand removed from the culture dishes (Sarstedt, Montréal,QC, Canada) with PBS/citrate/EDTA solution and were washed twicewith serum-free medium containing 1% BSA and fixed with 1% paraformaldehyde-PBS(1% PFA/PBS) for 20 minutes. Aliquots of fixed cells (1 x 10⁶)were washed twice and resuspended in PBS (pH 7.2) containing1% BSA. One microgram of a primary antibody directed againstthe ${alpha}$ 6 integrin subunit (MA6; Chemicon, Temecula, CA) was addedto cell suspensions for 60 minutes at room temperature and agitatedon a rotator. After 1 hour, cells were washed twice, and a dilutionof 1:100 of fluorescein isothiocyanate-conjugated (FITC) humananti-rat IgG suspended in PBS-1% BSA was added to cells andincubated for 30 minutes on a rotator at room temperature. Finally,cells were resuspended in 1% PFA/PBS and analyzed with a flowcytometer (Epics XL; Beckman Coulter, Miami, FL).

Laminin and Fibronectin Coating
Skin keratinocytes (2.5 x 10⁴/cm²) known for their ability tosecrete large amounts of LM-5⁴² and obtained from an adultskin donor (kindly provided by Lucie Germain, Laboratoire d’OrganogénèseExpérimentale [LOEX], Hôpital du Saint-Sacrementdu CHA, Québec, QC, Canada) were plated on an irradiated3T3 feeder layer (2 x 10⁴ 3T3/cm²) on tissue culture plates.Keratinocytes were cultured in Dulbecco-Vogt modified Eaglemedium (Life Technologies, Grand Island, NY), supplemented with10% fetal calf serum (FCS; Hyclone-PDI Bioscience, Aurora, ON,Canada), 100 IU/mL penicillin, and 25 µg/mL gentamicin(Sigma, St. Louis, MO) until they reached 30%, 70%, or 100%cell density for various periods of time (1, 3, 5, and 10 days)and then were completely removed from the plates by incubationin 20 mM NH₄OH for 5 to 10 minutes. The plates on which LM wasdeposited were then washed with PBS and reseeded either withRCECs (2.5 x 10⁴/cm²) or HCECs (5 x 10⁴/cm²) grown to midconfluencebefore transfection. A similar approach was used with Caco2/15cells, which are known for their ability to secrete LM-10⁴³ and LM-1. ⁴⁴ When indicated, coating of tissue-culture plateswith commercially purified LM (LM-1, 0.5–8 µg/cm²;Sigma) before RCECs were added, as described.³⁰ Human plasmaFN (obtained as previously described⁴⁵ ) was coated for 18 hoursat 37°C on the culture dishes at 8 µg/cm². Coatedpetri dishes were washed twice with PBS and blocked at 37°Cwith 2% BSA in PBS. Cells were then seeded and grown as described.

Plasmids and Oligonucleotides
Recombinant plasmids ${alpha}$ 6–84, ${alpha}$ 6–141, ${alpha}$ 6–181, ${alpha}$ 6–352, ${alpha}$ 6–430, and ${alpha}$ 6–590—all of which bore the chloramphenicolacetyltransferase (CAT) reporter gene fused to DNA fragmentsfrom the human ${alpha}$ 6 gene upstream regulatory sequence extendingto 5' positions –84, –141, –181, –352,–430, and –590 but shared a common 3' end locatedat position +76—were constructed. The PGEM-3Z f(+) AvaI/ ${alpha}$ 6plasmid that bears the human ${alpha}$ 6 gene promoter from position –930to +76 relative to the ${alpha}$ 6 mRNA start site (generously providedby Schei Kitazawa, Kobe University School of Medicine, Kusunoki-Cho,Chuo-Ku, Kobe, Japan) was linearized at its unique KpnI site(5' end) and was treated with the nuclease Bal31 before it wasblunted. The 5'-digested ${alpha}$ 6 promoter fragments generated werethen digested with HindIII (3' end at ${alpha}$ 6 position +76) beforethey were ligated into the unique SmaI/HindIII sites of theplasmid PGL3 to produce the PGL3/ ${alpha}$ 6–590 vector. The PGL3/ ${alpha}$ 6–590construct was digested with NheI and blunt-ended with Klenow(which then preserved the ${alpha}$ 6–590 5' end), before it wassecond-digested with XbaI (which preserved the ${alpha}$ 6 +76 3' end).The resultant ${alpha}$ 6 promoter-bearing DNA fragment was ligated upstreamof the CAT reporter gene from the pCATBasic vector (Promega,Madison, WI), which was first digested with PstI (5' end), blunt-endedwith Klenow, and second digested with XbaI (3' end) before itsdephosphorylation with alkaline phosphatase (to yield pCATBasic/ ${alpha}$ 6–590).Removal of the ${alpha}$ 6 promoter fragments from the common SphI site(located upstream from ${alpha}$ 6 promoter position –590 in themultiple cloning site of the parental plasmid pCATBasic) tothe internal restriction sites SacII (at ${alpha}$ 6 position –84),KpnI (at –141), SacI (at –181), NsiI (at –352),and AccI (at position –430) yielded, after blunt-endingwith Klenow and ligation, the plasmids ${alpha}$ 6–84, ${alpha}$ 6–141, ${alpha}$ 6–181, ${alpha}$ 6–352, and ${alpha}$ 6–430, respectively.

The plasmid derivatives ${alpha}$ 6–84/mSp1p, ${alpha}$ 6–141/mSp1p,and ${alpha}$ 6–352/mSp1p (which bear mutations into the proximalSp1 site), ${alpha}$ 6–352/mSp1d (which bear mutations into thedistal Sp1 site), and ${alpha}$ 6–352/mSp1pd (which bear mutationsinto the proximal and the distal Sp1 sites) were all producedby PCR with a site-directed mutagenesis kit (QuickChange; Stratagene,La Jolla, CA) according to the manufacturer’s instructions.Parental plasmids ${alpha}$ 6–84, ${alpha}$ 6–141, and ${alpha}$ 6–352 wereused as templates. Double-stranded oligonucleotides used tointroduce mutations in the Sp1 sites (mutations are shown inbold) contained the following sequences: proximal Sp1 site (topstrand, 5'-GGGGCGAGAGGGTGGGGAGGATCGCGGCCGGCGTCCTCGTC-3'; bottomstrand, 5'-GACGAGGACGCCGGCCGCGATCCTCCCCACCCTCTCGCCCC-3'); distalSp1 site (top strand, 5'-GTCCACAGAGATCGCCGCAGTGGGGCTGCTTCGCCG-3';bottom strand, 5'-CGGCGAAGCAGCCCCACTGCGGCGATCTCTGTGGAC-3').Sp1 and Sp3 expression plasmids pPacSp1 and pPacSp3, respectively,were obtained from Guntram Suske (Institute für Molecularbiologyund Tumorforschung, Philipps Universität, Marburg, Germany).Double-stranded oligonucleotides used for competition assaysin the EMSAs contained the following DNA sequences: proximal(5'-GAGGGTGGGGAGGGGCGGGGCCGGCGTCCTCGTCA-3') and distal (5'-TTCTGTCCACAGAGGGCGGCGCAGTGGGGCTGCTT-3');Sp1 sites identified in this study in the ${alpha}$ 6 gene promoter andin the alternative Sp1p_a site (5'-GGGCGCGCAAGGAGGGGCGAGAGGGTGGGGAGGGG-3');the high-affinity binding sites for the transcription factorsSp1 (5'-GATCATATCTGCGGGGCGGGGCAGACACAG-3')⁴⁶ and NFI (5'-TTATTTTGGATTGAAGCCAATATGAG-3')⁴⁷; the consensus sequence for the transcription factor E2F1 (5'-CAGAGCCGTTTCGCGCGGTGCGGGCGGTGC-3');and the AP-1 site identified in the promoter of the human ${alpha}$ 5integrin subunit gene (5'-GATCCCCGCGTTGAGTCATTCGCCTC-3').⁴⁸ All oligonucleotides used in the present study were chemicallysynthesized (Biosearch 8700 apparatus; Millipore, Beford, MA).

