Oncogenic BRAF Research Articles

The Prevalence and Prognostic Implications of BRAF K601E Mutations in Thyroid Neoplasms: A Systematic Review and Meta-Analysis.

Activating mutations in the BRAF oncogene occur in 45% of papillary thyroid carcinomas (PTCs). Though less studied, K601E may identify a clinically distinct subset of thyroid neoplasms. A bioinformatics assessment was conducted using the COSMIC database and in silico data analysis. A systematic search was conducted through August 2024 to identify studies reporting BRAF mutation in thyroid neoplasms. Pooled prevalence, histopathological subtype distribution, extrathyroidal extension, lymph node metastasis, recurrence, and survival were extracted/analyzed from 32 studies (13 191 patients). In the COSMIC database, BRAF K601E was found in various tissue types but mainly in the thyroid. In silico data analysis revealed a structural and functional basis for differences between K601E and V600E. Upon systematic review, the BRAF K601E mutation was identified in 2.8% of PTCs compared to 22% with V600E. The stratified analysis revealed geographical differences, with higher rates in Italy (5.23%) and the United States of America (3.31%). The K601E mutant was enriched for follicular-patterned variants like NIFTP (11.2% of cases). Meta-analysis demonstrated significantly reduced extrathyroidal extension for K601E versus V600E mutants (RR = 0.22, 95% CI = 0.10-0.50, p = 0.0003). K601E-mutated neoplasms could be a unique clinicopathological entity associated with low-risk histology and reduced extrathyroidal extension, consistent with a more indolent course than V600E mutants. Although detecting K601E may potentially guide conservative management, further prospective studies are needed.

Malignant Melanoma of Foot with Brain Metastasis – Case report

Melanoma is a rare type of skin cancer which has a strong correlation between occurrence and exposure to sun ultraviolet radiation. Though being uncommon, it has the highest mortality rate of all skin cancers. The patients with advanced disease may have higher mortality rates. The formation and development of melanoma metastases to brain are not fully understood. The most accepted way is the presence of oncogenic BRAF mutation, which occurs in up to 50% of metastatic melanoma patients. There was a lower survival rate in metastatic melanoma before detailed pathophysiology was understood. There are new research going on immunotherapy and targeted therapy to improve the prognosis of melanoma patients. Hereby, we would like to present a case of melanoma of foot with distant metastasis to brain.

Potential of mesoporous silica nanoparticles for the delivery of anticancer bioactive compounds

The potential for dosing anticancer target molecules of silica nanoparticles with ordered mesoporosity (SiMONPs), 28 nm in diameter and surface area of 706 m2/g, was evaluated by the loading and release of carvacrol, chloroquine, and rhodamine-B. The ligand–protein interaction (BRAF oncogene) was determined by docking. The fine structure of the SiMONPs with nanometric porosity allowed a slow and progressive release according to the passive diffusion mechanism. The most favorable anticancer interaction was displayed by carvacrol with a ligand efficiency value of −6.7 kcal/mol. At the same time, chloroquine and rhodamine-B had values of −5.0 kcal/mol and −3.4 kcal/mol, severally. The target displayed a “preference” to interact first with the SiMONPs rather than with carvacrol. The material could be dosed at 0.0009 mg/h for a week under PBS medium conditions, so the material resulted suitable for dosing and controlling the growth of skin cancer cells.

Ruthenium drug BOLD-100 regulates BRAFMT colorectal cancer cell apoptosis through AhR/ROS/ATR signaling axis modulation.

Patients with class I V600EBRAF-mutant (MT) colorectal cancer (CRC) have a poor prognosis and their response to combined anti-BRAF/EGFR inhibition remains limited. There is clearly an unmet need in further understanding the biology of V600EBRAFMT CRC. We have used differential gene expression of BRAFWT and MT CRC cells to identify pathways underpinning BRAFMT CRC. We tested a panel of molecularly/genetically subtyped CRC cells for their sensitivity to the Unfolded Protein Response (UPR) activator BOLD-100. To identify novel combination strategies for BOLD-100, we performed RNA sequencing and high-throughput drug screening. Pathway enrichment analysis identified that the UPR and DNA repair pathways were significantly enriched in BRAFMT CRC. We found that oncogenic BRAF plays a crucial role in mediating response to BOLD-100. Using a systems biology approach, we identified V600EBRAFMT-dependent activation of the replication stress response kinase ATR as a key mediator of resistance to BOLD-100. Further analysis identified acute increases in BRAFMT-dependent-reactive oxygen species (ROS) levels following treatment with BOLD-100 that was demonstrated to promote ATR/CHK1 activation and apoptosis. Furthermore, activation of ROS/ATR/CHK1 following BOLD-100 was found to be mediated through the AHR transcription factor and CYP1A1. Importantly, pharmacological blockade of this resistance pathway with ATR inhibitors synergistically increased BOLD-100-induced apoptosis and growth inhibition in BRAFMT models. These results unveil possible novel therapeutic opportunity for BRAFMT CRC. Implications: BOLD-100 induces BRAFMT-dependent replication stress, and targeted strategies against replication stress (eg. by using ATR inhibitors) in combination with BOLD-100 may serve as a potential novel therapeutic strategy for clinically aggressive BRAFMT CRC.

