Recurrent BRAF kinase fusions in melanocytic tumors offer an opportunity for targeted therapy

BRAF is the most prevalent oncogene and an important therapeutic target in melanoma. In some cancers, BRAF is activated by rearrangements that fuse its kinase domain to 5′ partner genes. We examined 848 comparative genomic hybridization profiles of melanocytic tumors and found copy number transitions within BRAF in 10 tumors, of which six could be further characterized by sequencing. In all, the BRAF kinase domain was fused in‐frame to six N‐terminal partners. No other mutations were identified in melanoma oncogenes. One of the seven melanoma cell lines without known oncogenic mutations harbored a similar BRAF fusion, which constitutively activated the MAP kinase pathway. Sorafenib, but not vemurafenib, could block MAP kinase pathway activation and proliferation of the cell line at clinically relevant concentrations, whereas BRAF^V600E mutant melanoma cell lines were significantly more sensitive to vemurafenib. The patient from whom the cell line was derived showed a durable clinical response to sorafenib.     

Modification,Biological Evaluation and SAR Studies of Novel 1H‐Pyrazol Derivatives Containing N,N′‐Disubstituted Urea Moiety as Potential Anti‐melanoma Agents

Malignant melanomas are amongst the most aggressive cancers. BRAF Inhibitors have exhibited therapeutic effects against BRAF‐mutant melanoma. In continuation of our earlier studies on anti‐melanoma agents based on 1H‐pyrazole skeleton, two sets of novel compounds that include 1H‐pyrazole‐4‐amines FA 1 – FA13 and corresponding urea derivatives FN 1 – FN13 have been synthesized and evaluated for their BRAF^V600E inhibitory and antiproliferation activities. Compound FN 10 displayed the most potent biological activity against BRAF^V600E (IC₅₀ = 0.066 μm ) and the A375 human melanoma cell line (GI₅₀ = 0.81 μm ), which was comparable to the positive control vemurafenib, and more potent than our previously reported 1H‐pyrazole‐3‐amines and their urea derivatives. The results of SAR studies and molecular docking can guide further optimization and may help to improve potency of these pyrazole‐based anti‐melanoma agents.     

Identification of PLX4032‐resistance mechanisms and implications for novel RAF inhibitors

BRAF inhibitors improve melanoma patient survival, but resistance invariably develops. Here we report the discovery of a novel BRAF mutation that confers resistance to PLX4032 employing whole‐exome sequencing of drug‐resistant BRAF^V600K melanoma cells. We further describe a new screening approach, a genome‐wide piggyBac mutagenesis screen that revealed clinically relevant aberrations (N‐terminal BRAF truncations and CRAF overexpression). The novel BRAF mutation, a Leu505 to His substitution (BRAF^L505H), is the first resistance‐conferring second‐site mutation identified in BRAF mutant cells. The mutation replaces a small nonpolar amino acid at the BRAF‐PLX4032 interface with a larger polar residue. Moreover, we show that BRAF^L505H, found in human prostate cancer, is itself a MAPK‐activating, PLX4032‐resistant oncogenic mutation. Lastly, we demonstrate that the PLX4032‐resistant melanoma cells are sensitive to novel, next‐generation BRAF inhibitors, especially the ‘paradox‐blocker’ PLX8394, supporting its use in clinical trials for treatment of melanoma patients with BRAF‐mutations.     

PIK3CA‐mutated melanoma cells rely on cooperative signaling through mTORC1/2 for sustained proliferation