DNAse I Footprinting
DNAse I footprinting was performed in DNAse I buffer⁴⁹ by incubating3 x 10⁴ cpm labeled probe with increasing amounts (1–10µL) of recombinant Sp1 protein (GST-Sp1–8xHis protein;kindly provided by Claude Labrie, Oncology and Molecular EndocrinologyResearch Center, CHUL). The recombinant GST-Sp1–8xHisprotein was overexpressed in Escherichia coli BL21 CodonPlusR1L cells with the pGEX-Sp1–8xHis plasmid before purification,as described.⁵⁰ The 217-bp HindIII-XbaI DNA fragment from the ${alpha}$ 6 promoter extending from positions –141 to +76 and the430-bp fragment spanning ${alpha}$ 6 promoter sequences from –352to +76 were used as labeled probes in these assays. DNAse Idigestion and further analysis of the digestion products ontopolyacrylamide sequencing gels were performed as described.⁴⁹

Chromatin Immunoprecipitation Assays
ChIP analyses were conducted as previously described.⁵¹ Briefly,HCECs were grown on 150-mm tissue culture dishes to approximately75% confluence in complete medium. Cells were then cross-linkedwith 1% formaldehyde for 10 minutes, harvested, and chromatinimmunoprecipitated with 1 µg polyclonal antibodies directedagainst the Sp1 (sc-59; Santa Cruz Biotechnology, Inc., SantaCruz, CA), Sp3 (sc-644; Santa Cruz Biotechnology), and NFI (SC-5567;Santa Cruz Biotechnology) and E2F1 (sc-193x; Santa Cruz Biotechnology)transcription factors. The resultant DNA was analyzed by PCRusing a pair of primers (ITGA6-U,5'CTATCAAGGTGTGCGCTGTG-3';ITGA6-L,5'CAGAATTGTGGTTGCCGAGTA-3') spanning the entire ITGA6gene-promoter area. As a negative control, each ChIP samplewas also subjected to PCR using primers (p21-U [5'AATTCCTCTGAAAGCTGACTGCC3']and p21-L [5'OAGGTTTACCTGGGGTCTTTA-GA-3']) specific to a regionlocated approximately 2 kbp upstream of the human p21 promoter.Standard deviation is provided and has been calculated fromthree separate experiments.

Transient Transfections and CAT Assays
HCECs and RCECs were grown to midconfluence (near 80% coverage)into six-well (35-mm) tissue culture plates and transientlytransfected using a polycationic detergent reagent (Lipofectamine;Gibco BRL) according to a procedure we previously described.³⁰⁵² Each reagent (Lipofectamine)-transfected plate received1 µg ${alpha}$ 6-CAT test plasmid and 0.5 µg human growthhormone (hGH)-encoding plasmid pXGH5.⁵³ Primary cultured HSFs,established tissue culture HeLa cells, and Drosophila SL2 Schneidercells were transfected according to the calcium phosphate precipitationprocedure⁴⁹ ⁵⁴ at a density of 5 x 10⁵ HSF, 4 x 10⁵ HeLa, or1 x 10⁶ SL2 cells per 60-mm culture plate. Levels of CAT activityfor all transfected cells were determined as described⁵⁴ andwere normalized to either ß-galactosidase or the amountof hGH secreted into the culture media and were assayed usinga kit for quantitative measurement of hGH (Immunocorp, Montréal,QC, Canada). The value presented for each individual test plasmidtransfected corresponded to the mean of at least three separatetransfections performed in triplicate. To be considered significant,each value had to be at least three times over the backgroundlevel caused by the reaction buffer used (usually correspondingto 0.15% chloramphenicol conversion). Student’s t-testwas performed for comparison of the groups. Differences wereconsidered statistically significant at P < 0.05. All dataare expressed as mean ± SD.

Nuclear Extracts, Electrophoretic Mobility Shift Assays, and Supershift Experiments
Crude nuclear extracts were prepared from midconfluent RCECs(5 x 10⁴ cells/cm² cultured for 72 hours usually yields almost70% coverage of the culture flasks) grown either on BSA- (2%BSA in PBS) or LM-coated culture dishes, as detailed previously.⁵⁵ Electrophoretic mobility shift assays (EMSAs) were conductedas described³⁰ by using the Sp1 oligomer as a probe and 5 µgnuclear proteins. When indicated, unlabeled oligomers bearingthe sequence of various target sites for known transcriptionfactors (SP1p, Sp1d, Sp1p_a, Sp1, NFI, AP-1) were added as unlabeledcompetitors (50-, 100-, 125- and 500-fold molar excesses) duringthe assay. DNA-protein complexes were then separated by gelelectrophoresis through 6% native polyacrylamide gels run againstTris-glycine buffer.⁵⁶ Supershift experiments in EMSA wereconducted by incubation of 5 µg nuclear proteins fromRCECs in the presence of no or 2 µL polyclonal antibodiesraised against the transcription factors Sp1 and Sp3 (SantaCruz Biotechnology, Inc.).

SDS-PAGE and Western Blot
Approximately 30 µg protein was added to 1 vol samplebuffer (6 M urea, 63 mM Tris [pH 6.8], 10% [vol/vol] glycerol,1% SDS, 0.00125% [wt/vol] bromophenol blue, 300 mM ß-mercaptoethanol)and was size-fractionated on a 10% SDS-polyacrylamide minigelbefore transfer to a nitrocellulose filter. The blot was thenwashed in TS and TSM buffers, as described.³⁰ A 1:5000 dilutionof a rabbit polyclonal antibody raised against Sp1 or Sp3 wasadded, and incubation proceeded for 2 hours at 22°C. Theblot was then washed and incubated with a 1:1000 dilution ofa peroxidase-conjugated goat anti-rabbit immunoglobulin G (JacksonImmunoResearch Laboratories, Inc., Bar Harbor, ME), and immunoreactivecomplexes were revealed with the use of Western blot chemiluminescencereagents (Amersham Biosciences, Arlington Heights, IL), as recentlydescribed.³⁰

