Oncogenic fusion protein EWS-FLI1 is a network hub that regulates alternative splicing
The synthesis and processing of mRNA, from transcription to translation initiation, often requires splicing of intragenic material. The final mRNA composition varies based on proteins that modulate splice site selection. EWS-FLI1 is an Ewing sarcoma (ES) oncoprotein with an interactome that we demonstrate to have multiple partners in spliceosomal complexes. We evaluate the effect of EWS-FLI1 on posttranscriptional gene regulation using both exon array and RNAseq. Genes that potentially regulate oncogenesis, including CLK1, CASP3, PPFIBP1, and TERT, validate as alternatively spliced by EWS-FLI1. In a CLIP-seq experiment, we find that EWS-FLI1 RNA-binding motifs most frequently occur adjacent to intron-exon boundaries. EWS-FLI1 also alters splicing by directly binding to known splicing factors including DDX5, hnRNP K, and PRPF6. Reduction of EWS-FLI1 produces an isoform of γ-TERT that has increased telomerase activity compared with wild-type (WT) TERT. The small molecule YK-4-279 is an inhibitor of EWS-FLI1 oncogenic function that disrupts specific protein interactions, including helicases DDX5 and RNA helicase A (RHA) that alters RNA-splicing ratios. As such, YK-4-279 validates the splicing mechanism of EWS-FLI1, showing alternatively spliced gene patterns that significantly overlap with EWS-FLI1 reduction and WT human mesenchymal stem cells (hMSC). Exon array analysis of 75 ES patient samples shows similar isoform expression patterns to cell line models expressing EWS-FLI1, supporting the clinical relevance of our findings. These experiments establish systemic alternative splicing as an oncogenic process modulated by EWS-FLI1. EWS-FLI1 modulation of mRNA splicing may provide insight into the contribution of splicing toward oncogenesis, and, reciprocally, EWS-FLI1 interactions with splicing proteins may inform the splicing code.T he alternative splicing of mRNA expands the diversity of the human proteome through evolution and ontogeny (1, 2). Spliceosomal network interactions, including proteins that recognize splice enhancer and silencer regions, are critical for the regulation of alternative splicing leading to protein isoforms with disparate functionality (3). Alternative splicing provides both a method by which to categorize subsets of cancers and an avenue for more effective targeted treatments (4). However, the spliceosomal protein interaction networks that are specific to cancer have not been systematically defined; alternative splicing can also change protein-protein interactions within networks (5). A systems biology approach can be used to study the relationship between splicing and oncogenesis by using tumor models with chromosomal translocations whose expressed fusion proteins have putative roles in splicing (6, 7).Fusion proteins produced by chromosomal translocations in sarcomas often contain the amino-terminal portion of EWS and are classified as transcription factors due to the presence of a canonical carboxyl-terminal DNA-binding domain (6). EWS-FLI1 is a well-established ES oncoprotein and is re...
Iron-sulfur (Fe-S) clusters are ancient enzyme cofactors found in virtually all life forms. We evaluated the physiological effects of chronic Fe-S cluster deficiency in human skeletal muscle, a tissue that relies heavily on Fe-S cluster-mediated aerobic energy metabolism. Despite greatly decreased oxidative capacity, muscle tissue from patients deficient in the Fe-S cluster scaffold protein ISCU showed a predominance of type I oxidative muscle fibers and higher capillary density, enhanced expression of transcriptional co-activator PGC-1α and increased mitochondrial fatty acid oxidation genes. These Fe-S cluster-deficient muscles showed a dramatic up-regulation of the ketogenic enzyme HMGCS2 and the secreted protein FGF21 (fibroblast growth factor 21). Enhanced muscle FGF21 expression was reflected by elevated circulating FGF21 levels in the patients, and robust FGF21 secretion could be recapitulated by respiratory chain inhibition in cultured myotubes. Our findings reveal that mitochondrial energy starvation elicits a coordinated response in Fe-S-deficient skeletal muscle that is reflected systemically by increased plasma FGF21 levels.
Somatic Mutation Spectrum of Non–Small-Cell Lung Cancer in African Americans: A Pooled Analysis
Introduction The mutational profile of non-small cell lung cancer (NSCLC) has become an important tool in tailoring therapy to patients, with clear differences according to the population of origin. African Americans have higher lung cancer incidence and mortality than Caucasians, yet discrepant results have been reported regarding the frequency of somatic driver mutations. We hypothesized that NSCLC has a distinct mutational profile in this group. Methods We collected NSCLC samples resected from self-reported African Americans in five sites from Tennessee, Michigan, and Ohio. Gene mutations were assessed by either SNaPshot or next generation sequencing, and ALK translocations were evaluated by fluorescence in situ hybridization. Results Two hundred sixty patients were included, mostly males (62.3%) and smokers (86.6%). Eighty-one samples (31.2%) were squamous cell carcinomas. The most frequently mutated genes were KRAS (15.4%), EGFR (5.0%), PIK3CA (0.8%), BRAF, NRAS, ERBB2, and AKT1 (0.4% each). ALK translocations were detected in 2 non-squamous tumors (1.7%), totaling 61 cases (23.5%) with driver oncogenic alterations. Among 179 non-squamous samples, 54 (30.2%) presented a driver alteration. The frequency of driver alterations altogether was lower than that reported in Caucasians, while no difference was detected in either EGFR or KRAS mutations. Overall survival was longer among patients with EGFR mutations. Conclusions We demonstrated that NSCLC from African Americans has a different pattern of somatic driver mutations than from Caucasians. The majority of driver alterations in this group are yet to be described, which will require more comprehensive panels and assessment of non-canonical alterations.
BackgroundMLL2, an epigenetic regulator in mammalian cells, mediates histone 3 lysine 4 tri-methylation (H3K4me3) through the formation of a multiprotein complex. MLL2 shares a high degree of structural similarity with MLL, which is frequently disrupted in leukemias via chromosomal translocations. However, this structural similarity is not accompanied by functional equivalence. In light of this difference, and previous reports on involvement of epigenetic regulators in malignancies, we investigated MLL2 expression in established cell lines from breast and colon tissues. We then investigated MLL2 in solid tumors of breast and colon by immunohistochemistry, and evaluated potential associations with established clinicopathologic variables.ResultsWe examined MLL2 at both transcript and protein levels in established cell lines from breast and colon cancers. Examination of these cell lines showed elevated levels of MLL2. Furthermore, we also identified incomplete proteolytic cleavage of MLL2 in the highly invasive tumor cell lines. To corroborate these results, we studied tumor tissues from patients by immunohistochemistry. Patient samples also revealed increased levels of MLL2 protein in invasive carcinomas of the breast and colon. In breast, cytoplasmic MLL2 was significantly increased in tumor tissues compared to adjacent benign epithelium (p < 0.05), and in colon, both nuclear and cytoplasmic immunostaining was significantly increased in tumor tissues compared to adjacent benign mucosa (p < 0.05).ConclusionOur study indicates that elevated levels of MLL2 in the breast and colon cells are associated with malignancy in these tissues, in contrast to MLL involvement in haematopoietic cancer. In addition, both abnormal cellular localization of MLL2 and incomplete proteolytic processing may be associated with tumor growth/progression in breast and colonic tissues. This involvement of MLL2 in malignancy may be another example of the role of epigenetic regulators in cancer.
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