Whole-exome sequencing reveals novel cancer genes and actionable targets in biliary tract cancers in primary sclerosing cholangitis.

People with primary sclerosing cholangitis (PSC) have a 20% lifetime risk of biliary tract cancer (BTC). Using whole-exome sequencing, we characterized genomic alterations in tissue samples from BTC with underlying PSC. We extracted DNA from formalin-fixed, paraffin-embedded tumor and paired nontumor tissue from 52 resection or biopsy specimens from patients with PSC and BTC and performed whole-exome sequencing. Following copy number analysis, variant calling, and filtering, putative PSC-BTC-associated genes were assessed by pathway analyses and annotated to targeted cancer therapies. We identified 53 candidate cancer genes with a total of 123 nonsynonymous alterations passing filtering thresholds in 2 or more samples. Of the identified genes, 19% had not previously been implicated in BTC, including CNGA3, KRT28, and EFCAB5. Another subset comprised genes previously implicated in hepato-pancreato-biliary cancer, such as ARID2, ELF3, and PTPRD. Finally, we identified a subset of genes implicated in a wide range of cancers such as the tumor suppressor genes TP53, CDKN2A, SMAD4, and RNF43 and the oncogenes KRAS, ERBB2, and BRAF. Focal copy number variations were found in 51.9% of the samples. Alterations in potential actionable genes, including ERBB2, MDM2, and FGFR3 were identified and alterations in the RTK/RAS (p = 0.036), TP53 (p = 0.04), and PI3K (p = 0.043) pathways were significantly associated with reduced overall survival. In this exome-wide characterization of PSC-associated BTC, we delineated both PSC-specific and universal cancer genes. Our findings provide opportunities for a better understanding of the development of BTC in PSC and could be used as a platform to develop personalized treatment approaches.

Overview of the Role of Liquid Biopsy in Non-small Cell Lung Cancer (NSCLC)

Solid tumour tissue has traditionally been used for cancer molecular diagnostics. Recently, biomarker assessment in blood or liquid biopsies has become relevant because it allows genotyping in a less invasive and costly manner. In addition, it is a very useful technique in cases with insufficient tumour samples.Recent data have shown that this method can provide the baseline molecular characteristics of the tumour and resistance changes that emerge during cancer treatment. In terms of diagnostic application, the platforms available for clinical use in lung cancer focus on the isolation and detection of circulating DNA (ctDNA) and generally cover a limited number of mutations in genes such as epidermal growth factor receptor (EGFR), Kirsten rat sarcoma viral oncogene homolog (KRAS) and BRAF, as well as anaplastic lymphoma kinase (ALK) rearrangements. In parallel, there are plasma genotyping platforms based on next-generation sequencing (NGS) techniques, which are much broader in scope, allowing multiple genes to be studied simultaneously in a more efficient manner.More recently, promising research scenarios for liquid biopsy have emerged, such as its utility for early diagnosis and evaluation of minimal residual disease after oncological treatment.In light of these advances, knowledge of the benefits and limitations of liquid biopsy, as well as awareness of emerging information on new indications for this technique in non-small cell lung cancer (NSCLC), are of paramount importance in developing more effective management strategies for patients with this neoplasm.

LGG-20. SELUMETINIB IN PEDIATRIC PATIENTS WITH RELAPSED/REFRACTORY OPTIC PATHWAY/HYPOTALAMIC LOW GRADE GLIOMA: A MONOINSTITUTIONAL EXPERIENCE

