Tài liệu Báo cáo khoa học: Fra-1 targets the AP-1 site/2G single nucleotide polymorphism (ETS site) in the MMP-1 promoter docx

In this study we demonstrate that the expression of Fos-like region antigen Fra-1, an AP-1 transcription factor component that also correlates strongly with neo-plastic disease, is neces

Fra-1 targets the AP-1 site/2G single nucleotide polymorphism

(ETS site) in the MMP-1 promoter

Grant B Tower1,*, Charles I Coon2, Karine Belguise3, Dany Chalbos3and Constance E Brinckerhoff1,2 Department of1Biochemistry and2Medicine at Dartmouth Medical School, Hanover, NH, USA;3Institut National

de la Sante´ et de la Recherche´ Me´dicale, Endocrinologie Moleculaire et Cellulaire des Cancers, Montpellier, France

The matrix metalloproteinase (MMP) family degrades the

extracellular matrix One member of this family, MMP-1,

initiates the breakdown of interstitial collagens The

expression of MMP-1 is controlled by the mitogen activated

protein kinase (MAPK) pathway(s) via the activity of

acti-vator protein-1 (AP-1) and polyoma enhancing activity-3/

E26 virus (PEA3/ETS) transcription factors through

con-sensus binding sites present in the promoter Another ETS

site in the MMP-1 promoter is created at)1607 bp by a

single nucleotide polymorphism (SNP), which contains two

guanines (5¢-GGAT-3¢; Ô2G SNPÕ), rather one guanine

(5¢-GAT-3¢; Ô1G SNPÕ), adjacent to an AP-1 binding site at

)1602 bp The 2G SNP displays greater transcriptional

activity than the 1G SNP, and AP-1 and Ets families of

transcription factors cooperate to increase transcription The

2G SNP has been linked to the incidence and the progression

of several cancers and is also associated with non-neoplastic diseases; although the underlying mechanism(s) has yet to be elucidated In this study we demonstrate that the expression

of Fos-like region antigen (Fra-1), an AP-1 transcription factor component that also correlates strongly with neo-plastic disease, is necessary for MMP-1 transcription in A2058 melanoma cells The inhibition of Fra-1 expression preferentially downregulates transcription from the MMP-1 promoter DNA containing the 2G SNP, compared to DNA containing the 1G SNP This study provides evidence that,

in cooperation with the 2G DNA polymorphism, the AP-1 family member, Fra-1, contributes to the high constitutive expression of MMP-1 in melanoma cells

Keywords: antisense; MAPK; matrix metalloproteinase; melanoma and metastasis; signal transduction

The extracellular matrix (ECM) acts as a structural support

network within tissues and as a barrier to cell migration

Additionally, the destruction of the ECM can regulate

disease progression and severity in a variety of pathological

situations [1–3] The matrix metalloproteinase (MMP)

family is responsible for degradation of the ECM, and the

MMP subfamily of collagenases specifically cleaves the

interstitial collagens (types I, II and III) MMP-1 is a

collagenase that is expressed at very low levels in normal

physiological situations, and expression can be increased

transiently when remodeling of the ECM is required (e.g

wound healing, uterine resorption and development)

However, in many pathological states, MMPs are expressed

at high levels This is due to continuous induction by external stimuli, as seen in rheumatoid arthritis and athlerosclerosis, or to constitutive expression because of

an activating mutation in a regulatory pathway [4–7] High constitutive levels of MMP-1 correlate with a poor prog-nosis in many types of cancer [8–10]

The mitogen activated protein kinase (MAPK) signaling pathway is composed of four main cascades, three of which are known to control the expression of MMP-1 They are the extracellular response kinase (ERK 1/2), the p38 and the Jun N-terminal kinase, and they activate factors that target multiple activator protein-1 (AP-1) and polyoma enhancing activity-3/E26 virus (PEA3/ETS) factor binding sites within the MMP-1 promoter [11–16] These families of transcrip-tion factors act synergistically when AP-1 and ETS consensus sites are located in proximity to one another [17,18], such as the AP-1/ETS site located at)73/)88 bp in the MMP-1 promoter [19]

We have described a single nucleotide polymorphism (SNP) at)1607 bp that generates an additional ETS site when two guanines (5¢-GGAT-3¢; Ô2G SNPÕ) are present instead of one guanine (5¢-GAT-3¢; Ô1G SNPÕ) (Fig 1), and this SNP results in increased transcription from the 2G-containing promoter relative to the 1G-containing promoter [20,21] We have verified this ETS site by demonstrating that it binds recombinant Ets-1 protein, and that the adjacent AP-1 site at)1602 bp binds recom-binant c-Jun Further, we carried out gel shift analyses with nuclear extracts from A2058 melanoma cells and

