Melanoma is one of the most lethal cancers when it reaches a metastatic stage. Despite advancements in targeted therapies (BRAF inhibitors) or immunotherapies (anti-CTLA-4 or anti-PD1), most patients with melanoma will need additional treatment. Thus, there is an urgent need to develop new therapeutical approaches to bypass resistance and achieve more prolonged responses. In this context, we were interested in E2F1, a transcription factor that plays a major role in the control of cell cycle under physiological and pathological conditions. Here we confirmed that E2F1 is highly expressed in melanoma cells. Inhibition of E2F1 activity further increased melanoma cell death and senescence, both in vitro and in vivo. Moreover, blocking E2F1 also induced death of melanoma cells resistant to BRAF inhibitors. In conclusion, our studies suggest that targeting the E2F1 signaling pathway may be therapeutically relevant for melanoma.
Cutaneous melanoma is one of the most lethal cancers among young adults. Melanoma has a high capability of rapid invasion and metastasizes to other organs. When lymph nodes metastase, the prognosis worsens considerably with a survival rate of 50% at 5 years. The increased knowledge about the molecular mechanisms of melanoma has revolutionized its treatment. Approximately half of melanomas express mutations in the protein kinase BRAF (such as BRAFV600E) that constitutively activate the mitogen-activated protein kinase (MAPK) pathway and result in a dysregulated proliferation irrespective of the presence of growth factors. The BRAF mutation constitutes a potential target for new anti-melanoma treatments, and the BRAF inhibitors vemurafenib and dabrafenib have demonstrated an improvement in both overall survival and progression-free survival1. Unfortunately, despite encouraging response rates seen using BRAF inhibitors, relapses usually occur within months after treatment2. Over the past 2 years, tremendous efforts have been directed toward understanding the molecular mechanisms of acquired BRAF inhibitor resistances3,4. Further, immunotherapies such as anti-CTLA-4 or anti-PD1 antibodies, which reactivate the immunity response of the patient, achieve durable responses or stable disease, but only in approximately 10 to 35% of patients5. Thus, there is an urgent need to develop new therapeutic approaches to bypass resistance and achieve more prolonged responses.
Cell proliferation is a tightly regulated process that comprises cyclins, cyclin-dependent kinases (CDKs), transcription factors, and CDK inhibitors6. The E2F1 transcription factor plays a major role in the control of cell cycle, in physiological and pathological conditions7. Deciphering the bona fide target genes of E2F1 demonstrated the key roles for this transcription factor in the regulation of cellular and tissue functions. Indeed, apoptosis, senescence, and glucose homeostasis are important mechanisms finely tuned by E2F1. Interestingly, recent data demonstrated that the overexpression of this factor is found in several types of cancers8. Altogether, these data suggest E2F1 as a potential therapeutic target for cancer cells. While E2F proteins, in particular E2F1, have emerged as critical players in melanoma development9,10,11, our mechanistic understanding of its regulation and function remains limited. Here, we report a key role for E2F1 in the control of melanoma cell death and drug sensitivity. E2F1 is highly expressed in melanoma cells. Depletion of E2F1 using small interfering RNA (siRNA) or pharmacological blockade of E2F activity further increased melanoma cell death and senescence, both in vitro and in vivo. Death and senescence induced by inhibition of E2F1 are as a result of p53 and p27 activation. Moreover, blocking E2F1 also induced death of melanoma cells resistant to BRAF inhibitors, and E2F1 inhibition increases sensitivity of melanoma cells to BRAF inhibitors. Our studies suggest that targeting the E2F1 signaling pathway may be therapeutically relevant for treatment of melanoma patients.
