Conclusion
These findings provide evidence for the significant involvement of JUND in cervical cancer pathogenesis, thereby positioning JUND as a potential therapeutic target for the treatment of this disease.
Methods
With bioinformatics and 3D genomics, we revealed the enhancers in cervical cancer cell line and calculated which transcription factor (TF) is specifically binding on them based on TFs motif database. We knockdowned this TF and studied its function in cervical cancer cell line in vivo and in vitro.
Purpose
Enhancers are genomic regulatory elements located distally from the target gene, which play a critical role in determining cell identity and function. Dysregulation of enhancers has been frequently observed in various types of cancer, including cervical cancer. However, the identity of enhancers and their associated transcriptional regulators that are involved in cervical cancer remains unclear.
Results
We found 14,826 activated enhancers and predicted that JUND (JunD Proto-Oncogene) is relatively enriched in the sequences of these enhancers. Well-known oncogene MYC and JUN were regulated by JUND through enhancers. To further explore the roles of JUND in cervical cancer, we analyzed the gene expression data of clinical cervical cancer samples and knock-downed JUND by CRISPR-Cas9 in Hela cell line. We found JUND is over-expressed in cervical cancer and the expression of JUND increased along with the cervical cancer progresses. Knockdown of JUND decreased the proliferation of Hela cells in vitro and in vivo and blocked cell cycle in G1-phase. Transcriptome sequencing analysis revealed the identification of 2,231 differentially expressed genes in response to the JUND knockdown treatment. This perturbation resulted in the modulation of several biological processes and pathways that have been previously linked to cancer.