Correspondence to C E Brinckerhoff, Department of Biochemistry,

505 Vail Building, Hanover, NH 03755, USA.

Fax: + 1 603 650 1128, Tel.: + 1 603 650 1609,

E-mail: brinckerhoff@dartmouth.edu

Abbreviations: MMP, matrix metalloproteinase; MAPK, mitogen

activated protein kinase; AP-1, activating protein; PEA3/ETS,

poly-oma enhancing activity-3/E26 virus; FGF, fibroblast growth factor;

SNP, single nucleotide polymorphism; ERK, extracellular response

kinase; Fra, Fos-related antigen; Elf, ETS-like factor; DMEM,

Dulbecco’s Modified Eagles Medium; CMV, cytomegalovirus;

GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

*Present address: Schering-Plough, 2015 Galloping Hill Rd., K-15,

D-129C Kenilworth, NJ 07033, USA.

(Received 11 June 2003, revised 4 September 2003,

accepted 8 September 2003)

competition experiments with AP-1 and PEA3

oligonucleo-tides to show specificity of binding [20]

Several studies correlate the presence of the 2G SNP

with invasive cancers, including melanoma [22,23], and

colorectal [24–26], lung [27], endometrial [28] and ovarian

cancers [29,30] The 2G polymorphism is also associated

with non-neoplastic diseases, such as premature rupture of

fetal membranes [31], increased risk of internal carotid

artery stenosis [32], rate of decline in lung function [33],

lower bone mineral density [34] and increased severity of

chronic periodontitis [35] These studies support the

hypothesis that the 2G polymorphism may increase

expression from the MMP-1 promoter and influence the

degree of pathology resulting from dysregulated matrix

degradation However, the mechanisms mediating the

increase in MMP-1 from the 2G promoter have not been

elucidated We have previously described one mechanism

responsible for the increase in expression from the

2G-containing promoter in A2058 melanoma cells, which

constitutively express copious amounts of MMP-1 [15] In

this system, we determined by means of transient

transfec-tions with MMP-1 reporter constructs, that the MAPK

pathway, ERK 1/2, targets the 2G SNP at)1607 bp and

the adjacent AP- 1 site at )1602 bp Activation and/or

production of transcription factors binding to these sites

are responsible for the elevated expression of MMP-1 from

the 2G allele compared to that from the 1G allele [15]

However, it is likely that other mechanisms exist, which

may also influence this response

Our previous study showed that the chemical inhibitors

PD098059 and U0126 blocked the phosphorylation of

ERK1/2 and reduced expression of MMP-1 mRNA [15]

We also determined that continuous synthesis of new

proteins is necessary for MMP-1 expression [15] and that

the levels of these proteins are decreased when ERK 1/2

signaling is disrupted by PD098059 Since the expression

and the mRNA stability of the AP-1 family member Fra-1 is

dependent on ERK activity [36], we hypothesized that Fra-1

may be produced by A2058 cells, that it may be necessary

for MMP-1 gene expression, and that it may be reduced by

PD098059

Fra-1 has been implicated in the regulation of MMP-1 [37–40], MMP-13 [41,42] and the urokinase plasminogen activator receptor [43], a receptor in the fibrinolytic cascade that activates MMPs Fra-1 is necessary for the induction of MMP-1 by mitogens [44,45] and it binds to the AP-1 responsive element in the proximal promoter [39,46] As the ERK pathway often regulates induction of the mitogen, fibroblast growth factor (FGF), which induces expression of MMP-1, Fra-1 may contribute to the transcriptional regulation of both FGF and MMP-1 Indeed, FGF responsiveness in the MMP-1 promoter requires both the AP-1 and ETS sites within a 63-bp region, from)123 bp to )61 bp, to which Fra-1 binds [39] These studies have suggested that Fra-1 interacts with Ets transcription factors

to induce MMP-1 gene expression The present study extends these findings to include a role for Fra-1 in augmenting MMP-1 transcription from the AP-1 site at )1602 bp and the 2G SNP (ETS site) at )1607 bp

Materials and methods

Cell culture Stock cultures of A2058 melanoma cells were grown in 150-mm culture plates in Dulbecco’s Modified Eagles Medium (DMEM) containing 10% fetal bovine serum,

L-glutamine, and penicillin/streptomycin (37C, 5% CO2), and passaged at confluency [20] For most experiments, confluent cultures of cells were washed twice with Hanks balanced salt solution to remove traces of serum and cultured in serum-free DMEM and 0.2% lactalbumin hydrolysate Cells were treated with increasing concentra-tions of PD098059 (Calbiochem), an inhibitor of the ERK 1/2 pathway, solubilized in dimethyl sulfoxide Electrophoresis mobility shift assay (EMSA) Nuclear extracts were prepared from untreated A2058 cells,

or from cells treated with PD098059 [20] Oligonucleotide probes containing 35 or 36 bp from regions of the MMP-l promoter encompassing the lG/2G site at)1607 bp and the AP-1 site at )1602 bp, from )1621 bp to )1586 bp [20], were end-labeled with [32P]dATP[cP] by T4 Kinase (Gibco/ BRL) in 1· polynucleotide kinase buffer (Roche) and

