Splicing occurs co-transcriptionally and is regulated by trans-acting factors (RNA binding proteins) via binding to cis-regulatory RNA elements. Y14 is a core factor of the exon junction complex (EJC), which functions in the post-splicing events, but recent studies have revealed that deletion of Y14 generated aberrant alternative splicing products. I unexpectedly discovered that the C-terminally truncated Y14 or phospho-deficient mutant (SA), but not wild type Y14, reversed Y14 knockdown-induced splicing changes. Besides, inhibition of RNA polymerase II and topoisomerase I & II prevented Y14 knockdown-induced splicing changes on a different scale. Next, we evaluated how the Y14-SA mutant exerts the dominant effect. We here observed that both wild-type and mutant (SA) Y14 can bind the promoter regions of its target genes, indicating a potential role of Y14 in coordinating transcription and splicing, which is independent of Y14’s phosphorylation. Moreover, my colleagues and I found that Y14 interacted with both the RNA demethylase ALKBH5 and RNA methyltransferase METTL16. Depletion of Y14 reduced m6A modification on U6 snRNA. However, depletion of METTL16 or overexpression of ALKBH5, although minimally affected m6A modification of U6 snRNA, had no effect on alternative splicing of Y14 target genes. At present, whether m6A modification of U6 snRNA is essential for splicing or involved in splicing regulation is yet unclear. Besides, we found that Y14 inhibited the demethylase activity of ALKBH5 in vitro. Whether the interaction between Y14 and m6A modifying enzymes has any biological functions remains to be examined. Investigation of Y14’s role in splicing regulation is still ongoing.