Gene Fusion Detection and Characterization in Long-Read Cancer Transcriptome Sequencing Data with FusionSeeker.

Gene fusions are prevalent in a wide array of cancer types with different frequencies. Long-read transcriptome sequencing technologies, such as PacBio, Iso-Seq, and Nanopore direct RNA sequencing, provide full-length transcript sequencing reads, which could facilitate detection of gene fusions. In this work, we developed a method, FusionSeeker, to comprehensively characterize gene fusions in long-read cancer transcriptome data and reconstruct accurate fused transcripts from raw reads. FusionSeeker identified gene fusions in both exonic and intronic regions, allowing comprehensive characterization of gene fusions in cancer transcriptomes. Fused transcript sequences were reconstructed with FusionSeeker by correcting sequencing errors in the raw reads through partial order alignment algorithm. Using these accurate transcript sequences, FusionSeeker refined gene fusion breakpoint positions and predicted breakpoints at single bp resolution. Overall, FusionSeeker will enable users to discover gene fusions accurately using long-read data, which can facilitate downstream functional analysis as well as improved cancer diagnosis and treatment. SIGNIFICANCE: FusionSeeker is a new method to discover gene fusions and reconstruct fused transcript sequences in long-read cancer transcriptome sequencing data to help identify novel gene fusions important for tumorigenesis and progression.

Loss of BRMS2 induces cell growth inhibition and translation capacity reduction in colorectal cancer cells.

A variety of chemotherapeutic drugs targeting ribosome processing have been developed and applied to cancer treatment mainly based on the impaired ribosome biogenesis checkpoint (IRBC). The IMP U3 small nucleolar ribonucleoprotein 3 (IMP3, BRMS2) has been identified as a participant in pre-rRNA processing for nearly twenty years. However, the roles of BRMS2 in cancers still unknown. In this research, a tissue microarray (TMA) with 151 paired tissues showed the aberrant overexpression of BRMS2 in CRC tissues which was associated with the worse prognosis. To clarify the function of BRMS2 in CRC cells, an inducible knockdown system was introduced in vitro and in vivo and the cell growth was drastically suppressed. Mechanistically, we found depletion of BRMS2 markedly decreased the protein translation rates which can limit cell growth. Furthermore, to confirm whether the IRBC played a role, multiple approaches including detection of the p53 pathway, depletion of BRMS2 in p53-mutated SW620 cells, and co-depletion of RPL11 were taken. To our surprise, IRBC was not activated. That indicated BRMS2 may play a unique role in ribosome biosynthesis and IRBC. Taken together, our results demonstrated the oncogenic function of BRMS2 in CRC cells and supported its potential as a therapeutic target.

Sesquiterpene lactone Bigelovin induces apoptosis of colon cancer cells through inducing IKK-ß degradation and suppressing nuclear factor kappa B activation.

Bigelovin, a sesquiterpene lactone extracted from plant Inula helianthus aquatica, exhibited multiple interesting biological activities, including anti-inflammation, antiangiogenesis and cytotoxic action against cancer cells. In the present study, we found that Bigelovin reduced the viability of human colon cancer cells and induced their apoptosis in a time- and dose-dependent manner, with an IC50-5 µM. RNAseq and luciferase reporter analyses revealed that the nuclear factor kappa B (NF-κB) signaling was one of the most significantly inhibited pathways after Bigelovin treatment. Further systemic examination showed that exposure to Bigelovin resulted in ubiquitination and degradation of inhibitor of kappa-B kinase-beta (IKK-ß) and decrease of IκB-α and p65 phosphorylation, which led to the downregulation of NF-κB-regulated genes expression. Moreover, enforced expression of exogenous IKK-ß attenuated Bigelovin-induced NF-κB suppression and cell viability reduction. These results indicated that Bigelovin exerts a cytotoxic action against colon cancer cells through the induction of IKK-ß degradation and consequently the inhibition of NF-κB signaling. Given the abnormal activation of NF-κB signaling in colorectal cancer (CRC) cells and the critical role of chronic inflammation in CRC development, it is conceivable that at least some colorectal cancer cells are addictive to NF-κB activation and targeting the pathway is an effective anti-CRC strategy.