2· 106c.p.m were incubated with 5 lg of nuclear extract for 20 min at 4C This amount was needed for probe excess with the 2G oligonucleotide Lesser amounts showed depletion of free probe at the bottom of the gel Binding reactions were separated on 7% Tris/glycine polyacrylamide gels and visualized by autoradiography

Transient transfection and luciferase assay One microgram of 4372 bp of the MMP-l promoter DNA containing either 1G or 2Gs at )1607 bp, linked to the luciferase reporter, was transiently transfected into cells using Geneporter (Gene Therapy Systems) To further elucidate the role of AP-1 sites in the MMP-1 promoter, reporter constructs containing mutations in selected AP-1 sites were used [15,20] To alter the expression levels of Fra-1, expression constructs containing the Fra-1 cDNA

in the sense and antisense orientation driven by the

Fig 1 Diagram of the MMP-1 promoter region spanning the region

from )1585 bp to )1620 bp The 1G SNP DNA contains an AP-1

consensus at )1602 bp, and the sequence 5¢-GAA-3¢ at )1607 bp The

2G SNP DNA has the AP-1 site at )1602 bp and the sequence

5¢-GGAA-3¢ at )1607 bp, conferring a consensus ETS site.

cytomegalovirus (CMV) minimal promoter in a pCl vector

[47] as well as empty vector to keep the DNA concentration

constant, were used Twenty-four hours post-transfection,

cells were washed and incubated with serum free medium,

with or without 5 lM PD098059 for 24 h and cell lysates

were then assayed for luciferase activity in a luminometer

All transfections were carried out in triplicate Disparities in

relative light unit (RLU) values among different

experi-ments are due to the use of different luminometers

Northern blot analyses

Total RNA (10 lg) was harvested from cells with Trizol

(Gibco) and separated on a 5% formaldehyde, 1% agarose

gel, transferred to a GeneScreen membrane (NEN Life

Sciences) and probed with a32P-labelled cDNA for MMP-1

[47], c-Fos (a generous gift from I Verma, the Salk Institute,

La Jolla, CA, USA) and Fra-1 The Fra-1 probe was

created by PCR, using primers to amplify a region unique

to the transcript The forward primer for Fra-1 was

5¢-TCTGGGCTGCAGCGAGAGATTGAGGAG-3¢ and

the reverse primer was 5¢-GGAGGAGACATTGGC

TAGGGTGGCATC-3¢, giving a product of 435 bp PCR

reactions were separated on a 1.5% agarose gel by

electrophoresis; the band of the correct size was excised

and purified The purified PCR fragment was labeled with

[32P]dCTP[aP] for probing Levels of

glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNA probed

with a32P-labelled cDNA controlled for loading

Western blot analysis

Whole cell lysates were harvested by mechanical scraping

and collected with 2· SDS buffer [15] Proteins were

separated on 10% Tris/HCl Ready Gels (Bio-Rad) and

transferred to ImmobilonTM-P poly(vinylidene difluoride)

membranes (Millipore) All membranes were blocked in 5%

dry milk (Carnation) at room temperature for 1 h Blots

were probed with antibodies against Fra-1, JunD, c-Fos,

Ets-1, Ets-2, and ETS-like factor (Elf-1; Santa Cruz, Inc.,

Santa Cruz, CA, USA) overnight at 4C, as suggested by

manufacturer Blots were then incubated with an anti-rabbit

horseradish peroxidase-linked secondary antibody (Cell

Signaling, Beverly, MA, USA) at a dilution of 1 : 2000 at

room temperature for 1 h Bands were visualized by

electro-chemiluminesence The membranes were stripped as

des-cribed in [48] and reprobed with an antibody against actin

(Oncogene, Boston, MA, USA) for 1 h at room

tempera-ture Blots were subsequently probed with an anti-goat IgM

secondary antibody (Oncogene) at a dilution of 1 : 2000 for

1 h at room temperature Bands were visualized by

electro-chemiluminesence

Results

Increasing concentrations of the ERK specific inhibitor,

PD098059, lead to a decrease in protein binding to the 2G

SNP Our earlier studies demonstrated that the 2G SNP

functioned as a bone fide ETS site, as measured by

competition experiments and by the specific binding of

recombinant Ets-1 protein [20] Further, treatment of A2058

melanoma cells with the chemical inhibitor PD098059

blocked the phosphorylation of ERK 1/2 and reduced MMP-1 mRNA [15] This reduction in MMP-1 mRNA occurred at the level of transcription, was greater in the 2G SNP-containing promoter than in the 1G SNP-containing promoter, and required the AP-1 site at )1602 bp [15] Therefore, we hypothesized that this inhibition may be a consequence of reduced binding of nuclear proteins to the AP-1 site and SNP at)1602 bp and )1607 bp, respectively

