Mechanistically, VIC-1911 disabled HR-mediated repair of DSBs in otherwise HR-proficient PC cells, leading to a "BRCAness" phenotype and pronounced accumulation of DNA damage and mitotic catastrophe. In summary, our study uncovers what we believe a novel mechanism to functional "BRCAness" by inducing mitotic arrest and highlights VIC-1911 as a promising therapeutic agent for advanced PC, either as a single agent or in combination, sensitizing HR-proficient tumors to PARP inhibitors.

These findings highlight the superiority of scL-ALI in overcoming delivery barriers and enhancing therapeutic efficacy of alisertib, while possibly minimizing undesirable side effects in normal tissues. The scL-ALI nanocomplex shows enhanced therapeutic potential for treating AURKA-driven malignancies, particularly in combination with radiation therapy.

P2, N=50, Not yet recruiting, Puma Biotechnology, Inc.

P1, N=24, Active, not recruiting, National Cancer Institute (NCI) | Trial completion date: Mar 2026 --> Mar 2027

P2, N=96, Completed, Mayo Clinic | Active, not recruiting --> Completed

The results demonstrated the potential of using cilia-promoting drugs, such as Alvocidib and Alisertib, to suppress cancer cell replication. Additionally, it shows the massive benefits of integrating accessible large language models to conduct sweeping, rapid, and accurate literature searches.

Our findings suggest that Res may regulate BCa cell expression through the AURKA/STAT3 axis, providing a theoretical foundation for the structural optimization of Res and the development of multi-target drugs for clinical application.

The success of post-transplant cyclophosphamide (PTCy) for graft-versus-host disease (GVHD) prophylaxis has driven efforts to optimize partner therapies that balance GVHD and relapse prevention. We report phase I dose-finding results of PTCy, sirolimus (SIR), and VIC-1911, a selective oral Aurora kinase A (AURKA) inhibitor, following myeloablative allogeneic hematopoietic cell transplantation (alloHCT)...Clinical outcomes included no grade III-IV acute GVHD through day 180 (0%) and low rates of moderate/severe chronic GVHD (6%) and relapse (0%) through 1 year (5/16 received maintenance). The 1-year overall survival for this cohort was 94%.VIC-1911 at 75 mg BID, combined with PTCy and SIR, effectively suppresses AURKA activity, offering promising GVHD and relapse prevention with a favorable safety profile and promising early clinical outcomes.

We developed NN-01-195 as a novel chimeric small molecule that combines an AURKA inhibitor related to TAS-119/VIC-1911 with an HSP90-binding moiety related to SNX2112, and evaluated its function. Further, in combination with an inhibitor of the G2/M checkpoint protein WEE1, NN-01-195 is more potent than VIC-1911 in limiting growth of xenograft tumors. These data support the exploration of NN-01-195 and improved analogs as promising new candidates for therapeutic evaluation.

Treatment of MM cells with the selective AURKA inhibitor LY3295668 induced dose-dependent cytotoxicity, caspase-3/7 activation, and cellular senescence. These findings underscore AURKA expression as a prognostic marker in plasma cell disorders and support the therapeutic potential of combining AURKA inhibition with selinexor for bortezomib-resistant MM and PCL. To explore biomarker-driven strategies for optimizing therapeutic outcomes, future studies are warranted.

P1, N=9, Not yet recruiting, Shanghai Jiao Tong University School of Medicine

In addition, we review the status of AURKA-specific inhibitors in clinical evaluation and their associated adverse effects. Finally, we cite the emerging therapeutic strategy of proteolysis targeting chimeras (PROTACs) as an innovative means to selectively degrade AURKs, offering a novel approach to targeted cancer therapy.