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. 2010 Jul;16(7):793-8.
doi: 10.1038/nm.2166. Epub 2010 Jun 6.

Rearrangements of the RAF kinase pathway in prostate cancer, gastric cancer and melanoma

Nallasivam Palanisamy  1 Bushra AteeqShanker Kalyana-SundaramDorothee PfluegerKalpana RamnarayananSunita ShankarBo HanQi CaoXuhong CaoKhalid SulemanChandan Kumar-SinhaSaravana M DhanasekaranYing-bei ChenRaquel EsguevaSamprit BanerjeeChristopher J LaFargueJaved SiddiquiFrancesca DemichelisPeter MoellerTarek A BismarRainer KueferDouglas R FullenTimothy M JohnsonJoel K GreensonThomas J GiordanoPatrick TanScott A TomlinsSooryanarayana VaramballyMark A RubinChristopher A MaherArul M Chinnaiyan
Affiliations

Rearrangements of the RAF kinase pathway in prostate cancer, gastric cancer and melanoma

Nallasivam Palanisamy et al. Nat Med. 2010 Jul.

Abstract

Although recurrent gene fusions involving erythroblastosis virus E26 transformation-specific (ETS) family transcription factors are common in prostate cancer, their products are considered 'undruggable' by conventional approaches. Recently, rare targetable gene fusions involving the anaplastic lymphoma receptor tyrosine kinase (ALK) gene, have been identified in 1-5% of lung cancers, suggesting that similar rare gene fusions may occur in other common epithelial cancers, including prostate cancer. Here we used paired-end transcriptome sequencing to screen ETS rearrangement-negative prostate cancers for targetable gene fusions and identified the SLC45A3-BRAF (solute carrier family 45, member 3-v-raf murine sarcoma viral oncogene homolog B1) and ESRP1-RAF1 (epithelial splicing regulatory protein-1-v-raf-1 murine leukemia viral oncogene homolog-1) gene fusions. Expression of SLC45A3-BRAF or ESRP1-RAF1 in prostate cells induced a neoplastic phenotype that was sensitive to RAF and mitogen-activated protein kinase kinase (MAP2K1) inhibitors. Screening a large cohort of patients, we found that, although rare, recurrent rearrangements in the RAF pathway tend to occur in advanced prostate cancers, gastric cancers and melanoma. Taken together, our results emphasize the key role of RAF family gene rearrangements in cancer, suggest that RAF and MEK inhibitors may be useful in a subset of gene fusion-harboring solid tumors and demonstrate that sequencing of tumor transcriptomes and genomes may lead to the identification of rare targetable fusions across cancer types.

