Abstract
Although mounting evidence indicates the involvement of galectin-3 in cancer progression and metastasis, the underlying molecular mechanisms remain largely unknown. In this study, we investigated the effect and possible mechanism of galectin-3 on the migration and invasion of B16F10, a metastatic melanoma cell line, in which galectin-3 and matrix metalloproteinase-1 (MMP-1) were both found to be highly expressed. Knockdown of galectin-3 with specific siRNA reduced migration and invasion, which was associated with reduced expression of MMP-1. To further investigate the underlying mechanism, we examined the effect of galectin-3 knockdown on the activity of AP-1, a transcriptional factor regulating MMP-1 expression. We found that galectin-3 directly interacted with AP-1 and facilitated the binding of this complex to the MMP-1 promoter that drives MMP-1 transcription. Moreover, silencing of galectin-3 inhibited binding of fra-1 and c-Jun to promoter sites of MMP-1 gene. Consistent with these in vitro findings, our in vivo study demonstrated that galectin-3 shRNA treatment significantly reduced the total number of mouse lung metastatic nodules. Taken together, galectin-3 facilitates cell migration and invasion in melanoma in vitro and can induce metastasis in vivo, in part through, regulating the transcription activity of AP-1 and thereby up-regulating MMP-1 expression.
Keywords: galectin 3; matrix metalloproteinase 1; melanoma; neoplasm metastasis; RNA, small interfering; transcription factor AP-1
Introduction
Galectin-3, a chimera-type of 31-kDa galactose-binding protein, is highly expressed in a variety of primary and metastatic tumors (Raz et al., 1990). Galectin-3 is associated with enhanced tumor progression, invasion and metastasis in various cancer cells, e.g., lung and gastric cancer cells (Hood and Cheresh, 2002; Liu and Rabinovich, 2005). Changes in circulating galectin-3 levels in cancer patients may reflect the metastatic spread of disseminating cancer cells (Yu, 2010). Thus, inhibition of galectin-3 may be a novel therapeutic approach for preventing metastasis and reducing cancer-associated mortality (Kim et al., 2010). However, the mechanisms underlying the role of galectin-3 in tumor progression and metastasis remain largely unclear.
Matrix metalloproteinases (MMPs) facilitate tumor progression and metastasis (Khokha, 1994; Ahonen et al., 1998; Valente et al., 1998). Among these, MMP-1, MMP-2, MMP-9 and MT1-MMP are involved in human melanoma invasion (Walker and Woolley, 1999; Hofmann et al., 2005). MMP-1, which is capable of degrading type I, II and III collagens, is the only MMP subtype able to degrade triple helical collagens (Pardo and Selman, 2005). Recent studies showed that MMP-1 knockdown cells reduce melanoma invasion into matrigel, whereas its activation promoted melanoma cell invasion into three dimensional type I collagen (Durko et al., 1997; Benbow et al., 1999). Clinical studies have also provided evidence that MMP-1 is positively correlated with malignancy of melanoma cells and poor prognosis of patients (Nikkola et al., 2002).
MMP-1 expression is controlled by mitogen activated protein kinase (MAPK) pathway(s) and the upstream transcription factor, activation of activator protein-1 (AP-1) (Tower et al., 2003; Jung et al., 2008). Although increasing attention has been paid to the roles of galectin-3 and MMP-1 in cancer metastasis, and a recent study showed a significant role of galectin-3 in MMP-1 expression in gastric cancer cells (Cheong et al., 2010; Cho et al., 2011; Kim et al., 2011), it is unclear whether similar regulation occurs in melanoma.
In this study, we demonstrated that galectin-3 regulated MMP-1 expression and melanoma cell metastasis using B16F10 cell line, as a highly expression of both galectin-3 and MMP-1 in a mouse melanoma cell line. The B16F10 cell line is well established in in vivo mouse lung metastasis systems (Nguyen et al., 2007). We demonstrated that knockdown of galectin-3 reduced MMP-1 expression and melanoma metastasis both in vitro and in vivo, in part by modulating AP-1 activity.