We tested this hypothesis with an EMSA, using a 35/36 bp nucleotide probe containing either 1G or 2Gs and nuclear extracts from untreated cells or from cells treated with PD098059 for 24 h Figure 2 illustrates that extracts from untreated cells bind to both the 1G and 2G probes In agreement with previous data [20,49], the binding to the 2G probe is greater than to the 1G probe, with a 2G specific band, indicated by a star Treating cells with increasing concentrations of PD098059 results in a decrease in the intensity and/or a complete disappearance of some bands, indicated by arrows In contrast, bands that are more intense in the lanes containing the 1G probe appear unchanged in the presence of the inhibitor (–) Thus, a decrease in the expression of MMP-1 in the presence of PD098059 may be due, at least in part, to a decrease in the binding of transcription factors to the MMP-1 promoter

Fig 2 Effects of the MEK/ERK inhibitor PD098059 on transcription factor binding EMSA of transcription factors binding to [ 32 P]dATP[cP] end-labeled 35- and 36-mer, 1G and 2G (respectively) oligonucleotides

in the presence of increasing concentrations of PD098059 for 24 h Lanes 1 and 2, free probe alone; lanes 3 and 4, extract from cells incubated in serum-free media alone; lanes 5–8, extract from cells incubated in the presence of 5 l M (5 and 6) and 10 l M (7 and 8) PD098059 *, 2G specific band; fi , inhibitable activities that bind 2G

to a greater extent; –, bands with greater affinity to 1G and not inhibited

by PD098059 EMSA was performed four times for reproducibility.

region containing the AP-1 site at)1602 bp and the 2G

SNP at)1607 bp

Fra-1 protein is decreased in response to PD098059

Previously, we demonstrated that recovery of MMP-1

mRNA expression after inhibition by PD098059 in A2058

melanoma cells required de novo protein synthesis [15] This

finding, together with the data in Fig 2, led us to

hypothesize that inhibition of the MEK/ERK pathway by

PD098059 may decrease the level of a transcription factor(s)

required for MMP-1 expression and may explain the

decrease in protein binding to the AP-1/2G site Therefore,

to determine which factors in the AP-1 or Ets family might

be downregulated, we compared protein levels of AP-1/Ets

family members in cells left untreated or treated for 24 h

with increasing concentrations of PD098059 Western blot

analysis showed that in A2058 cells, c-Fos, Fra-1, and JunD

of the AP-1 family and Ets-1, Ets-2 and Elf-1 of the Ets

family are expressed constitutively (Fig 3A, and data not

shown) We could not detect Fra-2 Fra-1 levels were downregulated in response to PD098059 (Fig 3A) The two bands in Fig 3A represent the phosphorylated protein (upper band) and the nonphosphorylated form (lower band) of Fra-1 Both forms of the protein are decreased by PD098059 treatment, suggesting that levels

of Fra-1 protein and its subsequent phosphorylation are mediated by the ERK pathway We found that c-Fos was also downregulated by PD098059, but its level of expres-sion was very low (data not shown) Thus, Fra-1 is the principal Fos family member expressed in these cells Further, while c-Fos expression can be regulated by many pathways [50,51], Fra-1 mRNA synthesis is solely regu-lated by the ERK 1/2 pathway [36,52–55] Since MMP-1 expression in these cells is unaffected by other signal transduction inhibitors [15], it is likely that Fra-1 is the dominant Fos family member involved in constitutive MMP-1 expression in these cells Therefore, we have focused on the possible role of Fra-1 in the transcription

of MMP-1

Fra-1 mRNA is reduced in response to PD098059 prior

to inhibition of MMP-1 gene expression

To ascertain whether there is a correlation between Fra-1 and MMP-1 expression, dose–response and time-courses comparing the inhibition of Fra-1 and MMP-1 mRNAs were performed Fra-1 has two mRNA transcripts, with the 1.7-kb transcript being dominantly expressed compared to the 3.3-kb transcript, which results from an extended 3¢ untranslated region [56], presumably due to an alternative polyadenylation site Since both transcripts are presumed to encode the Fra-1 protein [56], whether the reduction of one transcript precedes the other or is more completely down-regulated may be unimportant The dose–response for inhibiting Fra-1 and MMP-1 gene expression was similar, with complete inhibition of MMP-1 mRNA and the 3.3-kb transcript of Fra-1 at 5–10 lMPD098059 and substantial inhibition of the 1.7-kb Fra-1 transcript with 10 lM PD098059 (Fig 3B)