Malignant conversion of BRAF‐ or NRAS‐mutated melanocytes into melanoma cells can be promoted by PI3′‐lipid signaling. However, the mechanism by which PI3′‐lipid signaling cooperates with mutationally activated BRAF or NRAS has not been adequately explored. Using human NRAS‐ or BRAF‐mutated melanoma cells that co‐express mutationally activated PIK3CA, we explored the contribution of PI3′‐lipid signaling to cell proliferation. Despite mutational activation of PIK3CA, melanoma cells were more sensitive to the biochemical and antiproliferative effects of broader spectrum PI3K inhibitors than to an α‐selective PI3K inhibitor. Combined pharmacological inhibition of MEK1/2 and PI3K signaling elicited more potent antiproliferative effects and greater inhibition of the cell division cycle compared to single‐agent inhibition of either pathway alone. Analysis of signaling downstream of MEK1/2 or PI3K revealed that these pathways cooperate to regulate cell proliferation through mTORC1‐mediated effects on ribosomal protein S6 and 4E‐BP1 phosphorylation in an AKT‐dependent manner. Although PI3K inhibition resulted in cytostatic effects on xenografted NRAS^Q61H/PIK3CA^H1047R melanoma, combined inhibition of MEK1/2 plus PI3K elicited significant melanoma regression. This study provides insights as to how mutationally activated PIK3CA acts in concert with MEK1/2 signaling to cooperatively regulate mTORC1/2 to sustain PIK3CA‐mutated melanoma proliferation.     

A FAK scaffold inhibitor disrupts FAK and VEGFR-3 signaling and blocks melanoma growth by targeting both tumor and endothelial cells

Melanoma has the highest mortality rate of all skin cancers and a major cause of treatment failure is drug resistance. Tumors heterogeneity requires novel therapeutic strategies and new drugs targeting multiple pathways. One of the new approaches is targeting the scaffolding function of tumor related proteins such as focal adhesion kinase (FAK). FAK is overexpressed in most solid tumors and is involved in multiple protein-protein interactions critical for tumor cell survival, tumor neovascularization, progression and metastasis. In this study, we investigated the anticancer activity of the FAK scaffold inhibitor C4, targeted to the FAK-VEGFR-3 complex, against melanomas. We compared C4 inhibitory effects in BRAF mutant vs BRAF wild type melanomas. C4 effectively caused melanoma tumor regression in vivo, when administered alone and sensitized tumors to chemotherapy. The most dramatic effect of C4 was related to reduction of vasculature of both BRAF wild type and V600E mutant xenograft tumors. The in vivo effects of C4 were assessed in xenograft models using non-invasive multimodality imaging in conjunction with histologic and molecular biology methods. C4 inhibited cell viability, adhesion and motility of melanoma and endothelial cells, specifically blocked phosphorylation of VEGFR-3 and FAK and disrupted their complexes. Specificity of in vivo effects for C4 were confirmed by a decrease in tumor FAK and VEGFR-3 phosphorylation, reduction of vasculogenesis and reduced blood flow. Our collective observations provide evidence that a small molecule inhibitor targeted to the FAK protein-protein interaction site successfully inhibits melanoma growth through dual targeting of tumor and endothelial cells and is effective against both BRAF wild type and mutant melanomas.     

Eradicating tumor drug resistance at its YAP‐biomechanical roots

Treatment with BRAF kinase inhibitors leads to rapid resistance and tumor regression in BRAF V600E mutant melanoma patients. However, the underlying mechanism of the developed tumor resistance is not fully clear. In this issue of The EMBO Journal, Kim and colleagues show that melanoma cells acquire resistance to BRAF inhibitors by changing cell shape, modifying their cytoskeleton and, in turn, activating the YAP/TAZ mechanotransduction pathway (Kim et al, 2016 ).     

Mitogen‐activated protein kinase dependency in BRAF/RAS wild‐type melanoma: A rationale for combination inhibitors

Inhibitors targeting the mitogen‐activated protein kinase (MAPK) pathway and immune checkpoint molecules have dramatically improved the survival of patients with BRAF^V600‐mutant melanoma. For BRAF/RAS wild‐type (WT) melanoma patients, however, immune checkpoint inhibitors remain the only effective therapeutic option with 40% of patients responding to PD‐1 inhibition. In the present study, a large panel of 10 BRAF^V600‐mutant and 13 BRAF/RAS WT melanoma cell lines was analyzed to examine MAPK dependency and explore the potential utility of MAPK inhibitors in this melanoma subtype. We now show that the majority of BRAF/RAS WT melanoma cell lines (8/13) display some degree of sensitivity to trametinib treatment and resistance to trametinib in this melanoma subtype is associated with, but not mediated by NF1 suppression. Although knockdown of NF1 stimulates RAS and CRAF activity, the activation of CRAF by NF1 knockdown is limited by ERK‐dependent feedback in BRAF‐mutant cells, but not in BRAF/RAS WT melanoma cells. Thus, NF1 is not a dominant regulator of MAPK signaling in BRAF/RAS WT melanoma, and co‐targeting multiple MAP kinase nodes provides a therapeutic opportunity for this melanoma subtype.     