Abstract BACKGROUND Pediatric low-grade gliomas (pLGG) are the most common central nervous system tumors in children. The optic pathway and hypothalamic (OPH) frequent localizations are correlated with multiply relapses due to inoperability, thus emphasizing the need for alternative treatments. The results of activation of the BRAF oncogene through a tandem duplication resulting in a KIAA1549–BRAF fusion is the most common genetic aberration. Selumetinib is an oral mitogen-activated protein kinase (MEK) 1/2 inhibitor with promising efficacy and good tolerability on relapsed/refractory pLGG. METHODS From January 2021 to January 2024 three patients with refractory OPH-pLGG with KIIA1549-BRAF fusion were treated with Selumetinib 25 mg/sqm/day (compassionate use) all after two lines of chemotherapy. They were males, mean age at diagnosis 8 months, at starting Selumetinib 74 months. All had partial surgery at diagnosis and two of them other debulking surgeries during the treatment. All patients had numerous events of hydrocefalous with need of shunt revision. RESULTS Two patients experienced grade-3 stomatitis, one grade 3 nausea-vomiting, one grade 3 gastritis, one grade 1 increased level of CPK (CTCAE-V5.0). For grade 3 toxicity Selumetinib had to be stopped for a maximum of 7 days with clinical benefit. Two of them have completed treatment with Selumetinib, one is ongoing after 20 months, all with radiological stable disease at MRI. Median time of treatment is 26 months (range 20-30 months). All three experienced a trend in reduction of emergency room admission for ventricular-shunt problems. Median PFS at starting Selumetinib was 62 months, median OS is 97 months. CONCLUSIONS Selumetinib has a good profile of toxicity, allowing a good quality of life procrastinating radiotherapy and reducing surgery events in a context of heavily pretreated relapsed/refractory patients. Further data are needed on both visual and auxological parameters and late side effects.

The rapidly changing field of predictive biomarkers of non-small cell lung cancer.

Lung cancer is a leading cause of cancer-related death worldwide in both men and women, however mortality in the US and EU are recently declining in parallel with the gradual cut of smoking prevalence. Consequently, the relative frequency of adenocarcinoma increased while that of squamous and small cell carcinomas declined. During the last twodecades a plethora of targeted drug therapies have appeared for the treatment of metastasizing non-small cell lung carcinomas (NSCLC). Personalized oncology aims to precisely match patients to treatments with the highest potential of success. Extensive research is done to introduce biomarkers which can predict the effectiveness of a specific targeted therapeutic approach. The EGFR signaling pathway includes several sufficient targets for the treatment of human cancers including NSCLC. Lung adenocarcinoma may harbor both activating and resistance mutations of the EGFR gene, and further, mutations of KRAS and BRAF oncogenes. Less frequent but targetable genetic alterations include ALK, ROS1, RET gene rearrangements, and various alterations of MET proto-oncogene. In addition, the importance of anti-tumor immunity and of tumor microenvironment has become evident recently. Accumulation of mutations generally trigger tumor specific immune defense, but immune protection may be upregulated as an aggressive feature. The blockade of immune checkpoints results in potential reactivation of tumor cell killing and induces significant tumor regression in various tumor types, such as lung carcinoma. Therapeutic responses to anti PD1-PD-L1 treatment may correlate with the expression of PD-L1 by tumor cells. Due to the wide range of diagnostic and predictive features in lung cancer a plenty of tests are required from a single small biopsy or cytology specimen, which is challenged by major issues of sample quantity and quality. Thus, the efficacy of biomarker testing should be warranted by standardized policy and optimal material usage. In this review we aim to discuss major targeted therapy-related biomarkers in NSCLC and testing possibilities comprehensively.

RNA expression-based risk stratification of stage III cutaneous melanoma.

e21551 Background: Prognostication of locally advanced cutaneous melanoma (CM) relies on accurate assessment of primary tumor invasion depth and extent of lymph node involvement. However, precision is often limited by detection limits of positron emission computed tomography and sentinel lymph node biopsy, and the estimated disease-specific survival (DSS) can vary widely. In this study, we explored tumor gene expression-based risk stratification strategies and found that CDH1 (E-cadherin) and BRAF transcript level profiles can predict DSS in stage III CM. Methods: The Cancer Genome Atlas Skin Cutaneous Melanoma (TCGA-SKCM) project’s normalized RNA-Seq transcriptome profile (n = 288) was analyzed with MATLAB software. TCGA-SKCM adopted AJCC 7th edition staging. "High” or “low” level of each gene was determined by the median FPKM of the cohort used as cutoff. P-values were obtained from Cox proportional hazards regression model. Results: In stage III (n = 96), 3-year DSS for high- and low-CDH1 groups were 45% and 75%, respectively (p = 1.5x10-5). High-BRAF group was weakly associated with superior 3-year DSS compared to low-BRAF group (75% vs. 55%; p = 0.06), although high-BRAF group was composed of more BRAF hotspot mutants compared to low-BRAF group (56% vs. 30%). The 3-year DSS for high-CDH1/low-BRAF and low-CDH1/high-BRAF groups were 28% and 84%, respectively (p = 4.4x10-5). Composition of stages [IIIA, IIIB, IIIC, IIINOS] in high-CDH1/low-BRAF and low-CDH1/high-BRAF groups were [5%, 18%, 45%, 32%] and [23%, 13%, 37%, 27%], respectively. For high-CDH1/high-BRAF group, 3-year DSS was 54% with stage composition [6%, 33%, 39%, 22%]. DSS was not associated with CDH1/BRAF levels in stage I and II. Stage IV was not analyzed due to the small sample size. Conclusions: We demonstrate CDH1/BRAF transcript level-based prognostication of CM cases with regional metastasis (metastatic node, in-transit or satellite metastasis) defined as stage III. Our findings are contrary to the notion that CDH1 is a tumor/invasion suppressor gene, although we note the emerging evidence that CDH1 expression boosts establishment of cancer at a secondary site once they escape from the primary site1). The association between high BRAF level and superior survival may also seem counterintuitive given the well-accepted oncogenicity of activating BRAF mutations in variety of malignancies. However, we speculate that wild-type and oncogenic BRAF, which RNA-Seq cannot easily differentiate, may play independent roles in tumorigenesis similar to what has been previously reported in wild-type and oncogenic RAS2).