For the time-course experiment, A2058 cells were either left untreated or treated with PD098059 (5 lM) RNA was harvested immediately after addition of PD098059 (time zero), and at subsequent time points for measurement of Fra-1 and MMP-1 mRNA The level of the 3.3-kb transcript of Fra-1 began to decrease within 1 h of treatment, and was undetectable by 6 h Reduction of the 1.7-kb transcript lagged behind the 3.3-kb transcript, beginning at 2 h and reaching maximal inhibition by 4 h This reduction of the Fra-1 transcript preceded that of MMP-1 mRNA, which began at 4 h and was nearly complete by 10 h (Fig 4) The increase in MMP-1 mRNA levels in untreated cultures beginning at 4 h has been observed previously in response to removal of serum-containing medium [57] This increase in MMP-1 mRNA may be a stress response or a consequence of removing transforming growth factor-b, which is present in serum and can repress the expression of MMP-1 [58] These findings indicate that Fra-1 is downregulated in response

to PD098059 prior to MMP-1, and suggest that Fra-1 may be involved in regulating MMP-1 expression in these cells

Fig 3 Inhibition of Fra-1 protein and mRNA levels by PD098059 (A)

Fra-1 protein levels from confluent cultures of A2058 cells incubated in

serum-free media with or without increasing concentrations of

PD098059 Whole cell extracts were separated by SDS/PAGE,

trans-ferred to poly(vinylidene difluoride) membranes and probed with Fra- 1

antibody The blot was stripped as described [48] and reprobed with an

antibody against a-actin for 1 h (B) Dose–response of PD098059 on

Fra-1 and MMP-1 mRNA levels in A2058 cells GAPDH was used as

a loading control Dose–response experiments were performed at least

three times for reproducibility.

Fra-1 expression drives transcription from the MMP-1

promoter in a dose-responsive manner

Evidence thus far has indirectly implicated Fra-1 as one

factor contributing to constitutive expression of MMP-1 in

A2058 melanoma cells: Fra-1 is expressed in these cells,

and its pattern of repression in response to PD098059 is

coordinate with that of MMP-1 To more directly link Fra-1

to MMP-1 expression, we used a fra-1 sense expression

construct under control of the CMV promoter, which has

been described previously [47] Cells were transiently

cotransfected with MMP-1 promoter DNA containing

either the 1G or 2G SNP, driving luciferase, along with

increasing amounts of the Fra-1 expression construct

Expression from the 2G SNP was initially 2.7-fold higher

than the 1G SNP, and increasing quantities of Fra-1

preferentially augmented transcription from this promoter

(Fig 5A) With increasing amounts of Fra-1, expression of

the 1G promoter construct increased 2.9-, 5.2- and 8.8-fold

over the 1G control construct, compared to increases of

4.8-, 10.4- and 12.9-fold for the 2G construct For each

concentration of Fra-1, the increase in expression from the

2G SNP was approximately twofold greater than the

increase in expression from the 1G SNP Therefore, Fra-1

can drive transcription from both the 1G and 2G-containing

promoters but has the more dramatic effect on the 2G allele

Fra-1 antisense reduces MMP-1 transcription

in A2058 cells

To further address the role of Fra-1 in MMP-1

expres-sion, we used an antisense construct A2058 cells were

cotransfected with the 1G or 2G MMP-1 promoter constructs and increasing doses of a construct expressing Fra-1 antisense cDNA, which has been shown to lower AP-1 activity in a dose-dependent manner in MCF-7 and MDA-231 breast cancer cells [47] We reasoned therefore that it should antagonize production of endogenous Fra-1 Unfortunately, however, because the transfection effi-ciency was too low (< 10%), we could not measure changes in the level of Fra-1 protein Nonetheless, Fig 5B shows that expression of both the 1G and 2G-containing constructs was inhibited by fra-1 antisense Repression of luciferase activity from the 1G SNP was
50% at all doses of Fra-1 antisense In contrast, reporter expression from the 2G SNP promoter was inhibited in a dose-dependent fashion (Fig 5B), with maximal inhibition at

75% These results are similar to those seen with PD098059, where the 1G allele was inhibited by 50% and the 2G allele by
50–70% [15] Thus, the effects of decreasing Fra-1 expression mimic the effects of inhibition

by PD098059, and the reduction in Fra-1 expression by the addition of 3 lg of antisense construct abolished the difference in expression between the 1G and 2G alleles Therefore, in these melanoma cells, Fra-1 expression is required for the increase in transcription from the 2G SNP promoter over the 1G SNP promoter