Suppression of MAPK signaling in BRAF‐activated PTEN‐deficient melanoma by blocking β‐catenin signaling in cancer‐associated fibroblasts

Cancer‐associated fibroblasts (CAFs) in the tumor microenvironment have been associated with formation of a dynamic and optimized niche for tumor cells to grow and evade cell death induced by therapeutic agents. We recently reported that ablation of β‐catenin expression in stromal fibroblasts and CAFs disrupted their biological activities in in vitro studies and in an in vivo B16F10 mouse melanoma model. Here, we show that the development of a BRAF‐activated PTEN‐deficient mouse melanoma was significantly suppressed in vivo after blocking β‐catenin signaling in CAFs. Further analysis revealed that expression of phospho‐Erk1/2 and phospho‐Akt was greatly reduced, effectively abrogating the activating effects and abnormal cell cycle progression induced by Braf and Pten mutations. In addition, the epithelial–mesenchymal transition (EMT)‐like process was also suppressed in melanoma cells. Taken together, our data highlight an important crosstalk between CAFs and the RAF‐MEK‐ERK signaling cascade in BRAF‐activated melanoma and may offer a new approach to abrogate host‐dependent drug resistance in targeted therapy.     

Met amplification and tumor progression in Cdkn2a‐deficient melanocytes

While many genetic alterations have been identified in melanoma, the relevant molecular events that contribute to disease progression are poorly understood. Most primary human melanomas exhibit loss of expression of the CDKN2A locus in addition to activation of the canonical mitogen‐activated protein kinase signaling pathway. In this study, we used a Cdkn2a‐deficient mouse melanocyte cell line to screen for secondary genetic events in melanoma tumor progression. Upon investigation, intrachromosomal gene amplification of Met, a receptor tyrosine kinase implicated in melanoma progression, was identified in Cdkn2a‐deficient tumors. RNA interference targeting Met in these tumor cells resulted in a significant delay in tumor growth in vivo compared with the control cells. MET expression is rarely detected in primary human melanoma but is frequently observed in metastatic disease. This study validates a role for Met activation in melanoma tumor progression in the context of Cdkn2a deficiency.     

The broad‐spectrum receptor tyrosine kinase inhibitor dovitinib suppresses growth of BRAF‐mutant melanoma cells in combination with other signaling pathway inhibitors

BRAF inhibitors have revolutionized treatment of mutant BRAF metastatic melanomas. However, resistance develops rapidly following BRAF inhibitor treatment. We have found that BRAF‐mutant melanoma cell lines are more sensitive than wild‐type BRAF cells to the small molecule tyrosine kinase inhibitor dovitinib. Sensitivity is associated with inhibition of a series of known dovitinib targets. Dovitinib in combination with several agents inhibits growth more effectively than either agent alone. These combinations inhibit BRAF‐mutant melanoma and colorectal carcinoma cell lines, including cell lines with intrinsic or selected BRAF inhibitor resistance. Hence, combinations of dovitinib with second agents are potentially effective therapies for BRAF‐mutant melanomas, regardless of their sensitivity to BRAF inhibitors.     