E2F1 is overexpressed in melanoma
Using publically available microarray data12, we analyzed E2F1 expression and detected increased E2F1 mRNA levels in human melanoma biopsies compared to healthy skin and naevus (Fig. 1a). Interestingly, in a cohort of patients, followed in a clinic for 3 years after excision of metastatic lesions13, those with high E2F1 showed significantly lower survival (Fig. 1b). Using immunohistological analysis of human biopsies, we detected E2F1 staining in primary melanoma, with a robust expression in metastatic melanoma. E2F1 protein levels were not detected in non-cancerous tissues including skin and naevi (Fig. 1c and Table 1). By probing a panel of primary and metastatic melanoma cell lines and human melanocytes, we found that E2F1 is also strongly expressed in different melanoma cell lines and in melanoma cells freshly isolated from patients (Fig. 1d). Altogether, these findings confirm that E2F1 is highly expressed in melanoma cells.
Inhibition of E2F1 has an anti-proliferative effect on melanoma cells
To assess whether E2F1 modulates the proliferation of melanoma cells, we developed two complementary approaches to inhibit E2F1 expression and/or activity. First, depletion of E2F1 by two different siRNA resulted in the inhibition of cellular viability in a time-dependent manner (Fig. 2a). These results were replicated using several melanoma cells with different mutational status (Fig. 2b). We observed that the genetic inhibition of E2F1 induced loss of viability of these cancer cells. Interestingly, TP53-mutated cell lines (Sk-Mel 28 and the patient cells C-13.08) were resistant to E2F1 inhibition (Fig. 2b). In the complementary fashion, the use of pharmacological inhibitors of E2F1 and E2F4, HLM0064749, demonstrated the same effect on inhibition of cell viability (Supp Figure 1A and B). In parallel, we have evaluated some relevant E2F1 target genes by real-time quantitative reverse transcription PCR (qRT-PCR) after inhibition of E2F1 using siRNA or pharmacological inhibitor (Supp Figure 1C). Some genes such as BIRC5, CDC6, or BRCA1 are inhibited in the same way by siE2F1 and HLM006474 and other genes such BCL2 or C-jun are inhibited only by siE2F1.
We observed that inhibition of E2F1 does not affect E2F4 expression (Supp Figure 1D), suggesting a specificity of siRNA for E2F1. Interestingly, in the cohort of Bogunovic’s patients13, patients with high E2F4 did not have lower survival rates (Supp Figure 1E). We next observed that normal melanocytes and keratinocytes were resistant to the HLM006474 inhibitor (Supp Figure 1F). Finally, we tested HLM006474 in mice using xenograft experiments. Six days after injection of A375 in immunodeficient mice, we treated them with the vehicle or HLM006474 (2 mg per day per mouse) by intraperitoneal injection for 8 days and we followed their tumor development. Mice treated with HLM006474 demonstrated significantly reduced tumor growth compared to vehicle-treated animals (Supp Figure 1G). A strong decrease in the tumor weight and size were observed in mice treated with HLM006474 (Supp Figure 1H).
Since the genetic inhibition of E2F1 in melanoma cells that are mutated for p53 does not affect their viability, we hypothesized an implication of the p53 pathway. To test this, we performed different sets of experiments. First, we used a construct of p53-responsive elements fused to the luciferase reporter and observed that inhibition of E2F1 by siRNA led to transcriptional activation of p53 (Fig. 2c). This was confirmed by Western blot in two separate melanoma cell lines (A375 and 1205Lu) as well as in primary human melanoma cells (Fig. 2d). Interestingly, HLM006474 induced the same effect on p53 expression level (Supp Figure 2A), and tumors of HLM006474-treated mice had increased levels of p53 (Supp Figure 2B). Immunofluorescence experiments revealed that inhibition of E2F1 led to an increase expression and a nuclear localization of p53 (Fig. 2e and Supp Figure 2C).
To further decipher the functional contribution of p53 in E2F1-mediated control of melanoma cell proliferation, we silenced p53 expression in A375 cells and human melanoma cells freshly isolated from patient. Blocking p53 expression abrogated the decreased viability induced by E2F1 inhibition (Fig. 2f). Conversely, we performed rescue experiments in p53-mutated Mewo and SK-Mel 28 cells using an adenoviral approach. Although no effects on cell viability was observed when cells were transduced with the control adenovirus, wild-type p53 overexpression sensitized Mewo and SK-Mel 28 cells to E2F1 inhibition and reduced their cellular viability (Fig. 2g).
