Project description:The BRAF V600E mutation leads to constitutive activation of the mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) pathway and its downstream effector responses. Uncovering the hidden downstream effectors can aid in understanding melanoma biology and improve targeted therapy efficacy. The inflammasome sensor, NACHT, LRR, and PYD domains-containing protein 1 (NLRP1), is responsible for IL-1β maturation and itself is a melanoma tumor promoter. Here, we report that NLRP1 is a downstream effector of MAPK/ERK signaling through the activating transcription factor 4 (ATF4), creating regulation in metastatic melanoma cells. We confirmed that the NLRP1 gene is a target of ATF4. Interestingly, ATF4/NLRP1 regulation by the MAPK/ERK pathway uses distinct mechanisms in melanoma cells before and after the acquired resistance to targeted therapy. In parental cells, ATF4/NLRP1 is regulated by the MAPK/ERK pathway through the ribosomal S6 kinase 2 (RSK2). However, vemurafenib (VEM) and trametinib (TRA)-resistant cells lose the signaling via RSK2 and activate the cAMP/protein kinase A (PKA) pathway to redirect ATF4/NLRP1. Therefore, NLRP1 expression and IL-1β secretion were downregulated in response to VEM and TRA in parental cells but enhanced in drug-resistant cells. Lastly, silencing NLRP1 in drug-resistant cells reduced their cell growth and inhibited colony formation. In summary, we demonstrated that NLRP1 functions downstream of the MAPK/ERK signaling via ATF4 and is a player of targeted therapy resistance in melanoma. Targeting NLRP1 may improve the therapeutic efficacy of targeted therapy in melanoma.

Project description:Malignant melanoma (MM) remains a therapeutic challenge on account of extreme primary resistance to apoptosis and fated acquired chemoresistance. In the current context of molecular classification of MM, the understanding of molecular mechanisms giving rise to these resistances should drive therapeutic choice trough personalized medicine. In order to study mechanisms of MM acquire resistance to VAs, we previously established three VA-resistant cell lines, CAL1R-VCR, CAL1R-VDS, and CAL1R-VRB, by long time exposure of the CAL1-wt MM cell line to IC50 (4nM) of VCR, VDS and VRB respectively. CAL1R-VAs cell lines consisted of polyclonal populations to respect biological diversity of tumour. Then, we searched for determine the resistance process impact on MM cells. We thus performed genome-wide analyses based on comparison of global transcriptomic profile of CAL1R-VAs cells to CAL1-wt. In this way, RNA extracted from each cell line was hybridized to Affimetrix HG-U133 Plus 2.00 GeneChips. After hybridization, microarray data were processed with Robust Multi-array Average (RMA) algorithm. We then performed bioinformatic analyses of microarray data and in vitro investigations in the aim to identify genes and pathways that might predict drug resistance. Melanoma model: CAL1 cell line. Treatments: vinorelbine (VRB), vincristine (VCR), vindesine (VDS). Etablishment of 3 resistant cell lines by long time exposure to vinka-alkaloids (4nM, 6-12 months): CAL1R-VRB, CAL1R-VCR, CAL1R-VDS. RNA extracted from a pooled population of each cell line were hybridized to Affimetrix HG-U133 Plus 2.00 GeneChips. Then, microarray data were processed with Robust Multi-array Average (RMA) algorithm.

