Phase separation of p53 precedes aggregation and is affected by oncogenic mutations and ligands

Elaine C Petronilho; Murilo M Pedrote; Mayra A Marques; Yulli M Passos; Michelle F Mota; Benjamin Jakobus; Gileno Dos Santos de Sousa; Filipe Pereira da Costa; Adriani L Felix; Giulia D S Ferretti; Fernando P Almeida; Yraima Cordeiro; Tuane C R G Vieira; Guilherme A P de Oliveira; Jerson L Silva

doi:10.1039/d1sc01739j

Phase separation of p53 precedes aggregation and is affected by oncogenic mutations and ligands

Chem Sci. 2021 Apr 26;12(21):7334-7349. doi: 10.1039/d1sc01739j.

Authors

Elaine C Petronilho¹, Murilo M Pedrote¹, Mayra A Marques¹, Yulli M Passos², Michelle F Mota¹, Benjamin Jakobus³, Gileno Dos Santos de Sousa¹, Filipe Pereira da Costa¹, Adriani L Felix¹, Giulia D S Ferretti¹, Fernando P Almeida⁴, Yraima Cordeiro², Tuane C R G Vieira¹, Guilherme A P de Oliveira¹, Jerson L Silva¹

Affiliations

¹ Institute of Medical Biochemistry Leopoldo de Meis, National Institute of Science and Technology for Structural Biology and Bioimaging, National Center of Nuclear Magnetic Resonance Jiri Jonas, Federal University of Rio de Janeiro Rio de Janeiro RJ 21941-902 Brazil gaugusto@bioqmed.ufrj.br jerson@bioqmed.ufrj.br.
² Faculty of Pharmacy, Federal University of Rio de Janeiro Rio de Janeiro Brazil.
³ Modal Informática Ltda Almeida Godinho, 19, 304 Rio de Janeiro RJ 22741-140 Brazil.
⁴ National Center for Structural Biology and Bioimaging (CENABIO), Federal University of Rio de Janeiro Rio de Janeiro RJ 21941-902 Brazil.

Abstract

Mutant p53 tends to form aggregates with amyloid properties, especially amyloid oligomers inside the nucleus, which are believed to cause oncogenic gain-of-function (GoF). The mechanism of the formation of the aggregates in the nucleus remains uncertain. The present study demonstrated that the DNA-binding domain of p53 (p53C) underwent phase separation (PS) on the pathway to aggregation under various conditions. p53C phase separated in the presence of the crowding agent polyethylene glycol (PEG). Similarly, mutant p53C (M237I and R249S) underwent PS; however, the process evolved to a solid-like phase transition faster than that in the case of wild-type p53C. The data obtained by microscopy of live cells indicated that transfection of mutant full-length p53 into the cells tended to result in PS and phase transition (PT) in the nuclear compartments, which are likely the cause of the GoF effects. Fluorescence recovery after photobleaching (FRAP) experiments revealed liquid characteristics of the condensates in the nucleus. Mutant p53 tended to undergo gel- and solid-like phase transitions in the nucleus and in nuclear bodies demonstrated by slow and incomplete recovery of fluorescence after photobleaching. Polyanions, such as heparin and RNA, were able to modulate PS and PT in vitro. Heparin apparently stabilized the condensates in a gel-like state, and RNA apparently induced a solid-like state of the protein even in the absence of PEG. Conditions that destabilize p53C into a molten globule conformation also produced liquid droplets in the absence of crowding. The disordered transactivation domain (TAD) modulated both phase separation and amyloid aggregation. In summary, our data provide mechanistic insight into the formation of p53 condensates and conditions that may result in the formation of aggregated structures, such as mutant amyloid oligomers, in cancer. The pathway of mutant p53 from liquid droplets to gel-like and solid-like (amyloid) species may be a suitable target for anticancer therapy.