This study presents the first investigation of acetyl-11-keto-β-boswellic acid (AKBA)’s anti-human cytomegalovirus (HCMV) activity in vitro and elucidates its underlying mechanisms. In HCMV Towne strain-infected WI-38 cells, AKBA (1-12 μM) exhibited negligible cytotoxicity while significantly suppressing virus-induced cytopathic effects (CPE) at 6–10 μM, with dose-dependent reduction of viral proteins (IE1/2 and p52) expression, viral DNA copy number (UL123, UL44, and UL32), and infectious viral progeny titer (TCID₅₀). Time-of-addition experiments demonstrated the primary antiviral activity of AKBA during post-entry phase, along with direct virion inactivation. Transcriptome analysis revealed that AKBA significantly downregulated the expression of the host factor NR4A1 induced by HCMV, a finding further validated by Western blotting. Further gene knockdown experiments confirmed that silencing NR4A1 significantly reduced the expression of viral proteins IE1/2, thereby validating NR4A1 as a key host factor for HCMV infection. These findings indicate that AKBA has a potent and dose-dependent inhibitory effect on HCMV replication in WI-38 cells, and proves that this effect is mediated through two different mechanisms: one is the downregulation of the expression of the key host factor NR4A1, and the other is the direct inactivation of HCMV viral particles.

CRISPR-Cas9-based gene editing enables precise genetic modifications. However, its application to human cytomegalovirus (HCMV) remains challenging due to the large size of the viral genome and the essential roles of key regulatory genes. Here, we establish an optimized CRISPR-Cas9 system for precise labeling and functional analysis of HCMV immediate early (IE) genes. By integrating a multifunctional cassette encoding an auxin-inducible degron (AID), a self-cleaving peptide (P2A), and GFP into the viral genome via homology-directed repair (HDR), we achieved efficient knock-ins without reliance on bacterial artificial chromosome (BAC) cloning, a labor-intensive and time-consuming approach. We optimized delivery strategies, donor template designs, and component ratios to enhance HDR efficiency, significantly improving knock-in success rates. This system enables real-time fluorescent tracking and inducible protein degradation, allowing temporal control of essential viral proteins through auxin-mediated depletion. Our approach provides a powerful tool for dissecting the dynamic roles of viral proteins throughout the HCMV life cycle, facilitating a deeper understanding of viral pathogenesis and potential therapeutic targets.