A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C

AIM: The p53 cancer mutation Y220C creates a conformationally unstable protein with a unique elongated surface crevice that can be targeted by molecular chaperones. We report the structure-guided optimization of the carbazole-based stabilizer PK083. MATERIALS & METHODS: Biophysical, cellular and...

Descripción completa

Detalles Bibliográficos
Autores principales: Bauer, Matthias R, Jones, Rhiannon N, Tareque, Raysa K, Springett, Bradley, Dingler, Felix A, Verduci, Lorena, Patel, Ketan J, Fersht, Alan R, Joerger, Andreas C, Spencer, John
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Newlands Press Ltd 2019
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6803818/
https://www.ncbi.nlm.nih.gov/pubmed/31633398
http://dx.doi.org/10.4155/fmc-2019-0181
_version_ 1783461030440992768
author Bauer, Matthias R
Jones, Rhiannon N
Tareque, Raysa K
Springett, Bradley
Dingler, Felix A
Verduci, Lorena
Patel, Ketan J
Fersht, Alan R
Joerger, Andreas C
Spencer, John
author_facet Bauer, Matthias R
Jones, Rhiannon N
Tareque, Raysa K
Springett, Bradley
Dingler, Felix A
Verduci, Lorena
Patel, Ketan J
Fersht, Alan R
Joerger, Andreas C
Spencer, John
author_sort Bauer, Matthias R
collection PubMed
description AIM: The p53 cancer mutation Y220C creates a conformationally unstable protein with a unique elongated surface crevice that can be targeted by molecular chaperones. We report the structure-guided optimization of the carbazole-based stabilizer PK083. MATERIALS & METHODS: Biophysical, cellular and x-ray crystallographic techniques have been employed to elucidate the mode of action of the carbazole scaffolds. RESULTS: Targeting an unoccupied subsite of the surface crevice with heterocycle-substituted PK083 analogs resulted in a 70-fold affinity increase to single-digit micromolar levels, increased thermal stability and decreased rate of aggregation of the mutant protein. PK9318, one of the most potent binders, restored p53 signaling in the liver cancer cell line HUH-7 with homozygous Y220C mutation. CONCLUSION: The p53-Y220C mutant is an excellent paradigm for the development of mutant p53 rescue drugs via protein stabilization. Similar rescue strategies may be applicable to other cavity-creating p53 cancer mutations.
format Online
Article
Text
id pubmed-6803818
institution National Center for Biotechnology Information
language English
publishDate 2019
publisher Newlands Press Ltd
record_format MEDLINE/PubMed
spelling pubmed-68038182019-10-23 A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C Bauer, Matthias R Jones, Rhiannon N Tareque, Raysa K Springett, Bradley Dingler, Felix A Verduci, Lorena Patel, Ketan J Fersht, Alan R Joerger, Andreas C Spencer, John Future Med Chem Research Article AIM: The p53 cancer mutation Y220C creates a conformationally unstable protein with a unique elongated surface crevice that can be targeted by molecular chaperones. We report the structure-guided optimization of the carbazole-based stabilizer PK083. MATERIALS & METHODS: Biophysical, cellular and x-ray crystallographic techniques have been employed to elucidate the mode of action of the carbazole scaffolds. RESULTS: Targeting an unoccupied subsite of the surface crevice with heterocycle-substituted PK083 analogs resulted in a 70-fold affinity increase to single-digit micromolar levels, increased thermal stability and decreased rate of aggregation of the mutant protein. PK9318, one of the most potent binders, restored p53 signaling in the liver cancer cell line HUH-7 with homozygous Y220C mutation. CONCLUSION: The p53-Y220C mutant is an excellent paradigm for the development of mutant p53 rescue drugs via protein stabilization. Similar rescue strategies may be applicable to other cavity-creating p53 cancer mutations. Newlands Press Ltd 2019-10-21 2019-10 /pmc/articles/PMC6803818/ /pubmed/31633398 http://dx.doi.org/10.4155/fmc-2019-0181 Text en © 2019 John Spencer This work is licensed under the Attribution-NonCommercial-NoDerivatives 4.0 Unported License (http://creativecommons.org/licenses/by-nc-nd/4.0/)
spellingShingle Research Article
Bauer, Matthias R
Jones, Rhiannon N
Tareque, Raysa K
Springett, Bradley
Dingler, Felix A
Verduci, Lorena
Patel, Ketan J
Fersht, Alan R
Joerger, Andreas C
Spencer, John
A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title_full A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title_fullStr A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title_full_unstemmed A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title_short A structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant Y220C
title_sort structure-guided molecular chaperone approach for restoring the transcriptional activity of the p53 cancer mutant y220c
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6803818/
https://www.ncbi.nlm.nih.gov/pubmed/31633398
http://dx.doi.org/10.4155/fmc-2019-0181
work_keys_str_mv AT bauermatthiasr astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT jonesrhiannonn astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT tarequeraysak astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT springettbradley astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT dinglerfelixa astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT verducilorena astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT patelketanj astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT fershtalanr astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT joergerandreasc astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT spencerjohn astructureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT bauermatthiasr structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT jonesrhiannonn structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT tarequeraysak structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT springettbradley structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT dinglerfelixa structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT verducilorena structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT patelketanj structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT fershtalanr structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT joergerandreasc structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c
AT spencerjohn structureguidedmolecularchaperoneapproachforrestoringthetranscriptionalactivityofthep53cancermutanty220c

Ejemplares similares