Results
Expression levels of galectin-3 and MMP-1 in mouse cancer cell lines
The mRNA and protein expression of galectin-3 and MMP-1 were assessed in the following 4 cell types: highly metastatic melanoma cancer cell (B16F10), highly metastatic breast cancer cell (4T-1), HPV positive and invasive mouse cervical cancer cells (TC-1), and mouse fibroblast cells (NIH3T3). As shown in Figures 1A and 1B, galectin-3 was highly expressed in all four cell lines, whereas the expression of MMP-1 was obviously higher in the B16F10 cell line than in others. Compared to the non-metastatic cell line B16F1, B16F10 cells express a higher level of both galectin-3 and MMP-1, in both mRNA and protein levels, respectively (Figures 1C and 1D).
Figure 1.
Expression levels of galectin-3 and MMP-1 in several mouse cell lines. (A) mRNA and (B) protein expression levels of galectin-3 and MMP-1 in B16F10, 4T-1,TC-1 and NIH3T3 cell lines, determined by RT-PCR and western blotting. β-actin was used as a loading control. (C) mRNA and (D) protein expression levels of galectin-3 and MMP-1 in B16F1 and B16F10 cell lines were determined by RT-PCR and western blotting. β-actin was used as normalization control.
Galectin-3 knockdown inhibited B16F10 melanoma cell migration and invasion
To examine the effects of galectin-3 knockdown on B16F10 cell migration and invasion, cells were transfected with various concentrations of galectin-3 siRNA, and galectin-3 expression was assessed using real time PCR and western blotting respectively. As shown in Figure 2A, all three concentrations of galectin-3 siRNA significantly reduced protein expression, with no significant differences in potency. Thus, 20 nM of galectin-3 was chosen for the following experiments. After transfection of B16F10 cells with 20 nM galectin-3 siRNA for 24 h, the living cells were collected and subjected to wound healing, invasion and migration assays. As shown in Figure 2B, cells transfected with galectin-3 siRNA migrated significantly slower than those without transfection or transfected with a scRNA in wound healing assays. Representative images are shown in Figure 2C. In addition, our trans-well migration and invasion assays also demonstrated approximately 50% and 65% decrease in cell migration and invasion, respectively, in the galectin-3 siRNA transfected cells compared to the control cells (Figures 2D and 2E).
Figure 2.
Effect of galectin-3 silencing on the migration and invasion of B16F10 melanoma cells. (A) mRNA and protein levels of galectin-3 after transfection of B16F10 melanoma cells with different concentrations (10, 20, 30 nmol/L) of scrambled siRNA (scRNA, negative control) and galectin-3 siRNA. Total RNA and protein were obtained after transfection for 48 h, and cells were harvested and analyzed by real time-PCR and western blotting, respectively. β-actin was used as a loading control. (B-C) A wound healing assay of B16F10 cells was performed with scRNA or galectin-3 siRNA at 0, 12, 18 and 24h after scratching. (B) Quantification of cell migration as described in the Methods section and (C) the micrographs of B16F10 cells were obtained according to the width change of the area lacking cells (Bar = 100 µm). (D-E) Cell migration and invasion activities were measured respectively by a Transwell assay after transfection of melanoma cells with scRNA or galectin-3 siRNA for 24 h. All experiments were performed individually in triplicate (P < 0.001 vs. control group).
