Abstract
Background:
Melanoma, the most lethal form of skin cancer, is responsible for over 80% of all skin cancer deaths and is highly metastatic, readily spreading to the lymph nodes or metastasising to other organs. The frequent genetic mutation found in metastatic melanoma, BRAFV600E, results in constitutive activation of the mitogen-activated protein kinase pathway.
Methods:
In this study, we utilised genetically engineered melanoma cell lines and xenograft mouse models to investigate how BRAFV600E affected cytokine (IL-1β, IL-6, and IL-8) and matrix metalloproteinase-1 (MMP-1) expression in tumour cells and in human dermal fibroblasts.
Results:
We found that BRAFV600E melanoma cells expressed higher levels of these cytokines and of MMP-1 than wild-type counterparts. Further, conditioned medium from the BRAFV600E melanoma cells promoted the activation of stromal fibroblasts, inducing expression of SDF-1 and its receptor CXCR4. This increase was mitigated when the conditioned medium was taken from melanoma cells treated with the BRAFV600E specific inhibitor, vemurafenib.
Conclusions:
Our findings highlight the role of BRAFV600E in activating the stroma and suggest a mechanistic link between BRAFV600E and MMP-1 in mediating melanoma progression and in activating adjacent fibroblasts in the tumour microenvironment.
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Main
Metastatic melanoma is an aggressive cancer, with an increasing incidence worldwide, few durable and effective therapies, and an overall survival rate of <10% (Villares et al, 2011). Early stage melanoma, classified as radial growth phase (RGP), is curable by surgical excision. However, later stage vertical growth phase (VGP) is characterised by invasion into the dermal layer and is frequently metastatic with median survival times of less than 9 months.
Melanoma progression is often associated with a mutation in the BRAF oncogene. The most common mutation, BRAFV600E, is found in ∼50% of melanomas and promotes progression through constitutive activation of the mitogen-activated protein kinase (MAPK) signalling cascade (Hingorani et al, 2003; Sharma et al, 2006; Vultur et al, 2011) and target genes. Among these genes, matrix metalloproteinase-1 (MMP-1; Rutter et al, 1998; Huntington et al, 2004) and several cytokines and chemokines affect stromal cells in the tumour microenvironment (TME; Nicholas and Lesinski, 2011; Domanska et al, 2013). Importantly, the small molecule inhibitor, vemurafenib, specifically blocks BRAFV600E signalling and expression of these downstream genes, inducing tumour regression (Sullivan and Flaherty, 2013). Accumulating evidence highlights the critical role of the TME in enhancing the aggressive behaviour of melanomas, since products secreted by the tumour cells affect gene expression in adjacent stromal cells, causing them to adopt a carcinoma-activated fibroblast-like (CAF-like) phenotype (Eck et al, 2009).
The mechanisms that promote progression from less invasive RGP melanoma to aggressive VGP melanoma are unclear. However, this transition is associated with the destruction of the extracellular matrix, and an upregulation of proteolytic enzymes, particularly MMP-1 (Zigler et al, 2011; Austin et al, 2012). Matrix metalloproteinase-1 plays a prominent role in melanoma progression. It is secreted by melanoma and activated stromal cells and it degrades interstitial collagens (types I and III), which is an essential step in invasion and metastasis (Boire et al, 2005). Considering that melanomas are notorious for their capacity to invade, and that an activated TME facilitates tumour progression (Villanueva and Herlyn, 2008), a better understanding of how vemurafenib alters gene expression within the tumour and adjacent stromal cells is essential for determining the full impact of vemurafenib as a therapeutic agent.
Therefore, we investigated the effect of BRAFV600E expression on the transition from RGP to VGP and its influence on dermal fibroblasts in the TME. We developed a genetically controlled model where RGP Bowes cells, which are BRAF wild-type (WT), ectopically express BRAFV600E. By using Bowes cell lines containing an empty vector or BRAFV600E, we measured expression of MMP-1 and several secreted chemokines and cytokines, and we analysed activation of stromal fibroblasts. We found that PLX4032 (the experimental version of vemurafenib) decreased expression of these proteins and subdued stromal activation. We also found that ectopic expression of BRAFV600E can drive endogenous MMP-1 expression in the melanoma cells, resulting in enhanced tumourigenicity.
Our in vitro data confirm the findings of others (Khalili et al, 2012) on the induction of MMP-1, IL-1β, IL-6, and IL-8 by BRAFV600E in melanoma cells (Sumimoto et al, 2006; Ryu et al, 2011). Importantly, our work extends these previous findings by demonstrating a central role for IL-1β (produced by melanoma cells) in activating stromal fibroblasts. In addition, we show that PLX4032 reduces expression of these cytokines and of MMP-1, and subsequent stromal cell activation. Finally, in vivo studies investigating the tumourigenicity of engineered Bowes cells in nude mice demonstrate cooperativity between BRAFV600E and MMP-1 in mediating melanoma growth.