Collectively, these results suggest that the effects of E2F1 inhibition on melanoma cell death requires p53 activation and demonstrates that the E2F1 pharmacological inhibition may control tumor development in mice.
E2F1 inhibition induces cell cycle arrest and apoptosis
To further understand the molecular mechanisms linking E2F1 and melanoma cell viability, we measured cell cycle phases by propidium iodide (PI) labeling in A375 melanoma cells. Inhibiting E2F1 by siRNA induced an arrest in the G1 phase and HLM006474 induced an arrest in the G2/M phase (Supp Figure 3a). We confirmed these results by immunoblot (data not shown). We also determined apoptosis by performing a double Annexin V + DAPI (4',6-diamidino-2-phenylindole) labeling in A375 melanoma cells. Inhibiting E2F1 by siRNA or HLM006474 strongly increased the number of Annexin V + DAPI-positive cells, characteristic of apoptosis (Fig. 3a and Supp Figure 3B). This effect was associated with decreased levels of the anti-apoptotic protein Bcl-2, increased poly (ADP-ribose) polymerase (PARP) cleavage, and decreased zymogen form of caspase-3 (Fig. 3a and Supp Figure 3B). These results were confirmed in other melanoma cells (Fig. 3b, c and Supp Figure 3C and D) and tumors of mice injected with the E2F inhibitor (Supp Figure 3E). As expected, caspase-3 activation was observed after E2F1 inhibition (Fig. 3d). Flow cytometry measurements of apoptosis after silencing caspase-3 further demonstrated its contribution to apoptosis following E2F1 inhibition (Fig. 3e). Blocking caspase-3 or p53 by siRNA inhibited the cleavage of PARP (Fig. 3e), confirming that both caspase-3 and p53 are necessary to induce apoptosis upon E2F1 inhibition.
E2F1 inhibition leads to a p53-dependent program of senescence
Although we demonstrated that apoptosis contributed to the observed effect on cell proliferation, this process only partially restored the loss of cellular proliferation induced by the inhibition of E2F1 (Fig. 4a). This indicated that other mechanisms could contribute to reduced cell viability. Flow cytometry experiments demonstrated that the inhibition of E2F1 led to an increase in size and the granularity of melanoma cells (Fig. 4b and Supp Figure 4A and B), which are morphological characteristics of cellular senescence14. Inhibition of E2F1 increased the β-galactosidase activity of melanoma cells (Fig. 4c and Supp Figure 4C). The senescence program is associated with induction of DNA damage and increased 53BP1 foci in damaged cells. After inhibition of E2F1, immunofluorescence analysis confirmed increased 53BP1 foci in cells with altered E2F1 activity (Fig. 4d and Supp Figure 4D). The induction of DNA damage following the inhibition of E2F1 correlated with increased amount of phospho (p)-CHK2 and γH2AX protein, two markers of this process (Fig. 4e and Supp Figure 4E). We also observed p38 activation and a concomitant decrease in c-Myc and phosphorylated (p)-Rb, as well as an increase in p27 and p21 activation (Fig. 4e and Supp Figure 4E). These results were confirmed in other melanoma cells and in tumors of mice treated with E2F inhibitor (Supp Figure 4F and G).
We next determined whether p53 and p27 were key mediators of the senescence program triggered by E2F1 inhibition, and whether apoptosis and senescence were two independent mechanisms that contributed to reduce cell viability. siRNA-mediated inhibition of caspase-3 demonstrated increased size and granularity (Fig. 4f) and β-galactosidase staining (Fig. 4g) of melanoma cells. Moreover, these effects were associated with increased p21, p27, p-Chk2, and γH2AX protein but decreased p-Rb (Fig. 4h). In contrast, siRNA-mediated inhibition of p53 or p27 did not increase the size or the granularity of the cells (Fig. 4f), nor β-galactosidase activity (Fig. 4g) or p21, p27, p-Chk2, γH2AX, and p-Rb (Fig. 4h).