The AP-1 site at)1602 bp is necessary for modulation

of MMP-1 expression from the 2G SNP promoter

To identify the sequences in the MMP-1 promoter that are targeted by Fra-1, 1G/2G MMP-1 constructs with either wild-type or mutated AP-1 sites at)73 bp or )1602 bp were

Fig 4 Downregulation of Fra-1 and MMP-1 mRNA levels prior to MMP-1 by PD098059 A2058 cells were grown until confluent, washed with Hanks balanced salt solution and transferred to serum-free media with or without 5 l M PD098959 RNA was harvested at 0, 0.5, 1, 2, 4, 6, 8, 10 and

12 h RNA blots were probed with Fra-1 and MMP-1 and subsequently, with GAPDH probes as a loading control, as described in Materials and methods.

transfected into A2058 cells The AP-1 site at )73 bp is

important for basal and growth factor induced expression

(via ERK activation) [19] The AP-1 site at )1602 bp is

adjacent to the 2G SNP, which is targeted by the ERK 1/2

pathway, and it may also be responsible for growth factor

induced expression of MMP-1 [15] As seen in Fig 6,

expression of luciferase from the MMP-1 reporter

constructs with a wild-type AP-1 site at )1602 bp was

equivalent to previous reports [15], in that there is greater

expression from the wild-type 2G construct than from the

1G However, as noted previously [15], this difference in

expression was absent in the constructs containing a

mutated AP-1 site at)1602 bp (Fig 6) In this experiment,

some cells were also transfected with the Fra-1 antisense construct in order to determine whether the absence of Fra-1 can lower gene expression when the AP-1 sites are mutated We found that expression of Fra-1 antisense abolished the higher level of expression from the 2G MMP-1 reporter construct so that all constructs, wild-type

or with a mutated AP-1 site at)1602 bp, show equivalent activity These findings corroborate our previous results, which show that when A2058 cells were transfected with the same wild-type and mutant constructs and subsequently treated with PD098059, reporter levels were nearly identical [15], thereby suggesting that the ERK inhibitor and Fra-1 antisense may be working in a similar manner

We next examined the effect of mutating the AP-1 site

at )73 bp in the MMP-1 promoter (Fig 6, inset) Com-pared to constructs containing a wild-type site at)73 bp, mutating this site substantially decreased expression (
90%) from both the 1G and 2G SNP promoters (compare 1G vs 2G wild-type in Fig 6 with 1G vs 2G inset) While the absolute levels of expression from both alleles were reduced when the AP-1 site at )73 bp is mutated, the difference between expression of the 1G vs 2G alleles remained intact, further demonstrating that the proximal AP-1 site is not involved in the augmented expression from the 2G allele Co-transfection of con-structs with the mutated AP-1 site at )73 bp and Fra-1 antisense inhibited expression from both the 1G and 2G constructs but downregulated the 2G construct to a greater extent (49% repression vs 77% repression, respectively) The fact that Fra-1 antisense can inhibit transcription from the 1G SNP construct with the mutant AP-1 site at)73 bp indicates that Fra-1 can induce

MMP-1 through AP-MMP-1 sites other than that at )73 bp We conclude that the)73 bp site, in contrast to the AP-1 site

at)1602 bp, is not involved in the difference between the 1G and 2G SNP

Fra-1 rescues the 1G/2G response in cells treated with PD098059

To confirm that the attenuation of Fra-1 by PD098059 results in reduced MMP-1 expression, we attempted to reverse this repression by ectopic expression of Fra-1 A2058 cells were treated with PD098059 and cotransfected with the 1G or the 2G MMP-1 promoter constructs along with increasing amounts of the Fra-1 expression vector Exo-genous Fra-1, expressed under control of the CMV promoter, would not be subject to the same regulation as endogenous Fra-1 gene, and the high level of expression should allow the exogenous protein to be phosphorylated even in the presence of 5 lMPD098059 Although higher concentrations of the drug might block the phosphorylation

of all exogenous Fra-1, they may also introduce toxicity and nonspecific effects Thus, as expected, in cells transfected with the empty vector, there is about a threefold increase in expression of the 2G allele compared to the 1G allele, and treatment with 5 lM PD098059 abolished this difference (Fig 7) We reasoned that any increase in expression from the 2G allele in these treated cells cotransfected with Fra-1 would be due to rescue by Fra-1 Indeed, compared to the empty vector, we found that cotransfection of increasing amounts of the Fra-1 expression plasmid augments the level