RT-PCR and Northern Blot Analyses
Total RNA was isolated from midconfluent RCECs grown on BSAor on LM-coated culture plates using a reagent (Tri Reagent;Molecular Research Center, Inc., Cincinnati, OH) and was reversetranscribed using a transcriptase kit (Superscript II; Gibco-BRL),as recently detailed.⁵² The resultant newly synthesized first-strandcDNAs were column purified (QIAquick nucleotide removal kit;Qiagen, Santa Clarita, CA) and used for PCR amplification ofthe ${alpha}$ 6 integrin subunit transcript and the 18S ribosomal RNA.The DNA sequence of both the 5' and the 3' template primersfor ${alpha}$ 6 (5' primer, CAAGATGGCTACCCAGATAT-bp; 3' primer, CTGAATCTGAGAGGGAACCA-bp;PCR product, 210 bp) was derived from the corresponding human ${alpha}$ 6 integrin gene (GenBank accession no., NM 000210). Oligonucleotideprimers for the amplification of the 18S ribosomal RNA wereprovided (Quantum RNA 18S Internal Standards kit; Ambion Inc.,Austin, TX). Taq polymerase (Pharmacia-LKB, Uppsala, Sweden)was selected for PCR amplification. Cycle parameters were thesame for all primers used (denaturation 94°C, 30 seconds;annealing 58°C, 30 seconds; extension 72°C, 30 seconds)with an identical number of cycles (24, 26, 28, 30, 32, and34 cycles) for both sets of primers. PCR-amplified DNAs werefractionated on a 2% agarose gel, and their positions were revealedby ethidium bromide staining. The gel photograph was scanned(Visage 110S Bioimage analyzer; Millipore) to quantify the alterationsin the amount of the ${alpha}$ 6 and the 18S PCR-amplified fragments.

Northern blot analyses were conducted on total RNA isolatedfrom midconfluent RCECs grown on BSA- or LM-coated culture plates,as detailed. Total RNA was size-fractionated on a 1.2% formaldehyde-agarosegel and blotted onto a Hybond-N+ membrane (Amersham Canada,Oakville, ON, Canada), as described elsewhere. The membranewas then hybridized at 65°C in buffer (PerfectHybrid PlusHybridization; Sigma). Blots were washed once at 25°C in2x SSC-0.1% SDS (1x SSC is 150 mM NaCl; 15 mM sodium citrate)and twice at 50°C in 0.2x SSC-0.1% SDS. The labeled probeused for hybridization consisted of a 665-bp EcoRI–EcoRIrestriction fragment derived from the ${alpha}$ 6 cDNA. Membranes wereautoradiographed at –80°C for 18 hours before development.

Results

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Abstract
Materials and Methods
Results
Discussion
References

DNAse I Footprinting of the Sp1 Binding Sites along the Promoter of the ${alpha}$ 6 Integrin Gene Subunit
To determine precisely where Sp1 binds along the ${alpha}$ 6 integrinsubunit gene promoter, in vitro DNAse I footprinting was performedusing a recombinant preparation of Sp1. The DNA sequence, locatedbetween positions +76 to –352 and constituting the entire ${alpha}$ 6 promoter, was examined on both strands for Sp1 binding. Twodistinct target sites for Sp1 were identified along the ${alpha}$ 6 promotersequence: a proximal site, located between positions –38to –62 (Sp1p; Fig. 1A and also depicted on Fig. 1C ),and a more distal site, located between positions –195and –215 (Sp1d; Fig. 1B and also depicted on Fig. 1C). No binding site for Sp1 except Sp1p and Sp1d could be identifiedon the ${alpha}$ 6 promoter under the experimental conditions used.

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FIGURE 1. DNAse I footprinting of Sp1 binding to the ${alpha}$ 6 gene promoter. (A) A preparation of recombinant Sp1 (1–10 µL) was incubated with a 217-bp ${alpha}$ 6 probe labeled on either the top (Top) or the bottom strand (Bottom) and subjected to DNAse I digestion. The digestion products were then analyzed by gel electrophoresis through an 8% sequencing gel. The position of a promoter proximal Sp1 protected site (Sp1p) is indicated for both the top and bottom strands. G, Maxam and Gilbert G sequencing ladder; C, labeled probe incubated with DNAse I but without recombinant Sp1. (B) Same as in (A) except that the labeled probe consisted of a 430-bp HindIII-KpnI DNA fragment from the ${alpha}$ 6 promoter 5' end-labeled on either its bottom or top strand. The position of a promoter distal Sp1 protected site (Sp1d) is indicated for both the bottom and top strands. (C) Positioning of the DNAse I footprinted Sp1 sites along the ${alpha}$ 6 promoter sequence. The positions of proximal (Sp1p) and distal (Sp1d) Sp1 target sites (boxes) relative to the ${alpha}$ 6 mRNA start site (identified as +1) are provided, along with the ${alpha}$ 6 promoter 5' end point from the recombinant constructs ${alpha}$ 6–84, ${alpha}$ 6–141, ${alpha}$ 6–181, and ${alpha}$ 6–352.

Regulatory Influence Played by Both the Sp1p and the Sp1d Sites on ${alpha}$ 6 Promoter Activity
To assess the functional relevance of the proximal and distalSp1 sites, transfection of recombinant constructs bearing theCAT reporter gene fused to DNA segments from the ${alpha}$ 6 promoterbearing the proximal or both the proximal and the distal Sp1sites was conducted into primary cultured cells (HSFs, HSKs,RCECs) and established tissue cultured cells (HeLa, ARPE19).All these cells were shown to express the ${alpha}$ 6 integrin subunitto varying degrees in the following order: RCECs > HSKs >ARPE19/HeLa > HSFs, as revealed by FACS analysis (Fig. 2). As shown on Figure 3 , maximal basal promoter function isensured by the first 84 bp located immediately upstream of the ${alpha}$ 6 mRNA start site (in plasmid ${alpha}$ 6–84) in all types of transfectedcells. Surprisingly, extending the 5' end further up to position–352 to include the Sp1d site resulted in a dramatic reductionin CAT activity on transfection of the plasmid ${alpha}$ 6–352 intoall types of cells (near 5-, 3-, 15-, 9-, and 50-fold reductionrelative to the level directed by ${alpha}$ 6–84 in RCEC (Fig. 3B), HSK (Fig. 3C) , HeLa (Fig. 3D) , ARPE19 (Fig. 3E) , and HSF(Fig. 3F) cells, respectively. Elongating the 5' end up toposition –430 or –590 did not result in CAT activitiesstatistically different from those measured with the ${alpha}$ 6–352construct when transfected in RCECs and in HeLa cells (datanot shown), suggesting that most of the regulatory elementsrequired for the transcription of the ${alpha}$ 6 gene are located downstreamfrom position –352. In addition, comparison of CAT activityyielded by the transfection of the ${alpha}$ 6–84 construct clearlyindicated that the strength of the ${alpha}$ 6 promoter is higher in RCECsthan in any of the other cell types transfected (32,118 ±4941, 17,301 ± 3818, 6584 ± 1353, 1219 ±455, and 60 ± 16 in RCECs, HSKs, HeLa, ARPE-19 and HSFscells, respectively; similar results were observed with the ${alpha}$ 6–352 construct).