Our results indicate that the process of senescence induced by the inhibition of E2F1 is dependent on the p53 and p27 and that apoptosis and senescence may occur independently. Finally, we determined that siE2F4 are also able to induce death of melanoma cells by apoptosis. However, contrary to siE2F1, siE2F4 did not induce senescence (Supp Figure 5).
E2F1 inhibition increases sensitivity of the melanoma cells to BRAF inhibitors and induces the death of the vemurafenib-resistant melanoma cells
We next wondered whether inhibiting E2F1 could potentiate the effects of the BRAF inhibitors, vemurafenib (PLX4032) and dabrafenib. We first assessed the effect of PLX4032 on E2F1 and E2F4 levels and we observed that BRAF inhibitors, PLX4032 and dabrafenib, reduce E2F1 and E2F4 levels (Fig. 5a). Second, we investigated whether E2F1 depletion acts synergistically with BRAF inhibitors to enhance its pro-apoptotic effect on melanoma cells. Whereas increasing doses of PLX4032 or dabrafenib or E2F1 depletion alone reduced cell viability (Fig. 5b), combination of BRAF and E2F1 inhibition resulted in increased cell death in BRAF mutant lines (Fig. 5b). Using double-labeling Annexin V + DAPI and flow cytometry, we observed a strong increase in the percentage of double-positive cells that are characteristic of apoptotic cell death, when combined treatments were used (Fig. 5c). To confirm this apoptosis, western blot analysis indicates that the combination of BRAF inhibitor treatment and E2F1 depletion drastically decreased the pro-form of the caspase-3 and Bcl-2 and led to increased PARP cleavage (Fig. 5d). We next used a series of different BRAF-resistant melanoma cells15. Intriguingly, the inhibition of E2F1 induced loss of cell viability of sensitive and BRAF inhibitor-resistant melanoma cells (Fig. 5e). In order to determine whether apoptosis could be responsible for the apparent cell death, western blot analysis indicated that E2F1 depletion decreases pro-form of the caspase-3 and Bcl-2, and an increase in PARP cleavage, p53 and p27 (Fig. 5f). To confirm this apoptosis, we quantified Annexin V + DAPI co-stained cells by flow cytometry and have shown that inhibition of E2F1 led to an increase in Annexin V + DAPI labeling in double-labeled cells that were resistant to PLX4032 (Fig. 5g). In parallel, we observed that E2F1 inhibition is also able to induce DNA damage in A375-resistant melanoma cells as indicated by increased expression of γH2AX (Fig. 5f). We next carried out experiments to evaluate the effects of E2F1 blocking in combination with BRAF inhibitor, PLX4032, in BRAF inhibitor-resistant melanoma cells. As presented in Supp Figure 6, we observed that co-inhibition of BRAF by PLX4032 and E2F1 by siRNA did not increase apoptosis (PARP cleavage and Annexin V-positive cells) or DNA damage (γH2AX) in comparison to E2F1 inhibition alone. These results indicate that BRAF inhibitors do not increase the death induced by inhibition of E2F1.
Metastatic melanoma is notoriously refractory to conventional cancer therapies and remains largely resistant to current targeted therapies. Our study has demonstrated that inhibition of E2F1 (transcription factor from E2F1 family) is effective in decreasing melanoma cell viability in both sensitive and resistant metastatic melanoma cells.
E2F1 is the most studied member of the family and presents several yet opposing roles in the control of cell growth and apoptosis, depending on the cell type or tissue contexts. E2F gene amplification has been described in various cancer cell lines and tumor types11. Further, higher levels of E2F1 are frequently associated with high-grade tumors and poor patient survival prognosis13,16. Our results are in agreement with those in the literature showing higher expression of E2F1 in metastatic melanoma and bring novel data regarding its mechanisms of effect, and, importantly, give an important insight into its potential beneficial role in resistive patients.