Structure-Based De Novo Design for the Discovery of Miniprotein Inhibitors Targeting Oncogenic Mutant BRAF.

Being a component of the Ras/Raf/MEK/ERK signaling pathway crucial for cellular responses, the VRAF murine sarcoma viral oncogene homologue B1 (BRAF) kinase has emerged as a promising target for anticancer drug discovery due to oncogenic mutations that lead to pathway hyperactivation. Despite the discovery of several small-molecule BRAF kinase inhibitors targeting oncogenic mutants, their clinical utility has been limited by challenges such as off-target effects and suboptimal pharmacological properties. This study focuses on identifying miniprotein inhibitors for the oncogenic V600E mutant BRAF, leveraging their potential as versatile drug candidates. Using a structure-based de novo design approach based on binding affinity to V600E mutant BRAF and hydration energy, 39 candidate miniprotein inhibitors comprising three helices and 69 amino acids were generated from the substructure of the endogenous ligand protein (14-3-3). Through in vitro binding and kinase inhibition assays, two miniproteins (63 and 76) were discovered as novel inhibitors of V600E mutant BRAF with low-micromolar activity, with miniprotein 76 demonstrating a specific impediment to MEK1 phosphorylation in mammalian cells. These findings highlight miniprotein 76 as a potential lead compound for developing new cancer therapeutics, and the structural features contributing to its biochemical potency against V600E mutant BRAF are discussed in detail.

Tumor- and Fibroblast-Derived Cell-Free DNAs Differently Affect the Progression of B16 Melanoma In Vitro and In Vivo.

It is widely postulated that the majority of pathologically elevated extracellular or cell-free DNA (cfDNA) in cancer originates from tumor cells; however, evidence has emerged regarding the significant contributions of other cells from the tumor microenvironment. Here, the effect of cfDNA originating from murine B16 melanoma cells and L929 fibroblasts on B16 cells was investigated. It was found that cfDNAL929 increased the viability and migration properties of B16 cells in vitro and their invasiveness in vivo. In contrast, cfDNAB16 exhibited a negative effect on B16 cells, reducing their viability and migration in vitro, which in vivo led to decreased tumor size and metastasis number. It was shown that cell treatment with both cfDNAs resulted in an increase in the expression of genes encoding DNases and the oncogenes Braf, Kras, and Myc. cfDNAL929-treated cells were shown to experience oxidative stress. Gene expression changes in the case of cfDNAB16 treatment are well correlated with the observed decrease in proliferation and migration of B16 cells. The obtained data may indicate the possible involvement of fibroblast DNA in the tumor microenvironment in tumor progression and, potentially, in the formation of new tumor foci due to the transformation of normal cells.

Regulation of RAF family kinases: new insights from recent structural and biochemical studies.