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FIGURE 2. FACS analysis of integrin ${alpha}$ 6 expression in primary cultured and established tissue culture cells. Expression of the ${alpha}$ 6 integrin subunit was monitored by FACS analyses in primary cultures of RCEC, HSK, and HSF cells and in established HeLa and ARPE19 cells. Results are expressed as low (+) to very strong (++++) expression of ${alpha}$ 6 (bottom right table). Typical histograms of ++++ (RCECs), ++ (HeLa), and + (HSFs) are also provided. Values presented are from four individual measurements from two different batches of cells.

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FIGURE 3. Transfection analyses in primary and established tissue culture cells. (A) Schematic representation of the recombinant ${alpha}$ 6/CAT constructs used in this study. Positions of proximal (Sp1p) and distal (Sp1d) Sp1 target sites identified by DNAse I footprinting are indicated along with the 5' end of each of the ${alpha}$ 6 promoter segment contained on the recombinant construct. Mutations that disrupt binding of Sp1 to proximal or distal Sp1 sites (in plasmids ${alpha}$ 6–84/mSp1p, ${alpha}$ 6–352/mSp1p, and ${alpha}$ 6–352/mSp1d), or both (in ${alpha}$ 6–352/mSp1pd), are indicated by the removal of the corresponding Sp1 box. (B–F) Site-directed mutational analysis of Sp1p and Sp1d. Wild-type constructs ${alpha}$ 6–84 and ${alpha}$ 6–352, and their derivatives bearing mutations into either Sp1p ( ${alpha}$ 6–84/mSp1p and ${alpha}$ 6–352/mSp1p) or Sp1d ( ${alpha}$ 6–352/mSp1d), or both Sp1 sites ( ${alpha}$ 6–352/mSp1pd), were transfected into primary cultured cells (RCECs, B; HSKs, C; HSFs, F) or established tissue culture cells (HeLa, D; ARPE19, E). Cells were then harvested, and CAT activity was determined and normalized to secreted hGH. SD is provided.

We then exploited site-directed mutagenesis to establish theindividual contribution of Sp1p and Sp1d in the transcriptiondirected by the ${alpha}$ 6 gene promoter. As shown on Figure 3 , mutatingthe Sp1p site in the basal ${alpha}$ 6 promoter from the parental plasmid ${alpha}$ 6–84 (to yield the ${alpha}$ 6–84/mSp1p mutated derivative)resulted in dramatic reductions in CAT activity on transfectionof primary cultured cells and established tissue culture cells(24-, 29-, 27-, 14-, and 150-fold reduction in RCECs, HSKs,HeLa, ARPE19, and HSFs, respectively). However, mutating theSp1p site in the context of the longer construct ${alpha}$ 6–352(which bears Sp1p and Sp1d) had a statistically significantinfluence on the ${alpha}$ 6 promoter activity only in RCEC (40% reduction)and HSK (77% reduction) cells. Similarly, mutations that abolishthe Sp1d site in the construct ${alpha}$ 6–352/mSp1d only modestlyreduced ${alpha}$ 6 promoter activity by 48% in RCECs, whereas it hadno influence in the remaining cell types. On the other hand,mutating both the Sp1p and the Sp1d sites in ${alpha}$ 6–352/mSp1pdseverely reduced ${alpha}$ 6 promoter activity in all types of cells (fromthreefold in ARPE-19 to undetectable level in HSFs). These resultssuggest that a single, intact Sp1 site is required to ensurebasal transcription directed by the ${alpha}$ 6 promoter in all cell linestested and that negative regulatory elements that restrict promoteractivity must be present along the –84/–352 segmentfrom the ${alpha}$ 6 promoter.

To evaluate the respective contribution of Sp1 and Sp3 on theactivity directed by the ${alpha}$ 6 Sp1p and the Sp1d sites, cotransfectionexperiments were conducted into Drosophila SL2 Schneider cells.These cells have been reported to be deficient in producingthese transcription factors and many others expressed in highereukaryotes, making them an ideal system for studying gene expressionor transcription factors function (for a review, see Suske⁵⁷). The plasmids ${alpha}$ 6–141 or ${alpha}$ 6–352 or their derivatives—whichbear mutations into Sp1p ( ${alpha}$ 6–141/mSp1p and ${alpha}$ 6–352/mSp1p),Sp1d ( ${alpha}$ 6–352/mSp1d), or both sites ( ${alpha}$ 6–352/mSp1pd)—werecotransfected into Schneider cells alone or with recombinantplasmids (pPacSp1 and pPacSp3) containing Sp1 or Sp3 cDNA underthe control of the Drosophila actin gene promoter, thereforeensuring high levels of both these proteins in Schneider cells.Preliminary transfection experiments indicated that neither ${alpha}$ 6–141 nor ${alpha}$ 6–352 could sustain basal promoter activitywhen individually transfected into Schneider cells in the absenceof Sp1 and Sp3. However, when cotransfected along with pPacSp1,38- and 68-fold increases in promoter activity were observedwith the plasmids ${alpha}$ 6–141 and ${alpha}$ 6–352, respectively(Fig. 4) . Mutations that eliminated the Sp1p site did not completelyabolish Sp1 responsiveness because the ${alpha}$ 6 promoter preserved29% of its activity with the ${alpha}$ 6–141/mSp1p construct andapproximately 75% with ${alpha}$ 6–352/mSp1p. On the other hand,responsiveness toward Sp3 was much lower than that observedwith Sp1 (sevenfold and threefold increases in CAT activitywhen pPacSp3 was cotransfected along with ${alpha}$ 6–141 and ${alpha}$ 6–352,respectively). Mutating the Sp1p site into both constructs entirelyabolished promoter activity in SL2 cells, whereas disruptingSp1d had no influence at all on the Sp3 responsiveness of the ${alpha}$ 6 promoter (Fig. 4) . Surprisingly, mutations that disrupt theSp1d site in the ${alpha}$ 6–352/mSp1d construct did not suppress,but rather stimulated, ${alpha}$ 6 promoter function when cotransfectedwith pPacSp1 in SL2 cells. No such effect was observed withSp3. Cotransfection of pPacSp1 and pPacSp3, together with the ${alpha}$ 6 promoter constructs, provided evidence that Sp1 and Sp3 donot function synergistically to modulate the transcriptionalactivity directed by the ${alpha}$ 6 promoter. At the most, a weak additiveeffect is observed when the ${alpha}$ 6–352 construct is cotransfectedalong with both the Sp1 and Sp3 expression vectors.

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FIGURE 4. Transfections in Drosophila SL2 Schneider cells. Both the recombinant plasmids ${alpha}$ 6–141 (which bears only the Sp1p site) and ${alpha}$ 6–352 (which bears both the Sp1p and the Sp1d sites) and their Sp1-mutated derivatives ( ${alpha}$ 6–141/mSp1p, ${alpha}$ 6–352/mSp1p, ${alpha}$ 6–352/mSp1d, and ${alpha}$ 6–352/mSp1pd) were transfected alone or with pPacSp1 (Sp1), pPacSp3 (Sp3), or both (Sp1/Sp3) into Drosophila SL2 Schneider cells. Cells were harvested 48 hours later, and CAT activities (expressed as fold activity relative to the level directed by the ${alpha}$ 6–141 or the ${alpha}$ 6–352 promoter constructs alone) was determined and normalized to ß-gal. SD is also provided.