The role of E2F1 in apoptosis is contradictory. It has been reported that the ambivalent pro-apoptotic or anti-apoptotic function of E2F1 depends on the tissue type and/or cellular contexts. In our system, we confirm that inhibition of E2F1 using siRNA in melanoma cells leads to apoptotic cell death. This was demonstrated using multiple techniques including the number of Annexin V/DAPI-double-positive cells, PARP cleavage, activation of caspase-3, and anti-apoptotic protein Bcl-2. We also demonstrated that E2F1 inhibition in melanoma cells induces a cellular phenotype displaying several hallmarks of senescence, such as larger but flatter cells with more granulation and increased senescence-associated-β-gal (SA-β-Gal) activity. Analyzing the expression of proteins involved in the control of the cell cycle and senescence revealed increased p21CIP1 and p27KIP1 when E2F1 activity is lowered17,18,19,20. Our study also highlighted that the crucial role of p21 and/or p27 is the control of E2F1-dependent senescence.
The senescence program is often associated with DNA damage14,21. These observations prompted us to investigate the involvement and the role of DNA damage following E2F1 inhibition. In agreement with our hypothesis, we have shown that the senescence mediated by E2F1 inhibition engages a broad DNA damage response signaling pathway. In addition, we observed that inhibition of E2F1 in melanoma cells leads to the presence of 53BP1 foci and increased γH2AX, two mediators recruited and phosphorylated at DNA-damaged sites. We also observed the activation of the critical mediator of cellular responses to DNA damage, CHK2. Noteworthy, although we cannot rule out the existence of DNA single-strand breaks, engagement of the γH2AX/53BP1/CHK2 cascade in E2F1-inhibited cells strongly indicates that the type of DNA damage is mainly double-strand breaks. Recent data described that reactive oxygen species (ROS) play a crucial role in maintaining DNA damage, which is necessary for a stable arrest of the proliferation that is characteristic of a senescence program22. As shown here, E2F1 inhibition leads to increased ROS production, which could be the initiating factor of this program. However, our data using N-acetyl cysteine to prevent ROS induction did not inhibit cell viability and induction of senescence mediated by siE2F1, suggesting that ROS are not involved in these process (Supp Figure 3J and data not shown). Interestingly, these senescence program and DNA damage response are also independent of apoptosis mechanism.
One protein that can mediate these different effects is the tumor suppressor p53. Indeed, p53 functions as a transcriptional regulator of genes involved in cell cycle arrest, autophagy, senescence, and apoptosis pathways. First, we demonstrated that the inhibition of E2F1 increases p53 expression and activity. Second, melanoma cells harboring a mutated TP53 gene exhibited no modification of melanoma viability after E2F1 inhibition. Identical results were obtained when we invalidated endogenous p53 in melanoma cells. This effect is not associated with apoptosis, DNA damage, or senescence induction. Interestingly, rescuing the expression of TP53 in p53-knockdown cells restores E2F1 inhibition effects, further indicating the key function of p53 in mediating the effects of E2F1 inhibition in our cellular models. In addition, our studies suggest that E2F1 functions upstream of p53 in the crosstalk between these two transcription factors in the context of apoptosis and senescence.
In parallel, we have evaluated the anti-melanoma activity of the E2F inhibitor HLM006474 in intact melanoma cells and in a mouse model of melanoma xenograft. As previously described, HLM006474 is not specific for E2F1 as it can also inhibit E2F49. In melanoma cells, HLM006474 induces similar effect as observed with specific E2F1 siRNA. As blocking E2F4 also inhibited melanoma cell viability, it is not excluded that the effects of HLM006474 could also be mediated by E2F4 inhibition. Further studies will be necessary to determine the respective contribution of E2F1 and E2F4 in the effects of HLM006474 in melanoma cells.