Galectin-3 modulated MMP-1 expression through interacting with AP-1
Given the expressions of both galectin-3 and MMP-1 in the mouse B16F10 cell line, we examined their possible interactions and the effect of MMP-1 on cell motility. MMP-1 knockdown had no effect on the expression of galectin-3 but galectin-3 knockdown resulted a marked reduction of MMP-1 expression, indicating that galectin-3 is an upstream regulator of MMP-1 (Figure 3A). A cell proliferation assay demonstrated that transfection of gal-3 siRNA or MMP-1 siRNA slightly decreased cell proliferation compared to the scrambled siRNA transfected cells (Figure 3B). In contrast, MMP-1 knockdown dramatically decreased cell motility (Figures 3C and 3D). To further explore how galectin-3 increases MMP-1 expression in melanoma cells, we focused on the transcription factor, activator protein-1 (AP-1), which is a dimer composed of Jun and Fos-like region antigen (Fra-1) (Angel and Karin, 1991). The direct interaction between galectin-3 and members of AP-1, c-Jun and Fra-1 was demonstrated by immunoprecipitation (Figure 3E). Next, we assessed transcription activity of AP-1 using a luciferase assay. Compared to the control cells, transfection of the cells with galectin-3 shRNA significantly reduced AP-1 transcription activity (Figure 3F). Finally, we examined DNA binding activity of AP-1 with or without galectin-3. Figure 3G shows the binding site of the AP-1 complex on the MMP-1 promoter region. Our ChIP assay demonstrated that c-jun and fra-1 bound to the promoter regions of MMP-1 in the presence, but not in the absence, of galectin-3 (Figure 3H).
Figure 3.
Effect of galectin-3 on MMP-1 expression through binding with AP-1 complex and effect of MMP-1 silencing on the motility of B16F10 melanoma cells. (A) mRNA and protein expression levels of galectin-3 or MMP-1 were detected by RT-PCR and western blotting respectively after transfection of B16F10 melanoma cells with galectin-3 or MMP-1 siRNA. scRNA was used as negative control and β-actin was used as a loading control. (B) Cell proliferation was detected after transfection of B16F10 cells with scrambled siRNA, galectin-3 siRNA or MMP-1 siRNA for 24 and 40 h by MTT assay as described in the Methods section (*P < 0.001, **P < 0.001, ○P < 0.001, ○○P < 0.001). (C, D) Wound healing assays utilizing B16F10 melanoma cells were performed by scRNA or MMP-1 siRNA transfected cells at 0, 12, 18 and 24 h after creating a scratch. (C) The phase micrographs of B16F10 cells were obtained according to the data. (bar=100 µm) and (D) quantification of cell migration using the monolayer wound healing assay was performed as described in the Methods section. All experiments were performed individually in triplicate. (E) Interaction between galectin-3 and AP-1 (Fra-1 and c-Jun) was measured by immunoprecipitation as previously described in "Methods", and then expression of galectin-3, Fra-1 and c-Jun was detected by western blot. Whole-cell lysates (WCLs) were used as a positive control. (F) Luciferase activity of AP-1 in lacZ and galectin-3 knock down cells. Luciferase assay was performed using an AP-1 expression luciferase vector transfection to lacZ and galectin-3 knock down cells (P < 0.01, vs. Cont). (G) The proximal AP-1 binding site which is located between -80 and -68 from the initiation codon of the MMP-1 gene. (H) A ChIP assay was performed using antibodies against galectin-3, c-Jun and Fra-1 in melanoma cells transfected with scRNA and galectin-3 siRNA. In the input lane, total genomic DNA was used as a control for the PCR reaction.
Galectin-3 knockdown decreased B16F10 metastasis in lung metastasis mouse models
We constructed lentiviral vectors containing lacZ (negative control) or galectin-3 shRNA, and infected B16F10 cells with the lentivirus. As shown in Figure 4A, transfection of the B16F10 cells with galectin-3 siRNA resulted in approximately 53% reduction of the mRNA level of the target protein. As expected, transfection of B16F10 cells with galectin-3 markedly reduced the expression of MMP-1 (Figure 4B). To examine the effect of galectin-3 knockdown on melanoma metastasis in vivo, we applied the lentiviral infected cells to a mouse pulmonary metastasis model. Metastasis was assessed in C57BL/6 mice four weeks after tail vein injection of B16F10 parent cells, B16F10 cells infected with lentiviral lacZ, or gal-3shRNA. As shown in Figures 4C and 4D, the total numbers of lung metastatic nodule were reduced by approximately 50% in the animals injected with the B16F10 cells containing lentiviral gal-3 shRNA compared to the animals injected with B16F10 parent cells or lacZ expressing B16F10 cells.
