Polo-like kinase 1 (Plk1), a member of the Polo-like kinase family, plays a critical role in regulating mitosis and cell cycle progression. Aberrant expression of Plk1 has been observed in a variety of human cancers, and it is known to be associated with tumorigenesis as well as poor prognosis in cancer patients. Unlike normal cells, some cancer cells are dependent on augmented Plk1 levels to remain viable and are killed when Plk1 function is attenuated. Although Plk1 has proven to be an attractive target in cancer treatment, currently available Plk1 inhibitors have shown limited efficacy with significant dose-limiting toxicity and non-specificity in various preclinical or clinical trials. Thus, there remains an unmet need to develop anti-cancer drugs that are highly specific against Plk1 and have better clinical outcomes.
Scientists at the National Institutes of Health have identified a new heterocyclic scaffold with unique structural and chemical features that can be leveraged for anti-Plk1 drug discovery. This triazoloquinazolinone scaffold can be used to synthesize various S-methyl prodrugs that effectively inhibit the functionally essential, polo-box domain (PBD) of Plk1 without affecting its related Plk2 and Plk3 PBDs. These prodrugs effectively arrest mitotic progression and cell proliferation in cell-based assays. Low molecular weight and moderate hydrophobicity of these prodrugs increase their availability in intracellular compartments. Promising chemical features of these compounds could offer a new avenue for developing therapeutics against Plk1-dependent cancers.
The National Institutes of Health is seeking commercial partners to co-develop and/or license this technology.