Fig 5 Effect of Fra-1 expression on MMP-1 transcription (A) Fra-1

sense expression A2058 cells were transfected with 1 lg of 1G/2G

MMP-1 promoter constructs driving luciferase and the pCl empty

vector or with increasing concentrations of the Fra-1 overexpressing

vector, as described in Materials and methods For the empty vector,

the difference in expression between the 1G and 2G constructs is

indicated above the line spanning both the 1G and 2G bars

(mean ± SD) With increasing amounts of Fra-1 expression, (*)

indicates that the value is statistically significant (P £ 0.02), compared

to the 1G or 2G value in cells transfected with the empty vector (B)

Fra-1 antisense expression A2058 cells were transfected with 1 lg of

1G/2G MMP- 1 promoter constructs driving a luciferase reporter and

the pCl empty vector, or with increasing quantities of pCl fra-1

anti-sense (AS) vector The percent inhibition compared to the empty

vector control is indicated above the bar The (*) indicates that the

value is statistically significant (P £ 0.05) compared to the previous

respective 1G or 2G data point Transfection experiments were

per-formed three times for reproducibility.

of transcription from both the 1G and 2G promoter

constructs The increase is greater in cells transfected with

the 2G construct compared to the 1G construct, increasing

from 1.06-fold for the empty vector to 2.1-fold for cells

transfected with 3.0 lg Fra-1 Increasing the amount of the

Fra-1 not only restored the difference between the 1G and

2G alleles, but also partially abrogated the repression of the

2G allele by PD098059 Therefore, expression of Fra-1 is

reduced by PD098059 and this protein is required for

increased expression from the 2G allele over the 1G allele

Discussion

The SNP in the MMP-1 promoter at)1607 bp results in an ETS binding site (the 2G SNP) and is correlated with increased transcription [20] Subsequent investigations that demonstrated an association between the 2G allele and several cancers have generated interest as to the identity of factors that activate this site In this study, we identify Fra-1 as one of the potential transcription factors driving MMP-1 transcription and enhancing expression through the AP-1 site at)1602 bp, but only in combination with the 2G SNP (ETS site) at )1607 bp In the presence

of increasing concentrations of the ERK 1/2 inhibitor, PD098059, the dose–responses of Fra-1 and MMP-1 expression are similar (Fig 3B) The time-course of inhibi-tion of Fra-1 and MMP-1 mRNAs in response to PD098059 treatment (Fig 4) further supports a probable role of Fra-1 in MMP-1 transcription These correlations between Fra-1 and MMP-1 expression prompted us to find direct evidence implicating Fra-1 in constitutive MMP-1 production

AP-1 factors bind DNA as Jun/Jun homodimers or Jun/ Fos heterodimers, which have affinity for AP-1 responsive elements A2058 melanoma cells express both JunD (data not shown) and Fra-1 constitutively and these proteins may form a transactivating complex with other transcription factor families, such as members of the Ets family [18] Furthermore, Fra-1 is a potent transactivator in the presence of JunD, where either factor may be inhibitory without the other [42,59] In addition to the reduction in phosphorylation and expression of Fra-1, inhibition of the ERK pathway also decreases the stability of Fra-1 protein and its ability to bind to DNA [36] With the exception of Fra-2, this contrasts with other AP-1 members, which bind

Fig 6 Mutational analysis of AP-1 sites at )1602 bp and )73 bp A2058 cells were cotransfected with 1G/2G MMP-1 reporter constructs containing a wild-type AP-1 site or a mutated AP-1 site at either )1602 bp or (inset) )73 bp Additionally all cells were transfected with either a

Fra-1 expression, Fra-Fra-1 antisense (AS) or control construct Data points are the mean ± SD and the statistical significance of the Fra-1G compared to the 2G is **P ¼ 0.002 The transfection experiment was performed three times for consistency.

Fig 7 Partial rescue of MMP-1 transcription in cells treated with

PD098059 A2058 cells were transfected with 1 lg of 1G or 2G MMP-1

promoter constructs driving luciferase and the pCl vector or with

increasing quantities of pCl Fra-1 overexpression vector After 24 h

cells were incubated in serum-free media with or without 5 l M

PD098059 for an additional 24 h The fold increase of 2G expression

over 1G expression from the 2G allele treated with 5 l M PD098059

compared to the expression from the untreated 1G allele are charted

below the graph Data points represent the mean ± SD **P £ 0.05 is

the statistical significance of expression of the 1G allele compared to

the 2G allele.

