posted on 2022-12-19, 22:31authored byIgor D.
M. Lima, Murilo M. Pedrote, Mayra A. Marques, Gileno dos S. de Sousa, Jerson L. Silva, Guilherme A. P. de Oliveira, Elio A. Cino
The
gene encoding the p53 tumor suppressor protein is the most
frequently mutated oncogene in cancer patients; yet, generalized strategies
for rescuing the function of different p53 mutants remain elusive.
This work investigates factors that may contribute to the low inherent
stability of the wild-type p53 core domain (p53C) and structurally
compromised Y220C mutant. Pressure-induced unfolding of p53C was compared
to p63C, the p53 family member with the highest stability, the engineered
superstable p53C hexamutant (p53C HM), and lower stability p53C Y220C
cancer-associated mutant. The following pressure unfolding values
(P50% bar) were obtained: p53C 3346, p53C Y220C 2217, p53C HM 3943,
and p63C 4326. Molecular dynamics (MD) simulations revealed that p53C
Y220C was most prone to water infiltration, followed by p53C, whereas
the interiors of p53C HM and p63C remained comparably dry. A strong
correlation (r2 = 0.92) between P50% and
extent of interior hydration was observed. The pathways of individual
water molecule entry and exit were mapped and analyzed, revealing
a common route preserved across the p53 family involving a previously
reported pocket, along with a novel surface cleft, both of which appear
to be targetable by small molecules. Potential determinants of propensity
to water incursion were assessed, including backbone hydrogen bond
protection and combined sequence and structure similarity. Collectively,
our results indicate that p53C has an intrinsic susceptibility to
water leakage, which is exacerbated in a structural class mutant,
suggesting that there may be a common avenue for rescuing p53 function.