Materials and methods
Cell culture and conditioned media
Bowes cells and normal human neonatal dermal fibroblasts (HDFs) were obtained from American Type Cell Culture (ATCC, Manassas, VA, USA; Blackburn et al, 2009) and cultured according to manufacturer’s directions. Complete medium, EMEM (ATCC), contained 5% FBS, 5% HEPES (Fisher Bioreagents, Pittsburg, PA, USA), and penicillin/streptomycin (100 U ml−1 and 100 μg ml−1, respectively; Corning Inc., Corning, NY, USA). For serum-free (SF) conditions, cells were placed in EMEM (ATCC) with 0.2% lactalbumin hydrolysate (Sigma, St Louis, MO, USA), 5% HEPES, and penicillin/streptomycin. For conditioned medium (CM), 106 tumour cells were seeded in a 10-cm dish, incubated 24 h, washed with HBSS (Cellgro Mediatech Inc., Manassas, VA, USA), and 4 ml of SF medium was added to each dish. After 48 h, the CM was collected, spun at 1500 r.p.m. for 2 min, and used immediately or stored at −80 °C. All cells were cultured at 37 °C in humidified air with 5% CO2.
Construction and selection of expression clones with Bowes cells
Bowes cells were stably transfected with a BRAFV600E overexpression construct (under control of the 5′ LTR of the MoMuLV retrovirus in the pBABE vector (Addgene, Cambridge, MA, USA)) utilising Lipofectamine 2000 (Invitrogen, Carlsbad, CA, USA) according to manufacturer’s directions. A panel of engineered clones: WT for BRAF (vector only) or mutant BRAFV600E was isolated using 2 μg ml−1 of puromycin (Invitrogen).
cDNA synthesis and BRAFV600E sequencing
Clones were seeded in a 6-cm dish (3.5 × 105), incubated overnight, and RNA was isolated utilising the Qiagen RNeasy kit (Qiagen, Venlo, Limburg, Netherlands) following manual instructions. After cDNA synthesis utilising the iScript cDNA Synthesis kit (Bio-Rad, Hercule, CA, USA), the BRAF template was amplified via standard PCR profile. To confirm the presence of BRAFV600E, DNA was sequenced and compared to normal BRAF (nm_004333), with a T>A transversion at nucleotide 1799 indicating the presence of the mutant BRAF allele.
Real-time RT–PCR
cDNA was subjected to RT–PCR using Bio-Rads iQSybr Green Supermix and CFX96 Real Time System C1000 Thermal Cycler (Bio-Rad). All samples were normalised to B2M and relative fold change was calculated as 2−ΔΔCt. Primer sequences are listed in Supplementary Table 1.
Immunoblotting
Bowes cells, 2.5 × 105 or 5 × 105, were plated in 6- or 10-cm dishes, respectively, and incubated overnight. Cells were pelleted and lysed via sonication in cold cell extraction buffer (Invitrogen) 1X proteinase inhibitors (Calbiochem, Darmstadt, Germany) and 0.1 mM PMSF. Standard immunoblotting techniques were used (Huntington et al, 2004; Croteau et al, 2013): 2–5 μg total protein was visualised with anti-pMEK (1 : 1000, Cell Signaling, Beverly, MA, USA), anti-Total MEK (1 : 1000, Cell Signaling), or anti-MMP-1 (1 : 5000, Millipore, Billerica, MA, USA), followed by the donkey anti-rabbit HRP secondary antibody at 1 : 5000 (Millipore). Signal was detected with Western Lightning Plus—ECL (PerkinElmer, Waltham, MA, USA).
Trichloroacetic acid precipitation
Conditioned medium was spun at 1500 r.p.m. for 2 min, 500 μl cold 10% trichloroacetic acid (Fisher Scientific, Pittsburg, PA, USA) was added to 1 ml CM for 60 min on ice. Samples were spun for 15 min at 13 000 r.p.m., pellets were washed with cold 95% ETOH (containing 0.1 M potassium acetate), and centrifuged at 13 000 r.p.m. at 4 °C for 5 min. Pellets were air-dried; 30 μl of Laemmli buffer (Bio-Rad) was added; samples were boiled for 5 min, and 20 μl were loaded in a 12% Tris-glycine SDS–PAGE gel.
PLX4032 inhibition/cytokine production in tumour cells
One million cells were plated in a 10-cm dish, incubated 24 h in complete EMEM medium (ATCC), washed with HBSS (Cellgro Mediatech Inc.), and placed in 4 ml of SF medium with/without 3 μ M PLX4032 (ChemieTek, Indianapolis, IN, USA). After 48 h, the medium was spun 2 min at 1500 r.p.m., and stored at −80 °C. Total protein and mRNA were isolated.
PLX4032 inhibition/cytokine production in HDFs
Bowes cells, 1 × 106, were plated in a 10-cm dish, incubated overnight. Approximately, 4 ml of fresh serum-containing EMEM medium (ATCC), with/without 3 μ M PLX4032, was added to each plate. After 48 h, CM was collected. Human dermal fibroblasts, 2.5 × 105, were plated per well of a six-well dish for 24 h and 1 ml of CM was added to each well. After 24 h, the CM was removed; the cells were pelleted for subsequent RNA isolation and RT–PCR analysis of cytokine expression.
IL-1β rescue
Human dermal fibroblasts were treated as described above, except 10 ng ml−1 of IL-1β was added to the tumour cell CM before adding it to the HDFs. As a negative control, SF medium with/without 3 μ M of PLX4032 (ChemieTek) was placed in an empty 10-cm dish and incubated for 48 h alongside the tumour cells producing CM. This SF medium (with and without PLX) and the CM removed from the tumour cells were placed on the HDFs for 24 h as described above.
