The p53 protein has long been known to be a key protein associated with many cancers. Its main function is to suppress tumor formation in the body, and thus protect it from cancer development. However, p53 is considerably less stable compared to its two cousins, p63 and p73. Of the three proteins, p53 is the one that has deviated the most from its ancestral invertebrate version. All three proteins have a region in their sequences that is responsible for recognizing and binding to target gene sequences, called a DNA binding domain (DBD). Loss of p53 function, which in most cases is caused by destabilizing DBD mutations, is prone to aggregation and formation of amyloid fibrils, an outcome that may be explained by its high instability. Additionally, p53 aggregates have a prion-like behavior, in which p53 mutants highjack normal p53 molecules and convert them into the inactive amyloid form. Over 90% of p53 mutations leading to cancer development are in the DBD, making it an important target for new cancer therapies. However, the tendency of p53 to aggregate and form amyloids is an obstacle for developing new strategies. To gain a deeper understanding of the molecular features underlying p53 DBD stability, amyloid formation, and aggregation, a research group led by Jerson Lima Silva, Ph.D., at the Federal University of Rio de Janeiro, Brazil, used microsecond timescale molecular dynamics (MD) simulations, a computational method used for studying the precise movements of atoms over time. MD allows researchers to study biological processes at a level of detail that is difficult to obtain by conventional experiments, providing new insights into how proteins work and predicting the origins of malfunction.
Login Or Register To Read Full Story