constitutively to AP-1 consensus sequences in the presence

or absence of MAPK signaling [50,60] Additionally, Fra-1

is the factor that determines the DNA-binding activity of

the AP-1 transcription factor complex [61] Thus, if Fra-1 is

binding to the AP-1 site at)1602 bp, PD098059 should

reduce binding activity since ERK 1/2 is required for

stability/DNA binding [36] Our EMSA results suggest the

presence of a multi-family association of proteins required

to enhance synthesis of MMP-1 through the 2G SNP/AP-1

site [20,31,49], of which Fra-1 may be a component Specific

complexes bind to the probe containing the AP-1 site and

2G SNP as seen in Fig 2, and these complexes are absent in

the lanes containing the probe with the 1G SNP Although

increasing concentrations of PD098059 reduce the binding

of complexes to the probe containing the 1G SNP, a more

pronounced decrease is observed in the binding of

com-plexes to the 2G SNP probe Attempts to supershift

complexes with antibodies raised to Fra-1 or other AP-1

factors were unsuccessful (data not shown), potentially due

to the inability of the antibodies to access the epitope

Experiments with a Fra-1 antibody from another source

(Geneka, Canada) also failed to supershift (data not

shown) The downregulation of Fra-1 may decrease the

total number of complexes formed, thereby diminishing the

cooperative binding to the promoter and, subsequently

decreasing MMP-1 production

Transfection with increasing amounts of Fra-1 sense and

antisense expression constructs had a greater effect on

transcription from the 2G SNP than from the 1G allele

(Fig 5) It has been previously reported that Fra-1 protein

binds to the proximal AP-1 site at)73 bp in the MMP-1

promoter [39] Thus, the increase in expression from the

1G promoter in the presence of increasing amounts of

Fra-1 may be due to the effects of Fra-Fra-1 on the proximal AP-Fra-1

site The greater increase in the induction of the 2G

promoter may result from Fra-1 acting not only at the

proximal site but also at the AP-1 site at)1602 bp adjacent

to the 2G SNP Furthermore, our data implicate Fra-1 in

contributing to the increase in MMP-1 expression from the

2G SNP promoter via a cooperative mechanism between

the AP- 1 site at)1602 bp and the 2G SNP at )1607 bp

(Fig 6) Our previous results show that when A2058 cells

were transfected with wild-type and AP-1 mutant at

)1602 bp constructs and treated with PD098059, reporter

levels were identical from either the 1G or 2G promoter

[15] Thus, expression of Fra-1 antisense and PD098059

[15] have similar effects on transcription of the MMP-1

promoter The similarities between the wild-type and AP-1

()1602 bp) mutant constructs in response to Fra-1

anti-sense and ERK 1/2 inhibition provide additional support

for the concept that inhibition of Fra-1 is one target of

PD098059 [15], with the subsequent inhibition of MMP-1

mRNA

The ectopic expression of Fra-1 was able to moderately

rescue transcription from the 2G allele in the presence of

PD098059 (Fig 7), but was unable to fully overcome this

repression This partial rescue is probably because the

inhibition of the ERK 1/2 pathway greatly reduces

phos-phorylation and stability of downstream targets, including

Fra-1 [62] and because Fra-1 needs to be phosphorylated to

transactivate transcription Young et al [62] determined

that the threonine at 231 in Fra-1 is phosphorylated by the

ERK pathway and is essential for the transactivation of transcription by Fra-1 We attempted to overcome the need for phosphorylation by the ERK pathway by changing the threonine at 231 to an aspartic acid residue (T231D), which may mimic a phosphothreonine However, the T231D Fra-1 mutant was unable to transactivate MMP-1 tran-scription to the same levels as wild-type Fra-1 or rescue MMP-1 expression in the presence of PD098059 (data not shown) Two possible reasons why the T231D mutation did not work are that the mutant protein may have been unstable or the aspartic acid residue was unable to mimic the phosphorylation state Although the A2058 cells express c-Fos, levels of the protein are low (data not shown) However, it is possible that c-Fos may play a minimal role in the residual expression of MMP-1 in the presence of Fra-1 antisense

Fra-1 had previously been implicated in MMP-1 expres-sion through the AP-1/ETS site in the proximal promoter [39,46], but it is the first transcription factor to be identified that leads to the increase in expression from the MMP-1 2G SNP through its cooperation with the adjacent AP-1 site Fra-1 expression, like the presence of the 2G polymorphism, has been associated with the more aggressive and metastatic forms of breast cancer [63] and melanoma [64], further supporting the possible connection between Fra-1 expres-sion and the 2G polymorphism

Acknowledgements

Supported by grants from the NIH, AR-26599, CA-77267, the Department of Defense DAMD17-00-1-0221 (CEB), predoctoral fellowships from the Komen Foundation Austin, Texas (DISS00-000354), and the Department of Defense DAMD17-01-1-0225 (GBT), Institut National de la Sante´ et de la recherche Me´dicale, the Association pour la Recherche sur le Cancer (grant no 5825) (DC), the Fondation pour la Recherche Me´dicale and the Ligue Nationale Contre le Cancer (KB).

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