Importantly, we found that short-term administration of HLM006474 dramatically reduces the development of melanoma tumors in mice. In addition, HLM006474 induces no apparent toxicity, as the body weight and overall appearance of mice given an HLM006474 regimen were not different from controls. To determine whether the molecular events observed in melanoma cells were also found in xenograft mice, we performed western blot analysis which indicated p53 activation induced by HLM006474, induction of apoptosis, and DNA damage in tumors of treated mice. In mice, we saw no effect on normal cells (melanocytes/keratinocytes) demonstrating specificity of E2F inhibitor in melanoma cells.
The development of resistance to BRAF inhibitors is a major obstacle in targeted therapy for melanoma. Our data clearly indicate that E2F1 inhibition potentiates the anti-proliferative and pro-apoptotic effects of BRAF inhibitors, PLX4032 and dabrafenib, in melanoma cell lines sensitive to BRAF inhibitor. The restoration of p53 activity in melanoma p53-deficient cells is effective in increasing the sensitivity of melanoma cells to the BRAF-MAPK inhibitor pathway23,24. Given that the effects of E2F1 inhibition on cell viability are p53 dependent, we postulate that these effects on BRAF inhibitor sensitivity are mediated through p53 activation. This hypothesis is currently tested in our laboratory. Furthermore, our data also indicate that BRAF inhibitors reduce E2F1 expression and this is likely to be due to G1/S arrest observed in response to these compounds. We next performed experiments in BRAF inhibitor-resistant melanoma cells. There have been multiple mechanisms previously proposed25. We failed to detect classical secondary mutations in NRAS, KRAS, or MEK, or elevated levels of BRAF or alternatively splice isoforms15. E2F1 inhibition decreased the viability of melanoma cells with acquired resistance to BRAF inhibitor through the induction of apoptosis and DNA damage. We were not able to determine if the loss of E2F1 led to senescence process in the resistant cells due to the large cell death observed. Further, our experiments indicate that BRAF inhibitors do not increase the death induced by inhibition of E2F1 in melanoma cells resistant to BRAF inhibitors.
Taken together, E2F1 loss enhances sensitivity of melanoma cells to targeted therapies and induces the death of BRAF inhibitor-resistant melanoma cells. Collectively, these data suggest that E2F1 is a critical mediator of melanoma drug sensitivity and may serve as an important target for novel therapeutic strategies. Further, this study provides compelling data to support future evaluation of HLM006474 in clinical trials and strengthen the hypothesis that E2F inhibitors could be useful as a new therapeutic approach for melanoma treatment.
Materials and methods
Reagents and antibodies
Trypan blue, Dulbecco's modified Eagle's medium, RPMI, trypsin, and siRNA were purchased from Life Technologies. Annexin V and DAPI were purchased from Roche Applied Science. Dabrafenib and PLX4032 were purchased from Euromedex. Antibodies against HSP90, E2F1, E2F4, Rb, and phospho-Rb were from Santa Cruz Biotechnology (TEBU, Le Perray en Yvelines, France). Antibodies against PARP, pro-caspase-3, p38, phospho-p38, MDM2, Chk2, p-Chk2, p21, and p27 were from BD Bioscience (Pont de Claix, France) and anti-H2AX was from Merck Millipore (Fontenay-sous-Bois, France).
The E2F1 siRNA number 1 corresponds to a Smart pool (Dharmacon ref: L-003259-00-0005) and the siRNA number 2 was purchassed to Ambion (Ref: 4390824).
Melanocytes and fibroblasts were prepared as described26. Different melanoma cell lines were purchased from American Tissue Culture Collection. Resistant melanoma cell lines A375 and WM9 were a gift from Pr. Marchetti and as described15 (see Supplemental Materials and methods). Fresh sterile tissues were obtained as surgical waste from patients diagnosed for metastatic melanoma at the Nice CHU hospital and treated as reported27.
Transfection of duplex siRNAs was as described28.
Trypan blue exclusion assay
Trypan blue staining was conducted as described29.
Luciferase assays were conducted as described29.
Western blot assay
Western blot analyses were performed as described30.