Project description:Cancer cells gain drug resistance through a complex mechanism, in which nuclear factor-?B (NF-?B) and interleukin-1? (IL-1?) are critical contributors. Because NACHT, LRR and PYD domains-containing protein (NLRP) inflammasomes mediate IL-1? maturation and NF-?B activation, we investigated the role of inflammasome sensor NLRP1 in acquired drug resistance to temozolomide (TMZ) in melanoma. The sensitivity of melanoma cells to TMZ was negatively correlated with the expression levels of O6-methylguanine-DNA methyltransferase (MGMT), the enzyme to repair TMZ-induced DNA lesions. When MGMT-low human melanoma cells (1205Lu and HS294T) were treated with TMZ for over two months, MGMT was upregulated, and cells became resistant. However, the resistance mechanism was independent of MGMT, and the cells that acquired TMZ resistance showed increased NLRP1 expression, NLRP inflammasome activation, IL-1? secretion, and NF-?B activity, which contributed to the acquired resistance to TMZ. Finally, blocking IL-1 receptor (IL-1R) signaling with IL-1R antagonist decreased TMZ-resistant 1205Lu tumor growth in vivo. Although inflammation has been associated with drug resistance in various cancers, our paper is the first to demonstrate the involvement of NLRP in the development of acquired drug resistance. Because drug-tolerant cancer cells become cross-tolerant to other classes of cancer drugs, NLRP1 might be a suitable therapeutic target in drug-resistant melanoma, as well as in other cancers.

Project description:Malignant melanoma (MM) remains a therapeutic challenge on account of extreme primary resistance to apoptosis and fated acquired chemoresistance. In the current context of molecular classification of MM, the understanding of molecular mechanisms giving rise to these resistances should drive therapeutic choice trough personalized medicine. In order to study mechanisms of MM acquire resistance to VAs, we previously established three VA-resistant cell lines, CAL1R-VCR, CAL1R-VDS, and CAL1R-VRB, by long time exposure of the CAL1-wt MM cell line to IC50 (4nM) of VCR, VDS and VRB respectively. CAL1R-VAs cell lines consisted of polyclonal populations to respect biological diversity of tumour. Then, we searched for determine the resistance process impact on MM cells. We thus performed genome-wide analyses based on comparison of global transcriptomic profile of CAL1R-VAs cells to CAL1-wt. In this way, RNA extracted from each cell line was hybridized to Affimetrix HG-U133 Plus 2.00 GeneChips. After hybridization, microarray data were processed with Robust Multi-array Average (RMA) algorithm. We then performed bioinformatic analyses of microarray data and in vitro investigations in the aim to identify genes and pathways that might predict drug resistance. Melanoma model: CAL1 cell line. Treatments: vinorelbine (VRB), vincristine (VCR), vindesine (VDS). Etablishment of 3 resistant cell lines by long time exposure to vinka-alkaloids (4nM, 6-12 months): CAL1R-VRB, CAL1R-VCR, CAL1R-VDS. RNA extracted from a pooled population of each cell line were hybridized to Affimetrix HG-U133 Plus 2.00 GeneChips. Then, microarray data were processed with Robust Multi-array Average (RMA) algorithm.

Project description:BackgroundDevelopment of resistance to inhibitors of BRAF (BRAFi) and MEK (MEKi) remains a great challenge for targeted therapy in patients with BRAF-mutant melanoma. Here, we explored the role of miRNAs in melanoma acquired resistance to BRAFi.MethodsmiRNA expression in two BRAF-mutant melanoma cell lines and their dabrafenib-resistant sublines was determined using Affymetrix GeneChip® miRNA 3.1 microarrays and/or qRT-PCR. The effects of miR-126-3p re-expression on proliferation, apoptosis, cell cycle, ERK1/2 and AKT phosphorylation, dabrafenib sensitivity, invasiveness and VEGF-A secretion were evaluated in the dabrafenib-resistant sublines using MTT assays, flow cytometry, immunoblotting, invasion assays in Boyden chambers and ELISA. ADAM9, PIK3R2, MMP7 and CXCR4 expression in the sensitive and dabrafenib-resistant cells was determined by immunoblotting. Small RNA interference was performed to investigate the consequence of VEGFA or ADAM9 silencing on proliferation, invasiveness or dabrafenib sensitivity of the resistant sublines. Long-term proliferation assays were carried out in dabrafenib-sensitive cells to assess the effects of enforced miR-126-3p expression or ADAM9 silencing on resistance development. VEGF-A serum levels in melanoma patients treated with BRAFi or BRAFi+MEKi were evaluated at baseline (T0), after two months of treatment (T2) and at progression (TP) by ELISA.ResultsmiR-126-3p was significantly down-regulated in the dabrafenib-resistant sublines as compared with their parental counterparts. miR-126-3p replacement in the drug-resistant cells inhibited proliferation, cell cycle progression, phosphorylation of ERK1/2 and/or AKT, invasiveness, VEGF-A and ADAM9 expression, and increased dabrafenib sensitivity. VEGFA or ADAM9 silencing impaired proliferation and invasiveness of the drug-resistant sublines. ADAM9 knock-down in the resistant cells increased dabrafenib sensitivity, whereas miR-126-3p enforced expression or ADAM9 silencing in the drug-sensitive cells delayed the development of resistance. At T0 and T2, statistically significant differences were observed in VEGF-A serum levels between patients who responded to therapy and patients who did not. In responder patients, a significant increase of VEGF-A levels was observed at TP versus T2.ConclusionsStrategies restoring miR-126-3p expression or targeting VEGF-A or ADAM9 could restrain growth and metastasis of dabrafenib-resistant melanomas and increase their drug sensitivity. Circulating VEGF-A is a promising biomarker for predicting patients' response to BRAFi or BRAFi+MEKi and for monitoring the onset of resistance.