Tumour growth and analysis
Bowes cells were grown in culture to 80–90% confluency, washed, counted, and resuspended 1 × 106 cells per 50 μl of PBS. Six- to eight-week-old female nude mice (strain nu/nu, Charles River, Wilmington, MA, USA) were injected intradermally (1 × 106 cells) into the right flank. For statistical significance, there were eight mice per treatment group (Blackburn et al, 2009). Tumours were measured weekly with calipers. When the tumours were ∼10–12 mm in diameter, the mice were killed and tumours were excised.
Tumour pieces were flash frozen for mRNA isolation. Another portion of the tumour was cultured as explant in SF medium. For the tumour explant, tumour pieces were weighed, minced into 2–3 mm3 pieces, and divided between several wells of a 24-well dish, each well with 1 ml SF medium containing gentamicin (1 : 200) and Fungizone (1 : 250). After 48 h, CM was collected, spun at 1500 r.p.m. for 3 min, and stored at −80 °C. Cytokines in CM were measured by testing the CM in a MSD Multiplex Array per kit instructions (Meso Scale Diagnostics, Rockville, MD, USA). Matrix metalloproteinase-1 was measured with R&D Systems Fluorokine E Enzyme Activity Assay for Human Active MMP-1 per kit instructions (Minneapolis, MN, USA). All Animal procedures were reviewed and approved by the Institutional Animal Care and Use Committee at the Geisel School of Medicine at Dartmouth College.
Statistical analysis
Unless otherwise noted, Student’s t-test was used for statistical analysis, with P<0.05 defined as significant. All experiments were done in triplicate, at least three separate times. All numerical values represent the mean±s.e.
Results
Isolation and characterisation of Bowes melanoma clones
We transfected RGP Bowes cells with empty vector or vector expressing BRAFV600E. We isolated 10 clones harbouring the empty vector and 32 clones with BRAFV600E (data not shown). From these, we selected three for further investigation. Figure 1A shows total BRAF mRNA levels in WT (empty vector; clone 8) and in two clones expressing ectopic BRAFV600E (clones 7 and 21). Initial experiments in medium with 10% serum showed a significant increase (five-fold, P=0.0015) in total BRAF mRNA in clone 21 compared to clone 7 (Figure 1A). In WT Bowes cells (clone 8), BRAF mRNA levels are low, whereas ectopic expression of BRAFV600E increases total BRAF levels in clones 7 and 21. Next, we compared expression of mRNA for BRAFV600E in cells after 48 h culture in SF medium, conditions that we used to prepare the medium from melanoma cells to be tested on stromal fibroblasts (see below). Figure 1B shows that clone 21 displays higher BRAF mRNA than clone 7, which although not significantly higher than clone 7, was associated with high constitutive levels of MMP-1 and cytokines (see below). We attribute the difference to nutrients in serum-containing vs SF medium; SF medium may be limiting in allowing clone 21 to maintain higher levels of BRAF mRNA.
Effect of PLX4032 on pMEK
To confirm that BRAFV600E conferred increased constitutive signalling through the MAPK pathway and that PLX4032 could reduce this signalling, we measured pMEK after 48 h in SF medium. Wild-type Bowes (clone 8) displayed low pMEK, which was not affected by PLX4032 treatment (Figure 1C). In contrast, clones with BRAFV600E (clones 7 and 21) expressed higher pMEK and this was antagonised by PLX4032. Despite the slightly higher level of BRAF mRNA in clone 21, compared to clone 7 (Figure 1B), pMEK levels were not higher, suggesting that differences in BRAF mRNA levels (under SF conditions; Figure 1B) were not sufficient to alter levels of pMEK.
Effect of BRAFV600E and PLX4032 on proteins secreted by melanoma cells
Next, we compared gene expression in cells with WT vs mutant BRAFV600E. We focused on secreted proteins: IL-1β (Khalili et al, 2012), IL-6, and IL-8 (Frederick et al, 2013; cytokines known to contribute to melanoma progression), and MMP-1 (Ryu et al, 2011). Cells were cultured in SF medium for 48 h with or without 3 μ M PLX4032 (ChemieTek) and mRNA and total protein were isolated. Wild-type BRAF cells (clone 8) displayed low levels of IL-1β, IL-8, IL-6, and MMP-1, which were not affected by PLX4032 (Figure 2A and D, respectively). Similar to Khalili et al (2012), who found that introducing BRAFV600E into melanocytes increased expression of IL-1β, clones 7 and 21 displayed increased IL-1β mRNA and this expression was antagonised by PLX4032 (Figure 2A).
However, we also found increased expression of IL-8, IL-6, and MMP-1 in BRAFV600E cells (Figure 2B–D, respectively), and PLX4032 antagonised this expression. There were differences in the induction of cytokines and MMP-1 in clone 7 (lower BRAF mRNA expression) compared to clone 21 (higher BRAF mRNA). For example, IL-1β and IL-6 levels were higher in clone 7, while IL-8 and MMP-1 levels were higher in clone 21. These differences may reflect downstream mechanisms differentially regulating expression of these genes in response to BRAFV600E. Lastly, to confirm the mRNA data with protein analysis, we performed a human multiplex assay on CM collected from the tumour cells. In keeping with the results of mRNA, protein levels of cytokines, IL-1β and IL-8, increased with BRAFV600E (clones 7 and 21) and PLX4032 abrogated this increase (Table 1). Similarly, MMP-1 levels were increased with BRAFV600E clone 21 (although not detected, with clones 7 and 8). Thus, the changes in protein levels with PLX4032 mirrored those seen with mRNA.