The RAF kinases are required for signal transduction through the RAS-RAF-MEK-ERK pathway, and their activity is frequently up-regulated in human cancer and the RASopathy developmental syndromes. Due to their complex activation process, developing drugs that effectively target RAF function has been a challenging endeavor, highlighting the need for a more detailed understanding of RAF regulation. This review will focus on recent structural and biochemical studies that have provided 'snapshots' into the RAF regulatory cycle, revealing structures of the autoinhibited BRAF monomer, active BRAF and CRAF homodimers, as well as HSP90/CDC37 chaperone complexes containing CRAF or BRAFV600E. In addition, we will describe the insights obtained regarding how BRAF transitions between its regulatory states and examine the roles that various BRAF domains and 14-3-3 dimers play in both maintaining BRAF as an autoinhibited monomer and in facilitating its transition to an active dimer. We will also address the function of the HSP90/CDC37 chaperone complex in stabilizing the protein levels of CRAF and certain oncogenic BRAF mutants, and in serving as a platform for RAF dephosphorylation mediated by the PP5 protein phosphatase. Finally, we will discuss the regulatory differences observed between BRAF and CRAF and how these differences impact the function of BRAF and CRAF as drivers of human disease.

TGFβ-Responsive Stromal Activation Occurs Early in Serrated Colorectal Carcinogenesis.

Activated TGFβ signaling in the tumor microenvironment, which occurs independently of epithelial cancer cells, has emerged as a key driver of tumor progression in late-stage colorectal cancer (CRC). This study aimed to elucidate the contribution of TGFβ-activated stroma to serrated carcinogenesis, representing approximately 25% of CRCs and often characterized by oncogenic BRAF mutations. We used a transcriptional signature developed based on TGFβ-responsive, stroma-specific genes to infer TGFβ-dependent stromal activation and conducted in silico analyses in 3 single-cell RNA-seq datasets from a total of 39 CRC samples and 12 bulk transcriptomic datasets consisting of 2014 CRC and 416 precursor samples, of which 33 were serrated lesions. Single-cell analyses validated that the signature was expressed specifically by stromal cells, effectively excluding transcriptional signals derived from epithelial cells. We found that the signature was upregulated during malignant transformation and cancer progression, and it was particularly enriched in CRCs with mutant BRAF compared to wild-type counterparts. Furthermore, across four independent precursor datasets, serrated lesions exhibited significantly higher levels of TGFβ-responsive stromal activation compared to conventional adenomas. This large-scale analysis suggests that TGFβ-dependent stromal activation occurs early in serrated carcinogenesis. Our study provides novel insights into the molecular mechanisms underlying CRC development via the serrated pathway.

Resolving Discrepancies in Idylla BRAF Mutational Assay Results Using Targeted Next-Generation Sequencing.

BRAF mutation identification is important for the diagnosis and treatment of several tumor types, both solid and hematologic. Rapid identification of BRAF mutations is required to determine eligibility for targeted BRAF inhibitor therapy. The Idylla BRAF mutation assay is a rapid, multiplex allele-specific PCR test designed to detect the most common oncogenic BRAF V600 mutations in formalin-fixed paraffin-embedded (FFPE) tissue samples. Here, we describe the validation of the Idylla BRAF mutation assay in our laboratory. During routine clinical practice, we noticed cases in which BRAF V600 mutations were identified with unusual amplification curves, with three cases displaying a delayed amplification within a double amplification pattern and two false-positive calls. We therefore initiated a quality improvement effort to systematically and retrospectively evaluate next-generation sequencing (NGS)-tested cases with BRAF mutations identified within five amino acids of BRAF codon V600 and did not identify additional false-positive cases. We hypothesize that late amplification in a double amplification pattern may represent non-specific amplification, whereas cases displaying single delayed amplification curves may stem from the presence of either non-V600 variants, very low-level V600 variants, cytosine deamination artifacts, and/or non-specific amplification by an allele-specific PCR primer. Regardless, we recommend that Idylla BRAF cases with non-classical amplification curves undergo reflex NGS testing. These findings are likely relevant for other Idylla assays interrogating hotspot mutations in genes such as EGFR, IDH1/2, KRAS, and NRAS.

Abstract 5052: Novel drug resistance mechanisms and drug targets in BRAF mutated peritoneal metastasis from colorectal cancer

