Genome-wide circular RNA (circRNA) and mRNA profiling identify a circMET-miR-410-3p regulatory motif for cell growth in colorectal cancer.

ABSTRACT

Circular RNA (circRNA) is a non-coding RNA molecule that lacks polyadenylated tails and is highly stable, abundant, and conserved in human cells. CircRNAs can serve as a competing endogenous RNA (ceRNA) to sponge microRNAs (miRNA) and block their effects on target mRNA expression. CircRNAs also have possible relevance to cancer and therefore may be considered as ideal biomarkers for monitoring cancer progression. Of the about 300,000 predicted human circRNAs, only a few have validated biological functions related to cancer. To better understand the ceRNA role of circRNAs in colorectal cancer (CRC), we performed genome-wide circRNA-based RNA-sequencing (RNA-Seq) on nine CRC tumor samples and their paired histologically normal adjacent tissue samples. By profiling the mRNA expression in the same patients, we further explored the expression correlation between circRNAs and mRNAs generated from the same parental gene. Focusing on the concordant differential expression between circRNAs and mRNAs, we substantially reduced the regulatory noise. In total, we identified 694 circRNA-mRNA pairs that were consistently up or downregulated between tumor and normal tissues. These 694 circRNA-mRNA pairs are from 182 protein-coding genes associated with hormone responses and chemotaxis. Of these 182 genes, 43 are downstream targets of three highly conserved miRNAs (miR-410-3p, miR-135a, and miR-30a). Interestingly, these 43 genes are highly mutated in another cohort from eight independent CRC studies, which have significant effects on patient survival time. Focusing on miR-410-3p and its target oncogene MET, we experimentally validated the ceRNA regulatory motif of circMET. Notably, circMET is substantially upregulated in CRC cell lines and could promote cell proliferation and growth. By confirming the regulatory relationship between miR-410-3p and circMET, we propose a new mechanism for the observed sustained activation of MET in CRC. In conclusion, our work identifies a novel regulatory role of circMET and provides a potential diagnostic biomarker for CRC.