Modulation of stromal cell gene expression by tumour-derived proteins
As tumour cells interact with adjacent fibroblasts, the TME becomes activated (Blackburn et al, 2007; Gogas et al, 2007; Blackburn and Brinckerhoff, 2008; Melnikova et al, 2009; Boni et al, 2010; Villares et al, 2011; Zigler et al, 2011; Khalili et al, 2012; Koya et al, 2012; Straussman et al, 2012; Wang et al, 2012). Gene expression of these activated stromal cells is altered as they secrete their own profile of growth factors, cytokines and MMPs, which can disrupt normal stromal architecture (Blackburn et al, 2007; Gogas et al, 2007; Blackburn and Brinckerhoff, 2008; Blackburn et al, 2009; Eck et al, 2009; Zigler et al, 2011; Lu et al, 2012; Straussman et al, 2012; Wang et al, 2012). The result is the emergence of carcinoma-associated fibroblasts (Eck et al, 2009), which express a variety of markers such as alpha-smooth muscle actin, MMPs, stromal-derived factor-1 (SDF-1; CXCL12), and its receptor, CXCR4 (Eck et al, 2009; Lu et al, 2012). CXCR4 and its ligand SDF-1 are two factors mediating communication between the tumour cells and the TME, and increased expression of CXCR4 and SDF-1 correlates with enhanced tumour progression (Scala et al, 2005; Mantovani et al, 2010; Teicher and Fricker, 2010; Domanska et al, 2013; Portella et al, 2013).
Thus, we examined the ability of SF CM from the Bowes melanoma clones to activate HDFs, and whether PLX4032 could attenuate this activation. Figure 3 shows that CM from WT Bowes cells (clone 8) failed to increase expression of CXCR4, and its ligand SDF-1. However, CM from clone 7 mediated a small but significant increase in SDF-1 and CXCR4, while clone 21 gave a greater increase. For both clones, CM from PLX4032-treated tumour cells significantly reduced CXCR4 levels (Figure 3A); SDF-1 levels were also reduced with PLX4032 (Figure 3B). Perhaps the modest increase in SDF-1 with CM from clone 7 is due to the lower level of BRAF mRNA. Indeed, CM from clone 21, with higher expression of BRAF, substantially increased expression of CXCR4 and SDF-1, and CM from PLX4032-treated melanoma cells reduced this expression (Figure 3B). Importantly, non-conditioned SF medium with or without PLX4032 failed to modulate HDF gene expression (light grey bars, Figure 3). These findings suggest that cells with ectopic BRAFV600E secrete factors that activate a CAF-like phenotype in HDFs and BRAFV600E inhibition can mitigate these changes.
We examined the ability of CM from melanoma cells to influence expression of IL-1β, -8 and -6, and of MMP-1 in activated HDFs (Figure 3C–F, respectively). Serum-free CM from the melanoma cells was placed on cultures of HDFs and mRNA was measured at 24 h. CM from WT Bowes slightly increased gene expression in the HDFs, whereas CM from PLX4032-treated melanoma cells did not decrease this expression (Figure 3C–F). In contrast, CM from BRAFV600E clones increased expression of all four-marker genes, which are expressed by cells in the TME (Hwang et al, 2004; Goldstein et al, 2005; Crawford et al, 2008; van Kempen et al, 2008; Waugh and Wilson, 2008; Halaban et al, 2010; Lu et al, 2012; Yin et al, 2012). Further, CM from PLX4032-treated tumour cells decreased this expression. Therefore, it is likely that in the tumour cells, PLX4032 decreased production of factors that induce these proteins in the HDFs.
Ability of IL-1β to rescue cytokine expression in HDFs
PLX4032 treatment of melanoma cells suppresses the ability of CM from these cells to increased expression of IL-1β, IL-6, IL-8, and MMP-1 in HDFs (Figure 3). Since induction of these proteins occurs in response to IL-1β (Apte et al, 2006; Apte and Voronov, 2008; Weber et al, 2010a, 2010b), we asked whether adding exogenous IL-1β to the CM from melanoma cells treated with PLX4032 could reverse this reduction. Indeed, exogenous IL-1β significantly increased mRNA levels of IL-8, IL-6, and MMP-1 (even in clone 8; empty vector) over medium alone (Figure 4A–D, respectively). However, exogenous IL-1β could not rescue IL-1β expression (Figure 4A; see Discussion section). We also investigated whether exogenous IL-1β could reverse the reduction in SDF-1 and CXCR4 in the HDFs when these cells were exposed to CM from PLX4032-treated melanoma cells (Figure 3A and B). We found a partial rescue of CXCR4 in clone 21 and a full rescue in clone 7 (Figure 5A). However, IL-1β did not rescue SDF-1 in clone 7 or 21 (Figure 5B).