Figure 4.
Suppressive effects of galectin-3 silencing on metastasis of B16F10 melanoma cells in lung metastasis mouse models. (A) Expression levels of galectin-3 were detected by real time-PCR analysis in B16F10 cells infected with lenti-virus expressing LacZ or galectin-3 shRNA (gal-3shRNA). The preparation and infection of these lenti-viruses were described in the Methods section. (B) Expression levels of galectin-3 and MMP-1 were detected by RT-PCR and western blot analysis in B16F10 melanoma cells transfected stably with lacZ and gal-3shRNA respectively. β-actin was used as a loading control. (C, D) Four weeks after tail vein injection of PBS (negative control), parent B16F10 melanoma cells, lacZ expressing B16F10 cells or gal-3shRNA expressing cells into C57BL/6 mice, the formation of lung colonies was counted and illustrated as a histogram (P < 0.01 vs. lacZ group) (C) and photographs (D). The details are described in the Methods section.
Discussion
This study was performed to better understand the mechanisms underlying the role of galectin-3 in melanoma invasion and metastasis. We have previously shown that after silencing of galectin-3, some genes such as MMP-1 and MMP-3 are down-regulated, while other genes, such as serine protease inhibitor and tissue inhibitors of MMP-2 were up-regulated (data not shown) (Cheong et al., 2010). Among these genes, MMP-1 was down-regulated by galectin-3 to a greater extent than others, which was further confirmed by the following findingsWe confirmed the extensive expression of galectin-3 in different mouse cell lines including B16F1, B16F10 (melanoma), 4T-1 (breast carcinoma), TC-1 (lung cancer) and NIH3T3 (embryonic fibroblast), which may imply its conservation and significance in many types of cancer. However, much higher expression of MMP-1 was detected in the melanoma cell line B16F10 than in the 4T-1, TC-1 and NIH3T3 cell lines. We also assessed galectin-3 and MMP-1 expression in the B16F1 and B16F10 melanoma cell lines and found that the non-metastatic cell line (B16F1) did not express galectin-3 while the metastatic cell line (B16F10) did. A previous report indicated that galectin-3 regulates the metastasis of various types of cancer via different mechanisms (Liu and Rabinovich, 2005). However, the mechanisms underlying the involvement of galectin-3 in mouse cancer cell motility remain largely unknown. Our findings seem to indicate that one possible mechanism of melanoma cell motility in mice involves a putative relationship between galectin-3 and MMP-1 expression.
We observed that galectin-3 knockdown dramatically suppressed the motility, migration, and invasion of melanoma cells. In parallel, MMP-1 knockdown also significantly reduced the cell motility. Knockdown of galectin-3 reduced the expression of MMP-1 but not vice versa, and it is suggested that galectin-3 is an upstream regulator of MMP-1. This finding sheds new light on the mysterious relationships between galectin-3 and MMP-1. To understand how galectin-3 regulates MMP-1 expression, we determined the interaction between galectin-3 and the AP-1 complex (Song et al., 2005). The AP-1 family of transcription factors is composed of the homodimers or heterodimers of the Jun (JunB, JunD, c-Jun) and Fos (c-Fos, Fos B, fra-1, fra-2) onco-proteins (Lee et al., 1987). Among them, c-Jun plays important roles in regulating cancer invasion and metastasis. For instance, the c-Jun dominant-negative mutant, TAM67, inhibits the effects of AP-1 on the growth of breast cancer (Moore-Carrasco et al., 2006), as well as on the invasion and metastasis of murine osteosarcomas (Leaner et al., 2009). Fra-1, another component of the AP-1 family, plays a key role in MMP-1 transcription in A2058 melanoma cells (Tower et al., 2003). Here, we provide evidence for the association of galectin-3 with c-Jun and fra-1 and regulation of AP-1 transcription activity. Interestingly, c-Jun and fra-1 bound to the promoter regions of MMP-1 in the presence of galectin-3, but not in its absence. This is the first case reported in which galectin-3 contributes to MMP-1 promoter activity by forming a complex with c-Jun and fra-1 in melanoma cells. The role of galectin-3 in melanoma metastasis was also supported by the in vivo experimental results. In a mouse pulmonary metastasis model, animals treated with galectin-3 shRNA-transfected B16F10 melanoma cells showed considerable inhibition of lung metastasis compared with the untreated control group.