Sp1 Binds to an Alternative Target Site when the Sp1p Site Is Mutated In Vitro
Only two Sp1 target sites were initially identified throughDNAse I footprinting along the ${alpha}$ 6 promoter (Fig. 1) . However,the high residual ${alpha}$ 6 promoter activity observed in SL2 cellswhen the Sp1p and Sp1d sites were mutated, individually or incombination, suggested that Sp1 might have the ability to bindother alternative sequences with a lower affinity when it isprevented from interacting with its primary target sites. Toinvestigate such a possibility, DNAse I footprinting was repeatedwith the Sp1p-unmutated ${alpha}$ 6 promoter fragment used in Figure 1 (as a control) or with a similar fragment bearing the mutatedSp1p site as labeled probes. Incubation of the labeled probethat bore an intact Sp1p site with Sp1 yielded the same protectedsite on the top (Fig. 5A) and the bottom (Fig. 5B) strandsas that identified previously (Fig. 1) . However, when incubatedwith the labeled probe bearing the mutated Sp1p site, Sp1 couldstill bind, though with a lower affinity, to a stretch of sequencelocated immediately 5' from the Sp1p site to yield visible DNAseI protection (Sp1p_a) on both strands of the labeled probe. Examinationof the Sp1p_a site revealed that it has primarily a GA-rich structure(Fig. 5C) rather than the typical GC- or GT-rich structurenormally found in high-affinity Sp1 sites. Competition experimentsin EMSA were conducted next to more precisely define the affinityof Sp1 toward each target site identified for this transcriptionfactor in the ${alpha}$ 6 promoter. The oligonucleotide bearing the high-affinitybinding site for Sp1 was used as the labeled probe during theseassays (Fig. 6A) . Incubation of crude nuclear proteins frommidconfluent RCECs with the Sp1-labeled probe yielded DNA-proteincomplexes characteristic of Sp1 and Sp3 binding to their GC-richtarget site (Fig. 6B) . Formation of these complexes was almostentirely prevented by the addition of a 50-fold molar excessof the oligonucleotide bearing either the high-affinity Sp1site (Sp1; 86% and 95% reduction of binding at 50- and 100-foldmolar excess, respectively) or that from the ${alpha}$ 6 Sp1 proximalsite (Sp1p; 91% and 94% reduction of binding at 50- and 100-foldmolar excess, respectively). However, neither the Sp1d (41%and 58% reduction of binding at 50- and 100-fold molar excess,respectively) nor the Sp1p_a site (32% and 63% reduction of bindingat 50- and 100-fold molar excess, respectively) was as effectiveas the Sp1p site for competing with the formation of the Sp1/Sp3complexes in EMSA, as revealed by PhosphorImager analysis ofthe Sp1/Sp3 DNA-protein complexes. On average, Sp1d and Sp1p_awere approximately eight times less efficient in competing withthe formation of the Sp1/Sp3 complexes when used at a 100-foldmolar excess than Sp1p. We therefore conclude that Sp1 bindsstrongly to the Sp1p site but only weakly to either the Sp1dor the Sp1p_a site in the ${alpha}$ 6 gene promoter.

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FIGURE 5. DNAse I footprinting of an Sp1 alternative target site on the Sp1p-mutated ${alpha}$ 6 promoter. Recombinant Sp1 (2, 5, or 10 µL) was incubated with the 217-bp ${alpha}$ 6 probe used in Figure 1A , which bears either an intact (wt) or a mutated (mutant) Sp1p site and 5' end-labeled on either the top (A) or the bottom strand (B). DNA-protein complexes were then subjected to DNAse I digestion, and the products were analyzed by gel electrophoresis through an 8% sequencing gel. The position of the promoter proximal Sp1 protected site (Sp1p) identified on the wild-type promoter fragment (wt) is indicated, along with that of an alternative Sp1 target site (Sp1p_a) identified on the labeled probe bearing mutations in the Sp1p site (mutant). G, Maxam and Gilbert G sequencing ladder; C, labeled probe incubated with DNAse I but without recombinant Sp1. (C) Same as in Figure 1C except that the position of the alternative Sp1 site (Sp1p_a) is indicated relative to the ${alpha}$ 6 mRNA start site (identified as +1).

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FIGURE 6. EMSA analysis of Sp1 binding to the Sp1 sites from the ${alpha}$ 6 promoter. (A) DNA sequence of the various Sp1 oligonucleotides used in the EMSA. (B) Crude nuclear proteins (5 µg) from RCECs grown on BSA were incubated with the Sp1-labeled probe either alone (C) or in the presence of double-stranded oligonucleotides bearing the sequence of either the Sp1p or Sp1d sites identified in the ${alpha}$ 6 promoter, or that of the alternative Sp1p_a site, as unlabeled competitors. Oligonucleotides bearing the high-affinity binding sites for the unrelated transcription factors NFI and E2F1 were also used as negative controls for the competition experiment. Formation of the DNA-protein complexes was then monitored by EMSA. The position of the Sp1 and Sp3 complexes is shown. P, labeled probe alone; U, unbound fraction of the probe.

Influence of Laminin on the Activity Directed by the ${alpha}$ 6 Gene Promoter
Increased secretion of LM occurs late in the process of cornealwound healing. It follows that of the temporary FN matrix, whichpeaks a few hours after corneal injury. We demonstrated previouslythat expression of the gene encoding the FN-binding integrinsubunit ${alpha}$ 5 responds positively to the presence of FN when RCECsare grown on FN-coated culture plates.³⁰ We therefore examinedwhether LM could similarly alter the activity directed by the ${alpha}$ 6 gene promoter in vitro in RCECs grown in the presence of LM-coatedculture plates. LM deposition was accomplished after a modeldeveloped by Nguyen et al.⁴² in which culture plates are firstseeded with keratinocytes from the skin that are known for theirability to secrete substantial amounts of LM (predominantlyLM-5).⁴² ⁵⁸ ⁵⁹ ⁶⁰ Keratinocytes were cultured until they reachedvarying cell densities for various periods of time and thenwere removed from the culture plates before their reseedingwith RCECs, which were grown to midconfluence before they weretransfected. As a control, culture plates were also coated with8 µg/cm² FN before seeding with RCECs.