Tumourigenicity of Bowes cells, WT, and ectopic expression of BRAFV600E
Ectopic expression of MMP-1 can drive tumourigenicity in RGP Bowes cells (Blackburn et al, 2009). Therefore, we investigated whether ectopic expression of BRAFV600E, which increases endogenous MMP-1 (Figure 2D), might increase tumourigenicity of these cells when these cells were injected intradermally into nude mice. Figure 6A shows that tumour incidence varied, with 100% (8 of 8) tumour take for clone 21 and 3 of 8 for clones 7 and 8. The tumour incidence and growth rate for clone 8 were similar to that of WT Bowes cells (Blackburn et al, 2009), while clone 21 resembled Bowes cells ectopically expressing MMP-1 (Blackburn et al, 2009). Thus, our data suggest that while BRAFV600E confers some growth advantage to melanomas, MMP-1 is a mediator of tumourigenicity (see Discussion section).
The time at which mice were killed, tumours were excised and mRNAs for MMP-1, BRAF, and IL-1β were measured. Figure 6B–D demonstrates that clone 21 had higher expression of MMP-1 and BRAF, while clone 7 had the highest level of IL-1β. To confirm that protein levels mirrored mRNA expression in tumours, excised tumours were cultured as explants in SF medium for 48 h and CM subjected to a human multiplex assay for protein levels of selected cytokines and MMP-1. Results reflected those observed with mRNA: clone 7 showed significantly elevated IL-1β levels, whereas clone 21 showed significantly high IL-6, IL-8, and MMP-1 (compared to clone 8; Table 2).
Discussion
In this study, we demonstrate that ectopic expression of BRAFV600E in RGP BRAF WT Bowes melanoma cells confers increased expression of BRAF mRNA and a cohort of genes that are targets of the Ras-Raf-MEK-ERK pathway: cytokines, IL-1β, IL-6 and IL-8, and MMP-1 (Huntington et al, 2004; Ryu et al, 2011; Frederick et al, 2013; Sullivan and Flaherty, 2013), a major mediator of melanoma progression (Hofmann et al, 2005; Blackburn et al, 2009; Hua et al, 2011). BRAFV600E also increased expression of pMEK, which is abrogated by the small molecule inhibitor, PLX4032 (Ascierto et al, 2012). We show that CM from these BRAFV600E Bowes cells contains secreted factors that upregulate this same panel of target genes in human dermal fibroblasts. In addition, these fibroblasts express a CAF-like phenotype, with increases in SDF-1 and its receptor CXCR4, suggesting that BRAFV600E melanoma cells co-opt adjacent stromal cells in the TME and facilitate melanoma progression. Finally, we note that tumours from Bowes cells expressing BRAFV600E are more tumourigenic and grow more rapidly than their WT counterparts.
In vitro, BRAF mRNA levels fluctuate depending on whether cells are cultured in serum-containing or SF medium (Figure 1A and B). In vivo, the rate of tumour growth is associated with the level of BRAF mRNA, with the higher expressing clone (clone 21) more tumourigenic than the lower expresser (clone 7). Interestingly, high levels of BRAF mRNA expression correlated with high levels of MMP-1, confirming our previous studies showing that MMP-1 is a target of the Ras-Raf-MEK-ERK pathway in melanoma (Huntington et al, 2004; Blackburn and Brinckerhoff, 2008; Blackburn et al, 2009). Here we show that PLX4032 abrogates MMP-1 expression, thereby demonstrating that MMP-1 is a target of BRAFV600E.
We attribute differences in BRAF expression in clones 7 and 21 to a variation in the insertion site within genomic DNA (Kay et al, 2001; Schroder et al, 2002), which influences mRNA expression. Of potential importance, the higher level of BRAF mRNA seen in clone 21 may mimic a recent report describing BRAFV600E amplification in melanoma specimens (Koya et al, 2012; Shi et al, 2012), which appears to be necessary and sufficient for acquired resistance to PLX4032 (Koya et al, 2012; Shi et al, 2012). Thus, this clone may be a valuable experimental tool for investigating the molecular and biological effects of amplified BRAF on proteins secreted by the melanoma cells that affect the TME.
Khalili et al (2012) reported that ectopic expression of BRAFV600E in human primary melanocytes induces IL-1α and β as well as IL-8, which along with IL-6 constitute a cohort of target genes that can promote tumour growth by regulating a network of cytokines (Walker and Woolley, 1999; Lederle et al, 2011). In addition, they showed that increased IL-1β levels were associated with stromal cell-mediated immunosuppression, and that vemurafenib decreased IL-1β, leading them to conclude that BRAFV600E promoted stromal cell-mediated immunosuppression via induction of IL-1β (Khalili et al, 2012).
Our data suggest that IL-1β is a master regulator of gene expression in melanoma cells and stromal cells. We treated the Bowes cells with PLX4032 and found that expression of IL-1β, IL-8, IL-6, and MMP-1 were all reduced, as expected. However, we could rescue IL-8, IL-6, and MMP-1 expression with exogenous IL-1β, suggesting that this cytokine is an upstream regulator of these genes (Lazar-Molnar et al, 2000; Apte et al, 2006; Apte and Voronov, 2008). Further, tumour-derived IL-1β may increase gene expression in the stromal cells, since IL-1β is a known inducer of growth factors, chemokines (specifically SDF-1 and CXCR4), and MMP-1 (Apte et al, 2006; Apte and Voronov, 2008; Weber et al, 2010a, 2010b). However, since exogenous IL-1β could not restore expression of IL-1β in the melanoma cells, IL-1β does not appear to be regulated by an autocrine feedback loop.