Project description:When grown as three-dimensional structures, tumor cells can acquire an additional multicellular resistance to apoptosis that may mimic the chemoresistance found in solid tumors. We developed a multicellular spheroid model of malignant mesothelioma to investigate molecular mechanisms of acquired apoptotic resistance. We found that mesothelioma cell lines, when grown as multicellular spheroids, acquired resistance to a variety of apoptotic stimuli, including combinations of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL), ribotoxic stressors, histone deacetylase, and proteasome inhibitors, that were highly effective against mesothelioma cells when grown as monolayers. Inhibitors of the phosphatidylinositol 3-kinase/Akt/mammalian target of rapamycin (mTOR) pathway, particularly rapamycin, blocked much of the acquired resistance of the spheroids, suggesting a key role for mTOR. Knockdown by small interference RNA of S6K, a major downstream target of mTOR, reproduced the effect of rapamycin, thereby confirming the role of mTOR and of S6K in the acquired resistance of three dimensional spheroids. Rapamycin or S6K knockdown increased TRAIL-induced caspase-8 cleavage in spheroids, suggesting initially that mTOR inhibited apoptosis by actions at the death receptor pathway; however, isolation of the apoptotic pathways by means of Bid knockdown ablated this effect showing that mTOR actually controls a step distal to Bid, probably at the level of the mitochondria. In sum, mTOR and S6K contribute to the apoptotic resistance of mesothelioma cells in three-dimensional, not in two-dimensional, cultures. The three-dimensional model may reflect a more clinically relevant in vitro setting in which mTOR exhibits anti-apoptotic properties.

Project description:Understanding the role of mitogen-activated protein kinase (MAPK) pathway-activating mutations in the development and progression of melanoma and their possible use as therapeutic targets has substantially changed the management of this neoplasm, which, until a few years ago, was burdened by severe mortality. However, the presence of numerous intrinsic and extrinsic mechanisms of resistance to BRAF inhibitors compromises the treatment responses' effectiveness and durability. The strategy of overcoming these resistances by combination therapy has proved successful, with the additional benefit of reducing side effects derived from paradoxical activation of the MAPK pathway. Furthermore, the use of other highly specific inhibitors, intermittent dosing schedules and the association of combination therapy with immune checkpoint inhibitors are promising new therapeutic strategies. However, numerous issues related to dose, tolerability and administration sequence still need to be clarified, as is to be expected from currently ongoing trials. In this review, we describe the clinical results of using BRAF inhibitors in advanced melanoma, with a keen interest in strategies aimed at overcoming resistance.