Abstract Objective: Patients with peritoneal metastasis (PM) from colorectal cancer (CRC) have inferior prognosis and respond poorly to chemotherapy compared to other metastatic locations. This study aims to identify the molecular explanation for the observed clinical behavior and suggest novel treatment strategies in PM-CRC. Design: Tumor samples from a Norwegian national cohort of 230 patients undergoing surgery and hyperthermic intraperitoneal chemotherapy (HIPEC) with mitomycin C (MMC) for PM-CRC were subjected to targeted DNA sequencing, and associations between molecular findings and clinical data were analyzed. mRNA sequencing was conducted on a subset of thirty samples to compare gene expression in tumors harboring mutations in the BRAF or KRAS oncogenes and wild-type tumors. Results: Almost one-third of the patients had mutations in the BRAF oncogene, which were associated with RNF43/R-Spondin aberrations and low expression of negative Wnt regulators (ligand dependent Wnt activation). This molecular profile, with high abundance in PM, could be an underlying mechanism promoting aggressive tumor biology that facilitates metastasis to the peritoneal cavity, and could contribute to the observed poor overall survival of this patient subgroup. BRAF mutations were also associated with gene expression changes in transport solute carrier proteins and drug metabolism enzymes that could influence the efficacy of MMC and irinotecan, commonly used in PM-CRC treatment. BRAF-mutated tumors exhibited increased expression of BTN immune checkpoint molecules, and targeting these checkpoints in addition to ligand dependent Wnt activation could be two novel targeted therapy approaches. Conclusion: BRAF mutations were associated with particularly poor survival in this cohort, possibly related to altered drug transport and metabolism conferring resistance to MMC and irinotecan. Two potential novel therapeutic approaches were identified, suggesting specific targeting of BTN immune checkpoint molecules and the use of inhibitors to target ligand-dependent Wnt activation. Citation Format: Christin Lund-Andersen, Annette Torgunrud, Chakravarthi Kanduri, Vegar J. Dagenborg, Ida S. Frøysnes, Mette M. Larsen, Ben Davidson, Stein Larsen, Kjersti Flatmark. Novel drug resistance mechanisms and drug targets in BRAF mutated peritoneal metastasis from colorectal cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5052.

Abstract 325: Validation of Aventa FusionPlus: An LDT NGS assay for comprehensive cancer genomic profiling

Abstract Next-generation sequencing (NGS) assays play a pivotal role in illuminating the genomic landscape of cancer by providing insights into gene regulation and biomarker detection for the purpose of guiding therapeutic decisions to advance personalized medicine. We validated the Aventa FusionPlus Test, a Laboratory-Developed Test (LDT) that integrates HiC technology to enhance detection of actionable gene fusions and rearrangements in solid tumors, including those that are missed by current standard of care tests. This is a DNA-based test that is robust to DNA degradation in FFPE specimens, in contrast with RNA-seq and long-read technologies. The test utilizes the Element Biosciences AVITI sequencing platform to achieve high quality sequencing data at low cost per sample. The Aventa FusionPlus test enables gene-level detection of structural variants near or within 361 medically actionable or diagnostically relevant cancer genes. The 3D structure and long-range linkages captured by the test amplify the signal counts for each rearrangement. The test integrates the Arima-HiC+ FFPE sample prep and the Arima Library Prep Kit workflow. After dewaxing and rehydrating the FFPE tissue, the chromatinized DNA is fragmented and the fragmented ends are filled in with a biotinylated nucleotide. Next, spatially proximal fragmented ends of DNA are ligated, capturing the 3D structure of the genome. The proximally-ligated DNA is then purified and further fragmented, and the biotinylated ligation fragments are enriched. DNA libraries are prepared from these enriched fragments and sequenced in “paired-end” mode. Genes involved in genomic rearrangements were detected using the Arima-SV pipeline along with manual curation. The test achieved robust detection of structural variants, with accuracy of 98.8% relative to reference methods. FFPE tumor specimens from 10 different tissue types and a wide range of tumor content (20%-100%) were included. No correlation between tumor cellularity and sensitivity was observed, suggesting that samples with as low as 20% tumor cellularity can be tested. When comparing to RNA-based and other targeted reference methods, we found additional fusions nearby oncogenes missed by these reference methods. As an example, in a breast cancer case, a fusion of genomic regions neighboring BRAF and MYC oncogenes on chromosomes 7 and 8 respectively, was missed by the reference method but was successfully detected by the Aventa FusionPlus test. The Aventa FusionPlus test is a highly sensitive, specific, and accurate method for comprehensive cancer genomic profiling. The enhanced understanding of gene fusions and rearrangements positions the test as a valuable tool for clinical decision-making in oncology. Citation Format: Shadi Melnyk, Jon Belton, Sofia Nomikou, Katelyn Powell, Daniel Heiney, Roy Khalife, Damien Jones, Anthony Schmitt, Catherine Wilson, Melissa Won, Anthony Magliocco, Chris Roberts. Validation of Aventa FusionPlus: An LDT NGS assay for comprehensive cancer genomic profiling [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 325.