Interestingly, transfection of the ${alpha}$ 6–181 plasmid intoRCECs grown on LM-coated culture plates resulted in repressionof the ${alpha}$ 6 promoter activity; maximum (eightfold) repression wasreached when skin keratinocytes were maintained at after confluencefor 5 days before their removal, though this result cannot beconsidered statistically different from the other conditionsused (Fig. 7A) . On the contrary, transfection of ${alpha}$ 6–181in RCECs that have been grown on FN-coated culture plates resultednot in a reduction but rather in a nearly threefold increasein ${alpha}$ 6 promoter activity (Fig. 7A) . To test whether other typesof LM will trigger different regulatory responses on the ${alpha}$ 6 promoteractivity, we substituted skin keratinocytes with human colonadenocarcinoma Caco-2 cells because these cells were reportedto secrete primarily LM-10.⁴³ As shown on Figure 7B , growingRCECs on LM-10 also resulted in weaker, but significant, repressionof ${alpha}$ 6 promoter function. However, this repression was dependenton the seeding density of RCECs because no repression was observedwhen cells were seeded at 2.5 x 10⁴ RCECs/cm², whereas a 40%reduction was observed at 7.5 x 10⁴ RCECs/cm². Although skinkeratinocytes and Caco-2 cells were shown primarily to secreteLM-5 and LM-10, respectively, in the cell environment, we couldnot exclude the possibility that they may also secrete othercomponents from the ECM. To validate the results obtained withthe keratinocyte- and Caco-2-secreted LMs, RCECs were also grownon culture plates coated with increasing concentrations of acommercial preparation of LM type-1 (LM-1) as a control. Asshown on Figure 7C , LM-1 could also downregulate, though toa much lower level than with LM from skin keratinocytes, theexpression directed by the ${alpha}$ 6 promoter contained on the ${alpha}$ 6–181construct, validating the use of keratinocyte-mediated secretionof LM as a suitable model for the remaining experiments. Extendingthe ${alpha}$ 6 promoter 5' further from position –181 did not resultin any further LM-mediated repression (Fig. 7D) . In addition,deletion of the ${alpha}$ 6 promoter segment located from position –181to –84 (in plasmid ${alpha}$ 6–84) had no influence on therepression by LM, suggesting that LM-responsive sequences arelocated somewhere between the ${alpha}$ 6 mRNA start site and position–84.

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FIGURE 7. Transfection of the ${alpha}$ 6 promoter in RCECs and HCECs grown in the presence of LM. LM-producing dermal keratinocytes (A) or colon carcinoma Caco-2 cells (B) were grown to 30%, 70%, or 100% cell density for 1, 3, 5, and 10 days (for skin keratinocytes) or to 100% confluence for 25 days (for Caco-2). Keratinocytes and Caco-2 cells were then completely removed, and the culture plates were immediately reseeded with RCECs (2.5 x 10⁴/cm² on LM from skin keratinocytes and 2.5 x 10⁴, 5 x 10⁴, and 7.5 x 10⁴/cm² on LM from Caco-2 cells) that were grown to midconfluence before transfection with the recombinant plasmid ${alpha}$ 6–181. Negative controls (–LM) correspond to RCECs seeded on culture plates coated with BSA. CAT activities were measured and expressed relative to the level directed by ${alpha}$ 6–181 transfected in cells grown without LM. SD is also provided. (C) RCECs were plated on culture plates coated with BSA (used as a negative control; –LM) or with varying concentrations of a commercial preparation of LM type 1 (0.5–8 µg/cm²) before transfection with the plasmid ${alpha}$ 6–181, as in panel (A). (D) Dermal keratinocytes were grown on culture plates until they reached 100% confluence for 5 days and then were completely removed. Culture plates were reseeded with RCECs before they were transfected with the recombinant plasmids ${alpha}$ 6–84, ${alpha}$ 6–141, ${alpha}$ 6–181, ${alpha}$ 6–352, ${alpha}$ 6–430, and ${alpha}$ 6–590. CAT activities were measured and normalized as in Figure 2 and are expressed relative to the level directed when transfected in RCECs without LM. (E) Same as in panel (D), except that LM-coated plates were reseeded with RCECs (as a control) and HCECs at P2 or P3 before transfection with the ${alpha}$ 6–181 recombinant construct. As negative controls, RCECs and HCECs were also seeded on BSA before transfection with ${alpha}$ 6–181 (–LM).

To exclude the possibility that the LM-mediated negative influenceon the ${alpha}$ 6 promoter might be typical only of RCECs, similar experimentswere conducted on human corneal epithelial cells cultured fromthe corneal limbus obtained from the eyes of a healthy donor(HCECs) and grown to either passage (P) 2 or P3. As with RCECs,LM resulted in a severe downregulation of ${alpha}$ 6 promoter activityin HCECs (Fig. 7E) . However, the amplitude of this LM-mediatedrepression varied considerably with the number of passages reachedby these cells. Indeed, a dramatic 25-fold reduction of ${alpha}$ 6 promoterfunction was observed when P2 HCECs were grown on LM. However,expanding these cells for one more passage, at P3, considerablyreduced the amplitude of this repression to fivefold, consistentwith the abrupt terminal differentiation observed in HCECs;most of them cannot be cultured beyond P3 or P4.³⁷ ³⁸

Laminin Alters the Nuclear Level of Sp1 and Sp3 in RCECs
After we established that Sp1 and Sp3 contribute to the transcriptionof the ${alpha}$ 6 gene by interacting with proximal and distal Sp1p andSp1d sites, respectively, we reasoned that LM may exert itsrepressive influence by altering the nuclear level of each transcriptionfactor. Crude nuclear extracts were obtained from RCECs grownto midconfluence (near 80% coverage of the plate) on cultureplates coated with BSA (which is used as a negative control)or with LM and were examined in EMSA for their ability to sustainthe binding of both Sp1 and Sp3 to a labeled probe bearing ahigh-affinity target site for these transcription factors. Asshown on Figure 8A , shifted DNA-protein complexes with electrophoreticmobilities identical to those reported for Sp1 and Sp3 couldeasily be observed in the nuclear extract from RCECs grown solelyon BSA (–LM). Specificity of the formation of these complexeswas further confirmed through competition experiments in EMSA.Indeed, only the unlabeled Sp1 oligonucleotide, but not theoligomers bearing the target sites for the unrelated transcriptionfactor NFI or AP-1, could compete for the formation of the Sp1/Sp3complexes (Fig. 8A , right). The identity of the nuclear proteinsyielding these complexes as Sp1 and Sp3 was further verifiedby supershift experiments in EMSA. As shown on Figure 8B (left,–LM), adding a polyclonal antibody directed against Sp1dramatically reduced the formation of the slowest shifted complexon gel without altering that of the faster migrating complex.On the other hand, adding an Sp3 polyclonal antibody reducedthe formation of the slow-migrating complex but totally preventedthe formation of the faster one. Both antibodies generated slow-migrating,supershifted complexes (SCs) that corresponded to the recognitionof the Sp1 or the Sp3 protein component from the DNA-proteincomplexes detected on the gel by the Sp1 and Sp3 antibodies,respectively. These results suggest that Sp1 and Sp3 are constituentsof the more intense, slow-migrating complex seen in EMSA, whereasthe less intense, faster migrating complex is exclusively constitutedof Sp3 bound to the labeled probe. Both the slow- and the fast-migratingcomplexes disappeared when incubated along with both the Sp1and the Sp3 antibodies (Sp1/Sp3Abs; Fig. 8B , left).