Immunofluorescence staining was performed as described31.
SA-beta-Gal Kit (Cell Signaling Technology) was used to histochemically detect β-galactosidase activity.
Flow cytometry analysis
Cells were stained with DAPI and Annexin V or Cell ROX Deep Red and analyzed using fluorescence-activated cell sorter (MACSQuant Analyzer) and MACSQuantify software as described32.
In vivo murine cancer model
Animal experiments were carried out in accordance with French law and were approved by a local institutional ethical committee CIEPAL. A375 cells were subcutaneously inoculated in the left dorsal side of 6-week-old female athymic nude nu/nu mice (Harlan, Gannat, France). The tumor size was assessed using calipers, and the volume was calculated according to the formula: tumor volume (mm3) = tumor width × length2 × 0.5. At the end of the experiment, mice were killed, tumors were excised, and then analyzed.
Unless stated otherwise, experiments shown were representative of at least three independent experiments. All data were presented as means ± standard deviation. Statistical analysis was performed using the Student's t test: *P < 0.05 vs. control, **P < 0.01 vs. control, and *** P < 0.001 vs. control deemed statistically significant. For microarray analysis, Mann–Whitney test was performed.
Flaherty, K. T. et al. Inhibition of mutated, activated BRAF in metastatic melanoma. N. Engl. J. Med. 363, 809–819 (2010).
Sosman, J. A. et al. Survival in BRAF V600-mutant advanced melanoma treated with vemurafenib. N. Engl. J. Med. 366, 707–714 (2012).
Das Thakur, M. et al. Modelling vemurafenib resistance in melanoma reveals a strategy to forestall drug resistance. Nature 494, 251–255 (2013).
Millet, A., Martin, A. R., Ronco, C., Rocchi, S. & Benhida, R. Metastatic melanoma: insights into the evolution of the treatments and future challenges. Med. Res. Rev. 37, 98–148 (2016).
Ott, P. A., Hodi, F. S. & Robert, C. CTLA-4 and PD1/PD-L1 blockade: new immunotherapeutic modalities with durable clinical benefit in melanoma patients. Clin. Cancer Res. 19, 5300–5309 (2013).
Blanchet, E., Annicotte, J. S. & Fajas, L. Cell cycle regulators in the control of metabolism. Cell Cycle 8, 4029–4031 (2009).
Engelmann, D. & Putzer, B. M. The dark side of E2F1: in transit beyond apoptosis. Cancer Res. 72, 571–575 (2012).
Meng, P. & Ghosh, R. Transcription addiction: can we garner the Yin and Yang functions of E2F1 for cancer therapy? Cell Death Dis. 5, e1360 (2014).
Ma, Y. et al. A small-molecule E2F inhibitor blocks growth in a melanoma culture model. Cancer Res. 68, 6292–6299 (2008).
Verhaegen, M., Checinska, A., Riblett, M. B., Wang, S. & Soengas, M. S. E2F1-dependent oncogenic addiction of melanoma cells to MDM2. Oncogene 31, 828–841 (2012).
Alla, V. et al. E2F1 in melanoma progression and metastasis. J. Natl. Cancer Inst. 102, 127–133 (2010).
Talantov, D. et al. Novel genes associated with malignant melanoma but not benign melanocytic lesions. Clin. Cancer Res. 11, 7234–7242 (2005).
Bogunovic, D. et al. Immune profile and mitotic index of metastatic melanoma lesions enhance clinical staging in predicting patient survival. Proc. Natl. Acad. Sci. USA 106, 20429–20434 (2009).
Giuliano, S. et al. Microphthalmia-associated transcription factor controls the DNA damage response and a lineage-specific senescence program in melanomas. Cancer Res. 70, 3813–3822 (2010).
Corazao-Rozas, P. et al. Mitochondrial oxidative stress is the Achille’s heel of melanoma cells resistant to Braf mutant inhibitor. Oncotarget 4, 1986–1998 (2013).