Oncosuppressor methylation: a possible key role in colon metastatic progression

K‐RAS and BRAF gene mutations are mandatory to set anti‐EGFR therapy in metastatic colorectal cancer (mCRC) patients. Due to the relationship of these mutations with tumor epigenotype, we hypothesized the potential role of oncosuppressor methylation of genes involved in K‐RAS/BRAF pathway (CDKN2A, RASSF1A, and RARbeta suppressor genes) in inhibiting EGFR signaling cascade. Primary tumor and synchronous liver metastatic tissues of 75 mCRC patients were characterized for promoter methylation by QMSP and for K‐RAS and BRAF mutations. RARbeta, RASSF1A, and CDKN2A genes were methylated in 82%, 35%, and 26% of primary tumors, respectively. RASSF1A resulted significantly more frequently methylated in liver metastasis than in primary site (P = 0.015), while RARbeta was significantly lower methylated in distant metastasis (P = 1.2 × 10^?6). As regards methylation content, RASSF1A methylation status was significantly higher in liver metastasis with respect to primary tumor (P = 0.000) underlying the role of this gene in liver metastatic progression. In our series K‐RAS and BRAF were mutated in 39% and 4% of cases, respectively. Methylation frequencies seemed to be unrelated to gene mutations; on the other hand, RASSF1A mean content methylation resulted significantly higher in liver than in primary tumor (288.78 vs. 56.23, respectively, P = 0.05) only in K‐RAS wild‐type cases sustaining a specific role of this gene in metastatic site thus supporting its function in strengthening the apoptotic role of K‐RAS. These evidences held the role of oncosuppressor methylation in both colon tumorigenesis and progression and suggested that epigenetic events should be taken into account when biological therapies in mCRC patients have to be set. J. Cell. Physiol. 226: 1934–1939, 2011. © 2010 Wiley‐Liss, Inc.     

PTEN regulates IGF‐1R‐mediated therapy resistance in melanoma

Inhibition of the mitogen‐activated protein kinase (MAPK) pathway is a major advance in the treatment of metastatic melanoma. However, its therapeutic success is limited by the rapid emergence of drug resistance. The insulin‐like growth factor‐1 receptor (IGF‐1R) is overexpressed in melanomas developing resistance toward the BRAF^V600 inhibitor vemurafenib. Here, we show that hyperactivation of BRAF enhances IGF‐1R expression. In addition, the phosphatase activity of PTEN as well as heterocellular contact to stromal cells increases IGF‐1R expression in melanoma cells and enhances resistance to vemurafenib. Interestingly, PTEN‐negative melanoma cells escape IGF‐1R blockade by decreased expression of the receptor, implicating that only in melanoma patients with PTEN‐positive tumors treatment with IGF‐1R inhibitors would be a suitable strategy to combat therapy resistance. Our data emphasize the crosstalk and therapeutic relevance of microenvironmental and tumor cell‐autonomous mechanisms in regulating IGF‐1R expression and by this sensitivity toward targeted therapies.     

MicroRNA‐125a promotes resistance to BRAF inhibitors through suppression of the intrinsic apoptotic pathway

Melanoma patients with BRAF^V600E‐mutant tumors display striking responses to BRAF inhibitors (BRAFi); however, almost all invariably relapse with drug‐resistant disease. Here, we report that microRNA‐125a (miR‐125a) expression is upregulated in human melanoma cells and patient tissues upon acquisition of BRAFi resistance. We show that miR‐125a induction confers resistance to BRAF^V600E melanoma cells to BRAFi by directly suppressing pro‐apoptotic components of the intrinsic apoptosis pathway, including BAK1 and MLK3. Apoptotic suppression and prolonged survival favor reactivation of the MAPK and AKT pathways by drug‐resistant melanoma cells. We demonstrate that miR‐125a inhibition suppresses the emergence of resistance to BRAFi and, in a subset of resistant melanoma cell lines, leads to partial drug resensitization. Finally, we show that miR‐125a upregulation is mediated by TGFβ signaling. In conclusion, the identification of this novel role for miR‐125a in BRAFi resistance exposes clinically relevant mechanisms of melanoma cell survival that can be exploited therapeutically.     

Induction of strong antitumor immunity by an HSV-2-based oncolytic virus in a murine mammary tumor model

Oncolytic viruses have shown considerable promise for the treatment of solid tumors. In previous studies, we demonstrated that a novel oncolytic virus (FusOn‐H2), constructed by replacing the serine/threonine protein kinase (PK) domain of the ICP10 gene of type 2 herpes simplex virus (HSV‐2) with the gene encoding the green fluorescent protein, can selectively replicate in and thus lyse tumor cells. 4T1 tumor cells are weakly immunogenic and the mammary tumors derived from them aggressively metastasize to different parts of body, thus providing an attractive model for evaluating anticancer agents. We thus tested the antitumor effect of FusOn‐H2 in this tumor model, in comparisons with several other oncolytic HSVs derived from HSV‐1, including a nonfusogenic HSV‐1 (Baco‐1) and a doubly fusogenic virus (Synco‐2D). Our results show that FusOn‐H2 and Synco‐2D have greater oncolytic activity in vitro than Baco‐1. Moreover, FusOn‐H2 induced strong T cell responses against primary and metastatic mammary tumors in vivo, and splenocytes adoptively transferred from FusOn‐H2‐treated mice effectively prevented metastasis in naïve mice bearing implanted mammary tumors. We conclude that the HSV‐2‐based FusOn‐H2 oncolytic virus may be an effective agent for the treatment of both primary and metastatic breast cancer. Copyright © 2007 John Wiley & Sons, Ltd.     