In conclusion, the promotion of galectin-3 expression resulted in melanoma invasion/metastasis due at least in part to increased MMP-1 expression via the transcriptional activation of AP-1. These findings combined with the recent report by Kim et al, for the involvement of galectin-3 in gastric cancer cell motility (Kim et al., 2011), suggest that galectin-3 plays a role in various cancers' metastasis through a common molecular mechanism.
Methods
Cell culture and siRNAs transfection
B16F1, B16F10, 4T-1, TC-1 and NIH3T3 cell lines obtained from the Korea Cell Line Bank were cultured in DMEM or RPMI 1640 medium with 5% fetal bovine serum (FBS) and 1% Antibiotics (Invitrogen). Both galectin-3 and MMP-1 siRNAs were purchased from Invitrogen and transfection was performed with Lipofectamine RNAiMAX reagent (Invitrogen) following the manufacturer's instructions. The sequences of mouse galectin-3 and MMP-1 siRNAs were 5'-AUGAUUGUGAUCAGCAUGCTT-3' and 5'-GCCA GAACTTCCCAACCAT-3', respectively.
RNA isolation and RT-PCR
Total RNA was extracted from mouse melanoma cells with TRIzol reagent (Invitrogen) according to the manufacturer's protocol. RT was carried out using a Reverse Transcription system (Promega), and PCR was performed with Ex-taq DNA polymerase (TaKaRa). The sequences of primers were as follows: mMMP-1; 5'-CCTGGAATTGGCAACAAAGT-3' (sense) and 5'-TAGCACGCAAGAATCAGGTG-3' (anti-sense); mGalectin-3: 5'-CAGTGCTCCTGGAGG CTATC-3' (sense) and 5'-AAGGGGAAGGCTGACTGTCT-3' (anti-sense); mβ-actin: 5'-AGCCTCGCCTTTGCCGA-3' (anti-sense).
Western blot analysis
Western blot analysis was carried out as described previously (Kim et al., 2010). Briefly, cells were lysed in RIPA buffer (Biosesang) containing a protease inhibitor cocktail (Sigma), followed by sonication on ice. The cell lysate was centrifuged and the supernatant was collected. Twenty µg of proteins were subjected to SDS-PAGE and transferred to PVDF transfer membranes (Amersham). After being blocked with 5% skim milk for 1 h, the membrane was incubated with primary antibody dissolved in 5% BSA overnight at 4℃. The membrane was then incubated with secondary antibody for 1 h, followed by detection with an ECL kit (Amersham). The following antibodies were used: anti-β-actin (Santa Cruz); anti-galectin-3 (Santa Cruz); anti-MMP-1 (Calbiochem, Santa Cruz).
Immunoprecipitation assays
Cell lysate containing 750 µg of protein was pre-cleared by incubation with 40 µl protein-A/G linked agarose beads (Santa Cruz) for 1 h at 4℃. After the beads were spun down, the supernatant was incubated with 1 µg specific antibody (anti-galectin-3, anti-c-Jun and anti-Fra-1, respectively) overnight at 4℃, followed by incubation with 40 µl protein-A/G agarose beads for 1 h. Mouse/rabbit IgG (Santa Cruz) was used as the negative control. After the incubation, beads were washed 3 times in RIPA buffer before being dissolved in SDS-PAGE loading buffer. Western blot analysis was performed as described above.