Finally, we note the correlation among increased BRAF, MMP-1, and tumourigenicity. We have shown that ectopic expression of MMP-1 in Bowes cells confers tumourigenicity and metastasis (Blackburn et al, 2009). In those studies, MMP-1 mediated invasion and metastasis by degradation of the interstitial collagens, and it cleaved protease activator receptor-1 to mediate signal transduction and the expression of genes associated with tumour invasion and angiogenesis (Blackburn et al, 2007; Blackburn and Brinckerhoff, 2008; Blackburn et al, 2009). It is likely that the levels of MMP-1 in clone 21 may have mediated the tumourigenicity by similar mechanisms. Although other genes probably contribute, our data suggest a mechanistic link between BRAFV600E and MMP-1 in mediating melanoma progression. They also suggest that activation of similar genes in adjacent fibroblasts creates a ‘spill-over’ mechanism to enhance the tumourigenic behaviour of melanoma cells with BRAFV600E.
Change history
14 October 2014
This paper was modified 12 months after initial publication to switch to Creative Commons licence terms, as noted at publication
References
Apte RN, Dotan S, Elkabets M, White MR, Reich E, Carmi Y, Song X, Dvozkin T, Krelin Y, Voronov E (2006) The involvement of IL-1 in tumorigenesis, tumor invasiveness, metastasis and tumor-host interactions. Cancer Metastasis Rev 25 (3): 387–408.
Apte RN, Voronov E (2008) Is interleukin-1 a good or bad ‘guy’ in tumor immunobiology and immunotherapy? Immunol Rev 222: 222–241.
Ascierto PA, Kirkwood JM, Grob JJ, Simeone E, Grimaldi AM, Maio M, Palmieri G, Testori A, Marincola FM, Mozzillo N (2012) The role of BRAF V600 mutation in melanoma. J Transl Med 10: 85.
Austin KM, Covic L, Kuliopulos A (2012) Matrix metalloproteases and PAR1 activation. Blood 121: 431–439.
Blackburn JS, Brinckerhoff CE (2008) Matrix metalloproteinase-1 and thrombin differentially activate gene expression in endothelial cells via PAR-1 and promote angiogenesis. Am J Pathol 173 (6): 1736–1746.
Blackburn JS, Liu I, Coon CI, Brinckerhoff CE (2009) A matrix metalloproteinase-1/protease activated receptor-1 signaling axis promotes melanoma invasion and metastasis. Oncogene 28 (48): 4237–4248.
Blackburn JS, Rhodes CH, Coon CI, Brinckerhoff CE (2007) RNA interference inhibition of matrix metalloproteinase-1 prevents melanoma metastasis by reducing tumor collagenase activity and angiogenesis. Cancer Res 67 (22): 10849–10858.
Boire A, Covic L, Agarwal A, Jacques S, Sherifi S, Kuliopulos A (2005) PAR1 is a matrix metalloprotease-1 receptor that promotes invasion and tumorigenesis of breast cancer cells. Cell 120 (3): 303–313.
Boni A, Cogdill AP, Dang P, Udayakumar D, Njauw CN, Sloss CM, Ferrone CR, Flaherty KT, Lawrence DP, Fisher DE, Tsao H, Wargo JA (2010) Selective BRAFV600E inhibition enhances T-cell recognition of melanoma without affecting lymphocyte function. Cancer Res 70 (13): 5213–5219.
Crawford S, Belajic D, Wei J, Riley JP, Dunford PJ, Bembenek S, Fourie A, Edwards JP, Karlsson L, Brunmark A, Wolin RL, Blevitt JM (2008) A novel B-RAF inhibitor blocks interleukin-8 (IL-8) synthesis in human melanoma xenografts, revealing IL-8 as a potential pharmacodynamic biomarker. Mol Cancer Ther 7 (3): 492–499.
Croteau W, Jenkins MH, Ye S, Mullins DW, Brinckerhoff CE (2013) Differential mechanisms of tumor progression in clones from a single heterogeneous human melanoma. J Cell Physiol 228 (4): 773–780.
Domanska UM, Kruizinga RC, Nagengast WB, Timmer-Bosscha H, Huls G, de Vries EG, Walenkamp AM (2013) A review on CXCR4/CXCL12 axis in oncology: no place to hide. Eur J Cancer 49 (1): 219–230.
Eck SM, Cote AL, Winkelman WD, Brinckerhoff CE (2009) CXCR4 and matrix metalloproteinase-1 are elevated in breast carcinoma-associated fibroblasts and in normal mammary fibroblasts exposed to factors secreted by breast cancer cells. Mol Cancer Res 7 (7): 1033–1044.
Frederick DT, Piris A, Cogdill AP, Cooper ZA, Lezcano C, Ferrone CR, Mitra D, Boni A, Newton LP, Liu C, Peng W, Sullivan RJ, Lawrence DP, Hodi FS, Overwijk WW, Lizee G, Murphy GF, Hwu P, Flaherty KT, Fisher DE, Wargo JA (2013) BRAF inhibition is associated with enhanced melanoma antigen expression and a more favorable tumor microenvironment in patients with metastatic melanoma. Clin Cancer Res 19 (5): 1225–1231.
Gogas HJ, Kirkwood JM, Sondak VK (2007) Chemotherapy for metastatic melanoma: time for a change? Cancer 109 (3): 455–464.
Goldstein LJ, Chen H, Bauer RJ, Bauer SM, Velazquez OC (2005) Normal human fibroblasts enable melanoma cells to induce angiogenesis in type I collagen. Surgery 138 (3): 439–449.