Abstract 5847: Characterizing mechanisms of BRAF/MEK inhibitor resistance in BRAF V600 mutant colorectal cancer vs. melanoma

Abstract Background: BRAF V600 mutations comprise ~80% of all oncogenic BRAF mutations in metastatic colorectal cancer (mCRC). While most cancers with BRAF V600 mutations can be effectively treated with combined BRAF and MEK inhibition, BRAF V600 mutant mCRC acquire resistance through EGFR-mediated signaling. The profound difference in response rates to BRAF/MEK inhibitors in BRAF V600 mutant mCRC (12%) vs. melanoma (63-68%) is not sufficiently explained by increased EGFR signaling in CRC. Therefore, we sought to characterize the differences that exist between BRAF V600 mutant CRC and melanomas that could explain the differential sensitivity to BRAF/MEK inhibition and identify more effective treatments for BRAF V600 mutant CRC. Methods: We assessed cell survival by clonogenic assay in the presence of small molecule inhibitors. In parallel, we mined TCGA RNAseq data to calculate the MAPK Pathway Activity Score (MPAS). RTK expression was assessed in TCGA data from patients with BRAF V600 mutant CRC vs. melanoma. We developed cells with acquired resistance to BRAF+MEK inhibitors (Encorafenib+Binimetinib; E+B) by culturing cells in increasing concentrations of drug over several months. RNA-sequencing and analysis was performed on parental and resistant cells treated with vehicle control or BRAF+MEK inhibitors. Results: When comparing the efficacy of BRAF+MEK inhibitors across BRAF V600 mutant cells, we found that BRAF V600 mutant CRC cell lines (n=2) were less sensitive than melanoma cell lines (n=2). MPAS scores were significantly lower in BRAF V600 mutant CRC (n=46) vs. melanoma (n=188) tumors. We interrogated protein array data from the DepMap and identified increased activation of several RTKs (EGFR, HER2, HER3) in BRAF V600 CRC (n=8) vs. melanoma (n=39) cell lines. Similarly, we established resistant HT29 (BRAF V600 CRC) cells and observed sustained MAPK pathway activity despite a lack of difference in EGFR activity in the presence of BRAF+MEK inhibitor treatment. Both HT29 parental and resistant cells showed re-establishment of MAPK signaling after 72 hours. Resistant SkMel28 (BRAF V600 melanoma) cells showed increased pERK levels compared to resistant HT29 cells. RNAseq revealed increased expression of multiple RTKs (PDGFRB, ERBB2, ERBB3) and ligands/growth factors for multiple RTKs (FGF3, PDGFA, HB-EGF) in resistant HT29 cells. Shp2 is a protein tyrosine phosphatase that regulates signaling of multiple RTKs to activate the MAPK pathway. Accordingly, we assessed the efficacy of an inhibitor of Shp2 (TNO155) overcoming MAPKi resistance in BRAF V600 CRC cells. We confirmed that E+B+TNO155 more effectively inhibited cell growth and MAPK pathway activity in BRAF V600 CRC cell lines (n=2) in vitro. Conclusion: Together, these data identify key, actionable drivers of MAPK inhibitor resistance in CRC and highlight Shp2 as a potential therapeutic target for BRAF V600 CRC. Citation Format: Jennifer Maxwell, Emmanuelle Rousselle, Lucy An, April Rose. Characterizing mechanisms of BRAF/MEK inhibitor resistance in BRAF V600 mutant colorectal cancer vs. melanoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5847.

Abstract 3078: Role of HuR in metabolic reprogramming of BRAF mutant melanoma treated with dabrafenib