Transfilter migration and invasion assays
Transfilter migration and invasion assays were carried out with 8.0-µm pore inserts in 24-well Transwells (Corning Costar). Briefly, B16F10 cells were transfected with galectin-3 or MMP-1 siRNAs. One day after the transfection, cells were isolated and added to upper Transwell chambers with 0.5 mg/ml collagen type I (BD Bioscience) coated filters for the migration assay, and with 1/15 dilution of matrigel (BD Bioscience) coated filters for the invasion assays. DMEM containing 10% FBS and 1% antibiotics was added to the lower chamber and incubation continued for 20 h. Cells that had migrated or invaded into the lower chamber were quantified after H&E staining. For quantification, cells on were counted at 5 randomly selected areas in each well using a wide-field microscopy. Data were expressed as mean ± SD from three independent experiments.
Wound healing assays
B16F10 cells were seeded into 6-well culture dishes at 1 × 105 cells/well, and maintained in DMEM containing 5% FBS for 24 h. The nearly confluent cells were scratched with a pipette tip and cellular debris was removed. The scratched monolayer was then incubated for another 24 h in DMEM. Cells migrating into the gap were visualized and counted under a microscope.
Lentivial galectin-3 shRNA construction and stable cell line establishment
Lenti-viral vectors containing galectin-3 shRNA (Gal-3shRNA) was constructed by inserting the double strand gal-3 shRNA into the lentiviral vector pLL3.7 as described previously (Kim et al., 2010). The sequence of the shRNA was as following: gal-3shRNA sense: 5'-TGAACAACAGGAGA GTCATTGTTTCAAGAGAACAATGACTCTCCTGTTGTTC TTTTTTC-3'; gal-3shRNA antisense: 5'-TCGAGAAAAAA GAACAACAGGAGAGTCATTGTTCTCTTGAAACAATGAC TCTCCTGTTGTTCA-3'. The lentiviral vector containing lacZ was used as a control. Lentiviral infection of B16F10 melanoma cells was performed as described previously (Kim et al., 2010). Approximately 80% cells were infected and confirmed with FACS analysis.
Mouse pulmonary metastasis model
Female C57BL/6 mice, purchased from Orient Bio in Korea, were maintained in the animal facility at the National Cancer Center (NCC). B16F10 cells (1 × 106 cells/ml in 100 µl PBS) infected with lentiviral lacZ (control) or gal-3shRNA was injected into 6-week-old female C57BL/6 mice (five mice per group) through the lateral tail vein. Four weeks after the injection, mice were sacrificed with an overdose of anesthesia. The number of metastatic nodules on the surface of the lung was counted under the surgical microscope.
Chromatin immunoprecipitation assay
A chromatin immunoprecipitation (ChIP) assay was carried out using a ChIP assay kit (Upstate). Samples were applied to dishes after galectin-3 siRNA treatment and assays were conducted following the manufacturer's instructions. Anti-galectin-3, c-Jun and Fra-1 and normal mouse/rabbit IgG were used to immunoprecipitate DNA containing complexes. Prior to PCR, primers were prepared for AP-1 with MMP-1 promoter binding sites: MMP-1 promoter (-2950) 5'-AAGAAGAAGGTGGCCAGGAT-3' and (-2901) 5'-TGCCTTCATTT TCCATTTCC-3'. PCR was performed with Ex Taq (Takara).
Cell proliferation assay
B16F10 cells, growing in 96-well culture plates at a density of 3 × 103 cells/well were transfected with scrambled siRNA, galectin-3 siRNA, and MMP-1 siRNA respectively. 24 or 40-h post transfection, cell viability was analyzed by MTT assay, as described previously (Cheong et al., 2010).
Luciferase assays
B16F10 melanoma cell lines were co-transfected with an AP-1 reporter plasmid and galectin-3 siRNA 48 h before the luciferase assay was performed, as described previously (Kim et al., 2010).
Statistics analysis
All data were obtained from at least three independent experiments and are presented as mean ± SD, unless otherwise indicated. Statistical analysis was performed using one-way ANOVA. Data were considered significant if P < 0.05.
Acknowledgements
This study was supported by a grant of the Korea Health technology R&D Project, Ministry of Health & Welfare (A110961), Republic of Korea.
Abbreviations
- ChIP
chromatin immunoprecipitation
- IP
immunoprecipitation
- MMP-1
matrix metalloproteinase-1
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