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Figures

Fig. 1
Fig. 1. Discovery of the SLC45A3-BRAF and ESRP1-RAF1 gene fusions in prostate cancer by paired-end transcriptome sequencing
a, Histograms of gene fusion nomination scores in clinically localized prostate tumor samples PCA1, PCA2, PCA3, and PCA17 harboring FLJ35294-ETV1, TMPRSS2-ERG, SLC45A3-BRAF, ESRP1-RAF1 and RAF1-ESRP1, respectively, and a gastric cancer sample GCT15 harboring AGTRAP-BRAF. Co-occurring fusions in each sample are also indicated. Data from ETV1 and ERG fusions are provided as controls derived from paired-end transcriptome data presented in a previous study. b, Schematic representation of reliable paired-end reads supporting the inter-chromosomal gene fusion between SLC45A3 (purple) and BRAF (orange). The protein kinase domain in the BRAF gene (yellow) remains intact following the fusion event. Respective exons are numbered. c, d, As in b, except showing the fusions between ESRP1 (red) and RAF1 (blue), resulting in reciprocal fusion genes ESRP1-RAF1 and RAF1-ESRP1. e, As in b, except showing the fusion between AGTRAP (red) and BRAF (orange).
Fig. 2
Fig. 2. Experimental validation of the SLC45A3-BRAF, ESRP1-RAF1 and RAF1-ESRP1 and AGTRAP-BRAF gene fusions
qRT-PCR validation of a) SLC45A3-BRAF gene fusion in PCA3, b) ESRP1-RAF1 and RAF1-ESRP1 fusions in PCA17, and c) AGTRAP-BRAF fusion in GCT15. d, FISH validation of SLC45A3-BRAF (left) and ESRP1-RAF1 (right) gene fusions in PCA3 and PCA17, respectively. The individual green and red signals indicate the normal chromosomes 1 and 7 (SLC45A3 and BRAF, respectively) in PCA3 and chromosomes 8 and 3 (ESRP1 and RAF1, respectively) in PCA17. Co-localizing green and red signals (yellow signal and arrow) indicate the fusion event. Tumor PCA3 displays two copies of the rearranged chromosome. e, FISH validation of the BRAF rearrangement in GCT15. Individual green and red signals (arrows) indicate rearrangement and co-localizing yellow signals indicate the normal chromosome. A second case (#10) showed deletion of the 5′ region probe with an intact 3′ probe. f. FISH validation of the BRAF rearrangement in melanoma cases MEL23 and RAF1 rearrangement in melanoma case MEL24. Individual green and red signals (arrows) indicate the rearrangement and co-localizing yellow signals indicate the normal chromosome. Scale bars indicate 2μm. g, Expression of the 120kDa ESRP1-RAF1 fusion protein in the index case PCA17. ESRP1-RAF1 fusion was detected by an antibody against C-terminus of RAF1. HEK293 cells expressing ESRP1-RAF1 fusion served as a positive control. β-actin serves as a loading control. H, Expression of a 70kDa AGTRAP-BRAF fusion protein in GCT15.
Fig. 3
Fig. 3. Oncogenic properties of SLC45A3-BRAF and ESRP1-RAF1 gene fusions
a, Foci formation by SLC45A3-BRAF, BRAFV600E and vector controls (pDEST40 and pBABE) constructs in NIH3T3 cells. Representative plates are shown for each sample above the respective quantification of foci formation (from two independent experiments). b, Over-expression of SLC45A3-BRAF fusion transcript in NIH3T3 cells induces tumor formation in nude mice. Stable polyclonal NIH3T3 cells expressing SLC45A3-BRAF (5×106) were implanted subcutaneously into nude mice. Tumor growth was monitored weekly up to 5 weeks. The c) SLC45A3-BRAF and d) ESRP1-RAF1 fusions promote cell proliferation in RWPE prostate cells. Stable RWPE cells were treated with sorafenib (0.25μM) or DMSO vehicle and proliferation was monitored by WST-1 assay at indicated times. Error bars represent SEM. P-values represent Student’s t-test and the comparison was stable pDEST40 control cells. Sorafenib-treated SLC45A3-BRAF or ESRP1-RAF1 cells were compared with vehicle control.
Fig. 4
Fig. 4. RAF and MEK inhibitors block SLC45A3-BRAF or ESRP1-RAF1 gene fusion mediated oncogenic phenotypes
a, SLC45A3-BRAF or ESRP1-RAF1 mediated cell invasion in RWPE prostate cells is sensitive to sorafenib (10μM) or the MEK inhibitor U0126 (1 or 10μM). Cells were photographed after invasion through Matrigel and stained with crystal violet or b) quantitated by absorbance. pDEST40 represents the empty vector control. Error bars and P values were calculated as in Fig 3d. c, Photomicrographs or d) quantitation of SLC45A3-BRAF or ESRP1-RAF1 induced anchorage independent colony growth in soft agar, which was sensitive to sorafenib or U0126. Scale bars indicate 50μm. e, Evaluation of the downstream signaling pathways activated by the SLC45A3-BRAF or ESRP1-RAF1 gene fusions in RWPE prostate cells. SLC45A3-BRAF or ESRP1-RAF1 expressing pooled populations and vector controls were treated with U0126 (10 μM) for two hours and immunoblotted for phosphor (p)- and total (t) MEK-1/2 and ERK-1/2. SK-MEL-94, a BRAFV600E positive melanoma cell line, was included as a positive control.
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References

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