CDYL1-dependent decrease in lysine crotonylation at DNA double-strand break sites functionally uncouples transcriptional silencing and repair.

Previously, we showed that CDYL1 is recruited to DNA double-strand breaks (DSBs) to promote homologous recombination (HR) repair and foster transcriptional silencing. However, how CDYL1 elicits DSB-induced silencing is not fully understood. Here, we identify a CDYL1-dependent local decrease in the transcriptionally active marks histone lysine crotonylation (Kcr) and crotonylated lysine 9 of H3 (H3K9cr) at AsiSI-induced DSBs, which correlates with transcriptional silencing. Mechanistically, we reveal that CDYL1 crotonyl-CoA hydratase activity counteracts Kcr and H3K9cr at DSB sites, which triggers the eviction of the transcription elongation factor ENL and fosters transcriptional silencing. Furthermore, genetic inhibition of CDYL1 hydratase activity blocks the reduction in H3K9cr and alleviates DSB-induced silencing, whereas HR efficiency unexpectedly remains intact. Therefore, our results functionally uncouple the repair and silencing activity of CDYL1 at DSBs. In a broader context, we address a long-standing question concerning the functional relationship between HR repair and DSB-induced silencing, suggesting that they may occur independently.

Decoding the dynamic H3K9cr landscapes during neural commitment of P19 embryonal carcinoma cells.

Histone lysine crotonylation (Kcr) is a novel hydrophobic histone acylation modification, and we recently report its crucial roles in neural differentiation. However, it is still unclear how histone Kcr involve in early neural commitment. Here, we systematically investigate the H3K9cr landscapes during neuroectodermal differentiation of pluripotent P19 embryonal carcinoma cells (ECCs). We reveal that the genome-wide changes in H3K9cr favor neural fate specification, and identify potential co-factors binding H3K9cr. We also uncover that H3K9cr collaborates with H3K9ac to regulate gene expression changes. Our results provide novel insights into the epigenetic mechanisms underlying neural commitment.