Cleavage factor "CFIm25", as a key repressor at proximal poly (A) site, negatively correlates to cell proliferation and tumorigenicity in various cancers. Hence, understanding CFIm25 mechanism of action in breast cancer would be a great benefit. To this aim four steps were designed. First, potential miRNAs that target 3′-UtR of CFIm25 mRnA, retrieved from targetscan web server. Second, screened miRNAs were profiled in 100 breast cancer and 100 normal adjacent samples. Third, miRNAs that their expression was inversely correlated to the CFIm25, overexpressed in MDA-MB-231 cell line, and their effect on proliferation and migration monitored via MTT and wound healing assays, respectively. fourth, interaction of miRNAs of interest with 3′-UtR of CFIm25 confirmed via luciferase assay and western blot. our results indicate that CFIm25 considerably down-regulates in human breast cancer tissue. qRT-PCR assay, luciferase test, and western blotting confirm that CFIm25 itself could be directly regulated by oncomiRs such as miR-23,-24,-27,-135,-182 and-374. Besides, according to Mtt and wound healing assays of cell lines, CFIm25 knockdown intensifies cell growth, proliferation and migration. Our results also confirm indirect impact of CFIm25 on regulation of mRNA's 3′-UtR length, which then control corresponding miRNAs' action. miRNAs directly control CFIm25 expression level, which then tunes expression of the oncogenes and tumor proliferation. Therefore, regulation of CFIm25 expression level via miRNAs is expected to improve treatment responses in breast cancer. Abbreviations CPSF Cleavage and polyadenylation specificity factor CstF Cleavage stimulation factor PAS Polyadenylation site 3′-UTR 3′-Untranslated region UTR-APA Untranslated region-alternative polyadenylation miRNA/miR MicroRNA CFIm25 Cleavage factor Im 25 RF Random forest classifiers shRNA Short hairpin RNA HCC Hepatocellular carcinoma Living organisms apply complicated mechanisms of gene regulation to generate different cell types, which result in various behaviors from a single genome 1,2. Dynamic and highly polymorphic nature of mRNA polyadenylation, as a functional aspect of gene regulation, is one of the most recent discoveries in this field 3,4. Cleavage and polyadenylation of nascent mRNA accomplishes via application of two large multimeric complexes, which named as cleavage-polyadenylation specificity factor (CPSF) and cleavage stimulation factor (CstF), respectively. The
