Discovery of Nanomolar-Affinity Pharmacological Chaperones Stabilizing the Oncogenic p53 Mutant Y220C

The tumor suppressor protein p53 is inactivated in the majority of human cancers and remains a prime target for developing new drugs to reactivate its tumor suppressing activity for anticancer therapies. The oncogenic p53 mutant Y220C accounts for approximately 125,000 new cancer cases per annum and is one of the most prevalent p53 mutants overall. It harbors a narrow, mutationally induced pocket at the surface of the DNA-binding domain that destabilizes p53, leading to its rapid denaturation and aggregation. Here, we present the structure-guided development of high-affinity small molecules stabilizing p53-Y220C in vitro, along with the synthetic routes developed in the process, in vitro structure–activity relationship data, and confirmation of their binding mode by protein X-ray crystallography. We disclose two new chemical probes displaying sub-micromolar binding affinity in vitro, marking an important milestone since the discovery of the first small-molecule ligand of Y220C in 2008. New chemical probe JC744 displayed a Kd = 320 nM, along with potent in vitro protein stabilization. This study, therefore, represents a significant advance toward high-affinity Y220C ligands for clinical evaluation.

anticancer therapy, mutant p53, pharmacological chaperoning, small molecule, structure-based drug design

10.1021/acsptsci.2c00164

2575-9108

1169–1180

Stephenson Clarke, Joseph Richard

f92a6e84-4929-4908-a88b-0522b1703916

Douglas, Leon R

049b5f33-6870-4773-ae34-663489b472ba

Duriez, Patrick

4cf499bc-007a-43b3-b180-d6e5dc3d151b

Balourdas, Dimitrios-Ilias

b707bb64-fd49-4318-bc97-3de45c1e9017

Joerger, Andreas C.

69e42747-d541-4f47-92e5-d8ddd7d73c27

Khadiullina, Raniya

560b02a8-6381-4fb6-b359-5d020e76a675

Bulatov, Emil

604a6ecd-d91c-42d2-bb16-0eb720b2b7b3

Baud, Matthias G.J.

8752d519-3d33-43b6-9a77-ab731d410c2e

11 November 2022

Stephenson Clarke, Joseph Richard

f92a6e84-4929-4908-a88b-0522b1703916

Douglas, Leon R

049b5f33-6870-4773-ae34-663489b472ba

Duriez, Patrick

4cf499bc-007a-43b3-b180-d6e5dc3d151b

Balourdas, Dimitrios-Ilias

b707bb64-fd49-4318-bc97-3de45c1e9017

Joerger, Andreas C.

69e42747-d541-4f47-92e5-d8ddd7d73c27

Khadiullina, Raniya

560b02a8-6381-4fb6-b359-5d020e76a675

Bulatov, Emil

604a6ecd-d91c-42d2-bb16-0eb720b2b7b3

Baud, Matthias G.J.

8752d519-3d33-43b6-9a77-ab731d410c2e

Stephenson Clarke, Joseph Richard, Douglas, Leon R, Duriez, Patrick, Balourdas, Dimitrios-Ilias, Joerger, Andreas C., Khadiullina, Raniya, Bulatov, Emil and Baud, Matthias G.J. (2022) Discovery of Nanomolar-Affinity Pharmacological Chaperones Stabilizing the Oncogenic p53 Mutant Y220C. ACS Pharmacology and Translational Science, 5 (11), 1169–1180. (doi:10.1021/acsptsci.2c00164).

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Accepted/In Press date: 11 October 2022

Published date: 11 November 2022

Additional Information: This work was supported by awards to M.B. from the Engineering and Physical Sciences Research Council (grant EP/N509747/1, project reference 1940843) and the Royal Society (grant IEC\R2\181097). Nuclear magnetic resonance and mass spectrometry facilities in Southampton are supported by EPSRC core capability award (EP/K039466/1). L.R.D. and P.J.D. were supported by Cancer Research UK (CRUK grant C34999/A18087). A.C.J. was supported by German Research Foundation (DFG) grant JO 1473/1-3. D.-I.B. was supported by a Buchmann fellowship. The Structural Genomics Consortium is a registered charity (no. 1097737) that receives funds from Bayer AG, Boehringer Ingelheim, Bristol Myers Squibb, Genentech, Genome Canada through Ontario Genomics Institute [OGI-196], EU/EFPIA/OICR/McGill/ KTH/Diamond Innovative Medicines Initiative 2 Joint Undertaking [EUbOPEN grant 875510], Janssen, Merck KGaA (a.k.a. EMD in Canada and US), Pfizer, and Takeda. We thank the staff at beamline X06SA of the Swiss Light Source for assistance during data collection. E.B. was supported by the Russian Science Foundation (RSF grant 19-74-10022). R.K. was supported by the Kazan Federal University Strategic Academic Leadership Program (Priority- 2030).

Keywords: anticancer therapy, mutant p53, pharmacological chaperoning, small molecule, structure-based drug design

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