Halaban R, Zhang W, Bacchiocchi A, Cheng E, Parisi F, Ariyan S, Krauthammer M, McCusker JP, Kluger Y, Sznol M (2010) PLX4032, a selective BRAF(V600E) kinase inhibitor, activates the ERK pathway and enhances cell migration and proliferation of BRAF melanoma cells. Pigment Cell Melanoma Res 23 (2): 190–200.
Hingorani SR, Jacobetz MA, Robertson GP, Herlyn M, Tuveson DA (2003) Suppression of BRAF(V599E) in human melanoma abrogates transformation. Cancer Res 63 (17): 5198–5202.
Hofmann UB, Houben R, Brocker EB, Becker JC (2005) Role of matrix metalloproteinases in melanoma cell invasion. Biochimie 87 (3-4): 307–314.
Hua H, Li M, Luo T, Yin Y, Jiang Y (2011) Matrix metalloproteinases in tumorigenesis: an evolving paradigm. Cell Mol Life Sci 68 (23): 3853–3868.
Huntington JT, Shields JM, Der CJ, Wyatt CA, Benbow U, Slingluff CL Jr Brinckerhoff CE (2004) Overexpression of collagenase 1 (MMP-1) is mediated by the ERK pathway in invasive melanoma cells: role of BRAF mutation and fibroblast growth factor signaling. J Biol Chem 279 (32): 33168–33176.
Hwang YS, Jeong M, Park JS, Kim MH, Lee DB, Shin BA, Mukaida N, Ellis LM, Kim HR, Ahn BW, Jung YD (2004) Interleukin-1beta stimulates IL-8 expression through MAP kinase and ROS signaling in human gastric carcinoma cells. Oncogene 23 (39): 6603–6611.
Kay MA, Glorioso JC, Naldini L (2001) Viral vectors for gene therapy: the art of turning infectious agents into vehicles of therapeutics. Nat Med 7 (1): 33–40.
Khalili JS, Liu S, Rodriguez-Cruz TG, Whittington M, Wardell S, Liu C, Zhang M, Cooper ZA, Frederick DT, Li Y, Joseph RW, Bernatchez C, Ekmekcioglu S, Grimm E, Radvanyi LG, Davis RE, Davies MA, Wargo JA, Hwu P, Lizee G (2012) Oncogenic BRAF(V600E) promotes stromal cell-mediated immunosuppression via induction of interleukin-1 in melanoma. Clin Cancer Res 18 (19): 5329–5340.
Koya RC, Mok S, Otte N, Blacketor KJ, Comin-Anduix B, Tumeh PC, Minasyan A, Graham NA, Graeber TG, Chodon T, Ribas A (2012) BRAF inhibitor vemurafenib improves the antitumor activity of adoptive cell immunotherapy. Cancer Res 72 (16): 3928–3937.
Lazar-Molnar E, Hegyesi H, Toth S, Falus A (2000) Autocrine and paracrine regulation by cytokines and growth factors in melanoma. Cytokine 12 (6): 547–554.
Lederle W, Depner S, Schnur S, Obermueller E, Catone N, Just A, Fusenig NE, Mueller MM (2011) IL-6 promotes malignant growth of skin SCCs by regulating a network of autocrine and paracrine cytokines. Int J Cancer 128 (12): 2803–2814.
Lu P, Weaver VM, Werb Z (2012) The extracellular matrix: a dynamic niche in cancer progression. J Cell Biol 196 (4): 395–406.
Mantovani A, Savino B, Locati M, Zammataro L, Allavena P, Bonecchi R (2010) The chemokine system in cancer biology and therapy. Cytokine Growth Factor Rev 21 (1): 27–39.
Melnikova VO, Balasubramanian K, Villares GJ, Dobroff AS, Zigler M, Wang H, Petersson F, Price JE, Schroit A, Prieto VG, Hung MC, Bar-Eli M (2009) Crosstalk between protease-activated receptor 1 and platelet-activating factor receptor regulates melanoma cell adhesion molecule (MCAM/MUC18) expression and melanoma metastasis. J Biol Chem 284 (42): 28845–28855.
Nicholas C, Lesinski GB (2011) Immunomodulatory cytokines as therapeutic agents for melanoma. Immunotherapy 3 (5): 673–690.
Portella L, Vitale R, De Luca S, D’Alterio C, Ierano C, Napolitano M, Riccio A, Polimeno MN, Monfregola L, Barbieri A, Luciano A, Ciarmiello A, Arra C, Castello G, Amodeo P, Scala S (2013) Preclinical development of a novel class of CXCR4 antagonist impairing solid tumors growth and metastases. PLoS ONE 8 (9): e74548.
Rutter JL, Mitchell TI, Buttice G, Meyers J, Gusella JF, Ozelius LJ, Brinckerhoff CE (1998) A single nucleotide polymorphism in the matrix metalloproteinase-1 promoter creates an Ets binding site and augments transcription. Cancer Res 58 (23): 5321–5325.
Ryu B, Moriarty WF, Stine MJ, DeLuca A, Kim DS, Meeker AK, Grills LD, Switzer RA, Eller MS, Alani RM (2011) Global analysis of BRAFV600E target genes in human melanocytes identifies matrix metalloproteinase-1 as a critical mediator of melanoma growth. J Invest Dermatol 131 (7): 1579–1583.