Nelson, M. A. et al. Increased gene copy number of the transcription factor E2F1 in malignant melanoma. Cancer Biol. Ther. 5, 407–412 (2006).
Alexander, K. & Hinds, P. W. Requirement forp27(KIP1) in retinoblastoma protein-mediated senescence. Mol. Cell. Biol. 21, 3616–3631 (2001).
Ji, P. et al. An Rb-Skp2-p27 pathway mediates acute cell cycle inhibition by Rb and is retained in a partial-penetrance Rb mutant. Mol. Cell 16, 47–58 (2004).
Thomas, D. M. et al. Terminal osteoblast differentiation, mediated by runx2 and p27KIP1, is disrupted in osteosarcoma. J. Cell Biol. 167, 925–934 (2004).
Phalke, S. et al. p53-Independent regulation of p21Waf1/Cip1 expression and senescence by PRMT6. Nucleic Acids Res. 40, 9534–9542 (2012).
Falletta, P. et al. Translation reprogramming is an evolutionarily conserved driver of phenotypic plasticity and therapeutic resistance in melanoma. Genes Dev. 31, 18–33 (2017).
Passos, J. F. et al. Feedback between p21 and reactive oxygen production is necessary for cell senescence. Mol. Syst. Biol. 6, 347 (2010).
Ji, Z. et al. Vemurafenib synergizes with nutlin-3 to deplete survivin and suppresses melanoma viability and tumor growth. Clin. Cancer Res. 19, 4383–4391 (2013).
Posch, C. et al. Combined Inhibition of MEK and Plk1 has synergistic antitumor activity in NRAS mutant melanoma. J. Invest. Dermatol. 135, 2475–2483 (2015).
Eggermont, A. M., Spatz, A. & Robert, C. Cutaneous melanoma. Lancet 383, 816–827 (2014).
Botton, T. et al. In vitro and in vivo anti-melanoma effects of ciglitazone. J. Invest. Dermatol. 129, 1208–1218 (2009).
Lehraiki, A. et al. Increased CD271 expression by the NF-kB pathway promotes melanoma cell survival and drives acquired resistance to BRAF inhibitor vemurafenib. Cell Discov. 1, 15030 (2015).
Botton, T. et al. Ciglitazone negatively regulates CXCL1 signaling through MITF to suppress melanoma growth. Cell Death Differ. 18, 109–121 (2011).
Cerezo, M. et al. Compounds triggering ER stress exert anti-melanoma effects and overcome BRAF inhibitor resistance. Cancer Cell 29, 805–819 (2016).
Lehraiki, A. et al. Inhibition of melanogenesis by the antidiabetic metformin. J. Invest. Dermatol. 134, 2589–2597 (2014).
Cerezo, M. et al. Metformin blocks melanoma invasion and metastasis development in a p53-dependent manner. Mol. Cancer Ther. 12, 1605–1615 (2013).
Rouaud, F., Boucher, J. L., Slama-Schwok, A. & Rocchi, S. Mechanism of melanoma cells selective apoptosis induced by a photoactive NADPH Analogue. Oncotarget 7, 82804–82819 (2016).
We sincerely thank P. Marchetti and J. Kluza (INSERM U837, équipe 4, Lille, France) for A375 melanoma-resistant cell line. This research was supported by INSERM, University of Nice Sophia-Antipolis, INSERM transfert (COPOC grant), and ARC contract no. SFI 20121205378, by grants from « European Genomic Institute for Diabetes » (E.G.I.D, ANR-10-LABX-46 to J.-S.A.). M.C. is a recipient of a doctoral fellowship from the ARC. INSERM U1065, team 1 is « équipe labelisée ARC 2016».
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The authors declare that they have no conflict of interest.
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Rouaud, F., Hamouda-Tekaya, N., Cerezo, M. et al. E2F1 inhibition mediates cell death of metastatic melanoma. Cell Death Dis 9, 527 (2018). https://doi.org/10.1038/s41419-018-0566-1
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