Identification of unique sensitizing targets for anti‐inflammatory CDDO‐Me in metastatic melanoma by a large‐scale synthetic lethal RNAi screening

CDDO‐Me has been shown to exert potent anti‐inflammatory activity for chronic kidney disease and antitumor activity for several tumors, including melanoma, in early clinical trials. To improve CDDO‐Me response in melanoma, we utilized a large‐scale synthetic lethal RNAi screen targeting 6000 human druggable genes to identify targets that would sensitize melanoma cells to CDDO‐Me. Based on screening results, five unique genes (GNPAT, SUMO1, SPINT2, FLI1, and SSX1) significantly potentiated the growth inhibitory effects of CDDO‐Me and induced apoptosis in A375, a BRAF mutated melanoma line (P < 0.001). These five genes were then individually validated as targets to potentiate CDDO‐Me activity, and related downstream signaling pathways of these genes were analyzed. In addition, the levels of phosphorylated Erk1/2, Akt, GSK‐2, and PRAS40 were dramatically decreased by downregulating each of these five genes separately, suggesting a set of common mediators. Our findings indicate that GNPAT, SUMO1, SPINT2, FLI1, and SSX1 play critical roles in synergy with inflammation pathways in modulating melanoma cell survival and could serve as sensitizing targets to enhance CDDO‐Me efficacy in melanoma growth control.     

ROCK1 is a potential combinatorial drug target for BRAF mutant melanoma

Treatment of BRAF mutant melanomas with specific BRAF inhibitors leads to tumor remission. However, most patients eventually relapse due to drug resistance. Therefore, we designed an integrated strategy using (phospho)proteomic and functional genomic platforms to identify drug targets whose inhibition sensitizes melanoma cells to BRAF inhibition. We found many proteins to be induced upon PLX4720 (BRAF inhibitor) treatment that are known to be involved in BRAF inhibitor resistance, including FOXD3 and ErbB3. Several proteins were down‐regulated, including Rnd3, a negative regulator of ROCK1 kinase. For our genomic approach, we performed two parallel shRNA screens using a kinome library to identify genes whose inhibition sensitizes to BRAF or ERK inhibitor treatment. By integrating our functional genomic and (phospho)proteomic data, we identified ROCK1 as a potential drug target for BRAF mutant melanoma. ROCK1 silencing increased melanoma cell elimination when combined with BRAF or ERK inhibitor treatment. Translating this to a preclinical setting, a ROCK inhibitor showed augmented melanoma cell death upon BRAF or ERK inhibition in vitro. These data merit exploration of ROCK1 as a target in combination with current BRAF mutant melanoma therapies.     

Genetic evolution of nevus of Ota reveals clonal heterogeneity acquiring BAP1 and TP53 mutations

Melanoma presents molecular alterations based on its anatomical location and exposure to environmental factors. Due to its intrinsic genetic heterogeneity, a simple snapshot of a tumor's genetic alterations does not reflect the tumor clonal complexity or specific gene–gene cooperation. Here, we studied the genetic alterations and clonal evolution of a unique patient with a Nevus of Ota that developed into a recurring uveal‐like dermal melanoma. The Nevus of Ota and ulterior lesions contained GNAQ mutations were c‐KIT positive, and tumors showed an increased RAS pathway activity during progression. Whole‐exome sequencing of these lesions revealed the acquisition of BAP1 and TP53 mutations during tumor evolution, thereby unmasking clonal heterogeneity and allowing the identification of cooperating genes within the same tumor. Our results highlight the importance of studying tumor genetic evolution to identify cooperating mechanisms and delineate effective therapies.