Scala S, Ottaiano A, Ascierto PA, Cavalli M, Simeone E, Giuliano P, Napolitano M, Franco R, Botti G, Castello G (2005) Expression of CXCR4 predicts poor prognosis in patients with malignant melanoma. Clin Cancer Res 11 (5): 1835–1841.
Schroder AR, Shinn P, Chen H, Berry C, Ecker JR, Bushman F (2002) HIV-1 integration in the human genome favors active genes and local hotspots. Cell 110 (4): 521–529.
Sharma A, Tran MA, Liang S, Sharma AK, Amin S, Smith CD, Dong C, Robertson GP (2006) Targeting mitogen-activated protein kinase/extracellular signal-regulated kinase kinase in the mutant (V600E) B-Raf signaling cascade effectively inhibits melanoma lung metastases. Cancer Res 66 (16): 8200–8209.
Shi H, Moriceau G, Kong X, Lee MK, Lee H, Koya RC, Ng C, Chodon T, Scolyer RA, Dahlman KB, Sosman JA, Kefford RF, Long GV, Nelson SF, Ribas A, Lo RS (2012) Melanoma whole-exome sequencing identifies (V600E)B-RAF amplification-mediated acquired B-RAF inhibitor resistance. Nat Commun 3: 724.
Straussman R, Morikawa T, Shee K, Barzily-Rokni M, Qian ZR, Du J, Davis A, Mongare MM, Gould J, Frederick DT, Cooper ZA, Chapman PB, Solit DB, Ribas A, Lo RS, Flaherty KT, Ogino S, Wargo JA, Golub TR (2012) Tumour micro-environment elicits innate resistance to RAF inhibitors through HGF secretion. Nature 487 (7408): 500–504.
Sullivan RJ, Flaherty K (2013) MAP kinase signaling and inhibition in melanoma. Oncogene 32 (19): 2373–2379.
Sumimoto H, Imabayashi F, Iwata T, Kawakami Y (2006) The BRAF-MAPK signaling pathway is essential for cancer-immune evasion in human melanoma cells. J Exp Med 203 (7): 1651–1656.
Teicher BA, Fricker SP (2010) CXCL12 (SDF-1)/CXCR4 pathway in cancer. Clin Cancer Res 16 (11): 2927–2931.
van Kempen LC, Rijntjes J, Mamor-Cornelissen I, Vincent-Naulleau S, Gerritsen MJ, Ruiter DJ, van Dijk MC, Geffrotin C, van Muijen GN (2008) Type I collagen expression contributes to angiogenesis and the development of deeply invasive cutaneous melanoma. Int J Cancer 122 (5): 1019–1029.
Villanueva J, Herlyn M (2008) Melanoma and the tumor microenvironment. Curr Oncol Rep 10 (5): 439–446.
Villares GJ, Zigler M, Bar-Eli M (2011) The emerging role of the thrombin receptor (PAR-1) in melanoma metastasis—a possible therapeutic target. Oncotarget 2 (1-2): 8–17.
Vultur A, Villanueva J, Herlyn M (2011) Targeting BRAF in advanced melanoma: a first step toward manageable disease. Clin Cancer Res 17 (7): 1658–1663.
Walker RA, Woolley DE (1999) Immunolocalisation studies of matrix metalloproteinases-1, -2 and -3 in human melanoma. Virchows Arch 435 (6): 574–579.
Wang T, Ge Y, Xiao M, Lopez-Coral A, Azuma R, Somasundaram R, Zhang G, Wei Z, Xu X, Rauscher FJ 3rd, Herlyn M, Kaufman RE (2012) Melanoma-derived conditioned media efficiently induce the differentiation of monocytes to macrophages that display a highly invasive gene signature. Pigment Cell Melanoma Res 25 (4): 493–505.
Waugh DJ, Wilson C (2008) The interleukin-8 pathway in cancer. Clin Cancer Res 14 (21): 6735–6741.
Weber A, Wasiliew P, Kracht M (2010a) Interleukin-1 (IL-1) pathway. Sci Signal 3 (105): cm1.
Weber A, Wasiliew P, Kracht M (2010b) Interleukin-1beta (IL-1beta) processing pathway. Sci Signal 3 (105): cm2.
Yin M, Soikkeli J, Jahkola T, Virolainen S, Saksela O, Holtta E (2012) TGF-beta signaling, activated stromal fibroblasts, and cysteine cathepsins B and L drive the invasive growth of human melanoma cells. Am J Pathol 181 (6): 2202–2216.
Zigler M, Kamiya T, Brantley EC, Villares GJ, Bar-Eli M (2011) PAR-1 and thrombin: the ties that bind the microenvironment to melanoma metastasis. Cancer Res 71 (21): 6561–6566.
Acknowledgements
This work was supported by grants from the National Institutes of Health: R01 AR-26599 and R01 CA-77267, by a Norris Cotton Cancer Center Pilot Grant, and by the Ruth L. Kirschstein National Research Service award: F32FCA144479A.
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Whipple, C., Brinckerhoff, C. BRAFV600E melanoma cells secrete factors that activate stromal fibroblasts and enhance tumourigenicity. Br J Cancer 111, 1625–1633 (2014). https://doi.org/10.1038/bjc.2014.452
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DOI: https://doi.org/10.1038/bjc.2014.452
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