Human mono-ADP-ribosylating PARP enzymes have been linked to several clinically relevant processes and many of these PARPs have been suggested as potential drug targets. Despite recent advances in the field, efforts to discover such compounds have been hindered by the lack of tools to rapidly screen for high potency compounds and profile them against the different PARP enzymes of the ARTD family. We here expanded the methods and engineered mono-ART catalytic fragments to be incorporated into a cellulosome-based octavalent scaffold. Compared to the free enzymes, the scaffold-based system results in an improved activity for the tested PARPs due to improved solubility, stability and the proximity of the catalytic domains, altogether boosting their activity beyond 10-fold in the case of PARP12. This allows us to measure their enhanced activity using a simple and easily accessible homogeneous NAD+ conversion assay, facilitating its automation to reduce the assay volume and lowering the assay costs. The approach will enable the discovery of more potent compounds due to increased assay sensitivity and it can be applied to compound screening campaigns as well as inhibitor profiling.
Human mono-ADP-ribosylating PARP enzymes have been linked to several clinically relevant processes and many of these PARPs have been suggested as potential drug targets. Despite recent advances in the field, efforts to discover such compounds have been hindered by the lack of tools to rapidly screen for high potency compounds and profile them against the different PARP enzymes of the ARTD family. We here expanded the methods and engineered mono-ART catalytic fragments to be incorporated into a cellulosome-based octavalent scaffold. Compared to the free enzymes, the scaffold-based system results in an improved activity for the tested PARPs due to improved solubility, stability and the proximity of the catalytic domains, altogether boosting their activity beyond 10-fold in the case of PARP12. This allows us to measure their enhanced activity using a simple and easily accessible homogeneous NAD+ conversion assay, facilitating its automation to reduce the assay volume and lowering the assay costs. The approach will enable the discovery of more potent compounds due to increased assay sensitivity and it can be applied to compound screening campaigns as well as inhibitor profiling.
We report [1,2,4]triazolo[3,4-b]benzothiazole
(TBT) as a new inhibitor scaffold, which competes with nicotinamide
in the binding pocket of human poly- and mono-ADP-ribosylating enzymes.
The binding mode was studied through analogues and cocrystal structures
with TNKS2, PARP2, PARP14, and PARP15. Based on the substitution pattern,
we were able to identify 3-amino derivatives 21 (OUL243)
and 27 (OUL232) as inhibitors of mono-ARTs PARP7, PARP10,
PARP11, PARP12, PARP14, and PARP15 at nM potencies, with 27 being the most potent PARP10 inhibitor described to date (IC50 of 7.8 nM) and the first PARP12 inhibitor ever reported.
On the contrary, hydroxy derivative 16 (OUL245) inhibits
poly-ARTs with a selectivity toward PARP2. The scaffold does not possess
inherent cell toxicity, and the inhibitors can enter cells and engage
with the target protein. This, together with favorable ADME properties,
demonstrates the potential of TBT scaffold for future drug development
efforts toward selective inhibitors against specific enzymes.
Here we report [1,2,4]triazolo[3,4-b]benzothiazole (TBT) as a new inhibitor scaffold, which competes with nicotinamide in the binding pocket of human poly- and mono-ADP-ribosylating enzymes. The binding mode was studied through analogs and their crystal structures with TNKS2, PARP2, PARP14 and PARP15. Based on the substitution pattern, we were able to identify The 3-amino derivatives 21 (OUL243) and 27 (OUL232), as inhibitors of mono-ARTs PARP7, PARP10, PARP11, PARP12, PARP14 and PARP15 at nM potencies, with compound 27 being the most potent PARP10 inhibitor described to date with an IC50 of 7.8 nM and the first PARP12 inhibitor ever reported. On the contrary, hydroxy derivative 16 (OUL245) inhibits poly-ARTs with a selectivity towards PARP2. The scaffold does not possess inherent cell toxicity and the inhibitors can enter cells and engage with the target protein. This, together with favorable ADME properties, demonstrates the potential of the TBT scaffold for future drug development efforts towards selective inhibitors against specific enzymes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.