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FIGURE 8. Expression of Sp1 and Sp3 in RCECs grown on LM and FN. (A) EMSA analysis of Sp1 binding in RCECs cultured on LM-coated plates. Crude nuclear proteins (5 µg) from RCECs grown on BSA (–LM) or LM-coated culture plates (precultured with skin keratinocytes for 5 days before removal; +LM) were incubated with the Sp1-labeled probe (left). Where indicated, double-stranded oligonucleotides bearing high-affinity binding sites for the transcription factors Sp1, NFI, and AP-1 were added as unlabeled competitors (right). Formation of the DNA-protein complexes was then monitored by EMSA. The position of the Sp1 and Sp3 complexes is shown. P, labeled probe alone; U, unbound fraction of the probe. (B) Supershift analysis in EMSA. Nuclear proteins from RCECs grown on BSA (–LM) or on LM (+LM) were incubated with the Sp1-labeled probe in the presence of antibodies directed against Sp1 or Sp3, either individually (Sp1Ab, Sp3Ab) or in combination (Sp1/Sp3Abs). Positions of the Sp1 and Sp3 DNA-protein complexes were then revealed by EMSA, as in panel (A). SC, supershifted complexes of low electrophoretic mobility that correspond to the binding of the Sp-antibodies to the Sp1- and Sp3-DNA complexes; C, positive control in which the labeled probe was incubated with proteins but without antibodies. (C) Comparative influence of the ECM components LM and FN on the DNA-binding properties of Sp1/Sp3. Nuclear proteins (5 µg) from RCECs grown on BSA (–FN or –LM) or on culture plates coated with either LM (+LM) or FN (+FN) were incubated with the Sp1-labeled probe before analysis of the complexes formed by EMSA. (D) Approximately 30 µg nuclear proteins from the extracts used in (C) were examined in Western blot analyses using the Sp1 and Sp3 antisera. Positions of the molecular mass markers are shown.

To eliminate the possibility that the LM influence on Sp1 mighthave resulted from a sporadic event, crude nuclear extractswere prepared from RCECs grown to midconfluence on either LM-or FN-coated culture plates as a control. As shown on Figure 8C (left), recognition of the Sp1-labeled probe by both Sp1 andSp3 was substantially increased in RCECs grown in the presenceof FN, as previously reported.³⁰ On the other hand, bindingof both these proteins was again dramatically reduced when cellswere grown on LM-coated culture plates (Fig. 8C , right). Westernblot analyses were then conducted to discern whether these alterationsin the ability of Sp1 to recognize its target probe when cellswere grown on FN or LM resulted from changes in the affinityof these proteins toward their target sites or from correspondingalterations in the total amount of each individual protein.As we previously reported,³⁰ culturing cells on FN did notchange the amount of Sp1 or Sp3 proteins expressed by RCECs,a clear indication that alterations in the affinity of Sp1 andSp3 toward their target site accounted for the increased bindingof Sp1/Sp3 observed in EMSA (+FN; Fig. 8D ). However, culturingRCECs in the presence of LM caused a dramatic reduction in thenuclear concentration of Sp1 and Sp3 (+LM; Fig. 8D ) that correlatedperfectly with the reduced binding observed in EMSA for boththese proteins. These results are consistent with the reduced ${alpha}$ 6 promoter activity observed in RCECs when cells were grownon LM-coated culture plates (Fig. 7) .

To determine whether the LM-mediated repression of the ${alpha}$ 6 promoteralso translated to similar alterations in the expression ofthe endogenous ${alpha}$ 6 mRNA transcript, semiquantitative RT-PCR analyseswere conducted. To eliminate the possibility that saturationof the PCR reaction is reached, amplifications were performedat 24, 26, 28, 30, 32, and 34 cycles. The specific ${alpha}$ 6 PCR productbecame detectable on gel after 24 cycles of amplification. Itsformation happened to be nonlinear at 30 cycles and reachedcomplete saturation after 32 cycles. PCR amplification of the ${alpha}$ 6 product remained fairly linear from 26 to 30 cycles of amplification(data not shown). As shown on Figure 9A , PCR amplificationusing both ${alpha}$ 6 primers yielded a single ${alpha}$ 6 DNA fragment of thecorrect size (210 bp) when total RNA was extracted from RCECsgrown on BSA (only the result at 28 cycles of PCR amplificationis shown). However, a significant reduction was observed whentotal RNA was obtained from cells grown on LM-coated cultureplates. We then isolated total RNA from RCECs grown on eitherBSA or LM and examined the ${alpha}$ 6 mRNA transcript by Northern blotanalysis. As shown on Figure 9B , a single mRNA species of approximately5.5 kb that perfectly matched the size previously reported forthe major ${alpha}$ 6 mRNA transcript²² was observed just below the 18SrRNA. As with RT-PCR, expression of the ${alpha}$ 6 transcript was considerablyreduced when RNA was isolated from RCECs grown on LM, on normalizationto GAPDH.

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FIGURE 9. Influence of LM on the expression of the ${alpha}$ 6 mRNA transcript. (A) Total RNAs extracted from RCECs grown on BSA (–LM) or on LM-coated culture plates (+LM) were reverse transcribed and PCR amplified using synthetic, oligonucleotide primers specific to both the ${alpha}$ 6 and 18S ribosomal RNAs. Positions of the amplified 210-bp ${alpha}$ 6 ( ${alpha}$ 6) and the 489-bp 18S fragments (18S) is indicated along with that of the most relevant markers (left). (B) Total RNA preparations used in (A) were subjected to analyses by Northern blot. Positions of the ${alpha}$ 6 5.5-kb mRNA is indicated, along with that of the 28S ribosomal RNA. As a control, the membrane was also hybridized with a 548-bp HindIII-XbaI fragment digested from the human glyceraldehyde-3-phosphate-dehydrogenase (GAPDH) cDNA and used as a labeled probe for normalization of the ${alpha}$ 6 mRNA signal to that corresponding to GAPDH (1.2 kb).

As a further support of our in vitro results, binding of Sp1and Sp3 was also examined in vivo by the ChIP assay on HCECscultured on BSA or LM-coated culture plates (+LM). As additionalcontrols, ChIP was also conducted on other transcription factors,such as NFI and E2F1, of which some (E2F1) are suspected tobind the ${alpha}$ 6 promoter.⁶¹ Antibodies against these transcriptionfactors all enriched the ${alpha}$ 6 promoter sequences in HCECs, indicatingthat they are bound to this genomic area in vivo (Fig. 10A). However, among them, the signal obtained with the Sp3 antibodyclearly predominated. When ChIP was conducted on cells grownon LM, all four proteins again enriched the ${alpha}$ 6 promoter but withsignal intensities different from HCECs grown on BSA. Indeed,normalization of the PCR amplification products resulting fromthe ${alpha}$ 6 promoter segment immunoprecipitated by each antibody tothe input chromatin control indicated a clear reduction in thebinding of Sp3 and E2F1 and a tendency of Sp1 to decrease aswell when cells were grown on LM (Fig. 10B) . Occupancy of the ${alpha}$ 6 promoter by NFI in relation to the "input" was not alteredby growing cells on LM.