Project description:Malignant melanoma (MM) remains a therapeutic challenge on account of extreme primary resistance to apoptosis and fated acquired chemoresistance. In the current context of molecular classification of MM, the understanding of molecular mechanisms giving rise to these resistances should drive therapeutic choice trough personalized medicine. In order to study mechanisms of MM acquire resistance to VAs, we previously established three VA-resistant cell lines, CAL1R-VCR, CAL1R-VDS, and CAL1R-VRB, by long time exposure of the CAL1-wt MM cell line to IC50 (4nM) of VCR, VDS and VRB respectively. CAL1R-VAs cell lines consisted of polyclonal populations to respect biological diversity of tumour. Then, we searched for determine the resistance process impact on MM cells. We thus performed genome-wide analyses based on comparison of global transcriptomic profile of CAL1R-VAs cells to CAL1-wt. In this way, RNA extracted from each cell line was hybridized to Affimetrix HG-U133 Plus 2.00 GeneChips. After hybridization, microarray data were processed with Robust Multi-array Average (RMA) algorithm. We then performed bioinformatic analyses of microarray data and in vitro investigations in the aim to identify genes and pathways that might predict drug resistance.

Project description:Background: Alkylating agents are critical therapeutic options for melanoma, while dacarbazine (DTIC)-based chemotherapy showed poor sensitivity in clinical trials. Long non-coding RNAs (lncRNAs) were highlighted in the progression of malignant tumors in recent years, whereas little was known about their involvement in melanoma. Methods: The functional role and molecular mechanism of lncRNA POU3F3 were evaluated on DTIC-resistant melanoma cells. Further studies analyzed its clinical role in the disease progression of melanoma. Results: We observed elevated the expression of lncRNA POU3F3 in the DTIC-resistant melanoma cells. Gain-of-function assays showed that the overexpression of lncRNA POU3F3 maintained cell survival with DTIC treatment, while the knockdown of lncRNA POU3F3 restored cell sensitivity to DTIC. A positive correlation of the expression O6-methylguanine-DNA-methyltransferase (MGMT) was observed with lncRNA POU3F3 in vitro and in vivo. Bioinformatic analyses predicted that miR-650 was involved in the lncRNA POU3F3-regulated MGMT expression. Molecular analysis indicated that lncRNA POU3F3 worked as a competitive endogenous RNA to regulate the levels of miR-650, and the lncRNA POU3F3/miR-650 axis determined the transcription of MGMT in melanoma cells to a greater extent. Further clinical studies supported that lncRNA POU3F3 was a risk factor for the disease progression of melanoma. Conclusion: LncRNA POU3F3 upregulated the expression of MGMT by sponging miR-650, which is a crucial way for DTIC resistance in melanoma. Our results indicated that lncRNA POU3F3 was a valuable biomarker for the disease progression of melanoma.

Project description:Immunotherapies such as adoptive cell therapy (ACT) are promising treatments for solid cancers. However, relapsing disease remains a problem and the molecular mechanisms underlying resistance are poorly defined. We postulated that the deregulated epigenetic landscape in cancer cells could underpin the acquisition of resistance to immunotherapy. To address this question, two preclinical models of ACT were employed to study transcriptional and epigenetic regulatory processes within ACT-treated cancer cells. In these models ACT consistently causes robust tumor regression, but resistance develops and tumors relapse. We identified down-regulated expression of immunogenic antigens at the mRNA level correlated with escape from immune control. To determine whether this down-regulation was under epigenetic control, we treated escaped tumor cells with DNA demethylating agents, azacytidine (AZA) and decitabine (DEC). AZA or DEC treatment restored antigen expression in a proportion of the tumor population. To explore the importance of other epigenetic modifications we isolated tumor cells refractory to DNA demethylation and screened clones against a panel of 19 different epigenetic modifying agents (EMAs). The library of EMAs included inhibitors of a range of chromosomal and transcription regulatory protein complexes, however, when tested as single agents none restored further antigen expression. These findings suggest that tumor cells employ multiple epigenetic and genetic mechanisms to evade immune control, and a combinatorial approach employing several EMAs targeting transcription and genome stability may be required to overcome tumor resistance to immunotherapy.