Abstract Introduction: Oncogenic BRAF mutations are present in about 50% of melanoma and are clinically targetable by BRAF inhibitors such as dabrafenib. While BRAF inhibitors show high rates of clinical response, that response is transient and resistance inevitably develops. Previously we have demonstrated that BRAF inhibitors induce a metabolic shift towards the mitochondrial oxidative phosphorylation. We have shown that inhibition of wild type isocitrate dehydrogenase 1 (wtIDH1), a vital anaplerotic and anti-ROS enzyme, demonstrates synergy with dabrafenib in vitro and in vivo. IDH1 expression has been found in pancreatic cancer to be posttranscriptionally regulated by the RNA-binding and stress response protein, HuR (ELAVL1) under nutrient and chemotherapy stress. We hypothesize that HuR functions as a survival mechanism in melanoma under BRAF inhibition, regulating metabolic reprogramming including the expression of IDH1. Methods: The human BRAF V600E mutant melanoma cell line, A375, was used for all experiments. HuR and IDH1 expression was suppressed by siRNA oilgos through lipofectamine transfection, as validated by immunoblot analysis. The bioenergetic assay was conducted using Seahorse XFp mini extracellular analyzer to measure the oxygen consumption rate (OCR) under nutrient stress, both with and without dabrafenib exposure. The impact of HuR on IDH1 expression was further explored using qPCR and Immunoblot. Ivosidenib was used for pharmacologic inhibition of wtIDH as previously described. Results: Mitochondrial respiration (OCR) increased in parental A375 BRAF mutant melanoma cells following nutrient stress with low glucose conditions akin to the tumor microenvironment. OCR was further increased after dabrafenib exposure. Immunoblot analysis revealed that dabrafenib treated cells at 6-hour and 12-hour time points displayed HuR translocation from nucleus to cytoplasm, as detected in cytoplasmic lysates. Transient HuR silencing blocked the adaptive OCR response to both low glucose and BRAF inhibition. This suggests that HuR is involved in the metabolic response to acute BRAF inhibition in BRAF mutant melanoma. HuR cytoplasmic translocation is associated with increased IDH1 expression 24 hours after dabrafenib exposure. However, there is no increase in IDH1 levels under nutrient or treatment stress in HuR knockdown cells, indicating that IDH1 is regulated by HuR. Transient IDH1 knockdown, as well as pharmacologic IDH1 inhibition, blocks the OCR response of melanoma cells to BRAF inhibition and low glucose. This indicates that IDH1 is important in the HuR metabolic response to targeted therapy. Conclusion: We find that BRAF mutant melanoma cells adapt to acute dabrafenib exposure via HuR mediated expression of IDH1 to upregulate mitochondrial metabolism. This demonstrates a targeted therapy induced metabolic vulnerability that can be exploited by wtIDH1 inhibition. Citation Format: Alexander Loftus, Mehrdad Zarei, Hallie Graor, Omid Hajihassani, Christina Boutros, Jordan M. Winter, Luke D. Rothermel. Role of HuR in metabolic reprogramming of BRAF mutant melanoma treated with dabrafenib [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 3078.

Signaling and transcriptional dynamics underlying early adaptation to oncogenic BRAF inhibition.

A major contributor to poor sensitivity to anti-cancer kinase inhibitor therapy is drug-induced cellular adaptation, whereby remodeling of signaling and gene regulatory networks permits a drug-tolerant phenotype. Here, we resolve the scale and kinetics of critical subcellular events following oncogenic kinase inhibition and preceding cell cycle re-entry, using mass spectrometry-based phosphoproteomics and RNA sequencing to capture molecular snapshots within the first minutes, hours, and days of BRAF kinase inhibitor exposure in a human BRAF -mutant melanoma model of adaptive therapy resistance. By enriching specific phospho-motifs associated with mitogenic kinase activity, we monitored the dynamics of thousands of growth- and survival-related protein phosphorylation events under oncogenic BRAF inhibition and drug removal. We observed early and sustained inhibition of the BRAF-ERK axis, gradual downregulation of canonical cell cycle-dependent signals, and three distinct and reversible phase transitions toward quiescence. Statistical inference of kinetically-defined signaling and transcriptional modules revealed a concerted response to oncogenic BRAF inhibition and a dominant compensatory induction of SRC family kinase (SFK) signaling, which we found to be at least partially driven by accumulation of reactive oxygen species via impaired redox homeostasis. This induction sensitized cells to co-treatment with an SFK inhibitor across a panel of patient-derived melanoma cell lines and in an orthotopic mouse xenograft model, underscoring the translational potential for measuring the early temporal dynamics of signaling and transcriptional networks under therapeutic challenge.

Association of BRAF V600E Mutant Allele Proportion with the Dissemination Stage of Papillary Thyroid Cancer.

The early identification of aggressive forms of cancer is of high importance in treating papillary thyroid cancer (PTC). Disease dissemination is a major factor influencing patient survival. Mutation status of BRAF oncogene, BRAF V600E, is proposed to be an indicator of disease recurrence; however, its influence on PTC dissemination has not been deciphered. This study aimed to explore the association of the frequency of BRAF V600E alleles in PTC with disease dissemination. In this study, 173 PTC samples were analyzed, measuring the proportion of BRAF V600E alleles by qPCR, which was then normalized against the proportion of tumor cells. Semiquantitative analysis of BRAF V600E mutant protein was performed by immunohistochemistry. The BRAF V600E mutation was present in 60% of samples, while the normalized frequency of mutated BRAF alleles ranged from 1.55% to 92.06%. There was no significant association between the presence and/or proportion of the BRAF V600E mutation with the degree of PTC dissemination. However, the presence of the BRAF mutation was significantly linked with angioinvasion. This study's results suggest that there is a heterogeneous distribution of the BRAF mutation and the presence of oligoclonal forms of PTC. It is likely that the BRAF mutation alone does not significantly contribute to PTC aggressiveness.