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FIGURE 10. In vivo ChIP analysis on the ${alpha}$ 6 promoter. (A) ChIP assays were performed on HCECs grown on either BSA or LM. Chromatin was isolated and immunoprecipitated with antibodies directed against the transcription factors Sp1, Sp3, NFI, and E2F1. PCR of the ${alpha}$ 6 (ITGA6) gene promoter was then carried out on the ChIP samples, along with a "no antibody" control (No Ab) that contains chromatin but no antibody, an "input" sample corresponding to 0.2% of the total input chromatin, and a "mock" sample that does not contain chromatin. PCR amplification of a gene segment located approximately 2000 bp upstream of the p21 promoter was also conducted on the same sample as a negative control for all immunoprecipitates. (B) Graph representing the amount of specific PCR products expressed as the percentage of antibody binding versus the amount of PCR product obtained using a standardized aliquot of input chromatin. The signal in the no-antibody lane corresponds to the nonspecific binding background and was subtracted from each sample.

	Discussion

Top Abstract Materials and Methods Results Discussion References

Tissue repair requires the adhesion of proliferating cells tothe basement membrane and cell migration to cover the wound.⁶² The way wound healing of the corneal epithelium proceeds isbasically the same for every type of tissue epithelium (fora review, see Midwood et al.⁶³ ). In this study, we investigatedthe functions of Sp1 and Sp3 in the transcription of the LM-binding ${alpha}$ 6 integrin subunit gene in various primary cultured and establishedtissue culture cells. Both transcription factors were foundto contribute in varying degree to the transcription of the ${alpha}$ 6 gene by interacting with two distinct target sites, Sp1p andSp1d, along the promoter of the ${alpha}$ 6 gene. Most of all, culturingRCECs in the presence of LM caused a substantial reduction inthe expression directed by the ${alpha}$ 6 promoter that resulted froma coordinated reduction in the level of expression of Sp1 andSp3 in these cells.

Sp1 is the founding member of a Zn-finger family of transcriptionfactors, the Sp family, which now includes nine Sp genes (Sp1-Sp9;for a review, see Zhao and Meng⁶⁴ ). Sp1 is of a particularinterest as its GC-rich target site is found in a very largenumber of eukaryotic genes, including many integrin subunitgenes (for further details, see Zaniolo et al.⁶⁵ ). Consequently,Sp1 is likely to mediate some, if not most, of the regulatoryinfluences the many ECM components exert on the transcriptionof the integrin subunit genes. By exploiting in vitro DNAseI footprinting, two target sites for Sp1 and Sp3 were identifiedalong the human ${alpha}$ 6 promoter; a proximal site (Sp1p, centeredat position –50) located near the mRNA start site anda more distant site (Sp1d, centered at position –205).The position of the proximal Sp1 site identified in this study(–38 to –62) is consistent with that previouslyreported for this transcription factor,³¹ unlike the distalsite, which has never before been reported. However, the affinityof Sp1 for this more distantly located target site proved tobe eightfold lower than that of the proximal site, and its mutationalone had little influence on the basal promoter function inmost types of transfected cells. On the other hand, when theSp1p site was mutated in the shorter ${alpha}$ 6 promoter-bearing construct ${alpha}$ 6–84, dramatic reductions in basal promoter activity wereobserved in all types of cells. However, its mutation had marginalinfluence considering the longer construct that included anintact Sp1d site (in ${alpha}$ 6–352). It was only when both Sp1sites were mutated that a substantial reduction in ${alpha}$ 6 promoteractivity was observed in all types of cells, indicating thatboth Sp1 sites are redundant with each other. Yet, despite themutation of both Sp1 sites, basal ${alpha}$ 6 promoter activity remainedrelatively high in most types of cells. Remarkably, when theproximal site was mutated, Sp1 was found to bind with a loweraffinity to an alternative target site located immediately 5'of Sp1p. Examination of this sequence revealed that it containsa GA- and a GT-rich sequence. Sp1 and Sp3 have been reportedto bind to GC-, GT-, or GA-rich target sites with nearly thesame affinity⁶⁶ and are therefore likely to bind the alternativeSp1p_a GT- or GA-rich Sp1 sites identified in the ${alpha}$ 6 basal promoter.Use of an alternative degenerated site by Sp1 may explain theresidual promoter activity observed despite that both the Sp1pand the Sp1d sites were mutated in the ${alpha}$ 6–352 construct.This constitutes a noteworthy evolutionary advantage for Sp1.Its ability to bind and use alternative low-affinity bindingsites would ensure the maintenance of a minimal promoter activitywhen high-affinity sites are lost during the course of evolution.

Dramatic differences were observed in the level of ${alpha}$ 6 expression(evaluated by FACS analyses) and ${alpha}$ 6 promoter activity betweenprimary cultured RCECs and HSKs, both of which expressed ${alpha}$ 6 tohigh levels, and HSFs, which barely directed any promoter activityat all (5755- and 5025-fold lower than in RCECs and HSKs, respectively,with the ${alpha}$ 6–352 construct). These results are consistentwith basal corneal epithelial cells and skin keratinocytes,two epithelial-type cells, expressing high levels of the ${alpha}$ 6 integrinsubunit while stromal fibroblasts from the cornea do not.⁹ ²³³⁸ ⁶⁰ ⁶⁷ ⁶⁸ ⁶⁹ ⁷⁰ ⁷¹ By exploiting primary RCEC cultures tostudy the influence played by the ECM on the expression of integrinsubunit genes, we previously reported dramatic increases inthe activity directed by the promoter of the ${alpha}$ 4 and ${alpha}$ 5 integrinswhen these cells are grown in the presence of FN.³⁰ ⁷² In additionto ${alpha}$ 4 and ${alpha}$ 5, FN considerably increased (by approximately fivefold)the activity of the ${alpha}$ 6 promoter in in vitro cultures of RCECs(Fig. 7A) , consistent with the results reported by Grushkin-Lerneret al.²² Interestingly, human LM did not increase but ratherreduced to various degrees the expression of the ${alpha}$ 6 promoter(and that of the ${alpha}$ 4 and ${alpha}$ 5 integrin gene promoters⁷² ), irrespectiveof whether corneal epithelial cells were primary cultured fromrabbit or human eyes. Differences in the strength of LM repressionbetween keratinocyte-secreted LM and commercially produced LM-1may reside in the fact that skin keratinocytes primarily secretetype 5 LM, which is also the major LM isoform secreted duringcorneal wound healing. Binding of Sp1 and Sp3 to the ${alpha}$ 6 promoterprimarily accounts for its transcription in the many types ofcells transfected in the present study. Surprisingly, culturingRCECs in the presence of LM resulted in a reduction in Sp1 bindingcaused by a corresponding decrease in its expression at theprotein level. The appearance of faster migrating DNA-proteincomplexes in EMSA (Figs. 8A 8B 8C , +LM) and much smaller proteinproducts in Western blot (Fig. 8D , +LM), when cells are grownon LM but not on FN or BSA, indicate that both fac

Laminin Reduces Expression of the Human 6 Integrin Subunit Gene by Altering the Level of the Transcription Factors Sp1 and Sp3

Laminin Reduces Expression of the Human ${alpha}$ 6 Integrin Subunit Gene by Altering the Level of the Transcription Factors Sp1 and Sp3